luna-code/numpy · Datasets at Hugging Face

prompt stringlengths 123 92.3k	completion stringlengths 7 132	api stringlengths 9 35
import gym import numpy as np from itertools import product import matplotlib.pyplot as plt def print_policy(Q, env): """ This is a helper function to print a nice policy from the Q function""" moves = [u'←', u'↓',u'→', u'↑'] if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape policy = np.chararray(dims, unicode=True) policy[:] = ' ' for s in range(len(Q)): idx = np.unravel_index(s, dims) policy[idx] = moves[np.argmax(Q[s])] if env.desc[idx] in ['H', 'G']: policy[idx] = u'·' print('\n'.join([''.join([u'{:2}'.format(item) for item in row]) for row in policy])) def plot_V(Q, env): """ This is a helper function to plot the state values from the Q function""" fig = plt.figure() if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape V = np.zeros(dims) for s in range(len(Q)): idx = np.unravel_index(s, dims) V[idx] = np.max(Q[s]) if env.desc[idx] in ['H', 'G']: V[idx] = 0. plt.imshow(V, origin='upper', extent=[0,dims[0],0,dims[1]], vmin=.0, vmax=.6, cmap=plt.cm.RdYlGn, interpolation='none') for x, y in product(range(dims[0]), range(dims[1])): plt.text(y+0.5, dims[0]-x-0.5, '{:.3f}'.format(V[x,y]), horizontalalignment='center', verticalalignment='center') plt.xticks([]) plt.yticks([]) def plot_Q(Q, env): """ This is a helper function to plot the Q function """ from matplotlib import colors, patches fig = plt.figure() ax = fig.gca() if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape up = np.array([[0, 1], [0.5, 0.5], [1,1]]) down = np.array([[0, 0], [0.5, 0.5], [1,0]]) left = np.array([[0, 0], [0.5, 0.5], [0,1]]) right = np.array([[1, 0], [0.5, 0.5], [1,1]]) tri = [left, down, right, up] pos = [[0.2, 0.5], [0.5, 0.2], [0.8, 0.5], [0.5, 0.8]] cmap = plt.cm.RdYlGn norm = colors.Normalize(vmin=.0,vmax=.6) ax.imshow(np.zeros(dims), origin='upper', extent=[0,dims[0],0,dims[1]], vmin=.0, vmax=.6, cmap=cmap) ax.grid(which='major', color='black', linestyle='-', linewidth=2) for s in range(len(Q)): idx = np.unravel_index(s, dims) x, y = idx if env.desc[idx] in ['H', 'G']: ax.add_patch(patches.Rectangle((y, 3-x), 1, 1, color=cmap(.0))) plt.text(y+0.5, dims[0]-x-0.5, '{:.2f}'.format(.0), horizontalalignment='center', verticalalignment='center') continue for a in range(len(tri)): ax.add_patch(patches.Polygon(tri[a] + np.array([y, 3-x]), color=cmap(Q[s][a]))) plt.text(y+pos[a][0], dims[0]-1-x+pos[a][1], '{:.2f}'.format(Q[s][a]), horizontalalignment='center', verticalalignment='center', fontsize=9, fontweight=('bold' if Q[s][a] == np.max(Q[s]) else 'normal')) plt.xticks([]) plt.yticks([]) def choose_abs_greedy_action(state, Q, epsilon): action = None if np.random.uniform(0, 1) < epsilon: action = np.random.randint(env.action_space.n) else: action =	np.argmax(Q[state,:])	numpy.argmax
from abc import ABCMeta, abstractmethod import os from vmaf.tools.misc import make_absolute_path, run_process from vmaf.tools.stats import ListStats __copyright__ = "Copyright 2016-2018, Netflix, Inc." __license__ = "Apache, Version 2.0" import re import numpy as np import ast from vmaf import ExternalProgramCaller, to_list from vmaf.config import VmafConfig, VmafExternalConfig from vmaf.core.executor import Executor from vmaf.core.result import Result from vmaf.tools.reader import YuvReader class FeatureExtractor(Executor): """ FeatureExtractor takes in a list of assets, and run feature extraction on them, and return a list of corresponding results. A FeatureExtractor must specify a unique type and version combination (by the TYPE and VERSION attribute), so that the Result generated by it can be identified. A derived class of FeatureExtractor must: 1) Override TYPE and VERSION 2) Override _generate_result(self, asset), which call a command-line executable and generate feature scores in a log file. 3) Override _get_feature_scores(self, asset), which read the feature scores from the log file, and return the scores in a dictionary format. For an example, follow VmafFeatureExtractor. """ __metaclass__ = ABCMeta @property @abstractmethod def ATOM_FEATURES(self): raise NotImplementedError def _read_result(self, asset): result = {} result.update(self._get_feature_scores(asset)) executor_id = self.executor_id return Result(asset, executor_id, result) @classmethod def get_scores_key(cls, atom_feature): return "{type}_{atom_feature}_scores".format( type=cls.TYPE, atom_feature=atom_feature) @classmethod def get_score_key(cls, atom_feature): return "{type}_{atom_feature}_score".format( type=cls.TYPE, atom_feature=atom_feature) def _get_feature_scores(self, asset): # routine to read the feature scores from the log file, and return # the scores in a dictionary format. log_file_path = self._get_log_file_path(asset) atom_feature_scores_dict = {} atom_feature_idx_dict = {} for atom_feature in self.ATOM_FEATURES: atom_feature_scores_dict[atom_feature] = [] atom_feature_idx_dict[atom_feature] = 0 with open(log_file_path, 'rt') as log_file: for line in log_file.readlines(): for atom_feature in self.ATOM_FEATURES: re_template = "{af}: ([0-9]+) ([a-zA-Z0-9.-]+)".format(af=atom_feature) mo = re.match(re_template, line) if mo: cur_idx = int(mo.group(1)) assert cur_idx == atom_feature_idx_dict[atom_feature] # parse value, allowing NaN and inf val = float(mo.group(2)) if np.isnan(val) or np.isinf(val): val = None atom_feature_scores_dict[atom_feature].append(val) atom_feature_idx_dict[atom_feature] += 1 continue len_score = len(atom_feature_scores_dict[self.ATOM_FEATURES[0]]) assert len_score != 0 for atom_feature in self.ATOM_FEATURES[1:]: assert len_score == len(atom_feature_scores_dict[atom_feature]), \ "Feature data possibly corrupt. Run cleanup script and try again." feature_result = {} for atom_feature in self.ATOM_FEATURES: scores_key = self.get_scores_key(atom_feature) feature_result[scores_key] = atom_feature_scores_dict[atom_feature] return feature_result class VmafFeatureExtractor(FeatureExtractor): TYPE = "VMAF_feature" # VERSION = '0.1' # vmaf_study; Anush's VIF fix # VERSION = '0.2' # expose vif_num, vif_den, adm_num, adm_den, anpsnr # VERSION = '0.2.1' # expose vif num/den of each scale # VERSION = '0.2.2' # adm abs-->fabs, corrected border handling, uniform reading with option of offset for input YUV, updated VIF corner case # VERSION = '0.2.2b' # expose adm_den/num_scalex # VERSION = '0.2.3' # AVX for VMAF convolution; update adm features by folding noise floor into per coef # VERSION = '0.2.4' # Fix a bug in adm feature passing scale into dwt_quant_step # VERSION = '0.2.4b' # Modify by adding ADM noise floor outside cube root; add derived feature motion2 VERSION = '0.2.4c' # Modify by moving motion2 to c code ATOM_FEATURES = ['vif', 'adm', 'ansnr', 'motion', 'motion2', 'vif_num', 'vif_den', 'adm_num', 'adm_den', 'anpsnr', 'vif_num_scale0', 'vif_den_scale0', 'vif_num_scale1', 'vif_den_scale1', 'vif_num_scale2', 'vif_den_scale2', 'vif_num_scale3', 'vif_den_scale3', 'adm_num_scale0', 'adm_den_scale0', 'adm_num_scale1', 'adm_den_scale1', 'adm_num_scale2', 'adm_den_scale2', 'adm_num_scale3', 'adm_den_scale3', ] DERIVED_ATOM_FEATURES = ['vif_scale0', 'vif_scale1', 'vif_scale2', 'vif_scale3', 'vif2', 'adm2', 'adm3', 'adm_scale0', 'adm_scale1', 'adm_scale2', 'adm_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vmaf_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VmafFeatureExtractor, cls)._post_process_result(result) # adm2 = # (adm_num + ADM2_CONSTANT) / (adm_den + ADM2_CONSTANT) adm2_scores_key = cls.get_scores_key('adm2') adm_num_scores_key = cls.get_scores_key('adm_num') adm_den_scores_key = cls.get_scores_key('adm_den') result.result_dict[adm2_scores_key] = list( (np.array(result.result_dict[adm_num_scores_key]) + cls.ADM2_CONSTANT) / (np.array(result.result_dict[adm_den_scores_key]) + cls.ADM2_CONSTANT) ) # vif_scalei = vif_num_scalei / vif_den_scalei, i = 0, 1, 2, 3 vif_num_scale0_scores_key = cls.get_scores_key('vif_num_scale0') vif_den_scale0_scores_key = cls.get_scores_key('vif_den_scale0') vif_num_scale1_scores_key = cls.get_scores_key('vif_num_scale1') vif_den_scale1_scores_key = cls.get_scores_key('vif_den_scale1') vif_num_scale2_scores_key = cls.get_scores_key('vif_num_scale2') vif_den_scale2_scores_key = cls.get_scores_key('vif_den_scale2') vif_num_scale3_scores_key = cls.get_scores_key('vif_num_scale3') vif_den_scale3_scores_key = cls.get_scores_key('vif_den_scale3') vif_scale0_scores_key = cls.get_scores_key('vif_scale0') vif_scale1_scores_key = cls.get_scores_key('vif_scale1') vif_scale2_scores_key = cls.get_scores_key('vif_scale2') vif_scale3_scores_key = cls.get_scores_key('vif_scale3') result.result_dict[vif_scale0_scores_key] = list( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) ) result.result_dict[vif_scale1_scores_key] = list( (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) ) result.result_dict[vif_scale2_scores_key] = list( (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) ) result.result_dict[vif_scale3_scores_key] = list( (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) # vif2 = # ((vif_num_scale0 / vif_den_scale0) + (vif_num_scale1 / vif_den_scale1) + # (vif_num_scale2 / vif_den_scale2) + (vif_num_scale3 / vif_den_scale3)) / 4.0 vif_scores_key = cls.get_scores_key('vif2') result.result_dict[vif_scores_key] = list( ( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) + (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) + (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) + (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) / 4.0 ) # adm_scalei = adm_num_scalei / adm_den_scalei, i = 0, 1, 2, 3 adm_num_scale0_scores_key = cls.get_scores_key('adm_num_scale0') adm_den_scale0_scores_key = cls.get_scores_key('adm_den_scale0') adm_num_scale1_scores_key = cls.get_scores_key('adm_num_scale1') adm_den_scale1_scores_key = cls.get_scores_key('adm_den_scale1') adm_num_scale2_scores_key = cls.get_scores_key('adm_num_scale2') adm_den_scale2_scores_key = cls.get_scores_key('adm_den_scale2') adm_num_scale3_scores_key = cls.get_scores_key('adm_num_scale3') adm_den_scale3_scores_key = cls.get_scores_key('adm_den_scale3') adm_scale0_scores_key = cls.get_scores_key('adm_scale0') adm_scale1_scores_key = cls.get_scores_key('adm_scale1') adm_scale2_scores_key = cls.get_scores_key('adm_scale2') adm_scale3_scores_key = cls.get_scores_key('adm_scale3') result.result_dict[adm_scale0_scores_key] = list( (np.array(result.result_dict[adm_num_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale1_scores_key] = list( (np.array(result.result_dict[adm_num_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale2_scores_key] = list( (np.array(result.result_dict[adm_num_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale3_scores_key] = list( (np.array(result.result_dict[adm_num_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) ) # adm3 = \ # (((adm_num_scale0 + ADM_SCALE_CONSTANT) / (adm_den_scale0 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale1 + ADM_SCALE_CONSTANT) / (adm_den_scale1 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale2 + ADM_SCALE_CONSTANT) / (adm_den_scale2 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale3 + ADM_SCALE_CONSTANT) / (adm_den_scale3 + ADM_SCALE_CONSTANT))) / 4.0 adm3_scores_key = cls.get_scores_key('adm3') result.result_dict[adm3_scores_key] = list( ( ((np.array(result.result_dict[adm_num_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT)) ) / 4.0 ) # validate for feature in cls.DERIVED_ATOM_FEATURES: assert cls.get_scores_key(feature) in result.result_dict return result class VifFrameDifferenceFeatureExtractor(FeatureExtractor): TYPE = "VifDiff_feature" VERSION = '0.1' ATOM_FEATURES = ['vifdiff', 'vifdiff_num', 'vifdiff_den', 'vifdiff_num_scale0', 'vifdiff_den_scale0', 'vifdiff_num_scale1', 'vifdiff_den_scale1', 'vifdiff_num_scale2', 'vifdiff_den_scale2', 'vifdiff_num_scale3', 'vifdiff_den_scale3', ] DERIVED_ATOM_FEATURES = ['vifdiff_scale0', 'vifdiff_scale1', 'vifdiff_scale2', 'vifdiff_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vifdiff_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VifFrameDifferenceFeatureExtractor, cls)._post_process_result(result) # vifdiff_scalei = vifdiff_num_scalei / vifdiff_den_scalei, i = 0, 1, 2, 3 vifdiff_num_scale0_scores_key = cls.get_scores_key('vifdiff_num_scale0') vifdiff_den_scale0_scores_key = cls.get_scores_key('vifdiff_den_scale0') vifdiff_num_scale1_scores_key = cls.get_scores_key('vifdiff_num_scale1') vifdiff_den_scale1_scores_key = cls.get_scores_key('vifdiff_den_scale1') vifdiff_num_scale2_scores_key = cls.get_scores_key('vifdiff_num_scale2') vifdiff_den_scale2_scores_key = cls.get_scores_key('vifdiff_den_scale2') vifdiff_num_scale3_scores_key = cls.get_scores_key('vifdiff_num_scale3') vifdiff_den_scale3_scores_key = cls.get_scores_key('vifdiff_den_scale3') vifdiff_scale0_scores_key = cls.get_scores_key('vifdiff_scale0') vifdiff_scale1_scores_key = cls.get_scores_key('vifdiff_scale1') vifdiff_scale2_scores_key = cls.get_scores_key('vifdiff_scale2') vifdiff_scale3_scores_key = cls.get_scores_key('vifdiff_scale3') result.result_dict[vifdiff_scale0_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale0_scores_key]) / np.array(result.result_dict[vifdiff_den_scale0_scores_key])) ) result.result_dict[vifdiff_scale1_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale1_scores_key]) / np.array(result.result_dict[vifdiff_den_scale1_scores_key])) ) result.result_dict[vifdiff_scale2_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale2_scores_key]) / np.array(result.result_dict[vifdiff_den_scale2_scores_key])) ) result.result_dict[vifdiff_scale3_scores_key] = list( (	np.array(result.result_dict[vifdiff_num_scale3_scores_key])	numpy.array
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] *	np.ones(101)	numpy.ones
import numpy as np import pytest import theano import theano.tensor as tt # Don't import test classes otherwise they get tested as part of the file from tests import unittest_tools as utt from tests.gpuarray.config import mode_with_gpu, mode_without_gpu, test_ctx_name from tests.tensor.test_basic import ( TestAlloc, TestComparison, TestJoinAndSplit, TestReshape, ) from tests.tensor.utils import rand, safe_make_node from theano.gpuarray.basic_ops import ( GpuAlloc, GpuAllocEmpty, GpuContiguous, GpuEye, GpuFromHost, GpuJoin, GpuReshape, GpuSplit, GpuToGpu, GpuTri, HostFromGpu, gpu_contiguous, gpu_join, host_from_gpu, ) from theano.gpuarray.elemwise import GpuDimShuffle, GpuElemwise from theano.gpuarray.subtensor import GpuSubtensor from theano.gpuarray.type import GpuArrayType, get_context, gpuarray_shared_constructor from theano.tensor import TensorType from theano.tensor.basic import alloc pygpu = pytest.importorskip("pygpu") gpuarray = pygpu.gpuarray utt.seed_rng() rng = np.random.RandomState(seed=utt.fetch_seed()) def inplace_func( inputs, outputs, mode=None, allow_input_downcast=False, on_unused_input="raise", name=None, ): if mode is None: mode = mode_with_gpu return theano.function( inputs, outputs, mode=mode, allow_input_downcast=allow_input_downcast, accept_inplace=True, on_unused_input=on_unused_input, name=name, ) def fake_shared(value, name=None, strict=False, allow_downcast=None, kwargs): from theano.tensor.sharedvar import scalar_constructor, tensor_constructor for c in (gpuarray_shared_constructor, tensor_constructor, scalar_constructor): try: return c( value, name=name, strict=strict, allow_downcast=allow_downcast, kwargs ) except TypeError: continue def rand_gpuarray(shape, kwargs): r = rng.rand(shape) * 2 - 1 dtype = kwargs.pop("dtype", theano.config.floatX) cls = kwargs.pop("cls", None) if len(kwargs) != 0: raise TypeError("Unexpected argument %s", list(kwargs.keys())[0]) return gpuarray.array(r, dtype=dtype, cls=cls, context=get_context(test_ctx_name)) def makeTester( name, op, gpu_op, cases, checks=None, mode_gpu=mode_with_gpu, mode_nogpu=mode_without_gpu, skip=False, eps=1e-10, ): if checks is None: checks = {} _op = op _gpu_op = gpu_op _cases = cases _skip = skip _checks = checks class Checker(utt.OptimizationTestMixin): op = staticmethod(_op) gpu_op = staticmethod(_gpu_op) cases = _cases skip = _skip checks = _checks def setup_method(self): eval(self.__class__.__module__ + "." + self.__class__.__name__) def test_all(self): if skip: pytest.skip(skip) for testname, inputs in cases.items(): for _ in range(len(inputs)): if type(inputs[_]) is float: inputs[_] = np.asarray(inputs[_], dtype=theano.config.floatX) self.run_case(testname, inputs) def run_case(self, testname, inputs): inputs_ref = [theano.shared(inp) for inp in inputs] inputs_tst = [theano.shared(inp) for inp in inputs] try: node_ref = safe_make_node(self.op, inputs_ref) node_tst = safe_make_node(self.op, inputs_tst) except Exception as exc: err_msg = ( "Test %s::%s: Error occurred while making " "a node with inputs %s" ) % (self.gpu_op, testname, inputs) exc.args += (err_msg,) raise try: f_ref = inplace_func([], node_ref.outputs, mode=mode_nogpu) f_tst = inplace_func([], node_tst.outputs, mode=mode_gpu) except Exception as exc: err_msg = ( "Test %s::%s: Error occurred while trying to " "make a Function" ) % (self.gpu_op, testname) exc.args += (err_msg,) raise self.assertFunctionContains1(f_tst, self.gpu_op) ref_e = None try: expecteds = f_ref() except Exception as exc: ref_e = exc try: variables = f_tst() except Exception as exc: if ref_e is None: err_msg = ( "Test %s::%s: exception when calling the " "Function" ) % (self.gpu_op, testname) exc.args += (err_msg,) raise else: # if we raised an exception of the same type we're good. if isinstance(exc, type(ref_e)): return else: err_msg = ( "Test %s::%s: exception raised during test " "call was not the same as the reference " "call (got: %s, expected %s)" % (self.gpu_op, testname, type(exc), type(ref_e)) ) exc.args += (err_msg,) raise for i, (variable, expected) in enumerate(zip(variables, expecteds)): condition = ( variable.dtype != expected.dtype or variable.shape != expected.shape or not TensorType.values_eq_approx(variable, expected) ) assert not condition, ( "Test %s::%s: Output %s gave the wrong " "value. With inputs %s, expected %s " "(dtype %s), got %s (dtype %s)." % ( self.op, testname, i, inputs, expected, expected.dtype, variable, variable.dtype, ) ) for description, check in self.checks.items(): assert check(inputs, variables), ( "Test %s::%s: Failed check: %s " "(inputs were %s, ouputs were %s)" ) % (self.op, testname, description, inputs, variables) Checker.__name__ = name if hasattr(Checker, "__qualname__"): Checker.__qualname__ = name return Checker def test_transfer_cpu_gpu(): a = tt.fmatrix("a") g = GpuArrayType(dtype="float32", broadcastable=(False, False))("g") av = np.asarray(rng.rand(5, 4), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) f = theano.function([a], GpuFromHost(test_ctx_name)(a)) fv = f(av) assert GpuArrayType.values_eq(fv, gv) f = theano.function([g], host_from_gpu(g)) fv = f(gv) assert np.all(fv == av) def test_transfer_gpu_gpu(): g = GpuArrayType( dtype="float32", broadcastable=(False, False), context_name=test_ctx_name )() av = np.asarray(rng.rand(5, 4), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) mode = mode_with_gpu.excluding( "cut_gpua_host_transfers", "local_cut_gpua_host_gpua" ) f = theano.function([g], GpuToGpu(test_ctx_name)(g), mode=mode) topo = f.maker.fgraph.toposort() assert len(topo) == 1 assert isinstance(topo[0].op, GpuToGpu) fv = f(gv) assert GpuArrayType.values_eq(fv, gv) def test_transfer_strided(): # This is just to ensure that it works in theano # libgpuarray has a much more comprehensive suit of tests to # ensure correctness a = tt.fmatrix("a") g = GpuArrayType(dtype="float32", broadcastable=(False, False))("g") av = np.asarray(rng.rand(5, 8), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) av = av[:, ::2] gv = gv[:, ::2] f = theano.function([a], GpuFromHost(test_ctx_name)(a)) fv = f(av) assert GpuArrayType.values_eq(fv, gv) f = theano.function([g], host_from_gpu(g)) fv = f(gv) assert np.all(fv == av) def gpu_alloc_expected(x, shp): g = gpuarray.empty(shp, dtype=x.dtype, context=get_context(test_ctx_name)) g[:] = x return g TestGpuAlloc = makeTester( name="GpuAllocTester", # The +1 is there to allow the lift to the GPU. op=lambda args: alloc(*args) + 1, gpu_op=GpuAlloc(test_ctx_name), cases=dict( correct01=(rand(), np.int32(7)), # just gives a DeepCopyOp with possibly wrong results on the CPU # correct01_bcast=(rand(1), np.int32(7)), correct02=(rand(), np.int32(4), np.int32(7)), correct12=(rand(7), np.int32(4), np.int32(7)), correct13=(rand(7), np.int32(2), np.int32(4), np.int32(7)), correct23=(rand(4, 7),	np.int32(2)	numpy.int32
import numpy as np import pytest import theano import theano.tensor as tt # Don't import test classes otherwise they get tested as part of the file from tests import unittest_tools as utt from tests.gpuarray.config import mode_with_gpu, mode_without_gpu, test_ctx_name from tests.tensor.test_basic import ( TestAlloc, TestComparison, TestJoinAndSplit, TestReshape, ) from tests.tensor.utils import rand, safe_make_node from theano.gpuarray.basic_ops import ( GpuAlloc, GpuAllocEmpty, GpuContiguous, GpuEye, GpuFromHost, GpuJoin, GpuReshape, GpuSplit, GpuToGpu, GpuTri, HostFromGpu, gpu_contiguous, gpu_join, host_from_gpu, ) from theano.gpuarray.elemwise import GpuDimShuffle, GpuElemwise from theano.gpuarray.subtensor import GpuSubtensor from theano.gpuarray.type import GpuArrayType, get_context, gpuarray_shared_constructor from theano.tensor import TensorType from theano.tensor.basic import alloc pygpu = pytest.importorskip("pygpu") gpuarray = pygpu.gpuarray utt.seed_rng() rng = np.random.RandomState(seed=utt.fetch_seed()) def inplace_func( inputs, outputs, mode=None, allow_input_downcast=False, on_unused_input="raise", name=None, ): if mode is None: mode = mode_with_gpu return theano.function( inputs, outputs, mode=mode, allow_input_downcast=allow_input_downcast, accept_inplace=True, on_unused_input=on_unused_input, name=name, ) def fake_shared(value, name=None, strict=False, allow_downcast=None, kwargs): from theano.tensor.sharedvar import scalar_constructor, tensor_constructor for c in (gpuarray_shared_constructor, tensor_constructor, scalar_constructor): try: return c( value, name=name, strict=strict, allow_downcast=allow_downcast, kwargs ) except TypeError: continue def rand_gpuarray(shape, kwargs): r = rng.rand(shape) * 2 - 1 dtype = kwargs.pop("dtype", theano.config.floatX) cls = kwargs.pop("cls", None) if len(kwargs) != 0: raise TypeError("Unexpected argument %s", list(kwargs.keys())[0]) return gpuarray.array(r, dtype=dtype, cls=cls, context=get_context(test_ctx_name)) def makeTester( name, op, gpu_op, cases, checks=None, mode_gpu=mode_with_gpu, mode_nogpu=mode_without_gpu, skip=False, eps=1e-10, ): if checks is None: checks = {} _op = op _gpu_op = gpu_op _cases = cases _skip = skip _checks = checks class Checker(utt.OptimizationTestMixin): op = staticmethod(_op) gpu_op = staticmethod(_gpu_op) cases = _cases skip = _skip checks = _checks def setup_method(self): eval(self.__class__.__module__ + "." + self.__class__.__name__) def test_all(self): if skip: pytest.skip(skip) for testname, inputs in cases.items(): for _ in range(len(inputs)): if type(inputs[_]) is float: inputs[_] = np.asarray(inputs[_], dtype=theano.config.floatX) self.run_case(testname, inputs) def run_case(self, testname, inputs): inputs_ref = [theano.shared(inp) for inp in inputs] inputs_tst = [theano.shared(inp) for inp in inputs] try: node_ref = safe_make_node(self.op, inputs_ref) node_tst = safe_make_node(self.op, inputs_tst) except Exception as exc: err_msg = ( "Test %s::%s: Error occurred while making " "a node with inputs %s" ) % (self.gpu_op, testname, inputs) exc.args += (err_msg,) raise try: f_ref = inplace_func([], node_ref.outputs, mode=mode_nogpu) f_tst = inplace_func([], node_tst.outputs, mode=mode_gpu) except Exception as exc: err_msg = ( "Test %s::%s: Error occurred while trying to " "make a Function" ) % (self.gpu_op, testname) exc.args += (err_msg,) raise self.assertFunctionContains1(f_tst, self.gpu_op) ref_e = None try: expecteds = f_ref() except Exception as exc: ref_e = exc try: variables = f_tst() except Exception as exc: if ref_e is None: err_msg = ( "Test %s::%s: exception when calling the " "Function" ) % (self.gpu_op, testname) exc.args += (err_msg,) raise else: # if we raised an exception of the same type we're good. if isinstance(exc, type(ref_e)): return else: err_msg = ( "Test %s::%s: exception raised during test " "call was not the same as the reference " "call (got: %s, expected %s)" % (self.gpu_op, testname, type(exc), type(ref_e)) ) exc.args += (err_msg,) raise for i, (variable, expected) in enumerate(zip(variables, expecteds)): condition = ( variable.dtype != expected.dtype or variable.shape != expected.shape or not TensorType.values_eq_approx(variable, expected) ) assert not condition, ( "Test %s::%s: Output %s gave the wrong " "value. With inputs %s, expected %s " "(dtype %s), got %s (dtype %s)." % ( self.op, testname, i, inputs, expected, expected.dtype, variable, variable.dtype, ) ) for description, check in self.checks.items(): assert check(inputs, variables), ( "Test %s::%s: Failed check: %s " "(inputs were %s, ouputs were %s)" ) % (self.op, testname, description, inputs, variables) Checker.__name__ = name if hasattr(Checker, "__qualname__"): Checker.__qualname__ = name return Checker def test_transfer_cpu_gpu(): a = tt.fmatrix("a") g = GpuArrayType(dtype="float32", broadcastable=(False, False))("g") av = np.asarray(rng.rand(5, 4), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) f = theano.function([a], GpuFromHost(test_ctx_name)(a)) fv = f(av) assert GpuArrayType.values_eq(fv, gv) f = theano.function([g], host_from_gpu(g)) fv = f(gv) assert np.all(fv == av) def test_transfer_gpu_gpu(): g = GpuArrayType( dtype="float32", broadcastable=(False, False), context_name=test_ctx_name )() av = np.asarray(rng.rand(5, 4), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) mode = mode_with_gpu.excluding( "cut_gpua_host_transfers", "local_cut_gpua_host_gpua" ) f = theano.function([g], GpuToGpu(test_ctx_name)(g), mode=mode) topo = f.maker.fgraph.toposort() assert len(topo) == 1 assert isinstance(topo[0].op, GpuToGpu) fv = f(gv) assert GpuArrayType.values_eq(fv, gv) def test_transfer_strided(): # This is just to ensure that it works in theano # libgpuarray has a much more comprehensive suit of tests to # ensure correctness a = tt.fmatrix("a") g = GpuArrayType(dtype="float32", broadcastable=(False, False))("g") av = np.asarray(rng.rand(5, 8), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) av = av[:, ::2] gv = gv[:, ::2] f = theano.function([a], GpuFromHost(test_ctx_name)(a)) fv = f(av) assert GpuArrayType.values_eq(fv, gv) f = theano.function([g], host_from_gpu(g)) fv = f(gv) assert np.all(fv == av) def gpu_alloc_expected(x, shp): g = gpuarray.empty(shp, dtype=x.dtype, context=get_context(test_ctx_name)) g[:] = x return g TestGpuAlloc = makeTester( name="GpuAllocTester", # The +1 is there to allow the lift to the GPU. op=lambda args: alloc(*args) + 1, gpu_op=GpuAlloc(test_ctx_name), cases=dict( correct01=(rand(), np.int32(7)), # just gives a DeepCopyOp with possibly wrong results on the CPU # correct01_bcast=(rand(1), np.int32(7)), correct02=(rand(), np.int32(4), np.int32(7)), correct12=(rand(7), np.int32(4),	np.int32(7)	numpy.int32
# pvtrace is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 3 of the License, or # (at your option) any later version. # # pvtrace is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see <http://www.gnu.org/licenses/>. import numpy as np from external.transformations import translation_matrix, rotation_matrix import external.transformations as tf from Trace import Photon from Geometry import Box, Cylinder, FinitePlane, transform_point, transform_direction, rotation_matrix_from_vector_alignment, norm from Materials import Spectrum def random_spherecial_vector(): # This method of calculating isotropic vectors is taken from GNU Scientific Library LOOP = True while LOOP: x = -1. + 2. * np.random.uniform() y = -1. + 2. * np.random.uniform() s = x2 + y2 if s <= 1.0: LOOP = False z = -1. + 2. * s a = 2 * np.sqrt(1 - s) x = a * x y = a * y return np.array([x,y,z]) class SimpleSource(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, use_random_polarisation=False): super(SimpleSource, self).__init__() self.position = position self.direction = direction self.wavelength = wavelength self.use_random_polarisation = use_random_polarisation self.throw = 0 self.source_id = "SimpleSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength # If use_polarisation is set generate a random polarisation vector of the photon if self.use_random_polarisation: # Randomise rotation angle around xy-plane, the transform from +z to the direction of the photon vec = random_spherecial_vector() vec[2] = 0. vec = norm(vec) R = rotation_matrix_from_vector_alignment(self.direction, [0,0,1]) photon.polarisation = transform_direction(vec, R) else: photon.polarisation = None photon.id = self.throw self.throw = self.throw + 1 return photon class Laser(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, polarisation=None): super(Laser, self).__init__() self.position = np.array(position) self.direction = np.array(direction) self.wavelength = wavelength assert polarisation != None, "Polarisation of the Laser is not set." self.polarisation = np.array(polarisation) self.throw = 0 self.source_id = "LaserSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength photon.polarisation = self.polarisation photon.id = self.throw self.throw = self.throw + 1 return photon class PlanarSource(object): """A box that emits photons from the top surface (normal), sampled from the spectrum.""" def __init__(self, spectrum=None, wavelength=555, direction=(0,0,1), length=0.05, width=0.05): super(PlanarSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.plane = FinitePlane(length=length, width=width) self.length = length self.width = width # direction is the direction that photons are fired out of the plane in the GLOBAL FRAME. # i.e. this is passed directly to the photon to set is's direction self.direction = direction self.throw = 0 self.source_id = "PlanarSource_" + str(id(self)) def translate(self, translation): self.plane.append_transform(tf.translation_matrix(translation)) def rotate(self, angle, axis): self.plane.append_transform(tf.rotation_matrix(angle, axis)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Create a point which is on the surface of the finite plane in it's local frame x = np.random.uniform(0., self.length) y = np.random.uniform(0., self.width) local_point = (x, y, 0.) # Transform the direciton photon.position = transform_point(local_point, self.plane.transform) photon.direction = self.direction photon.active = True if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class LensSource(object): """ A source where photons generated in a plane are focused on a line with space tolerance given by variable "focussize". The focus line should be perpendicular to the plane normal and aligned with the z-axis. """ def __init__(self, spectrum = None, wavelength = 555, linepoint=(0,0,0), linedirection=(0,0,1), focussize = 0, planeorigin = (-1,-1,-1), planeextent = (-1,1,1)): super(LensSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.planeorigin = planeorigin self.planeextent = planeextent self.linepoint = np.array(linepoint) self.linedirection = np.array(linedirection) self.focussize = focussize self.throw = 0 self.source_id = "LensSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Position x = np.random.uniform(self.planeorigin[0],self.planeextent[0]) y = np.random.uniform(self.planeorigin[1],self.planeextent[1]) z =	np.random.uniform(self.planeorigin[2],self.planeextent[2])	numpy.random.uniform
# pvtrace is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 3 of the License, or # (at your option) any later version. # # pvtrace is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see <http://www.gnu.org/licenses/>. import numpy as np from external.transformations import translation_matrix, rotation_matrix import external.transformations as tf from Trace import Photon from Geometry import Box, Cylinder, FinitePlane, transform_point, transform_direction, rotation_matrix_from_vector_alignment, norm from Materials import Spectrum def random_spherecial_vector(): # This method of calculating isotropic vectors is taken from GNU Scientific Library LOOP = True while LOOP: x = -1. + 2. * np.random.uniform() y = -1. + 2. * np.random.uniform() s = x2 + y2 if s <= 1.0: LOOP = False z = -1. + 2. * s a = 2 * np.sqrt(1 - s) x = a * x y = a * y return np.array([x,y,z]) class SimpleSource(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, use_random_polarisation=False): super(SimpleSource, self).__init__() self.position = position self.direction = direction self.wavelength = wavelength self.use_random_polarisation = use_random_polarisation self.throw = 0 self.source_id = "SimpleSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength # If use_polarisation is set generate a random polarisation vector of the photon if self.use_random_polarisation: # Randomise rotation angle around xy-plane, the transform from +z to the direction of the photon vec = random_spherecial_vector() vec[2] = 0. vec = norm(vec) R = rotation_matrix_from_vector_alignment(self.direction, [0,0,1]) photon.polarisation = transform_direction(vec, R) else: photon.polarisation = None photon.id = self.throw self.throw = self.throw + 1 return photon class Laser(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, polarisation=None): super(Laser, self).__init__() self.position = np.array(position) self.direction = np.array(direction) self.wavelength = wavelength assert polarisation != None, "Polarisation of the Laser is not set." self.polarisation = np.array(polarisation) self.throw = 0 self.source_id = "LaserSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength photon.polarisation = self.polarisation photon.id = self.throw self.throw = self.throw + 1 return photon class PlanarSource(object): """A box that emits photons from the top surface (normal), sampled from the spectrum.""" def __init__(self, spectrum=None, wavelength=555, direction=(0,0,1), length=0.05, width=0.05): super(PlanarSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.plane = FinitePlane(length=length, width=width) self.length = length self.width = width # direction is the direction that photons are fired out of the plane in the GLOBAL FRAME. # i.e. this is passed directly to the photon to set is's direction self.direction = direction self.throw = 0 self.source_id = "PlanarSource_" + str(id(self)) def translate(self, translation): self.plane.append_transform(tf.translation_matrix(translation)) def rotate(self, angle, axis): self.plane.append_transform(tf.rotation_matrix(angle, axis)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Create a point which is on the surface of the finite plane in it's local frame x = np.random.uniform(0., self.length) y = np.random.uniform(0., self.width) local_point = (x, y, 0.) # Transform the direciton photon.position = transform_point(local_point, self.plane.transform) photon.direction = self.direction photon.active = True if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class LensSource(object): """ A source where photons generated in a plane are focused on a line with space tolerance given by variable "focussize". The focus line should be perpendicular to the plane normal and aligned with the z-axis. """ def __init__(self, spectrum = None, wavelength = 555, linepoint=(0,0,0), linedirection=(0,0,1), focussize = 0, planeorigin = (-1,-1,-1), planeextent = (-1,1,1)): super(LensSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.planeorigin = planeorigin self.planeextent = planeextent self.linepoint = np.array(linepoint) self.linedirection = np.array(linedirection) self.focussize = focussize self.throw = 0 self.source_id = "LensSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Position x = np.random.uniform(self.planeorigin[0],self.planeextent[0]) y = np.random.uniform(self.planeorigin[1],self.planeextent[1]) z = np.random.uniform(self.planeorigin[2],self.planeextent[2]) photon.position = np.array((x,y,z)) # Direction focuspoint = np.array((0.,0.,0.)) focuspoint[0] = self.linepoint[0] + np.random.uniform(-self.focussize,self.focussize) focuspoint[1] = self.linepoint[1] + np.random.uniform(-self.focussize,self.focussize) focuspoint[2] = photon.position[2] direction = focuspoint - photon.position modulus = (direction[0]2+direction[1]2+direction[2]2)0.5 photon.direction = direction/modulus # Wavelength if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class LensSourceAngle(object): """ A source where photons generated in a plane are focused on a line with space tolerance given by variable "focussize". The focus line should be perpendicular to the plane normal and aligned with the z-axis. For this lense an additional z-boost is added (Angle of incidence in z-direction). """ def __init__(self, spectrum = None, wavelength = 555, linepoint=(0,0,0), linedirection=(0,0,1), angle = 0, focussize = 0, planeorigin = (-1,-1,-1), planeextent = (-1,1,1)): super(LensSourceAngle, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.planeorigin = planeorigin self.planeextent = planeextent self.linepoint = np.array(linepoint) self.linedirection = np.array(linedirection) self.focussize = focussize self.angle = angle self.throw = 0 self.source_id = "LensSourceAngle_" + str(id(self)) def photon(self): photon = Photon() photon.id = self.throw self.throw = self.throw + 1 # Position x = np.random.uniform(self.planeorigin[0],self.planeextent[0]) y = np.random.uniform(self.planeorigin[1],self.planeextent[1]) boost = ynp.tan(self.angle) z = np.random.uniform(self.planeorigin[2],self.planeextent[2]) - boost photon.position = np.array((x,y,z)) # Direction focuspoint = np.array((0.,0.,0.)) focuspoint[0] = self.linepoint[0] + np.random.uniform(-self.focussize,self.focussize) focuspoint[1] = self.linepoint[1] + np.random.uniform(-self.focussize,self.focussize) focuspoint[2] = photon.position[2] + boost direction = focuspoint - photon.position modulus = (direction[0]2+direction[1]2+direction[2]2)0.5 photon.direction = direction/modulus # Wavelength if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class CylindricalSource(object): """ A source for photons emitted in a random direction and position inside a cylinder(radius, length) """ def __init__(self, spectrum = None, wavelength = 555, radius = 1, length = 10): super(CylindricalSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.shape = Cylinder(radius = radius, length = length) self.radius = radius self.length = length self.throw = 0 self.source_id = "CylindricalSource_" + str(id(self)) def translate(self, translation): self.shape.append_transform(tf.translation_matrix(translation)) def rotate(self, angle, axis): self.shape.append_transform(tf.rotation_matrix(angle, axis)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Position of emission phi = np.random.uniform(0., 2np.pi) r = np.random.uniform(0.,self.radius) x = rnp.cos(phi) y = rnp.sin(phi) z = np.random.uniform(0.,self.length) local_center = (x,y,z) photon.position = transform_point(local_center, self.shape.transform) # Direction of emission (no need to transform if meant to be isotropic) phi = np.random.uniform(0.,2np.pi) theta = np.random.uniform(0.,np.pi) x = np.cos(phi)np.sin(theta) y = np.sin(phi)np.sin(theta) z = np.cos(theta) local_direction = (x,y,z) photon.direction = local_direction # Set wavelength of photon if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength # Further initialisation photon.active = True return photon class PointSource(object): """ A point source that emits randomly in solid angle specified by phimin, ..., thetamax """ def __init__(self, spectrum = None, wavelength = 555, center = (0.,0.,0.), phimin = 0, phimax = 2np.pi, thetamin = 0, thetamax = np.pi): super(PointSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.center = center self.phimin = phimin self.phimax = phimax self.thetamin = thetamin self.thetamax = thetamax self.throw = 0 self.source_id = "PointSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 phi = np.random.uniform(self.phimin, self.phimax) theta =	np.random.uniform(self.thetamin, self.thetamax)	numpy.random.uniform
from __future__ import absolute_import from __future__ import division from __future__ import print_function import cntk as C import numpy as np from .common import floatx, epsilon, image_dim_ordering, image_data_format from collections import defaultdict from contextlib import contextmanager import warnings C.set_global_option('align_axis', 1) b_any = any dev = C.device.use_default_device() if dev.type() == 0: warnings.warn( 'CNTK backend warning: GPU is not detected. ' 'CNTK\'s CPU version is not fully optimized,' 'please run with GPU to get better performance.') # A learning phase is a bool tensor used to run Keras models in # either train mode (learning_phase == 1) or test mode (learning_phase == 0). # LEARNING_PHASE_PLACEHOLDER is the placeholder for dynamic learning phase _LEARNING_PHASE_PLACEHOLDER = C.constant(shape=(), dtype=np.float32, value=1.0, name='_keras_learning_phase') # static learning phase flag, if it is not 0 or 1, we will go with dynamic learning phase tensor. _LEARNING_PHASE = -1 _UID_PREFIXES = defaultdict(int) # cntk doesn't support gradient as symbolic op, to hook up with keras model, # we will create gradient as a constant placeholder, here use this global # map to keep the mapping from grad placeholder to parameter grad_parameter_dict = {} NAME_SCOPE_STACK = [] @contextmanager def name_scope(name): global NAME_SCOPE_STACK NAME_SCOPE_STACK.append(name) yield NAME_SCOPE_STACK.pop() def get_uid(prefix=''): _UID_PREFIXES[prefix] += 1 return _UID_PREFIXES[prefix] def learning_phase(): # If _LEARNING_PHASE is not 0 or 1, return dynamic learning phase tensor return _LEARNING_PHASE if _LEARNING_PHASE in {0, 1} else _LEARNING_PHASE_PLACEHOLDER def set_learning_phase(value): global _LEARNING_PHASE if value not in {0, 1}: raise ValueError('CNTK Backend: Set learning phase ' 'with value %s is not supported, ' 'expected 0 or 1.' % value) _LEARNING_PHASE = value def clear_session(): """Reset learning phase flag for cntk backend. """ global _LEARNING_PHASE global _LEARNING_PHASE_PLACEHOLDER _LEARNING_PHASE = -1 _LEARNING_PHASE_PLACEHOLDER.value = np.asarray(1.0) def in_train_phase(x, alt, training=None): global _LEARNING_PHASE if training is None: training = learning_phase() uses_learning_phase = True else: uses_learning_phase = False # CNTK currently don't support cond op, so here we use # element_select approach as workaround. It may have # perf issue, will resolve it later with cntk cond op. if callable(x) and isinstance(x, C.cntk_py.Function) is False: x = x() if callable(alt) and isinstance(alt, C.cntk_py.Function) is False: alt = alt() if training is True: x._uses_learning_phase = uses_learning_phase return x else: # if _LEARNING_PHASE is static if isinstance(training, int) or isinstance(training, bool): result = x if training == 1 or training is True else alt else: result = C.element_select(training, x, alt) result._uses_learning_phase = uses_learning_phase return result def in_test_phase(x, alt, training=None): return in_train_phase(alt, x, training=training) def _convert_string_dtype(dtype): # cntk only support float32 and float64 if dtype == 'float32': return np.float32 elif dtype == 'float64': return np.float64 else: # cntk only running with float, # try to cast to float to run the model return np.float32 def _convert_dtype_string(dtype): if dtype == np.float32: return 'float32' elif dtype == np.float64: return 'float64' else: raise ValueError('CNTK Backend: Unsupported dtype: %s. ' 'CNTK only supports float32 and ' 'float64.' % dtype) def variable(value, dtype=None, name=None, constraint=None): """Instantiates a variable and returns it. # Arguments value: Numpy array, initial value of the tensor. dtype: Tensor type. name: Optional name string for the tensor. constraint: Optional projection function to be applied to the variable after an optimizer update. # Returns A variable instance (with Keras metadata included). """ if dtype is None: dtype = floatx() if name is None: name = '' if isinstance( value, C.variables.Constant) or isinstance( value, C.variables.Parameter): value = value.value # we don't support init parameter with symbolic op, so eval it first as # workaround if isinstance(value, C.cntk_py.Function): value = eval(value) shape = value.shape if hasattr(value, 'shape') else () if hasattr(value, 'dtype') and value.dtype != dtype and len(shape) > 0: value = value.astype(dtype) # TODO: remove the conversion when cntk supports int32, int64 # https://docs.microsoft.com/en-us/python/api/cntk.variables.parameter dtype = 'float32' if 'int' in str(dtype) else dtype v = C.parameter(shape=shape, init=value, dtype=dtype, name=_prepare_name(name, 'variable')) v._keras_shape = v.shape v._uses_learning_phase = False v.constraint = constraint return v def bias_add(x, bias, data_format=None): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) dims = len(x.shape) if dims > 0 and x.shape[0] == C.InferredDimension: dims -= 1 bias_dims = len(bias.shape) if bias_dims != 1 and bias_dims != dims: raise ValueError('Unexpected bias dimensions %d, ' 'expected 1 or %d dimensions' % (bias_dims, dims)) if dims == 4: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1, 1, 1) else: shape = (bias.shape[3],) + bias.shape[:3] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, 1, 1, bias.shape[0]) else: shape = bias.shape elif dims == 3: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1, 1) else: shape = (bias.shape[2],) + bias.shape[:2] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, 1, bias.shape[0]) else: shape = bias.shape elif dims == 2: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1) else: shape = (bias.shape[1],) + bias.shape[:1] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, bias.shape[0]) else: shape = bias.shape else: shape = bias.shape return x + reshape(bias, shape) def eval(x): if isinstance(x, C.cntk_py.Function): return x.eval() elif isinstance(x, C.variables.Constant) or isinstance(x, C.variables.Parameter): return x.value else: raise ValueError('CNTK Backend: `eval` method on ' '`%s` type is not supported. ' 'CNTK only supports `eval` with ' '`Function`, `Constant` or ' '`Parameter`.' % type(x)) def placeholder( shape=None, ndim=None, dtype=None, sparse=False, name=None, dynamic_axis_num=1): if dtype is None: dtype = floatx() if not shape: if ndim: shape = tuple([None for _ in range(ndim)]) dynamic_dimension = C.FreeDimension if _get_cntk_version() >= 2.2 else C.InferredDimension cntk_shape = [dynamic_dimension if s is None else s for s in shape] cntk_shape = tuple(cntk_shape) if dynamic_axis_num > len(cntk_shape): raise ValueError('CNTK backend: creating placeholder with ' '%d dimension is not supported, at least ' '%d dimensions are needed.' % (len(cntk_shape, dynamic_axis_num))) if name is None: name = '' cntk_shape = cntk_shape[dynamic_axis_num:] x = C.input( shape=cntk_shape, dtype=_convert_string_dtype(dtype), is_sparse=sparse, name=name) x._keras_shape = shape x._uses_learning_phase = False x._cntk_placeholder = True return x def is_placeholder(x): """Returns whether `x` is a placeholder. # Arguments x: A candidate placeholder. # Returns Boolean. """ return hasattr(x, '_cntk_placeholder') and x._cntk_placeholder def is_keras_tensor(x): if not is_tensor(x): raise ValueError('Unexpectedly found an instance of type `' + str(type(x)) + '`. ' 'Expected a symbolic tensor instance.') return hasattr(x, '_keras_history') def is_tensor(x): return isinstance(x, (C.variables.Constant, C.variables.Variable, C.variables.Parameter, C.ops.functions.Function)) def shape(x): shape = list(int_shape(x)) num_dynamic = _get_dynamic_axis_num(x) non_dyn_shape = [] for i in range(len(x.shape)): if shape[i + num_dynamic] is None: non_dyn_shape.append(x.shape[i]) else: non_dyn_shape.append(shape[i + num_dynamic]) return shape[:num_dynamic] + non_dyn_shape def is_sparse(tensor): return tensor.is_sparse def int_shape(x): if hasattr(x, '_keras_shape'): return x._keras_shape shape = x.shape if hasattr(x, 'dynamic_axes'): dynamic_shape = [None for a in x.dynamic_axes] shape = tuple(dynamic_shape) + shape return shape def ndim(x): shape = int_shape(x) return len(shape) def _prepare_name(name, default): prefix = '_'.join(NAME_SCOPE_STACK) if name is None or name == '': return prefix + '/' + default return prefix + '/' + name def constant(value, dtype=None, shape=None, name=None): if dtype is None: dtype = floatx() if shape is None: shape = () np_value = value * np.ones(shape) const = C.constant(np_value, dtype=dtype, name=_prepare_name(name, 'constant')) const._keras_shape = const.shape const._uses_learning_phase = False return const def random_binomial(shape, p=0.0, dtype=None, seed=None): # use numpy workaround now if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed = np.random.randint(10e7) np.random.seed(seed) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) size = 1 for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') size *= _ binomial = np.random.binomial(1, p, size).astype(dtype).reshape(shape) return variable(value=binomial, dtype=dtype) def random_uniform(shape, minval=0.0, maxval=1.0, dtype=None, seed=None): for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') return random_uniform_variable(shape, minval, maxval, dtype, seed) def random_uniform_variable(shape, low, high, dtype=None, name=None, seed=None): if dtype is None: dtype = floatx() if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed =	np.random.randint(10e3)	numpy.random.randint
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series =	np.sin(knot_demonstrate_time)	numpy.sin
import pandas as pd import numpy as np import matplotlib.pyplot as plt import os import matplotlib.pyplot as plt import CurveFit import shutil #find all DIRECTORIES containing non-hidden files ending in FILENAME def getDataDirectories(DIRECTORY, FILENAME="valLoss.txt"): directories=[] for directory in os.scandir(DIRECTORY): for item in os.scandir(directory): if item.name.endswith(FILENAME) and not item.name.startswith("."): directories.append(directory.path) return directories #get all non-hidden data files in DIRECTORY with extension EXT def getDataFiles(DIRECTORY, EXT='txt'): datafiles=[] for item in os.scandir(DIRECTORY): if item.name.endswith("."+EXT) and not item.name.startswith("."): datafiles.append(item.path) return datafiles #checking if loss ever doesn't decrease for numEpochs epochs in a row. def stopsDecreasing(loss, epoch, numEpochs): minLoss=np.inf epochMin=0 for i in range(0,loss.size): if loss[i] < minLoss: minLoss=loss[i] epochMin=epoch[i] elif (epoch[i]-epochMin) >= numEpochs: return i, minLoss return i, minLoss #dirpath is where the accuracy and loss files are stored. want to move the files into the same format expected by grabNNData. def createFolders(SEARCHDIR, SAVEDIR): for item in os.scandir(SEARCHDIR): name=str(item.name) files=name.split('-') SAVEFULLDIR=SAVEDIR+str(files[0]) if not os.path.exists(SAVEFULLDIR): try: os.makedirs(SAVEFULLDIR) except FileExistsError: #directory already exists--must have been created between the if statement & our attempt at making directory pass shutil.move(item.path, SAVEFULLDIR+"/"+str(files[1])) #a function to read in information (e.g. accuracy, loss) stored at FILENAME def grabNNData(FILENAME, header='infer', sep=' '): data = pd.read_csv(FILENAME, sep, header=header) if ('epochs' in data.columns) and ('trainLoss' in data.columns) and ('valLoss' in data.columns) and ('valAcc' in data.columns) and ('batch_size' in data.columns) and ('learning_rate' in data.columns): sortedData=data.sort_values(by="epochs", axis=0, ascending=True) epoch=np.array(sortedData['epochs']) trainLoss=np.array(sortedData['trainLoss']) valLoss=np.array(sortedData['valLoss']) valAcc=np.array(sortedData['valAcc']) batch_size=np.array(sortedData['batch_size']) learning_rate=np.array(sortedData['learning_rate']) convKers=np.array(sortedData['convKernels']) return(epoch, trainLoss, valLoss, valAcc, batch_size, learning_rate, convKers) elif ('epochs' in data.columns) and ('trainLoss' in data.columns) and ('valLoss' in data.columns) and ('valAcc' in data.columns): sortedData=data.sort_values(by="epochs", axis=0, ascending=True) epoch=np.array(sortedData['epochs']) trainLoss=	np.array(sortedData['trainLoss'])	numpy.array
""" YTArray class. """ from __future__ import print_function #----------------------------------------------------------------------------- # Copyright (c) 2013, yt Development Team. # # Distributed under the terms of the Modified BSD License. # # The full license is in the file COPYING.txt, distributed with this software. #----------------------------------------------------------------------------- import copy import numpy as np from distutils.version import LooseVersion from functools import wraps from numpy import \ add, subtract, multiply, divide, logaddexp, logaddexp2, true_divide, \ floor_divide, negative, power, remainder, mod, absolute, rint, \ sign, conj, exp, exp2, log, log2, log10, expm1, log1p, sqrt, square, \ reciprocal, sin, cos, tan, arcsin, arccos, arctan, arctan2, \ hypot, sinh, cosh, tanh, arcsinh, arccosh, arctanh, deg2rad, rad2deg, \ bitwise_and, bitwise_or, bitwise_xor, invert, left_shift, right_shift, \ greater, greater_equal, less, less_equal, not_equal, equal, logical_and, \ logical_or, logical_xor, logical_not, maximum, minimum, fmax, fmin, \ isreal, iscomplex, isfinite, isinf, isnan, signbit, copysign, nextafter, \ modf, ldexp, frexp, fmod, floor, ceil, trunc, fabs, spacing try: # numpy 1.13 or newer from numpy import positive, divmod as divmod_, isnat, heaviside except ImportError: positive, divmod_, isnat, heaviside = (None,)4 from yt.units.unit_object import Unit, UnitParseError from yt.units.unit_registry import UnitRegistry from yt.units.dimensions import \ angle, \ current_mks, \ dimensionless, \ em_dimensions from yt.utilities.exceptions import \ YTUnitOperationError, YTUnitConversionError, \ YTUfuncUnitError, YTIterableUnitCoercionError, \ YTInvalidUnitEquivalence, YTEquivalentDimsError from yt.utilities.lru_cache import lru_cache from numbers import Number as numeric_type from yt.utilities.on_demand_imports import _astropy from sympy import Rational from yt.units.unit_lookup_table import \ default_unit_symbol_lut from yt.units.equivalencies import equivalence_registry from yt.utilities.logger import ytLogger as mylog from .pint_conversions import convert_pint_units NULL_UNIT = Unit() POWER_SIGN_MAPPING = {multiply: 1, divide: -1} # redefine this here to avoid a circular import from yt.funcs def iterable(obj): try: len(obj) except: return False return True def return_arr(func): @wraps(func) def wrapped(args, *kwargs): ret, units = func(args, kwargs) if ret.shape == (): return YTQuantity(ret, units) else: # This could be a subclass, so don't call YTArray directly. return type(args[0])(ret, units) return wrapped @lru_cache(maxsize=128, typed=False) def sqrt_unit(unit): return unit0.5 @lru_cache(maxsize=128, typed=False) def multiply_units(unit1, unit2): return unit1 * unit2 def preserve_units(unit1, unit2=None): return unit1 @lru_cache(maxsize=128, typed=False) def power_unit(unit, power): return unit*power @lru_cache(maxsize=128, typed=False) def square_unit(unit): return unitunit @lru_cache(maxsize=128, typed=False) def divide_units(unit1, unit2): return unit1/unit2 @lru_cache(maxsize=128, typed=False) def reciprocal_unit(unit): return unit*-1 def passthrough_unit(unit, unit2=None): return unit def return_without_unit(unit, unit2=None): return None def arctan2_unit(unit1, unit2): return NULL_UNIT def comparison_unit(unit1, unit2=None): return None def invert_units(unit): raise TypeError( "Bit-twiddling operators are not defined for YTArray instances") def bitop_units(unit1, unit2): raise TypeError( "Bit-twiddling operators are not defined for YTArray instances") def get_inp_u_unary(ufunc, inputs, out_arr=None): inp = inputs[0] u = getattr(inp, 'units', None) if u is None: u = NULL_UNIT if u.dimensions is angle and ufunc in trigonometric_operators: inp = inp.in_units('radian').v if out_arr is not None: out_arr = ufunc(inp).view(np.ndarray) return out_arr, inp, u def get_inp_u_binary(ufunc, inputs): inp1 = coerce_iterable_units(inputs[0]) inp2 = coerce_iterable_units(inputs[1]) unit1 = getattr(inp1, 'units', None) unit2 = getattr(inp2, 'units', None) ret_class = get_binary_op_return_class(type(inp1), type(inp2)) if unit1 is None: unit1 = Unit(registry=getattr(unit2, 'registry', None)) if unit2 is None and ufunc is not power: unit2 = Unit(registry=getattr(unit1, 'registry', None)) elif ufunc is power: unit2 = inp2 if isinstance(unit2, np.ndarray): if isinstance(unit2, YTArray): if unit2.units.is_dimensionless: pass else: raise YTUnitOperationError(ufunc, unit1, unit2) unit2 = 1.0 return (inp1, inp2), (unit1, unit2), ret_class def handle_preserve_units(inps, units, ufunc, ret_class): if units[0] != units[1]: any_nonzero = [np.any(inps[0]), np.any(inps[1])] if any_nonzero[0] == np.bool_(False): units = (units[1], units[1]) elif any_nonzero[1] == np.bool_(False): units = (units[0], units[0]) else: if not units[0].same_dimensions_as(units[1]): raise YTUnitOperationError(ufunc, units) inps = (inps[0], ret_class(inps[1]).to( ret_class(inps[0]).units)) return inps, units def handle_comparison_units(inps, units, ufunc, ret_class, raise_error=False): if units[0] != units[1]: u1d = units[0].is_dimensionless u2d = units[1].is_dimensionless any_nonzero = [np.any(inps[0]), np.any(inps[1])] if any_nonzero[0] == np.bool_(False): units = (units[1], units[1]) elif any_nonzero[1] == np.bool_(False): units = (units[0], units[0]) elif not any([u1d, u2d]): if not units[0].same_dimensions_as(units[1]): raise YTUnitOperationError(ufunc, units) else: if raise_error: raise YTUfuncUnitError(ufunc, units) inps = (inps[0], ret_class(inps[1]).to( ret_class(inps[0]).units)) return inps, units def handle_multiply_divide_units(unit, units, out, out_arr): if unit.is_dimensionless and unit.base_value != 1.0: if not units[0].is_dimensionless: if units[0].dimensions == units[1].dimensions: out_arr = np.multiply(out_arr.view(np.ndarray), unit.base_value, out=out) unit = Unit(registry=unit.registry) return out, out_arr, unit def coerce_iterable_units(input_object): if isinstance(input_object, np.ndarray): return input_object if iterable(input_object): if any([isinstance(o, YTArray) for o in input_object]): ff = getattr(input_object[0], 'units', NULL_UNIT, ) if any([ff != getattr(_, 'units', NULL_UNIT) for _ in input_object]): raise YTIterableUnitCoercionError(input_object) # This will create a copy of the data in the iterable. return YTArray(input_object) return input_object else: return input_object def sanitize_units_mul(this_object, other_object): inp = coerce_iterable_units(this_object) ret = coerce_iterable_units(other_object) # If the other object is a YTArray and has the same dimensions as the object # under consideration, convert so we don't mix units with the same # dimensions. if isinstance(ret, YTArray): if inp.units.same_dimensions_as(ret.units): ret.in_units(inp.units) return ret def sanitize_units_add(this_object, other_object, op_string): inp = coerce_iterable_units(this_object) ret = coerce_iterable_units(other_object) # Make sure the other object is a YTArray before we use the `units` # attribute. if isinstance(ret, YTArray): if not inp.units.same_dimensions_as(ret.units): # handle special case of adding or subtracting with zero or # array filled with zero if not np.any(other_object): return ret.view(np.ndarray) elif not np.any(this_object): return ret raise YTUnitOperationError(op_string, inp.units, ret.units) ret = ret.in_units(inp.units) else: # If the other object is not a YTArray, then one of the arrays must be # dimensionless or filled with zeros if not inp.units.is_dimensionless and np.any(ret): raise YTUnitOperationError(op_string, inp.units, dimensionless) return ret def validate_comparison_units(this, other, op_string): # Check that other is a YTArray. if hasattr(other, 'units'): if this.units.expr is other.units.expr: if this.units.base_value == other.units.base_value: return other if not this.units.same_dimensions_as(other.units): raise YTUnitOperationError(op_string, this.units, other.units) return other.in_units(this.units) return other @lru_cache(maxsize=128, typed=False) def _unit_repr_check_same(my_units, other_units): """ Takes a Unit object, or string of known unit symbol, and check that it is compatible with this quantity. Returns Unit object. """ # let Unit() handle units arg if it's not already a Unit obj. if not isinstance(other_units, Unit): other_units = Unit(other_units, registry=my_units.registry) equiv_dims = em_dimensions.get(my_units.dimensions, None) if equiv_dims == other_units.dimensions: if current_mks in equiv_dims.free_symbols: base = "SI" else: base = "CGS" raise YTEquivalentDimsError(my_units, other_units, base) if not my_units.same_dimensions_as(other_units): raise YTUnitConversionError( my_units, my_units.dimensions, other_units, other_units.dimensions) return other_units unary_operators = ( negative, absolute, rint, sign, conj, exp, exp2, log, log2, log10, expm1, log1p, sqrt, square, reciprocal, sin, cos, tan, arcsin, arccos, arctan, sinh, cosh, tanh, arcsinh, arccosh, arctanh, deg2rad, rad2deg, invert, logical_not, isreal, iscomplex, isfinite, isinf, isnan, signbit, floor, ceil, trunc, modf, frexp, fabs, spacing, positive, isnat, ) binary_operators = ( add, subtract, multiply, divide, logaddexp, logaddexp2, true_divide, power, remainder, mod, arctan2, hypot, bitwise_and, bitwise_or, bitwise_xor, left_shift, right_shift, greater, greater_equal, less, less_equal, not_equal, equal, logical_and, logical_or, logical_xor, maximum, minimum, fmax, fmin, copysign, nextafter, ldexp, fmod, divmod_, heaviside ) trigonometric_operators = ( sin, cos, tan, ) class YTArray(np.ndarray): """ An ndarray subclass that attaches a symbolic unit object to the array data. Parameters ---------- input_array : :obj:`!iterable` A tuple, list, or array to attach units to input_units : String unit specification, unit symbol object, or astropy units The units of the array. Powers must be specified using python syntax (cm*3, not cm^3). registry : ~yt.units.unit_registry.UnitRegistry The registry to create units from. If input_units is already associated with a unit registry and this is specified, this will be used instead of the registry associated with the unit object. dtype : data-type The dtype of the array data. Defaults to the dtype of the input data, or, if none is found, uses np.float64 bypass_validation : boolean If True, all input validation is skipped. Using this option may produce corrupted, invalid units or array data, but can lead to significant speedups in the input validation logic adds significant overhead. If set, input_units must* be a valid unit object. Defaults to False. Examples -------- >>> from yt import YTArray >>> a = YTArray([1, 2, 3], 'cm') >>> b = YTArray([4, 5, 6], 'm') >>> a + b YTArray([ 401., 502., 603.]) cm >>> b + a YTArray([ 4.01, 5.02, 6.03]) m NumPy ufuncs will pass through units where appropriate. >>> import numpy as np >>> a = YTArray(np.arange(8) - 4, 'g/cm3') >>> np.abs(a) YTArray([4, 3, 2, 1, 0, 1, 2, 3]) g/cm3 and strip them when it would be annoying to deal with them. >>> np.log10(a) array([ -inf, 0. , 0.30103 , 0.47712125, 0.60205999, 0.69897 , 0.77815125, 0.84509804]) YTArray is tightly integrated with yt datasets: >>> import yt >>> ds = yt.load('IsolatedGalaxy/galaxy0030/galaxy0030') >>> a = ds.arr(np.ones(5), 'code_length') >>> a.in_cgs() YTArray([ 3.08600000e+24, 3.08600000e+24, 3.08600000e+24, 3.08600000e+24, 3.08600000e+24]) cm This is equivalent to: >>> b = YTArray(np.ones(5), 'code_length', registry=ds.unit_registry) >>> np.all(a == b) True """ _ufunc_registry = { add: preserve_units, subtract: preserve_units, multiply: multiply_units, divide: divide_units, logaddexp: return_without_unit, logaddexp2: return_without_unit, true_divide: divide_units, floor_divide: divide_units, negative: passthrough_unit, power: power_unit, remainder: preserve_units, mod: preserve_units, fmod: preserve_units, absolute: passthrough_unit, fabs: passthrough_unit, rint: return_without_unit, sign: return_without_unit, conj: passthrough_unit, exp: return_without_unit, exp2: return_without_unit, log: return_without_unit, log2: return_without_unit, log10: return_without_unit, expm1: return_without_unit, log1p: return_without_unit, sqrt: sqrt_unit, square: square_unit, reciprocal: reciprocal_unit, sin: return_without_unit, cos: return_without_unit, tan: return_without_unit, sinh: return_without_unit, cosh: return_without_unit, tanh: return_without_unit, arcsin: return_without_unit, arccos: return_without_unit, arctan: return_without_unit, arctan2: arctan2_unit, arcsinh: return_without_unit, arccosh: return_without_unit, arctanh: return_without_unit, hypot: preserve_units, deg2rad: return_without_unit, rad2deg: return_without_unit, bitwise_and: bitop_units, bitwise_or: bitop_units, bitwise_xor: bitop_units, invert: invert_units, left_shift: bitop_units, right_shift: bitop_units, greater: comparison_unit, greater_equal: comparison_unit, less: comparison_unit, less_equal: comparison_unit, not_equal: comparison_unit, equal: comparison_unit, logical_and: comparison_unit, logical_or: comparison_unit, logical_xor: comparison_unit, logical_not: return_without_unit, maximum: preserve_units, minimum: preserve_units, fmax: preserve_units, fmin: preserve_units, isreal: return_without_unit, iscomplex: return_without_unit, isfinite: return_without_unit, isinf: return_without_unit, isnan: return_without_unit, signbit: return_without_unit, copysign: passthrough_unit, nextafter: preserve_units, modf: passthrough_unit, ldexp: bitop_units, frexp: return_without_unit, floor: passthrough_unit, ceil: passthrough_unit, trunc: passthrough_unit, spacing: passthrough_unit, positive: passthrough_unit, divmod_: passthrough_unit, isnat: return_without_unit, heaviside: preserve_units, } __array_priority__ = 2.0 def __new__(cls, input_array, input_units=None, registry=None, dtype=None, bypass_validation=False): if dtype is None: dtype = getattr(input_array, 'dtype', np.float64) if bypass_validation is True: obj = np.asarray(input_array, dtype=dtype).view(cls) obj.units = input_units if registry is not None: obj.units.registry = registry return obj if input_array is NotImplemented: return input_array.view(cls) if registry is None and isinstance(input_units, (str, bytes)): if input_units.startswith('code_'): raise UnitParseError( "Code units used without referring to a dataset. \n" "Perhaps you meant to do something like this instead: \n" "ds.arr(%s, \"%s\")" % (input_array, input_units) ) if isinstance(input_array, YTArray): ret = input_array.view(cls) if input_units is None: if registry is None: ret.units = input_array.units else: units = Unit(str(input_array.units), registry=registry) ret.units = units elif isinstance(input_units, Unit): ret.units = input_units else: ret.units = Unit(input_units, registry=registry) return ret elif isinstance(input_array, np.ndarray): pass elif iterable(input_array) and input_array: if isinstance(input_array[0], YTArray): return YTArray(np.array(input_array, dtype=dtype), input_array[0].units, registry=registry) # Input array is an already formed ndarray instance # We first cast to be our class type obj = np.asarray(input_array, dtype=dtype).view(cls) # Check units type if input_units is None: # Nothing provided. Make dimensionless... units = Unit() elif isinstance(input_units, Unit): if registry and registry is not input_units.registry: units = Unit(str(input_units), registry=registry) else: units = input_units else: # units kwarg set, but it's not a Unit object. # don't handle all the cases here, let the Unit class handle if # it's a str. units = Unit(input_units, registry=registry) # Attach the units obj.units = units return obj def __repr__(self): """ """ return super(YTArray, self).__repr__()+' '+self.units.__repr__() def __str__(self): """ """ return str(self.view(np.ndarray)) + ' ' + str(self.units) # # Start unit conversion methods # def convert_to_units(self, units): """ Convert the array and units to the given units. Parameters ---------- units : Unit object or str The units you want to convert to. """ new_units = _unit_repr_check_same(self.units, units) (conversion_factor, offset) = self.units.get_conversion_factor(new_units) self.units = new_units values = self.d values *= conversion_factor if offset:	np.subtract(self, offset*self.uq, self)	numpy.subtract
import numpy as np from typing import Tuple, Union, Optional from autoarray.structures.arrays.two_d import array_2d_util from autoarray.geometry import geometry_util from autoarray import numba_util from autoarray.mask import mask_2d_util @numba_util.jit() def grid_2d_centre_from(grid_2d_slim: np.ndarray) -> Tuple[float, float]: """ Returns the centre of a grid from a 1D grid. Parameters ---------- grid_2d_slim The 1D grid of values which are mapped to a 2D array. Returns ------- (float, float) The (y,x) central coordinates of the grid. """ centre_y = (	np.max(grid_2d_slim[:, 0])	numpy.max
import numpy as np import pytest import theano import theano.tensor as tt # Don't import test classes otherwise they get tested as part of the file from tests import unittest_tools as utt from tests.gpuarray.config import mode_with_gpu, mode_without_gpu, test_ctx_name from tests.tensor.test_basic import ( TestAlloc, TestComparison, TestJoinAndSplit, TestReshape, ) from tests.tensor.utils import rand, safe_make_node from theano.gpuarray.basic_ops import ( GpuAlloc, GpuAllocEmpty, GpuContiguous, GpuEye, GpuFromHost, GpuJoin, GpuReshape, GpuSplit, GpuToGpu, GpuTri, HostFromGpu, gpu_contiguous, gpu_join, host_from_gpu, ) from theano.gpuarray.elemwise import GpuDimShuffle, GpuElemwise from theano.gpuarray.subtensor import GpuSubtensor from theano.gpuarray.type import GpuArrayType, get_context, gpuarray_shared_constructor from theano.tensor import TensorType from theano.tensor.basic import alloc pygpu = pytest.importorskip("pygpu") gpuarray = pygpu.gpuarray utt.seed_rng() rng = np.random.RandomState(seed=utt.fetch_seed()) def inplace_func( inputs, outputs, mode=None, allow_input_downcast=False, on_unused_input="raise", name=None, ): if mode is None: mode = mode_with_gpu return theano.function( inputs, outputs, mode=mode, allow_input_downcast=allow_input_downcast, accept_inplace=True, on_unused_input=on_unused_input, name=name, ) def fake_shared(value, name=None, strict=False, allow_downcast=None, kwargs): from theano.tensor.sharedvar import scalar_constructor, tensor_constructor for c in (gpuarray_shared_constructor, tensor_constructor, scalar_constructor): try: return c( value, name=name, strict=strict, allow_downcast=allow_downcast, kwargs ) except TypeError: continue def rand_gpuarray(shape, kwargs): r = rng.rand(shape) * 2 - 1 dtype = kwargs.pop("dtype", theano.config.floatX) cls = kwargs.pop("cls", None) if len(kwargs) != 0: raise TypeError("Unexpected argument %s", list(kwargs.keys())[0]) return gpuarray.array(r, dtype=dtype, cls=cls, context=get_context(test_ctx_name)) def makeTester( name, op, gpu_op, cases, checks=None, mode_gpu=mode_with_gpu, mode_nogpu=mode_without_gpu, skip=False, eps=1e-10, ): if checks is None: checks = {} _op = op _gpu_op = gpu_op _cases = cases _skip = skip _checks = checks class Checker(utt.OptimizationTestMixin): op = staticmethod(_op) gpu_op = staticmethod(_gpu_op) cases = _cases skip = _skip checks = _checks def setup_method(self): eval(self.__class__.__module__ + "." + self.__class__.__name__) def test_all(self): if skip: pytest.skip(skip) for testname, inputs in cases.items(): for _ in range(len(inputs)): if type(inputs[_]) is float: inputs[_] = np.asarray(inputs[_], dtype=theano.config.floatX) self.run_case(testname, inputs) def run_case(self, testname, inputs): inputs_ref = [theano.shared(inp) for inp in inputs] inputs_tst = [theano.shared(inp) for inp in inputs] try: node_ref = safe_make_node(self.op, inputs_ref) node_tst = safe_make_node(self.op, inputs_tst) except Exception as exc: err_msg = ( "Test %s::%s: Error occurred while making " "a node with inputs %s" ) % (self.gpu_op, testname, inputs) exc.args += (err_msg,) raise try: f_ref = inplace_func([], node_ref.outputs, mode=mode_nogpu) f_tst = inplace_func([], node_tst.outputs, mode=mode_gpu) except Exception as exc: err_msg = ( "Test %s::%s: Error occurred while trying to " "make a Function" ) % (self.gpu_op, testname) exc.args += (err_msg,) raise self.assertFunctionContains1(f_tst, self.gpu_op) ref_e = None try: expecteds = f_ref() except Exception as exc: ref_e = exc try: variables = f_tst() except Exception as exc: if ref_e is None: err_msg = ( "Test %s::%s: exception when calling the " "Function" ) % (self.gpu_op, testname) exc.args += (err_msg,) raise else: # if we raised an exception of the same type we're good. if isinstance(exc, type(ref_e)): return else: err_msg = ( "Test %s::%s: exception raised during test " "call was not the same as the reference " "call (got: %s, expected %s)" % (self.gpu_op, testname, type(exc), type(ref_e)) ) exc.args += (err_msg,) raise for i, (variable, expected) in enumerate(zip(variables, expecteds)): condition = ( variable.dtype != expected.dtype or variable.shape != expected.shape or not TensorType.values_eq_approx(variable, expected) ) assert not condition, ( "Test %s::%s: Output %s gave the wrong " "value. With inputs %s, expected %s " "(dtype %s), got %s (dtype %s)." % ( self.op, testname, i, inputs, expected, expected.dtype, variable, variable.dtype, ) ) for description, check in self.checks.items(): assert check(inputs, variables), ( "Test %s::%s: Failed check: %s " "(inputs were %s, ouputs were %s)" ) % (self.op, testname, description, inputs, variables) Checker.__name__ = name if hasattr(Checker, "__qualname__"): Checker.__qualname__ = name return Checker def test_transfer_cpu_gpu(): a = tt.fmatrix("a") g = GpuArrayType(dtype="float32", broadcastable=(False, False))("g") av = np.asarray(rng.rand(5, 4), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) f = theano.function([a], GpuFromHost(test_ctx_name)(a)) fv = f(av) assert GpuArrayType.values_eq(fv, gv) f = theano.function([g], host_from_gpu(g)) fv = f(gv) assert np.all(fv == av) def test_transfer_gpu_gpu(): g = GpuArrayType( dtype="float32", broadcastable=(False, False), context_name=test_ctx_name )() av = np.asarray(rng.rand(5, 4), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) mode = mode_with_gpu.excluding( "cut_gpua_host_transfers", "local_cut_gpua_host_gpua" ) f = theano.function([g], GpuToGpu(test_ctx_name)(g), mode=mode) topo = f.maker.fgraph.toposort() assert len(topo) == 1 assert isinstance(topo[0].op, GpuToGpu) fv = f(gv) assert GpuArrayType.values_eq(fv, gv) def test_transfer_strided(): # This is just to ensure that it works in theano # libgpuarray has a much more comprehensive suit of tests to # ensure correctness a = tt.fmatrix("a") g = GpuArrayType(dtype="float32", broadcastable=(False, False))("g") av = np.asarray(rng.rand(5, 8), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) av = av[:, ::2] gv = gv[:, ::2] f = theano.function([a], GpuFromHost(test_ctx_name)(a)) fv = f(av) assert GpuArrayType.values_eq(fv, gv) f = theano.function([g], host_from_gpu(g)) fv = f(gv) assert np.all(fv == av) def gpu_alloc_expected(x, shp): g = gpuarray.empty(shp, dtype=x.dtype, context=get_context(test_ctx_name)) g[:] = x return g TestGpuAlloc = makeTester( name="GpuAllocTester", # The +1 is there to allow the lift to the GPU. op=lambda args: alloc(args) + 1, gpu_op=GpuAlloc(test_ctx_name), cases=dict( correct01=(rand(), np.int32(7)), # just gives a DeepCopyOp with possibly wrong results on the CPU # correct01_bcast=(rand(1), np.int32(7)), correct02=(rand(), np.int32(4), np.int32(7)), correct12=(rand(7), np.int32(4), np.int32(7)), correct13=(rand(7), np.int32(2), np.int32(4), np.int32(7)), correct23=(rand(4, 7), np.int32(2), np.int32(4), np.int32(7)), bad_shape12=(rand(7), np.int32(7), np.int32(5)), ), ) class TestGPUAlloc(TestAlloc): dtype = "float32" mode = mode_with_gpu shared = staticmethod(gpuarray_shared_constructor) allocs = [GpuAlloc(test_ctx_name), GpuAlloc(test_ctx_name), tt.Alloc()] def test_alloc_empty(): for dt in ["float32", "int8"]: f = theano.function([], GpuAllocEmpty(dt, context_name=test_ctx_name)(2, 3)) assert len(f.maker.fgraph.apply_nodes) == 1 out = f() assert out.shape == (2, 3) assert out.dtype == dt f = theano.function( [], [ GpuAllocEmpty("uint64", test_ctx_name)(3, 2), GpuAllocEmpty("uint64", test_ctx_name)(3, 2), ], ) out = f() assert out[0].shape == (3, 2) assert out[0].dtype == "uint64" assert out[1].shape == (3, 2) assert out[1].dtype == "uint64" assert ( len( [ node for node in f.maker.fgraph.apply_nodes if isinstance(node.op, GpuAllocEmpty) ] ) == 1 ) def test_shape(): x = GpuArrayType(dtype="float32", broadcastable=[False, False, False])() v = gpuarray.zeros((3, 4, 5), dtype="float32", context=get_context(test_ctx_name)) f = theano.function([x], x.shape) topo = f.maker.fgraph.toposort() assert np.all(f(v) == (3, 4, 5)) if theano.config.mode != "FAST_COMPILE": assert len(topo) == 4 assert isinstance(topo[0].op, tt.opt.Shape_i) assert isinstance(topo[1].op, tt.opt.Shape_i) assert isinstance(topo[2].op, tt.opt.Shape_i) assert isinstance(topo[3].op, tt.opt.MakeVector) mode = mode_with_gpu.excluding("local_shape_to_shape_i") f = theano.function([x], x.shape, mode=mode) topo = f.maker.fgraph.toposort() assert np.all(f(v) == (3, 4, 5)) assert len(topo) == 1 assert isinstance(topo[0].op, tt.Shape) def test_gpu_contiguous(): a = tt.fmatrix("a") i = tt.iscalar("i") a_val = np.asarray(np.random.rand(4, 5), dtype="float32") # The reshape is needed otherwise we make the subtensor on the CPU # to transfer less data. f = theano.function( [a, i], gpu_contiguous(a.reshape((5, 4))[::i]), mode=mode_with_gpu ) topo = f.maker.fgraph.toposort() assert any([isinstance(node.op, GpuSubtensor) for node in topo]) assert any([isinstance(node.op, GpuContiguous) for node in topo]) assert f(a_val, 1).flags.c_contiguous assert f(a_val, 2).flags.c_contiguous assert f(a_val, 2).flags.c_contiguous class TestGPUReshape(TestReshape): def setup_method(self): self.shared = gpuarray_shared_constructor self.op = GpuReshape self.mode = mode_with_gpu self.ignore_topo = ( HostFromGpu, GpuFromHost, theano.compile.DeepCopyOp, GpuDimShuffle, GpuElemwise, tt.opt.Shape_i, tt.opt.MakeVector, ) assert self.op == GpuReshape class TestGPUComparison(TestComparison): def setup_method(self): utt.seed_rng() self.mode = mode_with_gpu self.shared = gpuarray_shared_constructor self.dtypes = ["float64", "float32"] class TestGPUJoinAndSplit(TestJoinAndSplit): def setup_method(self): self.mode = mode_with_gpu.excluding("constant_folding") self.join_op = GpuJoin() self.split_op_class = GpuSplit # Use join instead of MakeVector since there is no MakeVector on GPU self.make_vector_op = GpuJoin() # this is to avoid errors with limited devices self.floatX = "float32" self.hide_error = theano.config.mode not in ["DebugMode", "DEBUG_MODE"] def shared(x, kwargs): return gpuarray_shared_constructor(x, target=test_ctx_name, *kwargs) self.shared = shared def test_gpusplit_opt(self): # Test that we move the node to the GPU # Also test float16 computation at the same time. rng = np.random.RandomState(seed=utt.fetch_seed()) m = self.shared(rng.rand(4, 6).astype("float16")) o = tt.Split(2)(m, 0, [2, 2]) assert o[0].dtype == "float16" f = theano.function([], o, mode=self.mode) assert any( [ isinstance(node.op, self.split_op_class) for node in f.maker.fgraph.toposort() ] ) o1, o2 = f() assert np.allclose(o1, m.get_value(borrow=True)[:2]) assert np.allclose(o2, m.get_value(borrow=True)[2:]) def test_gpujoin_gpualloc(): a = tt.fmatrix("a") a_val = np.asarray(np.random.rand(4, 5), dtype="float32") b = tt.fmatrix("b") b_val = np.asarray(np.random.rand(3, 5), dtype="float32") f = theano.function( [a, b], tt.join(0, tt.zeros_like(a), tt.ones_like(b)) + 4, mode=mode_without_gpu ) f_gpu = theano.function( [a, b], tt.join(0, tt.zeros_like(a), tt.ones_like(b)), mode=mode_with_gpu ) f_gpu2 = theano.function( [a, b], tt.join(0, tt.zeros_like(a), tt.ones_like(b)) + 4, mode=mode_with_gpu ) assert sum([node.op == tt.alloc for node in f.maker.fgraph.toposort()]) == 2 assert sum([node.op == tt.join_ for node in f.maker.fgraph.toposort()]) == 1 assert ( sum([isinstance(node.op, GpuAlloc) for node in f_gpu.maker.fgraph.toposort()]) == 2 ) assert sum([node.op == gpu_join for node in f_gpu.maker.fgraph.toposort()]) == 1 assert ( sum([isinstance(node.op, GpuAlloc) for node in f_gpu2.maker.fgraph.toposort()]) == 2 ) assert sum([node.op == gpu_join for node in f_gpu2.maker.fgraph.toposort()]) == 1 assert np.allclose(f(a_val, b_val), f_gpu2(a_val, b_val)) def test_gpueye(): def check(dtype, N, M_=None, k=0): # Theano does not accept None as a tensor. # So we must use a real value. M = M_ # Currently DebugMode does not support None as inputs even if this is # allowed. if M is None: M = N N_symb = tt.iscalar() M_symb = tt.iscalar() k_symb = tt.iscalar() out = tt.eye(N_symb, M_symb, k_symb, dtype=dtype) + np.array(1).astype(dtype) f = theano.function([N_symb, M_symb, k_symb], out, mode=mode_with_gpu) result = np.asarray(f(N, M, k)) - np.array(1).astype(dtype) assert np.allclose(result, np.eye(N, M_, k, dtype=dtype)) assert result.dtype == np.dtype(dtype) assert any([isinstance(node.op, GpuEye) for node in f.maker.fgraph.toposort()]) for dtype in ["float32", "int32", "float16"]: check(dtype, 3) # M != N, k = 0 check(dtype, 3, 5) check(dtype, 5, 3) # N == M, k != 0 check(dtype, 3, 3, 1) check(dtype, 3, 3, -1) # N < M, k != 0 check(dtype, 3, 5, 1) check(dtype, 3, 5, -1) # N > M, k != 0 check(dtype, 5, 3, 1) check(dtype, 5, 3, -1) # k > M, -k > N, k > M, k > N check(dtype, 5, 3, 3) check(dtype, 3, 5, 3) check(dtype, 5, 3, -3) check(dtype, 3, 5, -3) check(dtype, 5, 3, 6) check(dtype, 3, 5, -6) def test_hostfromgpu_shape_i(): # Test that the shape is lifted over hostfromgpu m = mode_with_gpu.including( "local_dot_to_dot22", "local_dot22_to_dot22scalar", "specialize" ) a = tt.fmatrix("a") ca = theano.gpuarray.type.GpuArrayType("float32", (False, False))() av = np.asarray(np.random.rand(5, 4), dtype="float32") cv = gpuarray.asarray( np.random.rand(5, 4), dtype="float32", context=get_context(test_ctx_name) ) f = theano.function([a], GpuFromHost(test_ctx_name)(a), mode=m) assert any(isinstance(x.op, GpuFromHost) for x in f.maker.fgraph.toposort()) f = theano.function([a], GpuFromHost(test_ctx_name)(a).shape, mode=m) topo = f.maker.fgraph.toposort() assert isinstance(topo[0].op, tt.opt.Shape_i) assert isinstance(topo[1].op, tt.opt.Shape_i) assert isinstance(topo[2].op, tt.opt.MakeVector) assert tuple(f(av)) == (5, 4) f = theano.function([ca], host_from_gpu(ca), mode=m) assert host_from_gpu in [x.op for x in f.maker.fgraph.toposort()] f = theano.function([ca], host_from_gpu(ca).shape, mode=m) topo = f.maker.fgraph.toposort() assert isinstance(topo[0].op, theano.compile.Shape_i) assert isinstance(topo[1].op, theano.compile.Shape_i) assert isinstance(topo[2].op, tt.opt.MakeVector) assert tuple(f(cv)) == (5, 4) def test_Gpujoin_inplace(): # Test Gpujoin to work inplace. # # This function tests the case when several elements are passed to the # Gpujoin function but all except one of them are empty. In this case # Gpujoin should work inplace and the output should be the view of the # non-empty element. s = tt.lscalar() data = np.array([3, 4, 5], dtype=theano.config.floatX) x = gpuarray_shared_constructor(data, borrow=True) z = tt.zeros((s,)) join = GpuJoin(view=0) c = join(0, x, z) f = theano.function([s], theano.Out(c, borrow=True)) if not isinstance(mode_with_gpu, theano.compile.DebugMode): assert x.get_value(borrow=True, return_internal_type=True) is f(0) assert np.allclose(f(0), [3, 4, 5]) def test_gpu_tril_triu(): def check_l(m, k=0): m_symb = tt.matrix(dtype=m.dtype) k_symb = tt.iscalar() f = theano.function( [m_symb, k_symb], tt.tril(m_symb, k_symb), mode=mode_with_gpu ) result = f(m, k) assert np.allclose(result, np.tril(m, k)) assert result.dtype == np.dtype(dtype) assert any([isinstance(node.op, GpuTri) for node in f.maker.fgraph.toposort()]) def check_u(m, k=0): m_symb = tt.matrix(dtype=m.dtype) k_symb = tt.iscalar() f = theano.function( [m_symb, k_symb], tt.triu(m_symb, k_symb), mode=mode_with_gpu ) result = f(m, k) assert np.allclose(result, np.triu(m, k)) assert result.dtype ==	np.dtype(dtype)	numpy.dtype
from __future__ import annotations from datetime import timedelta import operator from sys import getsizeof from typing import ( TYPE_CHECKING, Any, Callable, Hashable, List, cast, ) import warnings import numpy as np from pandas._libs import index as libindex from pandas._libs.lib import no_default from pandas._typing import Dtype from pandas.compat.numpy import function as nv from pandas.util._decorators import ( cache_readonly, doc, ) from pandas.util._exceptions import rewrite_exception from pandas.core.dtypes.common import ( ensure_platform_int, ensure_python_int, is_float, is_integer, is_scalar, is_signed_integer_dtype, is_timedelta64_dtype, ) from pandas.core.dtypes.generic import ABCTimedeltaIndex from pandas.core import ops import pandas.core.common as com from pandas.core.construction import extract_array import pandas.core.indexes.base as ibase from pandas.core.indexes.base import maybe_extract_name from pandas.core.indexes.numeric import ( Float64Index, Int64Index, NumericIndex, ) from pandas.core.ops.common import unpack_zerodim_and_defer if TYPE_CHECKING: from pandas import Index _empty_range = range(0) class RangeIndex(NumericIndex): """ Immutable Index implementing a monotonic integer range. RangeIndex is a memory-saving special case of Int64Index limited to representing monotonic ranges. Using RangeIndex may in some instances improve computing speed. This is the default index type used by DataFrame and Series when no explicit index is provided by the user. Parameters ---------- start : int (default: 0), range, or other RangeIndex instance If int and "stop" is not given, interpreted as "stop" instead. stop : int (default: 0) step : int (default: 1) dtype : np.int64 Unused, accepted for homogeneity with other index types. copy : bool, default False Unused, accepted for homogeneity with other index types. name : object, optional Name to be stored in the index. Attributes ---------- start stop step Methods ------- from_range See Also -------- Index : The base pandas Index type. Int64Index : Index of int64 data. """ _typ = "rangeindex" _engine_type = libindex.Int64Engine _dtype_validation_metadata = (is_signed_integer_dtype, "signed integer") _can_hold_na = False _range: range # -------------------------------------------------------------------- # Constructors def __new__( cls, start=None, stop=None, step=None, dtype: Dtype \| None = None, copy: bool = False, name: Hashable = None, ) -> RangeIndex: cls._validate_dtype(dtype) name = maybe_extract_name(name, start, cls) # RangeIndex if isinstance(start, RangeIndex): return start.copy(name=name) elif isinstance(start, range): return cls._simple_new(start, name=name) # validate the arguments if com.all_none(start, stop, step): raise TypeError("RangeIndex(...) must be called with integers") start = ensure_python_int(start) if start is not None else 0 if stop is None: start, stop = 0, start else: stop = ensure_python_int(stop) step = ensure_python_int(step) if step is not None else 1 if step == 0: raise ValueError("Step must not be zero") rng = range(start, stop, step) return cls._simple_new(rng, name=name) @classmethod def from_range( cls, data: range, name=None, dtype: Dtype \| None = None ) -> RangeIndex: """ Create RangeIndex from a range object. Returns ------- RangeIndex """ if not isinstance(data, range): raise TypeError( f"{cls.__name__}(...) must be called with object coercible to a " f"range, {repr(data)} was passed" ) cls._validate_dtype(dtype) return cls._simple_new(data, name=name) @classmethod def _simple_new(cls, values: range, name: Hashable = None) -> RangeIndex: result = object.__new__(cls) assert isinstance(values, range) result._range = values result._name = name result._cache = {} result._reset_identity() return result # -------------------------------------------------------------------- @cache_readonly def _constructor(self) -> type[Int64Index]: """ return the class to use for construction """ return Int64Index @cache_readonly def _data(self) -> np.ndarray: """ An int array that for performance reasons is created only when needed. The constructed array is saved in ``_cache``. """ return np.arange(self.start, self.stop, self.step, dtype=np.int64) @cache_readonly def _cached_int64index(self) -> Int64Index: return Int64Index._simple_new(self._data, name=self.name) @property def _int64index(self) -> Int64Index: # wrap _cached_int64index so we can be sure its name matches self.name res = self._cached_int64index res._name = self._name return res def _get_data_as_items(self): """ return a list of tuples of start, stop, step """ rng = self._range return [("start", rng.start), ("stop", rng.stop), ("step", rng.step)] def __reduce__(self): d = self._get_attributes_dict() d.update(dict(self._get_data_as_items())) return ibase._new_Index, (type(self), d), None # -------------------------------------------------------------------- # Rendering Methods def _format_attrs(self): """ Return a list of tuples of the (attr, formatted_value) """ attrs = self._get_data_as_items() if self.name is not None: attrs.append(("name", ibase.default_pprint(self.name))) return attrs def _format_data(self, name=None): # we are formatting thru the attributes return None def _format_with_header(self, header: list[str], na_rep: str = "NaN") -> list[str]: if not len(self._range): return header first_val_str = str(self._range[0]) last_val_str = str(self._range[-1]) max_length = max(len(first_val_str), len(last_val_str)) return header + [f"{x:<{max_length}}" for x in self._range] # -------------------------------------------------------------------- _deprecation_message = ( "RangeIndex.{} is deprecated and will be " "removed in a future version. Use RangeIndex.{} " "instead" ) @property def start(self) -> int: """ The value of the `start` parameter (``0`` if this was not supplied). """ # GH 25710 return self._range.start @property def _start(self) -> int: """ The value of the `start` parameter (``0`` if this was not supplied). .. deprecated:: 0.25.0 Use ``start`` instead. """ warnings.warn( self._deprecation_message.format("_start", "start"), FutureWarning, stacklevel=2, ) return self.start @property def stop(self) -> int: """ The value of the `stop` parameter. """ return self._range.stop @property def _stop(self) -> int: """ The value of the `stop` parameter. .. deprecated:: 0.25.0 Use ``stop`` instead. """ # GH 25710 warnings.warn( self._deprecation_message.format("_stop", "stop"), FutureWarning, stacklevel=2, ) return self.stop @property def step(self) -> int: """ The value of the `step` parameter (``1`` if this was not supplied). """ # GH 25710 return self._range.step @property def _step(self) -> int: """ The value of the `step` parameter (``1`` if this was not supplied). .. deprecated:: 0.25.0 Use ``step`` instead. """ # GH 25710 warnings.warn( self._deprecation_message.format("_step", "step"), FutureWarning, stacklevel=2, ) return self.step @cache_readonly def nbytes(self) -> int: """ Return the number of bytes in the underlying data. """ rng = self._range return getsizeof(rng) + sum( getsizeof(getattr(rng, attr_name)) for attr_name in ["start", "stop", "step"] ) def memory_usage(self, deep: bool = False) -> int: """ Memory usage of my values Parameters ---------- deep : bool Introspect the data deeply, interrogate `object` dtypes for system-level memory consumption Returns ------- bytes used Notes ----- Memory usage does not include memory consumed by elements that are not components of the array if deep=False See Also -------- numpy.ndarray.nbytes """ return self.nbytes @property def dtype(self) -> np.dtype: return np.dtype(np.int64) @property def is_unique(self) -> bool: """ return if the index has unique values """ return True @cache_readonly def is_monotonic_increasing(self) -> bool: return self._range.step > 0 or len(self) <= 1 @cache_readonly def is_monotonic_decreasing(self) -> bool: return self._range.step < 0 or len(self) <= 1 def __contains__(self, key: Any) -> bool: hash(key) try: key = ensure_python_int(key) except TypeError: return False return key in self._range @property def inferred_type(self) -> str: return "integer" # -------------------------------------------------------------------- # Indexing Methods @doc(Int64Index.get_loc) def get_loc(self, key, method=None, tolerance=None): if method is None and tolerance is None: if is_integer(key) or (is_float(key) and key.is_integer()): new_key = int(key) try: return self._range.index(new_key) except ValueError as err: raise KeyError(key) from err raise KeyError(key) return super().get_loc(key, method=method, tolerance=tolerance) def _get_indexer( self, target: Index, method: str \| None = None, limit: int \| None = None, tolerance=None, ) -> np.ndarray: # -> np.ndarray[np.intp] if com.any_not_none(method, tolerance, limit): return super()._get_indexer( target, method=method, tolerance=tolerance, limit=limit ) if self.step > 0: start, stop, step = self.start, self.stop, self.step else: # GH 28678: work on reversed range for simplicity reverse = self._range[::-1] start, stop, step = reverse.start, reverse.stop, reverse.step if not is_signed_integer_dtype(target): # checks/conversions/roundings are delegated to general method return super()._get_indexer(target, method=method, tolerance=tolerance) target_array = np.asarray(target) locs = target_array - start valid = (locs % step == 0) & (locs >= 0) & (target_array < stop) locs[~valid] = -1 locs[valid] = locs[valid] / step if step != self.step: # We reversed this range: transform to original locs locs[valid] = len(self) - 1 - locs[valid] return ensure_platform_int(locs) # -------------------------------------------------------------------- def repeat(self, repeats, axis=None) -> Int64Index: return self._int64index.repeat(repeats, axis=axis) def delete(self, loc) -> Int64Index: # type: ignore[override] return self._int64index.delete(loc) def take( self, indices, axis: int = 0, allow_fill: bool = True, fill_value=None, kwargs ) -> Int64Index: with rewrite_exception("Int64Index", type(self).__name__): return self._int64index.take( indices, axis=axis, allow_fill=allow_fill, fill_value=fill_value, kwargs, ) def tolist(self) -> list[int]: return list(self._range) @doc(Int64Index.__iter__) def __iter__(self): yield from self._range @doc(Int64Index._shallow_copy) def _shallow_copy(self, values, name: Hashable = no_default): name = self.name if name is no_default else name if values.dtype.kind == "f": return Float64Index(values, name=name) return Int64Index._simple_new(values, name=name) def _view(self: RangeIndex) -> RangeIndex: result = type(self)._simple_new(self._range, name=self._name) result._cache = self._cache return result @doc(Int64Index.copy) def copy( self, name: Hashable = None, deep: bool = False, dtype: Dtype \| None = None, names=None, ): name = self._validate_names(name=name, names=names, deep=deep)[0] new_index = self._rename(name=name) if dtype: warnings.warn( "parameter dtype is deprecated and will be removed in a future " "version. Use the astype method instead.", FutureWarning, stacklevel=2, ) new_index = new_index.astype(dtype) return new_index def _minmax(self, meth: str): no_steps = len(self) - 1 if no_steps == -1: return np.nan elif (meth == "min" and self.step > 0) or (meth == "max" and self.step < 0): return self.start return self.start + self.step * no_steps def min(self, axis=None, skipna: bool = True, args, kwargs) -> int: """The minimum value of the RangeIndex""" nv.validate_minmax_axis(axis) nv.validate_min(args, kwargs) return self._minmax("min") def max(self, axis=None, skipna: bool = True, args, *kwargs) -> int: """The maximum value of the RangeIndex""" nv.validate_minmax_axis(axis) nv.validate_max(args, kwargs) return self._minmax("max") def argsort(self, args, *kwargs) -> np.ndarray: """ Returns the indices that would sort the index and its underlying data. Returns ------- np.ndarray[np.intp] See Also -------- numpy.ndarray.argsort """ ascending = kwargs.pop("ascending", True) # EA compat nv.validate_argsort(args, kwargs) if self._range.step > 0: result = np.arange(len(self), dtype=np.intp) else: result = np.arange(len(self) - 1, -1, -1, dtype=np.intp) if not ascending: result = result[::-1] return result def factorize( self, sort: bool = False, na_sentinel: int \| None = -1 ) -> tuple[np.ndarray, RangeIndex]: codes = np.arange(len(self), dtype=np.intp) uniques = self if sort and self.step < 0: codes = codes[::-1] uniques = uniques[::-1] return codes, uniques def equals(self, other: object) -> bool: """ Determines if two Index objects contain the same elements. """ if isinstance(other, RangeIndex): return self._range == other._range return super().equals(other) # -------------------------------------------------------------------- # Set Operations def _intersection(self, other: Index, sort=False): if not isinstance(other, RangeIndex): # Int64Index return super()._intersection(other, sort=sort) if not len(self) or not len(other): return self._simple_new(_empty_range) first = self._range[::-1] if self.step < 0 else self._range second = other._range[::-1] if other.step < 0 else other._range # check whether intervals intersect # deals with in- and decreasing ranges int_low = max(first.start, second.start) int_high = min(first.stop, second.stop) if int_high <= int_low: return self._simple_new(_empty_range) # Method hint: linear Diophantine equation # solve intersection problem # performance hint: for identical step sizes, could use # cheaper alternative gcd, s, _ = self._extended_gcd(first.step, second.step) # check whether element sets intersect if (first.start - second.start) % gcd: return self._simple_new(_empty_range) # calculate parameters for the RangeIndex describing the # intersection disregarding the lower bounds tmp_start = first.start + (second.start - first.start) first.step // gcd * s new_step = first.step * second.step // gcd new_range = range(tmp_start, int_high, new_step) new_index = self._simple_new(new_range) # adjust index to limiting interval new_start = new_index._min_fitting_element(int_low) new_range = range(new_start, new_index.stop, new_index.step) new_index = self._simple_new(new_range) if (self.step < 0 and other.step < 0) is not (new_index.step < 0): new_index = new_index[::-1] if sort is None: new_index = new_index.sort_values() return new_index def _min_fitting_element(self, lower_limit: int) -> int: """Returns the smallest element greater than or equal to the limit""" no_steps = -(-(lower_limit - self.start) // abs(self.step)) return self.start + abs(self.step) * no_steps def _max_fitting_element(self, upper_limit: int) -> int: """Returns the largest element smaller than or equal to the limit""" no_steps = (upper_limit - self.start) // abs(self.step) return self.start + abs(self.step) * no_steps def _extended_gcd(self, a: int, b: int) -> tuple[int, int, int]: """ Extended Euclidean algorithms to solve Bezout's identity: ax + by = gcd(x, y) Finds one particular solution for x, y: s, t Returns: gcd, s, t """ s, old_s = 0, 1 t, old_t = 1, 0 r, old_r = b, a while r: quotient = old_r // r old_r, r = r, old_r - quotient * r old_s, s = s, old_s - quotient * s old_t, t = t, old_t - quotient * t return old_r, old_s, old_t def _union(self, other: Index, sort): """ Form the union of two Index objects and sorts if possible Parameters ---------- other : Index or array-like sort : False or None, default None Whether to sort resulting index. ``sort=None`` returns a monotonically increasing ``RangeIndex`` if possible or a sorted ``Int64Index`` if not. ``sort=False`` always returns an unsorted ``Int64Index`` .. versionadded:: 0.25.0 Returns ------- union : Index """ if isinstance(other, RangeIndex) and sort is None: start_s, step_s = self.start, self.step end_s = self.start + self.step * (len(self) - 1) start_o, step_o = other.start, other.step end_o = other.start + other.step * (len(other) - 1) if self.step < 0: start_s, step_s, end_s = end_s, -step_s, start_s if other.step < 0: start_o, step_o, end_o = end_o, -step_o, start_o if len(self) == 1 and len(other) == 1: step_s = step_o = abs(self.start - other.start) elif len(self) == 1: step_s = step_o elif len(other) == 1: step_o = step_s start_r = min(start_s, start_o) end_r = max(end_s, end_o) if step_o == step_s: if ( (start_s - start_o) % step_s == 0 and (start_s - end_o) <= step_s and (start_o - end_s) <= step_s ): return type(self)(start_r, end_r + step_s, step_s) if ( (step_s % 2 == 0) and (abs(start_s - start_o) <= step_s / 2) and (abs(end_s - end_o) <= step_s / 2) ): return type(self)(start_r, end_r + step_s / 2, step_s / 2) elif step_o % step_s == 0: if ( (start_o - start_s) % step_s == 0 and (start_o + step_s >= start_s) and (end_o - step_s <= end_s) ): return type(self)(start_r, end_r + step_s, step_s) elif step_s % step_o == 0: if ( (start_s - start_o) % step_o == 0 and (start_s + step_o >= start_o) and (end_s - step_o <= end_o) ): return type(self)(start_r, end_r + step_o, step_o) return self._int64index._union(other, sort=sort) def _difference(self, other, sort=None): # optimized set operation if we have another RangeIndex self._validate_sort_keyword(sort) self._assert_can_do_setop(other) other, result_name = self._convert_can_do_setop(other) if not isinstance(other, RangeIndex): return super()._difference(other, sort=sort) res_name = ops.get_op_result_name(self, other) first = self._range[::-1] if self.step < 0 else self._range overlap = self.intersection(other) if overlap.step < 0: overlap = overlap[::-1] if len(overlap) == 0: return self.rename(name=res_name) if len(overlap) == len(self): return self[:0].rename(res_name) if not isinstance(overlap, RangeIndex): # We won't end up with RangeIndex, so fall back return super()._difference(other, sort=sort) if overlap.step != first.step: # In some cases we might be able to get a RangeIndex back, # but not worth the effort. return super()._difference(other, sort=sort) if overlap[0] == first.start: # The difference is everything after the intersection new_rng = range(overlap[-1] + first.step, first.stop, first.step) elif overlap[-1] == first[-1]: # The difference is everything before the intersection new_rng = range(first.start, overlap[0], first.step) else: # The difference is not range-like return super()._difference(other, sort=sort) new_index = type(self)._simple_new(new_rng, name=res_name) if first is not self._range: new_index = new_index[::-1] return new_index def symmetric_difference(self, other, result_name: Hashable = None, sort=None): if not isinstance(other, RangeIndex) or sort is not None: return super().symmetric_difference(other, result_name, sort) left = self.difference(other) right = other.difference(self) result = left.union(right) if result_name is not None: result = result.rename(result_name) return result # -------------------------------------------------------------------- def _concat(self, indexes: list[Index], name: Hashable) -> Index: """ Overriding parent method for the case of all RangeIndex instances. When all members of "indexes" are of type RangeIndex: result will be RangeIndex if possible, Int64Index otherwise. E.g.: indexes = [RangeIndex(3), RangeIndex(3, 6)] -> RangeIndex(6) indexes = [RangeIndex(3), RangeIndex(4, 6)] -> Int64Index([0,1,2,4,5]) """ if not all(isinstance(x, RangeIndex) for x in indexes): return super()._concat(indexes, name) elif len(indexes) == 1: return indexes[0] rng_indexes = cast(List[RangeIndex], indexes) start = step = next_ = None # Filter the empty indexes non_empty_indexes = [obj for obj in rng_indexes if len(obj)] for obj in non_empty_indexes: rng = obj._range if start is None: # This is set by the first non-empty index start = rng.start if step is None and len(rng) > 1: step = rng.step elif step is None: # First non-empty index had only one element if rng.start == start: values = np.concatenate([x._values for x in rng_indexes]) result = Int64Index(values) return result.rename(name) step = rng.start - start non_consecutive = (step != rng.step and len(rng) > 1) or ( next_ is not None and rng.start != next_ ) if non_consecutive: result = Int64Index(np.concatenate([x._values for x in rng_indexes])) return result.rename(name) if step is not None: next_ = rng[-1] + step if non_empty_indexes: # Get the stop value from "next" or alternatively # from the last non-empty index stop = non_empty_indexes[-1].stop if next_ is None else next_ return RangeIndex(start, stop, step).rename(name) # Here all "indexes" had 0 length, i.e. were empty. # In this case return an empty range index. return RangeIndex(0, 0).rename(name) def __len__(self) -> int: """ return the length of the RangeIndex """ return len(self._range) @property def size(self) -> int: return len(self) def __getitem__(self, key): """ Conserve RangeIndex type for scalar and slice keys. """ if isinstance(key, slice): new_range = self._range[key] return self._simple_new(new_range, name=self._name) elif is_integer(key): new_key = int(key) try: return self._range[new_key] except IndexError as err: raise IndexError( f"index {key} is out of bounds for axis 0 with size {len(self)}" ) from err elif is_scalar(key): raise IndexError( "only integers, slices (`:`), " "ellipsis (`...`), numpy.newaxis (`None`) " "and integer or boolean " "arrays are valid indices" ) # fall back to Int64Index return super().__getitem__(key) def _getitem_slice(self: RangeIndex, slobj: slice) -> RangeIndex: """ Fastpath for __getitem__ when we know we have a slice. """ res = self._range[slobj] return type(self)._simple_new(res, name=self._name) @unpack_zerodim_and_defer("__floordiv__") def __floordiv__(self, other): if is_integer(other) and other != 0: if len(self) == 0 or self.start % other == 0 and self.step % other == 0: start = self.start // other step = self.step // other stop = start + len(self) * step new_range = range(start, stop, step or 1) return self._simple_new(new_range, name=self.name) if len(self) == 1: start = self.start // other new_range = range(start, start + 1, 1) return self._simple_new(new_range, name=self.name) return self._int64index // other # -------------------------------------------------------------------- # Reductions def all(self, args, kwargs) -> bool: return 0 not in self._range def any(self, args, **kwargs) -> bool: return any(self._range) # -------------------------------------------------------------------- def _cmp_method(self, other, op): if isinstance(other, RangeIndex) and self._range == other._range: # Both are immutable so if ._range attr. are equal, shortcut is possible return super()._cmp_method(self, op) return super()._cmp_method(other, op) def _arith_method(self, other, op): """ Parameters ---------- other : Any op : callable that accepts 2 params perform the binary op """ if isinstance(other, ABCTimedeltaIndex): # Defer to TimedeltaIndex implementation return NotImplemented elif isinstance(other, (timedelta, np.timedelta64)): # GH#19333 is_integer evaluated True on timedelta64, # so we need to catch these explicitly return op(self._int64index, other) elif is_timedelta64_dtype(other): # Must be an np.ndarray; GH#22390 return op(self._int64index, other) if op in [ operator.pow, ops.rpow, operator.mod, ops.rmod, ops.rfloordiv, divmod, ops.rdivmod, ]: return op(self._int64index, other) step: Callable \| None = None if op in [operator.mul, ops.rmul, operator.truediv, ops.rtruediv]: step = op # TODO: if other is a RangeIndex we may have more efficient options other = extract_array(other, extract_numpy=True, extract_range=True) attrs = self._get_attributes_dict() left, right = self, other try: # apply if we have an override if step: with	np.errstate(all="ignore")	numpy.errstate
# coding: utf-8 # Licensed under a 3-clause BSD style license - see LICENSE.rst """ Test the Logarithmic Units and Quantities """ from __future__ import (absolute_import, unicode_literals, division, print_function) from ...extern import six from ...extern.six.moves import zip import pickle import itertools import pytest import numpy as np from numpy.testing.utils import assert_allclose from ...tests.helper import assert_quantity_allclose from ... import units as u, constants as c lu_units = [u.dex, u.mag, u.decibel] lu_subclasses = [u.DexUnit, u.MagUnit, u.DecibelUnit] lq_subclasses = [u.Dex, u.Magnitude, u.Decibel] pu_sample = (u.dimensionless_unscaled, u.m, u.g/u.s*2, u.Jy) class TestLogUnitCreation(object): def test_logarithmic_units(self): """Check logarithmic units are set up correctly.""" assert u.dB.to(u.dex) == 0.1 assert u.dex.to(u.mag) == -2.5 assert u.mag.to(u.dB) == -4 @pytest.mark.parametrize('lu_unit, lu_cls', zip(lu_units, lu_subclasses)) def test_callable_units(self, lu_unit, lu_cls): assert isinstance(lu_unit, u.UnitBase) assert callable(lu_unit) assert lu_unit._function_unit_class is lu_cls @pytest.mark.parametrize('lu_unit', lu_units) def test_equality_to_normal_unit_for_dimensionless(self, lu_unit): lu = lu_unit() assert lu == lu._default_function_unit # eg, MagUnit() == u.mag assert lu._default_function_unit == lu # and u.mag == MagUnit() @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_call_units(self, lu_unit, physical_unit): """Create a LogUnit subclass using the callable unit and physical unit, and do basic check that output is right.""" lu1 = lu_unit(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit def test_call_invalid_unit(self): with pytest.raises(TypeError): u.mag([]) with pytest.raises(ValueError): u.mag(u.mag()) @pytest.mark.parametrize('lu_cls, physical_unit', itertools.product( lu_subclasses + [u.LogUnit], pu_sample)) def test_subclass_creation(self, lu_cls, physical_unit): """Create a LogUnit subclass object for given physical unit, and do basic check that output is right.""" lu1 = lu_cls(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit lu2 = lu_cls(physical_unit, function_unit=2lu1._default_function_unit) assert lu2.physical_unit == physical_unit assert lu2.function_unit == u.Unit(2lu2._default_function_unit) with pytest.raises(ValueError): lu_cls(physical_unit, u.m) def test_predefined_magnitudes(): assert_quantity_allclose((-21.1u.STmag).physical, 1.u.erg/u.cm2/u.s/u.AA) assert_quantity_allclose((-48.6u.ABmag).physical, 1.u.erg/u.cm2/u.s/u.Hz) assert_quantity_allclose((0u.M_bol).physical, c.L_bol0) assert_quantity_allclose((0u.m_bol).physical, c.L_bol0/(4.np.pi(10.c.pc)2)) def test_predefined_reinitialisation(): assert u.mag('ST') == u.STmag assert u.mag('AB') == u.ABmag assert u.mag('Bol') == u.M_bol assert u.mag('bol') == u.m_bol def test_predefined_string_roundtrip(): """Ensure roundtripping; see #5015""" with u.magnitude_zero_points.enable(): assert u.Unit(u.STmag.to_string()) == u.STmag assert u.Unit(u.ABmag.to_string()) == u.ABmag assert u.Unit(u.M_bol.to_string()) == u.M_bol assert u.Unit(u.m_bol.to_string()) == u.m_bol def test_inequality(): """Check __ne__ works (regresssion for #5342).""" lu1 = u.mag(u.Jy) lu2 = u.dex(u.Jy) lu3 = u.mag(u.Jy2) lu4 = lu3 - lu1 assert lu1 != lu2 assert lu1 != lu3 assert lu1 == lu4 class TestLogUnitStrings(object): def test_str(self): """Do some spot checks that str, repr, etc. work as expected.""" lu1 = u.mag(u.Jy) assert str(lu1) == 'mag(Jy)' assert repr(lu1) == 'Unit("mag(Jy)")' assert lu1.to_string('generic') == 'mag(Jy)' with pytest.raises(ValueError): lu1.to_string('fits') lu2 = u.dex() assert str(lu2) == 'dex' assert repr(lu2) == 'Unit("dex(1)")' assert lu2.to_string() == 'dex(1)' lu3 = u.MagUnit(u.Jy, function_unit=2u.mag) assert str(lu3) == '2 mag(Jy)' assert repr(lu3) == 'MagUnit("Jy", unit="2 mag")' assert lu3.to_string() == '2 mag(Jy)' lu4 = u.mag(u.ct) assert lu4.to_string('generic') == 'mag(ct)' assert lu4.to_string('latex') == ('$\\mathrm{mag}$$\\mathrm{\\left( ' '\\mathrm{ct} \\right)}$') assert lu4._repr_latex_() == lu4.to_string('latex') class TestLogUnitConversion(object): @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_physical_unit_conversion(self, lu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to their non-log counterparts.""" lu1 = lu_unit(physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(physical_unit, 0.) == 1. assert physical_unit.is_equivalent(lu1) assert physical_unit.to(lu1, 1.) == 0. pu = u.Unit(8.physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(pu, 0.) == 0.125 assert pu.is_equivalent(lu1) assert_allclose(pu.to(lu1, 0.125), 0., atol=1.e-15) # Check we round-trip. value = np.linspace(0., 10., 6) assert_allclose(pu.to(lu1, lu1.to(pu, value)), value, atol=1.e-15) # And that we're not just returning True all the time. pu2 = u.g assert not lu1.is_equivalent(pu2) with pytest.raises(u.UnitsError): lu1.to(pu2) assert not pu2.is_equivalent(lu1) with pytest.raises(u.UnitsError): pu2.to(lu1) @pytest.mark.parametrize('lu_unit', lu_units) def test_container_unit_conversion(self, lu_unit): """Check that conversion to logarithmic units (u.mag, u.dB, u.dex) is only possible when the physical unit is dimensionless.""" values = np.linspace(0., 10., 6) lu1 = lu_unit(u.dimensionless_unscaled) assert lu1.is_equivalent(lu1.function_unit) assert_allclose(lu1.to(lu1.function_unit, values), values) lu2 = lu_unit(u.Jy) assert not lu2.is_equivalent(lu2.function_unit) with pytest.raises(u.UnitsError): lu2.to(lu2.function_unit, values) @pytest.mark.parametrize( 'flu_unit, tlu_unit, physical_unit', itertools.product(lu_units, lu_units, pu_sample)) def test_subclass_conversion(self, flu_unit, tlu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to each other if they correspond to equivalent physical units.""" values = np.linspace(0., 10., 6) flu = flu_unit(physical_unit) tlu = tlu_unit(physical_unit) assert flu.is_equivalent(tlu) assert_allclose(flu.to(tlu), flu.function_unit.to(tlu.function_unit)) assert_allclose(flu.to(tlu, values), values * flu.function_unit.to(tlu.function_unit)) tlu2 = tlu_unit(u.Unit(100.physical_unit)) assert flu.is_equivalent(tlu2) # Check that we round-trip. assert_allclose(flu.to(tlu2, tlu2.to(flu, values)), values, atol=1.e-15) tlu3 = tlu_unit(physical_unit.to_system(u.si)[0]) assert flu.is_equivalent(tlu3) assert_allclose(flu.to(tlu3, tlu3.to(flu, values)), values, atol=1.e-15) tlu4 = tlu_unit(u.g) assert not flu.is_equivalent(tlu4) with pytest.raises(u.UnitsError): flu.to(tlu4, values) def test_unit_decomposition(self): lu = u.mag(u.Jy) assert lu.decompose() == u.mag(u.Jy.decompose()) assert lu.decompose().physical_unit.bases == [u.kg, u.s] assert lu.si == u.mag(u.Jy.si) assert lu.si.physical_unit.bases == [u.kg, u.s] assert lu.cgs == u.mag(u.Jy.cgs) assert lu.cgs.physical_unit.bases == [u.g, u.s] def test_unit_multiple_possible_equivalencies(self): lu = u.mag(u.Jy) assert lu.is_equivalent(pu_sample) class TestLogUnitArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other units is only possible when the physical unit is dimensionless, and that this turns the unit into a normal one.""" lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 u.m with pytest.raises(u.UnitsError): u.m * lu1 with pytest.raises(u.UnitsError): lu1 / lu1 for unit in (u.dimensionless_unscaled, u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lu1 / unit lu2 = u.mag(u.dimensionless_unscaled) with pytest.raises(u.UnitsError): lu2 * lu1 with pytest.raises(u.UnitsError): lu2 / lu1 # But dimensionless_unscaled can be cancelled. assert lu2 / lu2 == u.dimensionless_unscaled # With dimensionless, normal units are OK, but we return a plain unit. tf = lu2 * u.m tr = u.m * lu2 for t in (tf, tr): assert not isinstance(t, type(lu2)) assert t == lu2.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lu2.physical_unit) # Now we essentially have a LogUnit with a prefactor of 100, # so should be equivalent again. t = tf / u.cm with u.set_enabled_equivalencies(u.logarithmic()): assert t.is_equivalent(lu2.function_unit) assert_allclose(t.to(u.dimensionless_unscaled, np.arange(3.)/100.), lu2.to(lu2.physical_unit, np.arange(3.))) # If we effectively remove lu1, a normal unit should be returned. t2 = tf / lu2 assert not isinstance(t2, type(lu2)) assert t2 == u.m t3 = tf / lu2.function_unit assert not isinstance(t3, type(lu2)) assert t3 == u.m # For completeness, also ensure non-sensical operations fail with pytest.raises(TypeError): lu1 * object() with pytest.raises(TypeError): slice(None) * lu1 with pytest.raises(TypeError): lu1 / [] with pytest.raises(TypeError): 1 / lu1 @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogUnits to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (such as mag2) is incompatible.""" lu1 = u.mag(u.Jy) if power == 0: assert lu1 power == u.dimensionless_unscaled elif power == 1: assert lu1 power == lu1 else: with pytest.raises(u.UnitsError): lu1 power # With dimensionless, though, it works, but returns a normal unit. lu2 = u.mag(u.dimensionless_unscaled) t = lu2power if power == 0: assert t == u.dimensionless_unscaled elif power == 1: assert t == lu2 else: assert not isinstance(t, type(lu2)) assert t == lu2.function_unitpower # also check we roundtrip t2 = t*(1./power) assert t2 == lu2.function_unit with u.set_enabled_equivalencies(u.logarithmic()): assert_allclose(t2.to(u.dimensionless_unscaled, np.arange(3.)), lu2.to(lu2.physical_unit, np.arange(3.))) @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 + other with pytest.raises(u.UnitsError): lu1 - other with pytest.raises(u.UnitsError): other - lu1 def test_addition_subtraction_to_non_units_fails(self): lu1 = u.mag(u.Jy) with pytest.raises(TypeError): lu1 + 1. with pytest.raises(TypeError): lu1 - [1., 2., 3.] @pytest.mark.parametrize( 'other', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2u.mag), u.MagUnit('', 2.u.mag))) def test_addition_subtraction(self, other): """Check physical units are changed appropriately""" lu1 = u.mag(u.Jy) other_pu = getattr(other, 'physical_unit', u.dimensionless_unscaled) lu_sf = lu1 + other assert lu_sf.is_equivalent(lu1.physical_unit other_pu) lu_sr = other + lu1 assert lu_sr.is_equivalent(lu1.physical_unit * other_pu) lu_df = lu1 - other assert lu_df.is_equivalent(lu1.physical_unit / other_pu) lu_dr = other - lu1 assert lu_dr.is_equivalent(other_pu / lu1.physical_unit) def test_complicated_addition_subtraction(self): """for fun, a more complicated example of addition and subtraction""" dm0 = u.Unit('DM', 1./(4.np.pi(10.u.pc)2)) lu_dm = u.mag(dm0) lu_absST = u.STmag - lu_dm assert lu_absST.is_equivalent(u.erg/u.s/u.AA) def test_neg_pos(self): lu1 = u.mag(u.Jy) neg_lu = -lu1 assert neg_lu != lu1 assert neg_lu.physical_unit == u.Jy-1 assert -neg_lu == lu1 pos_lu = +lu1 assert pos_lu is not lu1 assert pos_lu == lu1 def test_pickle(): lu1 = u.dex(u.cm/u.s2) s = pickle.dumps(lu1) lu2 = pickle.loads(s) assert lu1 == lu2 def test_hashable(): lu1 = u.dB(u.mW) lu2 = u.dB(u.m) lu3 = u.dB(u.mW) assert hash(lu1) != hash(lu2) assert hash(lu1) == hash(lu3) luset = {lu1, lu2, lu3} assert len(luset) == 2 class TestLogQuantityCreation(object): @pytest.mark.parametrize('lq, lu', zip(lq_subclasses + [u.LogQuantity], lu_subclasses + [u.LogUnit])) def test_logarithmic_quantities(self, lq, lu): """Check logarithmic quantities are all set up correctly""" assert lq._unit_class == lu assert type(lu()._quantity_class(1.)) is lq @pytest.mark.parametrize('lq_cls, physical_unit', itertools.product(lq_subclasses, pu_sample)) def test_subclass_creation(self, lq_cls, physical_unit): """Create LogQuantity subclass objects for some physical units, and basic check on transformations""" value = np.arange(1., 10.) log_q = lq_cls(value physical_unit) assert log_q.unit.physical_unit == physical_unit assert log_q.unit.function_unit == log_q.unit._default_function_unit assert_allclose(log_q.physical.value, value) with pytest.raises(ValueError): lq_cls(value, physical_unit) @pytest.mark.parametrize( 'unit', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2u.mag), u.MagUnit('', 2.u.mag), u.MagUnit(u.Jy, -1u.mag), u.MagUnit(u.m, -2.u.mag))) def test_different_units(self, unit): q = u.Magnitude(1.23, unit) assert q.unit.function_unit == getattr(unit, 'function_unit', unit) assert q.unit.physical_unit is getattr(unit, 'physical_unit', u.dimensionless_unscaled) @pytest.mark.parametrize('value, unit', ( (1.u.mag(u.Jy), None), (1.u.dex(u.Jy), None), (1.u.mag(u.W/u.m2/u.Hz), u.mag(u.Jy)), (1.u.dex(u.W/u.m*2/u.Hz), u.mag(u.Jy)))) def test_function_values(self, value, unit): lq = u.Magnitude(value, unit) assert lq == value assert lq.unit.function_unit == u.mag assert lq.unit.physical_unit == getattr(unit, 'physical_unit', value.unit.physical_unit) @pytest.mark.parametrize( 'unit', (u.mag(), u.mag(u.Jy), u.mag(u.m), u.MagUnit('', 2.u.mag), u.MagUnit(u.Jy, -1u.mag), u.MagUnit(u.m, -2.u.mag))) def test_indirect_creation(self, unit): q1 = 2.5 * unit assert isinstance(q1, u.Magnitude) assert q1.value == 2.5 assert q1.unit == unit pv = 100. * unit.physical_unit q2 = unit * pv assert q2.unit == unit assert q2.unit.physical_unit == pv.unit assert q2.to_value(unit.physical_unit) == 100. assert (q2._function_view / u.mag).to_value(1) == -5. q3 = unit / 0.4 assert q3 == q1 def test_from_view(self): # Cannot view a physical quantity as a function quantity, since the # values would change. q = [100., 1000.] * u.cm/u.s*2 with pytest.raises(TypeError): q.view(u.Dex) # But fine if we have the right magnitude. q = [2., 3.] u.dex lq = q.view(u.Dex) assert isinstance(lq, u.Dex) assert lq.unit.physical_unit == u.dimensionless_unscaled assert np.all(q == lq) def test_using_quantity_class(self): """Check that we can use Quantity if we have subok=True""" # following issue #5851 lu = u.dex(u.AA) with pytest.raises(u.UnitTypeError): u.Quantity(1., lu) q = u.Quantity(1., lu, subok=True) assert type(q) is lu._quantity_class def test_conversion_to_and_from_physical_quantities(): """Ensures we can convert from regular quantities.""" mst = [10., 12., 14.] * u.STmag flux_lambda = mst.physical mst_roundtrip = flux_lambda.to(u.STmag) # check we return a logquantity; see #5178. assert isinstance(mst_roundtrip, u.Magnitude) assert mst_roundtrip.unit == mst.unit assert_allclose(mst_roundtrip.value, mst.value) wave = [4956.8, 4959.55, 4962.3] * u.AA flux_nu = mst.to(u.Jy, equivalencies=u.spectral_density(wave)) mst_roundtrip2 = flux_nu.to(u.STmag, u.spectral_density(wave)) assert isinstance(mst_roundtrip2, u.Magnitude) assert mst_roundtrip2.unit == mst.unit assert_allclose(mst_roundtrip2.value, mst.value) def test_quantity_decomposition(): lq = 10.u.mag(u.Jy) assert lq.decompose() == lq assert lq.decompose().unit.physical_unit.bases == [u.kg, u.s] assert lq.si == lq assert lq.si.unit.physical_unit.bases == [u.kg, u.s] assert lq.cgs == lq assert lq.cgs.unit.physical_unit.bases == [u.g, u.s] class TestLogQuantityViews(object): def setup(self): self.lq = u.Magnitude(np.arange(10.) u.Jy) self.lq2 = u.Magnitude(np.arange(5.)) def test_value_view(self): lq_value = self.lq.value assert type(lq_value) is np.ndarray lq_value[2] = -1. assert np.all(self.lq.value == lq_value) def test_function_view(self): lq_fv = self.lq._function_view assert type(lq_fv) is u.Quantity assert lq_fv.unit is self.lq.unit.function_unit lq_fv[3] = -2. * lq_fv.unit assert np.all(self.lq.value == lq_fv.value) def test_quantity_view(self): # Cannot view as Quantity, since the unit cannot be represented. with pytest.raises(TypeError): self.lq.view(u.Quantity) # But a dimensionless one is fine. q2 = self.lq2.view(u.Quantity) assert q2.unit is u.mag assert np.all(q2.value == self.lq2.value) lq3 = q2.view(u.Magnitude) assert type(lq3.unit) is u.MagUnit assert lq3.unit.physical_unit == u.dimensionless_unscaled assert np.all(lq3 == self.lq2) class TestLogQuantitySlicing(object): def test_item_get_and_set(self): lq1 = u.Magnitude(np.arange(1., 11.)u.Jy) assert lq1[9] == u.Magnitude(10.u.Jy) lq1[2] = 100.u.Jy assert lq1[2] == u.Magnitude(100.u.Jy) with pytest.raises(u.UnitsError): lq1[2] = 100.u.m with pytest.raises(u.UnitsError): lq1[2] = 100.u.mag with pytest.raises(u.UnitsError): lq1[2] = u.Magnitude(100.u.m) assert lq1[2] == u.Magnitude(100.u.Jy) def test_slice_get_and_set(self): lq1 = u.Magnitude(np.arange(1., 10.)u.Jy) lq1[2:4] = 100.u.Jy assert np.all(lq1[2:4] == u.Magnitude(100.u.Jy)) with pytest.raises(u.UnitsError): lq1[2:4] = 100.u.m with pytest.raises(u.UnitsError): lq1[2:4] = 100.u.mag with pytest.raises(u.UnitsError): lq1[2:4] = u.Magnitude(100.u.m) assert np.all(lq1[2] == u.Magnitude(100.u.Jy)) class TestLogQuantityArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other quantities is only possible when the physical unit is dimensionless, and that this turns the result into a normal quantity.""" lq = u.Magnitude(np.arange(1., 11.)u.Jy) with pytest.raises(u.UnitsError): lq * (1.u.m) with pytest.raises(u.UnitsError): (1.u.m) * lq with pytest.raises(u.UnitsError): lq / lq for unit in (u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lq / unit lq2 = u.Magnitude(np.arange(1, 11.)) with pytest.raises(u.UnitsError): lq2 * lq with pytest.raises(u.UnitsError): lq2 / lq with pytest.raises(u.UnitsError): lq / lq2 # but dimensionless_unscaled can be cancelled r = lq2 / u.Magnitude(2.) assert r.unit == u.dimensionless_unscaled assert np.all(r.value == lq2.value/2.) # with dimensionless, normal units OK, but return normal quantities tf = lq2 * u.m tr = u.m * lq2 for t in (tf, tr): assert not isinstance(t, type(lq2)) assert t.unit == lq2.unit.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lq2.unit.physical_unit) t = tf / (50.u.cm) # now we essentially have the same quantity but with a prefactor of 2 assert t.unit.is_equivalent(lq2.unit.function_unit) assert_allclose(t.to(lq2.unit.function_unit), lq2._function_view2) @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogQuantities to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (say, mag*2) is incompatible.""" lq = u.Magnitude(np.arange(1., 4.)u.Jy) if power == 0: assert np.all(lq power == 1.) elif power == 1: assert np.all(lq power == lq) else: with pytest.raises(u.UnitsError): lq power # with dimensionless, it works, but falls back to normal quantity # (except for power=1) lq2 = u.Magnitude(np.arange(10.)) t = lq2power if power == 0: assert t.unit is u.dimensionless_unscaled assert np.all(t.value == 1.) elif power == 1: assert np.all(t == lq2) else: assert not isinstance(t, type(lq2)) assert t.unit == lq2.unit.function_unit ** power with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(u.dimensionless_unscaled) def test_error_on_lq_as_power(self): lq = u.Magnitude(np.arange(1., 4.)u.Jy) with pytest.raises(TypeError): lq * lq @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lq = u.Magnitude(np.arange(1., 10.)u.Jy) q = 1.23 other with pytest.raises(u.UnitsError): lq + q with pytest.raises(u.UnitsError): lq - q with pytest.raises(u.UnitsError): q - lq @pytest.mark.parametrize( 'other', (1.23 * u.mag, 2.34 * u.mag(), u.Magnitude(3.45 * u.Jy), u.Magnitude(4.56 * u.m), 5.67 * u.Unit(2u.mag), u.Magnitude(6.78, 2.u.mag))) def test_addition_subtraction(self, other): """Check that addition/subtraction with quantities with magnitude or MagUnit units works, and that it changes the physical units appropriately.""" lq = u.Magnitude(np.arange(1., 10.)*u.Jy) other_physical = other.to(getattr(other.unit, 'physical_unit', u.dimensionless_unscaled), equivalencies=u.logarithmic()) lq_sf = lq + other	assert_allclose(lq_sf.physical, lq.physical * other_physical)	numpy.testing.utils.assert_allclose
import gym import numpy as np from itertools import product import matplotlib.pyplot as plt def print_policy(Q, env): """ This is a helper function to print a nice policy from the Q function""" moves = [u'←', u'↓',u'→', u'↑'] if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape policy = np.chararray(dims, unicode=True) policy[:] = ' ' for s in range(len(Q)): idx = np.unravel_index(s, dims) policy[idx] = moves[np.argmax(Q[s])] if env.desc[idx] in ['H', 'G']: policy[idx] = u'·' print('\n'.join([''.join([u'{:2}'.format(item) for item in row]) for row in policy])) def plot_V(Q, env): """ This is a helper function to plot the state values from the Q function""" fig = plt.figure() if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape V =	np.zeros(dims)	numpy.zeros
''' <NAME> set up :2020-1-9 intergrate img and label into one file -- fiducial1024_v1 ''' import argparse import sys, os import pickle import random import collections import json import numpy as np import scipy.io as io import scipy.misc as m import matplotlib.pyplot as plt import glob import math import time import threading import multiprocessing as mp from multiprocessing import Pool import re import cv2 # sys.path.append('/lustre/home/gwxie/hope/project/dewarp/datasets/') # /lustre/home/gwxie/program/project/unwarp/perturbed_imgaes/GAN import utils def getDatasets(dir): return os.listdir(dir) class perturbed(utils.BasePerturbed): def __init__(self, path, bg_path, save_path, save_suffix): self.path = path self.bg_path = bg_path self.save_path = save_path self.save_suffix = save_suffix def save_img(self, m, n, fold_curve='fold', repeat_time=4, fiducial_points = 16, relativeShift_position='relativeShift_v2'): origin_img = cv2.imread(self.path, flags=cv2.IMREAD_COLOR) save_img_shape = [5122, 4802] # 320 # reduce_value = np.random.choice([24, 25, 26, 27, 2*8], p=[0.01, 0.1, 0.4, 0.39, 0.1]) reduce_value = np.random.choice([22, 42, 82, 162, 242, 322, 402, 482], p=[0.02, 0.18, 0.2, 0.3, 0.1, 0.1, 0.08, 0.02]) # reduce_value = np.random.choice([82, 162, 242, 322, 402, 482], p=[0.01, 0.02, 0.2, 0.4, 0.19, 0.18]) # reduce_value = np.random.choice([16, 24, 32, 40, 48, 64], p=[0.01, 0.1, 0.2, 0.4, 0.2, 0.09]) base_img_shrink = save_img_shape[0] - reduce_value # enlarge_img_shrink = [1024, 768] # enlarge_img_shrink = [896, 672] # 420 enlarge_img_shrink = [5124, 4804] # 420 # enlarge_img_shrink = [8962, 7682] # 420 # enlarge_img_shrink = [896, 768] # 420 # enlarge_img_shrink = [768, 576] # 420 # enlarge_img_shrink = [640, 480] # 420 '''''' im_lr = origin_img.shape[0] im_ud = origin_img.shape[1] reduce_value_v2 = np.random.choice([22, 42, 82, 162, 242, 282, 322, 482], p=[0.02, 0.18, 0.2, 0.2, 0.1, 0.1, 0.1, 0.1]) # reduce_value_v2 = np.random.choice([16, 24, 28, 32, 48, 64], p=[0.01, 0.1, 0.2, 0.3, 0.25, 0.14]) if im_lr > im_ud: im_ud = min(int(im_ud / im_lr base_img_shrink), save_img_shape[1] - reduce_value_v2) im_lr = save_img_shape[0] - reduce_value else: base_img_shrink = save_img_shape[1] - reduce_value im_lr = min(int(im_lr / im_ud * base_img_shrink), save_img_shape[0] - reduce_value_v2) im_ud = base_img_shrink if round(im_lr / im_ud, 2) < 0.5 or round(im_ud / im_lr, 2) < 0.5: repeat_time = min(repeat_time, 8) edge_padding = 3 im_lr -= im_lr % (fiducial_points-1) - (2edge_padding) # im_lr % (fiducial_points-1) - 1 im_ud -= im_ud % (fiducial_points-1) - (2edge_padding) # im_ud % (fiducial_points-1) - 1 im_hight = np.linspace(edge_padding, im_lr - edge_padding, fiducial_points, dtype=np.int64) im_wide = np.linspace(edge_padding, im_ud - edge_padding, fiducial_points, dtype=np.int64) # im_lr -= im_lr % (fiducial_points-1) - (1+2edge_padding) # im_lr % (fiducial_points-1) - 1 # im_ud -= im_ud % (fiducial_points-1) - (1+2edge_padding) # im_ud % (fiducial_points-1) - 1 # im_hight = np.linspace(edge_padding, im_lr - (1+edge_padding), fiducial_points, dtype=np.int64) # im_wide = np.linspace(edge_padding, im_ud - (1+edge_padding), fiducial_points, dtype=np.int64) im_x, im_y = np.meshgrid(im_hight, im_wide) segment_x = (im_lr) // (fiducial_points-1) segment_y = (im_ud) // (fiducial_points-1) # plt.plot(im_x, im_y, # color='limegreen', # marker='.', # linestyle='') # plt.grid(True) # plt.show() self.origin_img = cv2.resize(origin_img, (im_ud, im_lr), interpolation=cv2.INTER_CUBIC) perturbed_bg_ = getDatasets(self.bg_path) perturbed_bg_img_ = self.bg_path+random.choice(perturbed_bg_) perturbed_bg_img = cv2.imread(perturbed_bg_img_, flags=cv2.IMREAD_COLOR) mesh_shape = self.origin_img.shape[:2] self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 256, dtype=np.float32)#np.zeros_like(perturbed_bg_img) # self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 0, dtype=np.int16)#np.zeros_like(perturbed_bg_img) self.new_shape = self.synthesis_perturbed_img.shape[:2] perturbed_bg_img = cv2.resize(perturbed_bg_img, (save_img_shape[1], save_img_shape[0]), cv2.INPAINT_TELEA) origin_pixel_position = np.argwhere(np.zeros(mesh_shape, dtype=np.uint32) == 0).reshape(mesh_shape[0], mesh_shape[1], 2) pixel_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape(self.new_shape[0], self.new_shape[1], 2) self.perturbed_xy_ = np.zeros((self.new_shape[0], self.new_shape[1], 2)) # self.perturbed_xy_ = pixel_position.copy().astype(np.float32) # fiducial_points_grid = origin_pixel_position[im_x, im_y] self.synthesis_perturbed_label = np.zeros((self.new_shape[0], self.new_shape[1], 2)) x_min, y_min, x_max, y_max = self.adjust_position_v2(0, 0, mesh_shape[0], mesh_shape[1], save_img_shape) origin_pixel_position += [x_min, y_min] x_min, y_min, x_max, y_max = self.adjust_position(0, 0, mesh_shape[0], mesh_shape[1]) x_shift = random.randint(-enlarge_img_shrink[0]//16, enlarge_img_shrink[0]//16) y_shift = random.randint(-enlarge_img_shrink[1]//16, enlarge_img_shrink[1]//16) x_min += x_shift x_max += x_shift y_min += y_shift y_max += y_shift '''im_x,y''' im_x += x_min im_y += y_min self.synthesis_perturbed_img[x_min:x_max, y_min:y_max] = self.origin_img self.synthesis_perturbed_label[x_min:x_max, y_min:y_max] = origin_pixel_position synthesis_perturbed_img_map = self.synthesis_perturbed_img.copy() synthesis_perturbed_label_map = self.synthesis_perturbed_label.copy() foreORbackground_label = np.full((mesh_shape), 1, dtype=np.int16) foreORbackground_label_map = np.full((self.new_shape), 0, dtype=np.int16) foreORbackground_label_map[x_min:x_max, y_min:y_max] = foreORbackground_label # synthesis_perturbed_img_map = self.pad(self.synthesis_perturbed_img.copy(), x_min, y_min, x_max, y_max) # synthesis_perturbed_label_map = self.pad(synthesis_perturbed_label_map, x_min, y_min, x_max, y_max) '''****************************************************************''' is_normalizationFun_mixture = self.is_perform(0.2, 0.8) # if not is_normalizationFun_mixture: normalizationFun_0_1 = False # normalizationFun_0_1 = self.is_perform(0.5, 0.5) if fold_curve == 'fold': fold_curve_random = True # is_normalizationFun_mixture = False normalizationFun_0_1 = self.is_perform(0.2, 0.8) if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: fold_curve_random = self.is_perform(0.1, 0.9) # False # self.is_perform(0.01, 0.99) alpha_perturbed = random.randint(80, 160) / 100 # is_normalizationFun_mixture = False # self.is_perform(0.01, 0.99) synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) # synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 0, dtype=np.int16) synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) alpha_perturbed_change = self.is_perform(0.5, 0.5) p_pp_choice = self.is_perform(0.8, 0.2) if fold_curve == 'fold' else self.is_perform(0.1, 0.9) for repeat_i in range(repeat_time): if alpha_perturbed_change: if fold_curve == 'fold': if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: alpha_perturbed = random.randint(80, 160) / 100 '''''' linspace_x = [0, (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - 1] linspace_y = [0, (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - 1] linspace_x_seq = [1, 2, 3] linspace_y_seq = [1, 2, 3] r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_p = np.array( [random.randint(linspace_x[r_x-1] 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 if ((r_x == 1 or r_x == 3) and (r_y == 1 or r_y == 3)) and p_pp_choice: linspace_x_seq.remove(r_x) linspace_y_seq.remove(r_y) r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_pp = np.array( [random.randint(linspace_x[r_x-1] * 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 # perturbed_p, perturbed_pp = np.array( # [random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) \ # , np.array([random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) # perturbed_p, perturbed_pp = np.array( # [random.randint((self.new_shape[0]-im_lr)//210, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) 10) / 10, # random.randint((self.new_shape[1]-im_ud)//210, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) 10) / 10]) \ # , np.array([random.randint((self.new_shape[0]-im_lr)//210, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) 10) / 10, # random.randint((self.new_shape[1]-im_ud)//210, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) 10) / 10]) '''''' perturbed_vp = perturbed_pp - perturbed_p perturbed_vp_norm = np.linalg.norm(perturbed_vp) perturbed_distance_vertex_and_line = np.dot((perturbed_p - pixel_position), perturbed_vp) / perturbed_vp_norm '''''' # perturbed_v = np.array([random.randint(-3000, 3000) / 100, random.randint(-3000, 3000) / 100]) # perturbed_v = np.array([random.randint(-4000, 4000) / 100, random.randint(-4000, 4000) / 100]) if fold_curve == 'fold' and self.is_perform(0.6, 0.4): # self.is_perform(0.3, 0.7): # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) perturbed_v = np.array([random.randint(-10000, 10000) / 100, random.randint(-10000, 10000) / 100]) # perturbed_v = np.array([random.randint(-11000, 11000) / 100, random.randint(-11000, 11000) / 100]) else: # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) # perturbed_v = np.array([random.randint(-16000, 16000) / 100, random.randint(-16000, 16000) / 100]) perturbed_v = np.array([random.randint(-8000, 8000) / 100, random.randint(-8000, 8000) / 100]) # perturbed_v = np.array([random.randint(-3500, 3500) / 100, random.randint(-3500, 3500) / 100]) # perturbed_v = np.array([random.randint(-600, 600) / 10, random.randint(-600, 600) / 10]) '''''' if fold_curve == 'fold': if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) '''''' if fold_curve_random: # omega_perturbed = (alpha_perturbed+0.2) / (perturbed_d + alpha_perturbed) # omega_perturbed = alpha_perturbedperturbed_d omega_perturbed = alpha_perturbed / (perturbed_d + alpha_perturbed) else: omega_perturbed = 1 - perturbed_d alpha_perturbed '''shadow''' if self.is_perform(0.6, 0.4): synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] = np.minimum(np.maximum(synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] - np.int16(np.round(omega_perturbed[x_min:x_max, y_min:y_max].repeat(3).reshape(x_max-x_min, y_max-y_min, 3) * abs(np.linalg.norm(perturbed_v//2))np.array([0.4-random.random()0.1, 0.4-random.random()0.1, 0.4-random.random()0.1]))), 0), 255) '''''' if relativeShift_position in ['position', 'relativeShift_v2']: self.perturbed_xy_ += np.array([omega_perturbed * perturbed_v[0], omega_perturbed * perturbed_v[1]]).transpose(1, 2, 0) else: print('relativeShift_position error') exit() ''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 # synthesis_perturbed_img = np.around(synthesis_perturbed_img).astype(np.uint8) synthesis_perturbed_label[:, :, 0] = foreORbackground_label synthesis_perturbed_label[:, :, 1] = foreORbackground_label synthesis_perturbed_img[:, :, 0] = foreORbackground_label synthesis_perturbed_img[:, :, 1] = foreORbackground_label synthesis_perturbed_img[:, :, 2] = foreORbackground_label self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label ''' '''perspective''' perspective_shreshold = random.randint(26, 36)10 # 280 x_min_per, y_min_per, x_max_per, y_max_per = self.adjust_position(perspective_shreshold, perspective_shreshold, self.new_shape[0]-perspective_shreshold, self.new_shape[1]-perspective_shreshold) pts1 = np.float32([[x_min_per, y_min_per], [x_max_per, y_min_per], [x_min_per, y_max_per], [x_max_per, y_max_per]]) e_1_ = x_max_per - x_min_per e_2_ = y_max_per - y_min_per e_3_ = e_2_ e_4_ = e_1_ perspective_shreshold_h = e_1_0.02 perspective_shreshold_w = e_2_0.02 a_min_, a_max_ = 70, 110 # if self.is_perform(1, 0): if fold_curve == 'curve' and self.is_perform(0.5, 0.5): if self.is_perform(0.5, 0.5): while True: pts2 = np.around( np.float32([[x_min_per - (random.random()) * perspective_shreshold, y_min_per + (random.random()) * perspective_shreshold], [x_max_per - (random.random()) * perspective_shreshold, y_min_per - (random.random()) * perspective_shreshold], [x_min_per + (random.random()) * perspective_shreshold, y_max_per + (random.random()) * perspective_shreshold], [x_max_per + (random.random()) * perspective_shreshold, y_max_per - (random.random()) * perspective_shreshold]])) # right e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break else: while True: pts2 = np.around( np.float32([[x_min_per + (random.random()) * perspective_shreshold, y_min_per - (random.random()) * perspective_shreshold], [x_max_per + (random.random()) * perspective_shreshold, y_min_per + (random.random()) * perspective_shreshold], [x_min_per - (random.random()) * perspective_shreshold, y_max_per - (random.random()) * perspective_shreshold], [x_max_per - (random.random()) * perspective_shreshold, y_max_per + (random.random()) * perspective_shreshold]])) e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break else: while True: pts2 = np.around(np.float32([[x_min_per+(random.random()-0.5)perspective_shreshold, y_min_per+(random.random()-0.5)perspective_shreshold], [x_max_per+(random.random()-0.5)perspective_shreshold, y_min_per+(random.random()-0.5)perspective_shreshold], [x_min_per+(random.random()-0.5)perspective_shreshold, y_max_per+(random.random()-0.5)perspective_shreshold], [x_max_per+(random.random()-0.5)perspective_shreshold, y_max_per+(random.random()-0.5)perspective_shreshold]])) e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break M = cv2.getPerspectiveTransform(pts1, pts2) one = np.ones((self.new_shape[0], self.new_shape[1], 1), dtype=np.int16) matr = np.dstack((pixel_position, one)) new = np.dot(M, matr.reshape(-1, 3).T).T.reshape(self.new_shape[0], self.new_shape[1], 3) x = new[:, :, 0]/new[:, :, 2] y = new[:, :, 1]/new[:, :, 2] perturbed_xy_ = np.dstack((x, y)) # perturbed_xy_round_int = np.around(cv2.bilateralFilter(perturbed_xy_round_int, 9, 75, 75)) # perturbed_xy_round_int = np.around(cv2.blur(perturbed_xy_, (17, 17))) # perturbed_xy_round_int = cv2.blur(perturbed_xy_round_int, (17, 17)) # perturbed_xy_round_int = cv2.GaussianBlur(perturbed_xy_round_int, (7, 7), 0) perturbed_xy_ = perturbed_xy_-np.min(perturbed_xy_.T.reshape(2, -1), 1) # perturbed_xy_round_int = np.around(perturbed_xy_round_int-np.min(perturbed_xy_round_int.T.reshape(2, -1), 1)).astype(np.int16) self.perturbed_xy_ += perturbed_xy_ '''perspective end''' '''to img''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) # self.perturbed_xy_ = cv2.blur(self.perturbed_xy_, (7, 7)) self.perturbed_xy_ = cv2.GaussianBlur(self.perturbed_xy_, (7, 7), 0) '''get fiducial points''' fiducial_points_coordinate = self.perturbed_xy_[im_x, im_y] vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label self.foreORbackground_label = foreORbackground_label '''draw fiducial points stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_img.copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1,2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[1] + math.ceil(stepSize / 2), l[0] + math.ceil(stepSize / 2)), 5, (0, 0, 255), -1) cv2.imwrite('/lustre/home/gwxie/program/project/unwarp/unwarp_perturbed/TPS/img/cv_TPS_large.jpg', fiducial_points_synthesis_perturbed_img) ''' '''clip''' perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = -1, -1, self.new_shape[0], self.new_shape[1] for x in range(self.new_shape[0] // 2, perturbed_x_max): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and perturbed_x_max - 1 > x: perturbed_x_max = x break for x in range(self.new_shape[0] // 2, perturbed_x_min, -1): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and x > 0: perturbed_x_min = x break for y in range(self.new_shape[1] // 2, perturbed_y_max): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and perturbed_y_max - 1 > y: perturbed_y_max = y break for y in range(self.new_shape[1] // 2, perturbed_y_min, -1): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and y > 0: perturbed_y_min = y break if perturbed_x_min == 0 or perturbed_x_max == self.new_shape[0] or perturbed_y_min == self.new_shape[1] or perturbed_y_max == self.new_shape[1]: raise Exception('clip error') if perturbed_x_max - perturbed_x_min < im_lr//2 or perturbed_y_max - perturbed_y_min < im_ud//2: raise Exception('clip error') perfix_ = self.save_suffix+'_'+str(m)+'_'+str(n) is_shrink = False if perturbed_x_max - perturbed_x_min > save_img_shape[0] or perturbed_y_max - perturbed_y_min > save_img_shape[1]: is_shrink = True synthesis_perturbed_img = cv2.resize(self.synthesis_perturbed_img[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) synthesis_perturbed_label = cv2.resize(self.synthesis_perturbed_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) foreORbackground_label = cv2.resize(self.foreORbackground_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 '''shrink fiducial points''' center_x_l, center_y_l = perturbed_x_min + (perturbed_x_max - perturbed_x_min) // 2, perturbed_y_min + (perturbed_y_max - perturbed_y_min) // 2 fiducial_points_coordinate_copy = fiducial_points_coordinate.copy() shrink_x = im_lr/(perturbed_x_max - perturbed_x_min) shrink_y = im_ud/(perturbed_y_max - perturbed_y_min) fiducial_points_coordinate = [shrink_x, shrink_y] center_x_l = shrink_x center_y_l = shrink_y # fiducial_points_coordinate[1:, 1:] = [shrink_x, shrink_y] # fiducial_points_coordinate[1:, :1, 0] = shrink_x # fiducial_points_coordinate[:1, 1:, 1] = shrink_y # perturbed_x_min_copy, perturbed_y_min_copy, perturbed_x_max_copy, perturbed_y_max_copy = perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = self.adjust_position_v2(0, 0, im_lr, im_ud, self.new_shape) self.synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) self.synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) self.foreORbackground_label = np.zeros_like(self.foreORbackground_label) self.synthesis_perturbed_img[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_img self.synthesis_perturbed_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_label self.foreORbackground_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max] = foreORbackground_label center_x, center_y = perturbed_x_min + (perturbed_x_max - perturbed_x_min) // 2, perturbed_y_min + (perturbed_y_max - perturbed_y_min) // 2 if is_shrink: fiducial_points_coordinate += [center_x-center_x_l, center_y-center_y_l] '''draw fiducial points stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_img.copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1, 2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[1] + math.ceil(stepSize / 2), l[0] + math.ceil(stepSize / 2)), 5, (0, 0, 255), -1) cv2.imwrite('/lustre/home/gwxie/program/project/unwarp/unwarp_perturbed/TPS/img/cv_TPS_small.jpg',fiducial_points_synthesis_perturbed_img) ''' self.new_shape = save_img_shape self.synthesis_perturbed_img = self.synthesis_perturbed_img[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2, :].copy() self.synthesis_perturbed_label = self.synthesis_perturbed_label[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2, :].copy() self.foreORbackground_label = self.foreORbackground_label[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2].copy() perturbed_x_ = max(self.new_shape[0] - (perturbed_x_max - perturbed_x_min), 0) perturbed_x_min = perturbed_x_ // 2 perturbed_x_max = self.new_shape[0] - perturbed_x_ // 2 if perturbed_x_%2 == 0 else self.new_shape[0] - (perturbed_x_ // 2 + 1) perturbed_y_ = max(self.new_shape[1] - (perturbed_y_max - perturbed_y_min), 0) perturbed_y_min = perturbed_y_ // 2 perturbed_y_max = self.new_shape[1] - perturbed_y_ // 2 if perturbed_y_%2 == 0 else self.new_shape[1] - (perturbed_y_ // 2 + 1) '''clip perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = -1, -1, self.new_shape[0], self.new_shape[1] for x in range(self.new_shape[0] // 2, perturbed_x_max): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and perturbed_x_max - 1 > x: perturbed_x_max = x break for x in range(self.new_shape[0] // 2, perturbed_x_min, -1): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and x > 0: perturbed_x_min = x break for y in range(self.new_shape[1] // 2, perturbed_y_max): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and perturbed_y_max - 1 > y: perturbed_y_max = y break for y in range(self.new_shape[1] // 2, perturbed_y_min, -1): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and y > 0: perturbed_y_min = y break center_x, center_y = perturbed_x_min+(perturbed_x_max - perturbed_x_min)//2, perturbed_y_min+(perturbed_y_max - perturbed_y_min)//2 perfix_ = self.save_suffix+'_'+str(m)+'_'+str(n) self.new_shape = save_img_shape perturbed_x_ = max(self.new_shape[0] - (perturbed_x_max - perturbed_x_min), 0) perturbed_x_min = perturbed_x_ // 2 perturbed_x_max = self.new_shape[0] - perturbed_x_ // 2 if perturbed_x_%2 == 0 else self.new_shape[0] - (perturbed_x_ // 2 + 1) perturbed_y_ = max(self.new_shape[1] - (perturbed_y_max - perturbed_y_min), 0) perturbed_y_min = perturbed_y_ // 2 perturbed_y_max = self.new_shape[1] - perturbed_y_ // 2 if perturbed_y_%2 == 0 else self.new_shape[1] - (perturbed_y_ // 2 + 1) self.synthesis_perturbed_img = self.synthesis_perturbed_img[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2, :].copy() self.synthesis_perturbed_label = self.synthesis_perturbed_label[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2, :].copy() self.foreORbackground_label = self.foreORbackground_label[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2].copy() ''' '''save''' pixel_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape(self.new_shape[0], self.new_shape[1], 2) if relativeShift_position == 'relativeShift_v2': self.synthesis_perturbed_label -= pixel_position fiducial_points_coordinate -= [center_x - self.new_shape[0] // 2, center_y - self.new_shape[1] // 2] self.synthesis_perturbed_label[:, :, 0] = self.foreORbackground_label self.synthesis_perturbed_label[:, :, 1] = self.foreORbackground_label self.synthesis_perturbed_img[:, :, 0] = self.foreORbackground_label self.synthesis_perturbed_img[:, :, 1] = self.foreORbackground_label self.synthesis_perturbed_img[:, :, 2] = self.foreORbackground_label ''' synthesis_perturbed_img_filter = self.synthesis_perturbed_img.copy() synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (3, 3), 0) # if self.is_perform(0.9, 0.1) or repeat_time > 5: # # if self.is_perform(0.1, 0.9) and repeat_time > 9: # # synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (7, 7), 0) # # else: # synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (5, 5), 0) # else: # synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (3, 3), 0) self.synthesis_perturbed_img[self.foreORbackground_label == 1] = synthesis_perturbed_img_filter[self.foreORbackground_label == 1] ''' ''' perturbed_bg_img = perturbed_bg_img.astype(np.float32) perturbed_bg_img[:, :, 0] = 1 - self.foreORbackground_label perturbed_bg_img[:, :, 1] = 1 - self.foreORbackground_label perturbed_bg_img[:, :, 2] = 1 - self.foreORbackground_label self.synthesis_perturbed_img += perturbed_bg_img HSV perturbed_bg_img = perturbed_bg_img.astype(np.float32) if self.is_perform(0.1, 0.9): if self.is_perform(0.2, 0.8): synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_RGB2HSV) H_, S_, V_ = (random.random()-0.2)20, (random.random()-0.2)/8, (random.random()-0.2)20 synthesis_perturbed_img_clip_HSV[:, :, 0], synthesis_perturbed_img_clip_HSV[:, :, 1], synthesis_perturbed_img_clip_HSV[:, :, 2] = synthesis_perturbed_img_clip_HSV[:, :, 0]-H_, synthesis_perturbed_img_clip_HSV[:, :, 1]-S_, synthesis_perturbed_img_clip_HSV[:, :, 2]-V_ synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_HSV2RGB) perturbed_bg_img[:, :, 0] = 1-self.foreORbackground_label perturbed_bg_img[:, :, 1] = 1-self.foreORbackground_label perturbed_bg_img[:, :, 2] = 1-self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV else: perturbed_bg_img_HSV = perturbed_bg_img perturbed_bg_img_HSV = cv2.cvtColor(perturbed_bg_img_HSV, cv2.COLOR_RGB2HSV) H_, S_, V_ = (random.random()-0.5)20, (random.random()-0.5)/8, (random.random()-0.2)20 perturbed_bg_img_HSV[:, :, 0], perturbed_bg_img_HSV[:, :, 1], perturbed_bg_img_HSV[:, :, 2] = perturbed_bg_img_HSV[:, :, 0]-H_, perturbed_bg_img_HSV[:, :, 1]-S_, perturbed_bg_img_HSV[:, :, 2]-V_ perturbed_bg_img_HSV = cv2.cvtColor(perturbed_bg_img_HSV, cv2.COLOR_HSV2RGB) perturbed_bg_img_HSV[:, :, 0] = 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 1] = 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 2] = 1-self.foreORbackground_label self.synthesis_perturbed_img += perturbed_bg_img_HSV # self.synthesis_perturbed_img[np.sum(self.synthesis_perturbed_img, 2) == 771] = perturbed_bg_img_HSV[np.sum(self.synthesis_perturbed_img, 2) == 771] else: synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() perturbed_bg_img[:, :, 0] = 1 - self.foreORbackground_label perturbed_bg_img[:, :, 1] = 1 - self.foreORbackground_label perturbed_bg_img[:, :, 2] = 1 - self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img # synthesis_perturbed_img_clip_HSV[np.sum(self.synthesis_perturbed_img, 2) == 771] = perturbed_bg_img[np.sum(self.synthesis_perturbed_img, 2) == 771] synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_RGB2HSV) H_, S_, V_ = (random.random()-0.5)20, (random.random()-0.5)/10, (random.random()-0.4)20 synthesis_perturbed_img_clip_HSV[:, :, 0], synthesis_perturbed_img_clip_HSV[:, :, 1], synthesis_perturbed_img_clip_HSV[:, :, 2] = synthesis_perturbed_img_clip_HSV[:, :, 0]-H_, synthesis_perturbed_img_clip_HSV[:, :, 1]-S_, synthesis_perturbed_img_clip_HSV[:, :, 2]-V_ synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_HSV2RGB) self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV ''' '''HSV_v2''' perturbed_bg_img = perturbed_bg_img.astype(np.float32) # if self.is_perform(1, 0): # if self.is_perform(1, 0): if self.is_perform(0.1, 0.9): if self.is_perform(0.2, 0.8): synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() synthesis_perturbed_img_clip_HSV = self.HSV_v1(synthesis_perturbed_img_clip_HSV) perturbed_bg_img[:, :, 0] = 1-self.foreORbackground_label perturbed_bg_img[:, :, 1] = 1-self.foreORbackground_label perturbed_bg_img[:, :, 2] = 1-self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV else: perturbed_bg_img_HSV = perturbed_bg_img perturbed_bg_img_HSV = self.HSV_v1(perturbed_bg_img_HSV) perturbed_bg_img_HSV[:, :, 0] = 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 1] = 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 2] = 1-self.foreORbackground_label self.synthesis_perturbed_img += perturbed_bg_img_HSV # self.synthesis_perturbed_img[np.sum(self.synthesis_perturbed_img, 2) == 771] = perturbed_bg_img_HSV[np.sum(self.synthesis_perturbed_img, 2) == 771] else: synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() perturbed_bg_img[:, :, 0] = 1 - self.foreORbackground_label perturbed_bg_img[:, :, 1] = 1 - self.foreORbackground_label perturbed_bg_img[:, :, 2] = 1 - self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img synthesis_perturbed_img_clip_HSV = self.HSV_v1(synthesis_perturbed_img_clip_HSV) self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV '''''' # cv2.imwrite(self.save_path+'clip/'+perfix_+'_'+fold_curve+str(perturbed_time)+'-'+str(repeat_time)+'.png', synthesis_perturbed_img_clip) self.synthesis_perturbed_img[self.synthesis_perturbed_img < 0] = 0 self.synthesis_perturbed_img[self.synthesis_perturbed_img > 255] = 255 self.synthesis_perturbed_img = np.around(self.synthesis_perturbed_img).astype(np.uint8) label = np.zeros_like(self.synthesis_perturbed_img, dtype=np.float32) label[:, :, :2] = self.synthesis_perturbed_label label[:, :, 2] = self.foreORbackground_label # grey = np.around(self.synthesis_perturbed_img[:, :, 0] * 0.2989 + self.synthesis_perturbed_img[:, :, 1] * 0.5870 + self.synthesis_perturbed_img[:, :, 0] * 0.1140).astype(np.int16) # synthesis_perturbed_grey = np.concatenate((grey.reshape(self.new_shape[0], self.new_shape[1], 1), label), axis=2) synthesis_perturbed_color =	np.concatenate((self.synthesis_perturbed_img, label), axis=2)	numpy.concatenate
''' <NAME> set up :2020-1-9 intergrate img and label into one file -- fiducial1024_v1 ''' import argparse import sys, os import pickle import random import collections import json import numpy as np import scipy.io as io import scipy.misc as m import matplotlib.pyplot as plt import glob import math import time import threading import multiprocessing as mp from multiprocessing import Pool import re import cv2 # sys.path.append('/lustre/home/gwxie/hope/project/dewarp/datasets/') # /lustre/home/gwxie/program/project/unwarp/perturbed_imgaes/GAN import utils def getDatasets(dir): return os.listdir(dir) class perturbed(utils.BasePerturbed): def __init__(self, path, bg_path, save_path, save_suffix): self.path = path self.bg_path = bg_path self.save_path = save_path self.save_suffix = save_suffix def save_img(self, m, n, fold_curve='fold', repeat_time=4, fiducial_points = 16, relativeShift_position='relativeShift_v2'): origin_img = cv2.imread(self.path, flags=cv2.IMREAD_COLOR) save_img_shape = [5122, 4802] # 320 # reduce_value = np.random.choice([24, 25, 26, 27, 2*8], p=[0.01, 0.1, 0.4, 0.39, 0.1]) reduce_value = np.random.choice([22, 42, 82, 162, 242, 322, 402, 482], p=[0.02, 0.18, 0.2, 0.3, 0.1, 0.1, 0.08, 0.02]) # reduce_value = np.random.choice([82, 162, 242, 322, 402, 482], p=[0.01, 0.02, 0.2, 0.4, 0.19, 0.18]) # reduce_value = np.random.choice([16, 24, 32, 40, 48, 64], p=[0.01, 0.1, 0.2, 0.4, 0.2, 0.09]) base_img_shrink = save_img_shape[0] - reduce_value # enlarge_img_shrink = [1024, 768] # enlarge_img_shrink = [896, 672] # 420 enlarge_img_shrink = [5124, 4804] # 420 # enlarge_img_shrink = [8962, 7682] # 420 # enlarge_img_shrink = [896, 768] # 420 # enlarge_img_shrink = [768, 576] # 420 # enlarge_img_shrink = [640, 480] # 420 '''''' im_lr = origin_img.shape[0] im_ud = origin_img.shape[1] reduce_value_v2 = np.random.choice([22, 42, 82, 162, 242, 282, 322, 482], p=[0.02, 0.18, 0.2, 0.2, 0.1, 0.1, 0.1, 0.1]) # reduce_value_v2 = np.random.choice([16, 24, 28, 32, 48, 64], p=[0.01, 0.1, 0.2, 0.3, 0.25, 0.14]) if im_lr > im_ud: im_ud = min(int(im_ud / im_lr base_img_shrink), save_img_shape[1] - reduce_value_v2) im_lr = save_img_shape[0] - reduce_value else: base_img_shrink = save_img_shape[1] - reduce_value im_lr = min(int(im_lr / im_ud * base_img_shrink), save_img_shape[0] - reduce_value_v2) im_ud = base_img_shrink if round(im_lr / im_ud, 2) < 0.5 or round(im_ud / im_lr, 2) < 0.5: repeat_time = min(repeat_time, 8) edge_padding = 3 im_lr -= im_lr % (fiducial_points-1) - (2edge_padding) # im_lr % (fiducial_points-1) - 1 im_ud -= im_ud % (fiducial_points-1) - (2edge_padding) # im_ud % (fiducial_points-1) - 1 im_hight = np.linspace(edge_padding, im_lr - edge_padding, fiducial_points, dtype=np.int64) im_wide = np.linspace(edge_padding, im_ud - edge_padding, fiducial_points, dtype=np.int64) # im_lr -= im_lr % (fiducial_points-1) - (1+2edge_padding) # im_lr % (fiducial_points-1) - 1 # im_ud -= im_ud % (fiducial_points-1) - (1+2edge_padding) # im_ud % (fiducial_points-1) - 1 # im_hight = np.linspace(edge_padding, im_lr - (1+edge_padding), fiducial_points, dtype=np.int64) # im_wide = np.linspace(edge_padding, im_ud - (1+edge_padding), fiducial_points, dtype=np.int64) im_x, im_y = np.meshgrid(im_hight, im_wide) segment_x = (im_lr) // (fiducial_points-1) segment_y = (im_ud) // (fiducial_points-1) # plt.plot(im_x, im_y, # color='limegreen', # marker='.', # linestyle='') # plt.grid(True) # plt.show() self.origin_img = cv2.resize(origin_img, (im_ud, im_lr), interpolation=cv2.INTER_CUBIC) perturbed_bg_ = getDatasets(self.bg_path) perturbed_bg_img_ = self.bg_path+random.choice(perturbed_bg_) perturbed_bg_img = cv2.imread(perturbed_bg_img_, flags=cv2.IMREAD_COLOR) mesh_shape = self.origin_img.shape[:2] self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 256, dtype=np.float32)#np.zeros_like(perturbed_bg_img) # self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 0, dtype=np.int16)#np.zeros_like(perturbed_bg_img) self.new_shape = self.synthesis_perturbed_img.shape[:2] perturbed_bg_img = cv2.resize(perturbed_bg_img, (save_img_shape[1], save_img_shape[0]), cv2.INPAINT_TELEA) origin_pixel_position = np.argwhere(np.zeros(mesh_shape, dtype=np.uint32) == 0).reshape(mesh_shape[0], mesh_shape[1], 2) pixel_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape(self.new_shape[0], self.new_shape[1], 2) self.perturbed_xy_ = np.zeros((self.new_shape[0], self.new_shape[1], 2)) # self.perturbed_xy_ = pixel_position.copy().astype(np.float32) # fiducial_points_grid = origin_pixel_position[im_x, im_y] self.synthesis_perturbed_label = np.zeros((self.new_shape[0], self.new_shape[1], 2)) x_min, y_min, x_max, y_max = self.adjust_position_v2(0, 0, mesh_shape[0], mesh_shape[1], save_img_shape) origin_pixel_position += [x_min, y_min] x_min, y_min, x_max, y_max = self.adjust_position(0, 0, mesh_shape[0], mesh_shape[1]) x_shift = random.randint(-enlarge_img_shrink[0]//16, enlarge_img_shrink[0]//16) y_shift = random.randint(-enlarge_img_shrink[1]//16, enlarge_img_shrink[1]//16) x_min += x_shift x_max += x_shift y_min += y_shift y_max += y_shift '''im_x,y''' im_x += x_min im_y += y_min self.synthesis_perturbed_img[x_min:x_max, y_min:y_max] = self.origin_img self.synthesis_perturbed_label[x_min:x_max, y_min:y_max] = origin_pixel_position synthesis_perturbed_img_map = self.synthesis_perturbed_img.copy() synthesis_perturbed_label_map = self.synthesis_perturbed_label.copy() foreORbackground_label = np.full((mesh_shape), 1, dtype=np.int16) foreORbackground_label_map = np.full((self.new_shape), 0, dtype=np.int16) foreORbackground_label_map[x_min:x_max, y_min:y_max] = foreORbackground_label # synthesis_perturbed_img_map = self.pad(self.synthesis_perturbed_img.copy(), x_min, y_min, x_max, y_max) # synthesis_perturbed_label_map = self.pad(synthesis_perturbed_label_map, x_min, y_min, x_max, y_max) '''****************************************************************''' is_normalizationFun_mixture = self.is_perform(0.2, 0.8) # if not is_normalizationFun_mixture: normalizationFun_0_1 = False # normalizationFun_0_1 = self.is_perform(0.5, 0.5) if fold_curve == 'fold': fold_curve_random = True # is_normalizationFun_mixture = False normalizationFun_0_1 = self.is_perform(0.2, 0.8) if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: fold_curve_random = self.is_perform(0.1, 0.9) # False # self.is_perform(0.01, 0.99) alpha_perturbed = random.randint(80, 160) / 100 # is_normalizationFun_mixture = False # self.is_perform(0.01, 0.99) synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) # synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 0, dtype=np.int16) synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) alpha_perturbed_change = self.is_perform(0.5, 0.5) p_pp_choice = self.is_perform(0.8, 0.2) if fold_curve == 'fold' else self.is_perform(0.1, 0.9) for repeat_i in range(repeat_time): if alpha_perturbed_change: if fold_curve == 'fold': if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: alpha_perturbed = random.randint(80, 160) / 100 '''''' linspace_x = [0, (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - 1] linspace_y = [0, (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - 1] linspace_x_seq = [1, 2, 3] linspace_y_seq = [1, 2, 3] r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_p = np.array( [random.randint(linspace_x[r_x-1] 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 if ((r_x == 1 or r_x == 3) and (r_y == 1 or r_y == 3)) and p_pp_choice: linspace_x_seq.remove(r_x) linspace_y_seq.remove(r_y) r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_pp = np.array( [random.randint(linspace_x[r_x-1] * 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 # perturbed_p, perturbed_pp = np.array( # [random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) \ # , np.array([random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) # perturbed_p, perturbed_pp = np.array( # [random.randint((self.new_shape[0]-im_lr)//210, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) 10) / 10, # random.randint((self.new_shape[1]-im_ud)//210, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) 10) / 10]) \ # , np.array([random.randint((self.new_shape[0]-im_lr)//210, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) 10) / 10, # random.randint((self.new_shape[1]-im_ud)//210, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) 10) / 10]) '''''' perturbed_vp = perturbed_pp - perturbed_p perturbed_vp_norm = np.linalg.norm(perturbed_vp) perturbed_distance_vertex_and_line = np.dot((perturbed_p - pixel_position), perturbed_vp) / perturbed_vp_norm '''''' # perturbed_v = np.array([random.randint(-3000, 3000) / 100, random.randint(-3000, 3000) / 100]) # perturbed_v = np.array([random.randint(-4000, 4000) / 100, random.randint(-4000, 4000) / 100]) if fold_curve == 'fold' and self.is_perform(0.6, 0.4): # self.is_perform(0.3, 0.7): # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) perturbed_v = np.array([random.randint(-10000, 10000) / 100, random.randint(-10000, 10000) / 100]) # perturbed_v = np.array([random.randint(-11000, 11000) / 100, random.randint(-11000, 11000) / 100]) else: # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) # perturbed_v = np.array([random.randint(-16000, 16000) / 100, random.randint(-16000, 16000) / 100]) perturbed_v = np.array([random.randint(-8000, 8000) / 100, random.randint(-8000, 8000) / 100]) # perturbed_v = np.array([random.randint(-3500, 3500) / 100, random.randint(-3500, 3500) / 100]) # perturbed_v = np.array([random.randint(-600, 600) / 10, random.randint(-600, 600) / 10]) '''''' if fold_curve == 'fold': if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) '''''' if fold_curve_random: # omega_perturbed = (alpha_perturbed+0.2) / (perturbed_d + alpha_perturbed) # omega_perturbed = alpha_perturbedperturbed_d omega_perturbed = alpha_perturbed / (perturbed_d + alpha_perturbed) else: omega_perturbed = 1 - perturbed_d alpha_perturbed '''shadow''' if self.is_perform(0.6, 0.4): synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] = np.minimum(np.maximum(synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] - np.int16(np.round(omega_perturbed[x_min:x_max, y_min:y_max].repeat(3).reshape(x_max-x_min, y_max-y_min, 3) * abs(np.linalg.norm(perturbed_v//2))np.array([0.4-random.random()0.1, 0.4-random.random()0.1, 0.4-random.random()0.1]))), 0), 255) '''''' if relativeShift_position in ['position', 'relativeShift_v2']: self.perturbed_xy_ += np.array([omega_perturbed * perturbed_v[0], omega_perturbed * perturbed_v[1]]).transpose(1, 2, 0) else: print('relativeShift_position error') exit() ''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 # synthesis_perturbed_img = np.around(synthesis_perturbed_img).astype(np.uint8) synthesis_perturbed_label[:, :, 0] = foreORbackground_label synthesis_perturbed_label[:, :, 1] = foreORbackground_label synthesis_perturbed_img[:, :, 0] = foreORbackground_label synthesis_perturbed_img[:, :, 1] = foreORbackground_label synthesis_perturbed_img[:, :, 2] = foreORbackground_label self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label ''' '''perspective''' perspective_shreshold = random.randint(26, 36)10 # 280 x_min_per, y_min_per, x_max_per, y_max_per = self.adjust_position(perspective_shreshold, perspective_shreshold, self.new_shape[0]-perspective_shreshold, self.new_shape[1]-perspective_shreshold) pts1 =	np.float32([[x_min_per, y_min_per], [x_max_per, y_min_per], [x_min_per, y_max_per], [x_max_per, y_max_per]])	numpy.float32
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) +	np.cos(5 * time)	numpy.cos
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] *	np.ones(101)	numpy.ones
############################################################################### # @todo add Pilot2-splash-app disclaimer ############################################################################### """ Get's KRAS states """ import MDAnalysis as mda from MDAnalysis.analysis import align from MDAnalysis.lib.mdamath import make_whole import os import numpy as np import math ############## Below section needs to be uncommented ############ import mummi_core import mummi_ras from mummi_core.utils import Naming # # Logger has to be initialized the first thing in the script from logging import getLogger LOGGER = getLogger(__name__) # # Innitilize MuMMI if it has not been done before # MUMMI_ROOT = mummi.init(True) # This is needed so the Naming works below #@TODO fix this so we don't have these on import make them as an init mummi_core.init() dirKRASStates = Naming.dir_res('states') dirKRASStructures = Naming.dir_res('structures') # #RAS_ONLY_macrostate = np.loadtxt(os.path.join(dirKRASStates, "RAS-ONLY.microstates.txt")) RAS_ONLY_macrostate = np.loadtxt(os.path.join(dirKRASStates, "ras-states.txt"),comments='#') # #RAS_RAF_macrostate = np.loadtxt(os.path.join(dirKRASStates, "RAS-RAF.microstates.txt")) RAS_RAF_macrostate = np.loadtxt(os.path.join(dirKRASStates, "ras-raf-states.txt"),comments='#') # Note diffrent number of columns so index change below # TODO: CS, my edits to test # RAS_ONLY_macrostate = np.loadtxt('ras-states.txt') # RAS_RAF_macrostate = np.loadtxt('ras-raf-states.txt') ############## above section needs to be uncommented ############ # TODO: CS, my edits to test # TODO: TSC, The reference structure has to currently be set as the 'RAS-ONLY-reference-structure.gro' # TODO: TSC, path to the reference structure is: mummi_resources/structures/ kras_ref_universe = mda.Universe(os.path.join(dirKRASStructures, "RAS-ONLY-reference-structure.gro")) # kras_ref_universe = mda.Universe("RAS-ONLY-reference-structure.gro") # kras_ref_universe = mda.Universe('AA_pfpatch_000000004641_RAS_RAF2_411.gro') # TODO: CS, not using these for x4 proteins; instead using protein_systems below to set num_res ######### Below hard codes the number of residues within RAS-only and RAS-RAF ########## RAS_only_num_res = 184 RAS_RAF_num_res = 320 ######### Above hard codes the number of residues within RAS-only and RAS-RAF ########## ####### This can be removed # def get_kras(syst, kras_start): # """Gets all atoms for a KRAS protein starting at 'kras_start'.""" # return syst.atoms[kras_start:kras_start+428] ####### This can be removed def get_segids(u): """Identifies the list of segments within the system. Only needs to be called x1 time""" segs = u.segments segs = segs.segids ras_segids = [] rasraf_segids = [] for i in range(len(segs)): # print(segs[i]) if segs[i][-3:] == 'RAS': ras_segids.append(segs[i]) if segs[i][-3:] == 'RAF': rasraf_segids.append(segs[i]) return ras_segids, rasraf_segids def get_protein_info(u,tag): """Uses the segments identified in get_segids to make a list of all proteins in the systems.\ Outputs a list of the first residue number of the protein, and whether it is 'RAS-ONLY', or 'RAS-RAF'.\ The 'tag' input defines what is used to identify the first residue of the protein. i.e. 'resname ACE1 and name BB'.\ Only needs to be called x1 time""" ras_segids, rasraf_segids = get_segids(u) if len(ras_segids) > 0: RAS = u.select_atoms('segid '+ras_segids[0]+' and '+str(tag)) else: RAS = [] if len(rasraf_segids) > 0: RAF = u.select_atoms('segid '+rasraf_segids[0]+' and '+str(tag)) else: RAF = [] protein_info = []#np.empty([len(RAS)+len(RAF),2]) for i in range(len(RAS)): protein_info.append((RAS[i].resid,'RAS-ONLY')) for i in range(len(RAF)): protein_info.append((RAF[i].resid,'RAS-RAF')) ######## sort protein info protein_info = sorted(protein_info) ######## sort protein info return protein_info def get_ref_kras(): """Gets the reference KRAS struct. Only called x1 time when class is loaded""" start_of_g_ref = kras_ref_universe.residues[0].resid ref_selection = 'resid '+str(start_of_g_ref)+':'+str(start_of_g_ref+24)+' ' +\ str(start_of_g_ref+38)+':'+str(start_of_g_ref+54)+' ' +\ str(start_of_g_ref+67)+':'+str(start_of_g_ref+164)+' ' +\ 'and (name CA or name BB)' r2_26r40_56r69_166_ref = kras_ref_universe.select_atoms(str(ref_selection)) return kras_ref_universe.select_atoms(str(ref_selection)).positions - kras_ref_universe.select_atoms(str(ref_selection)).center_of_mass() # Load inital ref frames (only need to do this once) ref0 = get_ref_kras() def getKRASstates(u,kras_indices): """Gets states for all KRAS proteins in path.""" # res_shift = 8 # all_glycine = u.select_atoms("resname GLY") # kras_indices = [] # for i in range(0, len(all_glycine), 26): # kras_indices.append(all_glycine[i].index) ########## Below is taken out of the function so it is only done once ######### # kras_indices = get_protein_info(u,'resname ACE1 and name BB') ########## Above is taken out of the function so it is only done once ######### # CS, for x4 cases: # [{protein_x4: (protein_type, num_res)}] protein_systems = [{'ras4a': ('RAS-ONLY', 185), 'ras4araf': ('RAS-RAF', 321), 'ras': ('RAS-ONLY', 184), 'rasraf': ('RAS-RAF', 320)}] ALLOUT = [] for k in range(len(kras_indices)): start_of_g = kras_indices[k][0] protein_x4 = str(kras_indices[k][1]) try: protein_type = [item[protein_x4] for item in protein_systems][0][0] # 'RAS-ONLY' OR 'RAS-RAF' num_res = [item[protein_x4] for item in protein_systems][0][1] except: LOGGER.error('Check KRas naming between modules') raise Exception('Error: unknown KRas name') # TODO: CS, replacing this comment section with the above, to handle x4 protein types # --------------------------------------- # ALLOUT = [] # for k in range(len(kras_indices)): # start_of_g = kras_indices[k][0] # protein_type = str(kras_indices[k][1]) # ########## BELOW SECTION TO DETERMINE WHICH RESIDUES ARE PART OF THE PROTEIN GROUP - NEEDED FOR PBC REMOVAL ############## # ########## POTENTIALLY REDO WITH A 'HARD-CODED' NUMBER OF RESIDUES PER PROTEIN GROUP (WHETHER RAS-ONLY OR RAS-RAF) ####### # ########## HAS BEEN REDONE WITH A 'HARD-CODED' NUMBER OF RESIDUES PER PROTEIN GROUP (WHETHER RAS-ONLY OR RAS-RAF) ######## # # if len(kras_indices) == 1: # # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(len(u.residues))+' and name BB') ####### HAS TO BE FIXED FOR BACKBONE ATOMS FOR SPECIFIC PROTEIN # # elif len(kras_indices) > 1: # # if k == len(kras_indices)-1: # # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(len(u.residues))+' and name BB') # # else: # # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(kras_indices[k+1][0])+' and name BB') # ########## ABOVE SECTION TO DETERMINE WHICH RESIDUES ARE PART OF THE PROTEIN GROUP - NEEDED FOR PBC REMOVAL ############## # # ########## Below hard codes the number of residues/beads in the RAS-ONLY and RAS-RAF simulations ######################### # if protein_type == 'RAS-ONLY': # num_res = RAS_only_num_res # elif protein_type == 'RAS-RAF': # num_res = RAS_RAF_num_res # ########## Above hard codes the number of residues/beads in the RAS-ONLY and RAS-RAF simulations ######################### # --------------------------------------- # TODO: TSC, I changed the selection below, which can be used for the make_whole... # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(start_of_g+num_res)+' and (name CA or name BB)') krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(start_of_g+num_res)) krases0_BB.guess_bonds() r2_26r40_56r69_166 = u.select_atoms('resid '+str(start_of_g)+':'+str(start_of_g+24)+' ' +\ str(start_of_g+38)+':'+str(start_of_g+54)+' ' +\ str(start_of_g+67)+':'+str(start_of_g+164)+\ ' and (name CA or name BB)') u_selection = \ 'resid '+str(start_of_g)+':'+str(start_of_g+24)+' '+str(start_of_g+38)+':'+str(start_of_g+54)+' ' +\ str(start_of_g+67)+':'+str(start_of_g+164)+' and (name CA or name BB)' mobile0 = u.select_atoms(str(u_selection)).positions - u.select_atoms(str(u_selection)).center_of_mass() # TODO: CS, something wrong with ref0 from get_kras_ref() # just making ref0 = mobile0 to test for now # ref0 = mobile0 # TSC removed this R, RMSD_junk = align.rotation_matrix(mobile0, ref0) ######## TODO: TSC, Adjusted for AA lipid names ######## # lipids = u.select_atoms('resname POPX POPC PAPC POPE DIPE DPSM PAPS PAP6 CHOL') lipids = u.select_atoms('resname POPC PAPC POPE DIPE SSM PAPS SAPI CHL1') coords = ref0 RotMat = [] OS = [] r152_165 = krases0_BB.select_atoms('resid '+str(start_of_g+150)+':'+str(start_of_g+163)+' and (name CA or name BB)') r65_74 = krases0_BB.select_atoms('resid '+str(start_of_g+63)+':'+str(start_of_g+72)+' and (name CA or name BB)') timeframes = [] # TODO: CS, for AA need bonds to run make_whole() # krases0_BB.guess_bonds() # TODO: CS, turn off for now to test beyond this point ''' * for AA, need to bring that back on once all else runs * ''' # @Tim and <NAME>. this was commented out - please check. #make_whole(krases0_BB) j, rmsd_junk = mda.analysis.align.rotation_matrix((r2_26r40_56r69_166.positions-r2_26r40_56r69_166.center_of_mass()), coords) RotMat.append(j) OS.append(r65_74.center_of_mass()-r152_165.center_of_mass()) timeframes.append(u.trajectory.time) if protein_type == 'RAS-RAF': z_pos = [] ############### NEED TO CONFIRM THE SELECTION OF THE RAF LOOP RESIDUES BELOW #################### ############### TODO: TSC, zshifting is set to -1 (instead of -2), as there are ACE caps that are separate residues in AA #zshifting=-1 if protein_x4 == 'rasraf': zshifting = -1 elif protein_x4 == 'ras4araf': zshifting = 0 else: zshifting = 0 LOGGER.error('Found unsupported protein_x4 type') raf_loops_selection = u.select_atoms('resid '+str(start_of_g+zshifting+291)+':'+str(start_of_g+zshifting+294)+' ' +\ str(start_of_g+zshifting+278)+':'+str(start_of_g+zshifting+281)+' ' +\ ' and (name CA or name BB)') ############### NEED TO CONFIRM THE SELECTION OF THE RAF LOOP RESIDUES ABOVE #################### diff = (lipids.center_of_mass()[2]-raf_loops_selection.center_of_mass(unwrap=True)[2])/10 if diff < 0: diff = diff+(u.dimensions[2]/10) z_pos.append(diff) z_pos = np.array(z_pos) RotMatNP = np.array(RotMat) OS = np.array(OS) OA = RotMatNP[:, 2, :]/(((RotMatNP[:, 2, 0]2)+(RotMatNP[:, 2, 1]2)+(RotMatNP[:, 2, 2]2))0.5)[:, None] OWAS = np.arccos(RotMatNP[:, 2, 2])180/math.pi OC_temp = np.concatenate((OA, OS), axis=1) t = ((OC_temp[:, 0]OC_temp[:, 3])+(OC_temp[:, 1]OC_temp[:, 4]) + (OC_temp[:, 2]OC_temp[:, 5]))/((OC_temp[:, 0]2)+(OC_temp[:, 1]2)+(OC_temp[:, 2]*2)) OC = OAt[:, None] ORS_tp = np.concatenate((OC, OS), axis=1) ORS_norm = (((ORS_tp[:, 3]-ORS_tp[:, 0])2)+((ORS_tp[:, 4]-ORS_tp[:, 1])2)+((ORS_tp[:, 5]-ORS_tp[:, 2])2))0.5 ORS = (OS - OC)/ORS_norm[:, None] OACRS =	np.cross(OA, ORS)	numpy.cross
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y =	np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101)	numpy.linspace
from abc import ABCMeta, abstractmethod import os from vmaf.tools.misc import make_absolute_path, run_process from vmaf.tools.stats import ListStats __copyright__ = "Copyright 2016-2018, Netflix, Inc." __license__ = "Apache, Version 2.0" import re import numpy as np import ast from vmaf import ExternalProgramCaller, to_list from vmaf.config import VmafConfig, VmafExternalConfig from vmaf.core.executor import Executor from vmaf.core.result import Result from vmaf.tools.reader import YuvReader class FeatureExtractor(Executor): """ FeatureExtractor takes in a list of assets, and run feature extraction on them, and return a list of corresponding results. A FeatureExtractor must specify a unique type and version combination (by the TYPE and VERSION attribute), so that the Result generated by it can be identified. A derived class of FeatureExtractor must: 1) Override TYPE and VERSION 2) Override _generate_result(self, asset), which call a command-line executable and generate feature scores in a log file. 3) Override _get_feature_scores(self, asset), which read the feature scores from the log file, and return the scores in a dictionary format. For an example, follow VmafFeatureExtractor. """ __metaclass__ = ABCMeta @property @abstractmethod def ATOM_FEATURES(self): raise NotImplementedError def _read_result(self, asset): result = {} result.update(self._get_feature_scores(asset)) executor_id = self.executor_id return Result(asset, executor_id, result) @classmethod def get_scores_key(cls, atom_feature): return "{type}_{atom_feature}_scores".format( type=cls.TYPE, atom_feature=atom_feature) @classmethod def get_score_key(cls, atom_feature): return "{type}_{atom_feature}_score".format( type=cls.TYPE, atom_feature=atom_feature) def _get_feature_scores(self, asset): # routine to read the feature scores from the log file, and return # the scores in a dictionary format. log_file_path = self._get_log_file_path(asset) atom_feature_scores_dict = {} atom_feature_idx_dict = {} for atom_feature in self.ATOM_FEATURES: atom_feature_scores_dict[atom_feature] = [] atom_feature_idx_dict[atom_feature] = 0 with open(log_file_path, 'rt') as log_file: for line in log_file.readlines(): for atom_feature in self.ATOM_FEATURES: re_template = "{af}: ([0-9]+) ([a-zA-Z0-9.-]+)".format(af=atom_feature) mo = re.match(re_template, line) if mo: cur_idx = int(mo.group(1)) assert cur_idx == atom_feature_idx_dict[atom_feature] # parse value, allowing NaN and inf val = float(mo.group(2)) if np.isnan(val) or np.isinf(val): val = None atom_feature_scores_dict[atom_feature].append(val) atom_feature_idx_dict[atom_feature] += 1 continue len_score = len(atom_feature_scores_dict[self.ATOM_FEATURES[0]]) assert len_score != 0 for atom_feature in self.ATOM_FEATURES[1:]: assert len_score == len(atom_feature_scores_dict[atom_feature]), \ "Feature data possibly corrupt. Run cleanup script and try again." feature_result = {} for atom_feature in self.ATOM_FEATURES: scores_key = self.get_scores_key(atom_feature) feature_result[scores_key] = atom_feature_scores_dict[atom_feature] return feature_result class VmafFeatureExtractor(FeatureExtractor): TYPE = "VMAF_feature" # VERSION = '0.1' # vmaf_study; Anush's VIF fix # VERSION = '0.2' # expose vif_num, vif_den, adm_num, adm_den, anpsnr # VERSION = '0.2.1' # expose vif num/den of each scale # VERSION = '0.2.2' # adm abs-->fabs, corrected border handling, uniform reading with option of offset for input YUV, updated VIF corner case # VERSION = '0.2.2b' # expose adm_den/num_scalex # VERSION = '0.2.3' # AVX for VMAF convolution; update adm features by folding noise floor into per coef # VERSION = '0.2.4' # Fix a bug in adm feature passing scale into dwt_quant_step # VERSION = '0.2.4b' # Modify by adding ADM noise floor outside cube root; add derived feature motion2 VERSION = '0.2.4c' # Modify by moving motion2 to c code ATOM_FEATURES = ['vif', 'adm', 'ansnr', 'motion', 'motion2', 'vif_num', 'vif_den', 'adm_num', 'adm_den', 'anpsnr', 'vif_num_scale0', 'vif_den_scale0', 'vif_num_scale1', 'vif_den_scale1', 'vif_num_scale2', 'vif_den_scale2', 'vif_num_scale3', 'vif_den_scale3', 'adm_num_scale0', 'adm_den_scale0', 'adm_num_scale1', 'adm_den_scale1', 'adm_num_scale2', 'adm_den_scale2', 'adm_num_scale3', 'adm_den_scale3', ] DERIVED_ATOM_FEATURES = ['vif_scale0', 'vif_scale1', 'vif_scale2', 'vif_scale3', 'vif2', 'adm2', 'adm3', 'adm_scale0', 'adm_scale1', 'adm_scale2', 'adm_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vmaf_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VmafFeatureExtractor, cls)._post_process_result(result) # adm2 = # (adm_num + ADM2_CONSTANT) / (adm_den + ADM2_CONSTANT) adm2_scores_key = cls.get_scores_key('adm2') adm_num_scores_key = cls.get_scores_key('adm_num') adm_den_scores_key = cls.get_scores_key('adm_den') result.result_dict[adm2_scores_key] = list( (np.array(result.result_dict[adm_num_scores_key]) + cls.ADM2_CONSTANT) / (np.array(result.result_dict[adm_den_scores_key]) + cls.ADM2_CONSTANT) ) # vif_scalei = vif_num_scalei / vif_den_scalei, i = 0, 1, 2, 3 vif_num_scale0_scores_key = cls.get_scores_key('vif_num_scale0') vif_den_scale0_scores_key = cls.get_scores_key('vif_den_scale0') vif_num_scale1_scores_key = cls.get_scores_key('vif_num_scale1') vif_den_scale1_scores_key = cls.get_scores_key('vif_den_scale1') vif_num_scale2_scores_key = cls.get_scores_key('vif_num_scale2') vif_den_scale2_scores_key = cls.get_scores_key('vif_den_scale2') vif_num_scale3_scores_key = cls.get_scores_key('vif_num_scale3') vif_den_scale3_scores_key = cls.get_scores_key('vif_den_scale3') vif_scale0_scores_key = cls.get_scores_key('vif_scale0') vif_scale1_scores_key = cls.get_scores_key('vif_scale1') vif_scale2_scores_key = cls.get_scores_key('vif_scale2') vif_scale3_scores_key = cls.get_scores_key('vif_scale3') result.result_dict[vif_scale0_scores_key] = list( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) ) result.result_dict[vif_scale1_scores_key] = list( (np.array(result.result_dict[vif_num_scale1_scores_key]) /	np.array(result.result_dict[vif_den_scale1_scores_key])	numpy.array
''' <NAME> set up :2020-1-9 intergrate img and label into one file -- fiducial1024_v1 ''' import argparse import sys, os import pickle import random import collections import json import numpy as np import scipy.io as io import scipy.misc as m import matplotlib.pyplot as plt import glob import math import time import threading import multiprocessing as mp from multiprocessing import Pool import re import cv2 # sys.path.append('/lustre/home/gwxie/hope/project/dewarp/datasets/') # /lustre/home/gwxie/program/project/unwarp/perturbed_imgaes/GAN import utils def getDatasets(dir): return os.listdir(dir) class perturbed(utils.BasePerturbed): def __init__(self, path, bg_path, save_path, save_suffix): self.path = path self.bg_path = bg_path self.save_path = save_path self.save_suffix = save_suffix def save_img(self, m, n, fold_curve='fold', repeat_time=4, fiducial_points = 16, relativeShift_position='relativeShift_v2'): origin_img = cv2.imread(self.path, flags=cv2.IMREAD_COLOR) save_img_shape = [5122, 4802] # 320 # reduce_value = np.random.choice([24, 25, 26, 27, 2*8], p=[0.01, 0.1, 0.4, 0.39, 0.1]) reduce_value = np.random.choice([22, 42, 82, 162, 242, 322, 402, 482], p=[0.02, 0.18, 0.2, 0.3, 0.1, 0.1, 0.08, 0.02]) # reduce_value = np.random.choice([82, 162, 242, 322, 402, 482], p=[0.01, 0.02, 0.2, 0.4, 0.19, 0.18]) # reduce_value = np.random.choice([16, 24, 32, 40, 48, 64], p=[0.01, 0.1, 0.2, 0.4, 0.2, 0.09]) base_img_shrink = save_img_shape[0] - reduce_value # enlarge_img_shrink = [1024, 768] # enlarge_img_shrink = [896, 672] # 420 enlarge_img_shrink = [5124, 4804] # 420 # enlarge_img_shrink = [8962, 7682] # 420 # enlarge_img_shrink = [896, 768] # 420 # enlarge_img_shrink = [768, 576] # 420 # enlarge_img_shrink = [640, 480] # 420 '''''' im_lr = origin_img.shape[0] im_ud = origin_img.shape[1] reduce_value_v2 = np.random.choice([22, 42, 82, 162, 242, 282, 322, 482], p=[0.02, 0.18, 0.2, 0.2, 0.1, 0.1, 0.1, 0.1]) # reduce_value_v2 = np.random.choice([16, 24, 28, 32, 48, 64], p=[0.01, 0.1, 0.2, 0.3, 0.25, 0.14]) if im_lr > im_ud: im_ud = min(int(im_ud / im_lr base_img_shrink), save_img_shape[1] - reduce_value_v2) im_lr = save_img_shape[0] - reduce_value else: base_img_shrink = save_img_shape[1] - reduce_value im_lr = min(int(im_lr / im_ud * base_img_shrink), save_img_shape[0] - reduce_value_v2) im_ud = base_img_shrink if round(im_lr / im_ud, 2) < 0.5 or round(im_ud / im_lr, 2) < 0.5: repeat_time = min(repeat_time, 8) edge_padding = 3 im_lr -= im_lr % (fiducial_points-1) - (2edge_padding) # im_lr % (fiducial_points-1) - 1 im_ud -= im_ud % (fiducial_points-1) - (2edge_padding) # im_ud % (fiducial_points-1) - 1 im_hight = np.linspace(edge_padding, im_lr - edge_padding, fiducial_points, dtype=np.int64) im_wide = np.linspace(edge_padding, im_ud - edge_padding, fiducial_points, dtype=np.int64) # im_lr -= im_lr % (fiducial_points-1) - (1+2edge_padding) # im_lr % (fiducial_points-1) - 1 # im_ud -= im_ud % (fiducial_points-1) - (1+2edge_padding) # im_ud % (fiducial_points-1) - 1 # im_hight = np.linspace(edge_padding, im_lr - (1+edge_padding), fiducial_points, dtype=np.int64) # im_wide = np.linspace(edge_padding, im_ud - (1+edge_padding), fiducial_points, dtype=np.int64) im_x, im_y = np.meshgrid(im_hight, im_wide) segment_x = (im_lr) // (fiducial_points-1) segment_y = (im_ud) // (fiducial_points-1) # plt.plot(im_x, im_y, # color='limegreen', # marker='.', # linestyle='') # plt.grid(True) # plt.show() self.origin_img = cv2.resize(origin_img, (im_ud, im_lr), interpolation=cv2.INTER_CUBIC) perturbed_bg_ = getDatasets(self.bg_path) perturbed_bg_img_ = self.bg_path+random.choice(perturbed_bg_) perturbed_bg_img = cv2.imread(perturbed_bg_img_, flags=cv2.IMREAD_COLOR) mesh_shape = self.origin_img.shape[:2] self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 256, dtype=np.float32)#np.zeros_like(perturbed_bg_img) # self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 0, dtype=np.int16)#np.zeros_like(perturbed_bg_img) self.new_shape = self.synthesis_perturbed_img.shape[:2] perturbed_bg_img = cv2.resize(perturbed_bg_img, (save_img_shape[1], save_img_shape[0]), cv2.INPAINT_TELEA) origin_pixel_position = np.argwhere(np.zeros(mesh_shape, dtype=np.uint32) == 0).reshape(mesh_shape[0], mesh_shape[1], 2) pixel_position = np.argwhere(	np.zeros(self.new_shape, dtype=np.uint32)	numpy.zeros
try: import importlib.resources as pkg_resources except ImportError: # Try backported to PY<37 `importlib_resources`. import importlib_resources as pkg_resources from . import images from gym import Env, spaces from time import time import numpy as np from copy import copy import colorsys import pygame from pygame.transform import scale class MinesweeperEnv(Env): def __init__(self, grid_shape=(10, 15), bombs_density=0.1, n_bombs=None, impact_size=3, max_time=999, chicken=False): self.grid_shape = grid_shape self.grid_size = np.prod(grid_shape) self.n_bombs = max(1, int(bombs_density * self.grid_size)) if n_bombs is None else n_bombs self.n_bombs = min(self.grid_size - 1, self.n_bombs) self.flaged_bombs = 0 self.flaged_empty = 0 self.max_time = max_time if impact_size % 2 == 0: raise ValueError('Impact_size must be an odd number !') self.impact_size = impact_size # Define constants self.HIDDEN = 0 self.REVEAL = 1 self.FLAG = 2 self.BOMB = self.impact_size ** 2 # Setting up gym Env conventions nvec_observation = (self.BOMB + 2) * np.ones(self.grid_shape) self.observation_space = spaces.MultiDiscrete(nvec_observation) nvec_action = np.array(self.grid_shape + (2,)) self.action_space = spaces.MultiDiscrete(nvec_action) # Initalize state self.state = np.zeros(self.grid_shape + (2,), dtype=np.uint8) ## Setup bombs places idx =	np.indices(self.grid_shape)	numpy.indices
"""Test the search module""" from collections.abc import Iterable, Sized from io import StringIO from itertools import chain, product from functools import partial import pickle import sys from types import GeneratorType import re import numpy as np import scipy.sparse as sp import pytest from sklearn.utils.fixes import sp_version from sklearn.utils._testing import assert_raises from sklearn.utils._testing import assert_warns from sklearn.utils._testing import assert_warns_message from sklearn.utils._testing import assert_raise_message from sklearn.utils._testing import assert_array_equal from sklearn.utils._testing import assert_array_almost_equal from sklearn.utils._testing import assert_allclose from sklearn.utils._testing import assert_almost_equal from sklearn.utils._testing import ignore_warnings from sklearn.utils._mocking import CheckingClassifier, MockDataFrame from scipy.stats import bernoulli, expon, uniform from sklearn.base import BaseEstimator, ClassifierMixin from sklearn.base import clone from sklearn.exceptions import NotFittedError from sklearn.datasets import make_classification from sklearn.datasets import make_blobs from sklearn.datasets import make_multilabel_classification from sklearn.model_selection import fit_grid_point from sklearn.model_selection import train_test_split from sklearn.model_selection import KFold from sklearn.model_selection import StratifiedKFold from sklearn.model_selection import StratifiedShuffleSplit from sklearn.model_selection import LeaveOneGroupOut from sklearn.model_selection import LeavePGroupsOut from sklearn.model_selection import GroupKFold from sklearn.model_selection import GroupShuffleSplit from sklearn.model_selection import GridSearchCV from sklearn.model_selection import RandomizedSearchCV from sklearn.model_selection import ParameterGrid from sklearn.model_selection import ParameterSampler from sklearn.model_selection._search import BaseSearchCV from sklearn.model_selection._validation import FitFailedWarning from sklearn.svm import LinearSVC, SVC from sklearn.tree import DecisionTreeRegressor from sklearn.tree import DecisionTreeClassifier from sklearn.cluster import KMeans from sklearn.neighbors import KernelDensity from sklearn.neighbors import KNeighborsClassifier from sklearn.metrics import f1_score from sklearn.metrics import recall_score from sklearn.metrics import accuracy_score from sklearn.metrics import make_scorer from sklearn.metrics import roc_auc_score from sklearn.metrics.pairwise import euclidean_distances from sklearn.impute import SimpleImputer from sklearn.pipeline import Pipeline from sklearn.linear_model import Ridge, SGDClassifier, LinearRegression from sklearn.experimental import enable_hist_gradient_boosting # noqa from sklearn.ensemble import HistGradientBoostingClassifier from sklearn.model_selection.tests.common import OneTimeSplitter # Neither of the following two estimators inherit from BaseEstimator, # to test hyperparameter search on user-defined classifiers. class MockClassifier: """Dummy classifier to test the parameter search algorithms""" def __init__(self, foo_param=0): self.foo_param = foo_param def fit(self, X, Y): assert len(X) == len(Y) self.classes_ = np.unique(Y) return self def predict(self, T): return T.shape[0] def transform(self, X): return X + self.foo_param def inverse_transform(self, X): return X - self.foo_param predict_proba = predict predict_log_proba = predict decision_function = predict def score(self, X=None, Y=None): if self.foo_param > 1: score = 1. else: score = 0. return score def get_params(self, deep=False): return {'foo_param': self.foo_param} def set_params(self, *params): self.foo_param = params['foo_param'] return self class LinearSVCNoScore(LinearSVC): """An LinearSVC classifier that has no score method.""" @property def score(self): raise AttributeError X = np.array([[-1, -1], [-2, -1], [1, 1], [2, 1]]) y = np.array([1, 1, 2, 2]) def assert_grid_iter_equals_getitem(grid): assert list(grid) == [grid[i] for i in range(len(grid))] @pytest.mark.parametrize("klass", [ParameterGrid, partial(ParameterSampler, n_iter=10)]) @pytest.mark.parametrize( "input, error_type, error_message", [(0, TypeError, r'Parameter . is not a dict or a list \(0\)'), ([{'foo': [0]}, 0], TypeError, r'Parameter .* is not a dict \(0\)'), ({'foo': 0}, TypeError, "Parameter.* value is not iterable ." r"\(key='foo', value=0\)")] ) def test_validate_parameter_input(klass, input, error_type, error_message): with pytest.raises(error_type, match=error_message): klass(input) def test_parameter_grid(): # Test basic properties of ParameterGrid. params1 = {"foo": [1, 2, 3]} grid1 = ParameterGrid(params1) assert isinstance(grid1, Iterable) assert isinstance(grid1, Sized) assert len(grid1) == 3 assert_grid_iter_equals_getitem(grid1) params2 = {"foo": [4, 2], "bar": ["ham", "spam", "eggs"]} grid2 = ParameterGrid(params2) assert len(grid2) == 6 # loop to assert we can iterate over the grid multiple times for i in range(2): # tuple + chain transforms {"a": 1, "b": 2} to ("a", 1, "b", 2) points = set(tuple(chain((sorted(p.items())))) for p in grid2) assert (points == set(("bar", x, "foo", y) for x, y in product(params2["bar"], params2["foo"]))) assert_grid_iter_equals_getitem(grid2) # Special case: empty grid (useful to get default estimator settings) empty = ParameterGrid({}) assert len(empty) == 1 assert list(empty) == [{}] assert_grid_iter_equals_getitem(empty) assert_raises(IndexError, lambda: empty[1]) has_empty = ParameterGrid([{'C': [1, 10]}, {}, {'C': [.5]}]) assert len(has_empty) == 4 assert list(has_empty) == [{'C': 1}, {'C': 10}, {}, {'C': .5}] assert_grid_iter_equals_getitem(has_empty) def test_grid_search(): # Test that the best estimator contains the right value for foo_param clf = MockClassifier() grid_search = GridSearchCV(clf, {'foo_param': [1, 2, 3]}, cv=3, verbose=3) # make sure it selects the smallest parameter in case of ties old_stdout = sys.stdout sys.stdout = StringIO() grid_search.fit(X, y) sys.stdout = old_stdout assert grid_search.best_estimator_.foo_param == 2 assert_array_equal(grid_search.cv_results_["param_foo_param"].data, [1, 2, 3]) # Smoke test the score etc: grid_search.score(X, y) grid_search.predict_proba(X) grid_search.decision_function(X) grid_search.transform(X) # Test exception handling on scoring grid_search.scoring = 'sklearn' assert_raises(ValueError, grid_search.fit, X, y) def test_grid_search_pipeline_steps(): # check that parameters that are estimators are cloned before fitting pipe = Pipeline([('regressor', LinearRegression())]) param_grid = {'regressor': [LinearRegression(), Ridge()]} grid_search = GridSearchCV(pipe, param_grid, cv=2) grid_search.fit(X, y) regressor_results = grid_search.cv_results_['param_regressor'] assert isinstance(regressor_results[0], LinearRegression) assert isinstance(regressor_results[1], Ridge) assert not hasattr(regressor_results[0], 'coef_') assert not hasattr(regressor_results[1], 'coef_') assert regressor_results[0] is not grid_search.best_estimator_ assert regressor_results[1] is not grid_search.best_estimator_ # check that we didn't modify the parameter grid that was passed assert not hasattr(param_grid['regressor'][0], 'coef_') assert not hasattr(param_grid['regressor'][1], 'coef_') @pytest.mark.parametrize("SearchCV", [GridSearchCV, RandomizedSearchCV]) def test_SearchCV_with_fit_params(SearchCV): X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) clf = CheckingClassifier(expected_fit_params=['spam', 'eggs']) searcher = SearchCV( clf, {'foo_param': [1, 2, 3]}, cv=2, error_score="raise" ) # The CheckingClassifier generates an assertion error if # a parameter is missing or has length != len(X). err_msg = r"Expected fit parameter\(s\) \['eggs'\] not seen." with pytest.raises(AssertionError, match=err_msg): searcher.fit(X, y, spam=np.ones(10)) err_msg = "Fit parameter spam has length 1; expected" with pytest.raises(AssertionError, match=err_msg): searcher.fit(X, y, spam=np.ones(1), eggs=np.zeros(10)) searcher.fit(X, y, spam=np.ones(10), eggs=np.zeros(10)) @ignore_warnings def test_grid_search_no_score(): # Test grid-search on classifier that has no score function. clf = LinearSVC(random_state=0) X, y = make_blobs(random_state=0, centers=2) Cs = [.1, 1, 10] clf_no_score = LinearSVCNoScore(random_state=0) grid_search = GridSearchCV(clf, {'C': Cs}, scoring='accuracy') grid_search.fit(X, y) grid_search_no_score = GridSearchCV(clf_no_score, {'C': Cs}, scoring='accuracy') # smoketest grid search grid_search_no_score.fit(X, y) # check that best params are equal assert grid_search_no_score.best_params_ == grid_search.best_params_ # check that we can call score and that it gives the correct result assert grid_search.score(X, y) == grid_search_no_score.score(X, y) # giving no scoring function raises an error grid_search_no_score = GridSearchCV(clf_no_score, {'C': Cs}) assert_raise_message(TypeError, "no scoring", grid_search_no_score.fit, [[1]]) def test_grid_search_score_method(): X, y = make_classification(n_samples=100, n_classes=2, flip_y=.2, random_state=0) clf = LinearSVC(random_state=0) grid = {'C': [.1]} search_no_scoring = GridSearchCV(clf, grid, scoring=None).fit(X, y) search_accuracy = GridSearchCV(clf, grid, scoring='accuracy').fit(X, y) search_no_score_method_auc = GridSearchCV(LinearSVCNoScore(), grid, scoring='roc_auc' ).fit(X, y) search_auc = GridSearchCV(clf, grid, scoring='roc_auc').fit(X, y) # Check warning only occurs in situation where behavior changed: # estimator requires score method to compete with scoring parameter score_no_scoring = search_no_scoring.score(X, y) score_accuracy = search_accuracy.score(X, y) score_no_score_auc = search_no_score_method_auc.score(X, y) score_auc = search_auc.score(X, y) # ensure the test is sane assert score_auc < 1.0 assert score_accuracy < 1.0 assert score_auc != score_accuracy assert_almost_equal(score_accuracy, score_no_scoring) assert_almost_equal(score_auc, score_no_score_auc) def test_grid_search_groups(): # Check if ValueError (when groups is None) propagates to GridSearchCV # And also check if groups is correctly passed to the cv object rng = np.random.RandomState(0) X, y = make_classification(n_samples=15, n_classes=2, random_state=0) groups = rng.randint(0, 3, 15) clf = LinearSVC(random_state=0) grid = {'C': [1]} group_cvs = [LeaveOneGroupOut(), LeavePGroupsOut(2), GroupKFold(n_splits=3), GroupShuffleSplit()] for cv in group_cvs: gs = GridSearchCV(clf, grid, cv=cv) assert_raise_message(ValueError, "The 'groups' parameter should not be None.", gs.fit, X, y) gs.fit(X, y, groups=groups) non_group_cvs = [StratifiedKFold(), StratifiedShuffleSplit()] for cv in non_group_cvs: gs = GridSearchCV(clf, grid, cv=cv) # Should not raise an error gs.fit(X, y) def test_classes__property(): # Test that classes_ property matches best_estimator_.classes_ X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) Cs = [.1, 1, 10] grid_search = GridSearchCV(LinearSVC(random_state=0), {'C': Cs}) grid_search.fit(X, y) assert_array_equal(grid_search.best_estimator_.classes_, grid_search.classes_) # Test that regressors do not have a classes_ attribute grid_search = GridSearchCV(Ridge(), {'alpha': [1.0, 2.0]}) grid_search.fit(X, y) assert not hasattr(grid_search, 'classes_') # Test that the grid searcher has no classes_ attribute before it's fit grid_search = GridSearchCV(LinearSVC(random_state=0), {'C': Cs}) assert not hasattr(grid_search, 'classes_') # Test that the grid searcher has no classes_ attribute without a refit grid_search = GridSearchCV(LinearSVC(random_state=0), {'C': Cs}, refit=False) grid_search.fit(X, y) assert not hasattr(grid_search, 'classes_') def test_trivial_cv_results_attr(): # Test search over a "grid" with only one point. clf = MockClassifier() grid_search = GridSearchCV(clf, {'foo_param': [1]}, cv=3) grid_search.fit(X, y) assert hasattr(grid_search, "cv_results_") random_search = RandomizedSearchCV(clf, {'foo_param': [0]}, n_iter=1, cv=3) random_search.fit(X, y) assert hasattr(grid_search, "cv_results_") def test_no_refit(): # Test that GSCV can be used for model selection alone without refitting clf = MockClassifier() for scoring in [None, ['accuracy', 'precision']]: grid_search = GridSearchCV( clf, {'foo_param': [1, 2, 3]}, refit=False, cv=3 ) grid_search.fit(X, y) assert not hasattr(grid_search, "best_estimator_") and \ hasattr(grid_search, "best_index_") and \ hasattr(grid_search, "best_params_") # Make sure the functions predict/transform etc raise meaningful # error messages for fn_name in ('predict', 'predict_proba', 'predict_log_proba', 'transform', 'inverse_transform'): assert_raise_message(NotFittedError, ('refit=False. %s is available only after ' 'refitting on the best parameters' % fn_name), getattr(grid_search, fn_name), X) # Test that an invalid refit param raises appropriate error messages for refit in ["", 5, True, 'recall', 'accuracy']: assert_raise_message(ValueError, "For multi-metric scoring, the " "parameter refit must be set to a scorer key", GridSearchCV(clf, {}, refit=refit, scoring={'acc': 'accuracy', 'prec': 'precision'} ).fit, X, y) def test_grid_search_error(): # Test that grid search will capture errors on data with different length X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) assert_raises(ValueError, cv.fit, X_[:180], y_) def test_grid_search_one_grid_point(): X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) param_dict = {"C": [1.0], "kernel": ["rbf"], "gamma": [0.1]} clf = SVC(gamma='auto') cv = GridSearchCV(clf, param_dict) cv.fit(X_, y_) clf = SVC(C=1.0, kernel="rbf", gamma=0.1) clf.fit(X_, y_) assert_array_equal(clf.dual_coef_, cv.best_estimator_.dual_coef_) def test_grid_search_when_param_grid_includes_range(): # Test that the best estimator contains the right value for foo_param clf = MockClassifier() grid_search = None grid_search = GridSearchCV(clf, {'foo_param': range(1, 4)}, cv=3) grid_search.fit(X, y) assert grid_search.best_estimator_.foo_param == 2 def test_grid_search_bad_param_grid(): param_dict = {"C": 1} clf = SVC(gamma='auto') assert_raise_message( ValueError, "Parameter grid for parameter (C) needs to" " be a list or numpy array, but got (<class 'int'>)." " Single values need to be wrapped in a list" " with one element.", GridSearchCV, clf, param_dict) param_dict = {"C": []} clf = SVC() assert_raise_message( ValueError, "Parameter values for parameter (C) need to be a non-empty sequence.", GridSearchCV, clf, param_dict) param_dict = {"C": "1,2,3"} clf = SVC(gamma='auto') assert_raise_message( ValueError, "Parameter grid for parameter (C) needs to" " be a list or numpy array, but got (<class 'str'>)." " Single values need to be wrapped in a list" " with one element.", GridSearchCV, clf, param_dict) param_dict = {"C": np.ones((3, 2))} clf = SVC() assert_raises(ValueError, GridSearchCV, clf, param_dict) def test_grid_search_sparse(): # Test that grid search works with both dense and sparse matrices X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) cv.fit(X_[:180], y_[:180]) y_pred = cv.predict(X_[180:]) C = cv.best_estimator_.C X_ = sp.csr_matrix(X_) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) cv.fit(X_[:180].tocoo(), y_[:180]) y_pred2 = cv.predict(X_[180:]) C2 = cv.best_estimator_.C assert np.mean(y_pred == y_pred2) >= .9 assert C == C2 def test_grid_search_sparse_scoring(): X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}, scoring="f1") cv.fit(X_[:180], y_[:180]) y_pred = cv.predict(X_[180:]) C = cv.best_estimator_.C X_ = sp.csr_matrix(X_) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}, scoring="f1") cv.fit(X_[:180], y_[:180]) y_pred2 = cv.predict(X_[180:]) C2 = cv.best_estimator_.C assert_array_equal(y_pred, y_pred2) assert C == C2 # Smoke test the score # np.testing.assert_allclose(f1_score(cv.predict(X_[:180]), y[:180]), # cv.score(X_[:180], y[:180])) # test loss where greater is worse def f1_loss(y_true_, y_pred_): return -f1_score(y_true_, y_pred_) F1Loss = make_scorer(f1_loss, greater_is_better=False) cv = GridSearchCV(clf, {'C': [0.1, 1.0]}, scoring=F1Loss) cv.fit(X_[:180], y_[:180]) y_pred3 = cv.predict(X_[180:]) C3 = cv.best_estimator_.C assert C == C3 assert_array_equal(y_pred, y_pred3) def test_grid_search_precomputed_kernel(): # Test that grid search works when the input features are given in the # form of a precomputed kernel matrix X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) # compute the training kernel matrix corresponding to the linear kernel K_train = np.dot(X_[:180], X_[:180].T) y_train = y_[:180] clf = SVC(kernel='precomputed') cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) cv.fit(K_train, y_train) assert cv.best_score_ >= 0 # compute the test kernel matrix K_test = np.dot(X_[180:], X_[:180].T) y_test = y_[180:] y_pred = cv.predict(K_test) assert np.mean(y_pred == y_test) >= 0 # test error is raised when the precomputed kernel is not array-like # or sparse assert_raises(ValueError, cv.fit, K_train.tolist(), y_train) def test_grid_search_precomputed_kernel_error_nonsquare(): # Test that grid search returns an error with a non-square precomputed # training kernel matrix K_train = np.zeros((10, 20)) y_train = np.ones((10, )) clf = SVC(kernel='precomputed') cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) assert_raises(ValueError, cv.fit, K_train, y_train) class BrokenClassifier(BaseEstimator): """Broken classifier that cannot be fit twice""" def __init__(self, parameter=None): self.parameter = parameter def fit(self, X, y): assert not hasattr(self, 'has_been_fit_') self.has_been_fit_ = True def predict(self, X): return np.zeros(X.shape[0]) @ignore_warnings def test_refit(): # Regression test for bug in refitting # Simulates re-fitting a broken estimator; this used to break with # sparse SVMs. X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) clf = GridSearchCV(BrokenClassifier(), [{'parameter': [0, 1]}], scoring="precision", refit=True) clf.fit(X, y) def test_refit_callable(): """ Test refit=callable, which adds flexibility in identifying the "best" estimator. """ def refit_callable(cv_results): """ A dummy function tests `refit=callable` interface. Return the index of a model that has the least `mean_test_score`. """ # Fit a dummy clf with `refit=True` to get a list of keys in # clf.cv_results_. X, y = make_classification(n_samples=100, n_features=4, random_state=42) clf = GridSearchCV(LinearSVC(random_state=42), {'C': [0.01, 0.1, 1]}, scoring='precision', refit=True) clf.fit(X, y) # Ensure that `best_index_ != 0` for this dummy clf assert clf.best_index_ != 0 # Assert every key matches those in `cv_results` for key in clf.cv_results_.keys(): assert key in cv_results return cv_results['mean_test_score'].argmin() X, y = make_classification(n_samples=100, n_features=4, random_state=42) clf = GridSearchCV(LinearSVC(random_state=42), {'C': [0.01, 0.1, 1]}, scoring='precision', refit=refit_callable) clf.fit(X, y) assert clf.best_index_ == 0 # Ensure `best_score_` is disabled when using `refit=callable` assert not hasattr(clf, 'best_score_') def test_refit_callable_invalid_type(): """ Test implementation catches the errors when 'best_index_' returns an invalid result. """ def refit_callable_invalid_type(cv_results): """ A dummy function tests when returned 'best_index_' is not integer. """ return None X, y = make_classification(n_samples=100, n_features=4, random_state=42) clf = GridSearchCV(LinearSVC(random_state=42), {'C': [0.1, 1]}, scoring='precision', refit=refit_callable_invalid_type) with pytest.raises(TypeError, match='best_index_ returned is not an integer'): clf.fit(X, y) @pytest.mark.parametrize('out_bound_value', [-1, 2]) @pytest.mark.parametrize('search_cv', [RandomizedSearchCV, GridSearchCV]) def test_refit_callable_out_bound(out_bound_value, search_cv): """ Test implementation catches the errors when 'best_index_' returns an out of bound result. """ def refit_callable_out_bound(cv_results): """ A dummy function tests when returned 'best_index_' is out of bounds. """ return out_bound_value X, y = make_classification(n_samples=100, n_features=4, random_state=42) clf = search_cv(LinearSVC(random_state=42), {'C': [0.1, 1]}, scoring='precision', refit=refit_callable_out_bound) with pytest.raises(IndexError, match='best_index_ index out of range'): clf.fit(X, y) def test_refit_callable_multi_metric(): """ Test refit=callable in multiple metric evaluation setting """ def refit_callable(cv_results): """ A dummy function tests `refit=callable` interface. Return the index of a model that has the least `mean_test_prec`. """ assert 'mean_test_prec' in cv_results return cv_results['mean_test_prec'].argmin() X, y = make_classification(n_samples=100, n_features=4, random_state=42) scoring = {'Accuracy': make_scorer(accuracy_score), 'prec': 'precision'} clf = GridSearchCV(LinearSVC(random_state=42), {'C': [0.01, 0.1, 1]}, scoring=scoring, refit=refit_callable) clf.fit(X, y) assert clf.best_index_ == 0 # Ensure `best_score_` is disabled when using `refit=callable` assert not hasattr(clf, 'best_score_') def test_gridsearch_nd(): # Pass X as list in GridSearchCV X_4d = np.arange(10 * 5 * 3 * 2).reshape(10, 5, 3, 2) y_3d = np.arange(10 * 7 * 11).reshape(10, 7, 11) check_X = lambda x: x.shape[1:] == (5, 3, 2) check_y = lambda x: x.shape[1:] == (7, 11) clf = CheckingClassifier( check_X=check_X, check_y=check_y, methods_to_check=["fit"], ) grid_search = GridSearchCV(clf, {'foo_param': [1, 2, 3]}) grid_search.fit(X_4d, y_3d).score(X, y) assert hasattr(grid_search, "cv_results_") def test_X_as_list(): # Pass X as list in GridSearchCV X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) clf = CheckingClassifier( check_X=lambda x: isinstance(x, list), methods_to_check=["fit"], ) cv = KFold(n_splits=3) grid_search = GridSearchCV(clf, {'foo_param': [1, 2, 3]}, cv=cv) grid_search.fit(X.tolist(), y).score(X, y) assert hasattr(grid_search, "cv_results_") def test_y_as_list(): # Pass y as list in GridSearchCV X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) clf = CheckingClassifier( check_y=lambda x: isinstance(x, list), methods_to_check=["fit"], ) cv = KFold(n_splits=3) grid_search = GridSearchCV(clf, {'foo_param': [1, 2, 3]}, cv=cv) grid_search.fit(X, y.tolist()).score(X, y) assert hasattr(grid_search, "cv_results_") @ignore_warnings def test_pandas_input(): # check cross_val_score doesn't destroy pandas dataframe types = [(MockDataFrame, MockDataFrame)] try: from pandas import Series, DataFrame types.append((DataFrame, Series)) except ImportError: pass X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) for InputFeatureType, TargetType in types: # X dataframe, y series X_df, y_ser = InputFeatureType(X), TargetType(y) def check_df(x): return isinstance(x, InputFeatureType) def check_series(x): return isinstance(x, TargetType) clf = CheckingClassifier(check_X=check_df, check_y=check_series) grid_search = GridSearchCV(clf, {'foo_param': [1, 2, 3]}) grid_search.fit(X_df, y_ser).score(X_df, y_ser) grid_search.predict(X_df) assert hasattr(grid_search, "cv_results_") def test_unsupervised_grid_search(): # test grid-search with unsupervised estimator X, y = make_blobs(n_samples=50, random_state=0) km = KMeans(random_state=0, init="random", n_init=1) # Multi-metric evaluation unsupervised scoring = ['adjusted_rand_score', 'fowlkes_mallows_score'] for refit in ['adjusted_rand_score', 'fowlkes_mallows_score']: grid_search = GridSearchCV(km, param_grid=dict(n_clusters=[2, 3, 4]), scoring=scoring, refit=refit) grid_search.fit(X, y) # Both ARI and FMS can find the right number :) assert grid_search.best_params_["n_clusters"] == 3 # Single metric evaluation unsupervised grid_search = GridSearchCV(km, param_grid=dict(n_clusters=[2, 3, 4]), scoring='fowlkes_mallows_score') grid_search.fit(X, y) assert grid_search.best_params_["n_clusters"] == 3 # Now without a score, and without y grid_search = GridSearchCV(km, param_grid=dict(n_clusters=[2, 3, 4])) grid_search.fit(X) assert grid_search.best_params_["n_clusters"] == 4 def test_gridsearch_no_predict(): # test grid-search with an estimator without predict. # slight duplication of a test from KDE def custom_scoring(estimator, X): return 42 if estimator.bandwidth == .1 else 0 X, _ = make_blobs(cluster_std=.1, random_state=1, centers=[[0, 1], [1, 0], [0, 0]]) search = GridSearchCV(KernelDensity(), param_grid=dict(bandwidth=[.01, .1, 1]), scoring=custom_scoring) search.fit(X) assert search.best_params_['bandwidth'] == .1 assert search.best_score_ == 42 def test_param_sampler(): # test basic properties of param sampler param_distributions = {"kernel": ["rbf", "linear"], "C": uniform(0, 1)} sampler = ParameterSampler(param_distributions=param_distributions, n_iter=10, random_state=0) samples = [x for x in sampler] assert len(samples) == 10 for sample in samples: assert sample["kernel"] in ["rbf", "linear"] assert 0 <= sample["C"] <= 1 # test that repeated calls yield identical parameters param_distributions = {"C": [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10]} sampler = ParameterSampler(param_distributions=param_distributions, n_iter=3, random_state=0) assert [x for x in sampler] == [x for x in sampler] if sp_version >= (0, 16): param_distributions = {"C": uniform(0, 1)} sampler = ParameterSampler(param_distributions=param_distributions, n_iter=10, random_state=0) assert [x for x in sampler] == [x for x in sampler] def check_cv_results_array_types(search, param_keys, score_keys): # Check if the search `cv_results`'s array are of correct types cv_results = search.cv_results_ assert all(isinstance(cv_results[param], np.ma.MaskedArray) for param in param_keys) assert all(cv_results[key].dtype == object for key in param_keys) assert not any(isinstance(cv_results[key], np.ma.MaskedArray) for key in score_keys) assert all(cv_results[key].dtype == np.float64 for key in score_keys if not key.startswith('rank')) scorer_keys = search.scorer_.keys() if search.multimetric_ else ['score'] for key in scorer_keys: assert cv_results['rank_test_%s' % key].dtype == np.int32 def check_cv_results_keys(cv_results, param_keys, score_keys, n_cand): # Test the search.cv_results_ contains all the required results assert_array_equal(sorted(cv_results.keys()), sorted(param_keys + score_keys + ('params',))) assert all(cv_results[key].shape == (n_cand,) for key in param_keys + score_keys) def test_grid_search_cv_results(): X, y = make_classification(n_samples=50, n_features=4, random_state=42) n_splits = 3 n_grid_points = 6 params = [dict(kernel=['rbf', ], C=[1, 10], gamma=[0.1, 1]), dict(kernel=['poly', ], degree=[1, 2])] param_keys = ('param_C', 'param_degree', 'param_gamma', 'param_kernel') score_keys = ('mean_test_score', 'mean_train_score', 'rank_test_score', 'split0_test_score', 'split1_test_score', 'split2_test_score', 'split0_train_score', 'split1_train_score', 'split2_train_score', 'std_test_score', 'std_train_score', 'mean_fit_time', 'std_fit_time', 'mean_score_time', 'std_score_time') n_candidates = n_grid_points search = GridSearchCV(SVC(), cv=n_splits, param_grid=params, return_train_score=True) search.fit(X, y) cv_results = search.cv_results_ # Check if score and timing are reasonable assert all(cv_results['rank_test_score'] >= 1) assert (all(cv_results[k] >= 0) for k in score_keys if k != 'rank_test_score') assert (all(cv_results[k] <= 1) for k in score_keys if 'time' not in k and k != 'rank_test_score') # Check cv_results structure check_cv_results_array_types(search, param_keys, score_keys) check_cv_results_keys(cv_results, param_keys, score_keys, n_candidates) # Check masking cv_results = search.cv_results_ n_candidates = len(search.cv_results_['params']) assert all((cv_results['param_C'].mask[i] and cv_results['param_gamma'].mask[i] and not cv_results['param_degree'].mask[i]) for i in range(n_candidates) if cv_results['param_kernel'][i] == 'linear') assert all((not cv_results['param_C'].mask[i] and not cv_results['param_gamma'].mask[i] and cv_results['param_degree'].mask[i]) for i in range(n_candidates) if cv_results['param_kernel'][i] == 'rbf') def test_random_search_cv_results(): X, y = make_classification(n_samples=50, n_features=4, random_state=42) n_splits = 3 n_search_iter = 30 params = [{'kernel': ['rbf'], 'C': expon(scale=10), 'gamma': expon(scale=0.1)}, {'kernel': ['poly'], 'degree': [2, 3]}] param_keys = ('param_C', 'param_degree', 'param_gamma', 'param_kernel') score_keys = ('mean_test_score', 'mean_train_score', 'rank_test_score', 'split0_test_score', 'split1_test_score', 'split2_test_score', 'split0_train_score', 'split1_train_score', 'split2_train_score', 'std_test_score', 'std_train_score', 'mean_fit_time', 'std_fit_time', 'mean_score_time', 'std_score_time') n_cand = n_search_iter search = RandomizedSearchCV(SVC(), n_iter=n_search_iter, cv=n_splits, param_distributions=params, return_train_score=True) search.fit(X, y) cv_results = search.cv_results_ # Check results structure check_cv_results_array_types(search, param_keys, score_keys) check_cv_results_keys(cv_results, param_keys, score_keys, n_cand) n_candidates = len(search.cv_results_['params']) assert all((cv_results['param_C'].mask[i] and cv_results['param_gamma'].mask[i] and not cv_results['param_degree'].mask[i]) for i in range(n_candidates) if cv_results['param_kernel'][i] == 'linear') assert all((not cv_results['param_C'].mask[i] and not cv_results['param_gamma'].mask[i] and cv_results['param_degree'].mask[i]) for i in range(n_candidates) if cv_results['param_kernel'][i] == 'rbf') @pytest.mark.parametrize( "SearchCV, specialized_params", [(GridSearchCV, {'param_grid': {'C': [1, 10]}}), (RandomizedSearchCV, {'param_distributions': {'C': [1, 10]}, 'n_iter': 2})] ) def test_search_default_iid(SearchCV, specialized_params): # Test the IID parameter TODO: Clearly this test does something else??? # noise-free simple 2d-data X, y = make_blobs(centers=[[0, 0], [1, 0], [0, 1], [1, 1]], random_state=0, cluster_std=0.1, shuffle=False, n_samples=80) # split dataset into two folds that are not iid # first one contains data of all 4 blobs, second only from two. mask = np.ones(X.shape[0], dtype=np.bool) mask[np.where(y == 1)[0][::2]] = 0 mask[np.where(y == 2)[0][::2]] = 0 # this leads to perfect classification on one fold and a score of 1/3 on # the other # create "cv" for splits cv = [[mask, ~mask], [~mask, mask]] common_params = {'estimator': SVC(), 'cv': cv, 'return_train_score': True} search = SearchCV(common_params, specialized_params) search.fit(X, y) test_cv_scores = np.array( [search.cv_results_['split%d_test_score' % s][0] for s in range(search.n_splits_)] ) test_mean = search.cv_results_['mean_test_score'][0] test_std = search.cv_results_['std_test_score'][0] train_cv_scores = np.array( [search.cv_results_['split%d_train_score' % s][0] for s in range(search.n_splits_)] ) train_mean = search.cv_results_['mean_train_score'][0] train_std = search.cv_results_['std_train_score'][0] assert search.cv_results_['param_C'][0] == 1 # scores are the same as above assert_allclose(test_cv_scores, [1, 1. / 3.]) assert_allclose(train_cv_scores, [1, 1]) # Unweighted mean/std is used assert test_mean == pytest.approx(np.mean(test_cv_scores)) assert test_std == pytest.approx(np.std(test_cv_scores)) # For the train scores, we do not take a weighted mean irrespective of # i.i.d. or not assert train_mean == pytest.approx(1) assert train_std == pytest.approx(0) def test_grid_search_cv_results_multimetric(): X, y = make_classification(n_samples=50, n_features=4, random_state=42) n_splits = 3 params = [dict(kernel=['rbf', ], C=[1, 10], gamma=[0.1, 1]), dict(kernel=['poly', ], degree=[1, 2])] grid_searches = [] for scoring in ({'accuracy': make_scorer(accuracy_score), 'recall': make_scorer(recall_score)}, 'accuracy', 'recall'): grid_search = GridSearchCV(SVC(), cv=n_splits, param_grid=params, scoring=scoring, refit=False) grid_search.fit(X, y) grid_searches.append(grid_search) compare_cv_results_multimetric_with_single(grid_searches) def test_random_search_cv_results_multimetric(): X, y = make_classification(n_samples=50, n_features=4, random_state=42) n_splits = 3 n_search_iter = 30 # Scipy 0.12's stats dists do not accept seed, hence we use param grid params = dict(C=np.logspace(-4, 1, 3), gamma=np.logspace(-5, 0, 3, base=0.1)) for refit in (True, False): random_searches = [] for scoring in (('accuracy', 'recall'), 'accuracy', 'recall'): # If True, for multi-metric pass refit='accuracy' if refit: probability = True refit = 'accuracy' if isinstance(scoring, tuple) else refit else: probability = False clf = SVC(probability=probability, random_state=42) random_search = RandomizedSearchCV(clf, n_iter=n_search_iter, cv=n_splits, param_distributions=params, scoring=scoring, refit=refit, random_state=0) random_search.fit(X, y) random_searches.append(random_search) compare_cv_results_multimetric_with_single(random_searches) compare_refit_methods_when_refit_with_acc( random_searches[0], random_searches[1], refit) def compare_cv_results_multimetric_with_single( search_multi, search_acc, search_rec): """Compare multi-metric cv_results with the ensemble of multiple single metric cv_results from single metric grid/random search""" assert search_multi.multimetric_ assert_array_equal(sorted(search_multi.scorer_), ('accuracy', 'recall')) cv_results_multi = search_multi.cv_results_ cv_results_acc_rec = {re.sub('_score$', '_accuracy', k): v for k, v in search_acc.cv_results_.items()} cv_results_acc_rec.update({re.sub('_score$', '_recall', k): v for k, v in search_rec.cv_results_.items()}) # Check if score and timing are reasonable, also checks if the keys # are present assert all((np.all(cv_results_multi[k] <= 1) for k in ( 'mean_score_time', 'std_score_time', 'mean_fit_time', 'std_fit_time'))) # Compare the keys, other than time keys, among multi-metric and # single metric grid search results. np.testing.assert_equal performs a # deep nested comparison of the two cv_results dicts np.testing.assert_equal({k: v for k, v in cv_results_multi.items() if not k.endswith('_time')}, {k: v for k, v in cv_results_acc_rec.items() if not k.endswith('_time')}) def compare_refit_methods_when_refit_with_acc(search_multi, search_acc, refit): """Compare refit multi-metric search methods with single metric methods""" assert search_acc.refit == refit if refit: assert search_multi.refit == 'accuracy' else: assert not search_multi.refit return # search cannot predict/score without refit X, y = make_blobs(n_samples=100, n_features=4, random_state=42) for method in ('predict', 'predict_proba', 'predict_log_proba'): assert_almost_equal(getattr(search_multi, method)(X), getattr(search_acc, method)(X)) assert_almost_equal(search_multi.score(X, y), search_acc.score(X, y)) for key in ('best_index_', 'best_score_', 'best_params_'): assert getattr(search_multi, key) == getattr(search_acc, key) def test_search_cv_results_rank_tie_breaking(): X, y = make_blobs(n_samples=50, random_state=42) # The two C values are close enough to give similar models # which would result in a tie of their mean cv-scores param_grid = {'C': [1, 1.001, 0.001]} grid_search = GridSearchCV(SVC(), param_grid=param_grid, return_train_score=True) random_search = RandomizedSearchCV(SVC(), n_iter=3, param_distributions=param_grid, return_train_score=True) for search in (grid_search, random_search): search.fit(X, y) cv_results = search.cv_results_ # Check tie breaking strategy - # Check that there is a tie in the mean scores between # candidates 1 and 2 alone assert_almost_equal(cv_results['mean_test_score'][0], cv_results['mean_test_score'][1]) assert_almost_equal(cv_results['mean_train_score'][0], cv_results['mean_train_score'][1]) assert not np.allclose(cv_results['mean_test_score'][1], cv_results['mean_test_score'][2]) assert not np.allclose(cv_results['mean_train_score'][1], cv_results['mean_train_score'][2]) # 'min' rank should be assigned to the tied candidates assert_almost_equal(search.cv_results_['rank_test_score'], [1, 1, 3]) def test_search_cv_results_none_param(): X, y = [[1], [2], [3], [4], [5]], [0, 0, 0, 0, 1] estimators = (DecisionTreeRegressor(), DecisionTreeClassifier()) est_parameters = {"random_state": [0, None]} cv = KFold() for est in estimators: grid_search = GridSearchCV(est, est_parameters, cv=cv, ).fit(X, y) assert_array_equal(grid_search.cv_results_['param_random_state'], [0, None]) @ignore_warnings() def test_search_cv_timing(): svc = LinearSVC(random_state=0) X = [[1, ], [2, ], [3, ], [4, ]] y = [0, 1, 1, 0] gs = GridSearchCV(svc, {'C': [0, 1]}, cv=2, error_score=0) rs = RandomizedSearchCV(svc, {'C': [0, 1]}, cv=2, error_score=0, n_iter=2) for search in (gs, rs): search.fit(X, y) for key in ['mean_fit_time', 'std_fit_time']: # NOTE The precision of time.time in windows is not high # enough for the fit/score times to be non-zero for trivial X and y assert np.all(search.cv_results_[key] >= 0) assert np.all(search.cv_results_[key] < 1) for key in ['mean_score_time', 'std_score_time']: assert search.cv_results_[key][1] >= 0 assert search.cv_results_[key][0] == 0.0 assert np.all(search.cv_results_[key] < 1) assert hasattr(search, "refit_time_") assert isinstance(search.refit_time_, float) assert search.refit_time_ >= 0 def test_grid_search_correct_score_results(): # test that correct scores are used n_splits = 3 clf = LinearSVC(random_state=0) X, y = make_blobs(random_state=0, centers=2) Cs = [.1, 1, 10] for score in ['f1', 'roc_auc']: grid_search = GridSearchCV(clf, {'C': Cs}, scoring=score, cv=n_splits) cv_results = grid_search.fit(X, y).cv_results_ # Test scorer names result_keys = list(cv_results.keys()) expected_keys = (("mean_test_score", "rank_test_score") + tuple("split%d_test_score" % cv_i for cv_i in range(n_splits))) assert all(	np.in1d(expected_keys, result_keys)	numpy.in1d
from abc import ABCMeta, abstractmethod import os from vmaf.tools.misc import make_absolute_path, run_process from vmaf.tools.stats import ListStats __copyright__ = "Copyright 2016-2018, Netflix, Inc." __license__ = "Apache, Version 2.0" import re import numpy as np import ast from vmaf import ExternalProgramCaller, to_list from vmaf.config import VmafConfig, VmafExternalConfig from vmaf.core.executor import Executor from vmaf.core.result import Result from vmaf.tools.reader import YuvReader class FeatureExtractor(Executor): """ FeatureExtractor takes in a list of assets, and run feature extraction on them, and return a list of corresponding results. A FeatureExtractor must specify a unique type and version combination (by the TYPE and VERSION attribute), so that the Result generated by it can be identified. A derived class of FeatureExtractor must: 1) Override TYPE and VERSION 2) Override _generate_result(self, asset), which call a command-line executable and generate feature scores in a log file. 3) Override _get_feature_scores(self, asset), which read the feature scores from the log file, and return the scores in a dictionary format. For an example, follow VmafFeatureExtractor. """ __metaclass__ = ABCMeta @property @abstractmethod def ATOM_FEATURES(self): raise NotImplementedError def _read_result(self, asset): result = {} result.update(self._get_feature_scores(asset)) executor_id = self.executor_id return Result(asset, executor_id, result) @classmethod def get_scores_key(cls, atom_feature): return "{type}_{atom_feature}_scores".format( type=cls.TYPE, atom_feature=atom_feature) @classmethod def get_score_key(cls, atom_feature): return "{type}_{atom_feature}_score".format( type=cls.TYPE, atom_feature=atom_feature) def _get_feature_scores(self, asset): # routine to read the feature scores from the log file, and return # the scores in a dictionary format. log_file_path = self._get_log_file_path(asset) atom_feature_scores_dict = {} atom_feature_idx_dict = {} for atom_feature in self.ATOM_FEATURES: atom_feature_scores_dict[atom_feature] = [] atom_feature_idx_dict[atom_feature] = 0 with open(log_file_path, 'rt') as log_file: for line in log_file.readlines(): for atom_feature in self.ATOM_FEATURES: re_template = "{af}: ([0-9]+) ([a-zA-Z0-9.-]+)".format(af=atom_feature) mo = re.match(re_template, line) if mo: cur_idx = int(mo.group(1)) assert cur_idx == atom_feature_idx_dict[atom_feature] # parse value, allowing NaN and inf val = float(mo.group(2)) if np.isnan(val) or np.isinf(val): val = None atom_feature_scores_dict[atom_feature].append(val) atom_feature_idx_dict[atom_feature] += 1 continue len_score = len(atom_feature_scores_dict[self.ATOM_FEATURES[0]]) assert len_score != 0 for atom_feature in self.ATOM_FEATURES[1:]: assert len_score == len(atom_feature_scores_dict[atom_feature]), \ "Feature data possibly corrupt. Run cleanup script and try again." feature_result = {} for atom_feature in self.ATOM_FEATURES: scores_key = self.get_scores_key(atom_feature) feature_result[scores_key] = atom_feature_scores_dict[atom_feature] return feature_result class VmafFeatureExtractor(FeatureExtractor): TYPE = "VMAF_feature" # VERSION = '0.1' # vmaf_study; Anush's VIF fix # VERSION = '0.2' # expose vif_num, vif_den, adm_num, adm_den, anpsnr # VERSION = '0.2.1' # expose vif num/den of each scale # VERSION = '0.2.2' # adm abs-->fabs, corrected border handling, uniform reading with option of offset for input YUV, updated VIF corner case # VERSION = '0.2.2b' # expose adm_den/num_scalex # VERSION = '0.2.3' # AVX for VMAF convolution; update adm features by folding noise floor into per coef # VERSION = '0.2.4' # Fix a bug in adm feature passing scale into dwt_quant_step # VERSION = '0.2.4b' # Modify by adding ADM noise floor outside cube root; add derived feature motion2 VERSION = '0.2.4c' # Modify by moving motion2 to c code ATOM_FEATURES = ['vif', 'adm', 'ansnr', 'motion', 'motion2', 'vif_num', 'vif_den', 'adm_num', 'adm_den', 'anpsnr', 'vif_num_scale0', 'vif_den_scale0', 'vif_num_scale1', 'vif_den_scale1', 'vif_num_scale2', 'vif_den_scale2', 'vif_num_scale3', 'vif_den_scale3', 'adm_num_scale0', 'adm_den_scale0', 'adm_num_scale1', 'adm_den_scale1', 'adm_num_scale2', 'adm_den_scale2', 'adm_num_scale3', 'adm_den_scale3', ] DERIVED_ATOM_FEATURES = ['vif_scale0', 'vif_scale1', 'vif_scale2', 'vif_scale3', 'vif2', 'adm2', 'adm3', 'adm_scale0', 'adm_scale1', 'adm_scale2', 'adm_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vmaf_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VmafFeatureExtractor, cls)._post_process_result(result) # adm2 = # (adm_num + ADM2_CONSTANT) / (adm_den + ADM2_CONSTANT) adm2_scores_key = cls.get_scores_key('adm2') adm_num_scores_key = cls.get_scores_key('adm_num') adm_den_scores_key = cls.get_scores_key('adm_den') result.result_dict[adm2_scores_key] = list( (np.array(result.result_dict[adm_num_scores_key]) + cls.ADM2_CONSTANT) / (np.array(result.result_dict[adm_den_scores_key]) + cls.ADM2_CONSTANT) ) # vif_scalei = vif_num_scalei / vif_den_scalei, i = 0, 1, 2, 3 vif_num_scale0_scores_key = cls.get_scores_key('vif_num_scale0') vif_den_scale0_scores_key = cls.get_scores_key('vif_den_scale0') vif_num_scale1_scores_key = cls.get_scores_key('vif_num_scale1') vif_den_scale1_scores_key = cls.get_scores_key('vif_den_scale1') vif_num_scale2_scores_key = cls.get_scores_key('vif_num_scale2') vif_den_scale2_scores_key = cls.get_scores_key('vif_den_scale2') vif_num_scale3_scores_key = cls.get_scores_key('vif_num_scale3') vif_den_scale3_scores_key = cls.get_scores_key('vif_den_scale3') vif_scale0_scores_key = cls.get_scores_key('vif_scale0') vif_scale1_scores_key = cls.get_scores_key('vif_scale1') vif_scale2_scores_key = cls.get_scores_key('vif_scale2') vif_scale3_scores_key = cls.get_scores_key('vif_scale3') result.result_dict[vif_scale0_scores_key] = list( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) ) result.result_dict[vif_scale1_scores_key] = list( (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) ) result.result_dict[vif_scale2_scores_key] = list( (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) ) result.result_dict[vif_scale3_scores_key] = list( (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) # vif2 = # ((vif_num_scale0 / vif_den_scale0) + (vif_num_scale1 / vif_den_scale1) + # (vif_num_scale2 / vif_den_scale2) + (vif_num_scale3 / vif_den_scale3)) / 4.0 vif_scores_key = cls.get_scores_key('vif2') result.result_dict[vif_scores_key] = list( ( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) + (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) + (	np.array(result.result_dict[vif_num_scale2_scores_key])	numpy.array
import hashlib from io import BytesIO import logging import os from typing import Any, cast, Dict, List, Optional, Sequence, Type, TYPE_CHECKING, Union from pkg_resources import parse_version import wandb from wandb import util from ._private import MEDIA_TMP from .base_types.media import BatchableMedia, Media from .helper_types.bounding_boxes_2d import BoundingBoxes2D from .helper_types.classes import Classes from .helper_types.image_mask import ImageMask if TYPE_CHECKING: # pragma: no cover import matplotlib # type: ignore import numpy as np # type: ignore import PIL # type: ignore import torch # type: ignore from wandb.apis.public import Artifact as PublicArtifact from ..wandb_artifacts import Artifact as LocalArtifact from ..wandb_run import Run as LocalRun ImageDataType = Union[ "matplotlib.artist.Artist", "PIL.Image", "TorchTensorType", "np.ndarray" ] ImageDataOrPathType = Union[str, "Image", ImageDataType] TorchTensorType = Union["torch.Tensor", "torch.Variable"] def _server_accepts_image_filenames() -> bool: # Newer versions of wandb accept large image filenames arrays # but older versions would have issues with this. max_cli_version = util._get_max_cli_version() if max_cli_version is None: return False return parse_version("0.12.10") <= parse_version(max_cli_version) class Image(BatchableMedia): """Format images for logging to W&B. Arguments: data_or_path: (numpy array, string, io) Accepts numpy array of image data, or a PIL image. The class attempts to infer the data format and converts it. mode: (string) The PIL mode for an image. Most common are "L", "RGB", "RGBA". Full explanation at https://pillow.readthedocs.io/en/4.2.x/handbook/concepts.html#concept-modes. caption: (string) Label for display of image. Examples: ### Create a wandb.Image from a numpy array <!--yeadoc-test:log-image-numpy-> ```python import numpy as np import wandb wandb.init() examples = [] for i in range(3): pixels = np.random.randint(low=0, high=256, size=(100, 100, 3)) image = wandb.Image(pixels, caption=f"random field {i}") examples.append(image) wandb.log({"examples": examples}) ``` ### Create a wandb.Image from a PILImage <!--yeadoc-test:log-image-pil-> ```python import numpy as np from PIL import Image as PILImage import wandb wandb.init() examples = [] for i in range(3): pixels = np.random.randint(low=0, high=256, size=(100, 100, 3), dtype=np.uint8) pil_image = PILImage.fromarray(pixels, mode="RGB") image = wandb.Image(pil_image, caption=f"random field {i}") examples.append(image) wandb.log({"examples": examples}) ``` """ MAX_ITEMS = 108 # PIL limit MAX_DIMENSION = 65500 _log_type = "image-file" format: Optional[str] _grouping: Optional[int] _caption: Optional[str] _width: Optional[int] _height: Optional[int] _image: Optional["PIL.Image"] _classes: Optional["Classes"] _boxes: Optional[Dict[str, "BoundingBoxes2D"]] _masks: Optional[Dict[str, "ImageMask"]] def __init__( self, data_or_path: "ImageDataOrPathType", mode: Optional[str] = None, caption: Optional[str] = None, grouping: Optional[int] = None, classes: Optional[Union["Classes", Sequence[dict]]] = None, boxes: Optional[Union[Dict[str, "BoundingBoxes2D"], Dict[str, dict]]] = None, masks: Optional[Union[Dict[str, "ImageMask"], Dict[str, dict]]] = None, ) -> None: super(Image, self).__init__() # TODO: We should remove grouping, it's a terrible name and I don't # think anyone uses it. self._grouping = None self._caption = None self._width = None self._height = None self._image = None self._classes = None self._boxes = None self._masks = None # Allows the user to pass an Image object as the first parameter and have a perfect copy, # only overriding additional metdata passed in. If this pattern is compelling, we can generalize. if isinstance(data_or_path, Image): self._initialize_from_wbimage(data_or_path) elif isinstance(data_or_path, str): self._initialize_from_path(data_or_path) else: self._initialize_from_data(data_or_path, mode) self._set_initialization_meta(grouping, caption, classes, boxes, masks) def _set_initialization_meta( self, grouping: Optional[int] = None, caption: Optional[str] = None, classes: Optional[Union["Classes", Sequence[dict]]] = None, boxes: Optional[Union[Dict[str, "BoundingBoxes2D"], Dict[str, dict]]] = None, masks: Optional[Union[Dict[str, "ImageMask"], Dict[str, dict]]] = None, ) -> None: if grouping is not None: self._grouping = grouping if caption is not None: self._caption = caption total_classes = {} if boxes: if not isinstance(boxes, dict): raise ValueError('Images "boxes" argument must be a dictionary') boxes_final: Dict[str, BoundingBoxes2D] = {} for key in boxes: box_item = boxes[key] if isinstance(box_item, BoundingBoxes2D): boxes_final[key] = box_item elif isinstance(box_item, dict): # TODO: Consider injecting top-level classes if user-provided is empty boxes_final[key] = BoundingBoxes2D(box_item, key) total_classes.update(boxes_final[key]._class_labels) self._boxes = boxes_final if masks: if not isinstance(masks, dict): raise ValueError('Images "masks" argument must be a dictionary') masks_final: Dict[str, ImageMask] = {} for key in masks: mask_item = masks[key] if isinstance(mask_item, ImageMask): masks_final[key] = mask_item elif isinstance(mask_item, dict): # TODO: Consider injecting top-level classes if user-provided is empty masks_final[key] = ImageMask(mask_item, key) if hasattr(masks_final[key], "_val"): total_classes.update(masks_final[key]._val["class_labels"]) self._masks = masks_final if classes is not None: if isinstance(classes, Classes): total_classes.update( {val["id"]: val["name"] for val in classes._class_set} ) else: total_classes.update({val["id"]: val["name"] for val in classes}) if len(total_classes.keys()) > 0: self._classes = Classes( [ {"id": key, "name": total_classes[key]} for key in total_classes.keys() ] ) self._width, self._height = self.image.size # type: ignore self._free_ram() def _initialize_from_wbimage(self, wbimage: "Image") -> None: self._grouping = wbimage._grouping self._caption = wbimage._caption self._width = wbimage._width self._height = wbimage._height self._image = wbimage._image self._classes = wbimage._classes self._path = wbimage._path self._is_tmp = wbimage._is_tmp self._extension = wbimage._extension self._sha256 = wbimage._sha256 self._size = wbimage._size self.format = wbimage.format self._artifact_source = wbimage._artifact_source self._artifact_target = wbimage._artifact_target # We do not want to implicitly copy boxes or masks, just the image-related data. # self._boxes = wbimage._boxes # self._masks = wbimage._masks def _initialize_from_path(self, path: str) -> None: pil_image = util.get_module( "PIL.Image", required='wandb.Image needs the PIL package. To get it, run "pip install pillow".', ) self._set_file(path, is_tmp=False) self._image = pil_image.open(path) self._image.load() ext = os.path.splitext(path)[1][1:] self.format = ext def _initialize_from_data(self, data: "ImageDataType", mode: str = None,) -> None: pil_image = util.get_module( "PIL.Image", required='wandb.Image needs the PIL package. To get it, run "pip install pillow".', ) if util.is_matplotlib_typename(util.get_full_typename(data)): buf = BytesIO() util.ensure_matplotlib_figure(data).savefig(buf) self._image = pil_image.open(buf) elif isinstance(data, pil_image.Image): self._image = data elif util.is_pytorch_tensor_typename(util.get_full_typename(data)): vis_util = util.get_module( "torchvision.utils", "torchvision is required to render images" ) if hasattr(data, "requires_grad") and data.requires_grad: data = data.detach() data = vis_util.make_grid(data, normalize=True) self._image = pil_image.fromarray( data.mul(255).clamp(0, 255).byte().permute(1, 2, 0).cpu().numpy() ) else: if hasattr(data, "numpy"): # TF data eager tensors data = data.numpy() if data.ndim > 2: data = data.squeeze() # get rid of trivial dimensions as a convenience self._image = pil_image.fromarray( self.to_uint8(data), mode=mode or self.guess_mode(data) ) tmp_path = os.path.join(MEDIA_TMP.name, str(util.generate_id()) + ".png") self.format = "png" self._image.save(tmp_path, transparency=None) self._set_file(tmp_path, is_tmp=True) @classmethod def from_json( cls: Type["Image"], json_obj: dict, source_artifact: "PublicArtifact" ) -> "Image": classes = None if json_obj.get("classes") is not None: classes = source_artifact.get(json_obj["classes"]["path"]) masks = json_obj.get("masks") _masks: Optional[Dict[str, ImageMask]] = None if masks: _masks = {} for key in masks: _masks[key] = ImageMask.from_json(masks[key], source_artifact) _masks[key]._set_artifact_source(source_artifact) _masks[key]._key = key boxes = json_obj.get("boxes") _boxes: Optional[Dict[str, BoundingBoxes2D]] = None if boxes: _boxes = {} for key in boxes: _boxes[key] = BoundingBoxes2D.from_json(boxes[key], source_artifact) _boxes[key]._key = key return cls( source_artifact.get_path(json_obj["path"]).download(), caption=json_obj.get("caption"), grouping=json_obj.get("grouping"), classes=classes, boxes=_boxes, masks=_masks, ) @classmethod def get_media_subdir(cls: Type["Image"]) -> str: return os.path.join("media", "images") def bind_to_run( self, run: "LocalRun", key: Union[int, str], step: Union[int, str], id_: Optional[Union[int, str]] = None, ignore_copy_err: Optional[bool] = None, ) -> None: super().bind_to_run(run, key, step, id_, ignore_copy_err=ignore_copy_err) if self._boxes is not None: for i, k in enumerate(self._boxes): id_ = "{}{}".format(id_, i) if id_ is not None else None self._boxes[k].bind_to_run( run, key, step, id_, ignore_copy_err=ignore_copy_err ) if self._masks is not None: for i, k in enumerate(self._masks): id_ = "{}{}".format(id_, i) if id_ is not None else None self._masks[k].bind_to_run( run, key, step, id_, ignore_copy_err=ignore_copy_err ) def to_json(self, run_or_artifact: Union["LocalRun", "LocalArtifact"]) -> dict: json_dict = super(Image, self).to_json(run_or_artifact) json_dict["_type"] = Image._log_type json_dict["format"] = self.format if self._width is not None: json_dict["width"] = self._width if self._height is not None: json_dict["height"] = self._height if self._grouping: json_dict["grouping"] = self._grouping if self._caption: json_dict["caption"] = self._caption if isinstance(run_or_artifact, wandb.wandb_sdk.wandb_artifacts.Artifact): artifact = run_or_artifact if ( self._masks is not None or self._boxes is not None ) and self._classes is None: raise ValueError( "classes must be passed to wandb.Image which have masks or bounding boxes when adding to artifacts" ) if self._classes is not None: class_id = hashlib.md5( str(self._classes._class_set).encode("utf-8") ).hexdigest() class_name = os.path.join("media", "classes", class_id + "_cls",) classes_entry = artifact.add(self._classes, class_name) json_dict["classes"] = { "type": "classes-file", "path": classes_entry.path, "digest": classes_entry.digest, } elif not isinstance(run_or_artifact, wandb.wandb_sdk.wandb_run.Run): raise ValueError("to_json accepts wandb_run.Run or wandb_artifact.Artifact") if self._boxes: json_dict["boxes"] = { k: box.to_json(run_or_artifact) for (k, box) in self._boxes.items() } if self._masks: json_dict["masks"] = { k: mask.to_json(run_or_artifact) for (k, mask) in self._masks.items() } return json_dict def guess_mode(self, data: "np.ndarray") -> str: """ Guess what type of image the np.array is representing """ # TODO: do we want to support dimensions being at the beginning of the array? if data.ndim == 2: return "L" elif data.shape[-1] == 3: return "RGB" elif data.shape[-1] == 4: return "RGBA" else: raise ValueError( "Un-supported shape for image conversion %s" % list(data.shape) ) @classmethod def to_uint8(cls, data: "np.ndarray") -> "np.ndarray": """ Converts floating point image on the range [0,1] and integer images on the range [0,255] to uint8, clipping if necessary. """ np = util.get_module( "numpy", required="wandb.Image requires numpy if not supplying PIL Images: pip install numpy", ) # I think it's better to check the image range vs the data type, since many # image libraries will return floats between 0 and 255 # some images have range -1...1 or 0-1 dmin =	np.min(data)	numpy.min
import argparse import glob import os import pickle from pathlib import Path import numpy as np from PIL import Image from tqdm import tqdm from src.align.align_trans import get_reference_facial_points, warp_and_crop_face # sys.path.append("../../") from src.align.detector import detect_faces if __name__ == "__main__": parser = argparse.ArgumentParser(description="face alignment") parser.add_argument( "-source_root", "--source_root", help="specify your source dir", default="../../data/fiw-videos/new-processed/", type=str, ) parser.add_argument( "-dest_root", "--dest_root", help="specify your destination dir", default="../../data/fiw-videos/new-processed/", type=str, ) parser.add_argument( "-crop_size", "--crop_size", help="specify size of aligned faces, align and crop with padding", default=112, type=int, ) args = parser.parse_args() source_root = args.source_root # specify your source dir dest_root = args.dest_root # specify your destination dir crop_size = ( args.crop_size ) # specify size of aligned faces, align and crop with padding scale = crop_size / 112.0 reference = get_reference_facial_points(default_square=True) * scale cwd = os.getcwd() # delete '.DS_Store' existed in the source_root os.chdir(source_root) os.system("find . -name '.DS_Store' -type f -delete") os.chdir(cwd) imfiles = [ f for f in glob.glob(f"{source_root}F????/MID/faces/msceleb*") if Path(f).is_file() ] # images = {imfile.replace(source_root, ''): Image.open(imfile) for imfile in imfiles} meta = {} # for subfolder in tqdm(os.listdir(source_root)): for imfile in tqdm(imfiles): ref = imfile.replace(source_root, "") print("Processing\t{}".format(imfile)) img = Image.open(imfile) try: # Handle exception bbs, landmarks = detect_faces(img) except Exception: print("{} is discarded due to exception!".format(imfile)) continue ref = imfile.replace(source_root, "") ndetections = len(landmarks) if ( ndetections == 0 ): # If the landmarks cannot be detected, the img will be discarded print("{} is discarded due to non-detected landmarks!".format(imfile)) meta[ref] = [] continue li_meta = [] for i in range(ndetections): im_meta = {} im_meta["face"] = i im_meta["landmarks"] = landmarks[i] im_meta["bb"] = bbs[i] facial5points = [[landmarks[i][j], landmarks[i][j + 5]] for j in range(5)] warped_face = warp_and_crop_face(	np.array(img)	numpy.array
import argparse import json import numpy as np import pandas as pd import os from sklearn.linear_model import LogisticRegression from sklearn.model_selection import train_test_split from sklearn.metrics import classification_report,f1_score from keras.models import Sequential from keras.layers import Dense, Dropout from keras import backend as K from keras.utils.vis_utils import plot_model from sklearn.externals import joblib import time def f1(y_true, y_pred): def recall(y_true, y_pred): """Recall metric. Only computes a batch-wise average of recall. Computes the recall, a metric for multi-label classification of how many relevant items are selected. """ true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1))) possible_positives = K.sum(K.round(K.clip(y_true, 0, 1))) recall = true_positives / (possible_positives + K.epsilon()) return recall def precision(y_true, y_pred): """Precision metric. Only computes a batch-wise average of precision. Computes the precision, a metric for multi-label classification of how many selected items are relevant. """ true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1))) predicted_positives = K.sum(K.round(K.clip(y_pred, 0, 1))) precision = true_positives / (predicted_positives + K.epsilon()) return precision precision = precision(y_true, y_pred) recall = recall(y_true, y_pred) return 2((precisionrecall)/(precision+recall+K.epsilon())) def get_embeddings(sentences_list,layer_json): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :return: Dictionary with key each sentence of the sentences_list and as value the embedding ''' sentences = dict()#dict with key the index of each line of the sentences_list.txt and as value the sentence embeddings = dict()##dict with key the index of each sentence and as value the its embedding sentence_emb = dict()#key:sentence,value:its embedding with open(sentences_list,'r') as file: for index,line in enumerate(file): sentences[index] = line.strip() with open(layer_json, 'r',encoding='utf-8') as f: for line in f: embeddings[json.loads(line)['linex_index']] = np.asarray(json.loads(line)['features']) for key,value in sentences.items(): sentence_emb[value] = embeddings[key] return sentence_emb def train_classifier(sentences_list,layer_json,dataset_csv,filename): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :param dataset_csv: the path of the dataset :param filename: The path of the pickle file that the model will be stored :return: ''' dataset = pd.read_csv(dataset_csv) bert_dict = get_embeddings(sentences_list,layer_json) length = list() sentence_emb = list() previous_emb = list() next_list = list() section_list = list() label = list() errors = 0 for row in dataset.iterrows(): sentence = row[1][0].strip() previous = row[1][1].strip() nexts = row[1][2].strip() section = row[1][3].strip() if sentence in bert_dict: sentence_emb.append(bert_dict[sentence]) else: sentence_emb.append(np.zeros(768)) print(sentence) errors += 1 if previous in bert_dict: previous_emb.append(bert_dict[previous]) else: previous_emb.append(np.zeros(768)) if nexts in bert_dict: next_list.append(bert_dict[nexts]) else: next_list.append(np.zeros(768)) if section in bert_dict: section_list.append(bert_dict[section]) else: section_list.append(np.zeros(768)) length.append(row[1][4]) label.append(row[1][5]) sentence_emb =	np.asarray(sentence_emb)	numpy.asarray
''' <NAME> set up :2020-1-9 intergrate img and label into one file -- fiducial1024_v1 ''' import argparse import sys, os import pickle import random import collections import json import numpy as np import scipy.io as io import scipy.misc as m import matplotlib.pyplot as plt import glob import math import time import threading import multiprocessing as mp from multiprocessing import Pool import re import cv2 # sys.path.append('/lustre/home/gwxie/hope/project/dewarp/datasets/') # /lustre/home/gwxie/program/project/unwarp/perturbed_imgaes/GAN import utils def getDatasets(dir): return os.listdir(dir) class perturbed(utils.BasePerturbed): def __init__(self, path, bg_path, save_path, save_suffix): self.path = path self.bg_path = bg_path self.save_path = save_path self.save_suffix = save_suffix def save_img(self, m, n, fold_curve='fold', repeat_time=4, fiducial_points = 16, relativeShift_position='relativeShift_v2'): origin_img = cv2.imread(self.path, flags=cv2.IMREAD_COLOR) save_img_shape = [5122, 4802] # 320 # reduce_value = np.random.choice([24, 25, 26, 27, 2*8], p=[0.01, 0.1, 0.4, 0.39, 0.1]) reduce_value = np.random.choice([22, 42, 82, 162, 242, 322, 402, 482], p=[0.02, 0.18, 0.2, 0.3, 0.1, 0.1, 0.08, 0.02]) # reduce_value = np.random.choice([82, 162, 242, 322, 402, 482], p=[0.01, 0.02, 0.2, 0.4, 0.19, 0.18]) # reduce_value = np.random.choice([16, 24, 32, 40, 48, 64], p=[0.01, 0.1, 0.2, 0.4, 0.2, 0.09]) base_img_shrink = save_img_shape[0] - reduce_value # enlarge_img_shrink = [1024, 768] # enlarge_img_shrink = [896, 672] # 420 enlarge_img_shrink = [5124, 4804] # 420 # enlarge_img_shrink = [8962, 7682] # 420 # enlarge_img_shrink = [896, 768] # 420 # enlarge_img_shrink = [768, 576] # 420 # enlarge_img_shrink = [640, 480] # 420 '''''' im_lr = origin_img.shape[0] im_ud = origin_img.shape[1] reduce_value_v2 = np.random.choice([22, 42, 82, 162, 242, 282, 322, 482], p=[0.02, 0.18, 0.2, 0.2, 0.1, 0.1, 0.1, 0.1]) # reduce_value_v2 = np.random.choice([16, 24, 28, 32, 48, 64], p=[0.01, 0.1, 0.2, 0.3, 0.25, 0.14]) if im_lr > im_ud: im_ud = min(int(im_ud / im_lr base_img_shrink), save_img_shape[1] - reduce_value_v2) im_lr = save_img_shape[0] - reduce_value else: base_img_shrink = save_img_shape[1] - reduce_value im_lr = min(int(im_lr / im_ud * base_img_shrink), save_img_shape[0] - reduce_value_v2) im_ud = base_img_shrink if round(im_lr / im_ud, 2) < 0.5 or round(im_ud / im_lr, 2) < 0.5: repeat_time = min(repeat_time, 8) edge_padding = 3 im_lr -= im_lr % (fiducial_points-1) - (2edge_padding) # im_lr % (fiducial_points-1) - 1 im_ud -= im_ud % (fiducial_points-1) - (2edge_padding) # im_ud % (fiducial_points-1) - 1 im_hight = np.linspace(edge_padding, im_lr - edge_padding, fiducial_points, dtype=np.int64) im_wide = np.linspace(edge_padding, im_ud - edge_padding, fiducial_points, dtype=np.int64) # im_lr -= im_lr % (fiducial_points-1) - (1+2edge_padding) # im_lr % (fiducial_points-1) - 1 # im_ud -= im_ud % (fiducial_points-1) - (1+2edge_padding) # im_ud % (fiducial_points-1) - 1 # im_hight = np.linspace(edge_padding, im_lr - (1+edge_padding), fiducial_points, dtype=np.int64) # im_wide = np.linspace(edge_padding, im_ud - (1+edge_padding), fiducial_points, dtype=np.int64) im_x, im_y = np.meshgrid(im_hight, im_wide) segment_x = (im_lr) // (fiducial_points-1) segment_y = (im_ud) // (fiducial_points-1) # plt.plot(im_x, im_y, # color='limegreen', # marker='.', # linestyle='') # plt.grid(True) # plt.show() self.origin_img = cv2.resize(origin_img, (im_ud, im_lr), interpolation=cv2.INTER_CUBIC) perturbed_bg_ = getDatasets(self.bg_path) perturbed_bg_img_ = self.bg_path+random.choice(perturbed_bg_) perturbed_bg_img = cv2.imread(perturbed_bg_img_, flags=cv2.IMREAD_COLOR) mesh_shape = self.origin_img.shape[:2] self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 256, dtype=np.float32)#np.zeros_like(perturbed_bg_img) # self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 0, dtype=np.int16)#np.zeros_like(perturbed_bg_img) self.new_shape = self.synthesis_perturbed_img.shape[:2] perturbed_bg_img = cv2.resize(perturbed_bg_img, (save_img_shape[1], save_img_shape[0]), cv2.INPAINT_TELEA) origin_pixel_position = np.argwhere(np.zeros(mesh_shape, dtype=np.uint32) == 0).reshape(mesh_shape[0], mesh_shape[1], 2) pixel_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape(self.new_shape[0], self.new_shape[1], 2) self.perturbed_xy_ = np.zeros((self.new_shape[0], self.new_shape[1], 2)) # self.perturbed_xy_ = pixel_position.copy().astype(np.float32) # fiducial_points_grid = origin_pixel_position[im_x, im_y] self.synthesis_perturbed_label = np.zeros((self.new_shape[0], self.new_shape[1], 2)) x_min, y_min, x_max, y_max = self.adjust_position_v2(0, 0, mesh_shape[0], mesh_shape[1], save_img_shape) origin_pixel_position += [x_min, y_min] x_min, y_min, x_max, y_max = self.adjust_position(0, 0, mesh_shape[0], mesh_shape[1]) x_shift = random.randint(-enlarge_img_shrink[0]//16, enlarge_img_shrink[0]//16) y_shift = random.randint(-enlarge_img_shrink[1]//16, enlarge_img_shrink[1]//16) x_min += x_shift x_max += x_shift y_min += y_shift y_max += y_shift '''im_x,y''' im_x += x_min im_y += y_min self.synthesis_perturbed_img[x_min:x_max, y_min:y_max] = self.origin_img self.synthesis_perturbed_label[x_min:x_max, y_min:y_max] = origin_pixel_position synthesis_perturbed_img_map = self.synthesis_perturbed_img.copy() synthesis_perturbed_label_map = self.synthesis_perturbed_label.copy() foreORbackground_label = np.full((mesh_shape), 1, dtype=np.int16) foreORbackground_label_map = np.full((self.new_shape), 0, dtype=np.int16) foreORbackground_label_map[x_min:x_max, y_min:y_max] = foreORbackground_label # synthesis_perturbed_img_map = self.pad(self.synthesis_perturbed_img.copy(), x_min, y_min, x_max, y_max) # synthesis_perturbed_label_map = self.pad(synthesis_perturbed_label_map, x_min, y_min, x_max, y_max) '''****************************************************************''' is_normalizationFun_mixture = self.is_perform(0.2, 0.8) # if not is_normalizationFun_mixture: normalizationFun_0_1 = False # normalizationFun_0_1 = self.is_perform(0.5, 0.5) if fold_curve == 'fold': fold_curve_random = True # is_normalizationFun_mixture = False normalizationFun_0_1 = self.is_perform(0.2, 0.8) if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: fold_curve_random = self.is_perform(0.1, 0.9) # False # self.is_perform(0.01, 0.99) alpha_perturbed = random.randint(80, 160) / 100 # is_normalizationFun_mixture = False # self.is_perform(0.01, 0.99) synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) # synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 0, dtype=np.int16) synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) alpha_perturbed_change = self.is_perform(0.5, 0.5) p_pp_choice = self.is_perform(0.8, 0.2) if fold_curve == 'fold' else self.is_perform(0.1, 0.9) for repeat_i in range(repeat_time): if alpha_perturbed_change: if fold_curve == 'fold': if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: alpha_perturbed = random.randint(80, 160) / 100 '''''' linspace_x = [0, (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - 1] linspace_y = [0, (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - 1] linspace_x_seq = [1, 2, 3] linspace_y_seq = [1, 2, 3] r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_p = np.array( [random.randint(linspace_x[r_x-1] 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 if ((r_x == 1 or r_x == 3) and (r_y == 1 or r_y == 3)) and p_pp_choice: linspace_x_seq.remove(r_x) linspace_y_seq.remove(r_y) r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_pp = np.array( [random.randint(linspace_x[r_x-1] * 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 # perturbed_p, perturbed_pp = np.array( # [random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) \ # , np.array([random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) # perturbed_p, perturbed_pp = np.array( # [random.randint((self.new_shape[0]-im_lr)//210, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) 10) / 10, # random.randint((self.new_shape[1]-im_ud)//210, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) 10) / 10]) \ # , np.array([random.randint((self.new_shape[0]-im_lr)//210, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) 10) / 10, # random.randint((self.new_shape[1]-im_ud)//210, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) 10) / 10]) '''''' perturbed_vp = perturbed_pp - perturbed_p perturbed_vp_norm = np.linalg.norm(perturbed_vp) perturbed_distance_vertex_and_line = np.dot((perturbed_p - pixel_position), perturbed_vp) / perturbed_vp_norm '''''' # perturbed_v = np.array([random.randint(-3000, 3000) / 100, random.randint(-3000, 3000) / 100]) # perturbed_v = np.array([random.randint(-4000, 4000) / 100, random.randint(-4000, 4000) / 100]) if fold_curve == 'fold' and self.is_perform(0.6, 0.4): # self.is_perform(0.3, 0.7): # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) perturbed_v = np.array([random.randint(-10000, 10000) / 100, random.randint(-10000, 10000) / 100]) # perturbed_v = np.array([random.randint(-11000, 11000) / 100, random.randint(-11000, 11000) / 100]) else: # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) # perturbed_v = np.array([random.randint(-16000, 16000) / 100, random.randint(-16000, 16000) / 100]) perturbed_v = np.array([random.randint(-8000, 8000) / 100, random.randint(-8000, 8000) / 100]) # perturbed_v = np.array([random.randint(-3500, 3500) / 100, random.randint(-3500, 3500) / 100]) # perturbed_v = np.array([random.randint(-600, 600) / 10, random.randint(-600, 600) / 10]) '''''' if fold_curve == 'fold': if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) '''''' if fold_curve_random: # omega_perturbed = (alpha_perturbed+0.2) / (perturbed_d + alpha_perturbed) # omega_perturbed = alpha_perturbedperturbed_d omega_perturbed = alpha_perturbed / (perturbed_d + alpha_perturbed) else: omega_perturbed = 1 - perturbed_d alpha_perturbed '''shadow''' if self.is_perform(0.6, 0.4): synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] = np.minimum(np.maximum(synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] - np.int16(np.round(omega_perturbed[x_min:x_max, y_min:y_max].repeat(3).reshape(x_max-x_min, y_max-y_min, 3) * abs(np.linalg.norm(perturbed_v//2))np.array([0.4-random.random()0.1, 0.4-random.random()0.1, 0.4-random.random()0.1]))), 0), 255) '''''' if relativeShift_position in ['position', 'relativeShift_v2']: self.perturbed_xy_ += np.array([omega_perturbed * perturbed_v[0], omega_perturbed * perturbed_v[1]]).transpose(1, 2, 0) else: print('relativeShift_position error') exit() ''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 # synthesis_perturbed_img = np.around(synthesis_perturbed_img).astype(np.uint8) synthesis_perturbed_label[:, :, 0] = foreORbackground_label synthesis_perturbed_label[:, :, 1] = foreORbackground_label synthesis_perturbed_img[:, :, 0] = foreORbackground_label synthesis_perturbed_img[:, :, 1] = foreORbackground_label synthesis_perturbed_img[:, :, 2] = foreORbackground_label self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label ''' '''perspective''' perspective_shreshold = random.randint(26, 36)10 # 280 x_min_per, y_min_per, x_max_per, y_max_per = self.adjust_position(perspective_shreshold, perspective_shreshold, self.new_shape[0]-perspective_shreshold, self.new_shape[1]-perspective_shreshold) pts1 = np.float32([[x_min_per, y_min_per], [x_max_per, y_min_per], [x_min_per, y_max_per], [x_max_per, y_max_per]]) e_1_ = x_max_per - x_min_per e_2_ = y_max_per - y_min_per e_3_ = e_2_ e_4_ = e_1_ perspective_shreshold_h = e_1_0.02 perspective_shreshold_w = e_2_0.02 a_min_, a_max_ = 70, 110 # if self.is_perform(1, 0): if fold_curve == 'curve' and self.is_perform(0.5, 0.5): if self.is_perform(0.5, 0.5): while True: pts2 = np.around( np.float32([[x_min_per - (random.random()) * perspective_shreshold, y_min_per + (random.random()) * perspective_shreshold], [x_max_per - (random.random()) * perspective_shreshold, y_min_per - (random.random()) * perspective_shreshold], [x_min_per + (random.random()) * perspective_shreshold, y_max_per + (random.random()) * perspective_shreshold], [x_max_per + (random.random()) * perspective_shreshold, y_max_per - (random.random()) * perspective_shreshold]])) # right e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break else: while True: pts2 = np.around( np.float32([[x_min_per + (random.random()) * perspective_shreshold, y_min_per - (random.random()) * perspective_shreshold], [x_max_per + (random.random()) * perspective_shreshold, y_min_per + (random.random()) * perspective_shreshold], [x_min_per - (random.random()) * perspective_shreshold, y_max_per - (random.random()) * perspective_shreshold], [x_max_per - (random.random()) * perspective_shreshold, y_max_per + (random.random()) * perspective_shreshold]])) e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break else: while True: pts2 = np.around(np.float32([[x_min_per+(random.random()-0.5)perspective_shreshold, y_min_per+(random.random()-0.5)perspective_shreshold], [x_max_per+(random.random()-0.5)perspective_shreshold, y_min_per+(random.random()-0.5)perspective_shreshold], [x_min_per+(random.random()-0.5)perspective_shreshold, y_max_per+(random.random()-0.5)perspective_shreshold], [x_max_per+(random.random()-0.5)perspective_shreshold, y_max_per+(random.random()-0.5)perspective_shreshold]])) e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break M = cv2.getPerspectiveTransform(pts1, pts2) one = np.ones((self.new_shape[0], self.new_shape[1], 1), dtype=np.int16) matr = np.dstack((pixel_position, one)) new = np.dot(M, matr.reshape(-1, 3).T).T.reshape(self.new_shape[0], self.new_shape[1], 3) x = new[:, :, 0]/new[:, :, 2] y = new[:, :, 1]/new[:, :, 2] perturbed_xy_ = np.dstack((x, y)) # perturbed_xy_round_int = np.around(cv2.bilateralFilter(perturbed_xy_round_int, 9, 75, 75)) # perturbed_xy_round_int = np.around(cv2.blur(perturbed_xy_, (17, 17))) # perturbed_xy_round_int = cv2.blur(perturbed_xy_round_int, (17, 17)) # perturbed_xy_round_int = cv2.GaussianBlur(perturbed_xy_round_int, (7, 7), 0) perturbed_xy_ = perturbed_xy_-np.min(perturbed_xy_.T.reshape(2, -1), 1) # perturbed_xy_round_int = np.around(perturbed_xy_round_int-np.min(perturbed_xy_round_int.T.reshape(2, -1), 1)).astype(np.int16) self.perturbed_xy_ += perturbed_xy_ '''perspective end''' '''to img''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) # self.perturbed_xy_ = cv2.blur(self.perturbed_xy_, (7, 7)) self.perturbed_xy_ = cv2.GaussianBlur(self.perturbed_xy_, (7, 7), 0) '''get fiducial points''' fiducial_points_coordinate = self.perturbed_xy_[im_x, im_y] vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label self.foreORbackground_label = foreORbackground_label '''draw fiducial points stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_img.copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1,2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[1] + math.ceil(stepSize / 2), l[0] + math.ceil(stepSize / 2)), 5, (0, 0, 255), -1) cv2.imwrite('/lustre/home/gwxie/program/project/unwarp/unwarp_perturbed/TPS/img/cv_TPS_large.jpg', fiducial_points_synthesis_perturbed_img) ''' '''clip''' perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = -1, -1, self.new_shape[0], self.new_shape[1] for x in range(self.new_shape[0] // 2, perturbed_x_max): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and perturbed_x_max - 1 > x: perturbed_x_max = x break for x in range(self.new_shape[0] // 2, perturbed_x_min, -1): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and x > 0: perturbed_x_min = x break for y in range(self.new_shape[1] // 2, perturbed_y_max): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and perturbed_y_max - 1 > y: perturbed_y_max = y break for y in range(self.new_shape[1] // 2, perturbed_y_min, -1): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and y > 0: perturbed_y_min = y break if perturbed_x_min == 0 or perturbed_x_max == self.new_shape[0] or perturbed_y_min == self.new_shape[1] or perturbed_y_max == self.new_shape[1]: raise Exception('clip error') if perturbed_x_max - perturbed_x_min < im_lr//2 or perturbed_y_max - perturbed_y_min < im_ud//2: raise Exception('clip error') perfix_ = self.save_suffix+'_'+str(m)+'_'+str(n) is_shrink = False if perturbed_x_max - perturbed_x_min > save_img_shape[0] or perturbed_y_max - perturbed_y_min > save_img_shape[1]: is_shrink = True synthesis_perturbed_img = cv2.resize(self.synthesis_perturbed_img[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) synthesis_perturbed_label = cv2.resize(self.synthesis_perturbed_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) foreORbackground_label = cv2.resize(self.foreORbackground_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 '''shrink fiducial points''' center_x_l, center_y_l = perturbed_x_min + (perturbed_x_max - perturbed_x_min) // 2, perturbed_y_min + (perturbed_y_max - perturbed_y_min) // 2 fiducial_points_coordinate_copy = fiducial_points_coordinate.copy() shrink_x = im_lr/(perturbed_x_max - perturbed_x_min) shrink_y = im_ud/(perturbed_y_max - perturbed_y_min) fiducial_points_coordinate = [shrink_x, shrink_y] center_x_l = shrink_x center_y_l = shrink_y # fiducial_points_coordinate[1:, 1:] = [shrink_x, shrink_y] # fiducial_points_coordinate[1:, :1, 0] = shrink_x # fiducial_points_coordinate[:1, 1:, 1] = shrink_y # perturbed_x_min_copy, perturbed_y_min_copy, perturbed_x_max_copy, perturbed_y_max_copy = perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = self.adjust_position_v2(0, 0, im_lr, im_ud, self.new_shape) self.synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) self.synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) self.foreORbackground_label = np.zeros_like(self.foreORbackground_label) self.synthesis_perturbed_img[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_img self.synthesis_perturbed_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_label self.foreORbackground_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max] = foreORbackground_label center_x, center_y = perturbed_x_min + (perturbed_x_max - perturbed_x_min) // 2, perturbed_y_min + (perturbed_y_max - perturbed_y_min) // 2 if is_shrink: fiducial_points_coordinate += [center_x-center_x_l, center_y-center_y_l] '''draw fiducial points stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_img.copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1, 2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[1] + math.ceil(stepSize / 2), l[0] + math.ceil(stepSize / 2)), 5, (0, 0, 255), -1) cv2.imwrite('/lustre/home/gwxie/program/project/unwarp/unwarp_perturbed/TPS/img/cv_TPS_small.jpg',fiducial_points_synthesis_perturbed_img) ''' self.new_shape = save_img_shape self.synthesis_perturbed_img = self.synthesis_perturbed_img[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2, :].copy() self.synthesis_perturbed_label = self.synthesis_perturbed_label[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2, :].copy() self.foreORbackground_label = self.foreORbackground_label[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2].copy() perturbed_x_ = max(self.new_shape[0] - (perturbed_x_max - perturbed_x_min), 0) perturbed_x_min = perturbed_x_ // 2 perturbed_x_max = self.new_shape[0] - perturbed_x_ // 2 if perturbed_x_%2 == 0 else self.new_shape[0] - (perturbed_x_ // 2 + 1) perturbed_y_ = max(self.new_shape[1] - (perturbed_y_max - perturbed_y_min), 0) perturbed_y_min = perturbed_y_ // 2 perturbed_y_max = self.new_shape[1] - perturbed_y_ // 2 if perturbed_y_%2 == 0 else self.new_shape[1] - (perturbed_y_ // 2 + 1) '''clip perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = -1, -1, self.new_shape[0], self.new_shape[1] for x in range(self.new_shape[0] // 2, perturbed_x_max): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and perturbed_x_max - 1 > x: perturbed_x_max = x break for x in range(self.new_shape[0] // 2, perturbed_x_min, -1): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and x > 0: perturbed_x_min = x break for y in range(self.new_shape[1] // 2, perturbed_y_max): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and perturbed_y_max - 1 > y: perturbed_y_max = y break for y in range(self.new_shape[1] // 2, perturbed_y_min, -1): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and y > 0: perturbed_y_min = y break center_x, center_y = perturbed_x_min+(perturbed_x_max - perturbed_x_min)//2, perturbed_y_min+(perturbed_y_max - perturbed_y_min)//2 perfix_ = self.save_suffix+'_'+str(m)+'_'+str(n) self.new_shape = save_img_shape perturbed_x_ = max(self.new_shape[0] - (perturbed_x_max - perturbed_x_min), 0) perturbed_x_min = perturbed_x_ // 2 perturbed_x_max = self.new_shape[0] - perturbed_x_ // 2 if perturbed_x_%2 == 0 else self.new_shape[0] - (perturbed_x_ // 2 + 1) perturbed_y_ = max(self.new_shape[1] - (perturbed_y_max - perturbed_y_min), 0) perturbed_y_min = perturbed_y_ // 2 perturbed_y_max = self.new_shape[1] - perturbed_y_ // 2 if perturbed_y_%2 == 0 else self.new_shape[1] - (perturbed_y_ // 2 + 1) self.synthesis_perturbed_img = self.synthesis_perturbed_img[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2, :].copy() self.synthesis_perturbed_label = self.synthesis_perturbed_label[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2, :].copy() self.foreORbackground_label = self.foreORbackground_label[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2].copy() ''' '''save''' pixel_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape(self.new_shape[0], self.new_shape[1], 2) if relativeShift_position == 'relativeShift_v2': self.synthesis_perturbed_label -= pixel_position fiducial_points_coordinate -= [center_x - self.new_shape[0] // 2, center_y - self.new_shape[1] // 2] self.synthesis_perturbed_label[:, :, 0] = self.foreORbackground_label self.synthesis_perturbed_label[:, :, 1] = self.foreORbackground_label self.synthesis_perturbed_img[:, :, 0] = self.foreORbackground_label self.synthesis_perturbed_img[:, :, 1] = self.foreORbackground_label self.synthesis_perturbed_img[:, :, 2] = self.foreORbackground_label ''' synthesis_perturbed_img_filter = self.synthesis_perturbed_img.copy() synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (3, 3), 0) # if self.is_perform(0.9, 0.1) or repeat_time > 5: # # if self.is_perform(0.1, 0.9) and repeat_time > 9: # # synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (7, 7), 0) # # else: # synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (5, 5), 0) # else: # synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (3, 3), 0) self.synthesis_perturbed_img[self.foreORbackground_label == 1] = synthesis_perturbed_img_filter[self.foreORbackground_label == 1] ''' ''' perturbed_bg_img = perturbed_bg_img.astype(np.float32) perturbed_bg_img[:, :, 0] = 1 - self.foreORbackground_label perturbed_bg_img[:, :, 1] = 1 - self.foreORbackground_label perturbed_bg_img[:, :, 2] = 1 - self.foreORbackground_label self.synthesis_perturbed_img += perturbed_bg_img HSV perturbed_bg_img = perturbed_bg_img.astype(np.float32) if self.is_perform(0.1, 0.9): if self.is_perform(0.2, 0.8): synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_RGB2HSV) H_, S_, V_ = (random.random()-0.2)20, (random.random()-0.2)/8, (random.random()-0.2)20 synthesis_perturbed_img_clip_HSV[:, :, 0], synthesis_perturbed_img_clip_HSV[:, :, 1], synthesis_perturbed_img_clip_HSV[:, :, 2] = synthesis_perturbed_img_clip_HSV[:, :, 0]-H_, synthesis_perturbed_img_clip_HSV[:, :, 1]-S_, synthesis_perturbed_img_clip_HSV[:, :, 2]-V_ synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_HSV2RGB) perturbed_bg_img[:, :, 0] = 1-self.foreORbackground_label perturbed_bg_img[:, :, 1] = 1-self.foreORbackground_label perturbed_bg_img[:, :, 2] = 1-self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV else: perturbed_bg_img_HSV = perturbed_bg_img perturbed_bg_img_HSV = cv2.cvtColor(perturbed_bg_img_HSV, cv2.COLOR_RGB2HSV) H_, S_, V_ = (random.random()-0.5)20, (random.random()-0.5)/8, (random.random()-0.2)20 perturbed_bg_img_HSV[:, :, 0], perturbed_bg_img_HSV[:, :, 1], perturbed_bg_img_HSV[:, :, 2] = perturbed_bg_img_HSV[:, :, 0]-H_, perturbed_bg_img_HSV[:, :, 1]-S_, perturbed_bg_img_HSV[:, :, 2]-V_ perturbed_bg_img_HSV = cv2.cvtColor(perturbed_bg_img_HSV, cv2.COLOR_HSV2RGB) perturbed_bg_img_HSV[:, :, 0] = 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 1] = 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 2] = 1-self.foreORbackground_label self.synthesis_perturbed_img += perturbed_bg_img_HSV # self.synthesis_perturbed_img[np.sum(self.synthesis_perturbed_img, 2) == 771] = perturbed_bg_img_HSV[np.sum(self.synthesis_perturbed_img, 2) == 771] else: synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() perturbed_bg_img[:, :, 0] = 1 - self.foreORbackground_label perturbed_bg_img[:, :, 1] = 1 - self.foreORbackground_label perturbed_bg_img[:, :, 2] = 1 - self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img # synthesis_perturbed_img_clip_HSV[np.sum(self.synthesis_perturbed_img, 2) == 771] = perturbed_bg_img[np.sum(self.synthesis_perturbed_img, 2) == 771] synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_RGB2HSV) H_, S_, V_ = (random.random()-0.5)20, (random.random()-0.5)/10, (random.random()-0.4)20 synthesis_perturbed_img_clip_HSV[:, :, 0], synthesis_perturbed_img_clip_HSV[:, :, 1], synthesis_perturbed_img_clip_HSV[:, :, 2] = synthesis_perturbed_img_clip_HSV[:, :, 0]-H_, synthesis_perturbed_img_clip_HSV[:, :, 1]-S_, synthesis_perturbed_img_clip_HSV[:, :, 2]-V_ synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_HSV2RGB) self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV ''' '''HSV_v2''' perturbed_bg_img = perturbed_bg_img.astype(np.float32) # if self.is_perform(1, 0): # if self.is_perform(1, 0): if self.is_perform(0.1, 0.9): if self.is_perform(0.2, 0.8): synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() synthesis_perturbed_img_clip_HSV = self.HSV_v1(synthesis_perturbed_img_clip_HSV) perturbed_bg_img[:, :, 0] = 1-self.foreORbackground_label perturbed_bg_img[:, :, 1] = 1-self.foreORbackground_label perturbed_bg_img[:, :, 2] = 1-self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV else: perturbed_bg_img_HSV = perturbed_bg_img perturbed_bg_img_HSV = self.HSV_v1(perturbed_bg_img_HSV) perturbed_bg_img_HSV[:, :, 0] = 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 1] = 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 2] = 1-self.foreORbackground_label self.synthesis_perturbed_img += perturbed_bg_img_HSV # self.synthesis_perturbed_img[np.sum(self.synthesis_perturbed_img, 2) == 771] = perturbed_bg_img_HSV[np.sum(self.synthesis_perturbed_img, 2) == 771] else: synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() perturbed_bg_img[:, :, 0] = 1 - self.foreORbackground_label perturbed_bg_img[:, :, 1] = 1 - self.foreORbackground_label perturbed_bg_img[:, :, 2] = 1 - self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img synthesis_perturbed_img_clip_HSV = self.HSV_v1(synthesis_perturbed_img_clip_HSV) self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV '''''' # cv2.imwrite(self.save_path+'clip/'+perfix_+'_'+fold_curve+str(perturbed_time)+'-'+str(repeat_time)+'.png', synthesis_perturbed_img_clip) self.synthesis_perturbed_img[self.synthesis_perturbed_img < 0] = 0 self.synthesis_perturbed_img[self.synthesis_perturbed_img > 255] = 255 self.synthesis_perturbed_img = np.around(self.synthesis_perturbed_img).astype(np.uint8) label = np.zeros_like(self.synthesis_perturbed_img, dtype=np.float32) label[:, :, :2] = self.synthesis_perturbed_label label[:, :, 2] = self.foreORbackground_label # grey = np.around(self.synthesis_perturbed_img[:, :, 0] * 0.2989 + self.synthesis_perturbed_img[:, :, 1] * 0.5870 + self.synthesis_perturbed_img[:, :, 0] * 0.1140).astype(np.int16) # synthesis_perturbed_grey = np.concatenate((grey.reshape(self.new_shape[0], self.new_shape[1], 1), label), axis=2) synthesis_perturbed_color = np.concatenate((self.synthesis_perturbed_img, label), axis=2) self.synthesis_perturbed_color = np.zeros_like(synthesis_perturbed_color, dtype=np.float32) # self.synthesis_perturbed_grey = np.zeros_like(synthesis_perturbed_grey, dtype=np.float32) reduce_value_x = int(round(min((random.random() / 2) * (self.new_shape[0] - (perturbed_x_max - perturbed_x_min)), min(reduce_value, reduce_value_v2)))) reduce_value_y = int(round(min((random.random() / 2) * (self.new_shape[1] - (perturbed_y_max - perturbed_y_min)), min(reduce_value, reduce_value_v2)))) perturbed_x_min = max(perturbed_x_min - reduce_value_x, 0) perturbed_x_max = min(perturbed_x_max + reduce_value_x, self.new_shape[0]) perturbed_y_min = max(perturbed_y_min - reduce_value_y, 0) perturbed_y_max = min(perturbed_y_max + reduce_value_y, self.new_shape[1]) if im_lr >= im_ud: self.synthesis_perturbed_color[:, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_color[:, perturbed_y_min:perturbed_y_max, :] # self.synthesis_perturbed_grey[:, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_grey[:, perturbed_y_min:perturbed_y_max, :] else: self.synthesis_perturbed_color[perturbed_x_min:perturbed_x_max, :, :] = synthesis_perturbed_color[perturbed_x_min:perturbed_x_max, :, :] # self.synthesis_perturbed_grey[perturbed_x_min:perturbed_x_max, :, :] = synthesis_perturbed_grey[perturbed_x_min:perturbed_x_max, :, :] '''blur''' if self.is_perform(0.1, 0.9): synthesis_perturbed_img_filter = self.synthesis_perturbed_color[:, :, :3].copy() if self.is_perform(0.1, 0.9): synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (5, 5), 0) else: synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (3, 3), 0) if self.is_perform(0.5, 0.5): self.synthesis_perturbed_color[:, :, :3][self.synthesis_perturbed_color[:, :, 5] == 1] = synthesis_perturbed_img_filter[self.synthesis_perturbed_color[:, :, 5] == 1] else: self.synthesis_perturbed_color[:, :, :3] = synthesis_perturbed_img_filter fiducial_points_coordinate = fiducial_points_coordinate[:, :, ::-1] '''draw fiducial points''' stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_color[:, :, :3].copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1, 2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[0] + math.ceil(stepSize / 2), l[1] + math.ceil(stepSize / 2)), 2, (0, 0, 255), -1) cv2.imwrite(self.save_path + 'fiducial_points/' + perfix_ + '_' + fold_curve + '.png', fiducial_points_synthesis_perturbed_img) cv2.imwrite(self.save_path + 'png/' + perfix_ + '_' + fold_curve + '.png', self.synthesis_perturbed_color[:, :, :3]) '''forward-begin''' self.forward_mapping = np.full((save_img_shape[0], save_img_shape[1], 2), 0, dtype=np.float32) forward_mapping = np.full((save_img_shape[0], save_img_shape[1], 2), 0, dtype=np.float32) forward_position = (self.synthesis_perturbed_color[:, :, 3:5] + pixel_position)[self.synthesis_perturbed_color[:, :, 5] != 0, :] flat_position = np.argwhere(np.zeros(save_img_shape, dtype=np.uint32) == 0) vtx, wts = self.interp_weights(forward_position, flat_position) wts_sum =	np.abs(wts)	numpy.abs
# -- coding: utf-8 -- """ Created on Thu Nov 28 12:10:11 2019 @author: Omer """ ## File handler ## This file was initially intended purely to generate the matrices for the near earth code found in: https://public.ccsds.org/Pubs/131x1o2e2s.pdf ## The values from the above pdf were copied manually to a txt file, and it is the purpose of this file to parse it. ## The emphasis here is on correctness, I currently do not see a reason to generalise this file, since matrices will be saved in either json or some matrix friendly format. import numpy as np from scipy.linalg import circulant #import matplotlib.pyplot as plt import scipy.io import common import hashlib import os projectDir = os.environ.get('LDPC') if projectDir == None: import pathlib projectDir = pathlib.Path(__file__).parent.absolute() ## <NAME>: added on 01/12/2020, need to make sure this doesn't break anything. import sys sys.path.insert(1, projectDir) FILE_HANDLER_INT_DATA_TYPE = np.int32 GENERAL_CODE_MATRIX_DATA_TYPE = np.int32 NIBBLE_CONVERTER = np.array([8, 4, 2, 1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) def nibbleToHex(inputArray): n = NIBBLE_CONVERTER.dot(inputArray) if n == 10: h = 'A' elif n== 11: h = 'B' elif n== 12: h = 'C' elif n== 13: h = 'D' elif n== 14: h = 'E' elif n== 15: h = 'F' else: h = str(n) return h def binaryArraytoHex(inputArray): d1 = len(inputArray) assert (d1 % 4 == 0) outputArray = np.zeros(d1//4, dtype = str) outputString = '' for j in range(d1//4): nibble = inputArray[4 * j : 4 * j + 4] h = nibbleToHex(nibble) outputArray[j] = h outputString = outputString + h return outputArray, outputString def hexStringToBinaryArray(hexString): outputBinary = np.array([], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) for i in hexString: if i == '0': nibble = np.array([0,0,0,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '1': nibble = np.array([0,0,0,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '2': nibble = np.array([0,0,1,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '3': nibble = np.array([0,0,1,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '4': nibble = np.array([0,1,0,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '5': nibble = np.array([0,1,0,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '6': nibble = np.array([0,1,1,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '7': nibble = np.array([0,1,1,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '8': nibble = np.array([1,0,0,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '9': nibble = np.array([1,0,0,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == 'A': nibble = np.array([1,0,1,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == 'B': nibble = np.array([1,0,1,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == 'C': nibble = np.array([1,1,0,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == 'D': nibble = np.array([1,1,0,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == 'E': nibble = np.array([1,1,1,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == 'F': nibble = np.array([1,1,1,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) else: #print('Error, 0-9 or A-F') pass nibble = np.array([], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) outputBinary =	np.hstack((outputBinary, nibble))	numpy.hstack
import argparse import json import numpy as np import pandas as pd import os from sklearn.linear_model import LogisticRegression from sklearn.model_selection import train_test_split from sklearn.metrics import classification_report,f1_score from keras.models import Sequential from keras.layers import Dense, Dropout from keras import backend as K from keras.utils.vis_utils import plot_model from sklearn.externals import joblib import time def f1(y_true, y_pred): def recall(y_true, y_pred): """Recall metric. Only computes a batch-wise average of recall. Computes the recall, a metric for multi-label classification of how many relevant items are selected. """ true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1))) possible_positives = K.sum(K.round(K.clip(y_true, 0, 1))) recall = true_positives / (possible_positives + K.epsilon()) return recall def precision(y_true, y_pred): """Precision metric. Only computes a batch-wise average of precision. Computes the precision, a metric for multi-label classification of how many selected items are relevant. """ true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1))) predicted_positives = K.sum(K.round(K.clip(y_pred, 0, 1))) precision = true_positives / (predicted_positives + K.epsilon()) return precision precision = precision(y_true, y_pred) recall = recall(y_true, y_pred) return 2((precisionrecall)/(precision+recall+K.epsilon())) def get_embeddings(sentences_list,layer_json): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :return: Dictionary with key each sentence of the sentences_list and as value the embedding ''' sentences = dict()#dict with key the index of each line of the sentences_list.txt and as value the sentence embeddings = dict()##dict with key the index of each sentence and as value the its embedding sentence_emb = dict()#key:sentence,value:its embedding with open(sentences_list,'r') as file: for index,line in enumerate(file): sentences[index] = line.strip() with open(layer_json, 'r',encoding='utf-8') as f: for line in f: embeddings[json.loads(line)['linex_index']] = np.asarray(json.loads(line)['features']) for key,value in sentences.items(): sentence_emb[value] = embeddings[key] return sentence_emb def train_classifier(sentences_list,layer_json,dataset_csv,filename): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :param dataset_csv: the path of the dataset :param filename: The path of the pickle file that the model will be stored :return: ''' dataset = pd.read_csv(dataset_csv) bert_dict = get_embeddings(sentences_list,layer_json) length = list() sentence_emb = list() previous_emb = list() next_list = list() section_list = list() label = list() errors = 0 for row in dataset.iterrows(): sentence = row[1][0].strip() previous = row[1][1].strip() nexts = row[1][2].strip() section = row[1][3].strip() if sentence in bert_dict: sentence_emb.append(bert_dict[sentence]) else: sentence_emb.append(np.zeros(768)) print(sentence) errors += 1 if previous in bert_dict: previous_emb.append(bert_dict[previous]) else: previous_emb.append(np.zeros(768)) if nexts in bert_dict: next_list.append(bert_dict[nexts]) else: next_list.append(np.zeros(768)) if section in bert_dict: section_list.append(bert_dict[section]) else: section_list.append(np.zeros(768)) length.append(row[1][4]) label.append(row[1][5]) sentence_emb = np.asarray(sentence_emb) print(sentence_emb.shape) next_emb = np.asarray(next_list) print(next_emb.shape) previous_emb = np.asarray(previous_emb) print(previous_emb.shape) section_emb = np.asarray(section_list) print(sentence_emb.shape) length = np.asarray(length) print(length.shape) label = np.asarray(label) print(errors) features = np.concatenate([sentence_emb, previous_emb, next_emb,section_emb], axis=1) features = np.column_stack([features, length]) # np.append(features,length,axis=1) print(features.shape) X_train, X_val, y_train, y_val = train_test_split(features, label, test_size=0.33, random_state=42) log = LogisticRegression(random_state=0, solver='newton-cg', max_iter=1000, C=0.1) log.fit(X_train, y_train) #save the model _ = joblib.dump(log, filename, compress=9) predictions = log.predict(X_val) print("###########################################") print("Results using embeddings from the",layer_json,"file") print(classification_report(y_val, predictions)) print("F1 score using Logistic Regression:",f1_score(y_val, predictions)) print("###########################################") #train a DNN f1_results = list() for i in range(3): model = Sequential() model.add(Dense(64, activation='relu', trainable=True)) model.add(Dense(128, activation='relu', trainable=True)) model.add(Dropout(0.30)) model.add(Dense(64, activation='relu', trainable=True)) model.add(Dropout(0.25)) model.add(Dense(64, activation='relu', trainable=True)) model.add(Dropout(0.35)) model.add(Dense(1, activation='sigmoid')) # compile network model.compile(loss='binary_crossentropy', optimizer='sgd', metrics=[f1]) # fit network model.fit(X_train, y_train, epochs=100, batch_size=64) loss, f_1 = model.evaluate(X_val, y_val, verbose=1) print('\nTest F1: %f' % (f_1 * 100)) f1_results.append(f_1) model = None print("###########################################") print("Results using embeddings from the", layer_json, "file") # evaluate print(np.mean(f1_results)) print("###########################################") def parameter_tuning_LR(sentences_list,layer_json,dataset_csv): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :param dataset_csv: the path of the dataset :return: ''' dataset = pd.read_csv(dataset_csv) bert_dict = get_embeddings(sentences_list,layer_json) length = list() sentence_emb = list() previous_emb = list() next_list = list() section_list = list() label = list() errors = 0 for row in dataset.iterrows(): sentence = row[1][0].strip() previous = row[1][1].strip() nexts = row[1][2].strip() section = row[1][3].strip() if sentence in bert_dict: sentence_emb.append(bert_dict[sentence]) else: sentence_emb.append(np.zeros(768)) print(sentence) errors += 1 if previous in bert_dict: previous_emb.append(bert_dict[previous]) else: previous_emb.append(np.zeros(768)) if nexts in bert_dict: next_list.append(bert_dict[nexts]) else: next_list.append(np.zeros(768)) if section in bert_dict: section_list.append(bert_dict[section]) else: section_list.append(np.zeros(768)) length.append(row[1][4]) label.append(row[1][5]) sentence_emb = np.asarray(sentence_emb) print(sentence_emb.shape) next_emb = np.asarray(next_list) print(next_emb.shape) previous_emb = np.asarray(previous_emb) print(previous_emb.shape) section_emb = np.asarray(section_list) print(sentence_emb.shape) length = np.asarray(length) print(length.shape) label = np.asarray(label) print(errors) features = np.concatenate([sentence_emb, previous_emb, next_emb,section_emb], axis=1) features = np.column_stack([features, length]) print(features.shape) X_train, X_val, y_train, y_val = train_test_split(features, label, test_size=0.33, random_state=42) C = [0.1,1,2,5,10] solver = ['newton-cg','saga','sag'] best_params = dict() best_score = 0.0 for c in C: for s in solver: start = time.time() log = LogisticRegression(random_state=0, solver=s, max_iter=1000, C=c) log.fit(X_train, y_train) predictions = log.predict(X_val) print("###########################################") print("LR with C =",c,'and solver = ',s) print("Results using embeddings from the", layer_json, "file") print(classification_report(y_val, predictions)) f1 = f1_score(y_val, predictions) if f1 > best_score: best_score = f1 best_params['c'] = c best_params['solver'] = s print("F1 score using Logistic Regression:",f1) print("###########################################") end = time.time() running_time = end - start print("Running time:"+str(running_time)) def visualize_DNN(file_to_save): ''' Save the DNN architecture to a png file. Better use the Visulize_DNN.ipynd :param file_to_save: the png file that the architecture of the DNN will be saved. :return: None ''' model = Sequential() model.add(Dense(64, activation='relu', trainable=True)) model.add(Dense(128, activation='relu', trainable=True)) model.add(Dropout(0.30)) model.add(Dense(64, activation='relu', trainable=True)) model.add(Dropout(0.25)) model.add(Dense(64, activation='relu', trainable=True)) model.add(Dropout(0.35)) model.add(Dense(1, activation='sigmoid')) plot_model(model, to_file=file_to_save, show_shapes=True) def save_model(sentences_list,layer_json,dataset_csv,pkl): dataset = pd.read_csv(dataset_csv) bert_dict = get_embeddings(sentences_list, layer_json) length = list() sentence_emb = list() previous_emb = list() next_list = list() section_list = list() label = list() errors = 0 for row in dataset.iterrows(): sentence = row[1][0].strip() previous = row[1][1].strip() nexts = row[1][2].strip() section = row[1][3].strip() if sentence in bert_dict: sentence_emb.append(bert_dict[sentence]) else: sentence_emb.append(np.zeros(768)) print(sentence) errors += 1 if previous in bert_dict: previous_emb.append(bert_dict[previous]) else: previous_emb.append(np.zeros(768)) if nexts in bert_dict: next_list.append(bert_dict[nexts]) else: next_list.append(np.zeros(768)) if section in bert_dict: section_list.append(bert_dict[section]) else: section_list.append(np.zeros(768)) length.append(row[1][4]) label.append(row[1][5]) sentence_emb = np.asarray(sentence_emb) print(sentence_emb.shape) next_emb =	np.asarray(next_list)	numpy.asarray
"""Routines for numerical differentiation.""" from __future__ import division import numpy as np from numpy.linalg import norm from scipy.sparse.linalg import LinearOperator from ..sparse import issparse, csc_matrix, csr_matrix, coo_matrix, find from ._group_columns import group_dense, group_sparse EPS = np.finfo(np.float64).eps def _adjust_scheme_to_bounds(x0, h, num_steps, scheme, lb, ub): """Adjust final difference scheme to the presence of bounds. Parameters ---------- x0 : ndarray, shape (n,) Point at which we wish to estimate derivative. h : ndarray, shape (n,) Desired finite difference steps. num_steps : int Number of `h` steps in one direction required to implement finite difference scheme. For example, 2 means that we need to evaluate f(x0 + 2 * h) or f(x0 - 2 * h) scheme : {'1-sided', '2-sided'} Whether steps in one or both directions are required. In other words '1-sided' applies to forward and backward schemes, '2-sided' applies to center schemes. lb : ndarray, shape (n,) Lower bounds on independent variables. ub : ndarray, shape (n,) Upper bounds on independent variables. Returns ------- h_adjusted : ndarray, shape (n,) Adjusted step sizes. Step size decreases only if a sign flip or switching to one-sided scheme doesn't allow to take a full step. use_one_sided : ndarray of bool, shape (n,) Whether to switch to one-sided scheme. Informative only for ``scheme='2-sided'``. """ if scheme == '1-sided': use_one_sided = np.ones_like(h, dtype=bool) elif scheme == '2-sided': h = np.abs(h) use_one_sided = np.zeros_like(h, dtype=bool) else: raise ValueError("`scheme` must be '1-sided' or '2-sided'.") if np.all((lb == -np.inf) & (ub == np.inf)): return h, use_one_sided h_total = h * num_steps h_adjusted = h.copy() lower_dist = x0 - lb upper_dist = ub - x0 if scheme == '1-sided': x = x0 + h_total violated = (x < lb) \| (x > ub) fitting = np.abs(h_total) <= np.maximum(lower_dist, upper_dist) h_adjusted[violated & fitting] = -1 forward = (upper_dist >= lower_dist) & ~fitting h_adjusted[forward] = upper_dist[forward] / num_steps backward = (upper_dist < lower_dist) & ~fitting h_adjusted[backward] = -lower_dist[backward] / num_steps elif scheme == '2-sided': central = (lower_dist >= h_total) & (upper_dist >= h_total) forward = (upper_dist >= lower_dist) & ~central h_adjusted[forward] = np.minimum( h[forward], 0.5 upper_dist[forward] / num_steps) use_one_sided[forward] = True backward = (upper_dist < lower_dist) & ~central h_adjusted[backward] = -np.minimum( h[backward], 0.5 * lower_dist[backward] / num_steps) use_one_sided[backward] = True min_dist = np.minimum(upper_dist, lower_dist) / num_steps adjusted_central = (~central & (np.abs(h_adjusted) <= min_dist)) h_adjusted[adjusted_central] = min_dist[adjusted_central] use_one_sided[adjusted_central] = False return h_adjusted, use_one_sided relative_step = {"2-point": EPS0.5, "3-point": EPS(1/3), "cs": EPS*0.5} def _compute_absolute_step(rel_step, x0, method): if rel_step is None: rel_step = relative_step[method] sign_x0 = (x0 >= 0).astype(float) 2 - 1 return rel_step * sign_x0 * np.maximum(1.0, np.abs(x0)) def _prepare_bounds(bounds, x0): lb, ub = [np.asarray(b, dtype=float) for b in bounds] if lb.ndim == 0: lb = np.resize(lb, x0.shape) if ub.ndim == 0: ub = np.resize(ub, x0.shape) return lb, ub def group_columns(A, order=0): """Group columns of a 2-D matrix for sparse finite differencing [1]_. Two columns are in the same group if in each row at least one of them has zero. A greedy sequential algorithm is used to construct groups. Parameters ---------- A : array_like or sparse matrix, shape (m, n) Matrix of which to group columns. order : int, iterable of int with shape (n,) or None Permutation array which defines the order of columns enumeration. If int or None, a random permutation is used with `order` used as a random seed. Default is 0, that is use a random permutation but guarantee repeatability. Returns ------- groups : ndarray of int, shape (n,) Contains values from 0 to n_groups-1, where n_groups is the number of found groups. Each value ``groups[i]`` is an index of a group to which ith column assigned. The procedure was helpful only if n_groups is significantly less than n. References ---------- .. [1] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. """ if issparse(A): A = csc_matrix(A) else: A = np.atleast_2d(A) A = (A != 0).astype(np.int32) if A.ndim != 2: raise ValueError("`A` must be 2-dimensional.") m, n = A.shape if order is None or np.isscalar(order): rng = np.random.RandomState(order) order = rng.permutation(n) else: order = np.asarray(order) if order.shape != (n,): raise ValueError("`order` has incorrect shape.") A = A[:, order] if issparse(A): groups = group_sparse(m, n, A.indices, A.indptr) else: groups = group_dense(m, n, A) groups[order] = groups.copy() return groups def approx_derivative(fun, x0, method='3-point', rel_step=None, f0=None, bounds=(-np.inf, np.inf), sparsity=None, as_linear_operator=False, args=(), kwargs={}): """Compute finite difference approximation of the derivatives of a vector-valued function. If a function maps from R^n to R^m, its derivatives form m-by-n matrix called the Jacobian, where an element (i, j) is a partial derivative of f[i] with respect to x[j]. Parameters ---------- fun : callable Function of which to estimate the derivatives. The argument x passed to this function is ndarray of shape (n,) (never a scalar even if n=1). It must return 1-D array_like of shape (m,) or a scalar. x0 : array_like of shape (n,) or float Point at which to estimate the derivatives. Float will be converted to a 1-D array. method : {'3-point', '2-point', 'cs'}, optional Finite difference method to use: - '2-point' - use the first order accuracy forward or backward difference. - '3-point' - use central difference in interior points and the second order accuracy forward or backward difference near the boundary. - 'cs' - use a complex-step finite difference scheme. This assumes that the user function is real-valued and can be analytically continued to the complex plane. Otherwise, produces bogus results. rel_step : None or array_like, optional Relative step size to use. The absolute step size is computed as ``h = rel_step * sign(x0) * max(1, abs(x0))``, possibly adjusted to fit into the bounds. For ``method='3-point'`` the sign of `h` is ignored. If None (default) then step is selected automatically, see Notes. f0 : None or array_like, optional If not None it is assumed to be equal to ``fun(x0)``, in this case the ``fun(x0)`` is not called. Default is None. bounds : tuple of array_like, optional Lower and upper bounds on independent variables. Defaults to no bounds. Each bound must match the size of `x0` or be a scalar, in the latter case the bound will be the same for all variables. Use it to limit the range of function evaluation. Bounds checking is not implemented when `as_linear_operator` is True. sparsity : {None, array_like, sparse matrix, 2-tuple}, optional Defines a sparsity structure of the Jacobian matrix. If the Jacobian matrix is known to have only few non-zero elements in each row, then it's possible to estimate its several columns by a single function evaluation [3]_. To perform such economic computations two ingredients are required: * structure : array_like or sparse matrix of shape (m, n). A zero element means that a corresponding element of the Jacobian identically equals to zero. * groups : array_like of shape (n,). A column grouping for a given sparsity structure, use `group_columns` to obtain it. A single array or a sparse matrix is interpreted as a sparsity structure, and groups are computed inside the function. A tuple is interpreted as (structure, groups). If None (default), a standard dense differencing will be used. Note, that sparse differencing makes sense only for large Jacobian matrices where each row contains few non-zero elements. as_linear_operator : bool, optional When True the function returns an `scipy.sparse.linalg.LinearOperator`. Otherwise it returns a dense array or a sparse matrix depending on `sparsity`. The linear operator provides an efficient way of computing ``J.dot(p)`` for any vector ``p`` of shape (n,), but does not allow direct access to individual elements of the matrix. By default `as_linear_operator` is False. args, kwargs : tuple and dict, optional Additional arguments passed to `fun`. Both empty by default. The calling signature is ``fun(x, args, kwargs)``. Returns ------- J : {ndarray, sparse matrix, LinearOperator} Finite difference approximation of the Jacobian matrix. If `as_linear_operator` is True returns a LinearOperator with shape (m, n). Otherwise it returns a dense array or sparse matrix depending on how `sparsity` is defined. If `sparsity` is None then a ndarray with shape (m, n) is returned. If `sparsity` is not None returns a csr_matrix with shape (m, n). For sparse matrices and linear operators it is always returned as a 2-D structure, for ndarrays, if m=1 it is returned as a 1-D gradient array with shape (n,). See Also -------- check_derivative : Check correctness of a function computing derivatives. Notes ----- If `rel_step` is not provided, it assigned to ``EPS(1/s)``, where EPS is machine epsilon for float64 numbers, s=2 for '2-point' method and s=3 for '3-point' method. Such relative step approximately minimizes a sum of truncation and round-off errors, see [1]_. A finite difference scheme for '3-point' method is selected automatically. The well-known central difference scheme is used for points sufficiently far from the boundary, and 3-point forward or backward scheme is used for points near the boundary. Both schemes have the second-order accuracy in terms of Taylor expansion. Refer to [2]_ for the formulas of 3-point forward and backward difference schemes. For dense differencing when m=1 Jacobian is returned with a shape (n,), on the other hand when n=1 Jacobian is returned with a shape (m, 1). Our motivation is the following: a) It handles a case of gradient computation (m=1) in a conventional way. b) It clearly separates these two different cases. b) In all cases np.atleast_2d can be called to get 2-D Jacobian with correct dimensions. References ---------- .. [1] W. H. Press et. al. "Numerical Recipes. The Art of Scientific Computing. 3rd edition", sec. 5.7. .. [2] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. .. [3] <NAME>, "Generation of Finite Difference Formulas on Arbitrarily Spaced Grids", Mathematics of Computation 51, 1988. Examples -------- >>> import numpy as np >>> from scipy.optimize import approx_derivative >>> >>> def f(x, c1, c2): ... return np.array([x[0] np.sin(c1 * x[1]), ... x[0] * np.cos(c2 * x[1])]) ... >>> x0 = np.array([1.0, 0.5 * np.pi]) >>> approx_derivative(f, x0, args=(1, 2)) array([[ 1., 0.], [-1., 0.]]) Bounds can be used to limit the region of function evaluation. In the example below we compute left and right derivative at point 1.0. >>> def g(x): ... return x*2 if x >= 1 else x ... >>> x0 = 1.0 >>> approx_derivative(g, x0, bounds=(-np.inf, 1.0)) array([ 1.]) >>> approx_derivative(g, x0, bounds=(1.0, np.inf)) array([ 2.]) """ if method not in ['2-point', '3-point', 'cs']: raise ValueError("Unknown method '%s'. " % method) x0 = np.atleast_1d(x0) if x0.ndim > 1: raise ValueError("`x0` must have at most 1 dimension.") lb, ub = _prepare_bounds(bounds, x0) if lb.shape != x0.shape or ub.shape != x0.shape: raise ValueError("Inconsistent shapes between bounds and `x0`.") if as_linear_operator and not (np.all(np.isinf(lb)) and np.all(np.isinf(ub))): raise ValueError("Bounds not supported when " "`as_linear_operator` is True.") def fun_wrapped(x): f = np.atleast_1d(fun(x, args, **kwargs)) if f.ndim > 1: raise RuntimeError("`fun` return value has " "more than 1 dimension.") return f if f0 is None: f0 = fun_wrapped(x0) else: f0 = np.atleast_1d(f0) if f0.ndim > 1: raise ValueError("`f0` passed has more than 1 dimension.") if np.any((x0 < lb) \| (x0 > ub)): raise ValueError("`x0` violates bound constraints.") if as_linear_operator: if rel_step is None: rel_step = relative_step[method] return _linear_operator_difference(fun_wrapped, x0, f0, rel_step, method) else: h = _compute_absolute_step(rel_step, x0, method) if method == '2-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '1-sided', lb, ub) elif method == '3-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '2-sided', lb, ub) elif method == 'cs': use_one_sided = False if sparsity is None: return _dense_difference(fun_wrapped, x0, f0, h, use_one_sided, method) else: if not issparse(sparsity) and len(sparsity) == 2: structure, groups = sparsity else: structure = sparsity groups = group_columns(sparsity) if issparse(structure): structure = csc_matrix(structure) else: structure = np.atleast_2d(structure) groups = np.atleast_1d(groups) return _sparse_difference(fun_wrapped, x0, f0, h, use_one_sided, structure, groups, method) def _linear_operator_difference(fun, x0, f0, h, method): m = f0.size n = x0.size if method == '2-point': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return	np.zeros(m)	numpy.zeros
import numpy as np from stumpff import C, S from CelestialBody import BODIES from numerical import newton, laguerre from lagrange import calc_f, calc_fd, calc_g, calc_gd def kepler_chi(chi, alpha, r0, vr0, mu, dt): ''' Kepler's Equation of the universal anomaly, modified for use in numerical solvers. ''' z = alphachi2 return (r0vr0/np.sqrt(mu))chi2C(z) + \ (1 - alphar0)chi*3S(z) + \ r0chi - np.sqrt(mu)dt def dkepler_dchi(chi, alpha, r0, vr0, mu, dt): ''' Derivative of Kepler's Equation of the universal anomaly, modified for use in numerical solvers. ''' z = alphachi2 return (r0vr0/np.sqrt(mu))chi(1 - alphachi2S(z)) + \ (1 - alphar0)chi*2C(z) + r0 def d2kepler_dchi2(chi, alpha, r0, vr0, mu, dt): ''' Second derivative of Kepler's Equation of the universal anomaly, modified for use in numerical solvers. ''' z = alphachi2 S_ = S(z) return (r0vr0/np.sqrt(mu))(1 - 3zS_ + z(C(z) - 3S_)) + \ chi(1 - zS_)(1 - alphar0) def solve_kepler_chi(r_0, v_0, dt, body=BODIES['Earth'], method='laguerre', tol=1e-7, max_iters=100): ''' Solve Kepler's Equation of the universal anomaly chi using the specified numerical method. Applies Algorithm 3.4 from Orbital Mechanics for Engineering Students, 4 ed, Curtis. :param r_0: `iterable` (km) initial position 3-vector :param v_0: `iterable` (km/s) initial velocity 3-vector :param dt: `float` (s) time after initial state to solve for r, v as 3-vectors :param body: `CelestialBody` (--) the celestial body to use for orbital parameters :param method: `str` (--) which numerical method to use to solve Kepler's Equation :param tol: `float` (--) decimal tolerance for numerical method (default 1e-7 is IEEE 745 single precision) :param max_iters: `int` (--) maximum number of iterations in numerical method before breaking :return: (km) final position 3-vector, (km/s) final velocity 3-vector ''' VALID_METHODS = ('laguerre', 'newton') mu = body.mu # (km3/s2) gravitational parameter of the specified primary body r0 = np.linalg.norm(r_0) # (km) initial position magnitude v0 = np.linalg.norm(v_0) # (km/s) initial velocity magnitude vr0 = np.dot(v_0, r_0)/r0 # (km/s) initial radial velocity magnitude alpha = 2/r0 - v02/mu # (1/km) inverse of semi-major axis chi0 = np.sqrt(mu)np.abs(alpha)dt if method not in VALID_METHODS: print(f'Method \'{method}\' is not valid, must be one of {VALID_METHODS}.\nDefaulting to laguerre method.') chi, _, _ = laguerre(chi0, kepler_chi, dkepler_dchi, d2kepler_dchi2, alpha, r0, vr0, mu, dt) elif method == 'newton': chi, _, _ = newton(chi0, kepler_chi, dkepler_dchi, alpha, r0, vr0, mu, dt) else: # method == 'laguerre' chi, _, _ = laguerre(chi0, kepler_chi, dkepler_dchi, d2kepler_dchi2, alpha, r0, vr0, mu, dt) f = calc_f(chi, r0, alpha) g = calc_g(dt, mu, chi, alpha) r_1 = fr_0 + gv_0 r1 = np.linalg.norm(r_1) fd = calc_fd(mu, r1, r0, alpha, chi) gd = calc_gd(chi, r1, alpha) v_1 = fdr_0 + gdv_0 return r_1, v_1 def solve_kepler_E(e, Me, tol=1e-7, max_iters=100): ''' Solve Kepler's Equation in the form containing Eccentric Anomaly (E), eccentricity (e), and Mean Anomaly of Ellipse (Me). Uses Algorithm 3.1 from Orbital Mechanics for Engineering Students, 4 ed, Curtis. ''' # TODO: have this function make use of one of the numerical methods in numerical.py def f(E, e, Me): return E - enp.sin(E) - Me def fp(E, e): return 1 - enp.cos(E) E = Me + e/2 if Me < np.pi else Me - e/2 ratio = f(E, e, Me)/fp(E, e) iters = 0 while abs(ratio) > tol and iters < max_iters: E -= ratio ratio = f(E, e, Me)/fp(E, e) iters += 1 E -= ratio converged = np.abs(ratio) <= tol return E, iters, converged def test(): ''' Test the functionality of solve_kepler_chi and solve_kepler_laguerre using Problem 3.20 from Orbital Mechanics for Engineering Students, 4 ed, Curtis. ''' # given starting information Earth = BODIES['Earth'] # `CelestialBody` (--) Earth and all the Earth things r_0 = np.array([20000, -105000, -19000]) # (km) initial position vector v_0 = np.array([0.9, -3.4, -1.5]) # (km/s) initial velocity vector dt = 260*60 # (s) time of interest after initial time # given correct answer from textbook correct_r_1 = np.array([26338, -128750, -29656]) # (km) final position vector correct_v_1 = np.array([0.86280, -3.2116, -1.4613]) # (km/s) final velocity vector # solve using above methods r_n, v_n = solve_kepler_chi(r_0, v_0, dt, Earth, method='newton') r_l, v_l = solve_kepler_chi(r_0, v_0, dt, Earth, method='laguerre') # check correctness # tolerance based on significant figures of given answers newton_valid = np.allclose(r_n, correct_r_1, atol=1) and np.allclose(v_n, correct_v_1, atol=1e-4) laguerre_valid =	np.allclose(r_l, correct_r_1, atol=1)	numpy.allclose
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect =	np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101)	numpy.linspace
""" This script will modulate the blinky lights using the following algorithm: 1) uses user-provided location to obtain row of pixel data from bathy image 2) samples a 'number of LEDs' number of pixels from that row 3) shifts the sampled row data to center it at the location specified by user 4) displays resulting pixels on Blinky Tape 5) shifts next row by a given latitude, also specified by user 6) sleeps for user-specified period of time Uses the following arguments: -l/--location: tuple Location of the user in tuple(lat, lon). This represents the center of the LED strip. Defaults to (0, 0) -u/--update-interval: int Update interval of the script, in minutes. Defaults to 10. -p/--port: str Serial port of the BlinkyLight (e.g., 'ttyAMA0', 'COM3'). Defaults to 'COM5'. -d/--delta_latitude: int Vertical change in latitude every update rate. May be 0, but this will result in a never-changing LEDs. -i/--image: str Name of the PNG image that contains the color coded pathymetric data. The file current named mapserv.png was obtained using the following API: https://www.gebco.net/data_and_products/gebco_web_services/web_map_service/mapserv?request=getmap&service=wms&BBOX=-90,-180,90,180&format=image/png&height=600&width=1200&crs=EPSG:4326&layers=GEBCO_LATEST_SUB_ICE_TOPO&version=1.3.0 In lieu of providing command line arguments, you may alternatively edit the defaults in bath_config.json. NOTE: runs via: runfile('/BlinkyTape_Python/bathymetry_blink/bathymetry_blink.py', wdir='/BlinkyTape_Python/') (C) 2021 <NAME> (https://joeycodes.dev) MIT Licensed """ import optparse import json from blinkytape import BlinkyTape from time import sleep from PIL import Image import numpy as np import sys MAX_ERRORS = 3 num_errors = 0 # Obtain default parameters with open("./bathymetry_blink/bathy_config.json") as f: config = json.load(f) # Default Blinky Tape port on Raspberry Pi is /dev/ttyACM0 parser = optparse.OptionParser() parser.add_option("-p", "--port", dest="portname", help="serial port (ex: /dev/ttyACM0)", default=config["port"]) parser.add_option("-l", "--location", dest="location", help="Location of the center of the LED strip (ex: 70,-110)", default=config["location"]) parser.add_option("-u", "--update-rate", dest="update_rate", help="How often to update elevation profile (mins) (ex: 5)", default=config["update_rate"]) parser.add_option("-d", "--delta-latitude", dest="delta_latitude", help="Change in latitude during update (ex: 5)", default=config["delta_latitude"]) parser.add_option("-n", "--num-leds", dest="num_leds", help="Number of LEDs in strip (ex: 60)", default=config["num_leds"]) parser.add_option("-i", "--image", dest="image_name", help="Name of the map/bathymetry image (ex: ./mapserv.png)", default=config["image"]) (options, args) = parser.parse_args() if args: print("Unknown parameters: " + args) # grab the values provided by user (or defaults) port = options.portname loc = options.location rate = options.update_rate delta = options.delta_latitude n_leds = options.num_leds i_name = options.image_name # Some visual indication that it works, for headless setups (green tape) bt = BlinkyTape(port, n_leds) bt.displayColor(0, 100, 0) bt.show() sleep(2) while True: try: # first, load image im = Image.open(i_name) # Can be many different formats. cols, rows = im.size a =	np.asarray(im)	numpy.asarray
# # Copyright (c) 2021 The GPflux Contributors. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. # import abc import numpy as np import pytest import tensorflow as tf import tensorflow_probability as tfp from gpflow.kullback_leiblers import gauss_kl from gpflux.encoders import DirectlyParameterizedNormalDiag from gpflux.layers import LatentVariableLayer, LayerWithObservations, TrackableLayer tf.keras.backend.set_floatx("float64") ############ # Utilities ############ def _zero_one_normal_prior(w_dim): """ N(0, I) prior """ return tfp.distributions.MultivariateNormalDiag(loc=np.zeros(w_dim), scale_diag=np.ones(w_dim)) def get_distributions_with_w_dim(): distributions = [] for d in [1, 5]: mean = np.zeros(d) scale_tri_l = np.eye(d) mvn = tfp.distributions.MultivariateNormalTriL(mean, scale_tri_l) std = np.ones(d) mvn_diag = tfp.distributions.MultivariateNormalDiag(mean, std) distributions.append((mvn, d)) distributions.append((mvn_diag, d)) return distributions ############ # Tests ############ @pytest.mark.parametrize("distribution, w_dim", get_distributions_with_w_dim()) def test_local_kls(distribution, w_dim): lv = LatentVariableLayer(encoder=None, prior=distribution) # test kl is 0 when posteriors == priors posterior = distribution assert lv._local_kls(posterior) == 0 # test kl > 0 when posteriors != priors batch_size = 10 params = distribution.parameters posterior_params = { k: [v + 0.5 for _ in range(batch_size)] for k, v in params.items() if isinstance(v, np.ndarray) } posterior = lv.distribution_class(**posterior_params) local_kls = lv._local_kls(posterior) assert	np.all(local_kls > 0)	numpy.all
import numpy as np from scipy import ndimage def erode_value_blobs(array, steps=1, values_to_ignore=tuple(), new_value=0): unique_values = list(	np.unique(array)	numpy.unique
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi *	np.ones(101)	numpy.ones
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 =	np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101)	numpy.linspace
"""Routines for numerical differentiation.""" from __future__ import division import numpy as np from numpy.linalg import norm from scipy.sparse.linalg import LinearOperator from ..sparse import issparse, csc_matrix, csr_matrix, coo_matrix, find from ._group_columns import group_dense, group_sparse EPS = np.finfo(np.float64).eps def _adjust_scheme_to_bounds(x0, h, num_steps, scheme, lb, ub): """Adjust final difference scheme to the presence of bounds. Parameters ---------- x0 : ndarray, shape (n,) Point at which we wish to estimate derivative. h : ndarray, shape (n,) Desired finite difference steps. num_steps : int Number of `h` steps in one direction required to implement finite difference scheme. For example, 2 means that we need to evaluate f(x0 + 2 * h) or f(x0 - 2 * h) scheme : {'1-sided', '2-sided'} Whether steps in one or both directions are required. In other words '1-sided' applies to forward and backward schemes, '2-sided' applies to center schemes. lb : ndarray, shape (n,) Lower bounds on independent variables. ub : ndarray, shape (n,) Upper bounds on independent variables. Returns ------- h_adjusted : ndarray, shape (n,) Adjusted step sizes. Step size decreases only if a sign flip or switching to one-sided scheme doesn't allow to take a full step. use_one_sided : ndarray of bool, shape (n,) Whether to switch to one-sided scheme. Informative only for ``scheme='2-sided'``. """ if scheme == '1-sided': use_one_sided = np.ones_like(h, dtype=bool) elif scheme == '2-sided': h = np.abs(h) use_one_sided = np.zeros_like(h, dtype=bool) else: raise ValueError("`scheme` must be '1-sided' or '2-sided'.") if np.all((lb == -np.inf) & (ub == np.inf)): return h, use_one_sided h_total = h * num_steps h_adjusted = h.copy() lower_dist = x0 - lb upper_dist = ub - x0 if scheme == '1-sided': x = x0 + h_total violated = (x < lb) \| (x > ub) fitting = np.abs(h_total) <= np.maximum(lower_dist, upper_dist) h_adjusted[violated & fitting] = -1 forward = (upper_dist >= lower_dist) & ~fitting h_adjusted[forward] = upper_dist[forward] / num_steps backward = (upper_dist < lower_dist) & ~fitting h_adjusted[backward] = -lower_dist[backward] / num_steps elif scheme == '2-sided': central = (lower_dist >= h_total) & (upper_dist >= h_total) forward = (upper_dist >= lower_dist) & ~central h_adjusted[forward] = np.minimum( h[forward], 0.5 upper_dist[forward] / num_steps) use_one_sided[forward] = True backward = (upper_dist < lower_dist) & ~central h_adjusted[backward] = -np.minimum( h[backward], 0.5 * lower_dist[backward] / num_steps) use_one_sided[backward] = True min_dist = np.minimum(upper_dist, lower_dist) / num_steps adjusted_central = (~central & (np.abs(h_adjusted) <= min_dist)) h_adjusted[adjusted_central] = min_dist[adjusted_central] use_one_sided[adjusted_central] = False return h_adjusted, use_one_sided relative_step = {"2-point": EPS0.5, "3-point": EPS(1/3), "cs": EPS*0.5} def _compute_absolute_step(rel_step, x0, method): if rel_step is None: rel_step = relative_step[method] sign_x0 = (x0 >= 0).astype(float) 2 - 1 return rel_step * sign_x0 * np.maximum(1.0, np.abs(x0)) def _prepare_bounds(bounds, x0): lb, ub = [np.asarray(b, dtype=float) for b in bounds] if lb.ndim == 0: lb = np.resize(lb, x0.shape) if ub.ndim == 0: ub = np.resize(ub, x0.shape) return lb, ub def group_columns(A, order=0): """Group columns of a 2-D matrix for sparse finite differencing [1]_. Two columns are in the same group if in each row at least one of them has zero. A greedy sequential algorithm is used to construct groups. Parameters ---------- A : array_like or sparse matrix, shape (m, n) Matrix of which to group columns. order : int, iterable of int with shape (n,) or None Permutation array which defines the order of columns enumeration. If int or None, a random permutation is used with `order` used as a random seed. Default is 0, that is use a random permutation but guarantee repeatability. Returns ------- groups : ndarray of int, shape (n,) Contains values from 0 to n_groups-1, where n_groups is the number of found groups. Each value ``groups[i]`` is an index of a group to which ith column assigned. The procedure was helpful only if n_groups is significantly less than n. References ---------- .. [1] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. """ if issparse(A): A = csc_matrix(A) else: A = np.atleast_2d(A) A = (A != 0).astype(np.int32) if A.ndim != 2: raise ValueError("`A` must be 2-dimensional.") m, n = A.shape if order is None or np.isscalar(order): rng = np.random.RandomState(order) order = rng.permutation(n) else: order = np.asarray(order) if order.shape != (n,): raise ValueError("`order` has incorrect shape.") A = A[:, order] if issparse(A): groups = group_sparse(m, n, A.indices, A.indptr) else: groups = group_dense(m, n, A) groups[order] = groups.copy() return groups def approx_derivative(fun, x0, method='3-point', rel_step=None, f0=None, bounds=(-np.inf, np.inf), sparsity=None, as_linear_operator=False, args=(), kwargs={}): """Compute finite difference approximation of the derivatives of a vector-valued function. If a function maps from R^n to R^m, its derivatives form m-by-n matrix called the Jacobian, where an element (i, j) is a partial derivative of f[i] with respect to x[j]. Parameters ---------- fun : callable Function of which to estimate the derivatives. The argument x passed to this function is ndarray of shape (n,) (never a scalar even if n=1). It must return 1-D array_like of shape (m,) or a scalar. x0 : array_like of shape (n,) or float Point at which to estimate the derivatives. Float will be converted to a 1-D array. method : {'3-point', '2-point', 'cs'}, optional Finite difference method to use: - '2-point' - use the first order accuracy forward or backward difference. - '3-point' - use central difference in interior points and the second order accuracy forward or backward difference near the boundary. - 'cs' - use a complex-step finite difference scheme. This assumes that the user function is real-valued and can be analytically continued to the complex plane. Otherwise, produces bogus results. rel_step : None or array_like, optional Relative step size to use. The absolute step size is computed as ``h = rel_step * sign(x0) * max(1, abs(x0))``, possibly adjusted to fit into the bounds. For ``method='3-point'`` the sign of `h` is ignored. If None (default) then step is selected automatically, see Notes. f0 : None or array_like, optional If not None it is assumed to be equal to ``fun(x0)``, in this case the ``fun(x0)`` is not called. Default is None. bounds : tuple of array_like, optional Lower and upper bounds on independent variables. Defaults to no bounds. Each bound must match the size of `x0` or be a scalar, in the latter case the bound will be the same for all variables. Use it to limit the range of function evaluation. Bounds checking is not implemented when `as_linear_operator` is True. sparsity : {None, array_like, sparse matrix, 2-tuple}, optional Defines a sparsity structure of the Jacobian matrix. If the Jacobian matrix is known to have only few non-zero elements in each row, then it's possible to estimate its several columns by a single function evaluation [3]_. To perform such economic computations two ingredients are required: * structure : array_like or sparse matrix of shape (m, n). A zero element means that a corresponding element of the Jacobian identically equals to zero. * groups : array_like of shape (n,). A column grouping for a given sparsity structure, use `group_columns` to obtain it. A single array or a sparse matrix is interpreted as a sparsity structure, and groups are computed inside the function. A tuple is interpreted as (structure, groups). If None (default), a standard dense differencing will be used. Note, that sparse differencing makes sense only for large Jacobian matrices where each row contains few non-zero elements. as_linear_operator : bool, optional When True the function returns an `scipy.sparse.linalg.LinearOperator`. Otherwise it returns a dense array or a sparse matrix depending on `sparsity`. The linear operator provides an efficient way of computing ``J.dot(p)`` for any vector ``p`` of shape (n,), but does not allow direct access to individual elements of the matrix. By default `as_linear_operator` is False. args, kwargs : tuple and dict, optional Additional arguments passed to `fun`. Both empty by default. The calling signature is ``fun(x, args, kwargs)``. Returns ------- J : {ndarray, sparse matrix, LinearOperator} Finite difference approximation of the Jacobian matrix. If `as_linear_operator` is True returns a LinearOperator with shape (m, n). Otherwise it returns a dense array or sparse matrix depending on how `sparsity` is defined. If `sparsity` is None then a ndarray with shape (m, n) is returned. If `sparsity` is not None returns a csr_matrix with shape (m, n). For sparse matrices and linear operators it is always returned as a 2-D structure, for ndarrays, if m=1 it is returned as a 1-D gradient array with shape (n,). See Also -------- check_derivative : Check correctness of a function computing derivatives. Notes ----- If `rel_step` is not provided, it assigned to ``EPS(1/s)``, where EPS is machine epsilon for float64 numbers, s=2 for '2-point' method and s=3 for '3-point' method. Such relative step approximately minimizes a sum of truncation and round-off errors, see [1]_. A finite difference scheme for '3-point' method is selected automatically. The well-known central difference scheme is used for points sufficiently far from the boundary, and 3-point forward or backward scheme is used for points near the boundary. Both schemes have the second-order accuracy in terms of Taylor expansion. Refer to [2]_ for the formulas of 3-point forward and backward difference schemes. For dense differencing when m=1 Jacobian is returned with a shape (n,), on the other hand when n=1 Jacobian is returned with a shape (m, 1). Our motivation is the following: a) It handles a case of gradient computation (m=1) in a conventional way. b) It clearly separates these two different cases. b) In all cases np.atleast_2d can be called to get 2-D Jacobian with correct dimensions. References ---------- .. [1] W. H. Press et. al. "Numerical Recipes. The Art of Scientific Computing. 3rd edition", sec. 5.7. .. [2] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. .. [3] <NAME>, "Generation of Finite Difference Formulas on Arbitrarily Spaced Grids", Mathematics of Computation 51, 1988. Examples -------- >>> import numpy as np >>> from scipy.optimize import approx_derivative >>> >>> def f(x, c1, c2): ... return np.array([x[0] np.sin(c1 * x[1]), ... x[0] * np.cos(c2 * x[1])]) ... >>> x0 = np.array([1.0, 0.5 * np.pi]) >>> approx_derivative(f, x0, args=(1, 2)) array([[ 1., 0.], [-1., 0.]]) Bounds can be used to limit the region of function evaluation. In the example below we compute left and right derivative at point 1.0. >>> def g(x): ... return x*2 if x >= 1 else x ... >>> x0 = 1.0 >>> approx_derivative(g, x0, bounds=(-np.inf, 1.0)) array([ 1.]) >>> approx_derivative(g, x0, bounds=(1.0, np.inf)) array([ 2.]) """ if method not in ['2-point', '3-point', 'cs']: raise ValueError("Unknown method '%s'. " % method) x0 = np.atleast_1d(x0) if x0.ndim > 1: raise ValueError("`x0` must have at most 1 dimension.") lb, ub = _prepare_bounds(bounds, x0) if lb.shape != x0.shape or ub.shape != x0.shape: raise ValueError("Inconsistent shapes between bounds and `x0`.") if as_linear_operator and not (np.all(np.isinf(lb)) and np.all(np.isinf(ub))): raise ValueError("Bounds not supported when " "`as_linear_operator` is True.") def fun_wrapped(x): f = np.atleast_1d(fun(x, args, *kwargs)) if f.ndim > 1: raise RuntimeError("`fun` return value has " "more than 1 dimension.") return f if f0 is None: f0 = fun_wrapped(x0) else: f0 = np.atleast_1d(f0) if f0.ndim > 1: raise ValueError("`f0` passed has more than 1 dimension.") if np.any((x0 < lb) \| (x0 > ub)): raise ValueError("`x0` violates bound constraints.") if as_linear_operator: if rel_step is None: rel_step = relative_step[method] return _linear_operator_difference(fun_wrapped, x0, f0, rel_step, method) else: h = _compute_absolute_step(rel_step, x0, method) if method == '2-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '1-sided', lb, ub) elif method == '3-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '2-sided', lb, ub) elif method == 'cs': use_one_sided = False if sparsity is None: return _dense_difference(fun_wrapped, x0, f0, h, use_one_sided, method) else: if not issparse(sparsity) and len(sparsity) == 2: structure, groups = sparsity else: structure = sparsity groups = group_columns(sparsity) if issparse(structure): structure = csc_matrix(structure) else: structure = np.atleast_2d(structure) groups = np.atleast_1d(groups) return _sparse_difference(fun_wrapped, x0, f0, h, use_one_sided, structure, groups, method) def _linear_operator_difference(fun, x0, f0, h, method): m = f0.size n = x0.size if method == '2-point': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return np.zeros(m) dx = h / norm(p) x = x0 + dxp df = fun(x) - f0 return df / dx elif method == '3-point': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return np.zeros(m) dx = 2h / norm(p) x1 = x0 - (dx/2)p x2 = x0 + (dx/2)*p f1 = fun(x1) f2 = fun(x2) df = f2 - f1 return df / dx elif method == 'cs': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return np.zeros(m) dx = h /	norm(p)	numpy.linalg.norm
from abc import ABCMeta, abstractmethod import os from vmaf.tools.misc import make_absolute_path, run_process from vmaf.tools.stats import ListStats __copyright__ = "Copyright 2016-2018, Netflix, Inc." __license__ = "Apache, Version 2.0" import re import numpy as np import ast from vmaf import ExternalProgramCaller, to_list from vmaf.config import VmafConfig, VmafExternalConfig from vmaf.core.executor import Executor from vmaf.core.result import Result from vmaf.tools.reader import YuvReader class FeatureExtractor(Executor): """ FeatureExtractor takes in a list of assets, and run feature extraction on them, and return a list of corresponding results. A FeatureExtractor must specify a unique type and version combination (by the TYPE and VERSION attribute), so that the Result generated by it can be identified. A derived class of FeatureExtractor must: 1) Override TYPE and VERSION 2) Override _generate_result(self, asset), which call a command-line executable and generate feature scores in a log file. 3) Override _get_feature_scores(self, asset), which read the feature scores from the log file, and return the scores in a dictionary format. For an example, follow VmafFeatureExtractor. """ __metaclass__ = ABCMeta @property @abstractmethod def ATOM_FEATURES(self): raise NotImplementedError def _read_result(self, asset): result = {} result.update(self._get_feature_scores(asset)) executor_id = self.executor_id return Result(asset, executor_id, result) @classmethod def get_scores_key(cls, atom_feature): return "{type}_{atom_feature}_scores".format( type=cls.TYPE, atom_feature=atom_feature) @classmethod def get_score_key(cls, atom_feature): return "{type}_{atom_feature}_score".format( type=cls.TYPE, atom_feature=atom_feature) def _get_feature_scores(self, asset): # routine to read the feature scores from the log file, and return # the scores in a dictionary format. log_file_path = self._get_log_file_path(asset) atom_feature_scores_dict = {} atom_feature_idx_dict = {} for atom_feature in self.ATOM_FEATURES: atom_feature_scores_dict[atom_feature] = [] atom_feature_idx_dict[atom_feature] = 0 with open(log_file_path, 'rt') as log_file: for line in log_file.readlines(): for atom_feature in self.ATOM_FEATURES: re_template = "{af}: ([0-9]+) ([a-zA-Z0-9.-]+)".format(af=atom_feature) mo = re.match(re_template, line) if mo: cur_idx = int(mo.group(1)) assert cur_idx == atom_feature_idx_dict[atom_feature] # parse value, allowing NaN and inf val = float(mo.group(2)) if np.isnan(val) or np.isinf(val): val = None atom_feature_scores_dict[atom_feature].append(val) atom_feature_idx_dict[atom_feature] += 1 continue len_score = len(atom_feature_scores_dict[self.ATOM_FEATURES[0]]) assert len_score != 0 for atom_feature in self.ATOM_FEATURES[1:]: assert len_score == len(atom_feature_scores_dict[atom_feature]), \ "Feature data possibly corrupt. Run cleanup script and try again." feature_result = {} for atom_feature in self.ATOM_FEATURES: scores_key = self.get_scores_key(atom_feature) feature_result[scores_key] = atom_feature_scores_dict[atom_feature] return feature_result class VmafFeatureExtractor(FeatureExtractor): TYPE = "VMAF_feature" # VERSION = '0.1' # vmaf_study; Anush's VIF fix # VERSION = '0.2' # expose vif_num, vif_den, adm_num, adm_den, anpsnr # VERSION = '0.2.1' # expose vif num/den of each scale # VERSION = '0.2.2' # adm abs-->fabs, corrected border handling, uniform reading with option of offset for input YUV, updated VIF corner case # VERSION = '0.2.2b' # expose adm_den/num_scalex # VERSION = '0.2.3' # AVX for VMAF convolution; update adm features by folding noise floor into per coef # VERSION = '0.2.4' # Fix a bug in adm feature passing scale into dwt_quant_step # VERSION = '0.2.4b' # Modify by adding ADM noise floor outside cube root; add derived feature motion2 VERSION = '0.2.4c' # Modify by moving motion2 to c code ATOM_FEATURES = ['vif', 'adm', 'ansnr', 'motion', 'motion2', 'vif_num', 'vif_den', 'adm_num', 'adm_den', 'anpsnr', 'vif_num_scale0', 'vif_den_scale0', 'vif_num_scale1', 'vif_den_scale1', 'vif_num_scale2', 'vif_den_scale2', 'vif_num_scale3', 'vif_den_scale3', 'adm_num_scale0', 'adm_den_scale0', 'adm_num_scale1', 'adm_den_scale1', 'adm_num_scale2', 'adm_den_scale2', 'adm_num_scale3', 'adm_den_scale3', ] DERIVED_ATOM_FEATURES = ['vif_scale0', 'vif_scale1', 'vif_scale2', 'vif_scale3', 'vif2', 'adm2', 'adm3', 'adm_scale0', 'adm_scale1', 'adm_scale2', 'adm_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vmaf_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VmafFeatureExtractor, cls)._post_process_result(result) # adm2 = # (adm_num + ADM2_CONSTANT) / (adm_den + ADM2_CONSTANT) adm2_scores_key = cls.get_scores_key('adm2') adm_num_scores_key = cls.get_scores_key('adm_num') adm_den_scores_key = cls.get_scores_key('adm_den') result.result_dict[adm2_scores_key] = list( (np.array(result.result_dict[adm_num_scores_key]) + cls.ADM2_CONSTANT) / (np.array(result.result_dict[adm_den_scores_key]) + cls.ADM2_CONSTANT) ) # vif_scalei = vif_num_scalei / vif_den_scalei, i = 0, 1, 2, 3 vif_num_scale0_scores_key = cls.get_scores_key('vif_num_scale0') vif_den_scale0_scores_key = cls.get_scores_key('vif_den_scale0') vif_num_scale1_scores_key = cls.get_scores_key('vif_num_scale1') vif_den_scale1_scores_key = cls.get_scores_key('vif_den_scale1') vif_num_scale2_scores_key = cls.get_scores_key('vif_num_scale2') vif_den_scale2_scores_key = cls.get_scores_key('vif_den_scale2') vif_num_scale3_scores_key = cls.get_scores_key('vif_num_scale3') vif_den_scale3_scores_key = cls.get_scores_key('vif_den_scale3') vif_scale0_scores_key = cls.get_scores_key('vif_scale0') vif_scale1_scores_key = cls.get_scores_key('vif_scale1') vif_scale2_scores_key = cls.get_scores_key('vif_scale2') vif_scale3_scores_key = cls.get_scores_key('vif_scale3') result.result_dict[vif_scale0_scores_key] = list( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) ) result.result_dict[vif_scale1_scores_key] = list( (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) ) result.result_dict[vif_scale2_scores_key] = list( (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) ) result.result_dict[vif_scale3_scores_key] = list( (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) # vif2 = # ((vif_num_scale0 / vif_den_scale0) + (vif_num_scale1 / vif_den_scale1) + # (vif_num_scale2 / vif_den_scale2) + (vif_num_scale3 / vif_den_scale3)) / 4.0 vif_scores_key = cls.get_scores_key('vif2') result.result_dict[vif_scores_key] = list( ( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) + (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) + (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) + (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) / 4.0 ) # adm_scalei = adm_num_scalei / adm_den_scalei, i = 0, 1, 2, 3 adm_num_scale0_scores_key = cls.get_scores_key('adm_num_scale0') adm_den_scale0_scores_key = cls.get_scores_key('adm_den_scale0') adm_num_scale1_scores_key = cls.get_scores_key('adm_num_scale1') adm_den_scale1_scores_key = cls.get_scores_key('adm_den_scale1') adm_num_scale2_scores_key = cls.get_scores_key('adm_num_scale2') adm_den_scale2_scores_key = cls.get_scores_key('adm_den_scale2') adm_num_scale3_scores_key = cls.get_scores_key('adm_num_scale3') adm_den_scale3_scores_key = cls.get_scores_key('adm_den_scale3') adm_scale0_scores_key = cls.get_scores_key('adm_scale0') adm_scale1_scores_key = cls.get_scores_key('adm_scale1') adm_scale2_scores_key = cls.get_scores_key('adm_scale2') adm_scale3_scores_key = cls.get_scores_key('adm_scale3') result.result_dict[adm_scale0_scores_key] = list( (np.array(result.result_dict[adm_num_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale1_scores_key] = list( (np.array(result.result_dict[adm_num_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale2_scores_key] = list( (np.array(result.result_dict[adm_num_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale3_scores_key] = list( (np.array(result.result_dict[adm_num_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) ) # adm3 = \ # (((adm_num_scale0 + ADM_SCALE_CONSTANT) / (adm_den_scale0 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale1 + ADM_SCALE_CONSTANT) / (adm_den_scale1 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale2 + ADM_SCALE_CONSTANT) / (adm_den_scale2 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale3 + ADM_SCALE_CONSTANT) / (adm_den_scale3 + ADM_SCALE_CONSTANT))) / 4.0 adm3_scores_key = cls.get_scores_key('adm3') result.result_dict[adm3_scores_key] = list( ( ((np.array(result.result_dict[adm_num_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT)) ) / 4.0 ) # validate for feature in cls.DERIVED_ATOM_FEATURES: assert cls.get_scores_key(feature) in result.result_dict return result class VifFrameDifferenceFeatureExtractor(FeatureExtractor): TYPE = "VifDiff_feature" VERSION = '0.1' ATOM_FEATURES = ['vifdiff', 'vifdiff_num', 'vifdiff_den', 'vifdiff_num_scale0', 'vifdiff_den_scale0', 'vifdiff_num_scale1', 'vifdiff_den_scale1', 'vifdiff_num_scale2', 'vifdiff_den_scale2', 'vifdiff_num_scale3', 'vifdiff_den_scale3', ] DERIVED_ATOM_FEATURES = ['vifdiff_scale0', 'vifdiff_scale1', 'vifdiff_scale2', 'vifdiff_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vifdiff_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VifFrameDifferenceFeatureExtractor, cls)._post_process_result(result) # vifdiff_scalei = vifdiff_num_scalei / vifdiff_den_scalei, i = 0, 1, 2, 3 vifdiff_num_scale0_scores_key = cls.get_scores_key('vifdiff_num_scale0') vifdiff_den_scale0_scores_key = cls.get_scores_key('vifdiff_den_scale0') vifdiff_num_scale1_scores_key = cls.get_scores_key('vifdiff_num_scale1') vifdiff_den_scale1_scores_key = cls.get_scores_key('vifdiff_den_scale1') vifdiff_num_scale2_scores_key = cls.get_scores_key('vifdiff_num_scale2') vifdiff_den_scale2_scores_key = cls.get_scores_key('vifdiff_den_scale2') vifdiff_num_scale3_scores_key = cls.get_scores_key('vifdiff_num_scale3') vifdiff_den_scale3_scores_key = cls.get_scores_key('vifdiff_den_scale3') vifdiff_scale0_scores_key = cls.get_scores_key('vifdiff_scale0') vifdiff_scale1_scores_key = cls.get_scores_key('vifdiff_scale1') vifdiff_scale2_scores_key = cls.get_scores_key('vifdiff_scale2') vifdiff_scale3_scores_key = cls.get_scores_key('vifdiff_scale3') result.result_dict[vifdiff_scale0_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale0_scores_key]) / np.array(result.result_dict[vifdiff_den_scale0_scores_key])) ) result.result_dict[vifdiff_scale1_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale1_scores_key]) / np.array(result.result_dict[vifdiff_den_scale1_scores_key])) ) result.result_dict[vifdiff_scale2_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale2_scores_key]) / np.array(result.result_dict[vifdiff_den_scale2_scores_key])) ) result.result_dict[vifdiff_scale3_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale3_scores_key]) / np.array(result.result_dict[vifdiff_den_scale3_scores_key])) ) # validate for feature in cls.DERIVED_ATOM_FEATURES: assert cls.get_scores_key(feature) in result.result_dict return result class PsnrFeatureExtractor(FeatureExtractor): TYPE = "PSNR_feature" VERSION = "1.0" ATOM_FEATURES = ['psnr'] def _generate_result(self, asset): # routine to call the command-line executable and generate quality # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_psnr(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) class MomentFeatureExtractor(FeatureExtractor): TYPE = "Moment_feature" # VERSION = "1.0" # call executable VERSION = "1.1" # python only ATOM_FEATURES = ['ref1st', 'ref2nd', 'dis1st', 'dis2nd', ] DERIVED_ATOM_FEATURES = ['refvar', 'disvar', ] def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_w, quality_h = asset.quality_width_height ref_scores_mtx = None with YuvReader(filepath=asset.ref_workfile_path, width=quality_w, height=quality_h, yuv_type=self._get_workfile_yuv_type(asset)) as ref_yuv_reader: scores_mtx_list = [] i = 0 for ref_yuv in ref_yuv_reader: ref_y = ref_yuv[0] firstm = ref_y.mean() secondm = ref_y.var() + firstm**2 scores_mtx_list.append(np.hstack(([firstm], [secondm]))) i += 1 ref_scores_mtx =	np.vstack(scores_mtx_list)	numpy.vstack
# coding: utf-8 # Licensed under a 3-clause BSD style license - see LICENSE.rst """ Test the Logarithmic Units and Quantities """ from __future__ import (absolute_import, unicode_literals, division, print_function) from ...extern import six from ...extern.six.moves import zip import pickle import itertools import pytest import numpy as np from numpy.testing.utils import assert_allclose from ...tests.helper import assert_quantity_allclose from ... import units as u, constants as c lu_units = [u.dex, u.mag, u.decibel] lu_subclasses = [u.DexUnit, u.MagUnit, u.DecibelUnit] lq_subclasses = [u.Dex, u.Magnitude, u.Decibel] pu_sample = (u.dimensionless_unscaled, u.m, u.g/u.s*2, u.Jy) class TestLogUnitCreation(object): def test_logarithmic_units(self): """Check logarithmic units are set up correctly.""" assert u.dB.to(u.dex) == 0.1 assert u.dex.to(u.mag) == -2.5 assert u.mag.to(u.dB) == -4 @pytest.mark.parametrize('lu_unit, lu_cls', zip(lu_units, lu_subclasses)) def test_callable_units(self, lu_unit, lu_cls): assert isinstance(lu_unit, u.UnitBase) assert callable(lu_unit) assert lu_unit._function_unit_class is lu_cls @pytest.mark.parametrize('lu_unit', lu_units) def test_equality_to_normal_unit_for_dimensionless(self, lu_unit): lu = lu_unit() assert lu == lu._default_function_unit # eg, MagUnit() == u.mag assert lu._default_function_unit == lu # and u.mag == MagUnit() @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_call_units(self, lu_unit, physical_unit): """Create a LogUnit subclass using the callable unit and physical unit, and do basic check that output is right.""" lu1 = lu_unit(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit def test_call_invalid_unit(self): with pytest.raises(TypeError): u.mag([]) with pytest.raises(ValueError): u.mag(u.mag()) @pytest.mark.parametrize('lu_cls, physical_unit', itertools.product( lu_subclasses + [u.LogUnit], pu_sample)) def test_subclass_creation(self, lu_cls, physical_unit): """Create a LogUnit subclass object for given physical unit, and do basic check that output is right.""" lu1 = lu_cls(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit lu2 = lu_cls(physical_unit, function_unit=2lu1._default_function_unit) assert lu2.physical_unit == physical_unit assert lu2.function_unit == u.Unit(2lu2._default_function_unit) with pytest.raises(ValueError): lu_cls(physical_unit, u.m) def test_predefined_magnitudes(): assert_quantity_allclose((-21.1u.STmag).physical, 1.u.erg/u.cm2/u.s/u.AA) assert_quantity_allclose((-48.6u.ABmag).physical, 1.u.erg/u.cm2/u.s/u.Hz) assert_quantity_allclose((0u.M_bol).physical, c.L_bol0) assert_quantity_allclose((0u.m_bol).physical, c.L_bol0/(4.np.pi(10.c.pc)2)) def test_predefined_reinitialisation(): assert u.mag('ST') == u.STmag assert u.mag('AB') == u.ABmag assert u.mag('Bol') == u.M_bol assert u.mag('bol') == u.m_bol def test_predefined_string_roundtrip(): """Ensure roundtripping; see #5015""" with u.magnitude_zero_points.enable(): assert u.Unit(u.STmag.to_string()) == u.STmag assert u.Unit(u.ABmag.to_string()) == u.ABmag assert u.Unit(u.M_bol.to_string()) == u.M_bol assert u.Unit(u.m_bol.to_string()) == u.m_bol def test_inequality(): """Check __ne__ works (regresssion for #5342).""" lu1 = u.mag(u.Jy) lu2 = u.dex(u.Jy) lu3 = u.mag(u.Jy2) lu4 = lu3 - lu1 assert lu1 != lu2 assert lu1 != lu3 assert lu1 == lu4 class TestLogUnitStrings(object): def test_str(self): """Do some spot checks that str, repr, etc. work as expected.""" lu1 = u.mag(u.Jy) assert str(lu1) == 'mag(Jy)' assert repr(lu1) == 'Unit("mag(Jy)")' assert lu1.to_string('generic') == 'mag(Jy)' with pytest.raises(ValueError): lu1.to_string('fits') lu2 = u.dex() assert str(lu2) == 'dex' assert repr(lu2) == 'Unit("dex(1)")' assert lu2.to_string() == 'dex(1)' lu3 = u.MagUnit(u.Jy, function_unit=2u.mag) assert str(lu3) == '2 mag(Jy)' assert repr(lu3) == 'MagUnit("Jy", unit="2 mag")' assert lu3.to_string() == '2 mag(Jy)' lu4 = u.mag(u.ct) assert lu4.to_string('generic') == 'mag(ct)' assert lu4.to_string('latex') == ('$\\mathrm{mag}$$\\mathrm{\\left( ' '\\mathrm{ct} \\right)}$') assert lu4._repr_latex_() == lu4.to_string('latex') class TestLogUnitConversion(object): @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_physical_unit_conversion(self, lu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to their non-log counterparts.""" lu1 = lu_unit(physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(physical_unit, 0.) == 1. assert physical_unit.is_equivalent(lu1) assert physical_unit.to(lu1, 1.) == 0. pu = u.Unit(8.physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(pu, 0.) == 0.125 assert pu.is_equivalent(lu1) assert_allclose(pu.to(lu1, 0.125), 0., atol=1.e-15) # Check we round-trip. value = np.linspace(0., 10., 6) assert_allclose(pu.to(lu1, lu1.to(pu, value)), value, atol=1.e-15) # And that we're not just returning True all the time. pu2 = u.g assert not lu1.is_equivalent(pu2) with pytest.raises(u.UnitsError): lu1.to(pu2) assert not pu2.is_equivalent(lu1) with pytest.raises(u.UnitsError): pu2.to(lu1) @pytest.mark.parametrize('lu_unit', lu_units) def test_container_unit_conversion(self, lu_unit): """Check that conversion to logarithmic units (u.mag, u.dB, u.dex) is only possible when the physical unit is dimensionless.""" values = np.linspace(0., 10., 6) lu1 = lu_unit(u.dimensionless_unscaled) assert lu1.is_equivalent(lu1.function_unit) assert_allclose(lu1.to(lu1.function_unit, values), values) lu2 = lu_unit(u.Jy) assert not lu2.is_equivalent(lu2.function_unit) with pytest.raises(u.UnitsError): lu2.to(lu2.function_unit, values) @pytest.mark.parametrize( 'flu_unit, tlu_unit, physical_unit', itertools.product(lu_units, lu_units, pu_sample)) def test_subclass_conversion(self, flu_unit, tlu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to each other if they correspond to equivalent physical units.""" values = np.linspace(0., 10., 6) flu = flu_unit(physical_unit) tlu = tlu_unit(physical_unit) assert flu.is_equivalent(tlu) assert_allclose(flu.to(tlu), flu.function_unit.to(tlu.function_unit)) assert_allclose(flu.to(tlu, values), values * flu.function_unit.to(tlu.function_unit)) tlu2 = tlu_unit(u.Unit(100.physical_unit)) assert flu.is_equivalent(tlu2) # Check that we round-trip. assert_allclose(flu.to(tlu2, tlu2.to(flu, values)), values, atol=1.e-15) tlu3 = tlu_unit(physical_unit.to_system(u.si)[0]) assert flu.is_equivalent(tlu3) assert_allclose(flu.to(tlu3, tlu3.to(flu, values)), values, atol=1.e-15) tlu4 = tlu_unit(u.g) assert not flu.is_equivalent(tlu4) with pytest.raises(u.UnitsError): flu.to(tlu4, values) def test_unit_decomposition(self): lu = u.mag(u.Jy) assert lu.decompose() == u.mag(u.Jy.decompose()) assert lu.decompose().physical_unit.bases == [u.kg, u.s] assert lu.si == u.mag(u.Jy.si) assert lu.si.physical_unit.bases == [u.kg, u.s] assert lu.cgs == u.mag(u.Jy.cgs) assert lu.cgs.physical_unit.bases == [u.g, u.s] def test_unit_multiple_possible_equivalencies(self): lu = u.mag(u.Jy) assert lu.is_equivalent(pu_sample) class TestLogUnitArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other units is only possible when the physical unit is dimensionless, and that this turns the unit into a normal one.""" lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 u.m with pytest.raises(u.UnitsError): u.m * lu1 with pytest.raises(u.UnitsError): lu1 / lu1 for unit in (u.dimensionless_unscaled, u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lu1 / unit lu2 = u.mag(u.dimensionless_unscaled) with pytest.raises(u.UnitsError): lu2 * lu1 with pytest.raises(u.UnitsError): lu2 / lu1 # But dimensionless_unscaled can be cancelled. assert lu2 / lu2 == u.dimensionless_unscaled # With dimensionless, normal units are OK, but we return a plain unit. tf = lu2 * u.m tr = u.m * lu2 for t in (tf, tr): assert not isinstance(t, type(lu2)) assert t == lu2.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lu2.physical_unit) # Now we essentially have a LogUnit with a prefactor of 100, # so should be equivalent again. t = tf / u.cm with u.set_enabled_equivalencies(u.logarithmic()): assert t.is_equivalent(lu2.function_unit) assert_allclose(t.to(u.dimensionless_unscaled, np.arange(3.)/100.), lu2.to(lu2.physical_unit, np.arange(3.))) # If we effectively remove lu1, a normal unit should be returned. t2 = tf / lu2 assert not isinstance(t2, type(lu2)) assert t2 == u.m t3 = tf / lu2.function_unit assert not isinstance(t3, type(lu2)) assert t3 == u.m # For completeness, also ensure non-sensical operations fail with pytest.raises(TypeError): lu1 * object() with pytest.raises(TypeError): slice(None) * lu1 with pytest.raises(TypeError): lu1 / [] with pytest.raises(TypeError): 1 / lu1 @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogUnits to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (such as mag2) is incompatible.""" lu1 = u.mag(u.Jy) if power == 0: assert lu1 power == u.dimensionless_unscaled elif power == 1: assert lu1 power == lu1 else: with pytest.raises(u.UnitsError): lu1 power # With dimensionless, though, it works, but returns a normal unit. lu2 = u.mag(u.dimensionless_unscaled) t = lu2power if power == 0: assert t == u.dimensionless_unscaled elif power == 1: assert t == lu2 else: assert not isinstance(t, type(lu2)) assert t == lu2.function_unitpower # also check we roundtrip t2 = t*(1./power) assert t2 == lu2.function_unit with u.set_enabled_equivalencies(u.logarithmic()): assert_allclose(t2.to(u.dimensionless_unscaled, np.arange(3.)), lu2.to(lu2.physical_unit, np.arange(3.))) @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 + other with pytest.raises(u.UnitsError): lu1 - other with pytest.raises(u.UnitsError): other - lu1 def test_addition_subtraction_to_non_units_fails(self): lu1 = u.mag(u.Jy) with pytest.raises(TypeError): lu1 + 1. with pytest.raises(TypeError): lu1 - [1., 2., 3.] @pytest.mark.parametrize( 'other', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2u.mag), u.MagUnit('', 2.u.mag))) def test_addition_subtraction(self, other): """Check physical units are changed appropriately""" lu1 = u.mag(u.Jy) other_pu = getattr(other, 'physical_unit', u.dimensionless_unscaled) lu_sf = lu1 + other assert lu_sf.is_equivalent(lu1.physical_unit other_pu) lu_sr = other + lu1 assert lu_sr.is_equivalent(lu1.physical_unit * other_pu) lu_df = lu1 - other assert lu_df.is_equivalent(lu1.physical_unit / other_pu) lu_dr = other - lu1 assert lu_dr.is_equivalent(other_pu / lu1.physical_unit) def test_complicated_addition_subtraction(self): """for fun, a more complicated example of addition and subtraction""" dm0 = u.Unit('DM', 1./(4.np.pi(10.u.pc)2)) lu_dm = u.mag(dm0) lu_absST = u.STmag - lu_dm assert lu_absST.is_equivalent(u.erg/u.s/u.AA) def test_neg_pos(self): lu1 = u.mag(u.Jy) neg_lu = -lu1 assert neg_lu != lu1 assert neg_lu.physical_unit == u.Jy-1 assert -neg_lu == lu1 pos_lu = +lu1 assert pos_lu is not lu1 assert pos_lu == lu1 def test_pickle(): lu1 = u.dex(u.cm/u.s2) s = pickle.dumps(lu1) lu2 = pickle.loads(s) assert lu1 == lu2 def test_hashable(): lu1 = u.dB(u.mW) lu2 = u.dB(u.m) lu3 = u.dB(u.mW) assert hash(lu1) != hash(lu2) assert hash(lu1) == hash(lu3) luset = {lu1, lu2, lu3} assert len(luset) == 2 class TestLogQuantityCreation(object): @pytest.mark.parametrize('lq, lu', zip(lq_subclasses + [u.LogQuantity], lu_subclasses + [u.LogUnit])) def test_logarithmic_quantities(self, lq, lu): """Check logarithmic quantities are all set up correctly""" assert lq._unit_class == lu assert type(lu()._quantity_class(1.)) is lq @pytest.mark.parametrize('lq_cls, physical_unit', itertools.product(lq_subclasses, pu_sample)) def test_subclass_creation(self, lq_cls, physical_unit): """Create LogQuantity subclass objects for some physical units, and basic check on transformations""" value = np.arange(1., 10.) log_q = lq_cls(value physical_unit) assert log_q.unit.physical_unit == physical_unit assert log_q.unit.function_unit == log_q.unit._default_function_unit assert_allclose(log_q.physical.value, value) with pytest.raises(ValueError): lq_cls(value, physical_unit) @pytest.mark.parametrize( 'unit', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2u.mag), u.MagUnit('', 2.u.mag), u.MagUnit(u.Jy, -1u.mag), u.MagUnit(u.m, -2.u.mag))) def test_different_units(self, unit): q = u.Magnitude(1.23, unit) assert q.unit.function_unit == getattr(unit, 'function_unit', unit) assert q.unit.physical_unit is getattr(unit, 'physical_unit', u.dimensionless_unscaled) @pytest.mark.parametrize('value, unit', ( (1.u.mag(u.Jy), None), (1.u.dex(u.Jy), None), (1.u.mag(u.W/u.m2/u.Hz), u.mag(u.Jy)), (1.u.dex(u.W/u.m*2/u.Hz), u.mag(u.Jy)))) def test_function_values(self, value, unit): lq = u.Magnitude(value, unit) assert lq == value assert lq.unit.function_unit == u.mag assert lq.unit.physical_unit == getattr(unit, 'physical_unit', value.unit.physical_unit) @pytest.mark.parametrize( 'unit', (u.mag(), u.mag(u.Jy), u.mag(u.m), u.MagUnit('', 2.u.mag), u.MagUnit(u.Jy, -1u.mag), u.MagUnit(u.m, -2.u.mag))) def test_indirect_creation(self, unit): q1 = 2.5 * unit assert isinstance(q1, u.Magnitude) assert q1.value == 2.5 assert q1.unit == unit pv = 100. * unit.physical_unit q2 = unit * pv assert q2.unit == unit assert q2.unit.physical_unit == pv.unit assert q2.to_value(unit.physical_unit) == 100. assert (q2._function_view / u.mag).to_value(1) == -5. q3 = unit / 0.4 assert q3 == q1 def test_from_view(self): # Cannot view a physical quantity as a function quantity, since the # values would change. q = [100., 1000.] * u.cm/u.s*2 with pytest.raises(TypeError): q.view(u.Dex) # But fine if we have the right magnitude. q = [2., 3.] u.dex lq = q.view(u.Dex) assert isinstance(lq, u.Dex) assert lq.unit.physical_unit == u.dimensionless_unscaled assert np.all(q == lq) def test_using_quantity_class(self): """Check that we can use Quantity if we have subok=True""" # following issue #5851 lu = u.dex(u.AA) with pytest.raises(u.UnitTypeError): u.Quantity(1., lu) q = u.Quantity(1., lu, subok=True) assert type(q) is lu._quantity_class def test_conversion_to_and_from_physical_quantities(): """Ensures we can convert from regular quantities.""" mst = [10., 12., 14.] * u.STmag flux_lambda = mst.physical mst_roundtrip = flux_lambda.to(u.STmag) # check we return a logquantity; see #5178. assert isinstance(mst_roundtrip, u.Magnitude) assert mst_roundtrip.unit == mst.unit assert_allclose(mst_roundtrip.value, mst.value) wave = [4956.8, 4959.55, 4962.3] * u.AA flux_nu = mst.to(u.Jy, equivalencies=u.spectral_density(wave)) mst_roundtrip2 = flux_nu.to(u.STmag, u.spectral_density(wave)) assert isinstance(mst_roundtrip2, u.Magnitude) assert mst_roundtrip2.unit == mst.unit assert_allclose(mst_roundtrip2.value, mst.value) def test_quantity_decomposition(): lq = 10.u.mag(u.Jy) assert lq.decompose() == lq assert lq.decompose().unit.physical_unit.bases == [u.kg, u.s] assert lq.si == lq assert lq.si.unit.physical_unit.bases == [u.kg, u.s] assert lq.cgs == lq assert lq.cgs.unit.physical_unit.bases == [u.g, u.s] class TestLogQuantityViews(object): def setup(self): self.lq = u.Magnitude(np.arange(10.) u.Jy) self.lq2 = u.Magnitude(np.arange(5.)) def test_value_view(self): lq_value = self.lq.value assert type(lq_value) is np.ndarray lq_value[2] = -1. assert np.all(self.lq.value == lq_value) def test_function_view(self): lq_fv = self.lq._function_view assert type(lq_fv) is u.Quantity assert lq_fv.unit is self.lq.unit.function_unit lq_fv[3] = -2. * lq_fv.unit assert np.all(self.lq.value == lq_fv.value) def test_quantity_view(self): # Cannot view as Quantity, since the unit cannot be represented. with pytest.raises(TypeError): self.lq.view(u.Quantity) # But a dimensionless one is fine. q2 = self.lq2.view(u.Quantity) assert q2.unit is u.mag assert np.all(q2.value == self.lq2.value) lq3 = q2.view(u.Magnitude) assert type(lq3.unit) is u.MagUnit assert lq3.unit.physical_unit == u.dimensionless_unscaled assert np.all(lq3 == self.lq2) class TestLogQuantitySlicing(object): def test_item_get_and_set(self): lq1 = u.Magnitude(np.arange(1., 11.)u.Jy) assert lq1[9] == u.Magnitude(10.u.Jy) lq1[2] = 100.u.Jy assert lq1[2] == u.Magnitude(100.u.Jy) with pytest.raises(u.UnitsError): lq1[2] = 100.u.m with pytest.raises(u.UnitsError): lq1[2] = 100.u.mag with pytest.raises(u.UnitsError): lq1[2] = u.Magnitude(100.u.m) assert lq1[2] == u.Magnitude(100.u.Jy) def test_slice_get_and_set(self): lq1 = u.Magnitude(np.arange(1., 10.)u.Jy) lq1[2:4] = 100.u.Jy assert np.all(lq1[2:4] == u.Magnitude(100.u.Jy)) with pytest.raises(u.UnitsError): lq1[2:4] = 100.u.m with pytest.raises(u.UnitsError): lq1[2:4] = 100.u.mag with pytest.raises(u.UnitsError): lq1[2:4] = u.Magnitude(100.u.m) assert np.all(lq1[2] == u.Magnitude(100.u.Jy)) class TestLogQuantityArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other quantities is only possible when the physical unit is dimensionless, and that this turns the result into a normal quantity.""" lq = u.Magnitude(np.arange(1., 11.)u.Jy) with pytest.raises(u.UnitsError): lq * (1.u.m) with pytest.raises(u.UnitsError): (1.u.m) * lq with pytest.raises(u.UnitsError): lq / lq for unit in (u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lq / unit lq2 = u.Magnitude(np.arange(1, 11.)) with pytest.raises(u.UnitsError): lq2 * lq with pytest.raises(u.UnitsError): lq2 / lq with pytest.raises(u.UnitsError): lq / lq2 # but dimensionless_unscaled can be cancelled r = lq2 / u.Magnitude(2.) assert r.unit == u.dimensionless_unscaled assert np.all(r.value == lq2.value/2.) # with dimensionless, normal units OK, but return normal quantities tf = lq2 * u.m tr = u.m * lq2 for t in (tf, tr): assert not isinstance(t, type(lq2)) assert t.unit == lq2.unit.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lq2.unit.physical_unit) t = tf / (50.u.cm) # now we essentially have the same quantity but with a prefactor of 2 assert t.unit.is_equivalent(lq2.unit.function_unit) assert_allclose(t.to(lq2.unit.function_unit), lq2._function_view2) @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogQuantities to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (say, mag*2) is incompatible.""" lq = u.Magnitude(np.arange(1., 4.)u.Jy) if power == 0: assert np.all(lq power == 1.) elif power == 1: assert np.all(lq power == lq) else: with pytest.raises(u.UnitsError): lq power # with dimensionless, it works, but falls back to normal quantity # (except for power=1) lq2 = u.Magnitude(np.arange(10.)) t = lq2power if power == 0: assert t.unit is u.dimensionless_unscaled assert np.all(t.value == 1.) elif power == 1: assert np.all(t == lq2) else: assert not isinstance(t, type(lq2)) assert t.unit == lq2.unit.function_unit ** power with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(u.dimensionless_unscaled) def test_error_on_lq_as_power(self): lq = u.Magnitude(np.arange(1., 4.)u.Jy) with pytest.raises(TypeError): lq * lq @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lq = u.Magnitude(np.arange(1., 10.)u.Jy) q = 1.23 other with pytest.raises(u.UnitsError): lq + q with pytest.raises(u.UnitsError): lq - q with pytest.raises(u.UnitsError): q - lq @pytest.mark.parametrize( 'other', (1.23 * u.mag, 2.34 * u.mag(), u.Magnitude(3.45 * u.Jy), u.Magnitude(4.56 * u.m), 5.67 * u.Unit(2u.mag), u.Magnitude(6.78, 2.u.mag))) def test_addition_subtraction(self, other): """Check that addition/subtraction with quantities with magnitude or MagUnit units works, and that it changes the physical units appropriately.""" lq = u.Magnitude(np.arange(1., 10.)u.Jy) other_physical = other.to(getattr(other.unit, 'physical_unit', u.dimensionless_unscaled), equivalencies=u.logarithmic()) lq_sf = lq + other assert_allclose(lq_sf.physical, lq.physical other_physical) lq_sr = other + lq assert_allclose(lq_sr.physical, lq.physical * other_physical) lq_df = lq - other assert_allclose(lq_df.physical, lq.physical / other_physical) lq_dr = other - lq assert_allclose(lq_dr.physical, other_physical / lq.physical) @pytest.mark.parametrize('other', pu_sample) def test_inplace_addition_subtraction_unit_checks(self, other): lu1 = u.mag(u.Jy) lq1 = u.Magnitude(np.arange(1., 10.), lu1) with pytest.raises(u.UnitsError): lq1 += other assert np.all(lq1.value == np.arange(1., 10.)) assert lq1.unit == lu1 with pytest.raises(u.UnitsError): lq1 -= other assert np.all(lq1.value == np.arange(1., 10.)) assert lq1.unit == lu1 @pytest.mark.parametrize( 'other', (1.23 * u.mag, 2.34 * u.mag(), u.Magnitude(3.45 * u.Jy), u.Magnitude(4.56 * u.m), 5.67 * u.Unit(2u.mag), u.Magnitude(6.78, 2.u.mag))) def test_inplace_addition_subtraction(self, other): """Check that inplace addition/subtraction with quantities with magnitude or MagUnit units works, and that it changes the physical units appropriately.""" lq = u.Magnitude(np.arange(1., 10.)u.Jy) other_physical = other.to(getattr(other.unit, 'physical_unit', u.dimensionless_unscaled), equivalencies=u.logarithmic()) lq_sf = lq.copy() lq_sf += other assert_allclose(lq_sf.physical, lq.physical other_physical) lq_df = lq.copy() lq_df -= other assert_allclose(lq_df.physical, lq.physical / other_physical) def test_complicated_addition_subtraction(self): """For fun, a more complicated example of addition and subtraction.""" dm0 = u.Unit('DM', 1./(4.np.pi(10.u.pc)2)) DMmag = u.mag(dm0) m_st = 10. u.STmag dm = 5. * DMmag M_st = m_st - dm assert M_st.unit.is_equivalent(u.erg/u.s/u.AA) assert np.abs(M_st.physical / (m_st.physical4.np.pi(100.u.pc)*2) - 1.) < 1.e-15 class TestLogQuantityComparisons(object): def test_comparison_to_non_quantities_fails(self): lq = u.Magnitude(np.arange(1., 10.)u.Jy) # On python2, ordering operations always succeed, given essentially # meaningless results. if not six.PY2: with pytest.raises(TypeError): lq > 'a' assert not (lq == 'a') assert lq != 'a' def test_comparison(self): lq1 = u.Magnitude(np.arange(1., 4.)u.Jy) lq2 = u.Magnitude(2.u.Jy) assert np.all((lq1 > lq2) == np.array([True, False, False])) assert np.all((lq1 == lq2) == np.array([False, True, False])) lq3 = u.Dex(2.u.Jy) assert np.all((lq1 > lq3) == np.array([True, False, False])) assert np.all((lq1 == lq3) == np.array([False, True, False])) lq4 = u.Magnitude(2.u.m) assert not (lq1 == lq4) assert lq1 != lq4 with pytest.raises(u.UnitsError): lq1 < lq4 q5 = 1.5 * u.Jy assert np.all((lq1 > q5) == np.array([True, False, False])) assert np.all((q5 < lq1) == np.array([True, False, False])) with pytest.raises(u.UnitsError): lq1 >= 2.u.m with pytest.raises(u.UnitsError): lq1 <= lq1.value u.mag # For physically dimensionless, we can compare with the function unit. lq6 = u.Magnitude(np.arange(1., 4.)) fv6 = lq6.value * u.mag assert np.all(lq6 == fv6) # but not some arbitrary unit, of course. with pytest.raises(u.UnitsError): lq6 < 2.u.m class TestLogQuantityMethods(object): def setup(self): self.mJy = np.arange(1., 5.).reshape(2, 2) u.mag(u.Jy) self.m1 = np.arange(1., 5.5, 0.5).reshape(3, 3) * u.mag() self.mags = (self.mJy, self.m1) @pytest.mark.parametrize('method', ('mean', 'min', 'max', 'round', 'trace', 'std', 'var', 'ptp', 'diff', 'ediff1d')) def test_always_ok(self, method): for mag in self.mags: res = getattr(mag, method)() assert np.all(res.value == getattr(mag._function_view, method)().value) if method in ('std', 'ptp', 'diff', 'ediff1d'): assert res.unit == u.mag() elif method == 'var': assert res.unit == u.mag*2 else: assert res.unit == mag.unit def test_clip(self): for mag in self.mags: assert np.all(mag.clip(2. mag.unit, 4. * mag.unit).value == mag.value.clip(2., 4.)) @pytest.mark.parametrize('method', ('sum', 'cumsum', 'nansum')) def test_only_ok_if_dimensionless(self, method): res = getattr(self.m1, method)() assert np.all(res.value == getattr(self.m1._function_view, method)().value) assert res.unit == self.m1.unit with pytest.raises(TypeError): getattr(self.mJy, method)() def test_dot(self): assert np.all(self.m1.dot(self.m1).value == self.m1.value.dot(self.m1.value)) @pytest.mark.parametrize('method', ('prod', 'cumprod')) def test_never_ok(self, method): with pytest.raises(ValueError): getattr(self.mJy, method)() with pytest.raises(ValueError): getattr(self.m1, method)() class TestLogQuantityUfuncs(object): """Spot checks on ufuncs.""" def setup(self): self.mJy = np.arange(1., 5.).reshape(2, 2) * u.mag(u.Jy) self.m1 = np.arange(1., 5.5, 0.5).reshape(3, 3) * u.mag() self.mags = (self.mJy, self.m1) def test_power(self): assert np.all(np.power(self.mJy, 0.) == 1.) assert np.all(np.power(self.m1, 1.) == self.m1) assert np.all(np.power(self.mJy, 1.) == self.mJy) assert np.all(np.power(self.m1, 2.) == self.m1 ** 2) with pytest.raises(u.UnitsError): np.power(self.mJy, 2.) def test_not_implemented_with_physical_unit(self): with pytest.raises(u.UnitsError): np.square(self.mJy) assert np.all(	np.square(self.m1)	numpy.square
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] *	np.ones_like(min_2_y)	numpy.ones_like
