boost_1_45_0/libs/math/doc/sf_and_dist/distributions/nc_beta.qbk - nest-learning-thermostat/5.0/boost - Git at Google

 [section:nc_beta_dist Noncentral Beta Distribution]

 ``#include <boost/math/distributions/non_central_beta.hpp>``

    namespace boost{ namespace math{

    template <class RealType = double,
              class ``__Policy``   = ``__policy_class`` >
    class non_central_beta_distribution;

    typedef non_central_beta_distribution<> non_central_beta;

    template <class RealType, class ``__Policy``>
    class non_central_beta_distribution
    {
    public:
       typedef RealType  value_type;
       typedef Policy    policy_type;

       // Constructor:
       non_central_beta_distribution(RealType alpha, RealType beta, RealType lambda);

       // Accessor to shape parameters:
       RealType alpha()const;
       RealType beta()const;

       // Accessor to non-centrality parameter lambda:
       RealType non_centrality()const;
    };

    }} // namespaces

 The noncentral beta distribution is a generalization of the __beta_distrib.

 It is defined as the ratio
 X = [chi][sub m][super 2]([lambda]) \/ ([chi][sub m][super 2]([lambda])
 + [chi][sub n][super 2])
 where [chi][sub m][super 2]([lambda]) is a noncentral [chi][super 2]
 random variable with /m/ degrees of freedom, and [chi][sub n][super 2]
 is a central [chi][super 2] random variable with /n/ degrees of freedom.

 This gives a PDF that can be expressed as a Poisson mixture
 of beta distribution PDFs:

 [equation nc_beta_ref1]

 where P(i;[lambda]\/2) is the discrete Poisson probablity at /i/, with mean
 [lambda]\/2, and I[sub x][super ']([alpha], [beta]) is the derivative of
 the incomplete beta function.  This leads to the usual form of the CDF
 as:

 [equation nc_beta_ref2]

 The following graph illustrates how the distribution changes
 for different values of [lambda]:

 [graph nc_beta_pdf]

 [h4 Member Functions]

       non_central_beta_distribution(RealType a, RealType b, RealType lambda);

 Constructs a noncentral beta distribution with shape parameters /a/ and /b/
 and non-centrality parameter /lambda/.

 Requires a > 0, b > 0 and lambda >= 0, otherwise calls __domain_error.

       RealType alpha()const;

 Returns the parameter /a/ from which this object was constructed.

       RealType beta()const;

 Returns the parameter /b/ from which this object was constructed.

       RealType non_centrality()const;

 Returns the parameter /lambda/ from which this object was constructed.

 [h4 Non-member Accessors]

 Most of the [link math_toolkit.dist.dist_ref.nmp usual non-member accessor functions]
 are supported: __cdf, __pdf, __quantile,
 __median, __mode, __hazard, __chf, __range and __support.

 However, the following are not currently implemented:
 __mean, __variance, __sd, __skewness,
    __kurtosis and __kurtosis_excess.

 The domain of the random variable is \[0, 1\].

 [h4 Accuracy]

 The following table shows the peak errors
 (in units of [@http://en.wikipedia.org/wiki/Machine_epsilon epsilon])
 found on various platforms with various floating point types.
 No comparison to the [@http://www.r-project.org/ R-2.5.1 Math library],
 or to the FORTRAN implementations of AS226 or AS310 are given since these appear
 to only guarantee absolute error: this would causes our test harness
 to assign an /"infinite"/ error to these libraries for some of our
 test values when measuring /relative error/.
 Unless otherwise specified any floating-point type that is narrower
 than the one shown will have __zero_error.

 [table Errors In CDF of the Noncentral Beta
 [[Significand Size] [Platform and Compiler] [[alpha], [beta],[lambda] < 200]  [[alpha],[beta],[lambda] > 200]]
 [[53] [Win32, Visual C++ 8] [Peak=620 Mean=22]  [Peak=8670 Mean=1040]]
 [[64] [RedHat Linux IA32, gcc-4.1.1] [Peak=825 Mean=50]  [Peak=2.5x10[super 4] Mean=4000]]

 [[64] [Redhat Linux IA64, gcc-3.4.4] [Peak=825 Mean=30]  [Peak=1.7x10[super 4] Mean=2500]]

 [[113] [HPUX IA64, aCC A.06.06] [Peak=420 Mean=50]  [Peak=9200 Mean=1200]]
 ]

 Error rates for the PDF, the complement of the CDF and for the quantile
 functions are broadly similar.

