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274 lines
10 KiB
Plaintext
274 lines
10 KiB
Plaintext
[section:nc_chi_squared_dist Noncentral Chi-Squared Distribution]
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``#include <boost/math/distributions/non_central_chi_squared.hpp>``
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namespace boost{ namespace math{
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template <class RealType = double,
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class ``__Policy`` = ``__policy_class`` >
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class non_central_chi_squared_distribution;
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typedef non_central_chi_squared_distribution<> non_central_chi_squared;
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template <class RealType, class ``__Policy``>
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class non_central_chi_squared_distribution
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{
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public:
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typedef RealType value_type;
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typedef Policy policy_type;
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// Constructor:
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non_central_chi_squared_distribution(RealType v, RealType lambda);
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// Accessor to degrees of freedom parameter v:
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RealType degrees_of_freedom()const;
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// Accessor to non centrality parameter lambda:
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RealType non_centrality()const;
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// Parameter finders:
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static RealType find_degrees_of_freedom(RealType lambda, RealType x, RealType p);
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template <class A, class B, class C>
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static RealType find_degrees_of_freedom(const complemented3_type<A,B,C>& c);
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static RealType find_non_centrality(RealType v, RealType x, RealType p);
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template <class A, class B, class C>
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static RealType find_non_centrality(const complemented3_type<A,B,C>& c);
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};
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}} // namespaces
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The noncentral chi-squared distribution is a generalization of the
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__chi_squared_distrib. If X[sub i] are [nu] independent, normally
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distributed random variables with means [mu][sub i] and variances
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[sigma][sub i][super 2], then the random variable
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[equation nc_chi_squ_ref1]
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is distributed according to the noncentral chi-squared distribution.
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The noncentral chi-squared distribution has two parameters:
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[nu] which specifies the number of degrees of freedom
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(i.e. the number of X[sub i]), and [lambda] which is related to the
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mean of the random variables X[sub i] by:
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[equation nc_chi_squ_ref2]
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(Note that some references define [lambda] as one half of the above sum).
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This leads to a PDF of:
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[equation nc_chi_squ_ref3]
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where ['f(x;k)] is the central chi-squared distribution PDF, and
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['I[sub v](x)] is a modified Bessel function of the first kind.
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The following graph illustrates how the distribution changes
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for different values of [lambda]:
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[graph nccs_pdf]
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[h4 Member Functions]
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non_central_chi_squared_distribution(RealType v, RealType lambda);
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Constructs a Chi-Squared distribution with /v/ degrees of freedom
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and non-centrality parameter /lambda/.
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Requires v > 0 and lambda >= 0, otherwise calls __domain_error.
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RealType degrees_of_freedom()const;
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Returns the parameter /v/ from which this object was constructed.
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RealType non_centrality()const;
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Returns the parameter /lambda/ from which this object was constructed.
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static RealType find_degrees_of_freedom(RealType lambda, RealType x, RealType p);
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This function returns the number of degrees of freedom /v/ such that:
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`cdf(non_central_chi_squared<RealType, Policy>(v, lambda), x) == p`
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template <class A, class B, class C>
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static RealType find_degrees_of_freedom(const complemented3_type<A,B,C>& c);
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When called with argument `boost::math::complement(lambda, x, q)`
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this function returns the number of degrees of freedom /v/ such that:
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`cdf(complement(non_central_chi_squared<RealType, Policy>(v, lambda), x)) == q`.
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static RealType find_non_centrality(RealType v, RealType x, RealType p);
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This function returns the non centrality parameter /lambda/ such that:
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`cdf(non_central_chi_squared<RealType, Policy>(v, lambda), x) == p`
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template <class A, class B, class C>
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static RealType find_non_centrality(const complemented3_type<A,B,C>& c);
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When called with argument `boost::math::complement(v, x, q)`
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this function returns the non centrality parameter /lambda/ such that:
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`cdf(complement(non_central_chi_squared<RealType, Policy>(v, lambda), x)) == q`.
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[h4 Non-member Accessors]
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All the [link math_toolkit.dist_ref.nmp usual non-member accessor functions]
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that are generic to all distributions are supported: __usual_accessors.
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The domain of the random variable is \[0, +[infin]\].
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[h4 Examples]
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There is a
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[link math_toolkit.stat_tut.weg.nccs_eg worked example]
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for the noncentral chi-squared distribution.
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[h4 Accuracy]
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The following table shows the peak errors
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(in units of [@http://en.wikipedia.org/wiki/Machine_epsilon epsilon])
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found on various platforms with various floating point types.
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The failures in the comparison to the [@http://www.r-project.org/ R Math library],
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seem to be mostly in the corner cases when the probablity would be very small.
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Unless otherwise specified any floating-point type that is narrower
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than the one shown will have __zero_error.
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[table_non_central_chi_squared_CDF]
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[table_non_central_chi_squared_CDF_complement]
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Error rates for the quantile
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functions are broadly similar. Special mention should go to
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the `mode` function: there is no closed form for this function,
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so it is evaluated numerically by finding the maxima of the PDF:
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in principal this can not produce an accuracy greater than the
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square root of the machine epsilon.
