Datasets:

sysmlv2research
/

source_raw

	standard library package StateSpaceRepresentation {
	doc
	/*
	* This package provides a model of the foundational state-space system representation,
	* commonly used in control systems.
	*/

	private import ISQ::DurationValue;
	private import Quantities::VectorQuantityValue;
	private import VectorCalculations::*;

	abstract attribute def StateSpace :> VectorQuantityValue;
	abstract attribute def Input :> VectorQuantityValue;
	abstract attribute def Output :> VectorQuantityValue;

	abstract calc def GetNextState {
	in input: Input;
	in stateSpace: StateSpace;
	in timeStep: DurationValue;
	return : StateSpace;
	}
	abstract calc def GetOutput {
	in input: Input;
	in stateSpace: StateSpace;
	return : Output;
	}

	abstract action def StateSpaceEventDef {
	doc
	/*
	* Events to be received.
	*/
	}
	action def ZeroCrossingEventDef :> StateSpaceEventDef;

	item def StateSpaceItem {
	doc
	/*
	* Item for SSR connection
	*/
	}

	abstract action def StateSpaceDynamics {
	doc
	/*
	* StateSpaceDynamics is the simplest form of State Space Representation,
	* and nextState directly computes the stateSpace of the next timestep.
	*/

	in attribute input: Input;

	abstract calc getNextState: GetNextState;
	abstract calc getOutput: GetOutput;
	attribute stateSpace: StateSpace;

	out attribute output: Output = getOutput(input, stateSpace);
	}

	abstract attribute def StateDerivative :> VectorQuantityValue {
	doc
	/*
	* The definition of the time derivative of StateSpace, which means dx/dt, where x is StateSpace
	*/

	ref stateSpace: StateSpace;
	constraint { stateSpace.order == order }
	}

	abstract calc def GetDerivative {
	doc
	/*
	* Computes the time derivative of stateSpace, which corresponds dx/dt = f(u, x), where u is input and x is stateSpace.
	*/

	in input: Input;
	in stateSpace: StateSpace;
	return : StateDerivative;
	}

	abstract calc def Integrate {
	doc
	/*
	* Integrates stateSpace to compute the next stateSpace, which corresponds to x + int dx/dt dt.
	* Its actual implementation should be given by a solver.
	*/

	in getDerivative: GetDerivative;
	in input: Input;
	in initialState: StateSpace;
	in timeInterval: DurationValue;
	return result: StateSpace;
	}

	abstract action def ContinuousStateSpaceDynamics :> StateSpaceDynamics {
	doc
	/*
	* ContinuousStateSpaceDynamics represents continuous behavior.
	* derivative needs to return a time derivative of stateSpace, i.e. dx/dt.
	*/

	abstract calc getDerivative: GetDerivative;
	calc :>> getNextState: GetNextState {
	/* We compute nextState by Integrate defined above by giving derivative calc. */
	calc integrate: Integrate {
	in getDerivative = ContinuousStateSpaceDynamics::getDerivative;
	in input = GetNextState::input;
	in initialState = GetNextState::stateSpace;
	in timeInterval = GetNextState::timeStep;
	}
	return result = integrate.result;
	}

	event occurrence zeroCrossingEvents[0..*] : ZeroCrossingEventDef {
	/* ContinuousStateSpaceDynamics may cause zero crossings anomaly. */
	}
	}

	abstract calc def GetDifference {
	doc
	/*
	* Computes difference of stateSpace by one timestep, that is x(k+1) - x(k),
	* where k is the timestep number.
	*/

	in input: Input;
	in stateSpace: StateSpace;
	return : StateSpace;
	}

	abstract action def DiscreteStateSpaceDynamics :> StateSpaceDynamics {
	doc
	/*
	* DiscreteStateSpaceDynamics represents discrete behavior.
	* differences needs to return difference of the stateSpace for each timestep.
	*/

	abstract calc getDifference: GetDifference;
	calc :>> getNextState: GetNextState {
	attribute diff: StateSpace = getDifference(input, stateSpace);
	return result = stateSpace + diff;
	}
	}
	}