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import numpy as np |
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def norm_kpt(K, kp): |
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kp = np.concatenate([kp, np.ones([kp.shape[0], 1])], axis=1) |
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kp = np.matmul(kp, np.linalg.inv(K).T)[:, :2] |
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return kp |
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def unnorm_kp(K,kp): |
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kp = np.concatenate([kp, np.ones([kp.shape[0], 1])], axis=1) |
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kp = np.matmul(kp,K.T)[:, :2] |
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return kp |
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def interpolate_depth(pos, depth): |
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ids = np.array(range(0, pos.shape[0])) |
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h, w = depth.shape |
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i = pos[:, 0] |
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j = pos[:, 1] |
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valid_corner=np.logical_and(np.logical_and(i>0,i<h-1),np.logical_and(j>0,j<w-1)) |
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i,j=i[valid_corner],j[valid_corner] |
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ids = ids[valid_corner] |
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i_top_left = np.floor(i).astype(np.int32) |
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j_top_left = np.floor(j).astype(np.int32) |
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i_top_right = np.floor(i).astype(np.int32) |
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j_top_right = np.ceil(j).astype(np.int32) |
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i_bottom_left = np.ceil(i).astype(np.int32) |
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j_bottom_left = np.floor(j).astype(np.int32) |
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i_bottom_right = np.ceil(i).astype(np.int32) |
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j_bottom_right = np.ceil(j).astype(np.int32) |
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depth_top_left,depth_top_right,depth_down_left,depth_down_right=depth[i_top_left, j_top_left],depth[i_top_right, j_top_right],\ |
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depth[i_bottom_left, j_bottom_left],depth[i_bottom_right, j_bottom_right] |
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valid_depth = np.logical_and( |
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np.logical_and( |
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depth_top_left > 0, |
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depth_top_right > 0 |
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), |
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np.logical_and( |
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depth_down_left > 0, |
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depth_down_left > 0 |
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) |
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) |
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ids=ids[valid_depth] |
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depth_top_left,depth_top_right,depth_down_left,depth_down_right=depth_top_left[valid_depth],depth_top_right[valid_depth],\ |
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depth_down_left[valid_depth],depth_down_right[valid_depth] |
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i,j,i_top_left,j_top_left=i[valid_depth],j[valid_depth],i_top_left[valid_depth],j_top_left[valid_depth] |
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dist_i_top_left = i - i_top_left.astype(np.float32) |
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dist_j_top_left = j - j_top_left.astype(np.float32) |
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w_top_left = (1 - dist_i_top_left) * (1 - dist_j_top_left) |
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w_top_right = (1 - dist_i_top_left) * dist_j_top_left |
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w_bottom_left = dist_i_top_left * (1 - dist_j_top_left) |
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w_bottom_right = dist_i_top_left * dist_j_top_left |
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interpolated_depth = ( |
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w_top_left * depth_top_left + |
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w_top_right * depth_top_right+ |
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w_bottom_left * depth_down_left + |
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w_bottom_right * depth_down_right |
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) |
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return [interpolated_depth, ids] |
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def reprojection(depth_map,kpt,dR,dt,K1_img2depth,K1,K2): |
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def swap_axis(data): |
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return np.stack([data[:, 1], data[:, 0]], axis=-1) |
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kp_depth = unnorm_kp(K1_img2depth,kpt) |
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uv_depth = swap_axis(kp_depth) |
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z,valid_idx = interpolate_depth(uv_depth, depth_map) |
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norm_kp=norm_kpt(K1,kpt) |
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norm_kp_valid = np.concatenate([norm_kp[valid_idx, :], np.ones((len(valid_idx), 1))], axis=-1) |
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xyz_valid = norm_kp_valid * z.reshape(-1, 1) |
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xyz2 = np.matmul(xyz_valid, dR.T) + dt.reshape(1, 3) |
