org.apache.commons.math3.special.Beta Maven / Gradle / Ivy
Go to download
Show more of this group Show more artifacts with this name
Show all versions of virtdata-lib-realer Show documentation
Show all versions of virtdata-lib-realer Show documentation
With inspiration from other libraries
/*
* 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.special;
import org.apache.commons.math3.exception.NumberIsTooSmallException;
import org.apache.commons.math3.exception.OutOfRangeException;
import org.apache.commons.math3.util.ContinuedFraction;
import org.apache.commons.math3.util.FastMath;
/**
*
* This is a utility class that provides computation methods related to the
* Beta family of functions.
*
*
* Implementation of {@link #logBeta(double, double)} is based on the
* algorithms described in
*
* - Didonato and Morris
* (1986), Computation of the Incomplete Gamma Function Ratios
* and their Inverse, TOMS 12(4), 377-393,
* - Didonato and Morris
* (1992), Algorithm 708: Significant Digit Computation of the
* Incomplete Beta Function Ratios, TOMS 18(3), 360-373,
*
* and implemented in the
* NSWC Library of Mathematical Functions,
* available
* here.
* This library is "approved for public release", and the
* Copyright guidance
* indicates that unless otherwise stated in the code, all FORTRAN functions in
* this library are license free. Since no such notice appears in the code these
* functions can safely be ported to Commons-Math.
*
*
*
*/
public class Beta {
/** Maximum allowed numerical error. */
private static final double DEFAULT_EPSILON = 1E-14;
/** The constant value of ½log 2π. */
private static final double HALF_LOG_TWO_PI = .9189385332046727;
/**
*
* The coefficients of the series expansion of the Δ function. This function
* is defined as follows
*
* Δ(x) = log Γ(x) - (x - 0.5) log a + a - 0.5 log 2π,
*
* see equation (23) in Didonato and Morris (1992). The series expansion,
* which applies for x ≥ 10, reads
*
*
* 14
* ====
* 1 \ 2 n
* Δ(x) = --- > d (10 / x)
* x / n
* ====
* n = 0
*
*/
private static final double[] DELTA = {
.833333333333333333333333333333E-01,
-.277777777777777777777777752282E-04,
.793650793650793650791732130419E-07,
-.595238095238095232389839236182E-09,
.841750841750832853294451671990E-11,
-.191752691751854612334149171243E-12,
.641025640510325475730918472625E-14,
-.295506514125338232839867823991E-15,
.179643716359402238723287696452E-16,
-.139228964661627791231203060395E-17,
.133802855014020915603275339093E-18,
-.154246009867966094273710216533E-19,
.197701992980957427278370133333E-20,
-.234065664793997056856992426667E-21,
.171348014966398575409015466667E-22
};
/**
* Default constructor. Prohibit instantiation.
*/
private Beta() {}
/**
* Returns the
*
* regularized beta function I(x, a, b).
*
* @param x Value.
* @param a Parameter {@code a}.
* @param b Parameter {@code b}.
* @return the regularized beta function I(x, a, b).
* @throws org.apache.commons.math3.exception.MaxCountExceededException
* if the algorithm fails to converge.
*/
public static double regularizedBeta(double x, double a, double b) {
return regularizedBeta(x, a, b, DEFAULT_EPSILON, Integer.MAX_VALUE);
}
/**
* Returns the
*
* regularized beta function I(x, a, b).
*
* @param x Value.
* @param a Parameter {@code a}.
* @param b Parameter {@code b}.
* @param epsilon When the absolute value of the nth item in the
* series is less than epsilon the approximation ceases to calculate
* further elements in the series.
* @return the regularized beta function I(x, a, b)
* @throws org.apache.commons.math3.exception.MaxCountExceededException
* if the algorithm fails to converge.
*/
public static double regularizedBeta(double x,
double a, double b,
double epsilon) {
return regularizedBeta(x, a, b, epsilon, Integer.MAX_VALUE);
}
/**
* Returns the regularized beta function I(x, a, b).
