// Copyright (c) 2007 John Maddock
// Use, modification and distribution are subject to 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)
//
// This is a partial header, do not include on it's own!!!
//
// Contains asymptotic expansions for Bessel J(v,x) and Y(v,x)
// functions, as x -> INF.
//
#ifndef BOOST_MATH_SF_DETAIL_BESSEL_JY_ASYM_HPP
#define BOOST_MATH_SF_DETAIL_BESSEL_JY_ASYM_HPP
#ifdef _MSC_VER
#pragma once
#endif
#include <boost/math/special_functions/factorials.hpp>
namespace boost{ namespace math{ namespace detail{
template <class T>
inline T asymptotic_bessel_j_large_x_P(T v, T x)
{
// A&S 9.2.9
T s = 1;
T mu = 4 * v * v;
T ez2 = 8 * x;
ez2 *= ez2;
s -= (mu-1) * (mu-9) / (2 * ez2);
s += (mu-1) * (mu-9) * (mu-25) * (mu - 49) / (24 * ez2 * ez2);
return s;
}
template <class T>
inline T asymptotic_bessel_j_large_x_Q(T v, T x)
{
// A&S 9.2.10
T s = 0;
T mu = 4 * v * v;
T ez = 8*x;
s += (mu-1) / ez;
s -= (mu-1) * (mu-9) * (mu-25) / (6 * ez*ez*ez);
return s;
}
template <class T>
inline T asymptotic_bessel_j_large_x(T v, T x)
{
//
// See http://functions.wolfram.com/BesselAiryStruveFunctions/BesselJ/06/02/02/0001/
//
// Also A&S 9.2.5
//
BOOST_MATH_STD_USING // ADL of std names
T chi = fabs(x) - constants::pi<T>() * (2 * v + 1) / 4;
return sqrt(2 / (constants::pi<T>() * x))
* (asymptotic_bessel_j_large_x_P(v, x) * cos(chi)
- asymptotic_bessel_j_large_x_Q(v, x) * sin(chi));
}
template <class T>
inline T asymptotic_bessel_y_large_x(T v, T x)
{
//
// See http://functions.wolfram.com/BesselAiryStruveFunctions/BesselJ/06/02/02/0001/
//
// Also A&S 9.2.5
//
BOOST_MATH_STD_USING // ADL of std names
T chi = fabs(x) - constants::pi<T>() * (2 * v + 1) / 4;
return sqrt(2 / (constants::pi<T>() * x))
* (asymptotic_bessel_j_large_x_P(v, x) * sin(chi)
- asymptotic_bessel_j_large_x_Q(v, x) * cos(chi));
}
template <class T>
inline T asymptotic_bessel_amplitude(T v, T x)
{
// Calculate the amplitude of J(v, x) and Y(v, x) for large
// x: see A&S 9.2.28.
BOOST_MATH_STD_USING
T s = 1;
T mu = 4 * v * v;
T txq = 2 * x;
txq *= txq;
s += (mu - 1) / (2 * txq);
s += 3 * (mu - 1) * (mu - 9) / (txq * txq * 8);
s += 15 * (mu - 1) * (mu - 9) * (mu - 25) / (txq * txq * txq * 8 * 6);
return sqrt(s * 2 / (constants::pi<T>() * x));
}
template <class T>
T asymptotic_bessel_phase_mx(T v, T x)
{
//
// Calculate the phase of J(v, x) and Y(v, x) for large x.
// See A&S 9.2.29.
// Note that the result returned is the phase less x.
//
T mu = 4 * v * v;
T denom = 4 * x;
T denom_mult = denom * denom;
T s = -constants::pi<T>() * (v / 2 + 0.25f);
s += (mu - 1) / (2 * denom);
denom *= denom_mult;
s += (mu - 1) * (mu - 25) / (6 * denom);
denom *= denom_mult;
s += (mu - 1) * (mu * mu - 114 * mu + 1073) / (5 * denom);
denom *= denom_mult;
s += (mu - 1) * (5 * mu * mu * mu - 1535 * mu * mu + 54703 * mu - 375733) / (14 * denom);
return s;
}
template <class T>
inline T asymptotic_bessel_y_large_x_2(T v, T x)
{
// See A&S 9.2.19.