 [h4 Tests]

 There are two sets of test data used to verify this implementation:
 firstly we can compare with a few sample values generated by the
 [@http://www.r-project.org/ R library].
 Secondly, we have tables of test data, computed with this
 implementation and using interval arithmetic - this data should
 be accurate to at least 50 decimal digits - and is the used for
 our accuracy tests.

 [h4 Implementation]

 The CDF and its complement are evaluated as follows:

 First we determine which of the two values (the CDF or its
 complement) is likely to be the smaller, the crossover point
 is taken to be the mean of the distribution: for this we use the
 approximation due to: R. Chattamvelli and R. Shanmugam,
 "Algorithm AS 310: Computing the Non-Central Beta Distribution Function",
 Applied Statistics, Vol. 46, No. 1. (1997), pp. 146-156.

 [equation nc_beta_ref3]

 Then either the CDF or its complement is computed using the
 relations:

 [equation nc_beta_ref4]

 The summation is performed by starting at i = [lambda]/2, and then recursing
 in both directions, using the usual recurrence relations for the Poisson
 PDF and incomplete beta functions.  This is the "Method 2" described
 by:

 Denise Benton and K. Krishnamoorthy,
 "Computing discrete mixtures of continuous
 distributions: noncentral chisquare, noncentral t
 and the distribution of the square of the sample
 multiple correlation coefficient",
 Computational Statistics & Data Analysis 43 (2003) 249-267.

 Specific applications of the above formulae to the noncentral
 beta distribution can be found in:

 Russell V. Lenth,
 "Algorithm AS 226: Computing Noncentral Beta Probabilities",
 Applied Statistics, Vol. 36, No. 2. (1987), pp. 241-244.

 H. Frick,
 "Algorithm AS R84: A Remark on Algorithm AS 226: Computing Non-Central Beta
 Probabilities", Applied Statistics, Vol. 39, No. 2. (1990), pp. 311-312.

 Ming Long Lam,
 "Remark AS R95: A Remark on Algorithm AS 226: Computing Non-Central Beta
 Probabilities", Applied Statistics, Vol. 44, No. 4. (1995), pp. 551-552.

 Harry O. Posten,
 "An Effective Algorithm for the Noncentral Beta Distribution Function",
 The American Statistician, Vol. 47, No. 2. (May, 1993), pp. 129-131.

 R. Chattamvelli,
 "A Note on the Noncentral Beta Distribution Function",
 The American Statistician, Vol. 49, No. 2. (May, 1995), pp. 231-234.

 Of these, the Posten reference provides the most complete overview,
 and includes the modification starting iteration at [lambda]/2.

 The main difference between this implementation and the above
 references is the direct computation of the complement when most
 efficient to do so, and the accumulation of the sum to -1 rather
 than subtracting the result from 1 at the end: this can substantially
 reduce the number of iterations required when the result is near 1.

 The PDF is computed using the methodology of Benton and Krishnamoorthy
 and the relation:

 [equation nc_beta_ref1]

 Quantiles are computed using a specially modified version of
 [link math_toolkit.toolkit.internals1.roots2 bracket_and_solve_root],
 starting the search for the root at the mean of the distribution.
 (A Cornish-Fisher type expansion was also tried, but while this gets
 quite close to the root in many cases, when it is wrong it tends to
 introduce quite pathological behaviour: more investigation in this
 area is probably warranted).

