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package org.apache.commons.math3.fitting;

import org.apache.commons.math3.analysis.polynomials.PolynomialFunction;
import org.apache.commons.math3.optim.nonlinear.vector.MultivariateVectorOptimizer;

Polynomial fitting is a very simple case of curve fitting. The estimated coefficients are the polynomial coefficients (see the fit method).
Since:2.0
Deprecated:As of 3.3. Please use PolynomialCurveFitter and WeightedObservedPoints instead.
/** * Polynomial fitting is a very simple case of {@link CurveFitter curve fitting}. * The estimated coefficients are the polynomial coefficients (see the * {@link #fit(double[]) fit} method). * * @since 2.0 * @deprecated As of 3.3. Please use {@link PolynomialCurveFitter} and * {@link WeightedObservedPoints} instead. */
@Deprecated public class PolynomialFitter extends CurveFitter<PolynomialFunction.Parametric> {
Simple constructor.
Params:
  • optimizer – Optimizer to use for the fitting.
/** * Simple constructor. * * @param optimizer Optimizer to use for the fitting. */
public PolynomialFitter(MultivariateVectorOptimizer optimizer) { super(optimizer); }
Get the coefficients of the polynomial fitting the weighted data points. The degree of the fitting polynomial is guess.length - 1.
Params:
  • guess – First guess for the coefficients. They must be sorted in increasing order of the polynomial's degree.
  • maxEval – Maximum number of evaluations of the polynomial.
Throws:
Returns:the coefficients of the polynomial that best fits the observed points.
/** * Get the coefficients of the polynomial fitting the weighted data points. * The degree of the fitting polynomial is {@code guess.length - 1}. * * @param guess First guess for the coefficients. They must be sorted in * increasing order of the polynomial's degree. * @param maxEval Maximum number of evaluations of the polynomial. * @return the coefficients of the polynomial that best fits the observed points. * @throws org.apache.commons.math3.exception.TooManyEvaluationsException if * the number of evaluations exceeds {@code maxEval}. * @throws org.apache.commons.math3.exception.ConvergenceException * if the algorithm failed to converge. */
public double[] fit(int maxEval, double[] guess) { return fit(maxEval, new PolynomialFunction.Parametric(), guess); }
Get the coefficients of the polynomial fitting the weighted data points. The degree of the fitting polynomial is guess.length - 1.
Params:
  • guess – First guess for the coefficients. They must be sorted in increasing order of the polynomial's degree.
Throws:
Returns:the coefficients of the polynomial that best fits the observed points.
/** * Get the coefficients of the polynomial fitting the weighted data points. * The degree of the fitting polynomial is {@code guess.length - 1}. * * @param guess First guess for the coefficients. They must be sorted in * increasing order of the polynomial's degree. * @return the coefficients of the polynomial that best fits the observed points. * @throws org.apache.commons.math3.exception.ConvergenceException * if the algorithm failed to converge. */
public double[] fit(double[] guess) { return fit(new PolynomialFunction.Parametric(), guess); } }