#!/usr/bin/env python # encoding: utf-8 -- """ This module contains unit tests of the rmgpy.reaction module. """ import numpy import unittest from external.wip import work_in_progress from rmgpy.species import Species, TransitionState from rmgpy.reaction import Reaction from rmgpy.statmech.translation import Translation, IdealGasTranslation from rmgpy.statmech.rotation import Rotation, LinearRotor, NonlinearRotor, KRotor, SphericalTopRotor from rmgpy.statmech.vibration import Vibration, HarmonicOscillator from rmgpy.statmech.torsion import Torsion, HinderedRotor from rmgpy.statmech.conformer import Conformer from rmgpy.kinetics import Arrhenius from rmgpy.thermo import Wilhoit import rmgpy.constants as constants ################################################################################ class PseudoSpecies: """ Can be used in place of a :class:`rmg.species.Species` for isomorphism checks. PseudoSpecies('a') is isomorphic with PseudoSpecies('A') but nothing else. """ def __init__(self, label): self.label = label def __repr__(self): return "PseudoSpecies('{0}')".format(self.label) def __str__(self): return self.label def isIsomorphic(self, other): return self.label.lower() == other.label.lower() class TestReactionIsomorphism(unittest.TestCase): """ Contains unit tests of the isomorphism testing of the Reaction class. """ def makeReaction(self,reaction_string): """" Make a Reaction (containing PseudoSpecies) of from a string like 'Ab=CD' """ reactants, products = reaction_string.split('=') reactants = [PseudoSpecies(i) for i in reactants] products = [PseudoSpecies(i) for i in products] return Reaction(reactants=reactants, products=products) def test1to1(self): r1 = self.makeReaction('A=B') self.assertTrue(r1.isIsomorphic(self.makeReaction('a=B'))) self.assertTrue(r1.isIsomorphic(self.makeReaction('b=A'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('B=a'),eitherDirection=False)) self.assertFalse(r1.isIsomorphic(self.makeReaction('A=C'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('A=BB'))) def test1to2(self): r1 = self.makeReaction('A=BC') self.assertTrue(r1.isIsomorphic(self.makeReaction('a=Bc'))) self.assertTrue(r1.isIsomorphic(self.makeReaction('cb=a'))) self.assertTrue(r1.isIsomorphic(self.makeReaction('a=cb'),eitherDirection=False)) self.assertFalse(r1.isIsomorphic(self.makeReaction('bc=a'),eitherDirection=False)) self.assertFalse(r1.isIsomorphic(self.makeReaction('a=c'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('ab=c'))) def test2to2(self): r1 = self.makeReaction('AB=CD') self.assertTrue(r1.isIsomorphic(self.makeReaction('ab=cd'))) self.assertTrue(r1.isIsomorphic(self.makeReaction('ab=dc'),eitherDirection=False)) self.assertTrue(r1.isIsomorphic(self.makeReaction('dc=ba'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('cd=ab'),eitherDirection=False)) self.assertFalse(r1.isIsomorphic(self.makeReaction('ab=ab'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('ab=cde'))) def test2to3(self): r1 = self.makeReaction('AB=CDE') self.assertTrue(r1.isIsomorphic(self.makeReaction('ab=cde'))) self.assertTrue(r1.isIsomorphic(self.makeReaction('ba=edc'),eitherDirection=False)) self.assertTrue(r1.isIsomorphic(self.makeReaction('dec=ba'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('cde=ab'),eitherDirection=False)) self.assertFalse(r1.isIsomorphic(self.makeReaction('ab=abc'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('abe=cde'))) class TestReaction(unittest.TestCase): """ Contains unit tests of the Reaction class. """ def setUp(self): """ A method that is called prior to each unit test in this class. """ ethylene = Species( label = 'C2H4', conformer = Conformer( E0 = (44.7127, 'kJ/mol'), modes = [ IdealGasTranslation( mass = (28.0313, 'amu'), ), NonlinearRotor( inertia = ( [3.41526, 16.6498, 20.065], 'amuangstrom^2', ), symmetry = 4, ), HarmonicOscillator( frequencies = ( [828.397, 970.652, 977.223, 1052.93, 1233.55, 1367.56, 1465.09, 1672.25, 3098.46, 3111.7, 3165.79, 3193.54], 'cm^-1', ), ), ], spinMultiplicity = 1, opticalIsomers = 1, ), ) hydrogen = Species( label = 'H', conformer = Conformer( E0 = (211.794, 'kJ/mol'), modes = [ IdealGasTranslation( mass = (1.00783, 'amu'), ), ], spinMultiplicity = 2, opticalIsomers = 1, ), ) ethyl = Species( label = 'C2H5', conformer = Conformer( E0 = (111.603, 'kJ/mol'), modes = [ IdealGasTranslation( mass = (29.0391, 'amu'), ), NonlinearRotor( inertia = ( [4.8709, 22.2353, 23.9925], 'amuangstrom^2', ), symmetry = 1, ), HarmonicOscillator( frequencies = ( [482.224, 791.876, 974.355, 1051.48, 1183.21, 1361.36, 1448.65, 1455.07, 1465.48, 2688.22, 2954.51, 3033.39, 3101.54, 3204.73], 'cm^-1', ), ), HinderedRotor( inertia = (1.11481, 'amuangstrom^2'), symmetry = 6, barrier = (0.244029, 'kJ/mol'), semiclassical = None, ), ], spinMultiplicity = 2, opticalIsomers = 1, ), ) TS = TransitionState( label = 'TS', conformer = Conformer( E0 = (266.694, 'kJ/mol'), modes = [ IdealGasTranslation( mass = (29.0391, 'amu'), ), NonlinearRotor( inertia = ( [6.78512, 22.1437, 22.2114], 'amuangstrom^2', ), symmetry = 1, ), HarmonicOscillator( frequencies = ( [412.75, 415.206, 821.495, 924.44, 982.714, 1024.16, 1224.21, 1326.36, 1455.06, 1600.35, 3101.46, 3110.55, 3175.34, 3201.88], 'cm^-1', ), ), ], spinMultiplicity = 2, opticalIsomers = 1, ), frequency = (-750.232, 'cm^-1'), ) self.reaction = Reaction( reactants = [hydrogen, ethylene], products = [ethyl], kinetics = Arrhenius( A = (501366000.0, 'cm^3/(mols)'), n = 1.637, Ea = (4.32508, 'kJ/mol'), T0 = (1, 'K'), Tmin = (300, 'K'), Tmax = (2500, 'K'), ), transitionState = TS, ) # CC(=O)O[O] acetylperoxy = Species( label='acetylperoxy', thermo=Wilhoit(Cp0=(4.0constants.R,"J/(molK)"), CpInf=(21.0constants.R,"J/(molK)"), a0=-3.95, a1=9.26, a2=-15.6, a3=8.55, B=(500.0,"K"), H0=(-6.151e+04,"J/mol"), S0=(-790.2,"J/(molK)")), ) # C[C]=O acetyl = Species( label='acetyl', thermo=Wilhoit(Cp0=(4.0constants.R,"J/(molK)"), CpInf=(15.5constants.R,"J/(molK)"), a0=0.2541, a1=-0.4712, a2=-4.434, a3=2.25, B=(500.0,"K"), H0=(-1.439e+05,"J/mol"), S0=(-524.6,"J/(molK)")), ) # [O][O] oxygen = Species( label='oxygen', thermo=Wilhoit(Cp0=(3.5constants.R,"J/(molK)"), CpInf=(4.5constants.R,"J/(molK)"), a0=-0.9324, a1=26.18, a2=-70.47, a3=44.12, B=(500.0,"K"), H0=(1.453e+04,"J/mol"), S0=(-12.19,"J/(molK)")), ) self.reaction2 = Reaction( reactants=[acetyl, oxygen], products=[acetylperoxy], kinetics = Arrhenius( A = (2.65e12, 'cm^3/(mols)'), n = 0.0, Ea = (0.0, 'kJ/mol'), T0 = (1, 'K'), Tmin = (300, 'K'), Tmax = (2000, 'K'), ), ) def testIsIsomerization(self): """ Test the Reaction.isIsomerization() method. """ isomerization = Reaction(reactants=[Species()], products=[Species()]) association = Reaction(reactants=[Species(),Species()], products=[Species()]) dissociation = Reaction(reactants=[Species()], products=[Species(),Species()]) bimolecular = Reaction(reactants=[Species(),Species()], products=[Species(),Species()]) self.assertTrue(isomerization.isIsomerization()) self.assertFalse(association.isIsomerization()) self.assertFalse(dissociation.isIsomerization()) self.assertFalse(bimolecular.isIsomerization()) def testIsAssociation(self): """ Test the Reaction.isAssociation() method. """ isomerization = Reaction(reactants=[Species()], products=[Species()]) association = Reaction(reactants=[Species(),Species()], products=[Species()]) dissociation = Reaction(reactants=[Species()], products=[Species(),Species()]) bimolecular = Reaction(reactants=[Species(),Species()], products=[Species(),Species()]) self.assertFalse(isomerization.isAssociation()) self.assertTrue(association.isAssociation()) self.assertFalse(dissociation.isAssociation()) self.assertFalse(bimolecular.isAssociation()) def testIsDissociation(self): """ Test the Reaction.isDissociation() method. """ isomerization = Reaction(reactants=[Species()], products=[Species()]) association = Reaction(reactants=[Species(),Species()], products=[Species()]) dissociation = Reaction(reactants=[Species()], products=[Species(),Species()]) bimolecular = Reaction(reactants=[Species(),Species()], products=[Species(),Species()]) self.assertFalse(isomerization.isDissociation()) self.assertFalse(association.isDissociation()) self.assertTrue(dissociation.isDissociation()) self.assertFalse(bimolecular.isDissociation()) def testHasTemplate(self): """ Test the Reaction.hasTemplate() method. """ reactants = self.reaction.reactants[:] products = self.reaction.products[:] self.assertTrue(self.reaction.hasTemplate(reactants, products)) self.assertTrue(self.reaction.hasTemplate(products, reactants)) self.assertFalse(self.reaction2.hasTemplate(reactants, products)) self.assertFalse(self.reaction2.hasTemplate(products, reactants)) reactants.reverse() products.reverse() self.assertTrue(self.reaction.hasTemplate(reactants, products)) self.assertTrue(self.reaction.hasTemplate(products, reactants)) self.assertFalse(self.reaction2.hasTemplate(reactants, products)) self.assertFalse(self.reaction2.hasTemplate(products, reactants)) reactants = self.reaction2.reactants[:] products = self.reaction2.products[:] self.assertFalse(self.reaction.hasTemplate(reactants, products)) self.assertFalse(self.reaction.hasTemplate(products, reactants)) self.assertTrue(self.reaction2.hasTemplate(reactants, products)) self.assertTrue(self.reaction2.hasTemplate(products, reactants)) reactants.reverse() products.reverse() self.assertFalse(self.reaction.hasTemplate(reactants, products)) self.assertFalse(self.reaction.hasTemplate(products, reactants)) self.assertTrue(self.reaction2.hasTemplate(reactants, products)) self.assertTrue(self.reaction2.hasTemplate(products, reactants)) def testEnthalpyOfReaction(self): """ Test the Reaction.getEnthalpyOfReaction() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) Hlist0 = [float(v) for v in ['-146007', '-145886', '-144195', '-141973', '-139633', '-137341', '-135155', '-133093', '-131150', '-129316']] Hlist = self.reaction2.getEnthalpiesOfReaction(Tlist) for i in range(len(Tlist)): self.assertAlmostEqual(Hlist[i] / 1000., Hlist0[i] / 1000., 2) def testEntropyOfReaction(self): """ Test the Reaction.getEntropyOfReaction() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) Slist0 = [float(v) for v in ['-156.793', '-156.872', '-153.504', '-150.317', '-147.707', '-145.616', '-143.93', '-142.552', '-141.407', '-140.441']] Slist = self.reaction2.getEntropiesOfReaction(Tlist) for i in range(len(Tlist)): self.assertAlmostEqual(Slist[i], Slist0[i], 2) def testFreeEnergyOfReaction(self): """ Test the Reaction.getFreeEnergyOfReaction() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) Glist0 = [float(v) for v in ['-114648', '-83137.2', '-52092.4', '-21719.3', '8073.53', '37398.1', '66346.8', '94990.6', '123383', '151565']] Glist = self.reaction2.getFreeEnergiesOfReaction(Tlist) for i in range(len(Tlist)): self.assertAlmostEqual(Glist[i] / 1000., Glist0[i] / 1000., 2) def testEquilibriumConstantKa(self): """ Test the Reaction.getEquilibriumConstant() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) Kalist0 = [float(v) for v in ['8.75951e+29', '7.1843e+10', '34272.7', '26.1877', '0.378696', '0.0235579', '0.00334673', '0.000792389', '0.000262777', '0.000110053']] Kalist = self.reaction2.getEquilibriumConstants(Tlist, type='Ka') for i in range(len(Tlist)): self.assertAlmostEqual(Kalist[i] / Kalist0[i], 1.0, 4) def testEquilibriumConstantKc(self): """ Test the Reaction.getEquilibriumConstant() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) Kclist0 = [float(v) for v in ['1.45661e+28', '2.38935e+09', '1709.76', '1.74189', '0.0314866', '0.00235045', '0.000389568', '0.000105413', '3.93273e-05', '1.83006e-05']] Kclist = self.reaction2.getEquilibriumConstants(Tlist, type='Kc') for i in range(len(Tlist)): self.assertAlmostEqual(Kclist[i] / Kclist0[i], 1.0, 4) def testEquilibriumConstantKp(self): """ Test the Reaction.getEquilibriumConstant() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) Kplist0 = [float(v) for v in ['8.75951e+24', '718430', '0.342727', '0.000261877', '3.78696e-06', '2.35579e-07', '3.34673e-08', '7.92389e-09', '2.62777e-09', '1.10053e-09']] Kplist = self.reaction2.getEquilibriumConstants(Tlist, type='Kp') for i in range(len(Tlist)): self.assertAlmostEqual(Kplist[i] / Kplist0[i], 1.0, 4) def testStoichiometricCoefficient(self): """ Test the Reaction.getStoichiometricCoefficient() method. """ for reactant in self.reaction.reactants: self.assertEqual(self.reaction.getStoichiometricCoefficient(reactant), -1) for product in self.reaction.products: self.assertEqual(self.reaction.getStoichiometricCoefficient(product), 1) for reactant in self.reaction2.reactants: self.assertEqual(self.reaction.getStoichiometricCoefficient(reactant), 0) for product in self.reaction2.products: self.assertEqual(self.reaction.getStoichiometricCoefficient(product), 0) def testRateCoefficient(self): """ Test the Reaction.getRateCoefficient() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) P = 1e5 for T in Tlist: self.assertAlmostEqual(self.reaction.getRateCoefficient(T, P) / self.reaction.kinetics.getRateCoefficient(T), 1.0, 6) def testGenerateReverseRateCoefficient(self): """ Test the Reaction.generateReverseRateCoefficient() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) P = 1e5 reverseKinetics = self.reaction2.generateReverseRateCoefficient() for T in Tlist: kr0 = self.reaction2.getRateCoefficient(T, P) / self.reaction2.getEquilibriumConstant(T) kr = reverseKinetics.getRateCoefficient(T) self.assertAlmostEqual(kr0 / kr, 1.0, 0) def testGenerateReverseRateCoefficientArrhenius(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the Arrhenius format. """ original_kinetics = Arrhenius( A = (2.65e12, 'cm^3/(mols)'), n = 0.0, Ea = (0.0, 'kJ/mol'), T0 = (1, 'K'), Tmin = (300, 'K'), Tmax = (2000, 'K'), ) self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist = numpy.arange(original_kinetics.Tmin.value_si, original_kinetics.Tmax.value_si, 200.0, numpy.float64) P = 1e5 for T in Tlist: korig = original_kinetics.getRateCoefficient(T, P) krevrev = reversereverseKinetics.getRateCoefficient(T, P) self.assertAlmostEqual(korig / krevrev, 1.0, 0) @work_in_progress def testGenerateReverseRateCoefficientArrheniusEP(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the ArrheniusEP format. """ from rmgpy.kinetics import ArrheniusEP original_kinetics = ArrheniusEP( A = (2.65e12, 'cm^3/(mols)'), n = 0.0, alpha = 0.5, E0 = (41.84, 'kJ/mol'), Tmin = (300, 'K'), Tmax = (2000, 'K'), ) self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist = numpy.arange(original_kinetics.Tmin, original_kinetics.Tmax, 200.0, numpy.float64) P = 1e5 for T in Tlist: korig = original_kinetics.getRateCoefficient(T, P) krevrev = reversereverseKinetics.getRateCoefficient(T, P) self.assertAlmostEqual(korig / krevrev, 1.0, 0) def testGenerateReverseRateCoefficientPDepArrhenius(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the PDepArrhenius format. """ from rmgpy.kinetics import PDepArrhenius arrhenius0 = Arrhenius( A = (1.0e6,"s^-1"), n = 1.0, Ea = (10.0,"kJ/mol"), T0 = (300.0,"K"), Tmin = (300.0,"K"), Tmax = (2000.0,"K"), comment = """This data is completely made up""", ) arrhenius1 = Arrhenius( A = (1.0e12,"s^-1"), n = 1.0, Ea = (20.0,"kJ/mol"), T0 = (300.0,"K"), Tmin = (300.0,"K"), Tmax = (2000.0,"K"), comment = """This data is completely made up""", ) pressures = numpy.array([0.1, 10.0]) arrhenius = [arrhenius0, arrhenius1] Tmin = 300.0 Tmax = 2000.0 Pmin = 0.1 Pmax = 10.0 comment = """This data is completely made up""" original_kinetics = PDepArrhenius( pressures = (pressures,"bar"), arrhenius = arrhenius, Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), Pmin = (Pmin,"bar"), Pmax = (Pmax,"bar"), comment = comment, ) self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist = numpy.arange(Tmin, Tmax, 200.0, numpy.float64) P = 1e5 for T in Tlist: korig = original_kinetics.getRateCoefficient(T, P) krevrev = reversereverseKinetics.getRateCoefficient(T, P) self.assertAlmostEqual(korig / krevrev, 1.0, 0) def testGenerateReverseRateCoefficientMultiArrhenius(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the MultiArrhenius format. """ from rmgpy.kinetics import MultiArrhenius pressures = numpy.array([0.1, 10.0]) Tmin = 300.0 Tmax = 2000.0 Pmin = 0.1 Pmax = 10.0 comment = """This data is completely made up""" arrhenius = [ Arrhenius( A = (9.3e-14,"cm^3/(molecules)"), n = 0.0, Ea = (4740constants.R0.001,"kJ/mol"), T0 = (1,"K"), Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ), Arrhenius( A = (1.4e-9,"cm^3/(molecules)"), n = 0.0, Ea = (11200constants.R0.001,"kJ/mol"), T0 = (1,"K"), Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ), ] original_kinetics = MultiArrhenius( arrhenius = arrhenius, Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ) self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist = numpy.arange(Tmin, Tmax, 200.0, numpy.float64) P = 1e5 for T in Tlist: korig = original_kinetics.getRateCoefficient(T, P) krevrev = reversereverseKinetics.getRateCoefficient(T, P) self.assertAlmostEqual(korig / krevrev, 1.0, 0) def testGenerateReverseRateCoefficientMultiPDepArrhenius(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the MultiPDepArrhenius format. """ from rmgpy.kinetics import PDepArrhenius, MultiPDepArrhenius Tmin = 350. Tmax = 1500. Pmin = 1e-1 Pmax = 1e1 pressures = numpy.array([1e-1,1e1]) comment = 'CH3 + C2H6 <=> CH4 + C2H5 (Baulch 2005)' arrhenius = [ PDepArrhenius( pressures = (pressures,"bar"), arrhenius = [ Arrhenius( A = (9.3e-16,"cm^3/(molecules)"), n = 0.0, Ea = (4740constants.R0.001,"kJ/mol"), T0 = (1,"K"), Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ), Arrhenius( A = (9.3e-14,"cm^3/(molecules)"), n = 0.0, Ea = (4740constants.R0.001,"kJ/mol"), T0 = (1,"K"), Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ), ], Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), Pmin = (Pmin,"bar"), Pmax = (Pmax,"bar"), comment = comment, ), PDepArrhenius( pressures = (pressures,"bar"), arrhenius = [ Arrhenius( A = (1.4e-11,"cm^3/(molecules)"), n = 0.0, Ea = (11200constants.R0.001,"kJ/mol"), T0 = (1,"K"), Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ), Arrhenius( A = (1.4e-9,"cm^3/(molecules)"), n = 0.0, Ea = (11200constants.R0.001,"kJ/mol"), T0 = (1,"K"), Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ), ], Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), Pmin = (Pmin,"bar"), Pmax = (Pmax,"bar"), comment = comment, ), ] original_kinetics = MultiPDepArrhenius( arrhenius = arrhenius, Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), Pmin = (Pmin,"bar"), Pmax = (Pmax,"bar"), comment = comment, ) self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist = numpy.arange(Tmin, Tmax, 200.0, numpy.float64) P = 1e5 for T in Tlist: korig = original_kinetics.getRateCoefficient(T, P) krevrev = reversereverseKinetics.getRateCoefficient(T, P) self.assertAlmostEqual(korig / krevrev, 1.0, 0) def testGenerateReverseRateCoefficientThirdBody(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the ThirdBody format. """ from rmgpy.kinetics import ThirdBody arrheniusLow = Arrhenius( A = (2.62e+33,"cm^6/(mol^2s)"), n = -4.76, Ea = (10.21,"kJ/mol"), T0 = (1,"K"), ) efficiencies = {"C": 3, "C(=O)=O": 2, "CC": 3, "O": 6, "[Ar]": 0.7, "[C]=O": 1.5, "[H][H]": 2} Tmin = 300. Tmax = 2000. Pmin = 0.01 Pmax = 100. comment = """H + CH3 -> CH4""" thirdBody = ThirdBody( arrheniusLow = arrheniusLow, Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), Pmin = (Pmin,"bar"), Pmax = (Pmax,"bar"), efficiencies = efficiencies, comment = comment, ) original_kinetics = thirdBody self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist = numpy.arange(Tmin, Tmax, 200.0, numpy.float64) P = 1e5 for T in Tlist: korig = original_kinetics.getRateCoefficient(T, P) krevrev = reversereverseKinetics.getRateCoefficient(T, P) self.assertAlmostEqual(korig / krevrev, 1.0, 0) def testGenerateReverseRateCoefficientLindemann(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the Lindemann format. """ from rmgpy.kinetics import Lindemann arrheniusHigh = Arrhenius( A = (1.39e+16,"cm^3/(mols)"), n = -0.534, Ea = (2.243,"kJ/mol"), T0 = (1,"K"), ) arrheniusLow = Arrhenius( A = (2.62e+33,"cm^6/(mol^2*s)"), n = -4.76, Ea = (10.21,"kJ/mol"), T0 = (1,"K"), ) efficiencies = {"C": 3, "C(=O)=O": 2, "CC": 3, "O": 6, "[Ar]": 0.7, "[C]=O": 1.5, "[H][H]": 2} Tmin = 300. Tmax = 2000. Pmin = 0.01 Pmax = 100. comment = """H + CH3 -> CH4""" lindemann = Lindemann( arrheniusHigh = arrheniusHigh, arrheniusLow = arrheniusLow, Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), Pmin = (Pmin,"bar"), Pmax = (Pmax,"bar"), efficiencies = efficiencies, comment = comment, ) original_kinetics = lindemann self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist =	numpy.arange(Tmin, Tmax, 200.0, numpy.float64)	numpy.arange
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k') plt.plot(((time[-202] + time[-201]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed', label=textwrap.fill('Neural network targets', 13)) plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(((time_extended[-1001] + time_extended[-1000]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed') plt.xlim(3.4 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/neural_network.png') plt.show() # plot 6a np.random.seed(0) time = np.linspace(0, 5 * np.pi, 1001) knots_51 = np.linspace(0, 5 * np.pi, 51) time_series = np.cos(2 * time) + np.cos(4 * time) + np.cos(8 * time) noise = np.random.normal(0, 1, len(time_series)) time_series += noise advemdpy = EMD(time=time, time_series=time_series) imfs_51, hts_51, ifs_51 = advemdpy.empirical_mode_decomposition(knots=knots_51, max_imfs=3, edge_effect='symmetric_anchor', verbose=False)[:3] knots_31 = np.linspace(0, 5 * np.pi, 31) imfs_31, hts_31, ifs_31 = advemdpy.empirical_mode_decomposition(knots=knots_31, max_imfs=2, edge_effect='symmetric_anchor', verbose=False)[:3] knots_11 = np.linspace(0, 5 * np.pi, 11) imfs_11, hts_11, ifs_11 = advemdpy.empirical_mode_decomposition(knots=knots_11, max_imfs=1, edge_effect='symmetric_anchor', verbose=False)[:3] fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) print(f'DFA fluctuation with 51 knots: {np.round(np.var(time_series - (imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :])), 3)}') for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[0].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[0].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) print(f'DFA fluctuation with 31 knots: {np.round(np.var(time_series - (imfs_31[1, :] + imfs_31[2, :])), 3)}') for knot in knots_31: axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[1].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[1].set_xticklabels(['', '', '', '', '', '']) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) axs[1].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[1].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[1].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[1].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') axs[2].plot(time, time_series, label='Time series') axs[2].plot(time, imfs_11[1, :], label='IMF 1 with 11 knots') axs[2].plot(time, imfs_31[2, :], label='IMF 2 with 31 knots') axs[2].plot(time, imfs_51[3, :], label='IMF 3 with 51 knots') print(f'DFA fluctuation with 11 knots: {np.round(np.var(time_series - imfs_51[3, :]), 3)}') for knot in knots_11: axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[2].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[2].set_xticklabels(['$0$', r'$\pi$', r'$2\pi$', r'$3\pi$', r'$4\pi$', r'$5\pi$']) box_2 = axs[2].get_position() axs[2].set_position([box_2.x0 - 0.05, box_2.y0, box_2.width * 0.85, box_2.height]) axs[2].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[2].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[2].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[2].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[2].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') plt.savefig('jss_figures/DFA_different_trends.png') plt.show() # plot 6b fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences Zoomed Region', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[0].set_ylim(-5.5, 5.5) axs[0].set_xlim(0.95 * np.pi, 1.55 * np.pi) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) for knot in knots_31: axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[1].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[1].set_xticklabels(['', '', '', '', '', '']) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) axs[1].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].set_ylim(-5.5, 5.5) axs[1].set_xlim(0.95 * np.pi, 1.55 * np.pi) axs[2].plot(time, time_series, label='Time series') axs[2].plot(time, imfs_11[1, :], label='IMF 1 with 11 knots') axs[2].plot(time, imfs_31[2, :], label='IMF 2 with 31 knots') axs[2].plot(time, imfs_51[3, :], label='IMF 3 with 51 knots') for knot in knots_11: axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[2].set_xticks([np.pi, (3 / 2) * np.pi]) axs[2].set_xticklabels([r'$\pi$', r'$\frac{3}{2}\pi$']) box_2 = axs[2].get_position() axs[2].set_position([box_2.x0 - 0.05, box_2.y0, box_2.width * 0.85, box_2.height]) axs[2].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[2].set_ylim(-5.5, 5.5) axs[2].set_xlim(0.95 * np.pi, 1.55 * np.pi) plt.savefig('jss_figures/DFA_different_trends_zoomed.png') plt.show() hs_ouputs = hilbert_spectrum(time, imfs_51, hts_51, ifs_51, max_frequency=12, plot=False) # plot 6c ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Simple Sinusoidal Time Seres with Added Noise', 50)) x_hs, y, z = hs_ouputs z_min, z_max = 0, np.abs(z).max() ax.pcolormesh(x_hs, y, np.abs(z), cmap='gist_rainbow', vmin=z_min, vmax=z_max) ax.plot(x_hs[0, :], 8 * np.ones_like(x_hs[0, :]), '--', label=r'$\omega = 8$', Linewidth=3) ax.plot(x_hs[0, :], 4 * np.ones_like(x_hs[0, :]), '--', label=r'$\omega = 4$', Linewidth=3) ax.plot(x_hs[0, :], 2 * np.ones_like(x_hs[0, :]), '--', label=r'$\omega = 2$', Linewidth=3) ax.set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi]) ax.set_xticklabels(['$0$', r'$\pi$', r'$2\pi$', r'$3\pi$', r'$4\pi$']) plt.ylabel(r'Frequency (rad.s$^{-1}$)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.85, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/DFA_hilbert_spectrum.png') plt.show() # plot 6c time = np.linspace(0, 5 * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 51) fluc = Fluctuation(time=time, time_series=time_series) max_unsmoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='maxima', smooth=False) max_smoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='maxima', smooth=True) min_unsmoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='minima', smooth=False) min_smoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='minima', smooth=True) util = Utility(time=time, time_series=time_series) maxima = util.max_bool_func_1st_order_fd() minima = util.min_bool_func_1st_order_fd() ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title(textwrap.fill('Plot Demonstrating Unsmoothed Extrema Envelopes if Schoenberg–Whitney Conditions are Not Satisfied', 50)) plt.plot(time, time_series, label='Time series', zorder=2, LineWidth=2) plt.scatter(time[maxima], time_series[maxima], c='r', label='Maxima', zorder=10) plt.scatter(time[minima], time_series[minima], c='b', label='Minima', zorder=10) plt.plot(time, max_unsmoothed[0], label=textwrap.fill('Unsmoothed maxima envelope', 10), c='darkorange') plt.plot(time, max_smoothed[0], label=textwrap.fill('Smoothed maxima envelope', 10), c='red') plt.plot(time, min_unsmoothed[0], label=textwrap.fill('Unsmoothed minima envelope', 10), c='cyan') plt.plot(time, min_smoothed[0], label=textwrap.fill('Smoothed minima envelope', 10), c='blue') for knot in knots[:-1]: plt.plot(knot * np.ones(101), np.linspace(-3.0, -2.0, 101), '--', c='grey', zorder=1) plt.plot(knots[-1] * np.ones(101), np.linspace(-3.0, -2.0, 101), '--', c='grey', label='Knots', zorder=1) plt.xticks((0, 1 * np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi), (r'$0$', r'$\pi$', r'2$\pi$', r'3$\pi$', r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) plt.xlim(-0.25 * np.pi, 5.25 * np.pi) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Schoenberg_Whitney_Conditions.png') plt.show() # plot 7 a = 0.25 width = 0.2 time = np.linspace((0 + a) * np.pi, (5 - a) * np.pi, 1001) knots = np.linspace((0 + a) * np.pi, (5 - a) * np.pi, 11) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] inflection_bool = utils.inflection_point() inflection_x = time[inflection_bool] inflection_y = time_series[inflection_bool] fluctuation = emd_mean.Fluctuation(time=time, time_series=time_series) maxima_envelope = fluctuation.envelope_basis_function_approximation(knots, 'maxima', smooth=False, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] maxima_envelope_smooth = fluctuation.envelope_basis_function_approximation(knots, 'maxima', smooth=True, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] minima_envelope = fluctuation.envelope_basis_function_approximation(knots, 'minima', smooth=False, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] minima_envelope_smooth = fluctuation.envelope_basis_function_approximation(knots, 'minima', smooth=True, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] inflection_points_envelope = fluctuation.direct_detrended_fluctuation_estimation(knots, smooth=True, smoothing_penalty=0.2, technique='inflection_points')[0] binomial_points_envelope = fluctuation.direct_detrended_fluctuation_estimation(knots, smooth=True, smoothing_penalty=0.2, technique='binomial_average', order=21, increment=20)[0] derivative_of_lsq = utils.derivative_forward_diff() derivative_time = time[:-1] derivative_knots = np.linspace(knots[0], knots[-1], 31) # change (1) detrended_fluctuation_technique and (2) max_internal_iter and (3) debug (confusing with external debugging) emd = AdvEMDpy.EMD(time=derivative_time, time_series=derivative_of_lsq) imf_1_of_derivative = emd.empirical_mode_decomposition(knots=derivative_knots, knot_time=derivative_time, text=False, verbose=False)[0][1, :] utils = emd_utils.Utility(time=time[:-1], time_series=imf_1_of_derivative) optimal_maxima = np.r_[False, utils.derivative_forward_diff() < 0, False] & \ np.r_[utils.zero_crossing() == 1, False] optimal_minima = np.r_[False, utils.derivative_forward_diff() > 0, False] & \ np.r_[utils.zero_crossing() == 1, False] EEMD_maxima_envelope = fluctuation.envelope_basis_function_approximation_fixed_points(knots, 'maxima', optimal_maxima, optimal_minima, smooth=False, smoothing_penalty=0.2, edge_effect='none')[0] EEMD_minima_envelope = fluctuation.envelope_basis_function_approximation_fixed_points(knots, 'minima', optimal_maxima, optimal_minima, smooth=False, smoothing_penalty=0.2, edge_effect='none')[0] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Detrended Fluctuation Analysis Examples') plt.plot(time, time_series, LineWidth=2, label='Time series') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(time[optimal_maxima], time_series[optimal_maxima], c='darkred', zorder=4, label=textwrap.fill('Optimal maxima', 10)) plt.scatter(time[optimal_minima], time_series[optimal_minima], c='darkblue', zorder=4, label=textwrap.fill('Optimal minima', 10)) plt.scatter(inflection_x, inflection_y, c='magenta', zorder=4, label=textwrap.fill('Inflection points', 10)) plt.plot(time, maxima_envelope, c='darkblue', label=textwrap.fill('EMD envelope', 10)) plt.plot(time, minima_envelope, c='darkblue') plt.plot(time, (maxima_envelope + minima_envelope) / 2, c='darkblue') plt.plot(time, maxima_envelope_smooth, c='darkred', label=textwrap.fill('SEMD envelope', 10)) plt.plot(time, minima_envelope_smooth, c='darkred') plt.plot(time, (maxima_envelope_smooth + minima_envelope_smooth) / 2, c='darkred') plt.plot(time, EEMD_maxima_envelope, c='darkgreen', label=textwrap.fill('EEMD envelope', 10)) plt.plot(time, EEMD_minima_envelope, c='darkgreen') plt.plot(time, (EEMD_maxima_envelope + EEMD_minima_envelope) / 2, c='darkgreen') plt.plot(time, inflection_points_envelope, c='darkorange', label=textwrap.fill('Inflection point envelope', 10)) plt.plot(time, binomial_points_envelope, c='deeppink', label=textwrap.fill('Binomial average envelope', 10)) plt.plot(time, np.cos(time), c='black', label='True mean') plt.xticks((0, 1 * np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi), (r'$0$', r'$\pi$', r'2$\pi$', r'3$\pi$', r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) plt.xlim(-0.25 * np.pi, 5.25 * np.pi) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/detrended_fluctuation_analysis.png') plt.show() # Duffing Equation Example def duffing_equation(xy, ts): gamma = 0.1 epsilon = 1 omega = ((2 * np.pi) / 25) return [xy[1], xy[0] - epsilon * xy[0] ** 3 + gamma * np.cos(omega * ts)] t = np.linspace(0, 150, 1501) XY0 = [1, 1] solution = odeint(duffing_equation, XY0, t) x = solution[:, 0] dxdt = solution[:, 1] x_points = [0, 50, 100, 150] x_names = {0, 50, 100, 150} y_points_1 = [-2, 0, 2] y_points_2 = [-1, 0, 1] fig, axs = plt.subplots(2, 1) plt.subplots_adjust(hspace=0.2) axs[0].plot(t, x) axs[0].set_title('Duffing Equation Displacement') axs[0].set_ylim([-2, 2]) axs[0].set_xlim([0, 150]) axs[1].plot(t, dxdt) axs[1].set_title('Duffing Equation Velocity') axs[1].set_ylim([-1.5, 1.5]) axs[1].set_xlim([0, 150]) axis = 0 for ax in axs.flat: ax.label_outer() if axis == 0: ax.set_ylabel('x(t)') ax.set_yticks(y_points_1) if axis == 1: ax.set_ylabel(r'$ \dfrac{dx(t)}{dt} $') ax.set(xlabel='t') ax.set_yticks(y_points_2) ax.set_xticks(x_points) ax.set_xticklabels(x_names) axis += 1 plt.savefig('jss_figures/Duffing_equation.png') plt.show() # compare other packages Duffing - top pyemd = pyemd0215() py_emd = pyemd(x) IP, IF, IA = emd040.spectra.frequency_transform(py_emd.T, 10, 'hilbert') freq_edges, freq_bins = emd040.spectra.define_hist_bins(0, 0.2, 100) hht = emd040.spectra.hilberthuang(IF, IA, freq_edges) hht = gaussian_filter(hht, sigma=1) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 1.0 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Duffing Equation using PyEMD 0.2.10', 40)) plt.pcolormesh(t, freq_bins, hht, cmap='gist_rainbow', vmin=0, vmax=np.max(np.max(np.abs(hht)))) plt.plot(t[:-1], 0.124 * np.ones_like(t[:-1]), '--', label=textwrap.fill('Hamiltonian frequency approximation', 15)) plt.plot(t[:-1], 0.04 * np.ones_like(t[:-1]), 'g--', label=textwrap.fill('Driving function frequency', 15)) plt.xticks([0, 50, 100, 150]) plt.yticks([0, 0.1, 0.2]) plt.ylabel('Frequency (Hz)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.75, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Duffing_equation_ht_pyemd.png') plt.show() plt.show() emd_sift = emd040.sift.sift(x) IP, IF, IA = emd040.spectra.frequency_transform(emd_sift, 10, 'hilbert') freq_edges, freq_bins = emd040.spectra.define_hist_bins(0, 0.2, 100) hht = emd040.spectra.hilberthuang(IF, IA, freq_edges) hht = gaussian_filter(hht, sigma=1) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 1.0 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Duffing Equation using emd 0.3.3', 40)) plt.pcolormesh(t, freq_bins, hht, cmap='gist_rainbow', vmin=0, vmax=np.max(np.max(np.abs(hht)))) plt.plot(t[:-1], 0.124 * np.ones_like(t[:-1]), '--', label=textwrap.fill('Hamiltonian frequency approximation', 15)) plt.plot(t[:-1], 0.04 * np.ones_like(t[:-1]), 'g--', label=textwrap.fill('Driving function frequency', 15)) plt.xticks([0, 50, 100, 150]) plt.yticks([0, 0.1, 0.2]) plt.ylabel('Frequency (Hz)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.75, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Duffing_equation_ht_emd.png') plt.show() # compare other packages Duffing - bottom emd_duffing = AdvEMDpy.EMD(time=t, time_series=x) emd_duff, emd_ht_duff, emd_if_duff, _, _, _, _ = emd_duffing.empirical_mode_decomposition(verbose=False) fig, axs = plt.subplots(2, 1) plt.subplots_adjust(hspace=0.3) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) axs[0].plot(t, emd_duff[1, :], label='AdvEMDpy') axs[0].plot(t, py_emd[0, :], '--', label='PyEMD 0.2.10') axs[0].plot(t, emd_sift[:, 0], '--', label='emd 0.3.3') axs[0].set_title('IMF 1') axs[0].set_ylim([-2, 2]) axs[0].set_xlim([0, 150]) axs[1].plot(t, emd_duff[2, :], label='AdvEMDpy') print(f'AdvEMDpy driving function error: {np.round(sum(abs(0.1 * np.cos(0.04 * 2 * np.pi * t) - emd_duff[2, :])), 3)}') axs[1].plot(t, py_emd[1, :], '--', label='PyEMD 0.2.10') print(f'PyEMD driving function error: {np.round(sum(abs(0.1 * np.cos(0.04 * 2 * np.pi * t) - py_emd[1, :])), 3)}') axs[1].plot(t, emd_sift[:, 1], '--', label='emd 0.3.3') print(f'emd driving function error: {np.round(sum(abs(0.1 * np.cos(0.04 * 2 * np.pi * t) - emd_sift[:, 1])), 3)}') axs[1].plot(t, 0.1 *	np.cos(0.04 * 2 * np.pi * t)	numpy.cos
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101),	np.linspace(-2, 2, 101)	numpy.linspace
import os from PIL import Image import cv2 from os import listdir from os.path import join import matplotlib.pyplot as plt import matplotlib from matplotlib.colors import LogNorm from io_utils.io_common import create_folder from viz_utils.constants import PlotMode, BackgroundType import pylab import numpy as np import cmocean import shapely import cartopy.crs as ccrs import cartopy.feature as cfeature import cartopy def select_colormap(field_name): ''' Based on the name if the field it chooses a colormap from cmocean Args: field_name: Returns: ''' if np.any([field_name.find(x) != -1 for x in ('ssh', 'srfhgt', 'adt','surf_el')]): # cmaps_fields.append(cmocean.cm.deep_r) return cmocean.cm.curl elif np.any([field_name.find(x) != -1 for x in ('temp', 'sst', 'temperature')]): return cmocean.cm.thermal elif np.any([field_name.find(x) != -1 for x in ('vorticity', 'vort')]): return cmocean.cm.curl elif np.any([field_name.find(x) != -1 for x in ('salin', 'sss', 'sal')]): return cmocean.cm.haline elif field_name.find('error') != -1: return cmocean.cm.diff elif field_name.find('binary') != -1: return cmocean.cm.oxy elif np.any([field_name.find(x) != -1 for x in ('u_', 'v_', 'u-vel.', 'v-vel.','velocity')]): return cmocean.cm.speed class EOAImageVisualizer: """This class makes plenty of plots assuming we are plotting Geospatial data (maps). It is made to read xarrays, numpy arrays, and numpy arrays in dictionaries vizobj = new EOAImageVisualizer(disp_images=True, output_folder='output', lats=[lats],lons=[lons]) """ _COLORS = ['y', 'r', 'c', 'b', 'g', 'w', 'k', 'y', 'r', 'c', 'b', 'g', 'w', 'k'] _figsize = 8 _font_size = 30 _units = '' _max_imgs_per_row = 4 _mincbar = np.nan # User can set a min and max colorbar values to 'force' same color bar to all plots _maxcbar = np.nan _flip_data = True _eoas_pyutils_path = './eoas_pyutils'# This is the path where the eoas_utils folder is stored with respect to the main project _contourf = False # When plotting non-regular grids and need precision _background = BackgroundType.BLUE_MARBLE_LR # Select the background to use _auto_colormap = True # Selects the colormap based on the name of the field _show_var_names = False # Includes the name of the field name in the titles _additional_polygons = [] # MUST BE SHAPELY GEOMETRIES In case we want to include additional polygons in the plots (all of them) # If you want to add a streamplot of a vector field. It must be a dictionary with keys x,y,u,v # and optional density, color, cmap, arrowsize, arrowstyle, minlength _vector_field = None _norm = None # Use to normalize the colormap. For example with LogNorm # vizobj = EOAImageVisualizer(disp_images=True, output_folder='output', # lats=[lats],lons=[lons]) def __init__(self, disp_images=True, output_folder='output', lats=[-90,90], lons =[-180,180], projection=ccrs.PlateCarree(), *kwargs): # All the arguments that are passed to the constructor of the class MUST have its name on it. self._disp_images = disp_images self._output_folder = output_folder self._projection = projection bbox = self.getExtent(lats, lons) self._extent = bbox self._lats = lats self._lons = lons self._fig_prop = (bbox[1]-bbox[0])/(bbox[3]-bbox[2]) self._contour_labels = False for arg_name, arg_value in kwargs.items(): self.__dict__["_" + arg_name] = arg_value print(self.__dict__["_" + arg_name]) def __getattr__(self, attr): '''Generic getter for all the properties of the class''' return self.__dict__["_" + attr] def __setattr__(self, attr, value): '''Generic setter for all the properties of the class''' self.__dict__["_" + attr] = value def add_colorbar(self, fig, im, ax, show_color_bar, label=""): # https://matplotlib.org/api/_as_gen/matplotlib.pyplot.colorbar.html if show_color_bar: font_size_cbar = self._font_size .5 # TODO how to make this automatic and works always cbar = fig.colorbar(im, ax=ax, shrink=.7) cbar.ax.tick_params(labelsize=font_size_cbar) if label != "": cbar.set_label(label, fontsize=font_size_cbar1.2) else: cbar.set_label(self._units, fontsize=font_size_cbar1.2) def plot_slice_eoa(self, c_img, ax, cmap='gray', mode=PlotMode.RASTER, mincbar=np.nan, maxcbar=np.nan) -> None: """ Plots a 2D img for EOA data. :param c_img: 2D array :param ax: geoaxes :return: """ c_ax = ax if self._flip_data: origin = 'lower' else: origin = 'upper' if self._background == BackgroundType.CARTO_DEF: c_ax.stock_img() else: if self._background == BackgroundType.BLUE_MARBLE_LR: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/bluemarble.png')) if self._background == BackgroundType.BLUE_MARBLE_HR: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/bluemarble_5400x2700.jpg')) if self._background == BackgroundType.TOPO: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/etopo.png')) if self._background == BackgroundType.BATHYMETRY: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/bathymetry_3600x1800.jpg')) c_ax.imshow(img, origin='upper', extent=(-180,180,-90,90), transform=ccrs.PlateCarree()) if mode == PlotMode.RASTER or mode == PlotMode.MERGED: if self._contourf: im = c_ax.contourf(self._lons, self._lats, c_img, num_colors=255, cmap='inferno', extent=self._extent) else: if np.isnan(mincbar): im = c_ax.imshow(c_img, extent=self._extent, origin=origin, cmap=cmap, transform=self._projection, norm=self._norm) else: im = c_ax.imshow(c_img, extent=self._extent, origin=origin, cmap=cmap, vmin=mincbar, vmax=maxcbar, transform=self._projection, norm=self._norm) if mode == PlotMode.CONTOUR or mode == PlotMode.MERGED: c_ax.set_extent(self.getExtent(list(self._lats), list(self._lons))) if mode == PlotMode.CONTOUR: im = c_ax.contour(c_img, extent=self._extent, transform=self._projection) if mode == PlotMode.MERGED: if self._contour_labels: c_ax.contour(c_img, self._contour_labels, colors='r', extent=self._extent, transform=self._projection) else: c_ax.contour(c_img, extent=self._extent, transform=self._projection) if len(self._additional_polygons) > 0: pol_lats = [] pol_lons = [] for c_polygon in self._additional_polygons: if isinstance(c_polygon, shapely.geometry.linestring.LineString): x,y = c_polygon.xy elif isinstance(c_polygon, shapely.geometry.polygon.Polygon): x, y = c_polygon.exterior.xy pol_lats += y pol_lons += x c_ax.plot(x,y, transform=self._projection, c='r') # Adds a threshold to the plot to see the polygons c_ax.set_extent(self.getExtent(list(self._lats) + pol_lats, list(self._lons) + pol_lons, 0.5)) if self._vector_field != None: try: u = self._vector_field['u'] v = self._vector_field['v'] x = self._vector_field['x'] y = self._vector_field['y'] vec_keys = self._vector_field.keys() c = 'r' density = 1 linewidth = 3 vec_cmap = cmocean.cm.solar if 'color' in vec_keys: c = self._vector_field['color'] if 'density' in vec_keys: density = self._vector_field['density'] if 'linewidth' in vec_keys: linewidth = self._vector_field['linewidth'] if 'cmap' in vec_keys: vec_cmap = self._vector_field['cmap'] c_ax.set_extent(self.getExtent(list(self._lats), list(self._lons))) c_ax.streamplot(x, y, u, v, transform=self._projection, density=density, color=c, cmap=vec_cmap, linewidth=linewidth) except Exception as e: print(F"Couldn't add vector field e:{e}") gl = c_ax.gridlines(draw_labels=True, color='grey', alpha=0.5, linestyle='--') # gl.xlabel_style = {'size': self._font_size/2, 'color': '#aaaaaa', 'weight':'bold'} font_coords = {'size': self._font_size.6} gl.xlabel_style = font_coords gl.ylabel_style = font_coords gl.top_labels = False gl.right_labels = False return im def get_proper_size(self, rows, cols): """ Obtains the proper size for a figure. :param rows: how many rows will the figure have :param cols: how many colswill the figure have :param prop: Proportion is the proportion to use w/h :return: """ if rows == 1: return self._figsize cols * self._fig_prop, self._figsize else: return self._figsize * cols * self._fig_prop, self._figsize * rows def _close_figure(self): """Depending on what is disp_images, the figures are displayed or just closed""" if self._disp_images: plt.show() else: plt.close() def getExtent(self, lats, lons, expand_ext=0.0): ''' Obtains the bbox of the coordinates. If included threshold then increases the bbox in all directions with that thres Args: lats: lons: inc_threshold: Returns: ''' minLat = np.amin(lats) - expand_ext maxLat = np.amax(lats) + expand_ext minLon = np.amin(lons) - expand_ext maxLon = np.amax(lons) + expand_ext bbox = (minLon, maxLon, minLat, maxLat) return bbox def xr_summary(self, ds): """ Prints a summary of the netcdf (global attributes, variables, etc) :param ds: :return: """ print("\n========== Global attributes =========") for name in ds.attrs: print(F"{name} = {getattr(ds, name)}") print("\n========== Dimensions =========") for name in ds.dims: print(F"{name}: {ds[name].shape}") print("\n========== Coordinates =========") for name in ds.coords: print(F"{name}: {ds[name].shape}") print("\n========== Variables =========") for cur_variable_name in ds.variables: cur_var = ds[cur_variable_name] print(F"{cur_variable_name}: {cur_var.dims} {cur_var.shape}") def nc_summary(self, ds): """ Prints a summary of the netcdf (global attributes, variables, etc) :param ds: :return: """ print("\n========== Global attributes =========") for name in ds.ncattrs(): print(F"{name} = {getattr(ds, name)}") print("\n========== Variables =========") netCDFvars = ds.variables for cur_variable_name in netCDFvars.keys(): cur_var = ds.variables[cur_variable_name] print(F"Dimensions for {cur_variable_name}: {cur_var.dimensions} {cur_var.shape}") def add_roads(self, ax): # Names come from: https://www.naturalearthdata.com/features/ # -- Add states roads = cfeature.NaturalEarthFeature( category='cultural', name='roads', scale='10m', facecolor='none') ax.add_feature(roads, edgecolor='black') return ax def add_states(self, ax): # Names come from: https://www.naturalearthdata.com/features/ # -- Add states states_provinces = cfeature.NaturalEarthFeature( category='cultural', name='admin_1_states_provinces_lines', scale='50m', facecolor='none') ax.add_feature(states_provinces, edgecolor='gray') return ax def plot_scatter_data(self, lats=None, lons=None, bbox=None, s=1, c='blue', cmap='plasma', title=''): ''' This function plots points in a map :param bbox: :return: ''' if bbox is None: bbox = (-180, 180, -90, 90) if lats is None: lats = self.lats if lons is None: lons = self.lons fig, ax = plt.subplots(1, 1, figsize=(self._figsize, self._figsize), subplot_kw={'projection': ccrs.PlateCarree()}) ax.set_extent(bbox) # If we do not set this, it will cropp it to the limits of the locations ax.gridlines() im = ax.scatter(lons, lats, s=s, c=c, cmap=cmap) fig.colorbar(im, ax=ax, shrink=0.7) ax.coastlines() plt.title(title) plt.show() def plot_3d_data_npdict(self, np_variables:list, var_names:list, z_levels= [], title='', file_name_prefix='', cmap=None, z_names = [], show_color_bar=True, plot_mode=PlotMode.RASTER, mincbar=np.nan, maxcbar=np.nan): """ Plots multiple z_levels for multiple fields. It uses rows for each depth, and columns for each variable """ create_folder(self._output_folder) orig_cmap = cmap # If the user do not requires any z-leve, then all are plotted if len(z_levels) == 0: z_levels = range(np_variables[var_names[0]].shape[0]) cols = np.min((self._max_imgs_per_row, len(var_names))) if cols == len(var_names): rows = len(z_levels) else: rows = int(len(z_levels) * np.ceil(len(var_names)/cols)) fig, _axs = plt.subplots(rows, cols, figsize=self.get_proper_size(rows, cols), subplot_kw={'projection': self._projection}) for c_zlevel, c_slice in enumerate(z_levels): # Iterates over the z-levels # Verify the index of the z_levels are the original ones. if len(z_names) != 0: c_slice_txt = z_names[c_slice] else: c_slice_txt = c_slice c_mincbar = np.nan c_maxcbar = np.nan for idx_var, c_var in enumerate(var_names): # Iterate over the fields if rowscols == 1: # Single figure ax = _axs else: ax = _axs.flatten()[c_zlevellen(var_names) + idx_var] # Here we chose the min and max colorbars for each field if not(np.all(np.isnan(mincbar))): if type(mincbar) is list: c_mincbar = mincbar[idx_var] else: c_mincbar = mincbar if not(np.all(	np.isnan(maxcbar)	numpy.isnan
#!/usr/bin/env python # encoding: utf-8 import numbers import os import re import sys from itertools import chain import numpy as np import scipy.sparse as sp import six import pickle from .model import get_convo_nn2 from .stop_words import THAI_STOP_WORDS from .utils import CHAR_TYPES_MAP, CHARS_MAP, create_feature_array MODULE_PATH = os.path.dirname(__file__) WEIGHT_PATH = os.path.join(MODULE_PATH, 'weight', 'cnn_without_ne_ab.h5') TOKENIZER = None def tokenize(text, custom_dict=None): """ Tokenize given Thai text string Input ===== text: str, Thai text string custom_dict: str (or list), path to customized dictionary file It allows the function not to tokenize given dictionary wrongly. The file should contain custom words separated by line. Alternatively, you can provide list of custom words too. Output ====== tokens: list, list of tokenized words Example ======= >> deepcut.tokenize('ตัดคำได้ดีมาก') >> ['ตัดคำ','ได้','ดี','มาก'] """ global TOKENIZER if not TOKENIZER: TOKENIZER = DeepcutTokenizer() return TOKENIZER.tokenize(text, custom_dict=custom_dict) def _custom_dict(word, text, word_end): word_length = len(word) initial_loc = 0 while True: try: start_char = re.search(word, text).start() first_char = start_char + initial_loc last_char = first_char + word_length - 1 initial_loc += start_char + word_length text = text[start_char + word_length:] word_end[first_char:last_char] = (word_length - 1) * [0] word_end[last_char] = 1 except: break return word_end def _document_frequency(X): """ Count the number of non-zero values for each feature in sparse X. """ if sp.isspmatrix_csr(X): return	np.bincount(X.indices, minlength=X.shape[1])	numpy.bincount
# -- coding: utf-8 -- """ Created on Thu Nov 28 12:10:11 2019 @author: Omer """ ## File handler ## This file was initially intended purely to generate the matrices for the near earth code found in: https://public.ccsds.org/Pubs/131x1o2e2s.pdf ## The values from the above pdf were copied manually to a txt file, and it is the purpose of this file to parse it. ## The emphasis here is on correctness, I currently do not see a reason to generalise this file, since matrices will be saved in either json or some matrix friendly format. import numpy as np from scipy.linalg import circulant #import matplotlib.pyplot as plt import scipy.io import common import hashlib import os projectDir = os.environ.get('LDPC') if projectDir == None: import pathlib projectDir = pathlib.Path(__file__).parent.absolute() ## <NAME>: added on 01/12/2020, need to make sure this doesn't break anything. import sys sys.path.insert(1, projectDir) FILE_HANDLER_INT_DATA_TYPE = np.int32 GENERAL_CODE_MATRIX_DATA_TYPE = np.int32 NIBBLE_CONVERTER = np.array([8, 4, 2, 1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) def nibbleToHex(inputArray): n = NIBBLE_CONVERTER.dot(inputArray) if n == 10: h = 'A' elif n== 11: h = 'B' elif n== 12: h = 'C' elif n== 13: h = 'D' elif n== 14: h = 'E' elif n== 15: h = 'F' else: h = str(n) return h def binaryArraytoHex(inputArray): d1 = len(inputArray) assert (d1 % 4 == 0) outputArray =	np.zeros(d1//4, dtype = str)	numpy.zeros
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 =	np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101)	numpy.linspace
# -- coding: utf-8 -- """ Created on Thu Nov 28 12:10:11 2019 @author: Omer """ ## File handler ## This file was initially intended purely to generate the matrices for the near earth code found in: https://public.ccsds.org/Pubs/131x1o2e2s.pdf ## The values from the above pdf were copied manually to a txt file, and it is the purpose of this file to parse it. ## The emphasis here is on correctness, I currently do not see a reason to generalise this file, since matrices will be saved in either json or some matrix friendly format. import numpy as np from scipy.linalg import circulant #import matplotlib.pyplot as plt import scipy.io import common import hashlib import os projectDir = os.environ.get('LDPC') if projectDir == None: import pathlib projectDir = pathlib.Path(__file__).parent.absolute() ## <NAME>: added on 01/12/2020, need to make sure this doesn't break anything. import sys sys.path.insert(1, projectDir) FILE_HANDLER_INT_DATA_TYPE = np.int32 GENERAL_CODE_MATRIX_DATA_TYPE = np.int32 NIBBLE_CONVERTER = np.array([8, 4, 2, 1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) def nibbleToHex(inputArray): n = NIBBLE_CONVERTER.dot(inputArray) if n == 10: h = 'A' elif n== 11: h = 'B' elif n== 12: h = 'C' elif n== 13: h = 'D' elif n== 14: h = 'E' elif n== 15: h = 'F' else: h = str(n) return h def binaryArraytoHex(inputArray): d1 = len(inputArray) assert (d1 % 4 == 0) outputArray = np.zeros(d1//4, dtype = str) outputString = '' for j in range(d1//4): nibble = inputArray[4 * j : 4 * j + 4] h = nibbleToHex(nibble) outputArray[j] = h outputString = outputString + h return outputArray, outputString def hexStringToBinaryArray(hexString): outputBinary = np.array([], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) for i in hexString: if i == '0': nibble = np.array([0,0,0,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '1': nibble = np.array([0,0,0,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '2': nibble = np.array([0,0,1,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '3': nibble = np.array([0,0,1,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '4': nibble = np.array([0,1,0,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '5': nibble = np.array([0,1,0,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '6': nibble =	np.array([0,1,1,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE)	numpy.array
"""Routines for numerical differentiation.""" from __future__ import division import numpy as np from numpy.linalg import norm from scipy.sparse.linalg import LinearOperator from ..sparse import issparse, csc_matrix, csr_matrix, coo_matrix, find from ._group_columns import group_dense, group_sparse EPS = np.finfo(np.float64).eps def _adjust_scheme_to_bounds(x0, h, num_steps, scheme, lb, ub): """Adjust final difference scheme to the presence of bounds. Parameters ---------- x0 : ndarray, shape (n,) Point at which we wish to estimate derivative. h : ndarray, shape (n,) Desired finite difference steps. num_steps : int Number of `h` steps in one direction required to implement finite difference scheme. For example, 2 means that we need to evaluate f(x0 + 2 * h) or f(x0 - 2 * h) scheme : {'1-sided', '2-sided'} Whether steps in one or both directions are required. In other words '1-sided' applies to forward and backward schemes, '2-sided' applies to center schemes. lb : ndarray, shape (n,) Lower bounds on independent variables. ub : ndarray, shape (n,) Upper bounds on independent variables. Returns ------- h_adjusted : ndarray, shape (n,) Adjusted step sizes. Step size decreases only if a sign flip or switching to one-sided scheme doesn't allow to take a full step. use_one_sided : ndarray of bool, shape (n,) Whether to switch to one-sided scheme. Informative only for ``scheme='2-sided'``. """ if scheme == '1-sided': use_one_sided = np.ones_like(h, dtype=bool) elif scheme == '2-sided': h = np.abs(h) use_one_sided = np.zeros_like(h, dtype=bool) else: raise ValueError("`scheme` must be '1-sided' or '2-sided'.") if np.all((lb == -np.inf) & (ub == np.inf)): return h, use_one_sided h_total = h * num_steps h_adjusted = h.copy() lower_dist = x0 - lb upper_dist = ub - x0 if scheme == '1-sided': x = x0 + h_total violated = (x < lb) \| (x > ub) fitting = np.abs(h_total) <= np.maximum(lower_dist, upper_dist) h_adjusted[violated & fitting] = -1 forward = (upper_dist >= lower_dist) & ~fitting h_adjusted[forward] = upper_dist[forward] / num_steps backward = (upper_dist < lower_dist) & ~fitting h_adjusted[backward] = -lower_dist[backward] / num_steps elif scheme == '2-sided': central = (lower_dist >= h_total) & (upper_dist >= h_total) forward = (upper_dist >= lower_dist) & ~central h_adjusted[forward] = np.minimum( h[forward], 0.5 upper_dist[forward] / num_steps) use_one_sided[forward] = True backward = (upper_dist < lower_dist) & ~central h_adjusted[backward] = -np.minimum( h[backward], 0.5 * lower_dist[backward] / num_steps) use_one_sided[backward] = True min_dist = np.minimum(upper_dist, lower_dist) / num_steps adjusted_central = (~central & (np.abs(h_adjusted) <= min_dist)) h_adjusted[adjusted_central] = min_dist[adjusted_central] use_one_sided[adjusted_central] = False return h_adjusted, use_one_sided relative_step = {"2-point": EPS0.5, "3-point": EPS(1/3), "cs": EPS*0.5} def _compute_absolute_step(rel_step, x0, method): if rel_step is None: rel_step = relative_step[method] sign_x0 = (x0 >= 0).astype(float) 2 - 1 return rel_step * sign_x0 * np.maximum(1.0, np.abs(x0)) def _prepare_bounds(bounds, x0): lb, ub = [np.asarray(b, dtype=float) for b in bounds] if lb.ndim == 0: lb = np.resize(lb, x0.shape) if ub.ndim == 0: ub = np.resize(ub, x0.shape) return lb, ub def group_columns(A, order=0): """Group columns of a 2-D matrix for sparse finite differencing [1]_. Two columns are in the same group if in each row at least one of them has zero. A greedy sequential algorithm is used to construct groups. Parameters ---------- A : array_like or sparse matrix, shape (m, n) Matrix of which to group columns. order : int, iterable of int with shape (n,) or None Permutation array which defines the order of columns enumeration. If int or None, a random permutation is used with `order` used as a random seed. Default is 0, that is use a random permutation but guarantee repeatability. Returns ------- groups : ndarray of int, shape (n,) Contains values from 0 to n_groups-1, where n_groups is the number of found groups. Each value ``groups[i]`` is an index of a group to which ith column assigned. The procedure was helpful only if n_groups is significantly less than n. References ---------- .. [1] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. """ if issparse(A): A = csc_matrix(A) else: A = np.atleast_2d(A) A = (A != 0).astype(np.int32) if A.ndim != 2: raise ValueError("`A` must be 2-dimensional.") m, n = A.shape if order is None or np.isscalar(order): rng = np.random.RandomState(order) order = rng.permutation(n) else: order = np.asarray(order) if order.shape != (n,): raise ValueError("`order` has incorrect shape.") A = A[:, order] if issparse(A): groups = group_sparse(m, n, A.indices, A.indptr) else: groups = group_dense(m, n, A) groups[order] = groups.copy() return groups def approx_derivative(fun, x0, method='3-point', rel_step=None, f0=None, bounds=(-np.inf, np.inf), sparsity=None, as_linear_operator=False, args=(), kwargs={}): """Compute finite difference approximation of the derivatives of a vector-valued function. If a function maps from R^n to R^m, its derivatives form m-by-n matrix called the Jacobian, where an element (i, j) is a partial derivative of f[i] with respect to x[j]. Parameters ---------- fun : callable Function of which to estimate the derivatives. The argument x passed to this function is ndarray of shape (n,) (never a scalar even if n=1). It must return 1-D array_like of shape (m,) or a scalar. x0 : array_like of shape (n,) or float Point at which to estimate the derivatives. Float will be converted to a 1-D array. method : {'3-point', '2-point', 'cs'}, optional Finite difference method to use: - '2-point' - use the first order accuracy forward or backward difference. - '3-point' - use central difference in interior points and the second order accuracy forward or backward difference near the boundary. - 'cs' - use a complex-step finite difference scheme. This assumes that the user function is real-valued and can be analytically continued to the complex plane. Otherwise, produces bogus results. rel_step : None or array_like, optional Relative step size to use. The absolute step size is computed as ``h = rel_step * sign(x0) * max(1, abs(x0))``, possibly adjusted to fit into the bounds. For ``method='3-point'`` the sign of `h` is ignored. If None (default) then step is selected automatically, see Notes. f0 : None or array_like, optional If not None it is assumed to be equal to ``fun(x0)``, in this case the ``fun(x0)`` is not called. Default is None. bounds : tuple of array_like, optional Lower and upper bounds on independent variables. Defaults to no bounds. Each bound must match the size of `x0` or be a scalar, in the latter case the bound will be the same for all variables. Use it to limit the range of function evaluation. Bounds checking is not implemented when `as_linear_operator` is True. sparsity : {None, array_like, sparse matrix, 2-tuple}, optional Defines a sparsity structure of the Jacobian matrix. If the Jacobian matrix is known to have only few non-zero elements in each row, then it's possible to estimate its several columns by a single function evaluation [3]_. To perform such economic computations two ingredients are required: * structure : array_like or sparse matrix of shape (m, n). A zero element means that a corresponding element of the Jacobian identically equals to zero. * groups : array_like of shape (n,). A column grouping for a given sparsity structure, use `group_columns` to obtain it. A single array or a sparse matrix is interpreted as a sparsity structure, and groups are computed inside the function. A tuple is interpreted as (structure, groups). If None (default), a standard dense differencing will be used. Note, that sparse differencing makes sense only for large Jacobian matrices where each row contains few non-zero elements. as_linear_operator : bool, optional When True the function returns an `scipy.sparse.linalg.LinearOperator`. Otherwise it returns a dense array or a sparse matrix depending on `sparsity`. The linear operator provides an efficient way of computing ``J.dot(p)`` for any vector ``p`` of shape (n,), but does not allow direct access to individual elements of the matrix. By default `as_linear_operator` is False. args, kwargs : tuple and dict, optional Additional arguments passed to `fun`. Both empty by default. The calling signature is ``fun(x, args, kwargs)``. Returns ------- J : {ndarray, sparse matrix, LinearOperator} Finite difference approximation of the Jacobian matrix. If `as_linear_operator` is True returns a LinearOperator with shape (m, n). Otherwise it returns a dense array or sparse matrix depending on how `sparsity` is defined. If `sparsity` is None then a ndarray with shape (m, n) is returned. If `sparsity` is not None returns a csr_matrix with shape (m, n). For sparse matrices and linear operators it is always returned as a 2-D structure, for ndarrays, if m=1 it is returned as a 1-D gradient array with shape (n,). See Also -------- check_derivative : Check correctness of a function computing derivatives. Notes ----- If `rel_step` is not provided, it assigned to ``EPS(1/s)``, where EPS is machine epsilon for float64 numbers, s=2 for '2-point' method and s=3 for '3-point' method. Such relative step approximately minimizes a sum of truncation and round-off errors, see [1]_. A finite difference scheme for '3-point' method is selected automatically. The well-known central difference scheme is used for points sufficiently far from the boundary, and 3-point forward or backward scheme is used for points near the boundary. Both schemes have the second-order accuracy in terms of Taylor expansion. Refer to [2]_ for the formulas of 3-point forward and backward difference schemes. For dense differencing when m=1 Jacobian is returned with a shape (n,), on the other hand when n=1 Jacobian is returned with a shape (m, 1). Our motivation is the following: a) It handles a case of gradient computation (m=1) in a conventional way. b) It clearly separates these two different cases. b) In all cases np.atleast_2d can be called to get 2-D Jacobian with correct dimensions. References ---------- .. [1] W. H. Press et. al. "Numerical Recipes. The Art of Scientific Computing. 3rd edition", sec. 5.7. .. [2] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. .. [3] <NAME>, "Generation of Finite Difference Formulas on Arbitrarily Spaced Grids", Mathematics of Computation 51, 1988. Examples -------- >>> import numpy as np >>> from scipy.optimize import approx_derivative >>> >>> def f(x, c1, c2): ... return np.array([x[0] np.sin(c1 * x[1]), ... x[0] * np.cos(c2 * x[1])]) ... >>> x0 = np.array([1.0, 0.5 * np.pi]) >>> approx_derivative(f, x0, args=(1, 2)) array([[ 1., 0.], [-1., 0.]]) Bounds can be used to limit the region of function evaluation. In the example below we compute left and right derivative at point 1.0. >>> def g(x): ... return x*2 if x >= 1 else x ... >>> x0 = 1.0 >>> approx_derivative(g, x0, bounds=(-np.inf, 1.0)) array([ 1.]) >>> approx_derivative(g, x0, bounds=(1.0, np.inf)) array([ 2.]) """ if method not in ['2-point', '3-point', 'cs']: raise ValueError("Unknown method '%s'. " % method) x0 = np.atleast_1d(x0) if x0.ndim > 1: raise ValueError("`x0` must have at most 1 dimension.") lb, ub = _prepare_bounds(bounds, x0) if lb.shape != x0.shape or ub.shape != x0.shape: raise ValueError("Inconsistent shapes between bounds and `x0`.") if as_linear_operator and not (np.all(np.isinf(lb)) and np.all(np.isinf(ub))): raise ValueError("Bounds not supported when " "`as_linear_operator` is True.") def fun_wrapped(x): f = np.atleast_1d(fun(x, args, **kwargs)) if f.ndim > 1: raise RuntimeError("`fun` return value has " "more than 1 dimension.") return f if f0 is None: f0 = fun_wrapped(x0) else: f0 = np.atleast_1d(f0) if f0.ndim > 1: raise ValueError("`f0` passed has more than 1 dimension.") if np.any((x0 < lb) \| (x0 > ub)): raise ValueError("`x0` violates bound constraints.") if as_linear_operator: if rel_step is None: rel_step = relative_step[method] return _linear_operator_difference(fun_wrapped, x0, f0, rel_step, method) else: h = _compute_absolute_step(rel_step, x0, method) if method == '2-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '1-sided', lb, ub) elif method == '3-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '2-sided', lb, ub) elif method == 'cs': use_one_sided = False if sparsity is None: return _dense_difference(fun_wrapped, x0, f0, h, use_one_sided, method) else: if not issparse(sparsity) and len(sparsity) == 2: structure, groups = sparsity else: structure = sparsity groups = group_columns(sparsity) if issparse(structure): structure = csc_matrix(structure) else: structure = np.atleast_2d(structure) groups = np.atleast_1d(groups) return _sparse_difference(fun_wrapped, x0, f0, h, use_one_sided, structure, groups, method) def _linear_operator_difference(fun, x0, f0, h, method): m = f0.size n = x0.size if method == '2-point': def matvec(p): if np.array_equal(p,	np.zeros_like(p)	numpy.zeros_like
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k') plt.plot(((time[-202] + time[-201]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed', label=textwrap.fill('Neural network targets', 13)) plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(((time_extended[-1001] + time_extended[-1000]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed') plt.xlim(3.4 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/neural_network.png') plt.show() # plot 6a np.random.seed(0) time = np.linspace(0, 5 * np.pi, 1001) knots_51 = np.linspace(0, 5 * np.pi, 51) time_series = np.cos(2 * time) + np.cos(4 * time) + np.cos(8 * time) noise = np.random.normal(0, 1, len(time_series)) time_series += noise advemdpy = EMD(time=time, time_series=time_series) imfs_51, hts_51, ifs_51 = advemdpy.empirical_mode_decomposition(knots=knots_51, max_imfs=3, edge_effect='symmetric_anchor', verbose=False)[:3] knots_31 = np.linspace(0, 5 * np.pi, 31) imfs_31, hts_31, ifs_31 = advemdpy.empirical_mode_decomposition(knots=knots_31, max_imfs=2, edge_effect='symmetric_anchor', verbose=False)[:3] knots_11 = np.linspace(0, 5 * np.pi, 11) imfs_11, hts_11, ifs_11 = advemdpy.empirical_mode_decomposition(knots=knots_11, max_imfs=1, edge_effect='symmetric_anchor', verbose=False)[:3] fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) print(f'DFA fluctuation with 51 knots: {np.round(np.var(time_series - (imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :])), 3)}') for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[0].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[0].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) print(f'DFA fluctuation with 31 knots: {np.round(np.var(time_series - (imfs_31[1, :] + imfs_31[2, :])), 3)}') for knot in knots_31: axs[1].plot(knot * np.ones(101),	np.linspace(-5, 5, 101)	numpy.linspace
"""Routines for numerical differentiation.""" from __future__ import division import numpy as np from numpy.linalg import norm from scipy.sparse.linalg import LinearOperator from ..sparse import issparse, csc_matrix, csr_matrix, coo_matrix, find from ._group_columns import group_dense, group_sparse EPS = np.finfo(np.float64).eps def _adjust_scheme_to_bounds(x0, h, num_steps, scheme, lb, ub): """Adjust final difference scheme to the presence of bounds. Parameters ---------- x0 : ndarray, shape (n,) Point at which we wish to estimate derivative. h : ndarray, shape (n,) Desired finite difference steps. num_steps : int Number of `h` steps in one direction required to implement finite difference scheme. For example, 2 means that we need to evaluate f(x0 + 2 * h) or f(x0 - 2 * h) scheme : {'1-sided', '2-sided'} Whether steps in one or both directions are required. In other words '1-sided' applies to forward and backward schemes, '2-sided' applies to center schemes. lb : ndarray, shape (n,) Lower bounds on independent variables. ub : ndarray, shape (n,) Upper bounds on independent variables. Returns ------- h_adjusted : ndarray, shape (n,) Adjusted step sizes. Step size decreases only if a sign flip or switching to one-sided scheme doesn't allow to take a full step. use_one_sided : ndarray of bool, shape (n,) Whether to switch to one-sided scheme. Informative only for ``scheme='2-sided'``. """ if scheme == '1-sided': use_one_sided = np.ones_like(h, dtype=bool) elif scheme == '2-sided': h = np.abs(h) use_one_sided = np.zeros_like(h, dtype=bool) else: raise ValueError("`scheme` must be '1-sided' or '2-sided'.") if np.all((lb == -np.inf) & (ub == np.inf)): return h, use_one_sided h_total = h * num_steps h_adjusted = h.copy() lower_dist = x0 - lb upper_dist = ub - x0 if scheme == '1-sided': x = x0 + h_total violated = (x < lb) \| (x > ub) fitting = np.abs(h_total) <= np.maximum(lower_dist, upper_dist) h_adjusted[violated & fitting] = -1 forward = (upper_dist >= lower_dist) & ~fitting h_adjusted[forward] = upper_dist[forward] / num_steps backward = (upper_dist < lower_dist) & ~fitting h_adjusted[backward] = -lower_dist[backward] / num_steps elif scheme == '2-sided': central = (lower_dist >= h_total) & (upper_dist >= h_total) forward = (upper_dist >= lower_dist) & ~central h_adjusted[forward] = np.minimum( h[forward], 0.5 upper_dist[forward] / num_steps) use_one_sided[forward] = True backward = (upper_dist < lower_dist) & ~central h_adjusted[backward] = -np.minimum( h[backward], 0.5 * lower_dist[backward] / num_steps) use_one_sided[backward] = True min_dist = np.minimum(upper_dist, lower_dist) / num_steps adjusted_central = (~central & (np.abs(h_adjusted) <= min_dist)) h_adjusted[adjusted_central] = min_dist[adjusted_central] use_one_sided[adjusted_central] = False return h_adjusted, use_one_sided relative_step = {"2-point": EPS0.5, "3-point": EPS(1/3), "cs": EPS*0.5} def _compute_absolute_step(rel_step, x0, method): if rel_step is None: rel_step = relative_step[method] sign_x0 = (x0 >= 0).astype(float) 2 - 1 return rel_step * sign_x0 * np.maximum(1.0, np.abs(x0)) def _prepare_bounds(bounds, x0): lb, ub = [np.asarray(b, dtype=float) for b in bounds] if lb.ndim == 0: lb = np.resize(lb, x0.shape) if ub.ndim == 0: ub = np.resize(ub, x0.shape) return lb, ub def group_columns(A, order=0): """Group columns of a 2-D matrix for sparse finite differencing [1]_. Two columns are in the same group if in each row at least one of them has zero. A greedy sequential algorithm is used to construct groups. Parameters ---------- A : array_like or sparse matrix, shape (m, n) Matrix of which to group columns. order : int, iterable of int with shape (n,) or None Permutation array which defines the order of columns enumeration. If int or None, a random permutation is used with `order` used as a random seed. Default is 0, that is use a random permutation but guarantee repeatability. Returns ------- groups : ndarray of int, shape (n,) Contains values from 0 to n_groups-1, where n_groups is the number of found groups. Each value ``groups[i]`` is an index of a group to which ith column assigned. The procedure was helpful only if n_groups is significantly less than n. References ---------- .. [1] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. """ if issparse(A): A = csc_matrix(A) else: A = np.atleast_2d(A) A = (A != 0).astype(np.int32) if A.ndim != 2: raise ValueError("`A` must be 2-dimensional.") m, n = A.shape if order is None or np.isscalar(order): rng = np.random.RandomState(order) order = rng.permutation(n) else: order = np.asarray(order) if order.shape != (n,): raise ValueError("`order` has incorrect shape.") A = A[:, order] if issparse(A): groups = group_sparse(m, n, A.indices, A.indptr) else: groups = group_dense(m, n, A) groups[order] = groups.copy() return groups def approx_derivative(fun, x0, method='3-point', rel_step=None, f0=None, bounds=(-np.inf, np.inf), sparsity=None, as_linear_operator=False, args=(), kwargs={}): """Compute finite difference approximation of the derivatives of a vector-valued function. If a function maps from R^n to R^m, its derivatives form m-by-n matrix called the Jacobian, where an element (i, j) is a partial derivative of f[i] with respect to x[j]. Parameters ---------- fun : callable Function of which to estimate the derivatives. The argument x passed to this function is ndarray of shape (n,) (never a scalar even if n=1). It must return 1-D array_like of shape (m,) or a scalar. x0 : array_like of shape (n,) or float Point at which to estimate the derivatives. Float will be converted to a 1-D array. method : {'3-point', '2-point', 'cs'}, optional Finite difference method to use: - '2-point' - use the first order accuracy forward or backward difference. - '3-point' - use central difference in interior points and the second order accuracy forward or backward difference near the boundary. - 'cs' - use a complex-step finite difference scheme. This assumes that the user function is real-valued and can be analytically continued to the complex plane. Otherwise, produces bogus results. rel_step : None or array_like, optional Relative step size to use. The absolute step size is computed as ``h = rel_step * sign(x0) * max(1, abs(x0))``, possibly adjusted to fit into the bounds. For ``method='3-point'`` the sign of `h` is ignored. If None (default) then step is selected automatically, see Notes. f0 : None or array_like, optional If not None it is assumed to be equal to ``fun(x0)``, in this case the ``fun(x0)`` is not called. Default is None. bounds : tuple of array_like, optional Lower and upper bounds on independent variables. Defaults to no bounds. Each bound must match the size of `x0` or be a scalar, in the latter case the bound will be the same for all variables. Use it to limit the range of function evaluation. Bounds checking is not implemented when `as_linear_operator` is True. sparsity : {None, array_like, sparse matrix, 2-tuple}, optional Defines a sparsity structure of the Jacobian matrix. If the Jacobian matrix is known to have only few non-zero elements in each row, then it's possible to estimate its several columns by a single function evaluation [3]_. To perform such economic computations two ingredients are required: * structure : array_like or sparse matrix of shape (m, n). A zero element means that a corresponding element of the Jacobian identically equals to zero. * groups : array_like of shape (n,). A column grouping for a given sparsity structure, use `group_columns` to obtain it. A single array or a sparse matrix is interpreted as a sparsity structure, and groups are computed inside the function. A tuple is interpreted as (structure, groups). If None (default), a standard dense differencing will be used. Note, that sparse differencing makes sense only for large Jacobian matrices where each row contains few non-zero elements. as_linear_operator : bool, optional When True the function returns an `scipy.sparse.linalg.LinearOperator`. Otherwise it returns a dense array or a sparse matrix depending on `sparsity`. The linear operator provides an efficient way of computing ``J.dot(p)`` for any vector ``p`` of shape (n,), but does not allow direct access to individual elements of the matrix. By default `as_linear_operator` is False. args, kwargs : tuple and dict, optional Additional arguments passed to `fun`. Both empty by default. The calling signature is ``fun(x, args, kwargs)``. Returns ------- J : {ndarray, sparse matrix, LinearOperator} Finite difference approximation of the Jacobian matrix. If `as_linear_operator` is True returns a LinearOperator with shape (m, n). Otherwise it returns a dense array or sparse matrix depending on how `sparsity` is defined. If `sparsity` is None then a ndarray with shape (m, n) is returned. If `sparsity` is not None returns a csr_matrix with shape (m, n). For sparse matrices and linear operators it is always returned as a 2-D structure, for ndarrays, if m=1 it is returned as a 1-D gradient array with shape (n,). See Also -------- check_derivative : Check correctness of a function computing derivatives. Notes ----- If `rel_step` is not provided, it assigned to ``EPS(1/s)``, where EPS is machine epsilon for float64 numbers, s=2 for '2-point' method and s=3 for '3-point' method. Such relative step approximately minimizes a sum of truncation and round-off errors, see [1]_. A finite difference scheme for '3-point' method is selected automatically. The well-known central difference scheme is used for points sufficiently far from the boundary, and 3-point forward or backward scheme is used for points near the boundary. Both schemes have the second-order accuracy in terms of Taylor expansion. Refer to [2]_ for the formulas of 3-point forward and backward difference schemes. For dense differencing when m=1 Jacobian is returned with a shape (n,), on the other hand when n=1 Jacobian is returned with a shape (m, 1). Our motivation is the following: a) It handles a case of gradient computation (m=1) in a conventional way. b) It clearly separates these two different cases. b) In all cases np.atleast_2d can be called to get 2-D Jacobian with correct dimensions. References ---------- .. [1] W. H. Press et. al. "Numerical Recipes. The Art of Scientific Computing. 3rd edition", sec. 5.7. .. [2] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. .. [3] <NAME>, "Generation of Finite Difference Formulas on Arbitrarily Spaced Grids", Mathematics of Computation 51, 1988. Examples -------- >>> import numpy as np >>> from scipy.optimize import approx_derivative >>> >>> def f(x, c1, c2): ... return np.array([x[0] np.sin(c1 * x[1]), ... x[0] * np.cos(c2 * x[1])]) ... >>> x0 = np.array([1.0, 0.5 * np.pi]) >>> approx_derivative(f, x0, args=(1, 2)) array([[ 1., 0.], [-1., 0.]]) Bounds can be used to limit the region of function evaluation. In the example below we compute left and right derivative at point 1.0. >>> def g(x): ... return x*2 if x >= 1 else x ... >>> x0 = 1.0 >>> approx_derivative(g, x0, bounds=(-np.inf, 1.0)) array([ 1.]) >>> approx_derivative(g, x0, bounds=(1.0, np.inf)) array([ 2.]) """ if method not in ['2-point', '3-point', 'cs']: raise ValueError("Unknown method '%s'. " % method) x0 = np.atleast_1d(x0) if x0.ndim > 1: raise ValueError("`x0` must have at most 1 dimension.") lb, ub = _prepare_bounds(bounds, x0) if lb.shape != x0.shape or ub.shape != x0.shape: raise ValueError("Inconsistent shapes between bounds and `x0`.") if as_linear_operator and not (np.all(np.isinf(lb)) and np.all(np.isinf(ub))): raise ValueError("Bounds not supported when " "`as_linear_operator` is True.") def fun_wrapped(x): f = np.atleast_1d(fun(x, args, *kwargs)) if f.ndim > 1: raise RuntimeError("`fun` return value has " "more than 1 dimension.") return f if f0 is None: f0 = fun_wrapped(x0) else: f0 = np.atleast_1d(f0) if f0.ndim > 1: raise ValueError("`f0` passed has more than 1 dimension.") if np.any((x0 < lb) \| (x0 > ub)): raise ValueError("`x0` violates bound constraints.") if as_linear_operator: if rel_step is None: rel_step = relative_step[method] return _linear_operator_difference(fun_wrapped, x0, f0, rel_step, method) else: h = _compute_absolute_step(rel_step, x0, method) if method == '2-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '1-sided', lb, ub) elif method == '3-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '2-sided', lb, ub) elif method == 'cs': use_one_sided = False if sparsity is None: return _dense_difference(fun_wrapped, x0, f0, h, use_one_sided, method) else: if not issparse(sparsity) and len(sparsity) == 2: structure, groups = sparsity else: structure = sparsity groups = group_columns(sparsity) if issparse(structure): structure = csc_matrix(structure) else: structure = np.atleast_2d(structure) groups = np.atleast_1d(groups) return _sparse_difference(fun_wrapped, x0, f0, h, use_one_sided, structure, groups, method) def _linear_operator_difference(fun, x0, f0, h, method): m = f0.size n = x0.size if method == '2-point': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return np.zeros(m) dx = h / norm(p) x = x0 + dxp df = fun(x) - f0 return df / dx elif method == '3-point': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return np.zeros(m) dx = 2h / norm(p) x1 = x0 - (dx/2)p x2 = x0 + (dx/2)p f1 = fun(x1) f2 = fun(x2) df = f2 - f1 return df / dx elif method == 'cs': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return np.zeros(m) dx = h / norm(p) x = x0 + dxp1.j f1 = fun(x) df = f1.imag return df / dx else: raise RuntimeError("Never be here.") return LinearOperator((m, n), matvec) def _dense_difference(fun, x0, f0, h, use_one_sided, method): m = f0.size n = x0.size J_transposed = np.empty((n, m)) h_vecs = np.diag(h) for i in range(h.size): if method == '2-point': x = x0 + h_vecs[i] dx = x[i] - x0[i] # Recompute dx as exactly representable number. df = fun(x) - f0 elif method == '3-point' and use_one_sided[i]: x1 = x0 + h_vecs[i] x2 = x0 + 2 h_vecs[i] dx = x2[i] - x0[i] f1 = fun(x1) f2 = fun(x2) df = -3.0 * f0 + 4 * f1 - f2 elif method == '3-point' and not use_one_sided[i]: x1 = x0 - h_vecs[i] x2 = x0 + h_vecs[i] dx = x2[i] - x1[i] f1 = fun(x1) f2 = fun(x2) df = f2 - f1 elif method == 'cs': f1 = fun(x0 + h_vecs[i]*1.j) df = f1.imag dx = h_vecs[i, i] else: raise RuntimeError("Never be here.") J_transposed[i] = df / dx if m == 1: J_transposed = np.ravel(J_transposed) return J_transposed.T def _sparse_difference(fun, x0, f0, h, use_one_sided, structure, groups, method): m = f0.size n = x0.size row_indices = [] col_indices = [] fractions = [] n_groups = np.max(groups) + 1 for group in range(n_groups): # Perturb variables which are in the same group simultaneously. e =	np.equal(group, groups)	numpy.equal
import numpy as np import sys import os from PIL import Image from visu.helper_functions import save_image from scipy.spatial.transform import Rotation as R from helper import re_quat import copy import torch import numpy as np import k3d class Visualizer(): def __init__(self, p_visu, writer=None): if p_visu[-1] != '/': p_visu = p_visu + '/' self.p_visu = p_visu self.writer = writer if not os.path.exists(self.p_visu): os.makedirs(self.p_visu) def plot_estimated_pose(self, tag, epoch, img, points, trans=[[0, 0, 0]], rot_mat=[[1, 0, 0], [0, 1, 0], [0, 0, 1]], cam_cx=0, cam_cy=0, cam_fx=0, cam_fy=0, store=False, jupyter=False, w=2): """ tag := tensorboard tag epoch := tensorboard epoche store := ture -> stores the image to standard path path := != None creats the path and store to it path/tag.png img:= original_image, [widht,height,RGB] points:= points of the object model [length,x,y,z] trans: [1,3] rot: [3,3] """ img_d = copy.deepcopy(img) points =	np.dot(points, rot_mat.T)	numpy.dot
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] *	np.ones_like(min_2_x_time)	numpy.ones_like
# pvtrace is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 3 of the License, or # (at your option) any later version. # # pvtrace is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see <http://www.gnu.org/licenses/>. import numpy as np from external.transformations import translation_matrix, rotation_matrix import external.transformations as tf from Trace import Photon from Geometry import Box, Cylinder, FinitePlane, transform_point, transform_direction, rotation_matrix_from_vector_alignment, norm from Materials import Spectrum def random_spherecial_vector(): # This method of calculating isotropic vectors is taken from GNU Scientific Library LOOP = True while LOOP: x = -1. + 2. * np.random.uniform() y = -1. + 2. * np.random.uniform() s = x2 + y2 if s <= 1.0: LOOP = False z = -1. + 2. * s a = 2 * np.sqrt(1 - s) x = a * x y = a * y return np.array([x,y,z]) class SimpleSource(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, use_random_polarisation=False): super(SimpleSource, self).__init__() self.position = position self.direction = direction self.wavelength = wavelength self.use_random_polarisation = use_random_polarisation self.throw = 0 self.source_id = "SimpleSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength # If use_polarisation is set generate a random polarisation vector of the photon if self.use_random_polarisation: # Randomise rotation angle around xy-plane, the transform from +z to the direction of the photon vec = random_spherecial_vector() vec[2] = 0. vec = norm(vec) R = rotation_matrix_from_vector_alignment(self.direction, [0,0,1]) photon.polarisation = transform_direction(vec, R) else: photon.polarisation = None photon.id = self.throw self.throw = self.throw + 1 return photon class Laser(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, polarisation=None): super(Laser, self).__init__() self.position = np.array(position) self.direction = np.array(direction) self.wavelength = wavelength assert polarisation != None, "Polarisation of the Laser is not set." self.polarisation = np.array(polarisation) self.throw = 0 self.source_id = "LaserSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength photon.polarisation = self.polarisation photon.id = self.throw self.throw = self.throw + 1 return photon class PlanarSource(object): """A box that emits photons from the top surface (normal), sampled from the spectrum.""" def __init__(self, spectrum=None, wavelength=555, direction=(0,0,1), length=0.05, width=0.05): super(PlanarSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.plane = FinitePlane(length=length, width=width) self.length = length self.width = width # direction is the direction that photons are fired out of the plane in the GLOBAL FRAME. # i.e. this is passed directly to the photon to set is's direction self.direction = direction self.throw = 0 self.source_id = "PlanarSource_" + str(id(self)) def translate(self, translation): self.plane.append_transform(tf.translation_matrix(translation)) def rotate(self, angle, axis): self.plane.append_transform(tf.rotation_matrix(angle, axis)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Create a point which is on the surface of the finite plane in it's local frame x =	np.random.uniform(0., self.length)	numpy.random.uniform
"""Routines for numerical differentiation.""" from __future__ import division import numpy as np from numpy.linalg import norm from scipy.sparse.linalg import LinearOperator from ..sparse import issparse, csc_matrix, csr_matrix, coo_matrix, find from ._group_columns import group_dense, group_sparse EPS = np.finfo(np.float64).eps def _adjust_scheme_to_bounds(x0, h, num_steps, scheme, lb, ub): """Adjust final difference scheme to the presence of bounds. Parameters ---------- x0 : ndarray, shape (n,) Point at which we wish to estimate derivative. h : ndarray, shape (n,) Desired finite difference steps. num_steps : int Number of `h` steps in one direction required to implement finite difference scheme. For example, 2 means that we need to evaluate f(x0 + 2 * h) or f(x0 - 2 * h) scheme : {'1-sided', '2-sided'} Whether steps in one or both directions are required. In other words '1-sided' applies to forward and backward schemes, '2-sided' applies to center schemes. lb : ndarray, shape (n,) Lower bounds on independent variables. ub : ndarray, shape (n,) Upper bounds on independent variables. Returns ------- h_adjusted : ndarray, shape (n,) Adjusted step sizes. Step size decreases only if a sign flip or switching to one-sided scheme doesn't allow to take a full step. use_one_sided : ndarray of bool, shape (n,) Whether to switch to one-sided scheme. Informative only for ``scheme='2-sided'``. """ if scheme == '1-sided': use_one_sided = np.ones_like(h, dtype=bool) elif scheme == '2-sided': h = np.abs(h) use_one_sided = np.zeros_like(h, dtype=bool) else: raise ValueError("`scheme` must be '1-sided' or '2-sided'.") if np.all((lb == -np.inf) & (ub == np.inf)): return h, use_one_sided h_total = h * num_steps h_adjusted = h.copy() lower_dist = x0 - lb upper_dist = ub - x0 if scheme == '1-sided': x = x0 + h_total violated = (x < lb) \| (x > ub) fitting = np.abs(h_total) <= np.maximum(lower_dist, upper_dist) h_adjusted[violated & fitting] = -1 forward = (upper_dist >= lower_dist) & ~fitting h_adjusted[forward] = upper_dist[forward] / num_steps backward = (upper_dist < lower_dist) & ~fitting h_adjusted[backward] = -lower_dist[backward] / num_steps elif scheme == '2-sided': central = (lower_dist >= h_total) & (upper_dist >= h_total) forward = (upper_dist >= lower_dist) & ~central h_adjusted[forward] = np.minimum( h[forward], 0.5 upper_dist[forward] / num_steps) use_one_sided[forward] = True backward = (upper_dist < lower_dist) & ~central h_adjusted[backward] = -np.minimum( h[backward], 0.5 * lower_dist[backward] / num_steps) use_one_sided[backward] = True min_dist = np.minimum(upper_dist, lower_dist) / num_steps adjusted_central = (~central & (np.abs(h_adjusted) <= min_dist)) h_adjusted[adjusted_central] = min_dist[adjusted_central] use_one_sided[adjusted_central] = False return h_adjusted, use_one_sided relative_step = {"2-point": EPS0.5, "3-point": EPS(1/3), "cs": EPS*0.5} def _compute_absolute_step(rel_step, x0, method): if rel_step is None: rel_step = relative_step[method] sign_x0 = (x0 >= 0).astype(float) 2 - 1 return rel_step * sign_x0 * np.maximum(1.0, np.abs(x0)) def _prepare_bounds(bounds, x0): lb, ub = [np.asarray(b, dtype=float) for b in bounds] if lb.ndim == 0: lb = np.resize(lb, x0.shape) if ub.ndim == 0: ub = np.resize(ub, x0.shape) return lb, ub def group_columns(A, order=0): """Group columns of a 2-D matrix for sparse finite differencing [1]_. Two columns are in the same group if in each row at least one of them has zero. A greedy sequential algorithm is used to construct groups. Parameters ---------- A : array_like or sparse matrix, shape (m, n) Matrix of which to group columns. order : int, iterable of int with shape (n,) or None Permutation array which defines the order of columns enumeration. If int or None, a random permutation is used with `order` used as a random seed. Default is 0, that is use a random permutation but guarantee repeatability. Returns ------- groups : ndarray of int, shape (n,) Contains values from 0 to n_groups-1, where n_groups is the number of found groups. Each value ``groups[i]`` is an index of a group to which ith column assigned. The procedure was helpful only if n_groups is significantly less than n. References ---------- .. [1] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. """ if issparse(A): A = csc_matrix(A) else: A = np.atleast_2d(A) A = (A != 0).astype(np.int32) if A.ndim != 2: raise ValueError("`A` must be 2-dimensional.") m, n = A.shape if order is None or np.isscalar(order): rng = np.random.RandomState(order) order = rng.permutation(n) else: order = np.asarray(order) if order.shape != (n,): raise ValueError("`order` has incorrect shape.") A = A[:, order] if issparse(A): groups = group_sparse(m, n, A.indices, A.indptr) else: groups = group_dense(m, n, A) groups[order] = groups.copy() return groups def approx_derivative(fun, x0, method='3-point', rel_step=None, f0=None, bounds=(-np.inf, np.inf), sparsity=None, as_linear_operator=False, args=(), kwargs={}): """Compute finite difference approximation of the derivatives of a vector-valued function. If a function maps from R^n to R^m, its derivatives form m-by-n matrix called the Jacobian, where an element (i, j) is a partial derivative of f[i] with respect to x[j]. Parameters ---------- fun : callable Function of which to estimate the derivatives. The argument x passed to this function is ndarray of shape (n,) (never a scalar even if n=1). It must return 1-D array_like of shape (m,) or a scalar. x0 : array_like of shape (n,) or float Point at which to estimate the derivatives. Float will be converted to a 1-D array. method : {'3-point', '2-point', 'cs'}, optional Finite difference method to use: - '2-point' - use the first order accuracy forward or backward difference. - '3-point' - use central difference in interior points and the second order accuracy forward or backward difference near the boundary. - 'cs' - use a complex-step finite difference scheme. This assumes that the user function is real-valued and can be analytically continued to the complex plane. Otherwise, produces bogus results. rel_step : None or array_like, optional Relative step size to use. The absolute step size is computed as ``h = rel_step * sign(x0) * max(1, abs(x0))``, possibly adjusted to fit into the bounds. For ``method='3-point'`` the sign of `h` is ignored. If None (default) then step is selected automatically, see Notes. f0 : None or array_like, optional If not None it is assumed to be equal to ``fun(x0)``, in this case the ``fun(x0)`` is not called. Default is None. bounds : tuple of array_like, optional Lower and upper bounds on independent variables. Defaults to no bounds. Each bound must match the size of `x0` or be a scalar, in the latter case the bound will be the same for all variables. Use it to limit the range of function evaluation. Bounds checking is not implemented when `as_linear_operator` is True. sparsity : {None, array_like, sparse matrix, 2-tuple}, optional Defines a sparsity structure of the Jacobian matrix. If the Jacobian matrix is known to have only few non-zero elements in each row, then it's possible to estimate its several columns by a single function evaluation [3]_. To perform such economic computations two ingredients are required: * structure : array_like or sparse matrix of shape (m, n). A zero element means that a corresponding element of the Jacobian identically equals to zero. * groups : array_like of shape (n,). A column grouping for a given sparsity structure, use `group_columns` to obtain it. A single array or a sparse matrix is interpreted as a sparsity structure, and groups are computed inside the function. A tuple is interpreted as (structure, groups). If None (default), a standard dense differencing will be used. Note, that sparse differencing makes sense only for large Jacobian matrices where each row contains few non-zero elements. as_linear_operator : bool, optional When True the function returns an `scipy.sparse.linalg.LinearOperator`. Otherwise it returns a dense array or a sparse matrix depending on `sparsity`. The linear operator provides an efficient way of computing ``J.dot(p)`` for any vector ``p`` of shape (n,), but does not allow direct access to individual elements of the matrix. By default `as_linear_operator` is False. args, kwargs : tuple and dict, optional Additional arguments passed to `fun`. Both empty by default. The calling signature is ``fun(x, args, kwargs)``. Returns ------- J : {ndarray, sparse matrix, LinearOperator} Finite difference approximation of the Jacobian matrix. If `as_linear_operator` is True returns a LinearOperator with shape (m, n). Otherwise it returns a dense array or sparse matrix depending on how `sparsity` is defined. If `sparsity` is None then a ndarray with shape (m, n) is returned. If `sparsity` is not None returns a csr_matrix with shape (m, n). For sparse matrices and linear operators it is always returned as a 2-D structure, for ndarrays, if m=1 it is returned as a 1-D gradient array with shape (n,). See Also -------- check_derivative : Check correctness of a function computing derivatives. Notes ----- If `rel_step` is not provided, it assigned to ``EPS(1/s)``, where EPS is machine epsilon for float64 numbers, s=2 for '2-point' method and s=3 for '3-point' method. Such relative step approximately minimizes a sum of truncation and round-off errors, see [1]_. A finite difference scheme for '3-point' method is selected automatically. The well-known central difference scheme is used for points sufficiently far from the boundary, and 3-point forward or backward scheme is used for points near the boundary. Both schemes have the second-order accuracy in terms of Taylor expansion. Refer to [2]_ for the formulas of 3-point forward and backward difference schemes. For dense differencing when m=1 Jacobian is returned with a shape (n,), on the other hand when n=1 Jacobian is returned with a shape (m, 1). Our motivation is the following: a) It handles a case of gradient computation (m=1) in a conventional way. b) It clearly separates these two different cases. b) In all cases np.atleast_2d can be called to get 2-D Jacobian with correct dimensions. References ---------- .. [1] W. H. Press et. al. "Numerical Recipes. The Art of Scientific Computing. 3rd edition", sec. 5.7. .. [2] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. .. [3] <NAME>, "Generation of Finite Difference Formulas on Arbitrarily Spaced Grids", Mathematics of Computation 51, 1988. Examples -------- >>> import numpy as np >>> from scipy.optimize import approx_derivative >>> >>> def f(x, c1, c2): ... return np.array([x[0] np.sin(c1 * x[1]), ... x[0] * np.cos(c2 * x[1])]) ... >>> x0 = np.array([1.0, 0.5 * np.pi]) >>> approx_derivative(f, x0, args=(1, 2)) array([[ 1., 0.], [-1., 0.]]) Bounds can be used to limit the region of function evaluation. In the example below we compute left and right derivative at point 1.0. >>> def g(x): ... return x*2 if x >= 1 else x ... >>> x0 = 1.0 >>> approx_derivative(g, x0, bounds=(-np.inf, 1.0)) array([ 1.]) >>> approx_derivative(g, x0, bounds=(1.0, np.inf)) array([ 2.]) """ if method not in ['2-point', '3-point', 'cs']: raise ValueError("Unknown method '%s'. " % method) x0 = np.atleast_1d(x0) if x0.ndim > 1: raise ValueError("`x0` must have at most 1 dimension.") lb, ub = _prepare_bounds(bounds, x0) if lb.shape != x0.shape or ub.shape != x0.shape: raise ValueError("Inconsistent shapes between bounds and `x0`.") if as_linear_operator and not (np.all(np.isinf(lb)) and np.all(np.isinf(ub))): raise ValueError("Bounds not supported when " "`as_linear_operator` is True.") def fun_wrapped(x): f = np.atleast_1d(fun(x, args, **kwargs)) if f.ndim > 1: raise RuntimeError("`fun` return value has " "more than 1 dimension.") return f if f0 is None: f0 = fun_wrapped(x0) else: f0 =	np.atleast_1d(f0)	numpy.atleast_1d
import numpy as np from defdap.quat import Quat hex_syms = Quat.symEqv("hexagonal") # subset of hexagonal symmetries that give unique orientations when the # Burgers transformation is applied unq_hex_syms = [ hex_syms[0], hex_syms[5], hex_syms[4], hex_syms[2], hex_syms[10], hex_syms[11] ] cubic_syms = Quat.symEqv("cubic") # subset of cubic symmetries that give unique orientations when the # Burgers transformation is applied unq_cub_syms = [ cubic_syms[0], cubic_syms[7], cubic_syms[9], cubic_syms[1], cubic_syms[22], cubic_syms[16], cubic_syms[12], cubic_syms[15], cubic_syms[4], cubic_syms[8], cubic_syms[21], cubic_syms[20] ] # HCP -> BCC burg_eulers =	np.array([135, 90, 354.74])	numpy.array
# coding: utf-8 # Licensed under a 3-clause BSD style license - see LICENSE.rst """ Test the Logarithmic Units and Quantities """ from __future__ import (absolute_import, unicode_literals, division, print_function) from ...extern import six from ...extern.six.moves import zip import pickle import itertools import pytest import numpy as np from numpy.testing.utils import assert_allclose from ...tests.helper import assert_quantity_allclose from ... import units as u, constants as c lu_units = [u.dex, u.mag, u.decibel] lu_subclasses = [u.DexUnit, u.MagUnit, u.DecibelUnit] lq_subclasses = [u.Dex, u.Magnitude, u.Decibel] pu_sample = (u.dimensionless_unscaled, u.m, u.g/u.s*2, u.Jy) class TestLogUnitCreation(object): def test_logarithmic_units(self): """Check logarithmic units are set up correctly.""" assert u.dB.to(u.dex) == 0.1 assert u.dex.to(u.mag) == -2.5 assert u.mag.to(u.dB) == -4 @pytest.mark.parametrize('lu_unit, lu_cls', zip(lu_units, lu_subclasses)) def test_callable_units(self, lu_unit, lu_cls): assert isinstance(lu_unit, u.UnitBase) assert callable(lu_unit) assert lu_unit._function_unit_class is lu_cls @pytest.mark.parametrize('lu_unit', lu_units) def test_equality_to_normal_unit_for_dimensionless(self, lu_unit): lu = lu_unit() assert lu == lu._default_function_unit # eg, MagUnit() == u.mag assert lu._default_function_unit == lu # and u.mag == MagUnit() @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_call_units(self, lu_unit, physical_unit): """Create a LogUnit subclass using the callable unit and physical unit, and do basic check that output is right.""" lu1 = lu_unit(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit def test_call_invalid_unit(self): with pytest.raises(TypeError): u.mag([]) with pytest.raises(ValueError): u.mag(u.mag()) @pytest.mark.parametrize('lu_cls, physical_unit', itertools.product( lu_subclasses + [u.LogUnit], pu_sample)) def test_subclass_creation(self, lu_cls, physical_unit): """Create a LogUnit subclass object for given physical unit, and do basic check that output is right.""" lu1 = lu_cls(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit lu2 = lu_cls(physical_unit, function_unit=2lu1._default_function_unit) assert lu2.physical_unit == physical_unit assert lu2.function_unit == u.Unit(2lu2._default_function_unit) with pytest.raises(ValueError): lu_cls(physical_unit, u.m) def test_predefined_magnitudes(): assert_quantity_allclose((-21.1u.STmag).physical, 1.u.erg/u.cm2/u.s/u.AA) assert_quantity_allclose((-48.6u.ABmag).physical, 1.u.erg/u.cm2/u.s/u.Hz) assert_quantity_allclose((0u.M_bol).physical, c.L_bol0) assert_quantity_allclose((0u.m_bol).physical, c.L_bol0/(4.np.pi(10.c.pc)2)) def test_predefined_reinitialisation(): assert u.mag('ST') == u.STmag assert u.mag('AB') == u.ABmag assert u.mag('Bol') == u.M_bol assert u.mag('bol') == u.m_bol def test_predefined_string_roundtrip(): """Ensure roundtripping; see #5015""" with u.magnitude_zero_points.enable(): assert u.Unit(u.STmag.to_string()) == u.STmag assert u.Unit(u.ABmag.to_string()) == u.ABmag assert u.Unit(u.M_bol.to_string()) == u.M_bol assert u.Unit(u.m_bol.to_string()) == u.m_bol def test_inequality(): """Check __ne__ works (regresssion for #5342).""" lu1 = u.mag(u.Jy) lu2 = u.dex(u.Jy) lu3 = u.mag(u.Jy2) lu4 = lu3 - lu1 assert lu1 != lu2 assert lu1 != lu3 assert lu1 == lu4 class TestLogUnitStrings(object): def test_str(self): """Do some spot checks that str, repr, etc. work as expected.""" lu1 = u.mag(u.Jy) assert str(lu1) == 'mag(Jy)' assert repr(lu1) == 'Unit("mag(Jy)")' assert lu1.to_string('generic') == 'mag(Jy)' with pytest.raises(ValueError): lu1.to_string('fits') lu2 = u.dex() assert str(lu2) == 'dex' assert repr(lu2) == 'Unit("dex(1)")' assert lu2.to_string() == 'dex(1)' lu3 = u.MagUnit(u.Jy, function_unit=2u.mag) assert str(lu3) == '2 mag(Jy)' assert repr(lu3) == 'MagUnit("Jy", unit="2 mag")' assert lu3.to_string() == '2 mag(Jy)' lu4 = u.mag(u.ct) assert lu4.to_string('generic') == 'mag(ct)' assert lu4.to_string('latex') == ('$\\mathrm{mag}$$\\mathrm{\\left( ' '\\mathrm{ct} \\right)}$') assert lu4._repr_latex_() == lu4.to_string('latex') class TestLogUnitConversion(object): @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_physical_unit_conversion(self, lu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to their non-log counterparts.""" lu1 = lu_unit(physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(physical_unit, 0.) == 1. assert physical_unit.is_equivalent(lu1) assert physical_unit.to(lu1, 1.) == 0. pu = u.Unit(8.physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(pu, 0.) == 0.125 assert pu.is_equivalent(lu1) assert_allclose(pu.to(lu1, 0.125), 0., atol=1.e-15) # Check we round-trip. value = np.linspace(0., 10., 6) assert_allclose(pu.to(lu1, lu1.to(pu, value)), value, atol=1.e-15) # And that we're not just returning True all the time. pu2 = u.g assert not lu1.is_equivalent(pu2) with pytest.raises(u.UnitsError): lu1.to(pu2) assert not pu2.is_equivalent(lu1) with pytest.raises(u.UnitsError): pu2.to(lu1) @pytest.mark.parametrize('lu_unit', lu_units) def test_container_unit_conversion(self, lu_unit): """Check that conversion to logarithmic units (u.mag, u.dB, u.dex) is only possible when the physical unit is dimensionless.""" values = np.linspace(0., 10., 6) lu1 = lu_unit(u.dimensionless_unscaled) assert lu1.is_equivalent(lu1.function_unit) assert_allclose(lu1.to(lu1.function_unit, values), values) lu2 = lu_unit(u.Jy) assert not lu2.is_equivalent(lu2.function_unit) with pytest.raises(u.UnitsError): lu2.to(lu2.function_unit, values) @pytest.mark.parametrize( 'flu_unit, tlu_unit, physical_unit', itertools.product(lu_units, lu_units, pu_sample)) def test_subclass_conversion(self, flu_unit, tlu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to each other if they correspond to equivalent physical units.""" values = np.linspace(0., 10., 6) flu = flu_unit(physical_unit) tlu = tlu_unit(physical_unit) assert flu.is_equivalent(tlu) assert_allclose(flu.to(tlu), flu.function_unit.to(tlu.function_unit)) assert_allclose(flu.to(tlu, values), values * flu.function_unit.to(tlu.function_unit)) tlu2 = tlu_unit(u.Unit(100.physical_unit)) assert flu.is_equivalent(tlu2) # Check that we round-trip. assert_allclose(flu.to(tlu2, tlu2.to(flu, values)), values, atol=1.e-15) tlu3 = tlu_unit(physical_unit.to_system(u.si)[0]) assert flu.is_equivalent(tlu3) assert_allclose(flu.to(tlu3, tlu3.to(flu, values)), values, atol=1.e-15) tlu4 = tlu_unit(u.g) assert not flu.is_equivalent(tlu4) with pytest.raises(u.UnitsError): flu.to(tlu4, values) def test_unit_decomposition(self): lu = u.mag(u.Jy) assert lu.decompose() == u.mag(u.Jy.decompose()) assert lu.decompose().physical_unit.bases == [u.kg, u.s] assert lu.si == u.mag(u.Jy.si) assert lu.si.physical_unit.bases == [u.kg, u.s] assert lu.cgs == u.mag(u.Jy.cgs) assert lu.cgs.physical_unit.bases == [u.g, u.s] def test_unit_multiple_possible_equivalencies(self): lu = u.mag(u.Jy) assert lu.is_equivalent(pu_sample) class TestLogUnitArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other units is only possible when the physical unit is dimensionless, and that this turns the unit into a normal one.""" lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 u.m with pytest.raises(u.UnitsError): u.m * lu1 with pytest.raises(u.UnitsError): lu1 / lu1 for unit in (u.dimensionless_unscaled, u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lu1 / unit lu2 = u.mag(u.dimensionless_unscaled) with pytest.raises(u.UnitsError): lu2 * lu1 with pytest.raises(u.UnitsError): lu2 / lu1 # But dimensionless_unscaled can be cancelled. assert lu2 / lu2 == u.dimensionless_unscaled # With dimensionless, normal units are OK, but we return a plain unit. tf = lu2 * u.m tr = u.m * lu2 for t in (tf, tr): assert not isinstance(t, type(lu2)) assert t == lu2.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lu2.physical_unit) # Now we essentially have a LogUnit with a prefactor of 100, # so should be equivalent again. t = tf / u.cm with u.set_enabled_equivalencies(u.logarithmic()): assert t.is_equivalent(lu2.function_unit) assert_allclose(t.to(u.dimensionless_unscaled, np.arange(3.)/100.), lu2.to(lu2.physical_unit, np.arange(3.))) # If we effectively remove lu1, a normal unit should be returned. t2 = tf / lu2 assert not isinstance(t2, type(lu2)) assert t2 == u.m t3 = tf / lu2.function_unit assert not isinstance(t3, type(lu2)) assert t3 == u.m # For completeness, also ensure non-sensical operations fail with pytest.raises(TypeError): lu1 * object() with pytest.raises(TypeError): slice(None) * lu1 with pytest.raises(TypeError): lu1 / [] with pytest.raises(TypeError): 1 / lu1 @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogUnits to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (such as mag2) is incompatible.""" lu1 = u.mag(u.Jy) if power == 0: assert lu1 power == u.dimensionless_unscaled elif power == 1: assert lu1 power == lu1 else: with pytest.raises(u.UnitsError): lu1 power # With dimensionless, though, it works, but returns a normal unit. lu2 = u.mag(u.dimensionless_unscaled) t = lu2power if power == 0: assert t == u.dimensionless_unscaled elif power == 1: assert t == lu2 else: assert not isinstance(t, type(lu2)) assert t == lu2.function_unitpower # also check we roundtrip t2 = t*(1./power) assert t2 == lu2.function_unit with u.set_enabled_equivalencies(u.logarithmic()): assert_allclose(t2.to(u.dimensionless_unscaled, np.arange(3.)), lu2.to(lu2.physical_unit, np.arange(3.))) @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 + other with pytest.raises(u.UnitsError): lu1 - other with pytest.raises(u.UnitsError): other - lu1 def test_addition_subtraction_to_non_units_fails(self): lu1 = u.mag(u.Jy) with pytest.raises(TypeError): lu1 + 1. with pytest.raises(TypeError): lu1 - [1., 2., 3.] @pytest.mark.parametrize( 'other', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2u.mag), u.MagUnit('', 2.u.mag))) def test_addition_subtraction(self, other): """Check physical units are changed appropriately""" lu1 = u.mag(u.Jy) other_pu = getattr(other, 'physical_unit', u.dimensionless_unscaled) lu_sf = lu1 + other assert lu_sf.is_equivalent(lu1.physical_unit other_pu) lu_sr = other + lu1 assert lu_sr.is_equivalent(lu1.physical_unit * other_pu) lu_df = lu1 - other assert lu_df.is_equivalent(lu1.physical_unit / other_pu) lu_dr = other - lu1 assert lu_dr.is_equivalent(other_pu / lu1.physical_unit) def test_complicated_addition_subtraction(self): """for fun, a more complicated example of addition and subtraction""" dm0 = u.Unit('DM', 1./(4.np.pi(10.u.pc)2)) lu_dm = u.mag(dm0) lu_absST = u.STmag - lu_dm assert lu_absST.is_equivalent(u.erg/u.s/u.AA) def test_neg_pos(self): lu1 = u.mag(u.Jy) neg_lu = -lu1 assert neg_lu != lu1 assert neg_lu.physical_unit == u.Jy-1 assert -neg_lu == lu1 pos_lu = +lu1 assert pos_lu is not lu1 assert pos_lu == lu1 def test_pickle(): lu1 = u.dex(u.cm/u.s2) s = pickle.dumps(lu1) lu2 = pickle.loads(s) assert lu1 == lu2 def test_hashable(): lu1 = u.dB(u.mW) lu2 = u.dB(u.m) lu3 = u.dB(u.mW) assert hash(lu1) != hash(lu2) assert hash(lu1) == hash(lu3) luset = {lu1, lu2, lu3} assert len(luset) == 2 class TestLogQuantityCreation(object): @pytest.mark.parametrize('lq, lu', zip(lq_subclasses + [u.LogQuantity], lu_subclasses + [u.LogUnit])) def test_logarithmic_quantities(self, lq, lu): """Check logarithmic quantities are all set up correctly""" assert lq._unit_class == lu assert type(lu()._quantity_class(1.)) is lq @pytest.mark.parametrize('lq_cls, physical_unit', itertools.product(lq_subclasses, pu_sample)) def test_subclass_creation(self, lq_cls, physical_unit): """Create LogQuantity subclass objects for some physical units, and basic check on transformations""" value = np.arange(1., 10.) log_q = lq_cls(value physical_unit) assert log_q.unit.physical_unit == physical_unit assert log_q.unit.function_unit == log_q.unit._default_function_unit assert_allclose(log_q.physical.value, value) with pytest.raises(ValueError): lq_cls(value, physical_unit) @pytest.mark.parametrize( 'unit', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2u.mag), u.MagUnit('', 2.u.mag), u.MagUnit(u.Jy, -1u.mag), u.MagUnit(u.m, -2.u.mag))) def test_different_units(self, unit): q = u.Magnitude(1.23, unit) assert q.unit.function_unit == getattr(unit, 'function_unit', unit) assert q.unit.physical_unit is getattr(unit, 'physical_unit', u.dimensionless_unscaled) @pytest.mark.parametrize('value, unit', ( (1.u.mag(u.Jy), None), (1.u.dex(u.Jy), None), (1.u.mag(u.W/u.m2/u.Hz), u.mag(u.Jy)), (1.u.dex(u.W/u.m*2/u.Hz), u.mag(u.Jy)))) def test_function_values(self, value, unit): lq = u.Magnitude(value, unit) assert lq == value assert lq.unit.function_unit == u.mag assert lq.unit.physical_unit == getattr(unit, 'physical_unit', value.unit.physical_unit) @pytest.mark.parametrize( 'unit', (u.mag(), u.mag(u.Jy), u.mag(u.m), u.MagUnit('', 2.u.mag), u.MagUnit(u.Jy, -1u.mag), u.MagUnit(u.m, -2.u.mag))) def test_indirect_creation(self, unit): q1 = 2.5 * unit assert isinstance(q1, u.Magnitude) assert q1.value == 2.5 assert q1.unit == unit pv = 100. * unit.physical_unit q2 = unit * pv assert q2.unit == unit assert q2.unit.physical_unit == pv.unit assert q2.to_value(unit.physical_unit) == 100. assert (q2._function_view / u.mag).to_value(1) == -5. q3 = unit / 0.4 assert q3 == q1 def test_from_view(self): # Cannot view a physical quantity as a function quantity, since the # values would change. q = [100., 1000.] * u.cm/u.s*2 with pytest.raises(TypeError): q.view(u.Dex) # But fine if we have the right magnitude. q = [2., 3.] u.dex lq = q.view(u.Dex) assert isinstance(lq, u.Dex) assert lq.unit.physical_unit == u.dimensionless_unscaled assert np.all(q == lq) def test_using_quantity_class(self): """Check that we can use Quantity if we have subok=True""" # following issue #5851 lu = u.dex(u.AA) with pytest.raises(u.UnitTypeError): u.Quantity(1., lu) q = u.Quantity(1., lu, subok=True) assert type(q) is lu._quantity_class def test_conversion_to_and_from_physical_quantities(): """Ensures we can convert from regular quantities.""" mst = [10., 12., 14.] * u.STmag flux_lambda = mst.physical mst_roundtrip = flux_lambda.to(u.STmag) # check we return a logquantity; see #5178. assert isinstance(mst_roundtrip, u.Magnitude) assert mst_roundtrip.unit == mst.unit assert_allclose(mst_roundtrip.value, mst.value) wave = [4956.8, 4959.55, 4962.3] * u.AA flux_nu = mst.to(u.Jy, equivalencies=u.spectral_density(wave)) mst_roundtrip2 = flux_nu.to(u.STmag, u.spectral_density(wave)) assert isinstance(mst_roundtrip2, u.Magnitude) assert mst_roundtrip2.unit == mst.unit assert_allclose(mst_roundtrip2.value, mst.value) def test_quantity_decomposition(): lq = 10.u.mag(u.Jy) assert lq.decompose() == lq assert lq.decompose().unit.physical_unit.bases == [u.kg, u.s] assert lq.si == lq assert lq.si.unit.physical_unit.bases == [u.kg, u.s] assert lq.cgs == lq assert lq.cgs.unit.physical_unit.bases == [u.g, u.s] class TestLogQuantityViews(object): def setup(self): self.lq = u.Magnitude(np.arange(10.) u.Jy) self.lq2 = u.Magnitude(np.arange(5.)) def test_value_view(self): lq_value = self.lq.value assert type(lq_value) is np.ndarray lq_value[2] = -1. assert np.all(self.lq.value == lq_value) def test_function_view(self): lq_fv = self.lq._function_view assert type(lq_fv) is u.Quantity assert lq_fv.unit is self.lq.unit.function_unit lq_fv[3] = -2. * lq_fv.unit assert np.all(self.lq.value == lq_fv.value) def test_quantity_view(self): # Cannot view as Quantity, since the unit cannot be represented. with pytest.raises(TypeError): self.lq.view(u.Quantity) # But a dimensionless one is fine. q2 = self.lq2.view(u.Quantity) assert q2.unit is u.mag assert np.all(q2.value == self.lq2.value) lq3 = q2.view(u.Magnitude) assert type(lq3.unit) is u.MagUnit assert lq3.unit.physical_unit == u.dimensionless_unscaled assert np.all(lq3 == self.lq2) class TestLogQuantitySlicing(object): def test_item_get_and_set(self): lq1 = u.Magnitude(np.arange(1., 11.)u.Jy) assert lq1[9] == u.Magnitude(10.u.Jy) lq1[2] = 100.u.Jy assert lq1[2] == u.Magnitude(100.u.Jy) with pytest.raises(u.UnitsError): lq1[2] = 100.u.m with pytest.raises(u.UnitsError): lq1[2] = 100.u.mag with pytest.raises(u.UnitsError): lq1[2] = u.Magnitude(100.u.m) assert lq1[2] == u.Magnitude(100.u.Jy) def test_slice_get_and_set(self): lq1 = u.Magnitude(np.arange(1., 10.)u.Jy) lq1[2:4] = 100.u.Jy assert np.all(lq1[2:4] == u.Magnitude(100.u.Jy)) with pytest.raises(u.UnitsError): lq1[2:4] = 100.u.m with pytest.raises(u.UnitsError): lq1[2:4] = 100.u.mag with pytest.raises(u.UnitsError): lq1[2:4] = u.Magnitude(100.u.m) assert np.all(lq1[2] == u.Magnitude(100.u.Jy)) class TestLogQuantityArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other quantities is only possible when the physical unit is dimensionless, and that this turns the result into a normal quantity.""" lq = u.Magnitude(np.arange(1., 11.)u.Jy) with pytest.raises(u.UnitsError): lq * (1.u.m) with pytest.raises(u.UnitsError): (1.u.m) * lq with pytest.raises(u.UnitsError): lq / lq for unit in (u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lq / unit lq2 = u.Magnitude(np.arange(1, 11.)) with pytest.raises(u.UnitsError): lq2 * lq with pytest.raises(u.UnitsError): lq2 / lq with pytest.raises(u.UnitsError): lq / lq2 # but dimensionless_unscaled can be cancelled r = lq2 / u.Magnitude(2.) assert r.unit == u.dimensionless_unscaled assert np.all(r.value == lq2.value/2.) # with dimensionless, normal units OK, but return normal quantities tf = lq2 * u.m tr = u.m * lq2 for t in (tf, tr): assert not isinstance(t, type(lq2)) assert t.unit == lq2.unit.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lq2.unit.physical_unit) t = tf / (50.u.cm) # now we essentially have the same quantity but with a prefactor of 2 assert t.unit.is_equivalent(lq2.unit.function_unit) assert_allclose(t.to(lq2.unit.function_unit), lq2._function_view2) @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogQuantities to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (say, mag*2) is incompatible.""" lq = u.Magnitude(np.arange(1., 4.)u.Jy) if power == 0: assert np.all(lq power == 1.) elif power == 1: assert np.all(lq power == lq) else: with pytest.raises(u.UnitsError): lq power # with dimensionless, it works, but falls back to normal quantity # (except for power=1) lq2 = u.Magnitude(np.arange(10.)) t = lq2power if power == 0: assert t.unit is u.dimensionless_unscaled assert np.all(t.value == 1.) elif power == 1: assert np.all(t == lq2) else: assert not isinstance(t, type(lq2)) assert t.unit == lq2.unit.function_unit ** power with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(u.dimensionless_unscaled) def test_error_on_lq_as_power(self): lq = u.Magnitude(np.arange(1., 4.)u.Jy) with pytest.raises(TypeError): lq * lq @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lq = u.Magnitude(np.arange(1., 10.)u.Jy) q = 1.23 other with pytest.raises(u.UnitsError): lq + q with pytest.raises(u.UnitsError): lq - q with pytest.raises(u.UnitsError): q - lq @pytest.mark.parametrize( 'other', (1.23 * u.mag, 2.34 * u.mag(), u.Magnitude(3.45 * u.Jy), u.Magnitude(4.56 * u.m), 5.67 * u.Unit(2u.mag), u.Magnitude(6.78, 2.u.mag))) def test_addition_subtraction(self, other): """Check that addition/subtraction with quantities with magnitude or MagUnit units works, and that it changes the physical units appropriately.""" lq = u.Magnitude(np.arange(1., 10.)u.Jy) other_physical = other.to(getattr(other.unit, 'physical_unit', u.dimensionless_unscaled), equivalencies=u.logarithmic()) lq_sf = lq + other assert_allclose(lq_sf.physical, lq.physical other_physical) lq_sr = other + lq assert_allclose(lq_sr.physical, lq.physical * other_physical) lq_df = lq - other assert_allclose(lq_df.physical, lq.physical / other_physical) lq_dr = other - lq assert_allclose(lq_dr.physical, other_physical / lq.physical) @pytest.mark.parametrize('other', pu_sample) def test_inplace_addition_subtraction_unit_checks(self, other): lu1 = u.mag(u.Jy) lq1 = u.Magnitude(np.arange(1., 10.), lu1) with pytest.raises(u.UnitsError): lq1 += other assert np.all(lq1.value == np.arange(1., 10.)) assert lq1.unit == lu1 with pytest.raises(u.UnitsError): lq1 -= other assert np.all(lq1.value == np.arange(1., 10.)) assert lq1.unit == lu1 @pytest.mark.parametrize( 'other', (1.23 * u.mag, 2.34 * u.mag(), u.Magnitude(3.45 * u.Jy), u.Magnitude(4.56 * u.m), 5.67 * u.Unit(2u.mag), u.Magnitude(6.78, 2.u.mag))) def test_inplace_addition_subtraction(self, other): """Check that inplace addition/subtraction with quantities with magnitude or MagUnit units works, and that it changes the physical units appropriately.""" lq = u.Magnitude(np.arange(1., 10.)u.Jy) other_physical = other.to(getattr(other.unit, 'physical_unit', u.dimensionless_unscaled), equivalencies=u.logarithmic()) lq_sf = lq.copy() lq_sf += other assert_allclose(lq_sf.physical, lq.physical other_physical) lq_df = lq.copy() lq_df -= other	assert_allclose(lq_df.physical, lq.physical / other_physical)	numpy.testing.utils.assert_allclose
""" YTArray class. """ from __future__ import print_function #----------------------------------------------------------------------------- # Copyright (c) 2013, yt Development Team. # # Distributed under the terms of the Modified BSD License. # # The full license is in the file COPYING.txt, distributed with this software. #----------------------------------------------------------------------------- import copy import numpy as np from distutils.version import LooseVersion from functools import wraps from numpy import \ add, subtract, multiply, divide, logaddexp, logaddexp2, true_divide, \ floor_divide, negative, power, remainder, mod, absolute, rint, \ sign, conj, exp, exp2, log, log2, log10, expm1, log1p, sqrt, square, \ reciprocal, sin, cos, tan, arcsin, arccos, arctan, arctan2, \ hypot, sinh, cosh, tanh, arcsinh, arccosh, arctanh, deg2rad, rad2deg, \ bitwise_and, bitwise_or, bitwise_xor, invert, left_shift, right_shift, \ greater, greater_equal, less, less_equal, not_equal, equal, logical_and, \ logical_or, logical_xor, logical_not, maximum, minimum, fmax, fmin, \ isreal, iscomplex, isfinite, isinf, isnan, signbit, copysign, nextafter, \ modf, ldexp, frexp, fmod, floor, ceil, trunc, fabs, spacing try: # numpy 1.13 or newer from numpy import positive, divmod as divmod_, isnat, heaviside except ImportError: positive, divmod_, isnat, heaviside = (None,)4 from yt.units.unit_object import Unit, UnitParseError from yt.units.unit_registry import UnitRegistry from yt.units.dimensions import \ angle, \ current_mks, \ dimensionless, \ em_dimensions from yt.utilities.exceptions import \ YTUnitOperationError, YTUnitConversionError, \ YTUfuncUnitError, YTIterableUnitCoercionError, \ YTInvalidUnitEquivalence, YTEquivalentDimsError from yt.utilities.lru_cache import lru_cache from numbers import Number as numeric_type from yt.utilities.on_demand_imports import _astropy from sympy import Rational from yt.units.unit_lookup_table import \ default_unit_symbol_lut from yt.units.equivalencies import equivalence_registry from yt.utilities.logger import ytLogger as mylog from .pint_conversions import convert_pint_units NULL_UNIT = Unit() POWER_SIGN_MAPPING = {multiply: 1, divide: -1} # redefine this here to avoid a circular import from yt.funcs def iterable(obj): try: len(obj) except: return False return True def return_arr(func): @wraps(func) def wrapped(args, *kwargs): ret, units = func(args, kwargs) if ret.shape == (): return YTQuantity(ret, units) else: # This could be a subclass, so don't call YTArray directly. return type(args[0])(ret, units) return wrapped @lru_cache(maxsize=128, typed=False) def sqrt_unit(unit): return unit0.5 @lru_cache(maxsize=128, typed=False) def multiply_units(unit1, unit2): return unit1 * unit2 def preserve_units(unit1, unit2=None): return unit1 @lru_cache(maxsize=128, typed=False) def power_unit(unit, power): return unit*power @lru_cache(maxsize=128, typed=False) def square_unit(unit): return unitunit @lru_cache(maxsize=128, typed=False) def divide_units(unit1, unit2): return unit1/unit2 @lru_cache(maxsize=128, typed=False) def reciprocal_unit(unit): return unit*-1 def passthrough_unit(unit, unit2=None): return unit def return_without_unit(unit, unit2=None): return None def arctan2_unit(unit1, unit2): return NULL_UNIT def comparison_unit(unit1, unit2=None): return None def invert_units(unit): raise TypeError( "Bit-twiddling operators are not defined for YTArray instances") def bitop_units(unit1, unit2): raise TypeError( "Bit-twiddling operators are not defined for YTArray instances") def get_inp_u_unary(ufunc, inputs, out_arr=None): inp = inputs[0] u = getattr(inp, 'units', None) if u is None: u = NULL_UNIT if u.dimensions is angle and ufunc in trigonometric_operators: inp = inp.in_units('radian').v if out_arr is not None: out_arr = ufunc(inp).view(np.ndarray) return out_arr, inp, u def get_inp_u_binary(ufunc, inputs): inp1 = coerce_iterable_units(inputs[0]) inp2 = coerce_iterable_units(inputs[1]) unit1 = getattr(inp1, 'units', None) unit2 = getattr(inp2, 'units', None) ret_class = get_binary_op_return_class(type(inp1), type(inp2)) if unit1 is None: unit1 = Unit(registry=getattr(unit2, 'registry', None)) if unit2 is None and ufunc is not power: unit2 = Unit(registry=getattr(unit1, 'registry', None)) elif ufunc is power: unit2 = inp2 if isinstance(unit2, np.ndarray): if isinstance(unit2, YTArray): if unit2.units.is_dimensionless: pass else: raise YTUnitOperationError(ufunc, unit1, unit2) unit2 = 1.0 return (inp1, inp2), (unit1, unit2), ret_class def handle_preserve_units(inps, units, ufunc, ret_class): if units[0] != units[1]: any_nonzero = [np.any(inps[0]), np.any(inps[1])] if any_nonzero[0] == np.bool_(False): units = (units[1], units[1]) elif any_nonzero[1] == np.bool_(False): units = (units[0], units[0]) else: if not units[0].same_dimensions_as(units[1]): raise YTUnitOperationError(ufunc, units) inps = (inps[0], ret_class(inps[1]).to( ret_class(inps[0]).units)) return inps, units def handle_comparison_units(inps, units, ufunc, ret_class, raise_error=False): if units[0] != units[1]: u1d = units[0].is_dimensionless u2d = units[1].is_dimensionless any_nonzero = [np.any(inps[0]), np.any(inps[1])] if any_nonzero[0] == np.bool_(False): units = (units[1], units[1]) elif any_nonzero[1] == np.bool_(False): units = (units[0], units[0]) elif not any([u1d, u2d]): if not units[0].same_dimensions_as(units[1]): raise YTUnitOperationError(ufunc, units) else: if raise_error: raise YTUfuncUnitError(ufunc, units) inps = (inps[0], ret_class(inps[1]).to( ret_class(inps[0]).units)) return inps, units def handle_multiply_divide_units(unit, units, out, out_arr): if unit.is_dimensionless and unit.base_value != 1.0: if not units[0].is_dimensionless: if units[0].dimensions == units[1].dimensions: out_arr = np.multiply(out_arr.view(np.ndarray), unit.base_value, out=out) unit = Unit(registry=unit.registry) return out, out_arr, unit def coerce_iterable_units(input_object): if isinstance(input_object, np.ndarray): return input_object if iterable(input_object): if any([isinstance(o, YTArray) for o in input_object]): ff = getattr(input_object[0], 'units', NULL_UNIT, ) if any([ff != getattr(_, 'units', NULL_UNIT) for _ in input_object]): raise YTIterableUnitCoercionError(input_object) # This will create a copy of the data in the iterable. return YTArray(input_object) return input_object else: return input_object def sanitize_units_mul(this_object, other_object): inp = coerce_iterable_units(this_object) ret = coerce_iterable_units(other_object) # If the other object is a YTArray and has the same dimensions as the object # under consideration, convert so we don't mix units with the same # dimensions. if isinstance(ret, YTArray): if inp.units.same_dimensions_as(ret.units): ret.in_units(inp.units) return ret def sanitize_units_add(this_object, other_object, op_string): inp = coerce_iterable_units(this_object) ret = coerce_iterable_units(other_object) # Make sure the other object is a YTArray before we use the `units` # attribute. if isinstance(ret, YTArray): if not inp.units.same_dimensions_as(ret.units): # handle special case of adding or subtracting with zero or # array filled with zero if not np.any(other_object): return ret.view(np.ndarray) elif not np.any(this_object): return ret raise YTUnitOperationError(op_string, inp.units, ret.units) ret = ret.in_units(inp.units) else: # If the other object is not a YTArray, then one of the arrays must be # dimensionless or filled with zeros if not inp.units.is_dimensionless and np.any(ret): raise YTUnitOperationError(op_string, inp.units, dimensionless) return ret def validate_comparison_units(this, other, op_string): # Check that other is a YTArray. if hasattr(other, 'units'): if this.units.expr is other.units.expr: if this.units.base_value == other.units.base_value: return other if not this.units.same_dimensions_as(other.units): raise YTUnitOperationError(op_string, this.units, other.units) return other.in_units(this.units) return other @lru_cache(maxsize=128, typed=False) def _unit_repr_check_same(my_units, other_units): """ Takes a Unit object, or string of known unit symbol, and check that it is compatible with this quantity. Returns Unit object. """ # let Unit() handle units arg if it's not already a Unit obj. if not isinstance(other_units, Unit): other_units = Unit(other_units, registry=my_units.registry) equiv_dims = em_dimensions.get(my_units.dimensions, None) if equiv_dims == other_units.dimensions: if current_mks in equiv_dims.free_symbols: base = "SI" else: base = "CGS" raise YTEquivalentDimsError(my_units, other_units, base) if not my_units.same_dimensions_as(other_units): raise YTUnitConversionError( my_units, my_units.dimensions, other_units, other_units.dimensions) return other_units unary_operators = ( negative, absolute, rint, sign, conj, exp, exp2, log, log2, log10, expm1, log1p, sqrt, square, reciprocal, sin, cos, tan, arcsin, arccos, arctan, sinh, cosh, tanh, arcsinh, arccosh, arctanh, deg2rad, rad2deg, invert, logical_not, isreal, iscomplex, isfinite, isinf, isnan, signbit, floor, ceil, trunc, modf, frexp, fabs, spacing, positive, isnat, ) binary_operators = ( add, subtract, multiply, divide, logaddexp, logaddexp2, true_divide, power, remainder, mod, arctan2, hypot, bitwise_and, bitwise_or, bitwise_xor, left_shift, right_shift, greater, greater_equal, less, less_equal, not_equal, equal, logical_and, logical_or, logical_xor, maximum, minimum, fmax, fmin, copysign, nextafter, ldexp, fmod, divmod_, heaviside ) trigonometric_operators = ( sin, cos, tan, ) class YTArray(np.ndarray): """ An ndarray subclass that attaches a symbolic unit object to the array data. Parameters ---------- input_array : :obj:`!iterable` A tuple, list, or array to attach units to input_units : String unit specification, unit symbol object, or astropy units The units of the array. Powers must be specified using python syntax (cm*3, not cm^3). registry : ~yt.units.unit_registry.UnitRegistry The registry to create units from. If input_units is already associated with a unit registry and this is specified, this will be used instead of the registry associated with the unit object. dtype : data-type The dtype of the array data. Defaults to the dtype of the input data, or, if none is found, uses np.float64 bypass_validation : boolean If True, all input validation is skipped. Using this option may produce corrupted, invalid units or array data, but can lead to significant speedups in the input validation logic adds significant overhead. If set, input_units must* be a valid unit object. Defaults to False. Examples -------- >>> from yt import YTArray >>> a = YTArray([1, 2, 3], 'cm') >>> b = YTArray([4, 5, 6], 'm') >>> a + b YTArray([ 401., 502., 603.]) cm >>> b + a YTArray([ 4.01, 5.02, 6.03]) m NumPy ufuncs will pass through units where appropriate. >>> import numpy as np >>> a = YTArray(np.arange(8) - 4, 'g/cm3') >>> np.abs(a) YTArray([4, 3, 2, 1, 0, 1, 2, 3]) g/cm3 and strip them when it would be annoying to deal with them. >>> np.log10(a) array([ -inf, 0. , 0.30103 , 0.47712125, 0.60205999, 0.69897 , 0.77815125, 0.84509804]) YTArray is tightly integrated with yt datasets: >>> import yt >>> ds = yt.load('IsolatedGalaxy/galaxy0030/galaxy0030') >>> a = ds.arr(np.ones(5), 'code_length') >>> a.in_cgs() YTArray([ 3.08600000e+24, 3.08600000e+24, 3.08600000e+24, 3.08600000e+24, 3.08600000e+24]) cm This is equivalent to: >>> b = YTArray(np.ones(5), 'code_length', registry=ds.unit_registry) >>> np.all(a == b) True """ _ufunc_registry = { add: preserve_units, subtract: preserve_units, multiply: multiply_units, divide: divide_units, logaddexp: return_without_unit, logaddexp2: return_without_unit, true_divide: divide_units, floor_divide: divide_units, negative: passthrough_unit, power: power_unit, remainder: preserve_units, mod: preserve_units, fmod: preserve_units, absolute: passthrough_unit, fabs: passthrough_unit, rint: return_without_unit, sign: return_without_unit, conj: passthrough_unit, exp: return_without_unit, exp2: return_without_unit, log: return_without_unit, log2: return_without_unit, log10: return_without_unit, expm1: return_without_unit, log1p: return_without_unit, sqrt: sqrt_unit, square: square_unit, reciprocal: reciprocal_unit, sin: return_without_unit, cos: return_without_unit, tan: return_without_unit, sinh: return_without_unit, cosh: return_without_unit, tanh: return_without_unit, arcsin: return_without_unit, arccos: return_without_unit, arctan: return_without_unit, arctan2: arctan2_unit, arcsinh: return_without_unit, arccosh: return_without_unit, arctanh: return_without_unit, hypot: preserve_units, deg2rad: return_without_unit, rad2deg: return_without_unit, bitwise_and: bitop_units, bitwise_or: bitop_units, bitwise_xor: bitop_units, invert: invert_units, left_shift: bitop_units, right_shift: bitop_units, greater: comparison_unit, greater_equal: comparison_unit, less: comparison_unit, less_equal: comparison_unit, not_equal: comparison_unit, equal: comparison_unit, logical_and: comparison_unit, logical_or: comparison_unit, logical_xor: comparison_unit, logical_not: return_without_unit, maximum: preserve_units, minimum: preserve_units, fmax: preserve_units, fmin: preserve_units, isreal: return_without_unit, iscomplex: return_without_unit, isfinite: return_without_unit, isinf: return_without_unit, isnan: return_without_unit, signbit: return_without_unit, copysign: passthrough_unit, nextafter: preserve_units, modf: passthrough_unit, ldexp: bitop_units, frexp: return_without_unit, floor: passthrough_unit, ceil: passthrough_unit, trunc: passthrough_unit, spacing: passthrough_unit, positive: passthrough_unit, divmod_: passthrough_unit, isnat: return_without_unit, heaviside: preserve_units, } __array_priority__ = 2.0 def __new__(cls, input_array, input_units=None, registry=None, dtype=None, bypass_validation=False): if dtype is None: dtype = getattr(input_array, 'dtype', np.float64) if bypass_validation is True: obj = np.asarray(input_array, dtype=dtype).view(cls) obj.units = input_units if registry is not None: obj.units.registry = registry return obj if input_array is NotImplemented: return input_array.view(cls) if registry is None and isinstance(input_units, (str, bytes)): if input_units.startswith('code_'): raise UnitParseError( "Code units used without referring to a dataset. \n" "Perhaps you meant to do something like this instead: \n" "ds.arr(%s, \"%s\")" % (input_array, input_units) ) if isinstance(input_array, YTArray): ret = input_array.view(cls) if input_units is None: if registry is None: ret.units = input_array.units else: units = Unit(str(input_array.units), registry=registry) ret.units = units elif isinstance(input_units, Unit): ret.units = input_units else: ret.units = Unit(input_units, registry=registry) return ret elif isinstance(input_array, np.ndarray): pass elif iterable(input_array) and input_array: if isinstance(input_array[0], YTArray): return YTArray(np.array(input_array, dtype=dtype), input_array[0].units, registry=registry) # Input array is an already formed ndarray instance # We first cast to be our class type obj = np.asarray(input_array, dtype=dtype).view(cls) # Check units type if input_units is None: # Nothing provided. Make dimensionless... units = Unit() elif isinstance(input_units, Unit): if registry and registry is not input_units.registry: units = Unit(str(input_units), registry=registry) else: units = input_units else: # units kwarg set, but it's not a Unit object. # don't handle all the cases here, let the Unit class handle if # it's a str. units = Unit(input_units, registry=registry) # Attach the units obj.units = units return obj def __repr__(self): """ """ return super(YTArray, self).__repr__()+' '+self.units.__repr__() def __str__(self): """ """ return str(self.view(np.ndarray)) + ' ' + str(self.units) # # Start unit conversion methods # def convert_to_units(self, units): """ Convert the array and units to the given units. Parameters ---------- units : Unit object or str The units you want to convert to. """ new_units = _unit_repr_check_same(self.units, units) (conversion_factor, offset) = self.units.get_conversion_factor(new_units) self.units = new_units values = self.d values = conversion_factor if offset: np.subtract(self, offsetself.uq, self) return self def convert_to_base(self, unit_system="cgs"): """ Convert the array and units to the equivalent base units in the specified unit system. Parameters ---------- unit_system : string, optional The unit system to be used in the conversion. If not specified, the default base units of cgs are used. Examples -------- >>> E = YTQuantity(2.5, "erg/s") >>> E.convert_to_base(unit_system="galactic") """ return self.convert_to_units(self.units.get_base_equivalent(unit_system)) def convert_to_cgs(self): """ Convert the array and units to the equivalent cgs units. """ return self.convert_to_units(self.units.get_cgs_equivalent()) def convert_to_mks(self): """ Convert the array and units to the equivalent mks units. """ return self.convert_to_units(self.units.get_mks_equivalent()) def in_units(self, units, equivalence=None, *kwargs): """ Creates a copy of this array with the data in the supplied units, and returns it. Optionally, an equivalence can be specified to convert to an equivalent quantity which is not in the same dimensions. .. note:: All additional keyword arguments are passed to the equivalency, which should be used if that particular equivalency requires them. Parameters ---------- units : Unit object or string The units you want to get a new quantity in. equivalence : string, optional The equivalence you wish to use. To see which equivalencies are supported for this unitful quantity, try the :meth:`list_equivalencies` method. Default: None Returns ------- YTArray """ if equivalence is None: new_units = _unit_repr_check_same(self.units, units) (conversion_factor, offset) = self.units.get_conversion_factor(new_units) new_array = type(self)(self.ndview conversion_factor, new_units) if offset: np.subtract(new_array, offsetnew_array.uq, new_array) return new_array else: return self.to_equivalent(units, equivalence, kwargs) def to(self, units, equivalence=None, kwargs): """ An alias for YTArray.in_units(). See the docstrings of that function for details. """ return self.in_units(units, equivalence=equivalence, kwargs) def to_value(self, units=None, equivalence=None, kwargs): """ Creates a copy of this array with the data in the supplied units, and returns it without units. Output is therefore a bare NumPy array. Optionally, an equivalence can be specified to convert to an equivalent quantity which is not in the same dimensions. .. note:: All additional keyword arguments are passed to the equivalency, which should be used if that particular equivalency requires them. Parameters ---------- units : Unit object or string, optional The units you want to get the bare quantity in. If not specified, the value will be returned in the current units. equivalence : string, optional The equivalence you wish to use. To see which equivalencies are supported for this unitful quantity, try the :meth:`list_equivalencies` method. Default: None Returns ------- NumPy array """ if units is None: v = self.value else: v = self.in_units(units, equivalence=equivalence, kwargs).value if isinstance(self, YTQuantity): return float(v) else: return v def in_base(self, unit_system="cgs"): """ Creates a copy of this array with the data in the specified unit system, and returns it in that system's base units. Parameters ---------- unit_system : string, optional The unit system to be used in the conversion. If not specified, the default base units of cgs are used. Examples -------- >>> E = YTQuantity(2.5, "erg/s") >>> E_new = E.in_base(unit_system="galactic") """ return self.in_units(self.units.get_base_equivalent(unit_system)) def in_cgs(self): """ Creates a copy of this array with the data in the equivalent cgs units, and returns it. Returns ------- Quantity object with data converted to cgs units. """ return self.in_units(self.units.get_cgs_equivalent()) def in_mks(self): """ Creates a copy of this array with the data in the equivalent mks units, and returns it. Returns ------- Quantity object with data converted to mks units. """ return self.in_units(self.units.get_mks_equivalent()) def to_equivalent(self, unit, equiv, kwargs): """ Convert a YTArray or YTQuantity to an equivalent, e.g., something that is related by only a constant factor but not in the same units. Parameters ---------- unit : string The unit that you wish to convert to. equiv : string The equivalence you wish to use. To see which equivalencies are supported for this unitful quantity, try the :meth:`list_equivalencies` method. Examples -------- >>> a = yt.YTArray(1.0e7,"K") >>> a.to_equivalent("keV", "thermal") """ conv_unit = Unit(unit, registry=self.units.registry) if self.units.same_dimensions_as(conv_unit): return self.in_units(conv_unit) this_equiv = equivalence_registry[equiv]() oneway_or_equivalent = ( conv_unit.has_equivalent(equiv) or this_equiv._one_way) if self.has_equivalent(equiv) and oneway_or_equivalent: new_arr = this_equiv.convert( self, conv_unit.dimensions, kwargs) if isinstance(new_arr, tuple): try: return type(self)(new_arr[0], new_arr[1]).in_units(unit) except YTUnitConversionError: raise YTInvalidUnitEquivalence(equiv, self.units, unit) else: return new_arr.in_units(unit) else: raise YTInvalidUnitEquivalence(equiv, self.units, unit) def list_equivalencies(self): """ Lists the possible equivalencies associated with this YTArray or YTQuantity. """ self.units.list_equivalencies() def has_equivalent(self, equiv): """ Check to see if this YTArray or YTQuantity has an equivalent unit in equiv. """ return self.units.has_equivalent(equiv) def ndarray_view(self): """ Returns a view into the array, but as an ndarray rather than ytarray. Returns ------- View of this array's data. """ return self.view(np.ndarray) def to_ndarray(self): """ Creates a copy of this array with the unit information stripped """ return np.array(self) @classmethod def from_astropy(cls, arr, unit_registry=None): """ Convert an AstroPy "Quantity" to a YTArray or YTQuantity. Parameters ---------- arr : AstroPy Quantity The Quantity to convert from. unit_registry : yt UnitRegistry, optional A yt unit registry to use in the conversion. If one is not supplied, the default one will be used. """ # Converting from AstroPy Quantity u = arr.unit ap_units = [] for base, exponent in zip(u.bases, u.powers): unit_str = base.to_string() # we have to do this because AstroPy is silly and defines # hour as "h" if unit_str == "h": unit_str = "hr" ap_units.append("%s(%s)" % (unit_str, Rational(exponent))) ap_units = "".join(ap_units) if isinstance(arr.value, np.ndarray): return YTArray(arr.value, ap_units, registry=unit_registry) else: return YTQuantity(arr.value, ap_units, registry=unit_registry) def to_astropy(self, *kwargs): """ Creates a new AstroPy quantity with the same unit information. """ if _astropy.units is None: raise ImportError("You don't have AstroPy installed, so you can't convert to " + "an AstroPy quantity.") return self.value_astropy.units.Unit(str(self.units), kwargs) @classmethod def from_pint(cls, arr, unit_registry=None): """ Convert a Pint "Quantity" to a YTArray or YTQuantity. Parameters ---------- arr : Pint Quantity The Quantity to convert from. unit_registry : yt UnitRegistry, optional A yt unit registry to use in the conversion. If one is not supplied, the default one will be used. Examples -------- >>> from pint import UnitRegistry >>> import numpy as np >>> ureg = UnitRegistry() >>> a = np.random.random(10) >>> b = ureg.Quantity(a, "erg/cm3") >>> c = yt.YTArray.from_pint(b) """ p_units = [] for base, exponent in arr._units.items(): bs = convert_pint_units(base) p_units.append("%s*(%s)" % (bs, Rational(exponent))) p_units = "".join(p_units) if isinstance(arr.magnitude, np.ndarray): return YTArray(arr.magnitude, p_units, registry=unit_registry) else: return YTQuantity(arr.magnitude, p_units, registry=unit_registry) def to_pint(self, unit_registry=None): """ Convert a YTArray or YTQuantity to a Pint Quantity. Parameters ---------- arr : YTArray or YTQuantity The unitful quantity to convert from. unit_registry : Pint UnitRegistry, optional The Pint UnitRegistry to use in the conversion. If one is not supplied, the default one will be used. NOTE: This is not the same as a yt UnitRegistry object. Examples -------- >>> a = YTQuantity(4.0, "cm2/s") >>> b = a.to_pint() """ from pint import UnitRegistry if unit_registry is None: unit_registry = UnitRegistry() powers_dict = self.units.expr.as_powers_dict() units = [] for unit, pow in powers_dict.items(): # we have to do this because Pint doesn't recognize # "yr" as "year" if str(unit).endswith("yr") and len(str(unit)) in [2,3]: unit = str(unit).replace("yr","year") units.append("%s(%s)" % (unit, Rational(pow))) units = "*".join(units) return unit_registry.Quantity(self.value, units) # # End unit conversion methods # def write_hdf5(self, filename, dataset_name=None, info=None, group_name=None): r"""Writes a YTArray to hdf5 file. Parameters ---------- filename: string The filename to create and write a dataset to dataset_name: string The name of the dataset to create in the file. info: dictionary A dictionary of supplementary info to write to append as attributes to the dataset. group_name: string An optional group to write the arrays to. If not specified, the arrays are datasets at the top level by default. Examples -------- >>> a = YTArray([1,2,3], 'cm') >>> myinfo = {'field':'dinosaurs', 'type':'field_data'} >>> a.write_hdf5('test_array_data.h5', dataset_name='dinosaurs', ... info=myinfo) """ from yt.utilities.on_demand_imports import _h5py as h5py from yt.extern.six.moves import cPickle as pickle if info is None: info = {} info['units'] = str(self.units) info['unit_registry'] = np.void(pickle.dumps(self.units.registry.lut)) if dataset_name is None: dataset_name = 'array_data' f = h5py.File(filename) if group_name is not None: if group_name in f: g = f[group_name] else: g = f.create_group(group_name) else: g = f if dataset_name in g.keys(): d = g[dataset_name] # Overwrite without deleting if we can get away with it. if d.shape == self.shape and d.dtype == self.dtype: d[...] = self for k in d.attrs.keys(): del d.attrs[k] else: del f[dataset_name] d = g.create_dataset(dataset_name, data=self) else: d = g.create_dataset(dataset_name, data=self) for k, v in info.items(): d.attrs[k] = v f.close() @classmethod def from_hdf5(cls, filename, dataset_name=None, group_name=None): r"""Attempts read in and convert a dataset in an hdf5 file into a YTArray. Parameters ---------- filename: string The filename to of the hdf5 file. dataset_name: string The name of the dataset to read from. If the dataset has a units attribute, attempt to infer units as well. group_name: string An optional group to read the arrays from. If not specified, the arrays are datasets at the top level by default. """ import h5py from yt.extern.six.moves import cPickle as pickle if dataset_name is None: dataset_name = 'array_data' f = h5py.File(filename) if group_name is not None: g = f[group_name] else: g = f dataset = g[dataset_name] data = dataset[:] units = dataset.attrs.get('units', '') if 'unit_registry' in dataset.attrs.keys(): unit_lut = pickle.loads(dataset.attrs['unit_registry'].tostring()) else: unit_lut = None f.close() registry = UnitRegistry(lut=unit_lut, add_default_symbols=False) return cls(data, units, registry=registry) # # Start convenience methods # @property def value(self): """Get a copy of the array data as a numpy ndarray""" return np.array(self) v = value @property def ndview(self): """Get a view of the array data.""" return self.ndarray_view() d = ndview @property def unit_quantity(self): """Get a YTQuantity with the same unit as this array and a value of 1.0""" return YTQuantity(1.0, self.units) uq = unit_quantity @property def unit_array(self): """Get a YTArray filled with ones with the same unit and shape as this array""" return	np.ones_like(self)	numpy.ones_like
from __future__ import print_function import numpy as np import matplotlib.pyplot as plt class TwoLayerNet(object): """ A two-layer fully-connected neural network. The net has an input dimension of N, a hidden layer dimension of H, and performs classification over C classes. We train the network with a softmax loss function and L2 regularization on the weight matrices. The network uses a ReLU nonlinearity after the first fully connected layer. In other words, the network has the following architecture: input - fully connected layer - ReLU - fully connected layer - softmax The outputs of the second fully-connected layer are the scores for each class. """ def __init__(self, input_size, hidden_size, output_size, std=1e-4): """ Initialize the model. Weights are initialized to small random values and biases are initialized to zero. Weights and biases are stored in the variable self.params, which is a dictionary with the following keys W1: First layer weights; has shape (D, H) b1: First layer biases; has shape (H,) W2: Second layer weights; has shape (H, C) b2: Second layer biases; has shape (C,) Inputs: - input_size: The dimension D of the input data. - hidden_size: The number of neurons H in the hidden layer. - output_size: The number of classes C. """ self.params = {} self.params['W1'] = std * np.random.randn(input_size, hidden_size) self.params['b1'] = np.zeros(hidden_size) self.params['W2'] = std * np.random.randn(hidden_size, output_size) self.params['b2'] = np.zeros(output_size) def loss(self, X, y=None, reg=0.0): """ Compute the loss and gradients for a two layer fully connected neural network. Inputs: - X: Input data of shape (N, D). Each X[i] is a training sample. - y: Vector of training labels. y[i] is the label for X[i], and each y[i] is an integer in the range 0 <= y[i] < C. This parameter is optional; if it is not passed then we only return scores, and if it is passed then we instead return the loss and gradients. - reg: Regularization strength. Returns: If y is None, return a matrix scores of shape (N, C) where scores[i, c] is the score for class c on input X[i]. If y is not None, instead return a tuple of: - loss: Loss (data loss and regularization loss) for this batch of training samples. - grads: Dictionary mapping parameter names to gradients of those parameters with respect to the loss function; has the same keys as self.params. """ # Unpack variables from the params dictionary W1, b1 = self.params['W1'], self.params['b1'] W2, b2 = self.params['W2'], self.params['b2'] N, D = X.shape # Compute the forward pass scores = None ####################################################################### # TODO: Perform the forward pass, computing the class scores for the # # input. Store the result in the scores variable, which should be an # # array of shape (N, C). # ####################################################################### scores1 = X.dot(W1) + b1 # FC1 X2 = np.maximum(0, scores1) # ReLU FC1 scores = X2.dot(W2) + b2 # FC2 ####################################################################### # END OF YOUR CODE # ####################################################################### # If the targets are not given then jump out, we're done if y is None: return scores scores -= np.max(scores) # Fix Number instability scores_exp = np.exp(scores) probs = scores_exp / np.sum(scores_exp, axis=1, keepdims=True) # Compute the loss loss = None ####################################################################### # TODO: Finish the forward pass, and compute the loss. This should # # include both the data loss and L2 regularization for W1 and W2. # # Store the result in the variable loss, which should be a scalar. Use# # the Softmax classifier loss. # ####################################################################### correct_probs = -np.log(probs[np.arange(N), y]) # L_i = -log(e^correct_score/sum(e^scores))) = -log(correct_probs) loss = np.sum(correct_probs) loss /= N # L2 regularization WRT W1 and W2 loss += reg * (np.sum(W1 * W1) +	np.sum(W2 * W2)	numpy.sum
import numpy as np import sys import os from PIL import Image from visu.helper_functions import save_image from scipy.spatial.transform import Rotation as R from helper import re_quat import copy import torch import numpy as np import k3d class Visualizer(): def __init__(self, p_visu, writer=None): if p_visu[-1] != '/': p_visu = p_visu + '/' self.p_visu = p_visu self.writer = writer if not os.path.exists(self.p_visu): os.makedirs(self.p_visu) def plot_estimated_pose(self, tag, epoch, img, points, trans=[[0, 0, 0]], rot_mat=[[1, 0, 0], [0, 1, 0], [0, 0, 1]], cam_cx=0, cam_cy=0, cam_fx=0, cam_fy=0, store=False, jupyter=False, w=2): """ tag := tensorboard tag epoch := tensorboard epoche store := ture -> stores the image to standard path path := != None creats the path and store to it path/tag.png img:= original_image, [widht,height,RGB] points:= points of the object model [length,x,y,z] trans: [1,3] rot: [3,3] """ img_d = copy.deepcopy(img) points = np.dot(points, rot_mat.T) points = np.add(points, trans[0, :]) for i in range(0, points.shape[0]): p_x = points[i, 0] p_y = points[i, 1] p_z = points[i, 2] u = int(((p_x / p_z) * cam_fx) + cam_cx) v = int(((p_y / p_z) * cam_fy) + cam_cy) try: img_d[v - w:v + w + 1, u - w:u + w + 1, 0] = 0 img_d[v - w:v + w + 1, u - w:u + w + 1, 1] = 255 img_d[v - w:v + w + 1, u - w:u + w + 1, 0] = 0 except: #print("out of bounce") pass if jupyter: display(Image.fromarray(img_d)) if store: #store_ar = (img_d* 255).round().astype(np.uint8) #print("IMAGE D:" ,img_d,img_d.shape ) save_image(img_d, tag=str(epoch) + tag, p_store=self.p_visu) if self.writer is not None: self.writer.add_image(tag, img_d.astype( np.uint8), global_step=epoch, dataformats='HWC') def plot_bounding_box(self, tag, epoch, img, rmin=0, rmax=0, cmin=0, cmax=0, str_width=2, store=False, jupyter=False, b=None): """ tag := tensorboard tag epoch := tensorboard epoche store := ture -> stores the image to standard path path := != None creats the path and store to it path/tag.png img:= original_image, [widht,height,RGB] """ if isinstance(b, dict): rmin = b['rmin'] rmax = b['rmax'] cmin = b['cmin'] cmax = b['cmax'] # ToDo check Input data img_d = np.array(copy.deepcopy(img)) c = [0, 0, 255] rmin_mi = max(0, rmin - str_width) rmin_ma = min(img_d.shape[0], rmin + str_width) rmax_mi = max(0, rmax - str_width) rmax_ma = min(img_d.shape[0], rmax + str_width) cmin_mi = max(0, cmin - str_width) cmin_ma = min(img_d.shape[1], cmin + str_width) cmax_mi = max(0, cmax - str_width) cmax_ma = min(img_d.shape[1], cmax + str_width) img_d[rmin_mi:rmin_ma, cmin:cmax, :] = c img_d[rmax_mi:rmax_ma, cmin:cmax, :] = c img_d[rmin:rmax, cmin_mi:cmin_ma, :] = c img_d[rmin:rmax, cmax_mi:cmax_ma, :] = c print("STORE", store) img_d = img_d.astype(np.uint8) if store: #store_ar = (img_d* 255).round().astype(np.uint8) save_image(img_d, tag=str(epoch) + tag, p_store=self.p_visu) if jupyter: display(Image.fromarray(img_d)) if self.writer is not None: self.writer.add_image(tag, img_d.astype( np.uint8), global_step=epoch, dataformats='HWC') def plot_pcd(x, point_size=0.005, c='g'): """ x: point_nr,3 """ if c == 'b': k = 245 elif c == 'g': k = 25811000 elif c == 'r': k = 11801000 elif c == 'black': k = 2580 else: k = 2580 colors = np.ones(x.shape[0]) * k plot = k3d.plot(name='points') plt_points = k3d.points(x, colors.astype(np.uint32), point_size=point_size) plot += plt_points plt_points.shader = '3d' plot.display() def plot_two_pcd(x, y, point_size=0.005, c1='g', c2='r'): if c1 == 'b': k = 245 elif c1 == 'g': k = 25811000 elif c1 == 'r': k = 11801000 elif c1 == 'black': k = 2580 else: k = 2580 if c2 == 'b': k2 = 245 elif c2 == 'g': k2 = 25811000 elif c2 == 'r': k2 = 11801000 elif c2 == 'black': k2 = 2580 else: k2 = 2580 col1 = np.ones(x.shape[0]) * k col2 =	np.ones(y.shape[0])	numpy.ones
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time =	np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101)	numpy.linspace
import sys import numpy as np from matplotlib import pyplot as pl from rw import WriteGTiff fn = '../pozo-steep-vegetated-pcl.npy' pts = np.load(fn) x, y, z, c = pts[:, 0], pts[:, 1], pts[:, 2], pts[:, 5] ix = (0.2 * (x - x.min())).astype('int') iy = (0.2 * (y - y.min())).astype('int') shape = (100, 100) xb =	np.arange(shape[1]+1)	numpy.arange
import logging import george import numpy as np from robo.priors.default_priors import DefaultPrior from robo.models.gaussian_process import GaussianProcess from robo.models.gaussian_process_mcmc import GaussianProcessMCMC from robo.maximizers.random_sampling import RandomSampling from robo.maximizers.scipy_optimizer import SciPyOptimizer from robo.maximizers.differential_evolution import DifferentialEvolution from robo.solver.bayesian_optimization import BayesianOptimization from robo.acquisition_functions.information_gain import InformationGain from robo.acquisition_functions.ei import EI from robo.acquisition_functions.marginalization import MarginalizationGPMCMC from robo.initial_design import init_latin_hypercube_sampling logger = logging.getLogger(__name__) def entropy_search(objective_function, lower, upper, num_iterations=30, maximizer="random", model="gp_mcmc", n_init=3, output_path=None, rng=None): """ Entropy search for global black box optimization problems. This is a reimplemenation of the entropy search algorithm by Henning and Schuler[1]. [1] Entropy search for information-efficient global optimization. <NAME> and <NAME>. JMLR, (1), 2012. Parameters ---------- objective_function: function The objective function that is minimized. This function gets a numpy array (D,) as input and returns the function value (scalar) lower: np.ndarray (D,) The lower bound of the search space upper: np.ndarray (D,) The upper bound of the search space num_iterations: int The number of iterations (initial design + BO) maximizer: {"random", "scipy", "differential_evolution"} Defines how the acquisition function is maximized. model: {"gp", "gp_mcmc"} The model for the objective function. n_init: int Number of points for the initial design. Make sure that it is <= num_iterations. output_path: string Specifies the path where the intermediate output after each iteration will be saved. If None no output will be saved to disk. rng: numpy.random.RandomState Random number generator Returns ------- dict with all results """ assert upper.shape[0] == lower.shape[0], "Dimension miss match" assert	np.all(lower < upper)	numpy.all
# coding: utf-8 # Licensed under a 3-clause BSD style license - see LICENSE.rst """ Test the Logarithmic Units and Quantities """ from __future__ import (absolute_import, unicode_literals, division, print_function) from ...extern import six from ...extern.six.moves import zip import pickle import itertools import pytest import numpy as np from numpy.testing.utils import assert_allclose from ...tests.helper import assert_quantity_allclose from ... import units as u, constants as c lu_units = [u.dex, u.mag, u.decibel] lu_subclasses = [u.DexUnit, u.MagUnit, u.DecibelUnit] lq_subclasses = [u.Dex, u.Magnitude, u.Decibel] pu_sample = (u.dimensionless_unscaled, u.m, u.g/u.s*2, u.Jy) class TestLogUnitCreation(object): def test_logarithmic_units(self): """Check logarithmic units are set up correctly.""" assert u.dB.to(u.dex) == 0.1 assert u.dex.to(u.mag) == -2.5 assert u.mag.to(u.dB) == -4 @pytest.mark.parametrize('lu_unit, lu_cls', zip(lu_units, lu_subclasses)) def test_callable_units(self, lu_unit, lu_cls): assert isinstance(lu_unit, u.UnitBase) assert callable(lu_unit) assert lu_unit._function_unit_class is lu_cls @pytest.mark.parametrize('lu_unit', lu_units) def test_equality_to_normal_unit_for_dimensionless(self, lu_unit): lu = lu_unit() assert lu == lu._default_function_unit # eg, MagUnit() == u.mag assert lu._default_function_unit == lu # and u.mag == MagUnit() @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_call_units(self, lu_unit, physical_unit): """Create a LogUnit subclass using the callable unit and physical unit, and do basic check that output is right.""" lu1 = lu_unit(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit def test_call_invalid_unit(self): with pytest.raises(TypeError): u.mag([]) with pytest.raises(ValueError): u.mag(u.mag()) @pytest.mark.parametrize('lu_cls, physical_unit', itertools.product( lu_subclasses + [u.LogUnit], pu_sample)) def test_subclass_creation(self, lu_cls, physical_unit): """Create a LogUnit subclass object for given physical unit, and do basic check that output is right.""" lu1 = lu_cls(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit lu2 = lu_cls(physical_unit, function_unit=2lu1._default_function_unit) assert lu2.physical_unit == physical_unit assert lu2.function_unit == u.Unit(2lu2._default_function_unit) with pytest.raises(ValueError): lu_cls(physical_unit, u.m) def test_predefined_magnitudes(): assert_quantity_allclose((-21.1u.STmag).physical, 1.u.erg/u.cm2/u.s/u.AA) assert_quantity_allclose((-48.6u.ABmag).physical, 1.u.erg/u.cm2/u.s/u.Hz) assert_quantity_allclose((0u.M_bol).physical, c.L_bol0) assert_quantity_allclose((0u.m_bol).physical, c.L_bol0/(4.np.pi(10.c.pc)2)) def test_predefined_reinitialisation(): assert u.mag('ST') == u.STmag assert u.mag('AB') == u.ABmag assert u.mag('Bol') == u.M_bol assert u.mag('bol') == u.m_bol def test_predefined_string_roundtrip(): """Ensure roundtripping; see #5015""" with u.magnitude_zero_points.enable(): assert u.Unit(u.STmag.to_string()) == u.STmag assert u.Unit(u.ABmag.to_string()) == u.ABmag assert u.Unit(u.M_bol.to_string()) == u.M_bol assert u.Unit(u.m_bol.to_string()) == u.m_bol def test_inequality(): """Check __ne__ works (regresssion for #5342).""" lu1 = u.mag(u.Jy) lu2 = u.dex(u.Jy) lu3 = u.mag(u.Jy2) lu4 = lu3 - lu1 assert lu1 != lu2 assert lu1 != lu3 assert lu1 == lu4 class TestLogUnitStrings(object): def test_str(self): """Do some spot checks that str, repr, etc. work as expected.""" lu1 = u.mag(u.Jy) assert str(lu1) == 'mag(Jy)' assert repr(lu1) == 'Unit("mag(Jy)")' assert lu1.to_string('generic') == 'mag(Jy)' with pytest.raises(ValueError): lu1.to_string('fits') lu2 = u.dex() assert str(lu2) == 'dex' assert repr(lu2) == 'Unit("dex(1)")' assert lu2.to_string() == 'dex(1)' lu3 = u.MagUnit(u.Jy, function_unit=2u.mag) assert str(lu3) == '2 mag(Jy)' assert repr(lu3) == 'MagUnit("Jy", unit="2 mag")' assert lu3.to_string() == '2 mag(Jy)' lu4 = u.mag(u.ct) assert lu4.to_string('generic') == 'mag(ct)' assert lu4.to_string('latex') == ('$\\mathrm{mag}$$\\mathrm{\\left( ' '\\mathrm{ct} \\right)}$') assert lu4._repr_latex_() == lu4.to_string('latex') class TestLogUnitConversion(object): @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_physical_unit_conversion(self, lu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to their non-log counterparts.""" lu1 = lu_unit(physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(physical_unit, 0.) == 1. assert physical_unit.is_equivalent(lu1) assert physical_unit.to(lu1, 1.) == 0. pu = u.Unit(8.physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(pu, 0.) == 0.125 assert pu.is_equivalent(lu1) assert_allclose(pu.to(lu1, 0.125), 0., atol=1.e-15) # Check we round-trip. value = np.linspace(0., 10., 6) assert_allclose(pu.to(lu1, lu1.to(pu, value)), value, atol=1.e-15) # And that we're not just returning True all the time. pu2 = u.g assert not lu1.is_equivalent(pu2) with pytest.raises(u.UnitsError): lu1.to(pu2) assert not pu2.is_equivalent(lu1) with pytest.raises(u.UnitsError): pu2.to(lu1) @pytest.mark.parametrize('lu_unit', lu_units) def test_container_unit_conversion(self, lu_unit): """Check that conversion to logarithmic units (u.mag, u.dB, u.dex) is only possible when the physical unit is dimensionless.""" values = np.linspace(0., 10., 6) lu1 = lu_unit(u.dimensionless_unscaled) assert lu1.is_equivalent(lu1.function_unit) assert_allclose(lu1.to(lu1.function_unit, values), values) lu2 = lu_unit(u.Jy) assert not lu2.is_equivalent(lu2.function_unit) with pytest.raises(u.UnitsError): lu2.to(lu2.function_unit, values) @pytest.mark.parametrize( 'flu_unit, tlu_unit, physical_unit', itertools.product(lu_units, lu_units, pu_sample)) def test_subclass_conversion(self, flu_unit, tlu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to each other if they correspond to equivalent physical units.""" values = np.linspace(0., 10., 6) flu = flu_unit(physical_unit) tlu = tlu_unit(physical_unit) assert flu.is_equivalent(tlu) assert_allclose(flu.to(tlu), flu.function_unit.to(tlu.function_unit)) assert_allclose(flu.to(tlu, values), values * flu.function_unit.to(tlu.function_unit)) tlu2 = tlu_unit(u.Unit(100.physical_unit)) assert flu.is_equivalent(tlu2) # Check that we round-trip. assert_allclose(flu.to(tlu2, tlu2.to(flu, values)), values, atol=1.e-15) tlu3 = tlu_unit(physical_unit.to_system(u.si)[0]) assert flu.is_equivalent(tlu3) assert_allclose(flu.to(tlu3, tlu3.to(flu, values)), values, atol=1.e-15) tlu4 = tlu_unit(u.g) assert not flu.is_equivalent(tlu4) with pytest.raises(u.UnitsError): flu.to(tlu4, values) def test_unit_decomposition(self): lu = u.mag(u.Jy) assert lu.decompose() == u.mag(u.Jy.decompose()) assert lu.decompose().physical_unit.bases == [u.kg, u.s] assert lu.si == u.mag(u.Jy.si) assert lu.si.physical_unit.bases == [u.kg, u.s] assert lu.cgs == u.mag(u.Jy.cgs) assert lu.cgs.physical_unit.bases == [u.g, u.s] def test_unit_multiple_possible_equivalencies(self): lu = u.mag(u.Jy) assert lu.is_equivalent(pu_sample) class TestLogUnitArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other units is only possible when the physical unit is dimensionless, and that this turns the unit into a normal one.""" lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 u.m with pytest.raises(u.UnitsError): u.m * lu1 with pytest.raises(u.UnitsError): lu1 / lu1 for unit in (u.dimensionless_unscaled, u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lu1 / unit lu2 = u.mag(u.dimensionless_unscaled) with pytest.raises(u.UnitsError): lu2 * lu1 with pytest.raises(u.UnitsError): lu2 / lu1 # But dimensionless_unscaled can be cancelled. assert lu2 / lu2 == u.dimensionless_unscaled # With dimensionless, normal units are OK, but we return a plain unit. tf = lu2 * u.m tr = u.m * lu2 for t in (tf, tr): assert not isinstance(t, type(lu2)) assert t == lu2.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lu2.physical_unit) # Now we essentially have a LogUnit with a prefactor of 100, # so should be equivalent again. t = tf / u.cm with u.set_enabled_equivalencies(u.logarithmic()): assert t.is_equivalent(lu2.function_unit) assert_allclose(t.to(u.dimensionless_unscaled, np.arange(3.)/100.), lu2.to(lu2.physical_unit, np.arange(3.))) # If we effectively remove lu1, a normal unit should be returned. t2 = tf / lu2 assert not isinstance(t2, type(lu2)) assert t2 == u.m t3 = tf / lu2.function_unit assert not isinstance(t3, type(lu2)) assert t3 == u.m # For completeness, also ensure non-sensical operations fail with pytest.raises(TypeError): lu1 * object() with pytest.raises(TypeError): slice(None) * lu1 with pytest.raises(TypeError): lu1 / [] with pytest.raises(TypeError): 1 / lu1 @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogUnits to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (such as mag2) is incompatible.""" lu1 = u.mag(u.Jy) if power == 0: assert lu1 power == u.dimensionless_unscaled elif power == 1: assert lu1 power == lu1 else: with pytest.raises(u.UnitsError): lu1 power # With dimensionless, though, it works, but returns a normal unit. lu2 = u.mag(u.dimensionless_unscaled) t = lu2power if power == 0: assert t == u.dimensionless_unscaled elif power == 1: assert t == lu2 else: assert not isinstance(t, type(lu2)) assert t == lu2.function_unitpower # also check we roundtrip t2 = t*(1./power) assert t2 == lu2.function_unit with u.set_enabled_equivalencies(u.logarithmic()): assert_allclose(t2.to(u.dimensionless_unscaled, np.arange(3.)), lu2.to(lu2.physical_unit, np.arange(3.))) @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 + other with pytest.raises(u.UnitsError): lu1 - other with pytest.raises(u.UnitsError): other - lu1 def test_addition_subtraction_to_non_units_fails(self): lu1 = u.mag(u.Jy) with pytest.raises(TypeError): lu1 + 1. with pytest.raises(TypeError): lu1 - [1., 2., 3.] @pytest.mark.parametrize( 'other', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2u.mag), u.MagUnit('', 2.u.mag))) def test_addition_subtraction(self, other): """Check physical units are changed appropriately""" lu1 = u.mag(u.Jy) other_pu = getattr(other, 'physical_unit', u.dimensionless_unscaled) lu_sf = lu1 + other assert lu_sf.is_equivalent(lu1.physical_unit other_pu) lu_sr = other + lu1 assert lu_sr.is_equivalent(lu1.physical_unit * other_pu) lu_df = lu1 - other assert lu_df.is_equivalent(lu1.physical_unit / other_pu) lu_dr = other - lu1 assert lu_dr.is_equivalent(other_pu / lu1.physical_unit) def test_complicated_addition_subtraction(self): """for fun, a more complicated example of addition and subtraction""" dm0 = u.Unit('DM', 1./(4.np.pi(10.u.pc)2)) lu_dm = u.mag(dm0) lu_absST = u.STmag - lu_dm assert lu_absST.is_equivalent(u.erg/u.s/u.AA) def test_neg_pos(self): lu1 = u.mag(u.Jy) neg_lu = -lu1 assert neg_lu != lu1 assert neg_lu.physical_unit == u.Jy-1 assert -neg_lu == lu1 pos_lu = +lu1 assert pos_lu is not lu1 assert pos_lu == lu1 def test_pickle(): lu1 = u.dex(u.cm/u.s2) s = pickle.dumps(lu1) lu2 = pickle.loads(s) assert lu1 == lu2 def test_hashable(): lu1 = u.dB(u.mW) lu2 = u.dB(u.m) lu3 = u.dB(u.mW) assert hash(lu1) != hash(lu2) assert hash(lu1) == hash(lu3) luset = {lu1, lu2, lu3} assert len(luset) == 2 class TestLogQuantityCreation(object): @pytest.mark.parametrize('lq, lu', zip(lq_subclasses + [u.LogQuantity], lu_subclasses + [u.LogUnit])) def test_logarithmic_quantities(self, lq, lu): """Check logarithmic quantities are all set up correctly""" assert lq._unit_class == lu assert type(lu()._quantity_class(1.)) is lq @pytest.mark.parametrize('lq_cls, physical_unit', itertools.product(lq_subclasses, pu_sample)) def test_subclass_creation(self, lq_cls, physical_unit): """Create LogQuantity subclass objects for some physical units, and basic check on transformations""" value = np.arange(1., 10.) log_q = lq_cls(value physical_unit) assert log_q.unit.physical_unit == physical_unit assert log_q.unit.function_unit == log_q.unit._default_function_unit assert_allclose(log_q.physical.value, value) with pytest.raises(ValueError): lq_cls(value, physical_unit) @pytest.mark.parametrize( 'unit', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2u.mag), u.MagUnit('', 2.u.mag), u.MagUnit(u.Jy, -1u.mag), u.MagUnit(u.m, -2.u.mag))) def test_different_units(self, unit): q = u.Magnitude(1.23, unit) assert q.unit.function_unit == getattr(unit, 'function_unit', unit) assert q.unit.physical_unit is getattr(unit, 'physical_unit', u.dimensionless_unscaled) @pytest.mark.parametrize('value, unit', ( (1.u.mag(u.Jy), None), (1.u.dex(u.Jy), None), (1.u.mag(u.W/u.m2/u.Hz), u.mag(u.Jy)), (1.u.dex(u.W/u.m*2/u.Hz), u.mag(u.Jy)))) def test_function_values(self, value, unit): lq = u.Magnitude(value, unit) assert lq == value assert lq.unit.function_unit == u.mag assert lq.unit.physical_unit == getattr(unit, 'physical_unit', value.unit.physical_unit) @pytest.mark.parametrize( 'unit', (u.mag(), u.mag(u.Jy), u.mag(u.m), u.MagUnit('', 2.u.mag), u.MagUnit(u.Jy, -1u.mag), u.MagUnit(u.m, -2.u.mag))) def test_indirect_creation(self, unit): q1 = 2.5 * unit assert isinstance(q1, u.Magnitude) assert q1.value == 2.5 assert q1.unit == unit pv = 100. * unit.physical_unit q2 = unit * pv assert q2.unit == unit assert q2.unit.physical_unit == pv.unit assert q2.to_value(unit.physical_unit) == 100. assert (q2._function_view / u.mag).to_value(1) == -5. q3 = unit / 0.4 assert q3 == q1 def test_from_view(self): # Cannot view a physical quantity as a function quantity, since the # values would change. q = [100., 1000.] * u.cm/u.s*2 with pytest.raises(TypeError): q.view(u.Dex) # But fine if we have the right magnitude. q = [2., 3.] u.dex lq = q.view(u.Dex) assert isinstance(lq, u.Dex) assert lq.unit.physical_unit == u.dimensionless_unscaled assert np.all(q == lq) def test_using_quantity_class(self): """Check that we can use Quantity if we have subok=True""" # following issue #5851 lu = u.dex(u.AA) with pytest.raises(u.UnitTypeError): u.Quantity(1., lu) q = u.Quantity(1., lu, subok=True) assert type(q) is lu._quantity_class def test_conversion_to_and_from_physical_quantities(): """Ensures we can convert from regular quantities.""" mst = [10., 12., 14.] * u.STmag flux_lambda = mst.physical mst_roundtrip = flux_lambda.to(u.STmag) # check we return a logquantity; see #5178. assert isinstance(mst_roundtrip, u.Magnitude) assert mst_roundtrip.unit == mst.unit assert_allclose(mst_roundtrip.value, mst.value) wave = [4956.8, 4959.55, 4962.3] * u.AA flux_nu = mst.to(u.Jy, equivalencies=u.spectral_density(wave)) mst_roundtrip2 = flux_nu.to(u.STmag, u.spectral_density(wave)) assert isinstance(mst_roundtrip2, u.Magnitude) assert mst_roundtrip2.unit == mst.unit	assert_allclose(mst_roundtrip2.value, mst.value)	numpy.testing.utils.assert_allclose
"""Test the search module""" from collections.abc import Iterable, Sized from io import StringIO from itertools import chain, product from functools import partial import pickle import sys from types import GeneratorType import re import numpy as np import scipy.sparse as sp import pytest from sklearn.utils.fixes import sp_version from sklearn.utils._testing import assert_raises from sklearn.utils._testing import assert_warns from sklearn.utils._testing import assert_warns_message from sklearn.utils._testing import assert_raise_message from sklearn.utils._testing import assert_array_equal from sklearn.utils._testing import assert_array_almost_equal from sklearn.utils._testing import assert_allclose from sklearn.utils._testing import assert_almost_equal from sklearn.utils._testing import ignore_warnings from sklearn.utils._mocking import CheckingClassifier, MockDataFrame from scipy.stats import bernoulli, expon, uniform from sklearn.base import BaseEstimator, ClassifierMixin from sklearn.base import clone from sklearn.exceptions import NotFittedError from sklearn.datasets import make_classification from sklearn.datasets import make_blobs from sklearn.datasets import make_multilabel_classification from sklearn.model_selection import fit_grid_point from sklearn.model_selection import train_test_split from sklearn.model_selection import KFold from sklearn.model_selection import StratifiedKFold from sklearn.model_selection import StratifiedShuffleSplit from sklearn.model_selection import LeaveOneGroupOut from sklearn.model_selection import LeavePGroupsOut from sklearn.model_selection import GroupKFold from sklearn.model_selection import GroupShuffleSplit from sklearn.model_selection import GridSearchCV from sklearn.model_selection import RandomizedSearchCV from sklearn.model_selection import ParameterGrid from sklearn.model_selection import ParameterSampler from sklearn.model_selection._search import BaseSearchCV from sklearn.model_selection._validation import FitFailedWarning from sklearn.svm import LinearSVC, SVC from sklearn.tree import DecisionTreeRegressor from sklearn.tree import DecisionTreeClassifier from sklearn.cluster import KMeans from sklearn.neighbors import KernelDensity from sklearn.neighbors import KNeighborsClassifier from sklearn.metrics import f1_score from sklearn.metrics import recall_score from sklearn.metrics import accuracy_score from sklearn.metrics import make_scorer from sklearn.metrics import roc_auc_score from sklearn.metrics.pairwise import euclidean_distances from sklearn.impute import SimpleImputer from sklearn.pipeline import Pipeline from sklearn.linear_model import Ridge, SGDClassifier, LinearRegression from sklearn.experimental import enable_hist_gradient_boosting # noqa from sklearn.ensemble import HistGradientBoostingClassifier from sklearn.model_selection.tests.common import OneTimeSplitter # Neither of the following two estimators inherit from BaseEstimator, # to test hyperparameter search on user-defined classifiers. class MockClassifier: """Dummy classifier to test the parameter search algorithms""" def __init__(self, foo_param=0): self.foo_param = foo_param def fit(self, X, Y): assert len(X) == len(Y) self.classes_ = np.unique(Y) return self def predict(self, T): return T.shape[0] def transform(self, X): return X + self.foo_param def inverse_transform(self, X): return X - self.foo_param predict_proba = predict predict_log_proba = predict decision_function = predict def score(self, X=None, Y=None): if self.foo_param > 1: score = 1. else: score = 0. return score def get_params(self, deep=False): return {'foo_param': self.foo_param} def set_params(self, *params): self.foo_param = params['foo_param'] return self class LinearSVCNoScore(LinearSVC): """An LinearSVC classifier that has no score method.""" @property def score(self): raise AttributeError X = np.array([[-1, -1], [-2, -1], [1, 1], [2, 1]]) y = np.array([1, 1, 2, 2]) def assert_grid_iter_equals_getitem(grid): assert list(grid) == [grid[i] for i in range(len(grid))] @pytest.mark.parametrize("klass", [ParameterGrid, partial(ParameterSampler, n_iter=10)]) @pytest.mark.parametrize( "input, error_type, error_message", [(0, TypeError, r'Parameter . is not a dict or a list \(0\)'), ([{'foo': [0]}, 0], TypeError, r'Parameter .* is not a dict \(0\)'), ({'foo': 0}, TypeError, "Parameter.* value is not iterable ." r"\(key='foo', value=0\)")] ) def test_validate_parameter_input(klass, input, error_type, error_message): with pytest.raises(error_type, match=error_message): klass(input) def test_parameter_grid(): # Test basic properties of ParameterGrid. params1 = {"foo": [1, 2, 3]} grid1 = ParameterGrid(params1) assert isinstance(grid1, Iterable) assert isinstance(grid1, Sized) assert len(grid1) == 3 assert_grid_iter_equals_getitem(grid1) params2 = {"foo": [4, 2], "bar": ["ham", "spam", "eggs"]} grid2 = ParameterGrid(params2) assert len(grid2) == 6 # loop to assert we can iterate over the grid multiple times for i in range(2): # tuple + chain transforms {"a": 1, "b": 2} to ("a", 1, "b", 2) points = set(tuple(chain((sorted(p.items())))) for p in grid2) assert (points == set(("bar", x, "foo", y) for x, y in product(params2["bar"], params2["foo"]))) assert_grid_iter_equals_getitem(grid2) # Special case: empty grid (useful to get default estimator settings) empty = ParameterGrid({}) assert len(empty) == 1 assert list(empty) == [{}] assert_grid_iter_equals_getitem(empty) assert_raises(IndexError, lambda: empty[1]) has_empty = ParameterGrid([{'C': [1, 10]}, {}, {'C': [.5]}]) assert len(has_empty) == 4 assert list(has_empty) == [{'C': 1}, {'C': 10}, {}, {'C': .5}] assert_grid_iter_equals_getitem(has_empty) def test_grid_search(): # Test that the best estimator contains the right value for foo_param clf = MockClassifier() grid_search = GridSearchCV(clf, {'foo_param': [1, 2, 3]}, cv=3, verbose=3) # make sure it selects the smallest parameter in case of ties old_stdout = sys.stdout sys.stdout = StringIO() grid_search.fit(X, y) sys.stdout = old_stdout assert grid_search.best_estimator_.foo_param == 2 assert_array_equal(grid_search.cv_results_["param_foo_param"].data, [1, 2, 3]) # Smoke test the score etc: grid_search.score(X, y) grid_search.predict_proba(X) grid_search.decision_function(X) grid_search.transform(X) # Test exception handling on scoring grid_search.scoring = 'sklearn' assert_raises(ValueError, grid_search.fit, X, y) def test_grid_search_pipeline_steps(): # check that parameters that are estimators are cloned before fitting pipe = Pipeline([('regressor', LinearRegression())]) param_grid = {'regressor': [LinearRegression(), Ridge()]} grid_search = GridSearchCV(pipe, param_grid, cv=2) grid_search.fit(X, y) regressor_results = grid_search.cv_results_['param_regressor'] assert isinstance(regressor_results[0], LinearRegression) assert isinstance(regressor_results[1], Ridge) assert not hasattr(regressor_results[0], 'coef_') assert not hasattr(regressor_results[1], 'coef_') assert regressor_results[0] is not grid_search.best_estimator_ assert regressor_results[1] is not grid_search.best_estimator_ # check that we didn't modify the parameter grid that was passed assert not hasattr(param_grid['regressor'][0], 'coef_') assert not hasattr(param_grid['regressor'][1], 'coef_') @pytest.mark.parametrize("SearchCV", [GridSearchCV, RandomizedSearchCV]) def test_SearchCV_with_fit_params(SearchCV): X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) clf = CheckingClassifier(expected_fit_params=['spam', 'eggs']) searcher = SearchCV( clf, {'foo_param': [1, 2, 3]}, cv=2, error_score="raise" ) # The CheckingClassifier generates an assertion error if # a parameter is missing or has length != len(X). err_msg = r"Expected fit parameter\(s\) \['eggs'\] not seen." with pytest.raises(AssertionError, match=err_msg): searcher.fit(X, y, spam=np.ones(10)) err_msg = "Fit parameter spam has length 1; expected" with pytest.raises(AssertionError, match=err_msg): searcher.fit(X, y, spam=np.ones(1), eggs=np.zeros(10)) searcher.fit(X, y, spam=np.ones(10), eggs=np.zeros(10)) @ignore_warnings def test_grid_search_no_score(): # Test grid-search on classifier that has no score function. clf = LinearSVC(random_state=0) X, y = make_blobs(random_state=0, centers=2) Cs = [.1, 1, 10] clf_no_score = LinearSVCNoScore(random_state=0) grid_search = GridSearchCV(clf, {'C': Cs}, scoring='accuracy') grid_search.fit(X, y) grid_search_no_score = GridSearchCV(clf_no_score, {'C': Cs}, scoring='accuracy') # smoketest grid search grid_search_no_score.fit(X, y) # check that best params are equal assert grid_search_no_score.best_params_ == grid_search.best_params_ # check that we can call score and that it gives the correct result assert grid_search.score(X, y) == grid_search_no_score.score(X, y) # giving no scoring function raises an error grid_search_no_score = GridSearchCV(clf_no_score, {'C': Cs}) assert_raise_message(TypeError, "no scoring", grid_search_no_score.fit, [[1]]) def test_grid_search_score_method(): X, y = make_classification(n_samples=100, n_classes=2, flip_y=.2, random_state=0) clf = LinearSVC(random_state=0) grid = {'C': [.1]} search_no_scoring = GridSearchCV(clf, grid, scoring=None).fit(X, y) search_accuracy = GridSearchCV(clf, grid, scoring='accuracy').fit(X, y) search_no_score_method_auc = GridSearchCV(LinearSVCNoScore(), grid, scoring='roc_auc' ).fit(X, y) search_auc = GridSearchCV(clf, grid, scoring='roc_auc').fit(X, y) # Check warning only occurs in situation where behavior changed: # estimator requires score method to compete with scoring parameter score_no_scoring = search_no_scoring.score(X, y) score_accuracy = search_accuracy.score(X, y) score_no_score_auc = search_no_score_method_auc.score(X, y) score_auc = search_auc.score(X, y) # ensure the test is sane assert score_auc < 1.0 assert score_accuracy < 1.0 assert score_auc != score_accuracy assert_almost_equal(score_accuracy, score_no_scoring) assert_almost_equal(score_auc, score_no_score_auc) def test_grid_search_groups(): # Check if ValueError (when groups is None) propagates to GridSearchCV # And also check if groups is correctly passed to the cv object rng = np.random.RandomState(0) X, y = make_classification(n_samples=15, n_classes=2, random_state=0) groups = rng.randint(0, 3, 15) clf = LinearSVC(random_state=0) grid = {'C': [1]} group_cvs = [LeaveOneGroupOut(), LeavePGroupsOut(2), GroupKFold(n_splits=3), GroupShuffleSplit()] for cv in group_cvs: gs = GridSearchCV(clf, grid, cv=cv) assert_raise_message(ValueError, "The 'groups' parameter should not be None.", gs.fit, X, y) gs.fit(X, y, groups=groups) non_group_cvs = [StratifiedKFold(), StratifiedShuffleSplit()] for cv in non_group_cvs: gs = GridSearchCV(clf, grid, cv=cv) # Should not raise an error gs.fit(X, y) def test_classes__property(): # Test that classes_ property matches best_estimator_.classes_ X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) Cs = [.1, 1, 10] grid_search = GridSearchCV(LinearSVC(random_state=0), {'C': Cs}) grid_search.fit(X, y) assert_array_equal(grid_search.best_estimator_.classes_, grid_search.classes_) # Test that regressors do not have a classes_ attribute grid_search = GridSearchCV(Ridge(), {'alpha': [1.0, 2.0]}) grid_search.fit(X, y) assert not hasattr(grid_search, 'classes_') # Test that the grid searcher has no classes_ attribute before it's fit grid_search = GridSearchCV(LinearSVC(random_state=0), {'C': Cs}) assert not hasattr(grid_search, 'classes_') # Test that the grid searcher has no classes_ attribute without a refit grid_search = GridSearchCV(LinearSVC(random_state=0), {'C': Cs}, refit=False) grid_search.fit(X, y) assert not hasattr(grid_search, 'classes_') def test_trivial_cv_results_attr(): # Test search over a "grid" with only one point. clf = MockClassifier() grid_search = GridSearchCV(clf, {'foo_param': [1]}, cv=3) grid_search.fit(X, y) assert hasattr(grid_search, "cv_results_") random_search = RandomizedSearchCV(clf, {'foo_param': [0]}, n_iter=1, cv=3) random_search.fit(X, y) assert hasattr(grid_search, "cv_results_") def test_no_refit(): # Test that GSCV can be used for model selection alone without refitting clf = MockClassifier() for scoring in [None, ['accuracy', 'precision']]: grid_search = GridSearchCV( clf, {'foo_param': [1, 2, 3]}, refit=False, cv=3 ) grid_search.fit(X, y) assert not hasattr(grid_search, "best_estimator_") and \ hasattr(grid_search, "best_index_") and \ hasattr(grid_search, "best_params_") # Make sure the functions predict/transform etc raise meaningful # error messages for fn_name in ('predict', 'predict_proba', 'predict_log_proba', 'transform', 'inverse_transform'): assert_raise_message(NotFittedError, ('refit=False. %s is available only after ' 'refitting on the best parameters' % fn_name), getattr(grid_search, fn_name), X) # Test that an invalid refit param raises appropriate error messages for refit in ["", 5, True, 'recall', 'accuracy']: assert_raise_message(ValueError, "For multi-metric scoring, the " "parameter refit must be set to a scorer key", GridSearchCV(clf, {}, refit=refit, scoring={'acc': 'accuracy', 'prec': 'precision'} ).fit, X, y) def test_grid_search_error(): # Test that grid search will capture errors on data with different length X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) assert_raises(ValueError, cv.fit, X_[:180], y_) def test_grid_search_one_grid_point(): X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) param_dict = {"C": [1.0], "kernel": ["rbf"], "gamma": [0.1]} clf = SVC(gamma='auto') cv = GridSearchCV(clf, param_dict) cv.fit(X_, y_) clf = SVC(C=1.0, kernel="rbf", gamma=0.1) clf.fit(X_, y_) assert_array_equal(clf.dual_coef_, cv.best_estimator_.dual_coef_) def test_grid_search_when_param_grid_includes_range(): # Test that the best estimator contains the right value for foo_param clf = MockClassifier() grid_search = None grid_search = GridSearchCV(clf, {'foo_param': range(1, 4)}, cv=3) grid_search.fit(X, y) assert grid_search.best_estimator_.foo_param == 2 def test_grid_search_bad_param_grid(): param_dict = {"C": 1} clf = SVC(gamma='auto') assert_raise_message( ValueError, "Parameter grid for parameter (C) needs to" " be a list or numpy array, but got (<class 'int'>)." " Single values need to be wrapped in a list" " with one element.", GridSearchCV, clf, param_dict) param_dict = {"C": []} clf = SVC() assert_raise_message( ValueError, "Parameter values for parameter (C) need to be a non-empty sequence.", GridSearchCV, clf, param_dict) param_dict = {"C": "1,2,3"} clf = SVC(gamma='auto') assert_raise_message( ValueError, "Parameter grid for parameter (C) needs to" " be a list or numpy array, but got (<class 'str'>)." " Single values need to be wrapped in a list" " with one element.", GridSearchCV, clf, param_dict) param_dict = {"C": np.ones((3, 2))} clf = SVC() assert_raises(ValueError, GridSearchCV, clf, param_dict) def test_grid_search_sparse(): # Test that grid search works with both dense and sparse matrices X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) cv.fit(X_[:180], y_[:180]) y_pred = cv.predict(X_[180:]) C = cv.best_estimator_.C X_ = sp.csr_matrix(X_) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) cv.fit(X_[:180].tocoo(), y_[:180]) y_pred2 = cv.predict(X_[180:]) C2 = cv.best_estimator_.C assert np.mean(y_pred == y_pred2) >= .9 assert C == C2 def test_grid_search_sparse_scoring(): X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}, scoring="f1") cv.fit(X_[:180], y_[:180]) y_pred = cv.predict(X_[180:]) C = cv.best_estimator_.C X_ = sp.csr_matrix(X_) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}, scoring="f1") cv.fit(X_[:180], y_[:180]) y_pred2 = cv.predict(X_[180:]) C2 = cv.best_estimator_.C assert_array_equal(y_pred, y_pred2) assert C == C2 # Smoke test the score # np.testing.assert_allclose(f1_score(cv.predict(X_[:180]), y[:180]), # cv.score(X_[:180], y[:180])) # test loss where greater is worse def f1_loss(y_true_, y_pred_): return -f1_score(y_true_, y_pred_) F1Loss = make_scorer(f1_loss, greater_is_better=False) cv = GridSearchCV(clf, {'C': [0.1, 1.0]}, scoring=F1Loss) cv.fit(X_[:180], y_[:180]) y_pred3 = cv.predict(X_[180:]) C3 = cv.best_estimator_.C assert C == C3 assert_array_equal(y_pred, y_pred3) def test_grid_search_precomputed_kernel(): # Test that grid search works when the input features are given in the # form of a precomputed kernel matrix X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) # compute the training kernel matrix corresponding to the linear kernel K_train = np.dot(X_[:180], X_[:180].T) y_train = y_[:180] clf = SVC(kernel='precomputed') cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) cv.fit(K_train, y_train) assert cv.best_score_ >= 0 # compute the test kernel matrix K_test = np.dot(X_[180:], X_[:180].T) y_test = y_[180:] y_pred = cv.predict(K_test) assert np.mean(y_pred == y_test) >= 0 # test error is raised when the precomputed kernel is not array-like # or sparse assert_raises(ValueError, cv.fit, K_train.tolist(), y_train) def test_grid_search_precomputed_kernel_error_nonsquare(): # Test that grid search returns an error with a non-square precomputed # training kernel matrix K_train =	np.zeros((10, 20))	numpy.zeros
from abc import ABCMeta, abstractmethod import os from vmaf.tools.misc import make_absolute_path, run_process from vmaf.tools.stats import ListStats __copyright__ = "Copyright 2016-2018, Netflix, Inc." __license__ = "Apache, Version 2.0" import re import numpy as np import ast from vmaf import ExternalProgramCaller, to_list from vmaf.config import VmafConfig, VmafExternalConfig from vmaf.core.executor import Executor from vmaf.core.result import Result from vmaf.tools.reader import YuvReader class FeatureExtractor(Executor): """ FeatureExtractor takes in a list of assets, and run feature extraction on them, and return a list of corresponding results. A FeatureExtractor must specify a unique type and version combination (by the TYPE and VERSION attribute), so that the Result generated by it can be identified. A derived class of FeatureExtractor must: 1) Override TYPE and VERSION 2) Override _generate_result(self, asset), which call a command-line executable and generate feature scores in a log file. 3) Override _get_feature_scores(self, asset), which read the feature scores from the log file, and return the scores in a dictionary format. For an example, follow VmafFeatureExtractor. """ __metaclass__ = ABCMeta @property @abstractmethod def ATOM_FEATURES(self): raise NotImplementedError def _read_result(self, asset): result = {} result.update(self._get_feature_scores(asset)) executor_id = self.executor_id return Result(asset, executor_id, result) @classmethod def get_scores_key(cls, atom_feature): return "{type}_{atom_feature}_scores".format( type=cls.TYPE, atom_feature=atom_feature) @classmethod def get_score_key(cls, atom_feature): return "{type}_{atom_feature}_score".format( type=cls.TYPE, atom_feature=atom_feature) def _get_feature_scores(self, asset): # routine to read the feature scores from the log file, and return # the scores in a dictionary format. log_file_path = self._get_log_file_path(asset) atom_feature_scores_dict = {} atom_feature_idx_dict = {} for atom_feature in self.ATOM_FEATURES: atom_feature_scores_dict[atom_feature] = [] atom_feature_idx_dict[atom_feature] = 0 with open(log_file_path, 'rt') as log_file: for line in log_file.readlines(): for atom_feature in self.ATOM_FEATURES: re_template = "{af}: ([0-9]+) ([a-zA-Z0-9.-]+)".format(af=atom_feature) mo = re.match(re_template, line) if mo: cur_idx = int(mo.group(1)) assert cur_idx == atom_feature_idx_dict[atom_feature] # parse value, allowing NaN and inf val = float(mo.group(2)) if np.isnan(val) or np.isinf(val): val = None atom_feature_scores_dict[atom_feature].append(val) atom_feature_idx_dict[atom_feature] += 1 continue len_score = len(atom_feature_scores_dict[self.ATOM_FEATURES[0]]) assert len_score != 0 for atom_feature in self.ATOM_FEATURES[1:]: assert len_score == len(atom_feature_scores_dict[atom_feature]), \ "Feature data possibly corrupt. Run cleanup script and try again." feature_result = {} for atom_feature in self.ATOM_FEATURES: scores_key = self.get_scores_key(atom_feature) feature_result[scores_key] = atom_feature_scores_dict[atom_feature] return feature_result class VmafFeatureExtractor(FeatureExtractor): TYPE = "VMAF_feature" # VERSION = '0.1' # vmaf_study; Anush's VIF fix # VERSION = '0.2' # expose vif_num, vif_den, adm_num, adm_den, anpsnr # VERSION = '0.2.1' # expose vif num/den of each scale # VERSION = '0.2.2' # adm abs-->fabs, corrected border handling, uniform reading with option of offset for input YUV, updated VIF corner case # VERSION = '0.2.2b' # expose adm_den/num_scalex # VERSION = '0.2.3' # AVX for VMAF convolution; update adm features by folding noise floor into per coef # VERSION = '0.2.4' # Fix a bug in adm feature passing scale into dwt_quant_step # VERSION = '0.2.4b' # Modify by adding ADM noise floor outside cube root; add derived feature motion2 VERSION = '0.2.4c' # Modify by moving motion2 to c code ATOM_FEATURES = ['vif', 'adm', 'ansnr', 'motion', 'motion2', 'vif_num', 'vif_den', 'adm_num', 'adm_den', 'anpsnr', 'vif_num_scale0', 'vif_den_scale0', 'vif_num_scale1', 'vif_den_scale1', 'vif_num_scale2', 'vif_den_scale2', 'vif_num_scale3', 'vif_den_scale3', 'adm_num_scale0', 'adm_den_scale0', 'adm_num_scale1', 'adm_den_scale1', 'adm_num_scale2', 'adm_den_scale2', 'adm_num_scale3', 'adm_den_scale3', ] DERIVED_ATOM_FEATURES = ['vif_scale0', 'vif_scale1', 'vif_scale2', 'vif_scale3', 'vif2', 'adm2', 'adm3', 'adm_scale0', 'adm_scale1', 'adm_scale2', 'adm_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vmaf_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VmafFeatureExtractor, cls)._post_process_result(result) # adm2 = # (adm_num + ADM2_CONSTANT) / (adm_den + ADM2_CONSTANT) adm2_scores_key = cls.get_scores_key('adm2') adm_num_scores_key = cls.get_scores_key('adm_num') adm_den_scores_key = cls.get_scores_key('adm_den') result.result_dict[adm2_scores_key] = list( (np.array(result.result_dict[adm_num_scores_key]) + cls.ADM2_CONSTANT) / (np.array(result.result_dict[adm_den_scores_key]) + cls.ADM2_CONSTANT) ) # vif_scalei = vif_num_scalei / vif_den_scalei, i = 0, 1, 2, 3 vif_num_scale0_scores_key = cls.get_scores_key('vif_num_scale0') vif_den_scale0_scores_key = cls.get_scores_key('vif_den_scale0') vif_num_scale1_scores_key = cls.get_scores_key('vif_num_scale1') vif_den_scale1_scores_key = cls.get_scores_key('vif_den_scale1') vif_num_scale2_scores_key = cls.get_scores_key('vif_num_scale2') vif_den_scale2_scores_key = cls.get_scores_key('vif_den_scale2') vif_num_scale3_scores_key = cls.get_scores_key('vif_num_scale3') vif_den_scale3_scores_key = cls.get_scores_key('vif_den_scale3') vif_scale0_scores_key = cls.get_scores_key('vif_scale0') vif_scale1_scores_key = cls.get_scores_key('vif_scale1') vif_scale2_scores_key = cls.get_scores_key('vif_scale2') vif_scale3_scores_key = cls.get_scores_key('vif_scale3') result.result_dict[vif_scale0_scores_key] = list( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) ) result.result_dict[vif_scale1_scores_key] = list( (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) ) result.result_dict[vif_scale2_scores_key] = list( (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) ) result.result_dict[vif_scale3_scores_key] = list( (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) # vif2 = # ((vif_num_scale0 / vif_den_scale0) + (vif_num_scale1 / vif_den_scale1) + # (vif_num_scale2 / vif_den_scale2) + (vif_num_scale3 / vif_den_scale3)) / 4.0 vif_scores_key = cls.get_scores_key('vif2') result.result_dict[vif_scores_key] = list( ( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) + (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) + (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) + (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) / 4.0 ) # adm_scalei = adm_num_scalei / adm_den_scalei, i = 0, 1, 2, 3 adm_num_scale0_scores_key = cls.get_scores_key('adm_num_scale0') adm_den_scale0_scores_key = cls.get_scores_key('adm_den_scale0') adm_num_scale1_scores_key = cls.get_scores_key('adm_num_scale1') adm_den_scale1_scores_key = cls.get_scores_key('adm_den_scale1') adm_num_scale2_scores_key = cls.get_scores_key('adm_num_scale2') adm_den_scale2_scores_key = cls.get_scores_key('adm_den_scale2') adm_num_scale3_scores_key = cls.get_scores_key('adm_num_scale3') adm_den_scale3_scores_key = cls.get_scores_key('adm_den_scale3') adm_scale0_scores_key = cls.get_scores_key('adm_scale0') adm_scale1_scores_key = cls.get_scores_key('adm_scale1') adm_scale2_scores_key = cls.get_scores_key('adm_scale2') adm_scale3_scores_key = cls.get_scores_key('adm_scale3') result.result_dict[adm_scale0_scores_key] = list( (np.array(result.result_dict[adm_num_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale1_scores_key] = list( (np.array(result.result_dict[adm_num_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale2_scores_key] = list( (np.array(result.result_dict[adm_num_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale3_scores_key] = list( (np.array(result.result_dict[adm_num_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) ) # adm3 = \ # (((adm_num_scale0 + ADM_SCALE_CONSTANT) / (adm_den_scale0 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale1 + ADM_SCALE_CONSTANT) / (adm_den_scale1 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale2 + ADM_SCALE_CONSTANT) / (adm_den_scale2 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale3 + ADM_SCALE_CONSTANT) / (adm_den_scale3 + ADM_SCALE_CONSTANT))) / 4.0 adm3_scores_key = cls.get_scores_key('adm3') result.result_dict[adm3_scores_key] = list( ( ((np.array(result.result_dict[adm_num_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT)) ) / 4.0 ) # validate for feature in cls.DERIVED_ATOM_FEATURES: assert cls.get_scores_key(feature) in result.result_dict return result class VifFrameDifferenceFeatureExtractor(FeatureExtractor): TYPE = "VifDiff_feature" VERSION = '0.1' ATOM_FEATURES = ['vifdiff', 'vifdiff_num', 'vifdiff_den', 'vifdiff_num_scale0', 'vifdiff_den_scale0', 'vifdiff_num_scale1', 'vifdiff_den_scale1', 'vifdiff_num_scale2', 'vifdiff_den_scale2', 'vifdiff_num_scale3', 'vifdiff_den_scale3', ] DERIVED_ATOM_FEATURES = ['vifdiff_scale0', 'vifdiff_scale1', 'vifdiff_scale2', 'vifdiff_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vifdiff_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VifFrameDifferenceFeatureExtractor, cls)._post_process_result(result) # vifdiff_scalei = vifdiff_num_scalei / vifdiff_den_scalei, i = 0, 1, 2, 3 vifdiff_num_scale0_scores_key = cls.get_scores_key('vifdiff_num_scale0') vifdiff_den_scale0_scores_key = cls.get_scores_key('vifdiff_den_scale0') vifdiff_num_scale1_scores_key = cls.get_scores_key('vifdiff_num_scale1') vifdiff_den_scale1_scores_key = cls.get_scores_key('vifdiff_den_scale1') vifdiff_num_scale2_scores_key = cls.get_scores_key('vifdiff_num_scale2') vifdiff_den_scale2_scores_key = cls.get_scores_key('vifdiff_den_scale2') vifdiff_num_scale3_scores_key = cls.get_scores_key('vifdiff_num_scale3') vifdiff_den_scale3_scores_key = cls.get_scores_key('vifdiff_den_scale3') vifdiff_scale0_scores_key = cls.get_scores_key('vifdiff_scale0') vifdiff_scale1_scores_key = cls.get_scores_key('vifdiff_scale1') vifdiff_scale2_scores_key = cls.get_scores_key('vifdiff_scale2') vifdiff_scale3_scores_key = cls.get_scores_key('vifdiff_scale3') result.result_dict[vifdiff_scale0_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale0_scores_key]) / np.array(result.result_dict[vifdiff_den_scale0_scores_key])) ) result.result_dict[vifdiff_scale1_scores_key] = list( (	np.array(result.result_dict[vifdiff_num_scale1_scores_key])	numpy.array
import gym import numpy as np from itertools import product import matplotlib.pyplot as plt def print_policy(Q, env): """ This is a helper function to print a nice policy from the Q function""" moves = [u'←', u'↓',u'→', u'↑'] if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape policy = np.chararray(dims, unicode=True) policy[:] = ' ' for s in range(len(Q)): idx = np.unravel_index(s, dims) policy[idx] = moves[np.argmax(Q[s])] if env.desc[idx] in ['H', 'G']: policy[idx] = u'·' print('\n'.join([''.join([u'{:2}'.format(item) for item in row]) for row in policy])) def plot_V(Q, env): """ This is a helper function to plot the state values from the Q function""" fig = plt.figure() if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape V = np.zeros(dims) for s in range(len(Q)): idx = np.unravel_index(s, dims) V[idx] = np.max(Q[s]) if env.desc[idx] in ['H', 'G']: V[idx] = 0. plt.imshow(V, origin='upper', extent=[0,dims[0],0,dims[1]], vmin=.0, vmax=.6, cmap=plt.cm.RdYlGn, interpolation='none') for x, y in product(range(dims[0]), range(dims[1])): plt.text(y+0.5, dims[0]-x-0.5, '{:.3f}'.format(V[x,y]), horizontalalignment='center', verticalalignment='center') plt.xticks([]) plt.yticks([]) def plot_Q(Q, env): """ This is a helper function to plot the Q function """ from matplotlib import colors, patches fig = plt.figure() ax = fig.gca() if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape up = np.array([[0, 1], [0.5, 0.5], [1,1]]) down = np.array([[0, 0], [0.5, 0.5], [1,0]]) left = np.array([[0, 0], [0.5, 0.5], [0,1]]) right = np.array([[1, 0], [0.5, 0.5], [1,1]]) tri = [left, down, right, up] pos = [[0.2, 0.5], [0.5, 0.2], [0.8, 0.5], [0.5, 0.8]] cmap = plt.cm.RdYlGn norm = colors.Normalize(vmin=.0,vmax=.6) ax.imshow(np.zeros(dims), origin='upper', extent=[0,dims[0],0,dims[1]], vmin=.0, vmax=.6, cmap=cmap) ax.grid(which='major', color='black', linestyle='-', linewidth=2) for s in range(len(Q)): idx = np.unravel_index(s, dims) x, y = idx if env.desc[idx] in ['H', 'G']: ax.add_patch(patches.Rectangle((y, 3-x), 1, 1, color=cmap(.0))) plt.text(y+0.5, dims[0]-x-0.5, '{:.2f}'.format(.0), horizontalalignment='center', verticalalignment='center') continue for a in range(len(tri)): ax.add_patch(patches.Polygon(tri[a] + np.array([y, 3-x]), color=cmap(Q[s][a]))) plt.text(y+pos[a][0], dims[0]-1-x+pos[a][1], '{:.2f}'.format(Q[s][a]), horizontalalignment='center', verticalalignment='center', fontsize=9, fontweight=('bold' if Q[s][a] ==	np.max(Q[s])	numpy.max
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100),	np.linspace(-2.75, 2.75, 100)	numpy.linspace
import io import logging import json import numpy import torch import numpy as np from tqdm import tqdm from clie.inputters import constant from clie.objects import Sentence from torch.utils.data import Dataset from torch.utils.data.sampler import Sampler logger = logging.getLogger(__name__) def load_word_embeddings(file): embeddings_index = {} fin = io.open(file, 'r', encoding='utf-8', newline='\n', errors='ignore') n, d = map(int, fin.readline().split()) for i, line in tqdm(enumerate(fin), total=n): tokens = line.rstrip().split(' ') v = numpy.array(tokens[1:], dtype=float) embeddings_index[tokens[0]] = v return embeddings_index # ------------------------------------------------------------------------------ # Data loading # ------------------------------------------------------------------------------ def load_data(filename, src_lang, tgt_lang, knn_file, knn_size, max_examples=-1): examples = [] wrong_subj_pos, wrong_obj_pos = 0, 0 with open(filename) as f: data = json.load(f) knn_dict = None if knn_file: with open(knn_file) as f: knn_dict = json.load(f) for idx, ex in enumerate(tqdm(data, total=len(data))): sentence = Sentence(ex['id']) sentence.language = src_lang sentence.words = ex['token'] sentence.pos = ex['stanford_pos'] sentence.ner = ex['stanford_ner'] sentence.deprel = ex['stanford_deprel'] sentence.head = [int(x) for x in ex['stanford_head']] sentence.subj_type = ex['subj_type'] sentence.obj_type = ex['obj_type'] sentence.relation = ex['relation'] if ex['subj_end'] - ex['subj_start'] < 0: # we swap the start and end index wrong_subj_pos += 1 sentence.subject = [ex['subj_end'], ex['subj_start']] else: sentence.subject = [ex['subj_start'], ex['subj_end']] if ex['obj_end'] - ex['obj_start'] < 0: # we swap the start and end index wrong_obj_pos += 1 sentence.object = [ex['obj_end'], ex['obj_start']] else: sentence.object = [ex['obj_start'], ex['obj_end']] # store KNN word info if knn_dict: sentence.tgt_lang = tgt_lang knn_words = [] for w in ex['token']: w = '!{}_{}'.format(src_lang, w) if w in knn_dict: assert len(knn_dict[w]) == knn_size knn_words.append(knn_dict[w]) else: knn_words.append([constant.UNK_WORD] * knn_size) sentence.knn_words = knn_words examples.append(sentence) if max_examples != -1 and len(examples) > max_examples: break if wrong_subj_pos > 0 or wrong_obj_pos > 0: logger.info('{} and {} wrong subject and object positions found!'.format( wrong_subj_pos, wrong_obj_pos)) return examples def vectorize(ex, model, iseval): """Torchify a single example.""" words = ['!{}_{}'.format(ex.language, w) for w in ex.words] words = [model.word_dict[w] for w in words] knn_word = None if ex.knn_words: knn_word = [[model.word_dict[w] for w in knn] for knn in ex.knn_words] knn_word = torch.LongTensor(knn_word) word = torch.LongTensor(words) pos = torch.LongTensor([model.pos_dict[p] for p in ex.pos]) ner = torch.LongTensor([model.ner_dict[n] for n in ex.ner]) deprel = torch.LongTensor([model.deprel_dict[d] for d in ex.deprel]) assert any([x == 0 for x in ex.head]) head = torch.LongTensor(ex.head) subj_position = torch.LongTensor(ex.subj_position) obj_position = torch.LongTensor(ex.obj_position) type = [0] * len(ex.words) ttype = model.type_dict[ex.subj_type] start, end = ex.subject type[start: end + 1] = [ttype] * (end - start + 1) atype = model.type_dict[ex.obj_type] start, end = ex.object type[start: end + 1] = [atype] * (end - start + 1) type = torch.LongTensor(type) return { 'id': ex.id, 'language': ex.language, 'word': word, 'pos': pos, 'ner': ner, 'deprel': deprel, 'type': type, 'head': head, 'subject': ex.subj_text, 'object': ex.obj_text, 'subject_pos': subj_position, 'object_pos': obj_position, 'relation': model.label_dict[ex.relation], 'knn_word': knn_word } def batchify(batch): """Gather a batch of individual examples into one batch.""" # batch is a list of vectorized examples batch_size = len(batch) ids = [ex['id'] for ex in batch] language = [ex['language'] for ex in batch] use_knn = batch[0]['knn_word'] is not None # NOTE. batch[0]['knn_word'] is a 2d list knn_size = len(batch[0]['knn_word'][0]) if use_knn else 0 # --------- Prepare Code tensors --------- max_len = max([ex['word'].size(0) for ex in batch]) # Batch Code Representations len_rep = torch.LongTensor(batch_size).fill_(constant.PAD) word_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) head_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) subject_pos_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) object_pos_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) pos_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) ner_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) deprel_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) type_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) labels = torch.LongTensor(batch_size) subject = [] object = [] knn_rep = None if use_knn: knn_rep = torch.LongTensor(batch_size, max_len, knn_size).fill_(constant.PAD) for i, ex in enumerate(batch): len_rep[i] = ex['word'].size(0) labels[i] = ex['relation'] word_rep[i, :len_rep[i]] = ex['word'] head_rep[i, :len_rep[i]] = ex['head'] subject_pos_rep[i, :len_rep[i]] = ex['subject_pos'] object_pos_rep[i, :len_rep[i]] = ex['object_pos'] pos_rep[i, :len_rep[i]] = ex['pos'] ner_rep[i, :len_rep[i]] = ex['ner'] deprel_rep[i, :len_rep[i]] = ex['deprel'] type_rep[i, :len_rep[i]] = ex['type'] subject.append(ex['subject']) object.append(ex['object']) if use_knn: knn_rep[i, :len_rep[i]] = ex['knn_word'] return { 'ids': ids, 'language': language, 'batch_size': batch_size, 'len_rep': len_rep, 'word_rep': word_rep, 'knn_rep': knn_rep, 'head_rep': head_rep, 'subject': subject, 'object': object, 'subject_pos_rep': subject_pos_rep, 'object_pos_rep': object_pos_rep, 'labels': labels, 'pos_rep': pos_rep, 'ner_rep': ner_rep, 'deprel_rep': deprel_rep, 'type_rep': type_rep } class ACE05Dataset(Dataset): def __init__(self, examples, model, evaluation=False): self.model = model self.examples = examples self.evaluation = evaluation def __len__(self): return len(self.examples) def __getitem__(self, index): return vectorize(self.examples[index], self.model, iseval=self.evaluation) def lengths(self): return [len(ex.words) for ex in self.examples] class SortedBatchSampler(Sampler): def __init__(self, lengths, batch_size, shuffle=True): self.lengths = lengths self.batch_size = batch_size self.shuffle = shuffle def __iter__(self): lengths = np.array( [(-l, np.random.random()) for l in self.lengths], dtype=[('l1', np.int_), ('rand', np.float_)] ) indices = np.argsort(lengths, order=('l1', 'rand')) batches = [indices[i:i + self.batch_size] for i in range(0, len(indices), self.batch_size)] if self.shuffle:	np.random.shuffle(batches)	numpy.random.shuffle
from __future__ import print_function import numpy as np import matplotlib.pyplot as plt class TwoLayerNet(object): """ A two-layer fully-connected neural network. The net has an input dimension of N, a hidden layer dimension of H, and performs classification over C classes. We train the network with a softmax loss function and L2 regularization on the weight matrices. The network uses a ReLU nonlinearity after the first fully connected layer. In other words, the network has the following architecture: input - fully connected layer - ReLU - fully connected layer - softmax The outputs of the second fully-connected layer are the scores for each class. """ def __init__(self, input_size, hidden_size, output_size, std=1e-4): """ Initialize the model. Weights are initialized to small random values and biases are initialized to zero. Weights and biases are stored in the variable self.params, which is a dictionary with the following keys W1: First layer weights; has shape (D, H) b1: First layer biases; has shape (H,) W2: Second layer weights; has shape (H, C) b2: Second layer biases; has shape (C,) Inputs: - input_size: The dimension D of the input data. - hidden_size: The number of neurons H in the hidden layer. - output_size: The number of classes C. """ self.params = {} self.params['W1'] = std * np.random.randn(input_size, hidden_size) self.params['b1'] = np.zeros(hidden_size) self.params['W2'] = std * np.random.randn(hidden_size, output_size) self.params['b2'] = np.zeros(output_size) def loss(self, X, y=None, reg=0.0): """ Compute the loss and gradients for a two layer fully connected neural network. Inputs: - X: Input data of shape (N, D). Each X[i] is a training sample. - y: Vector of training labels. y[i] is the label for X[i], and each y[i] is an integer in the range 0 <= y[i] < C. This parameter is optional; if it is not passed then we only return scores, and if it is passed then we instead return the loss and gradients. - reg: Regularization strength. Returns: If y is None, return a matrix scores of shape (N, C) where scores[i, c] is the score for class c on input X[i]. If y is not None, instead return a tuple of: - loss: Loss (data loss and regularization loss) for this batch of training samples. - grads: Dictionary mapping parameter names to gradients of those parameters with respect to the loss function; has the same keys as self.params. """ # Unpack variables from the params dictionary W1, b1 = self.params['W1'], self.params['b1'] W2, b2 = self.params['W2'], self.params['b2'] N, D = X.shape # Compute the forward pass scores = None ####################################################################### # TODO: Perform the forward pass, computing the class scores for the # # input. Store the result in the scores variable, which should be an # # array of shape (N, C). # ####################################################################### scores1 = X.dot(W1) + b1 # FC1 X2 = np.maximum(0, scores1) # ReLU FC1 scores = X2.dot(W2) + b2 # FC2 ####################################################################### # END OF YOUR CODE # ####################################################################### # If the targets are not given then jump out, we're done if y is None: return scores scores -= np.max(scores) # Fix Number instability scores_exp = np.exp(scores) probs = scores_exp / np.sum(scores_exp, axis=1, keepdims=True) # Compute the loss loss = None ####################################################################### # TODO: Finish the forward pass, and compute the loss. This should # # include both the data loss and L2 regularization for W1 and W2. # # Store the result in the variable loss, which should be a scalar. Use# # the Softmax classifier loss. # ####################################################################### correct_probs = -np.log(probs[np.arange(N), y]) # L_i = -log(e^correct_score/sum(e^scores))) = -log(correct_probs) loss =	np.sum(correct_probs)	numpy.sum
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k') plt.plot(((time[-202] + time[-201]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed', label=textwrap.fill('Neural network targets', 13)) plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(((time_extended[-1001] + time_extended[-1000]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed') plt.xlim(3.4 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/neural_network.png') plt.show() # plot 6a np.random.seed(0) time = np.linspace(0, 5 * np.pi, 1001) knots_51 = np.linspace(0, 5 * np.pi, 51) time_series = np.cos(2 * time) + np.cos(4 * time) +	np.cos(8 * time)	numpy.cos
# -- coding: utf-8 -- """ Script to execute example covarying MMGP regression forecasting model with full Krhh. Inputs: Data training and test sets (dictionary pickle) Data for example: - normalised solar data for 25 sites for 15 minute forecast - N_train = 4200, N_test = 2276, P = 25, D = 51 - Xtr[:, :50] 2 recent lagged observations for each site in order - Xtr[:, 50] time index - link inputs is a 25x2 array (link inputs repeated for every group) with normalised lat,long for each site in order Model Options: - Sparse or full x-function covariance prior Krhh (set bool SPARSE_PRIOR) - Diagonal or Kronecker-structured variational posterior covariance Sr (set bool DIAG_POST) - Sparse or full posterior covariance (when Kronecker posterior; set bool SPARSE_POST) Current Settings (sparse covarying mmgp model with sparse Kronecker posterior): DIAG_POST = False SPARSE_PRIOR = False # set True for equivalent sparse scmmgp model SPARSE_POST = True Note on specifying group structure for F: Grouping occurs via block_struct, a nested list of grouping order Where functions [i] are independent i.e. in own block, set link_kernel[i] = link_inputs[i] = 1.0 See model class preamble and example below for further details. """ import os import numpy as np import pickle import pandas as pd import traceback import time import sklearn.cluster import csv import sys import mmgp from mmgp import likelihoods from mmgp import kernels import tensorflow as tf from mmgp import datasets from mmgp import losses from mmgp import util dpath = '/experiments/datasets/' dfile = 'p25_inputsdict.pickle' dlinkfile = 'p25_linkinputsarray.pickle' outdir = '/experiments/results/p25_nonsparse_cmmgp/' try: os.makedirs(outdir) except FileExistsError: pass def get_inputs(): """ inputsdict contains {'Yte': Yte, 'Ytr': Ytr, 'Xtr': Xtr, 'Xte': Xte} where values are np.arrays np. arrays are truncated to evenly split into batches of size = batchsize returns inputsdict, Xtr_link (ndarray, shape = [P, D_link_features]) """ with open(os.path.join(dpath, dfile), 'rb') as f: d_all = pickle.load(f) with open(os.path.join(dpath, dlinkfile), 'rb') as f: d_link = pickle.load(f) return d_all, d_link def init_z(train_inputs, num_inducing): # Initialize inducing points using clustering. mini_batch = sklearn.cluster.MiniBatchKMeans(num_inducing) cluster_indices = mini_batch.fit_predict(train_inputs) inducing_locations = mini_batch.cluster_centers_ return inducing_locations FLAGS = util.util.get_flags() BATCH_SIZE = FLAGS.batch_size LEARNING_RATE = FLAGS.learning_rate DISPLAY_STEP = FLAGS.display_step EPOCHS = FLAGS.n_epochs NUM_SAMPLES = FLAGS.mc_train PRED_SAMPLES = FLAGS.mc_test NUM_INDUCING = FLAGS.n_inducing NUM_COMPONENTS = FLAGS.num_components IS_ARD = FLAGS.is_ard TOL = FLAGS.opt_tol VAR_STEPS = FLAGS.var_steps DIAG_POST = False SPARSE_PRIOR = False SPARSE_POST = True # option for non-diag post MAXTIME = 1200 print("settings done") # define GPRN P and Q output_dim = 25 #P node_dim = 25 #Q lag_dim = 2 save_nlpds = False # If True saves samples of nlpds for n,p,s # extract dataset d, d_link = get_inputs() Ytr, Yte, Xtr, Xte = d['Ytr'], d['Yte'], d['Xtr'], d['Xte'] data = datasets.DataSet(Xtr.astype(np.float32), Ytr.astype(np.float32), shuffle=False) test = datasets.DataSet(Xte.astype(np.float32), Yte.astype(np.float32), shuffle=False) print("dataset created") # model config block rows (where P=Q): block all w.1, w.2 etc, leave f independent # order of block_struct is rows, node functions # lists required: block_struct, link_inputs, kern_link, kern #block_struct nested list of grouping order weight_struct = [[] for _ in range(output_dim)] for i in range(output_dim): row = list(range(i, i+output_dim(node_dim-1)+1, output_dim)) row_0 = row.pop(i) # bring diag to pivot position weight_struct[i] = [row_0] + row nodes = [[x] for x in list(range(output_dim node_dim, output_dim * node_dim + output_dim))] block_struct = weight_struct + nodes # create link inputs (link inputs used repeatedly but can have link input per group) # permute to bring diagonal to first position link_inputs = [[] for _ in range(output_dim)] for i in range(output_dim): idx = list(range(d_link.shape[0])) link_inputs[i] = d_link[[idx.pop(i)] + idx, :] link_inputs = link_inputs + [1.0 for i in range(output_dim)] # for full W row blocks, independent nodes # create 'between' kernel list klink_rows = [kernels.CompositeKernel('mul',[kernels.RadialBasis(2, std_dev=2.0, lengthscale=1.0, white=0.01, input_scaling = IS_ARD), kernels.CompactSlice(2, active_dims=[0,1], lengthscale = 2.0, input_scaling = IS_ARD)] ) for i in range(output_dim) ] klink_f = [1.0 for i in range(node_dim)] kernlink = klink_rows + klink_f # create 'within' kernel # kern lag_active_dims_s = [ [] for _ in range(output_dim)] for i in range(output_dim): lag_active_dims_s[i] = list(range(lag_dimi, lag_dim(i+1))) k_rows = [kernels.CompositeKernel('mul',[kernels.RadialBasisSlice(lag_dim, active_dims=lag_active_dims_s[i], std_dev = 1.0, white = 0.01, input_scaling = IS_ARD), kernels.PeriodicSliceFixed(1, active_dims=[Xtr.shape[1]-1], lengthscale=0.5, std_dev=1.0, period = 144) ]) for i in range(output_dim)] k_f = [kernels.RadialBasisSlice(lag_dim, active_dims=lag_active_dims_s[i], std_dev = 1.0, white = 0.01, input_scaling = IS_ARD) for i in range(output_dim)] kern = k_rows + k_f print('len link_inputs ',len(link_inputs)) print('len kernlink ',len(kernlink)) print('len kern ', len(kern)) print('no. groups = ', len(block_struct), 'no. latent functions =', len([i for b in block_struct for i in b])) print('number latent functions', node_dim*(output_dim+1)) likelihood = likelihoods.CovaryingRegressionNetwork(output_dim, node_dim, std_dev = 0.2) # p, q, lik_noise print("likelihood and kernels set") Z = init_z(data.X, NUM_INDUCING) print('inducing points set') m = mmgp.ExplicitSCMMGP(output_dim, likelihood, kern, kernlink, block_struct, Z, link_inputs, num_components=NUM_COMPONENTS, diag_post=DIAG_POST, sparse_prior=SPARSE_PRIOR, sparse_post=SPARSE_POST, num_samples=NUM_SAMPLES, predict_samples=PRED_SAMPLES) print("model set") # initialise losses and logging error_rate = losses.RootMeanSqError(data.Dout) os.chdir(outdir) with open("log_results.csv", 'w', newline='') as f: csv.writer(f).writerow(['epoch', 'fit_runtime', 'nelbo', error_rate.get_name(),'generalised_nlpd']) with open("log_params.csv", 'w', newline='') as f: csv.writer(f).writerow(['epoch', 'raw_kernel_params', 'raw_kernlink_params', 'raw_likelihood_params', 'raw_weights']) with open("log_comp_time.csv", 'w', newline='') as f: csv.writer(f).writerow(['epoch', 'batch_time', 'nelbo_time', 'pred_time', 'gen_nlpd_time', error_rate.get_name()+'_time']) # optimise o = tf.train.AdamOptimizer(LEARNING_RATE, beta1=0.9,beta2=0.99) print("start time = ", time.strftime('%X %x %Z')) m.fit(data, o, var_steps = VAR_STEPS, epochs = EPOCHS, batch_size = BATCH_SIZE, display_step=DISPLAY_STEP, test = test, loss = error_rate, tolerance = TOL, max_time=MAXTIME ) print("optimisation complete") # export final predicted values and loss metrics ypred = m.predict(test.X, batch_size = BATCH_SIZE) #same batchsize used for convenience np.savetxt("predictions.csv", np.concatenate(ypred, axis=1), delimiter=",") if save_nlpds == True: nlpd_samples, nlpd_meanvar = m.nlpd_samples(test.X, test.Y, batch_size = BATCH_SIZE) try:	np.savetxt("nlpd_meanvar.csv", nlpd_meanvar, delimiter=",")	numpy.savetxt
# pvtrace is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 3 of the License, or # (at your option) any later version. # # pvtrace is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see <http://www.gnu.org/licenses/>. import numpy as np from external.transformations import translation_matrix, rotation_matrix import external.transformations as tf from Trace import Photon from Geometry import Box, Cylinder, FinitePlane, transform_point, transform_direction, rotation_matrix_from_vector_alignment, norm from Materials import Spectrum def random_spherecial_vector(): # This method of calculating isotropic vectors is taken from GNU Scientific Library LOOP = True while LOOP: x = -1. + 2. * np.random.uniform() y = -1. + 2. * np.random.uniform() s = x2 + y2 if s <= 1.0: LOOP = False z = -1. + 2. * s a = 2 * np.sqrt(1 - s) x = a * x y = a * y return np.array([x,y,z]) class SimpleSource(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, use_random_polarisation=False): super(SimpleSource, self).__init__() self.position = position self.direction = direction self.wavelength = wavelength self.use_random_polarisation = use_random_polarisation self.throw = 0 self.source_id = "SimpleSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength # If use_polarisation is set generate a random polarisation vector of the photon if self.use_random_polarisation: # Randomise rotation angle around xy-plane, the transform from +z to the direction of the photon vec = random_spherecial_vector() vec[2] = 0. vec = norm(vec) R = rotation_matrix_from_vector_alignment(self.direction, [0,0,1]) photon.polarisation = transform_direction(vec, R) else: photon.polarisation = None photon.id = self.throw self.throw = self.throw + 1 return photon class Laser(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, polarisation=None): super(Laser, self).__init__() self.position = np.array(position) self.direction = np.array(direction) self.wavelength = wavelength assert polarisation != None, "Polarisation of the Laser is not set." self.polarisation = np.array(polarisation) self.throw = 0 self.source_id = "LaserSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength photon.polarisation = self.polarisation photon.id = self.throw self.throw = self.throw + 1 return photon class PlanarSource(object): """A box that emits photons from the top surface (normal), sampled from the spectrum.""" def __init__(self, spectrum=None, wavelength=555, direction=(0,0,1), length=0.05, width=0.05): super(PlanarSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.plane = FinitePlane(length=length, width=width) self.length = length self.width = width # direction is the direction that photons are fired out of the plane in the GLOBAL FRAME. # i.e. this is passed directly to the photon to set is's direction self.direction = direction self.throw = 0 self.source_id = "PlanarSource_" + str(id(self)) def translate(self, translation): self.plane.append_transform(tf.translation_matrix(translation)) def rotate(self, angle, axis): self.plane.append_transform(tf.rotation_matrix(angle, axis)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Create a point which is on the surface of the finite plane in it's local frame x = np.random.uniform(0., self.length) y = np.random.uniform(0., self.width) local_point = (x, y, 0.) # Transform the direciton photon.position = transform_point(local_point, self.plane.transform) photon.direction = self.direction photon.active = True if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class LensSource(object): """ A source where photons generated in a plane are focused on a line with space tolerance given by variable "focussize". The focus line should be perpendicular to the plane normal and aligned with the z-axis. """ def __init__(self, spectrum = None, wavelength = 555, linepoint=(0,0,0), linedirection=(0,0,1), focussize = 0, planeorigin = (-1,-1,-1), planeextent = (-1,1,1)): super(LensSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.planeorigin = planeorigin self.planeextent = planeextent self.linepoint = np.array(linepoint) self.linedirection = np.array(linedirection) self.focussize = focussize self.throw = 0 self.source_id = "LensSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Position x = np.random.uniform(self.planeorigin[0],self.planeextent[0]) y = np.random.uniform(self.planeorigin[1],self.planeextent[1]) z = np.random.uniform(self.planeorigin[2],self.planeextent[2]) photon.position = np.array((x,y,z)) # Direction focuspoint = np.array((0.,0.,0.)) focuspoint[0] = self.linepoint[0] + np.random.uniform(-self.focussize,self.focussize) focuspoint[1] = self.linepoint[1] + np.random.uniform(-self.focussize,self.focussize) focuspoint[2] = photon.position[2] direction = focuspoint - photon.position modulus = (direction[0]2+direction[1]2+direction[2]2)0.5 photon.direction = direction/modulus # Wavelength if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class LensSourceAngle(object): """ A source where photons generated in a plane are focused on a line with space tolerance given by variable "focussize". The focus line should be perpendicular to the plane normal and aligned with the z-axis. For this lense an additional z-boost is added (Angle of incidence in z-direction). """ def __init__(self, spectrum = None, wavelength = 555, linepoint=(0,0,0), linedirection=(0,0,1), angle = 0, focussize = 0, planeorigin = (-1,-1,-1), planeextent = (-1,1,1)): super(LensSourceAngle, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.planeorigin = planeorigin self.planeextent = planeextent self.linepoint = np.array(linepoint) self.linedirection = np.array(linedirection) self.focussize = focussize self.angle = angle self.throw = 0 self.source_id = "LensSourceAngle_" + str(id(self)) def photon(self): photon = Photon() photon.id = self.throw self.throw = self.throw + 1 # Position x = np.random.uniform(self.planeorigin[0],self.planeextent[0]) y = np.random.uniform(self.planeorigin[1],self.planeextent[1]) boost = ynp.tan(self.angle) z = np.random.uniform(self.planeorigin[2],self.planeextent[2]) - boost photon.position = np.array((x,y,z)) # Direction focuspoint = np.array((0.,0.,0.)) focuspoint[0] = self.linepoint[0] + np.random.uniform(-self.focussize,self.focussize) focuspoint[1] = self.linepoint[1] + np.random.uniform(-self.focussize,self.focussize) focuspoint[2] = photon.position[2] + boost direction = focuspoint - photon.position modulus = (direction[0]2+direction[1]2+direction[2]2)0.5 photon.direction = direction/modulus # Wavelength if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class CylindricalSource(object): """ A source for photons emitted in a random direction and position inside a cylinder(radius, length) """ def __init__(self, spectrum = None, wavelength = 555, radius = 1, length = 10): super(CylindricalSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.shape = Cylinder(radius = radius, length = length) self.radius = radius self.length = length self.throw = 0 self.source_id = "CylindricalSource_" + str(id(self)) def translate(self, translation): self.shape.append_transform(tf.translation_matrix(translation)) def rotate(self, angle, axis): self.shape.append_transform(tf.rotation_matrix(angle, axis)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Position of emission phi = np.random.uniform(0., 2np.pi) r = np.random.uniform(0.,self.radius) x = rnp.cos(phi) y = rnp.sin(phi) z = np.random.uniform(0.,self.length) local_center = (x,y,z) photon.position = transform_point(local_center, self.shape.transform) # Direction of emission (no need to transform if meant to be isotropic) phi = np.random.uniform(0.,2np.pi) theta = np.random.uniform(0.,np.pi) x = np.cos(phi)np.sin(theta) y = np.sin(phi)np.sin(theta) z = np.cos(theta) local_direction = (x,y,z) photon.direction = local_direction # Set wavelength of photon if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength # Further initialisation photon.active = True return photon class PointSource(object): """ A point source that emits randomly in solid angle specified by phimin, ..., thetamax """ def __init__(self, spectrum = None, wavelength = 555, center = (0.,0.,0.), phimin = 0, phimax = 2np.pi, thetamin = 0, thetamax = np.pi): super(PointSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.center = center self.phimin = phimin self.phimax = phimax self.thetamin = thetamin self.thetamax = thetamax self.throw = 0 self.source_id = "PointSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 phi = np.random.uniform(self.phimin, self.phimax) theta = np.random.uniform(self.thetamin, self.thetamax) x = np.cos(phi)np.sin(theta) y = np.sin(phi)np.sin(theta) z = np.cos(theta) direction = (x,y,z) transform = tf.translation_matrix((0,0,0)) point = transform_point(self.center, transform) photon.direction = direction photon.position = point if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength photon.active = True return photon class RadialSource(object): """ A point source that emits at discrete angles theta(i) and phi(i) """ def __init__(self, spectrum = None, wavelength = 555, center = (0.,0.,0.), phimin = 0, phimax = 2*np.pi, thetamin = 0, thetamax = np.pi, spacing=20): super(RadialSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.center = center self.phimin = phimin self.phimax = phimax self.thetamin = thetamin self.thetamax = thetamax self.spacing = spacing self.throw = 0 self.source_id = "RadialSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 intphi = np.random.randint(1, self.spacing+1) inttheta =	np.random.randint(1, self.spacing+1)	numpy.random.randint
from abc import ABCMeta, abstractmethod import os from vmaf.tools.misc import make_absolute_path, run_process from vmaf.tools.stats import ListStats __copyright__ = "Copyright 2016-2018, Netflix, Inc." __license__ = "Apache, Version 2.0" import re import numpy as np import ast from vmaf import ExternalProgramCaller, to_list from vmaf.config import VmafConfig, VmafExternalConfig from vmaf.core.executor import Executor from vmaf.core.result import Result from vmaf.tools.reader import YuvReader class FeatureExtractor(Executor): """ FeatureExtractor takes in a list of assets, and run feature extraction on them, and return a list of corresponding results. A FeatureExtractor must specify a unique type and version combination (by the TYPE and VERSION attribute), so that the Result generated by it can be identified. A derived class of FeatureExtractor must: 1) Override TYPE and VERSION 2) Override _generate_result(self, asset), which call a command-line executable and generate feature scores in a log file. 3) Override _get_feature_scores(self, asset), which read the feature scores from the log file, and return the scores in a dictionary format. For an example, follow VmafFeatureExtractor. """ __metaclass__ = ABCMeta @property @abstractmethod def ATOM_FEATURES(self): raise NotImplementedError def _read_result(self, asset): result = {} result.update(self._get_feature_scores(asset)) executor_id = self.executor_id return Result(asset, executor_id, result) @classmethod def get_scores_key(cls, atom_feature): return "{type}_{atom_feature}_scores".format( type=cls.TYPE, atom_feature=atom_feature) @classmethod def get_score_key(cls, atom_feature): return "{type}_{atom_feature}_score".format( type=cls.TYPE, atom_feature=atom_feature) def _get_feature_scores(self, asset): # routine to read the feature scores from the log file, and return # the scores in a dictionary format. log_file_path = self._get_log_file_path(asset) atom_feature_scores_dict = {} atom_feature_idx_dict = {} for atom_feature in self.ATOM_FEATURES: atom_feature_scores_dict[atom_feature] = [] atom_feature_idx_dict[atom_feature] = 0 with open(log_file_path, 'rt') as log_file: for line in log_file.readlines(): for atom_feature in self.ATOM_FEATURES: re_template = "{af}: ([0-9]+) ([a-zA-Z0-9.-]+)".format(af=atom_feature) mo = re.match(re_template, line) if mo: cur_idx = int(mo.group(1)) assert cur_idx == atom_feature_idx_dict[atom_feature] # parse value, allowing NaN and inf val = float(mo.group(2)) if np.isnan(val) or np.isinf(val): val = None atom_feature_scores_dict[atom_feature].append(val) atom_feature_idx_dict[atom_feature] += 1 continue len_score = len(atom_feature_scores_dict[self.ATOM_FEATURES[0]]) assert len_score != 0 for atom_feature in self.ATOM_FEATURES[1:]: assert len_score == len(atom_feature_scores_dict[atom_feature]), \ "Feature data possibly corrupt. Run cleanup script and try again." feature_result = {} for atom_feature in self.ATOM_FEATURES: scores_key = self.get_scores_key(atom_feature) feature_result[scores_key] = atom_feature_scores_dict[atom_feature] return feature_result class VmafFeatureExtractor(FeatureExtractor): TYPE = "VMAF_feature" # VERSION = '0.1' # vmaf_study; Anush's VIF fix # VERSION = '0.2' # expose vif_num, vif_den, adm_num, adm_den, anpsnr # VERSION = '0.2.1' # expose vif num/den of each scale # VERSION = '0.2.2' # adm abs-->fabs, corrected border handling, uniform reading with option of offset for input YUV, updated VIF corner case # VERSION = '0.2.2b' # expose adm_den/num_scalex # VERSION = '0.2.3' # AVX for VMAF convolution; update adm features by folding noise floor into per coef # VERSION = '0.2.4' # Fix a bug in adm feature passing scale into dwt_quant_step # VERSION = '0.2.4b' # Modify by adding ADM noise floor outside cube root; add derived feature motion2 VERSION = '0.2.4c' # Modify by moving motion2 to c code ATOM_FEATURES = ['vif', 'adm', 'ansnr', 'motion', 'motion2', 'vif_num', 'vif_den', 'adm_num', 'adm_den', 'anpsnr', 'vif_num_scale0', 'vif_den_scale0', 'vif_num_scale1', 'vif_den_scale1', 'vif_num_scale2', 'vif_den_scale2', 'vif_num_scale3', 'vif_den_scale3', 'adm_num_scale0', 'adm_den_scale0', 'adm_num_scale1', 'adm_den_scale1', 'adm_num_scale2', 'adm_den_scale2', 'adm_num_scale3', 'adm_den_scale3', ] DERIVED_ATOM_FEATURES = ['vif_scale0', 'vif_scale1', 'vif_scale2', 'vif_scale3', 'vif2', 'adm2', 'adm3', 'adm_scale0', 'adm_scale1', 'adm_scale2', 'adm_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vmaf_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VmafFeatureExtractor, cls)._post_process_result(result) # adm2 = # (adm_num + ADM2_CONSTANT) / (adm_den + ADM2_CONSTANT) adm2_scores_key = cls.get_scores_key('adm2') adm_num_scores_key = cls.get_scores_key('adm_num') adm_den_scores_key = cls.get_scores_key('adm_den') result.result_dict[adm2_scores_key] = list( (np.array(result.result_dict[adm_num_scores_key]) + cls.ADM2_CONSTANT) / (np.array(result.result_dict[adm_den_scores_key]) + cls.ADM2_CONSTANT) ) # vif_scalei = vif_num_scalei / vif_den_scalei, i = 0, 1, 2, 3 vif_num_scale0_scores_key = cls.get_scores_key('vif_num_scale0') vif_den_scale0_scores_key = cls.get_scores_key('vif_den_scale0') vif_num_scale1_scores_key = cls.get_scores_key('vif_num_scale1') vif_den_scale1_scores_key = cls.get_scores_key('vif_den_scale1') vif_num_scale2_scores_key = cls.get_scores_key('vif_num_scale2') vif_den_scale2_scores_key = cls.get_scores_key('vif_den_scale2') vif_num_scale3_scores_key = cls.get_scores_key('vif_num_scale3') vif_den_scale3_scores_key = cls.get_scores_key('vif_den_scale3') vif_scale0_scores_key = cls.get_scores_key('vif_scale0') vif_scale1_scores_key = cls.get_scores_key('vif_scale1') vif_scale2_scores_key = cls.get_scores_key('vif_scale2') vif_scale3_scores_key = cls.get_scores_key('vif_scale3') result.result_dict[vif_scale0_scores_key] = list( (np.array(result.result_dict[vif_num_scale0_scores_key]) /	np.array(result.result_dict[vif_den_scale0_scores_key])	numpy.array
from __future__ import absolute_import from __future__ import division from __future__ import print_function import cntk as C import numpy as np from .common import floatx, epsilon, image_dim_ordering, image_data_format from collections import defaultdict from contextlib import contextmanager import warnings C.set_global_option('align_axis', 1) b_any = any dev = C.device.use_default_device() if dev.type() == 0: warnings.warn( 'CNTK backend warning: GPU is not detected. ' 'CNTK\'s CPU version is not fully optimized,' 'please run with GPU to get better performance.') # A learning phase is a bool tensor used to run Keras models in # either train mode (learning_phase == 1) or test mode (learning_phase == 0). # LEARNING_PHASE_PLACEHOLDER is the placeholder for dynamic learning phase _LEARNING_PHASE_PLACEHOLDER = C.constant(shape=(), dtype=np.float32, value=1.0, name='_keras_learning_phase') # static learning phase flag, if it is not 0 or 1, we will go with dynamic learning phase tensor. _LEARNING_PHASE = -1 _UID_PREFIXES = defaultdict(int) # cntk doesn't support gradient as symbolic op, to hook up with keras model, # we will create gradient as a constant placeholder, here use this global # map to keep the mapping from grad placeholder to parameter grad_parameter_dict = {} NAME_SCOPE_STACK = [] @contextmanager def name_scope(name): global NAME_SCOPE_STACK NAME_SCOPE_STACK.append(name) yield NAME_SCOPE_STACK.pop() def get_uid(prefix=''): _UID_PREFIXES[prefix] += 1 return _UID_PREFIXES[prefix] def learning_phase(): # If _LEARNING_PHASE is not 0 or 1, return dynamic learning phase tensor return _LEARNING_PHASE if _LEARNING_PHASE in {0, 1} else _LEARNING_PHASE_PLACEHOLDER def set_learning_phase(value): global _LEARNING_PHASE if value not in {0, 1}: raise ValueError('CNTK Backend: Set learning phase ' 'with value %s is not supported, ' 'expected 0 or 1.' % value) _LEARNING_PHASE = value def clear_session(): """Reset learning phase flag for cntk backend. """ global _LEARNING_PHASE global _LEARNING_PHASE_PLACEHOLDER _LEARNING_PHASE = -1 _LEARNING_PHASE_PLACEHOLDER.value = np.asarray(1.0) def in_train_phase(x, alt, training=None): global _LEARNING_PHASE if training is None: training = learning_phase() uses_learning_phase = True else: uses_learning_phase = False # CNTK currently don't support cond op, so here we use # element_select approach as workaround. It may have # perf issue, will resolve it later with cntk cond op. if callable(x) and isinstance(x, C.cntk_py.Function) is False: x = x() if callable(alt) and isinstance(alt, C.cntk_py.Function) is False: alt = alt() if training is True: x._uses_learning_phase = uses_learning_phase return x else: # if _LEARNING_PHASE is static if isinstance(training, int) or isinstance(training, bool): result = x if training == 1 or training is True else alt else: result = C.element_select(training, x, alt) result._uses_learning_phase = uses_learning_phase return result def in_test_phase(x, alt, training=None): return in_train_phase(alt, x, training=training) def _convert_string_dtype(dtype): # cntk only support float32 and float64 if dtype == 'float32': return np.float32 elif dtype == 'float64': return np.float64 else: # cntk only running with float, # try to cast to float to run the model return np.float32 def _convert_dtype_string(dtype): if dtype == np.float32: return 'float32' elif dtype == np.float64: return 'float64' else: raise ValueError('CNTK Backend: Unsupported dtype: %s. ' 'CNTK only supports float32 and ' 'float64.' % dtype) def variable(value, dtype=None, name=None, constraint=None): """Instantiates a variable and returns it. # Arguments value: Numpy array, initial value of the tensor. dtype: Tensor type. name: Optional name string for the tensor. constraint: Optional projection function to be applied to the variable after an optimizer update. # Returns A variable instance (with Keras metadata included). """ if dtype is None: dtype = floatx() if name is None: name = '' if isinstance( value, C.variables.Constant) or isinstance( value, C.variables.Parameter): value = value.value # we don't support init parameter with symbolic op, so eval it first as # workaround if isinstance(value, C.cntk_py.Function): value = eval(value) shape = value.shape if hasattr(value, 'shape') else () if hasattr(value, 'dtype') and value.dtype != dtype and len(shape) > 0: value = value.astype(dtype) # TODO: remove the conversion when cntk supports int32, int64 # https://docs.microsoft.com/en-us/python/api/cntk.variables.parameter dtype = 'float32' if 'int' in str(dtype) else dtype v = C.parameter(shape=shape, init=value, dtype=dtype, name=_prepare_name(name, 'variable')) v._keras_shape = v.shape v._uses_learning_phase = False v.constraint = constraint return v def bias_add(x, bias, data_format=None): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) dims = len(x.shape) if dims > 0 and x.shape[0] == C.InferredDimension: dims -= 1 bias_dims = len(bias.shape) if bias_dims != 1 and bias_dims != dims: raise ValueError('Unexpected bias dimensions %d, ' 'expected 1 or %d dimensions' % (bias_dims, dims)) if dims == 4: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1, 1, 1) else: shape = (bias.shape[3],) + bias.shape[:3] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, 1, 1, bias.shape[0]) else: shape = bias.shape elif dims == 3: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1, 1) else: shape = (bias.shape[2],) + bias.shape[:2] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, 1, bias.shape[0]) else: shape = bias.shape elif dims == 2: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1) else: shape = (bias.shape[1],) + bias.shape[:1] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, bias.shape[0]) else: shape = bias.shape else: shape = bias.shape return x + reshape(bias, shape) def eval(x): if isinstance(x, C.cntk_py.Function): return x.eval() elif isinstance(x, C.variables.Constant) or isinstance(x, C.variables.Parameter): return x.value else: raise ValueError('CNTK Backend: `eval` method on ' '`%s` type is not supported. ' 'CNTK only supports `eval` with ' '`Function`, `Constant` or ' '`Parameter`.' % type(x)) def placeholder( shape=None, ndim=None, dtype=None, sparse=False, name=None, dynamic_axis_num=1): if dtype is None: dtype = floatx() if not shape: if ndim: shape = tuple([None for _ in range(ndim)]) dynamic_dimension = C.FreeDimension if _get_cntk_version() >= 2.2 else C.InferredDimension cntk_shape = [dynamic_dimension if s is None else s for s in shape] cntk_shape = tuple(cntk_shape) if dynamic_axis_num > len(cntk_shape): raise ValueError('CNTK backend: creating placeholder with ' '%d dimension is not supported, at least ' '%d dimensions are needed.' % (len(cntk_shape, dynamic_axis_num))) if name is None: name = '' cntk_shape = cntk_shape[dynamic_axis_num:] x = C.input( shape=cntk_shape, dtype=_convert_string_dtype(dtype), is_sparse=sparse, name=name) x._keras_shape = shape x._uses_learning_phase = False x._cntk_placeholder = True return x def is_placeholder(x): """Returns whether `x` is a placeholder. # Arguments x: A candidate placeholder. # Returns Boolean. """ return hasattr(x, '_cntk_placeholder') and x._cntk_placeholder def is_keras_tensor(x): if not is_tensor(x): raise ValueError('Unexpectedly found an instance of type `' + str(type(x)) + '`. ' 'Expected a symbolic tensor instance.') return hasattr(x, '_keras_history') def is_tensor(x): return isinstance(x, (C.variables.Constant, C.variables.Variable, C.variables.Parameter, C.ops.functions.Function)) def shape(x): shape = list(int_shape(x)) num_dynamic = _get_dynamic_axis_num(x) non_dyn_shape = [] for i in range(len(x.shape)): if shape[i + num_dynamic] is None: non_dyn_shape.append(x.shape[i]) else: non_dyn_shape.append(shape[i + num_dynamic]) return shape[:num_dynamic] + non_dyn_shape def is_sparse(tensor): return tensor.is_sparse def int_shape(x): if hasattr(x, '_keras_shape'): return x._keras_shape shape = x.shape if hasattr(x, 'dynamic_axes'): dynamic_shape = [None for a in x.dynamic_axes] shape = tuple(dynamic_shape) + shape return shape def ndim(x): shape = int_shape(x) return len(shape) def _prepare_name(name, default): prefix = '_'.join(NAME_SCOPE_STACK) if name is None or name == '': return prefix + '/' + default return prefix + '/' + name def constant(value, dtype=None, shape=None, name=None): if dtype is None: dtype = floatx() if shape is None: shape = () np_value = value * np.ones(shape) const = C.constant(np_value, dtype=dtype, name=_prepare_name(name, 'constant')) const._keras_shape = const.shape const._uses_learning_phase = False return const def random_binomial(shape, p=0.0, dtype=None, seed=None): # use numpy workaround now if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed = np.random.randint(10e7) np.random.seed(seed) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) size = 1 for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') size *= _ binomial = np.random.binomial(1, p, size).astype(dtype).reshape(shape) return variable(value=binomial, dtype=dtype) def random_uniform(shape, minval=0.0, maxval=1.0, dtype=None, seed=None): for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') return random_uniform_variable(shape, minval, maxval, dtype, seed) def random_uniform_variable(shape, low, high, dtype=None, name=None, seed=None): if dtype is None: dtype = floatx() if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed = np.random.randint(10e3) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) if name is None: name = '' scale = (high - low) / 2 p = C.parameter( shape, init=C.initializer.uniform( scale, seed=seed), dtype=dtype, name=name) return variable(value=p.value + low + scale) def random_normal_variable( shape, mean, scale, dtype=None, name=None, seed=None): if dtype is None: dtype = floatx() if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed =	np.random.randint(10e7)	numpy.random.randint
""" Unit tests for the system interface.""" import unittest from six import assertRaisesRegex from six.moves import cStringIO import numpy as np from openmdao.api import Problem, Group, IndepVarComp, ExecComp from openmdao.test_suite.components.options_feature_vector import VectorDoublingComp from openmdao.utils.assert_utils import assert_rel_error, assert_warning class TestSystem(unittest.TestCase): def test_vector_context_managers(self): g1 = Group() g1.add_subsystem('Indep', IndepVarComp('a', 5.0), promotes=['a']) g2 = g1.add_subsystem('G2', Group(), promotes=['']) g2.add_subsystem('C1', ExecComp('b=2a'), promotes=['a', 'b']) model = Group() model.add_subsystem('G1', g1, promotes=['b']) model.add_subsystem('Sink', ExecComp('c=2b'), promotes=['b']) p = Problem(model=model) p.set_solver_print(level=0) # Test pre-setup errors with self.assertRaises(Exception) as cm: inputs, outputs, residuals = model.get_nonlinear_vectors() self.assertEqual(str(cm.exception), "Group: Cannot get vectors because setup has not yet been called.") with self.assertRaises(Exception) as cm: d_inputs, d_outputs, d_residuals = model.get_linear_vectors('vec') self.assertEqual(str(cm.exception), "Group: Cannot get vectors because setup has not yet been called.") p.setup() p.run_model() # Test inputs with original values inputs, outputs, residuals = model.get_nonlinear_vectors() self.assertEqual(inputs['G1.G2.C1.a'], 5.) inputs, outputs, residuals = g1.get_nonlinear_vectors() self.assertEqual(inputs['G2.C1.a'], 5.) # Test inputs after setting a new value inputs, outputs, residuals = g2.get_nonlinear_vectors() inputs['C1.a'] = -1. inputs, outputs, residuals = model.get_nonlinear_vectors() self.assertEqual(inputs['G1.G2.C1.a'], -1.) inputs, outputs, residuals = g1.get_nonlinear_vectors() self.assertEqual(inputs['G2.C1.a'], -1.) # Test outputs with original values inputs, outputs, residuals = model.get_nonlinear_vectors() self.assertEqual(outputs['G1.G2.C1.b'], 10.) inputs, outputs, residuals = g2.get_nonlinear_vectors() # Test outputs after setting a new value inputs, outputs, residuals = model.get_nonlinear_vectors() outputs['G1.G2.C1.b'] = 123. self.assertEqual(outputs['G1.G2.C1.b'], 123.) inputs, outputs, residuals = g2.get_nonlinear_vectors() outputs['C1.b'] = 789. self.assertEqual(outputs['C1.b'], 789.) # Test residuals inputs, outputs, residuals = model.get_nonlinear_vectors() residuals['G1.G2.C1.b'] = 99.0 self.assertEqual(residuals['G1.G2.C1.b'], 99.0) # Test linear d_inputs, d_outputs, d_residuals = model.get_linear_vectors('linear') d_outputs['G1.G2.C1.b'] = 10. self.assertEqual(d_outputs['G1.G2.C1.b'], 10.) # Test linear with invalid vec_name with self.assertRaises(Exception) as cm: d_inputs, d_outputs, d_residuals = model.get_linear_vectors('bad_name') self.assertEqual(str(cm.exception), "Group (<model>): There is no linear vector named %s" % 'bad_name') def test_set_checks_shape(self): indep = IndepVarComp() indep.add_output('a') indep.add_output('x', shape=(5, 1)) g1 = Group() g1.add_subsystem('Indep', indep, promotes=['a', 'x']) g2 = g1.add_subsystem('G2', Group(), promotes=['']) g2.add_subsystem('C1', ExecComp('b=2a'), promotes=['a', 'b']) g2.add_subsystem('C2', ExecComp('y=2x', x=np.zeros((5, 1)), y=np.zeros((5, 1))), promotes=['x', 'y']) model = Group() model.add_subsystem('G1', g1, promotes=['b', 'y']) model.add_subsystem('Sink', ExecComp(('c=2b', 'z=2y'), y=np.zeros((5, 1)), z=	np.zeros((5, 1))	numpy.zeros
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k') plt.plot(((time[-202] + time[-201]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed', label=textwrap.fill('Neural network targets', 13)) plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(((time_extended[-1001] + time_extended[-1000]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed') plt.xlim(3.4 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/neural_network.png') plt.show() # plot 6a np.random.seed(0) time = np.linspace(0, 5 * np.pi, 1001) knots_51 = np.linspace(0, 5 * np.pi, 51) time_series = np.cos(2 * time) + np.cos(4 * time) + np.cos(8 * time) noise = np.random.normal(0, 1, len(time_series)) time_series += noise advemdpy = EMD(time=time, time_series=time_series) imfs_51, hts_51, ifs_51 = advemdpy.empirical_mode_decomposition(knots=knots_51, max_imfs=3, edge_effect='symmetric_anchor', verbose=False)[:3] knots_31 = np.linspace(0, 5 * np.pi, 31) imfs_31, hts_31, ifs_31 = advemdpy.empirical_mode_decomposition(knots=knots_31, max_imfs=2, edge_effect='symmetric_anchor', verbose=False)[:3] knots_11 = np.linspace(0, 5 * np.pi, 11) imfs_11, hts_11, ifs_11 = advemdpy.empirical_mode_decomposition(knots=knots_11, max_imfs=1, edge_effect='symmetric_anchor', verbose=False)[:3] fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) print(f'DFA fluctuation with 51 knots: {np.round(np.var(time_series - (imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :])), 3)}') for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[0].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[0].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) print(f'DFA fluctuation with 31 knots: {np.round(np.var(time_series - (imfs_31[1, :] + imfs_31[2, :])), 3)}') for knot in knots_31: axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[1].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[1].set_xticklabels(['', '', '', '', '', '']) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) axs[1].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[1].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[1].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[1].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') axs[2].plot(time, time_series, label='Time series') axs[2].plot(time, imfs_11[1, :], label='IMF 1 with 11 knots') axs[2].plot(time, imfs_31[2, :], label='IMF 2 with 31 knots') axs[2].plot(time, imfs_51[3, :], label='IMF 3 with 51 knots') print(f'DFA fluctuation with 11 knots: {np.round(np.var(time_series - imfs_51[3, :]), 3)}') for knot in knots_11: axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[2].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[2].set_xticklabels(['$0$', r'$\pi$', r'$2\pi$', r'$3\pi$', r'$4\pi$', r'$5\pi$']) box_2 = axs[2].get_position() axs[2].set_position([box_2.x0 - 0.05, box_2.y0, box_2.width * 0.85, box_2.height]) axs[2].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[2].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[2].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[2].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[2].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') plt.savefig('jss_figures/DFA_different_trends.png') plt.show() # plot 6b fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences Zoomed Region', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[0].set_ylim(-5.5, 5.5) axs[0].set_xlim(0.95 * np.pi, 1.55 * np.pi) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) for knot in knots_31: axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[1].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[1].set_xticklabels(['', '', '', '', '', '']) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) axs[1].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].set_ylim(-5.5, 5.5) axs[1].set_xlim(0.95 * np.pi, 1.55 * np.pi) axs[2].plot(time, time_series, label='Time series') axs[2].plot(time, imfs_11[1, :], label='IMF 1 with 11 knots') axs[2].plot(time, imfs_31[2, :], label='IMF 2 with 31 knots') axs[2].plot(time, imfs_51[3, :], label='IMF 3 with 51 knots') for knot in knots_11: axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[2].set_xticks([np.pi, (3 / 2) * np.pi]) axs[2].set_xticklabels([r'$\pi$', r'$\frac{3}{2}\pi$']) box_2 = axs[2].get_position() axs[2].set_position([box_2.x0 - 0.05, box_2.y0, box_2.width * 0.85, box_2.height]) axs[2].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[2].set_ylim(-5.5, 5.5) axs[2].set_xlim(0.95 * np.pi, 1.55 * np.pi) plt.savefig('jss_figures/DFA_different_trends_zoomed.png') plt.show() hs_ouputs = hilbert_spectrum(time, imfs_51, hts_51, ifs_51, max_frequency=12, plot=False) # plot 6c ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Simple Sinusoidal Time Seres with Added Noise', 50)) x_hs, y, z = hs_ouputs z_min, z_max = 0, np.abs(z).max() ax.pcolormesh(x_hs, y,	np.abs(z)	numpy.abs
""" Greedy Word Swap with Word Importance Ranking =================================================== When WIR method is set to ``unk``, this is a reimplementation of the search method from the paper: Is BERT Really Robust? A Strong Baseline for Natural Language Attack on Text Classification and Entailment by Jin et. al, 2019. See https://arxiv.org/abs/1907.11932 and https://github.com/jind11/TextFooler. """ import numpy as np import torch from torch.nn.functional import softmax from textattack.goal_function_results import GoalFunctionResultStatus from textattack.search_methods import SearchMethod from textattack.shared.validators import ( transformation_consists_of_word_swaps_and_deletions, ) class GreedyWordSwapWIR(SearchMethod): """An attack that greedily chooses from a list of possible perturbations in order of index, after ranking indices by importance. Args: wir_method: method for ranking most important words """ def __init__(self, wir_method="unk"): self.wir_method = wir_method def _get_index_order(self, initial_text): """Returns word indices of ``initial_text`` in descending order of importance.""" len_text = len(initial_text.words) if self.wir_method == "unk": leave_one_texts = [ initial_text.replace_word_at_index(i, "[UNK]") for i in range(len_text) ] leave_one_results, search_over = self.get_goal_results(leave_one_texts) index_scores = np.array([result.score for result in leave_one_results]) elif self.wir_method == "weighted-saliency": # first, compute word saliency leave_one_texts = [ initial_text.replace_word_at_index(i, "[UNK]") for i in range(len_text) ] leave_one_results, search_over = self.get_goal_results(leave_one_texts) saliency_scores = np.array([result.score for result in leave_one_results]) softmax_saliency_scores = softmax( torch.Tensor(saliency_scores), dim=0 ).numpy() # compute the largest change in score we can find by swapping each word delta_ps = [] for idx in range(len_text): transformed_text_candidates = self.get_transformations( initial_text, original_text=initial_text, indices_to_modify=[idx], ) if not transformed_text_candidates: # no valid synonym substitutions for this word delta_ps.append(0.0) continue swap_results, _ = self.get_goal_results(transformed_text_candidates) score_change = [result.score for result in swap_results] max_score_change = np.max(score_change) delta_ps.append(max_score_change) index_scores = softmax_saliency_scores * np.array(delta_ps) elif self.wir_method == "delete": leave_one_texts = [ initial_text.delete_word_at_index(i) for i in range(len_text) ] leave_one_results, search_over = self.get_goal_results(leave_one_texts) index_scores =	np.array([result.score for result in leave_one_results])	numpy.array
from __future__ import absolute_import from __future__ import division from __future__ import print_function import cntk as C import numpy as np from .common import floatx, epsilon, image_dim_ordering, image_data_format from collections import defaultdict from contextlib import contextmanager import warnings C.set_global_option('align_axis', 1) b_any = any dev = C.device.use_default_device() if dev.type() == 0: warnings.warn( 'CNTK backend warning: GPU is not detected. ' 'CNTK\'s CPU version is not fully optimized,' 'please run with GPU to get better performance.') # A learning phase is a bool tensor used to run Keras models in # either train mode (learning_phase == 1) or test mode (learning_phase == 0). # LEARNING_PHASE_PLACEHOLDER is the placeholder for dynamic learning phase _LEARNING_PHASE_PLACEHOLDER = C.constant(shape=(), dtype=np.float32, value=1.0, name='_keras_learning_phase') # static learning phase flag, if it is not 0 or 1, we will go with dynamic learning phase tensor. _LEARNING_PHASE = -1 _UID_PREFIXES = defaultdict(int) # cntk doesn't support gradient as symbolic op, to hook up with keras model, # we will create gradient as a constant placeholder, here use this global # map to keep the mapping from grad placeholder to parameter grad_parameter_dict = {} NAME_SCOPE_STACK = [] @contextmanager def name_scope(name): global NAME_SCOPE_STACK NAME_SCOPE_STACK.append(name) yield NAME_SCOPE_STACK.pop() def get_uid(prefix=''): _UID_PREFIXES[prefix] += 1 return _UID_PREFIXES[prefix] def learning_phase(): # If _LEARNING_PHASE is not 0 or 1, return dynamic learning phase tensor return _LEARNING_PHASE if _LEARNING_PHASE in {0, 1} else _LEARNING_PHASE_PLACEHOLDER def set_learning_phase(value): global _LEARNING_PHASE if value not in {0, 1}: raise ValueError('CNTK Backend: Set learning phase ' 'with value %s is not supported, ' 'expected 0 or 1.' % value) _LEARNING_PHASE = value def clear_session(): """Reset learning phase flag for cntk backend. """ global _LEARNING_PHASE global _LEARNING_PHASE_PLACEHOLDER _LEARNING_PHASE = -1 _LEARNING_PHASE_PLACEHOLDER.value = np.asarray(1.0) def in_train_phase(x, alt, training=None): global _LEARNING_PHASE if training is None: training = learning_phase() uses_learning_phase = True else: uses_learning_phase = False # CNTK currently don't support cond op, so here we use # element_select approach as workaround. It may have # perf issue, will resolve it later with cntk cond op. if callable(x) and isinstance(x, C.cntk_py.Function) is False: x = x() if callable(alt) and isinstance(alt, C.cntk_py.Function) is False: alt = alt() if training is True: x._uses_learning_phase = uses_learning_phase return x else: # if _LEARNING_PHASE is static if isinstance(training, int) or isinstance(training, bool): result = x if training == 1 or training is True else alt else: result = C.element_select(training, x, alt) result._uses_learning_phase = uses_learning_phase return result def in_test_phase(x, alt, training=None): return in_train_phase(alt, x, training=training) def _convert_string_dtype(dtype): # cntk only support float32 and float64 if dtype == 'float32': return np.float32 elif dtype == 'float64': return np.float64 else: # cntk only running with float, # try to cast to float to run the model return np.float32 def _convert_dtype_string(dtype): if dtype == np.float32: return 'float32' elif dtype == np.float64: return 'float64' else: raise ValueError('CNTK Backend: Unsupported dtype: %s. ' 'CNTK only supports float32 and ' 'float64.' % dtype) def variable(value, dtype=None, name=None, constraint=None): """Instantiates a variable and returns it. # Arguments value: Numpy array, initial value of the tensor. dtype: Tensor type. name: Optional name string for the tensor. constraint: Optional projection function to be applied to the variable after an optimizer update. # Returns A variable instance (with Keras metadata included). """ if dtype is None: dtype = floatx() if name is None: name = '' if isinstance( value, C.variables.Constant) or isinstance( value, C.variables.Parameter): value = value.value # we don't support init parameter with symbolic op, so eval it first as # workaround if isinstance(value, C.cntk_py.Function): value = eval(value) shape = value.shape if hasattr(value, 'shape') else () if hasattr(value, 'dtype') and value.dtype != dtype and len(shape) > 0: value = value.astype(dtype) # TODO: remove the conversion when cntk supports int32, int64 # https://docs.microsoft.com/en-us/python/api/cntk.variables.parameter dtype = 'float32' if 'int' in str(dtype) else dtype v = C.parameter(shape=shape, init=value, dtype=dtype, name=_prepare_name(name, 'variable')) v._keras_shape = v.shape v._uses_learning_phase = False v.constraint = constraint return v def bias_add(x, bias, data_format=None): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) dims = len(x.shape) if dims > 0 and x.shape[0] == C.InferredDimension: dims -= 1 bias_dims = len(bias.shape) if bias_dims != 1 and bias_dims != dims: raise ValueError('Unexpected bias dimensions %d, ' 'expected 1 or %d dimensions' % (bias_dims, dims)) if dims == 4: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1, 1, 1) else: shape = (bias.shape[3],) + bias.shape[:3] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, 1, 1, bias.shape[0]) else: shape = bias.shape elif dims == 3: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1, 1) else: shape = (bias.shape[2],) + bias.shape[:2] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, 1, bias.shape[0]) else: shape = bias.shape elif dims == 2: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1) else: shape = (bias.shape[1],) + bias.shape[:1] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, bias.shape[0]) else: shape = bias.shape else: shape = bias.shape return x + reshape(bias, shape) def eval(x): if isinstance(x, C.cntk_py.Function): return x.eval() elif isinstance(x, C.variables.Constant) or isinstance(x, C.variables.Parameter): return x.value else: raise ValueError('CNTK Backend: `eval` method on ' '`%s` type is not supported. ' 'CNTK only supports `eval` with ' '`Function`, `Constant` or ' '`Parameter`.' % type(x)) def placeholder( shape=None, ndim=None, dtype=None, sparse=False, name=None, dynamic_axis_num=1): if dtype is None: dtype = floatx() if not shape: if ndim: shape = tuple([None for _ in range(ndim)]) dynamic_dimension = C.FreeDimension if _get_cntk_version() >= 2.2 else C.InferredDimension cntk_shape = [dynamic_dimension if s is None else s for s in shape] cntk_shape = tuple(cntk_shape) if dynamic_axis_num > len(cntk_shape): raise ValueError('CNTK backend: creating placeholder with ' '%d dimension is not supported, at least ' '%d dimensions are needed.' % (len(cntk_shape, dynamic_axis_num))) if name is None: name = '' cntk_shape = cntk_shape[dynamic_axis_num:] x = C.input( shape=cntk_shape, dtype=_convert_string_dtype(dtype), is_sparse=sparse, name=name) x._keras_shape = shape x._uses_learning_phase = False x._cntk_placeholder = True return x def is_placeholder(x): """Returns whether `x` is a placeholder. # Arguments x: A candidate placeholder. # Returns Boolean. """ return hasattr(x, '_cntk_placeholder') and x._cntk_placeholder def is_keras_tensor(x): if not is_tensor(x): raise ValueError('Unexpectedly found an instance of type `' + str(type(x)) + '`. ' 'Expected a symbolic tensor instance.') return hasattr(x, '_keras_history') def is_tensor(x): return isinstance(x, (C.variables.Constant, C.variables.Variable, C.variables.Parameter, C.ops.functions.Function)) def shape(x): shape = list(int_shape(x)) num_dynamic = _get_dynamic_axis_num(x) non_dyn_shape = [] for i in range(len(x.shape)): if shape[i + num_dynamic] is None: non_dyn_shape.append(x.shape[i]) else: non_dyn_shape.append(shape[i + num_dynamic]) return shape[:num_dynamic] + non_dyn_shape def is_sparse(tensor): return tensor.is_sparse def int_shape(x): if hasattr(x, '_keras_shape'): return x._keras_shape shape = x.shape if hasattr(x, 'dynamic_axes'): dynamic_shape = [None for a in x.dynamic_axes] shape = tuple(dynamic_shape) + shape return shape def ndim(x): shape = int_shape(x) return len(shape) def _prepare_name(name, default): prefix = '_'.join(NAME_SCOPE_STACK) if name is None or name == '': return prefix + '/' + default return prefix + '/' + name def constant(value, dtype=None, shape=None, name=None): if dtype is None: dtype = floatx() if shape is None: shape = () np_value = value * np.ones(shape) const = C.constant(np_value, dtype=dtype, name=_prepare_name(name, 'constant')) const._keras_shape = const.shape const._uses_learning_phase = False return const def random_binomial(shape, p=0.0, dtype=None, seed=None): # use numpy workaround now if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed = np.random.randint(10e7) np.random.seed(seed) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) size = 1 for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') size = _ binomial = np.random.binomial(1, p, size).astype(dtype).reshape(shape) return variable(value=binomial, dtype=dtype) def random_uniform(shape, minval=0.0, maxval=1.0, dtype=None, seed=None): for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') return random_uniform_variable(shape, minval, maxval, dtype, seed) def random_uniform_variable(shape, low, high, dtype=None, name=None, seed=None): if dtype is None: dtype = floatx() if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed = np.random.randint(10e3) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) if name is None: name = '' scale = (high - low) / 2 p = C.parameter( shape, init=C.initializer.uniform( scale, seed=seed), dtype=dtype, name=name) return variable(value=p.value + low + scale) def random_normal_variable( shape, mean, scale, dtype=None, name=None, seed=None): if dtype is None: dtype = floatx() if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed = np.random.randint(10e7) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) if name is None: name = '' return C.parameter( shape=shape, init=C.initializer.normal( scale=scale, seed=seed), dtype=dtype, name=name) def random_normal(shape, mean=0.0, stddev=1.0, dtype=None, seed=None): if dtype is None: dtype = floatx() for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') # how to apply mean and stddev return random_normal_variable(shape=shape, mean=mean, scale=1.0, seed=seed) def truncated_normal(shape, mean=0.0, stddev=1.0, dtype=None, seed=None): if seed is None: seed = np.random.randint(1, 10e6) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) return C.parameter( shape, init=C.initializer.truncated_normal( stddev, seed=seed), dtype=dtype) def dtype(x): return _convert_dtype_string(x.dtype) def zeros(shape, dtype=None, name=None): if dtype is None: dtype = floatx() ctype = _convert_string_dtype(dtype) return variable(value=np.zeros(shape, ctype), dtype=dtype, name=name) def ones(shape, dtype=None, name=None): if dtype is None: dtype = floatx() ctype = _convert_string_dtype(dtype) return variable(value=np.ones(shape, ctype), dtype=dtype, name=name) def eye(size, dtype=None, name=None): if dtype is None: dtype = floatx() return variable(np.eye(size), dtype, name) def zeros_like(x, dtype=None, name=None): return x 0 def ones_like(x, dtype=None, name=None): return zeros_like(x) + 1 def count_params(x): for _ in x.shape: if _ == C.InferredDimension or _ == C.FreeDimension: raise ValueError('CNTK backend: `count_params` with dynamic ' 'shape is not supported. Please provide ' 'fixed dimension instead of `None`.') return np.prod(int_shape(x)) def cast(x, dtype): # cntk calculate everything in float, so don't need case from bool / int return x def dot(x, y): if len(x.shape) > 2 or len(y.shape) > 2: y_shape = int_shape(y) if len(y_shape) > 2: permutation = [len(y_shape) - 2] permutation += list(range(len(y_shape) - 2)) permutation += [len(y_shape) - 1] y = C.transpose(y, perm=permutation) return C.times(x, y, len(y_shape) - 1) else: return C.times(x, y) def batch_dot(x, y, axes=None): x_shape = int_shape(x) y_shape = int_shape(y) if isinstance(axes, int): axes = (axes, axes) if axes is None: # behaves like tf.batch_matmul as default axes = [len(x_shape) - 1, len(y_shape) - 2] if b_any([isinstance(a, (list, tuple)) for a in axes]): raise ValueError('Multiple target dimensions are not supported. ' + 'Expected: None, int, (int, int), ' + 'Provided: ' + str(axes)) if len(x_shape) == 2 and len(y_shape) == 2: if axes[0] == axes[1]: result = sum(x * y, axis=axes[0], keepdims=True) return result if axes[0] == 1 else transpose(result) else: return sum(x * transpose(y), axis=axes[0], keepdims=True) else: if len(y_shape) == 2: y = expand_dims(y) normalized_axis = [] normalized_axis.append(_normalize_axis(axes[0], x)[0]) normalized_axis.append(_normalize_axis(axes[1], y)[0]) # transpose i = normalized_axis[0] while i < len(x.shape) - 1: x = C.swapaxes(x, i, i + 1) i += 1 i = normalized_axis[1] while i > 0: y = C.swapaxes(y, i, i - 1) i -= 1 result = C.times(x, y, output_rank=(len(y.shape) - 1) if len(y.shape) > 1 else 1) if len(y_shape) == 2: result = squeeze(result, -1) return result def transpose(x): return C.swapaxes(x, 0, 1) def gather(reference, indices): # There is a bug in cntk gather op which may cause crash. # We have made a fix but not catched in CNTK 2.1 release. # Will update with gather op in next release if _get_cntk_version() >= 2.2: return C.ops.gather(reference, indices) else: num_classes = reference.shape[0] one_hot_matrix = C.ops.one_hot(indices, num_classes) return C.times(one_hot_matrix, reference, output_rank=len(reference.shape) - 1) def _remove_dims(x, axis, keepdims=False): if keepdims is False and isinstance(axis, list): # sequence axis is removed by default, so don't need reshape on it reduce_axes = [] for a in axis: if isinstance(a, C.Axis) is False: reduce_axes.append(a) return _reshape_dummy_dim(x, reduce_axes) else: if isinstance(axis, list): has_seq = False for a in axis: if isinstance(a, C.Axis): has_seq = True break if has_seq: nones = _get_dynamic_axis_num(x) x = expand_dims(x, nones) return x def max(x, axis=None, keepdims=False): axis = _normalize_axis(axis, x) output = _reduce_on_axis(x, axis, 'reduce_max') return _remove_dims(output, axis, keepdims) def min(x, axis=None, keepdims=False): axis = _normalize_axis(axis, x) output = _reduce_on_axis(x, axis, 'reduce_min') return _remove_dims(output, axis, keepdims) def sum(x, axis=None, keepdims=False): axis = _normalize_axis(axis, x) output = _reduce_on_axis(x, axis, 'reduce_sum') return _remove_dims(output, axis, keepdims) def prod(x, axis=None, keepdims=False): axis = _normalize_axis(axis, x) output = _reduce_on_axis(x, axis, 'reduce_prod') return _remove_dims(output, axis, keepdims) def logsumexp(x, axis=None, keepdims=False): return log(sum(exp(x), axis=axis, keepdims=keepdims)) def var(x, axis=None, keepdims=False): m = mean(x, axis, keepdims=True) devs_squared = C.square(x - m) return mean(devs_squared, axis=axis, keepdims=keepdims) def std(x, axis=None, keepdims=False): return C.sqrt(var(x, axis=axis, keepdims=keepdims)) def expand_dims(x, axis=-1): shape = list(int_shape(x)) nones = _get_dynamic_axis_num(x) index = axis if axis >= 0 else len(shape) + 1 shape.insert(index, 1) new_shape = shape[nones:] new_shape = tuple( [C.InferredDimension if _ is None else _ for _ in new_shape]) result = C.reshape(x, new_shape) if index < nones: result._keras_shape = shape return result def squeeze(x, axis): if isinstance(axis, tuple): axis = list(axis) if not isinstance(axis, list): axis = [axis] shape = list(int_shape(x)) _axis = [] for _ in axis: if isinstance(_, int): _axis.append(_ if _ >= 0 else _ + len(shape)) if len(_axis) == 0: return x nones = _get_dynamic_axis_num(x) for _ in sorted(_axis, reverse=True): del shape[_] new_shape = shape[nones:] new_shape = tuple([C.InferredDimension if _ == C.FreeDimension else _ for _ in new_shape]) return C.reshape(x, new_shape) def tile(x, n): if isinstance(n, int): n = (n,) elif isinstance(n, list): n = tuple(n) shape = int_shape(x) num_dynamic_axis = _get_dynamic_axis_num(x) # Padding the axis if len(n) < len(shape): n = tuple([1 for _ in range(len(shape) - len(n))]) + n if len(n) != len(shape): raise NotImplementedError i = num_dynamic_axis for i, rep in enumerate(n): if i >= num_dynamic_axis and shape[i] is not None: tmp = [x] * rep x = C.splice(tmp, axis=i - num_dynamic_axis) i += 1 return x def _normalize_axis(axis, x): shape = int_shape(x) ndim = len(shape) nones = _get_dynamic_axis_num(x) if nones > ndim: raise ValueError('CNTK Backend: tensor with keras shape: `%s` has ' '%d cntk dynamic axis, this is not expected, please ' 'double check the keras shape history.' % (str(shape), nones)) # Current cntk does not support shape like (1, batch). so using the workaround # here to mapping the correct axis. Will remove this tricky after we add support # in native cntk op cntk_axis = [] dynamic_axis_index = 0 for i in range(ndim): if shape[i] is None and dynamic_axis_index < nones: cntk_axis.append(x.dynamic_axes[dynamic_axis_index]) dynamic_axis_index += 1 else: cntk_axis.append(i - dynamic_axis_index) if dynamic_axis_index < nones: i = 0 while dynamic_axis_index < nones: cntk_axis[i] = x.dynamic_axes[dynamic_axis_index] i += 1 dynamic_axis_index += 1 while i < len(cntk_axis): cntk_axis[i] -= nones i += 1 if isinstance(axis, tuple): _axis = list(axis) elif isinstance(axis, int): _axis = [axis] elif isinstance(axis, list): _axis = list(axis) else: _axis = axis if isinstance(_axis, list): for i, a in enumerate(_axis): if a is not None and a < 0: _axis[i] = (a % ndim) if _axis[i] is not None: _axis[i] = cntk_axis[_axis[i]] else: if _axis is None: _axis = C.Axis.all_axes() return _axis def _reshape_dummy_dim(x, axis): shape = list(x.shape) _axis = [_ + len(shape) if _ < 0 else _ for _ in axis] if shape.count(C.InferredDimension) > 1 or shape.count(C.FreeDimension) > 1: result = x for index in sorted(_axis, reverse=True): result = C.reshape(result, shape=(), begin_axis=index, end_axis=index + 1) return result else: for index in sorted(_axis, reverse=True): del shape[index] shape = [C.InferredDimension if _ == C.FreeDimension else _ for _ in shape] return C.reshape(x, shape) def mean(x, axis=None, keepdims=False): axis = _normalize_axis(axis, x) output = _reduce_on_axis(x, axis, 'reduce_mean') return _remove_dims(output, axis, keepdims) def any(x, axis=None, keepdims=False): reduce_result = sum(x, axis, keepdims=keepdims) any_matrix = C.element_select( reduce_result, ones_like(reduce_result), zeros_like(reduce_result)) if len(reduce_result.shape) == 0 and _get_dynamic_axis_num(x) == 0: return C.reduce_sum(any_matrix) else: return any_matrix def all(x, axis=None, keepdims=False): reduce_result = prod(x, axis, keepdims=keepdims) all_matrix = C.element_select( reduce_result, ones_like(reduce_result), zeros_like(reduce_result)) if len(reduce_result.shape) == 0 and _get_dynamic_axis_num(x) == 0: return C.reduce_sum(all_matrix) else: return all_matrix def classification_error(target, output, axis=-1): return C.ops.reduce_mean( C.equal( argmax( output, axis=-1), argmax( target, axis=-1)), axis=C.Axis.all_axes()) def argmax(x, axis=-1): axis = [axis] axis = _normalize_axis(axis, x) output = C.ops.argmax(x, axis=axis[0]) return _reshape_dummy_dim(output, axis) def argmin(x, axis=-1): axis = [axis] axis = _normalize_axis(axis, x) output = C.ops.argmin(x, axis=axis[0]) return _reshape_dummy_dim(output, axis) def square(x): return C.square(x) def abs(x): return C.abs(x) def sqrt(x): return C.sqrt(x) def exp(x): return C.exp(x) def log(x): return C.log(x) def round(x): return C.round(x) def sigmoid(x): return C.sigmoid(x) def sign(x): return x / C.abs(x) def pow(x, a): return C.pow(x, a) def clip(x, min_value, max_value): if max_value is not None and max_value < min_value: max_value = min_value if max_value is None: max_value = np.inf if min_value is None: min_value = -np.inf return C.clip(x, min_value, max_value) def binary_crossentropy(target, output, from_logits=False): if from_logits: output = C.sigmoid(output) output = C.clip(output, epsilon(), 1.0 - epsilon()) output = -target C.log(output) - (1.0 - target) * C.log(1.0 - output) return output def get_variable_shape(x): return int_shape(x) def update(x, new_x): return C.assign(x, new_x) def moving_average_update(variable, value, momentum): return C.assign(variable, variable * momentum + value * (1. - momentum)) def update_add(x, increment): result = x + increment return C.assign(x, result) def gradients(loss, variables): # cntk does not support gradients as symbolic op, # to hook up with keras model # we will return a constant as place holder, the cntk learner will apply # the gradient during training. global grad_parameter_dict if isinstance(variables, list) is False: variables = [variables] grads = [] for v in variables: g = C.constant(0, shape=v.shape, name='keras_grad_placeholder') grads.append(g) grad_parameter_dict[g] = v return grads def equal(x, y): return C.equal(x, y) def not_equal(x, y): return C.not_equal(x, y) def greater(x, y): return C.greater(x, y) def greater_equal(x, y): return C.greater_equal(x, y) def less(x, y): return C.less(x, y) def less_equal(x, y): return C.less_equal(x, y) def maximum(x, y): return C.element_max(x, y) def minimum(x, y): return C.element_min(x, y) def sin(x): return C.sin(x) def cos(x): return C.cos(x) def normalize_batch_in_training(x, gamma, beta, reduction_axes, epsilon=1e-3): if gamma is None: if beta is None: gamma = ones_like(x) else: gamma = ones_like(beta) if beta is None: if gamma is None: beta = zeros_like(x) else: beta = zeros_like(gamma) mean, variant = _moments(x, _normalize_axis(reduction_axes, x)) if sorted(reduction_axes) == list(range(ndim(x)))[:-1]: normalized = batch_normalization( x, mean, variant, beta, gamma, epsilon) else: # need broadcasting target_shape = [] x_shape = int_shape(x) # skip the batch axis for axis in range(1, ndim(x)): if axis in reduction_axes: target_shape.append(1) if ndim(gamma) > axis: gamma = C.reduce_mean(gamma, axis - 1) beta = C.reduce_mean(beta, axis - 1) else: target_shape.append(x_shape[axis]) broadcast_mean = C.reshape(mean, target_shape) broadcast_var = C.reshape(variant, target_shape) broadcast_gamma = C.reshape(gamma, target_shape) broadcast_beta = C.reshape(beta, target_shape) normalized = batch_normalization( x, broadcast_mean, broadcast_var, broadcast_beta, broadcast_gamma, epsilon) return normalized, mean, variant def _moments(x, axes=None, shift=None, keep_dims=False): _axes = tuple(axes) if shift is None: shift = x # Compute true mean while keeping the dims for proper broadcasting. for axis in _axes: shift = C.reduce_mean(shift, axis=axis) shift = C.stop_gradient(shift) shifted_mean = C.minus(x, shift) for axis in _axes: shifted_mean = C.reduce_mean(shifted_mean, axis=axis) variance_mean = C.square(C.minus(x, shift)) for axis in _axes: variance_mean = C.reduce_mean(variance_mean, axis=axis) variance = C.minus(variance_mean, C.square(shifted_mean)) mean = C.plus(shifted_mean, shift) if not keep_dims: mean = squeeze(mean, _axes) variance = squeeze(variance, _axes) return mean, variance def batch_normalization(x, mean, var, beta, gamma, epsilon=1e-3): # The mean / var / beta / gamma may be processed by broadcast # so it may have an extra batch axis with 1, it is not needed # in cntk, need to remove those dummy axis. if ndim(mean) == ndim(x) and shape(mean)[0] == 1: mean = _reshape_dummy_dim(mean, [0]) if ndim(var) == ndim(x) and shape(var)[0] == 1: var = _reshape_dummy_dim(var, [0]) if gamma is None: gamma = ones_like(var) elif ndim(gamma) == ndim(x) and shape(gamma)[0] == 1: gamma = _reshape_dummy_dim(gamma, [0]) if beta is None: beta = zeros_like(mean) elif ndim(beta) == ndim(x) and shape(beta)[0] == 1: beta = _reshape_dummy_dim(beta, [0]) return (x - mean) / (C.sqrt(var) + epsilon) * gamma + beta def concatenate(tensors, axis=-1): if len(tensors) == 0: return None axis = [axis] axis = _normalize_axis(axis, tensors[0]) return C.splice(tensors, axis=axis[0]) def flatten(x): return reshape(x, (-1,)) def reshape(x, shape): shape = tuple([C.InferredDimension if _ == C.FreeDimension else _ for _ in shape]) if isinstance(x, C.variables.Parameter): return C.reshape(x, shape) else: num_dynamic_axis = _get_dynamic_axis_num(x) if num_dynamic_axis == 1 and len(shape) > 0 and shape[0] == -1: # collapse axis with batch axis if b_any(_ == C.InferredDimension for _ in x.shape) or b_any( _ == C.FreeDimension for _ in x.shape): warnings.warn( 'Warning: CNTK backend does not support ' 'collapse of batch axis with inferred dimension. ' 'The reshape did not take place.') return x return _reshape_batch(x, shape) else: # no collapse, then first need to padding the shape if num_dynamic_axis >= len(shape): i = 0 while i < len(shape): if shape[i] is None or shape[i] == -1: i += 1 else: break shape = tuple([-1 for _ in range(num_dynamic_axis - i)]) + shape new_shape = list(shape) new_shape = new_shape[num_dynamic_axis:] new_shape = [C.InferredDimension if _ is None else _ for _ in new_shape] return C.reshape(x, new_shape) def permute_dimensions(x, pattern): dims = len(int_shape(x)) num_dynamic_axis = _get_dynamic_axis_num(x) if isinstance(pattern, list): current_layout = [i for i in range(dims)] else: current_layout = tuple([i for i in range(dims)]) if num_dynamic_axis > 0 and pattern[:num_dynamic_axis] != current_layout[:num_dynamic_axis]: raise ValueError('CNTK backend: the permute pattern %s ' 'requested permute on dynamic axis, ' 'which is not supported. Please do permute ' 'on static axis.' % pattern) axis = list(pattern) axis = axis[num_dynamic_axis:] axis = _normalize_axis(axis, x) return C.transpose(x, axis) def resize_images(x, height_factor, width_factor, data_format): if data_format == 'channels_first': output = repeat_elements(x, height_factor, axis=2) output = repeat_elements(output, width_factor, axis=3) return output elif data_format == 'channels_last': output = repeat_elements(x, height_factor, axis=1) output = repeat_elements(output, width_factor, axis=2) return output else: raise ValueError('CNTK Backend: Invalid data_format:', data_format) def resize_volumes(x, depth_factor, height_factor, width_factor, data_format): if data_format == 'channels_first': output = repeat_elements(x, depth_factor, axis=2) output = repeat_elements(output, height_factor, axis=3) output = repeat_elements(output, width_factor, axis=4) return output elif data_format == 'channels_last': output = repeat_elements(x, depth_factor, axis=1) output = repeat_elements(output, height_factor, axis=2) output = repeat_elements(output, width_factor, axis=3) return output else: raise ValueError('CNTK Backend: Invalid data_format:', data_format) def repeat_elements(x, rep, axis): axis = _normalize_axis(axis, x) axis = axis[0] slices = [] shape = x.shape i = 0 while i < shape[axis]: tmp = C.ops.slice(x, axis, i, i + 1) for _ in range(rep): slices.append(tmp) i += 1 return C.splice(slices, axis=axis) def repeat(x, n): # this is a workaround for recurrent layer # if n is inferred dimension, # we can't figure out how to repeat it in cntk now # return the same x to take cntk broadcast feature # to make the recurrent layer work. # need to be fixed in GA. if n is C.InferredDimension or n is C.FreeDimension: return x index = 1 - _get_dynamic_axis_num(x) if index < 0 or index > 1: raise NotImplementedError new_shape = list(x.shape) new_shape.insert(index, 1) new_shape = tuple(new_shape) x = C.reshape(x, new_shape) temp = [x] * n return C.splice(temp, axis=index) def tanh(x): return C.tanh(x) def _static_rnn(step_function, inputs, initial_states, go_backwards=False, mask=None, constants=None, unroll=False, input_length=None): shape = int_shape(inputs) dims = len(shape) uses_learning_phase = False if dims < 3: raise ValueError('Input should be at least 3D.') # if the second axis is static axis, CNTK will do unroll by default if shape[1] is None: raise ValueError('CNTK Backend: the input of static rnn ' 'has shape `%s`, the second axis ' 'is not static. If you want to run ' 'rnn with non-static axis, please try ' 'dynamic rnn with sequence axis.' % shape) if constants is None: constants = [] if mask is not None: mask_shape = int_shape(mask) if len(mask_shape) == dims - 1: mask = expand_dims(mask) nones = _get_dynamic_axis_num(inputs) states = tuple(initial_states) outputs = [] time_axis = 1 - nones if nones > 0 else 1 if go_backwards: i = shape[1] - 1 while i >= 0: current = C.ops.slice(inputs, time_axis, i, i + 1) # remove dummy dimension current = squeeze(current, time_axis) output, new_states = step_function( current, tuple(states) + tuple(constants)) if getattr(output, '_uses_learning_phase', False): uses_learning_phase = True if mask is not None: mask_slice = C.ops.slice(mask, time_axis, i, i + 1) mask_slice = squeeze(mask_slice, time_axis) if len(outputs) == 0: prev_output = zeros_like(output) else: prev_output = outputs[-1] output = C.ops.element_select(mask_slice, output, prev_output) return_states = [] for s, n_s in zip(states, new_states): return_states.append( C.ops.element_select( mask_slice, n_s, s)) new_states = return_states outputs.append(output) states = new_states i -= 1 else: i = 0 while i < shape[1]: current = C.ops.slice(inputs, time_axis, i, i + 1) # remove dummy dimension current = squeeze(current, 1) output, new_states = step_function( current, tuple(states) + tuple(constants)) if getattr(output, '_uses_learning_phase', False): uses_learning_phase = True if mask is not None: mask_slice = C.ops.slice(mask, time_axis, i, i + 1) mask_slice = squeeze(mask_slice, 1) if len(outputs) == 0: prev_output = zeros_like(output) else: prev_output = outputs[-1] output = C.ops.element_select(mask_slice, output, prev_output) return_states = [] for s, n_s in zip(states, new_states): return_states.append( C.ops.element_select( mask_slice, n_s, s)) new_states = return_states outputs.append(output) states = new_states[:len(states)] i += 1 i = 1 # add the time_step axis back final_output = expand_dims(outputs[0], 1) last_output = outputs[0] while i < len(outputs): # add the time_step axis back output_slice = expand_dims(outputs[i], 1) final_output = C.splice(final_output, output_slice, axis=time_axis) last_output = outputs[i] i += 1 last_output._uses_learning_phase = uses_learning_phase return last_output, final_output, states def rnn(step_function, inputs, initial_states, go_backwards=False, mask=None, constants=None, unroll=False, input_length=None): shape = int_shape(inputs) dims = len(shape) global uses_learning_phase uses_learning_phase = False if dims < 3: raise ValueError('CNTK Backend: the input of rnn has only rank %d ' 'Need at least rank 3 to run RNN.' % dims) if _get_dynamic_axis_num(inputs) == 0 or unroll: return _static_rnn( step_function, inputs, initial_states, go_backwards, mask, constants, unroll, input_length) if constants is None: constants = [] num_time_step = shape[1] if num_time_step is None and not has_seq_axis(inputs): num_time_step = inputs.shape[0] initial = [] for s in initial_states: if _get_dynamic_axis_num(s) == 0: if hasattr(C, 'to_batch'): initial.append(C.to_batch(s)) else: initial.append(C.user_function(ConvertToBatch(s))) else: initial.append(s) need_convert = not has_seq_axis(inputs) if go_backwards and need_convert is False: raise NotImplementedError('CNTK Backend: `go_backwards` is not supported with ' 'variable-length sequences. Please specify a ' 'static length for your sequences.') rnn_inputs = inputs if need_convert: if go_backwards: rnn_inputs = reverse(rnn_inputs, 1) rnn_inputs = C.to_sequence(rnn_inputs) rnn_constants = [] for constant in constants: if isinstance(constant, list): new_c = [] for c in constant: if _get_dynamic_axis_num(c) == 1: new_c.append(C.sequence.broadcast_as(c, rnn_inputs)) else: new_c.append(c) rnn_constants.append(new_c) else: if _get_dynamic_axis_num(constant) == 1: rnn_constants.append(C.sequence.broadcast_as(constant, rnn_inputs)) else: rnn_constants.append(constant) else: rnn_constants = constants if mask is not None and not has_seq_axis(mask): if go_backwards: mask = reverse(mask, 1) if len(int_shape(mask)) == 2: mask = expand_dims(mask) mask = C.to_sequence_like(mask, rnn_inputs) states = tuple(initial) with C.default_options(axis_offset=1): def _recurrence(x, states, m): # create place holder place_holders = [C.placeholder(dynamic_axes=x.dynamic_axes) for _ in states] past_values = [] for s, p in zip(states, place_holders): past_values.append(C.sequence.past_value(p, s)) new_output, new_states = step_function( x, tuple(past_values) + tuple(rnn_constants)) if getattr(new_output, '_uses_learning_phase', False): global uses_learning_phase uses_learning_phase = True if m is not None: new_states = [C.element_select(m, n, s) for n, s in zip(new_states, past_values)] n_s = [] for o, p in zip(new_states, place_holders): n_s.append(o.replace_placeholders({p: o.output})) if len(n_s) > 0: new_output = n_s[0] return new_output, n_s final_output, final_states = _recurrence(rnn_inputs, states, mask) last_output = C.sequence.last(final_output) last_states = [C.sequence.last(s) for s in final_states] if need_convert: final_output = C.sequence.unpack(final_output, 0, no_mask_output=True) if num_time_step is not None and num_time_step is not C.FreeDimension: final_output = _reshape_sequence(final_output, num_time_step) f_stats = [] for l_s, i_s in zip(last_states, initial_states): if _get_dynamic_axis_num(i_s) == 0 and _get_dynamic_axis_num(l_s) == 1: if hasattr(C, 'unpack_batch'): f_stats.append(C.unpack_batch(l_s)) else: f_stats.append(C.user_function(ConvertToStatic(l_s, batch_size=i_s.shape[0]))) else: f_stats.append(l_s) last_output._uses_learning_phase = uses_learning_phase return last_output, final_output, f_stats def has_seq_axis(x): return hasattr(x, 'dynamic_axes') and len(x.dynamic_axes) > 1 def l2_normalize(x, axis=None): axis = [axis] axis = _normalize_axis(axis, x) norm = C.sqrt(C.reduce_sum(C.square(x), axis=axis[0])) return x / norm def hard_sigmoid(x): x = (0.2 x) + 0.5 x = C.clip(x, 0.0, 1.0) return x def conv1d(x, kernel, strides=1, padding='valid', data_format=None, dilation_rate=1): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) if padding == 'causal': # causal (dilated) convolution: left_pad = dilation_rate * (kernel.shape[0] - 1) x = temporal_padding(x, (left_pad, 0)) padding = 'valid' if data_format == 'channels_last': x = C.swapaxes(x, 0, 1) kernel = C.swapaxes(kernel, 0, 2) padding = _preprocess_border_mode(padding) strides = [strides] x = C.convolution( kernel, x, strides=tuple(strides), auto_padding=[ False, padding]) if data_format == 'channels_last': x = C.swapaxes(x, 0, 1) return x def conv2d(x, kernel, strides=(1, 1), padding='valid', data_format=None, dilation_rate=(1, 1)): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) x = _preprocess_conv2d_input(x, data_format) kernel = _preprocess_conv2d_kernel(kernel, data_format) padding = _preprocess_border_mode(padding) if dilation_rate == (1, 1): strides = (1,) + strides x = C.convolution( kernel, x, strides, auto_padding=[ False, padding, padding]) else: assert dilation_rate[0] == dilation_rate[1] assert strides == (1, 1), 'Invalid strides for dilated convolution' x = C.convolution( kernel, x, strides=dilation_rate[0], auto_padding=[ False, padding, padding]) return _postprocess_conv2d_output(x, data_format) def separable_conv1d(x, depthwise_kernel, pointwise_kernel, strides=1, padding='valid', data_format=None, dilation_rate=1): raise NotImplementedError def separable_conv2d(x, depthwise_kernel, pointwise_kernel, strides=(1, 1), padding='valid', data_format=None, dilation_rate=(1, 1)): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) x = _preprocess_conv2d_input(x, data_format) depthwise_kernel = _preprocess_conv2d_kernel(depthwise_kernel, data_format) depthwise_kernel = C.reshape(C.transpose(depthwise_kernel, (1, 0, 2, 3)), (-1, 1) + depthwise_kernel.shape[2:]) pointwise_kernel = _preprocess_conv2d_kernel(pointwise_kernel, data_format) padding = _preprocess_border_mode(padding) if dilation_rate == (1, 1): strides = (1,) + strides x = C.convolution(depthwise_kernel, x, strides=strides, auto_padding=[False, padding, padding], groups=x.shape[0]) x = C.convolution(pointwise_kernel, x, strides=(1, 1, 1), auto_padding=[False]) else: if dilation_rate[0] != dilation_rate[1]: raise ValueError('CNTK Backend: non-square dilation_rate is ' 'not supported.') if strides != (1, 1): raise ValueError('Invalid strides for dilated convolution') x = C.convolution(depthwise_kernel, x, strides=dilation_rate[0], auto_padding=[False, padding, padding]) x = C.convolution(pointwise_kernel, x, strides=(1, 1, 1), auto_padding=[False]) return _postprocess_conv2d_output(x, data_format) def depthwise_conv2d(x, depthwise_kernel, strides=(1, 1), padding='valid', data_format=None, dilation_rate=(1, 1)): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) x = _preprocess_conv2d_input(x, data_format) depthwise_kernel = _preprocess_conv2d_kernel(depthwise_kernel, data_format) depthwise_kernel = C.reshape(C.transpose(depthwise_kernel, (1, 0, 2, 3)), (-1, 1) + depthwise_kernel.shape[2:]) padding = _preprocess_border_mode(padding) if dilation_rate == (1, 1): strides = (1,) + strides x = C.convolution(depthwise_kernel, x, strides=strides, auto_padding=[False, padding, padding], groups=x.shape[0]) else: if dilation_rate[0] != dilation_rate[1]: raise ValueError('CNTK Backend: non-square dilation_rate is ' 'not supported.') if strides != (1, 1): raise ValueError('Invalid strides for dilated convolution') x = C.convolution(depthwise_kernel, x, strides=dilation_rate[0], auto_padding=[False, padding, padding], groups=x.shape[0]) return _postprocess_conv2d_output(x, data_format) def conv3d(x, kernel, strides=(1, 1, 1), padding='valid', data_format=None, dilation_rate=(1, 1, 1)): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) x = _preprocess_conv3d_input(x, data_format) kernel = _preprocess_conv3d_kernel(kernel, data_format) padding = _preprocess_border_mode(padding) strides = strides + (strides[0],) x = C.convolution( kernel, x, strides, auto_padding=[ False, padding, padding, padding]) return _postprocess_conv3d_output(x, data_format) def conv3d_transpose(x, kernel, output_shape, strides=(1, 1, 1), padding='valid', data_format=None): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) x = _preprocess_conv3d_input(x, data_format) kernel = _preprocess_conv3d_kernel(kernel, data_format) padding = _preprocess_border_mode(padding) strides = (1,) + strides # cntk output_shape does not include batch axis output_shape = output_shape[1:] # in keras2, need handle output shape in different format if data_format == 'channels_last': shape = list(output_shape) shape[0] = output_shape[3] shape[1] = output_shape[0] shape[2] = output_shape[1] shape[3] = output_shape[2] output_shape = tuple(shape) x = C.convolution_transpose( kernel, x, strides, auto_padding=[ False, padding, padding, padding], output_shape=output_shape) return _postprocess_conv3d_output(x, data_format) def pool2d(x, pool_size, strides=(1, 1), padding='valid', data_format=None, pool_mode='max'): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) padding = _preprocess_border_mode(padding) strides = strides pool_size = pool_size x = _preprocess_conv2d_input(x, data_format) if pool_mode == 'max': x = C.pooling( x, C.MAX_POOLING, pool_size, strides, auto_padding=[padding]) elif pool_mode == 'avg': x = C.pooling( x, C.AVG_POOLING, pool_size, strides, auto_padding=[padding]) else: raise ValueError('Invalid pooling mode: ' + str(pool_mode)) return _postprocess_conv2d_output(x, data_format) def pool3d(x, pool_size, strides=(1, 1, 1), padding='valid', data_format=None, pool_mode='max'): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) padding = _preprocess_border_mode(padding) x = _preprocess_conv3d_input(x, data_format) if pool_mode == 'max': x = C.pooling( x, C.MAX_POOLING, pool_size, strides, auto_padding=[padding]) elif pool_mode == 'avg': x = C.pooling( x, C.AVG_POOLING, pool_size, strides, auto_padding=[padding]) else: raise ValueError('Invalid pooling mode: ' + str(pool_mode)) return _postprocess_conv3d_output(x, data_format) def relu(x, alpha=0., max_value=None): if alpha != 0.: negative_part = C.relu(-x) x = C.relu(x) if max_value is not None: x = C.clip(x, 0.0, max_value) if alpha != 0.: x -= alpha * negative_part return x def dropout(x, level, noise_shape=None, seed=None): if level < 0. or level >= 1: raise ValueError('CNTK Backend: Invalid dropout level %s, ' 'must be in interval [0, 1].' % level) return C.dropout(x, level) def batch_flatten(x): # cntk's batch axis is not in shape, # so just flatten all the dim in x.shape dim =	np.prod(x.shape)	numpy.prod
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k') plt.plot(((time[-202] + time[-201]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed', label=textwrap.fill('Neural network targets', 13)) plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(((time_extended[-1001] + time_extended[-1000]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed') plt.xlim(3.4 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/neural_network.png') plt.show() # plot 6a np.random.seed(0) time = np.linspace(0, 5 * np.pi, 1001) knots_51 = np.linspace(0, 5 * np.pi, 51) time_series = np.cos(2 * time) + np.cos(4 * time) + np.cos(8 * time) noise = np.random.normal(0, 1, len(time_series)) time_series += noise advemdpy = EMD(time=time, time_series=time_series) imfs_51, hts_51, ifs_51 = advemdpy.empirical_mode_decomposition(knots=knots_51, max_imfs=3, edge_effect='symmetric_anchor', verbose=False)[:3] knots_31 = np.linspace(0, 5 * np.pi, 31) imfs_31, hts_31, ifs_31 = advemdpy.empirical_mode_decomposition(knots=knots_31, max_imfs=2, edge_effect='symmetric_anchor', verbose=False)[:3] knots_11 = np.linspace(0, 5 * np.pi, 11) imfs_11, hts_11, ifs_11 = advemdpy.empirical_mode_decomposition(knots=knots_11, max_imfs=1, edge_effect='symmetric_anchor', verbose=False)[:3] fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) print(f'DFA fluctuation with 51 knots: {np.round(np.var(time_series - (imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :])), 3)}') for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[0].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[0].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) print(f'DFA fluctuation with 31 knots: {np.round(np.var(time_series - (imfs_31[1, :] + imfs_31[2, :])), 3)}') for knot in knots_31: axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[1].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[1].set_xticklabels(['', '', '', '', '', '']) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) axs[1].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[1].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[1].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[1].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') axs[2].plot(time, time_series, label='Time series') axs[2].plot(time, imfs_11[1, :], label='IMF 1 with 11 knots') axs[2].plot(time, imfs_31[2, :], label='IMF 2 with 31 knots') axs[2].plot(time, imfs_51[3, :], label='IMF 3 with 51 knots') print(f'DFA fluctuation with 11 knots: {np.round(np.var(time_series - imfs_51[3, :]), 3)}') for knot in knots_11: axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[2].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[2].set_xticklabels(['$0$', r'$\pi$', r'$2\pi$', r'$3\pi$', r'$4\pi$', r'$5\pi$']) box_2 = axs[2].get_position() axs[2].set_position([box_2.x0 - 0.05, box_2.y0, box_2.width * 0.85, box_2.height]) axs[2].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[2].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[2].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[2].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[2].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') plt.savefig('jss_figures/DFA_different_trends.png') plt.show() # plot 6b fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences Zoomed Region', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[0].set_ylim(-5.5, 5.5) axs[0].set_xlim(0.95 * np.pi, 1.55 * np.pi) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) for knot in knots_31: axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[1].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[1].set_xticklabels(['', '', '', '', '', '']) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) axs[1].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].set_ylim(-5.5, 5.5) axs[1].set_xlim(0.95 * np.pi, 1.55 * np.pi) axs[2].plot(time, time_series, label='Time series') axs[2].plot(time, imfs_11[1, :], label='IMF 1 with 11 knots') axs[2].plot(time, imfs_31[2, :], label='IMF 2 with 31 knots') axs[2].plot(time, imfs_51[3, :], label='IMF 3 with 51 knots') for knot in knots_11: axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[2].set_xticks([np.pi, (3 / 2) * np.pi]) axs[2].set_xticklabels([r'$\pi$', r'$\frac{3}{2}\pi$']) box_2 = axs[2].get_position() axs[2].set_position([box_2.x0 - 0.05, box_2.y0, box_2.width * 0.85, box_2.height]) axs[2].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[2].set_ylim(-5.5, 5.5) axs[2].set_xlim(0.95 * np.pi, 1.55 * np.pi) plt.savefig('jss_figures/DFA_different_trends_zoomed.png') plt.show() hs_ouputs = hilbert_spectrum(time, imfs_51, hts_51, ifs_51, max_frequency=12, plot=False) # plot 6c ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Simple Sinusoidal Time Seres with Added Noise', 50)) x_hs, y, z = hs_ouputs z_min, z_max = 0, np.abs(z).max() ax.pcolormesh(x_hs, y, np.abs(z), cmap='gist_rainbow', vmin=z_min, vmax=z_max) ax.plot(x_hs[0, :], 8 * np.ones_like(x_hs[0, :]), '--', label=r'$\omega = 8$', Linewidth=3) ax.plot(x_hs[0, :], 4 * np.ones_like(x_hs[0, :]), '--', label=r'$\omega = 4$', Linewidth=3) ax.plot(x_hs[0, :], 2 * np.ones_like(x_hs[0, :]), '--', label=r'$\omega = 2$', Linewidth=3) ax.set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi]) ax.set_xticklabels(['$0$', r'$\pi$', r'$2\pi$', r'$3\pi$', r'$4\pi$']) plt.ylabel(r'Frequency (rad.s$^{-1}$)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.85, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/DFA_hilbert_spectrum.png') plt.show() # plot 6c time = np.linspace(0, 5 * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 51) fluc = Fluctuation(time=time, time_series=time_series) max_unsmoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='maxima', smooth=False) max_smoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='maxima', smooth=True) min_unsmoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='minima', smooth=False) min_smoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='minima', smooth=True) util = Utility(time=time, time_series=time_series) maxima = util.max_bool_func_1st_order_fd() minima = util.min_bool_func_1st_order_fd() ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title(textwrap.fill('Plot Demonstrating Unsmoothed Extrema Envelopes if Schoenberg–Whitney Conditions are Not Satisfied', 50)) plt.plot(time, time_series, label='Time series', zorder=2, LineWidth=2) plt.scatter(time[maxima], time_series[maxima], c='r', label='Maxima', zorder=10) plt.scatter(time[minima], time_series[minima], c='b', label='Minima', zorder=10) plt.plot(time, max_unsmoothed[0], label=textwrap.fill('Unsmoothed maxima envelope', 10), c='darkorange') plt.plot(time, max_smoothed[0], label=textwrap.fill('Smoothed maxima envelope', 10), c='red') plt.plot(time, min_unsmoothed[0], label=textwrap.fill('Unsmoothed minima envelope', 10), c='cyan') plt.plot(time, min_smoothed[0], label=textwrap.fill('Smoothed minima envelope', 10), c='blue') for knot in knots[:-1]: plt.plot(knot * np.ones(101), np.linspace(-3.0, -2.0, 101), '--', c='grey', zorder=1) plt.plot(knots[-1] * np.ones(101), np.linspace(-3.0, -2.0, 101), '--', c='grey', label='Knots', zorder=1) plt.xticks((0, 1 * np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi), (r'$0$', r'$\pi$', r'2$\pi$', r'3$\pi$', r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) plt.xlim(-0.25 * np.pi, 5.25 * np.pi) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Schoenberg_Whitney_Conditions.png') plt.show() # plot 7 a = 0.25 width = 0.2 time = np.linspace((0 + a) * np.pi, (5 - a) * np.pi, 1001) knots = np.linspace((0 + a) * np.pi, (5 - a) * np.pi, 11) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] inflection_bool = utils.inflection_point() inflection_x = time[inflection_bool] inflection_y = time_series[inflection_bool] fluctuation = emd_mean.Fluctuation(time=time, time_series=time_series) maxima_envelope = fluctuation.envelope_basis_function_approximation(knots, 'maxima', smooth=False, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] maxima_envelope_smooth = fluctuation.envelope_basis_function_approximation(knots, 'maxima', smooth=True, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] minima_envelope = fluctuation.envelope_basis_function_approximation(knots, 'minima', smooth=False, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] minima_envelope_smooth = fluctuation.envelope_basis_function_approximation(knots, 'minima', smooth=True, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] inflection_points_envelope = fluctuation.direct_detrended_fluctuation_estimation(knots, smooth=True, smoothing_penalty=0.2, technique='inflection_points')[0] binomial_points_envelope = fluctuation.direct_detrended_fluctuation_estimation(knots, smooth=True, smoothing_penalty=0.2, technique='binomial_average', order=21, increment=20)[0] derivative_of_lsq = utils.derivative_forward_diff() derivative_time = time[:-1] derivative_knots = np.linspace(knots[0], knots[-1], 31) # change (1) detrended_fluctuation_technique and (2) max_internal_iter and (3) debug (confusing with external debugging) emd = AdvEMDpy.EMD(time=derivative_time, time_series=derivative_of_lsq) imf_1_of_derivative = emd.empirical_mode_decomposition(knots=derivative_knots, knot_time=derivative_time, text=False, verbose=False)[0][1, :] utils = emd_utils.Utility(time=time[:-1], time_series=imf_1_of_derivative) optimal_maxima = np.r_[False, utils.derivative_forward_diff() < 0, False] & \ np.r_[utils.zero_crossing() == 1, False] optimal_minima = np.r_[False, utils.derivative_forward_diff() > 0, False] & \ np.r_[utils.zero_crossing() == 1, False] EEMD_maxima_envelope = fluctuation.envelope_basis_function_approximation_fixed_points(knots, 'maxima', optimal_maxima, optimal_minima, smooth=False, smoothing_penalty=0.2, edge_effect='none')[0] EEMD_minima_envelope = fluctuation.envelope_basis_function_approximation_fixed_points(knots, 'minima', optimal_maxima, optimal_minima, smooth=False, smoothing_penalty=0.2, edge_effect='none')[0] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Detrended Fluctuation Analysis Examples') plt.plot(time, time_series, LineWidth=2, label='Time series') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(time[optimal_maxima], time_series[optimal_maxima], c='darkred', zorder=4, label=textwrap.fill('Optimal maxima', 10)) plt.scatter(time[optimal_minima], time_series[optimal_minima], c='darkblue', zorder=4, label=textwrap.fill('Optimal minima', 10)) plt.scatter(inflection_x, inflection_y, c='magenta', zorder=4, label=textwrap.fill('Inflection points', 10)) plt.plot(time, maxima_envelope, c='darkblue', label=textwrap.fill('EMD envelope', 10)) plt.plot(time, minima_envelope, c='darkblue') plt.plot(time, (maxima_envelope + minima_envelope) / 2, c='darkblue') plt.plot(time, maxima_envelope_smooth, c='darkred', label=textwrap.fill('SEMD envelope', 10)) plt.plot(time, minima_envelope_smooth, c='darkred') plt.plot(time, (maxima_envelope_smooth + minima_envelope_smooth) / 2, c='darkred') plt.plot(time, EEMD_maxima_envelope, c='darkgreen', label=textwrap.fill('EEMD envelope', 10)) plt.plot(time, EEMD_minima_envelope, c='darkgreen') plt.plot(time, (EEMD_maxima_envelope + EEMD_minima_envelope) / 2, c='darkgreen') plt.plot(time, inflection_points_envelope, c='darkorange', label=textwrap.fill('Inflection point envelope', 10)) plt.plot(time, binomial_points_envelope, c='deeppink', label=textwrap.fill('Binomial average envelope', 10)) plt.plot(time, np.cos(time), c='black', label='True mean') plt.xticks((0, 1 * np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi), (r'$0$', r'$\pi$', r'2$\pi$', r'3$\pi$', r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) plt.xlim(-0.25 * np.pi, 5.25 * np.pi) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/detrended_fluctuation_analysis.png') plt.show() # Duffing Equation Example def duffing_equation(xy, ts): gamma = 0.1 epsilon = 1 omega = ((2 * np.pi) / 25) return [xy[1], xy[0] - epsilon * xy[0] ** 3 + gamma * np.cos(omega * ts)] t = np.linspace(0, 150, 1501) XY0 = [1, 1] solution = odeint(duffing_equation, XY0, t) x = solution[:, 0] dxdt = solution[:, 1] x_points = [0, 50, 100, 150] x_names = {0, 50, 100, 150} y_points_1 = [-2, 0, 2] y_points_2 = [-1, 0, 1] fig, axs = plt.subplots(2, 1) plt.subplots_adjust(hspace=0.2) axs[0].plot(t, x) axs[0].set_title('Duffing Equation Displacement') axs[0].set_ylim([-2, 2]) axs[0].set_xlim([0, 150]) axs[1].plot(t, dxdt) axs[1].set_title('Duffing Equation Velocity') axs[1].set_ylim([-1.5, 1.5]) axs[1].set_xlim([0, 150]) axis = 0 for ax in axs.flat: ax.label_outer() if axis == 0: ax.set_ylabel('x(t)') ax.set_yticks(y_points_1) if axis == 1: ax.set_ylabel(r'$ \dfrac{dx(t)}{dt} $') ax.set(xlabel='t') ax.set_yticks(y_points_2) ax.set_xticks(x_points) ax.set_xticklabels(x_names) axis += 1 plt.savefig('jss_figures/Duffing_equation.png') plt.show() # compare other packages Duffing - top pyemd = pyemd0215() py_emd = pyemd(x) IP, IF, IA = emd040.spectra.frequency_transform(py_emd.T, 10, 'hilbert') freq_edges, freq_bins = emd040.spectra.define_hist_bins(0, 0.2, 100) hht = emd040.spectra.hilberthuang(IF, IA, freq_edges) hht = gaussian_filter(hht, sigma=1) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 1.0 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Duffing Equation using PyEMD 0.2.10', 40)) plt.pcolormesh(t, freq_bins, hht, cmap='gist_rainbow', vmin=0, vmax=np.max(np.max(np.abs(hht)))) plt.plot(t[:-1], 0.124 * np.ones_like(t[:-1]), '--', label=textwrap.fill('Hamiltonian frequency approximation', 15)) plt.plot(t[:-1], 0.04 * np.ones_like(t[:-1]), 'g--', label=textwrap.fill('Driving function frequency', 15)) plt.xticks([0, 50, 100, 150]) plt.yticks([0, 0.1, 0.2]) plt.ylabel('Frequency (Hz)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.75, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Duffing_equation_ht_pyemd.png') plt.show() plt.show() emd_sift = emd040.sift.sift(x) IP, IF, IA = emd040.spectra.frequency_transform(emd_sift, 10, 'hilbert') freq_edges, freq_bins = emd040.spectra.define_hist_bins(0, 0.2, 100) hht = emd040.spectra.hilberthuang(IF, IA, freq_edges) hht = gaussian_filter(hht, sigma=1) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 1.0 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Duffing Equation using emd 0.3.3', 40)) plt.pcolormesh(t, freq_bins, hht, cmap='gist_rainbow', vmin=0, vmax=np.max(np.max(np.abs(hht)))) plt.plot(t[:-1], 0.124 * np.ones_like(t[:-1]), '--', label=textwrap.fill('Hamiltonian frequency approximation', 15)) plt.plot(t[:-1], 0.04 * np.ones_like(t[:-1]), 'g--', label=textwrap.fill('Driving function frequency', 15)) plt.xticks([0, 50, 100, 150]) plt.yticks([0, 0.1, 0.2]) plt.ylabel('Frequency (Hz)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.75, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Duffing_equation_ht_emd.png') plt.show() # compare other packages Duffing - bottom emd_duffing = AdvEMDpy.EMD(time=t, time_series=x) emd_duff, emd_ht_duff, emd_if_duff, _, _, _, _ = emd_duffing.empirical_mode_decomposition(verbose=False) fig, axs = plt.subplots(2, 1) plt.subplots_adjust(hspace=0.3) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) axs[0].plot(t, emd_duff[1, :], label='AdvEMDpy') axs[0].plot(t, py_emd[0, :], '--', label='PyEMD 0.2.10') axs[0].plot(t, emd_sift[:, 0], '--', label='emd 0.3.3') axs[0].set_title('IMF 1') axs[0].set_ylim([-2, 2]) axs[0].set_xlim([0, 150]) axs[1].plot(t, emd_duff[2, :], label='AdvEMDpy') print(f'AdvEMDpy driving function error: {np.round(sum(abs(0.1 * np.cos(0.04 * 2 * np.pi * t) - emd_duff[2, :])), 3)}') axs[1].plot(t, py_emd[1, :], '--', label='PyEMD 0.2.10') print(f'PyEMD driving function error: {np.round(sum(abs(0.1 * np.cos(0.04 * 2 * np.pi * t) - py_emd[1, :])), 3)}') axs[1].plot(t, emd_sift[:, 1], '--', label='emd 0.3.3') print(f'emd driving function error: {np.round(sum(abs(0.1 * np.cos(0.04 * 2 * np.pi * t) - emd_sift[:, 1])), 3)}') axs[1].plot(t, 0.1 * np.cos(0.04 * 2 * np.pi * t), '--', label=r'$0.1$cos$(0.08{\pi}t)$') axs[1].set_title('IMF 2') axs[1].set_ylim([-0.2, 0.4]) axs[1].set_xlim([0, 150]) axis = 0 for ax in axs.flat: ax.label_outer() if axis == 0: ax.set_ylabel(r'$\gamma_1(t)$') ax.set_yticks([-2, 0, 2]) if axis == 1: ax.set_ylabel(r'$\gamma_2(t)$') ax.set_yticks([-0.2, 0, 0.2]) box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) ax.set_xticks(x_points) ax.set_xticklabels(x_names) axis += 1 plt.savefig('jss_figures/Duffing_equation_imfs.png') plt.show() hs_ouputs = hilbert_spectrum(t, emd_duff, emd_ht_duff, emd_if_duff, max_frequency=1.3, plot=False) ax = plt.subplot(111) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Duffing Equation using AdvEMDpy', 40)) x, y, z = hs_ouputs y = y / (2 * np.pi) z_min, z_max = 0, np.abs(z).max() figure_size = plt.gcf().get_size_inches() factor = 1.0 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) ax.pcolormesh(x, y, np.abs(z), cmap='gist_rainbow', vmin=z_min, vmax=z_max) plt.plot(t[:-1], 0.124 * np.ones_like(t[:-1]), '--', label=textwrap.fill('Hamiltonian frequency approximation', 15)) plt.plot(t[:-1], 0.04 * np.ones_like(t[:-1]), 'g--', label=textwrap.fill('Driving function frequency', 15)) plt.xticks([0, 50, 100, 150]) plt.yticks([0, 0.1, 0.2]) plt.ylabel('Frequency (Hz)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.75, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Duffing_equation_ht.png') plt.show() # Carbon Dioxide Concentration Example CO2_data = pd.read_csv('Data/co2_mm_mlo.csv', header=51) plt.plot(CO2_data['month'], CO2_data['decimal date']) plt.title(textwrap.fill('Mean Monthly Concentration of Carbon Dioxide in the Atmosphere', 35)) plt.ylabel('Parts per million') plt.xlabel('Time (years)') plt.savefig('jss_figures/CO2_concentration.png') plt.show() signal = CO2_data['decimal date'] signal = np.asarray(signal) time = CO2_data['month'] time = np.asarray(time) # compare other packages Carbon Dioxide - top pyemd = pyemd0215() py_emd = pyemd(signal) IP, IF, IA = emd040.spectra.frequency_transform(py_emd[:2, :].T, 12, 'hilbert') print(f'PyEMD annual frequency error: {np.round(sum(np.abs(IF[:, 0] - np.ones_like(IF[:, 0]))), 3)}') freq_edges, freq_bins = emd040.spectra.define_hist_bins(0, 2, 100) hht = emd040.spectra.hilberthuang(IF, IA, freq_edges) hht = gaussian_filter(hht, sigma=1) fig, ax = plt.subplots() figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of CO$_{2}$ Concentration using PyEMD 0.2.10', 45)) plt.ylabel('Frequency (year$^{-1}$)') plt.xlabel('Time (years)') plt.pcolormesh(time, freq_bins, hht, cmap='gist_rainbow', vmin=0, vmax=np.max(np.max(np.abs(hht)))) plt.plot(time, np.ones_like(time), 'k--', label=textwrap.fill('Annual cycle', 10)) box_0 = ax.get_position() ax.set_position([box_0.x0 + 0.0125, box_0.y0 + 0.075, box_0.width * 0.8, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/CO2_Hilbert_pyemd.png') plt.show() emd_sift = emd040.sift.sift(signal) IP, IF, IA = emd040.spectra.frequency_transform(emd_sift[:, :1], 12, 'hilbert') print(f'emd annual frequency error: {np.round(sum(np.abs(IF -	np.ones_like(IF)	numpy.ones_like
# # Copyright (c) 2021 The GPflux Contributors. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. # import abc import numpy as np import pytest import tensorflow as tf import tensorflow_probability as tfp from gpflow.kullback_leiblers import gauss_kl from gpflux.encoders import DirectlyParameterizedNormalDiag from gpflux.layers import LatentVariableLayer, LayerWithObservations, TrackableLayer tf.keras.backend.set_floatx("float64") ############ # Utilities ############ def _zero_one_normal_prior(w_dim): """ N(0, I) prior """ return tfp.distributions.MultivariateNormalDiag(loc=np.zeros(w_dim), scale_diag=np.ones(w_dim)) def get_distributions_with_w_dim(): distributions = [] for d in [1, 5]: mean = np.zeros(d) scale_tri_l = np.eye(d) mvn = tfp.distributions.MultivariateNormalTriL(mean, scale_tri_l) std =	np.ones(d)	numpy.ones
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k') plt.plot(((time[-202] + time[-201]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed', label=textwrap.fill('Neural network targets', 13)) plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(((time_extended[-1001] + time_extended[-1000]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed') plt.xlim(3.4 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/neural_network.png') plt.show() # plot 6a np.random.seed(0) time = np.linspace(0, 5 * np.pi, 1001) knots_51 = np.linspace(0, 5 * np.pi, 51) time_series = np.cos(2 * time) + np.cos(4 * time) + np.cos(8 * time) noise = np.random.normal(0, 1, len(time_series)) time_series += noise advemdpy = EMD(time=time, time_series=time_series) imfs_51, hts_51, ifs_51 = advemdpy.empirical_mode_decomposition(knots=knots_51, max_imfs=3, edge_effect='symmetric_anchor', verbose=False)[:3] knots_31 = np.linspace(0, 5 * np.pi, 31) imfs_31, hts_31, ifs_31 = advemdpy.empirical_mode_decomposition(knots=knots_31, max_imfs=2, edge_effect='symmetric_anchor', verbose=False)[:3] knots_11 = np.linspace(0, 5 * np.pi, 11) imfs_11, hts_11, ifs_11 = advemdpy.empirical_mode_decomposition(knots=knots_11, max_imfs=1, edge_effect='symmetric_anchor', verbose=False)[:3] fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) print(f'DFA fluctuation with 51 knots: {np.round(	np.var(time_series - (imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :]))	numpy.var
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] *	np.ones(101)	numpy.ones
''' <NAME> set up :2020-1-9 intergrate img and label into one file -- fiducial1024_v1 ''' import argparse import sys, os import pickle import random import collections import json import numpy as np import scipy.io as io import scipy.misc as m import matplotlib.pyplot as plt import glob import math import time import threading import multiprocessing as mp from multiprocessing import Pool import re import cv2 # sys.path.append('/lustre/home/gwxie/hope/project/dewarp/datasets/') # /lustre/home/gwxie/program/project/unwarp/perturbed_imgaes/GAN import utils def getDatasets(dir): return os.listdir(dir) class perturbed(utils.BasePerturbed): def __init__(self, path, bg_path, save_path, save_suffix): self.path = path self.bg_path = bg_path self.save_path = save_path self.save_suffix = save_suffix def save_img(self, m, n, fold_curve='fold', repeat_time=4, fiducial_points = 16, relativeShift_position='relativeShift_v2'): origin_img = cv2.imread(self.path, flags=cv2.IMREAD_COLOR) save_img_shape = [5122, 4802] # 320 # reduce_value = np.random.choice([24, 25, 26, 27, 2*8], p=[0.01, 0.1, 0.4, 0.39, 0.1]) reduce_value = np.random.choice([22, 42, 82, 162, 242, 322, 402, 482], p=[0.02, 0.18, 0.2, 0.3, 0.1, 0.1, 0.08, 0.02]) # reduce_value = np.random.choice([82, 162, 242, 322, 402, 482], p=[0.01, 0.02, 0.2, 0.4, 0.19, 0.18]) # reduce_value = np.random.choice([16, 24, 32, 40, 48, 64], p=[0.01, 0.1, 0.2, 0.4, 0.2, 0.09]) base_img_shrink = save_img_shape[0] - reduce_value # enlarge_img_shrink = [1024, 768] # enlarge_img_shrink = [896, 672] # 420 enlarge_img_shrink = [5124, 4804] # 420 # enlarge_img_shrink = [8962, 7682] # 420 # enlarge_img_shrink = [896, 768] # 420 # enlarge_img_shrink = [768, 576] # 420 # enlarge_img_shrink = [640, 480] # 420 '''''' im_lr = origin_img.shape[0] im_ud = origin_img.shape[1] reduce_value_v2 = np.random.choice([22, 42, 82, 162, 242, 282, 322, 482], p=[0.02, 0.18, 0.2, 0.2, 0.1, 0.1, 0.1, 0.1]) # reduce_value_v2 = np.random.choice([16, 24, 28, 32, 48, 64], p=[0.01, 0.1, 0.2, 0.3, 0.25, 0.14]) if im_lr > im_ud: im_ud = min(int(im_ud / im_lr base_img_shrink), save_img_shape[1] - reduce_value_v2) im_lr = save_img_shape[0] - reduce_value else: base_img_shrink = save_img_shape[1] - reduce_value im_lr = min(int(im_lr / im_ud * base_img_shrink), save_img_shape[0] - reduce_value_v2) im_ud = base_img_shrink if round(im_lr / im_ud, 2) < 0.5 or round(im_ud / im_lr, 2) < 0.5: repeat_time = min(repeat_time, 8) edge_padding = 3 im_lr -= im_lr % (fiducial_points-1) - (2edge_padding) # im_lr % (fiducial_points-1) - 1 im_ud -= im_ud % (fiducial_points-1) - (2edge_padding) # im_ud % (fiducial_points-1) - 1 im_hight = np.linspace(edge_padding, im_lr - edge_padding, fiducial_points, dtype=np.int64) im_wide = np.linspace(edge_padding, im_ud - edge_padding, fiducial_points, dtype=np.int64) # im_lr -= im_lr % (fiducial_points-1) - (1+2edge_padding) # im_lr % (fiducial_points-1) - 1 # im_ud -= im_ud % (fiducial_points-1) - (1+2edge_padding) # im_ud % (fiducial_points-1) - 1 # im_hight = np.linspace(edge_padding, im_lr - (1+edge_padding), fiducial_points, dtype=np.int64) # im_wide = np.linspace(edge_padding, im_ud - (1+edge_padding), fiducial_points, dtype=np.int64) im_x, im_y = np.meshgrid(im_hight, im_wide) segment_x = (im_lr) // (fiducial_points-1) segment_y = (im_ud) // (fiducial_points-1) # plt.plot(im_x, im_y, # color='limegreen', # marker='.', # linestyle='') # plt.grid(True) # plt.show() self.origin_img = cv2.resize(origin_img, (im_ud, im_lr), interpolation=cv2.INTER_CUBIC) perturbed_bg_ = getDatasets(self.bg_path) perturbed_bg_img_ = self.bg_path+random.choice(perturbed_bg_) perturbed_bg_img = cv2.imread(perturbed_bg_img_, flags=cv2.IMREAD_COLOR) mesh_shape = self.origin_img.shape[:2] self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 256, dtype=np.float32)#np.zeros_like(perturbed_bg_img) # self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 0, dtype=np.int16)#np.zeros_like(perturbed_bg_img) self.new_shape = self.synthesis_perturbed_img.shape[:2] perturbed_bg_img = cv2.resize(perturbed_bg_img, (save_img_shape[1], save_img_shape[0]), cv2.INPAINT_TELEA) origin_pixel_position = np.argwhere(np.zeros(mesh_shape, dtype=np.uint32) == 0).reshape(mesh_shape[0], mesh_shape[1], 2) pixel_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape(self.new_shape[0], self.new_shape[1], 2) self.perturbed_xy_ = np.zeros((self.new_shape[0], self.new_shape[1], 2)) # self.perturbed_xy_ = pixel_position.copy().astype(np.float32) # fiducial_points_grid = origin_pixel_position[im_x, im_y] self.synthesis_perturbed_label = np.zeros((self.new_shape[0], self.new_shape[1], 2)) x_min, y_min, x_max, y_max = self.adjust_position_v2(0, 0, mesh_shape[0], mesh_shape[1], save_img_shape) origin_pixel_position += [x_min, y_min] x_min, y_min, x_max, y_max = self.adjust_position(0, 0, mesh_shape[0], mesh_shape[1]) x_shift = random.randint(-enlarge_img_shrink[0]//16, enlarge_img_shrink[0]//16) y_shift = random.randint(-enlarge_img_shrink[1]//16, enlarge_img_shrink[1]//16) x_min += x_shift x_max += x_shift y_min += y_shift y_max += y_shift '''im_x,y''' im_x += x_min im_y += y_min self.synthesis_perturbed_img[x_min:x_max, y_min:y_max] = self.origin_img self.synthesis_perturbed_label[x_min:x_max, y_min:y_max] = origin_pixel_position synthesis_perturbed_img_map = self.synthesis_perturbed_img.copy() synthesis_perturbed_label_map = self.synthesis_perturbed_label.copy() foreORbackground_label = np.full((mesh_shape), 1, dtype=np.int16) foreORbackground_label_map = np.full((self.new_shape), 0, dtype=np.int16) foreORbackground_label_map[x_min:x_max, y_min:y_max] = foreORbackground_label # synthesis_perturbed_img_map = self.pad(self.synthesis_perturbed_img.copy(), x_min, y_min, x_max, y_max) # synthesis_perturbed_label_map = self.pad(synthesis_perturbed_label_map, x_min, y_min, x_max, y_max) '''****************************************************************''' is_normalizationFun_mixture = self.is_perform(0.2, 0.8) # if not is_normalizationFun_mixture: normalizationFun_0_1 = False # normalizationFun_0_1 = self.is_perform(0.5, 0.5) if fold_curve == 'fold': fold_curve_random = True # is_normalizationFun_mixture = False normalizationFun_0_1 = self.is_perform(0.2, 0.8) if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: fold_curve_random = self.is_perform(0.1, 0.9) # False # self.is_perform(0.01, 0.99) alpha_perturbed = random.randint(80, 160) / 100 # is_normalizationFun_mixture = False # self.is_perform(0.01, 0.99) synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) # synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 0, dtype=np.int16) synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) alpha_perturbed_change = self.is_perform(0.5, 0.5) p_pp_choice = self.is_perform(0.8, 0.2) if fold_curve == 'fold' else self.is_perform(0.1, 0.9) for repeat_i in range(repeat_time): if alpha_perturbed_change: if fold_curve == 'fold': if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: alpha_perturbed = random.randint(80, 160) / 100 '''''' linspace_x = [0, (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - 1] linspace_y = [0, (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - 1] linspace_x_seq = [1, 2, 3] linspace_y_seq = [1, 2, 3] r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_p = np.array( [random.randint(linspace_x[r_x-1] 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 if ((r_x == 1 or r_x == 3) and (r_y == 1 or r_y == 3)) and p_pp_choice: linspace_x_seq.remove(r_x) linspace_y_seq.remove(r_y) r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_pp = np.array( [random.randint(linspace_x[r_x-1] * 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 # perturbed_p, perturbed_pp = np.array( # [random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) \ # , np.array([random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) # perturbed_p, perturbed_pp = np.array( # [random.randint((self.new_shape[0]-im_lr)//210, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) 10) / 10, # random.randint((self.new_shape[1]-im_ud)//210, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) 10) / 10]) \ # , np.array([random.randint((self.new_shape[0]-im_lr)//210, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) 10) / 10, # random.randint((self.new_shape[1]-im_ud)//210, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) 10) / 10]) '''''' perturbed_vp = perturbed_pp - perturbed_p perturbed_vp_norm = np.linalg.norm(perturbed_vp) perturbed_distance_vertex_and_line = np.dot((perturbed_p - pixel_position), perturbed_vp) / perturbed_vp_norm '''''' # perturbed_v = np.array([random.randint(-3000, 3000) / 100, random.randint(-3000, 3000) / 100]) # perturbed_v = np.array([random.randint(-4000, 4000) / 100, random.randint(-4000, 4000) / 100]) if fold_curve == 'fold' and self.is_perform(0.6, 0.4): # self.is_perform(0.3, 0.7): # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) perturbed_v = np.array([random.randint(-10000, 10000) / 100, random.randint(-10000, 10000) / 100]) # perturbed_v = np.array([random.randint(-11000, 11000) / 100, random.randint(-11000, 11000) / 100]) else: # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) # perturbed_v = np.array([random.randint(-16000, 16000) / 100, random.randint(-16000, 16000) / 100]) perturbed_v = np.array([random.randint(-8000, 8000) / 100, random.randint(-8000, 8000) / 100]) # perturbed_v = np.array([random.randint(-3500, 3500) / 100, random.randint(-3500, 3500) / 100]) # perturbed_v = np.array([random.randint(-600, 600) / 10, random.randint(-600, 600) / 10]) '''''' if fold_curve == 'fold': if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) '''''' if fold_curve_random: # omega_perturbed = (alpha_perturbed+0.2) / (perturbed_d + alpha_perturbed) # omega_perturbed = alpha_perturbedperturbed_d omega_perturbed = alpha_perturbed / (perturbed_d + alpha_perturbed) else: omega_perturbed = 1 - perturbed_d alpha_perturbed '''shadow''' if self.is_perform(0.6, 0.4): synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] = np.minimum(np.maximum(synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] - np.int16(np.round(omega_perturbed[x_min:x_max, y_min:y_max].repeat(3).reshape(x_max-x_min, y_max-y_min, 3) * abs(np.linalg.norm(perturbed_v//2))np.array([0.4-random.random()0.1, 0.4-random.random()0.1, 0.4-random.random()0.1]))), 0), 255) '''''' if relativeShift_position in ['position', 'relativeShift_v2']: self.perturbed_xy_ += np.array([omega_perturbed * perturbed_v[0], omega_perturbed * perturbed_v[1]]).transpose(1, 2, 0) else: print('relativeShift_position error') exit() ''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 # synthesis_perturbed_img = np.around(synthesis_perturbed_img).astype(np.uint8) synthesis_perturbed_label[:, :, 0] = foreORbackground_label synthesis_perturbed_label[:, :, 1] = foreORbackground_label synthesis_perturbed_img[:, :, 0] = foreORbackground_label synthesis_perturbed_img[:, :, 1] = foreORbackground_label synthesis_perturbed_img[:, :, 2] = foreORbackground_label self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label ''' '''perspective''' perspective_shreshold = random.randint(26, 36)10 # 280 x_min_per, y_min_per, x_max_per, y_max_per = self.adjust_position(perspective_shreshold, perspective_shreshold, self.new_shape[0]-perspective_shreshold, self.new_shape[1]-perspective_shreshold) pts1 = np.float32([[x_min_per, y_min_per], [x_max_per, y_min_per], [x_min_per, y_max_per], [x_max_per, y_max_per]]) e_1_ = x_max_per - x_min_per e_2_ = y_max_per - y_min_per e_3_ = e_2_ e_4_ = e_1_ perspective_shreshold_h = e_1_0.02 perspective_shreshold_w = e_2_0.02 a_min_, a_max_ = 70, 110 # if self.is_perform(1, 0): if fold_curve == 'curve' and self.is_perform(0.5, 0.5): if self.is_perform(0.5, 0.5): while True: pts2 = np.around( np.float32([[x_min_per - (random.random()) * perspective_shreshold, y_min_per + (random.random()) * perspective_shreshold], [x_max_per - (random.random()) * perspective_shreshold, y_min_per - (random.random()) * perspective_shreshold], [x_min_per + (random.random()) * perspective_shreshold, y_max_per + (random.random()) * perspective_shreshold], [x_max_per + (random.random()) * perspective_shreshold, y_max_per - (random.random()) * perspective_shreshold]])) # right e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break else: while True: pts2 = np.around( np.float32([[x_min_per + (random.random()) * perspective_shreshold, y_min_per - (random.random()) * perspective_shreshold], [x_max_per + (random.random()) * perspective_shreshold, y_min_per + (random.random()) * perspective_shreshold], [x_min_per - (random.random()) * perspective_shreshold, y_max_per - (random.random()) * perspective_shreshold], [x_max_per - (random.random()) * perspective_shreshold, y_max_per + (random.random()) * perspective_shreshold]])) e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break else: while True: pts2 = np.around(np.float32([[x_min_per+(random.random()-0.5)perspective_shreshold, y_min_per+(random.random()-0.5)perspective_shreshold], [x_max_per+(random.random()-0.5)perspective_shreshold, y_min_per+(random.random()-0.5)perspective_shreshold], [x_min_per+(random.random()-0.5)perspective_shreshold, y_max_per+(random.random()-0.5)perspective_shreshold], [x_max_per+(random.random()-0.5)perspective_shreshold, y_max_per+(random.random()-0.5)perspective_shreshold]])) e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break M = cv2.getPerspectiveTransform(pts1, pts2) one = np.ones((self.new_shape[0], self.new_shape[1], 1), dtype=np.int16) matr = np.dstack((pixel_position, one)) new = np.dot(M, matr.reshape(-1, 3).T).T.reshape(self.new_shape[0], self.new_shape[1], 3) x = new[:, :, 0]/new[:, :, 2] y = new[:, :, 1]/new[:, :, 2] perturbed_xy_ = np.dstack((x, y)) # perturbed_xy_round_int = np.around(cv2.bilateralFilter(perturbed_xy_round_int, 9, 75, 75)) # perturbed_xy_round_int = np.around(cv2.blur(perturbed_xy_, (17, 17))) # perturbed_xy_round_int = cv2.blur(perturbed_xy_round_int, (17, 17)) # perturbed_xy_round_int = cv2.GaussianBlur(perturbed_xy_round_int, (7, 7), 0) perturbed_xy_ = perturbed_xy_-np.min(perturbed_xy_.T.reshape(2, -1), 1) # perturbed_xy_round_int = np.around(perturbed_xy_round_int-np.min(perturbed_xy_round_int.T.reshape(2, -1), 1)).astype(np.int16) self.perturbed_xy_ += perturbed_xy_ '''perspective end''' '''to img''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) # self.perturbed_xy_ = cv2.blur(self.perturbed_xy_, (7, 7)) self.perturbed_xy_ = cv2.GaussianBlur(self.perturbed_xy_, (7, 7), 0) '''get fiducial points''' fiducial_points_coordinate = self.perturbed_xy_[im_x, im_y] vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label self.foreORbackground_label = foreORbackground_label '''draw fiducial points stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_img.copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1,2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[1] + math.ceil(stepSize / 2), l[0] + math.ceil(stepSize / 2)), 5, (0, 0, 255), -1) cv2.imwrite('/lustre/home/gwxie/program/project/unwarp/unwarp_perturbed/TPS/img/cv_TPS_large.jpg', fiducial_points_synthesis_perturbed_img) ''' '''clip''' perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = -1, -1, self.new_shape[0], self.new_shape[1] for x in range(self.new_shape[0] // 2, perturbed_x_max): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and perturbed_x_max - 1 > x: perturbed_x_max = x break for x in range(self.new_shape[0] // 2, perturbed_x_min, -1): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and x > 0: perturbed_x_min = x break for y in range(self.new_shape[1] // 2, perturbed_y_max): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and perturbed_y_max - 1 > y: perturbed_y_max = y break for y in range(self.new_shape[1] // 2, perturbed_y_min, -1): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and y > 0: perturbed_y_min = y break if perturbed_x_min == 0 or perturbed_x_max == self.new_shape[0] or perturbed_y_min == self.new_shape[1] or perturbed_y_max == self.new_shape[1]: raise Exception('clip error') if perturbed_x_max - perturbed_x_min < im_lr//2 or perturbed_y_max - perturbed_y_min < im_ud//2: raise Exception('clip error') perfix_ = self.save_suffix+'_'+str(m)+'_'+str(n) is_shrink = False if perturbed_x_max - perturbed_x_min > save_img_shape[0] or perturbed_y_max - perturbed_y_min > save_img_shape[1]: is_shrink = True synthesis_perturbed_img = cv2.resize(self.synthesis_perturbed_img[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) synthesis_perturbed_label = cv2.resize(self.synthesis_perturbed_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) foreORbackground_label = cv2.resize(self.foreORbackground_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 '''shrink fiducial points''' center_x_l, center_y_l = perturbed_x_min + (perturbed_x_max - perturbed_x_min) // 2, perturbed_y_min + (perturbed_y_max - perturbed_y_min) // 2 fiducial_points_coordinate_copy = fiducial_points_coordinate.copy() shrink_x = im_lr/(perturbed_x_max - perturbed_x_min) shrink_y = im_ud/(perturbed_y_max - perturbed_y_min) fiducial_points_coordinate = [shrink_x, shrink_y] center_x_l = shrink_x center_y_l = shrink_y # fiducial_points_coordinate[1:, 1:] = [shrink_x, shrink_y] # fiducial_points_coordinate[1:, :1, 0] = shrink_x # fiducial_points_coordinate[:1, 1:, 1] = shrink_y # perturbed_x_min_copy, perturbed_y_min_copy, perturbed_x_max_copy, perturbed_y_max_copy = perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = self.adjust_position_v2(0, 0, im_lr, im_ud, self.new_shape) self.synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) self.synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) self.foreORbackground_label = np.zeros_like(self.foreORbackground_label) self.synthesis_perturbed_img[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_img self.synthesis_perturbed_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_label self.foreORbackground_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max] = foreORbackground_label center_x, center_y = perturbed_x_min + (perturbed_x_max - perturbed_x_min) // 2, perturbed_y_min + (perturbed_y_max - perturbed_y_min) // 2 if is_shrink: fiducial_points_coordinate += [center_x-center_x_l, center_y-center_y_l] '''draw fiducial points stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_img.copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1, 2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[1] + math.ceil(stepSize / 2), l[0] + math.ceil(stepSize / 2)), 5, (0, 0, 255), -1) cv2.imwrite('/lustre/home/gwxie/program/project/unwarp/unwarp_perturbed/TPS/img/cv_TPS_small.jpg',fiducial_points_synthesis_perturbed_img) ''' self.new_shape = save_img_shape self.synthesis_perturbed_img = self.synthesis_perturbed_img[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2, :].copy() self.synthesis_perturbed_label = self.synthesis_perturbed_label[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2, :].copy() self.foreORbackground_label = self.foreORbackground_label[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2].copy() perturbed_x_ = max(self.new_shape[0] - (perturbed_x_max - perturbed_x_min), 0) perturbed_x_min = perturbed_x_ // 2 perturbed_x_max = self.new_shape[0] - perturbed_x_ // 2 if perturbed_x_%2 == 0 else self.new_shape[0] - (perturbed_x_ // 2 + 1) perturbed_y_ = max(self.new_shape[1] - (perturbed_y_max - perturbed_y_min), 0) perturbed_y_min = perturbed_y_ // 2 perturbed_y_max = self.new_shape[1] - perturbed_y_ // 2 if perturbed_y_%2 == 0 else self.new_shape[1] - (perturbed_y_ // 2 + 1) '''clip perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = -1, -1, self.new_shape[0], self.new_shape[1] for x in range(self.new_shape[0] // 2, perturbed_x_max): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and perturbed_x_max - 1 > x: perturbed_x_max = x break for x in range(self.new_shape[0] // 2, perturbed_x_min, -1): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and x > 0: perturbed_x_min = x break for y in range(self.new_shape[1] // 2, perturbed_y_max): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and perturbed_y_max - 1 > y: perturbed_y_max = y break for y in range(self.new_shape[1] // 2, perturbed_y_min, -1): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and y > 0: perturbed_y_min = y break center_x, center_y = perturbed_x_min+(perturbed_x_max - perturbed_x_min)//2, perturbed_y_min+(perturbed_y_max - perturbed_y_min)//2 perfix_ = self.save_suffix+'_'+str(m)+'_'+str(n) self.new_shape = save_img_shape perturbed_x_ = max(self.new_shape[0] - (perturbed_x_max - perturbed_x_min), 0) perturbed_x_min = perturbed_x_ // 2 perturbed_x_max = self.new_shape[0] - perturbed_x_ // 2 if perturbed_x_%2 == 0 else self.new_shape[0] - (perturbed_x_ // 2 + 1) perturbed_y_ = max(self.new_shape[1] - (perturbed_y_max - perturbed_y_min), 0) perturbed_y_min = perturbed_y_ // 2 perturbed_y_max = self.new_shape[1] - perturbed_y_ // 2 if perturbed_y_%2 == 0 else self.new_shape[1] - (perturbed_y_ // 2 + 1) self.synthesis_perturbed_img = self.synthesis_perturbed_img[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2, :].copy() self.synthesis_perturbed_label = self.synthesis_perturbed_label[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2, :].copy() self.foreORbackground_label = self.foreORbackground_label[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2].copy() ''' '''save''' pixel_position = np.argwhere(	np.zeros(self.new_shape, dtype=np.uint32)	numpy.zeros
"""Test the search module""" from collections.abc import Iterable, Sized from io import StringIO from itertools import chain, product from functools import partial import pickle import sys from types import GeneratorType import re import numpy as np import scipy.sparse as sp import pytest from sklearn.utils.fixes import sp_version from sklearn.utils._testing import assert_raises from sklearn.utils._testing import assert_warns from sklearn.utils._testing import assert_warns_message from sklearn.utils._testing import assert_raise_message from sklearn.utils._testing import assert_array_equal from sklearn.utils._testing import assert_array_almost_equal from sklearn.utils._testing import assert_allclose from sklearn.utils._testing import assert_almost_equal from sklearn.utils._testing import ignore_warnings from sklearn.utils._mocking import CheckingClassifier, MockDataFrame from scipy.stats import bernoulli, expon, uniform from sklearn.base import BaseEstimator, ClassifierMixin from sklearn.base import clone from sklearn.exceptions import NotFittedError from sklearn.datasets import make_classification from sklearn.datasets import make_blobs from sklearn.datasets import make_multilabel_classification from sklearn.model_selection import fit_grid_point from sklearn.model_selection import train_test_split from sklearn.model_selection import KFold from sklearn.model_selection import StratifiedKFold from sklearn.model_selection import StratifiedShuffleSplit from sklearn.model_selection import LeaveOneGroupOut from sklearn.model_selection import LeavePGroupsOut from sklearn.model_selection import GroupKFold from sklearn.model_selection import GroupShuffleSplit from sklearn.model_selection import GridSearchCV from sklearn.model_selection import RandomizedSearchCV from sklearn.model_selection import ParameterGrid from sklearn.model_selection import ParameterSampler from sklearn.model_selection._search import BaseSearchCV from sklearn.model_selection._validation import FitFailedWarning from sklearn.svm import LinearSVC, SVC from sklearn.tree import DecisionTreeRegressor from sklearn.tree import DecisionTreeClassifier from sklearn.cluster import KMeans from sklearn.neighbors import KernelDensity from sklearn.neighbors import KNeighborsClassifier from sklearn.metrics import f1_score from sklearn.metrics import recall_score from sklearn.metrics import accuracy_score from sklearn.metrics import make_scorer from sklearn.metrics import roc_auc_score from sklearn.metrics.pairwise import euclidean_distances from sklearn.impute import SimpleImputer from sklearn.pipeline import Pipeline from sklearn.linear_model import Ridge, SGDClassifier, LinearRegression from sklearn.experimental import enable_hist_gradient_boosting # noqa from sklearn.ensemble import HistGradientBoostingClassifier from sklearn.model_selection.tests.common import OneTimeSplitter # Neither of the following two estimators inherit from BaseEstimator, # to test hyperparameter search on user-defined classifiers. class MockClassifier: """Dummy classifier to test the parameter search algorithms""" def __init__(self, foo_param=0): self.foo_param = foo_param def fit(self, X, Y): assert len(X) == len(Y) self.classes_ = np.unique(Y) return self def predict(self, T): return T.shape[0] def transform(self, X): return X + self.foo_param def inverse_transform(self, X): return X - self.foo_param predict_proba = predict predict_log_proba = predict decision_function = predict def score(self, X=None, Y=None): if self.foo_param > 1: score = 1. else: score = 0. return score def get_params(self, deep=False): return {'foo_param': self.foo_param} def set_params(self, **params): self.foo_param = params['foo_param'] return self class LinearSVCNoScore(LinearSVC): """An LinearSVC classifier that has no score method.""" @property def score(self): raise AttributeError X = np.array([[-1, -1], [-2, -1], [1, 1], [2, 1]]) y =	np.array([1, 1, 2, 2])	numpy.array
from __future__ import division from timeit import default_timer as timer import csv import numpy as np import itertools from munkres import Munkres, print_matrix, make_cost_matrix import sys from classes import * from functions import * from math import sqrt import Tkinter as tk import tkFileDialog as filedialog root = tk.Tk() root.withdraw() p_file = filedialog.askopenfilename(title='Please select the posting file') c_file = filedialog.askopenfilename(title='Please select the candidate file') """for use with /users/java_jonathan/postings_lge.csv and /Users/java_jonathan/candidates_lge.csv""" # p_file = raw_input("Please enter the path for the postings file: ") # p_file = p_file.strip() # c_file = raw_input("Please enter the path for the candidate file: ") # c_file = c_file.strip() start = timer() with open(p_file,'r') as f: #with open('/Users/Jonathan/Google Drive/CPD/Python/postings.csv','r') as f: reader = csv.reader(f) postingsAll = list(reader) with open(c_file,'r') as f: reader = csv.reader(f) candidatesAll = list(reader) """create empty lists to fill with lists of lists output by iterating function below""" names = [] totalMatrix = [] for list in candidatesAll: candidate = Candidate(list) names.append(candidate.name) n = 0 for list in postingsAll: posting = Posting(list) totalMatrix.append(matchDept(posting,candidate) + matchAnchor(posting,candidate) +matchLocation(posting,candidate) + matchCompetency(posting,candidate) + matchSkill(posting,candidate)+matchCohort(posting,candidate)) n += 1 l = len(names) names.extend([0] * (n-l)) totalMatrix.extend([0] * (n**2 - len(totalMatrix))) totalMatrix =	np.asarray(totalMatrix)	numpy.asarray
# coding=utf-8 import logging import traceback from os import makedirs from os.path import exists, join from textwrap import fill import matplotlib.patheffects as PathEffects import matplotlib.pyplot as plt import numpy as np import seaborn as sns from koino.plot import big_square, default_alpha from matplotlib import cm from ..utils.base import jaccard def plot_silhouette( X, figure_fp, n_clusters, silhouette_values, cluster_labels, silhouette_avg ): # Create a subplot with 1 row and 2 columns fig, (ax1, ax2) = plt.subplots(1, 2, figsize=(26, 10)) # The 1st subplot is the silhouette plot # The silhouette coefficient can range from -1, 1 but here all # lie within [-0.1, 1] ax1.set_xlim([-0.1, 1]) # The (n_clusters+1)10 is for inserting blank space between silhouette # plots of individual clusters, to demarcate them clearly. ax1.set_ylim([0, len(X) + (n_clusters + 1) 10]) y_lower = 10 for k in range(n_clusters): # Aggregate the silhouette scores for samples belonging to # cluster i, and sort them ith_cluster_silhouette_values = np.sort(silhouette_values[cluster_labels == k]) size_cluster_i = ith_cluster_silhouette_values.shape[0] y_upper = y_lower + size_cluster_i color = cm.spectral(float(k) / n_clusters) ax1.fill_betweenx( np.arange(y_lower, y_upper), 0, ith_cluster_silhouette_values, facecolor=color, edgecolor=color, alpha=default_alpha, ) # Label the silhouette plots with their cluster numbers at the # middle ax1.text(-0.05, y_lower + 0.5 * size_cluster_i, str(k)) # Compute the new y_lower for next plot y_lower = y_upper + 10 # 10 for the 0 samples ax1.set_title("The silhouette plot for the various clusters.") ax1.set_xlabel("The silhouette coefficient values") ax1.set_ylabel("Cluster label") # The vertical line for average silhouette score of all the values ax1.axvline(x=silhouette_avg, color="red", linestyle="--") ax1.set_yticks([]) # Clear the yaxis labels / ticks ax1.set_xticks([-0.1, 0, 0.2, 0.4, 0.6, 0.8, 1]) # Construct cluster # 2nd Plot showing the actual clusters formed colors = cm.spectral(cluster_labels.astype(float) / n_clusters) # colors = y ax2.scatter(X[:, 0], X[:, 1], marker=".", s=20, lw=0, alpha=default_alpha, c=colors) ax2.set_title("The visualization of the clustered data.") ax2.set_xlabel("Feature space for the 1st feature") ax2.set_ylabel("Feature space for the 2nd feature") plt.suptitle( ("Silhouette analysis for KMeans " "with n_clusters = %d" % n_clusters), fontsize=14, fontweight="bold", ) plt.savefig(figure_fp) plt.close() plt.clf() def plot_cluster_assignments( X, y, n_clusters, figures_dir, transparent=False, cluster_names=None, title="" ): """Clustering assignments scatter plot Notes ----- Can use mean or median to fix cluster centroid coordinates.""" if cluster_names is None: cluster_names = ["Cluster {}".format(i + 1) for i in range(n_clusters)] # We first reorder the data points according to the centroids labels X = np.vstack([X[y == i] for i in range(n_clusters)]) y = np.hstack([y[y == i] for i in range(n_clusters)]) # Choose a color palette with seaborn. palette = np.array(sns.color_palette("hls", n_clusters)) fig, ax = plt.subplots(figsize=big_square) # for i in range(n_clusters): # mask = y == i # ax.scatter(X[mask, 0], X[mask, 1], lw=0, s=20, c=palette[i], # label=cluster_names[i]) ax.set_title(title) ax.scatter(X[:, 0], X[:, 1], lw=0, s=20, c=palette[y.astype(np.int)]) ax.axis("off") # Add the labels for each cluster. for i in range(n_clusters): # Position of each label. samples = np.atleast_2d(X[y == i, :2]) if not len(samples): logging.warning( "Probably singular cluster {} (shape:{})".format(i + 1, X[y == i].shape) ) continue xtext, ytext =	np.median(samples, axis=0)	numpy.median
# Credit to https://medium.com/emergent-future/simple-reinforcement-learning-with-tensorflow-part-0-q-learning-with-tables-and-neural-networks-d195264329d0 import gym import tensorflow as tf import numpy as np import matplotlib.pyplot as plt env = gym.make('FrozenLake-v0') # NEURAL NETWORK IMPLEMENTATION tf.reset_default_graph() # Feature vector for current state representation input1 = tf.placeholder(shape=[1, env.observation_space.n], dtype=tf.float32) # tf.Variable(<initial-value>, name=<optional-name>) # tf.random_uniform(shape, minval=0, maxval=None, dtype=tf.float32, seed=None, name=None) # Weighting W vector in range 0 - 0.01 (like the way Andrew Ng did with 0.01 W = tf.Variable(tf.random_uniform([env.observation_space.n, env.action_space.n], 0, 0.01)) # Qout with shape [1, env.action_space.n] - Action state value for Q[s, a] with every a available at a state Qout = tf.matmul(input1, W) # Greedy action at a state predict = tf.argmax(Qout, axis=1) # Feature vector for next state representation nextQ = tf.placeholder(shape=[1, env.action_space.n], dtype=tf.float32) # Entropy loss loss = tf.reduce_sum(tf.square(Qout - nextQ)) trainer = tf.train.GradientDescentOptimizer(learning_rate=0.1) updateModel = trainer.minimize(loss) # TRAIN THE NETWORK init = tf.global_variables_initializer() # Set learning parameters y = 0.99 e = 0.1 number_episodes = 2000 # List to store total rewards and steps per episode jList = [] rList = [] with tf.Session() as sess: sess.run(init) for i in range(number_episodes): print("Episode #{} is running!".format(i)) # First state s = env.reset() rAll = 0 d = False j = 0 # Q network while j < 200: # or While not d: j += 1 # Choose action by epsilon (e) greedy # print("s = ", s," --> Identity s:s+1: ", np.identity(env.observation_space.n)[s:s+1]) # s = 0 --> Identity s: s + 1: [[1. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0.]] # s = 1 --> Identity s: s + 1: [[0. 1. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0.]] # Identity [s:s+1] is a one-hot vector # Therefore W is the actual Q value a, allQ = sess.run([predict, Qout], feed_dict={input1: np.identity(env.observation_space.n)[s:s+1]}) if np.random.rand(1) < e: a[0] = env.action_space.sample() s1, r, d, _ = env.step(a[0]) # Obtain next state Q value by feeding the new state throughout the network Q1 = sess.run(Qout, feed_dict={input1: np.identity(env.observation_space.n)[s1:s1+1]}) maxQ1 = np.max(Q1) targetQ = allQ targetQ[0, a[0]] = r + y maxQ1 # Train our network using target and predicted Q values _, W1 = sess.run([updateModel, W], feed_dict={input1:	np.identity(env.observation_space.n)	numpy.identity
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) +	np.sin(5 * pseudo_alg_time)	numpy.sin
# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side =	np.linspace(-2.1 - width, -2.1 + width, 101)	numpy.linspace
############################################################################### # @todo add Pilot2-splash-app disclaimer ############################################################################### """ Get's KRAS states """ import MDAnalysis as mda from MDAnalysis.analysis import align from MDAnalysis.lib.mdamath import make_whole import os import numpy as np import math ############## Below section needs to be uncommented ############ import mummi_core import mummi_ras from mummi_core.utils import Naming # # Logger has to be initialized the first thing in the script from logging import getLogger LOGGER = getLogger(__name__) # # Innitilize MuMMI if it has not been done before # MUMMI_ROOT = mummi.init(True) # This is needed so the Naming works below #@TODO fix this so we don't have these on import make them as an init mummi_core.init() dirKRASStates = Naming.dir_res('states') dirKRASStructures = Naming.dir_res('structures') # #RAS_ONLY_macrostate = np.loadtxt(os.path.join(dirKRASStates, "RAS-ONLY.microstates.txt")) RAS_ONLY_macrostate = np.loadtxt(os.path.join(dirKRASStates, "ras-states.txt"),comments='#') # #RAS_RAF_macrostate = np.loadtxt(os.path.join(dirKRASStates, "RAS-RAF.microstates.txt")) RAS_RAF_macrostate = np.loadtxt(os.path.join(dirKRASStates, "ras-raf-states.txt"),comments='#') # Note diffrent number of columns so index change below # TODO: CS, my edits to test # RAS_ONLY_macrostate = np.loadtxt('ras-states.txt') # RAS_RAF_macrostate = np.loadtxt('ras-raf-states.txt') ############## above section needs to be uncommented ############ # TODO: CS, my edits to test # TODO: TSC, The reference structure has to currently be set as the 'RAS-ONLY-reference-structure.gro' # TODO: TSC, path to the reference structure is: mummi_resources/structures/ kras_ref_universe = mda.Universe(os.path.join(dirKRASStructures, "RAS-ONLY-reference-structure.gro")) # kras_ref_universe = mda.Universe("RAS-ONLY-reference-structure.gro") # kras_ref_universe = mda.Universe('AA_pfpatch_000000004641_RAS_RAF2_411.gro') # TODO: CS, not using these for x4 proteins; instead using protein_systems below to set num_res ######### Below hard codes the number of residues within RAS-only and RAS-RAF ########## RAS_only_num_res = 184 RAS_RAF_num_res = 320 ######### Above hard codes the number of residues within RAS-only and RAS-RAF ########## ####### This can be removed # def get_kras(syst, kras_start): # """Gets all atoms for a KRAS protein starting at 'kras_start'.""" # return syst.atoms[kras_start:kras_start+428] ####### This can be removed def get_segids(u): """Identifies the list of segments within the system. Only needs to be called x1 time""" segs = u.segments segs = segs.segids ras_segids = [] rasraf_segids = [] for i in range(len(segs)): # print(segs[i]) if segs[i][-3:] == 'RAS': ras_segids.append(segs[i]) if segs[i][-3:] == 'RAF': rasraf_segids.append(segs[i]) return ras_segids, rasraf_segids def get_protein_info(u,tag): """Uses the segments identified in get_segids to make a list of all proteins in the systems.\ Outputs a list of the first residue number of the protein, and whether it is 'RAS-ONLY', or 'RAS-RAF'.\ The 'tag' input defines what is used to identify the first residue of the protein. i.e. 'resname ACE1 and name BB'.\ Only needs to be called x1 time""" ras_segids, rasraf_segids = get_segids(u) if len(ras_segids) > 0: RAS = u.select_atoms('segid '+ras_segids[0]+' and '+str(tag)) else: RAS = [] if len(rasraf_segids) > 0: RAF = u.select_atoms('segid '+rasraf_segids[0]+' and '+str(tag)) else: RAF = [] protein_info = []#np.empty([len(RAS)+len(RAF),2]) for i in range(len(RAS)): protein_info.append((RAS[i].resid,'RAS-ONLY')) for i in range(len(RAF)): protein_info.append((RAF[i].resid,'RAS-RAF')) ######## sort protein info protein_info = sorted(protein_info) ######## sort protein info return protein_info def get_ref_kras(): """Gets the reference KRAS struct. Only called x1 time when class is loaded""" start_of_g_ref = kras_ref_universe.residues[0].resid ref_selection = 'resid '+str(start_of_g_ref)+':'+str(start_of_g_ref+24)+' ' +\ str(start_of_g_ref+38)+':'+str(start_of_g_ref+54)+' ' +\ str(start_of_g_ref+67)+':'+str(start_of_g_ref+164)+' ' +\ 'and (name CA or name BB)' r2_26r40_56r69_166_ref = kras_ref_universe.select_atoms(str(ref_selection)) return kras_ref_universe.select_atoms(str(ref_selection)).positions - kras_ref_universe.select_atoms(str(ref_selection)).center_of_mass() # Load inital ref frames (only need to do this once) ref0 = get_ref_kras() def getKRASstates(u,kras_indices): """Gets states for all KRAS proteins in path.""" # res_shift = 8 # all_glycine = u.select_atoms("resname GLY") # kras_indices = [] # for i in range(0, len(all_glycine), 26): # kras_indices.append(all_glycine[i].index) ########## Below is taken out of the function so it is only done once ######### # kras_indices = get_protein_info(u,'resname ACE1 and name BB') ########## Above is taken out of the function so it is only done once ######### # CS, for x4 cases: # [{protein_x4: (protein_type, num_res)}] protein_systems = [{'ras4a': ('RAS-ONLY', 185), 'ras4araf': ('RAS-RAF', 321), 'ras': ('RAS-ONLY', 184), 'rasraf': ('RAS-RAF', 320)}] ALLOUT = [] for k in range(len(kras_indices)): start_of_g = kras_indices[k][0] protein_x4 = str(kras_indices[k][1]) try: protein_type = [item[protein_x4] for item in protein_systems][0][0] # 'RAS-ONLY' OR 'RAS-RAF' num_res = [item[protein_x4] for item in protein_systems][0][1] except: LOGGER.error('Check KRas naming between modules') raise Exception('Error: unknown KRas name') # TODO: CS, replacing this comment section with the above, to handle x4 protein types # --------------------------------------- # ALLOUT = [] # for k in range(len(kras_indices)): # start_of_g = kras_indices[k][0] # protein_type = str(kras_indices[k][1]) # ########## BELOW SECTION TO DETERMINE WHICH RESIDUES ARE PART OF THE PROTEIN GROUP - NEEDED FOR PBC REMOVAL ############## # ########## POTENTIALLY REDO WITH A 'HARD-CODED' NUMBER OF RESIDUES PER PROTEIN GROUP (WHETHER RAS-ONLY OR RAS-RAF) ####### # ########## HAS BEEN REDONE WITH A 'HARD-CODED' NUMBER OF RESIDUES PER PROTEIN GROUP (WHETHER RAS-ONLY OR RAS-RAF) ######## # # if len(kras_indices) == 1: # # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(len(u.residues))+' and name BB') ####### HAS TO BE FIXED FOR BACKBONE ATOMS FOR SPECIFIC PROTEIN # # elif len(kras_indices) > 1: # # if k == len(kras_indices)-1: # # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(len(u.residues))+' and name BB') # # else: # # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(kras_indices[k+1][0])+' and name BB') # ########## ABOVE SECTION TO DETERMINE WHICH RESIDUES ARE PART OF THE PROTEIN GROUP - NEEDED FOR PBC REMOVAL ############## # # ########## Below hard codes the number of residues/beads in the RAS-ONLY and RAS-RAF simulations ######################### # if protein_type == 'RAS-ONLY': # num_res = RAS_only_num_res # elif protein_type == 'RAS-RAF': # num_res = RAS_RAF_num_res # ########## Above hard codes the number of residues/beads in the RAS-ONLY and RAS-RAF simulations ######################### # --------------------------------------- # TODO: TSC, I changed the selection below, which can be used for the make_whole... # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(start_of_g+num_res)+' and (name CA or name BB)') krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(start_of_g+num_res)) krases0_BB.guess_bonds() r2_26r40_56r69_166 = u.select_atoms('resid '+str(start_of_g)+':'+str(start_of_g+24)+' ' +\ str(start_of_g+38)+':'+str(start_of_g+54)+' ' +\ str(start_of_g+67)+':'+str(start_of_g+164)+\ ' and (name CA or name BB)') u_selection = \ 'resid '+str(start_of_g)+':'+str(start_of_g+24)+' '+str(start_of_g+38)+':'+str(start_of_g+54)+' ' +\ str(start_of_g+67)+':'+str(start_of_g+164)+' and (name CA or name BB)' mobile0 = u.select_atoms(str(u_selection)).positions - u.select_atoms(str(u_selection)).center_of_mass() # TODO: CS, something wrong with ref0 from get_kras_ref() # just making ref0 = mobile0 to test for now # ref0 = mobile0 # TSC removed this R, RMSD_junk = align.rotation_matrix(mobile0, ref0) ######## TODO: TSC, Adjusted for AA lipid names ######## # lipids = u.select_atoms('resname POPX POPC PAPC POPE DIPE DPSM PAPS PAP6 CHOL') lipids = u.select_atoms('resname POPC PAPC POPE DIPE SSM PAPS SAPI CHL1') coords = ref0 RotMat = [] OS = [] r152_165 = krases0_BB.select_atoms('resid '+str(start_of_g+150)+':'+str(start_of_g+163)+' and (name CA or name BB)') r65_74 = krases0_BB.select_atoms('resid '+str(start_of_g+63)+':'+str(start_of_g+72)+' and (name CA or name BB)') timeframes = [] # TODO: CS, for AA need bonds to run make_whole() # krases0_BB.guess_bonds() # TODO: CS, turn off for now to test beyond this point ''' * for AA, need to bring that back on once all else runs * ''' # @Tim and <NAME>. this was commented out - please check. #make_whole(krases0_BB) j, rmsd_junk = mda.analysis.align.rotation_matrix((r2_26r40_56r69_166.positions-r2_26r40_56r69_166.center_of_mass()), coords) RotMat.append(j) OS.append(r65_74.center_of_mass()-r152_165.center_of_mass()) timeframes.append(u.trajectory.time) if protein_type == 'RAS-RAF': z_pos = [] ############### NEED TO CONFIRM THE SELECTION OF THE RAF LOOP RESIDUES BELOW #################### ############### TODO: TSC, zshifting is set to -1 (instead of -2), as there are ACE caps that are separate residues in AA #zshifting=-1 if protein_x4 == 'rasraf': zshifting = -1 elif protein_x4 == 'ras4araf': zshifting = 0 else: zshifting = 0 LOGGER.error('Found unsupported protein_x4 type') raf_loops_selection = u.select_atoms('resid '+str(start_of_g+zshifting+291)+':'+str(start_of_g+zshifting+294)+' ' +\ str(start_of_g+zshifting+278)+':'+str(start_of_g+zshifting+281)+' ' +\ ' and (name CA or name BB)') ############### NEED TO CONFIRM THE SELECTION OF THE RAF LOOP RESIDUES ABOVE #################### diff = (lipids.center_of_mass()[2]-raf_loops_selection.center_of_mass(unwrap=True)[2])/10 if diff < 0: diff = diff+(u.dimensions[2]/10) z_pos.append(diff) z_pos = np.array(z_pos) RotMatNP = np.array(RotMat) OS = np.array(OS) OA = RotMatNP[:, 2, :]/(((RotMatNP[:, 2, 0]2)+(RotMatNP[:, 2, 1]2)+(RotMatNP[:, 2, 2]2))0.5)[:, None] OWAS = np.arccos(RotMatNP[:, 2, 2])180/math.pi OC_temp = np.concatenate((OA, OS), axis=1) t = ((OC_temp[:, 0]OC_temp[:, 3])+(OC_temp[:, 1]OC_temp[:, 4]) + (OC_temp[:, 2]OC_temp[:, 5]))/((OC_temp[:, 0]2)+(OC_temp[:, 1]2)+(OC_temp[:, 2]*2)) OC = OAt[:, None] ORS_tp =	np.concatenate((OC, OS), axis=1)	numpy.concatenate
import argparse import json import numpy as np import pandas as pd import os from sklearn.linear_model import LogisticRegression from sklearn.model_selection import train_test_split from sklearn.metrics import classification_report,f1_score from keras.models import Sequential from keras.layers import Dense, Dropout from keras import backend as K from keras.utils.vis_utils import plot_model from sklearn.externals import joblib import time def f1(y_true, y_pred): def recall(y_true, y_pred): """Recall metric. Only computes a batch-wise average of recall. Computes the recall, a metric for multi-label classification of how many relevant items are selected. """ true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1))) possible_positives = K.sum(K.round(K.clip(y_true, 0, 1))) recall = true_positives / (possible_positives + K.epsilon()) return recall def precision(y_true, y_pred): """Precision metric. Only computes a batch-wise average of precision. Computes the precision, a metric for multi-label classification of how many selected items are relevant. """ true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1))) predicted_positives = K.sum(K.round(K.clip(y_pred, 0, 1))) precision = true_positives / (predicted_positives + K.epsilon()) return precision precision = precision(y_true, y_pred) recall = recall(y_true, y_pred) return 2((precisionrecall)/(precision+recall+K.epsilon())) def get_embeddings(sentences_list,layer_json): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :return: Dictionary with key each sentence of the sentences_list and as value the embedding ''' sentences = dict()#dict with key the index of each line of the sentences_list.txt and as value the sentence embeddings = dict()##dict with key the index of each sentence and as value the its embedding sentence_emb = dict()#key:sentence,value:its embedding with open(sentences_list,'r') as file: for index,line in enumerate(file): sentences[index] = line.strip() with open(layer_json, 'r',encoding='utf-8') as f: for line in f: embeddings[json.loads(line)['linex_index']] = np.asarray(json.loads(line)['features']) for key,value in sentences.items(): sentence_emb[value] = embeddings[key] return sentence_emb def train_classifier(sentences_list,layer_json,dataset_csv,filename): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :param dataset_csv: the path of the dataset :param filename: The path of the pickle file that the model will be stored :return: ''' dataset = pd.read_csv(dataset_csv) bert_dict = get_embeddings(sentences_list,layer_json) length = list() sentence_emb = list() previous_emb = list() next_list = list() section_list = list() label = list() errors = 0 for row in dataset.iterrows(): sentence = row[1][0].strip() previous = row[1][1].strip() nexts = row[1][2].strip() section = row[1][3].strip() if sentence in bert_dict: sentence_emb.append(bert_dict[sentence]) else: sentence_emb.append(np.zeros(768)) print(sentence) errors += 1 if previous in bert_dict: previous_emb.append(bert_dict[previous]) else: previous_emb.append(np.zeros(768)) if nexts in bert_dict: next_list.append(bert_dict[nexts]) else: next_list.append(np.zeros(768)) if section in bert_dict: section_list.append(bert_dict[section]) else: section_list.append(np.zeros(768)) length.append(row[1][4]) label.append(row[1][5]) sentence_emb = np.asarray(sentence_emb) print(sentence_emb.shape) next_emb = np.asarray(next_list) print(next_emb.shape) previous_emb = np.asarray(previous_emb) print(previous_emb.shape) section_emb = np.asarray(section_list) print(sentence_emb.shape) length = np.asarray(length) print(length.shape) label = np.asarray(label) print(errors) features = np.concatenate([sentence_emb, previous_emb, next_emb,section_emb], axis=1) features = np.column_stack([features, length]) # np.append(features,length,axis=1) print(features.shape) X_train, X_val, y_train, y_val = train_test_split(features, label, test_size=0.33, random_state=42) log = LogisticRegression(random_state=0, solver='newton-cg', max_iter=1000, C=0.1) log.fit(X_train, y_train) #save the model _ = joblib.dump(log, filename, compress=9) predictions = log.predict(X_val) print("###########################################") print("Results using embeddings from the",layer_json,"file") print(classification_report(y_val, predictions)) print("F1 score using Logistic Regression:",f1_score(y_val, predictions)) print("###########################################") #train a DNN f1_results = list() for i in range(3): model = Sequential() model.add(Dense(64, activation='relu', trainable=True)) model.add(Dense(128, activation='relu', trainable=True)) model.add(Dropout(0.30)) model.add(Dense(64, activation='relu', trainable=True)) model.add(Dropout(0.25)) model.add(Dense(64, activation='relu', trainable=True)) model.add(Dropout(0.35)) model.add(Dense(1, activation='sigmoid')) # compile network model.compile(loss='binary_crossentropy', optimizer='sgd', metrics=[f1]) # fit network model.fit(X_train, y_train, epochs=100, batch_size=64) loss, f_1 = model.evaluate(X_val, y_val, verbose=1) print('\nTest F1: %f' % (f_1 * 100)) f1_results.append(f_1) model = None print("###########################################") print("Results using embeddings from the", layer_json, "file") # evaluate print(np.mean(f1_results)) print("###########################################") def parameter_tuning_LR(sentences_list,layer_json,dataset_csv): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :param dataset_csv: the path of the dataset :return: ''' dataset = pd.read_csv(dataset_csv) bert_dict = get_embeddings(sentences_list,layer_json) length = list() sentence_emb = list() previous_emb = list() next_list = list() section_list = list() label = list() errors = 0 for row in dataset.iterrows(): sentence = row[1][0].strip() previous = row[1][1].strip() nexts = row[1][2].strip() section = row[1][3].strip() if sentence in bert_dict: sentence_emb.append(bert_dict[sentence]) else: sentence_emb.append(np.zeros(768)) print(sentence) errors += 1 if previous in bert_dict: previous_emb.append(bert_dict[previous]) else: previous_emb.append(	np.zeros(768)	numpy.zeros
try: import importlib.resources as pkg_resources except ImportError: # Try backported to PY<37 `importlib_resources`. import importlib_resources as pkg_resources from . import images from gym import Env, spaces from time import time import numpy as np from copy import copy import colorsys import pygame from pygame.transform import scale class MinesweeperEnv(Env): def __init__(self, grid_shape=(10, 15), bombs_density=0.1, n_bombs=None, impact_size=3, max_time=999, chicken=False): self.grid_shape = grid_shape self.grid_size = np.prod(grid_shape) self.n_bombs = max(1, int(bombs_density * self.grid_size)) if n_bombs is None else n_bombs self.n_bombs = min(self.grid_size - 1, self.n_bombs) self.flaged_bombs = 0 self.flaged_empty = 0 self.max_time = max_time if impact_size % 2 == 0: raise ValueError('Impact_size must be an odd number !') self.impact_size = impact_size # Define constants self.HIDDEN = 0 self.REVEAL = 1 self.FLAG = 2 self.BOMB = self.impact_size ** 2 # Setting up gym Env conventions nvec_observation = (self.BOMB + 2) * np.ones(self.grid_shape) self.observation_space = spaces.MultiDiscrete(nvec_observation) nvec_action = np.array(self.grid_shape + (2,)) self.action_space = spaces.MultiDiscrete(nvec_action) # Initalize state self.state = np.zeros(self.grid_shape + (2,), dtype=np.uint8) ## Setup bombs places idx = np.indices(self.grid_shape).reshape(2, -1) bombs_ids = np.random.choice(range(self.grid_size), size=self.n_bombs, replace=False) self.bombs_positions = idx[0][bombs_ids], idx[1][bombs_ids] ## Place numbers self.semi_impact_size = (self.impact_size-1)//2 bomb_impact = np.ones((self.impact_size, self.impact_size), dtype=np.uint8) for bombs_id in bombs_ids: bomb_x, bomb_y = idx[0][bombs_id], idx[1][bombs_id] x_min, x_max, dx_min, dx_max = self.clip_index(bomb_x, 0) y_min, y_max, dy_min, dy_max = self.clip_index(bomb_y, 1) bomb_region = self.state[x_min:x_max, y_min:y_max, 0] bomb_region += bomb_impact[dx_min:dx_max, dy_min:dy_max] ## Place bombs self.state[self.bombs_positions + (0,)] = self.BOMB self.start_time = time() self.time_left = int(time() - self.start_time) # Setup rendering self.pygame_is_init = False self.chicken = chicken self.done = False self.score = 0 def get_observation(self): observation = copy(self.state[:, :, 1]) revealed = observation == 1 flaged = observation == 2 observation += self.impact_size ** 2 + 1 observation[revealed] = copy(self.state[:, :, 0][revealed]) observation[flaged] -= 1 return observation def reveal_around(self, coords, reward, done, without_loss=False): if not done: x_min, x_max, _, _ = self.clip_index(coords[0], 0) y_min, y_max, _, _ = self.clip_index(coords[1], 1) region = self.state[x_min:x_max, y_min:y_max, :] unseen_around = np.sum(region[..., 1] == 0) if unseen_around == 0: if not without_loss: reward -= 0.001 return flags_around =	np.sum(region[..., 1] == 2)	numpy.sum
import pandas as pd import numpy as np import matplotlib.pyplot as plt import os import matplotlib.pyplot as plt import CurveFit import shutil #find all DIRECTORIES containing non-hidden files ending in FILENAME def getDataDirectories(DIRECTORY, FILENAME="valLoss.txt"): directories=[] for directory in os.scandir(DIRECTORY): for item in os.scandir(directory): if item.name.endswith(FILENAME) and not item.name.startswith("."): directories.append(directory.path) return directories #get all non-hidden data files in DIRECTORY with extension EXT def getDataFiles(DIRECTORY, EXT='txt'): datafiles=[] for item in os.scandir(DIRECTORY): if item.name.endswith("."+EXT) and not item.name.startswith("."): datafiles.append(item.path) return datafiles #checking if loss ever doesn't decrease for numEpochs epochs in a row. def stopsDecreasing(loss, epoch, numEpochs): minLoss=np.inf epochMin=0 for i in range(0,loss.size): if loss[i] < minLoss: minLoss=loss[i] epochMin=epoch[i] elif (epoch[i]-epochMin) >= numEpochs: return i, minLoss return i, minLoss #dirpath is where the accuracy and loss files are stored. want to move the files into the same format expected by grabNNData. def createFolders(SEARCHDIR, SAVEDIR): for item in os.scandir(SEARCHDIR): name=str(item.name) files=name.split('-') SAVEFULLDIR=SAVEDIR+str(files[0]) if not os.path.exists(SAVEFULLDIR): try: os.makedirs(SAVEFULLDIR) except FileExistsError: #directory already exists--must have been created between the if statement & our attempt at making directory pass shutil.move(item.path, SAVEFULLDIR+"/"+str(files[1])) #a function to read in information (e.g. accuracy, loss) stored at FILENAME def grabNNData(FILENAME, header='infer', sep=' '): data = pd.read_csv(FILENAME, sep, header=header) if ('epochs' in data.columns) and ('trainLoss' in data.columns) and ('valLoss' in data.columns) and ('valAcc' in data.columns) and ('batch_size' in data.columns) and ('learning_rate' in data.columns): sortedData=data.sort_values(by="epochs", axis=0, ascending=True) epoch=np.array(sortedData['epochs']) trainLoss=np.array(sortedData['trainLoss']) valLoss=np.array(sortedData['valLoss']) valAcc=	np.array(sortedData['valAcc'])	numpy.array
import os from PIL import Image import cv2 from os import listdir from os.path import join import matplotlib.pyplot as plt import matplotlib from matplotlib.colors import LogNorm from io_utils.io_common import create_folder from viz_utils.constants import PlotMode, BackgroundType import pylab import numpy as np import cmocean import shapely import cartopy.crs as ccrs import cartopy.feature as cfeature import cartopy def select_colormap(field_name): ''' Based on the name if the field it chooses a colormap from cmocean Args: field_name: Returns: ''' if np.any([field_name.find(x) != -1 for x in ('ssh', 'srfhgt', 'adt','surf_el')]): # cmaps_fields.append(cmocean.cm.deep_r) return cmocean.cm.curl elif np.any([field_name.find(x) != -1 for x in ('temp', 'sst', 'temperature')]): return cmocean.cm.thermal elif np.any([field_name.find(x) != -1 for x in ('vorticity', 'vort')]): return cmocean.cm.curl elif np.any([field_name.find(x) != -1 for x in ('salin', 'sss', 'sal')]): return cmocean.cm.haline elif field_name.find('error') != -1: return cmocean.cm.diff elif field_name.find('binary') != -1: return cmocean.cm.oxy elif np.any([field_name.find(x) != -1 for x in ('u_', 'v_', 'u-vel.', 'v-vel.','velocity')]): return cmocean.cm.speed class EOAImageVisualizer: """This class makes plenty of plots assuming we are plotting Geospatial data (maps). It is made to read xarrays, numpy arrays, and numpy arrays in dictionaries vizobj = new EOAImageVisualizer(disp_images=True, output_folder='output', lats=[lats],lons=[lons]) """ _COLORS = ['y', 'r', 'c', 'b', 'g', 'w', 'k', 'y', 'r', 'c', 'b', 'g', 'w', 'k'] _figsize = 8 _font_size = 30 _units = '' _max_imgs_per_row = 4 _mincbar = np.nan # User can set a min and max colorbar values to 'force' same color bar to all plots _maxcbar = np.nan _flip_data = True _eoas_pyutils_path = './eoas_pyutils'# This is the path where the eoas_utils folder is stored with respect to the main project _contourf = False # When plotting non-regular grids and need precision _background = BackgroundType.BLUE_MARBLE_LR # Select the background to use _auto_colormap = True # Selects the colormap based on the name of the field _show_var_names = False # Includes the name of the field name in the titles _additional_polygons = [] # MUST BE SHAPELY GEOMETRIES In case we want to include additional polygons in the plots (all of them) # If you want to add a streamplot of a vector field. It must be a dictionary with keys x,y,u,v # and optional density, color, cmap, arrowsize, arrowstyle, minlength _vector_field = None _norm = None # Use to normalize the colormap. For example with LogNorm # vizobj = EOAImageVisualizer(disp_images=True, output_folder='output', # lats=[lats],lons=[lons]) def __init__(self, disp_images=True, output_folder='output', lats=[-90,90], lons =[-180,180], projection=ccrs.PlateCarree(), *kwargs): # All the arguments that are passed to the constructor of the class MUST have its name on it. self._disp_images = disp_images self._output_folder = output_folder self._projection = projection bbox = self.getExtent(lats, lons) self._extent = bbox self._lats = lats self._lons = lons self._fig_prop = (bbox[1]-bbox[0])/(bbox[3]-bbox[2]) self._contour_labels = False for arg_name, arg_value in kwargs.items(): self.__dict__["_" + arg_name] = arg_value print(self.__dict__["_" + arg_name]) def __getattr__(self, attr): '''Generic getter for all the properties of the class''' return self.__dict__["_" + attr] def __setattr__(self, attr, value): '''Generic setter for all the properties of the class''' self.__dict__["_" + attr] = value def add_colorbar(self, fig, im, ax, show_color_bar, label=""): # https://matplotlib.org/api/_as_gen/matplotlib.pyplot.colorbar.html if show_color_bar: font_size_cbar = self._font_size .5 # TODO how to make this automatic and works always cbar = fig.colorbar(im, ax=ax, shrink=.7) cbar.ax.tick_params(labelsize=font_size_cbar) if label != "": cbar.set_label(label, fontsize=font_size_cbar1.2) else: cbar.set_label(self._units, fontsize=font_size_cbar1.2) def plot_slice_eoa(self, c_img, ax, cmap='gray', mode=PlotMode.RASTER, mincbar=np.nan, maxcbar=np.nan) -> None: """ Plots a 2D img for EOA data. :param c_img: 2D array :param ax: geoaxes :return: """ c_ax = ax if self._flip_data: origin = 'lower' else: origin = 'upper' if self._background == BackgroundType.CARTO_DEF: c_ax.stock_img() else: if self._background == BackgroundType.BLUE_MARBLE_LR: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/bluemarble.png')) if self._background == BackgroundType.BLUE_MARBLE_HR: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/bluemarble_5400x2700.jpg')) if self._background == BackgroundType.TOPO: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/etopo.png')) if self._background == BackgroundType.BATHYMETRY: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/bathymetry_3600x1800.jpg')) c_ax.imshow(img, origin='upper', extent=(-180,180,-90,90), transform=ccrs.PlateCarree()) if mode == PlotMode.RASTER or mode == PlotMode.MERGED: if self._contourf: im = c_ax.contourf(self._lons, self._lats, c_img, num_colors=255, cmap='inferno', extent=self._extent) else: if	np.isnan(mincbar)	numpy.isnan