*
* @param x the value.
* @param a Parameter {@code a}.
* @param b Parameter {@code b}.
* @param maxIterations Maximum number of "iterations" to complete.
* @return the regularized beta function I(x, a, b)
* @throws org.apache.commons.math3.exception.MaxCountExceededException
* if the algorithm fails to converge.
*/
public static double regularizedBeta(double x,
double a, double b,
int maxIterations) {
return regularizedBeta(x, a, b, DEFAULT_EPSILON, maxIterations);
}
/**
* Returns the regularized beta function I(x, a, b).
*
* The implementation of this method is based on:
*
*
* @param x the value.
* @param a Parameter {@code a}.
* @param b Parameter {@code b}.
* @param epsilon When the absolute value of the nth item in the
* series is less than epsilon the approximation ceases to calculate
* further elements in the series.
* @param maxIterations Maximum number of "iterations" to complete.
* @return the regularized beta function I(x, a, b)
* @throws org.apache.commons.math3.exception.MaxCountExceededException
* if the algorithm fails to converge.
*/
public static double regularizedBeta(double x,
final double a, final double b,
double epsilon, int maxIterations) {
double ret;
if (Double.isNaN(x) ||
Double.isNaN(a) ||
Double.isNaN(b) ||
x < 0 ||
x > 1 ||
a <= 0 ||
b <= 0) {
ret = Double.NaN;
} else if (x > (a + 1) / (2 + b + a) &&
1 - x <= (b + 1) / (2 + b + a)) {
ret = 1 - regularizedBeta(1 - x, b, a, epsilon, maxIterations);
} else {
ContinuedFraction fraction = new ContinuedFraction() {
/** {@inheritDoc} */
@Override
protected double getB(int n, double x) {
double ret;
double m;
if (n % 2 == 0) { // even
m = n / 2.0;
ret = (m * (b - m) * x) /
((a + (2 * m) - 1) * (a + (2 * m)));
} else {
m = (n - 1.0) / 2.0;
ret = -((a + m) * (a + b + m) * x) /
((a + (2 * m)) * (a + (2 * m) + 1.0));
}
return ret;
}
/** {@inheritDoc} */
@Override
protected double getA(int n, double x) {
return 1.0;
}
};
ret = FastMath.exp((a * FastMath.log(x)) + (b * FastMath.log1p(-x)) -
FastMath.log(a) - logBeta(a, b)) *
1.0 / fraction.evaluate(x, epsilon, maxIterations);
}
return ret;
}
/**
* Returns the natural logarithm of the beta function B(a, b).
*
* The implementation of this method is based on:
*
* -
* Beta Function, equation (1).
*
*
* @param a Parameter {@code a}.
* @param b Parameter {@code b}.
* @param epsilon This parameter is ignored.
* @param maxIterations This parameter is ignored.
* @return log(B(a, b)).
* @deprecated as of version 3.1, this method is deprecated as the
* computation of the beta function is no longer iterative; it will be
* removed in version 4.0. Current implementation of this method
* internally calls {@link #logBeta(double, double)}.
*/
@Deprecated
public static double logBeta(double a, double b,
double epsilon,
int maxIterations) {
return logBeta(a, b);
}
/**
* Returns the value of log Γ(a + b) for 1 ≤ a, b ≤ 2. Based on the
* NSWC Library of Mathematics Subroutines double precision
* implementation, {@code DGSMLN}. In {@code BetaTest.testLogGammaSum()},
* this private method is accessed through reflection.
*
* @param a First argument.
* @param b Second argument.
* @return the value of {@code log(Gamma(a + b))}.
* @throws OutOfRangeException if {@code a} or {@code b} is lower than
* {@code 1.0} or greater than {@code 2.0}.
