[section:hankel Hankel Functions] [section:cyl_hankel Cyclic Hankel Functions] [h4 Synopsis] template std::complex<``__sf_result``> cyl_hankel_1(T1 v, T2 x); template std::complex<``__sf_result``> cyl_hankel_1(T1 v, T2 x, const ``__Policy``&); template std::complex<``__sf_result``> cyl_hankel_2(T1 v, T2 x); template std::complex<``__sf_result``> cyl_hankel_2(T1 v, T2 x, const ``__Policy``&); [h4 Description] The functions __cyl_hankel_1 and __cyl_hankel_2 return the result of the [@http://dlmf.nist.gov/10.2#P3 Hankel functions] of the first and second kind respectively: [expression ['cyl_hankel_1(v, x) = H[sub v][super (1)](x) = J[sub v](x) + i Y[sub v](x)]] [expression ['cyl_hankel_2(v, x) = H[sub v][super (2)](x) = J[sub v](x) - i Y[sub v](x)]] where: ['J[sub v](x)] is the Bessel function of the first kind, and ['Y[sub v](x)] is the Bessel function of the second kind. The return type of these functions is computed using the __arg_promotion_rules when T1 and T2 are different types. The functions are also optimised for the relatively common case that T1 is an integer. [optional_policy] Note that while the arguments to these functions are real values, the results are complex. That means that the functions can only be instantiated on types `float`, `double` and `long double`. The functions have also been extended to operate over the whole range of ['v] and ['x] (unlike __cyl_bessel_j and __cyl_neumann). [h4 Performance] These functions are generally more efficient than two separate calls to the underlying Bessel functions as internally Bessel J and Y can be computed simultaneously. [h4 Testing] There are just a few spot tests to exercise all the special case handling - the bulk of the testing is done on the Bessel functions upon which these are based. [h4 Accuracy] Refer to __cyl_bessel_j and __cyl_neumann. [h4 Implementation] For ['x < 0] the following reflection formulae are used: [@http://functions.wolfram.com/Bessel-TypeFunctions/BesselJ/16/01/01/ [equation hankel1]] [@http://functions.wolfram.com/Bessel-TypeFunctions/BesselY/16/01/01/ [equation hankel2]] [@http://functions.wolfram.com/Bessel-TypeFunctions/BesselY/16/01/01/ [equation hankel3]] Otherwise the implementation is trivially in terms of the Bessel J and Y functions. Note however, that the Hankel functions compute the Bessel J and Y functions simultaneously, and therefore a single Hankel function call is more efficient than two Bessel function calls. The one exception is when ['v] is a small positive integer, in which case the usual Bessel function routines for integer order are used. [endsect] [/section:cyl_hankel Cyclic Hankel Functions] [section:sph_hankel Spherical Hankel Functions] [h4 Synopsis] template std::complex<``__sf_result``> sph_hankel_1(T1 v, T2 x); template std::complex<``__sf_result``> sph_hankel_1(T1 v, T2 x, const ``__Policy``&); template std::complex<``__sf_result``> sph_hankel_2(T1 v, T2 x); template std::complex<``__sf_result``> sph_hankel_2(T1 v, T2 x, const ``__Policy``&); [h4 Description] The functions __sph_hankel_1 and __sph_hankel_2 return the result of the [@http://dlmf.nist.gov/10.47#P1 spherical Hankel functions] of the first and second kind respectively: [equation hankel4] [equation hankel5] The return type of these functions is computed using the __arg_promotion_rules when T1 and T2 are different types. The functions are also optimised for the relatively common case that T1 is an integer. [optional_policy] Note that while the arguments to these functions are real values, the results are complex. That means that the functions can only be instantiated on types `float`, `double` and `long double`. The functions have also been extended to operate over the whole range of ['v] and ['x] (unlike __cyl_bessel_j and __cyl_neumann). [h4 Testing] There are just a few spot tests to exercise all the special case handling - the bulk of the testing is done on the Bessel functions upon which these are based. [h4 Accuracy] Refer to __cyl_bessel_j and __cyl_neumann. [h4 Implementation] These functions are trivially implemented in terms of __cyl_hankel_1 and __cyl_hankel_2. [endsect] [/section:sph_hankel Spherical Hankel Functions] [endsect] [/section:hankel Hankel Functions] [/ Copyright 2012 John Maddock. 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). ]