import gym import numpy as np from itertools import product import matplotlib.pyplot as plt def print_policy(Q, env): """ This is a helper function to print a nice policy from the Q function""" moves = [u'←', u'↓',u'→', u'↑'] if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape policy = np.chararray(dims, unicode=True) policy[:] = ' ' for s in range(len(Q)): idx = np.unravel_index(s, dims) policy[idx] = moves[np.argmax(Q[s])] if env.desc[idx] in ['H', 'G']: policy[idx] = u'·' print('\n'.join([''.join([u'{:2}'.format(item) for item in row]) for row in policy])) def plot_V(Q, env): """ This is a helper function to plot the state values from the Q function""" fig = plt.figure() if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape V = np.zeros(dims) for s in range(len(Q)): idx = np.unravel_index(s, dims) V[idx] = np.max(Q[s]) if env.desc[idx] in ['H', 'G']: V[idx] = 0. plt.imshow(V, origin='upper', extent=[0,dims[0],0,dims[1]], vmin=.0, vmax=.6, cmap=plt.cm.RdYlGn, interpolation='none') for x, y in product(range(dims[0]), range(dims[1])): plt.text(y+0.5, dims[0]-x-0.5, '{:.3f}'.format(V[x,y]), horizontalalignment='center', verticalalignment='center') plt.xticks([]) plt.yticks([]) def plot_Q(Q, env): """ This is a helper function to plot the Q function """ from matplotlib import colors, patches fig = plt.figure() ax = fig.gca() if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape up = np.array([[0, 1], [0.5, 0.5], [1,1]]) down = np.array([[0, 0], [0.5, 0.5], [1,0]]) left = np.array([[0, 0], [0.5, 0.5], [0,1]]) right = np.array([[1, 0], [0.5, 0.5], [1,1]]) tri = [left, down, right, up] pos = [[0.2, 0.5], [0.5, 0.2], [0.8, 0.5], [0.5, 0.8]] cmap = plt.cm.RdYlGn norm = colors.Normalize(vmin=.0,vmax=.6) ax.imshow(np.zeros(dims), origin='upper', extent=[0,dims[0],0,dims[1]], vmin=.0, vmax=.6, cmap=cmap) ax.grid(which='major', color='black', linestyle='-', linewidth=2) for s in range(len(Q)): idx = np.unravel_index(s, dims) x, y = idx if env.desc[idx] in ['H', 'G']: ax.add_patch(patches.Rectangle((y, 3-x), 1, 1, color=cmap(.0))) plt.text(y+0.5, dims[0]-x-0.5, '{:.2f}'.format(.0), horizontalalignment='center', verticalalignment='center') continue for a in range(len(tri)): ax.add_patch(patches.Polygon(tri[a] + np.array([y, 3-x]), color=cmap(Q[s][a]))) plt.text(y+pos[a][0], dims[0]-1-x+pos[a][1], '{:.2f}'.format(Q[s][a]), horizontalalignment='center', verticalalignment='center', fontsize=9, fontweight=('bold' if Q[s][a] == np.max(Q[s]) else 'normal')) plt.xticks([]) plt.yticks([]) def choose_abs_greedy_action(state, Q, epsilon): action = None if np.random.uniform(0, 1) < epsilon: action = np.random.randint(env.action_space.n) else: action =

