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net.finmath.marketdata.calibration.Solver Maven / Gradle / Ivy

/*
 * (c) Copyright Christian P. Fries, Germany. Contact: [email protected].
 *
 * Created on 26.11.2012
 */
package net.finmath.marketdata.calibration;

import java.util.List;
import java.util.Map;
import java.util.Set;
import java.util.Vector;

import net.finmath.marketdata.model.AnalyticModel;
import net.finmath.marketdata.products.AnalyticProduct;
import net.finmath.optimizer.Optimizer;
import net.finmath.optimizer.OptimizerFactory;
import net.finmath.optimizer.OptimizerFactoryLevenbergMarquardt;
import net.finmath.optimizer.SolverException;

/**
 * Generates a calibrated model for a given set
 * of calibrationProducts with respect to given CurveFromInterpolationPointss.
 *
 * The model and the curve are assumed to be immutable, i.e., the solver
 * will return a calibrate clone, containing clones for every curve
 * which is part of the set of curves to be calibrated.
 *
 * The calibration is performed as a multi-threaded global optimization.
 * I will greatly profit from a multi-core architecture.
 *
 * @author Christian Fries
 * @version 1.0
 */
public class Solver {

	private final AnalyticModel			model;
	private final List	calibrationProducts;
	private final List						calibrationTargetValues;
	private final double							calibrationAccuracy;
	private final ParameterTransformation			parameterTransformation;

	private OptimizerFactory			optimizerFactory;

	private	final	double	evaluationTime;
	private final	int		maxIterations	= 1000;

	private 		int		iterations		= 0;
	private 		double	accuracy		= Double.POSITIVE_INFINITY;

	/**
	 * Generate a solver for the given parameter objects (independents) and
	 * objective functions (dependents).
	 *
	 * @param model The model from which a calibrated clone should be created.
	 * @param calibrationProducts The objective functions.
	 * @param calibrationTargetValues Array of target values for the objective functions.
	 * @param parameterTransformation A parameter transformation, if any, otherwise null.
	 * @param evaluationTime Evaluation time applied to the calibration products.
	 * @param optimizerFactory A factory providing the optimizer (for the given objective function)
	 */
	public Solver(final AnalyticModel model, final Vector calibrationProducts, final List calibrationTargetValues, final ParameterTransformation parameterTransformation, final double evaluationTime, final OptimizerFactory optimizerFactory) {
		super();
		this.model = model;
		this.calibrationProducts = calibrationProducts;
		this.calibrationTargetValues = calibrationTargetValues;
		this.parameterTransformation = parameterTransformation;
		this.evaluationTime = evaluationTime;
		this.optimizerFactory = optimizerFactory;
		calibrationAccuracy = 0.0;
	}

	/**
	 * Generate a solver for the given parameter objects (independents) and
	 * objective functions (dependents).
	 *
	 * @param model The model from which a calibrated clone should be created.
	 * @param calibrationProducts The objective functions.
	 * @param calibrationTargetValues Array of target values for the objective functions.
	 * @param parameterTransformation A parameter transformation, if any, otherwise null.
	 * @param evaluationTime Evaluation time applied to the calibration products.
	 * @param calibrationAccuracy The error tolerance of the solver.
	 */
	public Solver(final AnalyticModel model, final Vector calibrationProducts, final List calibrationTargetValues, final ParameterTransformation parameterTransformation, final double evaluationTime, final double calibrationAccuracy) {
		super();
		this.model = model;
		this.calibrationProducts = calibrationProducts;
		this.calibrationTargetValues = calibrationTargetValues;
		this.parameterTransformation = parameterTransformation;
		this.evaluationTime = evaluationTime;
		this.calibrationAccuracy = calibrationAccuracy;
		optimizerFactory = null;
	}

