[section:igamma Incomplete Gamma Functions] [h4 Synopsis] `` #include `` namespace boost{ namespace math{ template BOOST_MATH_GPU_ENABLED ``__sf_result`` gamma_p(T1 a, T2 z); template BOOST_MATH_GPU_ENABLED ``__sf_result`` gamma_p(T1 a, T2 z, const ``__Policy``&); template BOOST_MATH_GPU_ENABLED ``__sf_result`` gamma_q(T1 a, T2 z); template BOOST_MATH_GPU_ENABLED ``__sf_result`` gamma_q(T1 a, T2 z, const ``__Policy``&); template BOOST_MATH_GPU_ENABLED ``__sf_result`` lgamma_q(T1 a, T2 z); template BOOST_MATH_GPU_ENABLED ``__sf_result`` lgamma_q(T1 a, T2 z, const ``__Policy``&); template BOOST_MATH_GPU_ENABLED ``__sf_result`` tgamma_lower(T1 a, T2 z); template BOOST_MATH_GPU_ENABLED ``__sf_result`` tgamma_lower(T1 a, T2 z, const ``__Policy``&); template BOOST_MATH_GPU_ENABLED ``__sf_result`` tgamma(T1 a, T2 z); template BOOST_MATH_GPU_ENABLED ``__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 BOOST_MATH_GPU_ENABLED ``__sf_result`` gamma_p(T1 a, T2 z); template BOOST_MATH_GPU_ENABLED ``__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 BOOST_MATH_GPU_ENABLED ``__sf_result`` gamma_q(T1 a, T2 z); template BOOST_MATH_GPU_ENABLED ``__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 BOOST_MATH_GPU_ENABLED ``__sf_result`` lgamma_q(T1 a, T2 z); template BOOST_MATH_GPU_ENABLED ``__sf_result`` lgamma_q(T1 a, T2 z, const ``__Policy``&); Returns the natural log of the normalized upper incomplete gamma function of a and z. template BOOST_MATH_GPU_ENABLED ``__sf_result`` tgamma_lower(T1 a, T2 z); template BOOST_MATH_GPU_ENABLED ``__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 BOOST_MATH_GPU_ENABLED ``__sf_result`` tgamma(T1 a, T2 z); template BOOST_MATH_GPU_ENABLED ``__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). The natural log of the normalized upper incomplete gamma function is computed as expected except when the normalized upper incomplete gamma function begins to underflow. This approximately occurs at ((x > 1000) && ((a < x) || (fabs(a - 50) / x < 1))) || ((x > log_max_value() - 10) && (x > a)) in which case an expansion, for large x, of the (non-normalised) upper incomplete gamma function is used. The return is then normalised by subtracting the log of the gamma function and adding /a log(x)-x-log(x)/. [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). ]