np.argmax(Q[state,:])

numpy.argmax

from abc import ABCMeta, abstractmethod import os from vmaf.tools.misc import make_absolute_path, run_process from vmaf.tools.stats import ListStats __copyright__ = "Copyright 2016-2018, Netflix, Inc." __license__ = "Apache, Version 2.0" import re import numpy as np import ast from vmaf import ExternalProgramCaller, to_list from vmaf.config import VmafConfig, VmafExternalConfig from vmaf.core.executor import Executor from vmaf.core.result import Result from vmaf.tools.reader import YuvReader class FeatureExtractor(Executor): """ FeatureExtractor takes in a list of assets, and run feature extraction on them, and return a list of corresponding results. A FeatureExtractor must specify a unique type and version combination (by the TYPE and VERSION attribute), so that the Result generated by it can be identified. A derived class of FeatureExtractor must: 1) Override TYPE and VERSION 2) Override _generate_result(self, asset), which call a command-line executable and generate feature scores in a log file. 3) Override _get_feature_scores(self, asset), which read the feature scores from the log file, and return the scores in a dictionary format. For an example, follow VmafFeatureExtractor. """ __metaclass__ = ABCMeta @property @abstractmethod def ATOM_FEATURES(self): raise NotImplementedError def _read_result(self, asset): result = {} result.update(self._get_feature_scores(asset)) executor_id = self.executor_id return Result(asset, executor_id, result) @classmethod def get_scores_key(cls, atom_feature): return "{type}_{atom_feature}_scores".format( type=cls.TYPE, atom_feature=atom_feature) @classmethod def get_score_key(cls, atom_feature): return "{type}_{atom_feature}_score".format( type=cls.TYPE, atom_feature=atom_feature) def _get_feature_scores(self, asset): # routine to read the feature scores from the log file, and return # the scores in a dictionary format. log_file_path = self._get_log_file_path(asset) atom_feature_scores_dict = {} atom_feature_idx_dict = {} for atom_feature in self.ATOM_FEATURES: atom_feature_scores_dict[atom_feature] = [] atom_feature_idx_dict[atom_feature] = 0 with open(log_file_path, 'rt') as log_file: for line in log_file.readlines(): for atom_feature in self.ATOM_FEATURES: re_template = "{af}: ([0-9]+) ([a-zA-Z0-9.-]+)".format(af=atom_feature) mo = re.match(re_template, line) if mo: cur_idx = int(mo.group(1)) assert cur_idx == atom_feature_idx_dict[atom_feature] # parse value, allowing NaN and inf val = float(mo.group(2)) if np.isnan(val) or np.isinf(val): val = None atom_feature_scores_dict[atom_feature].append(val) atom_feature_idx_dict[atom_feature] += 1 continue len_score = len(atom_feature_scores_dict[self.ATOM_FEATURES[0]]) assert len_score != 0 for atom_feature in self.ATOM_FEATURES[1:]: assert len_score == len(atom_feature_scores_dict[atom_feature]), \ "Feature data possibly corrupt. Run cleanup script and try again." feature_result = {} for atom_feature in self.ATOM_FEATURES: scores_key = self.get_scores_key(atom_feature) feature_result[scores_key] = atom_feature_scores_dict[atom_feature] return feature_result class VmafFeatureExtractor(FeatureExtractor): TYPE = "VMAF_feature" # VERSION = '0.1' # vmaf_study; Anush's VIF fix # VERSION = '0.2' # expose vif_num, vif_den, adm_num, adm_den, anpsnr # VERSION = '0.2.1' # expose vif num/den of each scale # VERSION = '0.2.2' # adm abs-->fabs, corrected border handling, uniform reading with option of offset for input YUV, updated VIF corner case # VERSION = '0.2.2b' # expose adm_den/num_scalex # VERSION = '0.2.3' # AVX for VMAF convolution; update adm features by folding noise floor into per coef # VERSION = '0.2.4' # Fix a bug in adm feature passing scale into dwt_quant_step # VERSION = '0.2.4b' # Modify by adding ADM noise floor outside cube root; add derived feature motion2 VERSION = '0.2.4c' # Modify by moving motion2 to c code ATOM_FEATURES = ['vif', 'adm', 'ansnr', 'motion', 'motion2', 'vif_num', 'vif_den', 'adm_num', 'adm_den', 'anpsnr', 'vif_num_scale0', 'vif_den_scale0', 'vif_num_scale1', 'vif_den_scale1', 'vif_num_scale2', 'vif_den_scale2', 'vif_num_scale3', 'vif_den_scale3', 'adm_num_scale0', 'adm_den_scale0', 'adm_num_scale1', 'adm_den_scale1', 'adm_num_scale2', 'adm_den_scale2', 'adm_num_scale3', 'adm_den_scale3', ] DERIVED_ATOM_FEATURES = ['vif_scale0', 'vif_scale1', 'vif_scale2', 'vif_scale3', 'vif2', 'adm2', 'adm3', 'adm_scale0', 'adm_scale1', 'adm_scale2', 'adm_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vmaf_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VmafFeatureExtractor, cls)._post_process_result(result) # adm2 = # (adm_num + ADM2_CONSTANT) / (adm_den + ADM2_CONSTANT) adm2_scores_key = cls.get_scores_key('adm2') adm_num_scores_key = cls.get_scores_key('adm_num') adm_den_scores_key = cls.get_scores_key('adm_den') result.result_dict[adm2_scores_key] = list( (np.array(result.result_dict[adm_num_scores_key]) + cls.ADM2_CONSTANT) / (np.array(result.result_dict[adm_den_scores_key]) + cls.ADM2_CONSTANT) ) # vif_scalei = vif_num_scalei / vif_den_scalei, i = 0, 1, 2, 3 vif_num_scale0_scores_key = cls.get_scores_key('vif_num_scale0') vif_den_scale0_scores_key = cls.get_scores_key('vif_den_scale0') vif_num_scale1_scores_key = cls.get_scores_key('vif_num_scale1') vif_den_scale1_scores_key = cls.get_scores_key('vif_den_scale1') vif_num_scale2_scores_key = cls.get_scores_key('vif_num_scale2') vif_den_scale2_scores_key = cls.get_scores_key('vif_den_scale2') vif_num_scale3_scores_key = cls.get_scores_key('vif_num_scale3') vif_den_scale3_scores_key = cls.get_scores_key('vif_den_scale3') vif_scale0_scores_key = cls.get_scores_key('vif_scale0') vif_scale1_scores_key = cls.get_scores_key('vif_scale1') vif_scale2_scores_key = cls.get_scores_key('vif_scale2') vif_scale3_scores_key = cls.get_scores_key('vif_scale3') result.result_dict[vif_scale0_scores_key] = list( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) ) result.result_dict[vif_scale1_scores_key] = list( (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) ) result.result_dict[vif_scale2_scores_key] = list( (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) ) result.result_dict[vif_scale3_scores_key] = list( (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) # vif2 = # ((vif_num_scale0 / vif_den_scale0) + (vif_num_scale1 / vif_den_scale1) + # (vif_num_scale2 / vif_den_scale2) + (vif_num_scale3 / vif_den_scale3)) / 4.0 vif_scores_key = cls.get_scores_key('vif2') result.result_dict[vif_scores_key] = list( ( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) + (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) + (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) + (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) / 4.0 ) # adm_scalei = adm_num_scalei / adm_den_scalei, i = 0, 1, 2, 3 adm_num_scale0_scores_key = cls.get_scores_key('adm_num_scale0') adm_den_scale0_scores_key = cls.get_scores_key('adm_den_scale0') adm_num_scale1_scores_key = cls.get_scores_key('adm_num_scale1') adm_den_scale1_scores_key = cls.get_scores_key('adm_den_scale1') adm_num_scale2_scores_key = cls.get_scores_key('adm_num_scale2') adm_den_scale2_scores_key = cls.get_scores_key('adm_den_scale2') adm_num_scale3_scores_key = cls.get_scores_key('adm_num_scale3') adm_den_scale3_scores_key = cls.get_scores_key('adm_den_scale3') adm_scale0_scores_key = cls.get_scores_key('adm_scale0') adm_scale1_scores_key = cls.get_scores_key('adm_scale1') adm_scale2_scores_key = cls.get_scores_key('adm_scale2') adm_scale3_scores_key = cls.get_scores_key('adm_scale3') result.result_dict[adm_scale0_scores_key] = list( (np.array(result.result_dict[adm_num_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale1_scores_key] = list( (np.array(result.result_dict[adm_num_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale2_scores_key] = list( (np.array(result.result_dict[adm_num_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale3_scores_key] = list( (np.array(result.result_dict[adm_num_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) ) # adm3 = \ # (((adm_num_scale0 + ADM_SCALE_CONSTANT) / (adm_den_scale0 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale1 + ADM_SCALE_CONSTANT) / (adm_den_scale1 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale2 + ADM_SCALE_CONSTANT) / (adm_den_scale2 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale3 + ADM_SCALE_CONSTANT) / (adm_den_scale3 + ADM_SCALE_CONSTANT))) / 4.0 adm3_scores_key = cls.get_scores_key('adm3') result.result_dict[adm3_scores_key] = list( ( ((np.array(result.result_dict[adm_num_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT)) ) / 4.0 ) # validate for feature in cls.DERIVED_ATOM_FEATURES: assert cls.get_scores_key(feature) in result.result_dict return result class VifFrameDifferenceFeatureExtractor(FeatureExtractor): TYPE = "VifDiff_feature" VERSION = '0.1' ATOM_FEATURES = ['vifdiff', 'vifdiff_num', 'vifdiff_den', 'vifdiff_num_scale0', 'vifdiff_den_scale0', 'vifdiff_num_scale1', 'vifdiff_den_scale1', 'vifdiff_num_scale2', 'vifdiff_den_scale2', 'vifdiff_num_scale3', 'vifdiff_den_scale3', ] DERIVED_ATOM_FEATURES = ['vifdiff_scale0', 'vifdiff_scale1', 'vifdiff_scale2', 'vifdiff_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vifdiff_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VifFrameDifferenceFeatureExtractor, cls)._post_process_result(result) # vifdiff_scalei = vifdiff_num_scalei / vifdiff_den_scalei, i = 0, 1, 2, 3 vifdiff_num_scale0_scores_key = cls.get_scores_key('vifdiff_num_scale0') vifdiff_den_scale0_scores_key = cls.get_scores_key('vifdiff_den_scale0') vifdiff_num_scale1_scores_key = cls.get_scores_key('vifdiff_num_scale1') vifdiff_den_scale1_scores_key = cls.get_scores_key('vifdiff_den_scale1') vifdiff_num_scale2_scores_key = cls.get_scores_key('vifdiff_num_scale2') vifdiff_den_scale2_scores_key = cls.get_scores_key('vifdiff_den_scale2') vifdiff_num_scale3_scores_key = cls.get_scores_key('vifdiff_num_scale3') vifdiff_den_scale3_scores_key = cls.get_scores_key('vifdiff_den_scale3') vifdiff_scale0_scores_key = cls.get_scores_key('vifdiff_scale0') vifdiff_scale1_scores_key = cls.get_scores_key('vifdiff_scale1') vifdiff_scale2_scores_key = cls.get_scores_key('vifdiff_scale2') vifdiff_scale3_scores_key = cls.get_scores_key('vifdiff_scale3') result.result_dict[vifdiff_scale0_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale0_scores_key]) / np.array(result.result_dict[vifdiff_den_scale0_scores_key])) ) result.result_dict[vifdiff_scale1_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale1_scores_key]) / np.array(result.result_dict[vifdiff_den_scale1_scores_key])) ) result.result_dict[vifdiff_scale2_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale2_scores_key]) / np.array(result.result_dict[vifdiff_den_scale2_scores_key])) ) result.result_dict[vifdiff_scale3_scores_key] = list( (

np.array(result.result_dict[vifdiff_num_scale3_scores_key])

numpy.array

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] *

np.ones(101)

numpy.ones

import numpy as np import pytest import theano import theano.tensor as tt # Don't import test classes otherwise they get tested as part of the file from tests import unittest_tools as utt from tests.gpuarray.config import mode_with_gpu, mode_without_gpu, test_ctx_name from tests.tensor.test_basic import ( TestAlloc, TestComparison, TestJoinAndSplit, TestReshape, ) from tests.tensor.utils import rand, safe_make_node from theano.gpuarray.basic_ops import ( GpuAlloc, GpuAllocEmpty, GpuContiguous, GpuEye, GpuFromHost, GpuJoin, GpuReshape, GpuSplit, GpuToGpu, GpuTri, HostFromGpu, gpu_contiguous, gpu_join, host_from_gpu, ) from theano.gpuarray.elemwise import GpuDimShuffle, GpuElemwise from theano.gpuarray.subtensor import GpuSubtensor from theano.gpuarray.type import GpuArrayType, get_context, gpuarray_shared_constructor from theano.tensor import TensorType from theano.tensor.basic import alloc pygpu = pytest.importorskip("pygpu") gpuarray = pygpu.gpuarray utt.seed_rng() rng = np.random.RandomState(seed=utt.fetch_seed()) def inplace_func( inputs, outputs, mode=None, allow_input_downcast=False, on_unused_input="raise", name=None, ): if mode is None: mode = mode_with_gpu return theano.function( inputs, outputs, mode=mode, allow_input_downcast=allow_input_downcast, accept_inplace=True, on_unused_input=on_unused_input, name=name, ) def fake_shared(value, name=None, strict=False, allow_downcast=None, **kwargs): from theano.tensor.sharedvar import scalar_constructor, tensor_constructor for c in (gpuarray_shared_constructor, tensor_constructor, scalar_constructor): try: return c( value, name=name, strict=strict, allow_downcast=allow_downcast, **kwargs ) except TypeError: continue def rand_gpuarray(*shape, **kwargs): r = rng.rand(*shape) * 2 - 1 dtype = kwargs.pop("dtype", theano.config.floatX) cls = kwargs.pop("cls", None) if len(kwargs) != 0: raise TypeError("Unexpected argument %s", list(kwargs.keys())[0]) return gpuarray.array(r, dtype=dtype, cls=cls, context=get_context(test_ctx_name)) def makeTester( name, op, gpu_op, cases, checks=None, mode_gpu=mode_with_gpu, mode_nogpu=mode_without_gpu, skip=False, eps=1e-10, ): if checks is None: checks = {} _op = op _gpu_op = gpu_op _cases = cases _skip = skip _checks = checks class Checker(utt.OptimizationTestMixin): op = staticmethod(_op) gpu_op = staticmethod(_gpu_op) cases = _cases skip = _skip checks = _checks def setup_method(self): eval(self.__class__.__module__ + "." + self.__class__.__name__) def test_all(self): if skip: pytest.skip(skip) for testname, inputs in cases.items(): for _ in range(len(inputs)): if type(inputs[_]) is float: inputs[_] = np.asarray(inputs[_], dtype=theano.config.floatX) self.run_case(testname, inputs) def run_case(self, testname, inputs): inputs_ref = [theano.shared(inp) for inp in inputs] inputs_tst = [theano.shared(inp) for inp in inputs] try: node_ref = safe_make_node(self.op, *inputs_ref) node_tst = safe_make_node(self.op, *inputs_tst) except Exception as exc: err_msg = ( "Test %s::%s: Error occurred while making " "a node with inputs %s" ) % (self.gpu_op, testname, inputs) exc.args += (err_msg,) raise try: f_ref = inplace_func([], node_ref.outputs, mode=mode_nogpu) f_tst = inplace_func([], node_tst.outputs, mode=mode_gpu) except Exception as exc: err_msg = ( "Test %s::%s: Error occurred while trying to " "make a Function" ) % (self.gpu_op, testname) exc.args += (err_msg,) raise self.assertFunctionContains1(f_tst, self.gpu_op) ref_e = None try: expecteds = f_ref() except Exception as exc: ref_e = exc try: variables = f_tst() except Exception as exc: if ref_e is None: err_msg = ( "Test %s::%s: exception when calling the " "Function" ) % (self.gpu_op, testname) exc.args += (err_msg,) raise else: # if we raised an exception of the same type we're good. if isinstance(exc, type(ref_e)): return else: err_msg = ( "Test %s::%s: exception raised during test " "call was not the same as the reference " "call (got: %s, expected %s)" % (self.gpu_op, testname, type(exc), type(ref_e)) ) exc.args += (err_msg,) raise for i, (variable, expected) in enumerate(zip(variables, expecteds)): condition = ( variable.dtype != expected.dtype or variable.shape != expected.shape or not TensorType.values_eq_approx(variable, expected) ) assert not condition, ( "Test %s::%s: Output %s gave the wrong " "value. With inputs %s, expected %s " "(dtype %s), got %s (dtype %s)." % ( self.op, testname, i, inputs, expected, expected.dtype, variable, variable.dtype, ) ) for description, check in self.checks.items(): assert check(inputs, variables), ( "Test %s::%s: Failed check: %s " "(inputs were %s, ouputs were %s)" ) % (self.op, testname, description, inputs, variables) Checker.__name__ = name if hasattr(Checker, "__qualname__"): Checker.__qualname__ = name return Checker def test_transfer_cpu_gpu(): a = tt.fmatrix("a") g = GpuArrayType(dtype="float32", broadcastable=(False, False))("g") av = np.asarray(rng.rand(5, 4), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) f = theano.function([a], GpuFromHost(test_ctx_name)(a)) fv = f(av) assert GpuArrayType.values_eq(fv, gv) f = theano.function([g], host_from_gpu(g)) fv = f(gv) assert np.all(fv == av) def test_transfer_gpu_gpu(): g = GpuArrayType( dtype="float32", broadcastable=(False, False), context_name=test_ctx_name )() av = np.asarray(rng.rand(5, 4), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) mode = mode_with_gpu.excluding( "cut_gpua_host_transfers", "local_cut_gpua_host_gpua" ) f = theano.function([g], GpuToGpu(test_ctx_name)(g), mode=mode) topo = f.maker.fgraph.toposort() assert len(topo) == 1 assert isinstance(topo[0].op, GpuToGpu) fv = f(gv) assert GpuArrayType.values_eq(fv, gv) def test_transfer_strided(): # This is just to ensure that it works in theano # libgpuarray has a much more comprehensive suit of tests to # ensure correctness a = tt.fmatrix("a") g = GpuArrayType(dtype="float32", broadcastable=(False, False))("g") av = np.asarray(rng.rand(5, 8), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) av = av[:, ::2] gv = gv[:, ::2] f = theano.function([a], GpuFromHost(test_ctx_name)(a)) fv = f(av) assert GpuArrayType.values_eq(fv, gv) f = theano.function([g], host_from_gpu(g)) fv = f(gv) assert np.all(fv == av) def gpu_alloc_expected(x, *shp): g = gpuarray.empty(shp, dtype=x.dtype, context=get_context(test_ctx_name)) g[:] = x return g TestGpuAlloc = makeTester( name="GpuAllocTester", # The +1 is there to allow the lift to the GPU. op=lambda *args: alloc(*args) + 1, gpu_op=GpuAlloc(test_ctx_name), cases=dict( correct01=(rand(), np.int32(7)), # just gives a DeepCopyOp with possibly wrong results on the CPU # correct01_bcast=(rand(1), np.int32(7)), correct02=(rand(), np.int32(4), np.int32(7)), correct12=(rand(7), np.int32(4), np.int32(7)), correct13=(rand(7), np.int32(2), np.int32(4), np.int32(7)), correct23=(rand(4, 7),

np.int32(2)

numpy.int32

import numpy as np import pytest import theano import theano.tensor as tt # Don't import test classes otherwise they get tested as part of the file from tests import unittest_tools as utt from tests.gpuarray.config import mode_with_gpu, mode_without_gpu, test_ctx_name from tests.tensor.test_basic import ( TestAlloc, TestComparison, TestJoinAndSplit, TestReshape, ) from tests.tensor.utils import rand, safe_make_node from theano.gpuarray.basic_ops import ( GpuAlloc, GpuAllocEmpty, GpuContiguous, GpuEye, GpuFromHost, GpuJoin, GpuReshape, GpuSplit, GpuToGpu, GpuTri, HostFromGpu, gpu_contiguous, gpu_join, host_from_gpu, ) from theano.gpuarray.elemwise import GpuDimShuffle, GpuElemwise from theano.gpuarray.subtensor import GpuSubtensor from theano.gpuarray.type import GpuArrayType, get_context, gpuarray_shared_constructor from theano.tensor import TensorType from theano.tensor.basic import alloc pygpu = pytest.importorskip("pygpu") gpuarray = pygpu.gpuarray utt.seed_rng() rng = np.random.RandomState(seed=utt.fetch_seed()) def inplace_func( inputs, outputs, mode=None, allow_input_downcast=False, on_unused_input="raise", name=None, ): if mode is None: mode = mode_with_gpu return theano.function( inputs, outputs, mode=mode, allow_input_downcast=allow_input_downcast, accept_inplace=True, on_unused_input=on_unused_input, name=name, ) def fake_shared(value, name=None, strict=False, allow_downcast=None, **kwargs): from theano.tensor.sharedvar import scalar_constructor, tensor_constructor for c in (gpuarray_shared_constructor, tensor_constructor, scalar_constructor): try: return c( value, name=name, strict=strict, allow_downcast=allow_downcast, **kwargs ) except TypeError: continue def rand_gpuarray(*shape, **kwargs): r = rng.rand(*shape) * 2 - 1 dtype = kwargs.pop("dtype", theano.config.floatX) cls = kwargs.pop("cls", None) if len(kwargs) != 0: raise TypeError("Unexpected argument %s", list(kwargs.keys())[0]) return gpuarray.array(r, dtype=dtype, cls=cls, context=get_context(test_ctx_name)) def makeTester( name, op, gpu_op, cases, checks=None, mode_gpu=mode_with_gpu, mode_nogpu=mode_without_gpu, skip=False, eps=1e-10, ): if checks is None: checks = {} _op = op _gpu_op = gpu_op _cases = cases _skip = skip _checks = checks class Checker(utt.OptimizationTestMixin): op = staticmethod(_op) gpu_op = staticmethod(_gpu_op) cases = _cases skip = _skip checks = _checks def setup_method(self): eval(self.__class__.__module__ + "." + self.__class__.__name__) def test_all(self): if skip: pytest.skip(skip) for testname, inputs in cases.items(): for _ in range(len(inputs)): if type(inputs[_]) is float: inputs[_] = np.asarray(inputs[_], dtype=theano.config.floatX) self.run_case(testname, inputs) def run_case(self, testname, inputs): inputs_ref = [theano.shared(inp) for inp in inputs] inputs_tst = [theano.shared(inp) for inp in inputs] try: node_ref = safe_make_node(self.op, *inputs_ref) node_tst = safe_make_node(self.op, *inputs_tst) except Exception as exc: err_msg = ( "Test %s::%s: Error occurred while making " "a node with inputs %s" ) % (self.gpu_op, testname, inputs) exc.args += (err_msg,) raise try: f_ref = inplace_func([], node_ref.outputs, mode=mode_nogpu) f_tst = inplace_func([], node_tst.outputs, mode=mode_gpu) except Exception as exc: err_msg = ( "Test %s::%s: Error occurred while trying to " "make a Function" ) % (self.gpu_op, testname) exc.args += (err_msg,) raise self.assertFunctionContains1(f_tst, self.gpu_op) ref_e = None try: expecteds = f_ref() except Exception as exc: ref_e = exc try: variables = f_tst() except Exception as exc: if ref_e is None: err_msg = ( "Test %s::%s: exception when calling the " "Function" ) % (self.gpu_op, testname) exc.args += (err_msg,) raise else: # if we raised an exception of the same type we're good. if isinstance(exc, type(ref_e)): return else: err_msg = ( "Test %s::%s: exception raised during test " "call was not the same as the reference " "call (got: %s, expected %s)" % (self.gpu_op, testname, type(exc), type(ref_e)) ) exc.args += (err_msg,) raise for i, (variable, expected) in enumerate(zip(variables, expecteds)): condition = ( variable.dtype != expected.dtype or variable.shape != expected.shape or not TensorType.values_eq_approx(variable, expected) ) assert not condition, ( "Test %s::%s: Output %s gave the wrong " "value. With inputs %s, expected %s " "(dtype %s), got %s (dtype %s)." % ( self.op, testname, i, inputs, expected, expected.dtype, variable, variable.dtype, ) ) for description, check in self.checks.items(): assert check(inputs, variables), ( "Test %s::%s: Failed check: %s " "(inputs were %s, ouputs were %s)" ) % (self.op, testname, description, inputs, variables) Checker.__name__ = name if hasattr(Checker, "__qualname__"): Checker.__qualname__ = name return Checker def test_transfer_cpu_gpu(): a = tt.fmatrix("a") g = GpuArrayType(dtype="float32", broadcastable=(False, False))("g") av = np.asarray(rng.rand(5, 4), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) f = theano.function([a], GpuFromHost(test_ctx_name)(a)) fv = f(av) assert GpuArrayType.values_eq(fv, gv) f = theano.function([g], host_from_gpu(g)) fv = f(gv) assert np.all(fv == av) def test_transfer_gpu_gpu(): g = GpuArrayType( dtype="float32", broadcastable=(False, False), context_name=test_ctx_name )() av = np.asarray(rng.rand(5, 4), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) mode = mode_with_gpu.excluding( "cut_gpua_host_transfers", "local_cut_gpua_host_gpua" ) f = theano.function([g], GpuToGpu(test_ctx_name)(g), mode=mode) topo = f.maker.fgraph.toposort() assert len(topo) == 1 assert isinstance(topo[0].op, GpuToGpu) fv = f(gv) assert GpuArrayType.values_eq(fv, gv) def test_transfer_strided(): # This is just to ensure that it works in theano # libgpuarray has a much more comprehensive suit of tests to # ensure correctness a = tt.fmatrix("a") g = GpuArrayType(dtype="float32", broadcastable=(False, False))("g") av = np.asarray(rng.rand(5, 8), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) av = av[:, ::2] gv = gv[:, ::2] f = theano.function([a], GpuFromHost(test_ctx_name)(a)) fv = f(av) assert GpuArrayType.values_eq(fv, gv) f = theano.function([g], host_from_gpu(g)) fv = f(gv) assert np.all(fv == av) def gpu_alloc_expected(x, *shp): g = gpuarray.empty(shp, dtype=x.dtype, context=get_context(test_ctx_name)) g[:] = x return g TestGpuAlloc = makeTester( name="GpuAllocTester", # The +1 is there to allow the lift to the GPU. op=lambda *args: alloc(*args) + 1, gpu_op=GpuAlloc(test_ctx_name), cases=dict( correct01=(rand(), np.int32(7)), # just gives a DeepCopyOp with possibly wrong results on the CPU # correct01_bcast=(rand(1), np.int32(7)), correct02=(rand(), np.int32(4), np.int32(7)), correct12=(rand(7), np.int32(4),