	/**
	 * Generate a solver for the given parameter objects (independents) and
	 * objective functions (dependents).
	 *
	 * @param model The model from which a calibrated clone should be created.
	 * @param calibrationProducts The objective functions.
	 * @param calibrationTargetValues Array of target values for the objective functions.
	 * @param evaluationTime Evaluation time applied to the calibration products.
	 * @param calibrationAccuracy The error tolerance of the solver.
	 */
	public Solver(final AnalyticModel model, final Vector calibrationProducts, final List calibrationTargetValues, final double evaluationTime, final double calibrationAccuracy) {
		this(model, calibrationProducts, calibrationTargetValues, null, evaluationTime, calibrationAccuracy);
	}

	/**
	 * Generate a solver for the given parameter objects (independents) and
	 * objective functions (dependents).
	 *
	 * @param model The model from which a calibrated clone should be created.
	 * @param calibrationProducts The objective functions.
	 * @param evaluationTime Evaluation time applied to the calibration products.
	 * @param calibrationAccuracy The error tolerance of the solver.
	 */
	public Solver(final AnalyticModel model, final Vector calibrationProducts, final double evaluationTime, final double calibrationAccuracy) {
		this(model, calibrationProducts, null, null, evaluationTime, calibrationAccuracy);
	}

	/**
	 * Generate a solver for the given parameter objects (independents) and
	 * objective functions (dependents).
	 *
	 * @param model The model from which a calibrated clone should be created.
	 * @param calibrationProducts The objective functions.
	 */
	public Solver(final AnalyticModel model, final Vector calibrationProducts) {
		this(model, calibrationProducts, 0.0, 0.0);
	}

	/**
	 * Find the model such that the equation
	 * 
	 * objectiveFunctions.getValue(model) = 0
	 * 
	 * holds.
	 *
	 * @param objectsToCalibrate The set of parameterized objects to calibrate.
	 * @return A reference to a calibrated clone of the given model.
	 * @throws net.finmath.optimizer.SolverException Thrown if the underlying optimizer does not find a solution.
	 */
	public AnalyticModel getCalibratedModel(final Set objectsToCalibrate) throws SolverException {
		final ParameterAggregation parameterAggregate = new ParameterAggregation<>(objectsToCalibrate);

		// Set solver parameters
		final double[] initialParameters;

		// Apply parameter transformation to solver parameter space
		if(parameterTransformation != null) {
			initialParameters = parameterTransformation.getSolverParameter(parameterAggregate.getParameter());
		} else {
			initialParameters = parameterAggregate.getParameter();
		}

		final double[] zeros				= new double[calibrationProducts.size()];
		final double[] ones					= new double[calibrationProducts.size()];
		final double[] lowerBound			= new double[initialParameters.length];
		final double[] upperBound			= new double[initialParameters.length];
		java.util.Arrays.fill(zeros, 0.0);
		java.util.Arrays.fill(ones, 1.0);
		java.util.Arrays.fill(lowerBound, Double.NEGATIVE_INFINITY);
		java.util.Arrays.fill(upperBound, Double.POSITIVE_INFINITY);
		final Optimizer.ObjectiveFunction objectiveFunction = new Optimizer.ObjectiveFunction() {
			@Override
			public void setValues(final double[] parameters, final double[] values) throws SolverException {
				double[] modelParameters = parameters;
				try {
					if(parameterTransformation != null) {
						modelParameters = parameterTransformation.getParameter(parameters);
						// Copy back the parameter constrain to inform the optimizer
						System.arraycopy(parameterTransformation.getSolverParameter(modelParameters), 0, parameters, 0, parameters.length);
					}

					final Map curvesParameterPairs = parameterAggregate.getObjectsToModifyForParameter(modelParameters);
					final AnalyticModel modelClone = model.getCloneForParameter(curvesParameterPairs);
					for(int i=0; i curvesParameterPairs = parameterAggregate.getObjectsToModifyForParameter(bestParameters);
			calibratedModel = model.getCloneForParameter(curvesParameterPairs);
		} catch (final CloneNotSupportedException e) {
			throw new SolverException(e);
		}

		accuracy = 0.0;
		for(int i=0; i




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