 [endsect][/section:nc_beta_dist]

 [/ nc_beta.qbk
   Copyright 2008 John Maddock and Paul A. Bristow.
   Distributed under the Boost Software License, Version 1.0.
   (See accompanying file LICENSE_1_0.txt or copy at
   http://www.boost.org/LICENSE_1_0.txt).
 ]
	[section:nc_beta_dist Noncentral Beta Distribution]

	``#include <boost/math/distributions/non_central_beta.hpp>``

	namespace boost{ namespace math{

	template <class RealType = double,
	class ``__Policy`` = ``__policy_class`` >
	class non_central_beta_distribution;

	typedef non_central_beta_distribution<> non_central_beta;

	template <class RealType, class ``__Policy``>
	class non_central_beta_distribution
	{
	public:
	typedef RealType value_type;
	typedef Policy policy_type;

	// Constructor:
	non_central_beta_distribution(RealType alpha, RealType beta, RealType lambda);

	// Accessor to shape parameters:
	RealType alpha()const;
	RealType beta()const;

	// Accessor to non-centrality parameter lambda:
	RealType non_centrality()const;
	};

	}} // namespaces

	The noncentral beta distribution is a generalization of the __beta_distrib.

	It is defined as the ratio
	X = [chi][sub m][super 2]([lambda]) \/ ([chi][sub m][super 2]([lambda])
	+ [chi][sub n][super 2])
	where [chi][sub m][super 2]([lambda]) is a noncentral [chi][super 2]
	random variable with /m/ degrees of freedom, and [chi][sub n][super 2]
	is a central [chi][super 2] random variable with /n/ degrees of freedom.

	This gives a PDF that can be expressed as a Poisson mixture
	of beta distribution PDFs:

	[equation nc_beta_ref1]

	where P(i;[lambda]\/2) is the discrete Poisson probablity at /i/, with mean
	[lambda]\/2, and I[sub x][super ']([alpha], [beta]) is the derivative of
	the incomplete beta function. This leads to the usual form of the CDF
	as:

	[equation nc_beta_ref2]

	The following graph illustrates how the distribution changes
	for different values of [lambda]:

	[graph nc_beta_pdf]

	[h4 Member Functions]

	non_central_beta_distribution(RealType a, RealType b, RealType lambda);

	Constructs a noncentral beta distribution with shape parameters /a/ and /b/
	and non-centrality parameter /lambda/.

	Requires a > 0, b > 0 and lambda >= 0, otherwise calls __domain_error.

	RealType alpha()const;

	Returns the parameter /a/ from which this object was constructed.

	RealType beta()const;

	Returns the parameter /b/ from which this object was constructed.

	RealType non_centrality()const;

	Returns the parameter /lambda/ from which this object was constructed.

	[h4 Non-member Accessors]

	Most of the [link math_toolkit.dist.dist_ref.nmp usual non-member accessor functions]
	are supported: __cdf, __pdf, __quantile,
	__median, __mode, __hazard, __chf, __range and __support.

	However, the following are not currently implemented:
	__mean, __variance, __sd, __skewness,
	__kurtosis and __kurtosis_excess.

	The domain of the random variable is \[0, 1\].

	[h4 Accuracy]

	The following table shows the peak errors
	(in units of [@http://en.wikipedia.org/wiki/Machine_epsilon epsilon])
	found on various platforms with various floating point types.
	No comparison to the [@http://www.r-project.org/ R-2.5.1 Math library],
	or to the FORTRAN implementations of AS226 or AS310 are given since these appear
	to only guarantee absolute error: this would causes our test harness
	to assign an /"infinite"/ error to these libraries for some of our
	test values when measuring /relative error/.
	Unless otherwise specified any floating-point type that is narrower
	than the one shown will have __zero_error.

	[table Errors In CDF of the Noncentral Beta
	[[Significand Size] [Platform and Compiler] [[alpha], [beta],[lambda] < 200] [[alpha],[beta],[lambda] > 200]]
	[[53] [Win32, Visual C++ 8] [Peak=620 Mean=22] [Peak=8670 Mean=1040]]
	[[64] [RedHat Linux IA32, gcc-4.1.1] [Peak=825 Mean=50] [Peak=2.5x10[super 4] Mean=4000]]

	[[64] [Redhat Linux IA64, gcc-3.4.4] [Peak=825 Mean=30] [Peak=1.7x10[super 4] Mean=2500]]

	[[113] [HPUX IA64, aCC A.06.06] [Peak=420 Mean=50] [Peak=9200 Mean=1200]]
	]

	Error rates for the PDF, the complement of the CDF and for the quantile
	functions are broadly similar.