*/
private static double logGammaSum(final double a, final double b)
throws OutOfRangeException {
if ((a < 1.0) || (a > 2.0)) {
throw new OutOfRangeException(a, 1.0, 2.0);
}
if ((b < 1.0) || (b > 2.0)) {
throw new OutOfRangeException(b, 1.0, 2.0);
}
final double x = (a - 1.0) + (b - 1.0);
if (x <= 0.5) {
return Gamma.logGamma1p(1.0 + x);
} else if (x <= 1.5) {
return Gamma.logGamma1p(x) + FastMath.log1p(x);
} else {
return Gamma.logGamma1p(x - 1.0) + FastMath.log(x * (1.0 + x));
}
}
/**
* Returns the value of log[Γ(b) / Γ(a + b)] for a ≥ 0 and b ≥ 10. Based on
* the NSWC Library of Mathematics Subroutines double precision
* implementation, {@code DLGDIV}. In
* {@code BetaTest.testLogGammaMinusLogGammaSum()}, this private method is
* accessed through reflection.
*
* @param a First argument.
* @param b Second argument.
* @return the value of {@code log(Gamma(b) / Gamma(a + b))}.
* @throws NumberIsTooSmallException if {@code a < 0.0} or {@code b < 10.0}.
*/
private static double logGammaMinusLogGammaSum(final double a,
final double b)
throws NumberIsTooSmallException {
if (a < 0.0) {
throw new NumberIsTooSmallException(a, 0.0, true);
}
if (b < 10.0) {
throw new NumberIsTooSmallException(b, 10.0, true);
}
/*
* d = a + b - 0.5
*/
final double d;
final double w;
if (a <= b) {
d = b + (a - 0.5);
w = deltaMinusDeltaSum(a, b);
} else {
d = a + (b - 0.5);
w = deltaMinusDeltaSum(b, a);
}
final double u = d * FastMath.log1p(a / b);
final double v = a * (FastMath.log(b) - 1.0);
return u <= v ? (w - u) - v : (w - v) - u;
}
/**
* Returns the value of Δ(b) - Δ(a + b), with 0 ≤ a ≤ b and b ≥ 10. Based
* on equations (26), (27) and (28) in Didonato and Morris (1992).
*
* @param a First argument.
* @param b Second argument.
* @return the value of {@code Delta(b) - Delta(a + b)}
* @throws OutOfRangeException if {@code a < 0} or {@code a > b}
* @throws NumberIsTooSmallException if {@code b < 10}
*/
private static double deltaMinusDeltaSum(final double a,
final double b)
throws OutOfRangeException, NumberIsTooSmallException {
if ((a < 0) || (a > b)) {
throw new OutOfRangeException(a, 0, b);
}
if (b < 10) {
throw new NumberIsTooSmallException(b, 10, true);
}
final double h = a / b;
final double p = h / (1.0 + h);
final double q = 1.0 / (1.0 + h);
final double q2 = q * q;
/*
* s[i] = 1 + q + ... - q**(2 * i)
*/
final double[] s = new double[DELTA.length];
s[0] = 1.0;
for (int i = 1; i < s.length; i++) {
s[i] = 1.0 + (q + q2 * s[i - 1]);
}
/*
* w = Delta(b) - Delta(a + b)
*/
final double sqrtT = 10.0 / b;
final double t = sqrtT * sqrtT;
double w = DELTA[DELTA.length - 1] * s[s.length - 1];
for (int i = DELTA.length - 2; i >= 0; i--) {
w = t * w + DELTA[i] * s[i];
}
return w * p / b;
}
/**
* Returns the value of Δ(p) + Δ(q) - Δ(p + q), with p, q ≥ 10. Based on
* the NSWC Library of Mathematics Subroutines double precision
* implementation, {@code DBCORR}. In
* {@code BetaTest.testSumDeltaMinusDeltaSum()}, this private method is
* accessed through reflection.
*
* @param p First argument.
* @param q Second argument.
* @return the value of {@code Delta(p) + Delta(q) - Delta(p + q)}.
* @throws NumberIsTooSmallException if {@code p < 10.0} or {@code q < 10.0}.