np.int32(7)

numpy.int32

# pvtrace is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 3 of the License, or # (at your option) any later version. # # pvtrace is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see <http://www.gnu.org/licenses/>. import numpy as np from external.transformations import translation_matrix, rotation_matrix import external.transformations as tf from Trace import Photon from Geometry import Box, Cylinder, FinitePlane, transform_point, transform_direction, rotation_matrix_from_vector_alignment, norm from Materials import Spectrum def random_spherecial_vector(): # This method of calculating isotropic vectors is taken from GNU Scientific Library LOOP = True while LOOP: x = -1. + 2. * np.random.uniform() y = -1. + 2. * np.random.uniform() s = x**2 + y**2 if s <= 1.0: LOOP = False z = -1. + 2. * s a = 2 * np.sqrt(1 - s) x = a * x y = a * y return np.array([x,y,z]) class SimpleSource(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, use_random_polarisation=False): super(SimpleSource, self).__init__() self.position = position self.direction = direction self.wavelength = wavelength self.use_random_polarisation = use_random_polarisation self.throw = 0 self.source_id = "SimpleSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength # If use_polarisation is set generate a random polarisation vector of the photon if self.use_random_polarisation: # Randomise rotation angle around xy-plane, the transform from +z to the direction of the photon vec = random_spherecial_vector() vec[2] = 0. vec = norm(vec) R = rotation_matrix_from_vector_alignment(self.direction, [0,0,1]) photon.polarisation = transform_direction(vec, R) else: photon.polarisation = None photon.id = self.throw self.throw = self.throw + 1 return photon class Laser(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, polarisation=None): super(Laser, self).__init__() self.position = np.array(position) self.direction = np.array(direction) self.wavelength = wavelength assert polarisation != None, "Polarisation of the Laser is not set." self.polarisation = np.array(polarisation) self.throw = 0 self.source_id = "LaserSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength photon.polarisation = self.polarisation photon.id = self.throw self.throw = self.throw + 1 return photon class PlanarSource(object): """A box that emits photons from the top surface (normal), sampled from the spectrum.""" def __init__(self, spectrum=None, wavelength=555, direction=(0,0,1), length=0.05, width=0.05): super(PlanarSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.plane = FinitePlane(length=length, width=width) self.length = length self.width = width # direction is the direction that photons are fired out of the plane in the GLOBAL FRAME. # i.e. this is passed directly to the photon to set is's direction self.direction = direction self.throw = 0 self.source_id = "PlanarSource_" + str(id(self)) def translate(self, translation): self.plane.append_transform(tf.translation_matrix(translation)) def rotate(self, angle, axis): self.plane.append_transform(tf.rotation_matrix(angle, axis)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Create a point which is on the surface of the finite plane in it's local frame x = np.random.uniform(0., self.length) y = np.random.uniform(0., self.width) local_point = (x, y, 0.) # Transform the direciton photon.position = transform_point(local_point, self.plane.transform) photon.direction = self.direction photon.active = True if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class LensSource(object): """ A source where photons generated in a plane are focused on a line with space tolerance given by variable "focussize". The focus line should be perpendicular to the plane normal and aligned with the z-axis. """ def __init__(self, spectrum = None, wavelength = 555, linepoint=(0,0,0), linedirection=(0,0,1), focussize = 0, planeorigin = (-1,-1,-1), planeextent = (-1,1,1)): super(LensSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.planeorigin = planeorigin self.planeextent = planeextent self.linepoint = np.array(linepoint) self.linedirection = np.array(linedirection) self.focussize = focussize self.throw = 0 self.source_id = "LensSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Position x = np.random.uniform(self.planeorigin[0],self.planeextent[0]) y = np.random.uniform(self.planeorigin[1],self.planeextent[1]) z =

np.random.uniform(self.planeorigin[2],self.planeextent[2])

numpy.random.uniform

# pvtrace is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 3 of the License, or # (at your option) any later version. # # pvtrace is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see <http://www.gnu.org/licenses/>. import numpy as np from external.transformations import translation_matrix, rotation_matrix import external.transformations as tf from Trace import Photon from Geometry import Box, Cylinder, FinitePlane, transform_point, transform_direction, rotation_matrix_from_vector_alignment, norm from Materials import Spectrum def random_spherecial_vector(): # This method of calculating isotropic vectors is taken from GNU Scientific Library LOOP = True while LOOP: x = -1. + 2. * np.random.uniform() y = -1. + 2. * np.random.uniform() s = x**2 + y**2 if s <= 1.0: LOOP = False z = -1. + 2. * s a = 2 * np.sqrt(1 - s) x = a * x y = a * y return np.array([x,y,z]) class SimpleSource(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, use_random_polarisation=False): super(SimpleSource, self).__init__() self.position = position self.direction = direction self.wavelength = wavelength self.use_random_polarisation = use_random_polarisation self.throw = 0 self.source_id = "SimpleSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength # If use_polarisation is set generate a random polarisation vector of the photon if self.use_random_polarisation: # Randomise rotation angle around xy-plane, the transform from +z to the direction of the photon vec = random_spherecial_vector() vec[2] = 0. vec = norm(vec) R = rotation_matrix_from_vector_alignment(self.direction, [0,0,1]) photon.polarisation = transform_direction(vec, R) else: photon.polarisation = None photon.id = self.throw self.throw = self.throw + 1 return photon class Laser(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, polarisation=None): super(Laser, self).__init__() self.position = np.array(position) self.direction = np.array(direction) self.wavelength = wavelength assert polarisation != None, "Polarisation of the Laser is not set." self.polarisation = np.array(polarisation) self.throw = 0 self.source_id = "LaserSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength photon.polarisation = self.polarisation photon.id = self.throw self.throw = self.throw + 1 return photon class PlanarSource(object): """A box that emits photons from the top surface (normal), sampled from the spectrum.""" def __init__(self, spectrum=None, wavelength=555, direction=(0,0,1), length=0.05, width=0.05): super(PlanarSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.plane = FinitePlane(length=length, width=width) self.length = length self.width = width # direction is the direction that photons are fired out of the plane in the GLOBAL FRAME. # i.e. this is passed directly to the photon to set is's direction self.direction = direction self.throw = 0 self.source_id = "PlanarSource_" + str(id(self)) def translate(self, translation): self.plane.append_transform(tf.translation_matrix(translation)) def rotate(self, angle, axis): self.plane.append_transform(tf.rotation_matrix(angle, axis)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Create a point which is on the surface of the finite plane in it's local frame x = np.random.uniform(0., self.length) y = np.random.uniform(0., self.width) local_point = (x, y, 0.) # Transform the direciton photon.position = transform_point(local_point, self.plane.transform) photon.direction = self.direction photon.active = True if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class LensSource(object): """ A source where photons generated in a plane are focused on a line with space tolerance given by variable "focussize". The focus line should be perpendicular to the plane normal and aligned with the z-axis. """ def __init__(self, spectrum = None, wavelength = 555, linepoint=(0,0,0), linedirection=(0,0,1), focussize = 0, planeorigin = (-1,-1,-1), planeextent = (-1,1,1)): super(LensSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.planeorigin = planeorigin self.planeextent = planeextent self.linepoint = np.array(linepoint) self.linedirection = np.array(linedirection) self.focussize = focussize self.throw = 0 self.source_id = "LensSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Position x = np.random.uniform(self.planeorigin[0],self.planeextent[0]) y = np.random.uniform(self.planeorigin[1],self.planeextent[1]) z = np.random.uniform(self.planeorigin[2],self.planeextent[2]) photon.position = np.array((x,y,z)) # Direction focuspoint = np.array((0.,0.,0.)) focuspoint[0] = self.linepoint[0] + np.random.uniform(-self.focussize,self.focussize) focuspoint[1] = self.linepoint[1] + np.random.uniform(-self.focussize,self.focussize) focuspoint[2] = photon.position[2] direction = focuspoint - photon.position modulus = (direction[0]**2+direction[1]**2+direction[2]**2)**0.5 photon.direction = direction/modulus # Wavelength if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class LensSourceAngle(object): """ A source where photons generated in a plane are focused on a line with space tolerance given by variable "focussize". The focus line should be perpendicular to the plane normal and aligned with the z-axis. For this lense an additional z-boost is added (Angle of incidence in z-direction). """ def __init__(self, spectrum = None, wavelength = 555, linepoint=(0,0,0), linedirection=(0,0,1), angle = 0, focussize = 0, planeorigin = (-1,-1,-1), planeextent = (-1,1,1)): super(LensSourceAngle, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.planeorigin = planeorigin self.planeextent = planeextent self.linepoint = np.array(linepoint) self.linedirection = np.array(linedirection) self.focussize = focussize self.angle = angle self.throw = 0 self.source_id = "LensSourceAngle_" + str(id(self)) def photon(self): photon = Photon() photon.id = self.throw self.throw = self.throw + 1 # Position x = np.random.uniform(self.planeorigin[0],self.planeextent[0]) y = np.random.uniform(self.planeorigin[1],self.planeextent[1]) boost = y*np.tan(self.angle) z = np.random.uniform(self.planeorigin[2],self.planeextent[2]) - boost photon.position = np.array((x,y,z)) # Direction focuspoint = np.array((0.,0.,0.)) focuspoint[0] = self.linepoint[0] + np.random.uniform(-self.focussize,self.focussize) focuspoint[1] = self.linepoint[1] + np.random.uniform(-self.focussize,self.focussize) focuspoint[2] = photon.position[2] + boost direction = focuspoint - photon.position modulus = (direction[0]**2+direction[1]**2+direction[2]**2)**0.5 photon.direction = direction/modulus # Wavelength if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class CylindricalSource(object): """ A source for photons emitted in a random direction and position inside a cylinder(radius, length) """ def __init__(self, spectrum = None, wavelength = 555, radius = 1, length = 10): super(CylindricalSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.shape = Cylinder(radius = radius, length = length) self.radius = radius self.length = length self.throw = 0 self.source_id = "CylindricalSource_" + str(id(self)) def translate(self, translation): self.shape.append_transform(tf.translation_matrix(translation)) def rotate(self, angle, axis): self.shape.append_transform(tf.rotation_matrix(angle, axis)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Position of emission phi = np.random.uniform(0., 2*np.pi) r = np.random.uniform(0.,self.radius) x = r*np.cos(phi) y = r*np.sin(phi) z = np.random.uniform(0.,self.length) local_center = (x,y,z) photon.position = transform_point(local_center, self.shape.transform) # Direction of emission (no need to transform if meant to be isotropic) phi = np.random.uniform(0.,2*np.pi) theta = np.random.uniform(0.,np.pi) x = np.cos(phi)*np.sin(theta) y = np.sin(phi)*np.sin(theta) z = np.cos(theta) local_direction = (x,y,z) photon.direction = local_direction # Set wavelength of photon if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength # Further initialisation photon.active = True return photon class PointSource(object): """ A point source that emits randomly in solid angle specified by phimin, ..., thetamax """ def __init__(self, spectrum = None, wavelength = 555, center = (0.,0.,0.), phimin = 0, phimax = 2*np.pi, thetamin = 0, thetamax = np.pi): super(PointSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.center = center self.phimin = phimin self.phimax = phimax self.thetamin = thetamin self.thetamax = thetamax self.throw = 0 self.source_id = "PointSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 phi = np.random.uniform(self.phimin, self.phimax) theta =

np.random.uniform(self.thetamin, self.thetamax)

numpy.random.uniform

from __future__ import absolute_import from __future__ import division from __future__ import print_function import cntk as C import numpy as np from .common import floatx, epsilon, image_dim_ordering, image_data_format from collections import defaultdict from contextlib import contextmanager import warnings C.set_global_option('align_axis', 1) b_any = any dev = C.device.use_default_device() if dev.type() == 0: warnings.warn( 'CNTK backend warning: GPU is not detected. ' 'CNTK\'s CPU version is not fully optimized,' 'please run with GPU to get better performance.') # A learning phase is a bool tensor used to run Keras models in # either train mode (learning_phase == 1) or test mode (learning_phase == 0). # LEARNING_PHASE_PLACEHOLDER is the placeholder for dynamic learning phase _LEARNING_PHASE_PLACEHOLDER = C.constant(shape=(), dtype=np.float32, value=1.0, name='_keras_learning_phase') # static learning phase flag, if it is not 0 or 1, we will go with dynamic learning phase tensor. _LEARNING_PHASE = -1 _UID_PREFIXES = defaultdict(int) # cntk doesn't support gradient as symbolic op, to hook up with keras model, # we will create gradient as a constant placeholder, here use this global # map to keep the mapping from grad placeholder to parameter grad_parameter_dict = {} NAME_SCOPE_STACK = [] @contextmanager def name_scope(name): global NAME_SCOPE_STACK NAME_SCOPE_STACK.append(name) yield NAME_SCOPE_STACK.pop() def get_uid(prefix=''): _UID_PREFIXES[prefix] += 1 return _UID_PREFIXES[prefix] def learning_phase(): # If _LEARNING_PHASE is not 0 or 1, return dynamic learning phase tensor return _LEARNING_PHASE if _LEARNING_PHASE in {0, 1} else _LEARNING_PHASE_PLACEHOLDER def set_learning_phase(value): global _LEARNING_PHASE if value not in {0, 1}: raise ValueError('CNTK Backend: Set learning phase ' 'with value %s is not supported, ' 'expected 0 or 1.' % value) _LEARNING_PHASE = value def clear_session(): """Reset learning phase flag for cntk backend. """ global _LEARNING_PHASE global _LEARNING_PHASE_PLACEHOLDER _LEARNING_PHASE = -1 _LEARNING_PHASE_PLACEHOLDER.value = np.asarray(1.0) def in_train_phase(x, alt, training=None): global _LEARNING_PHASE if training is None: training = learning_phase() uses_learning_phase = True else: uses_learning_phase = False # CNTK currently don't support cond op, so here we use # element_select approach as workaround. It may have # perf issue, will resolve it later with cntk cond op. if callable(x) and isinstance(x, C.cntk_py.Function) is False: x = x() if callable(alt) and isinstance(alt, C.cntk_py.Function) is False: alt = alt() if training is True: x._uses_learning_phase = uses_learning_phase return x else: # if _LEARNING_PHASE is static if isinstance(training, int) or isinstance(training, bool): result = x if training == 1 or training is True else alt else: result = C.element_select(training, x, alt) result._uses_learning_phase = uses_learning_phase return result def in_test_phase(x, alt, training=None): return in_train_phase(alt, x, training=training) def _convert_string_dtype(dtype): # cntk only support float32 and float64 if dtype == 'float32': return np.float32 elif dtype == 'float64': return np.float64 else: # cntk only running with float, # try to cast to float to run the model return np.float32 def _convert_dtype_string(dtype): if dtype == np.float32: return 'float32' elif dtype == np.float64: return 'float64' else: raise ValueError('CNTK Backend: Unsupported dtype: %s. ' 'CNTK only supports float32 and ' 'float64.' % dtype) def variable(value, dtype=None, name=None, constraint=None): """Instantiates a variable and returns it. # Arguments value: Numpy array, initial value of the tensor. dtype: Tensor type. name: Optional name string for the tensor. constraint: Optional projection function to be applied to the variable after an optimizer update. # Returns A variable instance (with Keras metadata included). """ if dtype is None: dtype = floatx() if name is None: name = '' if isinstance( value, C.variables.Constant) or isinstance( value, C.variables.Parameter): value = value.value # we don't support init parameter with symbolic op, so eval it first as # workaround if isinstance(value, C.cntk_py.Function): value = eval(value) shape = value.shape if hasattr(value, 'shape') else () if hasattr(value, 'dtype') and value.dtype != dtype and len(shape) > 0: value = value.astype(dtype) # TODO: remove the conversion when cntk supports int32, int64 # https://docs.microsoft.com/en-us/python/api/cntk.variables.parameter dtype = 'float32' if 'int' in str(dtype) else dtype v = C.parameter(shape=shape, init=value, dtype=dtype, name=_prepare_name(name, 'variable')) v._keras_shape = v.shape v._uses_learning_phase = False v.constraint = constraint return v def bias_add(x, bias, data_format=None): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) dims = len(x.shape) if dims > 0 and x.shape[0] == C.InferredDimension: dims -= 1 bias_dims = len(bias.shape) if bias_dims != 1 and bias_dims != dims: raise ValueError('Unexpected bias dimensions %d, ' 'expected 1 or %d dimensions' % (bias_dims, dims)) if dims == 4: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1, 1, 1) else: shape = (bias.shape[3],) + bias.shape[:3] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, 1, 1, bias.shape[0]) else: shape = bias.shape elif dims == 3: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1, 1) else: shape = (bias.shape[2],) + bias.shape[:2] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, 1, bias.shape[0]) else: shape = bias.shape elif dims == 2: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1) else: shape = (bias.shape[1],) + bias.shape[:1] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, bias.shape[0]) else: shape = bias.shape else: shape = bias.shape return x + reshape(bias, shape) def eval(x): if isinstance(x, C.cntk_py.Function): return x.eval() elif isinstance(x, C.variables.Constant) or isinstance(x, C.variables.Parameter): return x.value else: raise ValueError('CNTK Backend: `eval` method on ' '`%s` type is not supported. ' 'CNTK only supports `eval` with ' '`Function`, `Constant` or ' '`Parameter`.' % type(x)) def placeholder( shape=None, ndim=None, dtype=None, sparse=False, name=None, dynamic_axis_num=1): if dtype is None: dtype = floatx() if not shape: if ndim: shape = tuple([None for _ in range(ndim)]) dynamic_dimension = C.FreeDimension if _get_cntk_version() >= 2.2 else C.InferredDimension cntk_shape = [dynamic_dimension if s is None else s for s in shape] cntk_shape = tuple(cntk_shape) if dynamic_axis_num > len(cntk_shape): raise ValueError('CNTK backend: creating placeholder with ' '%d dimension is not supported, at least ' '%d dimensions are needed.' % (len(cntk_shape, dynamic_axis_num))) if name is None: name = '' cntk_shape = cntk_shape[dynamic_axis_num:] x = C.input( shape=cntk_shape, dtype=_convert_string_dtype(dtype), is_sparse=sparse, name=name) x._keras_shape = shape x._uses_learning_phase = False x._cntk_placeholder = True return x def is_placeholder(x): """Returns whether `x` is a placeholder. # Arguments x: A candidate placeholder. # Returns Boolean. """ return hasattr(x, '_cntk_placeholder') and x._cntk_placeholder def is_keras_tensor(x): if not is_tensor(x): raise ValueError('Unexpectedly found an instance of type `' + str(type(x)) + '`. ' 'Expected a symbolic tensor instance.') return hasattr(x, '_keras_history') def is_tensor(x): return isinstance(x, (C.variables.Constant, C.variables.Variable, C.variables.Parameter, C.ops.functions.Function)) def shape(x): shape = list(int_shape(x)) num_dynamic = _get_dynamic_axis_num(x) non_dyn_shape = [] for i in range(len(x.shape)): if shape[i + num_dynamic] is None: non_dyn_shape.append(x.shape[i]) else: non_dyn_shape.append(shape[i + num_dynamic]) return shape[:num_dynamic] + non_dyn_shape def is_sparse(tensor): return tensor.is_sparse def int_shape(x): if hasattr(x, '_keras_shape'): return x._keras_shape shape = x.shape if hasattr(x, 'dynamic_axes'): dynamic_shape = [None for a in x.dynamic_axes] shape = tuple(dynamic_shape) + shape return shape def ndim(x): shape = int_shape(x) return len(shape) def _prepare_name(name, default): prefix = '_'.join(NAME_SCOPE_STACK) if name is None or name == '': return prefix + '/' + default return prefix + '/' + name def constant(value, dtype=None, shape=None, name=None): if dtype is None: dtype = floatx() if shape is None: shape = () np_value = value * np.ones(shape) const = C.constant(np_value, dtype=dtype, name=_prepare_name(name, 'constant')) const._keras_shape = const.shape const._uses_learning_phase = False return const def random_binomial(shape, p=0.0, dtype=None, seed=None): # use numpy workaround now if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed = np.random.randint(10e7) np.random.seed(seed) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) size = 1 for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') size *= _ binomial = np.random.binomial(1, p, size).astype(dtype).reshape(shape) return variable(value=binomial, dtype=dtype) def random_uniform(shape, minval=0.0, maxval=1.0, dtype=None, seed=None): for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') return random_uniform_variable(shape, minval, maxval, dtype, seed) def random_uniform_variable(shape, low, high, dtype=None, name=None, seed=None): if dtype is None: dtype = floatx() if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed =

np.random.randint(10e3)

numpy.random.randint

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series =

np.sin(knot_demonstrate_time)

numpy.sin

import pandas as pd import numpy as np import matplotlib.pyplot as plt import os import matplotlib.pyplot as plt import CurveFit import shutil #find all DIRECTORIES containing non-hidden files ending in FILENAME def getDataDirectories(DIRECTORY, FILENAME="valLoss.txt"): directories=[] for directory in os.scandir(DIRECTORY): for item in os.scandir(directory): if item.name.endswith(FILENAME) and not item.name.startswith("."): directories.append(directory.path) return directories #get all non-hidden data files in DIRECTORY with extension EXT def getDataFiles(DIRECTORY, EXT='txt'): datafiles=[] for item in os.scandir(DIRECTORY): if item.name.endswith("."+EXT) and not item.name.startswith("."): datafiles.append(item.path) return datafiles #checking if loss ever doesn't decrease for numEpochs epochs in a row. def stopsDecreasing(loss, epoch, numEpochs): minLoss=np.inf epochMin=0 for i in range(0,loss.size): if loss[i] < minLoss: minLoss=loss[i] epochMin=epoch[i] elif (epoch[i]-epochMin) >= numEpochs: return i, minLoss return i, minLoss #dirpath is where the accuracy and loss files are stored. want to move the files into the same format expected by grabNNData. def createFolders(SEARCHDIR, SAVEDIR): for item in os.scandir(SEARCHDIR): name=str(item.name) files=name.split('-') SAVEFULLDIR=SAVEDIR+str(files[0]) if not os.path.exists(SAVEFULLDIR): try: os.makedirs(SAVEFULLDIR) except FileExistsError: #directory already exists--must have been created between the if statement & our attempt at making directory pass shutil.move(item.path, SAVEFULLDIR+"/"+str(files[1])) #a function to read in information (e.g. accuracy, loss) stored at FILENAME def grabNNData(FILENAME, header='infer', sep=' '): data = pd.read_csv(FILENAME, sep, header=header) if ('epochs' in data.columns) and ('trainLoss' in data.columns) and ('valLoss' in data.columns) and ('valAcc' in data.columns) and ('batch_size' in data.columns) and ('learning_rate' in data.columns): sortedData=data.sort_values(by="epochs", axis=0, ascending=True) epoch=np.array(sortedData['epochs']) trainLoss=np.array(sortedData['trainLoss']) valLoss=np.array(sortedData['valLoss']) valAcc=np.array(sortedData['valAcc']) batch_size=np.array(sortedData['batch_size']) learning_rate=np.array(sortedData['learning_rate']) convKers=np.array(sortedData['convKernels']) return(epoch, trainLoss, valLoss, valAcc, batch_size, learning_rate, convKers) elif ('epochs' in data.columns) and ('trainLoss' in data.columns) and ('valLoss' in data.columns) and ('valAcc' in data.columns): sortedData=data.sort_values(by="epochs", axis=0, ascending=True) epoch=np.array(sortedData['epochs']) trainLoss=

np.array(sortedData['trainLoss'])

numpy.array

""" YTArray class. """ from __future__ import print_function #----------------------------------------------------------------------------- # Copyright (c) 2013, yt Development Team. # # Distributed under the terms of the Modified BSD License. # # The full license is in the file COPYING.txt, distributed with this software. #----------------------------------------------------------------------------- import copy import numpy as np from distutils.version import LooseVersion from functools import wraps from numpy import \ add, subtract, multiply, divide, logaddexp, logaddexp2, true_divide, \ floor_divide, negative, power, remainder, mod, absolute, rint, \ sign, conj, exp, exp2, log, log2, log10, expm1, log1p, sqrt, square, \ reciprocal, sin, cos, tan, arcsin, arccos, arctan, arctan2, \ hypot, sinh, cosh, tanh, arcsinh, arccosh, arctanh, deg2rad, rad2deg, \ bitwise_and, bitwise_or, bitwise_xor, invert, left_shift, right_shift, \ greater, greater_equal, less, less_equal, not_equal, equal, logical_and, \ logical_or, logical_xor, logical_not, maximum, minimum, fmax, fmin, \ isreal, iscomplex, isfinite, isinf, isnan, signbit, copysign, nextafter, \ modf, ldexp, frexp, fmod, floor, ceil, trunc, fabs, spacing try: # numpy 1.13 or newer from numpy import positive, divmod as divmod_, isnat, heaviside except ImportError: positive, divmod_, isnat, heaviside = (None,)*4 from yt.units.unit_object import Unit, UnitParseError from yt.units.unit_registry import UnitRegistry from yt.units.dimensions import \ angle, \ current_mks, \ dimensionless, \ em_dimensions from yt.utilities.exceptions import \ YTUnitOperationError, YTUnitConversionError, \ YTUfuncUnitError, YTIterableUnitCoercionError, \ YTInvalidUnitEquivalence, YTEquivalentDimsError from yt.utilities.lru_cache import lru_cache from numbers import Number as numeric_type from yt.utilities.on_demand_imports import _astropy from sympy import Rational from yt.units.unit_lookup_table import \ default_unit_symbol_lut from yt.units.equivalencies import equivalence_registry from yt.utilities.logger import ytLogger as mylog from .pint_conversions import convert_pint_units NULL_UNIT = Unit() POWER_SIGN_MAPPING = {multiply: 1, divide: -1} # redefine this here to avoid a circular import from yt.funcs def iterable(obj): try: len(obj) except: return False return True def return_arr(func): @wraps(func) def wrapped(*args, **kwargs): ret, units = func(*args, **kwargs) if ret.shape == (): return YTQuantity(ret, units) else: # This could be a subclass, so don't call YTArray directly. return type(args[0])(ret, units) return wrapped @lru_cache(maxsize=128, typed=False) def sqrt_unit(unit): return unit**0.5 @lru_cache(maxsize=128, typed=False) def multiply_units(unit1, unit2): return unit1 * unit2 def preserve_units(unit1, unit2=None): return unit1 @lru_cache(maxsize=128, typed=False) def power_unit(unit, power): return unit**power @lru_cache(maxsize=128, typed=False) def square_unit(unit): return unit*unit @lru_cache(maxsize=128, typed=False) def divide_units(unit1, unit2): return unit1/unit2 @lru_cache(maxsize=128, typed=False) def reciprocal_unit(unit): return unit**-1 def passthrough_unit(unit, unit2=None): return unit def return_without_unit(unit, unit2=None): return None def arctan2_unit(unit1, unit2): return NULL_UNIT def comparison_unit(unit1, unit2=None): return None def invert_units(unit): raise TypeError( "Bit-twiddling operators are not defined for YTArray instances") def bitop_units(unit1, unit2): raise TypeError( "Bit-twiddling operators are not defined for YTArray instances") def get_inp_u_unary(ufunc, inputs, out_arr=None): inp = inputs[0] u = getattr(inp, 'units', None) if u is None: u = NULL_UNIT if u.dimensions is angle and ufunc in trigonometric_operators: inp = inp.in_units('radian').v if out_arr is not None: out_arr = ufunc(inp).view(np.ndarray) return out_arr, inp, u def get_inp_u_binary(ufunc, inputs): inp1 = coerce_iterable_units(inputs[0]) inp2 = coerce_iterable_units(inputs[1]) unit1 = getattr(inp1, 'units', None) unit2 = getattr(inp2, 'units', None) ret_class = get_binary_op_return_class(type(inp1), type(inp2)) if unit1 is None: unit1 = Unit(registry=getattr(unit2, 'registry', None)) if unit2 is None and ufunc is not power: unit2 = Unit(registry=getattr(unit1, 'registry', None)) elif ufunc is power: unit2 = inp2 if isinstance(unit2, np.ndarray): if isinstance(unit2, YTArray): if unit2.units.is_dimensionless: pass else: raise YTUnitOperationError(ufunc, unit1, unit2) unit2 = 1.0 return (inp1, inp2), (unit1, unit2), ret_class def handle_preserve_units(inps, units, ufunc, ret_class): if units[0] != units[1]: any_nonzero = [np.any(inps[0]), np.any(inps[1])] if any_nonzero[0] == np.bool_(False): units = (units[1], units[1]) elif any_nonzero[1] == np.bool_(False): units = (units[0], units[0]) else: if not units[0].same_dimensions_as(units[1]): raise YTUnitOperationError(ufunc, *units) inps = (inps[0], ret_class(inps[1]).to( ret_class(inps[0]).units)) return inps, units def handle_comparison_units(inps, units, ufunc, ret_class, raise_error=False): if units[0] != units[1]: u1d = units[0].is_dimensionless u2d = units[1].is_dimensionless any_nonzero = [np.any(inps[0]), np.any(inps[1])] if any_nonzero[0] == np.bool_(False): units = (units[1], units[1]) elif any_nonzero[1] == np.bool_(False): units = (units[0], units[0]) elif not any([u1d, u2d]): if not units[0].same_dimensions_as(units[1]): raise YTUnitOperationError(ufunc, *units) else: if raise_error: raise YTUfuncUnitError(ufunc, *units) inps = (inps[0], ret_class(inps[1]).to( ret_class(inps[0]).units)) return inps, units def handle_multiply_divide_units(unit, units, out, out_arr): if unit.is_dimensionless and unit.base_value != 1.0: if not units[0].is_dimensionless: if units[0].dimensions == units[1].dimensions: out_arr = np.multiply(out_arr.view(np.ndarray), unit.base_value, out=out) unit = Unit(registry=unit.registry) return out, out_arr, unit def coerce_iterable_units(input_object): if isinstance(input_object, np.ndarray): return input_object if iterable(input_object): if any([isinstance(o, YTArray) for o in input_object]): ff = getattr(input_object[0], 'units', NULL_UNIT, ) if any([ff != getattr(_, 'units', NULL_UNIT) for _ in input_object]): raise YTIterableUnitCoercionError(input_object) # This will create a copy of the data in the iterable. return YTArray(input_object) return input_object else: return input_object def sanitize_units_mul(this_object, other_object): inp = coerce_iterable_units(this_object) ret = coerce_iterable_units(other_object) # If the other object is a YTArray and has the same dimensions as the object # under consideration, convert so we don't mix units with the same # dimensions. if isinstance(ret, YTArray): if inp.units.same_dimensions_as(ret.units): ret.in_units(inp.units) return ret def sanitize_units_add(this_object, other_object, op_string): inp = coerce_iterable_units(this_object) ret = coerce_iterable_units(other_object) # Make sure the other object is a YTArray before we use the `units` # attribute. if isinstance(ret, YTArray): if not inp.units.same_dimensions_as(ret.units): # handle special case of adding or subtracting with zero or # array filled with zero if not np.any(other_object): return ret.view(np.ndarray) elif not np.any(this_object): return ret raise YTUnitOperationError(op_string, inp.units, ret.units) ret = ret.in_units(inp.units) else: # If the other object is not a YTArray, then one of the arrays must be # dimensionless or filled with zeros if not inp.units.is_dimensionless and np.any(ret): raise YTUnitOperationError(op_string, inp.units, dimensionless) return ret def validate_comparison_units(this, other, op_string): # Check that other is a YTArray. if hasattr(other, 'units'): if this.units.expr is other.units.expr: if this.units.base_value == other.units.base_value: return other if not this.units.same_dimensions_as(other.units): raise YTUnitOperationError(op_string, this.units, other.units) return other.in_units(this.units) return other @lru_cache(maxsize=128, typed=False) def _unit_repr_check_same(my_units, other_units): """ Takes a Unit object, or string of known unit symbol, and check that it is compatible with this quantity. Returns Unit object. """ # let Unit() handle units arg if it's not already a Unit obj. if not isinstance(other_units, Unit): other_units = Unit(other_units, registry=my_units.registry) equiv_dims = em_dimensions.get(my_units.dimensions, None) if equiv_dims == other_units.dimensions: if current_mks in equiv_dims.free_symbols: base = "SI" else: base = "CGS" raise YTEquivalentDimsError(my_units, other_units, base) if not my_units.same_dimensions_as(other_units): raise YTUnitConversionError( my_units, my_units.dimensions, other_units, other_units.dimensions) return other_units unary_operators = ( negative, absolute, rint, sign, conj, exp, exp2, log, log2, log10, expm1, log1p, sqrt, square, reciprocal, sin, cos, tan, arcsin, arccos, arctan, sinh, cosh, tanh, arcsinh, arccosh, arctanh, deg2rad, rad2deg, invert, logical_not, isreal, iscomplex, isfinite, isinf, isnan, signbit, floor, ceil, trunc, modf, frexp, fabs, spacing, positive, isnat, ) binary_operators = ( add, subtract, multiply, divide, logaddexp, logaddexp2, true_divide, power, remainder, mod, arctan2, hypot, bitwise_and, bitwise_or, bitwise_xor, left_shift, right_shift, greater, greater_equal, less, less_equal, not_equal, equal, logical_and, logical_or, logical_xor, maximum, minimum, fmax, fmin, copysign, nextafter, ldexp, fmod, divmod_, heaviside ) trigonometric_operators = ( sin, cos, tan, ) class YTArray(np.ndarray): """ An ndarray subclass that attaches a symbolic unit object to the array data. Parameters ---------- input_array : :obj:`!iterable` A tuple, list, or array to attach units to input_units : String unit specification, unit symbol object, or astropy units The units of the array. Powers must be specified using python syntax (cm**3, not cm^3). registry : ~yt.units.unit_registry.UnitRegistry The registry to create units from. If input_units is already associated with a unit registry and this is specified, this will be used instead of the registry associated with the unit object. dtype : data-type The dtype of the array data. Defaults to the dtype of the input data, or, if none is found, uses np.float64 bypass_validation : boolean If True, all input validation is skipped. Using this option may produce corrupted, invalid units or array data, but can lead to significant speedups in the input validation logic adds significant overhead. If set, input_units *must* be a valid unit object. Defaults to False. Examples -------- >>> from yt import YTArray >>> a = YTArray([1, 2, 3], 'cm') >>> b = YTArray([4, 5, 6], 'm') >>> a + b YTArray([ 401., 502., 603.]) cm >>> b + a YTArray([ 4.01, 5.02, 6.03]) m NumPy ufuncs will pass through units where appropriate. >>> import numpy as np >>> a = YTArray(np.arange(8) - 4, 'g/cm**3') >>> np.abs(a) YTArray([4, 3, 2, 1, 0, 1, 2, 3]) g/cm**3 and strip them when it would be annoying to deal with them. >>> np.log10(a) array([ -inf, 0. , 0.30103 , 0.47712125, 0.60205999, 0.69897 , 0.77815125, 0.84509804]) YTArray is tightly integrated with yt datasets: >>> import yt >>> ds = yt.load('IsolatedGalaxy/galaxy0030/galaxy0030') >>> a = ds.arr(np.ones(5), 'code_length') >>> a.in_cgs() YTArray([ 3.08600000e+24, 3.08600000e+24, 3.08600000e+24, 3.08600000e+24, 3.08600000e+24]) cm This is equivalent to: >>> b = YTArray(np.ones(5), 'code_length', registry=ds.unit_registry) >>> np.all(a == b) True """ _ufunc_registry = { add: preserve_units, subtract: preserve_units, multiply: multiply_units, divide: divide_units, logaddexp: return_without_unit, logaddexp2: return_without_unit, true_divide: divide_units, floor_divide: divide_units, negative: passthrough_unit, power: power_unit, remainder: preserve_units, mod: preserve_units, fmod: preserve_units, absolute: passthrough_unit, fabs: passthrough_unit, rint: return_without_unit, sign: return_without_unit, conj: passthrough_unit, exp: return_without_unit, exp2: return_without_unit, log: return_without_unit, log2: return_without_unit, log10: return_without_unit, expm1: return_without_unit, log1p: return_without_unit, sqrt: sqrt_unit, square: square_unit, reciprocal: reciprocal_unit, sin: return_without_unit, cos: return_without_unit, tan: return_without_unit, sinh: return_without_unit, cosh: return_without_unit, tanh: return_without_unit, arcsin: return_without_unit, arccos: return_without_unit, arctan: return_without_unit, arctan2: arctan2_unit, arcsinh: return_without_unit, arccosh: return_without_unit, arctanh: return_without_unit, hypot: preserve_units, deg2rad: return_without_unit, rad2deg: return_without_unit, bitwise_and: bitop_units, bitwise_or: bitop_units, bitwise_xor: bitop_units, invert: invert_units, left_shift: bitop_units, right_shift: bitop_units, greater: comparison_unit, greater_equal: comparison_unit, less: comparison_unit, less_equal: comparison_unit, not_equal: comparison_unit, equal: comparison_unit, logical_and: comparison_unit, logical_or: comparison_unit, logical_xor: comparison_unit, logical_not: return_without_unit, maximum: preserve_units, minimum: preserve_units, fmax: preserve_units, fmin: preserve_units, isreal: return_without_unit, iscomplex: return_without_unit, isfinite: return_without_unit, isinf: return_without_unit, isnan: return_without_unit, signbit: return_without_unit, copysign: passthrough_unit, nextafter: preserve_units, modf: passthrough_unit, ldexp: bitop_units, frexp: return_without_unit, floor: passthrough_unit, ceil: passthrough_unit, trunc: passthrough_unit, spacing: passthrough_unit, positive: passthrough_unit, divmod_: passthrough_unit, isnat: return_without_unit, heaviside: preserve_units, } __array_priority__ = 2.0 def __new__(cls, input_array, input_units=None, registry=None, dtype=None, bypass_validation=False): if dtype is None: dtype = getattr(input_array, 'dtype', np.float64) if bypass_validation is True: obj = np.asarray(input_array, dtype=dtype).view(cls) obj.units = input_units if registry is not None: obj.units.registry = registry return obj if input_array is NotImplemented: return input_array.view(cls) if registry is None and isinstance(input_units, (str, bytes)): if input_units.startswith('code_'): raise UnitParseError( "Code units used without referring to a dataset. \n" "Perhaps you meant to do something like this instead: \n" "ds.arr(%s, \"%s\")" % (input_array, input_units) ) if isinstance(input_array, YTArray): ret = input_array.view(cls) if input_units is None: if registry is None: ret.units = input_array.units else: units = Unit(str(input_array.units), registry=registry) ret.units = units elif isinstance(input_units, Unit): ret.units = input_units else: ret.units = Unit(input_units, registry=registry) return ret elif isinstance(input_array, np.ndarray): pass elif iterable(input_array) and input_array: if isinstance(input_array[0], YTArray): return YTArray(np.array(input_array, dtype=dtype), input_array[0].units, registry=registry) # Input array is an already formed ndarray instance # We first cast to be our class type obj = np.asarray(input_array, dtype=dtype).view(cls) # Check units type if input_units is None: # Nothing provided. Make dimensionless... units = Unit() elif isinstance(input_units, Unit): if registry and registry is not input_units.registry: units = Unit(str(input_units), registry=registry) else: units = input_units else: # units kwarg set, but it's not a Unit object. # don't handle all the cases here, let the Unit class handle if # it's a str. units = Unit(input_units, registry=registry) # Attach the units obj.units = units return obj def __repr__(self): """ """ return super(YTArray, self).__repr__()+' '+self.units.__repr__() def __str__(self): """ """ return str(self.view(np.ndarray)) + ' ' + str(self.units) # # Start unit conversion methods # def convert_to_units(self, units): """ Convert the array and units to the given units. Parameters ---------- units : Unit object or str The units you want to convert to. """ new_units = _unit_repr_check_same(self.units, units) (conversion_factor, offset) = self.units.get_conversion_factor(new_units) self.units = new_units values = self.d values *= conversion_factor if offset:

np.subtract(self, offset*self.uq, self)

numpy.subtract

import numpy as np from typing import Tuple, Union, Optional from autoarray.structures.arrays.two_d import array_2d_util from autoarray.geometry import geometry_util from autoarray import numba_util from autoarray.mask import mask_2d_util @numba_util.jit() def grid_2d_centre_from(grid_2d_slim: np.ndarray) -> Tuple[float, float]: """ Returns the centre of a grid from a 1D grid. Parameters ---------- grid_2d_slim The 1D grid of values which are mapped to a 2D array. Returns ------- (float, float) The (y,x) central coordinates of the grid. """ centre_y = (

np.max(grid_2d_slim[:, 0])

numpy.max

import numpy as np import pytest import theano import theano.tensor as tt # Don't import test classes otherwise they get tested as part of the file from tests import unittest_tools as utt from tests.gpuarray.config import mode_with_gpu, mode_without_gpu, test_ctx_name from tests.tensor.test_basic import ( TestAlloc, TestComparison, TestJoinAndSplit, TestReshape, ) from tests.tensor.utils import rand, safe_make_node from theano.gpuarray.basic_ops import ( GpuAlloc, GpuAllocEmpty, GpuContiguous, GpuEye, GpuFromHost, GpuJoin, GpuReshape, GpuSplit, GpuToGpu, GpuTri, HostFromGpu, gpu_contiguous, gpu_join, host_from_gpu, ) from theano.gpuarray.elemwise import GpuDimShuffle, GpuElemwise from theano.gpuarray.subtensor import GpuSubtensor from theano.gpuarray.type import GpuArrayType, get_context, gpuarray_shared_constructor from theano.tensor import TensorType from theano.tensor.basic import alloc pygpu = pytest.importorskip("pygpu") gpuarray = pygpu.gpuarray utt.seed_rng() rng = np.random.RandomState(seed=utt.fetch_seed()) def inplace_func( inputs, outputs, mode=None, allow_input_downcast=False, on_unused_input="raise", name=None, ): if mode is None: mode = mode_with_gpu return theano.function( inputs, outputs, mode=mode, allow_input_downcast=allow_input_downcast, accept_inplace=True, on_unused_input=on_unused_input, name=name, ) def fake_shared(value, name=None, strict=False, allow_downcast=None, **kwargs): from theano.tensor.sharedvar import scalar_constructor, tensor_constructor for c in (gpuarray_shared_constructor, tensor_constructor, scalar_constructor): try: return c( value, name=name, strict=strict, allow_downcast=allow_downcast, **kwargs ) except TypeError: continue def rand_gpuarray(*shape, **kwargs): r = rng.rand(*shape) * 2 - 1 dtype = kwargs.pop("dtype", theano.config.floatX) cls = kwargs.pop("cls", None) if len(kwargs) != 0: raise TypeError("Unexpected argument %s", list(kwargs.keys())[0]) return gpuarray.array(r, dtype=dtype, cls=cls, context=get_context(test_ctx_name)) def makeTester( name, op, gpu_op, cases, checks=None, mode_gpu=mode_with_gpu, mode_nogpu=mode_without_gpu, skip=False, eps=1e-10, ): if checks is None: checks = {} _op = op _gpu_op = gpu_op _cases = cases _skip = skip _checks = checks class Checker(utt.OptimizationTestMixin): op = staticmethod(_op) gpu_op = staticmethod(_gpu_op) cases = _cases skip = _skip checks = _checks def setup_method(self): eval(self.__class__.__module__ + "." + self.__class__.__name__) def test_all(self): if skip: pytest.skip(skip) for testname, inputs in cases.items(): for _ in range(len(inputs)): if type(inputs[_]) is float: inputs[_] = np.asarray(inputs[_], dtype=theano.config.floatX) self.run_case(testname, inputs) def run_case(self, testname, inputs): inputs_ref = [theano.shared(inp) for inp in inputs] inputs_tst = [theano.shared(inp) for inp in inputs] try: node_ref = safe_make_node(self.op, *inputs_ref) node_tst = safe_make_node(self.op, *inputs_tst) except Exception as exc: err_msg = ( "Test %s::%s: Error occurred while making " "a node with inputs %s" ) % (self.gpu_op, testname, inputs) exc.args += (err_msg,) raise try: f_ref = inplace_func([], node_ref.outputs, mode=mode_nogpu) f_tst = inplace_func([], node_tst.outputs, mode=mode_gpu) except Exception as exc: err_msg = ( "Test %s::%s: Error occurred while trying to " "make a Function" ) % (self.gpu_op, testname) exc.args += (err_msg,) raise self.assertFunctionContains1(f_tst, self.gpu_op) ref_e = None try: expecteds = f_ref() except Exception as exc: ref_e = exc try: variables = f_tst() except Exception as exc: if ref_e is None: err_msg = ( "Test %s::%s: exception when calling the " "Function" ) % (self.gpu_op, testname) exc.args += (err_msg,) raise else: # if we raised an exception of the same type we're good. if isinstance(exc, type(ref_e)): return else: err_msg = ( "Test %s::%s: exception raised during test " "call was not the same as the reference " "call (got: %s, expected %s)" % (self.gpu_op, testname, type(exc), type(ref_e)) ) exc.args += (err_msg,) raise for i, (variable, expected) in enumerate(zip(variables, expecteds)): condition = ( variable.dtype != expected.dtype or variable.shape != expected.shape or not TensorType.values_eq_approx(variable, expected) ) assert not condition, ( "Test %s::%s: Output %s gave the wrong " "value. With inputs %s, expected %s " "(dtype %s), got %s (dtype %s)." % ( self.op, testname, i, inputs, expected, expected.dtype, variable, variable.dtype, ) ) for description, check in self.checks.items(): assert check(inputs, variables), ( "Test %s::%s: Failed check: %s " "(inputs were %s, ouputs were %s)" ) % (self.op, testname, description, inputs, variables) Checker.__name__ = name if hasattr(Checker, "__qualname__"): Checker.__qualname__ = name return Checker def test_transfer_cpu_gpu(): a = tt.fmatrix("a") g = GpuArrayType(dtype="float32", broadcastable=(False, False))("g") av = np.asarray(rng.rand(5, 4), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) f = theano.function([a], GpuFromHost(test_ctx_name)(a)) fv = f(av) assert GpuArrayType.values_eq(fv, gv) f = theano.function([g], host_from_gpu(g)) fv = f(gv) assert np.all(fv == av) def test_transfer_gpu_gpu(): g = GpuArrayType( dtype="float32", broadcastable=(False, False), context_name=test_ctx_name )() av = np.asarray(rng.rand(5, 4), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) mode = mode_with_gpu.excluding( "cut_gpua_host_transfers", "local_cut_gpua_host_gpua" ) f = theano.function([g], GpuToGpu(test_ctx_name)(g), mode=mode) topo = f.maker.fgraph.toposort() assert len(topo) == 1 assert isinstance(topo[0].op, GpuToGpu) fv = f(gv) assert GpuArrayType.values_eq(fv, gv) def test_transfer_strided(): # This is just to ensure that it works in theano # libgpuarray has a much more comprehensive suit of tests to # ensure correctness a = tt.fmatrix("a") g = GpuArrayType(dtype="float32", broadcastable=(False, False))("g") av = np.asarray(rng.rand(5, 8), dtype="float32") gv = gpuarray.array(av, context=get_context(test_ctx_name)) av = av[:, ::2] gv = gv[:, ::2] f = theano.function([a], GpuFromHost(test_ctx_name)(a)) fv = f(av) assert GpuArrayType.values_eq(fv, gv) f = theano.function([g], host_from_gpu(g)) fv = f(gv) assert np.all(fv == av) def gpu_alloc_expected(x, *shp): g = gpuarray.empty(shp, dtype=x.dtype, context=get_context(test_ctx_name)) g[:] = x return g TestGpuAlloc = makeTester( name="GpuAllocTester", # The +1 is there to allow the lift to the GPU. op=lambda *args: alloc(*args) + 1, gpu_op=GpuAlloc(test_ctx_name), cases=dict( correct01=(rand(), np.int32(7)), # just gives a DeepCopyOp with possibly wrong results on the CPU # correct01_bcast=(rand(1), np.int32(7)), correct02=(rand(), np.int32(4), np.int32(7)), correct12=(rand(7), np.int32(4), np.int32(7)), correct13=(rand(7), np.int32(2), np.int32(4), np.int32(7)), correct23=(rand(4, 7), np.int32(2), np.int32(4), np.int32(7)), bad_shape12=(rand(7), np.int32(7), np.int32(5)), ), ) class TestGPUAlloc(TestAlloc): dtype = "float32" mode = mode_with_gpu shared = staticmethod(gpuarray_shared_constructor) allocs = [GpuAlloc(test_ctx_name), GpuAlloc(test_ctx_name), tt.Alloc()] def test_alloc_empty(): for dt in ["float32", "int8"]: f = theano.function([], GpuAllocEmpty(dt, context_name=test_ctx_name)(2, 3)) assert len(f.maker.fgraph.apply_nodes) == 1 out = f() assert out.shape == (2, 3) assert out.dtype == dt f = theano.function( [], [ GpuAllocEmpty("uint64", test_ctx_name)(3, 2), GpuAllocEmpty("uint64", test_ctx_name)(3, 2), ], ) out = f() assert out[0].shape == (3, 2) assert out[0].dtype == "uint64" assert out[1].shape == (3, 2) assert out[1].dtype == "uint64" assert ( len( [ node for node in f.maker.fgraph.apply_nodes if isinstance(node.op, GpuAllocEmpty) ] ) == 1 ) def test_shape(): x = GpuArrayType(dtype="float32", broadcastable=[False, False, False])() v = gpuarray.zeros((3, 4, 5), dtype="float32", context=get_context(test_ctx_name)) f = theano.function([x], x.shape) topo = f.maker.fgraph.toposort() assert np.all(f(v) == (3, 4, 5)) if theano.config.mode != "FAST_COMPILE": assert len(topo) == 4 assert isinstance(topo[0].op, tt.opt.Shape_i) assert isinstance(topo[1].op, tt.opt.Shape_i) assert isinstance(topo[2].op, tt.opt.Shape_i) assert isinstance(topo[3].op, tt.opt.MakeVector) mode = mode_with_gpu.excluding("local_shape_to_shape_i") f = theano.function([x], x.shape, mode=mode) topo = f.maker.fgraph.toposort() assert np.all(f(v) == (3, 4, 5)) assert len(topo) == 1 assert isinstance(topo[0].op, tt.Shape) def test_gpu_contiguous(): a = tt.fmatrix("a") i = tt.iscalar("i") a_val = np.asarray(np.random.rand(4, 5), dtype="float32") # The reshape is needed otherwise we make the subtensor on the CPU # to transfer less data. f = theano.function( [a, i], gpu_contiguous(a.reshape((5, 4))[::i]), mode=mode_with_gpu ) topo = f.maker.fgraph.toposort() assert any([isinstance(node.op, GpuSubtensor) for node in topo]) assert any([isinstance(node.op, GpuContiguous) for node in topo]) assert f(a_val, 1).flags.c_contiguous assert f(a_val, 2).flags.c_contiguous assert f(a_val, 2).flags.c_contiguous class TestGPUReshape(TestReshape): def setup_method(self): self.shared = gpuarray_shared_constructor self.op = GpuReshape self.mode = mode_with_gpu self.ignore_topo = ( HostFromGpu, GpuFromHost, theano.compile.DeepCopyOp, GpuDimShuffle, GpuElemwise, tt.opt.Shape_i, tt.opt.MakeVector, ) assert self.op == GpuReshape class TestGPUComparison(TestComparison): def setup_method(self): utt.seed_rng() self.mode = mode_with_gpu self.shared = gpuarray_shared_constructor self.dtypes = ["float64", "float32"] class TestGPUJoinAndSplit(TestJoinAndSplit): def setup_method(self): self.mode = mode_with_gpu.excluding("constant_folding") self.join_op = GpuJoin() self.split_op_class = GpuSplit # Use join instead of MakeVector since there is no MakeVector on GPU self.make_vector_op = GpuJoin() # this is to avoid errors with limited devices self.floatX = "float32" self.hide_error = theano.config.mode not in ["DebugMode", "DEBUG_MODE"] def shared(x, **kwargs): return gpuarray_shared_constructor(x, target=test_ctx_name, **kwargs) self.shared = shared def test_gpusplit_opt(self): # Test that we move the node to the GPU # Also test float16 computation at the same time. rng = np.random.RandomState(seed=utt.fetch_seed()) m = self.shared(rng.rand(4, 6).astype("float16")) o = tt.Split(2)(m, 0, [2, 2]) assert o[0].dtype == "float16" f = theano.function([], o, mode=self.mode) assert any( [ isinstance(node.op, self.split_op_class) for node in f.maker.fgraph.toposort() ] ) o1, o2 = f() assert np.allclose(o1, m.get_value(borrow=True)[:2]) assert np.allclose(o2, m.get_value(borrow=True)[2:]) def test_gpujoin_gpualloc(): a = tt.fmatrix("a") a_val = np.asarray(np.random.rand(4, 5), dtype="float32") b = tt.fmatrix("b") b_val = np.asarray(np.random.rand(3, 5), dtype="float32") f = theano.function( [a, b], tt.join(0, tt.zeros_like(a), tt.ones_like(b)) + 4, mode=mode_without_gpu ) f_gpu = theano.function( [a, b], tt.join(0, tt.zeros_like(a), tt.ones_like(b)), mode=mode_with_gpu ) f_gpu2 = theano.function( [a, b], tt.join(0, tt.zeros_like(a), tt.ones_like(b)) + 4, mode=mode_with_gpu ) assert sum([node.op == tt.alloc for node in f.maker.fgraph.toposort()]) == 2 assert sum([node.op == tt.join_ for node in f.maker.fgraph.toposort()]) == 1 assert ( sum([isinstance(node.op, GpuAlloc) for node in f_gpu.maker.fgraph.toposort()]) == 2 ) assert sum([node.op == gpu_join for node in f_gpu.maker.fgraph.toposort()]) == 1 assert ( sum([isinstance(node.op, GpuAlloc) for node in f_gpu2.maker.fgraph.toposort()]) == 2 ) assert sum([node.op == gpu_join for node in f_gpu2.maker.fgraph.toposort()]) == 1 assert np.allclose(f(a_val, b_val), f_gpu2(a_val, b_val)) def test_gpueye(): def check(dtype, N, M_=None, k=0): # Theano does not accept None as a tensor. # So we must use a real value. M = M_ # Currently DebugMode does not support None as inputs even if this is # allowed. if M is None: M = N N_symb = tt.iscalar() M_symb = tt.iscalar() k_symb = tt.iscalar() out = tt.eye(N_symb, M_symb, k_symb, dtype=dtype) + np.array(1).astype(dtype) f = theano.function([N_symb, M_symb, k_symb], out, mode=mode_with_gpu) result = np.asarray(f(N, M, k)) - np.array(1).astype(dtype) assert np.allclose(result, np.eye(N, M_, k, dtype=dtype)) assert result.dtype == np.dtype(dtype) assert any([isinstance(node.op, GpuEye) for node in f.maker.fgraph.toposort()]) for dtype in ["float32", "int32", "float16"]: check(dtype, 3) # M != N, k = 0 check(dtype, 3, 5) check(dtype, 5, 3) # N == M, k != 0 check(dtype, 3, 3, 1) check(dtype, 3, 3, -1) # N < M, k != 0 check(dtype, 3, 5, 1) check(dtype, 3, 5, -1) # N > M, k != 0 check(dtype, 5, 3, 1) check(dtype, 5, 3, -1) # k > M, -k > N, k > M, k > N check(dtype, 5, 3, 3) check(dtype, 3, 5, 3) check(dtype, 5, 3, -3) check(dtype, 3, 5, -3) check(dtype, 5, 3, 6) check(dtype, 3, 5, -6) def test_hostfromgpu_shape_i(): # Test that the shape is lifted over hostfromgpu m = mode_with_gpu.including( "local_dot_to_dot22", "local_dot22_to_dot22scalar", "specialize" ) a = tt.fmatrix("a") ca = theano.gpuarray.type.GpuArrayType("float32", (False, False))() av = np.asarray(np.random.rand(5, 4), dtype="float32") cv = gpuarray.asarray( np.random.rand(5, 4), dtype="float32", context=get_context(test_ctx_name) ) f = theano.function([a], GpuFromHost(test_ctx_name)(a), mode=m) assert any(isinstance(x.op, GpuFromHost) for x in f.maker.fgraph.toposort()) f = theano.function([a], GpuFromHost(test_ctx_name)(a).shape, mode=m) topo = f.maker.fgraph.toposort() assert isinstance(topo[0].op, tt.opt.Shape_i) assert isinstance(topo[1].op, tt.opt.Shape_i) assert isinstance(topo[2].op, tt.opt.MakeVector) assert tuple(f(av)) == (5, 4) f = theano.function([ca], host_from_gpu(ca), mode=m) assert host_from_gpu in [x.op for x in f.maker.fgraph.toposort()] f = theano.function([ca], host_from_gpu(ca).shape, mode=m) topo = f.maker.fgraph.toposort() assert isinstance(topo[0].op, theano.compile.Shape_i) assert isinstance(topo[1].op, theano.compile.Shape_i) assert isinstance(topo[2].op, tt.opt.MakeVector) assert tuple(f(cv)) == (5, 4) def test_Gpujoin_inplace(): # Test Gpujoin to work inplace. # # This function tests the case when several elements are passed to the # Gpujoin function but all except one of them are empty. In this case # Gpujoin should work inplace and the output should be the view of the # non-empty element. s = tt.lscalar() data = np.array([3, 4, 5], dtype=theano.config.floatX) x = gpuarray_shared_constructor(data, borrow=True) z = tt.zeros((s,)) join = GpuJoin(view=0) c = join(0, x, z) f = theano.function([s], theano.Out(c, borrow=True)) if not isinstance(mode_with_gpu, theano.compile.DebugMode): assert x.get_value(borrow=True, return_internal_type=True) is f(0) assert np.allclose(f(0), [3, 4, 5]) def test_gpu_tril_triu(): def check_l(m, k=0): m_symb = tt.matrix(dtype=m.dtype) k_symb = tt.iscalar() f = theano.function( [m_symb, k_symb], tt.tril(m_symb, k_symb), mode=mode_with_gpu ) result = f(m, k) assert np.allclose(result, np.tril(m, k)) assert result.dtype == np.dtype(dtype) assert any([isinstance(node.op, GpuTri) for node in f.maker.fgraph.toposort()]) def check_u(m, k=0): m_symb = tt.matrix(dtype=m.dtype) k_symb = tt.iscalar() f = theano.function( [m_symb, k_symb], tt.triu(m_symb, k_symb), mode=mode_with_gpu ) result = f(m, k) assert np.allclose(result, np.triu(m, k)) assert result.dtype ==

np.dtype(dtype)

numpy.dtype

from __future__ import annotations from datetime import timedelta import operator from sys import getsizeof from typing import ( TYPE_CHECKING, Any, Callable, Hashable, List, cast, ) import warnings import numpy as np from pandas._libs import index as libindex from pandas._libs.lib import no_default from pandas._typing import Dtype from pandas.compat.numpy import function as nv from pandas.util._decorators import ( cache_readonly, doc, ) from pandas.util._exceptions import rewrite_exception from pandas.core.dtypes.common import ( ensure_platform_int, ensure_python_int, is_float, is_integer, is_scalar, is_signed_integer_dtype, is_timedelta64_dtype, ) from pandas.core.dtypes.generic import ABCTimedeltaIndex from pandas.core import ops import pandas.core.common as com from pandas.core.construction import extract_array import pandas.core.indexes.base as ibase from pandas.core.indexes.base import maybe_extract_name from pandas.core.indexes.numeric import ( Float64Index, Int64Index, NumericIndex, ) from pandas.core.ops.common import unpack_zerodim_and_defer if TYPE_CHECKING: from pandas import Index _empty_range = range(0) class RangeIndex(NumericIndex): """ Immutable Index implementing a monotonic integer range. RangeIndex is a memory-saving special case of Int64Index limited to representing monotonic ranges. Using RangeIndex may in some instances improve computing speed. This is the default index type used by DataFrame and Series when no explicit index is provided by the user. Parameters ---------- start : int (default: 0), range, or other RangeIndex instance If int and "stop" is not given, interpreted as "stop" instead. stop : int (default: 0) step : int (default: 1) dtype : np.int64 Unused, accepted for homogeneity with other index types. copy : bool, default False Unused, accepted for homogeneity with other index types. name : object, optional Name to be stored in the index. Attributes ---------- start stop step Methods ------- from_range See Also -------- Index : The base pandas Index type. Int64Index : Index of int64 data. """ _typ = "rangeindex" _engine_type = libindex.Int64Engine _dtype_validation_metadata = (is_signed_integer_dtype, "signed integer") _can_hold_na = False _range: range # -------------------------------------------------------------------- # Constructors def __new__( cls, start=None, stop=None, step=None, dtype: Dtype | None = None, copy: bool = False, name: Hashable = None, ) -> RangeIndex: cls._validate_dtype(dtype) name = maybe_extract_name(name, start, cls) # RangeIndex if isinstance(start, RangeIndex): return start.copy(name=name) elif isinstance(start, range): return cls._simple_new(start, name=name) # validate the arguments if com.all_none(start, stop, step): raise TypeError("RangeIndex(...) must be called with integers") start = ensure_python_int(start) if start is not None else 0 if stop is None: start, stop = 0, start else: stop = ensure_python_int(stop) step = ensure_python_int(step) if step is not None else 1 if step == 0: raise ValueError("Step must not be zero") rng = range(start, stop, step) return cls._simple_new(rng, name=name) @classmethod def from_range( cls, data: range, name=None, dtype: Dtype | None = None ) -> RangeIndex: """ Create RangeIndex from a range object. Returns ------- RangeIndex """ if not isinstance(data, range): raise TypeError( f"{cls.__name__}(...) must be called with object coercible to a " f"range, {repr(data)} was passed" ) cls._validate_dtype(dtype) return cls._simple_new(data, name=name) @classmethod def _simple_new(cls, values: range, name: Hashable = None) -> RangeIndex: result = object.__new__(cls) assert isinstance(values, range) result._range = values result._name = name result._cache = {} result._reset_identity() return result # -------------------------------------------------------------------- @cache_readonly def _constructor(self) -> type[Int64Index]: """ return the class to use for construction """ return Int64Index @cache_readonly def _data(self) -> np.ndarray: """ An int array that for performance reasons is created only when needed. The constructed array is saved in ``_cache``. """ return np.arange(self.start, self.stop, self.step, dtype=np.int64) @cache_readonly def _cached_int64index(self) -> Int64Index: return Int64Index._simple_new(self._data, name=self.name) @property def _int64index(self) -> Int64Index: # wrap _cached_int64index so we can be sure its name matches self.name res = self._cached_int64index res._name = self._name return res def _get_data_as_items(self): """ return a list of tuples of start, stop, step """ rng = self._range return [("start", rng.start), ("stop", rng.stop), ("step", rng.step)] def __reduce__(self): d = self._get_attributes_dict() d.update(dict(self._get_data_as_items())) return ibase._new_Index, (type(self), d), None # -------------------------------------------------------------------- # Rendering Methods def _format_attrs(self): """ Return a list of tuples of the (attr, formatted_value) """ attrs = self._get_data_as_items() if self.name is not None: attrs.append(("name", ibase.default_pprint(self.name))) return attrs def _format_data(self, name=None): # we are formatting thru the attributes return None def _format_with_header(self, header: list[str], na_rep: str = "NaN") -> list[str]: if not len(self._range): return header first_val_str = str(self._range[0]) last_val_str = str(self._range[-1]) max_length = max(len(first_val_str), len(last_val_str)) return header + [f"{x:<{max_length}}" for x in self._range] # -------------------------------------------------------------------- _deprecation_message = ( "RangeIndex.{} is deprecated and will be " "removed in a future version. Use RangeIndex.{} " "instead" ) @property def start(self) -> int: """ The value of the `start` parameter (``0`` if this was not supplied). """ # GH 25710 return self._range.start @property def _start(self) -> int: """ The value of the `start` parameter (``0`` if this was not supplied). .. deprecated:: 0.25.0 Use ``start`` instead. """ warnings.warn( self._deprecation_message.format("_start", "start"), FutureWarning, stacklevel=2, ) return self.start @property def stop(self) -> int: """ The value of the `stop` parameter. """ return self._range.stop @property def _stop(self) -> int: """ The value of the `stop` parameter. .. deprecated:: 0.25.0 Use ``stop`` instead. """ # GH 25710 warnings.warn( self._deprecation_message.format("_stop", "stop"), FutureWarning, stacklevel=2, ) return self.stop @property def step(self) -> int: """ The value of the `step` parameter (``1`` if this was not supplied). """ # GH 25710 return self._range.step @property def _step(self) -> int: """ The value of the `step` parameter (``1`` if this was not supplied). .. deprecated:: 0.25.0 Use ``step`` instead. """ # GH 25710 warnings.warn( self._deprecation_message.format("_step", "step"), FutureWarning, stacklevel=2, ) return self.step @cache_readonly def nbytes(self) -> int: """ Return the number of bytes in the underlying data. """ rng = self._range return getsizeof(rng) + sum( getsizeof(getattr(rng, attr_name)) for attr_name in ["start", "stop", "step"] ) def memory_usage(self, deep: bool = False) -> int: """ Memory usage of my values Parameters ---------- deep : bool Introspect the data deeply, interrogate `object` dtypes for system-level memory consumption Returns ------- bytes used Notes ----- Memory usage does not include memory consumed by elements that are not components of the array if deep=False See Also -------- numpy.ndarray.nbytes """ return self.nbytes @property def dtype(self) -> np.dtype: return np.dtype(np.int64) @property def is_unique(self) -> bool: """ return if the index has unique values """ return True @cache_readonly def is_monotonic_increasing(self) -> bool: return self._range.step > 0 or len(self) <= 1 @cache_readonly def is_monotonic_decreasing(self) -> bool: return self._range.step < 0 or len(self) <= 1 def __contains__(self, key: Any) -> bool: hash(key) try: key = ensure_python_int(key) except TypeError: return False return key in self._range @property def inferred_type(self) -> str: return "integer" # -------------------------------------------------------------------- # Indexing Methods @doc(Int64Index.get_loc) def get_loc(self, key, method=None, tolerance=None): if method is None and tolerance is None: if is_integer(key) or (is_float(key) and key.is_integer()): new_key = int(key) try: return self._range.index(new_key) except ValueError as err: raise KeyError(key) from err raise KeyError(key) return super().get_loc(key, method=method, tolerance=tolerance) def _get_indexer( self, target: Index, method: str | None = None, limit: int | None = None, tolerance=None, ) -> np.ndarray: # -> np.ndarray[np.intp] if com.any_not_none(method, tolerance, limit): return super()._get_indexer( target, method=method, tolerance=tolerance, limit=limit ) if self.step > 0: start, stop, step = self.start, self.stop, self.step else: # GH 28678: work on reversed range for simplicity reverse = self._range[::-1] start, stop, step = reverse.start, reverse.stop, reverse.step if not is_signed_integer_dtype(target): # checks/conversions/roundings are delegated to general method return super()._get_indexer(target, method=method, tolerance=tolerance) target_array = np.asarray(target) locs = target_array - start valid = (locs % step == 0) & (locs >= 0) & (target_array < stop) locs[~valid] = -1 locs[valid] = locs[valid] / step if step != self.step: # We reversed this range: transform to original locs locs[valid] = len(self) - 1 - locs[valid] return ensure_platform_int(locs) # -------------------------------------------------------------------- def repeat(self, repeats, axis=None) -> Int64Index: return self._int64index.repeat(repeats, axis=axis) def delete(self, loc) -> Int64Index: # type: ignore[override] return self._int64index.delete(loc) def take( self, indices, axis: int = 0, allow_fill: bool = True, fill_value=None, **kwargs ) -> Int64Index: with rewrite_exception("Int64Index", type(self).__name__): return self._int64index.take( indices, axis=axis, allow_fill=allow_fill, fill_value=fill_value, **kwargs, ) def tolist(self) -> list[int]: return list(self._range) @doc(Int64Index.__iter__) def __iter__(self): yield from self._range @doc(Int64Index._shallow_copy) def _shallow_copy(self, values, name: Hashable = no_default): name = self.name if name is no_default else name if values.dtype.kind == "f": return Float64Index(values, name=name) return Int64Index._simple_new(values, name=name) def _view(self: RangeIndex) -> RangeIndex: result = type(self)._simple_new(self._range, name=self._name) result._cache = self._cache return result @doc(Int64Index.copy) def copy( self, name: Hashable = None, deep: bool = False, dtype: Dtype | None = None, names=None, ): name = self._validate_names(name=name, names=names, deep=deep)[0] new_index = self._rename(name=name) if dtype: warnings.warn( "parameter dtype is deprecated and will be removed in a future " "version. Use the astype method instead.", FutureWarning, stacklevel=2, ) new_index = new_index.astype(dtype) return new_index def _minmax(self, meth: str): no_steps = len(self) - 1 if no_steps == -1: return np.nan elif (meth == "min" and self.step > 0) or (meth == "max" and self.step < 0): return self.start return self.start + self.step * no_steps def min(self, axis=None, skipna: bool = True, *args, **kwargs) -> int: """The minimum value of the RangeIndex""" nv.validate_minmax_axis(axis) nv.validate_min(args, kwargs) return self._minmax("min") def max(self, axis=None, skipna: bool = True, *args, **kwargs) -> int: """The maximum value of the RangeIndex""" nv.validate_minmax_axis(axis) nv.validate_max(args, kwargs) return self._minmax("max") def argsort(self, *args, **kwargs) -> np.ndarray: """ Returns the indices that would sort the index and its underlying data. Returns ------- np.ndarray[np.intp] See Also -------- numpy.ndarray.argsort """ ascending = kwargs.pop("ascending", True) # EA compat nv.validate_argsort(args, kwargs) if self._range.step > 0: result = np.arange(len(self), dtype=np.intp) else: result = np.arange(len(self) - 1, -1, -1, dtype=np.intp) if not ascending: result = result[::-1] return result def factorize( self, sort: bool = False, na_sentinel: int | None = -1 ) -> tuple[np.ndarray, RangeIndex]: codes = np.arange(len(self), dtype=np.intp) uniques = self if sort and self.step < 0: codes = codes[::-1] uniques = uniques[::-1] return codes, uniques def equals(self, other: object) -> bool: """ Determines if two Index objects contain the same elements. """ if isinstance(other, RangeIndex): return self._range == other._range return super().equals(other) # -------------------------------------------------------------------- # Set Operations def _intersection(self, other: Index, sort=False): if not isinstance(other, RangeIndex): # Int64Index return super()._intersection(other, sort=sort) if not len(self) or not len(other): return self._simple_new(_empty_range) first = self._range[::-1] if self.step < 0 else self._range second = other._range[::-1] if other.step < 0 else other._range # check whether intervals intersect # deals with in- and decreasing ranges int_low = max(first.start, second.start) int_high = min(first.stop, second.stop) if int_high <= int_low: return self._simple_new(_empty_range) # Method hint: linear Diophantine equation # solve intersection problem # performance hint: for identical step sizes, could use # cheaper alternative gcd, s, _ = self._extended_gcd(first.step, second.step) # check whether element sets intersect if (first.start - second.start) % gcd: return self._simple_new(_empty_range) # calculate parameters for the RangeIndex describing the # intersection disregarding the lower bounds tmp_start = first.start + (second.start - first.start) * first.step // gcd * s new_step = first.step * second.step // gcd new_range = range(tmp_start, int_high, new_step) new_index = self._simple_new(new_range) # adjust index to limiting interval new_start = new_index._min_fitting_element(int_low) new_range = range(new_start, new_index.stop, new_index.step) new_index = self._simple_new(new_range) if (self.step < 0 and other.step < 0) is not (new_index.step < 0): new_index = new_index[::-1] if sort is None: new_index = new_index.sort_values() return new_index def _min_fitting_element(self, lower_limit: int) -> int: """Returns the smallest element greater than or equal to the limit""" no_steps = -(-(lower_limit - self.start) // abs(self.step)) return self.start + abs(self.step) * no_steps def _max_fitting_element(self, upper_limit: int) -> int: """Returns the largest element smaller than or equal to the limit""" no_steps = (upper_limit - self.start) // abs(self.step) return self.start + abs(self.step) * no_steps def _extended_gcd(self, a: int, b: int) -> tuple[int, int, int]: """ Extended Euclidean algorithms to solve Bezout's identity: a*x + b*y = gcd(x, y) Finds one particular solution for x, y: s, t Returns: gcd, s, t """ s, old_s = 0, 1 t, old_t = 1, 0 r, old_r = b, a while r: quotient = old_r // r old_r, r = r, old_r - quotient * r old_s, s = s, old_s - quotient * s old_t, t = t, old_t - quotient * t return old_r, old_s, old_t def _union(self, other: Index, sort): """ Form the union of two Index objects and sorts if possible Parameters ---------- other : Index or array-like sort : False or None, default None Whether to sort resulting index. ``sort=None`` returns a monotonically increasing ``RangeIndex`` if possible or a sorted ``Int64Index`` if not. ``sort=False`` always returns an unsorted ``Int64Index`` .. versionadded:: 0.25.0 Returns ------- union : Index """ if isinstance(other, RangeIndex) and sort is None: start_s, step_s = self.start, self.step end_s = self.start + self.step * (len(self) - 1) start_o, step_o = other.start, other.step end_o = other.start + other.step * (len(other) - 1) if self.step < 0: start_s, step_s, end_s = end_s, -step_s, start_s if other.step < 0: start_o, step_o, end_o = end_o, -step_o, start_o if len(self) == 1 and len(other) == 1: step_s = step_o = abs(self.start - other.start) elif len(self) == 1: step_s = step_o elif len(other) == 1: step_o = step_s start_r = min(start_s, start_o) end_r = max(end_s, end_o) if step_o == step_s: if ( (start_s - start_o) % step_s == 0 and (start_s - end_o) <= step_s and (start_o - end_s) <= step_s ): return type(self)(start_r, end_r + step_s, step_s) if ( (step_s % 2 == 0) and (abs(start_s - start_o) <= step_s / 2) and (abs(end_s - end_o) <= step_s / 2) ): return type(self)(start_r, end_r + step_s / 2, step_s / 2) elif step_o % step_s == 0: if ( (start_o - start_s) % step_s == 0 and (start_o + step_s >= start_s) and (end_o - step_s <= end_s) ): return type(self)(start_r, end_r + step_s, step_s) elif step_s % step_o == 0: if ( (start_s - start_o) % step_o == 0 and (start_s + step_o >= start_o) and (end_s - step_o <= end_o) ): return type(self)(start_r, end_r + step_o, step_o) return self._int64index._union(other, sort=sort) def _difference(self, other, sort=None): # optimized set operation if we have another RangeIndex self._validate_sort_keyword(sort) self._assert_can_do_setop(other) other, result_name = self._convert_can_do_setop(other) if not isinstance(other, RangeIndex): return super()._difference(other, sort=sort) res_name = ops.get_op_result_name(self, other) first = self._range[::-1] if self.step < 0 else self._range overlap = self.intersection(other) if overlap.step < 0: overlap = overlap[::-1] if len(overlap) == 0: return self.rename(name=res_name) if len(overlap) == len(self): return self[:0].rename(res_name) if not isinstance(overlap, RangeIndex): # We won't end up with RangeIndex, so fall back return super()._difference(other, sort=sort) if overlap.step != first.step: # In some cases we might be able to get a RangeIndex back, # but not worth the effort. return super()._difference(other, sort=sort) if overlap[0] == first.start: # The difference is everything after the intersection new_rng = range(overlap[-1] + first.step, first.stop, first.step) elif overlap[-1] == first[-1]: # The difference is everything before the intersection new_rng = range(first.start, overlap[0], first.step) else: # The difference is not range-like return super()._difference(other, sort=sort) new_index = type(self)._simple_new(new_rng, name=res_name) if first is not self._range: new_index = new_index[::-1] return new_index def symmetric_difference(self, other, result_name: Hashable = None, sort=None): if not isinstance(other, RangeIndex) or sort is not None: return super().symmetric_difference(other, result_name, sort) left = self.difference(other) right = other.difference(self) result = left.union(right) if result_name is not None: result = result.rename(result_name) return result # -------------------------------------------------------------------- def _concat(self, indexes: list[Index], name: Hashable) -> Index: """ Overriding parent method for the case of all RangeIndex instances. When all members of "indexes" are of type RangeIndex: result will be RangeIndex if possible, Int64Index otherwise. E.g.: indexes = [RangeIndex(3), RangeIndex(3, 6)] -> RangeIndex(6) indexes = [RangeIndex(3), RangeIndex(4, 6)] -> Int64Index([0,1,2,4,5]) """ if not all(isinstance(x, RangeIndex) for x in indexes): return super()._concat(indexes, name) elif len(indexes) == 1: return indexes[0] rng_indexes = cast(List[RangeIndex], indexes) start = step = next_ = None # Filter the empty indexes non_empty_indexes = [obj for obj in rng_indexes if len(obj)] for obj in non_empty_indexes: rng = obj._range if start is None: # This is set by the first non-empty index start = rng.start if step is None and len(rng) > 1: step = rng.step elif step is None: # First non-empty index had only one element if rng.start == start: values = np.concatenate([x._values for x in rng_indexes]) result = Int64Index(values) return result.rename(name) step = rng.start - start non_consecutive = (step != rng.step and len(rng) > 1) or ( next_ is not None and rng.start != next_ ) if non_consecutive: result = Int64Index(np.concatenate([x._values for x in rng_indexes])) return result.rename(name) if step is not None: next_ = rng[-1] + step if non_empty_indexes: # Get the stop value from "next" or alternatively # from the last non-empty index stop = non_empty_indexes[-1].stop if next_ is None else next_ return RangeIndex(start, stop, step).rename(name) # Here all "indexes" had 0 length, i.e. were empty. # In this case return an empty range index. return RangeIndex(0, 0).rename(name) def __len__(self) -> int: """ return the length of the RangeIndex """ return len(self._range) @property def size(self) -> int: return len(self) def __getitem__(self, key): """ Conserve RangeIndex type for scalar and slice keys. """ if isinstance(key, slice): new_range = self._range[key] return self._simple_new(new_range, name=self._name) elif is_integer(key): new_key = int(key) try: return self._range[new_key] except IndexError as err: raise IndexError( f"index {key} is out of bounds for axis 0 with size {len(self)}" ) from err elif is_scalar(key): raise IndexError( "only integers, slices (`:`), " "ellipsis (`...`), numpy.newaxis (`None`) " "and integer or boolean " "arrays are valid indices" ) # fall back to Int64Index return super().__getitem__(key) def _getitem_slice(self: RangeIndex, slobj: slice) -> RangeIndex: """ Fastpath for __getitem__ when we know we have a slice. """ res = self._range[slobj] return type(self)._simple_new(res, name=self._name) @unpack_zerodim_and_defer("__floordiv__") def __floordiv__(self, other): if is_integer(other) and other != 0: if len(self) == 0 or self.start % other == 0 and self.step % other == 0: start = self.start // other step = self.step // other stop = start + len(self) * step new_range = range(start, stop, step or 1) return self._simple_new(new_range, name=self.name) if len(self) == 1: start = self.start // other new_range = range(start, start + 1, 1) return self._simple_new(new_range, name=self.name) return self._int64index // other # -------------------------------------------------------------------- # Reductions def all(self, *args, **kwargs) -> bool: return 0 not in self._range def any(self, *args, **kwargs) -> bool: return any(self._range) # -------------------------------------------------------------------- def _cmp_method(self, other, op): if isinstance(other, RangeIndex) and self._range == other._range: # Both are immutable so if ._range attr. are equal, shortcut is possible return super()._cmp_method(self, op) return super()._cmp_method(other, op) def _arith_method(self, other, op): """ Parameters ---------- other : Any op : callable that accepts 2 params perform the binary op """ if isinstance(other, ABCTimedeltaIndex): # Defer to TimedeltaIndex implementation return NotImplemented elif isinstance(other, (timedelta, np.timedelta64)): # GH#19333 is_integer evaluated True on timedelta64, # so we need to catch these explicitly return op(self._int64index, other) elif is_timedelta64_dtype(other): # Must be an np.ndarray; GH#22390 return op(self._int64index, other) if op in [ operator.pow, ops.rpow, operator.mod, ops.rmod, ops.rfloordiv, divmod, ops.rdivmod, ]: return op(self._int64index, other) step: Callable | None = None if op in [operator.mul, ops.rmul, operator.truediv, ops.rtruediv]: step = op # TODO: if other is a RangeIndex we may have more efficient options other = extract_array(other, extract_numpy=True, extract_range=True) attrs = self._get_attributes_dict() left, right = self, other try: # apply if we have an override if step: with

np.errstate(all="ignore")

numpy.errstate

# coding: utf-8 # Licensed under a 3-clause BSD style license - see LICENSE.rst """ Test the Logarithmic Units and Quantities """ from __future__ import (absolute_import, unicode_literals, division, print_function) from ...extern import six from ...extern.six.moves import zip import pickle import itertools import pytest import numpy as np from numpy.testing.utils import assert_allclose from ...tests.helper import assert_quantity_allclose from ... import units as u, constants as c lu_units = [u.dex, u.mag, u.decibel] lu_subclasses = [u.DexUnit, u.MagUnit, u.DecibelUnit] lq_subclasses = [u.Dex, u.Magnitude, u.Decibel] pu_sample = (u.dimensionless_unscaled, u.m, u.g/u.s**2, u.Jy) class TestLogUnitCreation(object): def test_logarithmic_units(self): """Check logarithmic units are set up correctly.""" assert u.dB.to(u.dex) == 0.1 assert u.dex.to(u.mag) == -2.5 assert u.mag.to(u.dB) == -4 @pytest.mark.parametrize('lu_unit, lu_cls', zip(lu_units, lu_subclasses)) def test_callable_units(self, lu_unit, lu_cls): assert isinstance(lu_unit, u.UnitBase) assert callable(lu_unit) assert lu_unit._function_unit_class is lu_cls @pytest.mark.parametrize('lu_unit', lu_units) def test_equality_to_normal_unit_for_dimensionless(self, lu_unit): lu = lu_unit() assert lu == lu._default_function_unit # eg, MagUnit() == u.mag assert lu._default_function_unit == lu # and u.mag == MagUnit() @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_call_units(self, lu_unit, physical_unit): """Create a LogUnit subclass using the callable unit and physical unit, and do basic check that output is right.""" lu1 = lu_unit(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit def test_call_invalid_unit(self): with pytest.raises(TypeError): u.mag([]) with pytest.raises(ValueError): u.mag(u.mag()) @pytest.mark.parametrize('lu_cls, physical_unit', itertools.product( lu_subclasses + [u.LogUnit], pu_sample)) def test_subclass_creation(self, lu_cls, physical_unit): """Create a LogUnit subclass object for given physical unit, and do basic check that output is right.""" lu1 = lu_cls(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit lu2 = lu_cls(physical_unit, function_unit=2*lu1._default_function_unit) assert lu2.physical_unit == physical_unit assert lu2.function_unit == u.Unit(2*lu2._default_function_unit) with pytest.raises(ValueError): lu_cls(physical_unit, u.m) def test_predefined_magnitudes(): assert_quantity_allclose((-21.1*u.STmag).physical, 1.*u.erg/u.cm**2/u.s/u.AA) assert_quantity_allclose((-48.6*u.ABmag).physical, 1.*u.erg/u.cm**2/u.s/u.Hz) assert_quantity_allclose((0*u.M_bol).physical, c.L_bol0) assert_quantity_allclose((0*u.m_bol).physical, c.L_bol0/(4.*np.pi*(10.*c.pc)**2)) def test_predefined_reinitialisation(): assert u.mag('ST') == u.STmag assert u.mag('AB') == u.ABmag assert u.mag('Bol') == u.M_bol assert u.mag('bol') == u.m_bol def test_predefined_string_roundtrip(): """Ensure roundtripping; see #5015""" with u.magnitude_zero_points.enable(): assert u.Unit(u.STmag.to_string()) == u.STmag assert u.Unit(u.ABmag.to_string()) == u.ABmag assert u.Unit(u.M_bol.to_string()) == u.M_bol assert u.Unit(u.m_bol.to_string()) == u.m_bol def test_inequality(): """Check __ne__ works (regresssion for #5342).""" lu1 = u.mag(u.Jy) lu2 = u.dex(u.Jy) lu3 = u.mag(u.Jy**2) lu4 = lu3 - lu1 assert lu1 != lu2 assert lu1 != lu3 assert lu1 == lu4 class TestLogUnitStrings(object): def test_str(self): """Do some spot checks that str, repr, etc. work as expected.""" lu1 = u.mag(u.Jy) assert str(lu1) == 'mag(Jy)' assert repr(lu1) == 'Unit("mag(Jy)")' assert lu1.to_string('generic') == 'mag(Jy)' with pytest.raises(ValueError): lu1.to_string('fits') lu2 = u.dex() assert str(lu2) == 'dex' assert repr(lu2) == 'Unit("dex(1)")' assert lu2.to_string() == 'dex(1)' lu3 = u.MagUnit(u.Jy, function_unit=2*u.mag) assert str(lu3) == '2 mag(Jy)' assert repr(lu3) == 'MagUnit("Jy", unit="2 mag")' assert lu3.to_string() == '2 mag(Jy)' lu4 = u.mag(u.ct) assert lu4.to_string('generic') == 'mag(ct)' assert lu4.to_string('latex') == ('$\\mathrm{mag}$$\\mathrm{\\left( ' '\\mathrm{ct} \\right)}$') assert lu4._repr_latex_() == lu4.to_string('latex') class TestLogUnitConversion(object): @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_physical_unit_conversion(self, lu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to their non-log counterparts.""" lu1 = lu_unit(physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(physical_unit, 0.) == 1. assert physical_unit.is_equivalent(lu1) assert physical_unit.to(lu1, 1.) == 0. pu = u.Unit(8.*physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(pu, 0.) == 0.125 assert pu.is_equivalent(lu1) assert_allclose(pu.to(lu1, 0.125), 0., atol=1.e-15) # Check we round-trip. value = np.linspace(0., 10., 6) assert_allclose(pu.to(lu1, lu1.to(pu, value)), value, atol=1.e-15) # And that we're not just returning True all the time. pu2 = u.g assert not lu1.is_equivalent(pu2) with pytest.raises(u.UnitsError): lu1.to(pu2) assert not pu2.is_equivalent(lu1) with pytest.raises(u.UnitsError): pu2.to(lu1) @pytest.mark.parametrize('lu_unit', lu_units) def test_container_unit_conversion(self, lu_unit): """Check that conversion to logarithmic units (u.mag, u.dB, u.dex) is only possible when the physical unit is dimensionless.""" values = np.linspace(0., 10., 6) lu1 = lu_unit(u.dimensionless_unscaled) assert lu1.is_equivalent(lu1.function_unit) assert_allclose(lu1.to(lu1.function_unit, values), values) lu2 = lu_unit(u.Jy) assert not lu2.is_equivalent(lu2.function_unit) with pytest.raises(u.UnitsError): lu2.to(lu2.function_unit, values) @pytest.mark.parametrize( 'flu_unit, tlu_unit, physical_unit', itertools.product(lu_units, lu_units, pu_sample)) def test_subclass_conversion(self, flu_unit, tlu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to each other if they correspond to equivalent physical units.""" values = np.linspace(0., 10., 6) flu = flu_unit(physical_unit) tlu = tlu_unit(physical_unit) assert flu.is_equivalent(tlu) assert_allclose(flu.to(tlu), flu.function_unit.to(tlu.function_unit)) assert_allclose(flu.to(tlu, values), values * flu.function_unit.to(tlu.function_unit)) tlu2 = tlu_unit(u.Unit(100.*physical_unit)) assert flu.is_equivalent(tlu2) # Check that we round-trip. assert_allclose(flu.to(tlu2, tlu2.to(flu, values)), values, atol=1.e-15) tlu3 = tlu_unit(physical_unit.to_system(u.si)[0]) assert flu.is_equivalent(tlu3) assert_allclose(flu.to(tlu3, tlu3.to(flu, values)), values, atol=1.e-15) tlu4 = tlu_unit(u.g) assert not flu.is_equivalent(tlu4) with pytest.raises(u.UnitsError): flu.to(tlu4, values) def test_unit_decomposition(self): lu = u.mag(u.Jy) assert lu.decompose() == u.mag(u.Jy.decompose()) assert lu.decompose().physical_unit.bases == [u.kg, u.s] assert lu.si == u.mag(u.Jy.si) assert lu.si.physical_unit.bases == [u.kg, u.s] assert lu.cgs == u.mag(u.Jy.cgs) assert lu.cgs.physical_unit.bases == [u.g, u.s] def test_unit_multiple_possible_equivalencies(self): lu = u.mag(u.Jy) assert lu.is_equivalent(pu_sample) class TestLogUnitArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other units is only possible when the physical unit is dimensionless, and that this turns the unit into a normal one.""" lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 * u.m with pytest.raises(u.UnitsError): u.m * lu1 with pytest.raises(u.UnitsError): lu1 / lu1 for unit in (u.dimensionless_unscaled, u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lu1 / unit lu2 = u.mag(u.dimensionless_unscaled) with pytest.raises(u.UnitsError): lu2 * lu1 with pytest.raises(u.UnitsError): lu2 / lu1 # But dimensionless_unscaled can be cancelled. assert lu2 / lu2 == u.dimensionless_unscaled # With dimensionless, normal units are OK, but we return a plain unit. tf = lu2 * u.m tr = u.m * lu2 for t in (tf, tr): assert not isinstance(t, type(lu2)) assert t == lu2.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lu2.physical_unit) # Now we essentially have a LogUnit with a prefactor of 100, # so should be equivalent again. t = tf / u.cm with u.set_enabled_equivalencies(u.logarithmic()): assert t.is_equivalent(lu2.function_unit) assert_allclose(t.to(u.dimensionless_unscaled, np.arange(3.)/100.), lu2.to(lu2.physical_unit, np.arange(3.))) # If we effectively remove lu1, a normal unit should be returned. t2 = tf / lu2 assert not isinstance(t2, type(lu2)) assert t2 == u.m t3 = tf / lu2.function_unit assert not isinstance(t3, type(lu2)) assert t3 == u.m # For completeness, also ensure non-sensical operations fail with pytest.raises(TypeError): lu1 * object() with pytest.raises(TypeError): slice(None) * lu1 with pytest.raises(TypeError): lu1 / [] with pytest.raises(TypeError): 1 / lu1 @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogUnits to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (such as mag**2) is incompatible.""" lu1 = u.mag(u.Jy) if power == 0: assert lu1 ** power == u.dimensionless_unscaled elif power == 1: assert lu1 ** power == lu1 else: with pytest.raises(u.UnitsError): lu1 ** power # With dimensionless, though, it works, but returns a normal unit. lu2 = u.mag(u.dimensionless_unscaled) t = lu2**power if power == 0: assert t == u.dimensionless_unscaled elif power == 1: assert t == lu2 else: assert not isinstance(t, type(lu2)) assert t == lu2.function_unit**power # also check we roundtrip t2 = t**(1./power) assert t2 == lu2.function_unit with u.set_enabled_equivalencies(u.logarithmic()): assert_allclose(t2.to(u.dimensionless_unscaled, np.arange(3.)), lu2.to(lu2.physical_unit, np.arange(3.))) @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 + other with pytest.raises(u.UnitsError): lu1 - other with pytest.raises(u.UnitsError): other - lu1 def test_addition_subtraction_to_non_units_fails(self): lu1 = u.mag(u.Jy) with pytest.raises(TypeError): lu1 + 1. with pytest.raises(TypeError): lu1 - [1., 2., 3.] @pytest.mark.parametrize( 'other', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2*u.mag), u.MagUnit('', 2.*u.mag))) def test_addition_subtraction(self, other): """Check physical units are changed appropriately""" lu1 = u.mag(u.Jy) other_pu = getattr(other, 'physical_unit', u.dimensionless_unscaled) lu_sf = lu1 + other assert lu_sf.is_equivalent(lu1.physical_unit * other_pu) lu_sr = other + lu1 assert lu_sr.is_equivalent(lu1.physical_unit * other_pu) lu_df = lu1 - other assert lu_df.is_equivalent(lu1.physical_unit / other_pu) lu_dr = other - lu1 assert lu_dr.is_equivalent(other_pu / lu1.physical_unit) def test_complicated_addition_subtraction(self): """for fun, a more complicated example of addition and subtraction""" dm0 = u.Unit('DM', 1./(4.*np.pi*(10.*u.pc)**2)) lu_dm = u.mag(dm0) lu_absST = u.STmag - lu_dm assert lu_absST.is_equivalent(u.erg/u.s/u.AA) def test_neg_pos(self): lu1 = u.mag(u.Jy) neg_lu = -lu1 assert neg_lu != lu1 assert neg_lu.physical_unit == u.Jy**-1 assert -neg_lu == lu1 pos_lu = +lu1 assert pos_lu is not lu1 assert pos_lu == lu1 def test_pickle(): lu1 = u.dex(u.cm/u.s**2) s = pickle.dumps(lu1) lu2 = pickle.loads(s) assert lu1 == lu2 def test_hashable(): lu1 = u.dB(u.mW) lu2 = u.dB(u.m) lu3 = u.dB(u.mW) assert hash(lu1) != hash(lu2) assert hash(lu1) == hash(lu3) luset = {lu1, lu2, lu3} assert len(luset) == 2 class TestLogQuantityCreation(object): @pytest.mark.parametrize('lq, lu', zip(lq_subclasses + [u.LogQuantity], lu_subclasses + [u.LogUnit])) def test_logarithmic_quantities(self, lq, lu): """Check logarithmic quantities are all set up correctly""" assert lq._unit_class == lu assert type(lu()._quantity_class(1.)) is lq @pytest.mark.parametrize('lq_cls, physical_unit', itertools.product(lq_subclasses, pu_sample)) def test_subclass_creation(self, lq_cls, physical_unit): """Create LogQuantity subclass objects for some physical units, and basic check on transformations""" value = np.arange(1., 10.) log_q = lq_cls(value * physical_unit) assert log_q.unit.physical_unit == physical_unit assert log_q.unit.function_unit == log_q.unit._default_function_unit assert_allclose(log_q.physical.value, value) with pytest.raises(ValueError): lq_cls(value, physical_unit) @pytest.mark.parametrize( 'unit', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2*u.mag), u.MagUnit('', 2.*u.mag), u.MagUnit(u.Jy, -1*u.mag), u.MagUnit(u.m, -2.*u.mag))) def test_different_units(self, unit): q = u.Magnitude(1.23, unit) assert q.unit.function_unit == getattr(unit, 'function_unit', unit) assert q.unit.physical_unit is getattr(unit, 'physical_unit', u.dimensionless_unscaled) @pytest.mark.parametrize('value, unit', ( (1.*u.mag(u.Jy), None), (1.*u.dex(u.Jy), None), (1.*u.mag(u.W/u.m**2/u.Hz), u.mag(u.Jy)), (1.*u.dex(u.W/u.m**2/u.Hz), u.mag(u.Jy)))) def test_function_values(self, value, unit): lq = u.Magnitude(value, unit) assert lq == value assert lq.unit.function_unit == u.mag assert lq.unit.physical_unit == getattr(unit, 'physical_unit', value.unit.physical_unit) @pytest.mark.parametrize( 'unit', (u.mag(), u.mag(u.Jy), u.mag(u.m), u.MagUnit('', 2.*u.mag), u.MagUnit(u.Jy, -1*u.mag), u.MagUnit(u.m, -2.*u.mag))) def test_indirect_creation(self, unit): q1 = 2.5 * unit assert isinstance(q1, u.Magnitude) assert q1.value == 2.5 assert q1.unit == unit pv = 100. * unit.physical_unit q2 = unit * pv assert q2.unit == unit assert q2.unit.physical_unit == pv.unit assert q2.to_value(unit.physical_unit) == 100. assert (q2._function_view / u.mag).to_value(1) == -5. q3 = unit / 0.4 assert q3 == q1 def test_from_view(self): # Cannot view a physical quantity as a function quantity, since the # values would change. q = [100., 1000.] * u.cm/u.s**2 with pytest.raises(TypeError): q.view(u.Dex) # But fine if we have the right magnitude. q = [2., 3.] * u.dex lq = q.view(u.Dex) assert isinstance(lq, u.Dex) assert lq.unit.physical_unit == u.dimensionless_unscaled assert np.all(q == lq) def test_using_quantity_class(self): """Check that we can use Quantity if we have subok=True""" # following issue #5851 lu = u.dex(u.AA) with pytest.raises(u.UnitTypeError): u.Quantity(1., lu) q = u.Quantity(1., lu, subok=True) assert type(q) is lu._quantity_class def test_conversion_to_and_from_physical_quantities(): """Ensures we can convert from regular quantities.""" mst = [10., 12., 14.] * u.STmag flux_lambda = mst.physical mst_roundtrip = flux_lambda.to(u.STmag) # check we return a logquantity; see #5178. assert isinstance(mst_roundtrip, u.Magnitude) assert mst_roundtrip.unit == mst.unit assert_allclose(mst_roundtrip.value, mst.value) wave = [4956.8, 4959.55, 4962.3] * u.AA flux_nu = mst.to(u.Jy, equivalencies=u.spectral_density(wave)) mst_roundtrip2 = flux_nu.to(u.STmag, u.spectral_density(wave)) assert isinstance(mst_roundtrip2, u.Magnitude) assert mst_roundtrip2.unit == mst.unit assert_allclose(mst_roundtrip2.value, mst.value) def test_quantity_decomposition(): lq = 10.*u.mag(u.Jy) assert lq.decompose() == lq assert lq.decompose().unit.physical_unit.bases == [u.kg, u.s] assert lq.si == lq assert lq.si.unit.physical_unit.bases == [u.kg, u.s] assert lq.cgs == lq assert lq.cgs.unit.physical_unit.bases == [u.g, u.s] class TestLogQuantityViews(object): def setup(self): self.lq = u.Magnitude(np.arange(10.) * u.Jy) self.lq2 = u.Magnitude(np.arange(5.)) def test_value_view(self): lq_value = self.lq.value assert type(lq_value) is np.ndarray lq_value[2] = -1. assert np.all(self.lq.value == lq_value) def test_function_view(self): lq_fv = self.lq._function_view assert type(lq_fv) is u.Quantity assert lq_fv.unit is self.lq.unit.function_unit lq_fv[3] = -2. * lq_fv.unit assert np.all(self.lq.value == lq_fv.value) def test_quantity_view(self): # Cannot view as Quantity, since the unit cannot be represented. with pytest.raises(TypeError): self.lq.view(u.Quantity) # But a dimensionless one is fine. q2 = self.lq2.view(u.Quantity) assert q2.unit is u.mag assert np.all(q2.value == self.lq2.value) lq3 = q2.view(u.Magnitude) assert type(lq3.unit) is u.MagUnit assert lq3.unit.physical_unit == u.dimensionless_unscaled assert np.all(lq3 == self.lq2) class TestLogQuantitySlicing(object): def test_item_get_and_set(self): lq1 = u.Magnitude(np.arange(1., 11.)*u.Jy) assert lq1[9] == u.Magnitude(10.*u.Jy) lq1[2] = 100.*u.Jy assert lq1[2] == u.Magnitude(100.*u.Jy) with pytest.raises(u.UnitsError): lq1[2] = 100.*u.m with pytest.raises(u.UnitsError): lq1[2] = 100.*u.mag with pytest.raises(u.UnitsError): lq1[2] = u.Magnitude(100.*u.m) assert lq1[2] == u.Magnitude(100.*u.Jy) def test_slice_get_and_set(self): lq1 = u.Magnitude(np.arange(1., 10.)*u.Jy) lq1[2:4] = 100.*u.Jy assert np.all(lq1[2:4] == u.Magnitude(100.*u.Jy)) with pytest.raises(u.UnitsError): lq1[2:4] = 100.*u.m with pytest.raises(u.UnitsError): lq1[2:4] = 100.*u.mag with pytest.raises(u.UnitsError): lq1[2:4] = u.Magnitude(100.*u.m) assert np.all(lq1[2] == u.Magnitude(100.*u.Jy)) class TestLogQuantityArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other quantities is only possible when the physical unit is dimensionless, and that this turns the result into a normal quantity.""" lq = u.Magnitude(np.arange(1., 11.)*u.Jy) with pytest.raises(u.UnitsError): lq * (1.*u.m) with pytest.raises(u.UnitsError): (1.*u.m) * lq with pytest.raises(u.UnitsError): lq / lq for unit in (u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lq / unit lq2 = u.Magnitude(np.arange(1, 11.)) with pytest.raises(u.UnitsError): lq2 * lq with pytest.raises(u.UnitsError): lq2 / lq with pytest.raises(u.UnitsError): lq / lq2 # but dimensionless_unscaled can be cancelled r = lq2 / u.Magnitude(2.) assert r.unit == u.dimensionless_unscaled assert np.all(r.value == lq2.value/2.) # with dimensionless, normal units OK, but return normal quantities tf = lq2 * u.m tr = u.m * lq2 for t in (tf, tr): assert not isinstance(t, type(lq2)) assert t.unit == lq2.unit.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lq2.unit.physical_unit) t = tf / (50.*u.cm) # now we essentially have the same quantity but with a prefactor of 2 assert t.unit.is_equivalent(lq2.unit.function_unit) assert_allclose(t.to(lq2.unit.function_unit), lq2._function_view*2) @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogQuantities to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (say, mag**2) is incompatible.""" lq = u.Magnitude(np.arange(1., 4.)*u.Jy) if power == 0: assert np.all(lq ** power == 1.) elif power == 1: assert np.all(lq ** power == lq) else: with pytest.raises(u.UnitsError): lq ** power # with dimensionless, it works, but falls back to normal quantity # (except for power=1) lq2 = u.Magnitude(np.arange(10.)) t = lq2**power if power == 0: assert t.unit is u.dimensionless_unscaled assert np.all(t.value == 1.) elif power == 1: assert np.all(t == lq2) else: assert not isinstance(t, type(lq2)) assert t.unit == lq2.unit.function_unit ** power with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(u.dimensionless_unscaled) def test_error_on_lq_as_power(self): lq = u.Magnitude(np.arange(1., 4.)*u.Jy) with pytest.raises(TypeError): lq ** lq @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lq = u.Magnitude(np.arange(1., 10.)*u.Jy) q = 1.23 * other with pytest.raises(u.UnitsError): lq + q with pytest.raises(u.UnitsError): lq - q with pytest.raises(u.UnitsError): q - lq @pytest.mark.parametrize( 'other', (1.23 * u.mag, 2.34 * u.mag(), u.Magnitude(3.45 * u.Jy), u.Magnitude(4.56 * u.m), 5.67 * u.Unit(2*u.mag), u.Magnitude(6.78, 2.*u.mag))) def test_addition_subtraction(self, other): """Check that addition/subtraction with quantities with magnitude or MagUnit units works, and that it changes the physical units appropriately.""" lq = u.Magnitude(np.arange(1., 10.)*u.Jy) other_physical = other.to(getattr(other.unit, 'physical_unit', u.dimensionless_unscaled), equivalencies=u.logarithmic()) lq_sf = lq + other

assert_allclose(lq_sf.physical, lq.physical * other_physical)

numpy.testing.utils.assert_allclose

import gym import numpy as np from itertools import product import matplotlib.pyplot as plt def print_policy(Q, env): """ This is a helper function to print a nice policy from the Q function""" moves = [u'←', u'↓',u'→', u'↑'] if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape policy = np.chararray(dims, unicode=True) policy[:] = ' ' for s in range(len(Q)): idx = np.unravel_index(s, dims) policy[idx] = moves[np.argmax(Q[s])] if env.desc[idx] in ['H', 'G']: policy[idx] = u'·' print('\n'.join([''.join([u'{:2}'.format(item) for item in row]) for row in policy])) def plot_V(Q, env): """ This is a helper function to plot the state values from the Q function""" fig = plt.figure() if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape V =

np.zeros(dims)

numpy.zeros

''' <NAME> set up :2020-1-9 intergrate img and label into one file -- fiducial1024_v1 ''' import argparse import sys, os import pickle import random import collections import json import numpy as np import scipy.io as io import scipy.misc as m import matplotlib.pyplot as plt import glob import math import time import threading import multiprocessing as mp from multiprocessing import Pool import re import cv2 # sys.path.append('/lustre/home/gwxie/hope/project/dewarp/datasets/') # /lustre/home/gwxie/program/project/unwarp/perturbed_imgaes/GAN import utils def getDatasets(dir): return os.listdir(dir) class perturbed(utils.BasePerturbed): def __init__(self, path, bg_path, save_path, save_suffix): self.path = path self.bg_path = bg_path self.save_path = save_path self.save_suffix = save_suffix def save_img(self, m, n, fold_curve='fold', repeat_time=4, fiducial_points = 16, relativeShift_position='relativeShift_v2'): origin_img = cv2.imread(self.path, flags=cv2.IMREAD_COLOR) save_img_shape = [512*2, 480*2] # 320 # reduce_value = np.random.choice([2**4, 2**5, 2**6, 2**7, 2**8], p=[0.01, 0.1, 0.4, 0.39, 0.1]) reduce_value = np.random.choice([2*2, 4*2, 8*2, 16*2, 24*2, 32*2, 40*2, 48*2], p=[0.02, 0.18, 0.2, 0.3, 0.1, 0.1, 0.08, 0.02]) # reduce_value = np.random.choice([8*2, 16*2, 24*2, 32*2, 40*2, 48*2], p=[0.01, 0.02, 0.2, 0.4, 0.19, 0.18]) # reduce_value = np.random.choice([16, 24, 32, 40, 48, 64], p=[0.01, 0.1, 0.2, 0.4, 0.2, 0.09]) base_img_shrink = save_img_shape[0] - reduce_value # enlarge_img_shrink = [1024, 768] # enlarge_img_shrink = [896, 672] # 420 enlarge_img_shrink = [512*4, 480*4] # 420 # enlarge_img_shrink = [896*2, 768*2] # 420 # enlarge_img_shrink = [896, 768] # 420 # enlarge_img_shrink = [768, 576] # 420 # enlarge_img_shrink = [640, 480] # 420 '''''' im_lr = origin_img.shape[0] im_ud = origin_img.shape[1] reduce_value_v2 = np.random.choice([2*2, 4*2, 8*2, 16*2, 24*2, 28*2, 32*2, 48*2], p=[0.02, 0.18, 0.2, 0.2, 0.1, 0.1, 0.1, 0.1]) # reduce_value_v2 = np.random.choice([16, 24, 28, 32, 48, 64], p=[0.01, 0.1, 0.2, 0.3, 0.25, 0.14]) if im_lr > im_ud: im_ud = min(int(im_ud / im_lr * base_img_shrink), save_img_shape[1] - reduce_value_v2) im_lr = save_img_shape[0] - reduce_value else: base_img_shrink = save_img_shape[1] - reduce_value im_lr = min(int(im_lr / im_ud * base_img_shrink), save_img_shape[0] - reduce_value_v2) im_ud = base_img_shrink if round(im_lr / im_ud, 2) < 0.5 or round(im_ud / im_lr, 2) < 0.5: repeat_time = min(repeat_time, 8) edge_padding = 3 im_lr -= im_lr % (fiducial_points-1) - (2*edge_padding) # im_lr % (fiducial_points-1) - 1 im_ud -= im_ud % (fiducial_points-1) - (2*edge_padding) # im_ud % (fiducial_points-1) - 1 im_hight = np.linspace(edge_padding, im_lr - edge_padding, fiducial_points, dtype=np.int64) im_wide = np.linspace(edge_padding, im_ud - edge_padding, fiducial_points, dtype=np.int64) # im_lr -= im_lr % (fiducial_points-1) - (1+2*edge_padding) # im_lr % (fiducial_points-1) - 1 # im_ud -= im_ud % (fiducial_points-1) - (1+2*edge_padding) # im_ud % (fiducial_points-1) - 1 # im_hight = np.linspace(edge_padding, im_lr - (1+edge_padding), fiducial_points, dtype=np.int64) # im_wide = np.linspace(edge_padding, im_ud - (1+edge_padding), fiducial_points, dtype=np.int64) im_x, im_y = np.meshgrid(im_hight, im_wide) segment_x = (im_lr) // (fiducial_points-1) segment_y = (im_ud) // (fiducial_points-1) # plt.plot(im_x, im_y, # color='limegreen', # marker='.', # linestyle='') # plt.grid(True) # plt.show() self.origin_img = cv2.resize(origin_img, (im_ud, im_lr), interpolation=cv2.INTER_CUBIC) perturbed_bg_ = getDatasets(self.bg_path) perturbed_bg_img_ = self.bg_path+random.choice(perturbed_bg_) perturbed_bg_img = cv2.imread(perturbed_bg_img_, flags=cv2.IMREAD_COLOR) mesh_shape = self.origin_img.shape[:2] self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 256, dtype=np.float32)#np.zeros_like(perturbed_bg_img) # self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 0, dtype=np.int16)#np.zeros_like(perturbed_bg_img) self.new_shape = self.synthesis_perturbed_img.shape[:2] perturbed_bg_img = cv2.resize(perturbed_bg_img, (save_img_shape[1], save_img_shape[0]), cv2.INPAINT_TELEA) origin_pixel_position = np.argwhere(np.zeros(mesh_shape, dtype=np.uint32) == 0).reshape(mesh_shape[0], mesh_shape[1], 2) pixel_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape(self.new_shape[0], self.new_shape[1], 2) self.perturbed_xy_ = np.zeros((self.new_shape[0], self.new_shape[1], 2)) # self.perturbed_xy_ = pixel_position.copy().astype(np.float32) # fiducial_points_grid = origin_pixel_position[im_x, im_y] self.synthesis_perturbed_label = np.zeros((self.new_shape[0], self.new_shape[1], 2)) x_min, y_min, x_max, y_max = self.adjust_position_v2(0, 0, mesh_shape[0], mesh_shape[1], save_img_shape) origin_pixel_position += [x_min, y_min] x_min, y_min, x_max, y_max = self.adjust_position(0, 0, mesh_shape[0], mesh_shape[1]) x_shift = random.randint(-enlarge_img_shrink[0]//16, enlarge_img_shrink[0]//16) y_shift = random.randint(-enlarge_img_shrink[1]//16, enlarge_img_shrink[1]//16) x_min += x_shift x_max += x_shift y_min += y_shift y_max += y_shift '''im_x,y''' im_x += x_min im_y += y_min self.synthesis_perturbed_img[x_min:x_max, y_min:y_max] = self.origin_img self.synthesis_perturbed_label[x_min:x_max, y_min:y_max] = origin_pixel_position synthesis_perturbed_img_map = self.synthesis_perturbed_img.copy() synthesis_perturbed_label_map = self.synthesis_perturbed_label.copy() foreORbackground_label = np.full((mesh_shape), 1, dtype=np.int16) foreORbackground_label_map = np.full((self.new_shape), 0, dtype=np.int16) foreORbackground_label_map[x_min:x_max, y_min:y_max] = foreORbackground_label # synthesis_perturbed_img_map = self.pad(self.synthesis_perturbed_img.copy(), x_min, y_min, x_max, y_max) # synthesis_perturbed_label_map = self.pad(synthesis_perturbed_label_map, x_min, y_min, x_max, y_max) '''*****************************************************************''' is_normalizationFun_mixture = self.is_perform(0.2, 0.8) # if not is_normalizationFun_mixture: normalizationFun_0_1 = False # normalizationFun_0_1 = self.is_perform(0.5, 0.5) if fold_curve == 'fold': fold_curve_random = True # is_normalizationFun_mixture = False normalizationFun_0_1 = self.is_perform(0.2, 0.8) if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: fold_curve_random = self.is_perform(0.1, 0.9) # False # self.is_perform(0.01, 0.99) alpha_perturbed = random.randint(80, 160) / 100 # is_normalizationFun_mixture = False # self.is_perform(0.01, 0.99) synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) # synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 0, dtype=np.int16) synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) alpha_perturbed_change = self.is_perform(0.5, 0.5) p_pp_choice = self.is_perform(0.8, 0.2) if fold_curve == 'fold' else self.is_perform(0.1, 0.9) for repeat_i in range(repeat_time): if alpha_perturbed_change: if fold_curve == 'fold': if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: alpha_perturbed = random.randint(80, 160) / 100 '''''' linspace_x = [0, (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - 1] linspace_y = [0, (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - 1] linspace_x_seq = [1, 2, 3] linspace_y_seq = [1, 2, 3] r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_p = np.array( [random.randint(linspace_x[r_x-1] * 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 if ((r_x == 1 or r_x == 3) and (r_y == 1 or r_y == 3)) and p_pp_choice: linspace_x_seq.remove(r_x) linspace_y_seq.remove(r_y) r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_pp = np.array( [random.randint(linspace_x[r_x-1] * 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 # perturbed_p, perturbed_pp = np.array( # [random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) \ # , np.array([random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) # perturbed_p, perturbed_pp = np.array( # [random.randint((self.new_shape[0]-im_lr)//2*10, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) * 10) / 10, # random.randint((self.new_shape[1]-im_ud)//2*10, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) * 10) / 10]) \ # , np.array([random.randint((self.new_shape[0]-im_lr)//2*10, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) * 10) / 10, # random.randint((self.new_shape[1]-im_ud)//2*10, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) * 10) / 10]) '''''' perturbed_vp = perturbed_pp - perturbed_p perturbed_vp_norm = np.linalg.norm(perturbed_vp) perturbed_distance_vertex_and_line = np.dot((perturbed_p - pixel_position), perturbed_vp) / perturbed_vp_norm '''''' # perturbed_v = np.array([random.randint(-3000, 3000) / 100, random.randint(-3000, 3000) / 100]) # perturbed_v = np.array([random.randint(-4000, 4000) / 100, random.randint(-4000, 4000) / 100]) if fold_curve == 'fold' and self.is_perform(0.6, 0.4): # self.is_perform(0.3, 0.7): # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) perturbed_v = np.array([random.randint(-10000, 10000) / 100, random.randint(-10000, 10000) / 100]) # perturbed_v = np.array([random.randint(-11000, 11000) / 100, random.randint(-11000, 11000) / 100]) else: # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) # perturbed_v = np.array([random.randint(-16000, 16000) / 100, random.randint(-16000, 16000) / 100]) perturbed_v = np.array([random.randint(-8000, 8000) / 100, random.randint(-8000, 8000) / 100]) # perturbed_v = np.array([random.randint(-3500, 3500) / 100, random.randint(-3500, 3500) / 100]) # perturbed_v = np.array([random.randint(-600, 600) / 10, random.randint(-600, 600) / 10]) '''''' if fold_curve == 'fold': if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) '''''' if fold_curve_random: # omega_perturbed = (alpha_perturbed+0.2) / (perturbed_d + alpha_perturbed) # omega_perturbed = alpha_perturbed**perturbed_d omega_perturbed = alpha_perturbed / (perturbed_d + alpha_perturbed) else: omega_perturbed = 1 - perturbed_d ** alpha_perturbed '''shadow''' if self.is_perform(0.6, 0.4): synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] = np.minimum(np.maximum(synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] - np.int16(np.round(omega_perturbed[x_min:x_max, y_min:y_max].repeat(3).reshape(x_max-x_min, y_max-y_min, 3) * abs(np.linalg.norm(perturbed_v//2))*np.array([0.4-random.random()*0.1, 0.4-random.random()*0.1, 0.4-random.random()*0.1]))), 0), 255) '''''' if relativeShift_position in ['position', 'relativeShift_v2']: self.perturbed_xy_ += np.array([omega_perturbed * perturbed_v[0], omega_perturbed * perturbed_v[1]]).transpose(1, 2, 0) else: print('relativeShift_position error') exit() ''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 # synthesis_perturbed_img = np.around(synthesis_perturbed_img).astype(np.uint8) synthesis_perturbed_label[:, :, 0] *= foreORbackground_label synthesis_perturbed_label[:, :, 1] *= foreORbackground_label synthesis_perturbed_img[:, :, 0] *= foreORbackground_label synthesis_perturbed_img[:, :, 1] *= foreORbackground_label synthesis_perturbed_img[:, :, 2] *= foreORbackground_label self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label ''' '''perspective''' perspective_shreshold = random.randint(26, 36)*10 # 280 x_min_per, y_min_per, x_max_per, y_max_per = self.adjust_position(perspective_shreshold, perspective_shreshold, self.new_shape[0]-perspective_shreshold, self.new_shape[1]-perspective_shreshold) pts1 = np.float32([[x_min_per, y_min_per], [x_max_per, y_min_per], [x_min_per, y_max_per], [x_max_per, y_max_per]]) e_1_ = x_max_per - x_min_per e_2_ = y_max_per - y_min_per e_3_ = e_2_ e_4_ = e_1_ perspective_shreshold_h = e_1_*0.02 perspective_shreshold_w = e_2_*0.02 a_min_, a_max_ = 70, 110 # if self.is_perform(1, 0): if fold_curve == 'curve' and self.is_perform(0.5, 0.5): if self.is_perform(0.5, 0.5): while True: pts2 = np.around( np.float32([[x_min_per - (random.random()) * perspective_shreshold, y_min_per + (random.random()) * perspective_shreshold], [x_max_per - (random.random()) * perspective_shreshold, y_min_per - (random.random()) * perspective_shreshold], [x_min_per + (random.random()) * perspective_shreshold, y_max_per + (random.random()) * perspective_shreshold], [x_max_per + (random.random()) * perspective_shreshold, y_max_per - (random.random()) * perspective_shreshold]])) # right e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break else: while True: pts2 = np.around( np.float32([[x_min_per + (random.random()) * perspective_shreshold, y_min_per - (random.random()) * perspective_shreshold], [x_max_per + (random.random()) * perspective_shreshold, y_min_per + (random.random()) * perspective_shreshold], [x_min_per - (random.random()) * perspective_shreshold, y_max_per - (random.random()) * perspective_shreshold], [x_max_per - (random.random()) * perspective_shreshold, y_max_per + (random.random()) * perspective_shreshold]])) e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break else: while True: pts2 = np.around(np.float32([[x_min_per+(random.random()-0.5)*perspective_shreshold, y_min_per+(random.random()-0.5)*perspective_shreshold], [x_max_per+(random.random()-0.5)*perspective_shreshold, y_min_per+(random.random()-0.5)*perspective_shreshold], [x_min_per+(random.random()-0.5)*perspective_shreshold, y_max_per+(random.random()-0.5)*perspective_shreshold], [x_max_per+(random.random()-0.5)*perspective_shreshold, y_max_per+(random.random()-0.5)*perspective_shreshold]])) e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break M = cv2.getPerspectiveTransform(pts1, pts2) one = np.ones((self.new_shape[0], self.new_shape[1], 1), dtype=np.int16) matr = np.dstack((pixel_position, one)) new = np.dot(M, matr.reshape(-1, 3).T).T.reshape(self.new_shape[0], self.new_shape[1], 3) x = new[:, :, 0]/new[:, :, 2] y = new[:, :, 1]/new[:, :, 2] perturbed_xy_ = np.dstack((x, y)) # perturbed_xy_round_int = np.around(cv2.bilateralFilter(perturbed_xy_round_int, 9, 75, 75)) # perturbed_xy_round_int = np.around(cv2.blur(perturbed_xy_, (17, 17))) # perturbed_xy_round_int = cv2.blur(perturbed_xy_round_int, (17, 17)) # perturbed_xy_round_int = cv2.GaussianBlur(perturbed_xy_round_int, (7, 7), 0) perturbed_xy_ = perturbed_xy_-np.min(perturbed_xy_.T.reshape(2, -1), 1) # perturbed_xy_round_int = np.around(perturbed_xy_round_int-np.min(perturbed_xy_round_int.T.reshape(2, -1), 1)).astype(np.int16) self.perturbed_xy_ += perturbed_xy_ '''perspective end''' '''to img''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) # self.perturbed_xy_ = cv2.blur(self.perturbed_xy_, (7, 7)) self.perturbed_xy_ = cv2.GaussianBlur(self.perturbed_xy_, (7, 7), 0) '''get fiducial points''' fiducial_points_coordinate = self.perturbed_xy_[im_x, im_y] vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label self.foreORbackground_label = foreORbackground_label '''draw fiducial points stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_img.copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1,2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[1] + math.ceil(stepSize / 2), l[0] + math.ceil(stepSize / 2)), 5, (0, 0, 255), -1) cv2.imwrite('/lustre/home/gwxie/program/project/unwarp/unwarp_perturbed/TPS/img/cv_TPS_large.jpg', fiducial_points_synthesis_perturbed_img) ''' '''clip''' perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = -1, -1, self.new_shape[0], self.new_shape[1] for x in range(self.new_shape[0] // 2, perturbed_x_max): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and perturbed_x_max - 1 > x: perturbed_x_max = x break for x in range(self.new_shape[0] // 2, perturbed_x_min, -1): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and x > 0: perturbed_x_min = x break for y in range(self.new_shape[1] // 2, perturbed_y_max): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and perturbed_y_max - 1 > y: perturbed_y_max = y break for y in range(self.new_shape[1] // 2, perturbed_y_min, -1): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and y > 0: perturbed_y_min = y break if perturbed_x_min == 0 or perturbed_x_max == self.new_shape[0] or perturbed_y_min == self.new_shape[1] or perturbed_y_max == self.new_shape[1]: raise Exception('clip error') if perturbed_x_max - perturbed_x_min < im_lr//2 or perturbed_y_max - perturbed_y_min < im_ud//2: raise Exception('clip error') perfix_ = self.save_suffix+'_'+str(m)+'_'+str(n) is_shrink = False if perturbed_x_max - perturbed_x_min > save_img_shape[0] or perturbed_y_max - perturbed_y_min > save_img_shape[1]: is_shrink = True synthesis_perturbed_img = cv2.resize(self.synthesis_perturbed_img[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) synthesis_perturbed_label = cv2.resize(self.synthesis_perturbed_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) foreORbackground_label = cv2.resize(self.foreORbackground_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 '''shrink fiducial points''' center_x_l, center_y_l = perturbed_x_min + (perturbed_x_max - perturbed_x_min) // 2, perturbed_y_min + (perturbed_y_max - perturbed_y_min) // 2 fiducial_points_coordinate_copy = fiducial_points_coordinate.copy() shrink_x = im_lr/(perturbed_x_max - perturbed_x_min) shrink_y = im_ud/(perturbed_y_max - perturbed_y_min) fiducial_points_coordinate *= [shrink_x, shrink_y] center_x_l *= shrink_x center_y_l *= shrink_y # fiducial_points_coordinate[1:, 1:] *= [shrink_x, shrink_y] # fiducial_points_coordinate[1:, :1, 0] *= shrink_x # fiducial_points_coordinate[:1, 1:, 1] *= shrink_y # perturbed_x_min_copy, perturbed_y_min_copy, perturbed_x_max_copy, perturbed_y_max_copy = perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = self.adjust_position_v2(0, 0, im_lr, im_ud, self.new_shape) self.synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) self.synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) self.foreORbackground_label = np.zeros_like(self.foreORbackground_label) self.synthesis_perturbed_img[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_img self.synthesis_perturbed_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_label self.foreORbackground_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max] = foreORbackground_label center_x, center_y = perturbed_x_min + (perturbed_x_max - perturbed_x_min) // 2, perturbed_y_min + (perturbed_y_max - perturbed_y_min) // 2 if is_shrink: fiducial_points_coordinate += [center_x-center_x_l, center_y-center_y_l] '''draw fiducial points stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_img.copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1, 2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[1] + math.ceil(stepSize / 2), l[0] + math.ceil(stepSize / 2)), 5, (0, 0, 255), -1) cv2.imwrite('/lustre/home/gwxie/program/project/unwarp/unwarp_perturbed/TPS/img/cv_TPS_small.jpg',fiducial_points_synthesis_perturbed_img) ''' self.new_shape = save_img_shape self.synthesis_perturbed_img = self.synthesis_perturbed_img[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2, :].copy() self.synthesis_perturbed_label = self.synthesis_perturbed_label[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2, :].copy() self.foreORbackground_label = self.foreORbackground_label[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2].copy() perturbed_x_ = max(self.new_shape[0] - (perturbed_x_max - perturbed_x_min), 0) perturbed_x_min = perturbed_x_ // 2 perturbed_x_max = self.new_shape[0] - perturbed_x_ // 2 if perturbed_x_%2 == 0 else self.new_shape[0] - (perturbed_x_ // 2 + 1) perturbed_y_ = max(self.new_shape[1] - (perturbed_y_max - perturbed_y_min), 0) perturbed_y_min = perturbed_y_ // 2 perturbed_y_max = self.new_shape[1] - perturbed_y_ // 2 if perturbed_y_%2 == 0 else self.new_shape[1] - (perturbed_y_ // 2 + 1) '''clip perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = -1, -1, self.new_shape[0], self.new_shape[1] for x in range(self.new_shape[0] // 2, perturbed_x_max): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and perturbed_x_max - 1 > x: perturbed_x_max = x break for x in range(self.new_shape[0] // 2, perturbed_x_min, -1): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and x > 0: perturbed_x_min = x break for y in range(self.new_shape[1] // 2, perturbed_y_max): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and perturbed_y_max - 1 > y: perturbed_y_max = y break for y in range(self.new_shape[1] // 2, perturbed_y_min, -1): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and y > 0: perturbed_y_min = y break center_x, center_y = perturbed_x_min+(perturbed_x_max - perturbed_x_min)//2, perturbed_y_min+(perturbed_y_max - perturbed_y_min)//2 perfix_ = self.save_suffix+'_'+str(m)+'_'+str(n) self.new_shape = save_img_shape perturbed_x_ = max(self.new_shape[0] - (perturbed_x_max - perturbed_x_min), 0) perturbed_x_min = perturbed_x_ // 2 perturbed_x_max = self.new_shape[0] - perturbed_x_ // 2 if perturbed_x_%2 == 0 else self.new_shape[0] - (perturbed_x_ // 2 + 1) perturbed_y_ = max(self.new_shape[1] - (perturbed_y_max - perturbed_y_min), 0) perturbed_y_min = perturbed_y_ // 2 perturbed_y_max = self.new_shape[1] - perturbed_y_ // 2 if perturbed_y_%2 == 0 else self.new_shape[1] - (perturbed_y_ // 2 + 1) self.synthesis_perturbed_img = self.synthesis_perturbed_img[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2, :].copy() self.synthesis_perturbed_label = self.synthesis_perturbed_label[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2, :].copy() self.foreORbackground_label = self.foreORbackground_label[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2].copy() ''' '''save''' pixel_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape(self.new_shape[0], self.new_shape[1], 2) if relativeShift_position == 'relativeShift_v2': self.synthesis_perturbed_label -= pixel_position fiducial_points_coordinate -= [center_x - self.new_shape[0] // 2, center_y - self.new_shape[1] // 2] self.synthesis_perturbed_label[:, :, 0] *= self.foreORbackground_label self.synthesis_perturbed_label[:, :, 1] *= self.foreORbackground_label self.synthesis_perturbed_img[:, :, 0] *= self.foreORbackground_label self.synthesis_perturbed_img[:, :, 1] *= self.foreORbackground_label self.synthesis_perturbed_img[:, :, 2] *= self.foreORbackground_label ''' synthesis_perturbed_img_filter = self.synthesis_perturbed_img.copy() synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (3, 3), 0) # if self.is_perform(0.9, 0.1) or repeat_time > 5: # # if self.is_perform(0.1, 0.9) and repeat_time > 9: # # synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (7, 7), 0) # # else: # synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (5, 5), 0) # else: # synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (3, 3), 0) self.synthesis_perturbed_img[self.foreORbackground_label == 1] = synthesis_perturbed_img_filter[self.foreORbackground_label == 1] ''' ''' perturbed_bg_img = perturbed_bg_img.astype(np.float32) perturbed_bg_img[:, :, 0] *= 1 - self.foreORbackground_label perturbed_bg_img[:, :, 1] *= 1 - self.foreORbackground_label perturbed_bg_img[:, :, 2] *= 1 - self.foreORbackground_label self.synthesis_perturbed_img += perturbed_bg_img HSV perturbed_bg_img = perturbed_bg_img.astype(np.float32) if self.is_perform(0.1, 0.9): if self.is_perform(0.2, 0.8): synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_RGB2HSV) H_, S_, V_ = (random.random()-0.2)*20, (random.random()-0.2)/8, (random.random()-0.2)*20 synthesis_perturbed_img_clip_HSV[:, :, 0], synthesis_perturbed_img_clip_HSV[:, :, 1], synthesis_perturbed_img_clip_HSV[:, :, 2] = synthesis_perturbed_img_clip_HSV[:, :, 0]-H_, synthesis_perturbed_img_clip_HSV[:, :, 1]-S_, synthesis_perturbed_img_clip_HSV[:, :, 2]-V_ synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_HSV2RGB) perturbed_bg_img[:, :, 0] *= 1-self.foreORbackground_label perturbed_bg_img[:, :, 1] *= 1-self.foreORbackground_label perturbed_bg_img[:, :, 2] *= 1-self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV else: perturbed_bg_img_HSV = perturbed_bg_img perturbed_bg_img_HSV = cv2.cvtColor(perturbed_bg_img_HSV, cv2.COLOR_RGB2HSV) H_, S_, V_ = (random.random()-0.5)*20, (random.random()-0.5)/8, (random.random()-0.2)*20 perturbed_bg_img_HSV[:, :, 0], perturbed_bg_img_HSV[:, :, 1], perturbed_bg_img_HSV[:, :, 2] = perturbed_bg_img_HSV[:, :, 0]-H_, perturbed_bg_img_HSV[:, :, 1]-S_, perturbed_bg_img_HSV[:, :, 2]-V_ perturbed_bg_img_HSV = cv2.cvtColor(perturbed_bg_img_HSV, cv2.COLOR_HSV2RGB) perturbed_bg_img_HSV[:, :, 0] *= 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 1] *= 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 2] *= 1-self.foreORbackground_label self.synthesis_perturbed_img += perturbed_bg_img_HSV # self.synthesis_perturbed_img[np.sum(self.synthesis_perturbed_img, 2) == 771] = perturbed_bg_img_HSV[np.sum(self.synthesis_perturbed_img, 2) == 771] else: synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() perturbed_bg_img[:, :, 0] *= 1 - self.foreORbackground_label perturbed_bg_img[:, :, 1] *= 1 - self.foreORbackground_label perturbed_bg_img[:, :, 2] *= 1 - self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img # synthesis_perturbed_img_clip_HSV[np.sum(self.synthesis_perturbed_img, 2) == 771] = perturbed_bg_img[np.sum(self.synthesis_perturbed_img, 2) == 771] synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_RGB2HSV) H_, S_, V_ = (random.random()-0.5)*20, (random.random()-0.5)/10, (random.random()-0.4)*20 synthesis_perturbed_img_clip_HSV[:, :, 0], synthesis_perturbed_img_clip_HSV[:, :, 1], synthesis_perturbed_img_clip_HSV[:, :, 2] = synthesis_perturbed_img_clip_HSV[:, :, 0]-H_, synthesis_perturbed_img_clip_HSV[:, :, 1]-S_, synthesis_perturbed_img_clip_HSV[:, :, 2]-V_ synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_HSV2RGB) self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV ''' '''HSV_v2''' perturbed_bg_img = perturbed_bg_img.astype(np.float32) # if self.is_perform(1, 0): # if self.is_perform(1, 0): if self.is_perform(0.1, 0.9): if self.is_perform(0.2, 0.8): synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() synthesis_perturbed_img_clip_HSV = self.HSV_v1(synthesis_perturbed_img_clip_HSV) perturbed_bg_img[:, :, 0] *= 1-self.foreORbackground_label perturbed_bg_img[:, :, 1] *= 1-self.foreORbackground_label perturbed_bg_img[:, :, 2] *= 1-self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV else: perturbed_bg_img_HSV = perturbed_bg_img perturbed_bg_img_HSV = self.HSV_v1(perturbed_bg_img_HSV) perturbed_bg_img_HSV[:, :, 0] *= 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 1] *= 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 2] *= 1-self.foreORbackground_label self.synthesis_perturbed_img += perturbed_bg_img_HSV # self.synthesis_perturbed_img[np.sum(self.synthesis_perturbed_img, 2) == 771] = perturbed_bg_img_HSV[np.sum(self.synthesis_perturbed_img, 2) == 771] else: synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() perturbed_bg_img[:, :, 0] *= 1 - self.foreORbackground_label perturbed_bg_img[:, :, 1] *= 1 - self.foreORbackground_label perturbed_bg_img[:, :, 2] *= 1 - self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img synthesis_perturbed_img_clip_HSV = self.HSV_v1(synthesis_perturbed_img_clip_HSV) self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV '''''' # cv2.imwrite(self.save_path+'clip/'+perfix_+'_'+fold_curve+str(perturbed_time)+'-'+str(repeat_time)+'.png', synthesis_perturbed_img_clip) self.synthesis_perturbed_img[self.synthesis_perturbed_img < 0] = 0 self.synthesis_perturbed_img[self.synthesis_perturbed_img > 255] = 255 self.synthesis_perturbed_img = np.around(self.synthesis_perturbed_img).astype(np.uint8) label = np.zeros_like(self.synthesis_perturbed_img, dtype=np.float32) label[:, :, :2] = self.synthesis_perturbed_label label[:, :, 2] = self.foreORbackground_label # grey = np.around(self.synthesis_perturbed_img[:, :, 0] * 0.2989 + self.synthesis_perturbed_img[:, :, 1] * 0.5870 + self.synthesis_perturbed_img[:, :, 0] * 0.1140).astype(np.int16) # synthesis_perturbed_grey = np.concatenate((grey.reshape(self.new_shape[0], self.new_shape[1], 1), label), axis=2) synthesis_perturbed_color =

np.concatenate((self.synthesis_perturbed_img, label), axis=2)

numpy.concatenate

''' <NAME> set up :2020-1-9 intergrate img and label into one file -- fiducial1024_v1 ''' import argparse import sys, os import pickle import random import collections import json import numpy as np import scipy.io as io import scipy.misc as m import matplotlib.pyplot as plt import glob import math import time import threading import multiprocessing as mp from multiprocessing import Pool import re import cv2 # sys.path.append('/lustre/home/gwxie/hope/project/dewarp/datasets/') # /lustre/home/gwxie/program/project/unwarp/perturbed_imgaes/GAN import utils def getDatasets(dir): return os.listdir(dir) class perturbed(utils.BasePerturbed): def __init__(self, path, bg_path, save_path, save_suffix): self.path = path self.bg_path = bg_path self.save_path = save_path self.save_suffix = save_suffix def save_img(self, m, n, fold_curve='fold', repeat_time=4, fiducial_points = 16, relativeShift_position='relativeShift_v2'): origin_img = cv2.imread(self.path, flags=cv2.IMREAD_COLOR) save_img_shape = [512*2, 480*2] # 320 # reduce_value = np.random.choice([2**4, 2**5, 2**6, 2**7, 2**8], p=[0.01, 0.1, 0.4, 0.39, 0.1]) reduce_value = np.random.choice([2*2, 4*2, 8*2, 16*2, 24*2, 32*2, 40*2, 48*2], p=[0.02, 0.18, 0.2, 0.3, 0.1, 0.1, 0.08, 0.02]) # reduce_value = np.random.choice([8*2, 16*2, 24*2, 32*2, 40*2, 48*2], p=[0.01, 0.02, 0.2, 0.4, 0.19, 0.18]) # reduce_value = np.random.choice([16, 24, 32, 40, 48, 64], p=[0.01, 0.1, 0.2, 0.4, 0.2, 0.09]) base_img_shrink = save_img_shape[0] - reduce_value # enlarge_img_shrink = [1024, 768] # enlarge_img_shrink = [896, 672] # 420 enlarge_img_shrink = [512*4, 480*4] # 420 # enlarge_img_shrink = [896*2, 768*2] # 420 # enlarge_img_shrink = [896, 768] # 420 # enlarge_img_shrink = [768, 576] # 420 # enlarge_img_shrink = [640, 480] # 420 '''''' im_lr = origin_img.shape[0] im_ud = origin_img.shape[1] reduce_value_v2 = np.random.choice([2*2, 4*2, 8*2, 16*2, 24*2, 28*2, 32*2, 48*2], p=[0.02, 0.18, 0.2, 0.2, 0.1, 0.1, 0.1, 0.1]) # reduce_value_v2 = np.random.choice([16, 24, 28, 32, 48, 64], p=[0.01, 0.1, 0.2, 0.3, 0.25, 0.14]) if im_lr > im_ud: im_ud = min(int(im_ud / im_lr * base_img_shrink), save_img_shape[1] - reduce_value_v2) im_lr = save_img_shape[0] - reduce_value else: base_img_shrink = save_img_shape[1] - reduce_value im_lr = min(int(im_lr / im_ud * base_img_shrink), save_img_shape[0] - reduce_value_v2) im_ud = base_img_shrink if round(im_lr / im_ud, 2) < 0.5 or round(im_ud / im_lr, 2) < 0.5: repeat_time = min(repeat_time, 8) edge_padding = 3 im_lr -= im_lr % (fiducial_points-1) - (2*edge_padding) # im_lr % (fiducial_points-1) - 1 im_ud -= im_ud % (fiducial_points-1) - (2*edge_padding) # im_ud % (fiducial_points-1) - 1 im_hight = np.linspace(edge_padding, im_lr - edge_padding, fiducial_points, dtype=np.int64) im_wide = np.linspace(edge_padding, im_ud - edge_padding, fiducial_points, dtype=np.int64) # im_lr -= im_lr % (fiducial_points-1) - (1+2*edge_padding) # im_lr % (fiducial_points-1) - 1 # im_ud -= im_ud % (fiducial_points-1) - (1+2*edge_padding) # im_ud % (fiducial_points-1) - 1 # im_hight = np.linspace(edge_padding, im_lr - (1+edge_padding), fiducial_points, dtype=np.int64) # im_wide = np.linspace(edge_padding, im_ud - (1+edge_padding), fiducial_points, dtype=np.int64) im_x, im_y = np.meshgrid(im_hight, im_wide) segment_x = (im_lr) // (fiducial_points-1) segment_y = (im_ud) // (fiducial_points-1) # plt.plot(im_x, im_y, # color='limegreen', # marker='.', # linestyle='') # plt.grid(True) # plt.show() self.origin_img = cv2.resize(origin_img, (im_ud, im_lr), interpolation=cv2.INTER_CUBIC) perturbed_bg_ = getDatasets(self.bg_path) perturbed_bg_img_ = self.bg_path+random.choice(perturbed_bg_) perturbed_bg_img = cv2.imread(perturbed_bg_img_, flags=cv2.IMREAD_COLOR) mesh_shape = self.origin_img.shape[:2] self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 256, dtype=np.float32)#np.zeros_like(perturbed_bg_img) # self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 0, dtype=np.int16)#np.zeros_like(perturbed_bg_img) self.new_shape = self.synthesis_perturbed_img.shape[:2] perturbed_bg_img = cv2.resize(perturbed_bg_img, (save_img_shape[1], save_img_shape[0]), cv2.INPAINT_TELEA) origin_pixel_position = np.argwhere(np.zeros(mesh_shape, dtype=np.uint32) == 0).reshape(mesh_shape[0], mesh_shape[1], 2) pixel_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape(self.new_shape[0], self.new_shape[1], 2) self.perturbed_xy_ = np.zeros((self.new_shape[0], self.new_shape[1], 2)) # self.perturbed_xy_ = pixel_position.copy().astype(np.float32) # fiducial_points_grid = origin_pixel_position[im_x, im_y] self.synthesis_perturbed_label = np.zeros((self.new_shape[0], self.new_shape[1], 2)) x_min, y_min, x_max, y_max = self.adjust_position_v2(0, 0, mesh_shape[0], mesh_shape[1], save_img_shape) origin_pixel_position += [x_min, y_min] x_min, y_min, x_max, y_max = self.adjust_position(0, 0, mesh_shape[0], mesh_shape[1]) x_shift = random.randint(-enlarge_img_shrink[0]//16, enlarge_img_shrink[0]//16) y_shift = random.randint(-enlarge_img_shrink[1]//16, enlarge_img_shrink[1]//16) x_min += x_shift x_max += x_shift y_min += y_shift y_max += y_shift '''im_x,y''' im_x += x_min im_y += y_min self.synthesis_perturbed_img[x_min:x_max, y_min:y_max] = self.origin_img self.synthesis_perturbed_label[x_min:x_max, y_min:y_max] = origin_pixel_position synthesis_perturbed_img_map = self.synthesis_perturbed_img.copy() synthesis_perturbed_label_map = self.synthesis_perturbed_label.copy() foreORbackground_label = np.full((mesh_shape), 1, dtype=np.int16) foreORbackground_label_map = np.full((self.new_shape), 0, dtype=np.int16) foreORbackground_label_map[x_min:x_max, y_min:y_max] = foreORbackground_label # synthesis_perturbed_img_map = self.pad(self.synthesis_perturbed_img.copy(), x_min, y_min, x_max, y_max) # synthesis_perturbed_label_map = self.pad(synthesis_perturbed_label_map, x_min, y_min, x_max, y_max) '''*****************************************************************''' is_normalizationFun_mixture = self.is_perform(0.2, 0.8) # if not is_normalizationFun_mixture: normalizationFun_0_1 = False # normalizationFun_0_1 = self.is_perform(0.5, 0.5) if fold_curve == 'fold': fold_curve_random = True # is_normalizationFun_mixture = False normalizationFun_0_1 = self.is_perform(0.2, 0.8) if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: fold_curve_random = self.is_perform(0.1, 0.9) # False # self.is_perform(0.01, 0.99) alpha_perturbed = random.randint(80, 160) / 100 # is_normalizationFun_mixture = False # self.is_perform(0.01, 0.99) synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) # synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 0, dtype=np.int16) synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) alpha_perturbed_change = self.is_perform(0.5, 0.5) p_pp_choice = self.is_perform(0.8, 0.2) if fold_curve == 'fold' else self.is_perform(0.1, 0.9) for repeat_i in range(repeat_time): if alpha_perturbed_change: if fold_curve == 'fold': if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: alpha_perturbed = random.randint(80, 160) / 100 '''''' linspace_x = [0, (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - 1] linspace_y = [0, (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - 1] linspace_x_seq = [1, 2, 3] linspace_y_seq = [1, 2, 3] r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_p = np.array( [random.randint(linspace_x[r_x-1] * 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 if ((r_x == 1 or r_x == 3) and (r_y == 1 or r_y == 3)) and p_pp_choice: linspace_x_seq.remove(r_x) linspace_y_seq.remove(r_y) r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_pp = np.array( [random.randint(linspace_x[r_x-1] * 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 # perturbed_p, perturbed_pp = np.array( # [random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) \ # , np.array([random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) # perturbed_p, perturbed_pp = np.array( # [random.randint((self.new_shape[0]-im_lr)//2*10, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) * 10) / 10, # random.randint((self.new_shape[1]-im_ud)//2*10, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) * 10) / 10]) \ # , np.array([random.randint((self.new_shape[0]-im_lr)//2*10, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) * 10) / 10, # random.randint((self.new_shape[1]-im_ud)//2*10, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) * 10) / 10]) '''''' perturbed_vp = perturbed_pp - perturbed_p perturbed_vp_norm = np.linalg.norm(perturbed_vp) perturbed_distance_vertex_and_line = np.dot((perturbed_p - pixel_position), perturbed_vp) / perturbed_vp_norm '''''' # perturbed_v = np.array([random.randint(-3000, 3000) / 100, random.randint(-3000, 3000) / 100]) # perturbed_v = np.array([random.randint(-4000, 4000) / 100, random.randint(-4000, 4000) / 100]) if fold_curve == 'fold' and self.is_perform(0.6, 0.4): # self.is_perform(0.3, 0.7): # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) perturbed_v = np.array([random.randint(-10000, 10000) / 100, random.randint(-10000, 10000) / 100]) # perturbed_v = np.array([random.randint(-11000, 11000) / 100, random.randint(-11000, 11000) / 100]) else: # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) # perturbed_v = np.array([random.randint(-16000, 16000) / 100, random.randint(-16000, 16000) / 100]) perturbed_v = np.array([random.randint(-8000, 8000) / 100, random.randint(-8000, 8000) / 100]) # perturbed_v = np.array([random.randint(-3500, 3500) / 100, random.randint(-3500, 3500) / 100]) # perturbed_v = np.array([random.randint(-600, 600) / 10, random.randint(-600, 600) / 10]) '''''' if fold_curve == 'fold': if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) '''''' if fold_curve_random: # omega_perturbed = (alpha_perturbed+0.2) / (perturbed_d + alpha_perturbed) # omega_perturbed = alpha_perturbed**perturbed_d omega_perturbed = alpha_perturbed / (perturbed_d + alpha_perturbed) else: omega_perturbed = 1 - perturbed_d ** alpha_perturbed '''shadow''' if self.is_perform(0.6, 0.4): synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] = np.minimum(np.maximum(synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] - np.int16(np.round(omega_perturbed[x_min:x_max, y_min:y_max].repeat(3).reshape(x_max-x_min, y_max-y_min, 3) * abs(np.linalg.norm(perturbed_v//2))*np.array([0.4-random.random()*0.1, 0.4-random.random()*0.1, 0.4-random.random()*0.1]))), 0), 255) '''''' if relativeShift_position in ['position', 'relativeShift_v2']: self.perturbed_xy_ += np.array([omega_perturbed * perturbed_v[0], omega_perturbed * perturbed_v[1]]).transpose(1, 2, 0) else: print('relativeShift_position error') exit() ''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 # synthesis_perturbed_img = np.around(synthesis_perturbed_img).astype(np.uint8) synthesis_perturbed_label[:, :, 0] *= foreORbackground_label synthesis_perturbed_label[:, :, 1] *= foreORbackground_label synthesis_perturbed_img[:, :, 0] *= foreORbackground_label synthesis_perturbed_img[:, :, 1] *= foreORbackground_label synthesis_perturbed_img[:, :, 2] *= foreORbackground_label self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label ''' '''perspective''' perspective_shreshold = random.randint(26, 36)*10 # 280 x_min_per, y_min_per, x_max_per, y_max_per = self.adjust_position(perspective_shreshold, perspective_shreshold, self.new_shape[0]-perspective_shreshold, self.new_shape[1]-perspective_shreshold) pts1 =

np.float32([[x_min_per, y_min_per], [x_max_per, y_min_per], [x_min_per, y_max_per], [x_max_per, y_max_per]])

numpy.float32

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) +

np.cos(5 * time)

numpy.cos

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] *

np.ones(101)

numpy.ones

############################################################################### # @todo add Pilot2-splash-app disclaimer ############################################################################### """ Get's KRAS states """ import MDAnalysis as mda from MDAnalysis.analysis import align from MDAnalysis.lib.mdamath import make_whole import os import numpy as np import math ############## Below section needs to be uncommented ############ import mummi_core import mummi_ras from mummi_core.utils import Naming # # Logger has to be initialized the first thing in the script from logging import getLogger LOGGER = getLogger(__name__) # # Innitilize MuMMI if it has not been done before # MUMMI_ROOT = mummi.init(True) # This is needed so the Naming works below #@TODO fix this so we don't have these on import make them as an init mummi_core.init() dirKRASStates = Naming.dir_res('states') dirKRASStructures = Naming.dir_res('structures') # #RAS_ONLY_macrostate = np.loadtxt(os.path.join(dirKRASStates, "RAS-ONLY.microstates.txt")) RAS_ONLY_macrostate = np.loadtxt(os.path.join(dirKRASStates, "ras-states.txt"),comments='#') # #RAS_RAF_macrostate = np.loadtxt(os.path.join(dirKRASStates, "RAS-RAF.microstates.txt")) RAS_RAF_macrostate = np.loadtxt(os.path.join(dirKRASStates, "ras-raf-states.txt"),comments='#') # Note diffrent number of columns so index change below # TODO: CS, my edits to test # RAS_ONLY_macrostate = np.loadtxt('ras-states.txt') # RAS_RAF_macrostate = np.loadtxt('ras-raf-states.txt') ############## above section needs to be uncommented ############ # TODO: CS, my edits to test # TODO: TSC, The reference structure has to currently be set as the 'RAS-ONLY-reference-structure.gro' # TODO: TSC, path to the reference structure is: mummi_resources/structures/ kras_ref_universe = mda.Universe(os.path.join(dirKRASStructures, "RAS-ONLY-reference-structure.gro")) # kras_ref_universe = mda.Universe("RAS-ONLY-reference-structure.gro") # kras_ref_universe = mda.Universe('AA_pfpatch_000000004641_RAS_RAF2_411.gro') # TODO: CS, not using these for x4 proteins; instead using protein_systems below to set num_res ######### Below hard codes the number of residues within RAS-only and RAS-RAF ########## RAS_only_num_res = 184 RAS_RAF_num_res = 320 ######### Above hard codes the number of residues within RAS-only and RAS-RAF ########## ####### This can be removed # def get_kras(syst, kras_start): # """Gets all atoms for a KRAS protein starting at 'kras_start'.""" # return syst.atoms[kras_start:kras_start+428] ####### This can be removed def get_segids(u): """Identifies the list of segments within the system. Only needs to be called x1 time""" segs = u.segments segs = segs.segids ras_segids = [] rasraf_segids = [] for i in range(len(segs)): # print(segs[i]) if segs[i][-3:] == 'RAS': ras_segids.append(segs[i]) if segs[i][-3:] == 'RAF': rasraf_segids.append(segs[i]) return ras_segids, rasraf_segids def get_protein_info(u,tag): """Uses the segments identified in get_segids to make a list of all proteins in the systems.\ Outputs a list of the first residue number of the protein, and whether it is 'RAS-ONLY', or 'RAS-RAF'.\ The 'tag' input defines what is used to identify the first residue of the protein. i.e. 'resname ACE1 and name BB'.\ Only needs to be called x1 time""" ras_segids, rasraf_segids = get_segids(u) if len(ras_segids) > 0: RAS = u.select_atoms('segid '+ras_segids[0]+' and '+str(tag)) else: RAS = [] if len(rasraf_segids) > 0: RAF = u.select_atoms('segid '+rasraf_segids[0]+' and '+str(tag)) else: RAF = [] protein_info = []#np.empty([len(RAS)+len(RAF),2]) for i in range(len(RAS)): protein_info.append((RAS[i].resid,'RAS-ONLY')) for i in range(len(RAF)): protein_info.append((RAF[i].resid,'RAS-RAF')) ######## sort protein info protein_info = sorted(protein_info) ######## sort protein info return protein_info def get_ref_kras(): """Gets the reference KRAS struct. Only called x1 time when class is loaded""" start_of_g_ref = kras_ref_universe.residues[0].resid ref_selection = 'resid '+str(start_of_g_ref)+':'+str(start_of_g_ref+24)+' ' +\ str(start_of_g_ref+38)+':'+str(start_of_g_ref+54)+' ' +\ str(start_of_g_ref+67)+':'+str(start_of_g_ref+164)+' ' +\ 'and (name CA or name BB)' r2_26r40_56r69_166_ref = kras_ref_universe.select_atoms(str(ref_selection)) return kras_ref_universe.select_atoms(str(ref_selection)).positions - kras_ref_universe.select_atoms(str(ref_selection)).center_of_mass() # Load inital ref frames (only need to do this once) ref0 = get_ref_kras() def getKRASstates(u,kras_indices): """Gets states for all KRAS proteins in path.""" # res_shift = 8 # all_glycine = u.select_atoms("resname GLY") # kras_indices = [] # for i in range(0, len(all_glycine), 26): # kras_indices.append(all_glycine[i].index) ########## Below is taken out of the function so it is only done once ######### # kras_indices = get_protein_info(u,'resname ACE1 and name BB') ########## Above is taken out of the function so it is only done once ######### # CS, for x4 cases: # [{protein_x4: (protein_type, num_res)}] protein_systems = [{'ras4a': ('RAS-ONLY', 185), 'ras4araf': ('RAS-RAF', 321), 'ras': ('RAS-ONLY', 184), 'rasraf': ('RAS-RAF', 320)}] ALLOUT = [] for k in range(len(kras_indices)): start_of_g = kras_indices[k][0] protein_x4 = str(kras_indices[k][1]) try: protein_type = [item[protein_x4] for item in protein_systems][0][0] # 'RAS-ONLY' OR 'RAS-RAF' num_res = [item[protein_x4] for item in protein_systems][0][1] except: LOGGER.error('Check KRas naming between modules') raise Exception('Error: unknown KRas name') # TODO: CS, replacing this comment section with the above, to handle x4 protein types # --------------------------------------- # ALLOUT = [] # for k in range(len(kras_indices)): # start_of_g = kras_indices[k][0] # protein_type = str(kras_indices[k][1]) # ########## BELOW SECTION TO DETERMINE WHICH RESIDUES ARE PART OF THE PROTEIN GROUP - NEEDED FOR PBC REMOVAL ############## # ########## POTENTIALLY REDO WITH A 'HARD-CODED' NUMBER OF RESIDUES PER PROTEIN GROUP (WHETHER RAS-ONLY OR RAS-RAF) ####### # ########## HAS BEEN REDONE WITH A 'HARD-CODED' NUMBER OF RESIDUES PER PROTEIN GROUP (WHETHER RAS-ONLY OR RAS-RAF) ######## # # if len(kras_indices) == 1: # # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(len(u.residues))+' and name BB') ####### HAS TO BE FIXED FOR BACKBONE ATOMS FOR SPECIFIC PROTEIN # # elif len(kras_indices) > 1: # # if k == len(kras_indices)-1: # # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(len(u.residues))+' and name BB') # # else: # # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(kras_indices[k+1][0])+' and name BB') # ########## ABOVE SECTION TO DETERMINE WHICH RESIDUES ARE PART OF THE PROTEIN GROUP - NEEDED FOR PBC REMOVAL ############## # # ########## Below hard codes the number of residues/beads in the RAS-ONLY and RAS-RAF simulations ######################### # if protein_type == 'RAS-ONLY': # num_res = RAS_only_num_res # elif protein_type == 'RAS-RAF': # num_res = RAS_RAF_num_res # ########## Above hard codes the number of residues/beads in the RAS-ONLY and RAS-RAF simulations ######################### # --------------------------------------- # TODO: TSC, I changed the selection below, which can be used for the make_whole... # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(start_of_g+num_res)+' and (name CA or name BB)') krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(start_of_g+num_res)) krases0_BB.guess_bonds() r2_26r40_56r69_166 = u.select_atoms('resid '+str(start_of_g)+':'+str(start_of_g+24)+' ' +\ str(start_of_g+38)+':'+str(start_of_g+54)+' ' +\ str(start_of_g+67)+':'+str(start_of_g+164)+\ ' and (name CA or name BB)') u_selection = \ 'resid '+str(start_of_g)+':'+str(start_of_g+24)+' '+str(start_of_g+38)+':'+str(start_of_g+54)+' ' +\ str(start_of_g+67)+':'+str(start_of_g+164)+' and (name CA or name BB)' mobile0 = u.select_atoms(str(u_selection)).positions - u.select_atoms(str(u_selection)).center_of_mass() # TODO: CS, something wrong with ref0 from get_kras_ref() # just making ref0 = mobile0 to test for now # ref0 = mobile0 # TSC removed this R, RMSD_junk = align.rotation_matrix(mobile0, ref0) ######## TODO: TSC, Adjusted for AA lipid names ######## # lipids = u.select_atoms('resname POPX POPC PAPC POPE DIPE DPSM PAPS PAP6 CHOL') lipids = u.select_atoms('resname POPC PAPC POPE DIPE SSM PAPS SAPI CHL1') coords = ref0 RotMat = [] OS = [] r152_165 = krases0_BB.select_atoms('resid '+str(start_of_g+150)+':'+str(start_of_g+163)+' and (name CA or name BB)') r65_74 = krases0_BB.select_atoms('resid '+str(start_of_g+63)+':'+str(start_of_g+72)+' and (name CA or name BB)') timeframes = [] # TODO: CS, for AA need bonds to run make_whole() # krases0_BB.guess_bonds() # TODO: CS, turn off for now to test beyond this point ''' *** for AA, need to bring that back on once all else runs *** ''' # @Tim and <NAME>. this was commented out - please check. #make_whole(krases0_BB) j, rmsd_junk = mda.analysis.align.rotation_matrix((r2_26r40_56r69_166.positions-r2_26r40_56r69_166.center_of_mass()), coords) RotMat.append(j) OS.append(r65_74.center_of_mass()-r152_165.center_of_mass()) timeframes.append(u.trajectory.time) if protein_type == 'RAS-RAF': z_pos = [] ############### NEED TO CONFIRM THE SELECTION OF THE RAF LOOP RESIDUES BELOW #################### ############### TODO: TSC, zshifting is set to -1 (instead of -2), as there are ACE caps that are separate residues in AA #zshifting=-1 if protein_x4 == 'rasraf': zshifting = -1 elif protein_x4 == 'ras4araf': zshifting = 0 else: zshifting = 0 LOGGER.error('Found unsupported protein_x4 type') raf_loops_selection = u.select_atoms('resid '+str(start_of_g+zshifting+291)+':'+str(start_of_g+zshifting+294)+' ' +\ str(start_of_g+zshifting+278)+':'+str(start_of_g+zshifting+281)+' ' +\ ' and (name CA or name BB)') ############### NEED TO CONFIRM THE SELECTION OF THE RAF LOOP RESIDUES ABOVE #################### diff = (lipids.center_of_mass()[2]-raf_loops_selection.center_of_mass(unwrap=True)[2])/10 if diff < 0: diff = diff+(u.dimensions[2]/10) z_pos.append(diff) z_pos = np.array(z_pos) RotMatNP = np.array(RotMat) OS = np.array(OS) OA = RotMatNP[:, 2, :]/(((RotMatNP[:, 2, 0]**2)+(RotMatNP[:, 2, 1]**2)+(RotMatNP[:, 2, 2]**2))**0.5)[:, None] OWAS = np.arccos(RotMatNP[:, 2, 2])*180/math.pi OC_temp = np.concatenate((OA, OS), axis=1) t = ((OC_temp[:, 0]*OC_temp[:, 3])+(OC_temp[:, 1]*OC_temp[:, 4]) + (OC_temp[:, 2]*OC_temp[:, 5]))/((OC_temp[:, 0]**2)+(OC_temp[:, 1]**2)+(OC_temp[:, 2]**2)) OC = OA*t[:, None] ORS_tp = np.concatenate((OC, OS), axis=1) ORS_norm = (((ORS_tp[:, 3]-ORS_tp[:, 0])**2)+((ORS_tp[:, 4]-ORS_tp[:, 1])**2)+((ORS_tp[:, 5]-ORS_tp[:, 2])**2))**0.5 ORS = (OS - OC)/ORS_norm[:, None] OACRS =

np.cross(OA, ORS)

numpy.cross

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y =

np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101)

numpy.linspace

from abc import ABCMeta, abstractmethod import os from vmaf.tools.misc import make_absolute_path, run_process from vmaf.tools.stats import ListStats __copyright__ = "Copyright 2016-2018, Netflix, Inc." __license__ = "Apache, Version 2.0" import re import numpy as np import ast from vmaf import ExternalProgramCaller, to_list from vmaf.config import VmafConfig, VmafExternalConfig from vmaf.core.executor import Executor from vmaf.core.result import Result from vmaf.tools.reader import YuvReader class FeatureExtractor(Executor): """ FeatureExtractor takes in a list of assets, and run feature extraction on them, and return a list of corresponding results. A FeatureExtractor must specify a unique type and version combination (by the TYPE and VERSION attribute), so that the Result generated by it can be identified. A derived class of FeatureExtractor must: 1) Override TYPE and VERSION 2) Override _generate_result(self, asset), which call a command-line executable and generate feature scores in a log file. 3) Override _get_feature_scores(self, asset), which read the feature scores from the log file, and return the scores in a dictionary format. For an example, follow VmafFeatureExtractor. """ __metaclass__ = ABCMeta @property @abstractmethod def ATOM_FEATURES(self): raise NotImplementedError def _read_result(self, asset): result = {} result.update(self._get_feature_scores(asset)) executor_id = self.executor_id return Result(asset, executor_id, result) @classmethod def get_scores_key(cls, atom_feature): return "{type}_{atom_feature}_scores".format( type=cls.TYPE, atom_feature=atom_feature) @classmethod def get_score_key(cls, atom_feature): return "{type}_{atom_feature}_score".format( type=cls.TYPE, atom_feature=atom_feature) def _get_feature_scores(self, asset): # routine to read the feature scores from the log file, and return # the scores in a dictionary format. log_file_path = self._get_log_file_path(asset) atom_feature_scores_dict = {} atom_feature_idx_dict = {} for atom_feature in self.ATOM_FEATURES: atom_feature_scores_dict[atom_feature] = [] atom_feature_idx_dict[atom_feature] = 0 with open(log_file_path, 'rt') as log_file: for line in log_file.readlines(): for atom_feature in self.ATOM_FEATURES: re_template = "{af}: ([0-9]+) ([a-zA-Z0-9.-]+)".format(af=atom_feature) mo = re.match(re_template, line) if mo: cur_idx = int(mo.group(1)) assert cur_idx == atom_feature_idx_dict[atom_feature] # parse value, allowing NaN and inf val = float(mo.group(2)) if np.isnan(val) or np.isinf(val): val = None atom_feature_scores_dict[atom_feature].append(val) atom_feature_idx_dict[atom_feature] += 1 continue len_score = len(atom_feature_scores_dict[self.ATOM_FEATURES[0]]) assert len_score != 0 for atom_feature in self.ATOM_FEATURES[1:]: assert len_score == len(atom_feature_scores_dict[atom_feature]), \ "Feature data possibly corrupt. Run cleanup script and try again." feature_result = {} for atom_feature in self.ATOM_FEATURES: scores_key = self.get_scores_key(atom_feature) feature_result[scores_key] = atom_feature_scores_dict[atom_feature] return feature_result class VmafFeatureExtractor(FeatureExtractor): TYPE = "VMAF_feature" # VERSION = '0.1' # vmaf_study; Anush's VIF fix # VERSION = '0.2' # expose vif_num, vif_den, adm_num, adm_den, anpsnr # VERSION = '0.2.1' # expose vif num/den of each scale # VERSION = '0.2.2' # adm abs-->fabs, corrected border handling, uniform reading with option of offset for input YUV, updated VIF corner case # VERSION = '0.2.2b' # expose adm_den/num_scalex # VERSION = '0.2.3' # AVX for VMAF convolution; update adm features by folding noise floor into per coef # VERSION = '0.2.4' # Fix a bug in adm feature passing scale into dwt_quant_step # VERSION = '0.2.4b' # Modify by adding ADM noise floor outside cube root; add derived feature motion2 VERSION = '0.2.4c' # Modify by moving motion2 to c code ATOM_FEATURES = ['vif', 'adm', 'ansnr', 'motion', 'motion2', 'vif_num', 'vif_den', 'adm_num', 'adm_den', 'anpsnr', 'vif_num_scale0', 'vif_den_scale0', 'vif_num_scale1', 'vif_den_scale1', 'vif_num_scale2', 'vif_den_scale2', 'vif_num_scale3', 'vif_den_scale3', 'adm_num_scale0', 'adm_den_scale0', 'adm_num_scale1', 'adm_den_scale1', 'adm_num_scale2', 'adm_den_scale2', 'adm_num_scale3', 'adm_den_scale3', ] DERIVED_ATOM_FEATURES = ['vif_scale0', 'vif_scale1', 'vif_scale2', 'vif_scale3', 'vif2', 'adm2', 'adm3', 'adm_scale0', 'adm_scale1', 'adm_scale2', 'adm_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vmaf_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VmafFeatureExtractor, cls)._post_process_result(result) # adm2 = # (adm_num + ADM2_CONSTANT) / (adm_den + ADM2_CONSTANT) adm2_scores_key = cls.get_scores_key('adm2') adm_num_scores_key = cls.get_scores_key('adm_num') adm_den_scores_key = cls.get_scores_key('adm_den') result.result_dict[adm2_scores_key] = list( (np.array(result.result_dict[adm_num_scores_key]) + cls.ADM2_CONSTANT) / (np.array(result.result_dict[adm_den_scores_key]) + cls.ADM2_CONSTANT) ) # vif_scalei = vif_num_scalei / vif_den_scalei, i = 0, 1, 2, 3 vif_num_scale0_scores_key = cls.get_scores_key('vif_num_scale0') vif_den_scale0_scores_key = cls.get_scores_key('vif_den_scale0') vif_num_scale1_scores_key = cls.get_scores_key('vif_num_scale1') vif_den_scale1_scores_key = cls.get_scores_key('vif_den_scale1') vif_num_scale2_scores_key = cls.get_scores_key('vif_num_scale2') vif_den_scale2_scores_key = cls.get_scores_key('vif_den_scale2') vif_num_scale3_scores_key = cls.get_scores_key('vif_num_scale3') vif_den_scale3_scores_key = cls.get_scores_key('vif_den_scale3') vif_scale0_scores_key = cls.get_scores_key('vif_scale0') vif_scale1_scores_key = cls.get_scores_key('vif_scale1') vif_scale2_scores_key = cls.get_scores_key('vif_scale2') vif_scale3_scores_key = cls.get_scores_key('vif_scale3') result.result_dict[vif_scale0_scores_key] = list( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) ) result.result_dict[vif_scale1_scores_key] = list( (np.array(result.result_dict[vif_num_scale1_scores_key]) /

np.array(result.result_dict[vif_den_scale1_scores_key])

numpy.array

''' <NAME> set up :2020-1-9 intergrate img and label into one file -- fiducial1024_v1 ''' import argparse import sys, os import pickle import random import collections import json import numpy as np import scipy.io as io import scipy.misc as m import matplotlib.pyplot as plt import glob import math import time import threading import multiprocessing as mp from multiprocessing import Pool import re import cv2 # sys.path.append('/lustre/home/gwxie/hope/project/dewarp/datasets/') # /lustre/home/gwxie/program/project/unwarp/perturbed_imgaes/GAN import utils def getDatasets(dir): return os.listdir(dir) class perturbed(utils.BasePerturbed): def __init__(self, path, bg_path, save_path, save_suffix): self.path = path self.bg_path = bg_path self.save_path = save_path self.save_suffix = save_suffix def save_img(self, m, n, fold_curve='fold', repeat_time=4, fiducial_points = 16, relativeShift_position='relativeShift_v2'): origin_img = cv2.imread(self.path, flags=cv2.IMREAD_COLOR) save_img_shape = [512*2, 480*2] # 320 # reduce_value = np.random.choice([2**4, 2**5, 2**6, 2**7, 2**8], p=[0.01, 0.1, 0.4, 0.39, 0.1]) reduce_value = np.random.choice([2*2, 4*2, 8*2, 16*2, 24*2, 32*2, 40*2, 48*2], p=[0.02, 0.18, 0.2, 0.3, 0.1, 0.1, 0.08, 0.02]) # reduce_value = np.random.choice([8*2, 16*2, 24*2, 32*2, 40*2, 48*2], p=[0.01, 0.02, 0.2, 0.4, 0.19, 0.18]) # reduce_value = np.random.choice([16, 24, 32, 40, 48, 64], p=[0.01, 0.1, 0.2, 0.4, 0.2, 0.09]) base_img_shrink = save_img_shape[0] - reduce_value # enlarge_img_shrink = [1024, 768] # enlarge_img_shrink = [896, 672] # 420 enlarge_img_shrink = [512*4, 480*4] # 420 # enlarge_img_shrink = [896*2, 768*2] # 420 # enlarge_img_shrink = [896, 768] # 420 # enlarge_img_shrink = [768, 576] # 420 # enlarge_img_shrink = [640, 480] # 420 '''''' im_lr = origin_img.shape[0] im_ud = origin_img.shape[1] reduce_value_v2 = np.random.choice([2*2, 4*2, 8*2, 16*2, 24*2, 28*2, 32*2, 48*2], p=[0.02, 0.18, 0.2, 0.2, 0.1, 0.1, 0.1, 0.1]) # reduce_value_v2 = np.random.choice([16, 24, 28, 32, 48, 64], p=[0.01, 0.1, 0.2, 0.3, 0.25, 0.14]) if im_lr > im_ud: im_ud = min(int(im_ud / im_lr * base_img_shrink), save_img_shape[1] - reduce_value_v2) im_lr = save_img_shape[0] - reduce_value else: base_img_shrink = save_img_shape[1] - reduce_value im_lr = min(int(im_lr / im_ud * base_img_shrink), save_img_shape[0] - reduce_value_v2) im_ud = base_img_shrink if round(im_lr / im_ud, 2) < 0.5 or round(im_ud / im_lr, 2) < 0.5: repeat_time = min(repeat_time, 8) edge_padding = 3 im_lr -= im_lr % (fiducial_points-1) - (2*edge_padding) # im_lr % (fiducial_points-1) - 1 im_ud -= im_ud % (fiducial_points-1) - (2*edge_padding) # im_ud % (fiducial_points-1) - 1 im_hight = np.linspace(edge_padding, im_lr - edge_padding, fiducial_points, dtype=np.int64) im_wide = np.linspace(edge_padding, im_ud - edge_padding, fiducial_points, dtype=np.int64) # im_lr -= im_lr % (fiducial_points-1) - (1+2*edge_padding) # im_lr % (fiducial_points-1) - 1 # im_ud -= im_ud % (fiducial_points-1) - (1+2*edge_padding) # im_ud % (fiducial_points-1) - 1 # im_hight = np.linspace(edge_padding, im_lr - (1+edge_padding), fiducial_points, dtype=np.int64) # im_wide = np.linspace(edge_padding, im_ud - (1+edge_padding), fiducial_points, dtype=np.int64) im_x, im_y = np.meshgrid(im_hight, im_wide) segment_x = (im_lr) // (fiducial_points-1) segment_y = (im_ud) // (fiducial_points-1) # plt.plot(im_x, im_y, # color='limegreen', # marker='.', # linestyle='') # plt.grid(True) # plt.show() self.origin_img = cv2.resize(origin_img, (im_ud, im_lr), interpolation=cv2.INTER_CUBIC) perturbed_bg_ = getDatasets(self.bg_path) perturbed_bg_img_ = self.bg_path+random.choice(perturbed_bg_) perturbed_bg_img = cv2.imread(perturbed_bg_img_, flags=cv2.IMREAD_COLOR) mesh_shape = self.origin_img.shape[:2] self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 256, dtype=np.float32)#np.zeros_like(perturbed_bg_img) # self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 0, dtype=np.int16)#np.zeros_like(perturbed_bg_img) self.new_shape = self.synthesis_perturbed_img.shape[:2] perturbed_bg_img = cv2.resize(perturbed_bg_img, (save_img_shape[1], save_img_shape[0]), cv2.INPAINT_TELEA) origin_pixel_position = np.argwhere(np.zeros(mesh_shape, dtype=np.uint32) == 0).reshape(mesh_shape[0], mesh_shape[1], 2) pixel_position = np.argwhere(

np.zeros(self.new_shape, dtype=np.uint32)

numpy.zeros

try: import importlib.resources as pkg_resources except ImportError: # Try backported to PY<37 `importlib_resources`. import importlib_resources as pkg_resources from . import images from gym import Env, spaces from time import time import numpy as np from copy import copy import colorsys import pygame from pygame.transform import scale class MinesweeperEnv(Env): def __init__(self, grid_shape=(10, 15), bombs_density=0.1, n_bombs=None, impact_size=3, max_time=999, chicken=False): self.grid_shape = grid_shape self.grid_size = np.prod(grid_shape) self.n_bombs = max(1, int(bombs_density * self.grid_size)) if n_bombs is None else n_bombs self.n_bombs = min(self.grid_size - 1, self.n_bombs) self.flaged_bombs = 0 self.flaged_empty = 0 self.max_time = max_time if impact_size % 2 == 0: raise ValueError('Impact_size must be an odd number !') self.impact_size = impact_size # Define constants self.HIDDEN = 0 self.REVEAL = 1 self.FLAG = 2 self.BOMB = self.impact_size ** 2 # Setting up gym Env conventions nvec_observation = (self.BOMB + 2) * np.ones(self.grid_shape) self.observation_space = spaces.MultiDiscrete(nvec_observation) nvec_action = np.array(self.grid_shape + (2,)) self.action_space = spaces.MultiDiscrete(nvec_action) # Initalize state self.state = np.zeros(self.grid_shape + (2,), dtype=np.uint8) ## Setup bombs places idx =

np.indices(self.grid_shape)

numpy.indices

"""Test the search module""" from collections.abc import Iterable, Sized from io import StringIO from itertools import chain, product from functools import partial import pickle import sys from types import GeneratorType import re import numpy as np import scipy.sparse as sp import pytest from sklearn.utils.fixes import sp_version from sklearn.utils._testing import assert_raises from sklearn.utils._testing import assert_warns from sklearn.utils._testing import assert_warns_message from sklearn.utils._testing import assert_raise_message from sklearn.utils._testing import assert_array_equal from sklearn.utils._testing import assert_array_almost_equal from sklearn.utils._testing import assert_allclose from sklearn.utils._testing import assert_almost_equal from sklearn.utils._testing import ignore_warnings from sklearn.utils._mocking import CheckingClassifier, MockDataFrame from scipy.stats import bernoulli, expon, uniform from sklearn.base import BaseEstimator, ClassifierMixin from sklearn.base import clone from sklearn.exceptions import NotFittedError from sklearn.datasets import make_classification from sklearn.datasets import make_blobs from sklearn.datasets import make_multilabel_classification from sklearn.model_selection import fit_grid_point from sklearn.model_selection import train_test_split from sklearn.model_selection import KFold from sklearn.model_selection import StratifiedKFold from sklearn.model_selection import StratifiedShuffleSplit from sklearn.model_selection import LeaveOneGroupOut from sklearn.model_selection import LeavePGroupsOut from sklearn.model_selection import GroupKFold from sklearn.model_selection import GroupShuffleSplit from sklearn.model_selection import GridSearchCV from sklearn.model_selection import RandomizedSearchCV from sklearn.model_selection import ParameterGrid from sklearn.model_selection import ParameterSampler from sklearn.model_selection._search import BaseSearchCV from sklearn.model_selection._validation import FitFailedWarning from sklearn.svm import LinearSVC, SVC from sklearn.tree import DecisionTreeRegressor from sklearn.tree import DecisionTreeClassifier from sklearn.cluster import KMeans from sklearn.neighbors import KernelDensity from sklearn.neighbors import KNeighborsClassifier from sklearn.metrics import f1_score from sklearn.metrics import recall_score from sklearn.metrics import accuracy_score from sklearn.metrics import make_scorer from sklearn.metrics import roc_auc_score from sklearn.metrics.pairwise import euclidean_distances from sklearn.impute import SimpleImputer from sklearn.pipeline import Pipeline from sklearn.linear_model import Ridge, SGDClassifier, LinearRegression from sklearn.experimental import enable_hist_gradient_boosting # noqa from sklearn.ensemble import HistGradientBoostingClassifier from sklearn.model_selection.tests.common import OneTimeSplitter # Neither of the following two estimators inherit from BaseEstimator, # to test hyperparameter search on user-defined classifiers. class MockClassifier: """Dummy classifier to test the parameter search algorithms""" def __init__(self, foo_param=0): self.foo_param = foo_param def fit(self, X, Y): assert len(X) == len(Y) self.classes_ = np.unique(Y) return self def predict(self, T): return T.shape[0] def transform(self, X): return X + self.foo_param def inverse_transform(self, X): return X - self.foo_param predict_proba = predict predict_log_proba = predict decision_function = predict def score(self, X=None, Y=None): if self.foo_param > 1: score = 1. else: score = 0. return score def get_params(self, deep=False): return {'foo_param': self.foo_param} def set_params(self, **params): self.foo_param = params['foo_param'] return self class LinearSVCNoScore(LinearSVC): """An LinearSVC classifier that has no score method.""" @property def score(self): raise AttributeError X = np.array([[-1, -1], [-2, -1], [1, 1], [2, 1]]) y = np.array([1, 1, 2, 2]) def assert_grid_iter_equals_getitem(grid): assert list(grid) == [grid[i] for i in range(len(grid))] @pytest.mark.parametrize("klass", [ParameterGrid, partial(ParameterSampler, n_iter=10)]) @pytest.mark.parametrize( "input, error_type, error_message", [(0, TypeError, r'Parameter .* is not a dict or a list $0$'), ([{'foo': [0]}, 0], TypeError, r'Parameter .* is not a dict $0$'), ({'foo': 0}, TypeError, "Parameter.* value is not iterable .*" r"$key='foo', value=0$")] ) def test_validate_parameter_input(klass, input, error_type, error_message): with pytest.raises(error_type, match=error_message): klass(input) def test_parameter_grid(): # Test basic properties of ParameterGrid. params1 = {"foo": [1, 2, 3]} grid1 = ParameterGrid(params1) assert isinstance(grid1, Iterable) assert isinstance(grid1, Sized) assert len(grid1) == 3 assert_grid_iter_equals_getitem(grid1) params2 = {"foo": [4, 2], "bar": ["ham", "spam", "eggs"]} grid2 = ParameterGrid(params2) assert len(grid2) == 6 # loop to assert we can iterate over the grid multiple times for i in range(2): # tuple + chain transforms {"a": 1, "b": 2} to ("a", 1, "b", 2) points = set(tuple(chain(*(sorted(p.items())))) for p in grid2) assert (points == set(("bar", x, "foo", y) for x, y in product(params2["bar"], params2["foo"]))) assert_grid_iter_equals_getitem(grid2) # Special case: empty grid (useful to get default estimator settings) empty = ParameterGrid({}) assert len(empty) == 1 assert list(empty) == [{}] assert_grid_iter_equals_getitem(empty) assert_raises(IndexError, lambda: empty[1]) has_empty = ParameterGrid([{'C': [1, 10]}, {}, {'C': [.5]}]) assert len(has_empty) == 4 assert list(has_empty) == [{'C': 1}, {'C': 10}, {}, {'C': .5}] assert_grid_iter_equals_getitem(has_empty) def test_grid_search(): # Test that the best estimator contains the right value for foo_param clf = MockClassifier() grid_search = GridSearchCV(clf, {'foo_param': [1, 2, 3]}, cv=3, verbose=3) # make sure it selects the smallest parameter in case of ties old_stdout = sys.stdout sys.stdout = StringIO() grid_search.fit(X, y) sys.stdout = old_stdout assert grid_search.best_estimator_.foo_param == 2 assert_array_equal(grid_search.cv_results_["param_foo_param"].data, [1, 2, 3]) # Smoke test the score etc: grid_search.score(X, y) grid_search.predict_proba(X) grid_search.decision_function(X) grid_search.transform(X) # Test exception handling on scoring grid_search.scoring = 'sklearn' assert_raises(ValueError, grid_search.fit, X, y) def test_grid_search_pipeline_steps(): # check that parameters that are estimators are cloned before fitting pipe = Pipeline([('regressor', LinearRegression())]) param_grid = {'regressor': [LinearRegression(), Ridge()]} grid_search = GridSearchCV(pipe, param_grid, cv=2) grid_search.fit(X, y) regressor_results = grid_search.cv_results_['param_regressor'] assert isinstance(regressor_results[0], LinearRegression) assert isinstance(regressor_results[1], Ridge) assert not hasattr(regressor_results[0], 'coef_') assert not hasattr(regressor_results[1], 'coef_') assert regressor_results[0] is not grid_search.best_estimator_ assert regressor_results[1] is not grid_search.best_estimator_ # check that we didn't modify the parameter grid that was passed assert not hasattr(param_grid['regressor'][0], 'coef_') assert not hasattr(param_grid['regressor'][1], 'coef_') @pytest.mark.parametrize("SearchCV", [GridSearchCV, RandomizedSearchCV]) def test_SearchCV_with_fit_params(SearchCV): X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) clf = CheckingClassifier(expected_fit_params=['spam', 'eggs']) searcher = SearchCV( clf, {'foo_param': [1, 2, 3]}, cv=2, error_score="raise" ) # The CheckingClassifier generates an assertion error if # a parameter is missing or has length != len(X). err_msg = r"Expected fit parameter$s$ \['eggs'\] not seen." with pytest.raises(AssertionError, match=err_msg): searcher.fit(X, y, spam=np.ones(10)) err_msg = "Fit parameter spam has length 1; expected" with pytest.raises(AssertionError, match=err_msg): searcher.fit(X, y, spam=np.ones(1), eggs=np.zeros(10)) searcher.fit(X, y, spam=np.ones(10), eggs=np.zeros(10)) @ignore_warnings def test_grid_search_no_score(): # Test grid-search on classifier that has no score function. clf = LinearSVC(random_state=0) X, y = make_blobs(random_state=0, centers=2) Cs = [.1, 1, 10] clf_no_score = LinearSVCNoScore(random_state=0) grid_search = GridSearchCV(clf, {'C': Cs}, scoring='accuracy') grid_search.fit(X, y) grid_search_no_score = GridSearchCV(clf_no_score, {'C': Cs}, scoring='accuracy') # smoketest grid search grid_search_no_score.fit(X, y) # check that best params are equal assert grid_search_no_score.best_params_ == grid_search.best_params_ # check that we can call score and that it gives the correct result assert grid_search.score(X, y) == grid_search_no_score.score(X, y) # giving no scoring function raises an error grid_search_no_score = GridSearchCV(clf_no_score, {'C': Cs}) assert_raise_message(TypeError, "no scoring", grid_search_no_score.fit, [[1]]) def test_grid_search_score_method(): X, y = make_classification(n_samples=100, n_classes=2, flip_y=.2, random_state=0) clf = LinearSVC(random_state=0) grid = {'C': [.1]} search_no_scoring = GridSearchCV(clf, grid, scoring=None).fit(X, y) search_accuracy = GridSearchCV(clf, grid, scoring='accuracy').fit(X, y) search_no_score_method_auc = GridSearchCV(LinearSVCNoScore(), grid, scoring='roc_auc' ).fit(X, y) search_auc = GridSearchCV(clf, grid, scoring='roc_auc').fit(X, y) # Check warning only occurs in situation where behavior changed: # estimator requires score method to compete with scoring parameter score_no_scoring = search_no_scoring.score(X, y) score_accuracy = search_accuracy.score(X, y) score_no_score_auc = search_no_score_method_auc.score(X, y) score_auc = search_auc.score(X, y) # ensure the test is sane assert score_auc < 1.0 assert score_accuracy < 1.0 assert score_auc != score_accuracy assert_almost_equal(score_accuracy, score_no_scoring) assert_almost_equal(score_auc, score_no_score_auc) def test_grid_search_groups(): # Check if ValueError (when groups is None) propagates to GridSearchCV # And also check if groups is correctly passed to the cv object rng = np.random.RandomState(0) X, y = make_classification(n_samples=15, n_classes=2, random_state=0) groups = rng.randint(0, 3, 15) clf = LinearSVC(random_state=0) grid = {'C': [1]} group_cvs = [LeaveOneGroupOut(), LeavePGroupsOut(2), GroupKFold(n_splits=3), GroupShuffleSplit()] for cv in group_cvs: gs = GridSearchCV(clf, grid, cv=cv) assert_raise_message(ValueError, "The 'groups' parameter should not be None.", gs.fit, X, y) gs.fit(X, y, groups=groups) non_group_cvs = [StratifiedKFold(), StratifiedShuffleSplit()] for cv in non_group_cvs: gs = GridSearchCV(clf, grid, cv=cv) # Should not raise an error gs.fit(X, y) def test_classes__property(): # Test that classes_ property matches best_estimator_.classes_ X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) Cs = [.1, 1, 10] grid_search = GridSearchCV(LinearSVC(random_state=0), {'C': Cs}) grid_search.fit(X, y) assert_array_equal(grid_search.best_estimator_.classes_, grid_search.classes_) # Test that regressors do not have a classes_ attribute grid_search = GridSearchCV(Ridge(), {'alpha': [1.0, 2.0]}) grid_search.fit(X, y) assert not hasattr(grid_search, 'classes_') # Test that the grid searcher has no classes_ attribute before it's fit grid_search = GridSearchCV(LinearSVC(random_state=0), {'C': Cs}) assert not hasattr(grid_search, 'classes_') # Test that the grid searcher has no classes_ attribute without a refit grid_search = GridSearchCV(LinearSVC(random_state=0), {'C': Cs}, refit=False) grid_search.fit(X, y) assert not hasattr(grid_search, 'classes_') def test_trivial_cv_results_attr(): # Test search over a "grid" with only one point. clf = MockClassifier() grid_search = GridSearchCV(clf, {'foo_param': [1]}, cv=3) grid_search.fit(X, y) assert hasattr(grid_search, "cv_results_") random_search = RandomizedSearchCV(clf, {'foo_param': [0]}, n_iter=1, cv=3) random_search.fit(X, y) assert hasattr(grid_search, "cv_results_") def test_no_refit(): # Test that GSCV can be used for model selection alone without refitting clf = MockClassifier() for scoring in [None, ['accuracy', 'precision']]: grid_search = GridSearchCV( clf, {'foo_param': [1, 2, 3]}, refit=False, cv=3 ) grid_search.fit(X, y) assert not hasattr(grid_search, "best_estimator_") and \ hasattr(grid_search, "best_index_") and \ hasattr(grid_search, "best_params_") # Make sure the functions predict/transform etc raise meaningful # error messages for fn_name in ('predict', 'predict_proba', 'predict_log_proba', 'transform', 'inverse_transform'): assert_raise_message(NotFittedError, ('refit=False. %s is available only after ' 'refitting on the best parameters' % fn_name), getattr(grid_search, fn_name), X) # Test that an invalid refit param raises appropriate error messages for refit in ["", 5, True, 'recall', 'accuracy']: assert_raise_message(ValueError, "For multi-metric scoring, the " "parameter refit must be set to a scorer key", GridSearchCV(clf, {}, refit=refit, scoring={'acc': 'accuracy', 'prec': 'precision'} ).fit, X, y) def test_grid_search_error(): # Test that grid search will capture errors on data with different length X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) assert_raises(ValueError, cv.fit, X_[:180], y_) def test_grid_search_one_grid_point(): X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) param_dict = {"C": [1.0], "kernel": ["rbf"], "gamma": [0.1]} clf = SVC(gamma='auto') cv = GridSearchCV(clf, param_dict) cv.fit(X_, y_) clf = SVC(C=1.0, kernel="rbf", gamma=0.1) clf.fit(X_, y_) assert_array_equal(clf.dual_coef_, cv.best_estimator_.dual_coef_) def test_grid_search_when_param_grid_includes_range(): # Test that the best estimator contains the right value for foo_param clf = MockClassifier() grid_search = None grid_search = GridSearchCV(clf, {'foo_param': range(1, 4)}, cv=3) grid_search.fit(X, y) assert grid_search.best_estimator_.foo_param == 2 def test_grid_search_bad_param_grid(): param_dict = {"C": 1} clf = SVC(gamma='auto') assert_raise_message( ValueError, "Parameter grid for parameter (C) needs to" " be a list or numpy array, but got (<class 'int'>)." " Single values need to be wrapped in a list" " with one element.", GridSearchCV, clf, param_dict) param_dict = {"C": []} clf = SVC() assert_raise_message( ValueError, "Parameter values for parameter (C) need to be a non-empty sequence.", GridSearchCV, clf, param_dict) param_dict = {"C": "1,2,3"} clf = SVC(gamma='auto') assert_raise_message( ValueError, "Parameter grid for parameter (C) needs to" " be a list or numpy array, but got (<class 'str'>)." " Single values need to be wrapped in a list" " with one element.", GridSearchCV, clf, param_dict) param_dict = {"C": np.ones((3, 2))} clf = SVC() assert_raises(ValueError, GridSearchCV, clf, param_dict) def test_grid_search_sparse(): # Test that grid search works with both dense and sparse matrices X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) cv.fit(X_[:180], y_[:180]) y_pred = cv.predict(X_[180:]) C = cv.best_estimator_.C X_ = sp.csr_matrix(X_) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) cv.fit(X_[:180].tocoo(), y_[:180]) y_pred2 = cv.predict(X_[180:]) C2 = cv.best_estimator_.C assert np.mean(y_pred == y_pred2) >= .9 assert C == C2 def test_grid_search_sparse_scoring(): X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}, scoring="f1") cv.fit(X_[:180], y_[:180]) y_pred = cv.predict(X_[180:]) C = cv.best_estimator_.C X_ = sp.csr_matrix(X_) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}, scoring="f1") cv.fit(X_[:180], y_[:180]) y_pred2 = cv.predict(X_[180:]) C2 = cv.best_estimator_.C assert_array_equal(y_pred, y_pred2) assert C == C2 # Smoke test the score # np.testing.assert_allclose(f1_score(cv.predict(X_[:180]), y[:180]), # cv.score(X_[:180], y[:180])) # test loss where greater is worse def f1_loss(y_true_, y_pred_): return -f1_score(y_true_, y_pred_) F1Loss = make_scorer(f1_loss, greater_is_better=False) cv = GridSearchCV(clf, {'C': [0.1, 1.0]}, scoring=F1Loss) cv.fit(X_[:180], y_[:180]) y_pred3 = cv.predict(X_[180:]) C3 = cv.best_estimator_.C assert C == C3 assert_array_equal(y_pred, y_pred3) def test_grid_search_precomputed_kernel(): # Test that grid search works when the input features are given in the # form of a precomputed kernel matrix X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) # compute the training kernel matrix corresponding to the linear kernel K_train = np.dot(X_[:180], X_[:180].T) y_train = y_[:180] clf = SVC(kernel='precomputed') cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) cv.fit(K_train, y_train) assert cv.best_score_ >= 0 # compute the test kernel matrix K_test = np.dot(X_[180:], X_[:180].T) y_test = y_[180:] y_pred = cv.predict(K_test) assert np.mean(y_pred == y_test) >= 0 # test error is raised when the precomputed kernel is not array-like # or sparse assert_raises(ValueError, cv.fit, K_train.tolist(), y_train) def test_grid_search_precomputed_kernel_error_nonsquare(): # Test that grid search returns an error with a non-square precomputed # training kernel matrix K_train = np.zeros((10, 20)) y_train = np.ones((10, )) clf = SVC(kernel='precomputed') cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) assert_raises(ValueError, cv.fit, K_train, y_train) class BrokenClassifier(BaseEstimator): """Broken classifier that cannot be fit twice""" def __init__(self, parameter=None): self.parameter = parameter def fit(self, X, y): assert not hasattr(self, 'has_been_fit_') self.has_been_fit_ = True def predict(self, X): return np.zeros(X.shape[0]) @ignore_warnings def test_refit(): # Regression test for bug in refitting # Simulates re-fitting a broken estimator; this used to break with # sparse SVMs. X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) clf = GridSearchCV(BrokenClassifier(), [{'parameter': [0, 1]}], scoring="precision", refit=True) clf.fit(X, y) def test_refit_callable(): """ Test refit=callable, which adds flexibility in identifying the "best" estimator. """ def refit_callable(cv_results): """ A dummy function tests `refit=callable` interface. Return the index of a model that has the least `mean_test_score`. """ # Fit a dummy clf with `refit=True` to get a list of keys in # clf.cv_results_. X, y = make_classification(n_samples=100, n_features=4, random_state=42) clf = GridSearchCV(LinearSVC(random_state=42), {'C': [0.01, 0.1, 1]}, scoring='precision', refit=True) clf.fit(X, y) # Ensure that `best_index_ != 0` for this dummy clf assert clf.best_index_ != 0 # Assert every key matches those in `cv_results` for key in clf.cv_results_.keys(): assert key in cv_results return cv_results['mean_test_score'].argmin() X, y = make_classification(n_samples=100, n_features=4, random_state=42) clf = GridSearchCV(LinearSVC(random_state=42), {'C': [0.01, 0.1, 1]}, scoring='precision', refit=refit_callable) clf.fit(X, y) assert clf.best_index_ == 0 # Ensure `best_score_` is disabled when using `refit=callable` assert not hasattr(clf, 'best_score_') def test_refit_callable_invalid_type(): """ Test implementation catches the errors when 'best_index_' returns an invalid result. """ def refit_callable_invalid_type(cv_results): """ A dummy function tests when returned 'best_index_' is not integer. """ return None X, y = make_classification(n_samples=100, n_features=4, random_state=42) clf = GridSearchCV(LinearSVC(random_state=42), {'C': [0.1, 1]}, scoring='precision', refit=refit_callable_invalid_type) with pytest.raises(TypeError, match='best_index_ returned is not an integer'): clf.fit(X, y) @pytest.mark.parametrize('out_bound_value', [-1, 2]) @pytest.mark.parametrize('search_cv', [RandomizedSearchCV, GridSearchCV]) def test_refit_callable_out_bound(out_bound_value, search_cv): """ Test implementation catches the errors when 'best_index_' returns an out of bound result. """ def refit_callable_out_bound(cv_results): """ A dummy function tests when returned 'best_index_' is out of bounds. """ return out_bound_value X, y = make_classification(n_samples=100, n_features=4, random_state=42) clf = search_cv(LinearSVC(random_state=42), {'C': [0.1, 1]}, scoring='precision', refit=refit_callable_out_bound) with pytest.raises(IndexError, match='best_index_ index out of range'): clf.fit(X, y) def test_refit_callable_multi_metric(): """ Test refit=callable in multiple metric evaluation setting """ def refit_callable(cv_results): """ A dummy function tests `refit=callable` interface. Return the index of a model that has the least `mean_test_prec`. """ assert 'mean_test_prec' in cv_results return cv_results['mean_test_prec'].argmin() X, y = make_classification(n_samples=100, n_features=4, random_state=42) scoring = {'Accuracy': make_scorer(accuracy_score), 'prec': 'precision'} clf = GridSearchCV(LinearSVC(random_state=42), {'C': [0.01, 0.1, 1]}, scoring=scoring, refit=refit_callable) clf.fit(X, y) assert clf.best_index_ == 0 # Ensure `best_score_` is disabled when using `refit=callable` assert not hasattr(clf, 'best_score_') def test_gridsearch_nd(): # Pass X as list in GridSearchCV X_4d = np.arange(10 * 5 * 3 * 2).reshape(10, 5, 3, 2) y_3d = np.arange(10 * 7 * 11).reshape(10, 7, 11) check_X = lambda x: x.shape[1:] == (5, 3, 2) check_y = lambda x: x.shape[1:] == (7, 11) clf = CheckingClassifier( check_X=check_X, check_y=check_y, methods_to_check=["fit"], ) grid_search = GridSearchCV(clf, {'foo_param': [1, 2, 3]}) grid_search.fit(X_4d, y_3d).score(X, y) assert hasattr(grid_search, "cv_results_") def test_X_as_list(): # Pass X as list in GridSearchCV X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) clf = CheckingClassifier( check_X=lambda x: isinstance(x, list), methods_to_check=["fit"], ) cv = KFold(n_splits=3) grid_search = GridSearchCV(clf, {'foo_param': [1, 2, 3]}, cv=cv) grid_search.fit(X.tolist(), y).score(X, y) assert hasattr(grid_search, "cv_results_") def test_y_as_list(): # Pass y as list in GridSearchCV X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) clf = CheckingClassifier( check_y=lambda x: isinstance(x, list), methods_to_check=["fit"], ) cv = KFold(n_splits=3) grid_search = GridSearchCV(clf, {'foo_param': [1, 2, 3]}, cv=cv) grid_search.fit(X, y.tolist()).score(X, y) assert hasattr(grid_search, "cv_results_") @ignore_warnings def test_pandas_input(): # check cross_val_score doesn't destroy pandas dataframe types = [(MockDataFrame, MockDataFrame)] try: from pandas import Series, DataFrame types.append((DataFrame, Series)) except ImportError: pass X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) for InputFeatureType, TargetType in types: # X dataframe, y series X_df, y_ser = InputFeatureType(X), TargetType(y) def check_df(x): return isinstance(x, InputFeatureType) def check_series(x): return isinstance(x, TargetType) clf = CheckingClassifier(check_X=check_df, check_y=check_series) grid_search = GridSearchCV(clf, {'foo_param': [1, 2, 3]}) grid_search.fit(X_df, y_ser).score(X_df, y_ser) grid_search.predict(X_df) assert hasattr(grid_search, "cv_results_") def test_unsupervised_grid_search(): # test grid-search with unsupervised estimator X, y = make_blobs(n_samples=50, random_state=0) km = KMeans(random_state=0, init="random", n_init=1) # Multi-metric evaluation unsupervised scoring = ['adjusted_rand_score', 'fowlkes_mallows_score'] for refit in ['adjusted_rand_score', 'fowlkes_mallows_score']: grid_search = GridSearchCV(km, param_grid=dict(n_clusters=[2, 3, 4]), scoring=scoring, refit=refit) grid_search.fit(X, y) # Both ARI and FMS can find the right number :) assert grid_search.best_params_["n_clusters"] == 3 # Single metric evaluation unsupervised grid_search = GridSearchCV(km, param_grid=dict(n_clusters=[2, 3, 4]), scoring='fowlkes_mallows_score') grid_search.fit(X, y) assert grid_search.best_params_["n_clusters"] == 3 # Now without a score, and without y grid_search = GridSearchCV(km, param_grid=dict(n_clusters=[2, 3, 4])) grid_search.fit(X) assert grid_search.best_params_["n_clusters"] == 4 def test_gridsearch_no_predict(): # test grid-search with an estimator without predict. # slight duplication of a test from KDE def custom_scoring(estimator, X): return 42 if estimator.bandwidth == .1 else 0 X, _ = make_blobs(cluster_std=.1, random_state=1, centers=[[0, 1], [1, 0], [0, 0]]) search = GridSearchCV(KernelDensity(), param_grid=dict(bandwidth=[.01, .1, 1]), scoring=custom_scoring) search.fit(X) assert search.best_params_['bandwidth'] == .1 assert search.best_score_ == 42 def test_param_sampler(): # test basic properties of param sampler param_distributions = {"kernel": ["rbf", "linear"], "C": uniform(0, 1)} sampler = ParameterSampler(param_distributions=param_distributions, n_iter=10, random_state=0) samples = [x for x in sampler] assert len(samples) == 10 for sample in samples: assert sample["kernel"] in ["rbf", "linear"] assert 0 <= sample["C"] <= 1 # test that repeated calls yield identical parameters param_distributions = {"C": [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10]} sampler = ParameterSampler(param_distributions=param_distributions, n_iter=3, random_state=0) assert [x for x in sampler] == [x for x in sampler] if sp_version >= (0, 16): param_distributions = {"C": uniform(0, 1)} sampler = ParameterSampler(param_distributions=param_distributions, n_iter=10, random_state=0) assert [x for x in sampler] == [x for x in sampler] def check_cv_results_array_types(search, param_keys, score_keys): # Check if the search `cv_results`'s array are of correct types cv_results = search.cv_results_ assert all(isinstance(cv_results[param], np.ma.MaskedArray) for param in param_keys) assert all(cv_results[key].dtype == object for key in param_keys) assert not any(isinstance(cv_results[key], np.ma.MaskedArray) for key in score_keys) assert all(cv_results[key].dtype == np.float64 for key in score_keys if not key.startswith('rank')) scorer_keys = search.scorer_.keys() if search.multimetric_ else ['score'] for key in scorer_keys: assert cv_results['rank_test_%s' % key].dtype == np.int32 def check_cv_results_keys(cv_results, param_keys, score_keys, n_cand): # Test the search.cv_results_ contains all the required results assert_array_equal(sorted(cv_results.keys()), sorted(param_keys + score_keys + ('params',))) assert all(cv_results[key].shape == (n_cand,) for key in param_keys + score_keys) def test_grid_search_cv_results(): X, y = make_classification(n_samples=50, n_features=4, random_state=42) n_splits = 3 n_grid_points = 6 params = [dict(kernel=['rbf', ], C=[1, 10], gamma=[0.1, 1]), dict(kernel=['poly', ], degree=[1, 2])] param_keys = ('param_C', 'param_degree', 'param_gamma', 'param_kernel') score_keys = ('mean_test_score', 'mean_train_score', 'rank_test_score', 'split0_test_score', 'split1_test_score', 'split2_test_score', 'split0_train_score', 'split1_train_score', 'split2_train_score', 'std_test_score', 'std_train_score', 'mean_fit_time', 'std_fit_time', 'mean_score_time', 'std_score_time') n_candidates = n_grid_points search = GridSearchCV(SVC(), cv=n_splits, param_grid=params, return_train_score=True) search.fit(X, y) cv_results = search.cv_results_ # Check if score and timing are reasonable assert all(cv_results['rank_test_score'] >= 1) assert (all(cv_results[k] >= 0) for k in score_keys if k != 'rank_test_score') assert (all(cv_results[k] <= 1) for k in score_keys if 'time' not in k and k != 'rank_test_score') # Check cv_results structure check_cv_results_array_types(search, param_keys, score_keys) check_cv_results_keys(cv_results, param_keys, score_keys, n_candidates) # Check masking cv_results = search.cv_results_ n_candidates = len(search.cv_results_['params']) assert all((cv_results['param_C'].mask[i] and cv_results['param_gamma'].mask[i] and not cv_results['param_degree'].mask[i]) for i in range(n_candidates) if cv_results['param_kernel'][i] == 'linear') assert all((not cv_results['param_C'].mask[i] and not cv_results['param_gamma'].mask[i] and cv_results['param_degree'].mask[i]) for i in range(n_candidates) if cv_results['param_kernel'][i] == 'rbf') def test_random_search_cv_results(): X, y = make_classification(n_samples=50, n_features=4, random_state=42) n_splits = 3 n_search_iter = 30 params = [{'kernel': ['rbf'], 'C': expon(scale=10), 'gamma': expon(scale=0.1)}, {'kernel': ['poly'], 'degree': [2, 3]}] param_keys = ('param_C', 'param_degree', 'param_gamma', 'param_kernel') score_keys = ('mean_test_score', 'mean_train_score', 'rank_test_score', 'split0_test_score', 'split1_test_score', 'split2_test_score', 'split0_train_score', 'split1_train_score', 'split2_train_score', 'std_test_score', 'std_train_score', 'mean_fit_time', 'std_fit_time', 'mean_score_time', 'std_score_time') n_cand = n_search_iter search = RandomizedSearchCV(SVC(), n_iter=n_search_iter, cv=n_splits, param_distributions=params, return_train_score=True) search.fit(X, y) cv_results = search.cv_results_ # Check results structure check_cv_results_array_types(search, param_keys, score_keys) check_cv_results_keys(cv_results, param_keys, score_keys, n_cand) n_candidates = len(search.cv_results_['params']) assert all((cv_results['param_C'].mask[i] and cv_results['param_gamma'].mask[i] and not cv_results['param_degree'].mask[i]) for i in range(n_candidates) if cv_results['param_kernel'][i] == 'linear') assert all((not cv_results['param_C'].mask[i] and not cv_results['param_gamma'].mask[i] and cv_results['param_degree'].mask[i]) for i in range(n_candidates) if cv_results['param_kernel'][i] == 'rbf') @pytest.mark.parametrize( "SearchCV, specialized_params", [(GridSearchCV, {'param_grid': {'C': [1, 10]}}), (RandomizedSearchCV, {'param_distributions': {'C': [1, 10]}, 'n_iter': 2})] ) def test_search_default_iid(SearchCV, specialized_params): # Test the IID parameter TODO: Clearly this test does something else??? # noise-free simple 2d-data X, y = make_blobs(centers=[[0, 0], [1, 0], [0, 1], [1, 1]], random_state=0, cluster_std=0.1, shuffle=False, n_samples=80) # split dataset into two folds that are not iid # first one contains data of all 4 blobs, second only from two. mask = np.ones(X.shape[0], dtype=np.bool) mask[np.where(y == 1)[0][::2]] = 0 mask[np.where(y == 2)[0][::2]] = 0 # this leads to perfect classification on one fold and a score of 1/3 on # the other # create "cv" for splits cv = [[mask, ~mask], [~mask, mask]] common_params = {'estimator': SVC(), 'cv': cv, 'return_train_score': True} search = SearchCV(**common_params, **specialized_params) search.fit(X, y) test_cv_scores = np.array( [search.cv_results_['split%d_test_score' % s][0] for s in range(search.n_splits_)] ) test_mean = search.cv_results_['mean_test_score'][0] test_std = search.cv_results_['std_test_score'][0] train_cv_scores = np.array( [search.cv_results_['split%d_train_score' % s][0] for s in range(search.n_splits_)] ) train_mean = search.cv_results_['mean_train_score'][0] train_std = search.cv_results_['std_train_score'][0] assert search.cv_results_['param_C'][0] == 1 # scores are the same as above assert_allclose(test_cv_scores, [1, 1. / 3.]) assert_allclose(train_cv_scores, [1, 1]) # Unweighted mean/std is used assert test_mean == pytest.approx(np.mean(test_cv_scores)) assert test_std == pytest.approx(np.std(test_cv_scores)) # For the train scores, we do not take a weighted mean irrespective of # i.i.d. or not assert train_mean == pytest.approx(1) assert train_std == pytest.approx(0) def test_grid_search_cv_results_multimetric(): X, y = make_classification(n_samples=50, n_features=4, random_state=42) n_splits = 3 params = [dict(kernel=['rbf', ], C=[1, 10], gamma=[0.1, 1]), dict(kernel=['poly', ], degree=[1, 2])] grid_searches = [] for scoring in ({'accuracy': make_scorer(accuracy_score), 'recall': make_scorer(recall_score)}, 'accuracy', 'recall'): grid_search = GridSearchCV(SVC(), cv=n_splits, param_grid=params, scoring=scoring, refit=False) grid_search.fit(X, y) grid_searches.append(grid_search) compare_cv_results_multimetric_with_single(*grid_searches) def test_random_search_cv_results_multimetric(): X, y = make_classification(n_samples=50, n_features=4, random_state=42) n_splits = 3 n_search_iter = 30 # Scipy 0.12's stats dists do not accept seed, hence we use param grid params = dict(C=np.logspace(-4, 1, 3), gamma=np.logspace(-5, 0, 3, base=0.1)) for refit in (True, False): random_searches = [] for scoring in (('accuracy', 'recall'), 'accuracy', 'recall'): # If True, for multi-metric pass refit='accuracy' if refit: probability = True refit = 'accuracy' if isinstance(scoring, tuple) else refit else: probability = False clf = SVC(probability=probability, random_state=42) random_search = RandomizedSearchCV(clf, n_iter=n_search_iter, cv=n_splits, param_distributions=params, scoring=scoring, refit=refit, random_state=0) random_search.fit(X, y) random_searches.append(random_search) compare_cv_results_multimetric_with_single(*random_searches) compare_refit_methods_when_refit_with_acc( random_searches[0], random_searches[1], refit) def compare_cv_results_multimetric_with_single( search_multi, search_acc, search_rec): """Compare multi-metric cv_results with the ensemble of multiple single metric cv_results from single metric grid/random search""" assert search_multi.multimetric_ assert_array_equal(sorted(search_multi.scorer_), ('accuracy', 'recall')) cv_results_multi = search_multi.cv_results_ cv_results_acc_rec = {re.sub('_score$', '_accuracy', k): v for k, v in search_acc.cv_results_.items()} cv_results_acc_rec.update({re.sub('_score$', '_recall', k): v for k, v in search_rec.cv_results_.items()}) # Check if score and timing are reasonable, also checks if the keys # are present assert all((np.all(cv_results_multi[k] <= 1) for k in ( 'mean_score_time', 'std_score_time', 'mean_fit_time', 'std_fit_time'))) # Compare the keys, other than time keys, among multi-metric and # single metric grid search results. np.testing.assert_equal performs a # deep nested comparison of the two cv_results dicts np.testing.assert_equal({k: v for k, v in cv_results_multi.items() if not k.endswith('_time')}, {k: v for k, v in cv_results_acc_rec.items() if not k.endswith('_time')}) def compare_refit_methods_when_refit_with_acc(search_multi, search_acc, refit): """Compare refit multi-metric search methods with single metric methods""" assert search_acc.refit == refit if refit: assert search_multi.refit == 'accuracy' else: assert not search_multi.refit return # search cannot predict/score without refit X, y = make_blobs(n_samples=100, n_features=4, random_state=42) for method in ('predict', 'predict_proba', 'predict_log_proba'): assert_almost_equal(getattr(search_multi, method)(X), getattr(search_acc, method)(X)) assert_almost_equal(search_multi.score(X, y), search_acc.score(X, y)) for key in ('best_index_', 'best_score_', 'best_params_'): assert getattr(search_multi, key) == getattr(search_acc, key) def test_search_cv_results_rank_tie_breaking(): X, y = make_blobs(n_samples=50, random_state=42) # The two C values are close enough to give similar models # which would result in a tie of their mean cv-scores param_grid = {'C': [1, 1.001, 0.001]} grid_search = GridSearchCV(SVC(), param_grid=param_grid, return_train_score=True) random_search = RandomizedSearchCV(SVC(), n_iter=3, param_distributions=param_grid, return_train_score=True) for search in (grid_search, random_search): search.fit(X, y) cv_results = search.cv_results_ # Check tie breaking strategy - # Check that there is a tie in the mean scores between # candidates 1 and 2 alone assert_almost_equal(cv_results['mean_test_score'][0], cv_results['mean_test_score'][1]) assert_almost_equal(cv_results['mean_train_score'][0], cv_results['mean_train_score'][1]) assert not np.allclose(cv_results['mean_test_score'][1], cv_results['mean_test_score'][2]) assert not np.allclose(cv_results['mean_train_score'][1], cv_results['mean_train_score'][2]) # 'min' rank should be assigned to the tied candidates assert_almost_equal(search.cv_results_['rank_test_score'], [1, 1, 3]) def test_search_cv_results_none_param(): X, y = [[1], [2], [3], [4], [5]], [0, 0, 0, 0, 1] estimators = (DecisionTreeRegressor(), DecisionTreeClassifier()) est_parameters = {"random_state": [0, None]} cv = KFold() for est in estimators: grid_search = GridSearchCV(est, est_parameters, cv=cv, ).fit(X, y) assert_array_equal(grid_search.cv_results_['param_random_state'], [0, None]) @ignore_warnings() def test_search_cv_timing(): svc = LinearSVC(random_state=0) X = [[1, ], [2, ], [3, ], [4, ]] y = [0, 1, 1, 0] gs = GridSearchCV(svc, {'C': [0, 1]}, cv=2, error_score=0) rs = RandomizedSearchCV(svc, {'C': [0, 1]}, cv=2, error_score=0, n_iter=2) for search in (gs, rs): search.fit(X, y) for key in ['mean_fit_time', 'std_fit_time']: # NOTE The precision of time.time in windows is not high # enough for the fit/score times to be non-zero for trivial X and y assert np.all(search.cv_results_[key] >= 0) assert np.all(search.cv_results_[key] < 1) for key in ['mean_score_time', 'std_score_time']: assert search.cv_results_[key][1] >= 0 assert search.cv_results_[key][0] == 0.0 assert np.all(search.cv_results_[key] < 1) assert hasattr(search, "refit_time_") assert isinstance(search.refit_time_, float) assert search.refit_time_ >= 0 def test_grid_search_correct_score_results(): # test that correct scores are used n_splits = 3 clf = LinearSVC(random_state=0) X, y = make_blobs(random_state=0, centers=2) Cs = [.1, 1, 10] for score in ['f1', 'roc_auc']: grid_search = GridSearchCV(clf, {'C': Cs}, scoring=score, cv=n_splits) cv_results = grid_search.fit(X, y).cv_results_ # Test scorer names result_keys = list(cv_results.keys()) expected_keys = (("mean_test_score", "rank_test_score") + tuple("split%d_test_score" % cv_i for cv_i in range(n_splits))) assert all(

