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195 lines
6.3 KiB
Plaintext
195 lines
6.3 KiB
Plaintext
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[section:mbessel Modified Bessel Functions of the First and Second Kinds]
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[h4 Synopsis]
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`#include <boost/math/special_functions/bessel.hpp>`
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template <class T1, class T2>
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``__sf_result`` cyl_bessel_i(T1 v, T2 x);
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template <class T1, class T2, class ``__Policy``>
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``__sf_result`` cyl_bessel_i(T1 v, T2 x, const ``__Policy``&);
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template <class T1, class T2>
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``__sf_result`` cyl_bessel_k(T1 v, T2 x);
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template <class T1, class T2, class ``__Policy``>
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``__sf_result`` cyl_bessel_k(T1 v, T2 x, const ``__Policy``&);
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[h4 Description]
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The functions __cyl_bessel_i and __cyl_bessel_k return the result of the
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modified Bessel functions of the first and second kind respectively:
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cyl_bessel_i(v, x) = I[sub v](x)
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cyl_bessel_k(v, x) = K[sub v](x)
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where:
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[equation mbessel2]
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[equation mbessel3]
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The return type of these functions is computed using the __arg_promotion_rules
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when T1 and T2 are different types. The functions are also optimised for the
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relatively common case that T1 is an integer.
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[optional_policy]
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The functions return the result of __domain_error whenever the result is
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undefined or complex. For __cyl_bessel_j this occurs when `x < 0` and v is not
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an integer, or when `x == 0` and `v != 0`. For __cyl_neumann this occurs
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when `x <= 0`.
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The following graph illustrates the exponential behaviour of I[sub v].
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[graph cyl_bessel_i]
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The following graph illustrates the exponential decay of K[sub v].
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[graph cyl_bessel_k]
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[h4 Testing]
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There are two sets of test values: spot values calculated using
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[@http://functions.wolfram.com functions.wolfram.com],
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and a much larger set of tests computed using
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a simplified version of this implementation
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(with all the special case handling removed).
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[h4 Accuracy]
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The following tables show how the accuracy of these functions
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varies on various platforms, along with comparison to other libraries.
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Note that only results for the widest floating-point type on the
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system are given, as narrower types have __zero_error. All values
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are relative errors in units of epsilon. Note that our test suite
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includes some fairly extreme inputs which results in most of the worst
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problem cases in other libraries:
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[table_cyl_bessel_i_integer_orders_]
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[table_cyl_bessel_i]
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[table_cyl_bessel_k_integer_orders_]
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[table_cyl_bessel_k]
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[h4 Implementation]
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The following are handled as special cases first:
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When computing I[sub v][space] for ['x < 0], then [nu][space] must be an integer
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or a domain error occurs. If [nu][space] is an integer, then the function is
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odd if [nu][space] is odd and even if [nu][space] is even, and we can reflect to
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['x > 0].
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For I[sub v][space] with v equal to 0, 1 or 0.5 are handled as special cases.
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The 0 and 1 cases use minimax rational approximations on
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finite and infinite intervals. The coefficients are from:
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* J.M. Blair and C.A. Edwards, ['Stable rational minimax approximations
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to the modified Bessel functions I_0(x) and I_1(x)], Atomic Energy of Canada
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Limited Report 4928, Chalk River, 1974.
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* S. Moshier, ['Methods and Programs for Mathematical Functions],
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Ellis Horwood Ltd, Chichester, 1989.
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While the 0.5 case is a simple trigonometric function:
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I[sub 0.5](x) = sqrt(2 / [pi]x) * sinh(x)
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For K[sub v][space] with /v/ an integer, the result is calculated using the
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recurrence relation:
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[equation mbessel5]
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starting from K[sub 0][space] and K[sub 1][space] which are calculated
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using rational the approximations above. These rational approximations are
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accurate to around 19 digits, and are therefore only used when T has
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no more than 64 binary digits of precision.
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When /x/ is small compared to /v/, I[sub v]x[space] is best computed directly from the series:
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[equation mbessel17]
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In the general case, we first normalize [nu][space] to \[[^0, [inf]])
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with the help of the reflection formulae:
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[equation mbessel9]
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[equation mbessel10]
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Let [mu][space] = [nu] - floor([nu] + 1/2), then [mu][space] is the fractional part of
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[nu][space] such that |[mu]| <= 1/2 (we need this for convergence later). The idea is to
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calculate K[sub [mu]](x) and K[sub [mu]+1](x), and use them to obtain
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I[sub [nu]](x) and K[sub [nu]](x).
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The algorithm is proposed by Temme in
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N.M. Temme, ['On the numerical evaluation of the modified bessel function
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of the third kind], Journal of Computational Physics, vol 19, 324 (1975),
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which needs two continued fractions as well as the Wronskian:
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[equation mbessel11]
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[equation mbessel12]
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[equation mbessel8]
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The continued fractions are computed using the modified Lentz's method
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(W.J. Lentz, ['Generating Bessel functions in Mie scattering calculations
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using continued fractions], Applied Optics, vol 15, 668 (1976)).
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Their convergence rates depend on ['x], therefore we need
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different strategies for large ['x] and small ['x].
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['x > v], CF1 needs O(['x]) iterations to converge, CF2 converges rapidly.
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['x <= v], CF1 converges rapidly, CF2 fails to converge when ['x] [^->] 0.
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When ['x] is large (['x] > 2), both continued fractions converge (CF1
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may be slow for really large ['x]). K[sub [mu]][space] and K[sub [mu]+1][space]
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can be calculated by
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[equation mbessel13]
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where
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[equation mbessel14]
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['S] is also a series that is summed along with CF2, see
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I.J. Thompson and A.R. Barnett, ['Modified Bessel functions I_v and K_v
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of real order and complex argument to selected accuracy], Computer Physics
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Communications, vol 47, 245 (1987).
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When ['x] is small (['x] <= 2), CF2 convergence may fail (but CF1
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works very well). The solution here is Temme's series:
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[equation mbessel15]
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where
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[equation mbessel16]
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f[sub k][space] and h[sub k][space]
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are also computed by recursions (involving gamma functions), but the
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formulas are a little complicated, readers are referred to
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N.M. Temme, ['On the numerical evaluation of the modified Bessel function
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of the third kind], Journal of Computational Physics, vol 19, 324 (1975).
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Note: Temme's series converge only for |[mu]| <= 1/2.
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K[sub [nu]](x) is then calculated from the forward
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recurrence, as is K[sub [nu]+1](x). With these two values and
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f[sub [nu]], the Wronskian yields I[sub [nu]](x) directly.
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[endsect]
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[/
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Copyright 2006 John Maddock, Paul A. Bristow and Xiaogang Zhang.
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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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