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/*
 * (c) Copyright Christian P. Fries, Germany. Contact: [email protected].
 *
 * Created on 16.06.2006
 */
package net.finmath.optimizer;

import java.util.List;
import java.util.Map;
import java.util.concurrent.ExecutorService;

import net.finmath.montecarlo.automaticdifferentiation.RandomVariableDifferentiable;
import net.finmath.stochastic.RandomVariable;

/**
 * This class implements a stochastic Levenberg Marquardt non-linear least-squares fit
 * algorithm.
 * 

* The design avoids the need to define the objective function as a * separate class. The objective function is defined by overriding a class * method, see the sample code below. *

* *

* The Levenberg-Marquardt solver is implemented in using multi-threading. * The calculation of the derivatives (in case a specific implementation of * {@code setDerivatives(RandomVariable[] parameters, RandomVariable[][] derivatives)} is not * provided) may be performed in parallel by setting the parameter numberOfThreads. *

* *

* To use the solver inherit from it and implement the objective function as * {@code setValues(RandomVariable[] parameters, RandomVariable[] values)} where values has * to be set to the value of the objective functions for the given parameters. *
* You may also provide an a derivative for your objective function by * additionally overriding the function {@code setDerivatives(RandomVariable[] parameters, RandomVariable[][] derivatives)}, * otherwise the solver will calculate the derivative via finite differences. *

*

* To reject a point, it is allowed to set an element of values to {@link java.lang.Double#NaN} * in the implementation of {@code setValues(RandomVariable[] parameters, RandomVariable[] values)}. * Put differently: The solver handles NaN values in values as an error larger than * the current one (regardless of the current error) and rejects the point. *
* Note, however, that is is an error if the initial parameter guess results in an NaN value. * That is, the solver should be initialized with an initial parameter in an admissible region. *

* * The following simple example finds a solution for the equation
* * * * *
Sample linear system of equations.
* 0.0 * x1 + 1.0 * x2 = 5.0 *
* 2.0 * x1 + 1.0 * x2 = 10.0 *
* *
 * 
 * 	LevenbergMarquardt optimizer = new LevenbergMarquardt() {
 * 		// Override your objective function here
 * 		public void setValues(RandomVariable[] parameters, RandomVariable[] values) {
 * 			values[0] = parameters[0] * 0.0 + parameters[1];
 * 			values[1] = parameters[0] * 2.0 + parameters[1];
 * 		}
 * 	};
 *
 * 	// Set solver parameters
 * 	optimizer.setInitialParameters(new RandomVariable[] { 0, 0 });
 * 	optimizer.setWeights(new RandomVariable[] { 1, 1 });
 * 	optimizer.setMaxIteration(100);
 * 	optimizer.setTargetValues(new RandomVariable[] { 5, 10 });
 *
 * 	optimizer.run();
 *
 * 	RandomVariable[] bestParameters = optimizer.getBestFitParameters();
 * 
 * 
* * See the example in the main method below. * *

* The class can be initialized to use a multi-threaded valuation. If initialized * this way the implementation of setValues must be thread-safe. * The solver will evaluate the gradient of the value vector in parallel, i.e., * use as many threads as the number of parameters. *

* * Note: Iteration steps will be logged (java.util.logging) with LogLevel.FINE * * @author Christian Fries * @version 1.6 */ public abstract class StochasticPathwiseLevenbergMarquardtAD extends net.finmath.optimizer.StochasticPathwiseLevenbergMarquardt { /** * */ private static final long serialVersionUID = -8852002990042152135L; public StochasticPathwiseLevenbergMarquardtAD(final List initialParameters, final List targetValues, final int maxIteration, final ExecutorService executorService) { super(initialParameters, targetValues, maxIteration, executorService); } public StochasticPathwiseLevenbergMarquardtAD(final List initialParameters, final List targetValues, final int maxIteration, final int numberOfThreads) { super(initialParameters, targetValues, maxIteration, numberOfThreads); } public StochasticPathwiseLevenbergMarquardtAD(final RandomVariable[] initialParameters, final RandomVariable[] targetValues, final int maxIteration, final int numberOfThreads) { super(initialParameters, targetValues, maxIteration, numberOfThreads); } public StochasticPathwiseLevenbergMarquardtAD(final RandomVariable[] initialParameters, final RandomVariable[] targetValues, final RandomVariable[] weights, final RandomVariable[] parameterSteps, final int maxIteration, final RandomVariable errorTolerance, final ExecutorService executorService) { super(initialParameters, targetValues, weights, parameterSteps, maxIteration, errorTolerance, executorService); } @Override protected void prepareAndSetValues(final RandomVariable[] parameters, final RandomVariable[] values) throws SolverException { /* * Small modification to avoid growing operator trees. */ for(int i=0; i gradient = ((RandomVariableDifferentiable)values[valueIndex]).getGradient(); for (int parameterIndex = 0; parameterIndex < parameters.length; parameterIndex++) { derivatives[parameterIndex][valueIndex] = gradient.get(((RandomVariableDifferentiable)parameters[parameterIndex]).getID()); } } } else { setDerivatives(parameters, derivatives); } } }




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