np.in1d(expected_keys, result_keys)

numpy.in1d

from abc import ABCMeta, abstractmethod import os from vmaf.tools.misc import make_absolute_path, run_process from vmaf.tools.stats import ListStats __copyright__ = "Copyright 2016-2018, Netflix, Inc." __license__ = "Apache, Version 2.0" import re import numpy as np import ast from vmaf import ExternalProgramCaller, to_list from vmaf.config import VmafConfig, VmafExternalConfig from vmaf.core.executor import Executor from vmaf.core.result import Result from vmaf.tools.reader import YuvReader class FeatureExtractor(Executor): """ FeatureExtractor takes in a list of assets, and run feature extraction on them, and return a list of corresponding results. A FeatureExtractor must specify a unique type and version combination (by the TYPE and VERSION attribute), so that the Result generated by it can be identified. A derived class of FeatureExtractor must: 1) Override TYPE and VERSION 2) Override _generate_result(self, asset), which call a command-line executable and generate feature scores in a log file. 3) Override _get_feature_scores(self, asset), which read the feature scores from the log file, and return the scores in a dictionary format. For an example, follow VmafFeatureExtractor. """ __metaclass__ = ABCMeta @property @abstractmethod def ATOM_FEATURES(self): raise NotImplementedError def _read_result(self, asset): result = {} result.update(self._get_feature_scores(asset)) executor_id = self.executor_id return Result(asset, executor_id, result) @classmethod def get_scores_key(cls, atom_feature): return "{type}_{atom_feature}_scores".format( type=cls.TYPE, atom_feature=atom_feature) @classmethod def get_score_key(cls, atom_feature): return "{type}_{atom_feature}_score".format( type=cls.TYPE, atom_feature=atom_feature) def _get_feature_scores(self, asset): # routine to read the feature scores from the log file, and return # the scores in a dictionary format. log_file_path = self._get_log_file_path(asset) atom_feature_scores_dict = {} atom_feature_idx_dict = {} for atom_feature in self.ATOM_FEATURES: atom_feature_scores_dict[atom_feature] = [] atom_feature_idx_dict[atom_feature] = 0 with open(log_file_path, 'rt') as log_file: for line in log_file.readlines(): for atom_feature in self.ATOM_FEATURES: re_template = "{af}: ([0-9]+) ([a-zA-Z0-9.-]+)".format(af=atom_feature) mo = re.match(re_template, line) if mo: cur_idx = int(mo.group(1)) assert cur_idx == atom_feature_idx_dict[atom_feature] # parse value, allowing NaN and inf val = float(mo.group(2)) if np.isnan(val) or np.isinf(val): val = None atom_feature_scores_dict[atom_feature].append(val) atom_feature_idx_dict[atom_feature] += 1 continue len_score = len(atom_feature_scores_dict[self.ATOM_FEATURES[0]]) assert len_score != 0 for atom_feature in self.ATOM_FEATURES[1:]: assert len_score == len(atom_feature_scores_dict[atom_feature]), \ "Feature data possibly corrupt. Run cleanup script and try again." feature_result = {} for atom_feature in self.ATOM_FEATURES: scores_key = self.get_scores_key(atom_feature) feature_result[scores_key] = atom_feature_scores_dict[atom_feature] return feature_result class VmafFeatureExtractor(FeatureExtractor): TYPE = "VMAF_feature" # VERSION = '0.1' # vmaf_study; Anush's VIF fix # VERSION = '0.2' # expose vif_num, vif_den, adm_num, adm_den, anpsnr # VERSION = '0.2.1' # expose vif num/den of each scale # VERSION = '0.2.2' # adm abs-->fabs, corrected border handling, uniform reading with option of offset for input YUV, updated VIF corner case # VERSION = '0.2.2b' # expose adm_den/num_scalex # VERSION = '0.2.3' # AVX for VMAF convolution; update adm features by folding noise floor into per coef # VERSION = '0.2.4' # Fix a bug in adm feature passing scale into dwt_quant_step # VERSION = '0.2.4b' # Modify by adding ADM noise floor outside cube root; add derived feature motion2 VERSION = '0.2.4c' # Modify by moving motion2 to c code ATOM_FEATURES = ['vif', 'adm', 'ansnr', 'motion', 'motion2', 'vif_num', 'vif_den', 'adm_num', 'adm_den', 'anpsnr', 'vif_num_scale0', 'vif_den_scale0', 'vif_num_scale1', 'vif_den_scale1', 'vif_num_scale2', 'vif_den_scale2', 'vif_num_scale3', 'vif_den_scale3', 'adm_num_scale0', 'adm_den_scale0', 'adm_num_scale1', 'adm_den_scale1', 'adm_num_scale2', 'adm_den_scale2', 'adm_num_scale3', 'adm_den_scale3', ] DERIVED_ATOM_FEATURES = ['vif_scale0', 'vif_scale1', 'vif_scale2', 'vif_scale3', 'vif2', 'adm2', 'adm3', 'adm_scale0', 'adm_scale1', 'adm_scale2', 'adm_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vmaf_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VmafFeatureExtractor, cls)._post_process_result(result) # adm2 = # (adm_num + ADM2_CONSTANT) / (adm_den + ADM2_CONSTANT) adm2_scores_key = cls.get_scores_key('adm2') adm_num_scores_key = cls.get_scores_key('adm_num') adm_den_scores_key = cls.get_scores_key('adm_den') result.result_dict[adm2_scores_key] = list( (np.array(result.result_dict[adm_num_scores_key]) + cls.ADM2_CONSTANT) / (np.array(result.result_dict[adm_den_scores_key]) + cls.ADM2_CONSTANT) ) # vif_scalei = vif_num_scalei / vif_den_scalei, i = 0, 1, 2, 3 vif_num_scale0_scores_key = cls.get_scores_key('vif_num_scale0') vif_den_scale0_scores_key = cls.get_scores_key('vif_den_scale0') vif_num_scale1_scores_key = cls.get_scores_key('vif_num_scale1') vif_den_scale1_scores_key = cls.get_scores_key('vif_den_scale1') vif_num_scale2_scores_key = cls.get_scores_key('vif_num_scale2') vif_den_scale2_scores_key = cls.get_scores_key('vif_den_scale2') vif_num_scale3_scores_key = cls.get_scores_key('vif_num_scale3') vif_den_scale3_scores_key = cls.get_scores_key('vif_den_scale3') vif_scale0_scores_key = cls.get_scores_key('vif_scale0') vif_scale1_scores_key = cls.get_scores_key('vif_scale1') vif_scale2_scores_key = cls.get_scores_key('vif_scale2') vif_scale3_scores_key = cls.get_scores_key('vif_scale3') result.result_dict[vif_scale0_scores_key] = list( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) ) result.result_dict[vif_scale1_scores_key] = list( (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) ) result.result_dict[vif_scale2_scores_key] = list( (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) ) result.result_dict[vif_scale3_scores_key] = list( (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) # vif2 = # ((vif_num_scale0 / vif_den_scale0) + (vif_num_scale1 / vif_den_scale1) + # (vif_num_scale2 / vif_den_scale2) + (vif_num_scale3 / vif_den_scale3)) / 4.0 vif_scores_key = cls.get_scores_key('vif2') result.result_dict[vif_scores_key] = list( ( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) + (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) + (

np.array(result.result_dict[vif_num_scale2_scores_key])

numpy.array

import hashlib from io import BytesIO import logging import os from typing import Any, cast, Dict, List, Optional, Sequence, Type, TYPE_CHECKING, Union from pkg_resources import parse_version import wandb from wandb import util from ._private import MEDIA_TMP from .base_types.media import BatchableMedia, Media from .helper_types.bounding_boxes_2d import BoundingBoxes2D from .helper_types.classes import Classes from .helper_types.image_mask import ImageMask if TYPE_CHECKING: # pragma: no cover import matplotlib # type: ignore import numpy as np # type: ignore import PIL # type: ignore import torch # type: ignore from wandb.apis.public import Artifact as PublicArtifact from ..wandb_artifacts import Artifact as LocalArtifact from ..wandb_run import Run as LocalRun ImageDataType = Union[ "matplotlib.artist.Artist", "PIL.Image", "TorchTensorType", "np.ndarray" ] ImageDataOrPathType = Union[str, "Image", ImageDataType] TorchTensorType = Union["torch.Tensor", "torch.Variable"] def _server_accepts_image_filenames() -> bool: # Newer versions of wandb accept large image filenames arrays # but older versions would have issues with this. max_cli_version = util._get_max_cli_version() if max_cli_version is None: return False return parse_version("0.12.10") <= parse_version(max_cli_version) class Image(BatchableMedia): """Format images for logging to W&B. Arguments: data_or_path: (numpy array, string, io) Accepts numpy array of image data, or a PIL image. The class attempts to infer the data format and converts it. mode: (string) The PIL mode for an image. Most common are "L", "RGB", "RGBA". Full explanation at https://pillow.readthedocs.io/en/4.2.x/handbook/concepts.html#concept-modes. caption: (string) Label for display of image. Examples: ### Create a wandb.Image from a numpy array <!--yeadoc-test:log-image-numpy-> ```python import numpy as np import wandb wandb.init() examples = [] for i in range(3): pixels = np.random.randint(low=0, high=256, size=(100, 100, 3)) image = wandb.Image(pixels, caption=f"random field {i}") examples.append(image) wandb.log({"examples": examples}) ``` ### Create a wandb.Image from a PILImage <!--yeadoc-test:log-image-pil-> ```python import numpy as np from PIL import Image as PILImage import wandb wandb.init() examples = [] for i in range(3): pixels = np.random.randint(low=0, high=256, size=(100, 100, 3), dtype=np.uint8) pil_image = PILImage.fromarray(pixels, mode="RGB") image = wandb.Image(pil_image, caption=f"random field {i}") examples.append(image) wandb.log({"examples": examples}) ``` """ MAX_ITEMS = 108 # PIL limit MAX_DIMENSION = 65500 _log_type = "image-file" format: Optional[str] _grouping: Optional[int] _caption: Optional[str] _width: Optional[int] _height: Optional[int] _image: Optional["PIL.Image"] _classes: Optional["Classes"] _boxes: Optional[Dict[str, "BoundingBoxes2D"]] _masks: Optional[Dict[str, "ImageMask"]] def __init__( self, data_or_path: "ImageDataOrPathType", mode: Optional[str] = None, caption: Optional[str] = None, grouping: Optional[int] = None, classes: Optional[Union["Classes", Sequence[dict]]] = None, boxes: Optional[Union[Dict[str, "BoundingBoxes2D"], Dict[str, dict]]] = None, masks: Optional[Union[Dict[str, "ImageMask"], Dict[str, dict]]] = None, ) -> None: super(Image, self).__init__() # TODO: We should remove grouping, it's a terrible name and I don't # think anyone uses it. self._grouping = None self._caption = None self._width = None self._height = None self._image = None self._classes = None self._boxes = None self._masks = None # Allows the user to pass an Image object as the first parameter and have a perfect copy, # only overriding additional metdata passed in. If this pattern is compelling, we can generalize. if isinstance(data_or_path, Image): self._initialize_from_wbimage(data_or_path) elif isinstance(data_or_path, str): self._initialize_from_path(data_or_path) else: self._initialize_from_data(data_or_path, mode) self._set_initialization_meta(grouping, caption, classes, boxes, masks) def _set_initialization_meta( self, grouping: Optional[int] = None, caption: Optional[str] = None, classes: Optional[Union["Classes", Sequence[dict]]] = None, boxes: Optional[Union[Dict[str, "BoundingBoxes2D"], Dict[str, dict]]] = None, masks: Optional[Union[Dict[str, "ImageMask"], Dict[str, dict]]] = None, ) -> None: if grouping is not None: self._grouping = grouping if caption is not None: self._caption = caption total_classes = {} if boxes: if not isinstance(boxes, dict): raise ValueError('Images "boxes" argument must be a dictionary') boxes_final: Dict[str, BoundingBoxes2D] = {} for key in boxes: box_item = boxes[key] if isinstance(box_item, BoundingBoxes2D): boxes_final[key] = box_item elif isinstance(box_item, dict): # TODO: Consider injecting top-level classes if user-provided is empty boxes_final[key] = BoundingBoxes2D(box_item, key) total_classes.update(boxes_final[key]._class_labels) self._boxes = boxes_final if masks: if not isinstance(masks, dict): raise ValueError('Images "masks" argument must be a dictionary') masks_final: Dict[str, ImageMask] = {} for key in masks: mask_item = masks[key] if isinstance(mask_item, ImageMask): masks_final[key] = mask_item elif isinstance(mask_item, dict): # TODO: Consider injecting top-level classes if user-provided is empty masks_final[key] = ImageMask(mask_item, key) if hasattr(masks_final[key], "_val"): total_classes.update(masks_final[key]._val["class_labels"]) self._masks = masks_final if classes is not None: if isinstance(classes, Classes): total_classes.update( {val["id"]: val["name"] for val in classes._class_set} ) else: total_classes.update({val["id"]: val["name"] for val in classes}) if len(total_classes.keys()) > 0: self._classes = Classes( [ {"id": key, "name": total_classes[key]} for key in total_classes.keys() ] ) self._width, self._height = self.image.size # type: ignore self._free_ram() def _initialize_from_wbimage(self, wbimage: "Image") -> None: self._grouping = wbimage._grouping self._caption = wbimage._caption self._width = wbimage._width self._height = wbimage._height self._image = wbimage._image self._classes = wbimage._classes self._path = wbimage._path self._is_tmp = wbimage._is_tmp self._extension = wbimage._extension self._sha256 = wbimage._sha256 self._size = wbimage._size self.format = wbimage.format self._artifact_source = wbimage._artifact_source self._artifact_target = wbimage._artifact_target # We do not want to implicitly copy boxes or masks, just the image-related data. # self._boxes = wbimage._boxes # self._masks = wbimage._masks def _initialize_from_path(self, path: str) -> None: pil_image = util.get_module( "PIL.Image", required='wandb.Image needs the PIL package. To get it, run "pip install pillow".', ) self._set_file(path, is_tmp=False) self._image = pil_image.open(path) self._image.load() ext = os.path.splitext(path)[1][1:] self.format = ext def _initialize_from_data(self, data: "ImageDataType", mode: str = None,) -> None: pil_image = util.get_module( "PIL.Image", required='wandb.Image needs the PIL package. To get it, run "pip install pillow".', ) if util.is_matplotlib_typename(util.get_full_typename(data)): buf = BytesIO() util.ensure_matplotlib_figure(data).savefig(buf) self._image = pil_image.open(buf) elif isinstance(data, pil_image.Image): self._image = data elif util.is_pytorch_tensor_typename(util.get_full_typename(data)): vis_util = util.get_module( "torchvision.utils", "torchvision is required to render images" ) if hasattr(data, "requires_grad") and data.requires_grad: data = data.detach() data = vis_util.make_grid(data, normalize=True) self._image = pil_image.fromarray( data.mul(255).clamp(0, 255).byte().permute(1, 2, 0).cpu().numpy() ) else: if hasattr(data, "numpy"): # TF data eager tensors data = data.numpy() if data.ndim > 2: data = data.squeeze() # get rid of trivial dimensions as a convenience self._image = pil_image.fromarray( self.to_uint8(data), mode=mode or self.guess_mode(data) ) tmp_path = os.path.join(MEDIA_TMP.name, str(util.generate_id()) + ".png") self.format = "png" self._image.save(tmp_path, transparency=None) self._set_file(tmp_path, is_tmp=True) @classmethod def from_json( cls: Type["Image"], json_obj: dict, source_artifact: "PublicArtifact" ) -> "Image": classes = None if json_obj.get("classes") is not None: classes = source_artifact.get(json_obj["classes"]["path"]) masks = json_obj.get("masks") _masks: Optional[Dict[str, ImageMask]] = None if masks: _masks = {} for key in masks: _masks[key] = ImageMask.from_json(masks[key], source_artifact) _masks[key]._set_artifact_source(source_artifact) _masks[key]._key = key boxes = json_obj.get("boxes") _boxes: Optional[Dict[str, BoundingBoxes2D]] = None if boxes: _boxes = {} for key in boxes: _boxes[key] = BoundingBoxes2D.from_json(boxes[key], source_artifact) _boxes[key]._key = key return cls( source_artifact.get_path(json_obj["path"]).download(), caption=json_obj.get("caption"), grouping=json_obj.get("grouping"), classes=classes, boxes=_boxes, masks=_masks, ) @classmethod def get_media_subdir(cls: Type["Image"]) -> str: return os.path.join("media", "images") def bind_to_run( self, run: "LocalRun", key: Union[int, str], step: Union[int, str], id_: Optional[Union[int, str]] = None, ignore_copy_err: Optional[bool] = None, ) -> None: super().bind_to_run(run, key, step, id_, ignore_copy_err=ignore_copy_err) if self._boxes is not None: for i, k in enumerate(self._boxes): id_ = "{}{}".format(id_, i) if id_ is not None else None self._boxes[k].bind_to_run( run, key, step, id_, ignore_copy_err=ignore_copy_err ) if self._masks is not None: for i, k in enumerate(self._masks): id_ = "{}{}".format(id_, i) if id_ is not None else None self._masks[k].bind_to_run( run, key, step, id_, ignore_copy_err=ignore_copy_err ) def to_json(self, run_or_artifact: Union["LocalRun", "LocalArtifact"]) -> dict: json_dict = super(Image, self).to_json(run_or_artifact) json_dict["_type"] = Image._log_type json_dict["format"] = self.format if self._width is not None: json_dict["width"] = self._width if self._height is not None: json_dict["height"] = self._height if self._grouping: json_dict["grouping"] = self._grouping if self._caption: json_dict["caption"] = self._caption if isinstance(run_or_artifact, wandb.wandb_sdk.wandb_artifacts.Artifact): artifact = run_or_artifact if ( self._masks is not None or self._boxes is not None ) and self._classes is None: raise ValueError( "classes must be passed to wandb.Image which have masks or bounding boxes when adding to artifacts" ) if self._classes is not None: class_id = hashlib.md5( str(self._classes._class_set).encode("utf-8") ).hexdigest() class_name = os.path.join("media", "classes", class_id + "_cls",) classes_entry = artifact.add(self._classes, class_name) json_dict["classes"] = { "type": "classes-file", "path": classes_entry.path, "digest": classes_entry.digest, } elif not isinstance(run_or_artifact, wandb.wandb_sdk.wandb_run.Run): raise ValueError("to_json accepts wandb_run.Run or wandb_artifact.Artifact") if self._boxes: json_dict["boxes"] = { k: box.to_json(run_or_artifact) for (k, box) in self._boxes.items() } if self._masks: json_dict["masks"] = { k: mask.to_json(run_or_artifact) for (k, mask) in self._masks.items() } return json_dict def guess_mode(self, data: "np.ndarray") -> str: """ Guess what type of image the np.array is representing """ # TODO: do we want to support dimensions being at the beginning of the array? if data.ndim == 2: return "L" elif data.shape[-1] == 3: return "RGB" elif data.shape[-1] == 4: return "RGBA" else: raise ValueError( "Un-supported shape for image conversion %s" % list(data.shape) ) @classmethod def to_uint8(cls, data: "np.ndarray") -> "np.ndarray": """ Converts floating point image on the range [0,1] and integer images on the range [0,255] to uint8, clipping if necessary. """ np = util.get_module( "numpy", required="wandb.Image requires numpy if not supplying PIL Images: pip install numpy", ) # I think it's better to check the image range vs the data type, since many # image libraries will return floats between 0 and 255 # some images have range -1...1 or 0-1 dmin =

np.min(data)

numpy.min

import argparse import glob import os import pickle from pathlib import Path import numpy as np from PIL import Image from tqdm import tqdm from src.align.align_trans import get_reference_facial_points, warp_and_crop_face # sys.path.append("../../") from src.align.detector import detect_faces if __name__ == "__main__": parser = argparse.ArgumentParser(description="face alignment") parser.add_argument( "-source_root", "--source_root", help="specify your source dir", default="../../data/fiw-videos/new-processed/", type=str, ) parser.add_argument( "-dest_root", "--dest_root", help="specify your destination dir", default="../../data/fiw-videos/new-processed/", type=str, ) parser.add_argument( "-crop_size", "--crop_size", help="specify size of aligned faces, align and crop with padding", default=112, type=int, ) args = parser.parse_args() source_root = args.source_root # specify your source dir dest_root = args.dest_root # specify your destination dir crop_size = ( args.crop_size ) # specify size of aligned faces, align and crop with padding scale = crop_size / 112.0 reference = get_reference_facial_points(default_square=True) * scale cwd = os.getcwd() # delete '.DS_Store' existed in the source_root os.chdir(source_root) os.system("find . -name '*.DS_Store' -type f -delete") os.chdir(cwd) imfiles = [ f for f in glob.glob(f"{source_root}F????/MID*/faces/msceleb*") if Path(f).is_file() ] # images = {imfile.replace(source_root, ''): Image.open(imfile) for imfile in imfiles} meta = {} # for subfolder in tqdm(os.listdir(source_root)): for imfile in tqdm(imfiles): ref = imfile.replace(source_root, "") print("Processing\t{}".format(imfile)) img = Image.open(imfile) try: # Handle exception bbs, landmarks = detect_faces(img) except Exception: print("{} is discarded due to exception!".format(imfile)) continue ref = imfile.replace(source_root, "") ndetections = len(landmarks) if ( ndetections == 0 ): # If the landmarks cannot be detected, the img will be discarded print("{} is discarded due to non-detected landmarks!".format(imfile)) meta[ref] = [] continue li_meta = [] for i in range(ndetections): im_meta = {} im_meta["face"] = i im_meta["landmarks"] = landmarks[i] im_meta["bb"] = bbs[i] facial5points = [[landmarks[i][j], landmarks[i][j + 5]] for j in range(5)] warped_face = warp_and_crop_face(

np.array(img)

numpy.array

import argparse import json import numpy as np import pandas as pd import os from sklearn.linear_model import LogisticRegression from sklearn.model_selection import train_test_split from sklearn.metrics import classification_report,f1_score from keras.models import Sequential from keras.layers import Dense, Dropout from keras import backend as K from keras.utils.vis_utils import plot_model from sklearn.externals import joblib import time def f1(y_true, y_pred): def recall(y_true, y_pred): """Recall metric. Only computes a batch-wise average of recall. Computes the recall, a metric for multi-label classification of how many relevant items are selected. """ true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1))) possible_positives = K.sum(K.round(K.clip(y_true, 0, 1))) recall = true_positives / (possible_positives + K.epsilon()) return recall def precision(y_true, y_pred): """Precision metric. Only computes a batch-wise average of precision. Computes the precision, a metric for multi-label classification of how many selected items are relevant. """ true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1))) predicted_positives = K.sum(K.round(K.clip(y_pred, 0, 1))) precision = true_positives / (predicted_positives + K.epsilon()) return precision precision = precision(y_true, y_pred) recall = recall(y_true, y_pred) return 2*((precision*recall)/(precision+recall+K.epsilon())) def get_embeddings(sentences_list,layer_json): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :return: Dictionary with key each sentence of the sentences_list and as value the embedding ''' sentences = dict()#dict with key the index of each line of the sentences_list.txt and as value the sentence embeddings = dict()##dict with key the index of each sentence and as value the its embedding sentence_emb = dict()#key:sentence,value:its embedding with open(sentences_list,'r') as file: for index,line in enumerate(file): sentences[index] = line.strip() with open(layer_json, 'r',encoding='utf-8') as f: for line in f: embeddings[json.loads(line)['linex_index']] = np.asarray(json.loads(line)['features']) for key,value in sentences.items(): sentence_emb[value] = embeddings[key] return sentence_emb def train_classifier(sentences_list,layer_json,dataset_csv,filename): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :param dataset_csv: the path of the dataset :param filename: The path of the pickle file that the model will be stored :return: ''' dataset = pd.read_csv(dataset_csv) bert_dict = get_embeddings(sentences_list,layer_json) length = list() sentence_emb = list() previous_emb = list() next_list = list() section_list = list() label = list() errors = 0 for row in dataset.iterrows(): sentence = row[1][0].strip() previous = row[1][1].strip() nexts = row[1][2].strip() section = row[1][3].strip() if sentence in bert_dict: sentence_emb.append(bert_dict[sentence]) else: sentence_emb.append(np.zeros(768)) print(sentence) errors += 1 if previous in bert_dict: previous_emb.append(bert_dict[previous]) else: previous_emb.append(np.zeros(768)) if nexts in bert_dict: next_list.append(bert_dict[nexts]) else: next_list.append(np.zeros(768)) if section in bert_dict: section_list.append(bert_dict[section]) else: section_list.append(np.zeros(768)) length.append(row[1][4]) label.append(row[1][5]) sentence_emb =

np.asarray(sentence_emb)

numpy.asarray

''' <NAME> set up :2020-1-9 intergrate img and label into one file -- fiducial1024_v1 ''' import argparse import sys, os import pickle import random import collections import json import numpy as np import scipy.io as io import scipy.misc as m import matplotlib.pyplot as plt import glob import math import time import threading import multiprocessing as mp from multiprocessing import Pool import re import cv2 # sys.path.append('/lustre/home/gwxie/hope/project/dewarp/datasets/') # /lustre/home/gwxie/program/project/unwarp/perturbed_imgaes/GAN import utils def getDatasets(dir): return os.listdir(dir) class perturbed(utils.BasePerturbed): def __init__(self, path, bg_path, save_path, save_suffix): self.path = path self.bg_path = bg_path self.save_path = save_path self.save_suffix = save_suffix def save_img(self, m, n, fold_curve='fold', repeat_time=4, fiducial_points = 16, relativeShift_position='relativeShift_v2'): origin_img = cv2.imread(self.path, flags=cv2.IMREAD_COLOR) save_img_shape = [512*2, 480*2] # 320 # reduce_value = np.random.choice([2**4, 2**5, 2**6, 2**7, 2**8], p=[0.01, 0.1, 0.4, 0.39, 0.1]) reduce_value = np.random.choice([2*2, 4*2, 8*2, 16*2, 24*2, 32*2, 40*2, 48*2], p=[0.02, 0.18, 0.2, 0.3, 0.1, 0.1, 0.08, 0.02]) # reduce_value = np.random.choice([8*2, 16*2, 24*2, 32*2, 40*2, 48*2], p=[0.01, 0.02, 0.2, 0.4, 0.19, 0.18]) # reduce_value = np.random.choice([16, 24, 32, 40, 48, 64], p=[0.01, 0.1, 0.2, 0.4, 0.2, 0.09]) base_img_shrink = save_img_shape[0] - reduce_value # enlarge_img_shrink = [1024, 768] # enlarge_img_shrink = [896, 672] # 420 enlarge_img_shrink = [512*4, 480*4] # 420 # enlarge_img_shrink = [896*2, 768*2] # 420 # enlarge_img_shrink = [896, 768] # 420 # enlarge_img_shrink = [768, 576] # 420 # enlarge_img_shrink = [640, 480] # 420 '''''' im_lr = origin_img.shape[0] im_ud = origin_img.shape[1] reduce_value_v2 = np.random.choice([2*2, 4*2, 8*2, 16*2, 24*2, 28*2, 32*2, 48*2], p=[0.02, 0.18, 0.2, 0.2, 0.1, 0.1, 0.1, 0.1]) # reduce_value_v2 = np.random.choice([16, 24, 28, 32, 48, 64], p=[0.01, 0.1, 0.2, 0.3, 0.25, 0.14]) if im_lr > im_ud: im_ud = min(int(im_ud / im_lr * base_img_shrink), save_img_shape[1] - reduce_value_v2) im_lr = save_img_shape[0] - reduce_value else: base_img_shrink = save_img_shape[1] - reduce_value im_lr = min(int(im_lr / im_ud * base_img_shrink), save_img_shape[0] - reduce_value_v2) im_ud = base_img_shrink if round(im_lr / im_ud, 2) < 0.5 or round(im_ud / im_lr, 2) < 0.5: repeat_time = min(repeat_time, 8) edge_padding = 3 im_lr -= im_lr % (fiducial_points-1) - (2*edge_padding) # im_lr % (fiducial_points-1) - 1 im_ud -= im_ud % (fiducial_points-1) - (2*edge_padding) # im_ud % (fiducial_points-1) - 1 im_hight = np.linspace(edge_padding, im_lr - edge_padding, fiducial_points, dtype=np.int64) im_wide = np.linspace(edge_padding, im_ud - edge_padding, fiducial_points, dtype=np.int64) # im_lr -= im_lr % (fiducial_points-1) - (1+2*edge_padding) # im_lr % (fiducial_points-1) - 1 # im_ud -= im_ud % (fiducial_points-1) - (1+2*edge_padding) # im_ud % (fiducial_points-1) - 1 # im_hight = np.linspace(edge_padding, im_lr - (1+edge_padding), fiducial_points, dtype=np.int64) # im_wide = np.linspace(edge_padding, im_ud - (1+edge_padding), fiducial_points, dtype=np.int64) im_x, im_y = np.meshgrid(im_hight, im_wide) segment_x = (im_lr) // (fiducial_points-1) segment_y = (im_ud) // (fiducial_points-1) # plt.plot(im_x, im_y, # color='limegreen', # marker='.', # linestyle='') # plt.grid(True) # plt.show() self.origin_img = cv2.resize(origin_img, (im_ud, im_lr), interpolation=cv2.INTER_CUBIC) perturbed_bg_ = getDatasets(self.bg_path) perturbed_bg_img_ = self.bg_path+random.choice(perturbed_bg_) perturbed_bg_img = cv2.imread(perturbed_bg_img_, flags=cv2.IMREAD_COLOR) mesh_shape = self.origin_img.shape[:2] self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 256, dtype=np.float32)#np.zeros_like(perturbed_bg_img) # self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 0, dtype=np.int16)#np.zeros_like(perturbed_bg_img) self.new_shape = self.synthesis_perturbed_img.shape[:2] perturbed_bg_img = cv2.resize(perturbed_bg_img, (save_img_shape[1], save_img_shape[0]), cv2.INPAINT_TELEA) origin_pixel_position = np.argwhere(np.zeros(mesh_shape, dtype=np.uint32) == 0).reshape(mesh_shape[0], mesh_shape[1], 2) pixel_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape(self.new_shape[0], self.new_shape[1], 2) self.perturbed_xy_ = np.zeros((self.new_shape[0], self.new_shape[1], 2)) # self.perturbed_xy_ = pixel_position.copy().astype(np.float32) # fiducial_points_grid = origin_pixel_position[im_x, im_y] self.synthesis_perturbed_label = np.zeros((self.new_shape[0], self.new_shape[1], 2)) x_min, y_min, x_max, y_max = self.adjust_position_v2(0, 0, mesh_shape[0], mesh_shape[1], save_img_shape) origin_pixel_position += [x_min, y_min] x_min, y_min, x_max, y_max = self.adjust_position(0, 0, mesh_shape[0], mesh_shape[1]) x_shift = random.randint(-enlarge_img_shrink[0]//16, enlarge_img_shrink[0]//16) y_shift = random.randint(-enlarge_img_shrink[1]//16, enlarge_img_shrink[1]//16) x_min += x_shift x_max += x_shift y_min += y_shift y_max += y_shift '''im_x,y''' im_x += x_min im_y += y_min self.synthesis_perturbed_img[x_min:x_max, y_min:y_max] = self.origin_img self.synthesis_perturbed_label[x_min:x_max, y_min:y_max] = origin_pixel_position synthesis_perturbed_img_map = self.synthesis_perturbed_img.copy() synthesis_perturbed_label_map = self.synthesis_perturbed_label.copy() foreORbackground_label = np.full((mesh_shape), 1, dtype=np.int16) foreORbackground_label_map = np.full((self.new_shape), 0, dtype=np.int16) foreORbackground_label_map[x_min:x_max, y_min:y_max] = foreORbackground_label # synthesis_perturbed_img_map = self.pad(self.synthesis_perturbed_img.copy(), x_min, y_min, x_max, y_max) # synthesis_perturbed_label_map = self.pad(synthesis_perturbed_label_map, x_min, y_min, x_max, y_max) '''*****************************************************************''' is_normalizationFun_mixture = self.is_perform(0.2, 0.8) # if not is_normalizationFun_mixture: normalizationFun_0_1 = False # normalizationFun_0_1 = self.is_perform(0.5, 0.5) if fold_curve == 'fold': fold_curve_random = True # is_normalizationFun_mixture = False normalizationFun_0_1 = self.is_perform(0.2, 0.8) if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: fold_curve_random = self.is_perform(0.1, 0.9) # False # self.is_perform(0.01, 0.99) alpha_perturbed = random.randint(80, 160) / 100 # is_normalizationFun_mixture = False # self.is_perform(0.01, 0.99) synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) # synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 0, dtype=np.int16) synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) alpha_perturbed_change = self.is_perform(0.5, 0.5) p_pp_choice = self.is_perform(0.8, 0.2) if fold_curve == 'fold' else self.is_perform(0.1, 0.9) for repeat_i in range(repeat_time): if alpha_perturbed_change: if fold_curve == 'fold': if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: alpha_perturbed = random.randint(80, 160) / 100 '''''' linspace_x = [0, (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - 1] linspace_y = [0, (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - 1] linspace_x_seq = [1, 2, 3] linspace_y_seq = [1, 2, 3] r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_p = np.array( [random.randint(linspace_x[r_x-1] * 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 if ((r_x == 1 or r_x == 3) and (r_y == 1 or r_y == 3)) and p_pp_choice: linspace_x_seq.remove(r_x) linspace_y_seq.remove(r_y) r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_pp = np.array( [random.randint(linspace_x[r_x-1] * 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 # perturbed_p, perturbed_pp = np.array( # [random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) \ # , np.array([random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) # perturbed_p, perturbed_pp = np.array( # [random.randint((self.new_shape[0]-im_lr)//2*10, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) * 10) / 10, # random.randint((self.new_shape[1]-im_ud)//2*10, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) * 10) / 10]) \ # , np.array([random.randint((self.new_shape[0]-im_lr)//2*10, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) * 10) / 10, # random.randint((self.new_shape[1]-im_ud)//2*10, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) * 10) / 10]) '''''' perturbed_vp = perturbed_pp - perturbed_p perturbed_vp_norm = np.linalg.norm(perturbed_vp) perturbed_distance_vertex_and_line = np.dot((perturbed_p - pixel_position), perturbed_vp) / perturbed_vp_norm '''''' # perturbed_v = np.array([random.randint(-3000, 3000) / 100, random.randint(-3000, 3000) / 100]) # perturbed_v = np.array([random.randint(-4000, 4000) / 100, random.randint(-4000, 4000) / 100]) if fold_curve == 'fold' and self.is_perform(0.6, 0.4): # self.is_perform(0.3, 0.7): # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) perturbed_v = np.array([random.randint(-10000, 10000) / 100, random.randint(-10000, 10000) / 100]) # perturbed_v = np.array([random.randint(-11000, 11000) / 100, random.randint(-11000, 11000) / 100]) else: # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) # perturbed_v = np.array([random.randint(-16000, 16000) / 100, random.randint(-16000, 16000) / 100]) perturbed_v = np.array([random.randint(-8000, 8000) / 100, random.randint(-8000, 8000) / 100]) # perturbed_v = np.array([random.randint(-3500, 3500) / 100, random.randint(-3500, 3500) / 100]) # perturbed_v = np.array([random.randint(-600, 600) / 10, random.randint(-600, 600) / 10]) '''''' if fold_curve == 'fold': if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) '''''' if fold_curve_random: # omega_perturbed = (alpha_perturbed+0.2) / (perturbed_d + alpha_perturbed) # omega_perturbed = alpha_perturbed**perturbed_d omega_perturbed = alpha_perturbed / (perturbed_d + alpha_perturbed) else: omega_perturbed = 1 - perturbed_d ** alpha_perturbed '''shadow''' if self.is_perform(0.6, 0.4): synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] = np.minimum(np.maximum(synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] - np.int16(np.round(omega_perturbed[x_min:x_max, y_min:y_max].repeat(3).reshape(x_max-x_min, y_max-y_min, 3) * abs(np.linalg.norm(perturbed_v//2))*np.array([0.4-random.random()*0.1, 0.4-random.random()*0.1, 0.4-random.random()*0.1]))), 0), 255) '''''' if relativeShift_position in ['position', 'relativeShift_v2']: self.perturbed_xy_ += np.array([omega_perturbed * perturbed_v[0], omega_perturbed * perturbed_v[1]]).transpose(1, 2, 0) else: print('relativeShift_position error') exit() ''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 # synthesis_perturbed_img = np.around(synthesis_perturbed_img).astype(np.uint8) synthesis_perturbed_label[:, :, 0] *= foreORbackground_label synthesis_perturbed_label[:, :, 1] *= foreORbackground_label synthesis_perturbed_img[:, :, 0] *= foreORbackground_label synthesis_perturbed_img[:, :, 1] *= foreORbackground_label synthesis_perturbed_img[:, :, 2] *= foreORbackground_label self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label ''' '''perspective''' perspective_shreshold = random.randint(26, 36)*10 # 280 x_min_per, y_min_per, x_max_per, y_max_per = self.adjust_position(perspective_shreshold, perspective_shreshold, self.new_shape[0]-perspective_shreshold, self.new_shape[1]-perspective_shreshold) pts1 = np.float32([[x_min_per, y_min_per], [x_max_per, y_min_per], [x_min_per, y_max_per], [x_max_per, y_max_per]]) e_1_ = x_max_per - x_min_per e_2_ = y_max_per - y_min_per e_3_ = e_2_ e_4_ = e_1_ perspective_shreshold_h = e_1_*0.02 perspective_shreshold_w = e_2_*0.02 a_min_, a_max_ = 70, 110 # if self.is_perform(1, 0): if fold_curve == 'curve' and self.is_perform(0.5, 0.5): if self.is_perform(0.5, 0.5): while True: pts2 = np.around( np.float32([[x_min_per - (random.random()) * perspective_shreshold, y_min_per + (random.random()) * perspective_shreshold], [x_max_per - (random.random()) * perspective_shreshold, y_min_per - (random.random()) * perspective_shreshold], [x_min_per + (random.random()) * perspective_shreshold, y_max_per + (random.random()) * perspective_shreshold], [x_max_per + (random.random()) * perspective_shreshold, y_max_per - (random.random()) * perspective_shreshold]])) # right e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break else: while True: pts2 = np.around( np.float32([[x_min_per + (random.random()) * perspective_shreshold, y_min_per - (random.random()) * perspective_shreshold], [x_max_per + (random.random()) * perspective_shreshold, y_min_per + (random.random()) * perspective_shreshold], [x_min_per - (random.random()) * perspective_shreshold, y_max_per - (random.random()) * perspective_shreshold], [x_max_per - (random.random()) * perspective_shreshold, y_max_per + (random.random()) * perspective_shreshold]])) e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break else: while True: pts2 = np.around(np.float32([[x_min_per+(random.random()-0.5)*perspective_shreshold, y_min_per+(random.random()-0.5)*perspective_shreshold], [x_max_per+(random.random()-0.5)*perspective_shreshold, y_min_per+(random.random()-0.5)*perspective_shreshold], [x_min_per+(random.random()-0.5)*perspective_shreshold, y_max_per+(random.random()-0.5)*perspective_shreshold], [x_max_per+(random.random()-0.5)*perspective_shreshold, y_max_per+(random.random()-0.5)*perspective_shreshold]])) e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break M = cv2.getPerspectiveTransform(pts1, pts2) one = np.ones((self.new_shape[0], self.new_shape[1], 1), dtype=np.int16) matr = np.dstack((pixel_position, one)) new = np.dot(M, matr.reshape(-1, 3).T).T.reshape(self.new_shape[0], self.new_shape[1], 3) x = new[:, :, 0]/new[:, :, 2] y = new[:, :, 1]/new[:, :, 2] perturbed_xy_ = np.dstack((x, y)) # perturbed_xy_round_int = np.around(cv2.bilateralFilter(perturbed_xy_round_int, 9, 75, 75)) # perturbed_xy_round_int = np.around(cv2.blur(perturbed_xy_, (17, 17))) # perturbed_xy_round_int = cv2.blur(perturbed_xy_round_int, (17, 17)) # perturbed_xy_round_int = cv2.GaussianBlur(perturbed_xy_round_int, (7, 7), 0) perturbed_xy_ = perturbed_xy_-np.min(perturbed_xy_.T.reshape(2, -1), 1) # perturbed_xy_round_int = np.around(perturbed_xy_round_int-np.min(perturbed_xy_round_int.T.reshape(2, -1), 1)).astype(np.int16) self.perturbed_xy_ += perturbed_xy_ '''perspective end''' '''to img''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) # self.perturbed_xy_ = cv2.blur(self.perturbed_xy_, (7, 7)) self.perturbed_xy_ = cv2.GaussianBlur(self.perturbed_xy_, (7, 7), 0) '''get fiducial points''' fiducial_points_coordinate = self.perturbed_xy_[im_x, im_y] vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label self.foreORbackground_label = foreORbackground_label '''draw fiducial points stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_img.copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1,2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[1] + math.ceil(stepSize / 2), l[0] + math.ceil(stepSize / 2)), 5, (0, 0, 255), -1) cv2.imwrite('/lustre/home/gwxie/program/project/unwarp/unwarp_perturbed/TPS/img/cv_TPS_large.jpg', fiducial_points_synthesis_perturbed_img) ''' '''clip''' perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = -1, -1, self.new_shape[0], self.new_shape[1] for x in range(self.new_shape[0] // 2, perturbed_x_max): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and perturbed_x_max - 1 > x: perturbed_x_max = x break for x in range(self.new_shape[0] // 2, perturbed_x_min, -1): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and x > 0: perturbed_x_min = x break for y in range(self.new_shape[1] // 2, perturbed_y_max): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and perturbed_y_max - 1 > y: perturbed_y_max = y break for y in range(self.new_shape[1] // 2, perturbed_y_min, -1): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and y > 0: perturbed_y_min = y break if perturbed_x_min == 0 or perturbed_x_max == self.new_shape[0] or perturbed_y_min == self.new_shape[1] or perturbed_y_max == self.new_shape[1]: raise Exception('clip error') if perturbed_x_max - perturbed_x_min < im_lr//2 or perturbed_y_max - perturbed_y_min < im_ud//2: raise Exception('clip error') perfix_ = self.save_suffix+'_'+str(m)+'_'+str(n) is_shrink = False if perturbed_x_max - perturbed_x_min > save_img_shape[0] or perturbed_y_max - perturbed_y_min > save_img_shape[1]: is_shrink = True synthesis_perturbed_img = cv2.resize(self.synthesis_perturbed_img[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) synthesis_perturbed_label = cv2.resize(self.synthesis_perturbed_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) foreORbackground_label = cv2.resize(self.foreORbackground_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 '''shrink fiducial points''' center_x_l, center_y_l = perturbed_x_min + (perturbed_x_max - perturbed_x_min) // 2, perturbed_y_min + (perturbed_y_max - perturbed_y_min) // 2 fiducial_points_coordinate_copy = fiducial_points_coordinate.copy() shrink_x = im_lr/(perturbed_x_max - perturbed_x_min) shrink_y = im_ud/(perturbed_y_max - perturbed_y_min) fiducial_points_coordinate *= [shrink_x, shrink_y] center_x_l *= shrink_x center_y_l *= shrink_y # fiducial_points_coordinate[1:, 1:] *= [shrink_x, shrink_y] # fiducial_points_coordinate[1:, :1, 0] *= shrink_x # fiducial_points_coordinate[:1, 1:, 1] *= shrink_y # perturbed_x_min_copy, perturbed_y_min_copy, perturbed_x_max_copy, perturbed_y_max_copy = perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = self.adjust_position_v2(0, 0, im_lr, im_ud, self.new_shape) self.synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) self.synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) self.foreORbackground_label = np.zeros_like(self.foreORbackground_label) self.synthesis_perturbed_img[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_img self.synthesis_perturbed_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_label self.foreORbackground_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max] = foreORbackground_label center_x, center_y = perturbed_x_min + (perturbed_x_max - perturbed_x_min) // 2, perturbed_y_min + (perturbed_y_max - perturbed_y_min) // 2 if is_shrink: fiducial_points_coordinate += [center_x-center_x_l, center_y-center_y_l] '''draw fiducial points stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_img.copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1, 2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[1] + math.ceil(stepSize / 2), l[0] + math.ceil(stepSize / 2)), 5, (0, 0, 255), -1) cv2.imwrite('/lustre/home/gwxie/program/project/unwarp/unwarp_perturbed/TPS/img/cv_TPS_small.jpg',fiducial_points_synthesis_perturbed_img) ''' self.new_shape = save_img_shape self.synthesis_perturbed_img = self.synthesis_perturbed_img[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2, :].copy() self.synthesis_perturbed_label = self.synthesis_perturbed_label[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2, :].copy() self.foreORbackground_label = self.foreORbackground_label[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2].copy() perturbed_x_ = max(self.new_shape[0] - (perturbed_x_max - perturbed_x_min), 0) perturbed_x_min = perturbed_x_ // 2 perturbed_x_max = self.new_shape[0] - perturbed_x_ // 2 if perturbed_x_%2 == 0 else self.new_shape[0] - (perturbed_x_ // 2 + 1) perturbed_y_ = max(self.new_shape[1] - (perturbed_y_max - perturbed_y_min), 0) perturbed_y_min = perturbed_y_ // 2 perturbed_y_max = self.new_shape[1] - perturbed_y_ // 2 if perturbed_y_%2 == 0 else self.new_shape[1] - (perturbed_y_ // 2 + 1) '''clip perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = -1, -1, self.new_shape[0], self.new_shape[1] for x in range(self.new_shape[0] // 2, perturbed_x_max): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and perturbed_x_max - 1 > x: perturbed_x_max = x break for x in range(self.new_shape[0] // 2, perturbed_x_min, -1): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and x > 0: perturbed_x_min = x break for y in range(self.new_shape[1] // 2, perturbed_y_max): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and perturbed_y_max - 1 > y: perturbed_y_max = y break for y in range(self.new_shape[1] // 2, perturbed_y_min, -1): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and y > 0: perturbed_y_min = y break center_x, center_y = perturbed_x_min+(perturbed_x_max - perturbed_x_min)//2, perturbed_y_min+(perturbed_y_max - perturbed_y_min)//2 perfix_ = self.save_suffix+'_'+str(m)+'_'+str(n) self.new_shape = save_img_shape perturbed_x_ = max(self.new_shape[0] - (perturbed_x_max - perturbed_x_min), 0) perturbed_x_min = perturbed_x_ // 2 perturbed_x_max = self.new_shape[0] - perturbed_x_ // 2 if perturbed_x_%2 == 0 else self.new_shape[0] - (perturbed_x_ // 2 + 1) perturbed_y_ = max(self.new_shape[1] - (perturbed_y_max - perturbed_y_min), 0) perturbed_y_min = perturbed_y_ // 2 perturbed_y_max = self.new_shape[1] - perturbed_y_ // 2 if perturbed_y_%2 == 0 else self.new_shape[1] - (perturbed_y_ // 2 + 1) self.synthesis_perturbed_img = self.synthesis_perturbed_img[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2, :].copy() self.synthesis_perturbed_label = self.synthesis_perturbed_label[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2, :].copy() self.foreORbackground_label = self.foreORbackground_label[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2].copy() ''' '''save''' pixel_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape(self.new_shape[0], self.new_shape[1], 2) if relativeShift_position == 'relativeShift_v2': self.synthesis_perturbed_label -= pixel_position fiducial_points_coordinate -= [center_x - self.new_shape[0] // 2, center_y - self.new_shape[1] // 2] self.synthesis_perturbed_label[:, :, 0] *= self.foreORbackground_label self.synthesis_perturbed_label[:, :, 1] *= self.foreORbackground_label self.synthesis_perturbed_img[:, :, 0] *= self.foreORbackground_label self.synthesis_perturbed_img[:, :, 1] *= self.foreORbackground_label self.synthesis_perturbed_img[:, :, 2] *= self.foreORbackground_label ''' synthesis_perturbed_img_filter = self.synthesis_perturbed_img.copy() synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (3, 3), 0) # if self.is_perform(0.9, 0.1) or repeat_time > 5: # # if self.is_perform(0.1, 0.9) and repeat_time > 9: # # synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (7, 7), 0) # # else: # synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (5, 5), 0) # else: # synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (3, 3), 0) self.synthesis_perturbed_img[self.foreORbackground_label == 1] = synthesis_perturbed_img_filter[self.foreORbackground_label == 1] ''' ''' perturbed_bg_img = perturbed_bg_img.astype(np.float32) perturbed_bg_img[:, :, 0] *= 1 - self.foreORbackground_label perturbed_bg_img[:, :, 1] *= 1 - self.foreORbackground_label perturbed_bg_img[:, :, 2] *= 1 - self.foreORbackground_label self.synthesis_perturbed_img += perturbed_bg_img HSV perturbed_bg_img = perturbed_bg_img.astype(np.float32) if self.is_perform(0.1, 0.9): if self.is_perform(0.2, 0.8): synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_RGB2HSV) H_, S_, V_ = (random.random()-0.2)*20, (random.random()-0.2)/8, (random.random()-0.2)*20 synthesis_perturbed_img_clip_HSV[:, :, 0], synthesis_perturbed_img_clip_HSV[:, :, 1], synthesis_perturbed_img_clip_HSV[:, :, 2] = synthesis_perturbed_img_clip_HSV[:, :, 0]-H_, synthesis_perturbed_img_clip_HSV[:, :, 1]-S_, synthesis_perturbed_img_clip_HSV[:, :, 2]-V_ synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_HSV2RGB) perturbed_bg_img[:, :, 0] *= 1-self.foreORbackground_label perturbed_bg_img[:, :, 1] *= 1-self.foreORbackground_label perturbed_bg_img[:, :, 2] *= 1-self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV else: perturbed_bg_img_HSV = perturbed_bg_img perturbed_bg_img_HSV = cv2.cvtColor(perturbed_bg_img_HSV, cv2.COLOR_RGB2HSV) H_, S_, V_ = (random.random()-0.5)*20, (random.random()-0.5)/8, (random.random()-0.2)*20 perturbed_bg_img_HSV[:, :, 0], perturbed_bg_img_HSV[:, :, 1], perturbed_bg_img_HSV[:, :, 2] = perturbed_bg_img_HSV[:, :, 0]-H_, perturbed_bg_img_HSV[:, :, 1]-S_, perturbed_bg_img_HSV[:, :, 2]-V_ perturbed_bg_img_HSV = cv2.cvtColor(perturbed_bg_img_HSV, cv2.COLOR_HSV2RGB) perturbed_bg_img_HSV[:, :, 0] *= 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 1] *= 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 2] *= 1-self.foreORbackground_label self.synthesis_perturbed_img += perturbed_bg_img_HSV # self.synthesis_perturbed_img[np.sum(self.synthesis_perturbed_img, 2) == 771] = perturbed_bg_img_HSV[np.sum(self.synthesis_perturbed_img, 2) == 771] else: synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() perturbed_bg_img[:, :, 0] *= 1 - self.foreORbackground_label perturbed_bg_img[:, :, 1] *= 1 - self.foreORbackground_label perturbed_bg_img[:, :, 2] *= 1 - self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img # synthesis_perturbed_img_clip_HSV[np.sum(self.synthesis_perturbed_img, 2) == 771] = perturbed_bg_img[np.sum(self.synthesis_perturbed_img, 2) == 771] synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_RGB2HSV) H_, S_, V_ = (random.random()-0.5)*20, (random.random()-0.5)/10, (random.random()-0.4)*20 synthesis_perturbed_img_clip_HSV[:, :, 0], synthesis_perturbed_img_clip_HSV[:, :, 1], synthesis_perturbed_img_clip_HSV[:, :, 2] = synthesis_perturbed_img_clip_HSV[:, :, 0]-H_, synthesis_perturbed_img_clip_HSV[:, :, 1]-S_, synthesis_perturbed_img_clip_HSV[:, :, 2]-V_ synthesis_perturbed_img_clip_HSV = cv2.cvtColor(synthesis_perturbed_img_clip_HSV, cv2.COLOR_HSV2RGB) self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV ''' '''HSV_v2''' perturbed_bg_img = perturbed_bg_img.astype(np.float32) # if self.is_perform(1, 0): # if self.is_perform(1, 0): if self.is_perform(0.1, 0.9): if self.is_perform(0.2, 0.8): synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() synthesis_perturbed_img_clip_HSV = self.HSV_v1(synthesis_perturbed_img_clip_HSV) perturbed_bg_img[:, :, 0] *= 1-self.foreORbackground_label perturbed_bg_img[:, :, 1] *= 1-self.foreORbackground_label perturbed_bg_img[:, :, 2] *= 1-self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV else: perturbed_bg_img_HSV = perturbed_bg_img perturbed_bg_img_HSV = self.HSV_v1(perturbed_bg_img_HSV) perturbed_bg_img_HSV[:, :, 0] *= 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 1] *= 1-self.foreORbackground_label perturbed_bg_img_HSV[:, :, 2] *= 1-self.foreORbackground_label self.synthesis_perturbed_img += perturbed_bg_img_HSV # self.synthesis_perturbed_img[np.sum(self.synthesis_perturbed_img, 2) == 771] = perturbed_bg_img_HSV[np.sum(self.synthesis_perturbed_img, 2) == 771] else: synthesis_perturbed_img_clip_HSV = self.synthesis_perturbed_img.copy() perturbed_bg_img[:, :, 0] *= 1 - self.foreORbackground_label perturbed_bg_img[:, :, 1] *= 1 - self.foreORbackground_label perturbed_bg_img[:, :, 2] *= 1 - self.foreORbackground_label synthesis_perturbed_img_clip_HSV += perturbed_bg_img synthesis_perturbed_img_clip_HSV = self.HSV_v1(synthesis_perturbed_img_clip_HSV) self.synthesis_perturbed_img = synthesis_perturbed_img_clip_HSV '''''' # cv2.imwrite(self.save_path+'clip/'+perfix_+'_'+fold_curve+str(perturbed_time)+'-'+str(repeat_time)+'.png', synthesis_perturbed_img_clip) self.synthesis_perturbed_img[self.synthesis_perturbed_img < 0] = 0 self.synthesis_perturbed_img[self.synthesis_perturbed_img > 255] = 255 self.synthesis_perturbed_img = np.around(self.synthesis_perturbed_img).astype(np.uint8) label = np.zeros_like(self.synthesis_perturbed_img, dtype=np.float32) label[:, :, :2] = self.synthesis_perturbed_label label[:, :, 2] = self.foreORbackground_label # grey = np.around(self.synthesis_perturbed_img[:, :, 0] * 0.2989 + self.synthesis_perturbed_img[:, :, 1] * 0.5870 + self.synthesis_perturbed_img[:, :, 0] * 0.1140).astype(np.int16) # synthesis_perturbed_grey = np.concatenate((grey.reshape(self.new_shape[0], self.new_shape[1], 1), label), axis=2) synthesis_perturbed_color = np.concatenate((self.synthesis_perturbed_img, label), axis=2) self.synthesis_perturbed_color = np.zeros_like(synthesis_perturbed_color, dtype=np.float32) # self.synthesis_perturbed_grey = np.zeros_like(synthesis_perturbed_grey, dtype=np.float32) reduce_value_x = int(round(min((random.random() / 2) * (self.new_shape[0] - (perturbed_x_max - perturbed_x_min)), min(reduce_value, reduce_value_v2)))) reduce_value_y = int(round(min((random.random() / 2) * (self.new_shape[1] - (perturbed_y_max - perturbed_y_min)), min(reduce_value, reduce_value_v2)))) perturbed_x_min = max(perturbed_x_min - reduce_value_x, 0) perturbed_x_max = min(perturbed_x_max + reduce_value_x, self.new_shape[0]) perturbed_y_min = max(perturbed_y_min - reduce_value_y, 0) perturbed_y_max = min(perturbed_y_max + reduce_value_y, self.new_shape[1]) if im_lr >= im_ud: self.synthesis_perturbed_color[:, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_color[:, perturbed_y_min:perturbed_y_max, :] # self.synthesis_perturbed_grey[:, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_grey[:, perturbed_y_min:perturbed_y_max, :] else: self.synthesis_perturbed_color[perturbed_x_min:perturbed_x_max, :, :] = synthesis_perturbed_color[perturbed_x_min:perturbed_x_max, :, :] # self.synthesis_perturbed_grey[perturbed_x_min:perturbed_x_max, :, :] = synthesis_perturbed_grey[perturbed_x_min:perturbed_x_max, :, :] '''blur''' if self.is_perform(0.1, 0.9): synthesis_perturbed_img_filter = self.synthesis_perturbed_color[:, :, :3].copy() if self.is_perform(0.1, 0.9): synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (5, 5), 0) else: synthesis_perturbed_img_filter = cv2.GaussianBlur(synthesis_perturbed_img_filter, (3, 3), 0) if self.is_perform(0.5, 0.5): self.synthesis_perturbed_color[:, :, :3][self.synthesis_perturbed_color[:, :, 5] == 1] = synthesis_perturbed_img_filter[self.synthesis_perturbed_color[:, :, 5] == 1] else: self.synthesis_perturbed_color[:, :, :3] = synthesis_perturbed_img_filter fiducial_points_coordinate = fiducial_points_coordinate[:, :, ::-1] '''draw fiducial points''' stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_color[:, :, :3].copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1, 2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[0] + math.ceil(stepSize / 2), l[1] + math.ceil(stepSize / 2)), 2, (0, 0, 255), -1) cv2.imwrite(self.save_path + 'fiducial_points/' + perfix_ + '_' + fold_curve + '.png', fiducial_points_synthesis_perturbed_img) cv2.imwrite(self.save_path + 'png/' + perfix_ + '_' + fold_curve + '.png', self.synthesis_perturbed_color[:, :, :3]) '''forward-begin''' self.forward_mapping = np.full((save_img_shape[0], save_img_shape[1], 2), 0, dtype=np.float32) forward_mapping = np.full((save_img_shape[0], save_img_shape[1], 2), 0, dtype=np.float32) forward_position = (self.synthesis_perturbed_color[:, :, 3:5] + pixel_position)[self.synthesis_perturbed_color[:, :, 5] != 0, :] flat_position = np.argwhere(np.zeros(save_img_shape, dtype=np.uint32) == 0) vtx, wts = self.interp_weights(forward_position, flat_position) wts_sum =

np.abs(wts)

numpy.abs

# -*- coding: utf-8 -*- """ Created on Thu Nov 28 12:10:11 2019 @author: Omer """ ## File handler ## This file was initially intended purely to generate the matrices for the near earth code found in: https://public.ccsds.org/Pubs/131x1o2e2s.pdf ## The values from the above pdf were copied manually to a txt file, and it is the purpose of this file to parse it. ## The emphasis here is on correctness, I currently do not see a reason to generalise this file, since matrices will be saved in either json or some matrix friendly format. import numpy as np from scipy.linalg import circulant #import matplotlib.pyplot as plt import scipy.io import common import hashlib import os projectDir = os.environ.get('LDPC') if projectDir == None: import pathlib projectDir = pathlib.Path(__file__).parent.absolute() ## <NAME>: added on 01/12/2020, need to make sure this doesn't break anything. import sys sys.path.insert(1, projectDir) FILE_HANDLER_INT_DATA_TYPE = np.int32 GENERAL_CODE_MATRIX_DATA_TYPE = np.int32 NIBBLE_CONVERTER = np.array([8, 4, 2, 1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) def nibbleToHex(inputArray): n = NIBBLE_CONVERTER.dot(inputArray) if n == 10: h = 'A' elif n== 11: h = 'B' elif n== 12: h = 'C' elif n== 13: h = 'D' elif n== 14: h = 'E' elif n== 15: h = 'F' else: h = str(n) return h def binaryArraytoHex(inputArray): d1 = len(inputArray) assert (d1 % 4 == 0) outputArray = np.zeros(d1//4, dtype = str) outputString = '' for j in range(d1//4): nibble = inputArray[4 * j : 4 * j + 4] h = nibbleToHex(nibble) outputArray[j] = h outputString = outputString + h return outputArray, outputString def hexStringToBinaryArray(hexString): outputBinary = np.array([], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) for i in hexString: if i == '0': nibble = np.array([0,0,0,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '1': nibble = np.array([0,0,0,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '2': nibble = np.array([0,0,1,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '3': nibble = np.array([0,0,1,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '4': nibble = np.array([0,1,0,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '5': nibble = np.array([0,1,0,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '6': nibble = np.array([0,1,1,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '7': nibble = np.array([0,1,1,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '8': nibble = np.array([1,0,0,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '9': nibble = np.array([1,0,0,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == 'A': nibble = np.array([1,0,1,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == 'B': nibble = np.array([1,0,1,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == 'C': nibble = np.array([1,1,0,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == 'D': nibble = np.array([1,1,0,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == 'E': nibble = np.array([1,1,1,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == 'F': nibble = np.array([1,1,1,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) else: #print('Error, 0-9 or A-F') pass nibble = np.array([], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) outputBinary =

np.hstack((outputBinary, nibble))

numpy.hstack

import argparse import json import numpy as np import pandas as pd import os from sklearn.linear_model import LogisticRegression from sklearn.model_selection import train_test_split from sklearn.metrics import classification_report,f1_score from keras.models import Sequential from keras.layers import Dense, Dropout from keras import backend as K from keras.utils.vis_utils import plot_model from sklearn.externals import joblib import time def f1(y_true, y_pred): def recall(y_true, y_pred): """Recall metric. Only computes a batch-wise average of recall. Computes the recall, a metric for multi-label classification of how many relevant items are selected. """ true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1))) possible_positives = K.sum(K.round(K.clip(y_true, 0, 1))) recall = true_positives / (possible_positives + K.epsilon()) return recall def precision(y_true, y_pred): """Precision metric. Only computes a batch-wise average of precision. Computes the precision, a metric for multi-label classification of how many selected items are relevant. """ true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1))) predicted_positives = K.sum(K.round(K.clip(y_pred, 0, 1))) precision = true_positives / (predicted_positives + K.epsilon()) return precision precision = precision(y_true, y_pred) recall = recall(y_true, y_pred) return 2*((precision*recall)/(precision+recall+K.epsilon())) def get_embeddings(sentences_list,layer_json): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :return: Dictionary with key each sentence of the sentences_list and as value the embedding ''' sentences = dict()#dict with key the index of each line of the sentences_list.txt and as value the sentence embeddings = dict()##dict with key the index of each sentence and as value the its embedding sentence_emb = dict()#key:sentence,value:its embedding with open(sentences_list,'r') as file: for index,line in enumerate(file): sentences[index] = line.strip() with open(layer_json, 'r',encoding='utf-8') as f: for line in f: embeddings[json.loads(line)['linex_index']] = np.asarray(json.loads(line)['features']) for key,value in sentences.items(): sentence_emb[value] = embeddings[key] return sentence_emb def train_classifier(sentences_list,layer_json,dataset_csv,filename): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :param dataset_csv: the path of the dataset :param filename: The path of the pickle file that the model will be stored :return: ''' dataset = pd.read_csv(dataset_csv) bert_dict = get_embeddings(sentences_list,layer_json) length = list() sentence_emb = list() previous_emb = list() next_list = list() section_list = list() label = list() errors = 0 for row in dataset.iterrows(): sentence = row[1][0].strip() previous = row[1][1].strip() nexts = row[1][2].strip() section = row[1][3].strip() if sentence in bert_dict: sentence_emb.append(bert_dict[sentence]) else: sentence_emb.append(np.zeros(768)) print(sentence) errors += 1 if previous in bert_dict: previous_emb.append(bert_dict[previous]) else: previous_emb.append(np.zeros(768)) if nexts in bert_dict: next_list.append(bert_dict[nexts]) else: next_list.append(np.zeros(768)) if section in bert_dict: section_list.append(bert_dict[section]) else: section_list.append(np.zeros(768)) length.append(row[1][4]) label.append(row[1][5]) sentence_emb = np.asarray(sentence_emb) print(sentence_emb.shape) next_emb = np.asarray(next_list) print(next_emb.shape) previous_emb = np.asarray(previous_emb) print(previous_emb.shape) section_emb = np.asarray(section_list) print(sentence_emb.shape) length = np.asarray(length) print(length.shape) label = np.asarray(label) print(errors) features = np.concatenate([sentence_emb, previous_emb, next_emb,section_emb], axis=1) features = np.column_stack([features, length]) # np.append(features,length,axis=1) print(features.shape) X_train, X_val, y_train, y_val = train_test_split(features, label, test_size=0.33, random_state=42) log = LogisticRegression(random_state=0, solver='newton-cg', max_iter=1000, C=0.1) log.fit(X_train, y_train) #save the model _ = joblib.dump(log, filename, compress=9) predictions = log.predict(X_val) print("###########################################") print("Results using embeddings from the",layer_json,"file") print(classification_report(y_val, predictions)) print("F1 score using Logistic Regression:",f1_score(y_val, predictions)) print("###########################################") #train a DNN f1_results = list() for i in range(3): model = Sequential() model.add(Dense(64, activation='relu', trainable=True)) model.add(Dense(128, activation='relu', trainable=True)) model.add(Dropout(0.30)) model.add(Dense(64, activation='relu', trainable=True)) model.add(Dropout(0.25)) model.add(Dense(64, activation='relu', trainable=True)) model.add(Dropout(0.35)) model.add(Dense(1, activation='sigmoid')) # compile network model.compile(loss='binary_crossentropy', optimizer='sgd', metrics=[f1]) # fit network model.fit(X_train, y_train, epochs=100, batch_size=64) loss, f_1 = model.evaluate(X_val, y_val, verbose=1) print('\nTest F1: %f' % (f_1 * 100)) f1_results.append(f_1) model = None print("###########################################") print("Results using embeddings from the", layer_json, "file") # evaluate print(np.mean(f1_results)) print("###########################################") def parameter_tuning_LR(sentences_list,layer_json,dataset_csv): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :param dataset_csv: the path of the dataset :return: ''' dataset = pd.read_csv(dataset_csv) bert_dict = get_embeddings(sentences_list,layer_json) length = list() sentence_emb = list() previous_emb = list() next_list = list() section_list = list() label = list() errors = 0 for row in dataset.iterrows(): sentence = row[1][0].strip() previous = row[1][1].strip() nexts = row[1][2].strip() section = row[1][3].strip() if sentence in bert_dict: sentence_emb.append(bert_dict[sentence]) else: sentence_emb.append(np.zeros(768)) print(sentence) errors += 1 if previous in bert_dict: previous_emb.append(bert_dict[previous]) else: previous_emb.append(np.zeros(768)) if nexts in bert_dict: next_list.append(bert_dict[nexts]) else: next_list.append(np.zeros(768)) if section in bert_dict: section_list.append(bert_dict[section]) else: section_list.append(np.zeros(768)) length.append(row[1][4]) label.append(row[1][5]) sentence_emb = np.asarray(sentence_emb) print(sentence_emb.shape) next_emb = np.asarray(next_list) print(next_emb.shape) previous_emb = np.asarray(previous_emb) print(previous_emb.shape) section_emb = np.asarray(section_list) print(sentence_emb.shape) length = np.asarray(length) print(length.shape) label = np.asarray(label) print(errors) features = np.concatenate([sentence_emb, previous_emb, next_emb,section_emb], axis=1) features = np.column_stack([features, length]) print(features.shape) X_train, X_val, y_train, y_val = train_test_split(features, label, test_size=0.33, random_state=42) C = [0.1,1,2,5,10] solver = ['newton-cg','saga','sag'] best_params = dict() best_score = 0.0 for c in C: for s in solver: start = time.time() log = LogisticRegression(random_state=0, solver=s, max_iter=1000, C=c) log.fit(X_train, y_train) predictions = log.predict(X_val) print("###########################################") print("LR with C =",c,'and solver = ',s) print("Results using embeddings from the", layer_json, "file") print(classification_report(y_val, predictions)) f1 = f1_score(y_val, predictions) if f1 > best_score: best_score = f1 best_params['c'] = c best_params['solver'] = s print("F1 score using Logistic Regression:",f1) print("###########################################") end = time.time() running_time = end - start print("Running time:"+str(running_time)) def visualize_DNN(file_to_save): ''' Save the DNN architecture to a png file. Better use the Visulize_DNN.ipynd :param file_to_save: the png file that the architecture of the DNN will be saved. :return: None ''' model = Sequential() model.add(Dense(64, activation='relu', trainable=True)) model.add(Dense(128, activation='relu', trainable=True)) model.add(Dropout(0.30)) model.add(Dense(64, activation='relu', trainable=True)) model.add(Dropout(0.25)) model.add(Dense(64, activation='relu', trainable=True)) model.add(Dropout(0.35)) model.add(Dense(1, activation='sigmoid')) plot_model(model, to_file=file_to_save, show_shapes=True) def save_model(sentences_list,layer_json,dataset_csv,pkl): dataset = pd.read_csv(dataset_csv) bert_dict = get_embeddings(sentences_list, layer_json) length = list() sentence_emb = list() previous_emb = list() next_list = list() section_list = list() label = list() errors = 0 for row in dataset.iterrows(): sentence = row[1][0].strip() previous = row[1][1].strip() nexts = row[1][2].strip() section = row[1][3].strip() if sentence in bert_dict: sentence_emb.append(bert_dict[sentence]) else: sentence_emb.append(np.zeros(768)) print(sentence) errors += 1 if previous in bert_dict: previous_emb.append(bert_dict[previous]) else: previous_emb.append(np.zeros(768)) if nexts in bert_dict: next_list.append(bert_dict[nexts]) else: next_list.append(np.zeros(768)) if section in bert_dict: section_list.append(bert_dict[section]) else: section_list.append(np.zeros(768)) length.append(row[1][4]) label.append(row[1][5]) sentence_emb = np.asarray(sentence_emb) print(sentence_emb.shape) next_emb =

np.asarray(next_list)

numpy.asarray

"""Routines for numerical differentiation.""" from __future__ import division import numpy as np from numpy.linalg import norm from scipy.sparse.linalg import LinearOperator from ..sparse import issparse, csc_matrix, csr_matrix, coo_matrix, find from ._group_columns import group_dense, group_sparse EPS = np.finfo(np.float64).eps def _adjust_scheme_to_bounds(x0, h, num_steps, scheme, lb, ub): """Adjust final difference scheme to the presence of bounds. Parameters ---------- x0 : ndarray, shape (n,) Point at which we wish to estimate derivative. h : ndarray, shape (n,) Desired finite difference steps. num_steps : int Number of `h` steps in one direction required to implement finite difference scheme. For example, 2 means that we need to evaluate f(x0 + 2 * h) or f(x0 - 2 * h) scheme : {'1-sided', '2-sided'} Whether steps in one or both directions are required. In other words '1-sided' applies to forward and backward schemes, '2-sided' applies to center schemes. lb : ndarray, shape (n,) Lower bounds on independent variables. ub : ndarray, shape (n,) Upper bounds on independent variables. Returns ------- h_adjusted : ndarray, shape (n,) Adjusted step sizes. Step size decreases only if a sign flip or switching to one-sided scheme doesn't allow to take a full step. use_one_sided : ndarray of bool, shape (n,) Whether to switch to one-sided scheme. Informative only for ``scheme='2-sided'``. """ if scheme == '1-sided': use_one_sided = np.ones_like(h, dtype=bool) elif scheme == '2-sided': h = np.abs(h) use_one_sided = np.zeros_like(h, dtype=bool) else: raise ValueError("`scheme` must be '1-sided' or '2-sided'.") if np.all((lb == -np.inf) & (ub == np.inf)): return h, use_one_sided h_total = h * num_steps h_adjusted = h.copy() lower_dist = x0 - lb upper_dist = ub - x0 if scheme == '1-sided': x = x0 + h_total violated = (x < lb) | (x > ub) fitting = np.abs(h_total) <= np.maximum(lower_dist, upper_dist) h_adjusted[violated & fitting] *= -1 forward = (upper_dist >= lower_dist) & ~fitting h_adjusted[forward] = upper_dist[forward] / num_steps backward = (upper_dist < lower_dist) & ~fitting h_adjusted[backward] = -lower_dist[backward] / num_steps elif scheme == '2-sided': central = (lower_dist >= h_total) & (upper_dist >= h_total) forward = (upper_dist >= lower_dist) & ~central h_adjusted[forward] = np.minimum( h[forward], 0.5 * upper_dist[forward] / num_steps) use_one_sided[forward] = True backward = (upper_dist < lower_dist) & ~central h_adjusted[backward] = -np.minimum( h[backward], 0.5 * lower_dist[backward] / num_steps) use_one_sided[backward] = True min_dist = np.minimum(upper_dist, lower_dist) / num_steps adjusted_central = (~central & (np.abs(h_adjusted) <= min_dist)) h_adjusted[adjusted_central] = min_dist[adjusted_central] use_one_sided[adjusted_central] = False return h_adjusted, use_one_sided relative_step = {"2-point": EPS**0.5, "3-point": EPS**(1/3), "cs": EPS**0.5} def _compute_absolute_step(rel_step, x0, method): if rel_step is None: rel_step = relative_step[method] sign_x0 = (x0 >= 0).astype(float) * 2 - 1 return rel_step * sign_x0 * np.maximum(1.0, np.abs(x0)) def _prepare_bounds(bounds, x0): lb, ub = [np.asarray(b, dtype=float) for b in bounds] if lb.ndim == 0: lb = np.resize(lb, x0.shape) if ub.ndim == 0: ub = np.resize(ub, x0.shape) return lb, ub def group_columns(A, order=0): """Group columns of a 2-D matrix for sparse finite differencing [1]_. Two columns are in the same group if in each row at least one of them has zero. A greedy sequential algorithm is used to construct groups. Parameters ---------- A : array_like or sparse matrix, shape (m, n) Matrix of which to group columns. order : int, iterable of int with shape (n,) or None Permutation array which defines the order of columns enumeration. If int or None, a random permutation is used with `order` used as a random seed. Default is 0, that is use a random permutation but guarantee repeatability. Returns ------- groups : ndarray of int, shape (n,) Contains values from 0 to n_groups-1, where n_groups is the number of found groups. Each value ``groups[i]`` is an index of a group to which ith column assigned. The procedure was helpful only if n_groups is significantly less than n. References ---------- .. [1] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. """ if issparse(A): A = csc_matrix(A) else: A = np.atleast_2d(A) A = (A != 0).astype(np.int32) if A.ndim != 2: raise ValueError("`A` must be 2-dimensional.") m, n = A.shape if order is None or np.isscalar(order): rng = np.random.RandomState(order) order = rng.permutation(n) else: order = np.asarray(order) if order.shape != (n,): raise ValueError("`order` has incorrect shape.") A = A[:, order] if issparse(A): groups = group_sparse(m, n, A.indices, A.indptr) else: groups = group_dense(m, n, A) groups[order] = groups.copy() return groups def approx_derivative(fun, x0, method='3-point', rel_step=None, f0=None, bounds=(-np.inf, np.inf), sparsity=None, as_linear_operator=False, args=(), kwargs={}): """Compute finite difference approximation of the derivatives of a vector-valued function. If a function maps from R^n to R^m, its derivatives form m-by-n matrix called the Jacobian, where an element (i, j) is a partial derivative of f[i] with respect to x[j]. Parameters ---------- fun : callable Function of which to estimate the derivatives. The argument x passed to this function is ndarray of shape (n,) (never a scalar even if n=1). It must return 1-D array_like of shape (m,) or a scalar. x0 : array_like of shape (n,) or float Point at which to estimate the derivatives. Float will be converted to a 1-D array. method : {'3-point', '2-point', 'cs'}, optional Finite difference method to use: - '2-point' - use the first order accuracy forward or backward difference. - '3-point' - use central difference in interior points and the second order accuracy forward or backward difference near the boundary. - 'cs' - use a complex-step finite difference scheme. This assumes that the user function is real-valued and can be analytically continued to the complex plane. Otherwise, produces bogus results. rel_step : None or array_like, optional Relative step size to use. The absolute step size is computed as ``h = rel_step * sign(x0) * max(1, abs(x0))``, possibly adjusted to fit into the bounds. For ``method='3-point'`` the sign of `h` is ignored. If None (default) then step is selected automatically, see Notes. f0 : None or array_like, optional If not None it is assumed to be equal to ``fun(x0)``, in this case the ``fun(x0)`` is not called. Default is None. bounds : tuple of array_like, optional Lower and upper bounds on independent variables. Defaults to no bounds. Each bound must match the size of `x0` or be a scalar, in the latter case the bound will be the same for all variables. Use it to limit the range of function evaluation. Bounds checking is not implemented when `as_linear_operator` is True. sparsity : {None, array_like, sparse matrix, 2-tuple}, optional Defines a sparsity structure of the Jacobian matrix. If the Jacobian matrix is known to have only few non-zero elements in each row, then it's possible to estimate its several columns by a single function evaluation [3]_. To perform such economic computations two ingredients are required: * structure : array_like or sparse matrix of shape (m, n). A zero element means that a corresponding element of the Jacobian identically equals to zero. * groups : array_like of shape (n,). A column grouping for a given sparsity structure, use `group_columns` to obtain it. A single array or a sparse matrix is interpreted as a sparsity structure, and groups are computed inside the function. A tuple is interpreted as (structure, groups). If None (default), a standard dense differencing will be used. Note, that sparse differencing makes sense only for large Jacobian matrices where each row contains few non-zero elements. as_linear_operator : bool, optional When True the function returns an `scipy.sparse.linalg.LinearOperator`. Otherwise it returns a dense array or a sparse matrix depending on `sparsity`. The linear operator provides an efficient way of computing ``J.dot(p)`` for any vector ``p`` of shape (n,), but does not allow direct access to individual elements of the matrix. By default `as_linear_operator` is False. args, kwargs : tuple and dict, optional Additional arguments passed to `fun`. Both empty by default. The calling signature is ``fun(x, *args, **kwargs)``. Returns ------- J : {ndarray, sparse matrix, LinearOperator} Finite difference approximation of the Jacobian matrix. If `as_linear_operator` is True returns a LinearOperator with shape (m, n). Otherwise it returns a dense array or sparse matrix depending on how `sparsity` is defined. If `sparsity` is None then a ndarray with shape (m, n) is returned. If `sparsity` is not None returns a csr_matrix with shape (m, n). For sparse matrices and linear operators it is always returned as a 2-D structure, for ndarrays, if m=1 it is returned as a 1-D gradient array with shape (n,). See Also -------- check_derivative : Check correctness of a function computing derivatives. Notes ----- If `rel_step` is not provided, it assigned to ``EPS**(1/s)``, where EPS is machine epsilon for float64 numbers, s=2 for '2-point' method and s=3 for '3-point' method. Such relative step approximately minimizes a sum of truncation and round-off errors, see [1]_. A finite difference scheme for '3-point' method is selected automatically. The well-known central difference scheme is used for points sufficiently far from the boundary, and 3-point forward or backward scheme is used for points near the boundary. Both schemes have the second-order accuracy in terms of Taylor expansion. Refer to [2]_ for the formulas of 3-point forward and backward difference schemes. For dense differencing when m=1 Jacobian is returned with a shape (n,), on the other hand when n=1 Jacobian is returned with a shape (m, 1). Our motivation is the following: a) It handles a case of gradient computation (m=1) in a conventional way. b) It clearly separates these two different cases. b) In all cases np.atleast_2d can be called to get 2-D Jacobian with correct dimensions. References ---------- .. [1] W. H. Press et. al. "Numerical Recipes. The Art of Scientific Computing. 3rd edition", sec. 5.7. .. [2] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. .. [3] <NAME>, "Generation of Finite Difference Formulas on Arbitrarily Spaced Grids", Mathematics of Computation 51, 1988. Examples -------- >>> import numpy as np >>> from scipy.optimize import approx_derivative >>> >>> def f(x, c1, c2): ... return np.array([x[0] * np.sin(c1 * x[1]), ... x[0] * np.cos(c2 * x[1])]) ... >>> x0 = np.array([1.0, 0.5 * np.pi]) >>> approx_derivative(f, x0, args=(1, 2)) array([[ 1., 0.], [-1., 0.]]) Bounds can be used to limit the region of function evaluation. In the example below we compute left and right derivative at point 1.0. >>> def g(x): ... return x**2 if x >= 1 else x ... >>> x0 = 1.0 >>> approx_derivative(g, x0, bounds=(-np.inf, 1.0)) array([ 1.]) >>> approx_derivative(g, x0, bounds=(1.0, np.inf)) array([ 2.]) """ if method not in ['2-point', '3-point', 'cs']: raise ValueError("Unknown method '%s'. " % method) x0 = np.atleast_1d(x0) if x0.ndim > 1: raise ValueError("`x0` must have at most 1 dimension.") lb, ub = _prepare_bounds(bounds, x0) if lb.shape != x0.shape or ub.shape != x0.shape: raise ValueError("Inconsistent shapes between bounds and `x0`.") if as_linear_operator and not (np.all(np.isinf(lb)) and np.all(np.isinf(ub))): raise ValueError("Bounds not supported when " "`as_linear_operator` is True.") def fun_wrapped(x): f = np.atleast_1d(fun(x, *args, **kwargs)) if f.ndim > 1: raise RuntimeError("`fun` return value has " "more than 1 dimension.") return f if f0 is None: f0 = fun_wrapped(x0) else: f0 = np.atleast_1d(f0) if f0.ndim > 1: raise ValueError("`f0` passed has more than 1 dimension.") if np.any((x0 < lb) | (x0 > ub)): raise ValueError("`x0` violates bound constraints.") if as_linear_operator: if rel_step is None: rel_step = relative_step[method] return _linear_operator_difference(fun_wrapped, x0, f0, rel_step, method) else: h = _compute_absolute_step(rel_step, x0, method) if method == '2-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '1-sided', lb, ub) elif method == '3-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '2-sided', lb, ub) elif method == 'cs': use_one_sided = False if sparsity is None: return _dense_difference(fun_wrapped, x0, f0, h, use_one_sided, method) else: if not issparse(sparsity) and len(sparsity) == 2: structure, groups = sparsity else: structure = sparsity groups = group_columns(sparsity) if issparse(structure): structure = csc_matrix(structure) else: structure = np.atleast_2d(structure) groups = np.atleast_1d(groups) return _sparse_difference(fun_wrapped, x0, f0, h, use_one_sided, structure, groups, method) def _linear_operator_difference(fun, x0, f0, h, method): m = f0.size n = x0.size if method == '2-point': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return

np.zeros(m)

numpy.zeros

import numpy as np from stumpff import C, S from CelestialBody import BODIES from numerical import newton, laguerre from lagrange import calc_f, calc_fd, calc_g, calc_gd def kepler_chi(chi, alpha, r0, vr0, mu, dt): ''' Kepler's Equation of the universal anomaly, modified for use in numerical solvers. ''' z = alpha*chi**2 return (r0*vr0/np.sqrt(mu))*chi**2*C(z) + \ (1 - alpha*r0)*chi**3*S(z) + \ r0*chi - np.sqrt(mu)*dt def dkepler_dchi(chi, alpha, r0, vr0, mu, dt): ''' Derivative of Kepler's Equation of the universal anomaly, modified for use in numerical solvers. ''' z = alpha*chi**2 return (r0*vr0/np.sqrt(mu))*chi*(1 - alpha*chi**2*S(z)) + \ (1 - alpha*r0)*chi**2*C(z) + r0 def d2kepler_dchi2(chi, alpha, r0, vr0, mu, dt): ''' Second derivative of Kepler's Equation of the universal anomaly, modified for use in numerical solvers. ''' z = alpha*chi**2 S_ = S(z) return (r0*vr0/np.sqrt(mu))*(1 - 3*z*S_ + z*(C(z) - 3*S_)) + \ chi*(1 - z*S_)*(1 - alpha*r0) def solve_kepler_chi(r_0, v_0, dt, body=BODIES['Earth'], method='laguerre', tol=1e-7, max_iters=100): ''' Solve Kepler's Equation of the universal anomaly chi using the specified numerical method. Applies Algorithm 3.4 from Orbital Mechanics for Engineering Students, 4 ed, Curtis. :param r_0: `iterable` (km) initial position 3-vector :param v_0: `iterable` (km/s) initial velocity 3-vector :param dt: `float` (s) time after initial state to solve for r, v as 3-vectors :param body: `CelestialBody` (--) the celestial body to use for orbital parameters :param method: `str` (--) which numerical method to use to solve Kepler's Equation :param tol: `float` (--) decimal tolerance for numerical method (default 1e-7 is IEEE 745 single precision) :param max_iters: `int` (--) maximum number of iterations in numerical method before breaking :return: (km) final position 3-vector, (km/s) final velocity 3-vector ''' VALID_METHODS = ('laguerre', 'newton') mu = body.mu # (km**3/s**2) gravitational parameter of the specified primary body r0 = np.linalg.norm(r_0) # (km) initial position magnitude v0 = np.linalg.norm(v_0) # (km/s) initial velocity magnitude vr0 = np.dot(v_0, r_0)/r0 # (km/s) initial radial velocity magnitude alpha = 2/r0 - v0**2/mu # (1/km) inverse of semi-major axis chi0 = np.sqrt(mu)*np.abs(alpha)*dt if method not in VALID_METHODS: print(f'Method \'{method}\' is not valid, must be one of {VALID_METHODS}.\nDefaulting to laguerre method.') chi, _, _ = laguerre(chi0, kepler_chi, dkepler_dchi, d2kepler_dchi2, alpha, r0, vr0, mu, dt) elif method == 'newton': chi, _, _ = newton(chi0, kepler_chi, dkepler_dchi, alpha, r0, vr0, mu, dt) else: # method == 'laguerre' chi, _, _ = laguerre(chi0, kepler_chi, dkepler_dchi, d2kepler_dchi2, alpha, r0, vr0, mu, dt) f = calc_f(chi, r0, alpha) g = calc_g(dt, mu, chi, alpha) r_1 = f*r_0 + g*v_0 r1 = np.linalg.norm(r_1) fd = calc_fd(mu, r1, r0, alpha, chi) gd = calc_gd(chi, r1, alpha) v_1 = fd*r_0 + gd*v_0 return r_1, v_1 def solve_kepler_E(e, Me, tol=1e-7, max_iters=100): ''' Solve Kepler's Equation in the form containing Eccentric Anomaly (E), eccentricity (e), and Mean Anomaly of Ellipse (Me). Uses Algorithm 3.1 from Orbital Mechanics for Engineering Students, 4 ed, Curtis. ''' # TODO: have this function make use of one of the numerical methods in numerical.py def f(E, e, Me): return E - e*np.sin(E) - Me def fp(E, e): return 1 - e*np.cos(E) E = Me + e/2 if Me < np.pi else Me - e/2 ratio = f(E, e, Me)/fp(E, e) iters = 0 while abs(ratio) > tol and iters < max_iters: E -= ratio ratio = f(E, e, Me)/fp(E, e) iters += 1 E -= ratio converged = np.abs(ratio) <= tol return E, iters, converged def test(): ''' Test the functionality of solve_kepler_chi and solve_kepler_laguerre using Problem 3.20 from Orbital Mechanics for Engineering Students, 4 ed, Curtis. ''' # given starting information Earth = BODIES['Earth'] # `CelestialBody` (--) Earth and all the Earth things r_0 = np.array([20000, -105000, -19000]) # (km) initial position vector v_0 = np.array([0.9, -3.4, -1.5]) # (km/s) initial velocity vector dt = 2*60*60 # (s) time of interest after initial time # given correct answer from textbook correct_r_1 = np.array([26338, -128750, -29656]) # (km) final position vector correct_v_1 = np.array([0.86280, -3.2116, -1.4613]) # (km/s) final velocity vector # solve using above methods r_n, v_n = solve_kepler_chi(r_0, v_0, dt, Earth, method='newton') r_l, v_l = solve_kepler_chi(r_0, v_0, dt, Earth, method='laguerre') # check correctness # tolerance based on significant figures of given answers newton_valid = np.allclose(r_n, correct_r_1, atol=1) and np.allclose(v_n, correct_v_1, atol=1e-4) laguerre_valid =

np.allclose(r_l, correct_r_1, atol=1)

numpy.allclose

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect =

np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101)

numpy.linspace

""" This script will modulate the blinky lights using the following algorithm: 1) uses user-provided location to obtain row of pixel data from bathy image 2) samples a 'number of LEDs' number of pixels from that row 3) shifts the sampled row data to center it at the location specified by user 4) displays resulting pixels on Blinky Tape 5) shifts next row by a given latitude, also specified by user 6) sleeps for user-specified period of time Uses the following arguments: -l/--location: tuple Location of the user in tuple(lat, lon). This represents the center of the LED strip. Defaults to (0, 0) -u/--update-interval: int Update interval of the script, in minutes. Defaults to 10. -p/--port: str Serial port of the BlinkyLight (e.g., 'ttyAMA0', 'COM3'). Defaults to 'COM5'. -d/--delta_latitude: int Vertical change in latitude every update rate. May be 0, but this will result in a never-changing LEDs. -i/--image: str Name of the PNG image that contains the color coded pathymetric data. The file current named mapserv.png was obtained using the following API: https://www.gebco.net/data_and_products/gebco_web_services/web_map_service/mapserv?request=getmap&service=wms&BBOX=-90,-180,90,180&format=image/png&height=600&width=1200&crs=EPSG:4326&layers=GEBCO_LATEST_SUB_ICE_TOPO&version=1.3.0 In lieu of providing command line arguments, you may alternatively edit the defaults in bath_config.json. NOTE: runs via: runfile('/BlinkyTape_Python/bathymetry_blink/bathymetry_blink.py', wdir='/BlinkyTape_Python/') (C) 2021 <NAME> (https://joeycodes.dev) MIT Licensed """ import optparse import json from blinkytape import BlinkyTape from time import sleep from PIL import Image import numpy as np import sys MAX_ERRORS = 3 num_errors = 0 # Obtain default parameters with open("./bathymetry_blink/bathy_config.json") as f: config = json.load(f) # Default Blinky Tape port on Raspberry Pi is /dev/ttyACM0 parser = optparse.OptionParser() parser.add_option("-p", "--port", dest="portname", help="serial port (ex: /dev/ttyACM0)", default=config["port"]) parser.add_option("-l", "--location", dest="location", help="Location of the center of the LED strip (ex: 70,-110)", default=config["location"]) parser.add_option("-u", "--update-rate", dest="update_rate", help="How often to update elevation profile (mins) (ex: 5)", default=config["update_rate"]) parser.add_option("-d", "--delta-latitude", dest="delta_latitude", help="Change in latitude during update (ex: 5)", default=config["delta_latitude"]) parser.add_option("-n", "--num-leds", dest="num_leds", help="Number of LEDs in strip (ex: 60)", default=config["num_leds"]) parser.add_option("-i", "--image", dest="image_name", help="Name of the map/bathymetry image (ex: ./mapserv.png)", default=config["image"]) (options, args) = parser.parse_args() if args: print("Unknown parameters: " + args) # grab the values provided by user (or defaults) port = options.portname loc = options.location rate = options.update_rate delta = options.delta_latitude n_leds = options.num_leds i_name = options.image_name # Some visual indication that it works, for headless setups (green tape) bt = BlinkyTape(port, n_leds) bt.displayColor(0, 100, 0) bt.show() sleep(2) while True: try: # first, load image im = Image.open(i_name) # Can be many different formats. cols, rows = im.size a =

np.asarray(im)

numpy.asarray

# # Copyright (c) 2021 The GPflux Contributors. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. # import abc import numpy as np import pytest import tensorflow as tf import tensorflow_probability as tfp from gpflow.kullback_leiblers import gauss_kl from gpflux.encoders import DirectlyParameterizedNormalDiag from gpflux.layers import LatentVariableLayer, LayerWithObservations, TrackableLayer tf.keras.backend.set_floatx("float64") ############ # Utilities ############ def _zero_one_normal_prior(w_dim): """ N(0, I) prior """ return tfp.distributions.MultivariateNormalDiag(loc=np.zeros(w_dim), scale_diag=np.ones(w_dim)) def get_distributions_with_w_dim(): distributions = [] for d in [1, 5]: mean = np.zeros(d) scale_tri_l = np.eye(d) mvn = tfp.distributions.MultivariateNormalTriL(mean, scale_tri_l) std = np.ones(d) mvn_diag = tfp.distributions.MultivariateNormalDiag(mean, std) distributions.append((mvn, d)) distributions.append((mvn_diag, d)) return distributions ############ # Tests ############ @pytest.mark.parametrize("distribution, w_dim", get_distributions_with_w_dim()) def test_local_kls(distribution, w_dim): lv = LatentVariableLayer(encoder=None, prior=distribution) # test kl is 0 when posteriors == priors posterior = distribution assert lv._local_kls(posterior) == 0 # test kl > 0 when posteriors != priors batch_size = 10 params = distribution.parameters posterior_params = { k: [v + 0.5 for _ in range(batch_size)] for k, v in params.items() if isinstance(v, np.ndarray) } posterior = lv.distribution_class(**posterior_params) local_kls = lv._local_kls(posterior) assert

np.all(local_kls > 0)

numpy.all

import numpy as np from scipy import ndimage def erode_value_blobs(array, steps=1, values_to_ignore=tuple(), new_value=0): unique_values = list(

np.unique(array)

numpy.unique

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi *

np.ones(101)

numpy.ones

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 =

np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101)

numpy.linspace

"""Routines for numerical differentiation.""" from __future__ import division import numpy as np from numpy.linalg import norm from scipy.sparse.linalg import LinearOperator from ..sparse import issparse, csc_matrix, csr_matrix, coo_matrix, find from ._group_columns import group_dense, group_sparse EPS = np.finfo(np.float64).eps def _adjust_scheme_to_bounds(x0, h, num_steps, scheme, lb, ub): """Adjust final difference scheme to the presence of bounds. Parameters ---------- x0 : ndarray, shape (n,) Point at which we wish to estimate derivative. h : ndarray, shape (n,) Desired finite difference steps. num_steps : int Number of `h` steps in one direction required to implement finite difference scheme. For example, 2 means that we need to evaluate f(x0 + 2 * h) or f(x0 - 2 * h) scheme : {'1-sided', '2-sided'} Whether steps in one or both directions are required. In other words '1-sided' applies to forward and backward schemes, '2-sided' applies to center schemes. lb : ndarray, shape (n,) Lower bounds on independent variables. ub : ndarray, shape (n,) Upper bounds on independent variables. Returns ------- h_adjusted : ndarray, shape (n,) Adjusted step sizes. Step size decreases only if a sign flip or switching to one-sided scheme doesn't allow to take a full step. use_one_sided : ndarray of bool, shape (n,) Whether to switch to one-sided scheme. Informative only for ``scheme='2-sided'``. """ if scheme == '1-sided': use_one_sided = np.ones_like(h, dtype=bool) elif scheme == '2-sided': h = np.abs(h) use_one_sided = np.zeros_like(h, dtype=bool) else: raise ValueError("`scheme` must be '1-sided' or '2-sided'.") if np.all((lb == -np.inf) & (ub == np.inf)): return h, use_one_sided h_total = h * num_steps h_adjusted = h.copy() lower_dist = x0 - lb upper_dist = ub - x0 if scheme == '1-sided': x = x0 + h_total violated = (x < lb) | (x > ub) fitting = np.abs(h_total) <= np.maximum(lower_dist, upper_dist) h_adjusted[violated & fitting] *= -1 forward = (upper_dist >= lower_dist) & ~fitting h_adjusted[forward] = upper_dist[forward] / num_steps backward = (upper_dist < lower_dist) & ~fitting h_adjusted[backward] = -lower_dist[backward] / num_steps elif scheme == '2-sided': central = (lower_dist >= h_total) & (upper_dist >= h_total) forward = (upper_dist >= lower_dist) & ~central h_adjusted[forward] = np.minimum( h[forward], 0.5 * upper_dist[forward] / num_steps) use_one_sided[forward] = True backward = (upper_dist < lower_dist) & ~central h_adjusted[backward] = -np.minimum( h[backward], 0.5 * lower_dist[backward] / num_steps) use_one_sided[backward] = True min_dist = np.minimum(upper_dist, lower_dist) / num_steps adjusted_central = (~central & (np.abs(h_adjusted) <= min_dist)) h_adjusted[adjusted_central] = min_dist[adjusted_central] use_one_sided[adjusted_central] = False return h_adjusted, use_one_sided relative_step = {"2-point": EPS**0.5, "3-point": EPS**(1/3), "cs": EPS**0.5} def _compute_absolute_step(rel_step, x0, method): if rel_step is None: rel_step = relative_step[method] sign_x0 = (x0 >= 0).astype(float) * 2 - 1 return rel_step * sign_x0 * np.maximum(1.0, np.abs(x0)) def _prepare_bounds(bounds, x0): lb, ub = [np.asarray(b, dtype=float) for b in bounds] if lb.ndim == 0: lb = np.resize(lb, x0.shape) if ub.ndim == 0: ub = np.resize(ub, x0.shape) return lb, ub def group_columns(A, order=0): """Group columns of a 2-D matrix for sparse finite differencing [1]_. Two columns are in the same group if in each row at least one of them has zero. A greedy sequential algorithm is used to construct groups. Parameters ---------- A : array_like or sparse matrix, shape (m, n) Matrix of which to group columns. order : int, iterable of int with shape (n,) or None Permutation array which defines the order of columns enumeration. If int or None, a random permutation is used with `order` used as a random seed. Default is 0, that is use a random permutation but guarantee repeatability. Returns ------- groups : ndarray of int, shape (n,) Contains values from 0 to n_groups-1, where n_groups is the number of found groups. Each value ``groups[i]`` is an index of a group to which ith column assigned. The procedure was helpful only if n_groups is significantly less than n. References ---------- .. [1] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. """ if issparse(A): A = csc_matrix(A) else: A = np.atleast_2d(A) A = (A != 0).astype(np.int32) if A.ndim != 2: raise ValueError("`A` must be 2-dimensional.") m, n = A.shape if order is None or np.isscalar(order): rng = np.random.RandomState(order) order = rng.permutation(n) else: order = np.asarray(order) if order.shape != (n,): raise ValueError("`order` has incorrect shape.") A = A[:, order] if issparse(A): groups = group_sparse(m, n, A.indices, A.indptr) else: groups = group_dense(m, n, A) groups[order] = groups.copy() return groups def approx_derivative(fun, x0, method='3-point', rel_step=None, f0=None, bounds=(-np.inf, np.inf), sparsity=None, as_linear_operator=False, args=(), kwargs={}): """Compute finite difference approximation of the derivatives of a vector-valued function. If a function maps from R^n to R^m, its derivatives form m-by-n matrix called the Jacobian, where an element (i, j) is a partial derivative of f[i] with respect to x[j]. Parameters ---------- fun : callable Function of which to estimate the derivatives. The argument x passed to this function is ndarray of shape (n,) (never a scalar even if n=1). It must return 1-D array_like of shape (m,) or a scalar. x0 : array_like of shape (n,) or float Point at which to estimate the derivatives. Float will be converted to a 1-D array. method : {'3-point', '2-point', 'cs'}, optional Finite difference method to use: - '2-point' - use the first order accuracy forward or backward difference. - '3-point' - use central difference in interior points and the second order accuracy forward or backward difference near the boundary. - 'cs' - use a complex-step finite difference scheme. This assumes that the user function is real-valued and can be analytically continued to the complex plane. Otherwise, produces bogus results. rel_step : None or array_like, optional Relative step size to use. The absolute step size is computed as ``h = rel_step * sign(x0) * max(1, abs(x0))``, possibly adjusted to fit into the bounds. For ``method='3-point'`` the sign of `h` is ignored. If None (default) then step is selected automatically, see Notes. f0 : None or array_like, optional If not None it is assumed to be equal to ``fun(x0)``, in this case the ``fun(x0)`` is not called. Default is None. bounds : tuple of array_like, optional Lower and upper bounds on independent variables. Defaults to no bounds. Each bound must match the size of `x0` or be a scalar, in the latter case the bound will be the same for all variables. Use it to limit the range of function evaluation. Bounds checking is not implemented when `as_linear_operator` is True. sparsity : {None, array_like, sparse matrix, 2-tuple}, optional Defines a sparsity structure of the Jacobian matrix. If the Jacobian matrix is known to have only few non-zero elements in each row, then it's possible to estimate its several columns by a single function evaluation [3]_. To perform such economic computations two ingredients are required: * structure : array_like or sparse matrix of shape (m, n). A zero element means that a corresponding element of the Jacobian identically equals to zero. * groups : array_like of shape (n,). A column grouping for a given sparsity structure, use `group_columns` to obtain it. A single array or a sparse matrix is interpreted as a sparsity structure, and groups are computed inside the function. A tuple is interpreted as (structure, groups). If None (default), a standard dense differencing will be used. Note, that sparse differencing makes sense only for large Jacobian matrices where each row contains few non-zero elements. as_linear_operator : bool, optional When True the function returns an `scipy.sparse.linalg.LinearOperator`. Otherwise it returns a dense array or a sparse matrix depending on `sparsity`. The linear operator provides an efficient way of computing ``J.dot(p)`` for any vector ``p`` of shape (n,), but does not allow direct access to individual elements of the matrix. By default `as_linear_operator` is False. args, kwargs : tuple and dict, optional Additional arguments passed to `fun`. Both empty by default. The calling signature is ``fun(x, *args, **kwargs)``. Returns ------- J : {ndarray, sparse matrix, LinearOperator} Finite difference approximation of the Jacobian matrix. If `as_linear_operator` is True returns a LinearOperator with shape (m, n). Otherwise it returns a dense array or sparse matrix depending on how `sparsity` is defined. If `sparsity` is None then a ndarray with shape (m, n) is returned. If `sparsity` is not None returns a csr_matrix with shape (m, n). For sparse matrices and linear operators it is always returned as a 2-D structure, for ndarrays, if m=1 it is returned as a 1-D gradient array with shape (n,). See Also -------- check_derivative : Check correctness of a function computing derivatives. Notes ----- If `rel_step` is not provided, it assigned to ``EPS**(1/s)``, where EPS is machine epsilon for float64 numbers, s=2 for '2-point' method and s=3 for '3-point' method. Such relative step approximately minimizes a sum of truncation and round-off errors, see [1]_. A finite difference scheme for '3-point' method is selected automatically. The well-known central difference scheme is used for points sufficiently far from the boundary, and 3-point forward or backward scheme is used for points near the boundary. Both schemes have the second-order accuracy in terms of Taylor expansion. Refer to [2]_ for the formulas of 3-point forward and backward difference schemes. For dense differencing when m=1 Jacobian is returned with a shape (n,), on the other hand when n=1 Jacobian is returned with a shape (m, 1). Our motivation is the following: a) It handles a case of gradient computation (m=1) in a conventional way. b) It clearly separates these two different cases. b) In all cases np.atleast_2d can be called to get 2-D Jacobian with correct dimensions. References ---------- .. [1] W. H. Press et. al. "Numerical Recipes. The Art of Scientific Computing. 3rd edition", sec. 5.7. .. [2] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. .. [3] <NAME>, "Generation of Finite Difference Formulas on Arbitrarily Spaced Grids", Mathematics of Computation 51, 1988. Examples -------- >>> import numpy as np >>> from scipy.optimize import approx_derivative >>> >>> def f(x, c1, c2): ... return np.array([x[0] * np.sin(c1 * x[1]), ... x[0] * np.cos(c2 * x[1])]) ... >>> x0 = np.array([1.0, 0.5 * np.pi]) >>> approx_derivative(f, x0, args=(1, 2)) array([[ 1., 0.], [-1., 0.]]) Bounds can be used to limit the region of function evaluation. In the example below we compute left and right derivative at point 1.0. >>> def g(x): ... return x**2 if x >= 1 else x ... >>> x0 = 1.0 >>> approx_derivative(g, x0, bounds=(-np.inf, 1.0)) array([ 1.]) >>> approx_derivative(g, x0, bounds=(1.0, np.inf)) array([ 2.]) """ if method not in ['2-point', '3-point', 'cs']: raise ValueError("Unknown method '%s'. " % method) x0 = np.atleast_1d(x0) if x0.ndim > 1: raise ValueError("`x0` must have at most 1 dimension.") lb, ub = _prepare_bounds(bounds, x0) if lb.shape != x0.shape or ub.shape != x0.shape: raise ValueError("Inconsistent shapes between bounds and `x0`.") if as_linear_operator and not (np.all(np.isinf(lb)) and np.all(np.isinf(ub))): raise ValueError("Bounds not supported when " "`as_linear_operator` is True.") def fun_wrapped(x): f = np.atleast_1d(fun(x, *args, **kwargs)) if f.ndim > 1: raise RuntimeError("`fun` return value has " "more than 1 dimension.") return f if f0 is None: f0 = fun_wrapped(x0) else: f0 = np.atleast_1d(f0) if f0.ndim > 1: raise ValueError("`f0` passed has more than 1 dimension.") if np.any((x0 < lb) | (x0 > ub)): raise ValueError("`x0` violates bound constraints.") if as_linear_operator: if rel_step is None: rel_step = relative_step[method] return _linear_operator_difference(fun_wrapped, x0, f0, rel_step, method) else: h = _compute_absolute_step(rel_step, x0, method) if method == '2-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '1-sided', lb, ub) elif method == '3-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '2-sided', lb, ub) elif method == 'cs': use_one_sided = False if sparsity is None: return _dense_difference(fun_wrapped, x0, f0, h, use_one_sided, method) else: if not issparse(sparsity) and len(sparsity) == 2: structure, groups = sparsity else: structure = sparsity groups = group_columns(sparsity) if issparse(structure): structure = csc_matrix(structure) else: structure = np.atleast_2d(structure) groups = np.atleast_1d(groups) return _sparse_difference(fun_wrapped, x0, f0, h, use_one_sided, structure, groups, method) def _linear_operator_difference(fun, x0, f0, h, method): m = f0.size n = x0.size if method == '2-point': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return np.zeros(m) dx = h / norm(p) x = x0 + dx*p df = fun(x) - f0 return df / dx elif method == '3-point': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return np.zeros(m) dx = 2*h / norm(p) x1 = x0 - (dx/2)*p x2 = x0 + (dx/2)*p f1 = fun(x1) f2 = fun(x2) df = f2 - f1 return df / dx elif method == 'cs': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return np.zeros(m) dx = h /

norm(p)

numpy.linalg.norm

from abc import ABCMeta, abstractmethod import os from vmaf.tools.misc import make_absolute_path, run_process from vmaf.tools.stats import ListStats __copyright__ = "Copyright 2016-2018, Netflix, Inc." __license__ = "Apache, Version 2.0" import re import numpy as np import ast from vmaf import ExternalProgramCaller, to_list from vmaf.config import VmafConfig, VmafExternalConfig from vmaf.core.executor import Executor from vmaf.core.result import Result from vmaf.tools.reader import YuvReader class FeatureExtractor(Executor): """ FeatureExtractor takes in a list of assets, and run feature extraction on them, and return a list of corresponding results. A FeatureExtractor must specify a unique type and version combination (by the TYPE and VERSION attribute), so that the Result generated by it can be identified. A derived class of FeatureExtractor must: 1) Override TYPE and VERSION 2) Override _generate_result(self, asset), which call a command-line executable and generate feature scores in a log file. 3) Override _get_feature_scores(self, asset), which read the feature scores from the log file, and return the scores in a dictionary format. For an example, follow VmafFeatureExtractor. """ __metaclass__ = ABCMeta @property @abstractmethod def ATOM_FEATURES(self): raise NotImplementedError def _read_result(self, asset): result = {} result.update(self._get_feature_scores(asset)) executor_id = self.executor_id return Result(asset, executor_id, result) @classmethod def get_scores_key(cls, atom_feature): return "{type}_{atom_feature}_scores".format( type=cls.TYPE, atom_feature=atom_feature) @classmethod def get_score_key(cls, atom_feature): return "{type}_{atom_feature}_score".format( type=cls.TYPE, atom_feature=atom_feature) def _get_feature_scores(self, asset): # routine to read the feature scores from the log file, and return # the scores in a dictionary format. log_file_path = self._get_log_file_path(asset) atom_feature_scores_dict = {} atom_feature_idx_dict = {} for atom_feature in self.ATOM_FEATURES: atom_feature_scores_dict[atom_feature] = [] atom_feature_idx_dict[atom_feature] = 0 with open(log_file_path, 'rt') as log_file: for line in log_file.readlines(): for atom_feature in self.ATOM_FEATURES: re_template = "{af}: ([0-9]+) ([a-zA-Z0-9.-]+)".format(af=atom_feature) mo = re.match(re_template, line) if mo: cur_idx = int(mo.group(1)) assert cur_idx == atom_feature_idx_dict[atom_feature] # parse value, allowing NaN and inf val = float(mo.group(2)) if np.isnan(val) or np.isinf(val): val = None atom_feature_scores_dict[atom_feature].append(val) atom_feature_idx_dict[atom_feature] += 1 continue len_score = len(atom_feature_scores_dict[self.ATOM_FEATURES[0]]) assert len_score != 0 for atom_feature in self.ATOM_FEATURES[1:]: assert len_score == len(atom_feature_scores_dict[atom_feature]), \ "Feature data possibly corrupt. Run cleanup script and try again." feature_result = {} for atom_feature in self.ATOM_FEATURES: scores_key = self.get_scores_key(atom_feature) feature_result[scores_key] = atom_feature_scores_dict[atom_feature] return feature_result class VmafFeatureExtractor(FeatureExtractor): TYPE = "VMAF_feature" # VERSION = '0.1' # vmaf_study; Anush's VIF fix # VERSION = '0.2' # expose vif_num, vif_den, adm_num, adm_den, anpsnr # VERSION = '0.2.1' # expose vif num/den of each scale # VERSION = '0.2.2' # adm abs-->fabs, corrected border handling, uniform reading with option of offset for input YUV, updated VIF corner case # VERSION = '0.2.2b' # expose adm_den/num_scalex # VERSION = '0.2.3' # AVX for VMAF convolution; update adm features by folding noise floor into per coef # VERSION = '0.2.4' # Fix a bug in adm feature passing scale into dwt_quant_step # VERSION = '0.2.4b' # Modify by adding ADM noise floor outside cube root; add derived feature motion2 VERSION = '0.2.4c' # Modify by moving motion2 to c code ATOM_FEATURES = ['vif', 'adm', 'ansnr', 'motion', 'motion2', 'vif_num', 'vif_den', 'adm_num', 'adm_den', 'anpsnr', 'vif_num_scale0', 'vif_den_scale0', 'vif_num_scale1', 'vif_den_scale1', 'vif_num_scale2', 'vif_den_scale2', 'vif_num_scale3', 'vif_den_scale3', 'adm_num_scale0', 'adm_den_scale0', 'adm_num_scale1', 'adm_den_scale1', 'adm_num_scale2', 'adm_den_scale2', 'adm_num_scale3', 'adm_den_scale3', ] DERIVED_ATOM_FEATURES = ['vif_scale0', 'vif_scale1', 'vif_scale2', 'vif_scale3', 'vif2', 'adm2', 'adm3', 'adm_scale0', 'adm_scale1', 'adm_scale2', 'adm_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vmaf_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VmafFeatureExtractor, cls)._post_process_result(result) # adm2 = # (adm_num + ADM2_CONSTANT) / (adm_den + ADM2_CONSTANT) adm2_scores_key = cls.get_scores_key('adm2') adm_num_scores_key = cls.get_scores_key('adm_num') adm_den_scores_key = cls.get_scores_key('adm_den') result.result_dict[adm2_scores_key] = list( (np.array(result.result_dict[adm_num_scores_key]) + cls.ADM2_CONSTANT) / (np.array(result.result_dict[adm_den_scores_key]) + cls.ADM2_CONSTANT) ) # vif_scalei = vif_num_scalei / vif_den_scalei, i = 0, 1, 2, 3 vif_num_scale0_scores_key = cls.get_scores_key('vif_num_scale0') vif_den_scale0_scores_key = cls.get_scores_key('vif_den_scale0') vif_num_scale1_scores_key = cls.get_scores_key('vif_num_scale1') vif_den_scale1_scores_key = cls.get_scores_key('vif_den_scale1') vif_num_scale2_scores_key = cls.get_scores_key('vif_num_scale2') vif_den_scale2_scores_key = cls.get_scores_key('vif_den_scale2') vif_num_scale3_scores_key = cls.get_scores_key('vif_num_scale3') vif_den_scale3_scores_key = cls.get_scores_key('vif_den_scale3') vif_scale0_scores_key = cls.get_scores_key('vif_scale0') vif_scale1_scores_key = cls.get_scores_key('vif_scale1') vif_scale2_scores_key = cls.get_scores_key('vif_scale2') vif_scale3_scores_key = cls.get_scores_key('vif_scale3') result.result_dict[vif_scale0_scores_key] = list( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) ) result.result_dict[vif_scale1_scores_key] = list( (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) ) result.result_dict[vif_scale2_scores_key] = list( (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) ) result.result_dict[vif_scale3_scores_key] = list( (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) # vif2 = # ((vif_num_scale0 / vif_den_scale0) + (vif_num_scale1 / vif_den_scale1) + # (vif_num_scale2 / vif_den_scale2) + (vif_num_scale3 / vif_den_scale3)) / 4.0 vif_scores_key = cls.get_scores_key('vif2') result.result_dict[vif_scores_key] = list( ( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) + (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) + (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) + (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) / 4.0 ) # adm_scalei = adm_num_scalei / adm_den_scalei, i = 0, 1, 2, 3 adm_num_scale0_scores_key = cls.get_scores_key('adm_num_scale0') adm_den_scale0_scores_key = cls.get_scores_key('adm_den_scale0') adm_num_scale1_scores_key = cls.get_scores_key('adm_num_scale1') adm_den_scale1_scores_key = cls.get_scores_key('adm_den_scale1') adm_num_scale2_scores_key = cls.get_scores_key('adm_num_scale2') adm_den_scale2_scores_key = cls.get_scores_key('adm_den_scale2') adm_num_scale3_scores_key = cls.get_scores_key('adm_num_scale3') adm_den_scale3_scores_key = cls.get_scores_key('adm_den_scale3') adm_scale0_scores_key = cls.get_scores_key('adm_scale0') adm_scale1_scores_key = cls.get_scores_key('adm_scale1') adm_scale2_scores_key = cls.get_scores_key('adm_scale2') adm_scale3_scores_key = cls.get_scores_key('adm_scale3') result.result_dict[adm_scale0_scores_key] = list( (np.array(result.result_dict[adm_num_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale1_scores_key] = list( (np.array(result.result_dict[adm_num_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale2_scores_key] = list( (np.array(result.result_dict[adm_num_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale3_scores_key] = list( (np.array(result.result_dict[adm_num_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) ) # adm3 = \ # (((adm_num_scale0 + ADM_SCALE_CONSTANT) / (adm_den_scale0 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale1 + ADM_SCALE_CONSTANT) / (adm_den_scale1 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale2 + ADM_SCALE_CONSTANT) / (adm_den_scale2 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale3 + ADM_SCALE_CONSTANT) / (adm_den_scale3 + ADM_SCALE_CONSTANT))) / 4.0 adm3_scores_key = cls.get_scores_key('adm3') result.result_dict[adm3_scores_key] = list( ( ((np.array(result.result_dict[adm_num_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT)) ) / 4.0 ) # validate for feature in cls.DERIVED_ATOM_FEATURES: assert cls.get_scores_key(feature) in result.result_dict return result class VifFrameDifferenceFeatureExtractor(FeatureExtractor): TYPE = "VifDiff_feature" VERSION = '0.1' ATOM_FEATURES = ['vifdiff', 'vifdiff_num', 'vifdiff_den', 'vifdiff_num_scale0', 'vifdiff_den_scale0', 'vifdiff_num_scale1', 'vifdiff_den_scale1', 'vifdiff_num_scale2', 'vifdiff_den_scale2', 'vifdiff_num_scale3', 'vifdiff_den_scale3', ] DERIVED_ATOM_FEATURES = ['vifdiff_scale0', 'vifdiff_scale1', 'vifdiff_scale2', 'vifdiff_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vifdiff_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VifFrameDifferenceFeatureExtractor, cls)._post_process_result(result) # vifdiff_scalei = vifdiff_num_scalei / vifdiff_den_scalei, i = 0, 1, 2, 3 vifdiff_num_scale0_scores_key = cls.get_scores_key('vifdiff_num_scale0') vifdiff_den_scale0_scores_key = cls.get_scores_key('vifdiff_den_scale0') vifdiff_num_scale1_scores_key = cls.get_scores_key('vifdiff_num_scale1') vifdiff_den_scale1_scores_key = cls.get_scores_key('vifdiff_den_scale1') vifdiff_num_scale2_scores_key = cls.get_scores_key('vifdiff_num_scale2') vifdiff_den_scale2_scores_key = cls.get_scores_key('vifdiff_den_scale2') vifdiff_num_scale3_scores_key = cls.get_scores_key('vifdiff_num_scale3') vifdiff_den_scale3_scores_key = cls.get_scores_key('vifdiff_den_scale3') vifdiff_scale0_scores_key = cls.get_scores_key('vifdiff_scale0') vifdiff_scale1_scores_key = cls.get_scores_key('vifdiff_scale1') vifdiff_scale2_scores_key = cls.get_scores_key('vifdiff_scale2') vifdiff_scale3_scores_key = cls.get_scores_key('vifdiff_scale3') result.result_dict[vifdiff_scale0_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale0_scores_key]) / np.array(result.result_dict[vifdiff_den_scale0_scores_key])) ) result.result_dict[vifdiff_scale1_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale1_scores_key]) / np.array(result.result_dict[vifdiff_den_scale1_scores_key])) ) result.result_dict[vifdiff_scale2_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale2_scores_key]) / np.array(result.result_dict[vifdiff_den_scale2_scores_key])) ) result.result_dict[vifdiff_scale3_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale3_scores_key]) / np.array(result.result_dict[vifdiff_den_scale3_scores_key])) ) # validate for feature in cls.DERIVED_ATOM_FEATURES: assert cls.get_scores_key(feature) in result.result_dict return result class PsnrFeatureExtractor(FeatureExtractor): TYPE = "PSNR_feature" VERSION = "1.0" ATOM_FEATURES = ['psnr'] def _generate_result(self, asset): # routine to call the command-line executable and generate quality # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_psnr(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) class MomentFeatureExtractor(FeatureExtractor): TYPE = "Moment_feature" # VERSION = "1.0" # call executable VERSION = "1.1" # python only ATOM_FEATURES = ['ref1st', 'ref2nd', 'dis1st', 'dis2nd', ] DERIVED_ATOM_FEATURES = ['refvar', 'disvar', ] def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_w, quality_h = asset.quality_width_height ref_scores_mtx = None with YuvReader(filepath=asset.ref_workfile_path, width=quality_w, height=quality_h, yuv_type=self._get_workfile_yuv_type(asset)) as ref_yuv_reader: scores_mtx_list = [] i = 0 for ref_yuv in ref_yuv_reader: ref_y = ref_yuv[0] firstm = ref_y.mean() secondm = ref_y.var() + firstm**2 scores_mtx_list.append(np.hstack(([firstm], [secondm]))) i += 1 ref_scores_mtx =

np.vstack(scores_mtx_list)

numpy.vstack

# coding: utf-8 # Licensed under a 3-clause BSD style license - see LICENSE.rst """ Test the Logarithmic Units and Quantities """ from __future__ import (absolute_import, unicode_literals, division, print_function) from ...extern import six from ...extern.six.moves import zip import pickle import itertools import pytest import numpy as np from numpy.testing.utils import assert_allclose from ...tests.helper import assert_quantity_allclose from ... import units as u, constants as c lu_units = [u.dex, u.mag, u.decibel] lu_subclasses = [u.DexUnit, u.MagUnit, u.DecibelUnit] lq_subclasses = [u.Dex, u.Magnitude, u.Decibel] pu_sample = (u.dimensionless_unscaled, u.m, u.g/u.s**2, u.Jy) class TestLogUnitCreation(object): def test_logarithmic_units(self): """Check logarithmic units are set up correctly.""" assert u.dB.to(u.dex) == 0.1 assert u.dex.to(u.mag) == -2.5 assert u.mag.to(u.dB) == -4 @pytest.mark.parametrize('lu_unit, lu_cls', zip(lu_units, lu_subclasses)) def test_callable_units(self, lu_unit, lu_cls): assert isinstance(lu_unit, u.UnitBase) assert callable(lu_unit) assert lu_unit._function_unit_class is lu_cls @pytest.mark.parametrize('lu_unit', lu_units) def test_equality_to_normal_unit_for_dimensionless(self, lu_unit): lu = lu_unit() assert lu == lu._default_function_unit # eg, MagUnit() == u.mag assert lu._default_function_unit == lu # and u.mag == MagUnit() @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_call_units(self, lu_unit, physical_unit): """Create a LogUnit subclass using the callable unit and physical unit, and do basic check that output is right.""" lu1 = lu_unit(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit def test_call_invalid_unit(self): with pytest.raises(TypeError): u.mag([]) with pytest.raises(ValueError): u.mag(u.mag()) @pytest.mark.parametrize('lu_cls, physical_unit', itertools.product( lu_subclasses + [u.LogUnit], pu_sample)) def test_subclass_creation(self, lu_cls, physical_unit): """Create a LogUnit subclass object for given physical unit, and do basic check that output is right.""" lu1 = lu_cls(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit lu2 = lu_cls(physical_unit, function_unit=2*lu1._default_function_unit) assert lu2.physical_unit == physical_unit assert lu2.function_unit == u.Unit(2*lu2._default_function_unit) with pytest.raises(ValueError): lu_cls(physical_unit, u.m) def test_predefined_magnitudes(): assert_quantity_allclose((-21.1*u.STmag).physical, 1.*u.erg/u.cm**2/u.s/u.AA) assert_quantity_allclose((-48.6*u.ABmag).physical, 1.*u.erg/u.cm**2/u.s/u.Hz) assert_quantity_allclose((0*u.M_bol).physical, c.L_bol0) assert_quantity_allclose((0*u.m_bol).physical, c.L_bol0/(4.*np.pi*(10.*c.pc)**2)) def test_predefined_reinitialisation(): assert u.mag('ST') == u.STmag assert u.mag('AB') == u.ABmag assert u.mag('Bol') == u.M_bol assert u.mag('bol') == u.m_bol def test_predefined_string_roundtrip(): """Ensure roundtripping; see #5015""" with u.magnitude_zero_points.enable(): assert u.Unit(u.STmag.to_string()) == u.STmag assert u.Unit(u.ABmag.to_string()) == u.ABmag assert u.Unit(u.M_bol.to_string()) == u.M_bol assert u.Unit(u.m_bol.to_string()) == u.m_bol def test_inequality(): """Check __ne__ works (regresssion for #5342).""" lu1 = u.mag(u.Jy) lu2 = u.dex(u.Jy) lu3 = u.mag(u.Jy**2) lu4 = lu3 - lu1 assert lu1 != lu2 assert lu1 != lu3 assert lu1 == lu4 class TestLogUnitStrings(object): def test_str(self): """Do some spot checks that str, repr, etc. work as expected.""" lu1 = u.mag(u.Jy) assert str(lu1) == 'mag(Jy)' assert repr(lu1) == 'Unit("mag(Jy)")' assert lu1.to_string('generic') == 'mag(Jy)' with pytest.raises(ValueError): lu1.to_string('fits') lu2 = u.dex() assert str(lu2) == 'dex' assert repr(lu2) == 'Unit("dex(1)")' assert lu2.to_string() == 'dex(1)' lu3 = u.MagUnit(u.Jy, function_unit=2*u.mag) assert str(lu3) == '2 mag(Jy)' assert repr(lu3) == 'MagUnit("Jy", unit="2 mag")' assert lu3.to_string() == '2 mag(Jy)' lu4 = u.mag(u.ct) assert lu4.to_string('generic') == 'mag(ct)' assert lu4.to_string('latex') == ('$\\mathrm{mag}$$\\mathrm{\\left( ' '\\mathrm{ct} \\right)}$') assert lu4._repr_latex_() == lu4.to_string('latex') class TestLogUnitConversion(object): @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_physical_unit_conversion(self, lu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to their non-log counterparts.""" lu1 = lu_unit(physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(physical_unit, 0.) == 1. assert physical_unit.is_equivalent(lu1) assert physical_unit.to(lu1, 1.) == 0. pu = u.Unit(8.*physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(pu, 0.) == 0.125 assert pu.is_equivalent(lu1) assert_allclose(pu.to(lu1, 0.125), 0., atol=1.e-15) # Check we round-trip. value = np.linspace(0., 10., 6) assert_allclose(pu.to(lu1, lu1.to(pu, value)), value, atol=1.e-15) # And that we're not just returning True all the time. pu2 = u.g assert not lu1.is_equivalent(pu2) with pytest.raises(u.UnitsError): lu1.to(pu2) assert not pu2.is_equivalent(lu1) with pytest.raises(u.UnitsError): pu2.to(lu1) @pytest.mark.parametrize('lu_unit', lu_units) def test_container_unit_conversion(self, lu_unit): """Check that conversion to logarithmic units (u.mag, u.dB, u.dex) is only possible when the physical unit is dimensionless.""" values = np.linspace(0., 10., 6) lu1 = lu_unit(u.dimensionless_unscaled) assert lu1.is_equivalent(lu1.function_unit) assert_allclose(lu1.to(lu1.function_unit, values), values) lu2 = lu_unit(u.Jy) assert not lu2.is_equivalent(lu2.function_unit) with pytest.raises(u.UnitsError): lu2.to(lu2.function_unit, values) @pytest.mark.parametrize( 'flu_unit, tlu_unit, physical_unit', itertools.product(lu_units, lu_units, pu_sample)) def test_subclass_conversion(self, flu_unit, tlu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to each other if they correspond to equivalent physical units.""" values = np.linspace(0., 10., 6) flu = flu_unit(physical_unit) tlu = tlu_unit(physical_unit) assert flu.is_equivalent(tlu) assert_allclose(flu.to(tlu), flu.function_unit.to(tlu.function_unit)) assert_allclose(flu.to(tlu, values), values * flu.function_unit.to(tlu.function_unit)) tlu2 = tlu_unit(u.Unit(100.*physical_unit)) assert flu.is_equivalent(tlu2) # Check that we round-trip. assert_allclose(flu.to(tlu2, tlu2.to(flu, values)), values, atol=1.e-15) tlu3 = tlu_unit(physical_unit.to_system(u.si)[0]) assert flu.is_equivalent(tlu3) assert_allclose(flu.to(tlu3, tlu3.to(flu, values)), values, atol=1.e-15) tlu4 = tlu_unit(u.g) assert not flu.is_equivalent(tlu4) with pytest.raises(u.UnitsError): flu.to(tlu4, values) def test_unit_decomposition(self): lu = u.mag(u.Jy) assert lu.decompose() == u.mag(u.Jy.decompose()) assert lu.decompose().physical_unit.bases == [u.kg, u.s] assert lu.si == u.mag(u.Jy.si) assert lu.si.physical_unit.bases == [u.kg, u.s] assert lu.cgs == u.mag(u.Jy.cgs) assert lu.cgs.physical_unit.bases == [u.g, u.s] def test_unit_multiple_possible_equivalencies(self): lu = u.mag(u.Jy) assert lu.is_equivalent(pu_sample) class TestLogUnitArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other units is only possible when the physical unit is dimensionless, and that this turns the unit into a normal one.""" lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 * u.m with pytest.raises(u.UnitsError): u.m * lu1 with pytest.raises(u.UnitsError): lu1 / lu1 for unit in (u.dimensionless_unscaled, u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lu1 / unit lu2 = u.mag(u.dimensionless_unscaled) with pytest.raises(u.UnitsError): lu2 * lu1 with pytest.raises(u.UnitsError): lu2 / lu1 # But dimensionless_unscaled can be cancelled. assert lu2 / lu2 == u.dimensionless_unscaled # With dimensionless, normal units are OK, but we return a plain unit. tf = lu2 * u.m tr = u.m * lu2 for t in (tf, tr): assert not isinstance(t, type(lu2)) assert t == lu2.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lu2.physical_unit) # Now we essentially have a LogUnit with a prefactor of 100, # so should be equivalent again. t = tf / u.cm with u.set_enabled_equivalencies(u.logarithmic()): assert t.is_equivalent(lu2.function_unit) assert_allclose(t.to(u.dimensionless_unscaled, np.arange(3.)/100.), lu2.to(lu2.physical_unit, np.arange(3.))) # If we effectively remove lu1, a normal unit should be returned. t2 = tf / lu2 assert not isinstance(t2, type(lu2)) assert t2 == u.m t3 = tf / lu2.function_unit assert not isinstance(t3, type(lu2)) assert t3 == u.m # For completeness, also ensure non-sensical operations fail with pytest.raises(TypeError): lu1 * object() with pytest.raises(TypeError): slice(None) * lu1 with pytest.raises(TypeError): lu1 / [] with pytest.raises(TypeError): 1 / lu1 @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogUnits to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (such as mag**2) is incompatible.""" lu1 = u.mag(u.Jy) if power == 0: assert lu1 ** power == u.dimensionless_unscaled elif power == 1: assert lu1 ** power == lu1 else: with pytest.raises(u.UnitsError): lu1 ** power # With dimensionless, though, it works, but returns a normal unit. lu2 = u.mag(u.dimensionless_unscaled) t = lu2**power if power == 0: assert t == u.dimensionless_unscaled elif power == 1: assert t == lu2 else: assert not isinstance(t, type(lu2)) assert t == lu2.function_unit**power # also check we roundtrip t2 = t**(1./power) assert t2 == lu2.function_unit with u.set_enabled_equivalencies(u.logarithmic()): assert_allclose(t2.to(u.dimensionless_unscaled, np.arange(3.)), lu2.to(lu2.physical_unit, np.arange(3.))) @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 + other with pytest.raises(u.UnitsError): lu1 - other with pytest.raises(u.UnitsError): other - lu1 def test_addition_subtraction_to_non_units_fails(self): lu1 = u.mag(u.Jy) with pytest.raises(TypeError): lu1 + 1. with pytest.raises(TypeError): lu1 - [1., 2., 3.] @pytest.mark.parametrize( 'other', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2*u.mag), u.MagUnit('', 2.*u.mag))) def test_addition_subtraction(self, other): """Check physical units are changed appropriately""" lu1 = u.mag(u.Jy) other_pu = getattr(other, 'physical_unit', u.dimensionless_unscaled) lu_sf = lu1 + other assert lu_sf.is_equivalent(lu1.physical_unit * other_pu) lu_sr = other + lu1 assert lu_sr.is_equivalent(lu1.physical_unit * other_pu) lu_df = lu1 - other assert lu_df.is_equivalent(lu1.physical_unit / other_pu) lu_dr = other - lu1 assert lu_dr.is_equivalent(other_pu / lu1.physical_unit) def test_complicated_addition_subtraction(self): """for fun, a more complicated example of addition and subtraction""" dm0 = u.Unit('DM', 1./(4.*np.pi*(10.*u.pc)**2)) lu_dm = u.mag(dm0) lu_absST = u.STmag - lu_dm assert lu_absST.is_equivalent(u.erg/u.s/u.AA) def test_neg_pos(self): lu1 = u.mag(u.Jy) neg_lu = -lu1 assert neg_lu != lu1 assert neg_lu.physical_unit == u.Jy**-1 assert -neg_lu == lu1 pos_lu = +lu1 assert pos_lu is not lu1 assert pos_lu == lu1 def test_pickle(): lu1 = u.dex(u.cm/u.s**2) s = pickle.dumps(lu1) lu2 = pickle.loads(s) assert lu1 == lu2 def test_hashable(): lu1 = u.dB(u.mW) lu2 = u.dB(u.m) lu3 = u.dB(u.mW) assert hash(lu1) != hash(lu2) assert hash(lu1) == hash(lu3) luset = {lu1, lu2, lu3} assert len(luset) == 2 class TestLogQuantityCreation(object): @pytest.mark.parametrize('lq, lu', zip(lq_subclasses + [u.LogQuantity], lu_subclasses + [u.LogUnit])) def test_logarithmic_quantities(self, lq, lu): """Check logarithmic quantities are all set up correctly""" assert lq._unit_class == lu assert type(lu()._quantity_class(1.)) is lq @pytest.mark.parametrize('lq_cls, physical_unit', itertools.product(lq_subclasses, pu_sample)) def test_subclass_creation(self, lq_cls, physical_unit): """Create LogQuantity subclass objects for some physical units, and basic check on transformations""" value = np.arange(1., 10.) log_q = lq_cls(value * physical_unit) assert log_q.unit.physical_unit == physical_unit assert log_q.unit.function_unit == log_q.unit._default_function_unit assert_allclose(log_q.physical.value, value) with pytest.raises(ValueError): lq_cls(value, physical_unit) @pytest.mark.parametrize( 'unit', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2*u.mag), u.MagUnit('', 2.*u.mag), u.MagUnit(u.Jy, -1*u.mag), u.MagUnit(u.m, -2.*u.mag))) def test_different_units(self, unit): q = u.Magnitude(1.23, unit) assert q.unit.function_unit == getattr(unit, 'function_unit', unit) assert q.unit.physical_unit is getattr(unit, 'physical_unit', u.dimensionless_unscaled) @pytest.mark.parametrize('value, unit', ( (1.*u.mag(u.Jy), None), (1.*u.dex(u.Jy), None), (1.*u.mag(u.W/u.m**2/u.Hz), u.mag(u.Jy)), (1.*u.dex(u.W/u.m**2/u.Hz), u.mag(u.Jy)))) def test_function_values(self, value, unit): lq = u.Magnitude(value, unit) assert lq == value assert lq.unit.function_unit == u.mag assert lq.unit.physical_unit == getattr(unit, 'physical_unit', value.unit.physical_unit) @pytest.mark.parametrize( 'unit', (u.mag(), u.mag(u.Jy), u.mag(u.m), u.MagUnit('', 2.*u.mag), u.MagUnit(u.Jy, -1*u.mag), u.MagUnit(u.m, -2.*u.mag))) def test_indirect_creation(self, unit): q1 = 2.5 * unit assert isinstance(q1, u.Magnitude) assert q1.value == 2.5 assert q1.unit == unit pv = 100. * unit.physical_unit q2 = unit * pv assert q2.unit == unit assert q2.unit.physical_unit == pv.unit assert q2.to_value(unit.physical_unit) == 100. assert (q2._function_view / u.mag).to_value(1) == -5. q3 = unit / 0.4 assert q3 == q1 def test_from_view(self): # Cannot view a physical quantity as a function quantity, since the # values would change. q = [100., 1000.] * u.cm/u.s**2 with pytest.raises(TypeError): q.view(u.Dex) # But fine if we have the right magnitude. q = [2., 3.] * u.dex lq = q.view(u.Dex) assert isinstance(lq, u.Dex) assert lq.unit.physical_unit == u.dimensionless_unscaled assert np.all(q == lq) def test_using_quantity_class(self): """Check that we can use Quantity if we have subok=True""" # following issue #5851 lu = u.dex(u.AA) with pytest.raises(u.UnitTypeError): u.Quantity(1., lu) q = u.Quantity(1., lu, subok=True) assert type(q) is lu._quantity_class def test_conversion_to_and_from_physical_quantities(): """Ensures we can convert from regular quantities.""" mst = [10., 12., 14.] * u.STmag flux_lambda = mst.physical mst_roundtrip = flux_lambda.to(u.STmag) # check we return a logquantity; see #5178. assert isinstance(mst_roundtrip, u.Magnitude) assert mst_roundtrip.unit == mst.unit assert_allclose(mst_roundtrip.value, mst.value) wave = [4956.8, 4959.55, 4962.3] * u.AA flux_nu = mst.to(u.Jy, equivalencies=u.spectral_density(wave)) mst_roundtrip2 = flux_nu.to(u.STmag, u.spectral_density(wave)) assert isinstance(mst_roundtrip2, u.Magnitude) assert mst_roundtrip2.unit == mst.unit assert_allclose(mst_roundtrip2.value, mst.value) def test_quantity_decomposition(): lq = 10.*u.mag(u.Jy) assert lq.decompose() == lq assert lq.decompose().unit.physical_unit.bases == [u.kg, u.s] assert lq.si == lq assert lq.si.unit.physical_unit.bases == [u.kg, u.s] assert lq.cgs == lq assert lq.cgs.unit.physical_unit.bases == [u.g, u.s] class TestLogQuantityViews(object): def setup(self): self.lq = u.Magnitude(np.arange(10.) * u.Jy) self.lq2 = u.Magnitude(np.arange(5.)) def test_value_view(self): lq_value = self.lq.value assert type(lq_value) is np.ndarray lq_value[2] = -1. assert np.all(self.lq.value == lq_value) def test_function_view(self): lq_fv = self.lq._function_view assert type(lq_fv) is u.Quantity assert lq_fv.unit is self.lq.unit.function_unit lq_fv[3] = -2. * lq_fv.unit assert np.all(self.lq.value == lq_fv.value) def test_quantity_view(self): # Cannot view as Quantity, since the unit cannot be represented. with pytest.raises(TypeError): self.lq.view(u.Quantity) # But a dimensionless one is fine. q2 = self.lq2.view(u.Quantity) assert q2.unit is u.mag assert np.all(q2.value == self.lq2.value) lq3 = q2.view(u.Magnitude) assert type(lq3.unit) is u.MagUnit assert lq3.unit.physical_unit == u.dimensionless_unscaled assert np.all(lq3 == self.lq2) class TestLogQuantitySlicing(object): def test_item_get_and_set(self): lq1 = u.Magnitude(np.arange(1., 11.)*u.Jy) assert lq1[9] == u.Magnitude(10.*u.Jy) lq1[2] = 100.*u.Jy assert lq1[2] == u.Magnitude(100.*u.Jy) with pytest.raises(u.UnitsError): lq1[2] = 100.*u.m with pytest.raises(u.UnitsError): lq1[2] = 100.*u.mag with pytest.raises(u.UnitsError): lq1[2] = u.Magnitude(100.*u.m) assert lq1[2] == u.Magnitude(100.*u.Jy) def test_slice_get_and_set(self): lq1 = u.Magnitude(np.arange(1., 10.)*u.Jy) lq1[2:4] = 100.*u.Jy assert np.all(lq1[2:4] == u.Magnitude(100.*u.Jy)) with pytest.raises(u.UnitsError): lq1[2:4] = 100.*u.m with pytest.raises(u.UnitsError): lq1[2:4] = 100.*u.mag with pytest.raises(u.UnitsError): lq1[2:4] = u.Magnitude(100.*u.m) assert np.all(lq1[2] == u.Magnitude(100.*u.Jy)) class TestLogQuantityArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other quantities is only possible when the physical unit is dimensionless, and that this turns the result into a normal quantity.""" lq = u.Magnitude(np.arange(1., 11.)*u.Jy) with pytest.raises(u.UnitsError): lq * (1.*u.m) with pytest.raises(u.UnitsError): (1.*u.m) * lq with pytest.raises(u.UnitsError): lq / lq for unit in (u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lq / unit lq2 = u.Magnitude(np.arange(1, 11.)) with pytest.raises(u.UnitsError): lq2 * lq with pytest.raises(u.UnitsError): lq2 / lq with pytest.raises(u.UnitsError): lq / lq2 # but dimensionless_unscaled can be cancelled r = lq2 / u.Magnitude(2.) assert r.unit == u.dimensionless_unscaled assert np.all(r.value == lq2.value/2.) # with dimensionless, normal units OK, but return normal quantities tf = lq2 * u.m tr = u.m * lq2 for t in (tf, tr): assert not isinstance(t, type(lq2)) assert t.unit == lq2.unit.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lq2.unit.physical_unit) t = tf / (50.*u.cm) # now we essentially have the same quantity but with a prefactor of 2 assert t.unit.is_equivalent(lq2.unit.function_unit) assert_allclose(t.to(lq2.unit.function_unit), lq2._function_view*2) @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogQuantities to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (say, mag**2) is incompatible.""" lq = u.Magnitude(np.arange(1., 4.)*u.Jy) if power == 0: assert np.all(lq ** power == 1.) elif power == 1: assert np.all(lq ** power == lq) else: with pytest.raises(u.UnitsError): lq ** power # with dimensionless, it works, but falls back to normal quantity # (except for power=1) lq2 = u.Magnitude(np.arange(10.)) t = lq2**power if power == 0: assert t.unit is u.dimensionless_unscaled assert np.all(t.value == 1.) elif power == 1: assert np.all(t == lq2) else: assert not isinstance(t, type(lq2)) assert t.unit == lq2.unit.function_unit ** power with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(u.dimensionless_unscaled) def test_error_on_lq_as_power(self): lq = u.Magnitude(np.arange(1., 4.)*u.Jy) with pytest.raises(TypeError): lq ** lq @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lq = u.Magnitude(np.arange(1., 10.)*u.Jy) q = 1.23 * other with pytest.raises(u.UnitsError): lq + q with pytest.raises(u.UnitsError): lq - q with pytest.raises(u.UnitsError): q - lq @pytest.mark.parametrize( 'other', (1.23 * u.mag, 2.34 * u.mag(), u.Magnitude(3.45 * u.Jy), u.Magnitude(4.56 * u.m), 5.67 * u.Unit(2*u.mag), u.Magnitude(6.78, 2.*u.mag))) def test_addition_subtraction(self, other): """Check that addition/subtraction with quantities with magnitude or MagUnit units works, and that it changes the physical units appropriately.""" lq = u.Magnitude(np.arange(1., 10.)*u.Jy) other_physical = other.to(getattr(other.unit, 'physical_unit', u.dimensionless_unscaled), equivalencies=u.logarithmic()) lq_sf = lq + other assert_allclose(lq_sf.physical, lq.physical * other_physical) lq_sr = other + lq assert_allclose(lq_sr.physical, lq.physical * other_physical) lq_df = lq - other assert_allclose(lq_df.physical, lq.physical / other_physical) lq_dr = other - lq assert_allclose(lq_dr.physical, other_physical / lq.physical) @pytest.mark.parametrize('other', pu_sample) def test_inplace_addition_subtraction_unit_checks(self, other): lu1 = u.mag(u.Jy) lq1 = u.Magnitude(np.arange(1., 10.), lu1) with pytest.raises(u.UnitsError): lq1 += other assert np.all(lq1.value == np.arange(1., 10.)) assert lq1.unit == lu1 with pytest.raises(u.UnitsError): lq1 -= other assert np.all(lq1.value == np.arange(1., 10.)) assert lq1.unit == lu1 @pytest.mark.parametrize( 'other', (1.23 * u.mag, 2.34 * u.mag(), u.Magnitude(3.45 * u.Jy), u.Magnitude(4.56 * u.m), 5.67 * u.Unit(2*u.mag), u.Magnitude(6.78, 2.*u.mag))) def test_inplace_addition_subtraction(self, other): """Check that inplace addition/subtraction with quantities with magnitude or MagUnit units works, and that it changes the physical units appropriately.""" lq = u.Magnitude(np.arange(1., 10.)*u.Jy) other_physical = other.to(getattr(other.unit, 'physical_unit', u.dimensionless_unscaled), equivalencies=u.logarithmic()) lq_sf = lq.copy() lq_sf += other assert_allclose(lq_sf.physical, lq.physical * other_physical) lq_df = lq.copy() lq_df -= other assert_allclose(lq_df.physical, lq.physical / other_physical) def test_complicated_addition_subtraction(self): """For fun, a more complicated example of addition and subtraction.""" dm0 = u.Unit('DM', 1./(4.*np.pi*(10.*u.pc)**2)) DMmag = u.mag(dm0) m_st = 10. * u.STmag dm = 5. * DMmag M_st = m_st - dm assert M_st.unit.is_equivalent(u.erg/u.s/u.AA) assert np.abs(M_st.physical / (m_st.physical*4.*np.pi*(100.*u.pc)**2) - 1.) < 1.e-15 class TestLogQuantityComparisons(object): def test_comparison_to_non_quantities_fails(self): lq = u.Magnitude(np.arange(1., 10.)*u.Jy) # On python2, ordering operations always succeed, given essentially # meaningless results. if not six.PY2: with pytest.raises(TypeError): lq > 'a' assert not (lq == 'a') assert lq != 'a' def test_comparison(self): lq1 = u.Magnitude(np.arange(1., 4.)*u.Jy) lq2 = u.Magnitude(2.*u.Jy) assert np.all((lq1 > lq2) == np.array([True, False, False])) assert np.all((lq1 == lq2) == np.array([False, True, False])) lq3 = u.Dex(2.*u.Jy) assert np.all((lq1 > lq3) == np.array([True, False, False])) assert np.all((lq1 == lq3) == np.array([False, True, False])) lq4 = u.Magnitude(2.*u.m) assert not (lq1 == lq4) assert lq1 != lq4 with pytest.raises(u.UnitsError): lq1 < lq4 q5 = 1.5 * u.Jy assert np.all((lq1 > q5) == np.array([True, False, False])) assert np.all((q5 < lq1) == np.array([True, False, False])) with pytest.raises(u.UnitsError): lq1 >= 2.*u.m with pytest.raises(u.UnitsError): lq1 <= lq1.value * u.mag # For physically dimensionless, we can compare with the function unit. lq6 = u.Magnitude(np.arange(1., 4.)) fv6 = lq6.value * u.mag assert np.all(lq6 == fv6) # but not some arbitrary unit, of course. with pytest.raises(u.UnitsError): lq6 < 2.*u.m class TestLogQuantityMethods(object): def setup(self): self.mJy = np.arange(1., 5.).reshape(2, 2) * u.mag(u.Jy) self.m1 = np.arange(1., 5.5, 0.5).reshape(3, 3) * u.mag() self.mags = (self.mJy, self.m1) @pytest.mark.parametrize('method', ('mean', 'min', 'max', 'round', 'trace', 'std', 'var', 'ptp', 'diff', 'ediff1d')) def test_always_ok(self, method): for mag in self.mags: res = getattr(mag, method)() assert np.all(res.value == getattr(mag._function_view, method)().value) if method in ('std', 'ptp', 'diff', 'ediff1d'): assert res.unit == u.mag() elif method == 'var': assert res.unit == u.mag**2 else: assert res.unit == mag.unit def test_clip(self): for mag in self.mags: assert np.all(mag.clip(2. * mag.unit, 4. * mag.unit).value == mag.value.clip(2., 4.)) @pytest.mark.parametrize('method', ('sum', 'cumsum', 'nansum')) def test_only_ok_if_dimensionless(self, method): res = getattr(self.m1, method)() assert np.all(res.value == getattr(self.m1._function_view, method)().value) assert res.unit == self.m1.unit with pytest.raises(TypeError): getattr(self.mJy, method)() def test_dot(self): assert np.all(self.m1.dot(self.m1).value == self.m1.value.dot(self.m1.value)) @pytest.mark.parametrize('method', ('prod', 'cumprod')) def test_never_ok(self, method): with pytest.raises(ValueError): getattr(self.mJy, method)() with pytest.raises(ValueError): getattr(self.m1, method)() class TestLogQuantityUfuncs(object): """Spot checks on ufuncs.""" def setup(self): self.mJy = np.arange(1., 5.).reshape(2, 2) * u.mag(u.Jy) self.m1 = np.arange(1., 5.5, 0.5).reshape(3, 3) * u.mag() self.mags = (self.mJy, self.m1) def test_power(self): assert np.all(np.power(self.mJy, 0.) == 1.) assert np.all(np.power(self.m1, 1.) == self.m1) assert np.all(np.power(self.mJy, 1.) == self.mJy) assert np.all(np.power(self.m1, 2.) == self.m1 ** 2) with pytest.raises(u.UnitsError): np.power(self.mJy, 2.) def test_not_implemented_with_physical_unit(self): with pytest.raises(u.UnitsError): np.square(self.mJy) assert np.all(

np.square(self.m1)

numpy.square

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] *

np.ones_like(min_2_y)

numpy.ones_like

#!/usr/bin/env python # encoding: utf-8 -*- """ This module contains unit tests of the rmgpy.reaction module. """ import numpy import unittest from external.wip import work_in_progress from rmgpy.species import Species, TransitionState from rmgpy.reaction import Reaction from rmgpy.statmech.translation import Translation, IdealGasTranslation from rmgpy.statmech.rotation import Rotation, LinearRotor, NonlinearRotor, KRotor, SphericalTopRotor from rmgpy.statmech.vibration import Vibration, HarmonicOscillator from rmgpy.statmech.torsion import Torsion, HinderedRotor from rmgpy.statmech.conformer import Conformer from rmgpy.kinetics import Arrhenius from rmgpy.thermo import Wilhoit import rmgpy.constants as constants ################################################################################ class PseudoSpecies: """ Can be used in place of a :class:`rmg.species.Species` for isomorphism checks. PseudoSpecies('a') is isomorphic with PseudoSpecies('A') but nothing else. """ def __init__(self, label): self.label = label def __repr__(self): return "PseudoSpecies('{0}')".format(self.label) def __str__(self): return self.label def isIsomorphic(self, other): return self.label.lower() == other.label.lower() class TestReactionIsomorphism(unittest.TestCase): """ Contains unit tests of the isomorphism testing of the Reaction class. """ def makeReaction(self,reaction_string): """" Make a Reaction (containing PseudoSpecies) of from a string like 'Ab=CD' """ reactants, products = reaction_string.split('=') reactants = [PseudoSpecies(i) for i in reactants] products = [PseudoSpecies(i) for i in products] return Reaction(reactants=reactants, products=products) def test1to1(self): r1 = self.makeReaction('A=B') self.assertTrue(r1.isIsomorphic(self.makeReaction('a=B'))) self.assertTrue(r1.isIsomorphic(self.makeReaction('b=A'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('B=a'),eitherDirection=False)) self.assertFalse(r1.isIsomorphic(self.makeReaction('A=C'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('A=BB'))) def test1to2(self): r1 = self.makeReaction('A=BC') self.assertTrue(r1.isIsomorphic(self.makeReaction('a=Bc'))) self.assertTrue(r1.isIsomorphic(self.makeReaction('cb=a'))) self.assertTrue(r1.isIsomorphic(self.makeReaction('a=cb'),eitherDirection=False)) self.assertFalse(r1.isIsomorphic(self.makeReaction('bc=a'),eitherDirection=False)) self.assertFalse(r1.isIsomorphic(self.makeReaction('a=c'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('ab=c'))) def test2to2(self): r1 = self.makeReaction('AB=CD') self.assertTrue(r1.isIsomorphic(self.makeReaction('ab=cd'))) self.assertTrue(r1.isIsomorphic(self.makeReaction('ab=dc'),eitherDirection=False)) self.assertTrue(r1.isIsomorphic(self.makeReaction('dc=ba'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('cd=ab'),eitherDirection=False)) self.assertFalse(r1.isIsomorphic(self.makeReaction('ab=ab'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('ab=cde'))) def test2to3(self): r1 = self.makeReaction('AB=CDE') self.assertTrue(r1.isIsomorphic(self.makeReaction('ab=cde'))) self.assertTrue(r1.isIsomorphic(self.makeReaction('ba=edc'),eitherDirection=False)) self.assertTrue(r1.isIsomorphic(self.makeReaction('dec=ba'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('cde=ab'),eitherDirection=False)) self.assertFalse(r1.isIsomorphic(self.makeReaction('ab=abc'))) self.assertFalse(r1.isIsomorphic(self.makeReaction('abe=cde'))) class TestReaction(unittest.TestCase): """ Contains unit tests of the Reaction class. """ def setUp(self): """ A method that is called prior to each unit test in this class. """ ethylene = Species( label = 'C2H4', conformer = Conformer( E0 = (44.7127, 'kJ/mol'), modes = [ IdealGasTranslation( mass = (28.0313, 'amu'), ), NonlinearRotor( inertia = ( [3.41526, 16.6498, 20.065], 'amu*angstrom^2', ), symmetry = 4, ), HarmonicOscillator( frequencies = ( [828.397, 970.652, 977.223, 1052.93, 1233.55, 1367.56, 1465.09, 1672.25, 3098.46, 3111.7, 3165.79, 3193.54], 'cm^-1', ), ), ], spinMultiplicity = 1, opticalIsomers = 1, ), ) hydrogen = Species( label = 'H', conformer = Conformer( E0 = (211.794, 'kJ/mol'), modes = [ IdealGasTranslation( mass = (1.00783, 'amu'), ), ], spinMultiplicity = 2, opticalIsomers = 1, ), ) ethyl = Species( label = 'C2H5', conformer = Conformer( E0 = (111.603, 'kJ/mol'), modes = [ IdealGasTranslation( mass = (29.0391, 'amu'), ), NonlinearRotor( inertia = ( [4.8709, 22.2353, 23.9925], 'amu*angstrom^2', ), symmetry = 1, ), HarmonicOscillator( frequencies = ( [482.224, 791.876, 974.355, 1051.48, 1183.21, 1361.36, 1448.65, 1455.07, 1465.48, 2688.22, 2954.51, 3033.39, 3101.54, 3204.73], 'cm^-1', ), ), HinderedRotor( inertia = (1.11481, 'amu*angstrom^2'), symmetry = 6, barrier = (0.244029, 'kJ/mol'), semiclassical = None, ), ], spinMultiplicity = 2, opticalIsomers = 1, ), ) TS = TransitionState( label = 'TS', conformer = Conformer( E0 = (266.694, 'kJ/mol'), modes = [ IdealGasTranslation( mass = (29.0391, 'amu'), ), NonlinearRotor( inertia = ( [6.78512, 22.1437, 22.2114], 'amu*angstrom^2', ), symmetry = 1, ), HarmonicOscillator( frequencies = ( [412.75, 415.206, 821.495, 924.44, 982.714, 1024.16, 1224.21, 1326.36, 1455.06, 1600.35, 3101.46, 3110.55, 3175.34, 3201.88], 'cm^-1', ), ), ], spinMultiplicity = 2, opticalIsomers = 1, ), frequency = (-750.232, 'cm^-1'), ) self.reaction = Reaction( reactants = [hydrogen, ethylene], products = [ethyl], kinetics = Arrhenius( A = (501366000.0, 'cm^3/(mol*s)'), n = 1.637, Ea = (4.32508, 'kJ/mol'), T0 = (1, 'K'), Tmin = (300, 'K'), Tmax = (2500, 'K'), ), transitionState = TS, ) # CC(=O)O[O] acetylperoxy = Species( label='acetylperoxy', thermo=Wilhoit(Cp0=(4.0*constants.R,"J/(mol*K)"), CpInf=(21.0*constants.R,"J/(mol*K)"), a0=-3.95, a1=9.26, a2=-15.6, a3=8.55, B=(500.0,"K"), H0=(-6.151e+04,"J/mol"), S0=(-790.2,"J/(mol*K)")), ) # C[C]=O acetyl = Species( label='acetyl', thermo=Wilhoit(Cp0=(4.0*constants.R,"J/(mol*K)"), CpInf=(15.5*constants.R,"J/(mol*K)"), a0=0.2541, a1=-0.4712, a2=-4.434, a3=2.25, B=(500.0,"K"), H0=(-1.439e+05,"J/mol"), S0=(-524.6,"J/(mol*K)")), ) # [O][O] oxygen = Species( label='oxygen', thermo=Wilhoit(Cp0=(3.5*constants.R,"J/(mol*K)"), CpInf=(4.5*constants.R,"J/(mol*K)"), a0=-0.9324, a1=26.18, a2=-70.47, a3=44.12, B=(500.0,"K"), H0=(1.453e+04,"J/mol"), S0=(-12.19,"J/(mol*K)")), ) self.reaction2 = Reaction( reactants=[acetyl, oxygen], products=[acetylperoxy], kinetics = Arrhenius( A = (2.65e12, 'cm^3/(mol*s)'), n = 0.0, Ea = (0.0, 'kJ/mol'), T0 = (1, 'K'), Tmin = (300, 'K'), Tmax = (2000, 'K'), ), ) def testIsIsomerization(self): """ Test the Reaction.isIsomerization() method. """ isomerization = Reaction(reactants=[Species()], products=[Species()]) association = Reaction(reactants=[Species(),Species()], products=[Species()]) dissociation = Reaction(reactants=[Species()], products=[Species(),Species()]) bimolecular = Reaction(reactants=[Species(),Species()], products=[Species(),Species()]) self.assertTrue(isomerization.isIsomerization()) self.assertFalse(association.isIsomerization()) self.assertFalse(dissociation.isIsomerization()) self.assertFalse(bimolecular.isIsomerization()) def testIsAssociation(self): """ Test the Reaction.isAssociation() method. """ isomerization = Reaction(reactants=[Species()], products=[Species()]) association = Reaction(reactants=[Species(),Species()], products=[Species()]) dissociation = Reaction(reactants=[Species()], products=[Species(),Species()]) bimolecular = Reaction(reactants=[Species(),Species()], products=[Species(),Species()]) self.assertFalse(isomerization.isAssociation()) self.assertTrue(association.isAssociation()) self.assertFalse(dissociation.isAssociation()) self.assertFalse(bimolecular.isAssociation()) def testIsDissociation(self): """ Test the Reaction.isDissociation() method. """ isomerization = Reaction(reactants=[Species()], products=[Species()]) association = Reaction(reactants=[Species(),Species()], products=[Species()]) dissociation = Reaction(reactants=[Species()], products=[Species(),Species()]) bimolecular = Reaction(reactants=[Species(),Species()], products=[Species(),Species()]) self.assertFalse(isomerization.isDissociation()) self.assertFalse(association.isDissociation()) self.assertTrue(dissociation.isDissociation()) self.assertFalse(bimolecular.isDissociation()) def testHasTemplate(self): """ Test the Reaction.hasTemplate() method. """ reactants = self.reaction.reactants[:] products = self.reaction.products[:] self.assertTrue(self.reaction.hasTemplate(reactants, products)) self.assertTrue(self.reaction.hasTemplate(products, reactants)) self.assertFalse(self.reaction2.hasTemplate(reactants, products)) self.assertFalse(self.reaction2.hasTemplate(products, reactants)) reactants.reverse() products.reverse() self.assertTrue(self.reaction.hasTemplate(reactants, products)) self.assertTrue(self.reaction.hasTemplate(products, reactants)) self.assertFalse(self.reaction2.hasTemplate(reactants, products)) self.assertFalse(self.reaction2.hasTemplate(products, reactants)) reactants = self.reaction2.reactants[:] products = self.reaction2.products[:] self.assertFalse(self.reaction.hasTemplate(reactants, products)) self.assertFalse(self.reaction.hasTemplate(products, reactants)) self.assertTrue(self.reaction2.hasTemplate(reactants, products)) self.assertTrue(self.reaction2.hasTemplate(products, reactants)) reactants.reverse() products.reverse() self.assertFalse(self.reaction.hasTemplate(reactants, products)) self.assertFalse(self.reaction.hasTemplate(products, reactants)) self.assertTrue(self.reaction2.hasTemplate(reactants, products)) self.assertTrue(self.reaction2.hasTemplate(products, reactants)) def testEnthalpyOfReaction(self): """ Test the Reaction.getEnthalpyOfReaction() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) Hlist0 = [float(v) for v in ['-146007', '-145886', '-144195', '-141973', '-139633', '-137341', '-135155', '-133093', '-131150', '-129316']] Hlist = self.reaction2.getEnthalpiesOfReaction(Tlist) for i in range(len(Tlist)): self.assertAlmostEqual(Hlist[i] / 1000., Hlist0[i] / 1000., 2) def testEntropyOfReaction(self): """ Test the Reaction.getEntropyOfReaction() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) Slist0 = [float(v) for v in ['-156.793', '-156.872', '-153.504', '-150.317', '-147.707', '-145.616', '-143.93', '-142.552', '-141.407', '-140.441']] Slist = self.reaction2.getEntropiesOfReaction(Tlist) for i in range(len(Tlist)): self.assertAlmostEqual(Slist[i], Slist0[i], 2) def testFreeEnergyOfReaction(self): """ Test the Reaction.getFreeEnergyOfReaction() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) Glist0 = [float(v) for v in ['-114648', '-83137.2', '-52092.4', '-21719.3', '8073.53', '37398.1', '66346.8', '94990.6', '123383', '151565']] Glist = self.reaction2.getFreeEnergiesOfReaction(Tlist) for i in range(len(Tlist)): self.assertAlmostEqual(Glist[i] / 1000., Glist0[i] / 1000., 2) def testEquilibriumConstantKa(self): """ Test the Reaction.getEquilibriumConstant() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) Kalist0 = [float(v) for v in ['8.75951e+29', '7.1843e+10', '34272.7', '26.1877', '0.378696', '0.0235579', '0.00334673', '0.000792389', '0.000262777', '0.000110053']] Kalist = self.reaction2.getEquilibriumConstants(Tlist, type='Ka') for i in range(len(Tlist)): self.assertAlmostEqual(Kalist[i] / Kalist0[i], 1.0, 4) def testEquilibriumConstantKc(self): """ Test the Reaction.getEquilibriumConstant() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) Kclist0 = [float(v) for v in ['1.45661e+28', '2.38935e+09', '1709.76', '1.74189', '0.0314866', '0.00235045', '0.000389568', '0.000105413', '3.93273e-05', '1.83006e-05']] Kclist = self.reaction2.getEquilibriumConstants(Tlist, type='Kc') for i in range(len(Tlist)): self.assertAlmostEqual(Kclist[i] / Kclist0[i], 1.0, 4) def testEquilibriumConstantKp(self): """ Test the Reaction.getEquilibriumConstant() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) Kplist0 = [float(v) for v in ['8.75951e+24', '718430', '0.342727', '0.000261877', '3.78696e-06', '2.35579e-07', '3.34673e-08', '7.92389e-09', '2.62777e-09', '1.10053e-09']] Kplist = self.reaction2.getEquilibriumConstants(Tlist, type='Kp') for i in range(len(Tlist)): self.assertAlmostEqual(Kplist[i] / Kplist0[i], 1.0, 4) def testStoichiometricCoefficient(self): """ Test the Reaction.getStoichiometricCoefficient() method. """ for reactant in self.reaction.reactants: self.assertEqual(self.reaction.getStoichiometricCoefficient(reactant), -1) for product in self.reaction.products: self.assertEqual(self.reaction.getStoichiometricCoefficient(product), 1) for reactant in self.reaction2.reactants: self.assertEqual(self.reaction.getStoichiometricCoefficient(reactant), 0) for product in self.reaction2.products: self.assertEqual(self.reaction.getStoichiometricCoefficient(product), 0) def testRateCoefficient(self): """ Test the Reaction.getRateCoefficient() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) P = 1e5 for T in Tlist: self.assertAlmostEqual(self.reaction.getRateCoefficient(T, P) / self.reaction.kinetics.getRateCoefficient(T), 1.0, 6) def testGenerateReverseRateCoefficient(self): """ Test the Reaction.generateReverseRateCoefficient() method. """ Tlist = numpy.arange(200.0, 2001.0, 200.0, numpy.float64) P = 1e5 reverseKinetics = self.reaction2.generateReverseRateCoefficient() for T in Tlist: kr0 = self.reaction2.getRateCoefficient(T, P) / self.reaction2.getEquilibriumConstant(T) kr = reverseKinetics.getRateCoefficient(T) self.assertAlmostEqual(kr0 / kr, 1.0, 0) def testGenerateReverseRateCoefficientArrhenius(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the Arrhenius format. """ original_kinetics = Arrhenius( A = (2.65e12, 'cm^3/(mol*s)'), n = 0.0, Ea = (0.0, 'kJ/mol'), T0 = (1, 'K'), Tmin = (300, 'K'), Tmax = (2000, 'K'), ) self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist = numpy.arange(original_kinetics.Tmin.value_si, original_kinetics.Tmax.value_si, 200.0, numpy.float64) P = 1e5 for T in Tlist: korig = original_kinetics.getRateCoefficient(T, P) krevrev = reversereverseKinetics.getRateCoefficient(T, P) self.assertAlmostEqual(korig / krevrev, 1.0, 0) @work_in_progress def testGenerateReverseRateCoefficientArrheniusEP(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the ArrheniusEP format. """ from rmgpy.kinetics import ArrheniusEP original_kinetics = ArrheniusEP( A = (2.65e12, 'cm^3/(mol*s)'), n = 0.0, alpha = 0.5, E0 = (41.84, 'kJ/mol'), Tmin = (300, 'K'), Tmax = (2000, 'K'), ) self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist = numpy.arange(original_kinetics.Tmin, original_kinetics.Tmax, 200.0, numpy.float64) P = 1e5 for T in Tlist: korig = original_kinetics.getRateCoefficient(T, P) krevrev = reversereverseKinetics.getRateCoefficient(T, P) self.assertAlmostEqual(korig / krevrev, 1.0, 0) def testGenerateReverseRateCoefficientPDepArrhenius(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the PDepArrhenius format. """ from rmgpy.kinetics import PDepArrhenius arrhenius0 = Arrhenius( A = (1.0e6,"s^-1"), n = 1.0, Ea = (10.0,"kJ/mol"), T0 = (300.0,"K"), Tmin = (300.0,"K"), Tmax = (2000.0,"K"), comment = """This data is completely made up""", ) arrhenius1 = Arrhenius( A = (1.0e12,"s^-1"), n = 1.0, Ea = (20.0,"kJ/mol"), T0 = (300.0,"K"), Tmin = (300.0,"K"), Tmax = (2000.0,"K"), comment = """This data is completely made up""", ) pressures = numpy.array([0.1, 10.0]) arrhenius = [arrhenius0, arrhenius1] Tmin = 300.0 Tmax = 2000.0 Pmin = 0.1 Pmax = 10.0 comment = """This data is completely made up""" original_kinetics = PDepArrhenius( pressures = (pressures,"bar"), arrhenius = arrhenius, Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), Pmin = (Pmin,"bar"), Pmax = (Pmax,"bar"), comment = comment, ) self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist = numpy.arange(Tmin, Tmax, 200.0, numpy.float64) P = 1e5 for T in Tlist: korig = original_kinetics.getRateCoefficient(T, P) krevrev = reversereverseKinetics.getRateCoefficient(T, P) self.assertAlmostEqual(korig / krevrev, 1.0, 0) def testGenerateReverseRateCoefficientMultiArrhenius(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the MultiArrhenius format. """ from rmgpy.kinetics import MultiArrhenius pressures = numpy.array([0.1, 10.0]) Tmin = 300.0 Tmax = 2000.0 Pmin = 0.1 Pmax = 10.0 comment = """This data is completely made up""" arrhenius = [ Arrhenius( A = (9.3e-14,"cm^3/(molecule*s)"), n = 0.0, Ea = (4740*constants.R*0.001,"kJ/mol"), T0 = (1,"K"), Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ), Arrhenius( A = (1.4e-9,"cm^3/(molecule*s)"), n = 0.0, Ea = (11200*constants.R*0.001,"kJ/mol"), T0 = (1,"K"), Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ), ] original_kinetics = MultiArrhenius( arrhenius = arrhenius, Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ) self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist = numpy.arange(Tmin, Tmax, 200.0, numpy.float64) P = 1e5 for T in Tlist: korig = original_kinetics.getRateCoefficient(T, P) krevrev = reversereverseKinetics.getRateCoefficient(T, P) self.assertAlmostEqual(korig / krevrev, 1.0, 0) def testGenerateReverseRateCoefficientMultiPDepArrhenius(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the MultiPDepArrhenius format. """ from rmgpy.kinetics import PDepArrhenius, MultiPDepArrhenius Tmin = 350. Tmax = 1500. Pmin = 1e-1 Pmax = 1e1 pressures = numpy.array([1e-1,1e1]) comment = 'CH3 + C2H6 <=> CH4 + C2H5 (Baulch 2005)' arrhenius = [ PDepArrhenius( pressures = (pressures,"bar"), arrhenius = [ Arrhenius( A = (9.3e-16,"cm^3/(molecule*s)"), n = 0.0, Ea = (4740*constants.R*0.001,"kJ/mol"), T0 = (1,"K"), Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ), Arrhenius( A = (9.3e-14,"cm^3/(molecule*s)"), n = 0.0, Ea = (4740*constants.R*0.001,"kJ/mol"), T0 = (1,"K"), Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ), ], Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), Pmin = (Pmin,"bar"), Pmax = (Pmax,"bar"), comment = comment, ), PDepArrhenius( pressures = (pressures,"bar"), arrhenius = [ Arrhenius( A = (1.4e-11,"cm^3/(molecule*s)"), n = 0.0, Ea = (11200*constants.R*0.001,"kJ/mol"), T0 = (1,"K"), Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ), Arrhenius( A = (1.4e-9,"cm^3/(molecule*s)"), n = 0.0, Ea = (11200*constants.R*0.001,"kJ/mol"), T0 = (1,"K"), Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), comment = comment, ), ], Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), Pmin = (Pmin,"bar"), Pmax = (Pmax,"bar"), comment = comment, ), ] original_kinetics = MultiPDepArrhenius( arrhenius = arrhenius, Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), Pmin = (Pmin,"bar"), Pmax = (Pmax,"bar"), comment = comment, ) self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist = numpy.arange(Tmin, Tmax, 200.0, numpy.float64) P = 1e5 for T in Tlist: korig = original_kinetics.getRateCoefficient(T, P) krevrev = reversereverseKinetics.getRateCoefficient(T, P) self.assertAlmostEqual(korig / krevrev, 1.0, 0) def testGenerateReverseRateCoefficientThirdBody(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the ThirdBody format. """ from rmgpy.kinetics import ThirdBody arrheniusLow = Arrhenius( A = (2.62e+33,"cm^6/(mol^2*s)"), n = -4.76, Ea = (10.21,"kJ/mol"), T0 = (1,"K"), ) efficiencies = {"C": 3, "C(=O)=O": 2, "CC": 3, "O": 6, "[Ar]": 0.7, "[C]=O": 1.5, "[H][H]": 2} Tmin = 300. Tmax = 2000. Pmin = 0.01 Pmax = 100. comment = """H + CH3 -> CH4""" thirdBody = ThirdBody( arrheniusLow = arrheniusLow, Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), Pmin = (Pmin,"bar"), Pmax = (Pmax,"bar"), efficiencies = efficiencies, comment = comment, ) original_kinetics = thirdBody self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist = numpy.arange(Tmin, Tmax, 200.0, numpy.float64) P = 1e5 for T in Tlist: korig = original_kinetics.getRateCoefficient(T, P) krevrev = reversereverseKinetics.getRateCoefficient(T, P) self.assertAlmostEqual(korig / krevrev, 1.0, 0) def testGenerateReverseRateCoefficientLindemann(self): """ Test the Reaction.generateReverseRateCoefficient() method works for the Lindemann format. """ from rmgpy.kinetics import Lindemann arrheniusHigh = Arrhenius( A = (1.39e+16,"cm^3/(mol*s)"), n = -0.534, Ea = (2.243,"kJ/mol"), T0 = (1,"K"), ) arrheniusLow = Arrhenius( A = (2.62e+33,"cm^6/(mol^2*s)"), n = -4.76, Ea = (10.21,"kJ/mol"), T0 = (1,"K"), ) efficiencies = {"C": 3, "C(=O)=O": 2, "CC": 3, "O": 6, "[Ar]": 0.7, "[C]=O": 1.5, "[H][H]": 2} Tmin = 300. Tmax = 2000. Pmin = 0.01 Pmax = 100. comment = """H + CH3 -> CH4""" lindemann = Lindemann( arrheniusHigh = arrheniusHigh, arrheniusLow = arrheniusLow, Tmin = (Tmin,"K"), Tmax = (Tmax,"K"), Pmin = (Pmin,"bar"), Pmax = (Pmax,"bar"), efficiencies = efficiencies, comment = comment, ) original_kinetics = lindemann self.reaction2.kinetics = original_kinetics reverseKinetics = self.reaction2.generateReverseRateCoefficient() self.reaction2.kinetics = reverseKinetics # reverse reactants, products to ensure Keq is correctly computed self.reaction2.reactants, self.reaction2.products = self.reaction2.products, self.reaction2.reactants reversereverseKinetics = self.reaction2.generateReverseRateCoefficient() # check that reverting the reverse yields the original Tlist =

numpy.arange(Tmin, Tmax, 200.0, numpy.float64)

numpy.arange

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k') plt.plot(((time[-202] + time[-201]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed', label=textwrap.fill('Neural network targets', 13)) plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(((time_extended[-1001] + time_extended[-1000]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed') plt.xlim(3.4 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/neural_network.png') plt.show() # plot 6a np.random.seed(0) time = np.linspace(0, 5 * np.pi, 1001) knots_51 = np.linspace(0, 5 * np.pi, 51) time_series = np.cos(2 * time) + np.cos(4 * time) + np.cos(8 * time) noise = np.random.normal(0, 1, len(time_series)) time_series += noise advemdpy = EMD(time=time, time_series=time_series) imfs_51, hts_51, ifs_51 = advemdpy.empirical_mode_decomposition(knots=knots_51, max_imfs=3, edge_effect='symmetric_anchor', verbose=False)[:3] knots_31 = np.linspace(0, 5 * np.pi, 31) imfs_31, hts_31, ifs_31 = advemdpy.empirical_mode_decomposition(knots=knots_31, max_imfs=2, edge_effect='symmetric_anchor', verbose=False)[:3] knots_11 = np.linspace(0, 5 * np.pi, 11) imfs_11, hts_11, ifs_11 = advemdpy.empirical_mode_decomposition(knots=knots_11, max_imfs=1, edge_effect='symmetric_anchor', verbose=False)[:3] fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) print(f'DFA fluctuation with 51 knots: {np.round(np.var(time_series - (imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :])), 3)}') for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[0].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[0].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) print(f'DFA fluctuation with 31 knots: {np.round(np.var(time_series - (imfs_31[1, :] + imfs_31[2, :])), 3)}') for knot in knots_31: axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[1].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[1].set_xticklabels(['', '', '', '', '', '']) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) axs[1].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[1].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[1].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[1].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') axs[2].plot(time, time_series, label='Time series') axs[2].plot(time, imfs_11[1, :], label='IMF 1 with 11 knots') axs[2].plot(time, imfs_31[2, :], label='IMF 2 with 31 knots') axs[2].plot(time, imfs_51[3, :], label='IMF 3 with 51 knots') print(f'DFA fluctuation with 11 knots: {np.round(np.var(time_series - imfs_51[3, :]), 3)}') for knot in knots_11: axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[2].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[2].set_xticklabels(['$0$', r'$\pi$', r'$2\pi$', r'$3\pi$', r'$4\pi$', r'$5\pi$']) box_2 = axs[2].get_position() axs[2].set_position([box_2.x0 - 0.05, box_2.y0, box_2.width * 0.85, box_2.height]) axs[2].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[2].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[2].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[2].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[2].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') plt.savefig('jss_figures/DFA_different_trends.png') plt.show() # plot 6b fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences Zoomed Region', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[0].set_ylim(-5.5, 5.5) axs[0].set_xlim(0.95 * np.pi, 1.55 * np.pi) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) for knot in knots_31: axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[1].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[1].set_xticklabels(['', '', '', '', '', '']) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) axs[1].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].set_ylim(-5.5, 5.5) axs[1].set_xlim(0.95 * np.pi, 1.55 * np.pi) axs[2].plot(time, time_series, label='Time series') axs[2].plot(time, imfs_11[1, :], label='IMF 1 with 11 knots') axs[2].plot(time, imfs_31[2, :], label='IMF 2 with 31 knots') axs[2].plot(time, imfs_51[3, :], label='IMF 3 with 51 knots') for knot in knots_11: axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[2].set_xticks([np.pi, (3 / 2) * np.pi]) axs[2].set_xticklabels([r'$\pi$', r'$\frac{3}{2}\pi$']) box_2 = axs[2].get_position() axs[2].set_position([box_2.x0 - 0.05, box_2.y0, box_2.width * 0.85, box_2.height]) axs[2].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[2].set_ylim(-5.5, 5.5) axs[2].set_xlim(0.95 * np.pi, 1.55 * np.pi) plt.savefig('jss_figures/DFA_different_trends_zoomed.png') plt.show() hs_ouputs = hilbert_spectrum(time, imfs_51, hts_51, ifs_51, max_frequency=12, plot=False) # plot 6c ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Simple Sinusoidal Time Seres with Added Noise', 50)) x_hs, y, z = hs_ouputs z_min, z_max = 0, np.abs(z).max() ax.pcolormesh(x_hs, y, np.abs(z), cmap='gist_rainbow', vmin=z_min, vmax=z_max) ax.plot(x_hs[0, :], 8 * np.ones_like(x_hs[0, :]), '--', label=r'$\omega = 8$', Linewidth=3) ax.plot(x_hs[0, :], 4 * np.ones_like(x_hs[0, :]), '--', label=r'$\omega = 4$', Linewidth=3) ax.plot(x_hs[0, :], 2 * np.ones_like(x_hs[0, :]), '--', label=r'$\omega = 2$', Linewidth=3) ax.set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi]) ax.set_xticklabels(['$0$', r'$\pi$', r'$2\pi$', r'$3\pi$', r'$4\pi$']) plt.ylabel(r'Frequency (rad.s$^{-1}$)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.85, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/DFA_hilbert_spectrum.png') plt.show() # plot 6c time = np.linspace(0, 5 * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 51) fluc = Fluctuation(time=time, time_series=time_series) max_unsmoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='maxima', smooth=False) max_smoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='maxima', smooth=True) min_unsmoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='minima', smooth=False) min_smoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='minima', smooth=True) util = Utility(time=time, time_series=time_series) maxima = util.max_bool_func_1st_order_fd() minima = util.min_bool_func_1st_order_fd() ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title(textwrap.fill('Plot Demonstrating Unsmoothed Extrema Envelopes if Schoenberg–Whitney Conditions are Not Satisfied', 50)) plt.plot(time, time_series, label='Time series', zorder=2, LineWidth=2) plt.scatter(time[maxima], time_series[maxima], c='r', label='Maxima', zorder=10) plt.scatter(time[minima], time_series[minima], c='b', label='Minima', zorder=10) plt.plot(time, max_unsmoothed[0], label=textwrap.fill('Unsmoothed maxima envelope', 10), c='darkorange') plt.plot(time, max_smoothed[0], label=textwrap.fill('Smoothed maxima envelope', 10), c='red') plt.plot(time, min_unsmoothed[0], label=textwrap.fill('Unsmoothed minima envelope', 10), c='cyan') plt.plot(time, min_smoothed[0], label=textwrap.fill('Smoothed minima envelope', 10), c='blue') for knot in knots[:-1]: plt.plot(knot * np.ones(101), np.linspace(-3.0, -2.0, 101), '--', c='grey', zorder=1) plt.plot(knots[-1] * np.ones(101), np.linspace(-3.0, -2.0, 101), '--', c='grey', label='Knots', zorder=1) plt.xticks((0, 1 * np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi), (r'$0$', r'$\pi$', r'2$\pi$', r'3$\pi$', r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) plt.xlim(-0.25 * np.pi, 5.25 * np.pi) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Schoenberg_Whitney_Conditions.png') plt.show() # plot 7 a = 0.25 width = 0.2 time = np.linspace((0 + a) * np.pi, (5 - a) * np.pi, 1001) knots = np.linspace((0 + a) * np.pi, (5 - a) * np.pi, 11) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] inflection_bool = utils.inflection_point() inflection_x = time[inflection_bool] inflection_y = time_series[inflection_bool] fluctuation = emd_mean.Fluctuation(time=time, time_series=time_series) maxima_envelope = fluctuation.envelope_basis_function_approximation(knots, 'maxima', smooth=False, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] maxima_envelope_smooth = fluctuation.envelope_basis_function_approximation(knots, 'maxima', smooth=True, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] minima_envelope = fluctuation.envelope_basis_function_approximation(knots, 'minima', smooth=False, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] minima_envelope_smooth = fluctuation.envelope_basis_function_approximation(knots, 'minima', smooth=True, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] inflection_points_envelope = fluctuation.direct_detrended_fluctuation_estimation(knots, smooth=True, smoothing_penalty=0.2, technique='inflection_points')[0] binomial_points_envelope = fluctuation.direct_detrended_fluctuation_estimation(knots, smooth=True, smoothing_penalty=0.2, technique='binomial_average', order=21, increment=20)[0] derivative_of_lsq = utils.derivative_forward_diff() derivative_time = time[:-1] derivative_knots = np.linspace(knots[0], knots[-1], 31) # change (1) detrended_fluctuation_technique and (2) max_internal_iter and (3) debug (confusing with external debugging) emd = AdvEMDpy.EMD(time=derivative_time, time_series=derivative_of_lsq) imf_1_of_derivative = emd.empirical_mode_decomposition(knots=derivative_knots, knot_time=derivative_time, text=False, verbose=False)[0][1, :] utils = emd_utils.Utility(time=time[:-1], time_series=imf_1_of_derivative) optimal_maxima = np.r_[False, utils.derivative_forward_diff() < 0, False] & \ np.r_[utils.zero_crossing() == 1, False] optimal_minima = np.r_[False, utils.derivative_forward_diff() > 0, False] & \ np.r_[utils.zero_crossing() == 1, False] EEMD_maxima_envelope = fluctuation.envelope_basis_function_approximation_fixed_points(knots, 'maxima', optimal_maxima, optimal_minima, smooth=False, smoothing_penalty=0.2, edge_effect='none')[0] EEMD_minima_envelope = fluctuation.envelope_basis_function_approximation_fixed_points(knots, 'minima', optimal_maxima, optimal_minima, smooth=False, smoothing_penalty=0.2, edge_effect='none')[0] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Detrended Fluctuation Analysis Examples') plt.plot(time, time_series, LineWidth=2, label='Time series') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(time[optimal_maxima], time_series[optimal_maxima], c='darkred', zorder=4, label=textwrap.fill('Optimal maxima', 10)) plt.scatter(time[optimal_minima], time_series[optimal_minima], c='darkblue', zorder=4, label=textwrap.fill('Optimal minima', 10)) plt.scatter(inflection_x, inflection_y, c='magenta', zorder=4, label=textwrap.fill('Inflection points', 10)) plt.plot(time, maxima_envelope, c='darkblue', label=textwrap.fill('EMD envelope', 10)) plt.plot(time, minima_envelope, c='darkblue') plt.plot(time, (maxima_envelope + minima_envelope) / 2, c='darkblue') plt.plot(time, maxima_envelope_smooth, c='darkred', label=textwrap.fill('SEMD envelope', 10)) plt.plot(time, minima_envelope_smooth, c='darkred') plt.plot(time, (maxima_envelope_smooth + minima_envelope_smooth) / 2, c='darkred') plt.plot(time, EEMD_maxima_envelope, c='darkgreen', label=textwrap.fill('EEMD envelope', 10)) plt.plot(time, EEMD_minima_envelope, c='darkgreen') plt.plot(time, (EEMD_maxima_envelope + EEMD_minima_envelope) / 2, c='darkgreen') plt.plot(time, inflection_points_envelope, c='darkorange', label=textwrap.fill('Inflection point envelope', 10)) plt.plot(time, binomial_points_envelope, c='deeppink', label=textwrap.fill('Binomial average envelope', 10)) plt.plot(time, np.cos(time), c='black', label='True mean') plt.xticks((0, 1 * np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi), (r'$0$', r'$\pi$', r'2$\pi$', r'3$\pi$', r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) plt.xlim(-0.25 * np.pi, 5.25 * np.pi) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/detrended_fluctuation_analysis.png') plt.show() # Duffing Equation Example def duffing_equation(xy, ts): gamma = 0.1 epsilon = 1 omega = ((2 * np.pi) / 25) return [xy[1], xy[0] - epsilon * xy[0] ** 3 + gamma * np.cos(omega * ts)] t = np.linspace(0, 150, 1501) XY0 = [1, 1] solution = odeint(duffing_equation, XY0, t) x = solution[:, 0] dxdt = solution[:, 1] x_points = [0, 50, 100, 150] x_names = {0, 50, 100, 150} y_points_1 = [-2, 0, 2] y_points_2 = [-1, 0, 1] fig, axs = plt.subplots(2, 1) plt.subplots_adjust(hspace=0.2) axs[0].plot(t, x) axs[0].set_title('Duffing Equation Displacement') axs[0].set_ylim([-2, 2]) axs[0].set_xlim([0, 150]) axs[1].plot(t, dxdt) axs[1].set_title('Duffing Equation Velocity') axs[1].set_ylim([-1.5, 1.5]) axs[1].set_xlim([0, 150]) axis = 0 for ax in axs.flat: ax.label_outer() if axis == 0: ax.set_ylabel('x(t)') ax.set_yticks(y_points_1) if axis == 1: ax.set_ylabel(r'$ \dfrac{dx(t)}{dt} $') ax.set(xlabel='t') ax.set_yticks(y_points_2) ax.set_xticks(x_points) ax.set_xticklabels(x_names) axis += 1 plt.savefig('jss_figures/Duffing_equation.png') plt.show() # compare other packages Duffing - top pyemd = pyemd0215() py_emd = pyemd(x) IP, IF, IA = emd040.spectra.frequency_transform(py_emd.T, 10, 'hilbert') freq_edges, freq_bins = emd040.spectra.define_hist_bins(0, 0.2, 100) hht = emd040.spectra.hilberthuang(IF, IA, freq_edges) hht = gaussian_filter(hht, sigma=1) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 1.0 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Duffing Equation using PyEMD 0.2.10', 40)) plt.pcolormesh(t, freq_bins, hht, cmap='gist_rainbow', vmin=0, vmax=np.max(np.max(np.abs(hht)))) plt.plot(t[:-1], 0.124 * np.ones_like(t[:-1]), '--', label=textwrap.fill('Hamiltonian frequency approximation', 15)) plt.plot(t[:-1], 0.04 * np.ones_like(t[:-1]), 'g--', label=textwrap.fill('Driving function frequency', 15)) plt.xticks([0, 50, 100, 150]) plt.yticks([0, 0.1, 0.2]) plt.ylabel('Frequency (Hz)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.75, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Duffing_equation_ht_pyemd.png') plt.show() plt.show() emd_sift = emd040.sift.sift(x) IP, IF, IA = emd040.spectra.frequency_transform(emd_sift, 10, 'hilbert') freq_edges, freq_bins = emd040.spectra.define_hist_bins(0, 0.2, 100) hht = emd040.spectra.hilberthuang(IF, IA, freq_edges) hht = gaussian_filter(hht, sigma=1) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 1.0 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Duffing Equation using emd 0.3.3', 40)) plt.pcolormesh(t, freq_bins, hht, cmap='gist_rainbow', vmin=0, vmax=np.max(np.max(np.abs(hht)))) plt.plot(t[:-1], 0.124 * np.ones_like(t[:-1]), '--', label=textwrap.fill('Hamiltonian frequency approximation', 15)) plt.plot(t[:-1], 0.04 * np.ones_like(t[:-1]), 'g--', label=textwrap.fill('Driving function frequency', 15)) plt.xticks([0, 50, 100, 150]) plt.yticks([0, 0.1, 0.2]) plt.ylabel('Frequency (Hz)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.75, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Duffing_equation_ht_emd.png') plt.show() # compare other packages Duffing - bottom emd_duffing = AdvEMDpy.EMD(time=t, time_series=x) emd_duff, emd_ht_duff, emd_if_duff, _, _, _, _ = emd_duffing.empirical_mode_decomposition(verbose=False) fig, axs = plt.subplots(2, 1) plt.subplots_adjust(hspace=0.3) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) axs[0].plot(t, emd_duff[1, :], label='AdvEMDpy') axs[0].plot(t, py_emd[0, :], '--', label='PyEMD 0.2.10') axs[0].plot(t, emd_sift[:, 0], '--', label='emd 0.3.3') axs[0].set_title('IMF 1') axs[0].set_ylim([-2, 2]) axs[0].set_xlim([0, 150]) axs[1].plot(t, emd_duff[2, :], label='AdvEMDpy') print(f'AdvEMDpy driving function error: {np.round(sum(abs(0.1 * np.cos(0.04 * 2 * np.pi * t) - emd_duff[2, :])), 3)}') axs[1].plot(t, py_emd[1, :], '--', label='PyEMD 0.2.10') print(f'PyEMD driving function error: {np.round(sum(abs(0.1 * np.cos(0.04 * 2 * np.pi * t) - py_emd[1, :])), 3)}') axs[1].plot(t, emd_sift[:, 1], '--', label='emd 0.3.3') print(f'emd driving function error: {np.round(sum(abs(0.1 * np.cos(0.04 * 2 * np.pi * t) - emd_sift[:, 1])), 3)}') axs[1].plot(t, 0.1 *

np.cos(0.04 * 2 * np.pi * t)

numpy.cos

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101),

np.linspace(-2, 2, 101)