	[h4 Tests]

	There are two sets of test data used to verify this implementation:
	firstly we can compare with a few sample values generated by the
	[@http://www.r-project.org/ R library].
	Secondly, we have tables of test data, computed with this
	implementation and using interval arithmetic - this data should
	be accurate to at least 50 decimal digits - and is the used for
	our accuracy tests.

	[h4 Implementation]

	The CDF and its complement are evaluated as follows:

	First we determine which of the two values (the CDF or its
	complement) is likely to be the smaller, the crossover point
	is taken to be the mean of the distribution: for this we use the
	approximation due to: R. Chattamvelli and R. Shanmugam,
	"Algorithm AS 310: Computing the Non-Central Beta Distribution Function",
	Applied Statistics, Vol. 46, No. 1. (1997), pp. 146-156.

	[equation nc_beta_ref3]

	Then either the CDF or its complement is computed using the
	relations:

	[equation nc_beta_ref4]

	The summation is performed by starting at i = [lambda]/2, and then recursing
	in both directions, using the usual recurrence relations for the Poisson
	PDF and incomplete beta functions. This is the "Method 2" described
	by:

	Denise Benton and K. Krishnamoorthy,
	"Computing discrete mixtures of continuous
	distributions: noncentral chisquare, noncentral t
	and the distribution of the square of the sample
	multiple correlation coefficient",
	Computational Statistics & Data Analysis 43 (2003) 249-267.

	Specific applications of the above formulae to the noncentral
	beta distribution can be found in:

	Russell V. Lenth,
	"Algorithm AS 226: Computing Noncentral Beta Probabilities",
	Applied Statistics, Vol. 36, No. 2. (1987), pp. 241-244.

	H. Frick,
	"Algorithm AS R84: A Remark on Algorithm AS 226: Computing Non-Central Beta
	Probabilities", Applied Statistics, Vol. 39, No. 2. (1990), pp. 311-312.

	Ming Long Lam,
	"Remark AS R95: A Remark on Algorithm AS 226: Computing Non-Central Beta
	Probabilities", Applied Statistics, Vol. 44, No. 4. (1995), pp. 551-552.

	Harry O. Posten,
	"An Effective Algorithm for the Noncentral Beta Distribution Function",
	The American Statistician, Vol. 47, No. 2. (May, 1993), pp. 129-131.

	R. Chattamvelli,
	"A Note on the Noncentral Beta Distribution Function",
	The American Statistician, Vol. 49, No. 2. (May, 1995), pp. 231-234.

	Of these, the Posten reference provides the most complete overview,
	and includes the modification starting iteration at [lambda]/2.

	The main difference between this implementation and the above
	references is the direct computation of the complement when most
	efficient to do so, and the accumulation of the sum to -1 rather
	than subtracting the result from 1 at the end: this can substantially
	reduce the number of iterations required when the result is near 1.

	The PDF is computed using the methodology of Benton and Krishnamoorthy
	and the relation:

	[equation nc_beta_ref1]

	Quantiles are computed using a specially modified version of
	[link math_toolkit.toolkit.internals1.roots2 bracket_and_solve_root],
	starting the search for the root at the mean of the distribution.
	(A Cornish-Fisher type expansion was also tried, but while this gets
	quite close to the root in many cases, when it is wrong it tends to
	introduce quite pathological behaviour: more investigation in this
	area is probably warranted).

	[endsect][/section:nc_beta_dist]

	[/ nc_beta.qbk
	Copyright 2008 John Maddock and Paul A. Bristow.
	Distributed under the Boost Software License, Version 1.0.
	(See accompanying file LICENSE_1_0.txt or copy at
	http://www.boost.org/LICENSE_1_0.txt).
	]