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xy2 = xyz2[:, :2] / xyz2[:, 2:] |
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kp2, valid = np.ones(kpt.shape) * 1e5, np.zeros(kpt.shape[0]) |
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kp2[valid_idx] = unnorm_kp(K2,xy2) |
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valid[valid_idx] = 1 |
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return kp2, valid.astype(bool) |
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def reprojection_2s(kp1, kp2,depth1, depth2, K1, K2, dR, dt, size1,size2): |
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depth_size1,depth_size2 = [depth1.shape[0], depth1.shape[1]], [depth2.shape[0], depth2.shape[1]] |
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scale_1= [float(depth_size1[0]) / size1[0], float(depth_size1[1]) / size1[1], 1] |
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scale_2= [float(depth_size2[0]) / size2[0], float(depth_size2[1]) / size2[1], 1] |
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K1_img2depth, K2_img2depth = np.diag(np.asarray(scale_1)), np.diag(np.asarray(scale_2)) |
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kp1_2_proj, valid1_2 = reprojection(depth1, kp1, dR, dt, K1_img2depth,K1,K2) |
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kp2_1_proj, valid2_1 = reprojection(depth2, kp2, dR.T, -np.matmul(dR.T, dt), K2_img2depth,K2,K1) |
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return [kp1_2_proj,kp2_1_proj],[valid1_2,valid2_1] |
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def make_corr(kp1,kp2,desc1,desc2,depth1,depth2,K1,K2,dR,dt,size1,size2,corr_th,incorr_th,check_desc=False): |
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[kp1_2,kp2_1],[valid1_2,valid2_1]=reprojection_2s(kp1,kp2,depth1,depth2,K1,K2,dR,dt,size1,size2) |
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num_pts1, num_pts2 = kp1.shape[0], kp2.shape[0] |
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dis_mat1=np.sqrt(abs((kp1 ** 2).sum(1,keepdims=True) + (kp2_1 ** 2).sum(1,keepdims=False)[np.newaxis] - 2 * np.matmul(kp1, kp2_1.T))) |
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dis_mat2 =np.sqrt(abs((kp2 ** 2).sum(1,keepdims=True) + (kp1_2 ** 2).sum(1,keepdims=False)[np.newaxis] - 2 * np.matmul(kp2,kp1_2.T))) |
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repro_error = np.maximum(dis_mat1,dis_mat2.T) |
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nn_sort1 = np.argmin(repro_error, axis=1) |
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nn_sort2 = np.argmin(repro_error, axis=0) |
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mask_mutual = nn_sort2[nn_sort1] == np.arange(kp1.shape[0]) |
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mask_inlier=np.take_along_axis(repro_error,indices=nn_sort1[:,np.newaxis],axis=-1).squeeze(1)<corr_th |
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mask = mask_mutual&mask_inlier |
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corr_index=np.stack([np.arange(num_pts1)[mask], np.arange(num_pts2)[nn_sort1[mask]]], axis=-1) |
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if check_desc: |
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x1_valid, x2_valid = kp1[corr_index[:, 0]], kp2[corr_index[:, 1]] |
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mask_samepos1=np.logical_and(x1_valid[:, 0,np.newaxis] == kp1[np.newaxis,:, 0],x1_valid[:, 1,np.newaxis] == kp1[np.newaxis,:, 1]) |
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mask_samepos2=np.logical_and(x2_valid[:, 0,np.newaxis]== kp2[np.newaxis,:, 0],x2_valid[:, 1,np.newaxis] == kp2[np.newaxis,:, 1]) |
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duplicated_mask=np.logical_or(mask_samepos1.sum(-1)>1,mask_samepos2.sum(-1)>1) |
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duplicated_index=np.nonzero(duplicated_mask)[0] |
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unique_corr_index=corr_index[~duplicated_mask] |
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clean_duplicated_corr=[] |
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for index in duplicated_index: |
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cur_desc1, cur_desc2 = desc1[mask_samepos1[index]], desc2[mask_samepos2[index]] |
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cur_desc_mat = np.matmul(cur_desc1, cur_desc2.T) |
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cur_max_index =[np.argmax(cur_desc_mat)//cur_desc_mat.shape[1],np.argmax(cur_desc_mat)%cur_desc_mat.shape[1]] |
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clean_duplicated_corr.append(np.stack([np.arange(num_pts1)[mask_samepos1[index]][cur_max_index[0]], |
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np.arange(num_pts2)[mask_samepos2[index]][cur_max_index[1]]])) |
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clean_corr_index=unique_corr_index |
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if len(clean_duplicated_corr)!=0: |
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clean_duplicated_corr=np.stack(clean_duplicated_corr,axis=0) |
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clean_corr_index=np.concatenate([clean_corr_index,clean_duplicated_corr],axis=0) |
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else: |
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clean_corr_index=corr_index |
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mask_incorr1 = np.min(dis_mat2.T[valid1_2], axis=-1) > incorr_th |
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mask_incorr2 = np.min(dis_mat1.T[valid2_1], axis=-1) > incorr_th |
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incorr_index1, incorr_index2 = np.arange(num_pts1)[valid1_2][mask_incorr1.squeeze()], \ |
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np.arange(num_pts2)[valid2_1][mask_incorr2.squeeze()] |
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return clean_corr_index,incorr_index1,incorr_index2 |
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