numpy.linspace

import os from PIL import Image import cv2 from os import listdir from os.path import join import matplotlib.pyplot as plt import matplotlib from matplotlib.colors import LogNorm from io_utils.io_common import create_folder from viz_utils.constants import PlotMode, BackgroundType import pylab import numpy as np import cmocean import shapely import cartopy.crs as ccrs import cartopy.feature as cfeature import cartopy def select_colormap(field_name): ''' Based on the name if the field it chooses a colormap from cmocean Args: field_name: Returns: ''' if np.any([field_name.find(x) != -1 for x in ('ssh', 'srfhgt', 'adt','surf_el')]): # cmaps_fields.append(cmocean.cm.deep_r) return cmocean.cm.curl elif np.any([field_name.find(x) != -1 for x in ('temp', 'sst', 'temperature')]): return cmocean.cm.thermal elif np.any([field_name.find(x) != -1 for x in ('vorticity', 'vort')]): return cmocean.cm.curl elif np.any([field_name.find(x) != -1 for x in ('salin', 'sss', 'sal')]): return cmocean.cm.haline elif field_name.find('error') != -1: return cmocean.cm.diff elif field_name.find('binary') != -1: return cmocean.cm.oxy elif np.any([field_name.find(x) != -1 for x in ('u_', 'v_', 'u-vel.', 'v-vel.','velocity')]): return cmocean.cm.speed class EOAImageVisualizer: """This class makes plenty of plots assuming we are plotting Geospatial data (maps). It is made to read xarrays, numpy arrays, and numpy arrays in dictionaries vizobj = new EOAImageVisualizer(disp_images=True, output_folder='output', lats=[lats],lons=[lons]) """ _COLORS = ['y', 'r', 'c', 'b', 'g', 'w', 'k', 'y', 'r', 'c', 'b', 'g', 'w', 'k'] _figsize = 8 _font_size = 30 _units = '' _max_imgs_per_row = 4 _mincbar = np.nan # User can set a min and max colorbar values to 'force' same color bar to all plots _maxcbar = np.nan _flip_data = True _eoas_pyutils_path = './eoas_pyutils'# This is the path where the eoas_utils folder is stored with respect to the main project _contourf = False # When plotting non-regular grids and need precision _background = BackgroundType.BLUE_MARBLE_LR # Select the background to use _auto_colormap = True # Selects the colormap based on the name of the field _show_var_names = False # Includes the name of the field name in the titles _additional_polygons = [] # MUST BE SHAPELY GEOMETRIES In case we want to include additional polygons in the plots (all of them) # If you want to add a streamplot of a vector field. It must be a dictionary with keys x,y,u,v # and optional density, color, cmap, arrowsize, arrowstyle, minlength _vector_field = None _norm = None # Use to normalize the colormap. For example with LogNorm # vizobj = EOAImageVisualizer(disp_images=True, output_folder='output', # lats=[lats],lons=[lons]) def __init__(self, disp_images=True, output_folder='output', lats=[-90,90], lons =[-180,180], projection=ccrs.PlateCarree(), **kwargs): # All the arguments that are passed to the constructor of the class MUST have its name on it. self._disp_images = disp_images self._output_folder = output_folder self._projection = projection bbox = self.getExtent(lats, lons) self._extent = bbox self._lats = lats self._lons = lons self._fig_prop = (bbox[1]-bbox[0])/(bbox[3]-bbox[2]) self._contour_labels = False for arg_name, arg_value in kwargs.items(): self.__dict__["_" + arg_name] = arg_value print(self.__dict__["_" + arg_name]) def __getattr__(self, attr): '''Generic getter for all the properties of the class''' return self.__dict__["_" + attr] def __setattr__(self, attr, value): '''Generic setter for all the properties of the class''' self.__dict__["_" + attr] = value def add_colorbar(self, fig, im, ax, show_color_bar, label=""): # https://matplotlib.org/api/_as_gen/matplotlib.pyplot.colorbar.html if show_color_bar: font_size_cbar = self._font_size * .5 # TODO how to make this automatic and works always cbar = fig.colorbar(im, ax=ax, shrink=.7) cbar.ax.tick_params(labelsize=font_size_cbar) if label != "": cbar.set_label(label, fontsize=font_size_cbar*1.2) else: cbar.set_label(self._units, fontsize=font_size_cbar*1.2) def plot_slice_eoa(self, c_img, ax, cmap='gray', mode=PlotMode.RASTER, mincbar=np.nan, maxcbar=np.nan) -> None: """ Plots a 2D img for EOA data. :param c_img: 2D array :param ax: geoaxes :return: """ c_ax = ax if self._flip_data: origin = 'lower' else: origin = 'upper' if self._background == BackgroundType.CARTO_DEF: c_ax.stock_img() else: if self._background == BackgroundType.BLUE_MARBLE_LR: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/bluemarble.png')) if self._background == BackgroundType.BLUE_MARBLE_HR: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/bluemarble_5400x2700.jpg')) if self._background == BackgroundType.TOPO: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/etopo.png')) if self._background == BackgroundType.BATHYMETRY: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/bathymetry_3600x1800.jpg')) c_ax.imshow(img, origin='upper', extent=(-180,180,-90,90), transform=ccrs.PlateCarree()) if mode == PlotMode.RASTER or mode == PlotMode.MERGED: if self._contourf: im = c_ax.contourf(self._lons, self._lats, c_img, num_colors=255, cmap='inferno', extent=self._extent) else: if np.isnan(mincbar): im = c_ax.imshow(c_img, extent=self._extent, origin=origin, cmap=cmap, transform=self._projection, norm=self._norm) else: im = c_ax.imshow(c_img, extent=self._extent, origin=origin, cmap=cmap, vmin=mincbar, vmax=maxcbar, transform=self._projection, norm=self._norm) if mode == PlotMode.CONTOUR or mode == PlotMode.MERGED: c_ax.set_extent(self.getExtent(list(self._lats), list(self._lons))) if mode == PlotMode.CONTOUR: im = c_ax.contour(c_img, extent=self._extent, transform=self._projection) if mode == PlotMode.MERGED: if self._contour_labels: c_ax.contour(c_img, self._contour_labels, colors='r', extent=self._extent, transform=self._projection) else: c_ax.contour(c_img, extent=self._extent, transform=self._projection) if len(self._additional_polygons) > 0: pol_lats = [] pol_lons = [] for c_polygon in self._additional_polygons: if isinstance(c_polygon, shapely.geometry.linestring.LineString): x,y = c_polygon.xy elif isinstance(c_polygon, shapely.geometry.polygon.Polygon): x, y = c_polygon.exterior.xy pol_lats += y pol_lons += x c_ax.plot(x,y, transform=self._projection, c='r') # Adds a threshold to the plot to see the polygons c_ax.set_extent(self.getExtent(list(self._lats) + pol_lats, list(self._lons) + pol_lons, 0.5)) if self._vector_field != None: try: u = self._vector_field['u'] v = self._vector_field['v'] x = self._vector_field['x'] y = self._vector_field['y'] vec_keys = self._vector_field.keys() c = 'r' density = 1 linewidth = 3 vec_cmap = cmocean.cm.solar if 'color' in vec_keys: c = self._vector_field['color'] if 'density' in vec_keys: density = self._vector_field['density'] if 'linewidth' in vec_keys: linewidth = self._vector_field['linewidth'] if 'cmap' in vec_keys: vec_cmap = self._vector_field['cmap'] c_ax.set_extent(self.getExtent(list(self._lats), list(self._lons))) c_ax.streamplot(x, y, u, v, transform=self._projection, density=density, color=c, cmap=vec_cmap, linewidth=linewidth) except Exception as e: print(F"Couldn't add vector field e:{e}") gl = c_ax.gridlines(draw_labels=True, color='grey', alpha=0.5, linestyle='--') # gl.xlabel_style = {'size': self._font_size/2, 'color': '#aaaaaa', 'weight':'bold'} font_coords = {'size': self._font_size*.6} gl.xlabel_style = font_coords gl.ylabel_style = font_coords gl.top_labels = False gl.right_labels = False return im def get_proper_size(self, rows, cols): """ Obtains the proper size for a figure. :param rows: how many rows will the figure have :param cols: how many colswill the figure have :param prop: Proportion is the proportion to use w/h :return: """ if rows == 1: return self._figsize * cols * self._fig_prop, self._figsize else: return self._figsize * cols * self._fig_prop, self._figsize * rows def _close_figure(self): """Depending on what is disp_images, the figures are displayed or just closed""" if self._disp_images: plt.show() else: plt.close() def getExtent(self, lats, lons, expand_ext=0.0): ''' Obtains the bbox of the coordinates. If included threshold then increases the bbox in all directions with that thres Args: lats: lons: inc_threshold: Returns: ''' minLat = np.amin(lats) - expand_ext maxLat = np.amax(lats) + expand_ext minLon = np.amin(lons) - expand_ext maxLon = np.amax(lons) + expand_ext bbox = (minLon, maxLon, minLat, maxLat) return bbox def xr_summary(self, ds): """ Prints a summary of the netcdf (global attributes, variables, etc) :param ds: :return: """ print("\n========== Global attributes =========") for name in ds.attrs: print(F"{name} = {getattr(ds, name)}") print("\n========== Dimensions =========") for name in ds.dims: print(F"{name}: {ds[name].shape}") print("\n========== Coordinates =========") for name in ds.coords: print(F"{name}: {ds[name].shape}") print("\n========== Variables =========") for cur_variable_name in ds.variables: cur_var = ds[cur_variable_name] print(F"{cur_variable_name}: {cur_var.dims} {cur_var.shape}") def nc_summary(self, ds): """ Prints a summary of the netcdf (global attributes, variables, etc) :param ds: :return: """ print("\n========== Global attributes =========") for name in ds.ncattrs(): print(F"{name} = {getattr(ds, name)}") print("\n========== Variables =========") netCDFvars = ds.variables for cur_variable_name in netCDFvars.keys(): cur_var = ds.variables[cur_variable_name] print(F"Dimensions for {cur_variable_name}: {cur_var.dimensions} {cur_var.shape}") def add_roads(self, ax): # Names come from: https://www.naturalearthdata.com/features/ # -- Add states roads = cfeature.NaturalEarthFeature( category='cultural', name='roads', scale='10m', facecolor='none') ax.add_feature(roads, edgecolor='black') return ax def add_states(self, ax): # Names come from: https://www.naturalearthdata.com/features/ # -- Add states states_provinces = cfeature.NaturalEarthFeature( category='cultural', name='admin_1_states_provinces_lines', scale='50m', facecolor='none') ax.add_feature(states_provinces, edgecolor='gray') return ax def plot_scatter_data(self, lats=None, lons=None, bbox=None, s=1, c='blue', cmap='plasma', title=''): ''' This function plots points in a map :param bbox: :return: ''' if bbox is None: bbox = (-180, 180, -90, 90) if lats is None: lats = self.lats if lons is None: lons = self.lons fig, ax = plt.subplots(1, 1, figsize=(self._figsize, self._figsize), subplot_kw={'projection': ccrs.PlateCarree()}) ax.set_extent(bbox) # If we do not set this, it will cropp it to the limits of the locations ax.gridlines() im = ax.scatter(lons, lats, s=s, c=c, cmap=cmap) fig.colorbar(im, ax=ax, shrink=0.7) ax.coastlines() plt.title(title) plt.show() def plot_3d_data_npdict(self, np_variables:list, var_names:list, z_levels= [], title='', file_name_prefix='', cmap=None, z_names = [], show_color_bar=True, plot_mode=PlotMode.RASTER, mincbar=np.nan, maxcbar=np.nan): """ Plots multiple z_levels for multiple fields. It uses rows for each depth, and columns for each variable """ create_folder(self._output_folder) orig_cmap = cmap # If the user do not requires any z-leve, then all are plotted if len(z_levels) == 0: z_levels = range(np_variables[var_names[0]].shape[0]) cols = np.min((self._max_imgs_per_row, len(var_names))) if cols == len(var_names): rows = len(z_levels) else: rows = int(len(z_levels) * np.ceil(len(var_names)/cols)) fig, _axs = plt.subplots(rows, cols, figsize=self.get_proper_size(rows, cols), subplot_kw={'projection': self._projection}) for c_zlevel, c_slice in enumerate(z_levels): # Iterates over the z-levels # Verify the index of the z_levels are the original ones. if len(z_names) != 0: c_slice_txt = z_names[c_slice] else: c_slice_txt = c_slice c_mincbar = np.nan c_maxcbar = np.nan for idx_var, c_var in enumerate(var_names): # Iterate over the fields if rows*cols == 1: # Single figure ax = _axs else: ax = _axs.flatten()[c_zlevel*len(var_names) + idx_var] # Here we chose the min and max colorbars for each field if not(np.all(np.isnan(mincbar))): if type(mincbar) is list: c_mincbar = mincbar[idx_var] else: c_mincbar = mincbar if not(np.all(

np.isnan(maxcbar)

numpy.isnan

#!/usr/bin/env python # encoding: utf-8 import numbers import os import re import sys from itertools import chain import numpy as np import scipy.sparse as sp import six import pickle from .model import get_convo_nn2 from .stop_words import THAI_STOP_WORDS from .utils import CHAR_TYPES_MAP, CHARS_MAP, create_feature_array MODULE_PATH = os.path.dirname(__file__) WEIGHT_PATH = os.path.join(MODULE_PATH, 'weight', 'cnn_without_ne_ab.h5') TOKENIZER = None def tokenize(text, custom_dict=None): """ Tokenize given Thai text string Input ===== text: str, Thai text string custom_dict: str (or list), path to customized dictionary file It allows the function not to tokenize given dictionary wrongly. The file should contain custom words separated by line. Alternatively, you can provide list of custom words too. Output ====== tokens: list, list of tokenized words Example ======= >> deepcut.tokenize('ตัดคำได้ดีมาก') >> ['ตัดคำ','ได้','ดี','มาก'] """ global TOKENIZER if not TOKENIZER: TOKENIZER = DeepcutTokenizer() return TOKENIZER.tokenize(text, custom_dict=custom_dict) def _custom_dict(word, text, word_end): word_length = len(word) initial_loc = 0 while True: try: start_char = re.search(word, text).start() first_char = start_char + initial_loc last_char = first_char + word_length - 1 initial_loc += start_char + word_length text = text[start_char + word_length:] word_end[first_char:last_char] = (word_length - 1) * [0] word_end[last_char] = 1 except: break return word_end def _document_frequency(X): """ Count the number of non-zero values for each feature in sparse X. """ if sp.isspmatrix_csr(X): return

np.bincount(X.indices, minlength=X.shape[1])

numpy.bincount

# -*- coding: utf-8 -*- """ Created on Thu Nov 28 12:10:11 2019 @author: Omer """ ## File handler ## This file was initially intended purely to generate the matrices for the near earth code found in: https://public.ccsds.org/Pubs/131x1o2e2s.pdf ## The values from the above pdf were copied manually to a txt file, and it is the purpose of this file to parse it. ## The emphasis here is on correctness, I currently do not see a reason to generalise this file, since matrices will be saved in either json or some matrix friendly format. import numpy as np from scipy.linalg import circulant #import matplotlib.pyplot as plt import scipy.io import common import hashlib import os projectDir = os.environ.get('LDPC') if projectDir == None: import pathlib projectDir = pathlib.Path(__file__).parent.absolute() ## <NAME>: added on 01/12/2020, need to make sure this doesn't break anything. import sys sys.path.insert(1, projectDir) FILE_HANDLER_INT_DATA_TYPE = np.int32 GENERAL_CODE_MATRIX_DATA_TYPE = np.int32 NIBBLE_CONVERTER = np.array([8, 4, 2, 1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) def nibbleToHex(inputArray): n = NIBBLE_CONVERTER.dot(inputArray) if n == 10: h = 'A' elif n== 11: h = 'B' elif n== 12: h = 'C' elif n== 13: h = 'D' elif n== 14: h = 'E' elif n== 15: h = 'F' else: h = str(n) return h def binaryArraytoHex(inputArray): d1 = len(inputArray) assert (d1 % 4 == 0) outputArray =

np.zeros(d1//4, dtype = str)

numpy.zeros

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 =

np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101)

numpy.linspace

# -*- coding: utf-8 -*- """ Created on Thu Nov 28 12:10:11 2019 @author: Omer """ ## File handler ## This file was initially intended purely to generate the matrices for the near earth code found in: https://public.ccsds.org/Pubs/131x1o2e2s.pdf ## The values from the above pdf were copied manually to a txt file, and it is the purpose of this file to parse it. ## The emphasis here is on correctness, I currently do not see a reason to generalise this file, since matrices will be saved in either json or some matrix friendly format. import numpy as np from scipy.linalg import circulant #import matplotlib.pyplot as plt import scipy.io import common import hashlib import os projectDir = os.environ.get('LDPC') if projectDir == None: import pathlib projectDir = pathlib.Path(__file__).parent.absolute() ## <NAME>: added on 01/12/2020, need to make sure this doesn't break anything. import sys sys.path.insert(1, projectDir) FILE_HANDLER_INT_DATA_TYPE = np.int32 GENERAL_CODE_MATRIX_DATA_TYPE = np.int32 NIBBLE_CONVERTER = np.array([8, 4, 2, 1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) def nibbleToHex(inputArray): n = NIBBLE_CONVERTER.dot(inputArray) if n == 10: h = 'A' elif n== 11: h = 'B' elif n== 12: h = 'C' elif n== 13: h = 'D' elif n== 14: h = 'E' elif n== 15: h = 'F' else: h = str(n) return h def binaryArraytoHex(inputArray): d1 = len(inputArray) assert (d1 % 4 == 0) outputArray = np.zeros(d1//4, dtype = str) outputString = '' for j in range(d1//4): nibble = inputArray[4 * j : 4 * j + 4] h = nibbleToHex(nibble) outputArray[j] = h outputString = outputString + h return outputArray, outputString def hexStringToBinaryArray(hexString): outputBinary = np.array([], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) for i in hexString: if i == '0': nibble = np.array([0,0,0,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '1': nibble = np.array([0,0,0,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '2': nibble = np.array([0,0,1,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '3': nibble = np.array([0,0,1,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '4': nibble = np.array([0,1,0,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '5': nibble = np.array([0,1,0,1], dtype = GENERAL_CODE_MATRIX_DATA_TYPE) elif i == '6': nibble =

np.array([0,1,1,0], dtype = GENERAL_CODE_MATRIX_DATA_TYPE)

numpy.array

"""Routines for numerical differentiation.""" from __future__ import division import numpy as np from numpy.linalg import norm from scipy.sparse.linalg import LinearOperator from ..sparse import issparse, csc_matrix, csr_matrix, coo_matrix, find from ._group_columns import group_dense, group_sparse EPS = np.finfo(np.float64).eps def _adjust_scheme_to_bounds(x0, h, num_steps, scheme, lb, ub): """Adjust final difference scheme to the presence of bounds. Parameters ---------- x0 : ndarray, shape (n,) Point at which we wish to estimate derivative. h : ndarray, shape (n,) Desired finite difference steps. num_steps : int Number of `h` steps in one direction required to implement finite difference scheme. For example, 2 means that we need to evaluate f(x0 + 2 * h) or f(x0 - 2 * h) scheme : {'1-sided', '2-sided'} Whether steps in one or both directions are required. In other words '1-sided' applies to forward and backward schemes, '2-sided' applies to center schemes. lb : ndarray, shape (n,) Lower bounds on independent variables. ub : ndarray, shape (n,) Upper bounds on independent variables. Returns ------- h_adjusted : ndarray, shape (n,) Adjusted step sizes. Step size decreases only if a sign flip or switching to one-sided scheme doesn't allow to take a full step. use_one_sided : ndarray of bool, shape (n,) Whether to switch to one-sided scheme. Informative only for ``scheme='2-sided'``. """ if scheme == '1-sided': use_one_sided = np.ones_like(h, dtype=bool) elif scheme == '2-sided': h = np.abs(h) use_one_sided = np.zeros_like(h, dtype=bool) else: raise ValueError("`scheme` must be '1-sided' or '2-sided'.") if np.all((lb == -np.inf) & (ub == np.inf)): return h, use_one_sided h_total = h * num_steps h_adjusted = h.copy() lower_dist = x0 - lb upper_dist = ub - x0 if scheme == '1-sided': x = x0 + h_total violated = (x < lb) | (x > ub) fitting = np.abs(h_total) <= np.maximum(lower_dist, upper_dist) h_adjusted[violated & fitting] *= -1 forward = (upper_dist >= lower_dist) & ~fitting h_adjusted[forward] = upper_dist[forward] / num_steps backward = (upper_dist < lower_dist) & ~fitting h_adjusted[backward] = -lower_dist[backward] / num_steps elif scheme == '2-sided': central = (lower_dist >= h_total) & (upper_dist >= h_total) forward = (upper_dist >= lower_dist) & ~central h_adjusted[forward] = np.minimum( h[forward], 0.5 * upper_dist[forward] / num_steps) use_one_sided[forward] = True backward = (upper_dist < lower_dist) & ~central h_adjusted[backward] = -np.minimum( h[backward], 0.5 * lower_dist[backward] / num_steps) use_one_sided[backward] = True min_dist = np.minimum(upper_dist, lower_dist) / num_steps adjusted_central = (~central & (np.abs(h_adjusted) <= min_dist)) h_adjusted[adjusted_central] = min_dist[adjusted_central] use_one_sided[adjusted_central] = False return h_adjusted, use_one_sided relative_step = {"2-point": EPS**0.5, "3-point": EPS**(1/3), "cs": EPS**0.5} def _compute_absolute_step(rel_step, x0, method): if rel_step is None: rel_step = relative_step[method] sign_x0 = (x0 >= 0).astype(float) * 2 - 1 return rel_step * sign_x0 * np.maximum(1.0, np.abs(x0)) def _prepare_bounds(bounds, x0): lb, ub = [np.asarray(b, dtype=float) for b in bounds] if lb.ndim == 0: lb = np.resize(lb, x0.shape) if ub.ndim == 0: ub = np.resize(ub, x0.shape) return lb, ub def group_columns(A, order=0): """Group columns of a 2-D matrix for sparse finite differencing [1]_. Two columns are in the same group if in each row at least one of them has zero. A greedy sequential algorithm is used to construct groups. Parameters ---------- A : array_like or sparse matrix, shape (m, n) Matrix of which to group columns. order : int, iterable of int with shape (n,) or None Permutation array which defines the order of columns enumeration. If int or None, a random permutation is used with `order` used as a random seed. Default is 0, that is use a random permutation but guarantee repeatability. Returns ------- groups : ndarray of int, shape (n,) Contains values from 0 to n_groups-1, where n_groups is the number of found groups. Each value ``groups[i]`` is an index of a group to which ith column assigned. The procedure was helpful only if n_groups is significantly less than n. References ---------- .. [1] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. """ if issparse(A): A = csc_matrix(A) else: A = np.atleast_2d(A) A = (A != 0).astype(np.int32) if A.ndim != 2: raise ValueError("`A` must be 2-dimensional.") m, n = A.shape if order is None or np.isscalar(order): rng = np.random.RandomState(order) order = rng.permutation(n) else: order = np.asarray(order) if order.shape != (n,): raise ValueError("`order` has incorrect shape.") A = A[:, order] if issparse(A): groups = group_sparse(m, n, A.indices, A.indptr) else: groups = group_dense(m, n, A) groups[order] = groups.copy() return groups def approx_derivative(fun, x0, method='3-point', rel_step=None, f0=None, bounds=(-np.inf, np.inf), sparsity=None, as_linear_operator=False, args=(), kwargs={}): """Compute finite difference approximation of the derivatives of a vector-valued function. If a function maps from R^n to R^m, its derivatives form m-by-n matrix called the Jacobian, where an element (i, j) is a partial derivative of f[i] with respect to x[j]. Parameters ---------- fun : callable Function of which to estimate the derivatives. The argument x passed to this function is ndarray of shape (n,) (never a scalar even if n=1). It must return 1-D array_like of shape (m,) or a scalar. x0 : array_like of shape (n,) or float Point at which to estimate the derivatives. Float will be converted to a 1-D array. method : {'3-point', '2-point', 'cs'}, optional Finite difference method to use: - '2-point' - use the first order accuracy forward or backward difference. - '3-point' - use central difference in interior points and the second order accuracy forward or backward difference near the boundary. - 'cs' - use a complex-step finite difference scheme. This assumes that the user function is real-valued and can be analytically continued to the complex plane. Otherwise, produces bogus results. rel_step : None or array_like, optional Relative step size to use. The absolute step size is computed as ``h = rel_step * sign(x0) * max(1, abs(x0))``, possibly adjusted to fit into the bounds. For ``method='3-point'`` the sign of `h` is ignored. If None (default) then step is selected automatically, see Notes. f0 : None or array_like, optional If not None it is assumed to be equal to ``fun(x0)``, in this case the ``fun(x0)`` is not called. Default is None. bounds : tuple of array_like, optional Lower and upper bounds on independent variables. Defaults to no bounds. Each bound must match the size of `x0` or be a scalar, in the latter case the bound will be the same for all variables. Use it to limit the range of function evaluation. Bounds checking is not implemented when `as_linear_operator` is True. sparsity : {None, array_like, sparse matrix, 2-tuple}, optional Defines a sparsity structure of the Jacobian matrix. If the Jacobian matrix is known to have only few non-zero elements in each row, then it's possible to estimate its several columns by a single function evaluation [3]_. To perform such economic computations two ingredients are required: * structure : array_like or sparse matrix of shape (m, n). A zero element means that a corresponding element of the Jacobian identically equals to zero. * groups : array_like of shape (n,). A column grouping for a given sparsity structure, use `group_columns` to obtain it. A single array or a sparse matrix is interpreted as a sparsity structure, and groups are computed inside the function. A tuple is interpreted as (structure, groups). If None (default), a standard dense differencing will be used. Note, that sparse differencing makes sense only for large Jacobian matrices where each row contains few non-zero elements. as_linear_operator : bool, optional When True the function returns an `scipy.sparse.linalg.LinearOperator`. Otherwise it returns a dense array or a sparse matrix depending on `sparsity`. The linear operator provides an efficient way of computing ``J.dot(p)`` for any vector ``p`` of shape (n,), but does not allow direct access to individual elements of the matrix. By default `as_linear_operator` is False. args, kwargs : tuple and dict, optional Additional arguments passed to `fun`. Both empty by default. The calling signature is ``fun(x, *args, **kwargs)``. Returns ------- J : {ndarray, sparse matrix, LinearOperator} Finite difference approximation of the Jacobian matrix. If `as_linear_operator` is True returns a LinearOperator with shape (m, n). Otherwise it returns a dense array or sparse matrix depending on how `sparsity` is defined. If `sparsity` is None then a ndarray with shape (m, n) is returned. If `sparsity` is not None returns a csr_matrix with shape (m, n). For sparse matrices and linear operators it is always returned as a 2-D structure, for ndarrays, if m=1 it is returned as a 1-D gradient array with shape (n,). See Also -------- check_derivative : Check correctness of a function computing derivatives. Notes ----- If `rel_step` is not provided, it assigned to ``EPS**(1/s)``, where EPS is machine epsilon for float64 numbers, s=2 for '2-point' method and s=3 for '3-point' method. Such relative step approximately minimizes a sum of truncation and round-off errors, see [1]_. A finite difference scheme for '3-point' method is selected automatically. The well-known central difference scheme is used for points sufficiently far from the boundary, and 3-point forward or backward scheme is used for points near the boundary. Both schemes have the second-order accuracy in terms of Taylor expansion. Refer to [2]_ for the formulas of 3-point forward and backward difference schemes. For dense differencing when m=1 Jacobian is returned with a shape (n,), on the other hand when n=1 Jacobian is returned with a shape (m, 1). Our motivation is the following: a) It handles a case of gradient computation (m=1) in a conventional way. b) It clearly separates these two different cases. b) In all cases np.atleast_2d can be called to get 2-D Jacobian with correct dimensions. References ---------- .. [1] W. H. Press et. al. "Numerical Recipes. The Art of Scientific Computing. 3rd edition", sec. 5.7. .. [2] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. .. [3] <NAME>, "Generation of Finite Difference Formulas on Arbitrarily Spaced Grids", Mathematics of Computation 51, 1988. Examples -------- >>> import numpy as np >>> from scipy.optimize import approx_derivative >>> >>> def f(x, c1, c2): ... return np.array([x[0] * np.sin(c1 * x[1]), ... x[0] * np.cos(c2 * x[1])]) ... >>> x0 = np.array([1.0, 0.5 * np.pi]) >>> approx_derivative(f, x0, args=(1, 2)) array([[ 1., 0.], [-1., 0.]]) Bounds can be used to limit the region of function evaluation. In the example below we compute left and right derivative at point 1.0. >>> def g(x): ... return x**2 if x >= 1 else x ... >>> x0 = 1.0 >>> approx_derivative(g, x0, bounds=(-np.inf, 1.0)) array([ 1.]) >>> approx_derivative(g, x0, bounds=(1.0, np.inf)) array([ 2.]) """ if method not in ['2-point', '3-point', 'cs']: raise ValueError("Unknown method '%s'. " % method) x0 = np.atleast_1d(x0) if x0.ndim > 1: raise ValueError("`x0` must have at most 1 dimension.") lb, ub = _prepare_bounds(bounds, x0) if lb.shape != x0.shape or ub.shape != x0.shape: raise ValueError("Inconsistent shapes between bounds and `x0`.") if as_linear_operator and not (np.all(np.isinf(lb)) and np.all(np.isinf(ub))): raise ValueError("Bounds not supported when " "`as_linear_operator` is True.") def fun_wrapped(x): f = np.atleast_1d(fun(x, *args, **kwargs)) if f.ndim > 1: raise RuntimeError("`fun` return value has " "more than 1 dimension.") return f if f0 is None: f0 = fun_wrapped(x0) else: f0 = np.atleast_1d(f0) if f0.ndim > 1: raise ValueError("`f0` passed has more than 1 dimension.") if np.any((x0 < lb) | (x0 > ub)): raise ValueError("`x0` violates bound constraints.") if as_linear_operator: if rel_step is None: rel_step = relative_step[method] return _linear_operator_difference(fun_wrapped, x0, f0, rel_step, method) else: h = _compute_absolute_step(rel_step, x0, method) if method == '2-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '1-sided', lb, ub) elif method == '3-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '2-sided', lb, ub) elif method == 'cs': use_one_sided = False if sparsity is None: return _dense_difference(fun_wrapped, x0, f0, h, use_one_sided, method) else: if not issparse(sparsity) and len(sparsity) == 2: structure, groups = sparsity else: structure = sparsity groups = group_columns(sparsity) if issparse(structure): structure = csc_matrix(structure) else: structure = np.atleast_2d(structure) groups = np.atleast_1d(groups) return _sparse_difference(fun_wrapped, x0, f0, h, use_one_sided, structure, groups, method) def _linear_operator_difference(fun, x0, f0, h, method): m = f0.size n = x0.size if method == '2-point': def matvec(p): if np.array_equal(p,

np.zeros_like(p)

numpy.zeros_like

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k') plt.plot(((time[-202] + time[-201]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed', label=textwrap.fill('Neural network targets', 13)) plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(((time_extended[-1001] + time_extended[-1000]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed') plt.xlim(3.4 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/neural_network.png') plt.show() # plot 6a np.random.seed(0) time = np.linspace(0, 5 * np.pi, 1001) knots_51 = np.linspace(0, 5 * np.pi, 51) time_series = np.cos(2 * time) + np.cos(4 * time) + np.cos(8 * time) noise = np.random.normal(0, 1, len(time_series)) time_series += noise advemdpy = EMD(time=time, time_series=time_series) imfs_51, hts_51, ifs_51 = advemdpy.empirical_mode_decomposition(knots=knots_51, max_imfs=3, edge_effect='symmetric_anchor', verbose=False)[:3] knots_31 = np.linspace(0, 5 * np.pi, 31) imfs_31, hts_31, ifs_31 = advemdpy.empirical_mode_decomposition(knots=knots_31, max_imfs=2, edge_effect='symmetric_anchor', verbose=False)[:3] knots_11 = np.linspace(0, 5 * np.pi, 11) imfs_11, hts_11, ifs_11 = advemdpy.empirical_mode_decomposition(knots=knots_11, max_imfs=1, edge_effect='symmetric_anchor', verbose=False)[:3] fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) print(f'DFA fluctuation with 51 knots: {np.round(np.var(time_series - (imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :])), 3)}') for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[0].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[0].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) print(f'DFA fluctuation with 31 knots: {np.round(np.var(time_series - (imfs_31[1, :] + imfs_31[2, :])), 3)}') for knot in knots_31: axs[1].plot(knot * np.ones(101),

np.linspace(-5, 5, 101)

numpy.linspace

"""Routines for numerical differentiation.""" from __future__ import division import numpy as np from numpy.linalg import norm from scipy.sparse.linalg import LinearOperator from ..sparse import issparse, csc_matrix, csr_matrix, coo_matrix, find from ._group_columns import group_dense, group_sparse EPS = np.finfo(np.float64).eps def _adjust_scheme_to_bounds(x0, h, num_steps, scheme, lb, ub): """Adjust final difference scheme to the presence of bounds. Parameters ---------- x0 : ndarray, shape (n,) Point at which we wish to estimate derivative. h : ndarray, shape (n,) Desired finite difference steps. num_steps : int Number of `h` steps in one direction required to implement finite difference scheme. For example, 2 means that we need to evaluate f(x0 + 2 * h) or f(x0 - 2 * h) scheme : {'1-sided', '2-sided'} Whether steps in one or both directions are required. In other words '1-sided' applies to forward and backward schemes, '2-sided' applies to center schemes. lb : ndarray, shape (n,) Lower bounds on independent variables. ub : ndarray, shape (n,) Upper bounds on independent variables. Returns ------- h_adjusted : ndarray, shape (n,) Adjusted step sizes. Step size decreases only if a sign flip or switching to one-sided scheme doesn't allow to take a full step. use_one_sided : ndarray of bool, shape (n,) Whether to switch to one-sided scheme. Informative only for ``scheme='2-sided'``. """ if scheme == '1-sided': use_one_sided = np.ones_like(h, dtype=bool) elif scheme == '2-sided': h = np.abs(h) use_one_sided = np.zeros_like(h, dtype=bool) else: raise ValueError("`scheme` must be '1-sided' or '2-sided'.") if np.all((lb == -np.inf) & (ub == np.inf)): return h, use_one_sided h_total = h * num_steps h_adjusted = h.copy() lower_dist = x0 - lb upper_dist = ub - x0 if scheme == '1-sided': x = x0 + h_total violated = (x < lb) | (x > ub) fitting = np.abs(h_total) <= np.maximum(lower_dist, upper_dist) h_adjusted[violated & fitting] *= -1 forward = (upper_dist >= lower_dist) & ~fitting h_adjusted[forward] = upper_dist[forward] / num_steps backward = (upper_dist < lower_dist) & ~fitting h_adjusted[backward] = -lower_dist[backward] / num_steps elif scheme == '2-sided': central = (lower_dist >= h_total) & (upper_dist >= h_total) forward = (upper_dist >= lower_dist) & ~central h_adjusted[forward] = np.minimum( h[forward], 0.5 * upper_dist[forward] / num_steps) use_one_sided[forward] = True backward = (upper_dist < lower_dist) & ~central h_adjusted[backward] = -np.minimum( h[backward], 0.5 * lower_dist[backward] / num_steps) use_one_sided[backward] = True min_dist = np.minimum(upper_dist, lower_dist) / num_steps adjusted_central = (~central & (np.abs(h_adjusted) <= min_dist)) h_adjusted[adjusted_central] = min_dist[adjusted_central] use_one_sided[adjusted_central] = False return h_adjusted, use_one_sided relative_step = {"2-point": EPS**0.5, "3-point": EPS**(1/3), "cs": EPS**0.5} def _compute_absolute_step(rel_step, x0, method): if rel_step is None: rel_step = relative_step[method] sign_x0 = (x0 >= 0).astype(float) * 2 - 1 return rel_step * sign_x0 * np.maximum(1.0, np.abs(x0)) def _prepare_bounds(bounds, x0): lb, ub = [np.asarray(b, dtype=float) for b in bounds] if lb.ndim == 0: lb = np.resize(lb, x0.shape) if ub.ndim == 0: ub = np.resize(ub, x0.shape) return lb, ub def group_columns(A, order=0): """Group columns of a 2-D matrix for sparse finite differencing [1]_. Two columns are in the same group if in each row at least one of them has zero. A greedy sequential algorithm is used to construct groups. Parameters ---------- A : array_like or sparse matrix, shape (m, n) Matrix of which to group columns. order : int, iterable of int with shape (n,) or None Permutation array which defines the order of columns enumeration. If int or None, a random permutation is used with `order` used as a random seed. Default is 0, that is use a random permutation but guarantee repeatability. Returns ------- groups : ndarray of int, shape (n,) Contains values from 0 to n_groups-1, where n_groups is the number of found groups. Each value ``groups[i]`` is an index of a group to which ith column assigned. The procedure was helpful only if n_groups is significantly less than n. References ---------- .. [1] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. """ if issparse(A): A = csc_matrix(A) else: A = np.atleast_2d(A) A = (A != 0).astype(np.int32) if A.ndim != 2: raise ValueError("`A` must be 2-dimensional.") m, n = A.shape if order is None or np.isscalar(order): rng = np.random.RandomState(order) order = rng.permutation(n) else: order = np.asarray(order) if order.shape != (n,): raise ValueError("`order` has incorrect shape.") A = A[:, order] if issparse(A): groups = group_sparse(m, n, A.indices, A.indptr) else: groups = group_dense(m, n, A) groups[order] = groups.copy() return groups def approx_derivative(fun, x0, method='3-point', rel_step=None, f0=None, bounds=(-np.inf, np.inf), sparsity=None, as_linear_operator=False, args=(), kwargs={}): """Compute finite difference approximation of the derivatives of a vector-valued function. If a function maps from R^n to R^m, its derivatives form m-by-n matrix called the Jacobian, where an element (i, j) is a partial derivative of f[i] with respect to x[j]. Parameters ---------- fun : callable Function of which to estimate the derivatives. The argument x passed to this function is ndarray of shape (n,) (never a scalar even if n=1). It must return 1-D array_like of shape (m,) or a scalar. x0 : array_like of shape (n,) or float Point at which to estimate the derivatives. Float will be converted to a 1-D array. method : {'3-point', '2-point', 'cs'}, optional Finite difference method to use: - '2-point' - use the first order accuracy forward or backward difference. - '3-point' - use central difference in interior points and the second order accuracy forward or backward difference near the boundary. - 'cs' - use a complex-step finite difference scheme. This assumes that the user function is real-valued and can be analytically continued to the complex plane. Otherwise, produces bogus results. rel_step : None or array_like, optional Relative step size to use. The absolute step size is computed as ``h = rel_step * sign(x0) * max(1, abs(x0))``, possibly adjusted to fit into the bounds. For ``method='3-point'`` the sign of `h` is ignored. If None (default) then step is selected automatically, see Notes. f0 : None or array_like, optional If not None it is assumed to be equal to ``fun(x0)``, in this case the ``fun(x0)`` is not called. Default is None. bounds : tuple of array_like, optional Lower and upper bounds on independent variables. Defaults to no bounds. Each bound must match the size of `x0` or be a scalar, in the latter case the bound will be the same for all variables. Use it to limit the range of function evaluation. Bounds checking is not implemented when `as_linear_operator` is True. sparsity : {None, array_like, sparse matrix, 2-tuple}, optional Defines a sparsity structure of the Jacobian matrix. If the Jacobian matrix is known to have only few non-zero elements in each row, then it's possible to estimate its several columns by a single function evaluation [3]_. To perform such economic computations two ingredients are required: * structure : array_like or sparse matrix of shape (m, n). A zero element means that a corresponding element of the Jacobian identically equals to zero. * groups : array_like of shape (n,). A column grouping for a given sparsity structure, use `group_columns` to obtain it. A single array or a sparse matrix is interpreted as a sparsity structure, and groups are computed inside the function. A tuple is interpreted as (structure, groups). If None (default), a standard dense differencing will be used. Note, that sparse differencing makes sense only for large Jacobian matrices where each row contains few non-zero elements. as_linear_operator : bool, optional When True the function returns an `scipy.sparse.linalg.LinearOperator`. Otherwise it returns a dense array or a sparse matrix depending on `sparsity`. The linear operator provides an efficient way of computing ``J.dot(p)`` for any vector ``p`` of shape (n,), but does not allow direct access to individual elements of the matrix. By default `as_linear_operator` is False. args, kwargs : tuple and dict, optional Additional arguments passed to `fun`. Both empty by default. The calling signature is ``fun(x, *args, **kwargs)``. Returns ------- J : {ndarray, sparse matrix, LinearOperator} Finite difference approximation of the Jacobian matrix. If `as_linear_operator` is True returns a LinearOperator with shape (m, n). Otherwise it returns a dense array or sparse matrix depending on how `sparsity` is defined. If `sparsity` is None then a ndarray with shape (m, n) is returned. If `sparsity` is not None returns a csr_matrix with shape (m, n). For sparse matrices and linear operators it is always returned as a 2-D structure, for ndarrays, if m=1 it is returned as a 1-D gradient array with shape (n,). See Also -------- check_derivative : Check correctness of a function computing derivatives. Notes ----- If `rel_step` is not provided, it assigned to ``EPS**(1/s)``, where EPS is machine epsilon for float64 numbers, s=2 for '2-point' method and s=3 for '3-point' method. Such relative step approximately minimizes a sum of truncation and round-off errors, see [1]_. A finite difference scheme for '3-point' method is selected automatically. The well-known central difference scheme is used for points sufficiently far from the boundary, and 3-point forward or backward scheme is used for points near the boundary. Both schemes have the second-order accuracy in terms of Taylor expansion. Refer to [2]_ for the formulas of 3-point forward and backward difference schemes. For dense differencing when m=1 Jacobian is returned with a shape (n,), on the other hand when n=1 Jacobian is returned with a shape (m, 1). Our motivation is the following: a) It handles a case of gradient computation (m=1) in a conventional way. b) It clearly separates these two different cases. b) In all cases np.atleast_2d can be called to get 2-D Jacobian with correct dimensions. References ---------- .. [1] W. H. Press et. al. "Numerical Recipes. The Art of Scientific Computing. 3rd edition", sec. 5.7. .. [2] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. .. [3] <NAME>, "Generation of Finite Difference Formulas on Arbitrarily Spaced Grids", Mathematics of Computation 51, 1988. Examples -------- >>> import numpy as np >>> from scipy.optimize import approx_derivative >>> >>> def f(x, c1, c2): ... return np.array([x[0] * np.sin(c1 * x[1]), ... x[0] * np.cos(c2 * x[1])]) ... >>> x0 = np.array([1.0, 0.5 * np.pi]) >>> approx_derivative(f, x0, args=(1, 2)) array([[ 1., 0.], [-1., 0.]]) Bounds can be used to limit the region of function evaluation. In the example below we compute left and right derivative at point 1.0. >>> def g(x): ... return x**2 if x >= 1 else x ... >>> x0 = 1.0 >>> approx_derivative(g, x0, bounds=(-np.inf, 1.0)) array([ 1.]) >>> approx_derivative(g, x0, bounds=(1.0, np.inf)) array([ 2.]) """ if method not in ['2-point', '3-point', 'cs']: raise ValueError("Unknown method '%s'. " % method) x0 = np.atleast_1d(x0) if x0.ndim > 1: raise ValueError("`x0` must have at most 1 dimension.") lb, ub = _prepare_bounds(bounds, x0) if lb.shape != x0.shape or ub.shape != x0.shape: raise ValueError("Inconsistent shapes between bounds and `x0`.") if as_linear_operator and not (np.all(np.isinf(lb)) and np.all(np.isinf(ub))): raise ValueError("Bounds not supported when " "`as_linear_operator` is True.") def fun_wrapped(x): f = np.atleast_1d(fun(x, *args, **kwargs)) if f.ndim > 1: raise RuntimeError("`fun` return value has " "more than 1 dimension.") return f if f0 is None: f0 = fun_wrapped(x0) else: f0 = np.atleast_1d(f0) if f0.ndim > 1: raise ValueError("`f0` passed has more than 1 dimension.") if np.any((x0 < lb) | (x0 > ub)): raise ValueError("`x0` violates bound constraints.") if as_linear_operator: if rel_step is None: rel_step = relative_step[method] return _linear_operator_difference(fun_wrapped, x0, f0, rel_step, method) else: h = _compute_absolute_step(rel_step, x0, method) if method == '2-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '1-sided', lb, ub) elif method == '3-point': h, use_one_sided = _adjust_scheme_to_bounds( x0, h, 1, '2-sided', lb, ub) elif method == 'cs': use_one_sided = False if sparsity is None: return _dense_difference(fun_wrapped, x0, f0, h, use_one_sided, method) else: if not issparse(sparsity) and len(sparsity) == 2: structure, groups = sparsity else: structure = sparsity groups = group_columns(sparsity) if issparse(structure): structure = csc_matrix(structure) else: structure = np.atleast_2d(structure) groups = np.atleast_1d(groups) return _sparse_difference(fun_wrapped, x0, f0, h, use_one_sided, structure, groups, method) def _linear_operator_difference(fun, x0, f0, h, method): m = f0.size n = x0.size if method == '2-point': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return np.zeros(m) dx = h / norm(p) x = x0 + dx*p df = fun(x) - f0 return df / dx elif method == '3-point': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return np.zeros(m) dx = 2*h / norm(p) x1 = x0 - (dx/2)*p x2 = x0 + (dx/2)*p f1 = fun(x1) f2 = fun(x2) df = f2 - f1 return df / dx elif method == 'cs': def matvec(p): if np.array_equal(p, np.zeros_like(p)): return np.zeros(m) dx = h / norm(p) x = x0 + dx*p*1.j f1 = fun(x) df = f1.imag return df / dx else: raise RuntimeError("Never be here.") return LinearOperator((m, n), matvec) def _dense_difference(fun, x0, f0, h, use_one_sided, method): m = f0.size n = x0.size J_transposed = np.empty((n, m)) h_vecs = np.diag(h) for i in range(h.size): if method == '2-point': x = x0 + h_vecs[i] dx = x[i] - x0[i] # Recompute dx as exactly representable number. df = fun(x) - f0 elif method == '3-point' and use_one_sided[i]: x1 = x0 + h_vecs[i] x2 = x0 + 2 * h_vecs[i] dx = x2[i] - x0[i] f1 = fun(x1) f2 = fun(x2) df = -3.0 * f0 + 4 * f1 - f2 elif method == '3-point' and not use_one_sided[i]: x1 = x0 - h_vecs[i] x2 = x0 + h_vecs[i] dx = x2[i] - x1[i] f1 = fun(x1) f2 = fun(x2) df = f2 - f1 elif method == 'cs': f1 = fun(x0 + h_vecs[i]*1.j) df = f1.imag dx = h_vecs[i, i] else: raise RuntimeError("Never be here.") J_transposed[i] = df / dx if m == 1: J_transposed = np.ravel(J_transposed) return J_transposed.T def _sparse_difference(fun, x0, f0, h, use_one_sided, structure, groups, method): m = f0.size n = x0.size row_indices = [] col_indices = [] fractions = [] n_groups = np.max(groups) + 1 for group in range(n_groups): # Perturb variables which are in the same group simultaneously. e =

np.equal(group, groups)

numpy.equal

import numpy as np import sys import os from PIL import Image from visu.helper_functions import save_image from scipy.spatial.transform import Rotation as R from helper import re_quat import copy import torch import numpy as np import k3d class Visualizer(): def __init__(self, p_visu, writer=None): if p_visu[-1] != '/': p_visu = p_visu + '/' self.p_visu = p_visu self.writer = writer if not os.path.exists(self.p_visu): os.makedirs(self.p_visu) def plot_estimated_pose(self, tag, epoch, img, points, trans=[[0, 0, 0]], rot_mat=[[1, 0, 0], [0, 1, 0], [0, 0, 1]], cam_cx=0, cam_cy=0, cam_fx=0, cam_fy=0, store=False, jupyter=False, w=2): """ tag := tensorboard tag epoch := tensorboard epoche store := ture -> stores the image to standard path path := != None creats the path and store to it path/tag.png img:= original_image, [widht,height,RGB] points:= points of the object model [length,x,y,z] trans: [1,3] rot: [3,3] """ img_d = copy.deepcopy(img) points =

np.dot(points, rot_mat.T)

numpy.dot

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] *

np.ones_like(min_2_x_time)

numpy.ones_like

# pvtrace is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 3 of the License, or # (at your option) any later version. # # pvtrace is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see <http://www.gnu.org/licenses/>. import numpy as np from external.transformations import translation_matrix, rotation_matrix import external.transformations as tf from Trace import Photon from Geometry import Box, Cylinder, FinitePlane, transform_point, transform_direction, rotation_matrix_from_vector_alignment, norm from Materials import Spectrum def random_spherecial_vector(): # This method of calculating isotropic vectors is taken from GNU Scientific Library LOOP = True while LOOP: x = -1. + 2. * np.random.uniform() y = -1. + 2. * np.random.uniform() s = x**2 + y**2 if s <= 1.0: LOOP = False z = -1. + 2. * s a = 2 * np.sqrt(1 - s) x = a * x y = a * y return np.array([x,y,z]) class SimpleSource(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, use_random_polarisation=False): super(SimpleSource, self).__init__() self.position = position self.direction = direction self.wavelength = wavelength self.use_random_polarisation = use_random_polarisation self.throw = 0 self.source_id = "SimpleSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength # If use_polarisation is set generate a random polarisation vector of the photon if self.use_random_polarisation: # Randomise rotation angle around xy-plane, the transform from +z to the direction of the photon vec = random_spherecial_vector() vec[2] = 0. vec = norm(vec) R = rotation_matrix_from_vector_alignment(self.direction, [0,0,1]) photon.polarisation = transform_direction(vec, R) else: photon.polarisation = None photon.id = self.throw self.throw = self.throw + 1 return photon class Laser(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, polarisation=None): super(Laser, self).__init__() self.position = np.array(position) self.direction = np.array(direction) self.wavelength = wavelength assert polarisation != None, "Polarisation of the Laser is not set." self.polarisation = np.array(polarisation) self.throw = 0 self.source_id = "LaserSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength photon.polarisation = self.polarisation photon.id = self.throw self.throw = self.throw + 1 return photon class PlanarSource(object): """A box that emits photons from the top surface (normal), sampled from the spectrum.""" def __init__(self, spectrum=None, wavelength=555, direction=(0,0,1), length=0.05, width=0.05): super(PlanarSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.plane = FinitePlane(length=length, width=width) self.length = length self.width = width # direction is the direction that photons are fired out of the plane in the GLOBAL FRAME. # i.e. this is passed directly to the photon to set is's direction self.direction = direction self.throw = 0 self.source_id = "PlanarSource_" + str(id(self)) def translate(self, translation): self.plane.append_transform(tf.translation_matrix(translation)) def rotate(self, angle, axis): self.plane.append_transform(tf.rotation_matrix(angle, axis)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Create a point which is on the surface of the finite plane in it's local frame x =

np.random.uniform(0., self.length)

numpy.random.uniform

"""Routines for numerical differentiation.""" from __future__ import division import numpy as np from numpy.linalg import norm from scipy.sparse.linalg import LinearOperator from ..sparse import issparse, csc_matrix, csr_matrix, coo_matrix, find from ._group_columns import group_dense, group_sparse EPS = np.finfo(np.float64).eps def _adjust_scheme_to_bounds(x0, h, num_steps, scheme, lb, ub): """Adjust final difference scheme to the presence of bounds. Parameters ---------- x0 : ndarray, shape (n,) Point at which we wish to estimate derivative. h : ndarray, shape (n,) Desired finite difference steps. num_steps : int Number of `h` steps in one direction required to implement finite difference scheme. For example, 2 means that we need to evaluate f(x0 + 2 * h) or f(x0 - 2 * h) scheme : {'1-sided', '2-sided'} Whether steps in one or both directions are required. In other words '1-sided' applies to forward and backward schemes, '2-sided' applies to center schemes. lb : ndarray, shape (n,) Lower bounds on independent variables. ub : ndarray, shape (n,) Upper bounds on independent variables. Returns ------- h_adjusted : ndarray, shape (n,) Adjusted step sizes. Step size decreases only if a sign flip or switching to one-sided scheme doesn't allow to take a full step. use_one_sided : ndarray of bool, shape (n,) Whether to switch to one-sided scheme. Informative only for ``scheme='2-sided'``. """ if scheme == '1-sided': use_one_sided = np.ones_like(h, dtype=bool) elif scheme == '2-sided': h = np.abs(h) use_one_sided = np.zeros_like(h, dtype=bool) else: raise ValueError("`scheme` must be '1-sided' or '2-sided'.") if np.all((lb == -np.inf) & (ub == np.inf)): return h, use_one_sided h_total = h * num_steps h_adjusted = h.copy() lower_dist = x0 - lb upper_dist = ub - x0 if scheme == '1-sided': x = x0 + h_total violated = (x < lb) | (x > ub) fitting = np.abs(h_total) <= np.maximum(lower_dist, upper_dist) h_adjusted[violated & fitting] *= -1 forward = (upper_dist >= lower_dist) & ~fitting h_adjusted[forward] = upper_dist[forward] / num_steps backward = (upper_dist < lower_dist) & ~fitting h_adjusted[backward] = -lower_dist[backward] / num_steps elif scheme == '2-sided': central = (lower_dist >= h_total) & (upper_dist >= h_total) forward = (upper_dist >= lower_dist) & ~central h_adjusted[forward] = np.minimum( h[forward], 0.5 * upper_dist[forward] / num_steps) use_one_sided[forward] = True backward = (upper_dist < lower_dist) & ~central h_adjusted[backward] = -np.minimum( h[backward], 0.5 * lower_dist[backward] / num_steps) use_one_sided[backward] = True min_dist = np.minimum(upper_dist, lower_dist) / num_steps adjusted_central = (~central & (np.abs(h_adjusted) <= min_dist)) h_adjusted[adjusted_central] = min_dist[adjusted_central] use_one_sided[adjusted_central] = False return h_adjusted, use_one_sided relative_step = {"2-point": EPS**0.5, "3-point": EPS**(1/3), "cs": EPS**0.5} def _compute_absolute_step(rel_step, x0, method): if rel_step is None: rel_step = relative_step[method] sign_x0 = (x0 >= 0).astype(float) * 2 - 1 return rel_step * sign_x0 * np.maximum(1.0, np.abs(x0)) def _prepare_bounds(bounds, x0): lb, ub = [np.asarray(b, dtype=float) for b in bounds] if lb.ndim == 0: lb = np.resize(lb, x0.shape) if ub.ndim == 0: ub = np.resize(ub, x0.shape) return lb, ub def group_columns(A, order=0): """Group columns of a 2-D matrix for sparse finite differencing [1]_. Two columns are in the same group if in each row at least one of them has zero. A greedy sequential algorithm is used to construct groups. Parameters ---------- A : array_like or sparse matrix, shape (m, n) Matrix of which to group columns. order : int, iterable of int with shape (n,) or None Permutation array which defines the order of columns enumeration. If int or None, a random permutation is used with `order` used as a random seed. Default is 0, that is use a random permutation but guarantee repeatability. Returns ------- groups : ndarray of int, shape (n,) Contains values from 0 to n_groups-1, where n_groups is the number of found groups. Each value ``groups[i]`` is an index of a group to which ith column assigned. The procedure was helpful only if n_groups is significantly less than n. References ---------- .. [1] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. """ if issparse(A): A = csc_matrix(A) else: A = np.atleast_2d(A) A = (A != 0).astype(np.int32) if A.ndim != 2: raise ValueError("`A` must be 2-dimensional.") m, n = A.shape if order is None or np.isscalar(order): rng = np.random.RandomState(order) order = rng.permutation(n) else: order = np.asarray(order) if order.shape != (n,): raise ValueError("`order` has incorrect shape.") A = A[:, order] if issparse(A): groups = group_sparse(m, n, A.indices, A.indptr) else: groups = group_dense(m, n, A) groups[order] = groups.copy() return groups def approx_derivative(fun, x0, method='3-point', rel_step=None, f0=None, bounds=(-np.inf, np.inf), sparsity=None, as_linear_operator=False, args=(), kwargs={}): """Compute finite difference approximation of the derivatives of a vector-valued function. If a function maps from R^n to R^m, its derivatives form m-by-n matrix called the Jacobian, where an element (i, j) is a partial derivative of f[i] with respect to x[j]. Parameters ---------- fun : callable Function of which to estimate the derivatives. The argument x passed to this function is ndarray of shape (n,) (never a scalar even if n=1). It must return 1-D array_like of shape (m,) or a scalar. x0 : array_like of shape (n,) or float Point at which to estimate the derivatives. Float will be converted to a 1-D array. method : {'3-point', '2-point', 'cs'}, optional Finite difference method to use: - '2-point' - use the first order accuracy forward or backward difference. - '3-point' - use central difference in interior points and the second order accuracy forward or backward difference near the boundary. - 'cs' - use a complex-step finite difference scheme. This assumes that the user function is real-valued and can be analytically continued to the complex plane. Otherwise, produces bogus results. rel_step : None or array_like, optional Relative step size to use. The absolute step size is computed as ``h = rel_step * sign(x0) * max(1, abs(x0))``, possibly adjusted to fit into the bounds. For ``method='3-point'`` the sign of `h` is ignored. If None (default) then step is selected automatically, see Notes. f0 : None or array_like, optional If not None it is assumed to be equal to ``fun(x0)``, in this case the ``fun(x0)`` is not called. Default is None. bounds : tuple of array_like, optional Lower and upper bounds on independent variables. Defaults to no bounds. Each bound must match the size of `x0` or be a scalar, in the latter case the bound will be the same for all variables. Use it to limit the range of function evaluation. Bounds checking is not implemented when `as_linear_operator` is True. sparsity : {None, array_like, sparse matrix, 2-tuple}, optional Defines a sparsity structure of the Jacobian matrix. If the Jacobian matrix is known to have only few non-zero elements in each row, then it's possible to estimate its several columns by a single function evaluation [3]_. To perform such economic computations two ingredients are required: * structure : array_like or sparse matrix of shape (m, n). A zero element means that a corresponding element of the Jacobian identically equals to zero. * groups : array_like of shape (n,). A column grouping for a given sparsity structure, use `group_columns` to obtain it. A single array or a sparse matrix is interpreted as a sparsity structure, and groups are computed inside the function. A tuple is interpreted as (structure, groups). If None (default), a standard dense differencing will be used. Note, that sparse differencing makes sense only for large Jacobian matrices where each row contains few non-zero elements. as_linear_operator : bool, optional When True the function returns an `scipy.sparse.linalg.LinearOperator`. Otherwise it returns a dense array or a sparse matrix depending on `sparsity`. The linear operator provides an efficient way of computing ``J.dot(p)`` for any vector ``p`` of shape (n,), but does not allow direct access to individual elements of the matrix. By default `as_linear_operator` is False. args, kwargs : tuple and dict, optional Additional arguments passed to `fun`. Both empty by default. The calling signature is ``fun(x, *args, **kwargs)``. Returns ------- J : {ndarray, sparse matrix, LinearOperator} Finite difference approximation of the Jacobian matrix. If `as_linear_operator` is True returns a LinearOperator with shape (m, n). Otherwise it returns a dense array or sparse matrix depending on how `sparsity` is defined. If `sparsity` is None then a ndarray with shape (m, n) is returned. If `sparsity` is not None returns a csr_matrix with shape (m, n). For sparse matrices and linear operators it is always returned as a 2-D structure, for ndarrays, if m=1 it is returned as a 1-D gradient array with shape (n,). See Also -------- check_derivative : Check correctness of a function computing derivatives. Notes ----- If `rel_step` is not provided, it assigned to ``EPS**(1/s)``, where EPS is machine epsilon for float64 numbers, s=2 for '2-point' method and s=3 for '3-point' method. Such relative step approximately minimizes a sum of truncation and round-off errors, see [1]_. A finite difference scheme for '3-point' method is selected automatically. The well-known central difference scheme is used for points sufficiently far from the boundary, and 3-point forward or backward scheme is used for points near the boundary. Both schemes have the second-order accuracy in terms of Taylor expansion. Refer to [2]_ for the formulas of 3-point forward and backward difference schemes. For dense differencing when m=1 Jacobian is returned with a shape (n,), on the other hand when n=1 Jacobian is returned with a shape (m, 1). Our motivation is the following: a) It handles a case of gradient computation (m=1) in a conventional way. b) It clearly separates these two different cases. b) In all cases np.atleast_2d can be called to get 2-D Jacobian with correct dimensions. References ---------- .. [1] W. H. Press et. al. "Numerical Recipes. The Art of Scientific Computing. 3rd edition", sec. 5.7. .. [2] <NAME>, <NAME>, and <NAME>, "On the estimation of sparse Jacobian matrices", Journal of the Institute of Mathematics and its Applications, 13 (1974), pp. 117-120. .. [3] <NAME>, "Generation of Finite Difference Formulas on Arbitrarily Spaced Grids", Mathematics of Computation 51, 1988. Examples -------- >>> import numpy as np >>> from scipy.optimize import approx_derivative >>> >>> def f(x, c1, c2): ... return np.array([x[0] * np.sin(c1 * x[1]), ... x[0] * np.cos(c2 * x[1])]) ... >>> x0 = np.array([1.0, 0.5 * np.pi]) >>> approx_derivative(f, x0, args=(1, 2)) array([[ 1., 0.], [-1., 0.]]) Bounds can be used to limit the region of function evaluation. In the example below we compute left and right derivative at point 1.0. >>> def g(x): ... return x**2 if x >= 1 else x ... >>> x0 = 1.0 >>> approx_derivative(g, x0, bounds=(-np.inf, 1.0)) array([ 1.]) >>> approx_derivative(g, x0, bounds=(1.0, np.inf)) array([ 2.]) """ if method not in ['2-point', '3-point', 'cs']: raise ValueError("Unknown method '%s'. " % method) x0 = np.atleast_1d(x0) if x0.ndim > 1: raise ValueError("`x0` must have at most 1 dimension.") lb, ub = _prepare_bounds(bounds, x0) if lb.shape != x0.shape or ub.shape != x0.shape: raise ValueError("Inconsistent shapes between bounds and `x0`.") if as_linear_operator and not (np.all(np.isinf(lb)) and np.all(np.isinf(ub))): raise ValueError("Bounds not supported when " "`as_linear_operator` is True.") def fun_wrapped(x): f = np.atleast_1d(fun(x, *args, **kwargs)) if f.ndim > 1: raise RuntimeError("`fun` return value has " "more than 1 dimension.") return f if f0 is None: f0 = fun_wrapped(x0) else: f0 =

np.atleast_1d(f0)

numpy.atleast_1d

import numpy as np from defdap.quat import Quat hex_syms = Quat.symEqv("hexagonal") # subset of hexagonal symmetries that give unique orientations when the # Burgers transformation is applied unq_hex_syms = [ hex_syms[0], hex_syms[5], hex_syms[4], hex_syms[2], hex_syms[10], hex_syms[11] ] cubic_syms = Quat.symEqv("cubic") # subset of cubic symmetries that give unique orientations when the # Burgers transformation is applied unq_cub_syms = [ cubic_syms[0], cubic_syms[7], cubic_syms[9], cubic_syms[1], cubic_syms[22], cubic_syms[16], cubic_syms[12], cubic_syms[15], cubic_syms[4], cubic_syms[8], cubic_syms[21], cubic_syms[20] ] # HCP -> BCC burg_eulers =

np.array([135, 90, 354.74])

numpy.array

# coding: utf-8 # Licensed under a 3-clause BSD style license - see LICENSE.rst """ Test the Logarithmic Units and Quantities """ from __future__ import (absolute_import, unicode_literals, division, print_function) from ...extern import six from ...extern.six.moves import zip import pickle import itertools import pytest import numpy as np from numpy.testing.utils import assert_allclose from ...tests.helper import assert_quantity_allclose from ... import units as u, constants as c lu_units = [u.dex, u.mag, u.decibel] lu_subclasses = [u.DexUnit, u.MagUnit, u.DecibelUnit] lq_subclasses = [u.Dex, u.Magnitude, u.Decibel] pu_sample = (u.dimensionless_unscaled, u.m, u.g/u.s**2, u.Jy) class TestLogUnitCreation(object): def test_logarithmic_units(self): """Check logarithmic units are set up correctly.""" assert u.dB.to(u.dex) == 0.1 assert u.dex.to(u.mag) == -2.5 assert u.mag.to(u.dB) == -4 @pytest.mark.parametrize('lu_unit, lu_cls', zip(lu_units, lu_subclasses)) def test_callable_units(self, lu_unit, lu_cls): assert isinstance(lu_unit, u.UnitBase) assert callable(lu_unit) assert lu_unit._function_unit_class is lu_cls @pytest.mark.parametrize('lu_unit', lu_units) def test_equality_to_normal_unit_for_dimensionless(self, lu_unit): lu = lu_unit() assert lu == lu._default_function_unit # eg, MagUnit() == u.mag assert lu._default_function_unit == lu # and u.mag == MagUnit() @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_call_units(self, lu_unit, physical_unit): """Create a LogUnit subclass using the callable unit and physical unit, and do basic check that output is right.""" lu1 = lu_unit(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit def test_call_invalid_unit(self): with pytest.raises(TypeError): u.mag([]) with pytest.raises(ValueError): u.mag(u.mag()) @pytest.mark.parametrize('lu_cls, physical_unit', itertools.product( lu_subclasses + [u.LogUnit], pu_sample)) def test_subclass_creation(self, lu_cls, physical_unit): """Create a LogUnit subclass object for given physical unit, and do basic check that output is right.""" lu1 = lu_cls(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit lu2 = lu_cls(physical_unit, function_unit=2*lu1._default_function_unit) assert lu2.physical_unit == physical_unit assert lu2.function_unit == u.Unit(2*lu2._default_function_unit) with pytest.raises(ValueError): lu_cls(physical_unit, u.m) def test_predefined_magnitudes(): assert_quantity_allclose((-21.1*u.STmag).physical, 1.*u.erg/u.cm**2/u.s/u.AA) assert_quantity_allclose((-48.6*u.ABmag).physical, 1.*u.erg/u.cm**2/u.s/u.Hz) assert_quantity_allclose((0*u.M_bol).physical, c.L_bol0) assert_quantity_allclose((0*u.m_bol).physical, c.L_bol0/(4.*np.pi*(10.*c.pc)**2)) def test_predefined_reinitialisation(): assert u.mag('ST') == u.STmag assert u.mag('AB') == u.ABmag assert u.mag('Bol') == u.M_bol assert u.mag('bol') == u.m_bol def test_predefined_string_roundtrip(): """Ensure roundtripping; see #5015""" with u.magnitude_zero_points.enable(): assert u.Unit(u.STmag.to_string()) == u.STmag assert u.Unit(u.ABmag.to_string()) == u.ABmag assert u.Unit(u.M_bol.to_string()) == u.M_bol assert u.Unit(u.m_bol.to_string()) == u.m_bol def test_inequality(): """Check __ne__ works (regresssion for #5342).""" lu1 = u.mag(u.Jy) lu2 = u.dex(u.Jy) lu3 = u.mag(u.Jy**2) lu4 = lu3 - lu1 assert lu1 != lu2 assert lu1 != lu3 assert lu1 == lu4 class TestLogUnitStrings(object): def test_str(self): """Do some spot checks that str, repr, etc. work as expected.""" lu1 = u.mag(u.Jy) assert str(lu1) == 'mag(Jy)' assert repr(lu1) == 'Unit("mag(Jy)")' assert lu1.to_string('generic') == 'mag(Jy)' with pytest.raises(ValueError): lu1.to_string('fits') lu2 = u.dex() assert str(lu2) == 'dex' assert repr(lu2) == 'Unit("dex(1)")' assert lu2.to_string() == 'dex(1)' lu3 = u.MagUnit(u.Jy, function_unit=2*u.mag) assert str(lu3) == '2 mag(Jy)' assert repr(lu3) == 'MagUnit("Jy", unit="2 mag")' assert lu3.to_string() == '2 mag(Jy)' lu4 = u.mag(u.ct) assert lu4.to_string('generic') == 'mag(ct)' assert lu4.to_string('latex') == ('$\\mathrm{mag}$$\\mathrm{\\left( ' '\\mathrm{ct} \\right)}$') assert lu4._repr_latex_() == lu4.to_string('latex') class TestLogUnitConversion(object): @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_physical_unit_conversion(self, lu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to their non-log counterparts.""" lu1 = lu_unit(physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(physical_unit, 0.) == 1. assert physical_unit.is_equivalent(lu1) assert physical_unit.to(lu1, 1.) == 0. pu = u.Unit(8.*physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(pu, 0.) == 0.125 assert pu.is_equivalent(lu1) assert_allclose(pu.to(lu1, 0.125), 0., atol=1.e-15) # Check we round-trip. value = np.linspace(0., 10., 6) assert_allclose(pu.to(lu1, lu1.to(pu, value)), value, atol=1.e-15) # And that we're not just returning True all the time. pu2 = u.g assert not lu1.is_equivalent(pu2) with pytest.raises(u.UnitsError): lu1.to(pu2) assert not pu2.is_equivalent(lu1) with pytest.raises(u.UnitsError): pu2.to(lu1) @pytest.mark.parametrize('lu_unit', lu_units) def test_container_unit_conversion(self, lu_unit): """Check that conversion to logarithmic units (u.mag, u.dB, u.dex) is only possible when the physical unit is dimensionless.""" values = np.linspace(0., 10., 6) lu1 = lu_unit(u.dimensionless_unscaled) assert lu1.is_equivalent(lu1.function_unit) assert_allclose(lu1.to(lu1.function_unit, values), values) lu2 = lu_unit(u.Jy) assert not lu2.is_equivalent(lu2.function_unit) with pytest.raises(u.UnitsError): lu2.to(lu2.function_unit, values) @pytest.mark.parametrize( 'flu_unit, tlu_unit, physical_unit', itertools.product(lu_units, lu_units, pu_sample)) def test_subclass_conversion(self, flu_unit, tlu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to each other if they correspond to equivalent physical units.""" values = np.linspace(0., 10., 6) flu = flu_unit(physical_unit) tlu = tlu_unit(physical_unit) assert flu.is_equivalent(tlu) assert_allclose(flu.to(tlu), flu.function_unit.to(tlu.function_unit)) assert_allclose(flu.to(tlu, values), values * flu.function_unit.to(tlu.function_unit)) tlu2 = tlu_unit(u.Unit(100.*physical_unit)) assert flu.is_equivalent(tlu2) # Check that we round-trip. assert_allclose(flu.to(tlu2, tlu2.to(flu, values)), values, atol=1.e-15) tlu3 = tlu_unit(physical_unit.to_system(u.si)[0]) assert flu.is_equivalent(tlu3) assert_allclose(flu.to(tlu3, tlu3.to(flu, values)), values, atol=1.e-15) tlu4 = tlu_unit(u.g) assert not flu.is_equivalent(tlu4) with pytest.raises(u.UnitsError): flu.to(tlu4, values) def test_unit_decomposition(self): lu = u.mag(u.Jy) assert lu.decompose() == u.mag(u.Jy.decompose()) assert lu.decompose().physical_unit.bases == [u.kg, u.s] assert lu.si == u.mag(u.Jy.si) assert lu.si.physical_unit.bases == [u.kg, u.s] assert lu.cgs == u.mag(u.Jy.cgs) assert lu.cgs.physical_unit.bases == [u.g, u.s] def test_unit_multiple_possible_equivalencies(self): lu = u.mag(u.Jy) assert lu.is_equivalent(pu_sample) class TestLogUnitArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other units is only possible when the physical unit is dimensionless, and that this turns the unit into a normal one.""" lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 * u.m with pytest.raises(u.UnitsError): u.m * lu1 with pytest.raises(u.UnitsError): lu1 / lu1 for unit in (u.dimensionless_unscaled, u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lu1 / unit lu2 = u.mag(u.dimensionless_unscaled) with pytest.raises(u.UnitsError): lu2 * lu1 with pytest.raises(u.UnitsError): lu2 / lu1 # But dimensionless_unscaled can be cancelled. assert lu2 / lu2 == u.dimensionless_unscaled # With dimensionless, normal units are OK, but we return a plain unit. tf = lu2 * u.m tr = u.m * lu2 for t in (tf, tr): assert not isinstance(t, type(lu2)) assert t == lu2.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lu2.physical_unit) # Now we essentially have a LogUnit with a prefactor of 100, # so should be equivalent again. t = tf / u.cm with u.set_enabled_equivalencies(u.logarithmic()): assert t.is_equivalent(lu2.function_unit) assert_allclose(t.to(u.dimensionless_unscaled, np.arange(3.)/100.), lu2.to(lu2.physical_unit, np.arange(3.))) # If we effectively remove lu1, a normal unit should be returned. t2 = tf / lu2 assert not isinstance(t2, type(lu2)) assert t2 == u.m t3 = tf / lu2.function_unit assert not isinstance(t3, type(lu2)) assert t3 == u.m # For completeness, also ensure non-sensical operations fail with pytest.raises(TypeError): lu1 * object() with pytest.raises(TypeError): slice(None) * lu1 with pytest.raises(TypeError): lu1 / [] with pytest.raises(TypeError): 1 / lu1 @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogUnits to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (such as mag**2) is incompatible.""" lu1 = u.mag(u.Jy) if power == 0: assert lu1 ** power == u.dimensionless_unscaled elif power == 1: assert lu1 ** power == lu1 else: with pytest.raises(u.UnitsError): lu1 ** power # With dimensionless, though, it works, but returns a normal unit. lu2 = u.mag(u.dimensionless_unscaled) t = lu2**power if power == 0: assert t == u.dimensionless_unscaled elif power == 1: assert t == lu2 else: assert not isinstance(t, type(lu2)) assert t == lu2.function_unit**power # also check we roundtrip t2 = t**(1./power) assert t2 == lu2.function_unit with u.set_enabled_equivalencies(u.logarithmic()): assert_allclose(t2.to(u.dimensionless_unscaled, np.arange(3.)), lu2.to(lu2.physical_unit, np.arange(3.))) @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 + other with pytest.raises(u.UnitsError): lu1 - other with pytest.raises(u.UnitsError): other - lu1 def test_addition_subtraction_to_non_units_fails(self): lu1 = u.mag(u.Jy) with pytest.raises(TypeError): lu1 + 1. with pytest.raises(TypeError): lu1 - [1., 2., 3.] @pytest.mark.parametrize( 'other', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2*u.mag), u.MagUnit('', 2.*u.mag))) def test_addition_subtraction(self, other): """Check physical units are changed appropriately""" lu1 = u.mag(u.Jy) other_pu = getattr(other, 'physical_unit', u.dimensionless_unscaled) lu_sf = lu1 + other assert lu_sf.is_equivalent(lu1.physical_unit * other_pu) lu_sr = other + lu1 assert lu_sr.is_equivalent(lu1.physical_unit * other_pu) lu_df = lu1 - other assert lu_df.is_equivalent(lu1.physical_unit / other_pu) lu_dr = other - lu1 assert lu_dr.is_equivalent(other_pu / lu1.physical_unit) def test_complicated_addition_subtraction(self): """for fun, a more complicated example of addition and subtraction""" dm0 = u.Unit('DM', 1./(4.*np.pi*(10.*u.pc)**2)) lu_dm = u.mag(dm0) lu_absST = u.STmag - lu_dm assert lu_absST.is_equivalent(u.erg/u.s/u.AA) def test_neg_pos(self): lu1 = u.mag(u.Jy) neg_lu = -lu1 assert neg_lu != lu1 assert neg_lu.physical_unit == u.Jy**-1 assert -neg_lu == lu1 pos_lu = +lu1 assert pos_lu is not lu1 assert pos_lu == lu1 def test_pickle(): lu1 = u.dex(u.cm/u.s**2) s = pickle.dumps(lu1) lu2 = pickle.loads(s) assert lu1 == lu2 def test_hashable(): lu1 = u.dB(u.mW) lu2 = u.dB(u.m) lu3 = u.dB(u.mW) assert hash(lu1) != hash(lu2) assert hash(lu1) == hash(lu3) luset = {lu1, lu2, lu3} assert len(luset) == 2 class TestLogQuantityCreation(object): @pytest.mark.parametrize('lq, lu', zip(lq_subclasses + [u.LogQuantity], lu_subclasses + [u.LogUnit])) def test_logarithmic_quantities(self, lq, lu): """Check logarithmic quantities are all set up correctly""" assert lq._unit_class == lu assert type(lu()._quantity_class(1.)) is lq @pytest.mark.parametrize('lq_cls, physical_unit', itertools.product(lq_subclasses, pu_sample)) def test_subclass_creation(self, lq_cls, physical_unit): """Create LogQuantity subclass objects for some physical units, and basic check on transformations""" value = np.arange(1., 10.) log_q = lq_cls(value * physical_unit) assert log_q.unit.physical_unit == physical_unit assert log_q.unit.function_unit == log_q.unit._default_function_unit assert_allclose(log_q.physical.value, value) with pytest.raises(ValueError): lq_cls(value, physical_unit) @pytest.mark.parametrize( 'unit', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2*u.mag), u.MagUnit('', 2.*u.mag), u.MagUnit(u.Jy, -1*u.mag), u.MagUnit(u.m, -2.*u.mag))) def test_different_units(self, unit): q = u.Magnitude(1.23, unit) assert q.unit.function_unit == getattr(unit, 'function_unit', unit) assert q.unit.physical_unit is getattr(unit, 'physical_unit', u.dimensionless_unscaled) @pytest.mark.parametrize('value, unit', ( (1.*u.mag(u.Jy), None), (1.*u.dex(u.Jy), None), (1.*u.mag(u.W/u.m**2/u.Hz), u.mag(u.Jy)), (1.*u.dex(u.W/u.m**2/u.Hz), u.mag(u.Jy)))) def test_function_values(self, value, unit): lq = u.Magnitude(value, unit) assert lq == value assert lq.unit.function_unit == u.mag assert lq.unit.physical_unit == getattr(unit, 'physical_unit', value.unit.physical_unit) @pytest.mark.parametrize( 'unit', (u.mag(), u.mag(u.Jy), u.mag(u.m), u.MagUnit('', 2.*u.mag), u.MagUnit(u.Jy, -1*u.mag), u.MagUnit(u.m, -2.*u.mag))) def test_indirect_creation(self, unit): q1 = 2.5 * unit assert isinstance(q1, u.Magnitude) assert q1.value == 2.5 assert q1.unit == unit pv = 100. * unit.physical_unit q2 = unit * pv assert q2.unit == unit assert q2.unit.physical_unit == pv.unit assert q2.to_value(unit.physical_unit) == 100. assert (q2._function_view / u.mag).to_value(1) == -5. q3 = unit / 0.4 assert q3 == q1 def test_from_view(self): # Cannot view a physical quantity as a function quantity, since the # values would change. q = [100., 1000.] * u.cm/u.s**2 with pytest.raises(TypeError): q.view(u.Dex) # But fine if we have the right magnitude. q = [2., 3.] * u.dex lq = q.view(u.Dex) assert isinstance(lq, u.Dex) assert lq.unit.physical_unit == u.dimensionless_unscaled assert np.all(q == lq) def test_using_quantity_class(self): """Check that we can use Quantity if we have subok=True""" # following issue #5851 lu = u.dex(u.AA) with pytest.raises(u.UnitTypeError): u.Quantity(1., lu) q = u.Quantity(1., lu, subok=True) assert type(q) is lu._quantity_class def test_conversion_to_and_from_physical_quantities(): """Ensures we can convert from regular quantities.""" mst = [10., 12., 14.] * u.STmag flux_lambda = mst.physical mst_roundtrip = flux_lambda.to(u.STmag) # check we return a logquantity; see #5178. assert isinstance(mst_roundtrip, u.Magnitude) assert mst_roundtrip.unit == mst.unit assert_allclose(mst_roundtrip.value, mst.value) wave = [4956.8, 4959.55, 4962.3] * u.AA flux_nu = mst.to(u.Jy, equivalencies=u.spectral_density(wave)) mst_roundtrip2 = flux_nu.to(u.STmag, u.spectral_density(wave)) assert isinstance(mst_roundtrip2, u.Magnitude) assert mst_roundtrip2.unit == mst.unit assert_allclose(mst_roundtrip2.value, mst.value) def test_quantity_decomposition(): lq = 10.*u.mag(u.Jy) assert lq.decompose() == lq assert lq.decompose().unit.physical_unit.bases == [u.kg, u.s] assert lq.si == lq assert lq.si.unit.physical_unit.bases == [u.kg, u.s] assert lq.cgs == lq assert lq.cgs.unit.physical_unit.bases == [u.g, u.s] class TestLogQuantityViews(object): def setup(self): self.lq = u.Magnitude(np.arange(10.) * u.Jy) self.lq2 = u.Magnitude(np.arange(5.)) def test_value_view(self): lq_value = self.lq.value assert type(lq_value) is np.ndarray lq_value[2] = -1. assert np.all(self.lq.value == lq_value) def test_function_view(self): lq_fv = self.lq._function_view assert type(lq_fv) is u.Quantity assert lq_fv.unit is self.lq.unit.function_unit lq_fv[3] = -2. * lq_fv.unit assert np.all(self.lq.value == lq_fv.value) def test_quantity_view(self): # Cannot view as Quantity, since the unit cannot be represented. with pytest.raises(TypeError): self.lq.view(u.Quantity) # But a dimensionless one is fine. q2 = self.lq2.view(u.Quantity) assert q2.unit is u.mag assert np.all(q2.value == self.lq2.value) lq3 = q2.view(u.Magnitude) assert type(lq3.unit) is u.MagUnit assert lq3.unit.physical_unit == u.dimensionless_unscaled assert np.all(lq3 == self.lq2) class TestLogQuantitySlicing(object): def test_item_get_and_set(self): lq1 = u.Magnitude(np.arange(1., 11.)*u.Jy) assert lq1[9] == u.Magnitude(10.*u.Jy) lq1[2] = 100.*u.Jy assert lq1[2] == u.Magnitude(100.*u.Jy) with pytest.raises(u.UnitsError): lq1[2] = 100.*u.m with pytest.raises(u.UnitsError): lq1[2] = 100.*u.mag with pytest.raises(u.UnitsError): lq1[2] = u.Magnitude(100.*u.m) assert lq1[2] == u.Magnitude(100.*u.Jy) def test_slice_get_and_set(self): lq1 = u.Magnitude(np.arange(1., 10.)*u.Jy) lq1[2:4] = 100.*u.Jy assert np.all(lq1[2:4] == u.Magnitude(100.*u.Jy)) with pytest.raises(u.UnitsError): lq1[2:4] = 100.*u.m with pytest.raises(u.UnitsError): lq1[2:4] = 100.*u.mag with pytest.raises(u.UnitsError): lq1[2:4] = u.Magnitude(100.*u.m) assert np.all(lq1[2] == u.Magnitude(100.*u.Jy)) class TestLogQuantityArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other quantities is only possible when the physical unit is dimensionless, and that this turns the result into a normal quantity.""" lq = u.Magnitude(np.arange(1., 11.)*u.Jy) with pytest.raises(u.UnitsError): lq * (1.*u.m) with pytest.raises(u.UnitsError): (1.*u.m) * lq with pytest.raises(u.UnitsError): lq / lq for unit in (u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lq / unit lq2 = u.Magnitude(np.arange(1, 11.)) with pytest.raises(u.UnitsError): lq2 * lq with pytest.raises(u.UnitsError): lq2 / lq with pytest.raises(u.UnitsError): lq / lq2 # but dimensionless_unscaled can be cancelled r = lq2 / u.Magnitude(2.) assert r.unit == u.dimensionless_unscaled assert np.all(r.value == lq2.value/2.) # with dimensionless, normal units OK, but return normal quantities tf = lq2 * u.m tr = u.m * lq2 for t in (tf, tr): assert not isinstance(t, type(lq2)) assert t.unit == lq2.unit.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lq2.unit.physical_unit) t = tf / (50.*u.cm) # now we essentially have the same quantity but with a prefactor of 2 assert t.unit.is_equivalent(lq2.unit.function_unit) assert_allclose(t.to(lq2.unit.function_unit), lq2._function_view*2) @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogQuantities to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (say, mag**2) is incompatible.""" lq = u.Magnitude(np.arange(1., 4.)*u.Jy) if power == 0: assert np.all(lq ** power == 1.) elif power == 1: assert np.all(lq ** power == lq) else: with pytest.raises(u.UnitsError): lq ** power # with dimensionless, it works, but falls back to normal quantity # (except for power=1) lq2 = u.Magnitude(np.arange(10.)) t = lq2**power if power == 0: assert t.unit is u.dimensionless_unscaled assert np.all(t.value == 1.) elif power == 1: assert np.all(t == lq2) else: assert not isinstance(t, type(lq2)) assert t.unit == lq2.unit.function_unit ** power with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(u.dimensionless_unscaled) def test_error_on_lq_as_power(self): lq = u.Magnitude(np.arange(1., 4.)*u.Jy) with pytest.raises(TypeError): lq ** lq @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lq = u.Magnitude(np.arange(1., 10.)*u.Jy) q = 1.23 * other with pytest.raises(u.UnitsError): lq + q with pytest.raises(u.UnitsError): lq - q with pytest.raises(u.UnitsError): q - lq @pytest.mark.parametrize( 'other', (1.23 * u.mag, 2.34 * u.mag(), u.Magnitude(3.45 * u.Jy), u.Magnitude(4.56 * u.m), 5.67 * u.Unit(2*u.mag), u.Magnitude(6.78, 2.*u.mag))) def test_addition_subtraction(self, other): """Check that addition/subtraction with quantities with magnitude or MagUnit units works, and that it changes the physical units appropriately.""" lq = u.Magnitude(np.arange(1., 10.)*u.Jy) other_physical = other.to(getattr(other.unit, 'physical_unit', u.dimensionless_unscaled), equivalencies=u.logarithmic()) lq_sf = lq + other assert_allclose(lq_sf.physical, lq.physical * other_physical) lq_sr = other + lq assert_allclose(lq_sr.physical, lq.physical * other_physical) lq_df = lq - other assert_allclose(lq_df.physical, lq.physical / other_physical) lq_dr = other - lq assert_allclose(lq_dr.physical, other_physical / lq.physical) @pytest.mark.parametrize('other', pu_sample) def test_inplace_addition_subtraction_unit_checks(self, other): lu1 = u.mag(u.Jy) lq1 = u.Magnitude(np.arange(1., 10.), lu1) with pytest.raises(u.UnitsError): lq1 += other assert np.all(lq1.value == np.arange(1., 10.)) assert lq1.unit == lu1 with pytest.raises(u.UnitsError): lq1 -= other assert np.all(lq1.value == np.arange(1., 10.)) assert lq1.unit == lu1 @pytest.mark.parametrize( 'other', (1.23 * u.mag, 2.34 * u.mag(), u.Magnitude(3.45 * u.Jy), u.Magnitude(4.56 * u.m), 5.67 * u.Unit(2*u.mag), u.Magnitude(6.78, 2.*u.mag))) def test_inplace_addition_subtraction(self, other): """Check that inplace addition/subtraction with quantities with magnitude or MagUnit units works, and that it changes the physical units appropriately.""" lq = u.Magnitude(np.arange(1., 10.)*u.Jy) other_physical = other.to(getattr(other.unit, 'physical_unit', u.dimensionless_unscaled), equivalencies=u.logarithmic()) lq_sf = lq.copy() lq_sf += other assert_allclose(lq_sf.physical, lq.physical * other_physical) lq_df = lq.copy() lq_df -= other

assert_allclose(lq_df.physical, lq.physical / other_physical)

numpy.testing.utils.assert_allclose

""" YTArray class. """ from __future__ import print_function #----------------------------------------------------------------------------- # Copyright (c) 2013, yt Development Team. # # Distributed under the terms of the Modified BSD License. # # The full license is in the file COPYING.txt, distributed with this software. #----------------------------------------------------------------------------- import copy import numpy as np from distutils.version import LooseVersion from functools import wraps from numpy import \ add, subtract, multiply, divide, logaddexp, logaddexp2, true_divide, \ floor_divide, negative, power, remainder, mod, absolute, rint, \ sign, conj, exp, exp2, log, log2, log10, expm1, log1p, sqrt, square, \ reciprocal, sin, cos, tan, arcsin, arccos, arctan, arctan2, \ hypot, sinh, cosh, tanh, arcsinh, arccosh, arctanh, deg2rad, rad2deg, \ bitwise_and, bitwise_or, bitwise_xor, invert, left_shift, right_shift, \ greater, greater_equal, less, less_equal, not_equal, equal, logical_and, \ logical_or, logical_xor, logical_not, maximum, minimum, fmax, fmin, \ isreal, iscomplex, isfinite, isinf, isnan, signbit, copysign, nextafter, \ modf, ldexp, frexp, fmod, floor, ceil, trunc, fabs, spacing try: # numpy 1.13 or newer from numpy import positive, divmod as divmod_, isnat, heaviside except ImportError: positive, divmod_, isnat, heaviside = (None,)*4 from yt.units.unit_object import Unit, UnitParseError from yt.units.unit_registry import UnitRegistry from yt.units.dimensions import \ angle, \ current_mks, \ dimensionless, \ em_dimensions from yt.utilities.exceptions import \ YTUnitOperationError, YTUnitConversionError, \ YTUfuncUnitError, YTIterableUnitCoercionError, \ YTInvalidUnitEquivalence, YTEquivalentDimsError from yt.utilities.lru_cache import lru_cache from numbers import Number as numeric_type from yt.utilities.on_demand_imports import _astropy from sympy import Rational from yt.units.unit_lookup_table import \ default_unit_symbol_lut from yt.units.equivalencies import equivalence_registry from yt.utilities.logger import ytLogger as mylog from .pint_conversions import convert_pint_units NULL_UNIT = Unit() POWER_SIGN_MAPPING = {multiply: 1, divide: -1} # redefine this here to avoid a circular import from yt.funcs def iterable(obj): try: len(obj) except: return False return True def return_arr(func): @wraps(func) def wrapped(*args, **kwargs): ret, units = func(*args, **kwargs) if ret.shape == (): return YTQuantity(ret, units) else: # This could be a subclass, so don't call YTArray directly. return type(args[0])(ret, units) return wrapped @lru_cache(maxsize=128, typed=False) def sqrt_unit(unit): return unit**0.5 @lru_cache(maxsize=128, typed=False) def multiply_units(unit1, unit2): return unit1 * unit2 def preserve_units(unit1, unit2=None): return unit1 @lru_cache(maxsize=128, typed=False) def power_unit(unit, power): return unit**power @lru_cache(maxsize=128, typed=False) def square_unit(unit): return unit*unit @lru_cache(maxsize=128, typed=False) def divide_units(unit1, unit2): return unit1/unit2 @lru_cache(maxsize=128, typed=False) def reciprocal_unit(unit): return unit**-1 def passthrough_unit(unit, unit2=None): return unit def return_without_unit(unit, unit2=None): return None def arctan2_unit(unit1, unit2): return NULL_UNIT def comparison_unit(unit1, unit2=None): return None def invert_units(unit): raise TypeError( "Bit-twiddling operators are not defined for YTArray instances") def bitop_units(unit1, unit2): raise TypeError( "Bit-twiddling operators are not defined for YTArray instances") def get_inp_u_unary(ufunc, inputs, out_arr=None): inp = inputs[0] u = getattr(inp, 'units', None) if u is None: u = NULL_UNIT if u.dimensions is angle and ufunc in trigonometric_operators: inp = inp.in_units('radian').v if out_arr is not None: out_arr = ufunc(inp).view(np.ndarray) return out_arr, inp, u def get_inp_u_binary(ufunc, inputs): inp1 = coerce_iterable_units(inputs[0]) inp2 = coerce_iterable_units(inputs[1]) unit1 = getattr(inp1, 'units', None) unit2 = getattr(inp2, 'units', None) ret_class = get_binary_op_return_class(type(inp1), type(inp2)) if unit1 is None: unit1 = Unit(registry=getattr(unit2, 'registry', None)) if unit2 is None and ufunc is not power: unit2 = Unit(registry=getattr(unit1, 'registry', None)) elif ufunc is power: unit2 = inp2 if isinstance(unit2, np.ndarray): if isinstance(unit2, YTArray): if unit2.units.is_dimensionless: pass else: raise YTUnitOperationError(ufunc, unit1, unit2) unit2 = 1.0 return (inp1, inp2), (unit1, unit2), ret_class def handle_preserve_units(inps, units, ufunc, ret_class): if units[0] != units[1]: any_nonzero = [np.any(inps[0]), np.any(inps[1])] if any_nonzero[0] == np.bool_(False): units = (units[1], units[1]) elif any_nonzero[1] == np.bool_(False): units = (units[0], units[0]) else: if not units[0].same_dimensions_as(units[1]): raise YTUnitOperationError(ufunc, *units) inps = (inps[0], ret_class(inps[1]).to( ret_class(inps[0]).units)) return inps, units def handle_comparison_units(inps, units, ufunc, ret_class, raise_error=False): if units[0] != units[1]: u1d = units[0].is_dimensionless u2d = units[1].is_dimensionless any_nonzero = [np.any(inps[0]), np.any(inps[1])] if any_nonzero[0] == np.bool_(False): units = (units[1], units[1]) elif any_nonzero[1] == np.bool_(False): units = (units[0], units[0]) elif not any([u1d, u2d]): if not units[0].same_dimensions_as(units[1]): raise YTUnitOperationError(ufunc, *units) else: if raise_error: raise YTUfuncUnitError(ufunc, *units) inps = (inps[0], ret_class(inps[1]).to( ret_class(inps[0]).units)) return inps, units def handle_multiply_divide_units(unit, units, out, out_arr): if unit.is_dimensionless and unit.base_value != 1.0: if not units[0].is_dimensionless: if units[0].dimensions == units[1].dimensions: out_arr = np.multiply(out_arr.view(np.ndarray), unit.base_value, out=out) unit = Unit(registry=unit.registry) return out, out_arr, unit def coerce_iterable_units(input_object): if isinstance(input_object, np.ndarray): return input_object if iterable(input_object): if any([isinstance(o, YTArray) for o in input_object]): ff = getattr(input_object[0], 'units', NULL_UNIT, ) if any([ff != getattr(_, 'units', NULL_UNIT) for _ in input_object]): raise YTIterableUnitCoercionError(input_object) # This will create a copy of the data in the iterable. return YTArray(input_object) return input_object else: return input_object def sanitize_units_mul(this_object, other_object): inp = coerce_iterable_units(this_object) ret = coerce_iterable_units(other_object) # If the other object is a YTArray and has the same dimensions as the object # under consideration, convert so we don't mix units with the same # dimensions. if isinstance(ret, YTArray): if inp.units.same_dimensions_as(ret.units): ret.in_units(inp.units) return ret def sanitize_units_add(this_object, other_object, op_string): inp = coerce_iterable_units(this_object) ret = coerce_iterable_units(other_object) # Make sure the other object is a YTArray before we use the `units` # attribute. if isinstance(ret, YTArray): if not inp.units.same_dimensions_as(ret.units): # handle special case of adding or subtracting with zero or # array filled with zero if not np.any(other_object): return ret.view(np.ndarray) elif not np.any(this_object): return ret raise YTUnitOperationError(op_string, inp.units, ret.units) ret = ret.in_units(inp.units) else: # If the other object is not a YTArray, then one of the arrays must be # dimensionless or filled with zeros if not inp.units.is_dimensionless and np.any(ret): raise YTUnitOperationError(op_string, inp.units, dimensionless) return ret def validate_comparison_units(this, other, op_string): # Check that other is a YTArray. if hasattr(other, 'units'): if this.units.expr is other.units.expr: if this.units.base_value == other.units.base_value: return other if not this.units.same_dimensions_as(other.units): raise YTUnitOperationError(op_string, this.units, other.units) return other.in_units(this.units) return other @lru_cache(maxsize=128, typed=False) def _unit_repr_check_same(my_units, other_units): """ Takes a Unit object, or string of known unit symbol, and check that it is compatible with this quantity. Returns Unit object. """ # let Unit() handle units arg if it's not already a Unit obj. if not isinstance(other_units, Unit): other_units = Unit(other_units, registry=my_units.registry) equiv_dims = em_dimensions.get(my_units.dimensions, None) if equiv_dims == other_units.dimensions: if current_mks in equiv_dims.free_symbols: base = "SI" else: base = "CGS" raise YTEquivalentDimsError(my_units, other_units, base) if not my_units.same_dimensions_as(other_units): raise YTUnitConversionError( my_units, my_units.dimensions, other_units, other_units.dimensions) return other_units unary_operators = ( negative, absolute, rint, sign, conj, exp, exp2, log, log2, log10, expm1, log1p, sqrt, square, reciprocal, sin, cos, tan, arcsin, arccos, arctan, sinh, cosh, tanh, arcsinh, arccosh, arctanh, deg2rad, rad2deg, invert, logical_not, isreal, iscomplex, isfinite, isinf, isnan, signbit, floor, ceil, trunc, modf, frexp, fabs, spacing, positive, isnat, ) binary_operators = ( add, subtract, multiply, divide, logaddexp, logaddexp2, true_divide, power, remainder, mod, arctan2, hypot, bitwise_and, bitwise_or, bitwise_xor, left_shift, right_shift, greater, greater_equal, less, less_equal, not_equal, equal, logical_and, logical_or, logical_xor, maximum, minimum, fmax, fmin, copysign, nextafter, ldexp, fmod, divmod_, heaviside ) trigonometric_operators = ( sin, cos, tan, ) class YTArray(np.ndarray): """ An ndarray subclass that attaches a symbolic unit object to the array data. Parameters ---------- input_array : :obj:`!iterable` A tuple, list, or array to attach units to input_units : String unit specification, unit symbol object, or astropy units The units of the array. Powers must be specified using python syntax (cm**3, not cm^3). registry : ~yt.units.unit_registry.UnitRegistry The registry to create units from. If input_units is already associated with a unit registry and this is specified, this will be used instead of the registry associated with the unit object. dtype : data-type The dtype of the array data. Defaults to the dtype of the input data, or, if none is found, uses np.float64 bypass_validation : boolean If True, all input validation is skipped. Using this option may produce corrupted, invalid units or array data, but can lead to significant speedups in the input validation logic adds significant overhead. If set, input_units *must* be a valid unit object. Defaults to False. Examples -------- >>> from yt import YTArray >>> a = YTArray([1, 2, 3], 'cm') >>> b = YTArray([4, 5, 6], 'm') >>> a + b YTArray([ 401., 502., 603.]) cm >>> b + a YTArray([ 4.01, 5.02, 6.03]) m NumPy ufuncs will pass through units where appropriate. >>> import numpy as np >>> a = YTArray(np.arange(8) - 4, 'g/cm**3') >>> np.abs(a) YTArray([4, 3, 2, 1, 0, 1, 2, 3]) g/cm**3 and strip them when it would be annoying to deal with them. >>> np.log10(a) array([ -inf, 0. , 0.30103 , 0.47712125, 0.60205999, 0.69897 , 0.77815125, 0.84509804]) YTArray is tightly integrated with yt datasets: >>> import yt >>> ds = yt.load('IsolatedGalaxy/galaxy0030/galaxy0030') >>> a = ds.arr(np.ones(5), 'code_length') >>> a.in_cgs() YTArray([ 3.08600000e+24, 3.08600000e+24, 3.08600000e+24, 3.08600000e+24, 3.08600000e+24]) cm This is equivalent to: >>> b = YTArray(np.ones(5), 'code_length', registry=ds.unit_registry) >>> np.all(a == b) True """ _ufunc_registry = { add: preserve_units, subtract: preserve_units, multiply: multiply_units, divide: divide_units, logaddexp: return_without_unit, logaddexp2: return_without_unit, true_divide: divide_units, floor_divide: divide_units, negative: passthrough_unit, power: power_unit, remainder: preserve_units, mod: preserve_units, fmod: preserve_units, absolute: passthrough_unit, fabs: passthrough_unit, rint: return_without_unit, sign: return_without_unit, conj: passthrough_unit, exp: return_without_unit, exp2: return_without_unit, log: return_without_unit, log2: return_without_unit, log10: return_without_unit, expm1: return_without_unit, log1p: return_without_unit, sqrt: sqrt_unit, square: square_unit, reciprocal: reciprocal_unit, sin: return_without_unit, cos: return_without_unit, tan: return_without_unit, sinh: return_without_unit, cosh: return_without_unit, tanh: return_without_unit, arcsin: return_without_unit, arccos: return_without_unit, arctan: return_without_unit, arctan2: arctan2_unit, arcsinh: return_without_unit, arccosh: return_without_unit, arctanh: return_without_unit, hypot: preserve_units, deg2rad: return_without_unit, rad2deg: return_without_unit, bitwise_and: bitop_units, bitwise_or: bitop_units, bitwise_xor: bitop_units, invert: invert_units, left_shift: bitop_units, right_shift: bitop_units, greater: comparison_unit, greater_equal: comparison_unit, less: comparison_unit, less_equal: comparison_unit, not_equal: comparison_unit, equal: comparison_unit, logical_and: comparison_unit, logical_or: comparison_unit, logical_xor: comparison_unit, logical_not: return_without_unit, maximum: preserve_units, minimum: preserve_units, fmax: preserve_units, fmin: preserve_units, isreal: return_without_unit, iscomplex: return_without_unit, isfinite: return_without_unit, isinf: return_without_unit, isnan: return_without_unit, signbit: return_without_unit, copysign: passthrough_unit, nextafter: preserve_units, modf: passthrough_unit, ldexp: bitop_units, frexp: return_without_unit, floor: passthrough_unit, ceil: passthrough_unit, trunc: passthrough_unit, spacing: passthrough_unit, positive: passthrough_unit, divmod_: passthrough_unit, isnat: return_without_unit, heaviside: preserve_units, } __array_priority__ = 2.0 def __new__(cls, input_array, input_units=None, registry=None, dtype=None, bypass_validation=False): if dtype is None: dtype = getattr(input_array, 'dtype', np.float64) if bypass_validation is True: obj = np.asarray(input_array, dtype=dtype).view(cls) obj.units = input_units if registry is not None: obj.units.registry = registry return obj if input_array is NotImplemented: return input_array.view(cls) if registry is None and isinstance(input_units, (str, bytes)): if input_units.startswith('code_'): raise UnitParseError( "Code units used without referring to a dataset. \n" "Perhaps you meant to do something like this instead: \n" "ds.arr(%s, \"%s\")" % (input_array, input_units) ) if isinstance(input_array, YTArray): ret = input_array.view(cls) if input_units is None: if registry is None: ret.units = input_array.units else: units = Unit(str(input_array.units), registry=registry) ret.units = units elif isinstance(input_units, Unit): ret.units = input_units else: ret.units = Unit(input_units, registry=registry) return ret elif isinstance(input_array, np.ndarray): pass elif iterable(input_array) and input_array: if isinstance(input_array[0], YTArray): return YTArray(np.array(input_array, dtype=dtype), input_array[0].units, registry=registry) # Input array is an already formed ndarray instance # We first cast to be our class type obj = np.asarray(input_array, dtype=dtype).view(cls) # Check units type if input_units is None: # Nothing provided. Make dimensionless... units = Unit() elif isinstance(input_units, Unit): if registry and registry is not input_units.registry: units = Unit(str(input_units), registry=registry) else: units = input_units else: # units kwarg set, but it's not a Unit object. # don't handle all the cases here, let the Unit class handle if # it's a str. units = Unit(input_units, registry=registry) # Attach the units obj.units = units return obj def __repr__(self): """ """ return super(YTArray, self).__repr__()+' '+self.units.__repr__() def __str__(self): """ """ return str(self.view(np.ndarray)) + ' ' + str(self.units) # # Start unit conversion methods # def convert_to_units(self, units): """ Convert the array and units to the given units. Parameters ---------- units : Unit object or str The units you want to convert to. """ new_units = _unit_repr_check_same(self.units, units) (conversion_factor, offset) = self.units.get_conversion_factor(new_units) self.units = new_units values = self.d values *= conversion_factor if offset: np.subtract(self, offset*self.uq, self) return self def convert_to_base(self, unit_system="cgs"): """ Convert the array and units to the equivalent base units in the specified unit system. Parameters ---------- unit_system : string, optional The unit system to be used in the conversion. If not specified, the default base units of cgs are used. Examples -------- >>> E = YTQuantity(2.5, "erg/s") >>> E.convert_to_base(unit_system="galactic") """ return self.convert_to_units(self.units.get_base_equivalent(unit_system)) def convert_to_cgs(self): """ Convert the array and units to the equivalent cgs units. """ return self.convert_to_units(self.units.get_cgs_equivalent()) def convert_to_mks(self): """ Convert the array and units to the equivalent mks units. """ return self.convert_to_units(self.units.get_mks_equivalent()) def in_units(self, units, equivalence=None, **kwargs): """ Creates a copy of this array with the data in the supplied units, and returns it. Optionally, an equivalence can be specified to convert to an equivalent quantity which is not in the same dimensions. .. note:: All additional keyword arguments are passed to the equivalency, which should be used if that particular equivalency requires them. Parameters ---------- units : Unit object or string The units you want to get a new quantity in. equivalence : string, optional The equivalence you wish to use. To see which equivalencies are supported for this unitful quantity, try the :meth:`list_equivalencies` method. Default: None Returns ------- YTArray """ if equivalence is None: new_units = _unit_repr_check_same(self.units, units) (conversion_factor, offset) = self.units.get_conversion_factor(new_units) new_array = type(self)(self.ndview * conversion_factor, new_units) if offset: np.subtract(new_array, offset*new_array.uq, new_array) return new_array else: return self.to_equivalent(units, equivalence, **kwargs) def to(self, units, equivalence=None, **kwargs): """ An alias for YTArray.in_units(). See the docstrings of that function for details. """ return self.in_units(units, equivalence=equivalence, **kwargs) def to_value(self, units=None, equivalence=None, **kwargs): """ Creates a copy of this array with the data in the supplied units, and returns it without units. Output is therefore a bare NumPy array. Optionally, an equivalence can be specified to convert to an equivalent quantity which is not in the same dimensions. .. note:: All additional keyword arguments are passed to the equivalency, which should be used if that particular equivalency requires them. Parameters ---------- units : Unit object or string, optional The units you want to get the bare quantity in. If not specified, the value will be returned in the current units. equivalence : string, optional The equivalence you wish to use. To see which equivalencies are supported for this unitful quantity, try the :meth:`list_equivalencies` method. Default: None Returns ------- NumPy array """ if units is None: v = self.value else: v = self.in_units(units, equivalence=equivalence, **kwargs).value if isinstance(self, YTQuantity): return float(v) else: return v def in_base(self, unit_system="cgs"): """ Creates a copy of this array with the data in the specified unit system, and returns it in that system's base units. Parameters ---------- unit_system : string, optional The unit system to be used in the conversion. If not specified, the default base units of cgs are used. Examples -------- >>> E = YTQuantity(2.5, "erg/s") >>> E_new = E.in_base(unit_system="galactic") """ return self.in_units(self.units.get_base_equivalent(unit_system)) def in_cgs(self): """ Creates a copy of this array with the data in the equivalent cgs units, and returns it. Returns ------- Quantity object with data converted to cgs units. """ return self.in_units(self.units.get_cgs_equivalent()) def in_mks(self): """ Creates a copy of this array with the data in the equivalent mks units, and returns it. Returns ------- Quantity object with data converted to mks units. """ return self.in_units(self.units.get_mks_equivalent()) def to_equivalent(self, unit, equiv, **kwargs): """ Convert a YTArray or YTQuantity to an equivalent, e.g., something that is related by only a constant factor but not in the same units. Parameters ---------- unit : string The unit that you wish to convert to. equiv : string The equivalence you wish to use. To see which equivalencies are supported for this unitful quantity, try the :meth:`list_equivalencies` method. Examples -------- >>> a = yt.YTArray(1.0e7,"K") >>> a.to_equivalent("keV", "thermal") """ conv_unit = Unit(unit, registry=self.units.registry) if self.units.same_dimensions_as(conv_unit): return self.in_units(conv_unit) this_equiv = equivalence_registry[equiv]() oneway_or_equivalent = ( conv_unit.has_equivalent(equiv) or this_equiv._one_way) if self.has_equivalent(equiv) and oneway_or_equivalent: new_arr = this_equiv.convert( self, conv_unit.dimensions, **kwargs) if isinstance(new_arr, tuple): try: return type(self)(new_arr[0], new_arr[1]).in_units(unit) except YTUnitConversionError: raise YTInvalidUnitEquivalence(equiv, self.units, unit) else: return new_arr.in_units(unit) else: raise YTInvalidUnitEquivalence(equiv, self.units, unit) def list_equivalencies(self): """ Lists the possible equivalencies associated with this YTArray or YTQuantity. """ self.units.list_equivalencies() def has_equivalent(self, equiv): """ Check to see if this YTArray or YTQuantity has an equivalent unit in *equiv*. """ return self.units.has_equivalent(equiv) def ndarray_view(self): """ Returns a view into the array, but as an ndarray rather than ytarray. Returns ------- View of this array's data. """ return self.view(np.ndarray) def to_ndarray(self): """ Creates a copy of this array with the unit information stripped """ return np.array(self) @classmethod def from_astropy(cls, arr, unit_registry=None): """ Convert an AstroPy "Quantity" to a YTArray or YTQuantity. Parameters ---------- arr : AstroPy Quantity The Quantity to convert from. unit_registry : yt UnitRegistry, optional A yt unit registry to use in the conversion. If one is not supplied, the default one will be used. """ # Converting from AstroPy Quantity u = arr.unit ap_units = [] for base, exponent in zip(u.bases, u.powers): unit_str = base.to_string() # we have to do this because AstroPy is silly and defines # hour as "h" if unit_str == "h": unit_str = "hr" ap_units.append("%s**(%s)" % (unit_str, Rational(exponent))) ap_units = "*".join(ap_units) if isinstance(arr.value, np.ndarray): return YTArray(arr.value, ap_units, registry=unit_registry) else: return YTQuantity(arr.value, ap_units, registry=unit_registry) def to_astropy(self, **kwargs): """ Creates a new AstroPy quantity with the same unit information. """ if _astropy.units is None: raise ImportError("You don't have AstroPy installed, so you can't convert to " + "an AstroPy quantity.") return self.value*_astropy.units.Unit(str(self.units), **kwargs) @classmethod def from_pint(cls, arr, unit_registry=None): """ Convert a Pint "Quantity" to a YTArray or YTQuantity. Parameters ---------- arr : Pint Quantity The Quantity to convert from. unit_registry : yt UnitRegistry, optional A yt unit registry to use in the conversion. If one is not supplied, the default one will be used. Examples -------- >>> from pint import UnitRegistry >>> import numpy as np >>> ureg = UnitRegistry() >>> a = np.random.random(10) >>> b = ureg.Quantity(a, "erg/cm**3") >>> c = yt.YTArray.from_pint(b) """ p_units = [] for base, exponent in arr._units.items(): bs = convert_pint_units(base) p_units.append("%s**(%s)" % (bs, Rational(exponent))) p_units = "*".join(p_units) if isinstance(arr.magnitude, np.ndarray): return YTArray(arr.magnitude, p_units, registry=unit_registry) else: return YTQuantity(arr.magnitude, p_units, registry=unit_registry) def to_pint(self, unit_registry=None): """ Convert a YTArray or YTQuantity to a Pint Quantity. Parameters ---------- arr : YTArray or YTQuantity The unitful quantity to convert from. unit_registry : Pint UnitRegistry, optional The Pint UnitRegistry to use in the conversion. If one is not supplied, the default one will be used. NOTE: This is not the same as a yt UnitRegistry object. Examples -------- >>> a = YTQuantity(4.0, "cm**2/s") >>> b = a.to_pint() """ from pint import UnitRegistry if unit_registry is None: unit_registry = UnitRegistry() powers_dict = self.units.expr.as_powers_dict() units = [] for unit, pow in powers_dict.items(): # we have to do this because Pint doesn't recognize # "yr" as "year" if str(unit).endswith("yr") and len(str(unit)) in [2,3]: unit = str(unit).replace("yr","year") units.append("%s**(%s)" % (unit, Rational(pow))) units = "*".join(units) return unit_registry.Quantity(self.value, units) # # End unit conversion methods # def write_hdf5(self, filename, dataset_name=None, info=None, group_name=None): r"""Writes a YTArray to hdf5 file. Parameters ---------- filename: string The filename to create and write a dataset to dataset_name: string The name of the dataset to create in the file. info: dictionary A dictionary of supplementary info to write to append as attributes to the dataset. group_name: string An optional group to write the arrays to. If not specified, the arrays are datasets at the top level by default. Examples -------- >>> a = YTArray([1,2,3], 'cm') >>> myinfo = {'field':'dinosaurs', 'type':'field_data'} >>> a.write_hdf5('test_array_data.h5', dataset_name='dinosaurs', ... info=myinfo) """ from yt.utilities.on_demand_imports import _h5py as h5py from yt.extern.six.moves import cPickle as pickle if info is None: info = {} info['units'] = str(self.units) info['unit_registry'] = np.void(pickle.dumps(self.units.registry.lut)) if dataset_name is None: dataset_name = 'array_data' f = h5py.File(filename) if group_name is not None: if group_name in f: g = f[group_name] else: g = f.create_group(group_name) else: g = f if dataset_name in g.keys(): d = g[dataset_name] # Overwrite without deleting if we can get away with it. if d.shape == self.shape and d.dtype == self.dtype: d[...] = self for k in d.attrs.keys(): del d.attrs[k] else: del f[dataset_name] d = g.create_dataset(dataset_name, data=self) else: d = g.create_dataset(dataset_name, data=self) for k, v in info.items(): d.attrs[k] = v f.close() @classmethod def from_hdf5(cls, filename, dataset_name=None, group_name=None): r"""Attempts read in and convert a dataset in an hdf5 file into a YTArray. Parameters ---------- filename: string The filename to of the hdf5 file. dataset_name: string The name of the dataset to read from. If the dataset has a units attribute, attempt to infer units as well. group_name: string An optional group to read the arrays from. If not specified, the arrays are datasets at the top level by default. """ import h5py from yt.extern.six.moves import cPickle as pickle if dataset_name is None: dataset_name = 'array_data' f = h5py.File(filename) if group_name is not None: g = f[group_name] else: g = f dataset = g[dataset_name] data = dataset[:] units = dataset.attrs.get('units', '') if 'unit_registry' in dataset.attrs.keys(): unit_lut = pickle.loads(dataset.attrs['unit_registry'].tostring()) else: unit_lut = None f.close() registry = UnitRegistry(lut=unit_lut, add_default_symbols=False) return cls(data, units, registry=registry) # # Start convenience methods # @property def value(self): """Get a copy of the array data as a numpy ndarray""" return np.array(self) v = value @property def ndview(self): """Get a view of the array data.""" return self.ndarray_view() d = ndview @property def unit_quantity(self): """Get a YTQuantity with the same unit as this array and a value of 1.0""" return YTQuantity(1.0, self.units) uq = unit_quantity @property def unit_array(self): """Get a YTArray filled with ones with the same unit and shape as this array""" return

np.ones_like(self)

numpy.ones_like

from __future__ import print_function import numpy as np import matplotlib.pyplot as plt class TwoLayerNet(object): """ A two-layer fully-connected neural network. The net has an input dimension of N, a hidden layer dimension of H, and performs classification over C classes. We train the network with a softmax loss function and L2 regularization on the weight matrices. The network uses a ReLU nonlinearity after the first fully connected layer. In other words, the network has the following architecture: input - fully connected layer - ReLU - fully connected layer - softmax The outputs of the second fully-connected layer are the scores for each class. """ def __init__(self, input_size, hidden_size, output_size, std=1e-4): """ Initialize the model. Weights are initialized to small random values and biases are initialized to zero. Weights and biases are stored in the variable self.params, which is a dictionary with the following keys W1: First layer weights; has shape (D, H) b1: First layer biases; has shape (H,) W2: Second layer weights; has shape (H, C) b2: Second layer biases; has shape (C,) Inputs: - input_size: The dimension D of the input data. - hidden_size: The number of neurons H in the hidden layer. - output_size: The number of classes C. """ self.params = {} self.params['W1'] = std * np.random.randn(input_size, hidden_size) self.params['b1'] = np.zeros(hidden_size) self.params['W2'] = std * np.random.randn(hidden_size, output_size) self.params['b2'] = np.zeros(output_size) def loss(self, X, y=None, reg=0.0): """ Compute the loss and gradients for a two layer fully connected neural network. Inputs: - X: Input data of shape (N, D). Each X[i] is a training sample. - y: Vector of training labels. y[i] is the label for X[i], and each y[i] is an integer in the range 0 <= y[i] < C. This parameter is optional; if it is not passed then we only return scores, and if it is passed then we instead return the loss and gradients. - reg: Regularization strength. Returns: If y is None, return a matrix scores of shape (N, C) where scores[i, c] is the score for class c on input X[i]. If y is not None, instead return a tuple of: - loss: Loss (data loss and regularization loss) for this batch of training samples. - grads: Dictionary mapping parameter names to gradients of those parameters with respect to the loss function; has the same keys as self.params. """ # Unpack variables from the params dictionary W1, b1 = self.params['W1'], self.params['b1'] W2, b2 = self.params['W2'], self.params['b2'] N, D = X.shape # Compute the forward pass scores = None ####################################################################### # TODO: Perform the forward pass, computing the class scores for the # # input. Store the result in the scores variable, which should be an # # array of shape (N, C). # ####################################################################### scores1 = X.dot(W1) + b1 # FC1 X2 = np.maximum(0, scores1) # ReLU FC1 scores = X2.dot(W2) + b2 # FC2 ####################################################################### # END OF YOUR CODE # ####################################################################### # If the targets are not given then jump out, we're done if y is None: return scores scores -= np.max(scores) # Fix Number instability scores_exp = np.exp(scores) probs = scores_exp / np.sum(scores_exp, axis=1, keepdims=True) # Compute the loss loss = None ####################################################################### # TODO: Finish the forward pass, and compute the loss. This should # # include both the data loss and L2 regularization for W1 and W2. # # Store the result in the variable loss, which should be a scalar. Use# # the Softmax classifier loss. # ####################################################################### correct_probs = -np.log(probs[np.arange(N), y]) # L_i = -log(e^correct_score/sum(e^scores))) = -log(correct_probs) loss = np.sum(correct_probs) loss /= N # L2 regularization WRT W1 and W2 loss += reg * (np.sum(W1 * W1) +

np.sum(W2 * W2)

numpy.sum

import numpy as np import sys import os from PIL import Image from visu.helper_functions import save_image from scipy.spatial.transform import Rotation as R from helper import re_quat import copy import torch import numpy as np import k3d class Visualizer(): def __init__(self, p_visu, writer=None): if p_visu[-1] != '/': p_visu = p_visu + '/' self.p_visu = p_visu self.writer = writer if not os.path.exists(self.p_visu): os.makedirs(self.p_visu) def plot_estimated_pose(self, tag, epoch, img, points, trans=[[0, 0, 0]], rot_mat=[[1, 0, 0], [0, 1, 0], [0, 0, 1]], cam_cx=0, cam_cy=0, cam_fx=0, cam_fy=0, store=False, jupyter=False, w=2): """ tag := tensorboard tag epoch := tensorboard epoche store := ture -> stores the image to standard path path := != None creats the path and store to it path/tag.png img:= original_image, [widht,height,RGB] points:= points of the object model [length,x,y,z] trans: [1,3] rot: [3,3] """ img_d = copy.deepcopy(img) points = np.dot(points, rot_mat.T) points = np.add(points, trans[0, :]) for i in range(0, points.shape[0]): p_x = points[i, 0] p_y = points[i, 1] p_z = points[i, 2] u = int(((p_x / p_z) * cam_fx) + cam_cx) v = int(((p_y / p_z) * cam_fy) + cam_cy) try: img_d[v - w:v + w + 1, u - w:u + w + 1, 0] = 0 img_d[v - w:v + w + 1, u - w:u + w + 1, 1] = 255 img_d[v - w:v + w + 1, u - w:u + w + 1, 0] = 0 except: #print("out of bounce") pass if jupyter: display(Image.fromarray(img_d)) if store: #store_ar = (img_d* 255).round().astype(np.uint8) #print("IMAGE D:" ,img_d,img_d.shape ) save_image(img_d, tag=str(epoch) + tag, p_store=self.p_visu) if self.writer is not None: self.writer.add_image(tag, img_d.astype( np.uint8), global_step=epoch, dataformats='HWC') def plot_bounding_box(self, tag, epoch, img, rmin=0, rmax=0, cmin=0, cmax=0, str_width=2, store=False, jupyter=False, b=None): """ tag := tensorboard tag epoch := tensorboard epoche store := ture -> stores the image to standard path path := != None creats the path and store to it path/tag.png img:= original_image, [widht,height,RGB] """ if isinstance(b, dict): rmin = b['rmin'] rmax = b['rmax'] cmin = b['cmin'] cmax = b['cmax'] # ToDo check Input data img_d = np.array(copy.deepcopy(img)) c = [0, 0, 255] rmin_mi = max(0, rmin - str_width) rmin_ma = min(img_d.shape[0], rmin + str_width) rmax_mi = max(0, rmax - str_width) rmax_ma = min(img_d.shape[0], rmax + str_width) cmin_mi = max(0, cmin - str_width) cmin_ma = min(img_d.shape[1], cmin + str_width) cmax_mi = max(0, cmax - str_width) cmax_ma = min(img_d.shape[1], cmax + str_width) img_d[rmin_mi:rmin_ma, cmin:cmax, :] = c img_d[rmax_mi:rmax_ma, cmin:cmax, :] = c img_d[rmin:rmax, cmin_mi:cmin_ma, :] = c img_d[rmin:rmax, cmax_mi:cmax_ma, :] = c print("STORE", store) img_d = img_d.astype(np.uint8) if store: #store_ar = (img_d* 255).round().astype(np.uint8) save_image(img_d, tag=str(epoch) + tag, p_store=self.p_visu) if jupyter: display(Image.fromarray(img_d)) if self.writer is not None: self.writer.add_image(tag, img_d.astype( np.uint8), global_step=epoch, dataformats='HWC') def plot_pcd(x, point_size=0.005, c='g'): """ x: point_nr,3 """ if c == 'b': k = 245 elif c == 'g': k = 25811000 elif c == 'r': k = 11801000 elif c == 'black': k = 2580 else: k = 2580 colors = np.ones(x.shape[0]) * k plot = k3d.plot(name='points') plt_points = k3d.points(x, colors.astype(np.uint32), point_size=point_size) plot += plt_points plt_points.shader = '3d' plot.display() def plot_two_pcd(x, y, point_size=0.005, c1='g', c2='r'): if c1 == 'b': k = 245 elif c1 == 'g': k = 25811000 elif c1 == 'r': k = 11801000 elif c1 == 'black': k = 2580 else: k = 2580 if c2 == 'b': k2 = 245 elif c2 == 'g': k2 = 25811000 elif c2 == 'r': k2 = 11801000 elif c2 == 'black': k2 = 2580 else: k2 = 2580 col1 = np.ones(x.shape[0]) * k col2 =

np.ones(y.shape[0])

numpy.ones

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time =

np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101)

numpy.linspace

import sys import numpy as np from matplotlib import pyplot as pl from rw import WriteGTiff fn = '../pozo-steep-vegetated-pcl.npy' pts = np.load(fn) x, y, z, c = pts[:, 0], pts[:, 1], pts[:, 2], pts[:, 5] ix = (0.2 * (x - x.min())).astype('int') iy = (0.2 * (y - y.min())).astype('int') shape = (100, 100) xb =

np.arange(shape[1]+1)

numpy.arange

import logging import george import numpy as np from robo.priors.default_priors import DefaultPrior from robo.models.gaussian_process import GaussianProcess from robo.models.gaussian_process_mcmc import GaussianProcessMCMC from robo.maximizers.random_sampling import RandomSampling from robo.maximizers.scipy_optimizer import SciPyOptimizer from robo.maximizers.differential_evolution import DifferentialEvolution from robo.solver.bayesian_optimization import BayesianOptimization from robo.acquisition_functions.information_gain import InformationGain from robo.acquisition_functions.ei import EI from robo.acquisition_functions.marginalization import MarginalizationGPMCMC from robo.initial_design import init_latin_hypercube_sampling logger = logging.getLogger(__name__) def entropy_search(objective_function, lower, upper, num_iterations=30, maximizer="random", model="gp_mcmc", n_init=3, output_path=None, rng=None): """ Entropy search for global black box optimization problems. This is a reimplemenation of the entropy search algorithm by Henning and Schuler[1]. [1] Entropy search for information-efficient global optimization. <NAME> and <NAME>. JMLR, (1), 2012. Parameters ---------- objective_function: function The objective function that is minimized. This function gets a numpy array (D,) as input and returns the function value (scalar) lower: np.ndarray (D,) The lower bound of the search space upper: np.ndarray (D,) The upper bound of the search space num_iterations: int The number of iterations (initial design + BO) maximizer: {"random", "scipy", "differential_evolution"} Defines how the acquisition function is maximized. model: {"gp", "gp_mcmc"} The model for the objective function. n_init: int Number of points for the initial design. Make sure that it is <= num_iterations. output_path: string Specifies the path where the intermediate output after each iteration will be saved. If None no output will be saved to disk. rng: numpy.random.RandomState Random number generator Returns ------- dict with all results """ assert upper.shape[0] == lower.shape[0], "Dimension miss match" assert

np.all(lower < upper)

numpy.all

# coding: utf-8 # Licensed under a 3-clause BSD style license - see LICENSE.rst """ Test the Logarithmic Units and Quantities """ from __future__ import (absolute_import, unicode_literals, division, print_function) from ...extern import six from ...extern.six.moves import zip import pickle import itertools import pytest import numpy as np from numpy.testing.utils import assert_allclose from ...tests.helper import assert_quantity_allclose from ... import units as u, constants as c lu_units = [u.dex, u.mag, u.decibel] lu_subclasses = [u.DexUnit, u.MagUnit, u.DecibelUnit] lq_subclasses = [u.Dex, u.Magnitude, u.Decibel] pu_sample = (u.dimensionless_unscaled, u.m, u.g/u.s**2, u.Jy) class TestLogUnitCreation(object): def test_logarithmic_units(self): """Check logarithmic units are set up correctly.""" assert u.dB.to(u.dex) == 0.1 assert u.dex.to(u.mag) == -2.5 assert u.mag.to(u.dB) == -4 @pytest.mark.parametrize('lu_unit, lu_cls', zip(lu_units, lu_subclasses)) def test_callable_units(self, lu_unit, lu_cls): assert isinstance(lu_unit, u.UnitBase) assert callable(lu_unit) assert lu_unit._function_unit_class is lu_cls @pytest.mark.parametrize('lu_unit', lu_units) def test_equality_to_normal_unit_for_dimensionless(self, lu_unit): lu = lu_unit() assert lu == lu._default_function_unit # eg, MagUnit() == u.mag assert lu._default_function_unit == lu # and u.mag == MagUnit() @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_call_units(self, lu_unit, physical_unit): """Create a LogUnit subclass using the callable unit and physical unit, and do basic check that output is right.""" lu1 = lu_unit(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit def test_call_invalid_unit(self): with pytest.raises(TypeError): u.mag([]) with pytest.raises(ValueError): u.mag(u.mag()) @pytest.mark.parametrize('lu_cls, physical_unit', itertools.product( lu_subclasses + [u.LogUnit], pu_sample)) def test_subclass_creation(self, lu_cls, physical_unit): """Create a LogUnit subclass object for given physical unit, and do basic check that output is right.""" lu1 = lu_cls(physical_unit) assert lu1.physical_unit == physical_unit assert lu1.function_unit == lu1._default_function_unit lu2 = lu_cls(physical_unit, function_unit=2*lu1._default_function_unit) assert lu2.physical_unit == physical_unit assert lu2.function_unit == u.Unit(2*lu2._default_function_unit) with pytest.raises(ValueError): lu_cls(physical_unit, u.m) def test_predefined_magnitudes(): assert_quantity_allclose((-21.1*u.STmag).physical, 1.*u.erg/u.cm**2/u.s/u.AA) assert_quantity_allclose((-48.6*u.ABmag).physical, 1.*u.erg/u.cm**2/u.s/u.Hz) assert_quantity_allclose((0*u.M_bol).physical, c.L_bol0) assert_quantity_allclose((0*u.m_bol).physical, c.L_bol0/(4.*np.pi*(10.*c.pc)**2)) def test_predefined_reinitialisation(): assert u.mag('ST') == u.STmag assert u.mag('AB') == u.ABmag assert u.mag('Bol') == u.M_bol assert u.mag('bol') == u.m_bol def test_predefined_string_roundtrip(): """Ensure roundtripping; see #5015""" with u.magnitude_zero_points.enable(): assert u.Unit(u.STmag.to_string()) == u.STmag assert u.Unit(u.ABmag.to_string()) == u.ABmag assert u.Unit(u.M_bol.to_string()) == u.M_bol assert u.Unit(u.m_bol.to_string()) == u.m_bol def test_inequality(): """Check __ne__ works (regresssion for #5342).""" lu1 = u.mag(u.Jy) lu2 = u.dex(u.Jy) lu3 = u.mag(u.Jy**2) lu4 = lu3 - lu1 assert lu1 != lu2 assert lu1 != lu3 assert lu1 == lu4 class TestLogUnitStrings(object): def test_str(self): """Do some spot checks that str, repr, etc. work as expected.""" lu1 = u.mag(u.Jy) assert str(lu1) == 'mag(Jy)' assert repr(lu1) == 'Unit("mag(Jy)")' assert lu1.to_string('generic') == 'mag(Jy)' with pytest.raises(ValueError): lu1.to_string('fits') lu2 = u.dex() assert str(lu2) == 'dex' assert repr(lu2) == 'Unit("dex(1)")' assert lu2.to_string() == 'dex(1)' lu3 = u.MagUnit(u.Jy, function_unit=2*u.mag) assert str(lu3) == '2 mag(Jy)' assert repr(lu3) == 'MagUnit("Jy", unit="2 mag")' assert lu3.to_string() == '2 mag(Jy)' lu4 = u.mag(u.ct) assert lu4.to_string('generic') == 'mag(ct)' assert lu4.to_string('latex') == ('$\\mathrm{mag}$$\\mathrm{\\left( ' '\\mathrm{ct} \\right)}$') assert lu4._repr_latex_() == lu4.to_string('latex') class TestLogUnitConversion(object): @pytest.mark.parametrize('lu_unit, physical_unit', itertools.product(lu_units, pu_sample)) def test_physical_unit_conversion(self, lu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to their non-log counterparts.""" lu1 = lu_unit(physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(physical_unit, 0.) == 1. assert physical_unit.is_equivalent(lu1) assert physical_unit.to(lu1, 1.) == 0. pu = u.Unit(8.*physical_unit) assert lu1.is_equivalent(physical_unit) assert lu1.to(pu, 0.) == 0.125 assert pu.is_equivalent(lu1) assert_allclose(pu.to(lu1, 0.125), 0., atol=1.e-15) # Check we round-trip. value = np.linspace(0., 10., 6) assert_allclose(pu.to(lu1, lu1.to(pu, value)), value, atol=1.e-15) # And that we're not just returning True all the time. pu2 = u.g assert not lu1.is_equivalent(pu2) with pytest.raises(u.UnitsError): lu1.to(pu2) assert not pu2.is_equivalent(lu1) with pytest.raises(u.UnitsError): pu2.to(lu1) @pytest.mark.parametrize('lu_unit', lu_units) def test_container_unit_conversion(self, lu_unit): """Check that conversion to logarithmic units (u.mag, u.dB, u.dex) is only possible when the physical unit is dimensionless.""" values = np.linspace(0., 10., 6) lu1 = lu_unit(u.dimensionless_unscaled) assert lu1.is_equivalent(lu1.function_unit) assert_allclose(lu1.to(lu1.function_unit, values), values) lu2 = lu_unit(u.Jy) assert not lu2.is_equivalent(lu2.function_unit) with pytest.raises(u.UnitsError): lu2.to(lu2.function_unit, values) @pytest.mark.parametrize( 'flu_unit, tlu_unit, physical_unit', itertools.product(lu_units, lu_units, pu_sample)) def test_subclass_conversion(self, flu_unit, tlu_unit, physical_unit): """Check various LogUnit subclasses are equivalent and convertible to each other if they correspond to equivalent physical units.""" values = np.linspace(0., 10., 6) flu = flu_unit(physical_unit) tlu = tlu_unit(physical_unit) assert flu.is_equivalent(tlu) assert_allclose(flu.to(tlu), flu.function_unit.to(tlu.function_unit)) assert_allclose(flu.to(tlu, values), values * flu.function_unit.to(tlu.function_unit)) tlu2 = tlu_unit(u.Unit(100.*physical_unit)) assert flu.is_equivalent(tlu2) # Check that we round-trip. assert_allclose(flu.to(tlu2, tlu2.to(flu, values)), values, atol=1.e-15) tlu3 = tlu_unit(physical_unit.to_system(u.si)[0]) assert flu.is_equivalent(tlu3) assert_allclose(flu.to(tlu3, tlu3.to(flu, values)), values, atol=1.e-15) tlu4 = tlu_unit(u.g) assert not flu.is_equivalent(tlu4) with pytest.raises(u.UnitsError): flu.to(tlu4, values) def test_unit_decomposition(self): lu = u.mag(u.Jy) assert lu.decompose() == u.mag(u.Jy.decompose()) assert lu.decompose().physical_unit.bases == [u.kg, u.s] assert lu.si == u.mag(u.Jy.si) assert lu.si.physical_unit.bases == [u.kg, u.s] assert lu.cgs == u.mag(u.Jy.cgs) assert lu.cgs.physical_unit.bases == [u.g, u.s] def test_unit_multiple_possible_equivalencies(self): lu = u.mag(u.Jy) assert lu.is_equivalent(pu_sample) class TestLogUnitArithmetic(object): def test_multiplication_division(self): """Check that multiplication/division with other units is only possible when the physical unit is dimensionless, and that this turns the unit into a normal one.""" lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 * u.m with pytest.raises(u.UnitsError): u.m * lu1 with pytest.raises(u.UnitsError): lu1 / lu1 for unit in (u.dimensionless_unscaled, u.m, u.mag, u.dex): with pytest.raises(u.UnitsError): lu1 / unit lu2 = u.mag(u.dimensionless_unscaled) with pytest.raises(u.UnitsError): lu2 * lu1 with pytest.raises(u.UnitsError): lu2 / lu1 # But dimensionless_unscaled can be cancelled. assert lu2 / lu2 == u.dimensionless_unscaled # With dimensionless, normal units are OK, but we return a plain unit. tf = lu2 * u.m tr = u.m * lu2 for t in (tf, tr): assert not isinstance(t, type(lu2)) assert t == lu2.function_unit * u.m with u.set_enabled_equivalencies(u.logarithmic()): with pytest.raises(u.UnitsError): t.to(lu2.physical_unit) # Now we essentially have a LogUnit with a prefactor of 100, # so should be equivalent again. t = tf / u.cm with u.set_enabled_equivalencies(u.logarithmic()): assert t.is_equivalent(lu2.function_unit) assert_allclose(t.to(u.dimensionless_unscaled, np.arange(3.)/100.), lu2.to(lu2.physical_unit, np.arange(3.))) # If we effectively remove lu1, a normal unit should be returned. t2 = tf / lu2 assert not isinstance(t2, type(lu2)) assert t2 == u.m t3 = tf / lu2.function_unit assert not isinstance(t3, type(lu2)) assert t3 == u.m # For completeness, also ensure non-sensical operations fail with pytest.raises(TypeError): lu1 * object() with pytest.raises(TypeError): slice(None) * lu1 with pytest.raises(TypeError): lu1 / [] with pytest.raises(TypeError): 1 / lu1 @pytest.mark.parametrize('power', (2, 0.5, 1, 0)) def test_raise_to_power(self, power): """Check that raising LogUnits to some power is only possible when the physical unit is dimensionless, and that conversion is turned off when the resulting logarithmic unit (such as mag**2) is incompatible.""" lu1 = u.mag(u.Jy) if power == 0: assert lu1 ** power == u.dimensionless_unscaled elif power == 1: assert lu1 ** power == lu1 else: with pytest.raises(u.UnitsError): lu1 ** power # With dimensionless, though, it works, but returns a normal unit. lu2 = u.mag(u.dimensionless_unscaled) t = lu2**power if power == 0: assert t == u.dimensionless_unscaled elif power == 1: assert t == lu2 else: assert not isinstance(t, type(lu2)) assert t == lu2.function_unit**power # also check we roundtrip t2 = t**(1./power) assert t2 == lu2.function_unit with u.set_enabled_equivalencies(u.logarithmic()): assert_allclose(t2.to(u.dimensionless_unscaled, np.arange(3.)), lu2.to(lu2.physical_unit, np.arange(3.))) @pytest.mark.parametrize('other', pu_sample) def test_addition_subtraction_to_normal_units_fails(self, other): lu1 = u.mag(u.Jy) with pytest.raises(u.UnitsError): lu1 + other with pytest.raises(u.UnitsError): lu1 - other with pytest.raises(u.UnitsError): other - lu1 def test_addition_subtraction_to_non_units_fails(self): lu1 = u.mag(u.Jy) with pytest.raises(TypeError): lu1 + 1. with pytest.raises(TypeError): lu1 - [1., 2., 3.] @pytest.mark.parametrize( 'other', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2*u.mag), u.MagUnit('', 2.*u.mag))) def test_addition_subtraction(self, other): """Check physical units are changed appropriately""" lu1 = u.mag(u.Jy) other_pu = getattr(other, 'physical_unit', u.dimensionless_unscaled) lu_sf = lu1 + other assert lu_sf.is_equivalent(lu1.physical_unit * other_pu) lu_sr = other + lu1 assert lu_sr.is_equivalent(lu1.physical_unit * other_pu) lu_df = lu1 - other assert lu_df.is_equivalent(lu1.physical_unit / other_pu) lu_dr = other - lu1 assert lu_dr.is_equivalent(other_pu / lu1.physical_unit) def test_complicated_addition_subtraction(self): """for fun, a more complicated example of addition and subtraction""" dm0 = u.Unit('DM', 1./(4.*np.pi*(10.*u.pc)**2)) lu_dm = u.mag(dm0) lu_absST = u.STmag - lu_dm assert lu_absST.is_equivalent(u.erg/u.s/u.AA) def test_neg_pos(self): lu1 = u.mag(u.Jy) neg_lu = -lu1 assert neg_lu != lu1 assert neg_lu.physical_unit == u.Jy**-1 assert -neg_lu == lu1 pos_lu = +lu1 assert pos_lu is not lu1 assert pos_lu == lu1 def test_pickle(): lu1 = u.dex(u.cm/u.s**2) s = pickle.dumps(lu1) lu2 = pickle.loads(s) assert lu1 == lu2 def test_hashable(): lu1 = u.dB(u.mW) lu2 = u.dB(u.m) lu3 = u.dB(u.mW) assert hash(lu1) != hash(lu2) assert hash(lu1) == hash(lu3) luset = {lu1, lu2, lu3} assert len(luset) == 2 class TestLogQuantityCreation(object): @pytest.mark.parametrize('lq, lu', zip(lq_subclasses + [u.LogQuantity], lu_subclasses + [u.LogUnit])) def test_logarithmic_quantities(self, lq, lu): """Check logarithmic quantities are all set up correctly""" assert lq._unit_class == lu assert type(lu()._quantity_class(1.)) is lq @pytest.mark.parametrize('lq_cls, physical_unit', itertools.product(lq_subclasses, pu_sample)) def test_subclass_creation(self, lq_cls, physical_unit): """Create LogQuantity subclass objects for some physical units, and basic check on transformations""" value = np.arange(1., 10.) log_q = lq_cls(value * physical_unit) assert log_q.unit.physical_unit == physical_unit assert log_q.unit.function_unit == log_q.unit._default_function_unit assert_allclose(log_q.physical.value, value) with pytest.raises(ValueError): lq_cls(value, physical_unit) @pytest.mark.parametrize( 'unit', (u.mag, u.mag(), u.mag(u.Jy), u.mag(u.m), u.Unit(2*u.mag), u.MagUnit('', 2.*u.mag), u.MagUnit(u.Jy, -1*u.mag), u.MagUnit(u.m, -2.*u.mag))) def test_different_units(self, unit): q = u.Magnitude(1.23, unit) assert q.unit.function_unit == getattr(unit, 'function_unit', unit) assert q.unit.physical_unit is getattr(unit, 'physical_unit', u.dimensionless_unscaled) @pytest.mark.parametrize('value, unit', ( (1.*u.mag(u.Jy), None), (1.*u.dex(u.Jy), None), (1.*u.mag(u.W/u.m**2/u.Hz), u.mag(u.Jy)), (1.*u.dex(u.W/u.m**2/u.Hz), u.mag(u.Jy)))) def test_function_values(self, value, unit): lq = u.Magnitude(value, unit) assert lq == value assert lq.unit.function_unit == u.mag assert lq.unit.physical_unit == getattr(unit, 'physical_unit', value.unit.physical_unit) @pytest.mark.parametrize( 'unit', (u.mag(), u.mag(u.Jy), u.mag(u.m), u.MagUnit('', 2.*u.mag), u.MagUnit(u.Jy, -1*u.mag), u.MagUnit(u.m, -2.*u.mag))) def test_indirect_creation(self, unit): q1 = 2.5 * unit assert isinstance(q1, u.Magnitude) assert q1.value == 2.5 assert q1.unit == unit pv = 100. * unit.physical_unit q2 = unit * pv assert q2.unit == unit assert q2.unit.physical_unit == pv.unit assert q2.to_value(unit.physical_unit) == 100. assert (q2._function_view / u.mag).to_value(1) == -5. q3 = unit / 0.4 assert q3 == q1 def test_from_view(self): # Cannot view a physical quantity as a function quantity, since the # values would change. q = [100., 1000.] * u.cm/u.s**2 with pytest.raises(TypeError): q.view(u.Dex) # But fine if we have the right magnitude. q = [2., 3.] * u.dex lq = q.view(u.Dex) assert isinstance(lq, u.Dex) assert lq.unit.physical_unit == u.dimensionless_unscaled assert np.all(q == lq) def test_using_quantity_class(self): """Check that we can use Quantity if we have subok=True""" # following issue #5851 lu = u.dex(u.AA) with pytest.raises(u.UnitTypeError): u.Quantity(1., lu) q = u.Quantity(1., lu, subok=True) assert type(q) is lu._quantity_class def test_conversion_to_and_from_physical_quantities(): """Ensures we can convert from regular quantities.""" mst = [10., 12., 14.] * u.STmag flux_lambda = mst.physical mst_roundtrip = flux_lambda.to(u.STmag) # check we return a logquantity; see #5178. assert isinstance(mst_roundtrip, u.Magnitude) assert mst_roundtrip.unit == mst.unit assert_allclose(mst_roundtrip.value, mst.value) wave = [4956.8, 4959.55, 4962.3] * u.AA flux_nu = mst.to(u.Jy, equivalencies=u.spectral_density(wave)) mst_roundtrip2 = flux_nu.to(u.STmag, u.spectral_density(wave)) assert isinstance(mst_roundtrip2, u.Magnitude) assert mst_roundtrip2.unit == mst.unit

assert_allclose(mst_roundtrip2.value, mst.value)

numpy.testing.utils.assert_allclose

"""Test the search module""" from collections.abc import Iterable, Sized from io import StringIO from itertools import chain, product from functools import partial import pickle import sys from types import GeneratorType import re import numpy as np import scipy.sparse as sp import pytest from sklearn.utils.fixes import sp_version from sklearn.utils._testing import assert_raises from sklearn.utils._testing import assert_warns from sklearn.utils._testing import assert_warns_message from sklearn.utils._testing import assert_raise_message from sklearn.utils._testing import assert_array_equal from sklearn.utils._testing import assert_array_almost_equal from sklearn.utils._testing import assert_allclose from sklearn.utils._testing import assert_almost_equal from sklearn.utils._testing import ignore_warnings from sklearn.utils._mocking import CheckingClassifier, MockDataFrame from scipy.stats import bernoulli, expon, uniform from sklearn.base import BaseEstimator, ClassifierMixin from sklearn.base import clone from sklearn.exceptions import NotFittedError from sklearn.datasets import make_classification from sklearn.datasets import make_blobs from sklearn.datasets import make_multilabel_classification from sklearn.model_selection import fit_grid_point from sklearn.model_selection import train_test_split from sklearn.model_selection import KFold from sklearn.model_selection import StratifiedKFold from sklearn.model_selection import StratifiedShuffleSplit from sklearn.model_selection import LeaveOneGroupOut from sklearn.model_selection import LeavePGroupsOut from sklearn.model_selection import GroupKFold from sklearn.model_selection import GroupShuffleSplit from sklearn.model_selection import GridSearchCV from sklearn.model_selection import RandomizedSearchCV from sklearn.model_selection import ParameterGrid from sklearn.model_selection import ParameterSampler from sklearn.model_selection._search import BaseSearchCV from sklearn.model_selection._validation import FitFailedWarning from sklearn.svm import LinearSVC, SVC from sklearn.tree import DecisionTreeRegressor from sklearn.tree import DecisionTreeClassifier from sklearn.cluster import KMeans from sklearn.neighbors import KernelDensity from sklearn.neighbors import KNeighborsClassifier from sklearn.metrics import f1_score from sklearn.metrics import recall_score from sklearn.metrics import accuracy_score from sklearn.metrics import make_scorer from sklearn.metrics import roc_auc_score from sklearn.metrics.pairwise import euclidean_distances from sklearn.impute import SimpleImputer from sklearn.pipeline import Pipeline from sklearn.linear_model import Ridge, SGDClassifier, LinearRegression from sklearn.experimental import enable_hist_gradient_boosting # noqa from sklearn.ensemble import HistGradientBoostingClassifier from sklearn.model_selection.tests.common import OneTimeSplitter # Neither of the following two estimators inherit from BaseEstimator, # to test hyperparameter search on user-defined classifiers. class MockClassifier: """Dummy classifier to test the parameter search algorithms""" def __init__(self, foo_param=0): self.foo_param = foo_param def fit(self, X, Y): assert len(X) == len(Y) self.classes_ = np.unique(Y) return self def predict(self, T): return T.shape[0] def transform(self, X): return X + self.foo_param def inverse_transform(self, X): return X - self.foo_param predict_proba = predict predict_log_proba = predict decision_function = predict def score(self, X=None, Y=None): if self.foo_param > 1: score = 1. else: score = 0. return score def get_params(self, deep=False): return {'foo_param': self.foo_param} def set_params(self, **params): self.foo_param = params['foo_param'] return self class LinearSVCNoScore(LinearSVC): """An LinearSVC classifier that has no score method.""" @property def score(self): raise AttributeError X = np.array([[-1, -1], [-2, -1], [1, 1], [2, 1]]) y = np.array([1, 1, 2, 2]) def assert_grid_iter_equals_getitem(grid): assert list(grid) == [grid[i] for i in range(len(grid))] @pytest.mark.parametrize("klass", [ParameterGrid, partial(ParameterSampler, n_iter=10)]) @pytest.mark.parametrize( "input, error_type, error_message", [(0, TypeError, r'Parameter .* is not a dict or a list $0$'), ([{'foo': [0]}, 0], TypeError, r'Parameter .* is not a dict $0$'), ({'foo': 0}, TypeError, "Parameter.* value is not iterable .*" r"$key='foo', value=0$")] ) def test_validate_parameter_input(klass, input, error_type, error_message): with pytest.raises(error_type, match=error_message): klass(input) def test_parameter_grid(): # Test basic properties of ParameterGrid. params1 = {"foo": [1, 2, 3]} grid1 = ParameterGrid(params1) assert isinstance(grid1, Iterable) assert isinstance(grid1, Sized) assert len(grid1) == 3 assert_grid_iter_equals_getitem(grid1) params2 = {"foo": [4, 2], "bar": ["ham", "spam", "eggs"]} grid2 = ParameterGrid(params2) assert len(grid2) == 6 # loop to assert we can iterate over the grid multiple times for i in range(2): # tuple + chain transforms {"a": 1, "b": 2} to ("a", 1, "b", 2) points = set(tuple(chain(*(sorted(p.items())))) for p in grid2) assert (points == set(("bar", x, "foo", y) for x, y in product(params2["bar"], params2["foo"]))) assert_grid_iter_equals_getitem(grid2) # Special case: empty grid (useful to get default estimator settings) empty = ParameterGrid({}) assert len(empty) == 1 assert list(empty) == [{}] assert_grid_iter_equals_getitem(empty) assert_raises(IndexError, lambda: empty[1]) has_empty = ParameterGrid([{'C': [1, 10]}, {}, {'C': [.5]}]) assert len(has_empty) == 4 assert list(has_empty) == [{'C': 1}, {'C': 10}, {}, {'C': .5}] assert_grid_iter_equals_getitem(has_empty) def test_grid_search(): # Test that the best estimator contains the right value for foo_param clf = MockClassifier() grid_search = GridSearchCV(clf, {'foo_param': [1, 2, 3]}, cv=3, verbose=3) # make sure it selects the smallest parameter in case of ties old_stdout = sys.stdout sys.stdout = StringIO() grid_search.fit(X, y) sys.stdout = old_stdout assert grid_search.best_estimator_.foo_param == 2 assert_array_equal(grid_search.cv_results_["param_foo_param"].data, [1, 2, 3]) # Smoke test the score etc: grid_search.score(X, y) grid_search.predict_proba(X) grid_search.decision_function(X) grid_search.transform(X) # Test exception handling on scoring grid_search.scoring = 'sklearn' assert_raises(ValueError, grid_search.fit, X, y) def test_grid_search_pipeline_steps(): # check that parameters that are estimators are cloned before fitting pipe = Pipeline([('regressor', LinearRegression())]) param_grid = {'regressor': [LinearRegression(), Ridge()]} grid_search = GridSearchCV(pipe, param_grid, cv=2) grid_search.fit(X, y) regressor_results = grid_search.cv_results_['param_regressor'] assert isinstance(regressor_results[0], LinearRegression) assert isinstance(regressor_results[1], Ridge) assert not hasattr(regressor_results[0], 'coef_') assert not hasattr(regressor_results[1], 'coef_') assert regressor_results[0] is not grid_search.best_estimator_ assert regressor_results[1] is not grid_search.best_estimator_ # check that we didn't modify the parameter grid that was passed assert not hasattr(param_grid['regressor'][0], 'coef_') assert not hasattr(param_grid['regressor'][1], 'coef_') @pytest.mark.parametrize("SearchCV", [GridSearchCV, RandomizedSearchCV]) def test_SearchCV_with_fit_params(SearchCV): X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) clf = CheckingClassifier(expected_fit_params=['spam', 'eggs']) searcher = SearchCV( clf, {'foo_param': [1, 2, 3]}, cv=2, error_score="raise" ) # The CheckingClassifier generates an assertion error if # a parameter is missing or has length != len(X). err_msg = r"Expected fit parameter$s$ \['eggs'\] not seen." with pytest.raises(AssertionError, match=err_msg): searcher.fit(X, y, spam=np.ones(10)) err_msg = "Fit parameter spam has length 1; expected" with pytest.raises(AssertionError, match=err_msg): searcher.fit(X, y, spam=np.ones(1), eggs=np.zeros(10)) searcher.fit(X, y, spam=np.ones(10), eggs=np.zeros(10)) @ignore_warnings def test_grid_search_no_score(): # Test grid-search on classifier that has no score function. clf = LinearSVC(random_state=0) X, y = make_blobs(random_state=0, centers=2) Cs = [.1, 1, 10] clf_no_score = LinearSVCNoScore(random_state=0) grid_search = GridSearchCV(clf, {'C': Cs}, scoring='accuracy') grid_search.fit(X, y) grid_search_no_score = GridSearchCV(clf_no_score, {'C': Cs}, scoring='accuracy') # smoketest grid search grid_search_no_score.fit(X, y) # check that best params are equal assert grid_search_no_score.best_params_ == grid_search.best_params_ # check that we can call score and that it gives the correct result assert grid_search.score(X, y) == grid_search_no_score.score(X, y) # giving no scoring function raises an error grid_search_no_score = GridSearchCV(clf_no_score, {'C': Cs}) assert_raise_message(TypeError, "no scoring", grid_search_no_score.fit, [[1]]) def test_grid_search_score_method(): X, y = make_classification(n_samples=100, n_classes=2, flip_y=.2, random_state=0) clf = LinearSVC(random_state=0) grid = {'C': [.1]} search_no_scoring = GridSearchCV(clf, grid, scoring=None).fit(X, y) search_accuracy = GridSearchCV(clf, grid, scoring='accuracy').fit(X, y) search_no_score_method_auc = GridSearchCV(LinearSVCNoScore(), grid, scoring='roc_auc' ).fit(X, y) search_auc = GridSearchCV(clf, grid, scoring='roc_auc').fit(X, y) # Check warning only occurs in situation where behavior changed: # estimator requires score method to compete with scoring parameter score_no_scoring = search_no_scoring.score(X, y) score_accuracy = search_accuracy.score(X, y) score_no_score_auc = search_no_score_method_auc.score(X, y) score_auc = search_auc.score(X, y) # ensure the test is sane assert score_auc < 1.0 assert score_accuracy < 1.0 assert score_auc != score_accuracy assert_almost_equal(score_accuracy, score_no_scoring) assert_almost_equal(score_auc, score_no_score_auc) def test_grid_search_groups(): # Check if ValueError (when groups is None) propagates to GridSearchCV # And also check if groups is correctly passed to the cv object rng = np.random.RandomState(0) X, y = make_classification(n_samples=15, n_classes=2, random_state=0) groups = rng.randint(0, 3, 15) clf = LinearSVC(random_state=0) grid = {'C': [1]} group_cvs = [LeaveOneGroupOut(), LeavePGroupsOut(2), GroupKFold(n_splits=3), GroupShuffleSplit()] for cv in group_cvs: gs = GridSearchCV(clf, grid, cv=cv) assert_raise_message(ValueError, "The 'groups' parameter should not be None.", gs.fit, X, y) gs.fit(X, y, groups=groups) non_group_cvs = [StratifiedKFold(), StratifiedShuffleSplit()] for cv in non_group_cvs: gs = GridSearchCV(clf, grid, cv=cv) # Should not raise an error gs.fit(X, y) def test_classes__property(): # Test that classes_ property matches best_estimator_.classes_ X = np.arange(100).reshape(10, 10) y = np.array([0] * 5 + [1] * 5) Cs = [.1, 1, 10] grid_search = GridSearchCV(LinearSVC(random_state=0), {'C': Cs}) grid_search.fit(X, y) assert_array_equal(grid_search.best_estimator_.classes_, grid_search.classes_) # Test that regressors do not have a classes_ attribute grid_search = GridSearchCV(Ridge(), {'alpha': [1.0, 2.0]}) grid_search.fit(X, y) assert not hasattr(grid_search, 'classes_') # Test that the grid searcher has no classes_ attribute before it's fit grid_search = GridSearchCV(LinearSVC(random_state=0), {'C': Cs}) assert not hasattr(grid_search, 'classes_') # Test that the grid searcher has no classes_ attribute without a refit grid_search = GridSearchCV(LinearSVC(random_state=0), {'C': Cs}, refit=False) grid_search.fit(X, y) assert not hasattr(grid_search, 'classes_') def test_trivial_cv_results_attr(): # Test search over a "grid" with only one point. clf = MockClassifier() grid_search = GridSearchCV(clf, {'foo_param': [1]}, cv=3) grid_search.fit(X, y) assert hasattr(grid_search, "cv_results_") random_search = RandomizedSearchCV(clf, {'foo_param': [0]}, n_iter=1, cv=3) random_search.fit(X, y) assert hasattr(grid_search, "cv_results_") def test_no_refit(): # Test that GSCV can be used for model selection alone without refitting clf = MockClassifier() for scoring in [None, ['accuracy', 'precision']]: grid_search = GridSearchCV( clf, {'foo_param': [1, 2, 3]}, refit=False, cv=3 ) grid_search.fit(X, y) assert not hasattr(grid_search, "best_estimator_") and \ hasattr(grid_search, "best_index_") and \ hasattr(grid_search, "best_params_") # Make sure the functions predict/transform etc raise meaningful # error messages for fn_name in ('predict', 'predict_proba', 'predict_log_proba', 'transform', 'inverse_transform'): assert_raise_message(NotFittedError, ('refit=False. %s is available only after ' 'refitting on the best parameters' % fn_name), getattr(grid_search, fn_name), X) # Test that an invalid refit param raises appropriate error messages for refit in ["", 5, True, 'recall', 'accuracy']: assert_raise_message(ValueError, "For multi-metric scoring, the " "parameter refit must be set to a scorer key", GridSearchCV(clf, {}, refit=refit, scoring={'acc': 'accuracy', 'prec': 'precision'} ).fit, X, y) def test_grid_search_error(): # Test that grid search will capture errors on data with different length X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) assert_raises(ValueError, cv.fit, X_[:180], y_) def test_grid_search_one_grid_point(): X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) param_dict = {"C": [1.0], "kernel": ["rbf"], "gamma": [0.1]} clf = SVC(gamma='auto') cv = GridSearchCV(clf, param_dict) cv.fit(X_, y_) clf = SVC(C=1.0, kernel="rbf", gamma=0.1) clf.fit(X_, y_) assert_array_equal(clf.dual_coef_, cv.best_estimator_.dual_coef_) def test_grid_search_when_param_grid_includes_range(): # Test that the best estimator contains the right value for foo_param clf = MockClassifier() grid_search = None grid_search = GridSearchCV(clf, {'foo_param': range(1, 4)}, cv=3) grid_search.fit(X, y) assert grid_search.best_estimator_.foo_param == 2 def test_grid_search_bad_param_grid(): param_dict = {"C": 1} clf = SVC(gamma='auto') assert_raise_message( ValueError, "Parameter grid for parameter (C) needs to" " be a list or numpy array, but got (<class 'int'>)." " Single values need to be wrapped in a list" " with one element.", GridSearchCV, clf, param_dict) param_dict = {"C": []} clf = SVC() assert_raise_message( ValueError, "Parameter values for parameter (C) need to be a non-empty sequence.", GridSearchCV, clf, param_dict) param_dict = {"C": "1,2,3"} clf = SVC(gamma='auto') assert_raise_message( ValueError, "Parameter grid for parameter (C) needs to" " be a list or numpy array, but got (<class 'str'>)." " Single values need to be wrapped in a list" " with one element.", GridSearchCV, clf, param_dict) param_dict = {"C": np.ones((3, 2))} clf = SVC() assert_raises(ValueError, GridSearchCV, clf, param_dict) def test_grid_search_sparse(): # Test that grid search works with both dense and sparse matrices X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) cv.fit(X_[:180], y_[:180]) y_pred = cv.predict(X_[180:]) C = cv.best_estimator_.C X_ = sp.csr_matrix(X_) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) cv.fit(X_[:180].tocoo(), y_[:180]) y_pred2 = cv.predict(X_[180:]) C2 = cv.best_estimator_.C assert np.mean(y_pred == y_pred2) >= .9 assert C == C2 def test_grid_search_sparse_scoring(): X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}, scoring="f1") cv.fit(X_[:180], y_[:180]) y_pred = cv.predict(X_[180:]) C = cv.best_estimator_.C X_ = sp.csr_matrix(X_) clf = LinearSVC() cv = GridSearchCV(clf, {'C': [0.1, 1.0]}, scoring="f1") cv.fit(X_[:180], y_[:180]) y_pred2 = cv.predict(X_[180:]) C2 = cv.best_estimator_.C assert_array_equal(y_pred, y_pred2) assert C == C2 # Smoke test the score # np.testing.assert_allclose(f1_score(cv.predict(X_[:180]), y[:180]), # cv.score(X_[:180], y[:180])) # test loss where greater is worse def f1_loss(y_true_, y_pred_): return -f1_score(y_true_, y_pred_) F1Loss = make_scorer(f1_loss, greater_is_better=False) cv = GridSearchCV(clf, {'C': [0.1, 1.0]}, scoring=F1Loss) cv.fit(X_[:180], y_[:180]) y_pred3 = cv.predict(X_[180:]) C3 = cv.best_estimator_.C assert C == C3 assert_array_equal(y_pred, y_pred3) def test_grid_search_precomputed_kernel(): # Test that grid search works when the input features are given in the # form of a precomputed kernel matrix X_, y_ = make_classification(n_samples=200, n_features=100, random_state=0) # compute the training kernel matrix corresponding to the linear kernel K_train = np.dot(X_[:180], X_[:180].T) y_train = y_[:180] clf = SVC(kernel='precomputed') cv = GridSearchCV(clf, {'C': [0.1, 1.0]}) cv.fit(K_train, y_train) assert cv.best_score_ >= 0 # compute the test kernel matrix K_test = np.dot(X_[180:], X_[:180].T) y_test = y_[180:] y_pred = cv.predict(K_test) assert np.mean(y_pred == y_test) >= 0 # test error is raised when the precomputed kernel is not array-like # or sparse assert_raises(ValueError, cv.fit, K_train.tolist(), y_train) def test_grid_search_precomputed_kernel_error_nonsquare(): # Test that grid search returns an error with a non-square precomputed # training kernel matrix K_train =

np.zeros((10, 20))

numpy.zeros

from abc import ABCMeta, abstractmethod import os from vmaf.tools.misc import make_absolute_path, run_process from vmaf.tools.stats import ListStats __copyright__ = "Copyright 2016-2018, Netflix, Inc." __license__ = "Apache, Version 2.0" import re import numpy as np import ast from vmaf import ExternalProgramCaller, to_list from vmaf.config import VmafConfig, VmafExternalConfig from vmaf.core.executor import Executor from vmaf.core.result import Result from vmaf.tools.reader import YuvReader class FeatureExtractor(Executor): """ FeatureExtractor takes in a list of assets, and run feature extraction on them, and return a list of corresponding results. A FeatureExtractor must specify a unique type and version combination (by the TYPE and VERSION attribute), so that the Result generated by it can be identified. A derived class of FeatureExtractor must: 1) Override TYPE and VERSION 2) Override _generate_result(self, asset), which call a command-line executable and generate feature scores in a log file. 3) Override _get_feature_scores(self, asset), which read the feature scores from the log file, and return the scores in a dictionary format. For an example, follow VmafFeatureExtractor. """ __metaclass__ = ABCMeta @property @abstractmethod def ATOM_FEATURES(self): raise NotImplementedError def _read_result(self, asset): result = {} result.update(self._get_feature_scores(asset)) executor_id = self.executor_id return Result(asset, executor_id, result) @classmethod def get_scores_key(cls, atom_feature): return "{type}_{atom_feature}_scores".format( type=cls.TYPE, atom_feature=atom_feature) @classmethod def get_score_key(cls, atom_feature): return "{type}_{atom_feature}_score".format( type=cls.TYPE, atom_feature=atom_feature) def _get_feature_scores(self, asset): # routine to read the feature scores from the log file, and return # the scores in a dictionary format. log_file_path = self._get_log_file_path(asset) atom_feature_scores_dict = {} atom_feature_idx_dict = {} for atom_feature in self.ATOM_FEATURES: atom_feature_scores_dict[atom_feature] = [] atom_feature_idx_dict[atom_feature] = 0 with open(log_file_path, 'rt') as log_file: for line in log_file.readlines(): for atom_feature in self.ATOM_FEATURES: re_template = "{af}: ([0-9]+) ([a-zA-Z0-9.-]+)".format(af=atom_feature) mo = re.match(re_template, line) if mo: cur_idx = int(mo.group(1)) assert cur_idx == atom_feature_idx_dict[atom_feature] # parse value, allowing NaN and inf val = float(mo.group(2)) if np.isnan(val) or np.isinf(val): val = None atom_feature_scores_dict[atom_feature].append(val) atom_feature_idx_dict[atom_feature] += 1 continue len_score = len(atom_feature_scores_dict[self.ATOM_FEATURES[0]]) assert len_score != 0 for atom_feature in self.ATOM_FEATURES[1:]: assert len_score == len(atom_feature_scores_dict[atom_feature]), \ "Feature data possibly corrupt. Run cleanup script and try again." feature_result = {} for atom_feature in self.ATOM_FEATURES: scores_key = self.get_scores_key(atom_feature) feature_result[scores_key] = atom_feature_scores_dict[atom_feature] return feature_result class VmafFeatureExtractor(FeatureExtractor): TYPE = "VMAF_feature" # VERSION = '0.1' # vmaf_study; Anush's VIF fix # VERSION = '0.2' # expose vif_num, vif_den, adm_num, adm_den, anpsnr # VERSION = '0.2.1' # expose vif num/den of each scale # VERSION = '0.2.2' # adm abs-->fabs, corrected border handling, uniform reading with option of offset for input YUV, updated VIF corner case # VERSION = '0.2.2b' # expose adm_den/num_scalex # VERSION = '0.2.3' # AVX for VMAF convolution; update adm features by folding noise floor into per coef # VERSION = '0.2.4' # Fix a bug in adm feature passing scale into dwt_quant_step # VERSION = '0.2.4b' # Modify by adding ADM noise floor outside cube root; add derived feature motion2 VERSION = '0.2.4c' # Modify by moving motion2 to c code ATOM_FEATURES = ['vif', 'adm', 'ansnr', 'motion', 'motion2', 'vif_num', 'vif_den', 'adm_num', 'adm_den', 'anpsnr', 'vif_num_scale0', 'vif_den_scale0', 'vif_num_scale1', 'vif_den_scale1', 'vif_num_scale2', 'vif_den_scale2', 'vif_num_scale3', 'vif_den_scale3', 'adm_num_scale0', 'adm_den_scale0', 'adm_num_scale1', 'adm_den_scale1', 'adm_num_scale2', 'adm_den_scale2', 'adm_num_scale3', 'adm_den_scale3', ] DERIVED_ATOM_FEATURES = ['vif_scale0', 'vif_scale1', 'vif_scale2', 'vif_scale3', 'vif2', 'adm2', 'adm3', 'adm_scale0', 'adm_scale1', 'adm_scale2', 'adm_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vmaf_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VmafFeatureExtractor, cls)._post_process_result(result) # adm2 = # (adm_num + ADM2_CONSTANT) / (adm_den + ADM2_CONSTANT) adm2_scores_key = cls.get_scores_key('adm2') adm_num_scores_key = cls.get_scores_key('adm_num') adm_den_scores_key = cls.get_scores_key('adm_den') result.result_dict[adm2_scores_key] = list( (np.array(result.result_dict[adm_num_scores_key]) + cls.ADM2_CONSTANT) / (np.array(result.result_dict[adm_den_scores_key]) + cls.ADM2_CONSTANT) ) # vif_scalei = vif_num_scalei / vif_den_scalei, i = 0, 1, 2, 3 vif_num_scale0_scores_key = cls.get_scores_key('vif_num_scale0') vif_den_scale0_scores_key = cls.get_scores_key('vif_den_scale0') vif_num_scale1_scores_key = cls.get_scores_key('vif_num_scale1') vif_den_scale1_scores_key = cls.get_scores_key('vif_den_scale1') vif_num_scale2_scores_key = cls.get_scores_key('vif_num_scale2') vif_den_scale2_scores_key = cls.get_scores_key('vif_den_scale2') vif_num_scale3_scores_key = cls.get_scores_key('vif_num_scale3') vif_den_scale3_scores_key = cls.get_scores_key('vif_den_scale3') vif_scale0_scores_key = cls.get_scores_key('vif_scale0') vif_scale1_scores_key = cls.get_scores_key('vif_scale1') vif_scale2_scores_key = cls.get_scores_key('vif_scale2') vif_scale3_scores_key = cls.get_scores_key('vif_scale3') result.result_dict[vif_scale0_scores_key] = list( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) ) result.result_dict[vif_scale1_scores_key] = list( (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) ) result.result_dict[vif_scale2_scores_key] = list( (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) ) result.result_dict[vif_scale3_scores_key] = list( (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) # vif2 = # ((vif_num_scale0 / vif_den_scale0) + (vif_num_scale1 / vif_den_scale1) + # (vif_num_scale2 / vif_den_scale2) + (vif_num_scale3 / vif_den_scale3)) / 4.0 vif_scores_key = cls.get_scores_key('vif2') result.result_dict[vif_scores_key] = list( ( (np.array(result.result_dict[vif_num_scale0_scores_key]) / np.array(result.result_dict[vif_den_scale0_scores_key])) + (np.array(result.result_dict[vif_num_scale1_scores_key]) / np.array(result.result_dict[vif_den_scale1_scores_key])) + (np.array(result.result_dict[vif_num_scale2_scores_key]) / np.array(result.result_dict[vif_den_scale2_scores_key])) + (np.array(result.result_dict[vif_num_scale3_scores_key]) / np.array(result.result_dict[vif_den_scale3_scores_key])) ) / 4.0 ) # adm_scalei = adm_num_scalei / adm_den_scalei, i = 0, 1, 2, 3 adm_num_scale0_scores_key = cls.get_scores_key('adm_num_scale0') adm_den_scale0_scores_key = cls.get_scores_key('adm_den_scale0') adm_num_scale1_scores_key = cls.get_scores_key('adm_num_scale1') adm_den_scale1_scores_key = cls.get_scores_key('adm_den_scale1') adm_num_scale2_scores_key = cls.get_scores_key('adm_num_scale2') adm_den_scale2_scores_key = cls.get_scores_key('adm_den_scale2') adm_num_scale3_scores_key = cls.get_scores_key('adm_num_scale3') adm_den_scale3_scores_key = cls.get_scores_key('adm_den_scale3') adm_scale0_scores_key = cls.get_scores_key('adm_scale0') adm_scale1_scores_key = cls.get_scores_key('adm_scale1') adm_scale2_scores_key = cls.get_scores_key('adm_scale2') adm_scale3_scores_key = cls.get_scores_key('adm_scale3') result.result_dict[adm_scale0_scores_key] = list( (np.array(result.result_dict[adm_num_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale1_scores_key] = list( (np.array(result.result_dict[adm_num_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale2_scores_key] = list( (np.array(result.result_dict[adm_num_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) ) result.result_dict[adm_scale3_scores_key] = list( (np.array(result.result_dict[adm_num_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) ) # adm3 = \ # (((adm_num_scale0 + ADM_SCALE_CONSTANT) / (adm_den_scale0 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale1 + ADM_SCALE_CONSTANT) / (adm_den_scale1 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale2 + ADM_SCALE_CONSTANT) / (adm_den_scale2 + ADM_SCALE_CONSTANT)) # + ((adm_num_scale3 + ADM_SCALE_CONSTANT) / (adm_den_scale3 + ADM_SCALE_CONSTANT))) / 4.0 adm3_scores_key = cls.get_scores_key('adm3') result.result_dict[adm3_scores_key] = list( ( ((np.array(result.result_dict[adm_num_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale0_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale1_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale2_scores_key]) + cls.ADM_SCALE_CONSTANT)) + ((np.array(result.result_dict[adm_num_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT) / (np.array(result.result_dict[adm_den_scale3_scores_key]) + cls.ADM_SCALE_CONSTANT)) ) / 4.0 ) # validate for feature in cls.DERIVED_ATOM_FEATURES: assert cls.get_scores_key(feature) in result.result_dict return result class VifFrameDifferenceFeatureExtractor(FeatureExtractor): TYPE = "VifDiff_feature" VERSION = '0.1' ATOM_FEATURES = ['vifdiff', 'vifdiff_num', 'vifdiff_den', 'vifdiff_num_scale0', 'vifdiff_den_scale0', 'vifdiff_num_scale1', 'vifdiff_den_scale1', 'vifdiff_num_scale2', 'vifdiff_den_scale2', 'vifdiff_num_scale3', 'vifdiff_den_scale3', ] DERIVED_ATOM_FEATURES = ['vifdiff_scale0', 'vifdiff_scale1', 'vifdiff_scale2', 'vifdiff_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vifdiff_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VifFrameDifferenceFeatureExtractor, cls)._post_process_result(result) # vifdiff_scalei = vifdiff_num_scalei / vifdiff_den_scalei, i = 0, 1, 2, 3 vifdiff_num_scale0_scores_key = cls.get_scores_key('vifdiff_num_scale0') vifdiff_den_scale0_scores_key = cls.get_scores_key('vifdiff_den_scale0') vifdiff_num_scale1_scores_key = cls.get_scores_key('vifdiff_num_scale1') vifdiff_den_scale1_scores_key = cls.get_scores_key('vifdiff_den_scale1') vifdiff_num_scale2_scores_key = cls.get_scores_key('vifdiff_num_scale2') vifdiff_den_scale2_scores_key = cls.get_scores_key('vifdiff_den_scale2') vifdiff_num_scale3_scores_key = cls.get_scores_key('vifdiff_num_scale3') vifdiff_den_scale3_scores_key = cls.get_scores_key('vifdiff_den_scale3') vifdiff_scale0_scores_key = cls.get_scores_key('vifdiff_scale0') vifdiff_scale1_scores_key = cls.get_scores_key('vifdiff_scale1') vifdiff_scale2_scores_key = cls.get_scores_key('vifdiff_scale2') vifdiff_scale3_scores_key = cls.get_scores_key('vifdiff_scale3') result.result_dict[vifdiff_scale0_scores_key] = list( (np.array(result.result_dict[vifdiff_num_scale0_scores_key]) / np.array(result.result_dict[vifdiff_den_scale0_scores_key])) ) result.result_dict[vifdiff_scale1_scores_key] = list( (

np.array(result.result_dict[vifdiff_num_scale1_scores_key])

numpy.array

import gym import numpy as np from itertools import product import matplotlib.pyplot as plt def print_policy(Q, env): """ This is a helper function to print a nice policy from the Q function""" moves = [u'←', u'↓',u'→', u'↑'] if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape policy = np.chararray(dims, unicode=True) policy[:] = ' ' for s in range(len(Q)): idx = np.unravel_index(s, dims) policy[idx] = moves[np.argmax(Q[s])] if env.desc[idx] in ['H', 'G']: policy[idx] = u'·' print('\n'.join([''.join([u'{:2}'.format(item) for item in row]) for row in policy])) def plot_V(Q, env): """ This is a helper function to plot the state values from the Q function""" fig = plt.figure() if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape V = np.zeros(dims) for s in range(len(Q)): idx = np.unravel_index(s, dims) V[idx] = np.max(Q[s]) if env.desc[idx] in ['H', 'G']: V[idx] = 0. plt.imshow(V, origin='upper', extent=[0,dims[0],0,dims[1]], vmin=.0, vmax=.6, cmap=plt.cm.RdYlGn, interpolation='none') for x, y in product(range(dims[0]), range(dims[1])): plt.text(y+0.5, dims[0]-x-0.5, '{:.3f}'.format(V[x,y]), horizontalalignment='center', verticalalignment='center') plt.xticks([]) plt.yticks([]) def plot_Q(Q, env): """ This is a helper function to plot the Q function """ from matplotlib import colors, patches fig = plt.figure() ax = fig.gca() if not hasattr(env, 'desc'): env = env.env dims = env.desc.shape up = np.array([[0, 1], [0.5, 0.5], [1,1]]) down = np.array([[0, 0], [0.5, 0.5], [1,0]]) left = np.array([[0, 0], [0.5, 0.5], [0,1]]) right = np.array([[1, 0], [0.5, 0.5], [1,1]]) tri = [left, down, right, up] pos = [[0.2, 0.5], [0.5, 0.2], [0.8, 0.5], [0.5, 0.8]] cmap = plt.cm.RdYlGn norm = colors.Normalize(vmin=.0,vmax=.6) ax.imshow(np.zeros(dims), origin='upper', extent=[0,dims[0],0,dims[1]], vmin=.0, vmax=.6, cmap=cmap) ax.grid(which='major', color='black', linestyle='-', linewidth=2) for s in range(len(Q)): idx = np.unravel_index(s, dims) x, y = idx if env.desc[idx] in ['H', 'G']: ax.add_patch(patches.Rectangle((y, 3-x), 1, 1, color=cmap(.0))) plt.text(y+0.5, dims[0]-x-0.5, '{:.2f}'.format(.0), horizontalalignment='center', verticalalignment='center') continue for a in range(len(tri)): ax.add_patch(patches.Polygon(tri[a] + np.array([y, 3-x]), color=cmap(Q[s][a]))) plt.text(y+pos[a][0], dims[0]-1-x+pos[a][1], '{:.2f}'.format(Q[s][a]), horizontalalignment='center', verticalalignment='center', fontsize=9, fontweight=('bold' if Q[s][a] ==

np.max(Q[s])

numpy.max

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100),

np.linspace(-2.75, 2.75, 100)

numpy.linspace

import io import logging import json import numpy import torch import numpy as np from tqdm import tqdm from clie.inputters import constant from clie.objects import Sentence from torch.utils.data import Dataset from torch.utils.data.sampler import Sampler logger = logging.getLogger(__name__) def load_word_embeddings(file): embeddings_index = {} fin = io.open(file, 'r', encoding='utf-8', newline='\n', errors='ignore') n, d = map(int, fin.readline().split()) for i, line in tqdm(enumerate(fin), total=n): tokens = line.rstrip().split(' ') v = numpy.array(tokens[1:], dtype=float) embeddings_index[tokens[0]] = v return embeddings_index # ------------------------------------------------------------------------------ # Data loading # ------------------------------------------------------------------------------ def load_data(filename, src_lang, tgt_lang, knn_file, knn_size, max_examples=-1): examples = [] wrong_subj_pos, wrong_obj_pos = 0, 0 with open(filename) as f: data = json.load(f) knn_dict = None if knn_file: with open(knn_file) as f: knn_dict = json.load(f) for idx, ex in enumerate(tqdm(data, total=len(data))): sentence = Sentence(ex['id']) sentence.language = src_lang sentence.words = ex['token'] sentence.pos = ex['stanford_pos'] sentence.ner = ex['stanford_ner'] sentence.deprel = ex['stanford_deprel'] sentence.head = [int(x) for x in ex['stanford_head']] sentence.subj_type = ex['subj_type'] sentence.obj_type = ex['obj_type'] sentence.relation = ex['relation'] if ex['subj_end'] - ex['subj_start'] < 0: # we swap the start and end index wrong_subj_pos += 1 sentence.subject = [ex['subj_end'], ex['subj_start']] else: sentence.subject = [ex['subj_start'], ex['subj_end']] if ex['obj_end'] - ex['obj_start'] < 0: # we swap the start and end index wrong_obj_pos += 1 sentence.object = [ex['obj_end'], ex['obj_start']] else: sentence.object = [ex['obj_start'], ex['obj_end']] # store KNN word info if knn_dict: sentence.tgt_lang = tgt_lang knn_words = [] for w in ex['token']: w = '!{}_{}'.format(src_lang, w) if w in knn_dict: assert len(knn_dict[w]) == knn_size knn_words.append(knn_dict[w]) else: knn_words.append([constant.UNK_WORD] * knn_size) sentence.knn_words = knn_words examples.append(sentence) if max_examples != -1 and len(examples) > max_examples: break if wrong_subj_pos > 0 or wrong_obj_pos > 0: logger.info('{} and {} wrong subject and object positions found!'.format( wrong_subj_pos, wrong_obj_pos)) return examples def vectorize(ex, model, iseval): """Torchify a single example.""" words = ['!{}_{}'.format(ex.language, w) for w in ex.words] words = [model.word_dict[w] for w in words] knn_word = None if ex.knn_words: knn_word = [[model.word_dict[w] for w in knn] for knn in ex.knn_words] knn_word = torch.LongTensor(knn_word) word = torch.LongTensor(words) pos = torch.LongTensor([model.pos_dict[p] for p in ex.pos]) ner = torch.LongTensor([model.ner_dict[n] for n in ex.ner]) deprel = torch.LongTensor([model.deprel_dict[d] for d in ex.deprel]) assert any([x == 0 for x in ex.head]) head = torch.LongTensor(ex.head) subj_position = torch.LongTensor(ex.subj_position) obj_position = torch.LongTensor(ex.obj_position) type = [0] * len(ex.words) ttype = model.type_dict[ex.subj_type] start, end = ex.subject type[start: end + 1] = [ttype] * (end - start + 1) atype = model.type_dict[ex.obj_type] start, end = ex.object type[start: end + 1] = [atype] * (end - start + 1) type = torch.LongTensor(type) return { 'id': ex.id, 'language': ex.language, 'word': word, 'pos': pos, 'ner': ner, 'deprel': deprel, 'type': type, 'head': head, 'subject': ex.subj_text, 'object': ex.obj_text, 'subject_pos': subj_position, 'object_pos': obj_position, 'relation': model.label_dict[ex.relation], 'knn_word': knn_word } def batchify(batch): """Gather a batch of individual examples into one batch.""" # batch is a list of vectorized examples batch_size = len(batch) ids = [ex['id'] for ex in batch] language = [ex['language'] for ex in batch] use_knn = batch[0]['knn_word'] is not None # NOTE. batch[0]['knn_word'] is a 2d list knn_size = len(batch[0]['knn_word'][0]) if use_knn else 0 # --------- Prepare Code tensors --------- max_len = max([ex['word'].size(0) for ex in batch]) # Batch Code Representations len_rep = torch.LongTensor(batch_size).fill_(constant.PAD) word_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) head_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) subject_pos_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) object_pos_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) pos_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) ner_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) deprel_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) type_rep = torch.LongTensor(batch_size, max_len).fill_(constant.PAD) labels = torch.LongTensor(batch_size) subject = [] object = [] knn_rep = None if use_knn: knn_rep = torch.LongTensor(batch_size, max_len, knn_size).fill_(constant.PAD) for i, ex in enumerate(batch): len_rep[i] = ex['word'].size(0) labels[i] = ex['relation'] word_rep[i, :len_rep[i]] = ex['word'] head_rep[i, :len_rep[i]] = ex['head'] subject_pos_rep[i, :len_rep[i]] = ex['subject_pos'] object_pos_rep[i, :len_rep[i]] = ex['object_pos'] pos_rep[i, :len_rep[i]] = ex['pos'] ner_rep[i, :len_rep[i]] = ex['ner'] deprel_rep[i, :len_rep[i]] = ex['deprel'] type_rep[i, :len_rep[i]] = ex['type'] subject.append(ex['subject']) object.append(ex['object']) if use_knn: knn_rep[i, :len_rep[i]] = ex['knn_word'] return { 'ids': ids, 'language': language, 'batch_size': batch_size, 'len_rep': len_rep, 'word_rep': word_rep, 'knn_rep': knn_rep, 'head_rep': head_rep, 'subject': subject, 'object': object, 'subject_pos_rep': subject_pos_rep, 'object_pos_rep': object_pos_rep, 'labels': labels, 'pos_rep': pos_rep, 'ner_rep': ner_rep, 'deprel_rep': deprel_rep, 'type_rep': type_rep } class ACE05Dataset(Dataset): def __init__(self, examples, model, evaluation=False): self.model = model self.examples = examples self.evaluation = evaluation def __len__(self): return len(self.examples) def __getitem__(self, index): return vectorize(self.examples[index], self.model, iseval=self.evaluation) def lengths(self): return [len(ex.words) for ex in self.examples] class SortedBatchSampler(Sampler): def __init__(self, lengths, batch_size, shuffle=True): self.lengths = lengths self.batch_size = batch_size self.shuffle = shuffle def __iter__(self): lengths = np.array( [(-l, np.random.random()) for l in self.lengths], dtype=[('l1', np.int_), ('rand', np.float_)] ) indices = np.argsort(lengths, order=('l1', 'rand')) batches = [indices[i:i + self.batch_size] for i in range(0, len(indices), self.batch_size)] if self.shuffle:

np.random.shuffle(batches)

numpy.random.shuffle

from __future__ import print_function import numpy as np import matplotlib.pyplot as plt class TwoLayerNet(object): """ A two-layer fully-connected neural network. The net has an input dimension of N, a hidden layer dimension of H, and performs classification over C classes. We train the network with a softmax loss function and L2 regularization on the weight matrices. The network uses a ReLU nonlinearity after the first fully connected layer. In other words, the network has the following architecture: input - fully connected layer - ReLU - fully connected layer - softmax The outputs of the second fully-connected layer are the scores for each class. """ def __init__(self, input_size, hidden_size, output_size, std=1e-4): """ Initialize the model. Weights are initialized to small random values and biases are initialized to zero. Weights and biases are stored in the variable self.params, which is a dictionary with the following keys W1: First layer weights; has shape (D, H) b1: First layer biases; has shape (H,) W2: Second layer weights; has shape (H, C) b2: Second layer biases; has shape (C,) Inputs: - input_size: The dimension D of the input data. - hidden_size: The number of neurons H in the hidden layer. - output_size: The number of classes C. """ self.params = {} self.params['W1'] = std * np.random.randn(input_size, hidden_size) self.params['b1'] = np.zeros(hidden_size) self.params['W2'] = std * np.random.randn(hidden_size, output_size) self.params['b2'] = np.zeros(output_size) def loss(self, X, y=None, reg=0.0): """ Compute the loss and gradients for a two layer fully connected neural network. Inputs: - X: Input data of shape (N, D). Each X[i] is a training sample. - y: Vector of training labels. y[i] is the label for X[i], and each y[i] is an integer in the range 0 <= y[i] < C. This parameter is optional; if it is not passed then we only return scores, and if it is passed then we instead return the loss and gradients. - reg: Regularization strength. Returns: If y is None, return a matrix scores of shape (N, C) where scores[i, c] is the score for class c on input X[i]. If y is not None, instead return a tuple of: - loss: Loss (data loss and regularization loss) for this batch of training samples. - grads: Dictionary mapping parameter names to gradients of those parameters with respect to the loss function; has the same keys as self.params. """ # Unpack variables from the params dictionary W1, b1 = self.params['W1'], self.params['b1'] W2, b2 = self.params['W2'], self.params['b2'] N, D = X.shape # Compute the forward pass scores = None ####################################################################### # TODO: Perform the forward pass, computing the class scores for the # # input. Store the result in the scores variable, which should be an # # array of shape (N, C). # ####################################################################### scores1 = X.dot(W1) + b1 # FC1 X2 = np.maximum(0, scores1) # ReLU FC1 scores = X2.dot(W2) + b2 # FC2 ####################################################################### # END OF YOUR CODE # ####################################################################### # If the targets are not given then jump out, we're done if y is None: return scores scores -= np.max(scores) # Fix Number instability scores_exp = np.exp(scores) probs = scores_exp / np.sum(scores_exp, axis=1, keepdims=True) # Compute the loss loss = None ####################################################################### # TODO: Finish the forward pass, and compute the loss. This should # # include both the data loss and L2 regularization for W1 and W2. # # Store the result in the variable loss, which should be a scalar. Use# # the Softmax classifier loss. # ####################################################################### correct_probs = -np.log(probs[np.arange(N), y]) # L_i = -log(e^correct_score/sum(e^scores))) = -log(correct_probs) loss =

np.sum(correct_probs)

numpy.sum

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k') plt.plot(((time[-202] + time[-201]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed', label=textwrap.fill('Neural network targets', 13)) plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(((time_extended[-1001] + time_extended[-1000]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed') plt.xlim(3.4 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/neural_network.png') plt.show() # plot 6a np.random.seed(0) time = np.linspace(0, 5 * np.pi, 1001) knots_51 = np.linspace(0, 5 * np.pi, 51) time_series = np.cos(2 * time) + np.cos(4 * time) +

np.cos(8 * time)

numpy.cos

# -*- coding: utf-8 -*- """ Script to execute example covarying MMGP regression forecasting model with full Krhh. Inputs: Data training and test sets (dictionary pickle) Data for example: - normalised solar data for 25 sites for 15 minute forecast - N_train = 4200, N_test = 2276, P = 25, D = 51 - Xtr[:, :50] 2 recent lagged observations for each site in order - Xtr[:, 50] time index - link inputs is a 25x2 array (link inputs repeated for every group) with normalised lat,long for each site in order Model Options: - Sparse or full x-function covariance prior Krhh (set bool SPARSE_PRIOR) - Diagonal or Kronecker-structured variational posterior covariance Sr (set bool DIAG_POST) - Sparse or full posterior covariance (when Kronecker posterior; set bool SPARSE_POST) Current Settings (sparse covarying mmgp model with sparse Kronecker posterior): DIAG_POST = False SPARSE_PRIOR = False # set True for equivalent sparse scmmgp model SPARSE_POST = True Note on specifying group structure for F: Grouping occurs via block_struct, a nested list of grouping order Where functions [i] are independent i.e. in own block, set link_kernel[i] = link_inputs[i] = 1.0 See model class preamble and example below for further details. """ import os import numpy as np import pickle import pandas as pd import traceback import time import sklearn.cluster import csv import sys import mmgp from mmgp import likelihoods from mmgp import kernels import tensorflow as tf from mmgp import datasets from mmgp import losses from mmgp import util dpath = '/experiments/datasets/' dfile = 'p25_inputsdict.pickle' dlinkfile = 'p25_linkinputsarray.pickle' outdir = '/experiments/results/p25_nonsparse_cmmgp/' try: os.makedirs(outdir) except FileExistsError: pass def get_inputs(): """ inputsdict contains {'Yte': Yte, 'Ytr': Ytr, 'Xtr': Xtr, 'Xte': Xte} where values are np.arrays np. arrays are truncated to evenly split into batches of size = batchsize returns inputsdict, Xtr_link (ndarray, shape = [P, D_link_features]) """ with open(os.path.join(dpath, dfile), 'rb') as f: d_all = pickle.load(f) with open(os.path.join(dpath, dlinkfile), 'rb') as f: d_link = pickle.load(f) return d_all, d_link def init_z(train_inputs, num_inducing): # Initialize inducing points using clustering. mini_batch = sklearn.cluster.MiniBatchKMeans(num_inducing) cluster_indices = mini_batch.fit_predict(train_inputs) inducing_locations = mini_batch.cluster_centers_ return inducing_locations FLAGS = util.util.get_flags() BATCH_SIZE = FLAGS.batch_size LEARNING_RATE = FLAGS.learning_rate DISPLAY_STEP = FLAGS.display_step EPOCHS = FLAGS.n_epochs NUM_SAMPLES = FLAGS.mc_train PRED_SAMPLES = FLAGS.mc_test NUM_INDUCING = FLAGS.n_inducing NUM_COMPONENTS = FLAGS.num_components IS_ARD = FLAGS.is_ard TOL = FLAGS.opt_tol VAR_STEPS = FLAGS.var_steps DIAG_POST = False SPARSE_PRIOR = False SPARSE_POST = True # option for non-diag post MAXTIME = 1200 print("settings done") # define GPRN P and Q output_dim = 25 #P node_dim = 25 #Q lag_dim = 2 save_nlpds = False # If True saves samples of nlpds for n,p,s # extract dataset d, d_link = get_inputs() Ytr, Yte, Xtr, Xte = d['Ytr'], d['Yte'], d['Xtr'], d['Xte'] data = datasets.DataSet(Xtr.astype(np.float32), Ytr.astype(np.float32), shuffle=False) test = datasets.DataSet(Xte.astype(np.float32), Yte.astype(np.float32), shuffle=False) print("dataset created") # model config block rows (where P=Q): block all w.1, w.2 etc, leave f independent # order of block_struct is rows, node functions # lists required: block_struct, link_inputs, kern_link, kern #block_struct nested list of grouping order weight_struct = [[] for _ in range(output_dim)] for i in range(output_dim): row = list(range(i, i+output_dim*(node_dim-1)+1, output_dim)) row_0 = row.pop(i) # bring diag to pivot position weight_struct[i] = [row_0] + row nodes = [[x] for x in list(range(output_dim * node_dim, output_dim * node_dim + output_dim))] block_struct = weight_struct + nodes # create link inputs (link inputs used repeatedly but can have link input per group) # permute to bring diagonal to first position link_inputs = [[] for _ in range(output_dim)] for i in range(output_dim): idx = list(range(d_link.shape[0])) link_inputs[i] = d_link[[idx.pop(i)] + idx, :] link_inputs = link_inputs + [1.0 for i in range(output_dim)] # for full W row blocks, independent nodes # create 'between' kernel list klink_rows = [kernels.CompositeKernel('mul',[kernels.RadialBasis(2, std_dev=2.0, lengthscale=1.0, white=0.01, input_scaling = IS_ARD), kernels.CompactSlice(2, active_dims=[0,1], lengthscale = 2.0, input_scaling = IS_ARD)] ) for i in range(output_dim) ] klink_f = [1.0 for i in range(node_dim)] kernlink = klink_rows + klink_f # create 'within' kernel # kern lag_active_dims_s = [ [] for _ in range(output_dim)] for i in range(output_dim): lag_active_dims_s[i] = list(range(lag_dim*i, lag_dim*(i+1))) k_rows = [kernels.CompositeKernel('mul',[kernels.RadialBasisSlice(lag_dim, active_dims=lag_active_dims_s[i], std_dev = 1.0, white = 0.01, input_scaling = IS_ARD), kernels.PeriodicSliceFixed(1, active_dims=[Xtr.shape[1]-1], lengthscale=0.5, std_dev=1.0, period = 144) ]) for i in range(output_dim)] k_f = [kernels.RadialBasisSlice(lag_dim, active_dims=lag_active_dims_s[i], std_dev = 1.0, white = 0.01, input_scaling = IS_ARD) for i in range(output_dim)] kern = k_rows + k_f print('len link_inputs ',len(link_inputs)) print('len kernlink ',len(kernlink)) print('len kern ', len(kern)) print('no. groups = ', len(block_struct), 'no. latent functions =', len([i for b in block_struct for i in b])) print('number latent functions', node_dim*(output_dim+1)) likelihood = likelihoods.CovaryingRegressionNetwork(output_dim, node_dim, std_dev = 0.2) # p, q, lik_noise print("likelihood and kernels set") Z = init_z(data.X, NUM_INDUCING) print('inducing points set') m = mmgp.ExplicitSCMMGP(output_dim, likelihood, kern, kernlink, block_struct, Z, link_inputs, num_components=NUM_COMPONENTS, diag_post=DIAG_POST, sparse_prior=SPARSE_PRIOR, sparse_post=SPARSE_POST, num_samples=NUM_SAMPLES, predict_samples=PRED_SAMPLES) print("model set") # initialise losses and logging error_rate = losses.RootMeanSqError(data.Dout) os.chdir(outdir) with open("log_results.csv", 'w', newline='') as f: csv.writer(f).writerow(['epoch', 'fit_runtime', 'nelbo', error_rate.get_name(),'generalised_nlpd']) with open("log_params.csv", 'w', newline='') as f: csv.writer(f).writerow(['epoch', 'raw_kernel_params', 'raw_kernlink_params', 'raw_likelihood_params', 'raw_weights']) with open("log_comp_time.csv", 'w', newline='') as f: csv.writer(f).writerow(['epoch', 'batch_time', 'nelbo_time', 'pred_time', 'gen_nlpd_time', error_rate.get_name()+'_time']) # optimise o = tf.train.AdamOptimizer(LEARNING_RATE, beta1=0.9,beta2=0.99) print("start time = ", time.strftime('%X %x %Z')) m.fit(data, o, var_steps = VAR_STEPS, epochs = EPOCHS, batch_size = BATCH_SIZE, display_step=DISPLAY_STEP, test = test, loss = error_rate, tolerance = TOL, max_time=MAXTIME ) print("optimisation complete") # export final predicted values and loss metrics ypred = m.predict(test.X, batch_size = BATCH_SIZE) #same batchsize used for convenience np.savetxt("predictions.csv", np.concatenate(ypred, axis=1), delimiter=",") if save_nlpds == True: nlpd_samples, nlpd_meanvar = m.nlpd_samples(test.X, test.Y, batch_size = BATCH_SIZE) try:

np.savetxt("nlpd_meanvar.csv", nlpd_meanvar, delimiter=",")

numpy.savetxt

# pvtrace is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 3 of the License, or # (at your option) any later version. # # pvtrace is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see <http://www.gnu.org/licenses/>. import numpy as np from external.transformations import translation_matrix, rotation_matrix import external.transformations as tf from Trace import Photon from Geometry import Box, Cylinder, FinitePlane, transform_point, transform_direction, rotation_matrix_from_vector_alignment, norm from Materials import Spectrum def random_spherecial_vector(): # This method of calculating isotropic vectors is taken from GNU Scientific Library LOOP = True while LOOP: x = -1. + 2. * np.random.uniform() y = -1. + 2. * np.random.uniform() s = x**2 + y**2 if s <= 1.0: LOOP = False z = -1. + 2. * s a = 2 * np.sqrt(1 - s) x = a * x y = a * y return np.array([x,y,z]) class SimpleSource(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, use_random_polarisation=False): super(SimpleSource, self).__init__() self.position = position self.direction = direction self.wavelength = wavelength self.use_random_polarisation = use_random_polarisation self.throw = 0 self.source_id = "SimpleSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength # If use_polarisation is set generate a random polarisation vector of the photon if self.use_random_polarisation: # Randomise rotation angle around xy-plane, the transform from +z to the direction of the photon vec = random_spherecial_vector() vec[2] = 0. vec = norm(vec) R = rotation_matrix_from_vector_alignment(self.direction, [0,0,1]) photon.polarisation = transform_direction(vec, R) else: photon.polarisation = None photon.id = self.throw self.throw = self.throw + 1 return photon class Laser(object): """A light source that will generate photons of a single colour, direction and position.""" def __init__(self, position=[0,0,0], direction=[0,0,1], wavelength=555, polarisation=None): super(Laser, self).__init__() self.position = np.array(position) self.direction = np.array(direction) self.wavelength = wavelength assert polarisation != None, "Polarisation of the Laser is not set." self.polarisation = np.array(polarisation) self.throw = 0 self.source_id = "LaserSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.position = np.array(self.position) photon.direction = np.array(self.direction) photon.active = True photon.wavelength = self.wavelength photon.polarisation = self.polarisation photon.id = self.throw self.throw = self.throw + 1 return photon class PlanarSource(object): """A box that emits photons from the top surface (normal), sampled from the spectrum.""" def __init__(self, spectrum=None, wavelength=555, direction=(0,0,1), length=0.05, width=0.05): super(PlanarSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.plane = FinitePlane(length=length, width=width) self.length = length self.width = width # direction is the direction that photons are fired out of the plane in the GLOBAL FRAME. # i.e. this is passed directly to the photon to set is's direction self.direction = direction self.throw = 0 self.source_id = "PlanarSource_" + str(id(self)) def translate(self, translation): self.plane.append_transform(tf.translation_matrix(translation)) def rotate(self, angle, axis): self.plane.append_transform(tf.rotation_matrix(angle, axis)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Create a point which is on the surface of the finite plane in it's local frame x = np.random.uniform(0., self.length) y = np.random.uniform(0., self.width) local_point = (x, y, 0.) # Transform the direciton photon.position = transform_point(local_point, self.plane.transform) photon.direction = self.direction photon.active = True if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class LensSource(object): """ A source where photons generated in a plane are focused on a line with space tolerance given by variable "focussize". The focus line should be perpendicular to the plane normal and aligned with the z-axis. """ def __init__(self, spectrum = None, wavelength = 555, linepoint=(0,0,0), linedirection=(0,0,1), focussize = 0, planeorigin = (-1,-1,-1), planeextent = (-1,1,1)): super(LensSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.planeorigin = planeorigin self.planeextent = planeextent self.linepoint = np.array(linepoint) self.linedirection = np.array(linedirection) self.focussize = focussize self.throw = 0 self.source_id = "LensSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Position x = np.random.uniform(self.planeorigin[0],self.planeextent[0]) y = np.random.uniform(self.planeorigin[1],self.planeextent[1]) z = np.random.uniform(self.planeorigin[2],self.planeextent[2]) photon.position = np.array((x,y,z)) # Direction focuspoint = np.array((0.,0.,0.)) focuspoint[0] = self.linepoint[0] + np.random.uniform(-self.focussize,self.focussize) focuspoint[1] = self.linepoint[1] + np.random.uniform(-self.focussize,self.focussize) focuspoint[2] = photon.position[2] direction = focuspoint - photon.position modulus = (direction[0]**2+direction[1]**2+direction[2]**2)**0.5 photon.direction = direction/modulus # Wavelength if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class LensSourceAngle(object): """ A source where photons generated in a plane are focused on a line with space tolerance given by variable "focussize". The focus line should be perpendicular to the plane normal and aligned with the z-axis. For this lense an additional z-boost is added (Angle of incidence in z-direction). """ def __init__(self, spectrum = None, wavelength = 555, linepoint=(0,0,0), linedirection=(0,0,1), angle = 0, focussize = 0, planeorigin = (-1,-1,-1), planeextent = (-1,1,1)): super(LensSourceAngle, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.planeorigin = planeorigin self.planeextent = planeextent self.linepoint = np.array(linepoint) self.linedirection = np.array(linedirection) self.focussize = focussize self.angle = angle self.throw = 0 self.source_id = "LensSourceAngle_" + str(id(self)) def photon(self): photon = Photon() photon.id = self.throw self.throw = self.throw + 1 # Position x = np.random.uniform(self.planeorigin[0],self.planeextent[0]) y = np.random.uniform(self.planeorigin[1],self.planeextent[1]) boost = y*np.tan(self.angle) z = np.random.uniform(self.planeorigin[2],self.planeextent[2]) - boost photon.position = np.array((x,y,z)) # Direction focuspoint = np.array((0.,0.,0.)) focuspoint[0] = self.linepoint[0] + np.random.uniform(-self.focussize,self.focussize) focuspoint[1] = self.linepoint[1] + np.random.uniform(-self.focussize,self.focussize) focuspoint[2] = photon.position[2] + boost direction = focuspoint - photon.position modulus = (direction[0]**2+direction[1]**2+direction[2]**2)**0.5 photon.direction = direction/modulus # Wavelength if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength return photon class CylindricalSource(object): """ A source for photons emitted in a random direction and position inside a cylinder(radius, length) """ def __init__(self, spectrum = None, wavelength = 555, radius = 1, length = 10): super(CylindricalSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.shape = Cylinder(radius = radius, length = length) self.radius = radius self.length = length self.throw = 0 self.source_id = "CylindricalSource_" + str(id(self)) def translate(self, translation): self.shape.append_transform(tf.translation_matrix(translation)) def rotate(self, angle, axis): self.shape.append_transform(tf.rotation_matrix(angle, axis)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 # Position of emission phi = np.random.uniform(0., 2*np.pi) r = np.random.uniform(0.,self.radius) x = r*np.cos(phi) y = r*np.sin(phi) z = np.random.uniform(0.,self.length) local_center = (x,y,z) photon.position = transform_point(local_center, self.shape.transform) # Direction of emission (no need to transform if meant to be isotropic) phi = np.random.uniform(0.,2*np.pi) theta = np.random.uniform(0.,np.pi) x = np.cos(phi)*np.sin(theta) y = np.sin(phi)*np.sin(theta) z = np.cos(theta) local_direction = (x,y,z) photon.direction = local_direction # Set wavelength of photon if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength # Further initialisation photon.active = True return photon class PointSource(object): """ A point source that emits randomly in solid angle specified by phimin, ..., thetamax """ def __init__(self, spectrum = None, wavelength = 555, center = (0.,0.,0.), phimin = 0, phimax = 2*np.pi, thetamin = 0, thetamax = np.pi): super(PointSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.center = center self.phimin = phimin self.phimax = phimax self.thetamin = thetamin self.thetamax = thetamax self.throw = 0 self.source_id = "PointSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 phi = np.random.uniform(self.phimin, self.phimax) theta = np.random.uniform(self.thetamin, self.thetamax) x = np.cos(phi)*np.sin(theta) y = np.sin(phi)*np.sin(theta) z = np.cos(theta) direction = (x,y,z) transform = tf.translation_matrix((0,0,0)) point = transform_point(self.center, transform) photon.direction = direction photon.position = point if self.spectrum != None: photon.wavelength = self.spectrum.wavelength_at_probability(np.random.uniform()) else: photon.wavelength = self.wavelength photon.active = True return photon class RadialSource(object): """ A point source that emits at discrete angles theta(i) and phi(i) """ def __init__(self, spectrum = None, wavelength = 555, center = (0.,0.,0.), phimin = 0, phimax = 2*np.pi, thetamin = 0, thetamax = np.pi, spacing=20): super(RadialSource, self).__init__() self.spectrum = spectrum self.wavelength = wavelength self.center = center self.phimin = phimin self.phimax = phimax self.thetamin = thetamin self.thetamax = thetamax self.spacing = spacing self.throw = 0 self.source_id = "RadialSource_" + str(id(self)) def photon(self): photon = Photon() photon.source = self.source_id photon.id = self.throw self.throw = self.throw + 1 intphi = np.random.randint(1, self.spacing+1) inttheta =

