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package org.apache.commons.math.optimization;

import org.apache.commons.math.analysis.DifferentiableMultivariateVectorialFunction;
import org.apache.commons.math.FunctionEvaluationException;

/**
 * This interface represents an optimization algorithm for {@link DifferentiableMultivariateVectorialFunction
 * vectorial differentiable objective functions}.
 * 

Optimization algorithms find the input point set that either {@link GoalType * maximize or minimize} an objective function.

* @see MultivariateRealOptimizer * @see DifferentiableMultivariateRealOptimizer * @version $Revision: 1073158 $ $Date: 2011-02-21 22:46:52 +0100 (lun. 21 févr. 2011) $ * @since 2.0 */ public interface DifferentiableMultivariateVectorialOptimizer { /** Set the maximal number of iterations of the algorithm. * @param maxIterations maximal number of function calls * . */ void setMaxIterations(int maxIterations); /** Get the maximal number of iterations of the algorithm. * @return maximal number of iterations */ int getMaxIterations(); /** Get the number of iterations realized by the algorithm. * @return number of iterations */ int getIterations(); /** Set the maximal number of functions evaluations. * @param maxEvaluations maximal number of function evaluations */ void setMaxEvaluations(int maxEvaluations); /** Get the maximal number of functions evaluations. * @return maximal number of functions evaluations */ int getMaxEvaluations(); /** Get the number of evaluations of the objective function. *

* The number of evaluation correspond to the last call to the * {@link #optimize(DifferentiableMultivariateVectorialFunction, * double[], double[], double[]) optimize} method. It is 0 if * the method has not been called yet. *

* @return number of evaluations of the objective function */ int getEvaluations(); /** Get the number of evaluations of the objective function jacobian . *

* The number of evaluation correspond to the last call to the * {@link #optimize(DifferentiableMultivariateVectorialFunction, * double[], double[], double[]) optimize} method. It is 0 if * the method has not been called yet. *

* @return number of evaluations of the objective function jacobian */ int getJacobianEvaluations(); /** Set the convergence checker. * @param checker object to use to check for convergence */ void setConvergenceChecker(VectorialConvergenceChecker checker); /** Get the convergence checker. * @return object used to check for convergence */ VectorialConvergenceChecker getConvergenceChecker(); /** Optimizes an objective function. *

* Optimization is considered to be a weighted least-squares minimization. * The cost function to be minimized is * ∑weighti(objectivei-targeti)2 *

* @param f objective function * @param target target value for the objective functions at optimum * @param weights weight for the least squares cost computation * @param startPoint the start point for optimization * @return the point/value pair giving the optimal value for objective function * @exception FunctionEvaluationException if the objective function throws one during * the search * @exception OptimizationException if the algorithm failed to converge * @exception IllegalArgumentException if the start point dimension is wrong */ VectorialPointValuePair optimize(DifferentiableMultivariateVectorialFunction f, double[] target, double[] weights, double[] startPoint) throws FunctionEvaluationException, OptimizationException, IllegalArgumentException; }




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