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[h4 Tests]
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There are two sets of test data used to verify this implementation:
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firstly we can compare with published data, for example with
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Table 6 of "Self-Validating Computations of Probabilities for
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Selected Central and Noncentral Univariate Probability Functions",
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Morgan C. Wang and William J. Kennedy,
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Journal of the American Statistical Association,
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Vol. 89, No. 427. (Sep., 1994), pp. 878-887.
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Secondly, we have tables of test data, computed with this
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implementation and using interval arithmetic - this data should
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be accurate to at least 50 decimal digits - and is the used for
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our accuracy tests.
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[h4 Implementation]
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The CDF and its complement are evaluated as follows:
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First we determine which of the two values (the CDF or its
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complement) is likely to be the smaller: for this we can use the
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relation due to Temme (see "Asymptotic and Numerical Aspects of the
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Noncentral Chi-Square Distribution", N. M. Temme, Computers Math. Applic.
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Vol 25, No. 5, 55-63, 1993) that:
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F([nu],[lambda];[nu]+[lambda]) [asymp] 0.5
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and so compute the CDF when the random variable is less than
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[nu]+[lambda], and its complement when the random variable is
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greater than [nu]+[lambda]. If necessary the computed result
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is then subtracted from 1 to give the desired result (the CDF or its
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complement).
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For small values of the non centrality parameter, the CDF is computed
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using the method of Ding (see "Algorithm AS 275: Computing the Non-Central
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#2 Distribution Function", Cherng G. Ding, Applied Statistics, Vol. 41,
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No. 2. (1992), pp. 478-482). This uses the following series representation:
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[equation nc_chi_squ_ref4]
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which requires just one call to __gamma_p_derivative with the subsequent
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terms being computed by recursion as shown above.
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For larger values of the non-centrality parameter, Ding's method can take
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an unreasonable number of terms before convergence is achieved. Furthermore,
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the largest term is not the first term, so in extreme cases the first term may
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be zero, leading to a zero result, even though the true value may be non-zero.
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Therefore, when the non-centrality parameter is greater than 200, the method due
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to Krishnamoorthy (see "Computing discrete mixtures of continuous distributions:
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noncentral chisquare, noncentral t and the distribution of the
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square of the sample multiple correlation coefficient",
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Denise Benton and K. Krishnamoorthy, Computational Statistics &
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Data Analysis, 43, (2003), 249-267) is used.
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This method uses the well known sum:
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[equation nc_chi_squ_ref5]
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Where P[sub a](x) is the incomplete gamma function.
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The method starts at the [lambda]th term, which is where the Poisson weighting
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function achieves its maximum value, although this is not necessarily
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the largest overall term. Subsequent terms are calculated via the normal
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recurrence relations for the incomplete gamma function, and iteration proceeds
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both forwards and backwards until sufficient precision has been achieved. It
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should be noted that recurrence in the forwards direction of P[sub a](x) is
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numerically unstable. However, since we always start /after/ the largest
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term in the series, numeric instability is introduced more slowly than the
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series converges.
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Computation of the complement of the CDF uses an extension of Krishnamoorthy's
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method, given that:
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[equation nc_chi_squ_ref6]
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we can again start at the [lambda]'th term and proceed in both directions from
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there until the required precision is achieved. This time it is backwards
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recursion on the incomplete gamma function Q[sub a](x) which is unstable.
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However, as long as we start well /before/ the largest term, this is not an
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issue in practice.
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The PDF is computed directly using the relation:
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[equation nc_chi_squ_ref3]
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Where ['f(x; v)] is the PDF of the central __chi_squared_distrib and
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['I[sub v](x)] is a modified Bessel function, see __cyl_bessel_i.
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For small values of the
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non-centrality parameter the relation in terms of __cyl_bessel_i
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is used. However, this method fails for large values of the
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non-centrality parameter, so in that case the infinite sum is
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evaluated using the method of Benton and Krishnamoorthy, and
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the usual recurrence relations for successive terms.
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The quantile functions are computed by numeric inversion of the CDF.
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An improve starting quess is from
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Thomas Luu,
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[@http://discovery.ucl.ac.uk/1482128/, Fast and accurate parallel computation of quantile functions for random number generation, Doctorial Thesis, 2016].
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There is no [@http://en.wikipedia.org/wiki/Closed_form closed form]
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for the mode of the noncentral chi-squared
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distribution: it is computed numerically by finding the maximum
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of the PDF. Likewise, the median is computed numerically via
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the quantile.
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The remaining non-member functions use the following formulas:
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[equation nc_chi_squ_ref7]
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Some analytic properties of noncentral distributions
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(particularly unimodality, and monotonicity of their modes)
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are surveyed and summarized by:
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Andrea van Aubel & Wolfgang Gawronski, Applied Mathematics and Computation, 141 (2003) 3-12.
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[endsect] [/section:nc_chi_squared_dist]
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[/ nc_chi_squared.qbk
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Copyright 2008 John Maddock and Paul A. Bristow.
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Distributed under the Boost Software License, Version 1.0.
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(See accompanying file LICENSE_1_0.txt or copy at
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http://www.boost.org/LICENSE_1_0.txt).
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]
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