math/doc/sf/igamma.qbk

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[section:igamma Incomplete Gamma Functions]
[h4 Synopsis]
``
#include <boost/math/special_functions/gamma.hpp>
``
namespace boost{ namespace math{
template <class T1, class T2>
``__sf_result`` gamma_p(T1 a, T2 z);
template <class T1, class T2, class ``__Policy``>
``__sf_result`` gamma_p(T1 a, T2 z, const ``__Policy``&);
template <class T1, class T2>
``__sf_result`` gamma_q(T1 a, T2 z);
template <class T1, class T2, class ``__Policy``>
``__sf_result`` gamma_q(T1 a, T2 z, const ``__Policy``&);
template <class T1, class T2>
``__sf_result`` tgamma_lower(T1 a, T2 z);
template <class T1, class T2, class ``__Policy``>
``__sf_result`` tgamma_lower(T1 a, T2 z, const ``__Policy``&);
template <class T1, class T2>
``__sf_result`` tgamma(T1 a, T2 z);
template <class T1, class T2, class ``__Policy``>
``__sf_result`` tgamma(T1 a, T2 z, const ``__Policy``&);
}} // namespaces
[h4 Description]
There are four [@http://mathworld.wolfram.com/IncompleteGammaFunction.html
incomplete gamma functions]:
two are normalised versions (also known as /regularized/ incomplete gamma functions)
that return values in the range [0, 1], and two are non-normalised and
return values in the range [0, [Gamma](a)]. Users interested in statistical
applications should use the
[@http://mathworld.wolfram.com/RegularizedGammaFunction.html normalised versions (`gamma_p` and `gamma_q`)].
All of these functions require /a > 0/ and /z >= 0/, otherwise they return
the result of __domain_error.
[optional_policy]
The return type of these functions is computed using the __arg_promotion_rules
when T1 and T2 are different types, otherwise the return type is simply T1.
template <class T1, class T2>
``__sf_result`` gamma_p(T1 a, T2 z);
template <class T1, class T2, class Policy>
``__sf_result`` gamma_p(T1 a, T2 z, const ``__Policy``&);
Returns the normalised lower incomplete gamma function of a and z:
[equation igamma4]
This function changes rapidly from 0 to 1 around the point z == a:
[graph gamma_p]
template <class T1, class T2>
``__sf_result`` gamma_q(T1 a, T2 z);
template <class T1, class T2, class ``__Policy``>
``__sf_result`` gamma_q(T1 a, T2 z, const ``__Policy``&);
Returns the normalised upper incomplete gamma function of a and z:
[equation igamma3]
This function changes rapidly from 1 to 0 around the point z == a:
[graph gamma_q]
template <class T1, class T2>
``__sf_result`` tgamma_lower(T1 a, T2 z);
template <class T1, class T2, class ``__Policy``>
``__sf_result`` tgamma_lower(T1 a, T2 z, const ``__Policy``&);
Returns the full (non-normalised) lower incomplete gamma function of a and z:
[equation igamma2]
template <class T1, class T2>
``__sf_result`` tgamma(T1 a, T2 z);
template <class T1, class T2, class ``__Policy``>
``__sf_result`` tgamma(T1 a, T2 z, const ``__Policy``&);
Returns the full (non-normalised) upper incomplete gamma function of a and z:
[equation igamma1]
[h4 Accuracy]
The following tables give peak and mean relative errors in over various domains of
a and z, along with comparisons to the __gsl and __cephes libraries.
Note that only results for the widest floating-point type on the system are given as
narrower types have __zero_error.
Note that errors grow as /a/ grows larger.
Note also that the higher error rates for the 80 and 128 bit
long double results are somewhat misleading: expected results that are
zero at 64-bit double precision may be non-zero - but exceptionally small -
with the larger exponent range of a long double. These results therefore
reflect the more extreme nature of the tests conducted for these types.
All values are in units of epsilon.
[table_gamma_p]
[table_gamma_q]
[table_tgamma_lower]
[table_tgamma_incomplete_]
[h4 Testing]
There are two sets of tests: spot tests compare values taken from
[@http://functions.wolfram.com/GammaBetaErf/ Mathworld's online evaluator]
with this implementation to perform a basic "sanity check".
Accuracy tests use data generated at very high precision
(using NTL's RR class set at 1000-bit precision) using this implementation
with a very high precision 60-term __lanczos, and some but not all of the special
case handling disabled.
This is less than satisfactory: an independent method should really be used,
but apparently a complete lack of such methods are available. We can't even use a deliberately
naive implementation without special case handling since Legendre's continued fraction
(see below) is unstable for small a and z.
[h4 Implementation]
These four functions share a common implementation since
they are all related via:
1) [equation igamma5]
2) [equation igamma6]
3) [equation igamma7]
The lower incomplete gamma is computed from its series representation:
4) [equation igamma8]
Or by subtraction of the upper integral from either [Gamma](a) or 1
when /x - (1/(3x)) > a and x > 1.1/.