np.random.randint(1, self.spacing+1)

numpy.random.randint

from abc import ABCMeta, abstractmethod import os from vmaf.tools.misc import make_absolute_path, run_process from vmaf.tools.stats import ListStats __copyright__ = "Copyright 2016-2018, Netflix, Inc." __license__ = "Apache, Version 2.0" import re import numpy as np import ast from vmaf import ExternalProgramCaller, to_list from vmaf.config import VmafConfig, VmafExternalConfig from vmaf.core.executor import Executor from vmaf.core.result import Result from vmaf.tools.reader import YuvReader class FeatureExtractor(Executor): """ FeatureExtractor takes in a list of assets, and run feature extraction on them, and return a list of corresponding results. A FeatureExtractor must specify a unique type and version combination (by the TYPE and VERSION attribute), so that the Result generated by it can be identified. A derived class of FeatureExtractor must: 1) Override TYPE and VERSION 2) Override _generate_result(self, asset), which call a command-line executable and generate feature scores in a log file. 3) Override _get_feature_scores(self, asset), which read the feature scores from the log file, and return the scores in a dictionary format. For an example, follow VmafFeatureExtractor. """ __metaclass__ = ABCMeta @property @abstractmethod def ATOM_FEATURES(self): raise NotImplementedError def _read_result(self, asset): result = {} result.update(self._get_feature_scores(asset)) executor_id = self.executor_id return Result(asset, executor_id, result) @classmethod def get_scores_key(cls, atom_feature): return "{type}_{atom_feature}_scores".format( type=cls.TYPE, atom_feature=atom_feature) @classmethod def get_score_key(cls, atom_feature): return "{type}_{atom_feature}_score".format( type=cls.TYPE, atom_feature=atom_feature) def _get_feature_scores(self, asset): # routine to read the feature scores from the log file, and return # the scores in a dictionary format. log_file_path = self._get_log_file_path(asset) atom_feature_scores_dict = {} atom_feature_idx_dict = {} for atom_feature in self.ATOM_FEATURES: atom_feature_scores_dict[atom_feature] = [] atom_feature_idx_dict[atom_feature] = 0 with open(log_file_path, 'rt') as log_file: for line in log_file.readlines(): for atom_feature in self.ATOM_FEATURES: re_template = "{af}: ([0-9]+) ([a-zA-Z0-9.-]+)".format(af=atom_feature) mo = re.match(re_template, line) if mo: cur_idx = int(mo.group(1)) assert cur_idx == atom_feature_idx_dict[atom_feature] # parse value, allowing NaN and inf val = float(mo.group(2)) if np.isnan(val) or np.isinf(val): val = None atom_feature_scores_dict[atom_feature].append(val) atom_feature_idx_dict[atom_feature] += 1 continue len_score = len(atom_feature_scores_dict[self.ATOM_FEATURES[0]]) assert len_score != 0 for atom_feature in self.ATOM_FEATURES[1:]: assert len_score == len(atom_feature_scores_dict[atom_feature]), \ "Feature data possibly corrupt. Run cleanup script and try again." feature_result = {} for atom_feature in self.ATOM_FEATURES: scores_key = self.get_scores_key(atom_feature) feature_result[scores_key] = atom_feature_scores_dict[atom_feature] return feature_result class VmafFeatureExtractor(FeatureExtractor): TYPE = "VMAF_feature" # VERSION = '0.1' # vmaf_study; Anush's VIF fix # VERSION = '0.2' # expose vif_num, vif_den, adm_num, adm_den, anpsnr # VERSION = '0.2.1' # expose vif num/den of each scale # VERSION = '0.2.2' # adm abs-->fabs, corrected border handling, uniform reading with option of offset for input YUV, updated VIF corner case # VERSION = '0.2.2b' # expose adm_den/num_scalex # VERSION = '0.2.3' # AVX for VMAF convolution; update adm features by folding noise floor into per coef # VERSION = '0.2.4' # Fix a bug in adm feature passing scale into dwt_quant_step # VERSION = '0.2.4b' # Modify by adding ADM noise floor outside cube root; add derived feature motion2 VERSION = '0.2.4c' # Modify by moving motion2 to c code ATOM_FEATURES = ['vif', 'adm', 'ansnr', 'motion', 'motion2', 'vif_num', 'vif_den', 'adm_num', 'adm_den', 'anpsnr', 'vif_num_scale0', 'vif_den_scale0', 'vif_num_scale1', 'vif_den_scale1', 'vif_num_scale2', 'vif_den_scale2', 'vif_num_scale3', 'vif_den_scale3', 'adm_num_scale0', 'adm_den_scale0', 'adm_num_scale1', 'adm_den_scale1', 'adm_num_scale2', 'adm_den_scale2', 'adm_num_scale3', 'adm_den_scale3', ] DERIVED_ATOM_FEATURES = ['vif_scale0', 'vif_scale1', 'vif_scale2', 'vif_scale3', 'vif2', 'adm2', 'adm3', 'adm_scale0', 'adm_scale1', 'adm_scale2', 'adm_scale3', ] ADM2_CONSTANT = 0 ADM_SCALE_CONSTANT = 0 def _generate_result(self, asset): # routine to call the command-line executable and generate feature # scores in the log file. quality_width, quality_height = asset.quality_width_height log_file_path = self._get_log_file_path(asset) yuv_type=self._get_workfile_yuv_type(asset) ref_path=asset.ref_workfile_path dis_path=asset.dis_workfile_path w=quality_width h=quality_height logger = self.logger ExternalProgramCaller.call_vmaf_feature(yuv_type, ref_path, dis_path, w, h, log_file_path, logger) @classmethod def _post_process_result(cls, result): # override Executor._post_process_result result = super(VmafFeatureExtractor, cls)._post_process_result(result) # adm2 = # (adm_num + ADM2_CONSTANT) / (adm_den + ADM2_CONSTANT) adm2_scores_key = cls.get_scores_key('adm2') adm_num_scores_key = cls.get_scores_key('adm_num') adm_den_scores_key = cls.get_scores_key('adm_den') result.result_dict[adm2_scores_key] = list( (np.array(result.result_dict[adm_num_scores_key]) + cls.ADM2_CONSTANT) / (np.array(result.result_dict[adm_den_scores_key]) + cls.ADM2_CONSTANT) ) # vif_scalei = vif_num_scalei / vif_den_scalei, i = 0, 1, 2, 3 vif_num_scale0_scores_key = cls.get_scores_key('vif_num_scale0') vif_den_scale0_scores_key = cls.get_scores_key('vif_den_scale0') vif_num_scale1_scores_key = cls.get_scores_key('vif_num_scale1') vif_den_scale1_scores_key = cls.get_scores_key('vif_den_scale1') vif_num_scale2_scores_key = cls.get_scores_key('vif_num_scale2') vif_den_scale2_scores_key = cls.get_scores_key('vif_den_scale2') vif_num_scale3_scores_key = cls.get_scores_key('vif_num_scale3') vif_den_scale3_scores_key = cls.get_scores_key('vif_den_scale3') vif_scale0_scores_key = cls.get_scores_key('vif_scale0') vif_scale1_scores_key = cls.get_scores_key('vif_scale1') vif_scale2_scores_key = cls.get_scores_key('vif_scale2') vif_scale3_scores_key = cls.get_scores_key('vif_scale3') result.result_dict[vif_scale0_scores_key] = list( (np.array(result.result_dict[vif_num_scale0_scores_key]) /

np.array(result.result_dict[vif_den_scale0_scores_key])

numpy.array

from __future__ import absolute_import from __future__ import division from __future__ import print_function import cntk as C import numpy as np from .common import floatx, epsilon, image_dim_ordering, image_data_format from collections import defaultdict from contextlib import contextmanager import warnings C.set_global_option('align_axis', 1) b_any = any dev = C.device.use_default_device() if dev.type() == 0: warnings.warn( 'CNTK backend warning: GPU is not detected. ' 'CNTK\'s CPU version is not fully optimized,' 'please run with GPU to get better performance.') # A learning phase is a bool tensor used to run Keras models in # either train mode (learning_phase == 1) or test mode (learning_phase == 0). # LEARNING_PHASE_PLACEHOLDER is the placeholder for dynamic learning phase _LEARNING_PHASE_PLACEHOLDER = C.constant(shape=(), dtype=np.float32, value=1.0, name='_keras_learning_phase') # static learning phase flag, if it is not 0 or 1, we will go with dynamic learning phase tensor. _LEARNING_PHASE = -1 _UID_PREFIXES = defaultdict(int) # cntk doesn't support gradient as symbolic op, to hook up with keras model, # we will create gradient as a constant placeholder, here use this global # map to keep the mapping from grad placeholder to parameter grad_parameter_dict = {} NAME_SCOPE_STACK = [] @contextmanager def name_scope(name): global NAME_SCOPE_STACK NAME_SCOPE_STACK.append(name) yield NAME_SCOPE_STACK.pop() def get_uid(prefix=''): _UID_PREFIXES[prefix] += 1 return _UID_PREFIXES[prefix] def learning_phase(): # If _LEARNING_PHASE is not 0 or 1, return dynamic learning phase tensor return _LEARNING_PHASE if _LEARNING_PHASE in {0, 1} else _LEARNING_PHASE_PLACEHOLDER def set_learning_phase(value): global _LEARNING_PHASE if value not in {0, 1}: raise ValueError('CNTK Backend: Set learning phase ' 'with value %s is not supported, ' 'expected 0 or 1.' % value) _LEARNING_PHASE = value def clear_session(): """Reset learning phase flag for cntk backend. """ global _LEARNING_PHASE global _LEARNING_PHASE_PLACEHOLDER _LEARNING_PHASE = -1 _LEARNING_PHASE_PLACEHOLDER.value = np.asarray(1.0) def in_train_phase(x, alt, training=None): global _LEARNING_PHASE if training is None: training = learning_phase() uses_learning_phase = True else: uses_learning_phase = False # CNTK currently don't support cond op, so here we use # element_select approach as workaround. It may have # perf issue, will resolve it later with cntk cond op. if callable(x) and isinstance(x, C.cntk_py.Function) is False: x = x() if callable(alt) and isinstance(alt, C.cntk_py.Function) is False: alt = alt() if training is True: x._uses_learning_phase = uses_learning_phase return x else: # if _LEARNING_PHASE is static if isinstance(training, int) or isinstance(training, bool): result = x if training == 1 or training is True else alt else: result = C.element_select(training, x, alt) result._uses_learning_phase = uses_learning_phase return result def in_test_phase(x, alt, training=None): return in_train_phase(alt, x, training=training) def _convert_string_dtype(dtype): # cntk only support float32 and float64 if dtype == 'float32': return np.float32 elif dtype == 'float64': return np.float64 else: # cntk only running with float, # try to cast to float to run the model return np.float32 def _convert_dtype_string(dtype): if dtype == np.float32: return 'float32' elif dtype == np.float64: return 'float64' else: raise ValueError('CNTK Backend: Unsupported dtype: %s. ' 'CNTK only supports float32 and ' 'float64.' % dtype) def variable(value, dtype=None, name=None, constraint=None): """Instantiates a variable and returns it. # Arguments value: Numpy array, initial value of the tensor. dtype: Tensor type. name: Optional name string for the tensor. constraint: Optional projection function to be applied to the variable after an optimizer update. # Returns A variable instance (with Keras metadata included). """ if dtype is None: dtype = floatx() if name is None: name = '' if isinstance( value, C.variables.Constant) or isinstance( value, C.variables.Parameter): value = value.value # we don't support init parameter with symbolic op, so eval it first as # workaround if isinstance(value, C.cntk_py.Function): value = eval(value) shape = value.shape if hasattr(value, 'shape') else () if hasattr(value, 'dtype') and value.dtype != dtype and len(shape) > 0: value = value.astype(dtype) # TODO: remove the conversion when cntk supports int32, int64 # https://docs.microsoft.com/en-us/python/api/cntk.variables.parameter dtype = 'float32' if 'int' in str(dtype) else dtype v = C.parameter(shape=shape, init=value, dtype=dtype, name=_prepare_name(name, 'variable')) v._keras_shape = v.shape v._uses_learning_phase = False v.constraint = constraint return v def bias_add(x, bias, data_format=None): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) dims = len(x.shape) if dims > 0 and x.shape[0] == C.InferredDimension: dims -= 1 bias_dims = len(bias.shape) if bias_dims != 1 and bias_dims != dims: raise ValueError('Unexpected bias dimensions %d, ' 'expected 1 or %d dimensions' % (bias_dims, dims)) if dims == 4: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1, 1, 1) else: shape = (bias.shape[3],) + bias.shape[:3] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, 1, 1, bias.shape[0]) else: shape = bias.shape elif dims == 3: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1, 1) else: shape = (bias.shape[2],) + bias.shape[:2] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, 1, bias.shape[0]) else: shape = bias.shape elif dims == 2: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1) else: shape = (bias.shape[1],) + bias.shape[:1] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, bias.shape[0]) else: shape = bias.shape else: shape = bias.shape return x + reshape(bias, shape) def eval(x): if isinstance(x, C.cntk_py.Function): return x.eval() elif isinstance(x, C.variables.Constant) or isinstance(x, C.variables.Parameter): return x.value else: raise ValueError('CNTK Backend: `eval` method on ' '`%s` type is not supported. ' 'CNTK only supports `eval` with ' '`Function`, `Constant` or ' '`Parameter`.' % type(x)) def placeholder( shape=None, ndim=None, dtype=None, sparse=False, name=None, dynamic_axis_num=1): if dtype is None: dtype = floatx() if not shape: if ndim: shape = tuple([None for _ in range(ndim)]) dynamic_dimension = C.FreeDimension if _get_cntk_version() >= 2.2 else C.InferredDimension cntk_shape = [dynamic_dimension if s is None else s for s in shape] cntk_shape = tuple(cntk_shape) if dynamic_axis_num > len(cntk_shape): raise ValueError('CNTK backend: creating placeholder with ' '%d dimension is not supported, at least ' '%d dimensions are needed.' % (len(cntk_shape, dynamic_axis_num))) if name is None: name = '' cntk_shape = cntk_shape[dynamic_axis_num:] x = C.input( shape=cntk_shape, dtype=_convert_string_dtype(dtype), is_sparse=sparse, name=name) x._keras_shape = shape x._uses_learning_phase = False x._cntk_placeholder = True return x def is_placeholder(x): """Returns whether `x` is a placeholder. # Arguments x: A candidate placeholder. # Returns Boolean. """ return hasattr(x, '_cntk_placeholder') and x._cntk_placeholder def is_keras_tensor(x): if not is_tensor(x): raise ValueError('Unexpectedly found an instance of type `' + str(type(x)) + '`. ' 'Expected a symbolic tensor instance.') return hasattr(x, '_keras_history') def is_tensor(x): return isinstance(x, (C.variables.Constant, C.variables.Variable, C.variables.Parameter, C.ops.functions.Function)) def shape(x): shape = list(int_shape(x)) num_dynamic = _get_dynamic_axis_num(x) non_dyn_shape = [] for i in range(len(x.shape)): if shape[i + num_dynamic] is None: non_dyn_shape.append(x.shape[i]) else: non_dyn_shape.append(shape[i + num_dynamic]) return shape[:num_dynamic] + non_dyn_shape def is_sparse(tensor): return tensor.is_sparse def int_shape(x): if hasattr(x, '_keras_shape'): return x._keras_shape shape = x.shape if hasattr(x, 'dynamic_axes'): dynamic_shape = [None for a in x.dynamic_axes] shape = tuple(dynamic_shape) + shape return shape def ndim(x): shape = int_shape(x) return len(shape) def _prepare_name(name, default): prefix = '_'.join(NAME_SCOPE_STACK) if name is None or name == '': return prefix + '/' + default return prefix + '/' + name def constant(value, dtype=None, shape=None, name=None): if dtype is None: dtype = floatx() if shape is None: shape = () np_value = value * np.ones(shape) const = C.constant(np_value, dtype=dtype, name=_prepare_name(name, 'constant')) const._keras_shape = const.shape const._uses_learning_phase = False return const def random_binomial(shape, p=0.0, dtype=None, seed=None): # use numpy workaround now if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed = np.random.randint(10e7) np.random.seed(seed) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) size = 1 for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') size *= _ binomial = np.random.binomial(1, p, size).astype(dtype).reshape(shape) return variable(value=binomial, dtype=dtype) def random_uniform(shape, minval=0.0, maxval=1.0, dtype=None, seed=None): for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') return random_uniform_variable(shape, minval, maxval, dtype, seed) def random_uniform_variable(shape, low, high, dtype=None, name=None, seed=None): if dtype is None: dtype = floatx() if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed = np.random.randint(10e3) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) if name is None: name = '' scale = (high - low) / 2 p = C.parameter( shape, init=C.initializer.uniform( scale, seed=seed), dtype=dtype, name=name) return variable(value=p.value + low + scale) def random_normal_variable( shape, mean, scale, dtype=None, name=None, seed=None): if dtype is None: dtype = floatx() if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed =

np.random.randint(10e7)

numpy.random.randint

""" Unit tests for the system interface.""" import unittest from six import assertRaisesRegex from six.moves import cStringIO import numpy as np from openmdao.api import Problem, Group, IndepVarComp, ExecComp from openmdao.test_suite.components.options_feature_vector import VectorDoublingComp from openmdao.utils.assert_utils import assert_rel_error, assert_warning class TestSystem(unittest.TestCase): def test_vector_context_managers(self): g1 = Group() g1.add_subsystem('Indep', IndepVarComp('a', 5.0), promotes=['a']) g2 = g1.add_subsystem('G2', Group(), promotes=['*']) g2.add_subsystem('C1', ExecComp('b=2*a'), promotes=['a', 'b']) model = Group() model.add_subsystem('G1', g1, promotes=['b']) model.add_subsystem('Sink', ExecComp('c=2*b'), promotes=['b']) p = Problem(model=model) p.set_solver_print(level=0) # Test pre-setup errors with self.assertRaises(Exception) as cm: inputs, outputs, residuals = model.get_nonlinear_vectors() self.assertEqual(str(cm.exception), "Group: Cannot get vectors because setup has not yet been called.") with self.assertRaises(Exception) as cm: d_inputs, d_outputs, d_residuals = model.get_linear_vectors('vec') self.assertEqual(str(cm.exception), "Group: Cannot get vectors because setup has not yet been called.") p.setup() p.run_model() # Test inputs with original values inputs, outputs, residuals = model.get_nonlinear_vectors() self.assertEqual(inputs['G1.G2.C1.a'], 5.) inputs, outputs, residuals = g1.get_nonlinear_vectors() self.assertEqual(inputs['G2.C1.a'], 5.) # Test inputs after setting a new value inputs, outputs, residuals = g2.get_nonlinear_vectors() inputs['C1.a'] = -1. inputs, outputs, residuals = model.get_nonlinear_vectors() self.assertEqual(inputs['G1.G2.C1.a'], -1.) inputs, outputs, residuals = g1.get_nonlinear_vectors() self.assertEqual(inputs['G2.C1.a'], -1.) # Test outputs with original values inputs, outputs, residuals = model.get_nonlinear_vectors() self.assertEqual(outputs['G1.G2.C1.b'], 10.) inputs, outputs, residuals = g2.get_nonlinear_vectors() # Test outputs after setting a new value inputs, outputs, residuals = model.get_nonlinear_vectors() outputs['G1.G2.C1.b'] = 123. self.assertEqual(outputs['G1.G2.C1.b'], 123.) inputs, outputs, residuals = g2.get_nonlinear_vectors() outputs['C1.b'] = 789. self.assertEqual(outputs['C1.b'], 789.) # Test residuals inputs, outputs, residuals = model.get_nonlinear_vectors() residuals['G1.G2.C1.b'] = 99.0 self.assertEqual(residuals['G1.G2.C1.b'], 99.0) # Test linear d_inputs, d_outputs, d_residuals = model.get_linear_vectors('linear') d_outputs['G1.G2.C1.b'] = 10. self.assertEqual(d_outputs['G1.G2.C1.b'], 10.) # Test linear with invalid vec_name with self.assertRaises(Exception) as cm: d_inputs, d_outputs, d_residuals = model.get_linear_vectors('bad_name') self.assertEqual(str(cm.exception), "Group (<model>): There is no linear vector named %s" % 'bad_name') def test_set_checks_shape(self): indep = IndepVarComp() indep.add_output('a') indep.add_output('x', shape=(5, 1)) g1 = Group() g1.add_subsystem('Indep', indep, promotes=['a', 'x']) g2 = g1.add_subsystem('G2', Group(), promotes=['*']) g2.add_subsystem('C1', ExecComp('b=2*a'), promotes=['a', 'b']) g2.add_subsystem('C2', ExecComp('y=2*x', x=np.zeros((5, 1)), y=np.zeros((5, 1))), promotes=['x', 'y']) model = Group() model.add_subsystem('G1', g1, promotes=['b', 'y']) model.add_subsystem('Sink', ExecComp(('c=2*b', 'z=2*y'), y=np.zeros((5, 1)), z=

np.zeros((5, 1))

numpy.zeros

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k') plt.plot(((time[-202] + time[-201]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed', label=textwrap.fill('Neural network targets', 13)) plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(((time_extended[-1001] + time_extended[-1000]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed') plt.xlim(3.4 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/neural_network.png') plt.show() # plot 6a np.random.seed(0) time = np.linspace(0, 5 * np.pi, 1001) knots_51 = np.linspace(0, 5 * np.pi, 51) time_series = np.cos(2 * time) + np.cos(4 * time) + np.cos(8 * time) noise = np.random.normal(0, 1, len(time_series)) time_series += noise advemdpy = EMD(time=time, time_series=time_series) imfs_51, hts_51, ifs_51 = advemdpy.empirical_mode_decomposition(knots=knots_51, max_imfs=3, edge_effect='symmetric_anchor', verbose=False)[:3] knots_31 = np.linspace(0, 5 * np.pi, 31) imfs_31, hts_31, ifs_31 = advemdpy.empirical_mode_decomposition(knots=knots_31, max_imfs=2, edge_effect='symmetric_anchor', verbose=False)[:3] knots_11 = np.linspace(0, 5 * np.pi, 11) imfs_11, hts_11, ifs_11 = advemdpy.empirical_mode_decomposition(knots=knots_11, max_imfs=1, edge_effect='symmetric_anchor', verbose=False)[:3] fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) print(f'DFA fluctuation with 51 knots: {np.round(np.var(time_series - (imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :])), 3)}') for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[0].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[0].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) print(f'DFA fluctuation with 31 knots: {np.round(np.var(time_series - (imfs_31[1, :] + imfs_31[2, :])), 3)}') for knot in knots_31: axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[1].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[1].set_xticklabels(['', '', '', '', '', '']) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) axs[1].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[1].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[1].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[1].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') axs[2].plot(time, time_series, label='Time series') axs[2].plot(time, imfs_11[1, :], label='IMF 1 with 11 knots') axs[2].plot(time, imfs_31[2, :], label='IMF 2 with 31 knots') axs[2].plot(time, imfs_51[3, :], label='IMF 3 with 51 knots') print(f'DFA fluctuation with 11 knots: {np.round(np.var(time_series - imfs_51[3, :]), 3)}') for knot in knots_11: axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[2].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[2].set_xticklabels(['$0$', r'$\pi$', r'$2\pi$', r'$3\pi$', r'$4\pi$', r'$5\pi$']) box_2 = axs[2].get_position() axs[2].set_position([box_2.x0 - 0.05, box_2.y0, box_2.width * 0.85, box_2.height]) axs[2].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[2].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[2].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[2].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[2].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') plt.savefig('jss_figures/DFA_different_trends.png') plt.show() # plot 6b fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences Zoomed Region', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[0].set_ylim(-5.5, 5.5) axs[0].set_xlim(0.95 * np.pi, 1.55 * np.pi) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) for knot in knots_31: axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[1].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[1].set_xticklabels(['', '', '', '', '', '']) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) axs[1].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].set_ylim(-5.5, 5.5) axs[1].set_xlim(0.95 * np.pi, 1.55 * np.pi) axs[2].plot(time, time_series, label='Time series') axs[2].plot(time, imfs_11[1, :], label='IMF 1 with 11 knots') axs[2].plot(time, imfs_31[2, :], label='IMF 2 with 31 knots') axs[2].plot(time, imfs_51[3, :], label='IMF 3 with 51 knots') for knot in knots_11: axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[2].set_xticks([np.pi, (3 / 2) * np.pi]) axs[2].set_xticklabels([r'$\pi$', r'$\frac{3}{2}\pi$']) box_2 = axs[2].get_position() axs[2].set_position([box_2.x0 - 0.05, box_2.y0, box_2.width * 0.85, box_2.height]) axs[2].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[2].set_ylim(-5.5, 5.5) axs[2].set_xlim(0.95 * np.pi, 1.55 * np.pi) plt.savefig('jss_figures/DFA_different_trends_zoomed.png') plt.show() hs_ouputs = hilbert_spectrum(time, imfs_51, hts_51, ifs_51, max_frequency=12, plot=False) # plot 6c ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Simple Sinusoidal Time Seres with Added Noise', 50)) x_hs, y, z = hs_ouputs z_min, z_max = 0, np.abs(z).max() ax.pcolormesh(x_hs, y,

np.abs(z)

numpy.abs

""" Greedy Word Swap with Word Importance Ranking =================================================== When WIR method is set to ``unk``, this is a reimplementation of the search method from the paper: Is BERT Really Robust? A Strong Baseline for Natural Language Attack on Text Classification and Entailment by Jin et. al, 2019. See https://arxiv.org/abs/1907.11932 and https://github.com/jind11/TextFooler. """ import numpy as np import torch from torch.nn.functional import softmax from textattack.goal_function_results import GoalFunctionResultStatus from textattack.search_methods import SearchMethod from textattack.shared.validators import ( transformation_consists_of_word_swaps_and_deletions, ) class GreedyWordSwapWIR(SearchMethod): """An attack that greedily chooses from a list of possible perturbations in order of index, after ranking indices by importance. Args: wir_method: method for ranking most important words """ def __init__(self, wir_method="unk"): self.wir_method = wir_method def _get_index_order(self, initial_text): """Returns word indices of ``initial_text`` in descending order of importance.""" len_text = len(initial_text.words) if self.wir_method == "unk": leave_one_texts = [ initial_text.replace_word_at_index(i, "[UNK]") for i in range(len_text) ] leave_one_results, search_over = self.get_goal_results(leave_one_texts) index_scores = np.array([result.score for result in leave_one_results]) elif self.wir_method == "weighted-saliency": # first, compute word saliency leave_one_texts = [ initial_text.replace_word_at_index(i, "[UNK]") for i in range(len_text) ] leave_one_results, search_over = self.get_goal_results(leave_one_texts) saliency_scores = np.array([result.score for result in leave_one_results]) softmax_saliency_scores = softmax( torch.Tensor(saliency_scores), dim=0 ).numpy() # compute the largest change in score we can find by swapping each word delta_ps = [] for idx in range(len_text): transformed_text_candidates = self.get_transformations( initial_text, original_text=initial_text, indices_to_modify=[idx], ) if not transformed_text_candidates: # no valid synonym substitutions for this word delta_ps.append(0.0) continue swap_results, _ = self.get_goal_results(transformed_text_candidates) score_change = [result.score for result in swap_results] max_score_change = np.max(score_change) delta_ps.append(max_score_change) index_scores = softmax_saliency_scores * np.array(delta_ps) elif self.wir_method == "delete": leave_one_texts = [ initial_text.delete_word_at_index(i) for i in range(len_text) ] leave_one_results, search_over = self.get_goal_results(leave_one_texts) index_scores =

np.array([result.score for result in leave_one_results])

numpy.array

from __future__ import absolute_import from __future__ import division from __future__ import print_function import cntk as C import numpy as np from .common import floatx, epsilon, image_dim_ordering, image_data_format from collections import defaultdict from contextlib import contextmanager import warnings C.set_global_option('align_axis', 1) b_any = any dev = C.device.use_default_device() if dev.type() == 0: warnings.warn( 'CNTK backend warning: GPU is not detected. ' 'CNTK\'s CPU version is not fully optimized,' 'please run with GPU to get better performance.') # A learning phase is a bool tensor used to run Keras models in # either train mode (learning_phase == 1) or test mode (learning_phase == 0). # LEARNING_PHASE_PLACEHOLDER is the placeholder for dynamic learning phase _LEARNING_PHASE_PLACEHOLDER = C.constant(shape=(), dtype=np.float32, value=1.0, name='_keras_learning_phase') # static learning phase flag, if it is not 0 or 1, we will go with dynamic learning phase tensor. _LEARNING_PHASE = -1 _UID_PREFIXES = defaultdict(int) # cntk doesn't support gradient as symbolic op, to hook up with keras model, # we will create gradient as a constant placeholder, here use this global # map to keep the mapping from grad placeholder to parameter grad_parameter_dict = {} NAME_SCOPE_STACK = [] @contextmanager def name_scope(name): global NAME_SCOPE_STACK NAME_SCOPE_STACK.append(name) yield NAME_SCOPE_STACK.pop() def get_uid(prefix=''): _UID_PREFIXES[prefix] += 1 return _UID_PREFIXES[prefix] def learning_phase(): # If _LEARNING_PHASE is not 0 or 1, return dynamic learning phase tensor return _LEARNING_PHASE if _LEARNING_PHASE in {0, 1} else _LEARNING_PHASE_PLACEHOLDER def set_learning_phase(value): global _LEARNING_PHASE if value not in {0, 1}: raise ValueError('CNTK Backend: Set learning phase ' 'with value %s is not supported, ' 'expected 0 or 1.' % value) _LEARNING_PHASE = value def clear_session(): """Reset learning phase flag for cntk backend. """ global _LEARNING_PHASE global _LEARNING_PHASE_PLACEHOLDER _LEARNING_PHASE = -1 _LEARNING_PHASE_PLACEHOLDER.value = np.asarray(1.0) def in_train_phase(x, alt, training=None): global _LEARNING_PHASE if training is None: training = learning_phase() uses_learning_phase = True else: uses_learning_phase = False # CNTK currently don't support cond op, so here we use # element_select approach as workaround. It may have # perf issue, will resolve it later with cntk cond op. if callable(x) and isinstance(x, C.cntk_py.Function) is False: x = x() if callable(alt) and isinstance(alt, C.cntk_py.Function) is False: alt = alt() if training is True: x._uses_learning_phase = uses_learning_phase return x else: # if _LEARNING_PHASE is static if isinstance(training, int) or isinstance(training, bool): result = x if training == 1 or training is True else alt else: result = C.element_select(training, x, alt) result._uses_learning_phase = uses_learning_phase return result def in_test_phase(x, alt, training=None): return in_train_phase(alt, x, training=training) def _convert_string_dtype(dtype): # cntk only support float32 and float64 if dtype == 'float32': return np.float32 elif dtype == 'float64': return np.float64 else: # cntk only running with float, # try to cast to float to run the model return np.float32 def _convert_dtype_string(dtype): if dtype == np.float32: return 'float32' elif dtype == np.float64: return 'float64' else: raise ValueError('CNTK Backend: Unsupported dtype: %s. ' 'CNTK only supports float32 and ' 'float64.' % dtype) def variable(value, dtype=None, name=None, constraint=None): """Instantiates a variable and returns it. # Arguments value: Numpy array, initial value of the tensor. dtype: Tensor type. name: Optional name string for the tensor. constraint: Optional projection function to be applied to the variable after an optimizer update. # Returns A variable instance (with Keras metadata included). """ if dtype is None: dtype = floatx() if name is None: name = '' if isinstance( value, C.variables.Constant) or isinstance( value, C.variables.Parameter): value = value.value # we don't support init parameter with symbolic op, so eval it first as # workaround if isinstance(value, C.cntk_py.Function): value = eval(value) shape = value.shape if hasattr(value, 'shape') else () if hasattr(value, 'dtype') and value.dtype != dtype and len(shape) > 0: value = value.astype(dtype) # TODO: remove the conversion when cntk supports int32, int64 # https://docs.microsoft.com/en-us/python/api/cntk.variables.parameter dtype = 'float32' if 'int' in str(dtype) else dtype v = C.parameter(shape=shape, init=value, dtype=dtype, name=_prepare_name(name, 'variable')) v._keras_shape = v.shape v._uses_learning_phase = False v.constraint = constraint return v def bias_add(x, bias, data_format=None): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) dims = len(x.shape) if dims > 0 and x.shape[0] == C.InferredDimension: dims -= 1 bias_dims = len(bias.shape) if bias_dims != 1 and bias_dims != dims: raise ValueError('Unexpected bias dimensions %d, ' 'expected 1 or %d dimensions' % (bias_dims, dims)) if dims == 4: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1, 1, 1) else: shape = (bias.shape[3],) + bias.shape[:3] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, 1, 1, bias.shape[0]) else: shape = bias.shape elif dims == 3: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1, 1) else: shape = (bias.shape[2],) + bias.shape[:2] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, 1, bias.shape[0]) else: shape = bias.shape elif dims == 2: if data_format == 'channels_first': if bias_dims == 1: shape = (bias.shape[0], 1) else: shape = (bias.shape[1],) + bias.shape[:1] elif data_format == 'channels_last': if bias_dims == 1: shape = (1, bias.shape[0]) else: shape = bias.shape else: shape = bias.shape return x + reshape(bias, shape) def eval(x): if isinstance(x, C.cntk_py.Function): return x.eval() elif isinstance(x, C.variables.Constant) or isinstance(x, C.variables.Parameter): return x.value else: raise ValueError('CNTK Backend: `eval` method on ' '`%s` type is not supported. ' 'CNTK only supports `eval` with ' '`Function`, `Constant` or ' '`Parameter`.' % type(x)) def placeholder( shape=None, ndim=None, dtype=None, sparse=False, name=None, dynamic_axis_num=1): if dtype is None: dtype = floatx() if not shape: if ndim: shape = tuple([None for _ in range(ndim)]) dynamic_dimension = C.FreeDimension if _get_cntk_version() >= 2.2 else C.InferredDimension cntk_shape = [dynamic_dimension if s is None else s for s in shape] cntk_shape = tuple(cntk_shape) if dynamic_axis_num > len(cntk_shape): raise ValueError('CNTK backend: creating placeholder with ' '%d dimension is not supported, at least ' '%d dimensions are needed.' % (len(cntk_shape, dynamic_axis_num))) if name is None: name = '' cntk_shape = cntk_shape[dynamic_axis_num:] x = C.input( shape=cntk_shape, dtype=_convert_string_dtype(dtype), is_sparse=sparse, name=name) x._keras_shape = shape x._uses_learning_phase = False x._cntk_placeholder = True return x def is_placeholder(x): """Returns whether `x` is a placeholder. # Arguments x: A candidate placeholder. # Returns Boolean. """ return hasattr(x, '_cntk_placeholder') and x._cntk_placeholder def is_keras_tensor(x): if not is_tensor(x): raise ValueError('Unexpectedly found an instance of type `' + str(type(x)) + '`. ' 'Expected a symbolic tensor instance.') return hasattr(x, '_keras_history') def is_tensor(x): return isinstance(x, (C.variables.Constant, C.variables.Variable, C.variables.Parameter, C.ops.functions.Function)) def shape(x): shape = list(int_shape(x)) num_dynamic = _get_dynamic_axis_num(x) non_dyn_shape = [] for i in range(len(x.shape)): if shape[i + num_dynamic] is None: non_dyn_shape.append(x.shape[i]) else: non_dyn_shape.append(shape[i + num_dynamic]) return shape[:num_dynamic] + non_dyn_shape def is_sparse(tensor): return tensor.is_sparse def int_shape(x): if hasattr(x, '_keras_shape'): return x._keras_shape shape = x.shape if hasattr(x, 'dynamic_axes'): dynamic_shape = [None for a in x.dynamic_axes] shape = tuple(dynamic_shape) + shape return shape def ndim(x): shape = int_shape(x) return len(shape) def _prepare_name(name, default): prefix = '_'.join(NAME_SCOPE_STACK) if name is None or name == '': return prefix + '/' + default return prefix + '/' + name def constant(value, dtype=None, shape=None, name=None): if dtype is None: dtype = floatx() if shape is None: shape = () np_value = value * np.ones(shape) const = C.constant(np_value, dtype=dtype, name=_prepare_name(name, 'constant')) const._keras_shape = const.shape const._uses_learning_phase = False return const def random_binomial(shape, p=0.0, dtype=None, seed=None): # use numpy workaround now if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed = np.random.randint(10e7) np.random.seed(seed) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) size = 1 for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') size *= _ binomial = np.random.binomial(1, p, size).astype(dtype).reshape(shape) return variable(value=binomial, dtype=dtype) def random_uniform(shape, minval=0.0, maxval=1.0, dtype=None, seed=None): for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') return random_uniform_variable(shape, minval, maxval, dtype, seed) def random_uniform_variable(shape, low, high, dtype=None, name=None, seed=None): if dtype is None: dtype = floatx() if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed = np.random.randint(10e3) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) if name is None: name = '' scale = (high - low) / 2 p = C.parameter( shape, init=C.initializer.uniform( scale, seed=seed), dtype=dtype, name=name) return variable(value=p.value + low + scale) def random_normal_variable( shape, mean, scale, dtype=None, name=None, seed=None): if dtype is None: dtype = floatx() if seed is None: # ensure that randomness is conditioned by the Numpy RNG seed = np.random.randint(10e7) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) if name is None: name = '' return C.parameter( shape=shape, init=C.initializer.normal( scale=scale, seed=seed), dtype=dtype, name=name) def random_normal(shape, mean=0.0, stddev=1.0, dtype=None, seed=None): if dtype is None: dtype = floatx() for _ in shape: if _ is None: raise ValueError('CNTK Backend: randomness op with ' 'dynamic shape is not supported now. ' 'Please provide fixed dimension ' 'instead of `None`.') # how to apply mean and stddev return random_normal_variable(shape=shape, mean=mean, scale=1.0, seed=seed) def truncated_normal(shape, mean=0.0, stddev=1.0, dtype=None, seed=None): if seed is None: seed = np.random.randint(1, 10e6) if dtype is None: dtype = np.float32 else: dtype = _convert_string_dtype(dtype) return C.parameter( shape, init=C.initializer.truncated_normal( stddev, seed=seed), dtype=dtype) def dtype(x): return _convert_dtype_string(x.dtype) def zeros(shape, dtype=None, name=None): if dtype is None: dtype = floatx() ctype = _convert_string_dtype(dtype) return variable(value=np.zeros(shape, ctype), dtype=dtype, name=name) def ones(shape, dtype=None, name=None): if dtype is None: dtype = floatx() ctype = _convert_string_dtype(dtype) return variable(value=np.ones(shape, ctype), dtype=dtype, name=name) def eye(size, dtype=None, name=None): if dtype is None: dtype = floatx() return variable(np.eye(size), dtype, name) def zeros_like(x, dtype=None, name=None): return x * 0 def ones_like(x, dtype=None, name=None): return zeros_like(x) + 1 def count_params(x): for _ in x.shape: if _ == C.InferredDimension or _ == C.FreeDimension: raise ValueError('CNTK backend: `count_params` with dynamic ' 'shape is not supported. Please provide ' 'fixed dimension instead of `None`.') return np.prod(int_shape(x)) def cast(x, dtype): # cntk calculate everything in float, so don't need case from bool / int return x def dot(x, y): if len(x.shape) > 2 or len(y.shape) > 2: y_shape = int_shape(y) if len(y_shape) > 2: permutation = [len(y_shape) - 2] permutation += list(range(len(y_shape) - 2)) permutation += [len(y_shape) - 1] y = C.transpose(y, perm=permutation) return C.times(x, y, len(y_shape) - 1) else: return C.times(x, y) def batch_dot(x, y, axes=None): x_shape = int_shape(x) y_shape = int_shape(y) if isinstance(axes, int): axes = (axes, axes) if axes is None: # behaves like tf.batch_matmul as default axes = [len(x_shape) - 1, len(y_shape) - 2] if b_any([isinstance(a, (list, tuple)) for a in axes]): raise ValueError('Multiple target dimensions are not supported. ' + 'Expected: None, int, (int, int), ' + 'Provided: ' + str(axes)) if len(x_shape) == 2 and len(y_shape) == 2: if axes[0] == axes[1]: result = sum(x * y, axis=axes[0], keepdims=True) return result if axes[0] == 1 else transpose(result) else: return sum(x * transpose(y), axis=axes[0], keepdims=True) else: if len(y_shape) == 2: y = expand_dims(y) normalized_axis = [] normalized_axis.append(_normalize_axis(axes[0], x)[0]) normalized_axis.append(_normalize_axis(axes[1], y)[0]) # transpose i = normalized_axis[0] while i < len(x.shape) - 1: x = C.swapaxes(x, i, i + 1) i += 1 i = normalized_axis[1] while i > 0: y = C.swapaxes(y, i, i - 1) i -= 1 result = C.times(x, y, output_rank=(len(y.shape) - 1) if len(y.shape) > 1 else 1) if len(y_shape) == 2: result = squeeze(result, -1) return result def transpose(x): return C.swapaxes(x, 0, 1) def gather(reference, indices): # There is a bug in cntk gather op which may cause crash. # We have made a fix but not catched in CNTK 2.1 release. # Will update with gather op in next release if _get_cntk_version() >= 2.2: return C.ops.gather(reference, indices) else: num_classes = reference.shape[0] one_hot_matrix = C.ops.one_hot(indices, num_classes) return C.times(one_hot_matrix, reference, output_rank=len(reference.shape) - 1) def _remove_dims(x, axis, keepdims=False): if keepdims is False and isinstance(axis, list): # sequence axis is removed by default, so don't need reshape on it reduce_axes = [] for a in axis: if isinstance(a, C.Axis) is False: reduce_axes.append(a) return _reshape_dummy_dim(x, reduce_axes) else: if isinstance(axis, list): has_seq = False for a in axis: if isinstance(a, C.Axis): has_seq = True break if has_seq: nones = _get_dynamic_axis_num(x) x = expand_dims(x, nones) return x def max(x, axis=None, keepdims=False): axis = _normalize_axis(axis, x) output = _reduce_on_axis(x, axis, 'reduce_max') return _remove_dims(output, axis, keepdims) def min(x, axis=None, keepdims=False): axis = _normalize_axis(axis, x) output = _reduce_on_axis(x, axis, 'reduce_min') return _remove_dims(output, axis, keepdims) def sum(x, axis=None, keepdims=False): axis = _normalize_axis(axis, x) output = _reduce_on_axis(x, axis, 'reduce_sum') return _remove_dims(output, axis, keepdims) def prod(x, axis=None, keepdims=False): axis = _normalize_axis(axis, x) output = _reduce_on_axis(x, axis, 'reduce_prod') return _remove_dims(output, axis, keepdims) def logsumexp(x, axis=None, keepdims=False): return log(sum(exp(x), axis=axis, keepdims=keepdims)) def var(x, axis=None, keepdims=False): m = mean(x, axis, keepdims=True) devs_squared = C.square(x - m) return mean(devs_squared, axis=axis, keepdims=keepdims) def std(x, axis=None, keepdims=False): return C.sqrt(var(x, axis=axis, keepdims=keepdims)) def expand_dims(x, axis=-1): shape = list(int_shape(x)) nones = _get_dynamic_axis_num(x) index = axis if axis >= 0 else len(shape) + 1 shape.insert(index, 1) new_shape = shape[nones:] new_shape = tuple( [C.InferredDimension if _ is None else _ for _ in new_shape]) result = C.reshape(x, new_shape) if index < nones: result._keras_shape = shape return result def squeeze(x, axis): if isinstance(axis, tuple): axis = list(axis) if not isinstance(axis, list): axis = [axis] shape = list(int_shape(x)) _axis = [] for _ in axis: if isinstance(_, int): _axis.append(_ if _ >= 0 else _ + len(shape)) if len(_axis) == 0: return x nones = _get_dynamic_axis_num(x) for _ in sorted(_axis, reverse=True): del shape[_] new_shape = shape[nones:] new_shape = tuple([C.InferredDimension if _ == C.FreeDimension else _ for _ in new_shape]) return C.reshape(x, new_shape) def tile(x, n): if isinstance(n, int): n = (n,) elif isinstance(n, list): n = tuple(n) shape = int_shape(x) num_dynamic_axis = _get_dynamic_axis_num(x) # Padding the axis if len(n) < len(shape): n = tuple([1 for _ in range(len(shape) - len(n))]) + n if len(n) != len(shape): raise NotImplementedError i = num_dynamic_axis for i, rep in enumerate(n): if i >= num_dynamic_axis and shape[i] is not None: tmp = [x] * rep x = C.splice(*tmp, axis=i - num_dynamic_axis) i += 1 return x def _normalize_axis(axis, x): shape = int_shape(x) ndim = len(shape) nones = _get_dynamic_axis_num(x) if nones > ndim: raise ValueError('CNTK Backend: tensor with keras shape: `%s` has ' '%d cntk dynamic axis, this is not expected, please ' 'double check the keras shape history.' % (str(shape), nones)) # Current cntk does not support shape like (1, batch). so using the workaround # here to mapping the correct axis. Will remove this tricky after we add support # in native cntk op cntk_axis = [] dynamic_axis_index = 0 for i in range(ndim): if shape[i] is None and dynamic_axis_index < nones: cntk_axis.append(x.dynamic_axes[dynamic_axis_index]) dynamic_axis_index += 1 else: cntk_axis.append(i - dynamic_axis_index) if dynamic_axis_index < nones: i = 0 while dynamic_axis_index < nones: cntk_axis[i] = x.dynamic_axes[dynamic_axis_index] i += 1 dynamic_axis_index += 1 while i < len(cntk_axis): cntk_axis[i] -= nones i += 1 if isinstance(axis, tuple): _axis = list(axis) elif isinstance(axis, int): _axis = [axis] elif isinstance(axis, list): _axis = list(axis) else: _axis = axis if isinstance(_axis, list): for i, a in enumerate(_axis): if a is not None and a < 0: _axis[i] = (a % ndim) if _axis[i] is not None: _axis[i] = cntk_axis[_axis[i]] else: if _axis is None: _axis = C.Axis.all_axes() return _axis def _reshape_dummy_dim(x, axis): shape = list(x.shape) _axis = [_ + len(shape) if _ < 0 else _ for _ in axis] if shape.count(C.InferredDimension) > 1 or shape.count(C.FreeDimension) > 1: result = x for index in sorted(_axis, reverse=True): result = C.reshape(result, shape=(), begin_axis=index, end_axis=index + 1) return result else: for index in sorted(_axis, reverse=True): del shape[index] shape = [C.InferredDimension if _ == C.FreeDimension else _ for _ in shape] return C.reshape(x, shape) def mean(x, axis=None, keepdims=False): axis = _normalize_axis(axis, x) output = _reduce_on_axis(x, axis, 'reduce_mean') return _remove_dims(output, axis, keepdims) def any(x, axis=None, keepdims=False): reduce_result = sum(x, axis, keepdims=keepdims) any_matrix = C.element_select( reduce_result, ones_like(reduce_result), zeros_like(reduce_result)) if len(reduce_result.shape) == 0 and _get_dynamic_axis_num(x) == 0: return C.reduce_sum(any_matrix) else: return any_matrix def all(x, axis=None, keepdims=False): reduce_result = prod(x, axis, keepdims=keepdims) all_matrix = C.element_select( reduce_result, ones_like(reduce_result), zeros_like(reduce_result)) if len(reduce_result.shape) == 0 and _get_dynamic_axis_num(x) == 0: return C.reduce_sum(all_matrix) else: return all_matrix def classification_error(target, output, axis=-1): return C.ops.reduce_mean( C.equal( argmax( output, axis=-1), argmax( target, axis=-1)), axis=C.Axis.all_axes()) def argmax(x, axis=-1): axis = [axis] axis = _normalize_axis(axis, x) output = C.ops.argmax(x, axis=axis[0]) return _reshape_dummy_dim(output, axis) def argmin(x, axis=-1): axis = [axis] axis = _normalize_axis(axis, x) output = C.ops.argmin(x, axis=axis[0]) return _reshape_dummy_dim(output, axis) def square(x): return C.square(x) def abs(x): return C.abs(x) def sqrt(x): return C.sqrt(x) def exp(x): return C.exp(x) def log(x): return C.log(x) def round(x): return C.round(x) def sigmoid(x): return C.sigmoid(x) def sign(x): return x / C.abs(x) def pow(x, a): return C.pow(x, a) def clip(x, min_value, max_value): if max_value is not None and max_value < min_value: max_value = min_value if max_value is None: max_value = np.inf if min_value is None: min_value = -np.inf return C.clip(x, min_value, max_value) def binary_crossentropy(target, output, from_logits=False): if from_logits: output = C.sigmoid(output) output = C.clip(output, epsilon(), 1.0 - epsilon()) output = -target * C.log(output) - (1.0 - target) * C.log(1.0 - output) return output def get_variable_shape(x): return int_shape(x) def update(x, new_x): return C.assign(x, new_x) def moving_average_update(variable, value, momentum): return C.assign(variable, variable * momentum + value * (1. - momentum)) def update_add(x, increment): result = x + increment return C.assign(x, result) def gradients(loss, variables): # cntk does not support gradients as symbolic op, # to hook up with keras model # we will return a constant as place holder, the cntk learner will apply # the gradient during training. global grad_parameter_dict if isinstance(variables, list) is False: variables = [variables] grads = [] for v in variables: g = C.constant(0, shape=v.shape, name='keras_grad_placeholder') grads.append(g) grad_parameter_dict[g] = v return grads def equal(x, y): return C.equal(x, y) def not_equal(x, y): return C.not_equal(x, y) def greater(x, y): return C.greater(x, y) def greater_equal(x, y): return C.greater_equal(x, y) def less(x, y): return C.less(x, y) def less_equal(x, y): return C.less_equal(x, y) def maximum(x, y): return C.element_max(x, y) def minimum(x, y): return C.element_min(x, y) def sin(x): return C.sin(x) def cos(x): return C.cos(x) def normalize_batch_in_training(x, gamma, beta, reduction_axes, epsilon=1e-3): if gamma is None: if beta is None: gamma = ones_like(x) else: gamma = ones_like(beta) if beta is None: if gamma is None: beta = zeros_like(x) else: beta = zeros_like(gamma) mean, variant = _moments(x, _normalize_axis(reduction_axes, x)) if sorted(reduction_axes) == list(range(ndim(x)))[:-1]: normalized = batch_normalization( x, mean, variant, beta, gamma, epsilon) else: # need broadcasting target_shape = [] x_shape = int_shape(x) # skip the batch axis for axis in range(1, ndim(x)): if axis in reduction_axes: target_shape.append(1) if ndim(gamma) > axis: gamma = C.reduce_mean(gamma, axis - 1) beta = C.reduce_mean(beta, axis - 1) else: target_shape.append(x_shape[axis]) broadcast_mean = C.reshape(mean, target_shape) broadcast_var = C.reshape(variant, target_shape) broadcast_gamma = C.reshape(gamma, target_shape) broadcast_beta = C.reshape(beta, target_shape) normalized = batch_normalization( x, broadcast_mean, broadcast_var, broadcast_beta, broadcast_gamma, epsilon) return normalized, mean, variant def _moments(x, axes=None, shift=None, keep_dims=False): _axes = tuple(axes) if shift is None: shift = x # Compute true mean while keeping the dims for proper broadcasting. for axis in _axes: shift = C.reduce_mean(shift, axis=axis) shift = C.stop_gradient(shift) shifted_mean = C.minus(x, shift) for axis in _axes: shifted_mean = C.reduce_mean(shifted_mean, axis=axis) variance_mean = C.square(C.minus(x, shift)) for axis in _axes: variance_mean = C.reduce_mean(variance_mean, axis=axis) variance = C.minus(variance_mean, C.square(shifted_mean)) mean = C.plus(shifted_mean, shift) if not keep_dims: mean = squeeze(mean, _axes) variance = squeeze(variance, _axes) return mean, variance def batch_normalization(x, mean, var, beta, gamma, epsilon=1e-3): # The mean / var / beta / gamma may be processed by broadcast # so it may have an extra batch axis with 1, it is not needed # in cntk, need to remove those dummy axis. if ndim(mean) == ndim(x) and shape(mean)[0] == 1: mean = _reshape_dummy_dim(mean, [0]) if ndim(var) == ndim(x) and shape(var)[0] == 1: var = _reshape_dummy_dim(var, [0]) if gamma is None: gamma = ones_like(var) elif ndim(gamma) == ndim(x) and shape(gamma)[0] == 1: gamma = _reshape_dummy_dim(gamma, [0]) if beta is None: beta = zeros_like(mean) elif ndim(beta) == ndim(x) and shape(beta)[0] == 1: beta = _reshape_dummy_dim(beta, [0]) return (x - mean) / (C.sqrt(var) + epsilon) * gamma + beta def concatenate(tensors, axis=-1): if len(tensors) == 0: return None axis = [axis] axis = _normalize_axis(axis, tensors[0]) return C.splice(*tensors, axis=axis[0]) def flatten(x): return reshape(x, (-1,)) def reshape(x, shape): shape = tuple([C.InferredDimension if _ == C.FreeDimension else _ for _ in shape]) if isinstance(x, C.variables.Parameter): return C.reshape(x, shape) else: num_dynamic_axis = _get_dynamic_axis_num(x) if num_dynamic_axis == 1 and len(shape) > 0 and shape[0] == -1: # collapse axis with batch axis if b_any(_ == C.InferredDimension for _ in x.shape) or b_any( _ == C.FreeDimension for _ in x.shape): warnings.warn( 'Warning: CNTK backend does not support ' 'collapse of batch axis with inferred dimension. ' 'The reshape did not take place.') return x return _reshape_batch(x, shape) else: # no collapse, then first need to padding the shape if num_dynamic_axis >= len(shape): i = 0 while i < len(shape): if shape[i] is None or shape[i] == -1: i += 1 else: break shape = tuple([-1 for _ in range(num_dynamic_axis - i)]) + shape new_shape = list(shape) new_shape = new_shape[num_dynamic_axis:] new_shape = [C.InferredDimension if _ is None else _ for _ in new_shape] return C.reshape(x, new_shape) def permute_dimensions(x, pattern): dims = len(int_shape(x)) num_dynamic_axis = _get_dynamic_axis_num(x) if isinstance(pattern, list): current_layout = [i for i in range(dims)] else: current_layout = tuple([i for i in range(dims)]) if num_dynamic_axis > 0 and pattern[:num_dynamic_axis] != current_layout[:num_dynamic_axis]: raise ValueError('CNTK backend: the permute pattern %s ' 'requested permute on dynamic axis, ' 'which is not supported. Please do permute ' 'on static axis.' % pattern) axis = list(pattern) axis = axis[num_dynamic_axis:] axis = _normalize_axis(axis, x) return C.transpose(x, axis) def resize_images(x, height_factor, width_factor, data_format): if data_format == 'channels_first': output = repeat_elements(x, height_factor, axis=2) output = repeat_elements(output, width_factor, axis=3) return output elif data_format == 'channels_last': output = repeat_elements(x, height_factor, axis=1) output = repeat_elements(output, width_factor, axis=2) return output else: raise ValueError('CNTK Backend: Invalid data_format:', data_format) def resize_volumes(x, depth_factor, height_factor, width_factor, data_format): if data_format == 'channels_first': output = repeat_elements(x, depth_factor, axis=2) output = repeat_elements(output, height_factor, axis=3) output = repeat_elements(output, width_factor, axis=4) return output elif data_format == 'channels_last': output = repeat_elements(x, depth_factor, axis=1) output = repeat_elements(output, height_factor, axis=2) output = repeat_elements(output, width_factor, axis=3) return output else: raise ValueError('CNTK Backend: Invalid data_format:', data_format) def repeat_elements(x, rep, axis): axis = _normalize_axis(axis, x) axis = axis[0] slices = [] shape = x.shape i = 0 while i < shape[axis]: tmp = C.ops.slice(x, axis, i, i + 1) for _ in range(rep): slices.append(tmp) i += 1 return C.splice(*slices, axis=axis) def repeat(x, n): # this is a workaround for recurrent layer # if n is inferred dimension, # we can't figure out how to repeat it in cntk now # return the same x to take cntk broadcast feature # to make the recurrent layer work. # need to be fixed in GA. if n is C.InferredDimension or n is C.FreeDimension: return x index = 1 - _get_dynamic_axis_num(x) if index < 0 or index > 1: raise NotImplementedError new_shape = list(x.shape) new_shape.insert(index, 1) new_shape = tuple(new_shape) x = C.reshape(x, new_shape) temp = [x] * n return C.splice(*temp, axis=index) def tanh(x): return C.tanh(x) def _static_rnn(step_function, inputs, initial_states, go_backwards=False, mask=None, constants=None, unroll=False, input_length=None): shape = int_shape(inputs) dims = len(shape) uses_learning_phase = False if dims < 3: raise ValueError('Input should be at least 3D.') # if the second axis is static axis, CNTK will do unroll by default if shape[1] is None: raise ValueError('CNTK Backend: the input of static rnn ' 'has shape `%s`, the second axis ' 'is not static. If you want to run ' 'rnn with non-static axis, please try ' 'dynamic rnn with sequence axis.' % shape) if constants is None: constants = [] if mask is not None: mask_shape = int_shape(mask) if len(mask_shape) == dims - 1: mask = expand_dims(mask) nones = _get_dynamic_axis_num(inputs) states = tuple(initial_states) outputs = [] time_axis = 1 - nones if nones > 0 else 1 if go_backwards: i = shape[1] - 1 while i >= 0: current = C.ops.slice(inputs, time_axis, i, i + 1) # remove dummy dimension current = squeeze(current, time_axis) output, new_states = step_function( current, tuple(states) + tuple(constants)) if getattr(output, '_uses_learning_phase', False): uses_learning_phase = True if mask is not None: mask_slice = C.ops.slice(mask, time_axis, i, i + 1) mask_slice = squeeze(mask_slice, time_axis) if len(outputs) == 0: prev_output = zeros_like(output) else: prev_output = outputs[-1] output = C.ops.element_select(mask_slice, output, prev_output) return_states = [] for s, n_s in zip(states, new_states): return_states.append( C.ops.element_select( mask_slice, n_s, s)) new_states = return_states outputs.append(output) states = new_states i -= 1 else: i = 0 while i < shape[1]: current = C.ops.slice(inputs, time_axis, i, i + 1) # remove dummy dimension current = squeeze(current, 1) output, new_states = step_function( current, tuple(states) + tuple(constants)) if getattr(output, '_uses_learning_phase', False): uses_learning_phase = True if mask is not None: mask_slice = C.ops.slice(mask, time_axis, i, i + 1) mask_slice = squeeze(mask_slice, 1) if len(outputs) == 0: prev_output = zeros_like(output) else: prev_output = outputs[-1] output = C.ops.element_select(mask_slice, output, prev_output) return_states = [] for s, n_s in zip(states, new_states): return_states.append( C.ops.element_select( mask_slice, n_s, s)) new_states = return_states outputs.append(output) states = new_states[:len(states)] i += 1 i = 1 # add the time_step axis back final_output = expand_dims(outputs[0], 1) last_output = outputs[0] while i < len(outputs): # add the time_step axis back output_slice = expand_dims(outputs[i], 1) final_output = C.splice(final_output, output_slice, axis=time_axis) last_output = outputs[i] i += 1 last_output._uses_learning_phase = uses_learning_phase return last_output, final_output, states def rnn(step_function, inputs, initial_states, go_backwards=False, mask=None, constants=None, unroll=False, input_length=None): shape = int_shape(inputs) dims = len(shape) global uses_learning_phase uses_learning_phase = False if dims < 3: raise ValueError('CNTK Backend: the input of rnn has only rank %d ' 'Need at least rank 3 to run RNN.' % dims) if _get_dynamic_axis_num(inputs) == 0 or unroll: return _static_rnn( step_function, inputs, initial_states, go_backwards, mask, constants, unroll, input_length) if constants is None: constants = [] num_time_step = shape[1] if num_time_step is None and not has_seq_axis(inputs): num_time_step = inputs.shape[0] initial = [] for s in initial_states: if _get_dynamic_axis_num(s) == 0: if hasattr(C, 'to_batch'): initial.append(C.to_batch(s)) else: initial.append(C.user_function(ConvertToBatch(s))) else: initial.append(s) need_convert = not has_seq_axis(inputs) if go_backwards and need_convert is False: raise NotImplementedError('CNTK Backend: `go_backwards` is not supported with ' 'variable-length sequences. Please specify a ' 'static length for your sequences.') rnn_inputs = inputs if need_convert: if go_backwards: rnn_inputs = reverse(rnn_inputs, 1) rnn_inputs = C.to_sequence(rnn_inputs) rnn_constants = [] for constant in constants: if isinstance(constant, list): new_c = [] for c in constant: if _get_dynamic_axis_num(c) == 1: new_c.append(C.sequence.broadcast_as(c, rnn_inputs)) else: new_c.append(c) rnn_constants.append(new_c) else: if _get_dynamic_axis_num(constant) == 1: rnn_constants.append(C.sequence.broadcast_as(constant, rnn_inputs)) else: rnn_constants.append(constant) else: rnn_constants = constants if mask is not None and not has_seq_axis(mask): if go_backwards: mask = reverse(mask, 1) if len(int_shape(mask)) == 2: mask = expand_dims(mask) mask = C.to_sequence_like(mask, rnn_inputs) states = tuple(initial) with C.default_options(axis_offset=1): def _recurrence(x, states, m): # create place holder place_holders = [C.placeholder(dynamic_axes=x.dynamic_axes) for _ in states] past_values = [] for s, p in zip(states, place_holders): past_values.append(C.sequence.past_value(p, s)) new_output, new_states = step_function( x, tuple(past_values) + tuple(rnn_constants)) if getattr(new_output, '_uses_learning_phase', False): global uses_learning_phase uses_learning_phase = True if m is not None: new_states = [C.element_select(m, n, s) for n, s in zip(new_states, past_values)] n_s = [] for o, p in zip(new_states, place_holders): n_s.append(o.replace_placeholders({p: o.output})) if len(n_s) > 0: new_output = n_s[0] return new_output, n_s final_output, final_states = _recurrence(rnn_inputs, states, mask) last_output = C.sequence.last(final_output) last_states = [C.sequence.last(s) for s in final_states] if need_convert: final_output = C.sequence.unpack(final_output, 0, no_mask_output=True) if num_time_step is not None and num_time_step is not C.FreeDimension: final_output = _reshape_sequence(final_output, num_time_step) f_stats = [] for l_s, i_s in zip(last_states, initial_states): if _get_dynamic_axis_num(i_s) == 0 and _get_dynamic_axis_num(l_s) == 1: if hasattr(C, 'unpack_batch'): f_stats.append(C.unpack_batch(l_s)) else: f_stats.append(C.user_function(ConvertToStatic(l_s, batch_size=i_s.shape[0]))) else: f_stats.append(l_s) last_output._uses_learning_phase = uses_learning_phase return last_output, final_output, f_stats def has_seq_axis(x): return hasattr(x, 'dynamic_axes') and len(x.dynamic_axes) > 1 def l2_normalize(x, axis=None): axis = [axis] axis = _normalize_axis(axis, x) norm = C.sqrt(C.reduce_sum(C.square(x), axis=axis[0])) return x / norm def hard_sigmoid(x): x = (0.2 * x) + 0.5 x = C.clip(x, 0.0, 1.0) return x def conv1d(x, kernel, strides=1, padding='valid', data_format=None, dilation_rate=1): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) if padding == 'causal': # causal (dilated) convolution: left_pad = dilation_rate * (kernel.shape[0] - 1) x = temporal_padding(x, (left_pad, 0)) padding = 'valid' if data_format == 'channels_last': x = C.swapaxes(x, 0, 1) kernel = C.swapaxes(kernel, 0, 2) padding = _preprocess_border_mode(padding) strides = [strides] x = C.convolution( kernel, x, strides=tuple(strides), auto_padding=[ False, padding]) if data_format == 'channels_last': x = C.swapaxes(x, 0, 1) return x def conv2d(x, kernel, strides=(1, 1), padding='valid', data_format=None, dilation_rate=(1, 1)): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) x = _preprocess_conv2d_input(x, data_format) kernel = _preprocess_conv2d_kernel(kernel, data_format) padding = _preprocess_border_mode(padding) if dilation_rate == (1, 1): strides = (1,) + strides x = C.convolution( kernel, x, strides, auto_padding=[ False, padding, padding]) else: assert dilation_rate[0] == dilation_rate[1] assert strides == (1, 1), 'Invalid strides for dilated convolution' x = C.convolution( kernel, x, strides=dilation_rate[0], auto_padding=[ False, padding, padding]) return _postprocess_conv2d_output(x, data_format) def separable_conv1d(x, depthwise_kernel, pointwise_kernel, strides=1, padding='valid', data_format=None, dilation_rate=1): raise NotImplementedError def separable_conv2d(x, depthwise_kernel, pointwise_kernel, strides=(1, 1), padding='valid', data_format=None, dilation_rate=(1, 1)): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) x = _preprocess_conv2d_input(x, data_format) depthwise_kernel = _preprocess_conv2d_kernel(depthwise_kernel, data_format) depthwise_kernel = C.reshape(C.transpose(depthwise_kernel, (1, 0, 2, 3)), (-1, 1) + depthwise_kernel.shape[2:]) pointwise_kernel = _preprocess_conv2d_kernel(pointwise_kernel, data_format) padding = _preprocess_border_mode(padding) if dilation_rate == (1, 1): strides = (1,) + strides x = C.convolution(depthwise_kernel, x, strides=strides, auto_padding=[False, padding, padding], groups=x.shape[0]) x = C.convolution(pointwise_kernel, x, strides=(1, 1, 1), auto_padding=[False]) else: if dilation_rate[0] != dilation_rate[1]: raise ValueError('CNTK Backend: non-square dilation_rate is ' 'not supported.') if strides != (1, 1): raise ValueError('Invalid strides for dilated convolution') x = C.convolution(depthwise_kernel, x, strides=dilation_rate[0], auto_padding=[False, padding, padding]) x = C.convolution(pointwise_kernel, x, strides=(1, 1, 1), auto_padding=[False]) return _postprocess_conv2d_output(x, data_format) def depthwise_conv2d(x, depthwise_kernel, strides=(1, 1), padding='valid', data_format=None, dilation_rate=(1, 1)): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) x = _preprocess_conv2d_input(x, data_format) depthwise_kernel = _preprocess_conv2d_kernel(depthwise_kernel, data_format) depthwise_kernel = C.reshape(C.transpose(depthwise_kernel, (1, 0, 2, 3)), (-1, 1) + depthwise_kernel.shape[2:]) padding = _preprocess_border_mode(padding) if dilation_rate == (1, 1): strides = (1,) + strides x = C.convolution(depthwise_kernel, x, strides=strides, auto_padding=[False, padding, padding], groups=x.shape[0]) else: if dilation_rate[0] != dilation_rate[1]: raise ValueError('CNTK Backend: non-square dilation_rate is ' 'not supported.') if strides != (1, 1): raise ValueError('Invalid strides for dilated convolution') x = C.convolution(depthwise_kernel, x, strides=dilation_rate[0], auto_padding=[False, padding, padding], groups=x.shape[0]) return _postprocess_conv2d_output(x, data_format) def conv3d(x, kernel, strides=(1, 1, 1), padding='valid', data_format=None, dilation_rate=(1, 1, 1)): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) x = _preprocess_conv3d_input(x, data_format) kernel = _preprocess_conv3d_kernel(kernel, data_format) padding = _preprocess_border_mode(padding) strides = strides + (strides[0],) x = C.convolution( kernel, x, strides, auto_padding=[ False, padding, padding, padding]) return _postprocess_conv3d_output(x, data_format) def conv3d_transpose(x, kernel, output_shape, strides=(1, 1, 1), padding='valid', data_format=None): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) x = _preprocess_conv3d_input(x, data_format) kernel = _preprocess_conv3d_kernel(kernel, data_format) padding = _preprocess_border_mode(padding) strides = (1,) + strides # cntk output_shape does not include batch axis output_shape = output_shape[1:] # in keras2, need handle output shape in different format if data_format == 'channels_last': shape = list(output_shape) shape[0] = output_shape[3] shape[1] = output_shape[0] shape[2] = output_shape[1] shape[3] = output_shape[2] output_shape = tuple(shape) x = C.convolution_transpose( kernel, x, strides, auto_padding=[ False, padding, padding, padding], output_shape=output_shape) return _postprocess_conv3d_output(x, data_format) def pool2d(x, pool_size, strides=(1, 1), padding='valid', data_format=None, pool_mode='max'): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) padding = _preprocess_border_mode(padding) strides = strides pool_size = pool_size x = _preprocess_conv2d_input(x, data_format) if pool_mode == 'max': x = C.pooling( x, C.MAX_POOLING, pool_size, strides, auto_padding=[padding]) elif pool_mode == 'avg': x = C.pooling( x, C.AVG_POOLING, pool_size, strides, auto_padding=[padding]) else: raise ValueError('Invalid pooling mode: ' + str(pool_mode)) return _postprocess_conv2d_output(x, data_format) def pool3d(x, pool_size, strides=(1, 1, 1), padding='valid', data_format=None, pool_mode='max'): if data_format is None: data_format = image_data_format() if data_format not in {'channels_first', 'channels_last'}: raise ValueError('Unknown data_format ' + str(data_format)) padding = _preprocess_border_mode(padding) x = _preprocess_conv3d_input(x, data_format) if pool_mode == 'max': x = C.pooling( x, C.MAX_POOLING, pool_size, strides, auto_padding=[padding]) elif pool_mode == 'avg': x = C.pooling( x, C.AVG_POOLING, pool_size, strides, auto_padding=[padding]) else: raise ValueError('Invalid pooling mode: ' + str(pool_mode)) return _postprocess_conv3d_output(x, data_format) def relu(x, alpha=0., max_value=None): if alpha != 0.: negative_part = C.relu(-x) x = C.relu(x) if max_value is not None: x = C.clip(x, 0.0, max_value) if alpha != 0.: x -= alpha * negative_part return x def dropout(x, level, noise_shape=None, seed=None): if level < 0. or level >= 1: raise ValueError('CNTK Backend: Invalid dropout level %s, ' 'must be in interval [0, 1].' % level) return C.dropout(x, level) def batch_flatten(x): # cntk's batch axis is not in shape, # so just flatten all the dim in x.shape dim =

np.prod(x.shape)

numpy.prod

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k') plt.plot(((time[-202] + time[-201]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed', label=textwrap.fill('Neural network targets', 13)) plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(((time_extended[-1001] + time_extended[-1000]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed') plt.xlim(3.4 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/neural_network.png') plt.show() # plot 6a np.random.seed(0) time = np.linspace(0, 5 * np.pi, 1001) knots_51 = np.linspace(0, 5 * np.pi, 51) time_series = np.cos(2 * time) + np.cos(4 * time) + np.cos(8 * time) noise = np.random.normal(0, 1, len(time_series)) time_series += noise advemdpy = EMD(time=time, time_series=time_series) imfs_51, hts_51, ifs_51 = advemdpy.empirical_mode_decomposition(knots=knots_51, max_imfs=3, edge_effect='symmetric_anchor', verbose=False)[:3] knots_31 = np.linspace(0, 5 * np.pi, 31) imfs_31, hts_31, ifs_31 = advemdpy.empirical_mode_decomposition(knots=knots_31, max_imfs=2, edge_effect='symmetric_anchor', verbose=False)[:3] knots_11 = np.linspace(0, 5 * np.pi, 11) imfs_11, hts_11, ifs_11 = advemdpy.empirical_mode_decomposition(knots=knots_11, max_imfs=1, edge_effect='symmetric_anchor', verbose=False)[:3] fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) print(f'DFA fluctuation with 51 knots: {np.round(np.var(time_series - (imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :])), 3)}') for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[0].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[0].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[0].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) print(f'DFA fluctuation with 31 knots: {np.round(np.var(time_series - (imfs_31[1, :] + imfs_31[2, :])), 3)}') for knot in knots_31: axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[1].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[1].set_xticklabels(['', '', '', '', '', '']) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) axs[1].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[1].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[1].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[1].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') axs[2].plot(time, time_series, label='Time series') axs[2].plot(time, imfs_11[1, :], label='IMF 1 with 11 knots') axs[2].plot(time, imfs_31[2, :], label='IMF 2 with 31 knots') axs[2].plot(time, imfs_51[3, :], label='IMF 3 with 51 knots') print(f'DFA fluctuation with 11 knots: {np.round(np.var(time_series - imfs_51[3, :]), 3)}') for knot in knots_11: axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[2].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[2].set_xticklabels(['$0$', r'$\pi$', r'$2\pi$', r'$3\pi$', r'$4\pi$', r'$5\pi$']) box_2 = axs[2].get_position() axs[2].set_position([box_2.x0 - 0.05, box_2.y0, box_2.width * 0.85, box_2.height]) axs[2].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[2].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), 5.5 * np.ones(101), 'k--') axs[2].plot(np.linspace(0.95 * np.pi, 1.55 * np.pi, 101), -5.5 * np.ones(101), 'k--') axs[2].plot(0.95 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--') axs[2].plot(1.55 * np.pi * np.ones(101), np.linspace(-5.5, 5.5, 101), 'k--', label='Zoomed region') plt.savefig('jss_figures/DFA_different_trends.png') plt.show() # plot 6b fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences Zoomed Region', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) for knot in knots_51: axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[0].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[0].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[0].set_xticklabels(['', '', '', '', '', '']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[0].set_ylim(-5.5, 5.5) axs[0].set_xlim(0.95 * np.pi, 1.55 * np.pi) axs[1].plot(time, time_series, label='Time series') axs[1].plot(time, imfs_31[1, :] + imfs_31[2, :], label=textwrap.fill('Sum of IMF 1 and IMF 2 with 31 knots', 19)) axs[1].plot(time, imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 2 and IMF 3 with 51 knots', 19)) for knot in knots_31: axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[1].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[1].set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi]) axs[1].set_xticklabels(['', '', '', '', '', '']) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) axs[1].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[1].set_ylim(-5.5, 5.5) axs[1].set_xlim(0.95 * np.pi, 1.55 * np.pi) axs[2].plot(time, time_series, label='Time series') axs[2].plot(time, imfs_11[1, :], label='IMF 1 with 11 knots') axs[2].plot(time, imfs_31[2, :], label='IMF 2 with 31 knots') axs[2].plot(time, imfs_51[3, :], label='IMF 3 with 51 knots') for knot in knots_11: axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1) axs[2].plot(knot * np.ones(101), np.linspace(-5, 5, 101), '--', c='grey', zorder=1, label='Knots') axs[2].set_xticks([np.pi, (3 / 2) * np.pi]) axs[2].set_xticklabels([r'$\pi$', r'$\frac{3}{2}\pi$']) box_2 = axs[2].get_position() axs[2].set_position([box_2.x0 - 0.05, box_2.y0, box_2.width * 0.85, box_2.height]) axs[2].legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) axs[2].set_ylim(-5.5, 5.5) axs[2].set_xlim(0.95 * np.pi, 1.55 * np.pi) plt.savefig('jss_figures/DFA_different_trends_zoomed.png') plt.show() hs_ouputs = hilbert_spectrum(time, imfs_51, hts_51, ifs_51, max_frequency=12, plot=False) # plot 6c ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Simple Sinusoidal Time Seres with Added Noise', 50)) x_hs, y, z = hs_ouputs z_min, z_max = 0, np.abs(z).max() ax.pcolormesh(x_hs, y, np.abs(z), cmap='gist_rainbow', vmin=z_min, vmax=z_max) ax.plot(x_hs[0, :], 8 * np.ones_like(x_hs[0, :]), '--', label=r'$\omega = 8$', Linewidth=3) ax.plot(x_hs[0, :], 4 * np.ones_like(x_hs[0, :]), '--', label=r'$\omega = 4$', Linewidth=3) ax.plot(x_hs[0, :], 2 * np.ones_like(x_hs[0, :]), '--', label=r'$\omega = 2$', Linewidth=3) ax.set_xticks([0, np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi]) ax.set_xticklabels(['$0$', r'$\pi$', r'$2\pi$', r'$3\pi$', r'$4\pi$']) plt.ylabel(r'Frequency (rad.s$^{-1}$)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.85, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/DFA_hilbert_spectrum.png') plt.show() # plot 6c time = np.linspace(0, 5 * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 51) fluc = Fluctuation(time=time, time_series=time_series) max_unsmoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='maxima', smooth=False) max_smoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='maxima', smooth=True) min_unsmoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='minima', smooth=False) min_smoothed = fluc.envelope_basis_function_approximation(knots_for_envelope=knots, extrema_type='minima', smooth=True) util = Utility(time=time, time_series=time_series) maxima = util.max_bool_func_1st_order_fd() minima = util.min_bool_func_1st_order_fd() ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title(textwrap.fill('Plot Demonstrating Unsmoothed Extrema Envelopes if Schoenberg–Whitney Conditions are Not Satisfied', 50)) plt.plot(time, time_series, label='Time series', zorder=2, LineWidth=2) plt.scatter(time[maxima], time_series[maxima], c='r', label='Maxima', zorder=10) plt.scatter(time[minima], time_series[minima], c='b', label='Minima', zorder=10) plt.plot(time, max_unsmoothed[0], label=textwrap.fill('Unsmoothed maxima envelope', 10), c='darkorange') plt.plot(time, max_smoothed[0], label=textwrap.fill('Smoothed maxima envelope', 10), c='red') plt.plot(time, min_unsmoothed[0], label=textwrap.fill('Unsmoothed minima envelope', 10), c='cyan') plt.plot(time, min_smoothed[0], label=textwrap.fill('Smoothed minima envelope', 10), c='blue') for knot in knots[:-1]: plt.plot(knot * np.ones(101), np.linspace(-3.0, -2.0, 101), '--', c='grey', zorder=1) plt.plot(knots[-1] * np.ones(101), np.linspace(-3.0, -2.0, 101), '--', c='grey', label='Knots', zorder=1) plt.xticks((0, 1 * np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi), (r'$0$', r'$\pi$', r'2$\pi$', r'3$\pi$', r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) plt.xlim(-0.25 * np.pi, 5.25 * np.pi) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Schoenberg_Whitney_Conditions.png') plt.show() # plot 7 a = 0.25 width = 0.2 time = np.linspace((0 + a) * np.pi, (5 - a) * np.pi, 1001) knots = np.linspace((0 + a) * np.pi, (5 - a) * np.pi, 11) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] inflection_bool = utils.inflection_point() inflection_x = time[inflection_bool] inflection_y = time_series[inflection_bool] fluctuation = emd_mean.Fluctuation(time=time, time_series=time_series) maxima_envelope = fluctuation.envelope_basis_function_approximation(knots, 'maxima', smooth=False, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] maxima_envelope_smooth = fluctuation.envelope_basis_function_approximation(knots, 'maxima', smooth=True, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] minima_envelope = fluctuation.envelope_basis_function_approximation(knots, 'minima', smooth=False, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] minima_envelope_smooth = fluctuation.envelope_basis_function_approximation(knots, 'minima', smooth=True, smoothing_penalty=0.2, edge_effect='none', spline_method='b_spline')[0] inflection_points_envelope = fluctuation.direct_detrended_fluctuation_estimation(knots, smooth=True, smoothing_penalty=0.2, technique='inflection_points')[0] binomial_points_envelope = fluctuation.direct_detrended_fluctuation_estimation(knots, smooth=True, smoothing_penalty=0.2, technique='binomial_average', order=21, increment=20)[0] derivative_of_lsq = utils.derivative_forward_diff() derivative_time = time[:-1] derivative_knots = np.linspace(knots[0], knots[-1], 31) # change (1) detrended_fluctuation_technique and (2) max_internal_iter and (3) debug (confusing with external debugging) emd = AdvEMDpy.EMD(time=derivative_time, time_series=derivative_of_lsq) imf_1_of_derivative = emd.empirical_mode_decomposition(knots=derivative_knots, knot_time=derivative_time, text=False, verbose=False)[0][1, :] utils = emd_utils.Utility(time=time[:-1], time_series=imf_1_of_derivative) optimal_maxima = np.r_[False, utils.derivative_forward_diff() < 0, False] & \ np.r_[utils.zero_crossing() == 1, False] optimal_minima = np.r_[False, utils.derivative_forward_diff() > 0, False] & \ np.r_[utils.zero_crossing() == 1, False] EEMD_maxima_envelope = fluctuation.envelope_basis_function_approximation_fixed_points(knots, 'maxima', optimal_maxima, optimal_minima, smooth=False, smoothing_penalty=0.2, edge_effect='none')[0] EEMD_minima_envelope = fluctuation.envelope_basis_function_approximation_fixed_points(knots, 'minima', optimal_maxima, optimal_minima, smooth=False, smoothing_penalty=0.2, edge_effect='none')[0] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Detrended Fluctuation Analysis Examples') plt.plot(time, time_series, LineWidth=2, label='Time series') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(time[optimal_maxima], time_series[optimal_maxima], c='darkred', zorder=4, label=textwrap.fill('Optimal maxima', 10)) plt.scatter(time[optimal_minima], time_series[optimal_minima], c='darkblue', zorder=4, label=textwrap.fill('Optimal minima', 10)) plt.scatter(inflection_x, inflection_y, c='magenta', zorder=4, label=textwrap.fill('Inflection points', 10)) plt.plot(time, maxima_envelope, c='darkblue', label=textwrap.fill('EMD envelope', 10)) plt.plot(time, minima_envelope, c='darkblue') plt.plot(time, (maxima_envelope + minima_envelope) / 2, c='darkblue') plt.plot(time, maxima_envelope_smooth, c='darkred', label=textwrap.fill('SEMD envelope', 10)) plt.plot(time, minima_envelope_smooth, c='darkred') plt.plot(time, (maxima_envelope_smooth + minima_envelope_smooth) / 2, c='darkred') plt.plot(time, EEMD_maxima_envelope, c='darkgreen', label=textwrap.fill('EEMD envelope', 10)) plt.plot(time, EEMD_minima_envelope, c='darkgreen') plt.plot(time, (EEMD_maxima_envelope + EEMD_minima_envelope) / 2, c='darkgreen') plt.plot(time, inflection_points_envelope, c='darkorange', label=textwrap.fill('Inflection point envelope', 10)) plt.plot(time, binomial_points_envelope, c='deeppink', label=textwrap.fill('Binomial average envelope', 10)) plt.plot(time, np.cos(time), c='black', label='True mean') plt.xticks((0, 1 * np.pi, 2 * np.pi, 3 * np.pi, 4 * np.pi, 5 * np.pi), (r'$0$', r'$\pi$', r'2$\pi$', r'3$\pi$', r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) plt.xlim(-0.25 * np.pi, 5.25 * np.pi) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/detrended_fluctuation_analysis.png') plt.show() # Duffing Equation Example def duffing_equation(xy, ts): gamma = 0.1 epsilon = 1 omega = ((2 * np.pi) / 25) return [xy[1], xy[0] - epsilon * xy[0] ** 3 + gamma * np.cos(omega * ts)] t = np.linspace(0, 150, 1501) XY0 = [1, 1] solution = odeint(duffing_equation, XY0, t) x = solution[:, 0] dxdt = solution[:, 1] x_points = [0, 50, 100, 150] x_names = {0, 50, 100, 150} y_points_1 = [-2, 0, 2] y_points_2 = [-1, 0, 1] fig, axs = plt.subplots(2, 1) plt.subplots_adjust(hspace=0.2) axs[0].plot(t, x) axs[0].set_title('Duffing Equation Displacement') axs[0].set_ylim([-2, 2]) axs[0].set_xlim([0, 150]) axs[1].plot(t, dxdt) axs[1].set_title('Duffing Equation Velocity') axs[1].set_ylim([-1.5, 1.5]) axs[1].set_xlim([0, 150]) axis = 0 for ax in axs.flat: ax.label_outer() if axis == 0: ax.set_ylabel('x(t)') ax.set_yticks(y_points_1) if axis == 1: ax.set_ylabel(r'$ \dfrac{dx(t)}{dt} $') ax.set(xlabel='t') ax.set_yticks(y_points_2) ax.set_xticks(x_points) ax.set_xticklabels(x_names) axis += 1 plt.savefig('jss_figures/Duffing_equation.png') plt.show() # compare other packages Duffing - top pyemd = pyemd0215() py_emd = pyemd(x) IP, IF, IA = emd040.spectra.frequency_transform(py_emd.T, 10, 'hilbert') freq_edges, freq_bins = emd040.spectra.define_hist_bins(0, 0.2, 100) hht = emd040.spectra.hilberthuang(IF, IA, freq_edges) hht = gaussian_filter(hht, sigma=1) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 1.0 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Duffing Equation using PyEMD 0.2.10', 40)) plt.pcolormesh(t, freq_bins, hht, cmap='gist_rainbow', vmin=0, vmax=np.max(np.max(np.abs(hht)))) plt.plot(t[:-1], 0.124 * np.ones_like(t[:-1]), '--', label=textwrap.fill('Hamiltonian frequency approximation', 15)) plt.plot(t[:-1], 0.04 * np.ones_like(t[:-1]), 'g--', label=textwrap.fill('Driving function frequency', 15)) plt.xticks([0, 50, 100, 150]) plt.yticks([0, 0.1, 0.2]) plt.ylabel('Frequency (Hz)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.75, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Duffing_equation_ht_pyemd.png') plt.show() plt.show() emd_sift = emd040.sift.sift(x) IP, IF, IA = emd040.spectra.frequency_transform(emd_sift, 10, 'hilbert') freq_edges, freq_bins = emd040.spectra.define_hist_bins(0, 0.2, 100) hht = emd040.spectra.hilberthuang(IF, IA, freq_edges) hht = gaussian_filter(hht, sigma=1) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 1.0 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Duffing Equation using emd 0.3.3', 40)) plt.pcolormesh(t, freq_bins, hht, cmap='gist_rainbow', vmin=0, vmax=np.max(np.max(np.abs(hht)))) plt.plot(t[:-1], 0.124 * np.ones_like(t[:-1]), '--', label=textwrap.fill('Hamiltonian frequency approximation', 15)) plt.plot(t[:-1], 0.04 * np.ones_like(t[:-1]), 'g--', label=textwrap.fill('Driving function frequency', 15)) plt.xticks([0, 50, 100, 150]) plt.yticks([0, 0.1, 0.2]) plt.ylabel('Frequency (Hz)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.75, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Duffing_equation_ht_emd.png') plt.show() # compare other packages Duffing - bottom emd_duffing = AdvEMDpy.EMD(time=t, time_series=x) emd_duff, emd_ht_duff, emd_if_duff, _, _, _, _ = emd_duffing.empirical_mode_decomposition(verbose=False) fig, axs = plt.subplots(2, 1) plt.subplots_adjust(hspace=0.3) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) axs[0].plot(t, emd_duff[1, :], label='AdvEMDpy') axs[0].plot(t, py_emd[0, :], '--', label='PyEMD 0.2.10') axs[0].plot(t, emd_sift[:, 0], '--', label='emd 0.3.3') axs[0].set_title('IMF 1') axs[0].set_ylim([-2, 2]) axs[0].set_xlim([0, 150]) axs[1].plot(t, emd_duff[2, :], label='AdvEMDpy') print(f'AdvEMDpy driving function error: {np.round(sum(abs(0.1 * np.cos(0.04 * 2 * np.pi * t) - emd_duff[2, :])), 3)}') axs[1].plot(t, py_emd[1, :], '--', label='PyEMD 0.2.10') print(f'PyEMD driving function error: {np.round(sum(abs(0.1 * np.cos(0.04 * 2 * np.pi * t) - py_emd[1, :])), 3)}') axs[1].plot(t, emd_sift[:, 1], '--', label='emd 0.3.3') print(f'emd driving function error: {np.round(sum(abs(0.1 * np.cos(0.04 * 2 * np.pi * t) - emd_sift[:, 1])), 3)}') axs[1].plot(t, 0.1 * np.cos(0.04 * 2 * np.pi * t), '--', label=r'$0.1$cos$(0.08{\pi}t)$') axs[1].set_title('IMF 2') axs[1].set_ylim([-0.2, 0.4]) axs[1].set_xlim([0, 150]) axis = 0 for ax in axs.flat: ax.label_outer() if axis == 0: ax.set_ylabel(r'$\gamma_1(t)$') ax.set_yticks([-2, 0, 2]) if axis == 1: ax.set_ylabel(r'$\gamma_2(t)$') ax.set_yticks([-0.2, 0, 0.2]) box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5), fontsize=8) ax.set_xticks(x_points) ax.set_xticklabels(x_names) axis += 1 plt.savefig('jss_figures/Duffing_equation_imfs.png') plt.show() hs_ouputs = hilbert_spectrum(t, emd_duff, emd_ht_duff, emd_if_duff, max_frequency=1.3, plot=False) ax = plt.subplot(111) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of Duffing Equation using AdvEMDpy', 40)) x, y, z = hs_ouputs y = y / (2 * np.pi) z_min, z_max = 0, np.abs(z).max() figure_size = plt.gcf().get_size_inches() factor = 1.0 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) ax.pcolormesh(x, y, np.abs(z), cmap='gist_rainbow', vmin=z_min, vmax=z_max) plt.plot(t[:-1], 0.124 * np.ones_like(t[:-1]), '--', label=textwrap.fill('Hamiltonian frequency approximation', 15)) plt.plot(t[:-1], 0.04 * np.ones_like(t[:-1]), 'g--', label=textwrap.fill('Driving function frequency', 15)) plt.xticks([0, 50, 100, 150]) plt.yticks([0, 0.1, 0.2]) plt.ylabel('Frequency (Hz)') plt.xlabel('Time (s)') box_0 = ax.get_position() ax.set_position([box_0.x0, box_0.y0 + 0.05, box_0.width * 0.75, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/Duffing_equation_ht.png') plt.show() # Carbon Dioxide Concentration Example CO2_data = pd.read_csv('Data/co2_mm_mlo.csv', header=51) plt.plot(CO2_data['month'], CO2_data['decimal date']) plt.title(textwrap.fill('Mean Monthly Concentration of Carbon Dioxide in the Atmosphere', 35)) plt.ylabel('Parts per million') plt.xlabel('Time (years)') plt.savefig('jss_figures/CO2_concentration.png') plt.show() signal = CO2_data['decimal date'] signal = np.asarray(signal) time = CO2_data['month'] time = np.asarray(time) # compare other packages Carbon Dioxide - top pyemd = pyemd0215() py_emd = pyemd(signal) IP, IF, IA = emd040.spectra.frequency_transform(py_emd[:2, :].T, 12, 'hilbert') print(f'PyEMD annual frequency error: {np.round(sum(np.abs(IF[:, 0] - np.ones_like(IF[:, 0]))), 3)}') freq_edges, freq_bins = emd040.spectra.define_hist_bins(0, 2, 100) hht = emd040.spectra.hilberthuang(IF, IA, freq_edges) hht = gaussian_filter(hht, sigma=1) fig, ax = plt.subplots() figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.title(textwrap.fill('Gaussian Filtered Hilbert Spectrum of CO$_{2}$ Concentration using PyEMD 0.2.10', 45)) plt.ylabel('Frequency (year$^{-1}$)') plt.xlabel('Time (years)') plt.pcolormesh(time, freq_bins, hht, cmap='gist_rainbow', vmin=0, vmax=np.max(np.max(np.abs(hht)))) plt.plot(time, np.ones_like(time), 'k--', label=textwrap.fill('Annual cycle', 10)) box_0 = ax.get_position() ax.set_position([box_0.x0 + 0.0125, box_0.y0 + 0.075, box_0.width * 0.8, box_0.height * 0.9]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/CO2_Hilbert_pyemd.png') plt.show() emd_sift = emd040.sift.sift(signal) IP, IF, IA = emd040.spectra.frequency_transform(emd_sift[:, :1], 12, 'hilbert') print(f'emd annual frequency error: {np.round(sum(np.abs(IF -

np.ones_like(IF)

numpy.ones_like

# # Copyright (c) 2021 The GPflux Contributors. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. # import abc import numpy as np import pytest import tensorflow as tf import tensorflow_probability as tfp from gpflow.kullback_leiblers import gauss_kl from gpflux.encoders import DirectlyParameterizedNormalDiag from gpflux.layers import LatentVariableLayer, LayerWithObservations, TrackableLayer tf.keras.backend.set_floatx("float64") ############ # Utilities ############ def _zero_one_normal_prior(w_dim): """ N(0, I) prior """ return tfp.distributions.MultivariateNormalDiag(loc=np.zeros(w_dim), scale_diag=np.ones(w_dim)) def get_distributions_with_w_dim(): distributions = [] for d in [1, 5]: mean = np.zeros(d) scale_tri_l = np.eye(d) mvn = tfp.distributions.MultivariateNormalTriL(mean, scale_tri_l) std =

np.ones(d)

numpy.ones

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) min_1_y_time = minima_x[-1] * np.ones_like(min_1_y) dash_max_min_1_y_time = np.linspace(minima_x[-1], maxima_x[-1], 101) dash_max_min_1_y = -2.1 * np.ones_like(dash_max_min_1_y_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Characteristic Wave Effects Example') plt.plot(time, time_series, LineWidth=2, label='Signal') plt.scatter(Huang_max_time, Huang_max, c='magenta', zorder=4, label=textwrap.fill('Huang maximum', 10)) plt.scatter(Huang_min_time, Huang_min, c='lime', zorder=4, label=textwrap.fill('Huang minimum', 10)) plt.scatter(Coughlin_max_time, Coughlin_max, c='darkorange', zorder=4, label=textwrap.fill('Coughlin maximum', 14)) plt.scatter(Coughlin_min_time, Coughlin_min, c='dodgerblue', zorder=4, label=textwrap.fill('Coughlin minimum', 14)) plt.scatter(Average_max_time, Average_max, c='orangered', zorder=4, label=textwrap.fill('Average maximum', 14)) plt.scatter(Average_min_time, Average_min, c='cyan', zorder=4, label=textwrap.fill('Average minimum', 14)) plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.plot(Huang_time, Huang_wave, '--', c='darkviolet', label=textwrap.fill('Huang Characteristic Wave', 14)) plt.plot(Coughlin_time, Coughlin_wave, '--', c='darkgreen', label=textwrap.fill('Coughlin Characteristic Wave', 14)) plt.plot(max_2_x_time, max_2_x, 'k-') plt.plot(max_2_x_time_side, max_2_x, 'k-') plt.plot(min_2_x_time, min_2_x, 'k-') plt.plot(min_2_x_time_side, min_2_x, 'k-') plt.plot(dash_max_min_2_x_time, dash_max_min_2_x, 'k--') plt.text(5.16 * np.pi, 0.85, r'$2a_2$') plt.plot(max_2_y_time, max_2_y, 'k-') plt.plot(max_2_y_time, max_2_y_side, 'k-') plt.plot(min_2_y_time, min_2_y, 'k-') plt.plot(min_2_y_time, min_2_y_side, 'k-') plt.plot(dash_max_min_2_y_time, dash_max_min_2_y, 'k--') plt.text(4.08 * np.pi, -2.2, r'$\frac{p_2}{2}$') plt.plot(max_1_x_time, max_1_x, 'k-') plt.plot(max_1_x_time_side, max_1_x, 'k-') plt.plot(min_1_x_time, min_1_x, 'k-') plt.plot(min_1_x_time_side, min_1_x, 'k-') plt.plot(dash_max_min_1_x_time, dash_max_min_1_x, 'k--') plt.text(5.42 * np.pi, -0.1, r'$2a_1$') plt.plot(max_1_y_time, max_1_y, 'k-') plt.plot(max_1_y_time, max_1_y_side, 'k-') plt.plot(min_1_y_time, min_1_y, 'k-') plt.plot(min_1_y_time, min_1_y_side, 'k-') plt.plot(dash_max_min_1_y_time, dash_max_min_1_y, 'k--') plt.text(4.48 * np.pi, -2.5, r'$\frac{p_1}{2}$') plt.xlim(3.9 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_characteristic_wave.png') plt.show() # plot 6 t = np.linspace(5, 95, 100) signal_orig = np.cos(2 * np.pi * t / 50) + 0.6 * np.cos(2 * np.pi * t / 25) + 0.5 * np.sin(2 * np.pi * t / 200) util_nn = emd_utils.Utility(time=t, time_series=signal_orig) maxima = signal_orig[util_nn.max_bool_func_1st_order_fd()] minima = signal_orig[util_nn.min_bool_func_1st_order_fd()] cs_max = CubicSpline(t[util_nn.max_bool_func_1st_order_fd()], maxima) cs_min = CubicSpline(t[util_nn.min_bool_func_1st_order_fd()], minima) time = np.linspace(0, 5 * np.pi, 1001) lsq_signal = np.cos(time) + np.cos(5 * time) knots = np.linspace(0, 5 * np.pi, 101) time_extended = time_extension(time) time_series_extended = np.zeros_like(time_extended) / 0 time_series_extended[int(len(lsq_signal) - 1):int(2 * (len(lsq_signal) - 1) + 1)] = lsq_signal neural_network_m = 200 neural_network_k = 100 # forward -> P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[(-(neural_network_m + neural_network_k - col)):(-(neural_network_m - col))] P[-1, col] = 1 # for additive constant t = lsq_signal[-neural_network_m:] # test - top seed_weights = np.ones(neural_network_k) / neural_network_k weights = 0 * seed_weights.copy() train_input = P[:-1, :] lr = 0.01 for iterations in range(1000): output = np.matmul(weights, train_input) error = (t - output) gradients = error * (- train_input) # guess average gradients average_gradients = np.mean(gradients, axis=1) # steepest descent max_gradient_vector = average_gradients * (np.abs(average_gradients) == max(np.abs(average_gradients))) adjustment = - lr * average_gradients # adjustment = - lr * max_gradient_vector weights += adjustment # test - bottom weights_right = np.hstack((weights, 0)) max_count_right = 0 min_count_right = 0 i_right = 0 while ((max_count_right < 1) or (min_count_right < 1)) and (i_right < len(lsq_signal) - 1): time_series_extended[int(2 * (len(lsq_signal) - 1) + 1 + i_right)] = \ sum(weights_right * np.hstack((time_series_extended[ int(2 * (len(lsq_signal) - 1) + 1 - neural_network_k + i_right): int(2 * (len(lsq_signal) - 1) + 1 + i_right)], 1))) i_right += 1 if i_right > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_right += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)], time_series=time_series_extended[int(2 * (len(lsq_signal) - 1) + 1): int(2 * (len(lsq_signal) - 1) + 1 + i_right + 1)]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_right += 1 # backward <- P = np.zeros((int(neural_network_k + 1), neural_network_m)) for col in range(neural_network_m): P[:-1, col] = lsq_signal[int(col + 1):int(col + neural_network_k + 1)] P[-1, col] = 1 # for additive constant t = lsq_signal[:neural_network_m] vx = cvx.Variable(int(neural_network_k + 1)) objective = cvx.Minimize(cvx.norm((2 * (vx * P) + 1 - t), 2)) # linear activation function is arbitrary prob = cvx.Problem(objective) result = prob.solve(verbose=True, solver=cvx.ECOS) weights_left = np.array(vx.value) max_count_left = 0 min_count_left = 0 i_left = 0 while ((max_count_left < 1) or (min_count_left < 1)) and (i_left < len(lsq_signal) - 1): time_series_extended[int(len(lsq_signal) - 2 - i_left)] = \ 2 * sum(weights_left * np.hstack((time_series_extended[int(len(lsq_signal) - 1 - i_left): int(len(lsq_signal) - 1 - i_left + neural_network_k)], 1))) + 1 i_left += 1 if i_left > 1: emd_utils_max = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_max.max_bool_func_1st_order_fd()) > 0: max_count_left += 1 emd_utils_min = \ emd_utils.Utility(time=time_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))], time_series=time_series_extended[int(len(lsq_signal) - 1 - i_left):int(len(lsq_signal))]) if sum(emd_utils_min.min_bool_func_1st_order_fd()) > 0: min_count_left += 1 lsq_utils = emd_utils.Utility(time=time, time_series=lsq_signal) utils_extended = emd_utils.Utility(time=time_extended, time_series=time_series_extended) maxima = lsq_signal[lsq_utils.max_bool_func_1st_order_fd()] maxima_time = time[lsq_utils.max_bool_func_1st_order_fd()] maxima_extrapolate = time_series_extended[utils_extended.max_bool_func_1st_order_fd()][-1] maxima_extrapolate_time = time_extended[utils_extended.max_bool_func_1st_order_fd()][-1] minima = lsq_signal[lsq_utils.min_bool_func_1st_order_fd()] minima_time = time[lsq_utils.min_bool_func_1st_order_fd()] minima_extrapolate = time_series_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] minima_extrapolate_time = time_extended[utils_extended.min_bool_func_1st_order_fd()][-2:] ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('Single Neuron Neural Network Example') plt.plot(time, lsq_signal, zorder=2, label='Signal') plt.plot(time_extended, time_series_extended, c='g', zorder=1, label=textwrap.fill('Extrapolated signal', 12)) plt.scatter(maxima_time, maxima, c='r', zorder=3, label='Maxima') plt.scatter(minima_time, minima, c='b', zorder=3, label='Minima') plt.scatter(maxima_extrapolate_time, maxima_extrapolate, c='magenta', zorder=3, label=textwrap.fill('Extrapolated maxima', 12)) plt.scatter(minima_extrapolate_time, minima_extrapolate, c='cyan', zorder=4, label=textwrap.fill('Extrapolated minima', 12)) plt.plot(((time[-302] + time[-301]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k', label=textwrap.fill('Neural network inputs', 13)) plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time[-302] + time[-301]) / 2), ((time[-302] + time[-301]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='k') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1002]) / 2), ((time_extended[-1001] + time_extended[-1002]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='k') plt.plot(((time_extended[-1001] + time_extended[-1002]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='k') plt.plot(((time[-202] + time[-201]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed', label=textwrap.fill('Neural network targets', 13)) plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time[-202] + time[-201]) / 2), ((time[-202] + time[-201]) / 2) + 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), -2.75 * np.ones(100), c='gray') plt.plot(np.linspace(((time_extended[-1001] + time_extended[-1000]) / 2), ((time_extended[-1001] + time_extended[-1000]) / 2) - 0.1, 100), 2.75 * np.ones(100), c='gray') plt.plot(((time_extended[-1001] + time_extended[-1000]) / 2) * np.ones(100), np.linspace(-2.75, 2.75, 100), c='gray', linestyle='dashed') plt.xlim(3.4 * np.pi, 5.6 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.84, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/neural_network.png') plt.show() # plot 6a np.random.seed(0) time = np.linspace(0, 5 * np.pi, 1001) knots_51 = np.linspace(0, 5 * np.pi, 51) time_series = np.cos(2 * time) + np.cos(4 * time) + np.cos(8 * time) noise = np.random.normal(0, 1, len(time_series)) time_series += noise advemdpy = EMD(time=time, time_series=time_series) imfs_51, hts_51, ifs_51 = advemdpy.empirical_mode_decomposition(knots=knots_51, max_imfs=3, edge_effect='symmetric_anchor', verbose=False)[:3] knots_31 = np.linspace(0, 5 * np.pi, 31) imfs_31, hts_31, ifs_31 = advemdpy.empirical_mode_decomposition(knots=knots_31, max_imfs=2, edge_effect='symmetric_anchor', verbose=False)[:3] knots_11 = np.linspace(0, 5 * np.pi, 11) imfs_11, hts_11, ifs_11 = advemdpy.empirical_mode_decomposition(knots=knots_11, max_imfs=1, edge_effect='symmetric_anchor', verbose=False)[:3] fig, axs = plt.subplots(3, 1) plt.suptitle(textwrap.fill('Comparison of Trends Extracted with Different Knot Sequences', 40)) plt.subplots_adjust(hspace=0.1) axs[0].plot(time, time_series, label='Time series') axs[0].plot(time, imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :], label=textwrap.fill('Sum of IMF 1, IMF 2, & IMF 3 with 51 knots', 21)) print(f'DFA fluctuation with 51 knots: {np.round(

np.var(time_series - (imfs_51[1, :] + imfs_51[2, :] + imfs_51[3, :]))

numpy.var

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] *

np.ones(101)

numpy.ones

''' <NAME> set up :2020-1-9 intergrate img and label into one file -- fiducial1024_v1 ''' import argparse import sys, os import pickle import random import collections import json import numpy as np import scipy.io as io import scipy.misc as m import matplotlib.pyplot as plt import glob import math import time import threading import multiprocessing as mp from multiprocessing import Pool import re import cv2 # sys.path.append('/lustre/home/gwxie/hope/project/dewarp/datasets/') # /lustre/home/gwxie/program/project/unwarp/perturbed_imgaes/GAN import utils def getDatasets(dir): return os.listdir(dir) class perturbed(utils.BasePerturbed): def __init__(self, path, bg_path, save_path, save_suffix): self.path = path self.bg_path = bg_path self.save_path = save_path self.save_suffix = save_suffix def save_img(self, m, n, fold_curve='fold', repeat_time=4, fiducial_points = 16, relativeShift_position='relativeShift_v2'): origin_img = cv2.imread(self.path, flags=cv2.IMREAD_COLOR) save_img_shape = [512*2, 480*2] # 320 # reduce_value = np.random.choice([2**4, 2**5, 2**6, 2**7, 2**8], p=[0.01, 0.1, 0.4, 0.39, 0.1]) reduce_value = np.random.choice([2*2, 4*2, 8*2, 16*2, 24*2, 32*2, 40*2, 48*2], p=[0.02, 0.18, 0.2, 0.3, 0.1, 0.1, 0.08, 0.02]) # reduce_value = np.random.choice([8*2, 16*2, 24*2, 32*2, 40*2, 48*2], p=[0.01, 0.02, 0.2, 0.4, 0.19, 0.18]) # reduce_value = np.random.choice([16, 24, 32, 40, 48, 64], p=[0.01, 0.1, 0.2, 0.4, 0.2, 0.09]) base_img_shrink = save_img_shape[0] - reduce_value # enlarge_img_shrink = [1024, 768] # enlarge_img_shrink = [896, 672] # 420 enlarge_img_shrink = [512*4, 480*4] # 420 # enlarge_img_shrink = [896*2, 768*2] # 420 # enlarge_img_shrink = [896, 768] # 420 # enlarge_img_shrink = [768, 576] # 420 # enlarge_img_shrink = [640, 480] # 420 '''''' im_lr = origin_img.shape[0] im_ud = origin_img.shape[1] reduce_value_v2 = np.random.choice([2*2, 4*2, 8*2, 16*2, 24*2, 28*2, 32*2, 48*2], p=[0.02, 0.18, 0.2, 0.2, 0.1, 0.1, 0.1, 0.1]) # reduce_value_v2 = np.random.choice([16, 24, 28, 32, 48, 64], p=[0.01, 0.1, 0.2, 0.3, 0.25, 0.14]) if im_lr > im_ud: im_ud = min(int(im_ud / im_lr * base_img_shrink), save_img_shape[1] - reduce_value_v2) im_lr = save_img_shape[0] - reduce_value else: base_img_shrink = save_img_shape[1] - reduce_value im_lr = min(int(im_lr / im_ud * base_img_shrink), save_img_shape[0] - reduce_value_v2) im_ud = base_img_shrink if round(im_lr / im_ud, 2) < 0.5 or round(im_ud / im_lr, 2) < 0.5: repeat_time = min(repeat_time, 8) edge_padding = 3 im_lr -= im_lr % (fiducial_points-1) - (2*edge_padding) # im_lr % (fiducial_points-1) - 1 im_ud -= im_ud % (fiducial_points-1) - (2*edge_padding) # im_ud % (fiducial_points-1) - 1 im_hight = np.linspace(edge_padding, im_lr - edge_padding, fiducial_points, dtype=np.int64) im_wide = np.linspace(edge_padding, im_ud - edge_padding, fiducial_points, dtype=np.int64) # im_lr -= im_lr % (fiducial_points-1) - (1+2*edge_padding) # im_lr % (fiducial_points-1) - 1 # im_ud -= im_ud % (fiducial_points-1) - (1+2*edge_padding) # im_ud % (fiducial_points-1) - 1 # im_hight = np.linspace(edge_padding, im_lr - (1+edge_padding), fiducial_points, dtype=np.int64) # im_wide = np.linspace(edge_padding, im_ud - (1+edge_padding), fiducial_points, dtype=np.int64) im_x, im_y = np.meshgrid(im_hight, im_wide) segment_x = (im_lr) // (fiducial_points-1) segment_y = (im_ud) // (fiducial_points-1) # plt.plot(im_x, im_y, # color='limegreen', # marker='.', # linestyle='') # plt.grid(True) # plt.show() self.origin_img = cv2.resize(origin_img, (im_ud, im_lr), interpolation=cv2.INTER_CUBIC) perturbed_bg_ = getDatasets(self.bg_path) perturbed_bg_img_ = self.bg_path+random.choice(perturbed_bg_) perturbed_bg_img = cv2.imread(perturbed_bg_img_, flags=cv2.IMREAD_COLOR) mesh_shape = self.origin_img.shape[:2] self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 256, dtype=np.float32)#np.zeros_like(perturbed_bg_img) # self.synthesis_perturbed_img = np.full((enlarge_img_shrink[0], enlarge_img_shrink[1], 3), 0, dtype=np.int16)#np.zeros_like(perturbed_bg_img) self.new_shape = self.synthesis_perturbed_img.shape[:2] perturbed_bg_img = cv2.resize(perturbed_bg_img, (save_img_shape[1], save_img_shape[0]), cv2.INPAINT_TELEA) origin_pixel_position = np.argwhere(np.zeros(mesh_shape, dtype=np.uint32) == 0).reshape(mesh_shape[0], mesh_shape[1], 2) pixel_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape(self.new_shape[0], self.new_shape[1], 2) self.perturbed_xy_ = np.zeros((self.new_shape[0], self.new_shape[1], 2)) # self.perturbed_xy_ = pixel_position.copy().astype(np.float32) # fiducial_points_grid = origin_pixel_position[im_x, im_y] self.synthesis_perturbed_label = np.zeros((self.new_shape[0], self.new_shape[1], 2)) x_min, y_min, x_max, y_max = self.adjust_position_v2(0, 0, mesh_shape[0], mesh_shape[1], save_img_shape) origin_pixel_position += [x_min, y_min] x_min, y_min, x_max, y_max = self.adjust_position(0, 0, mesh_shape[0], mesh_shape[1]) x_shift = random.randint(-enlarge_img_shrink[0]//16, enlarge_img_shrink[0]//16) y_shift = random.randint(-enlarge_img_shrink[1]//16, enlarge_img_shrink[1]//16) x_min += x_shift x_max += x_shift y_min += y_shift y_max += y_shift '''im_x,y''' im_x += x_min im_y += y_min self.synthesis_perturbed_img[x_min:x_max, y_min:y_max] = self.origin_img self.synthesis_perturbed_label[x_min:x_max, y_min:y_max] = origin_pixel_position synthesis_perturbed_img_map = self.synthesis_perturbed_img.copy() synthesis_perturbed_label_map = self.synthesis_perturbed_label.copy() foreORbackground_label = np.full((mesh_shape), 1, dtype=np.int16) foreORbackground_label_map = np.full((self.new_shape), 0, dtype=np.int16) foreORbackground_label_map[x_min:x_max, y_min:y_max] = foreORbackground_label # synthesis_perturbed_img_map = self.pad(self.synthesis_perturbed_img.copy(), x_min, y_min, x_max, y_max) # synthesis_perturbed_label_map = self.pad(synthesis_perturbed_label_map, x_min, y_min, x_max, y_max) '''*****************************************************************''' is_normalizationFun_mixture = self.is_perform(0.2, 0.8) # if not is_normalizationFun_mixture: normalizationFun_0_1 = False # normalizationFun_0_1 = self.is_perform(0.5, 0.5) if fold_curve == 'fold': fold_curve_random = True # is_normalizationFun_mixture = False normalizationFun_0_1 = self.is_perform(0.2, 0.8) if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: fold_curve_random = self.is_perform(0.1, 0.9) # False # self.is_perform(0.01, 0.99) alpha_perturbed = random.randint(80, 160) / 100 # is_normalizationFun_mixture = False # self.is_perform(0.01, 0.99) synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) # synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 0, dtype=np.int16) synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) alpha_perturbed_change = self.is_perform(0.5, 0.5) p_pp_choice = self.is_perform(0.8, 0.2) if fold_curve == 'fold' else self.is_perform(0.1, 0.9) for repeat_i in range(repeat_time): if alpha_perturbed_change: if fold_curve == 'fold': if is_normalizationFun_mixture: alpha_perturbed = random.randint(80, 120) / 100 else: if normalizationFun_0_1 and repeat_time < 8: alpha_perturbed = random.randint(50, 70) / 100 else: alpha_perturbed = random.randint(70, 130) / 100 else: alpha_perturbed = random.randint(80, 160) / 100 '''''' linspace_x = [0, (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - (self.new_shape[0] - im_lr) // 2 - 1, self.new_shape[0] - 1] linspace_y = [0, (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - (self.new_shape[1] - im_ud) // 2 - 1, self.new_shape[1] - 1] linspace_x_seq = [1, 2, 3] linspace_y_seq = [1, 2, 3] r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_p = np.array( [random.randint(linspace_x[r_x-1] * 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 if ((r_x == 1 or r_x == 3) and (r_y == 1 or r_y == 3)) and p_pp_choice: linspace_x_seq.remove(r_x) linspace_y_seq.remove(r_y) r_x = random.choice(linspace_x_seq) r_y = random.choice(linspace_y_seq) perturbed_pp = np.array( [random.randint(linspace_x[r_x-1] * 10, linspace_x[r_x] * 10), random.randint(linspace_y[r_y-1] * 10, linspace_y[r_y] * 10)])/10 # perturbed_p, perturbed_pp = np.array( # [random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) \ # , np.array([random.randint(0, self.new_shape[0] * 10) / 10, # random.randint(0, self.new_shape[1] * 10) / 10]) # perturbed_p, perturbed_pp = np.array( # [random.randint((self.new_shape[0]-im_lr)//2*10, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) * 10) / 10, # random.randint((self.new_shape[1]-im_ud)//2*10, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) * 10) / 10]) \ # , np.array([random.randint((self.new_shape[0]-im_lr)//2*10, (self.new_shape[0]-(self.new_shape[0]-im_lr)//2) * 10) / 10, # random.randint((self.new_shape[1]-im_ud)//2*10, (self.new_shape[1]-(self.new_shape[1]-im_ud)//2) * 10) / 10]) '''''' perturbed_vp = perturbed_pp - perturbed_p perturbed_vp_norm = np.linalg.norm(perturbed_vp) perturbed_distance_vertex_and_line = np.dot((perturbed_p - pixel_position), perturbed_vp) / perturbed_vp_norm '''''' # perturbed_v = np.array([random.randint(-3000, 3000) / 100, random.randint(-3000, 3000) / 100]) # perturbed_v = np.array([random.randint(-4000, 4000) / 100, random.randint(-4000, 4000) / 100]) if fold_curve == 'fold' and self.is_perform(0.6, 0.4): # self.is_perform(0.3, 0.7): # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) perturbed_v = np.array([random.randint(-10000, 10000) / 100, random.randint(-10000, 10000) / 100]) # perturbed_v = np.array([random.randint(-11000, 11000) / 100, random.randint(-11000, 11000) / 100]) else: # perturbed_v = np.array([random.randint(-9000, 9000) / 100, random.randint(-9000, 9000) / 100]) # perturbed_v = np.array([random.randint(-16000, 16000) / 100, random.randint(-16000, 16000) / 100]) perturbed_v = np.array([random.randint(-8000, 8000) / 100, random.randint(-8000, 8000) / 100]) # perturbed_v = np.array([random.randint(-3500, 3500) / 100, random.randint(-3500, 3500) / 100]) # perturbed_v = np.array([random.randint(-600, 600) / 10, random.randint(-600, 600) / 10]) '''''' if fold_curve == 'fold': if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: if is_normalizationFun_mixture: if self.is_perform(0.5, 0.5): perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) else: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), random.randint(1, 2)) else: if normalizationFun_0_1: perturbed_d = self.get_0_1_d(np.abs(perturbed_distance_vertex_and_line), 2) else: perturbed_d = np.abs(self.get_normalize(perturbed_distance_vertex_and_line)) '''''' if fold_curve_random: # omega_perturbed = (alpha_perturbed+0.2) / (perturbed_d + alpha_perturbed) # omega_perturbed = alpha_perturbed**perturbed_d omega_perturbed = alpha_perturbed / (perturbed_d + alpha_perturbed) else: omega_perturbed = 1 - perturbed_d ** alpha_perturbed '''shadow''' if self.is_perform(0.6, 0.4): synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] = np.minimum(np.maximum(synthesis_perturbed_img_map[x_min:x_max, y_min:y_max] - np.int16(np.round(omega_perturbed[x_min:x_max, y_min:y_max].repeat(3).reshape(x_max-x_min, y_max-y_min, 3) * abs(np.linalg.norm(perturbed_v//2))*np.array([0.4-random.random()*0.1, 0.4-random.random()*0.1, 0.4-random.random()*0.1]))), 0), 255) '''''' if relativeShift_position in ['position', 'relativeShift_v2']: self.perturbed_xy_ += np.array([omega_perturbed * perturbed_v[0], omega_perturbed * perturbed_v[1]]).transpose(1, 2, 0) else: print('relativeShift_position error') exit() ''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 # synthesis_perturbed_img = np.around(synthesis_perturbed_img).astype(np.uint8) synthesis_perturbed_label[:, :, 0] *= foreORbackground_label synthesis_perturbed_label[:, :, 1] *= foreORbackground_label synthesis_perturbed_img[:, :, 0] *= foreORbackground_label synthesis_perturbed_img[:, :, 1] *= foreORbackground_label synthesis_perturbed_img[:, :, 2] *= foreORbackground_label self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label ''' '''perspective''' perspective_shreshold = random.randint(26, 36)*10 # 280 x_min_per, y_min_per, x_max_per, y_max_per = self.adjust_position(perspective_shreshold, perspective_shreshold, self.new_shape[0]-perspective_shreshold, self.new_shape[1]-perspective_shreshold) pts1 = np.float32([[x_min_per, y_min_per], [x_max_per, y_min_per], [x_min_per, y_max_per], [x_max_per, y_max_per]]) e_1_ = x_max_per - x_min_per e_2_ = y_max_per - y_min_per e_3_ = e_2_ e_4_ = e_1_ perspective_shreshold_h = e_1_*0.02 perspective_shreshold_w = e_2_*0.02 a_min_, a_max_ = 70, 110 # if self.is_perform(1, 0): if fold_curve == 'curve' and self.is_perform(0.5, 0.5): if self.is_perform(0.5, 0.5): while True: pts2 = np.around( np.float32([[x_min_per - (random.random()) * perspective_shreshold, y_min_per + (random.random()) * perspective_shreshold], [x_max_per - (random.random()) * perspective_shreshold, y_min_per - (random.random()) * perspective_shreshold], [x_min_per + (random.random()) * perspective_shreshold, y_max_per + (random.random()) * perspective_shreshold], [x_max_per + (random.random()) * perspective_shreshold, y_max_per - (random.random()) * perspective_shreshold]])) # right e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break else: while True: pts2 = np.around( np.float32([[x_min_per + (random.random()) * perspective_shreshold, y_min_per - (random.random()) * perspective_shreshold], [x_max_per + (random.random()) * perspective_shreshold, y_min_per + (random.random()) * perspective_shreshold], [x_min_per - (random.random()) * perspective_shreshold, y_max_per - (random.random()) * perspective_shreshold], [x_max_per - (random.random()) * perspective_shreshold, y_max_per + (random.random()) * perspective_shreshold]])) e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break else: while True: pts2 = np.around(np.float32([[x_min_per+(random.random()-0.5)*perspective_shreshold, y_min_per+(random.random()-0.5)*perspective_shreshold], [x_max_per+(random.random()-0.5)*perspective_shreshold, y_min_per+(random.random()-0.5)*perspective_shreshold], [x_min_per+(random.random()-0.5)*perspective_shreshold, y_max_per+(random.random()-0.5)*perspective_shreshold], [x_max_per+(random.random()-0.5)*perspective_shreshold, y_max_per+(random.random()-0.5)*perspective_shreshold]])) e_1 = np.linalg.norm(pts2[0]-pts2[1]) e_2 = np.linalg.norm(pts2[0]-pts2[2]) e_3 = np.linalg.norm(pts2[1]-pts2[3]) e_4 = np.linalg.norm(pts2[2]-pts2[3]) if e_1_+perspective_shreshold_h > e_1 and e_2_+perspective_shreshold_w > e_2 and e_3_+perspective_shreshold_w > e_3 and e_4_+perspective_shreshold_h > e_4 and \ e_1_ - perspective_shreshold_h < e_1 and e_2_ - perspective_shreshold_w < e_2 and e_3_ - perspective_shreshold_w < e_3 and e_4_ - perspective_shreshold_h < e_4 and \ abs(e_1-e_4) < perspective_shreshold_h and abs(e_2-e_3) < perspective_shreshold_w: a0_, a1_, a2_, a3_ = self.get_angle_4(pts2) if (a0_ > a_min_ and a0_ < a_max_) or (a1_ > a_min_ and a1_ < a_max_) or (a2_ > a_min_ and a2_ < a_max_) or (a3_ > a_min_ and a3_ < a_max_): break M = cv2.getPerspectiveTransform(pts1, pts2) one = np.ones((self.new_shape[0], self.new_shape[1], 1), dtype=np.int16) matr = np.dstack((pixel_position, one)) new = np.dot(M, matr.reshape(-1, 3).T).T.reshape(self.new_shape[0], self.new_shape[1], 3) x = new[:, :, 0]/new[:, :, 2] y = new[:, :, 1]/new[:, :, 2] perturbed_xy_ = np.dstack((x, y)) # perturbed_xy_round_int = np.around(cv2.bilateralFilter(perturbed_xy_round_int, 9, 75, 75)) # perturbed_xy_round_int = np.around(cv2.blur(perturbed_xy_, (17, 17))) # perturbed_xy_round_int = cv2.blur(perturbed_xy_round_int, (17, 17)) # perturbed_xy_round_int = cv2.GaussianBlur(perturbed_xy_round_int, (7, 7), 0) perturbed_xy_ = perturbed_xy_-np.min(perturbed_xy_.T.reshape(2, -1), 1) # perturbed_xy_round_int = np.around(perturbed_xy_round_int-np.min(perturbed_xy_round_int.T.reshape(2, -1), 1)).astype(np.int16) self.perturbed_xy_ += perturbed_xy_ '''perspective end''' '''to img''' flat_position = np.argwhere(np.zeros(self.new_shape, dtype=np.uint32) == 0).reshape( self.new_shape[0] * self.new_shape[1], 2) # self.perturbed_xy_ = cv2.blur(self.perturbed_xy_, (7, 7)) self.perturbed_xy_ = cv2.GaussianBlur(self.perturbed_xy_, (7, 7), 0) '''get fiducial points''' fiducial_points_coordinate = self.perturbed_xy_[im_x, im_y] vtx, wts = self.interp_weights(self.perturbed_xy_.reshape(self.new_shape[0] * self.new_shape[1], 2), flat_position) wts_sum = np.abs(wts).sum(-1) # flat_img.reshape(flat_shape[0] * flat_shape[1], 3)[:] = interpolate(pixel, vtx, wts) wts = wts[wts_sum <= 1, :] vtx = vtx[wts_sum <= 1, :] synthesis_perturbed_img.reshape(self.new_shape[0] * self.new_shape[1], 3)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_img_map.reshape(self.new_shape[0] * self.new_shape[1], 3), vtx, wts) synthesis_perturbed_label.reshape(self.new_shape[0] * self.new_shape[1], 2)[wts_sum <= 1, :] = self.interpolate(synthesis_perturbed_label_map.reshape(self.new_shape[0] * self.new_shape[1], 2), vtx, wts) foreORbackground_label = np.zeros(self.new_shape) foreORbackground_label.reshape(self.new_shape[0] * self.new_shape[1], 1)[wts_sum <= 1, :] = self.interpolate(foreORbackground_label_map.reshape(self.new_shape[0] * self.new_shape[1], 1), vtx, wts) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 self.synthesis_perturbed_img = synthesis_perturbed_img self.synthesis_perturbed_label = synthesis_perturbed_label self.foreORbackground_label = foreORbackground_label '''draw fiducial points stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_img.copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1,2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[1] + math.ceil(stepSize / 2), l[0] + math.ceil(stepSize / 2)), 5, (0, 0, 255), -1) cv2.imwrite('/lustre/home/gwxie/program/project/unwarp/unwarp_perturbed/TPS/img/cv_TPS_large.jpg', fiducial_points_synthesis_perturbed_img) ''' '''clip''' perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = -1, -1, self.new_shape[0], self.new_shape[1] for x in range(self.new_shape[0] // 2, perturbed_x_max): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and perturbed_x_max - 1 > x: perturbed_x_max = x break for x in range(self.new_shape[0] // 2, perturbed_x_min, -1): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and x > 0: perturbed_x_min = x break for y in range(self.new_shape[1] // 2, perturbed_y_max): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and perturbed_y_max - 1 > y: perturbed_y_max = y break for y in range(self.new_shape[1] // 2, perturbed_y_min, -1): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and y > 0: perturbed_y_min = y break if perturbed_x_min == 0 or perturbed_x_max == self.new_shape[0] or perturbed_y_min == self.new_shape[1] or perturbed_y_max == self.new_shape[1]: raise Exception('clip error') if perturbed_x_max - perturbed_x_min < im_lr//2 or perturbed_y_max - perturbed_y_min < im_ud//2: raise Exception('clip error') perfix_ = self.save_suffix+'_'+str(m)+'_'+str(n) is_shrink = False if perturbed_x_max - perturbed_x_min > save_img_shape[0] or perturbed_y_max - perturbed_y_min > save_img_shape[1]: is_shrink = True synthesis_perturbed_img = cv2.resize(self.synthesis_perturbed_img[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) synthesis_perturbed_label = cv2.resize(self.synthesis_perturbed_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) foreORbackground_label = cv2.resize(self.foreORbackground_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max].copy(), (im_ud, im_lr), interpolation=cv2.INTER_LINEAR) foreORbackground_label[foreORbackground_label < 0.99] = 0 foreORbackground_label[foreORbackground_label >= 0.99] = 1 '''shrink fiducial points''' center_x_l, center_y_l = perturbed_x_min + (perturbed_x_max - perturbed_x_min) // 2, perturbed_y_min + (perturbed_y_max - perturbed_y_min) // 2 fiducial_points_coordinate_copy = fiducial_points_coordinate.copy() shrink_x = im_lr/(perturbed_x_max - perturbed_x_min) shrink_y = im_ud/(perturbed_y_max - perturbed_y_min) fiducial_points_coordinate *= [shrink_x, shrink_y] center_x_l *= shrink_x center_y_l *= shrink_y # fiducial_points_coordinate[1:, 1:] *= [shrink_x, shrink_y] # fiducial_points_coordinate[1:, :1, 0] *= shrink_x # fiducial_points_coordinate[:1, 1:, 1] *= shrink_y # perturbed_x_min_copy, perturbed_y_min_copy, perturbed_x_max_copy, perturbed_y_max_copy = perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = self.adjust_position_v2(0, 0, im_lr, im_ud, self.new_shape) self.synthesis_perturbed_img = np.full_like(self.synthesis_perturbed_img, 256) self.synthesis_perturbed_label = np.zeros_like(self.synthesis_perturbed_label) self.foreORbackground_label = np.zeros_like(self.foreORbackground_label) self.synthesis_perturbed_img[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_img self.synthesis_perturbed_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max, :] = synthesis_perturbed_label self.foreORbackground_label[perturbed_x_min:perturbed_x_max, perturbed_y_min:perturbed_y_max] = foreORbackground_label center_x, center_y = perturbed_x_min + (perturbed_x_max - perturbed_x_min) // 2, perturbed_y_min + (perturbed_y_max - perturbed_y_min) // 2 if is_shrink: fiducial_points_coordinate += [center_x-center_x_l, center_y-center_y_l] '''draw fiducial points stepSize = 0 fiducial_points_synthesis_perturbed_img = self.synthesis_perturbed_img.copy() for l in fiducial_points_coordinate.astype(np.int64).reshape(-1, 2): cv2.circle(fiducial_points_synthesis_perturbed_img, (l[1] + math.ceil(stepSize / 2), l[0] + math.ceil(stepSize / 2)), 5, (0, 0, 255), -1) cv2.imwrite('/lustre/home/gwxie/program/project/unwarp/unwarp_perturbed/TPS/img/cv_TPS_small.jpg',fiducial_points_synthesis_perturbed_img) ''' self.new_shape = save_img_shape self.synthesis_perturbed_img = self.synthesis_perturbed_img[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2, :].copy() self.synthesis_perturbed_label = self.synthesis_perturbed_label[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2, :].copy() self.foreORbackground_label = self.foreORbackground_label[ center_x - self.new_shape[0] // 2:center_x + self.new_shape[0] // 2, center_y - self.new_shape[1] // 2:center_y + self.new_shape[1] // 2].copy() perturbed_x_ = max(self.new_shape[0] - (perturbed_x_max - perturbed_x_min), 0) perturbed_x_min = perturbed_x_ // 2 perturbed_x_max = self.new_shape[0] - perturbed_x_ // 2 if perturbed_x_%2 == 0 else self.new_shape[0] - (perturbed_x_ // 2 + 1) perturbed_y_ = max(self.new_shape[1] - (perturbed_y_max - perturbed_y_min), 0) perturbed_y_min = perturbed_y_ // 2 perturbed_y_max = self.new_shape[1] - perturbed_y_ // 2 if perturbed_y_%2 == 0 else self.new_shape[1] - (perturbed_y_ // 2 + 1) '''clip perturbed_x_min, perturbed_y_min, perturbed_x_max, perturbed_y_max = -1, -1, self.new_shape[0], self.new_shape[1] for x in range(self.new_shape[0] // 2, perturbed_x_max): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and perturbed_x_max - 1 > x: perturbed_x_max = x break for x in range(self.new_shape[0] // 2, perturbed_x_min, -1): if np.sum(self.synthesis_perturbed_img[x, :]) == 768 * self.new_shape[1] and x > 0: perturbed_x_min = x break for y in range(self.new_shape[1] // 2, perturbed_y_max): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and perturbed_y_max - 1 > y: perturbed_y_max = y break for y in range(self.new_shape[1] // 2, perturbed_y_min, -1): if np.sum(self.synthesis_perturbed_img[:, y]) == 768 * self.new_shape[0] and y > 0: perturbed_y_min = y break center_x, center_y = perturbed_x_min+(perturbed_x_max - perturbed_x_min)//2, perturbed_y_min+(perturbed_y_max - perturbed_y_min)//2 perfix_ = self.save_suffix+'_'+str(m)+'_'+str(n) self.new_shape = save_img_shape perturbed_x_ = max(self.new_shape[0] - (perturbed_x_max - perturbed_x_min), 0) perturbed_x_min = perturbed_x_ // 2 perturbed_x_max = self.new_shape[0] - perturbed_x_ // 2 if perturbed_x_%2 == 0 else self.new_shape[0] - (perturbed_x_ // 2 + 1) perturbed_y_ = max(self.new_shape[1] - (perturbed_y_max - perturbed_y_min), 0) perturbed_y_min = perturbed_y_ // 2 perturbed_y_max = self.new_shape[1] - perturbed_y_ // 2 if perturbed_y_%2 == 0 else self.new_shape[1] - (perturbed_y_ // 2 + 1) self.synthesis_perturbed_img = self.synthesis_perturbed_img[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2, :].copy() self.synthesis_perturbed_label = self.synthesis_perturbed_label[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2, :].copy() self.foreORbackground_label = self.foreORbackground_label[center_x-self.new_shape[0]//2:center_x+self.new_shape[0]//2, center_y-self.new_shape[1]//2:center_y+self.new_shape[1]//2].copy() ''' '''save''' pixel_position = np.argwhere(

np.zeros(self.new_shape, dtype=np.uint32)

numpy.zeros

"""Test the search module""" from collections.abc import Iterable, Sized from io import StringIO from itertools import chain, product from functools import partial import pickle import sys from types import GeneratorType import re import numpy as np import scipy.sparse as sp import pytest from sklearn.utils.fixes import sp_version from sklearn.utils._testing import assert_raises from sklearn.utils._testing import assert_warns from sklearn.utils._testing import assert_warns_message from sklearn.utils._testing import assert_raise_message from sklearn.utils._testing import assert_array_equal from sklearn.utils._testing import assert_array_almost_equal from sklearn.utils._testing import assert_allclose from sklearn.utils._testing import assert_almost_equal from sklearn.utils._testing import ignore_warnings from sklearn.utils._mocking import CheckingClassifier, MockDataFrame from scipy.stats import bernoulli, expon, uniform from sklearn.base import BaseEstimator, ClassifierMixin from sklearn.base import clone from sklearn.exceptions import NotFittedError from sklearn.datasets import make_classification from sklearn.datasets import make_blobs from sklearn.datasets import make_multilabel_classification from sklearn.model_selection import fit_grid_point from sklearn.model_selection import train_test_split from sklearn.model_selection import KFold from sklearn.model_selection import StratifiedKFold from sklearn.model_selection import StratifiedShuffleSplit from sklearn.model_selection import LeaveOneGroupOut from sklearn.model_selection import LeavePGroupsOut from sklearn.model_selection import GroupKFold from sklearn.model_selection import GroupShuffleSplit from sklearn.model_selection import GridSearchCV from sklearn.model_selection import RandomizedSearchCV from sklearn.model_selection import ParameterGrid from sklearn.model_selection import ParameterSampler from sklearn.model_selection._search import BaseSearchCV from sklearn.model_selection._validation import FitFailedWarning from sklearn.svm import LinearSVC, SVC from sklearn.tree import DecisionTreeRegressor from sklearn.tree import DecisionTreeClassifier from sklearn.cluster import KMeans from sklearn.neighbors import KernelDensity from sklearn.neighbors import KNeighborsClassifier from sklearn.metrics import f1_score from sklearn.metrics import recall_score from sklearn.metrics import accuracy_score from sklearn.metrics import make_scorer from sklearn.metrics import roc_auc_score from sklearn.metrics.pairwise import euclidean_distances from sklearn.impute import SimpleImputer from sklearn.pipeline import Pipeline from sklearn.linear_model import Ridge, SGDClassifier, LinearRegression from sklearn.experimental import enable_hist_gradient_boosting # noqa from sklearn.ensemble import HistGradientBoostingClassifier from sklearn.model_selection.tests.common import OneTimeSplitter # Neither of the following two estimators inherit from BaseEstimator, # to test hyperparameter search on user-defined classifiers. class MockClassifier: """Dummy classifier to test the parameter search algorithms""" def __init__(self, foo_param=0): self.foo_param = foo_param def fit(self, X, Y): assert len(X) == len(Y) self.classes_ = np.unique(Y) return self def predict(self, T): return T.shape[0] def transform(self, X): return X + self.foo_param def inverse_transform(self, X): return X - self.foo_param predict_proba = predict predict_log_proba = predict decision_function = predict def score(self, X=None, Y=None): if self.foo_param > 1: score = 1. else: score = 0. return score def get_params(self, deep=False): return {'foo_param': self.foo_param} def set_params(self, **params): self.foo_param = params['foo_param'] return self class LinearSVCNoScore(LinearSVC): """An LinearSVC classifier that has no score method.""" @property def score(self): raise AttributeError X = np.array([[-1, -1], [-2, -1], [1, 1], [2, 1]]) y =

np.array([1, 1, 2, 2])

numpy.array

from __future__ import division from timeit import default_timer as timer import csv import numpy as np import itertools from munkres import Munkres, print_matrix, make_cost_matrix import sys from classes import * from functions import * from math import sqrt import Tkinter as tk import tkFileDialog as filedialog root = tk.Tk() root.withdraw() p_file = filedialog.askopenfilename(title='Please select the posting file') c_file = filedialog.askopenfilename(title='Please select the candidate file') """for use with /users/java_jonathan/postings_lge.csv and /Users/java_jonathan/candidates_lge.csv""" # p_file = raw_input("Please enter the path for the postings file: ") # p_file = p_file.strip() # c_file = raw_input("Please enter the path for the candidate file: ") # c_file = c_file.strip() start = timer() with open(p_file,'r') as f: #with open('/Users/Jonathan/Google Drive/CPD/Python/postings.csv','r') as f: reader = csv.reader(f) postingsAll = list(reader) with open(c_file,'r') as f: reader = csv.reader(f) candidatesAll = list(reader) """create empty lists to fill with lists of lists output by iterating function below""" names = [] totalMatrix = [] for list in candidatesAll: candidate = Candidate(*list) names.append(candidate.name) n = 0 for list in postingsAll: posting = Posting(*list) totalMatrix.append(matchDept(posting,candidate) + matchAnchor(posting,candidate) +matchLocation(posting,candidate) + matchCompetency(posting,candidate) + matchSkill(posting,candidate)+matchCohort(posting,candidate)) n += 1 l = len(names) names.extend([0] * (n-l)) totalMatrix.extend([0] * (n**2 - len(totalMatrix))) totalMatrix =

np.asarray(totalMatrix)

numpy.asarray

# coding=utf-8 import logging import traceback from os import makedirs from os.path import exists, join from textwrap import fill import matplotlib.patheffects as PathEffects import matplotlib.pyplot as plt import numpy as np import seaborn as sns from koino.plot import big_square, default_alpha from matplotlib import cm from ..utils.base import jaccard def plot_silhouette( X, figure_fp, n_clusters, silhouette_values, cluster_labels, silhouette_avg ): # Create a subplot with 1 row and 2 columns fig, (ax1, ax2) = plt.subplots(1, 2, figsize=(26, 10)) # The 1st subplot is the silhouette plot # The silhouette coefficient can range from -1, 1 but here all # lie within [-0.1, 1] ax1.set_xlim([-0.1, 1]) # The (n_clusters+1)*10 is for inserting blank space between silhouette # plots of individual clusters, to demarcate them clearly. ax1.set_ylim([0, len(X) + (n_clusters + 1) * 10]) y_lower = 10 for k in range(n_clusters): # Aggregate the silhouette scores for samples belonging to # cluster i, and sort them ith_cluster_silhouette_values = np.sort(silhouette_values[cluster_labels == k]) size_cluster_i = ith_cluster_silhouette_values.shape[0] y_upper = y_lower + size_cluster_i color = cm.spectral(float(k) / n_clusters) ax1.fill_betweenx( np.arange(y_lower, y_upper), 0, ith_cluster_silhouette_values, facecolor=color, edgecolor=color, alpha=default_alpha, ) # Label the silhouette plots with their cluster numbers at the # middle ax1.text(-0.05, y_lower + 0.5 * size_cluster_i, str(k)) # Compute the new y_lower for next plot y_lower = y_upper + 10 # 10 for the 0 samples ax1.set_title("The silhouette plot for the various clusters.") ax1.set_xlabel("The silhouette coefficient values") ax1.set_ylabel("Cluster label") # The vertical line for average silhouette score of all the values ax1.axvline(x=silhouette_avg, color="red", linestyle="--") ax1.set_yticks([]) # Clear the yaxis labels / ticks ax1.set_xticks([-0.1, 0, 0.2, 0.4, 0.6, 0.8, 1]) # Construct cluster # 2nd Plot showing the actual clusters formed colors = cm.spectral(cluster_labels.astype(float) / n_clusters) # colors = y ax2.scatter(X[:, 0], X[:, 1], marker=".", s=20, lw=0, alpha=default_alpha, c=colors) ax2.set_title("The visualization of the clustered data.") ax2.set_xlabel("Feature space for the 1st feature") ax2.set_ylabel("Feature space for the 2nd feature") plt.suptitle( ("Silhouette analysis for KMeans " "with n_clusters = %d" % n_clusters), fontsize=14, fontweight="bold", ) plt.savefig(figure_fp) plt.close() plt.clf() def plot_cluster_assignments( X, y, n_clusters, figures_dir, transparent=False, cluster_names=None, title="" ): """Clustering assignments scatter plot Notes ----- Can use mean or median to fix cluster centroid coordinates.""" if cluster_names is None: cluster_names = ["Cluster {}".format(i + 1) for i in range(n_clusters)] # We first reorder the data points according to the centroids labels X = np.vstack([X[y == i] for i in range(n_clusters)]) y = np.hstack([y[y == i] for i in range(n_clusters)]) # Choose a color palette with seaborn. palette = np.array(sns.color_palette("hls", n_clusters)) fig, ax = plt.subplots(figsize=big_square) # for i in range(n_clusters): # mask = y == i # ax.scatter(X[mask, 0], X[mask, 1], lw=0, s=20, c=palette[i], # label=cluster_names[i]) ax.set_title(title) ax.scatter(X[:, 0], X[:, 1], lw=0, s=20, c=palette[y.astype(np.int)]) ax.axis("off") # Add the labels for each cluster. for i in range(n_clusters): # Position of each label. samples = np.atleast_2d(X[y == i, :2]) if not len(samples): logging.warning( "Probably singular cluster {} (shape:{})".format(i + 1, X[y == i].shape) ) continue xtext, ytext =

np.median(samples, axis=0)

numpy.median

# Credit to https://medium.com/emergent-future/simple-reinforcement-learning-with-tensorflow-part-0-q-learning-with-tables-and-neural-networks-d195264329d0 import gym import tensorflow as tf import numpy as np import matplotlib.pyplot as plt env = gym.make('FrozenLake-v0') # NEURAL NETWORK IMPLEMENTATION tf.reset_default_graph() # Feature vector for current state representation input1 = tf.placeholder(shape=[1, env.observation_space.n], dtype=tf.float32) # tf.Variable(<initial-value>, name=<optional-name>) # tf.random_uniform(shape, minval=0, maxval=None, dtype=tf.float32, seed=None, name=None) # Weighting W vector in range 0 - 0.01 (like the way Andrew Ng did with *0.01 W = tf.Variable(tf.random_uniform([env.observation_space.n, env.action_space.n], 0, 0.01)) # Qout with shape [1, env.action_space.n] - Action state value for Q[s, a] with every a available at a state Qout = tf.matmul(input1, W) # Greedy action at a state predict = tf.argmax(Qout, axis=1) # Feature vector for next state representation nextQ = tf.placeholder(shape=[1, env.action_space.n], dtype=tf.float32) # Entropy loss loss = tf.reduce_sum(tf.square(Qout - nextQ)) trainer = tf.train.GradientDescentOptimizer(learning_rate=0.1) updateModel = trainer.minimize(loss) # TRAIN THE NETWORK init = tf.global_variables_initializer() # Set learning parameters y = 0.99 e = 0.1 number_episodes = 2000 # List to store total rewards and steps per episode jList = [] rList = [] with tf.Session() as sess: sess.run(init) for i in range(number_episodes): print("Episode #{} is running!".format(i)) # First state s = env.reset() rAll = 0 d = False j = 0 # Q network while j < 200: # or While not d: j += 1 # Choose action by epsilon (e) greedy # print("s = ", s," --> Identity s:s+1: ", np.identity(env.observation_space.n)[s:s+1]) # s = 0 --> Identity s: s + 1: [[1. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0.]] # s = 1 --> Identity s: s + 1: [[0. 1. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0.]] # Identity [s:s+1] is a one-hot vector # Therefore W is the actual Q value a, allQ = sess.run([predict, Qout], feed_dict={input1: np.identity(env.observation_space.n)[s:s+1]}) if np.random.rand(1) < e: a[0] = env.action_space.sample() s1, r, d, _ = env.step(a[0]) # Obtain next state Q value by feeding the new state throughout the network Q1 = sess.run(Qout, feed_dict={input1: np.identity(env.observation_space.n)[s1:s1+1]}) maxQ1 = np.max(Q1) targetQ = allQ targetQ[0, a[0]] = r + y * maxQ1 # Train our network using target and predicted Q values _, W1 = sess.run([updateModel, W], feed_dict={input1:

np.identity(env.observation_space.n)

numpy.identity

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) +

np.sin(5 * pseudo_alg_time)

numpy.sin

# ________ # / # \ / # \ / # \/ import random import textwrap import emd_mean import AdvEMDpy import emd_basis import emd_utils import numpy as np import pandas as pd import cvxpy as cvx import seaborn as sns import matplotlib.pyplot as plt from scipy.integrate import odeint from scipy.ndimage import gaussian_filter from emd_utils import time_extension, Utility from scipy.interpolate import CubicSpline from emd_hilbert import Hilbert, hilbert_spectrum from emd_preprocess import Preprocess from emd_mean import Fluctuation from AdvEMDpy import EMD # alternate packages from PyEMD import EMD as pyemd0215 import emd as emd040 sns.set(style='darkgrid') pseudo_alg_time = np.linspace(0, 2 * np.pi, 1001) pseudo_alg_time_series = np.sin(pseudo_alg_time) + np.sin(5 * pseudo_alg_time) pseudo_utils = Utility(time=pseudo_alg_time, time_series=pseudo_alg_time_series) # plot 0 - addition fig = plt.figure(figsize=(9, 4)) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.title('First Iteration of Sifting Algorithm') plt.plot(pseudo_alg_time, pseudo_alg_time_series, label=r'$h_{(1,0)}(t)$', zorder=1) plt.scatter(pseudo_alg_time[pseudo_utils.max_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.max_bool_func_1st_order_fd()], c='r', label=r'$M(t_i)$', zorder=2) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) + 1, '--', c='r', label=r'$\tilde{h}_{(1,0)}^M(t)$', zorder=4) plt.scatter(pseudo_alg_time[pseudo_utils.min_bool_func_1st_order_fd()], pseudo_alg_time_series[pseudo_utils.min_bool_func_1st_order_fd()], c='c', label=r'$m(t_j)$', zorder=3) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time) - 1, '--', c='c', label=r'$\tilde{h}_{(1,0)}^m(t)$', zorder=5) plt.plot(pseudo_alg_time, np.sin(pseudo_alg_time), '--', c='purple', label=r'$\tilde{h}_{(1,0)}^{\mu}(t)$', zorder=5) plt.yticks(ticks=[-2, -1, 0, 1, 2]) plt.xticks(ticks=[0, np.pi, 2 * np.pi], labels=[r'0', r'$\pi$', r'$2\pi$']) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.95, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/pseudo_algorithm.png') plt.show() knots = np.arange(12) time = np.linspace(0, 11, 1101) basis = emd_basis.Basis(time=time, time_series=time) b_spline_basis = basis.cubic_b_spline(knots) chsi_basis = basis.chsi_basis(knots) # plot 1 plt.title('Non-Natural Cubic B-Spline Bases at Boundary') plt.plot(time[500:], b_spline_basis[2, 500:].T, '--', label=r'$ B_{-3,4}(t) $') plt.plot(time[500:], b_spline_basis[3, 500:].T, '--', label=r'$ B_{-2,4}(t) $') plt.plot(time[500:], b_spline_basis[4, 500:].T, '--', label=r'$ B_{-1,4}(t) $') plt.plot(time[500:], b_spline_basis[5, 500:].T, '--', label=r'$ B_{0,4}(t) $') plt.plot(time[500:], b_spline_basis[6, 500:].T, '--', label=r'$ B_{1,4}(t) $') plt.xticks([5, 6], [r'$ \tau_0 $', r'$ \tau_1 $']) plt.xlim(4.4, 6.6) plt.plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') plt.legend(loc='upper left') plt.savefig('jss_figures/boundary_bases.png') plt.show() # plot 1a - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) knots_uniform = np.linspace(0, 2 * np.pi, 51) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs = emd.empirical_mode_decomposition(knots=knots_uniform, edge_effect='anti-symmetric', verbose=False)[0] fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Uniform Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Uniform Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Uniform Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots_uniform[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots_uniform)): axs[i].plot(knots_uniform[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_uniform.png') plt.show() # plot 1b - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=1, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Statically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Statically Optimised Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Statically Optimised Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots)): axs[i].plot(knots[j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_1.png') plt.show() # plot 1c - addition knot_demonstrate_time = np.linspace(0, 2 * np.pi, 1001) knot_demonstrate_time_series = np.sin(knot_demonstrate_time) + np.sin(5 * knot_demonstrate_time) emd = EMD(time=knot_demonstrate_time, time_series=knot_demonstrate_time_series) imfs, _, _, _, knots, _, _ = emd.empirical_mode_decomposition(edge_effect='anti-symmetric', optimise_knots=2, verbose=False) fig, axs = plt.subplots(3, 1) fig.subplots_adjust(hspace=0.6) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Time Series and Dynamically Optimised Knots') axs[0].plot(knot_demonstrate_time, knot_demonstrate_time_series, Linewidth=2, zorder=100) axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].set_title('IMF 1 and Dynamically Knots') axs[1].plot(knot_demonstrate_time, imfs[1, :], Linewidth=2, zorder=100) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[1].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[2].set_title('IMF 2 and Dynamically Knots') axs[2].plot(knot_demonstrate_time, imfs[2, :], Linewidth=2, zorder=100) axs[2].set_yticks(ticks=[-2, 0, 2]) axs[2].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[2].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[0].plot(knots[0][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[0].legend(loc='lower left') axs[1].plot(knots[1][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') axs[2].plot(knots[2][0] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey', label='Knots') for i in range(3): for j in range(1, len(knots[i])): axs[i].plot(knots[i][j] * np.ones(101), np.linspace(-2, 2, 101), '--', c='grey') plt.savefig('jss_figures/knot_2.png') plt.show() # plot 1d - addition window = 81 fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Filtering Demonstration') axs[1].set_title('Zoomed Region') preprocess_time = pseudo_alg_time.copy() np.random.seed(1) random.seed(1) preprocess_time_series = pseudo_alg_time_series + np.random.normal(0, 0.1, len(preprocess_time)) for i in random.sample(range(1000), 500): preprocess_time_series[i] += np.random.normal(0, 1) preprocess = Preprocess(time=preprocess_time, time_series=preprocess_time_series) axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[0].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[0].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[0].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[0].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.mean_filter(window_width=window)[1], label=textwrap.fill('Mean filter', 12)) axs[1].plot(preprocess_time, preprocess.median_filter(window_width=window)[1], label=textwrap.fill('Median filter', 13)) axs[1].plot(preprocess_time, preprocess.winsorize(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize filter', 12)) axs[1].plot(preprocess_time, preprocess.winsorize_interpolate(window_width=window, a=0.8)[1], label=textwrap.fill('Windsorize interpolation filter', 14)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.90)[1], c='grey', label=textwrap.fill('Quantile window', 12)) axs[1].plot(preprocess_time, preprocess.quantile_filter(window_width=window, q=0.10)[1], c='grey') axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.05, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_filter.png') plt.show() # plot 1e - addition fig, axs = plt.subplots(2, 1) fig.subplots_adjust(hspace=0.4) figure_size = plt.gcf().get_size_inches() factor = 0.8 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) axs[0].set_title('Preprocess Smoothing Demonstration') axs[1].set_title('Zoomed Region') axs[0].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[0].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[0].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[0].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) downsampled_and_decimated = preprocess.downsample() axs[0].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 11)) downsampled = preprocess.downsample(decimate=False) axs[0].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), -3 * np.ones(101), '--', c='black', label=textwrap.fill('Zoomed region', 10)) axs[0].plot(np.linspace(0.85 * np.pi, 1.15 * np.pi, 101), 3 * np.ones(101), '--', c='black') axs[0].plot(0.85 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].plot(1.15 * np.pi * np.ones(101), np.linspace(-3, 3, 101), '--', c='black') axs[0].set_yticks(ticks=[-2, 0, 2]) axs[0].set_xticks(ticks=[0, np.pi, 2 * np.pi]) axs[0].set_xticklabels(labels=['0', r'$\pi$', r'$2\pi$']) axs[1].plot(preprocess_time, preprocess_time_series, label='x(t)') axs[1].plot(pseudo_alg_time, pseudo_alg_time_series, '--', c='purple', label=textwrap.fill('Noiseless time series', 12)) axs[1].plot(preprocess_time, preprocess.hp()[1], label=textwrap.fill('Hodrick-Prescott smoothing', 12)) axs[1].plot(preprocess_time, preprocess.hw(order=51)[1], label=textwrap.fill('Henderson-Whittaker smoothing', 13)) axs[1].plot(downsampled_and_decimated[0], downsampled_and_decimated[1], label=textwrap.fill('Downsampled & decimated', 13)) axs[1].plot(downsampled[0], downsampled[1], label=textwrap.fill('Downsampled', 13)) axs[1].set_xlim(0.85 * np.pi, 1.15 * np.pi) axs[1].set_ylim(-3, 3) axs[1].set_yticks(ticks=[-2, 0, 2]) axs[1].set_xticks(ticks=[np.pi]) axs[1].set_xticklabels(labels=[r'$\pi$']) box_0 = axs[0].get_position() axs[0].set_position([box_0.x0 - 0.06, box_0.y0, box_0.width * 0.85, box_0.height]) axs[0].legend(loc='center left', bbox_to_anchor=(1, -0.15)) box_1 = axs[1].get_position() axs[1].set_position([box_1.x0 - 0.06, box_1.y0, box_1.width * 0.85, box_1.height]) plt.savefig('jss_figures/preprocess_smooth.png') plt.show() # plot 2 fig, axs = plt.subplots(1, 2, sharey=True) axs[0].set_title('Cubic B-Spline Bases') axs[0].plot(time, b_spline_basis[2, :].T, '--', label='Basis 1') axs[0].plot(time, b_spline_basis[3, :].T, '--', label='Basis 2') axs[0].plot(time, b_spline_basis[4, :].T, '--', label='Basis 3') axs[0].plot(time, b_spline_basis[5, :].T, '--', label='Basis 4') axs[0].legend(loc='upper left') axs[0].plot(5 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].plot(6 * np.ones(100), np.linspace(-0.2, 0.8, 100), 'k-') axs[0].set_xticks([5, 6]) axs[0].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[0].set_xlim(4.5, 6.5) axs[1].set_title('Cubic Hermite Spline Bases') axs[1].plot(time, chsi_basis[10, :].T, '--') axs[1].plot(time, chsi_basis[11, :].T, '--') axs[1].plot(time, chsi_basis[12, :].T, '--') axs[1].plot(time, chsi_basis[13, :].T, '--') axs[1].plot(5 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].plot(6 * np.ones(100), np.linspace(-0.2, 1.2, 100), 'k-') axs[1].set_xticks([5, 6]) axs[1].set_xticklabels([r'$ \tau_k $', r'$ \tau_{k+1} $']) axs[1].set_xlim(4.5, 6.5) plt.savefig('jss_figures/comparing_bases.png') plt.show() # plot 3 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_dash = maxima_y[-1] * np.ones_like(max_dash_time) min_dash_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_dash = minima_y[-1] * np.ones_like(min_dash_time) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) max_discard = maxima_y[-1] max_discard_time = minima_x[-1] - maxima_x[-1] + minima_x[-1] max_discard_dash_time = np.linspace(max_discard_time - width, max_discard_time + width, 101) max_discard_dash = max_discard * np.ones_like(max_discard_dash_time) dash_2_time = np.linspace(minima_x[-1], max_discard_time, 101) dash_2 = np.linspace(minima_y[-1], max_discard, 101) end_point_time = time[-1] end_point = time_series[-1] time_reflect = np.linspace((5 - a) * np.pi, (5 + a) * np.pi, 101) time_series_reflect = np.flip(np.cos(np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101)) + np.cos(5 * np.linspace((5 - 2.6 * a) * np.pi, (5 - a) * np.pi, 101))) time_series_anti_reflect = time_series_reflect[0] - time_series_reflect utils = emd_utils.Utility(time=time, time_series=time_series_anti_reflect) anti_max_bool = utils.max_bool_func_1st_order_fd() anti_max_point_time = time_reflect[anti_max_bool] anti_max_point = time_series_anti_reflect[anti_max_bool] utils = emd_utils.Utility(time=time, time_series=time_series_reflect) no_anchor_max_time = time_reflect[utils.max_bool_func_1st_order_fd()] no_anchor_max = time_series_reflect[utils.max_bool_func_1st_order_fd()] point_1 = 5.4 length_distance = np.linspace(maxima_y[-1], minima_y[-1], 101) length_distance_time = point_1 * np.pi * np.ones_like(length_distance) length_time = np.linspace(point_1 * np.pi - width, point_1 * np.pi + width, 101) length_top = maxima_y[-1] * np.ones_like(length_time) length_bottom = minima_y[-1] * np.ones_like(length_time) point_2 = 5.2 length_distance_2 = np.linspace(time_series[-1], minima_y[-1], 101) length_distance_time_2 = point_2 * np.pi * np.ones_like(length_distance_2) length_time_2 = np.linspace(point_2 * np.pi - width, point_2 * np.pi + width, 101) length_top_2 = time_series[-1] * np.ones_like(length_time_2) length_bottom_2 = minima_y[-1] * np.ones_like(length_time_2) symmetry_axis_1_time = minima_x[-1] * np.ones(101) symmetry_axis_2_time = time[-1] * np.ones(101) symmetry_axis = np.linspace(-2, 2, 101) end_time = np.linspace(time[-1] - width, time[-1] + width, 101) end_signal = time_series[-1] * np.ones_like(end_time) anti_symmetric_time = np.linspace(time[-1] - 0.5, time[-1] + 0.5, 101) anti_symmetric_signal = time_series[-1] * np.ones_like(anti_symmetric_time) ax = plt.subplot(111) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Symmetry Edge Effects Example') plt.plot(time_reflect, time_series_reflect, 'g--', LineWidth=2, label=textwrap.fill('Symmetric signal', 10)) plt.plot(time_reflect[:51], time_series_anti_reflect[:51], '--', c='purple', LineWidth=2, label=textwrap.fill('Anti-symmetric signal', 10)) plt.plot(max_dash_time, max_dash, 'k-') plt.plot(min_dash_time, min_dash, 'k-') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(length_distance_time, length_distance, 'k--') plt.plot(length_distance_time_2, length_distance_2, 'k--') plt.plot(length_time, length_top, 'k-') plt.plot(length_time, length_bottom, 'k-') plt.plot(length_time_2, length_top_2, 'k-') plt.plot(length_time_2, length_bottom_2, 'k-') plt.plot(end_time, end_signal, 'k-') plt.plot(symmetry_axis_1_time, symmetry_axis, 'r--', zorder=1) plt.plot(anti_symmetric_time, anti_symmetric_signal, 'r--', zorder=1) plt.plot(symmetry_axis_2_time, symmetry_axis, 'r--', label=textwrap.fill('Axes of symmetry', 10), zorder=1) plt.text(5.1 * np.pi, -0.7, r'$\beta$L') plt.text(5.34 * np.pi, -0.05, 'L') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(max_discard_time, max_discard, c='purple', zorder=4, label=textwrap.fill('Symmetric Discard maxima', 10)) plt.scatter(end_point_time, end_point, c='orange', zorder=4, label=textwrap.fill('Symmetric Anchor maxima', 10)) plt.scatter(anti_max_point_time, anti_max_point, c='green', zorder=4, label=textwrap.fill('Anti-Symmetric maxima', 10)) plt.scatter(no_anchor_max_time, no_anchor_max, c='gray', zorder=4, label=textwrap.fill('Symmetric maxima', 10)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-2, -1, 0, 1, 2), ('-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_symmetry_anti.png') plt.show() # plot 4 a = 0.21 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] max_dash_1 = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_dash_2 = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_dash_time_1 = maxima_x[-1] * np.ones_like(max_dash_1) max_dash_time_2 = maxima_x[-2] * np.ones_like(max_dash_1) min_dash_1 = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_dash_2 = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_dash_time_1 = minima_x[-1] * np.ones_like(min_dash_1) min_dash_time_2 = minima_x[-2] * np.ones_like(min_dash_1) dash_1_time = np.linspace(maxima_x[-1], minima_x[-1], 101) dash_1 = np.linspace(maxima_y[-1], minima_y[-1], 101) dash_2_time = np.linspace(maxima_x[-1], minima_x[-2], 101) dash_2 = np.linspace(maxima_y[-1], minima_y[-2], 101) s1 = (minima_y[-2] - maxima_y[-1]) / (minima_x[-2] - maxima_x[-1]) slope_based_maximum_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) slope_based_maximum = minima_y[-1] + (slope_based_maximum_time - minima_x[-1]) * s1 max_dash_time_3 = slope_based_maximum_time * np.ones_like(max_dash_1) max_dash_3 = np.linspace(slope_based_maximum - width, slope_based_maximum + width, 101) dash_3_time = np.linspace(minima_x[-1], slope_based_maximum_time, 101) dash_3 = np.linspace(minima_y[-1], slope_based_maximum, 101) s2 = (minima_y[-1] - maxima_y[-1]) / (minima_x[-1] - maxima_x[-1]) slope_based_minimum_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) slope_based_minimum = slope_based_maximum - (slope_based_maximum_time - slope_based_minimum_time) * s2 min_dash_time_3 = slope_based_minimum_time * np.ones_like(min_dash_1) min_dash_3 = np.linspace(slope_based_minimum - width, slope_based_minimum + width, 101) dash_4_time = np.linspace(slope_based_maximum_time, slope_based_minimum_time) dash_4 = np.linspace(slope_based_maximum, slope_based_minimum) maxima_dash = np.linspace(2.5 - width, 2.5 + width, 101) maxima_dash_time_1 = maxima_x[-2] * np.ones_like(maxima_dash) maxima_dash_time_2 = maxima_x[-1] * np.ones_like(maxima_dash) maxima_dash_time_3 = slope_based_maximum_time * np.ones_like(maxima_dash) maxima_line_dash_time = np.linspace(maxima_x[-2], slope_based_maximum_time, 101) maxima_line_dash = 2.5 * np.ones_like(maxima_line_dash_time) minima_dash = np.linspace(-3.4 - width, -3.4 + width, 101) minima_dash_time_1 = minima_x[-2] * np.ones_like(minima_dash) minima_dash_time_2 = minima_x[-1] * np.ones_like(minima_dash) minima_dash_time_3 = slope_based_minimum_time * np.ones_like(minima_dash) minima_line_dash_time = np.linspace(minima_x[-2], slope_based_minimum_time, 101) minima_line_dash = -3.4 * np.ones_like(minima_line_dash_time) # slightly edit signal to make difference between slope-based method and improved slope-based method more clear time_series[time >= minima_x[-1]] = 1.5 * (time_series[time >= minima_x[-1]] - time_series[time == minima_x[-1]]) + \ time_series[time == minima_x[-1]] improved_slope_based_maximum_time = time[-1] improved_slope_based_maximum = time_series[-1] improved_slope_based_minimum_time = slope_based_minimum_time improved_slope_based_minimum = improved_slope_based_maximum + s2 * (improved_slope_based_minimum_time - improved_slope_based_maximum_time) min_dash_4 = np.linspace(improved_slope_based_minimum - width, improved_slope_based_minimum + width, 101) min_dash_time_4 = improved_slope_based_minimum_time * np.ones_like(min_dash_4) dash_final_time = np.linspace(improved_slope_based_maximum_time, improved_slope_based_minimum_time, 101) dash_final = np.linspace(improved_slope_based_maximum, improved_slope_based_minimum, 101) ax = plt.subplot(111) figure_size = plt.gcf().get_size_inches() factor = 0.9 plt.gcf().set_size_inches((figure_size[0], factor * figure_size[1])) plt.gcf().subplots_adjust(bottom=0.10) plt.plot(time, time_series, LineWidth=2, label='Signal') plt.title('Slope-Based Edge Effects Example') plt.plot(max_dash_time_1, max_dash_1, 'k-') plt.plot(max_dash_time_2, max_dash_2, 'k-') plt.plot(max_dash_time_3, max_dash_3, 'k-') plt.plot(min_dash_time_1, min_dash_1, 'k-') plt.plot(min_dash_time_2, min_dash_2, 'k-') plt.plot(min_dash_time_3, min_dash_3, 'k-') plt.plot(min_dash_time_4, min_dash_4, 'k-') plt.plot(maxima_dash_time_1, maxima_dash, 'k-') plt.plot(maxima_dash_time_2, maxima_dash, 'k-') plt.plot(maxima_dash_time_3, maxima_dash, 'k-') plt.plot(minima_dash_time_1, minima_dash, 'k-') plt.plot(minima_dash_time_2, minima_dash, 'k-') plt.plot(minima_dash_time_3, minima_dash, 'k-') plt.text(4.34 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.74 * np.pi, -3.2, r'$\Delta{t^{min}_{m}}$') plt.text(4.12 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.50 * np.pi, 2, r'$\Delta{t^{max}_{M}}$') plt.text(4.30 * np.pi, 0.35, r'$s_1$') plt.text(4.43 * np.pi, -0.20, r'$s_2$') plt.text(4.30 * np.pi + (minima_x[-1] - minima_x[-2]), 0.35 + (minima_y[-1] - minima_y[-2]), r'$s_1$') plt.text(4.43 * np.pi + (slope_based_minimum_time - minima_x[-1]), -0.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.text(4.50 * np.pi + (slope_based_minimum_time - minima_x[-1]), 1.20 + (slope_based_minimum - minima_y[-1]), r'$s_2$') plt.plot(minima_line_dash_time, minima_line_dash, 'k--') plt.plot(maxima_line_dash_time, maxima_line_dash, 'k--') plt.plot(dash_1_time, dash_1, 'k--') plt.plot(dash_2_time, dash_2, 'k--') plt.plot(dash_3_time, dash_3, 'k--') plt.plot(dash_4_time, dash_4, 'k--') plt.plot(dash_final_time, dash_final, 'k--') plt.scatter(maxima_x, maxima_y, c='r', zorder=4, label='Maxima') plt.scatter(minima_x, minima_y, c='b', zorder=4, label='Minima') plt.scatter(slope_based_maximum_time, slope_based_maximum, c='orange', zorder=4, label=textwrap.fill('Slope-based maximum', 11)) plt.scatter(slope_based_minimum_time, slope_based_minimum, c='purple', zorder=4, label=textwrap.fill('Slope-based minimum', 11)) plt.scatter(improved_slope_based_maximum_time, improved_slope_based_maximum, c='deeppink', zorder=4, label=textwrap.fill('Improved slope-based maximum', 11)) plt.scatter(improved_slope_based_minimum_time, improved_slope_based_minimum, c='dodgerblue', zorder=4, label=textwrap.fill('Improved slope-based minimum', 11)) plt.xlim(3.9 * np.pi, 5.5 * np.pi) plt.xticks((4 * np.pi, 5 * np.pi), (r'4$\pi$', r'5$\pi$')) plt.yticks((-3, -2, -1, 0, 1, 2), ('-3', '-2', '-1', '0', '1', '2')) box_0 = ax.get_position() ax.set_position([box_0.x0 - 0.05, box_0.y0, box_0.width * 0.85, box_0.height]) ax.legend(loc='center left', bbox_to_anchor=(1, 0.5)) plt.savefig('jss_figures/edge_effects_slope_based.png') plt.show() # plot 5 a = 0.25 width = 0.2 time = np.linspace(0, (5 - a) * np.pi, 1001) time_series = np.cos(time) + np.cos(5 * time) utils = emd_utils.Utility(time=time, time_series=time_series) max_bool = utils.max_bool_func_1st_order_fd() maxima_x = time[max_bool] maxima_y = time_series[max_bool] min_bool = utils.min_bool_func_1st_order_fd() minima_x = time[min_bool] minima_y = time_series[min_bool] A2 = np.abs(maxima_y[-2] - minima_y[-2]) / 2 A1 = np.abs(maxima_y[-1] - minima_y[-1]) / 2 P2 = 2 * np.abs(maxima_x[-2] - minima_x[-2]) P1 = 2 * np.abs(maxima_x[-1] - minima_x[-1]) Huang_time = (P1 / P2) * (time[time >= maxima_x[-2]] - time[time == maxima_x[-2]]) + maxima_x[-1] Huang_wave = (A1 / A2) * (time_series[time >= maxima_x[-2]] - time_series[time == maxima_x[-2]]) + maxima_y[-1] Coughlin_time = Huang_time Coughlin_wave = A1 * np.cos(2 * np.pi * (1 / P1) * (Coughlin_time - Coughlin_time[0])) Average_max_time = maxima_x[-1] + (maxima_x[-1] - maxima_x[-2]) Average_max = (maxima_y[-2] + maxima_y[-1]) / 2 Average_min_time = minima_x[-1] + (minima_x[-1] - minima_x[-2]) Average_min = (minima_y[-2] + minima_y[-1]) / 2 utils_Huang = emd_utils.Utility(time=time, time_series=Huang_wave) Huang_max_bool = utils_Huang.max_bool_func_1st_order_fd() Huang_min_bool = utils_Huang.min_bool_func_1st_order_fd() utils_Coughlin = emd_utils.Utility(time=time, time_series=Coughlin_wave) Coughlin_max_bool = utils_Coughlin.max_bool_func_1st_order_fd() Coughlin_min_bool = utils_Coughlin.min_bool_func_1st_order_fd() Huang_max_time = Huang_time[Huang_max_bool] Huang_max = Huang_wave[Huang_max_bool] Huang_min_time = Huang_time[Huang_min_bool] Huang_min = Huang_wave[Huang_min_bool] Coughlin_max_time = Coughlin_time[Coughlin_max_bool] Coughlin_max = Coughlin_wave[Coughlin_max_bool] Coughlin_min_time = Coughlin_time[Coughlin_min_bool] Coughlin_min = Coughlin_wave[Coughlin_min_bool] max_2_x_time = np.linspace(maxima_x[-2] - width, maxima_x[-2] + width, 101) max_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) max_2_x = maxima_y[-2] * np.ones_like(max_2_x_time) min_2_x_time = np.linspace(minima_x[-2] - width, minima_x[-2] + width, 101) min_2_x_time_side = np.linspace(5.3 * np.pi - width, 5.3 * np.pi + width, 101) min_2_x = minima_y[-2] * np.ones_like(min_2_x_time) dash_max_min_2_x = np.linspace(minima_y[-2], maxima_y[-2], 101) dash_max_min_2_x_time = 5.3 * np.pi * np.ones_like(dash_max_min_2_x) max_2_y = np.linspace(maxima_y[-2] - width, maxima_y[-2] + width, 101) max_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) max_2_y_time = maxima_x[-2] * np.ones_like(max_2_y) min_2_y = np.linspace(minima_y[-2] - width, minima_y[-2] + width, 101) min_2_y_side = np.linspace(-1.8 - width, -1.8 + width, 101) min_2_y_time = minima_x[-2] * np.ones_like(min_2_y) dash_max_min_2_y_time = np.linspace(minima_x[-2], maxima_x[-2], 101) dash_max_min_2_y = -1.8 * np.ones_like(dash_max_min_2_y_time) max_1_x_time = np.linspace(maxima_x[-1] - width, maxima_x[-1] + width, 101) max_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) max_1_x = maxima_y[-1] * np.ones_like(max_1_x_time) min_1_x_time = np.linspace(minima_x[-1] - width, minima_x[-1] + width, 101) min_1_x_time_side = np.linspace(5.4 * np.pi - width, 5.4 * np.pi + width, 101) min_1_x = minima_y[-1] * np.ones_like(min_1_x_time) dash_max_min_1_x = np.linspace(minima_y[-1], maxima_y[-1], 101) dash_max_min_1_x_time = 5.4 * np.pi * np.ones_like(dash_max_min_1_x) max_1_y = np.linspace(maxima_y[-1] - width, maxima_y[-1] + width, 101) max_1_y_side = np.linspace(-2.1 - width, -2.1 + width, 101) max_1_y_time = maxima_x[-1] * np.ones_like(max_1_y) min_1_y = np.linspace(minima_y[-1] - width, minima_y[-1] + width, 101) min_1_y_side =

np.linspace(-2.1 - width, -2.1 + width, 101)

numpy.linspace

############################################################################### # @todo add Pilot2-splash-app disclaimer ############################################################################### """ Get's KRAS states """ import MDAnalysis as mda from MDAnalysis.analysis import align from MDAnalysis.lib.mdamath import make_whole import os import numpy as np import math ############## Below section needs to be uncommented ############ import mummi_core import mummi_ras from mummi_core.utils import Naming # # Logger has to be initialized the first thing in the script from logging import getLogger LOGGER = getLogger(__name__) # # Innitilize MuMMI if it has not been done before # MUMMI_ROOT = mummi.init(True) # This is needed so the Naming works below #@TODO fix this so we don't have these on import make them as an init mummi_core.init() dirKRASStates = Naming.dir_res('states') dirKRASStructures = Naming.dir_res('structures') # #RAS_ONLY_macrostate = np.loadtxt(os.path.join(dirKRASStates, "RAS-ONLY.microstates.txt")) RAS_ONLY_macrostate = np.loadtxt(os.path.join(dirKRASStates, "ras-states.txt"),comments='#') # #RAS_RAF_macrostate = np.loadtxt(os.path.join(dirKRASStates, "RAS-RAF.microstates.txt")) RAS_RAF_macrostate = np.loadtxt(os.path.join(dirKRASStates, "ras-raf-states.txt"),comments='#') # Note diffrent number of columns so index change below # TODO: CS, my edits to test # RAS_ONLY_macrostate = np.loadtxt('ras-states.txt') # RAS_RAF_macrostate = np.loadtxt('ras-raf-states.txt') ############## above section needs to be uncommented ############ # TODO: CS, my edits to test # TODO: TSC, The reference structure has to currently be set as the 'RAS-ONLY-reference-structure.gro' # TODO: TSC, path to the reference structure is: mummi_resources/structures/ kras_ref_universe = mda.Universe(os.path.join(dirKRASStructures, "RAS-ONLY-reference-structure.gro")) # kras_ref_universe = mda.Universe("RAS-ONLY-reference-structure.gro") # kras_ref_universe = mda.Universe('AA_pfpatch_000000004641_RAS_RAF2_411.gro') # TODO: CS, not using these for x4 proteins; instead using protein_systems below to set num_res ######### Below hard codes the number of residues within RAS-only and RAS-RAF ########## RAS_only_num_res = 184 RAS_RAF_num_res = 320 ######### Above hard codes the number of residues within RAS-only and RAS-RAF ########## ####### This can be removed # def get_kras(syst, kras_start): # """Gets all atoms for a KRAS protein starting at 'kras_start'.""" # return syst.atoms[kras_start:kras_start+428] ####### This can be removed def get_segids(u): """Identifies the list of segments within the system. Only needs to be called x1 time""" segs = u.segments segs = segs.segids ras_segids = [] rasraf_segids = [] for i in range(len(segs)): # print(segs[i]) if segs[i][-3:] == 'RAS': ras_segids.append(segs[i]) if segs[i][-3:] == 'RAF': rasraf_segids.append(segs[i]) return ras_segids, rasraf_segids def get_protein_info(u,tag): """Uses the segments identified in get_segids to make a list of all proteins in the systems.\ Outputs a list of the first residue number of the protein, and whether it is 'RAS-ONLY', or 'RAS-RAF'.\ The 'tag' input defines what is used to identify the first residue of the protein. i.e. 'resname ACE1 and name BB'.\ Only needs to be called x1 time""" ras_segids, rasraf_segids = get_segids(u) if len(ras_segids) > 0: RAS = u.select_atoms('segid '+ras_segids[0]+' and '+str(tag)) else: RAS = [] if len(rasraf_segids) > 0: RAF = u.select_atoms('segid '+rasraf_segids[0]+' and '+str(tag)) else: RAF = [] protein_info = []#np.empty([len(RAS)+len(RAF),2]) for i in range(len(RAS)): protein_info.append((RAS[i].resid,'RAS-ONLY')) for i in range(len(RAF)): protein_info.append((RAF[i].resid,'RAS-RAF')) ######## sort protein info protein_info = sorted(protein_info) ######## sort protein info return protein_info def get_ref_kras(): """Gets the reference KRAS struct. Only called x1 time when class is loaded""" start_of_g_ref = kras_ref_universe.residues[0].resid ref_selection = 'resid '+str(start_of_g_ref)+':'+str(start_of_g_ref+24)+' ' +\ str(start_of_g_ref+38)+':'+str(start_of_g_ref+54)+' ' +\ str(start_of_g_ref+67)+':'+str(start_of_g_ref+164)+' ' +\ 'and (name CA or name BB)' r2_26r40_56r69_166_ref = kras_ref_universe.select_atoms(str(ref_selection)) return kras_ref_universe.select_atoms(str(ref_selection)).positions - kras_ref_universe.select_atoms(str(ref_selection)).center_of_mass() # Load inital ref frames (only need to do this once) ref0 = get_ref_kras() def getKRASstates(u,kras_indices): """Gets states for all KRAS proteins in path.""" # res_shift = 8 # all_glycine = u.select_atoms("resname GLY") # kras_indices = [] # for i in range(0, len(all_glycine), 26): # kras_indices.append(all_glycine[i].index) ########## Below is taken out of the function so it is only done once ######### # kras_indices = get_protein_info(u,'resname ACE1 and name BB') ########## Above is taken out of the function so it is only done once ######### # CS, for x4 cases: # [{protein_x4: (protein_type, num_res)}] protein_systems = [{'ras4a': ('RAS-ONLY', 185), 'ras4araf': ('RAS-RAF', 321), 'ras': ('RAS-ONLY', 184), 'rasraf': ('RAS-RAF', 320)}] ALLOUT = [] for k in range(len(kras_indices)): start_of_g = kras_indices[k][0] protein_x4 = str(kras_indices[k][1]) try: protein_type = [item[protein_x4] for item in protein_systems][0][0] # 'RAS-ONLY' OR 'RAS-RAF' num_res = [item[protein_x4] for item in protein_systems][0][1] except: LOGGER.error('Check KRas naming between modules') raise Exception('Error: unknown KRas name') # TODO: CS, replacing this comment section with the above, to handle x4 protein types # --------------------------------------- # ALLOUT = [] # for k in range(len(kras_indices)): # start_of_g = kras_indices[k][0] # protein_type = str(kras_indices[k][1]) # ########## BELOW SECTION TO DETERMINE WHICH RESIDUES ARE PART OF THE PROTEIN GROUP - NEEDED FOR PBC REMOVAL ############## # ########## POTENTIALLY REDO WITH A 'HARD-CODED' NUMBER OF RESIDUES PER PROTEIN GROUP (WHETHER RAS-ONLY OR RAS-RAF) ####### # ########## HAS BEEN REDONE WITH A 'HARD-CODED' NUMBER OF RESIDUES PER PROTEIN GROUP (WHETHER RAS-ONLY OR RAS-RAF) ######## # # if len(kras_indices) == 1: # # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(len(u.residues))+' and name BB') ####### HAS TO BE FIXED FOR BACKBONE ATOMS FOR SPECIFIC PROTEIN # # elif len(kras_indices) > 1: # # if k == len(kras_indices)-1: # # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(len(u.residues))+' and name BB') # # else: # # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(kras_indices[k+1][0])+' and name BB') # ########## ABOVE SECTION TO DETERMINE WHICH RESIDUES ARE PART OF THE PROTEIN GROUP - NEEDED FOR PBC REMOVAL ############## # # ########## Below hard codes the number of residues/beads in the RAS-ONLY and RAS-RAF simulations ######################### # if protein_type == 'RAS-ONLY': # num_res = RAS_only_num_res # elif protein_type == 'RAS-RAF': # num_res = RAS_RAF_num_res # ########## Above hard codes the number of residues/beads in the RAS-ONLY and RAS-RAF simulations ######################### # --------------------------------------- # TODO: TSC, I changed the selection below, which can be used for the make_whole... # krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(start_of_g+num_res)+' and (name CA or name BB)') krases0_BB = u.select_atoms('resid '+str(start_of_g)+':'+str(start_of_g+num_res)) krases0_BB.guess_bonds() r2_26r40_56r69_166 = u.select_atoms('resid '+str(start_of_g)+':'+str(start_of_g+24)+' ' +\ str(start_of_g+38)+':'+str(start_of_g+54)+' ' +\ str(start_of_g+67)+':'+str(start_of_g+164)+\ ' and (name CA or name BB)') u_selection = \ 'resid '+str(start_of_g)+':'+str(start_of_g+24)+' '+str(start_of_g+38)+':'+str(start_of_g+54)+' ' +\ str(start_of_g+67)+':'+str(start_of_g+164)+' and (name CA or name BB)' mobile0 = u.select_atoms(str(u_selection)).positions - u.select_atoms(str(u_selection)).center_of_mass() # TODO: CS, something wrong with ref0 from get_kras_ref() # just making ref0 = mobile0 to test for now # ref0 = mobile0 # TSC removed this R, RMSD_junk = align.rotation_matrix(mobile0, ref0) ######## TODO: TSC, Adjusted for AA lipid names ######## # lipids = u.select_atoms('resname POPX POPC PAPC POPE DIPE DPSM PAPS PAP6 CHOL') lipids = u.select_atoms('resname POPC PAPC POPE DIPE SSM PAPS SAPI CHL1') coords = ref0 RotMat = [] OS = [] r152_165 = krases0_BB.select_atoms('resid '+str(start_of_g+150)+':'+str(start_of_g+163)+' and (name CA or name BB)') r65_74 = krases0_BB.select_atoms('resid '+str(start_of_g+63)+':'+str(start_of_g+72)+' and (name CA or name BB)') timeframes = [] # TODO: CS, for AA need bonds to run make_whole() # krases0_BB.guess_bonds() # TODO: CS, turn off for now to test beyond this point ''' *** for AA, need to bring that back on once all else runs *** ''' # @Tim and <NAME>. this was commented out - please check. #make_whole(krases0_BB) j, rmsd_junk = mda.analysis.align.rotation_matrix((r2_26r40_56r69_166.positions-r2_26r40_56r69_166.center_of_mass()), coords) RotMat.append(j) OS.append(r65_74.center_of_mass()-r152_165.center_of_mass()) timeframes.append(u.trajectory.time) if protein_type == 'RAS-RAF': z_pos = [] ############### NEED TO CONFIRM THE SELECTION OF THE RAF LOOP RESIDUES BELOW #################### ############### TODO: TSC, zshifting is set to -1 (instead of -2), as there are ACE caps that are separate residues in AA #zshifting=-1 if protein_x4 == 'rasraf': zshifting = -1 elif protein_x4 == 'ras4araf': zshifting = 0 else: zshifting = 0 LOGGER.error('Found unsupported protein_x4 type') raf_loops_selection = u.select_atoms('resid '+str(start_of_g+zshifting+291)+':'+str(start_of_g+zshifting+294)+' ' +\ str(start_of_g+zshifting+278)+':'+str(start_of_g+zshifting+281)+' ' +\ ' and (name CA or name BB)') ############### NEED TO CONFIRM THE SELECTION OF THE RAF LOOP RESIDUES ABOVE #################### diff = (lipids.center_of_mass()[2]-raf_loops_selection.center_of_mass(unwrap=True)[2])/10 if diff < 0: diff = diff+(u.dimensions[2]/10) z_pos.append(diff) z_pos = np.array(z_pos) RotMatNP = np.array(RotMat) OS = np.array(OS) OA = RotMatNP[:, 2, :]/(((RotMatNP[:, 2, 0]**2)+(RotMatNP[:, 2, 1]**2)+(RotMatNP[:, 2, 2]**2))**0.5)[:, None] OWAS = np.arccos(RotMatNP[:, 2, 2])*180/math.pi OC_temp = np.concatenate((OA, OS), axis=1) t = ((OC_temp[:, 0]*OC_temp[:, 3])+(OC_temp[:, 1]*OC_temp[:, 4]) + (OC_temp[:, 2]*OC_temp[:, 5]))/((OC_temp[:, 0]**2)+(OC_temp[:, 1]**2)+(OC_temp[:, 2]**2)) OC = OA*t[:, None] ORS_tp =

np.concatenate((OC, OS), axis=1)

numpy.concatenate

import argparse import json import numpy as np import pandas as pd import os from sklearn.linear_model import LogisticRegression from sklearn.model_selection import train_test_split from sklearn.metrics import classification_report,f1_score from keras.models import Sequential from keras.layers import Dense, Dropout from keras import backend as K from keras.utils.vis_utils import plot_model from sklearn.externals import joblib import time def f1(y_true, y_pred): def recall(y_true, y_pred): """Recall metric. Only computes a batch-wise average of recall. Computes the recall, a metric for multi-label classification of how many relevant items are selected. """ true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1))) possible_positives = K.sum(K.round(K.clip(y_true, 0, 1))) recall = true_positives / (possible_positives + K.epsilon()) return recall def precision(y_true, y_pred): """Precision metric. Only computes a batch-wise average of precision. Computes the precision, a metric for multi-label classification of how many selected items are relevant. """ true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1))) predicted_positives = K.sum(K.round(K.clip(y_pred, 0, 1))) precision = true_positives / (predicted_positives + K.epsilon()) return precision precision = precision(y_true, y_pred) recall = recall(y_true, y_pred) return 2*((precision*recall)/(precision+recall+K.epsilon())) def get_embeddings(sentences_list,layer_json): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :return: Dictionary with key each sentence of the sentences_list and as value the embedding ''' sentences = dict()#dict with key the index of each line of the sentences_list.txt and as value the sentence embeddings = dict()##dict with key the index of each sentence and as value the its embedding sentence_emb = dict()#key:sentence,value:its embedding with open(sentences_list,'r') as file: for index,line in enumerate(file): sentences[index] = line.strip() with open(layer_json, 'r',encoding='utf-8') as f: for line in f: embeddings[json.loads(line)['linex_index']] = np.asarray(json.loads(line)['features']) for key,value in sentences.items(): sentence_emb[value] = embeddings[key] return sentence_emb def train_classifier(sentences_list,layer_json,dataset_csv,filename): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :param dataset_csv: the path of the dataset :param filename: The path of the pickle file that the model will be stored :return: ''' dataset = pd.read_csv(dataset_csv) bert_dict = get_embeddings(sentences_list,layer_json) length = list() sentence_emb = list() previous_emb = list() next_list = list() section_list = list() label = list() errors = 0 for row in dataset.iterrows(): sentence = row[1][0].strip() previous = row[1][1].strip() nexts = row[1][2].strip() section = row[1][3].strip() if sentence in bert_dict: sentence_emb.append(bert_dict[sentence]) else: sentence_emb.append(np.zeros(768)) print(sentence) errors += 1 if previous in bert_dict: previous_emb.append(bert_dict[previous]) else: previous_emb.append(np.zeros(768)) if nexts in bert_dict: next_list.append(bert_dict[nexts]) else: next_list.append(np.zeros(768)) if section in bert_dict: section_list.append(bert_dict[section]) else: section_list.append(np.zeros(768)) length.append(row[1][4]) label.append(row[1][5]) sentence_emb = np.asarray(sentence_emb) print(sentence_emb.shape) next_emb = np.asarray(next_list) print(next_emb.shape) previous_emb = np.asarray(previous_emb) print(previous_emb.shape) section_emb = np.asarray(section_list) print(sentence_emb.shape) length = np.asarray(length) print(length.shape) label = np.asarray(label) print(errors) features = np.concatenate([sentence_emb, previous_emb, next_emb,section_emb], axis=1) features = np.column_stack([features, length]) # np.append(features,length,axis=1) print(features.shape) X_train, X_val, y_train, y_val = train_test_split(features, label, test_size=0.33, random_state=42) log = LogisticRegression(random_state=0, solver='newton-cg', max_iter=1000, C=0.1) log.fit(X_train, y_train) #save the model _ = joblib.dump(log, filename, compress=9) predictions = log.predict(X_val) print("###########################################") print("Results using embeddings from the",layer_json,"file") print(classification_report(y_val, predictions)) print("F1 score using Logistic Regression:",f1_score(y_val, predictions)) print("###########################################") #train a DNN f1_results = list() for i in range(3): model = Sequential() model.add(Dense(64, activation='relu', trainable=True)) model.add(Dense(128, activation='relu', trainable=True)) model.add(Dropout(0.30)) model.add(Dense(64, activation='relu', trainable=True)) model.add(Dropout(0.25)) model.add(Dense(64, activation='relu', trainable=True)) model.add(Dropout(0.35)) model.add(Dense(1, activation='sigmoid')) # compile network model.compile(loss='binary_crossentropy', optimizer='sgd', metrics=[f1]) # fit network model.fit(X_train, y_train, epochs=100, batch_size=64) loss, f_1 = model.evaluate(X_val, y_val, verbose=1) print('\nTest F1: %f' % (f_1 * 100)) f1_results.append(f_1) model = None print("###########################################") print("Results using embeddings from the", layer_json, "file") # evaluate print(np.mean(f1_results)) print("###########################################") def parameter_tuning_LR(sentences_list,layer_json,dataset_csv): ''' :param sentences_list: the path o the sentences.txt :param layer_json: the path of the json file that contains the embeddings of the sentences :param dataset_csv: the path of the dataset :return: ''' dataset = pd.read_csv(dataset_csv) bert_dict = get_embeddings(sentences_list,layer_json) length = list() sentence_emb = list() previous_emb = list() next_list = list() section_list = list() label = list() errors = 0 for row in dataset.iterrows(): sentence = row[1][0].strip() previous = row[1][1].strip() nexts = row[1][2].strip() section = row[1][3].strip() if sentence in bert_dict: sentence_emb.append(bert_dict[sentence]) else: sentence_emb.append(np.zeros(768)) print(sentence) errors += 1 if previous in bert_dict: previous_emb.append(bert_dict[previous]) else: previous_emb.append(

np.zeros(768)

numpy.zeros

try: import importlib.resources as pkg_resources except ImportError: # Try backported to PY<37 `importlib_resources`. import importlib_resources as pkg_resources from . import images from gym import Env, spaces from time import time import numpy as np from copy import copy import colorsys import pygame from pygame.transform import scale class MinesweeperEnv(Env): def __init__(self, grid_shape=(10, 15), bombs_density=0.1, n_bombs=None, impact_size=3, max_time=999, chicken=False): self.grid_shape = grid_shape self.grid_size = np.prod(grid_shape) self.n_bombs = max(1, int(bombs_density * self.grid_size)) if n_bombs is None else n_bombs self.n_bombs = min(self.grid_size - 1, self.n_bombs) self.flaged_bombs = 0 self.flaged_empty = 0 self.max_time = max_time if impact_size % 2 == 0: raise ValueError('Impact_size must be an odd number !') self.impact_size = impact_size # Define constants self.HIDDEN = 0 self.REVEAL = 1 self.FLAG = 2 self.BOMB = self.impact_size ** 2 # Setting up gym Env conventions nvec_observation = (self.BOMB + 2) * np.ones(self.grid_shape) self.observation_space = spaces.MultiDiscrete(nvec_observation) nvec_action = np.array(self.grid_shape + (2,)) self.action_space = spaces.MultiDiscrete(nvec_action) # Initalize state self.state = np.zeros(self.grid_shape + (2,), dtype=np.uint8) ## Setup bombs places idx = np.indices(self.grid_shape).reshape(2, -1) bombs_ids = np.random.choice(range(self.grid_size), size=self.n_bombs, replace=False) self.bombs_positions = idx[0][bombs_ids], idx[1][bombs_ids] ## Place numbers self.semi_impact_size = (self.impact_size-1)//2 bomb_impact = np.ones((self.impact_size, self.impact_size), dtype=np.uint8) for bombs_id in bombs_ids: bomb_x, bomb_y = idx[0][bombs_id], idx[1][bombs_id] x_min, x_max, dx_min, dx_max = self.clip_index(bomb_x, 0) y_min, y_max, dy_min, dy_max = self.clip_index(bomb_y, 1) bomb_region = self.state[x_min:x_max, y_min:y_max, 0] bomb_region += bomb_impact[dx_min:dx_max, dy_min:dy_max] ## Place bombs self.state[self.bombs_positions + (0,)] = self.BOMB self.start_time = time() self.time_left = int(time() - self.start_time) # Setup rendering self.pygame_is_init = False self.chicken = chicken self.done = False self.score = 0 def get_observation(self): observation = copy(self.state[:, :, 1]) revealed = observation == 1 flaged = observation == 2 observation += self.impact_size ** 2 + 1 observation[revealed] = copy(self.state[:, :, 0][revealed]) observation[flaged] -= 1 return observation def reveal_around(self, coords, reward, done, without_loss=False): if not done: x_min, x_max, _, _ = self.clip_index(coords[0], 0) y_min, y_max, _, _ = self.clip_index(coords[1], 1) region = self.state[x_min:x_max, y_min:y_max, :] unseen_around = np.sum(region[..., 1] == 0) if unseen_around == 0: if not without_loss: reward -= 0.001 return flags_around =

np.sum(region[..., 1] == 2)

numpy.sum

import pandas as pd import numpy as np import matplotlib.pyplot as plt import os import matplotlib.pyplot as plt import CurveFit import shutil #find all DIRECTORIES containing non-hidden files ending in FILENAME def getDataDirectories(DIRECTORY, FILENAME="valLoss.txt"): directories=[] for directory in os.scandir(DIRECTORY): for item in os.scandir(directory): if item.name.endswith(FILENAME) and not item.name.startswith("."): directories.append(directory.path) return directories #get all non-hidden data files in DIRECTORY with extension EXT def getDataFiles(DIRECTORY, EXT='txt'): datafiles=[] for item in os.scandir(DIRECTORY): if item.name.endswith("."+EXT) and not item.name.startswith("."): datafiles.append(item.path) return datafiles #checking if loss ever doesn't decrease for numEpochs epochs in a row. def stopsDecreasing(loss, epoch, numEpochs): minLoss=np.inf epochMin=0 for i in range(0,loss.size): if loss[i] < minLoss: minLoss=loss[i] epochMin=epoch[i] elif (epoch[i]-epochMin) >= numEpochs: return i, minLoss return i, minLoss #dirpath is where the accuracy and loss files are stored. want to move the files into the same format expected by grabNNData. def createFolders(SEARCHDIR, SAVEDIR): for item in os.scandir(SEARCHDIR): name=str(item.name) files=name.split('-') SAVEFULLDIR=SAVEDIR+str(files[0]) if not os.path.exists(SAVEFULLDIR): try: os.makedirs(SAVEFULLDIR) except FileExistsError: #directory already exists--must have been created between the if statement & our attempt at making directory pass shutil.move(item.path, SAVEFULLDIR+"/"+str(files[1])) #a function to read in information (e.g. accuracy, loss) stored at FILENAME def grabNNData(FILENAME, header='infer', sep=' '): data = pd.read_csv(FILENAME, sep, header=header) if ('epochs' in data.columns) and ('trainLoss' in data.columns) and ('valLoss' in data.columns) and ('valAcc' in data.columns) and ('batch_size' in data.columns) and ('learning_rate' in data.columns): sortedData=data.sort_values(by="epochs", axis=0, ascending=True) epoch=np.array(sortedData['epochs']) trainLoss=np.array(sortedData['trainLoss']) valLoss=np.array(sortedData['valLoss']) valAcc=

np.array(sortedData['valAcc'])

numpy.array

import os from PIL import Image import cv2 from os import listdir from os.path import join import matplotlib.pyplot as plt import matplotlib from matplotlib.colors import LogNorm from io_utils.io_common import create_folder from viz_utils.constants import PlotMode, BackgroundType import pylab import numpy as np import cmocean import shapely import cartopy.crs as ccrs import cartopy.feature as cfeature import cartopy def select_colormap(field_name): ''' Based on the name if the field it chooses a colormap from cmocean Args: field_name: Returns: ''' if np.any([field_name.find(x) != -1 for x in ('ssh', 'srfhgt', 'adt','surf_el')]): # cmaps_fields.append(cmocean.cm.deep_r) return cmocean.cm.curl elif np.any([field_name.find(x) != -1 for x in ('temp', 'sst', 'temperature')]): return cmocean.cm.thermal elif np.any([field_name.find(x) != -1 for x in ('vorticity', 'vort')]): return cmocean.cm.curl elif np.any([field_name.find(x) != -1 for x in ('salin', 'sss', 'sal')]): return cmocean.cm.haline elif field_name.find('error') != -1: return cmocean.cm.diff elif field_name.find('binary') != -1: return cmocean.cm.oxy elif np.any([field_name.find(x) != -1 for x in ('u_', 'v_', 'u-vel.', 'v-vel.','velocity')]): return cmocean.cm.speed class EOAImageVisualizer: """This class makes plenty of plots assuming we are plotting Geospatial data (maps). It is made to read xarrays, numpy arrays, and numpy arrays in dictionaries vizobj = new EOAImageVisualizer(disp_images=True, output_folder='output', lats=[lats],lons=[lons]) """ _COLORS = ['y', 'r', 'c', 'b', 'g', 'w', 'k', 'y', 'r', 'c', 'b', 'g', 'w', 'k'] _figsize = 8 _font_size = 30 _units = '' _max_imgs_per_row = 4 _mincbar = np.nan # User can set a min and max colorbar values to 'force' same color bar to all plots _maxcbar = np.nan _flip_data = True _eoas_pyutils_path = './eoas_pyutils'# This is the path where the eoas_utils folder is stored with respect to the main project _contourf = False # When plotting non-regular grids and need precision _background = BackgroundType.BLUE_MARBLE_LR # Select the background to use _auto_colormap = True # Selects the colormap based on the name of the field _show_var_names = False # Includes the name of the field name in the titles _additional_polygons = [] # MUST BE SHAPELY GEOMETRIES In case we want to include additional polygons in the plots (all of them) # If you want to add a streamplot of a vector field. It must be a dictionary with keys x,y,u,v # and optional density, color, cmap, arrowsize, arrowstyle, minlength _vector_field = None _norm = None # Use to normalize the colormap. For example with LogNorm # vizobj = EOAImageVisualizer(disp_images=True, output_folder='output', # lats=[lats],lons=[lons]) def __init__(self, disp_images=True, output_folder='output', lats=[-90,90], lons =[-180,180], projection=ccrs.PlateCarree(), **kwargs): # All the arguments that are passed to the constructor of the class MUST have its name on it. self._disp_images = disp_images self._output_folder = output_folder self._projection = projection bbox = self.getExtent(lats, lons) self._extent = bbox self._lats = lats self._lons = lons self._fig_prop = (bbox[1]-bbox[0])/(bbox[3]-bbox[2]) self._contour_labels = False for arg_name, arg_value in kwargs.items(): self.__dict__["_" + arg_name] = arg_value print(self.__dict__["_" + arg_name]) def __getattr__(self, attr): '''Generic getter for all the properties of the class''' return self.__dict__["_" + attr] def __setattr__(self, attr, value): '''Generic setter for all the properties of the class''' self.__dict__["_" + attr] = value def add_colorbar(self, fig, im, ax, show_color_bar, label=""): # https://matplotlib.org/api/_as_gen/matplotlib.pyplot.colorbar.html if show_color_bar: font_size_cbar = self._font_size * .5 # TODO how to make this automatic and works always cbar = fig.colorbar(im, ax=ax, shrink=.7) cbar.ax.tick_params(labelsize=font_size_cbar) if label != "": cbar.set_label(label, fontsize=font_size_cbar*1.2) else: cbar.set_label(self._units, fontsize=font_size_cbar*1.2) def plot_slice_eoa(self, c_img, ax, cmap='gray', mode=PlotMode.RASTER, mincbar=np.nan, maxcbar=np.nan) -> None: """ Plots a 2D img for EOA data. :param c_img: 2D array :param ax: geoaxes :return: """ c_ax = ax if self._flip_data: origin = 'lower' else: origin = 'upper' if self._background == BackgroundType.CARTO_DEF: c_ax.stock_img() else: if self._background == BackgroundType.BLUE_MARBLE_LR: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/bluemarble.png')) if self._background == BackgroundType.BLUE_MARBLE_HR: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/bluemarble_5400x2700.jpg')) if self._background == BackgroundType.TOPO: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/etopo.png')) if self._background == BackgroundType.BATHYMETRY: img = plt.imread(join(self._eoas_pyutils_path,'viz_utils/imgs/bathymetry_3600x1800.jpg')) c_ax.imshow(img, origin='upper', extent=(-180,180,-90,90), transform=ccrs.PlateCarree()) if mode == PlotMode.RASTER or mode == PlotMode.MERGED: if self._contourf: im = c_ax.contourf(self._lons, self._lats, c_img, num_colors=255, cmap='inferno', extent=self._extent) else: if

np.isnan(mincbar)

numpy.isnan