*/
private static double sumDeltaMinusDeltaSum(final double p,
final double q) {
if (p < 10.0) {
throw new NumberIsTooSmallException(p, 10.0, true);
}
if (q < 10.0) {
throw new NumberIsTooSmallException(q, 10.0, true);
}
final double a = FastMath.min(p, q);
final double b = FastMath.max(p, q);
final double sqrtT = 10.0 / a;
final double t = sqrtT * sqrtT;
double z = DELTA[DELTA.length - 1];
for (int i = DELTA.length - 2; i >= 0; i--) {
z = t * z + DELTA[i];
}
return z / a + deltaMinusDeltaSum(a, b);
}
/**
* Returns the value of log B(p, q) for 0 ≤ x ≤ 1 and p, q > 0. Based on the
* NSWC Library of Mathematics Subroutines implementation,
* {@code DBETLN}.
*
* @param p First argument.
* @param q Second argument.
* @return the value of {@code log(Beta(p, q))}, {@code NaN} if
* {@code p <= 0} or {@code q <= 0}.
*/
public static double logBeta(final double p, final double q) {
if (Double.isNaN(p) || Double.isNaN(q) || (p <= 0.0) || (q <= 0.0)) {
return Double.NaN;
}
final double a = FastMath.min(p, q);
final double b = FastMath.max(p, q);
if (a >= 10.0) {
final double w = sumDeltaMinusDeltaSum(a, b);
final double h = a / b;
final double c = h / (1.0 + h);
final double u = -(a - 0.5) * FastMath.log(c);
final double v = b * FastMath.log1p(h);
if (u <= v) {
return (((-0.5 * FastMath.log(b) + HALF_LOG_TWO_PI) + w) - u) - v;
} else {
return (((-0.5 * FastMath.log(b) + HALF_LOG_TWO_PI) + w) - v) - u;
}
} else if (a > 2.0) {
if (b > 1000.0) {
final int n = (int) FastMath.floor(a - 1.0);
double prod = 1.0;
double ared = a;
for (int i = 0; i < n; i++) {
ared -= 1.0;
prod *= ared / (1.0 + ared / b);
}
return (FastMath.log(prod) - n * FastMath.log(b)) +
(Gamma.logGamma(ared) +
logGammaMinusLogGammaSum(ared, b));
} else {
double prod1 = 1.0;
double ared = a;
while (ared > 2.0) {
ared -= 1.0;
final double h = ared / b;
prod1 *= h / (1.0 + h);
}
if (b < 10.0) {
double prod2 = 1.0;
double bred = b;
while (bred > 2.0) {
bred -= 1.0;
prod2 *= bred / (ared + bred);
}
return FastMath.log(prod1) +
FastMath.log(prod2) +
(Gamma.logGamma(ared) +
(Gamma.logGamma(bred) -
logGammaSum(ared, bred)));
} else {
return FastMath.log(prod1) +
Gamma.logGamma(ared) +
logGammaMinusLogGammaSum(ared, b);
}
}
} else if (a >= 1.0) {
if (b > 2.0) {
if (b < 10.0) {
double prod = 1.0;
double bred = b;
while (bred > 2.0) {
bred -= 1.0;
prod *= bred / (a + bred);
}
return FastMath.log(prod) +
(Gamma.logGamma(a) +
(Gamma.logGamma(bred) -
logGammaSum(a, bred)));
} else {
return Gamma.logGamma(a) +
logGammaMinusLogGammaSum(a, b);
}
} else {
return Gamma.logGamma(a) +
Gamma.logGamma(b) -
logGammaSum(a, b);
}
} else {
if (b >= 10.0) {
return Gamma.logGamma(a) +
logGammaMinusLogGammaSum(a, b);
} else {
// The following command is the original NSWC implementation.
// return Gamma.logGamma(a) +
// (Gamma.logGamma(b) - Gamma.logGamma(a + b));
// The following command turns out to be more accurate.
return FastMath.log(Gamma.gamma(a) * Gamma.gamma(b) /
Gamma.gamma(a + b));
}
}
}
}