The upper integral is computed from Legendre's continued fraction representation:
5) [equation igamma9]
When /(x > 1.1)/ or by subtraction of the lower integral from either [Gamma](a) or 1
when /x - (1/(3x)) < a/.
For /x < 1.1/ computation of the upper integral is more complex as the continued
fraction representation is unstable in this area. However there is another
series representation for the lower integral:
6) [equation igamma10]
That lends itself to calculation of the upper integral via rearrangement
to:
7) [equation igamma11]
Refer to the documentation for __powm1 and __tgamma1pm1 for details
of their implementation.
For /x < 1.1/ the crossover point where the result is ~0.5 no longer
occurs for /x ~ y/. Using /x * 0.75 < a/ as the crossover criterion
for /0.5 < x <= 1.1/ keeps the maximum value computed (whether
it's the upper or lower interval) to around 0.75. Likewise for
/x <= 0.5/ then using /-0.4 / log(x) < a/ as the crossover criterion
keeps the maximum value computed to around 0.7
(whether it's the upper or lower interval).
There are two special cases used when a is an integer or half integer,
and the crossover conditions listed above indicate that we should compute
the upper integral Q.
If a is an integer in the range /1 <= a < 30/ then the following
finite sum is used:
9) [equation igamma1f]
While for half-integers in the range /0.5 <= a < 30/ then the
following finite sum is used:
10) [equation igamma2f]
These are both more stable and more efficient than the continued fraction
alternative.
When the argument /a/ is large, and /x ~ a/ then the series (4) and continued
fraction (5) above are very slow to converge. In this area an expansion due to
Temme is used:
11) [equation igamma16]
12) [equation igamma17]
13) [equation igamma18]
14) [equation igamma19]
The double sum is truncated to a fixed number of terms - to give a specific
target precision - and evaluated as a polynomial-of-polynomials. There are
versions for up to 128-bit long double precision: types requiring
greater precision than that do not use these expansions. The
coefficients C[sub k][super n] are computed in advance using the recurrence
relations given by Temme. The zone where these expansions are used is
(a > 20) && (a < 200) && fabs(x-a)/a < 0.4
And:
(a > 200) && (fabs(x-a)/a < 4.5/sqrt(a))
The latter range is valid for all types up to 128-bit long doubles, and
is designed to ensure that the result is larger than 10[super -6], the
first range is used only for types up to 80-bit long doubles. These
domains are narrower than the ones recommended by either Temme or Didonato
and Morris. However, using a wider range results in large and inexact
(i.e. computed) values being passed to the `exp` and `erfc` functions
resulting in significantly larger error rates. In other words there is a
fine trade off here between efficiency and error. The current limits should
keep the number of terms required by (4) and (5) to no more than ~20
at double precision.
For the normalised incomplete gamma functions, calculation of the
leading power terms is central to the accuracy of the function.
For smallish a and x combining
the power terms with the __lanczos gives the greatest accuracy:
15) [equation igamma12]
In the event that this causes underflow/overflow then the exponent can
be reduced by a factor of /a/ and brought inside the power term.
When a and x are large, we end up with a very large exponent with a base
near one: this will not be computed accurately via the pow function,
and taking logs simply leads to cancellation errors. The worst of the
errors can be avoided by using:
16) [equation igamma13]
when /a-x/ is small and a and x are large. There is still a subtraction
and therefore some cancellation errors - but the terms are small so the absolute
error will be small - and it is absolute rather than relative error that
counts in the argument to the /exp/ function. Note that for sufficiently
large a and x the errors will still get you eventually, although this does
delay the inevitable much longer than other methods. Use of /log(1+x)-x/ here
is inspired by Temme (see references below).
[h4 References]
* N. M. Temme, A Set of Algorithms for the Incomplete Gamma Functions,
Probability in the Engineering and Informational Sciences, 8, 1994.
* N. M. Temme, The Asymptotic Expansion of the Incomplete Gamma Functions,
Siam J. Math Anal. Vol 10 No 4, July 1979, p757.
* A. R. Didonato and A. H. Morris, Computation of the Incomplete Gamma
Function Ratios and their Inverse. ACM TOMS, Vol 12, No 4, Dec 1986, p377.
* W. Gautschi, The Incomplete Gamma Functions Since Tricomi, In Tricomi's Ideas
and Contemporary Applied Mathematics, Atti dei Convegni Lincei, n. 147,
Accademia Nazionale dei Lincei, Roma, 1998, pp. 203--237.
[@http://citeseer.ist.psu.edu/gautschi98incomplete.html http://citeseer.ist.psu.edu/gautschi98incomplete.html]
[endsect] [/section:igamma The Incomplete Gamma Function]
[/
Copyright 2006 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).
]