Gamma (patrius 4.0 API)

java.lang.Object
- fr.cnes.sirius.patrius.math.special.Gamma

```
public final class Gamma
extends Object
```
This is a utility class that provides computation methods related to the Γ (Gamma) family of functions.

Implementation of invGamma1pm1(double) and logGamma1p(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.
Version:

$Id: Gamma.java 18108 2017-10-04 06:45:27Z bignon $

Field Summary

Fields
Modifier and Type	Field and Description
`static double`	`GAMMA` Euler-Mascheroni constant
`static double`	`LANCZOS_G` The value of the `g` constant in the Lanczos approximation, see `lanczos(double)`.

Method Summary

Methods
Modifier and Type	Method and Description
`static double`	`digamma(double x)` Computes the digamma function of x.
`static double`	`gamma(double x)` Returns the value of Γ(x).
`static double`	`invGamma1pm1(double x)` Returns the value of 1 / Γ(1 + x) - 1 for -0.5 ≤ x ≤ 1.5.
`static double`	`lanczos(double x)` Returns the Lanczos approximation used to compute the gamma function.
`static double`	`logGamma(double x)` Returns the value of log Γ(x) for x > 0.
`static double`	`logGamma1p(double x)` Returns the value of log Γ(1 + x) for -0.5 ≤ x ≤ 1.5.
`static double`	`regularizedGammaP(double a, double x)` Returns the regularized gamma function P(a, x).
`static double`	`regularizedGammaP(double a, double x, double epsilon, int maxIterations)` Returns the regularized gamma function P(a, x).
`static double`	`regularizedGammaQ(double a, double x)` Returns the regularized gamma function Q(a, x) = 1 - P(a, x).
`static double`	`regularizedGammaQ(double a, double x, double epsilon, int maxIterations)` Returns the regularized gamma function Q(a, x) = 1 - P(a, x).
`static double`	`trigamma(double x)` Computes the trigamma function of x.

Methods inherited from class java.lang.Object
clone, equals, finalize, getClass, hashCode, notify, notifyAll, toString, wait, wait, wait

- Field Detail
  - GAMMA
```
public static final double GAMMA
```
    Euler-Mascheroni constant
    
    Since:
    
    2.0
    
    See Also:
    Constant Field Values
  - LANCZOS_G
```
public static final double LANCZOS_G
```
    The value of the g constant in the Lanczos approximation, see lanczos(double).
    
    Since:
    
    3.1
    
    See Also:
    Constant Field Values
- Method Detail
  - logGamma
```
public static double logGamma(double x)
```
    Returns the value of log Γ(x) for x > 0.
    
    For x ≤ 8, the implementation is based on the double precision implementation in the NSWC Library of Mathematics Subroutines, DGAMLN. For x > 8, the implementation is based on
    - Gamma Function, equation (28).
    - Lanczos Approximation, equations (1) through (5).
    - Paul Godfrey, A note on the computation of the convergent Lanczos complex Gamma approximation
    Parameters:
    x - Argument.
    
    Returns:
    the value of log(Gamma(x)), Double.NaN if x <= 0.0.
  - regularizedGammaP
```
public static double regularizedGammaP(double a,
                       double x)
```
    Returns the regularized gamma function P(a, x).
    
    Parameters:
    a - Parameter.
    x - Value.
    
    Returns:
    the regularized gamma function P(a, x).
    
    Throws:
    
    MaxCountExceededException - if the algorithm fails to converge.
  - regularizedGammaP
```
public static double regularizedGammaP(double a,
                       double x,
                       double epsilon,
                       int maxIterations)
```
    Returns the regularized gamma function P(a, x). The implementation of this method is based on:
    - Regularized Gamma Function, equation (1)
    - Incomplete Gamma Function, equation (4).
    - Confluent Hypergeometric Function of the First Kind, equation (1).
    Parameters:
    a - the a parameter.
    x - the value.
    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.
    maxIterations - Maximum number of "iterations" to complete.
    
    Returns:
    the regularized gamma function P(a, x)
    
    Throws:
    
    MaxCountExceededException - if the algorithm fails to converge.
  - regularizedGammaQ
```
public static double regularizedGammaQ(double a,
                       double x)
```
    Returns the regularized gamma function Q(a, x) = 1 - P(a, x).
    
    Parameters:
    a - the a parameter.
    x - the value.
    
