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The Apache Commons Math project is a library of lightweight, self-contained mathematics and statistics components addressing the most common practical problems not immediately available in the Java programming language or commons-lang.

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/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
package org.apache.commons.math3.optimization.univariate;

import org.apache.commons.math3.util.Precision;
import org.apache.commons.math3.util.FastMath;
import org.apache.commons.math3.exception.NumberIsTooSmallException;
import org.apache.commons.math3.exception.NotStrictlyPositiveException;
import org.apache.commons.math3.optimization.ConvergenceChecker;
import org.apache.commons.math3.optimization.GoalType;

/**
 * For a function defined on some interval {@code (lo, hi)}, this class
 * finds an approximation {@code x} to the point at which the function
 * attains its minimum.
 * It implements Richard Brent's algorithm (from his book "Algorithms for
 * Minimization without Derivatives", p. 79) for finding minima of real
 * univariate functions.
 * 
* This code is an adaptation, partly based on the Python code from SciPy * (module "optimize.py" v0.5); the original algorithm is also modified *
    *
  • to use an initial guess provided by the user,
  • *
  • to ensure that the best point encountered is the one returned.
  • *
* * @deprecated As of 3.1 (to be removed in 4.0). * @since 2.0 */ @Deprecated public class BrentOptimizer extends BaseAbstractUnivariateOptimizer { /** * Golden section. */ private static final double GOLDEN_SECTION = 0.5 * (3 - FastMath.sqrt(5)); /** * Minimum relative tolerance. */ private static final double MIN_RELATIVE_TOLERANCE = 2 * FastMath.ulp(1d); /** * Relative threshold. */ private final double relativeThreshold; /** * Absolute threshold. */ private final double absoluteThreshold; /** * The arguments are used implement the original stopping criterion * of Brent's algorithm. * {@code abs} and {@code rel} define a tolerance * {@code tol = rel |x| + abs}. {@code rel} should be no smaller than * 2 macheps and preferably not much less than sqrt(macheps), * where macheps is the relative machine precision. {@code abs} must * be positive. * * @param rel Relative threshold. * @param abs Absolute threshold. * @param checker Additional, user-defined, convergence checking * procedure. * @throws NotStrictlyPositiveException if {@code abs <= 0}. * @throws NumberIsTooSmallException if {@code rel < 2 * Math.ulp(1d)}. */ public BrentOptimizer(double rel, double abs, ConvergenceChecker checker) { super(checker); if (rel < MIN_RELATIVE_TOLERANCE) { throw new NumberIsTooSmallException(rel, MIN_RELATIVE_TOLERANCE, true); } if (abs <= 0) { throw new NotStrictlyPositiveException(abs); } relativeThreshold = rel; absoluteThreshold = abs; } /** * The arguments are used for implementing the original stopping criterion * of Brent's algorithm. * {@code abs} and {@code rel} define a tolerance * {@code tol = rel |x| + abs}. {@code rel} should be no smaller than * 2 macheps and preferably not much less than sqrt(macheps), * where macheps is the relative machine precision. {@code abs} must * be positive. * * @param rel Relative threshold. * @param abs Absolute threshold. * @throws NotStrictlyPositiveException if {@code abs <= 0}. * @throws NumberIsTooSmallException if {@code rel < 2 * Math.ulp(1d)}. */ public BrentOptimizer(double rel, double abs) { this(rel, abs, null); } /** {@inheritDoc} */ @Override protected UnivariatePointValuePair doOptimize() { final boolean isMinim = getGoalType() == GoalType.MINIMIZE; final double lo = getMin(); final double mid = getStartValue(); final double hi = getMax(); // Optional additional convergence criteria. final ConvergenceChecker checker = getConvergenceChecker(); double a; double b; if (lo < hi) { a = lo; b = hi; } else { a = hi; b = lo; } double x = mid; double v = x; double w = x; double d = 0; double e = 0; double fx = computeObjectiveValue(x); if (!isMinim) { fx = -fx; } double fv = fx; double fw = fx; UnivariatePointValuePair previous = null; UnivariatePointValuePair current = new UnivariatePointValuePair(x, isMinim ? fx : -fx); // Best point encountered so far (which is the initial guess). UnivariatePointValuePair best = current; int iter = 0; while (true) { final double m = 0.5 * (a + b); final double tol1 = relativeThreshold * FastMath.abs(x) + absoluteThreshold; final double tol2 = 2 * tol1; // Default stopping criterion. final boolean stop = FastMath.abs(x - m) <= tol2 - 0.5 * (b - a); if (!stop) { double p = 0; double q = 0; double r = 0; double u = 0; if (FastMath.abs(e) > tol1) { // Fit parabola. r = (x - w) * (fx - fv); q = (x - v) * (fx - fw); p = (x - v) * q - (x - w) * r; q = 2 * (q - r); if (q > 0) { p = -p; } else { q = -q; } r = e; e = d; if (p > q * (a - x) && p < q * (b - x) && FastMath.abs(p) < FastMath.abs(0.5 * q * r)) { // Parabolic interpolation step. d = p / q; u = x + d; // f must not be evaluated too close to a or b. if (u - a < tol2 || b - u < tol2) { if (x <= m) { d = tol1; } else { d = -tol1; } } } else { // Golden section step. if (x < m) { e = b - x; } else { e = a - x; } d = GOLDEN_SECTION * e; } } else { // Golden section step. if (x < m) { e = b - x; } else { e = a - x; } d = GOLDEN_SECTION * e; } // Update by at least "tol1". if (FastMath.abs(d) < tol1) { if (d >= 0) { u = x + tol1; } else { u = x - tol1; } } else { u = x + d; } double fu = computeObjectiveValue(u); if (!isMinim) { fu = -fu; } // User-defined convergence checker. previous = current; current = new UnivariatePointValuePair(u, isMinim ? fu : -fu); best = best(best, best(previous, current, isMinim), isMinim); if (checker != null && checker.converged(iter, previous, current)) { return best; } // Update a, b, v, w and x. if (fu <= fx) { if (u < x) { b = x; } else { a = x; } v = w; fv = fw; w = x; fw = fx; x = u; fx = fu; } else { if (u < x) { a = u; } else { b = u; } if (fu <= fw || Precision.equals(w, x)) { v = w; fv = fw; w = u; fw = fu; } else if (fu <= fv || Precision.equals(v, x) || Precision.equals(v, w)) { v = u; fv = fu; } } } else { // Default termination (Brent's criterion). return best(best, best(previous, current, isMinim), isMinim); } ++iter; } } /** * Selects the best of two points. * * @param a Point and value. * @param b Point and value. * @param isMinim {@code true} if the selected point must be the one with * the lowest value. * @return the best point, or {@code null} if {@code a} and {@code b} are * both {@code null}. When {@code a} and {@code b} have the same function * value, {@code a} is returned. */ private UnivariatePointValuePair best(UnivariatePointValuePair a, UnivariatePointValuePair b, boolean isMinim) { if (a == null) { return b; } if (b == null) { return a; } if (isMinim) { return a.getValue() <= b.getValue() ? a : b; } else { return a.getValue() >= b.getValue() ? a : b; } } }




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