    Returns:
    the regularized gamma function Q(a, x)
    
    Throws:
    
    MaxCountExceededException - if the algorithm fails to converge.
  - regularizedGammaQ
```
public static double regularizedGammaQ(double a,
                       double x,
                       double epsilon,
                       int maxIterations)
```
    Returns the regularized gamma function Q(a, x) = 1 - P(a, x). The implementation of this method is based on:
    - Regularized Gamma Function, equation (1).
    - Regularized incomplete gamma function: Continued fraction representations (formula 06.08.10.0003)
    Parameters:
    a - the a parameter.
    x - the value.
    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.
    maxIterations - Maximum number of "iterations" to complete.
    
    Returns:
    the regularized gamma function P(a, x)
    
    Throws:
    
    MaxCountExceededException - if the algorithm fails to converge.
  - digamma
```
public static double digamma(double x)
```
    Computes the digamma function of x.
    
    This is an independently written implementation of the algorithm described in Jose Bernardo, Algorithm AS 103: Psi (Digamma) Function, Applied Statistics, 1976.
    
    Some of the constants have been changed to increase accuracy at the moderate expense of run-time. The result should be accurate to within 10^-8 absolute tolerance for x >= 10^-5 and within 10^-8 relative tolerance for x > 0.
    
    Performance for large negative values of x will be quite expensive (proportional to |x|). Accuracy for negative values of x should be about 10^-8 absolute for results less than 10^5 and 10^-8 relative for results larger than that.
    
    Parameters:
    x - Argument.
    
    Returns:
    digamma(x) to within 10-8 relative or absolute error whichever is smaller.
    Since:
    
    2.0
    
    See Also:
    Digamma, Bernardo's original article
  - trigamma
```
public static double trigamma(double x)
```
    Computes the trigamma function of x. This function is derived by taking the derivative of the implementation of digamma.
    
    Parameters:
    x - Argument.
    
    Returns:
    trigamma(x) to within 10-8 relative or absolute error whichever is smaller
    Since:
    
    2.0
    
    See Also:
    Trigamma, digamma(double)
  - lanczos
```
public static double lanczos(double x)
```
    Returns the Lanczos approximation used to compute the gamma function. The Lanczos approximation is related to the Gamma function by the following equation
    gamma(x) = sqrt(2 * pi) / x * (x + g + 0.5) ^ (x + 0.5) * exp(-x - g - 0.5) * lanczos(x), where g is the Lanczos constant.
    
    Parameters:
    x - Argument.
    
    Returns:
    The Lanczos approximation.
    Since:
    
    3.1
    
    See Also:
    Lanczos Approximation equations (1) through (5), and Paul Godfrey's Note on the computation of the convergent Lanczos complex Gamma approximation
  - invGamma1pm1
```
public static double invGamma1pm1(double x)
```
    Returns the value of 1 / Γ(1 + x) - 1 for -0.5 ≤ x ≤ 1.5. This implementation is based on the double precision implementation in the NSWC Library of Mathematics Subroutines, DGAM1.
    
    Parameters:
    x - Argument.
    
    Returns:
    The value of 1.0 / Gamma(1.0 + x) - 1.0.
    
    Throws:
    
    NumberIsTooSmallException - if x < -0.5
    
    NumberIsTooLargeException - if x > 1.5
    Since:
    
    3.1
  - logGamma1p
```
public static double logGamma1p(double x)
```
    Returns the value of log Γ(1 + x) for -0.5 ≤ x ≤ 1.5. This implementation is based on the double precision implementation in the NSWC Library of Mathematics Subroutines, DGMLN1.
    
    Parameters:
    x - Argument.
    
    Returns:
    The value of log(Gamma(1 + x)).
    
    Throws:
    
    NumberIsTooSmallException - if x < -0.5.
    
    NumberIsTooLargeException - if x > 1.5.
    Since:
    
    3.1
  - gamma
```
public static double gamma(double x)
```
    Returns the value of Γ(x). Based on the NSWC Library of Mathematics Subroutines double precision implementation, DGAMMA.
    
    Parameters:
    x - Argument.
    
    Returns:
    the value of Gamma(x).
    Since:
    
    3.1

Class Gamma

Field Summary

Method Summary

Methods inherited from class java.lang.Object

Field Detail

GAMMA

LANCZOS_G

Method Detail

logGamma

regularizedGammaP

regularizedGammaP

regularizedGammaQ

regularizedGammaQ

digamma

trigamma

lanczos

invGamma1pm1

logGamma1p

gamma