BOOST_MATH_STD_USING
// Get the phase and amplitude:
T ampl = asymptotic_bessel_amplitude(v, x);
T phase = asymptotic_bessel_phase_mx(v, x);
BOOST_MATH_INSTRUMENT_VARIABLE(ampl);
BOOST_MATH_INSTRUMENT_VARIABLE(phase);
//
// Calculate the sine of the phase, using:
// sin(x+p) = sin(x)cos(p) + cos(x)sin(p)
//
T sin_phase = sin(phase) * cos(x) + cos(phase) * sin(x);
BOOST_MATH_INSTRUMENT_CODE(sin(phase));
BOOST_MATH_INSTRUMENT_CODE(cos(x));
BOOST_MATH_INSTRUMENT_CODE(cos(phase));
BOOST_MATH_INSTRUMENT_CODE(sin(x));
return sin_phase * ampl;
}
template <class T>
inline T asymptotic_bessel_j_large_x_2(T v, T x)
{
// See A&S 9.2.19.
BOOST_MATH_STD_USING
// Get the phase and amplitude:
T ampl = asymptotic_bessel_amplitude(v, x);
T phase = asymptotic_bessel_phase_mx(v, x);
BOOST_MATH_INSTRUMENT_VARIABLE(ampl);
BOOST_MATH_INSTRUMENT_VARIABLE(phase);
//
// Calculate the sine of the phase, using:
// cos(x+p) = cos(x)cos(p) - sin(x)sin(p)
//
BOOST_MATH_INSTRUMENT_CODE(cos(phase));
BOOST_MATH_INSTRUMENT_CODE(cos(x));
BOOST_MATH_INSTRUMENT_CODE(sin(phase));
BOOST_MATH_INSTRUMENT_CODE(sin(x));
T sin_phase = cos(phase) * cos(x) - sin(phase) * sin(x);
BOOST_MATH_INSTRUMENT_VARIABLE(sin_phase);
return sin_phase * ampl;
}
//
// Various limits for the J and Y asymptotics
// (the asympotic expansions are safe to use if
// x is less than the limit given).
// We assume that if we don't use these expansions then the
// error will likely be >100eps, so the limits given are chosen
// to lead to < 100eps truncation error.
//
template <class T>
inline T asymptotic_bessel_y_limit(const mpl::int_<0>&)
{
// default case:
BOOST_MATH_STD_USING
return 2.25 / pow(100 * tools::epsilon<T>() / T(0.001f), T(0.2f));
}
template <class T>
inline T asymptotic_bessel_y_limit(const mpl::int_<53>&)
{
// double case:
return 304 /*780*/;
}
template <class T>
inline T asymptotic_bessel_y_limit(const mpl::int_<64>&)
{
// 80-bit extended-double case:
return 1552 /*3500*/;
}
template <class T>
inline T asymptotic_bessel_y_limit(const mpl::int_<113>&)
{
// 128-bit long double case:
return 1245243 /*3128000*/;
}
template <class T, class Policy>
struct bessel_asymptotic_tag
{
typedef typename policies::precision<T, Policy>::type precision_type;
typedef typename mpl::if_<
mpl::or_<
mpl::equal_to<precision_type, mpl::int_<0> >,
mpl::greater<precision_type, mpl::int_<113> > >,
mpl::int_<0>,
typename mpl::if_<
mpl::greater<precision_type, mpl::int_<64> >,
mpl::int_<113>,
typename mpl::if_<
mpl::greater<precision_type, mpl::int_<53> >,
mpl::int_<64>,
mpl::int_<53>
>::type
>::type
>::type type;
};
template <class T>
inline T asymptotic_bessel_j_limit(const T& v, const mpl::int_<0>&)
{
// default case:
BOOST_MATH_STD_USING
T v2 = (std::max)(T(3), T(v * v));
return v2 / pow(100 * tools::epsilon<T>() / T(2e-5f), T(0.17f));
}
template <class T>
inline T asymptotic_bessel_j_limit(const T& v, const mpl::int_<53>&)
{
// double case:
T v2 = (std::max)(T(3), T(v * v));
return v2 * 33 /*73*/;
}
template <class T>
inline T asymptotic_bessel_j_limit(const T& v, const mpl::int_<64>&)
{
// 80-bit extended-double case:
T v2 = (std::max)(T(3), T(v * v));
return v2 * 121 /*266*/;
}
template <class T>
inline T asymptotic_bessel_j_limit(const T& v, const mpl::int_<113>&)
{
// 128-bit long double case:
T v2 = (std::max)(T(3), T(v * v));
return v2 * 39154 /*85700*/;
}
template <class T, class Policy>
void temme_asyptotic_y_small_x(T v, T x, T* Y, T* Y1, const Policy& pol)
{
T c = 1;
T p = (v / boost::math::sin_pi(v, pol)) * pow(x / 2, -v) / boost::math::tgamma(1 - v, pol);
T q = (v / boost::math::sin_pi(v, pol)) * pow(x / 2, v) / boost::math::tgamma(1 + v, pol);
T f = (p - q) / v;
T g_prefix = boost::math::sin_pi(v / 2, pol);
g_prefix *= g_prefix * 2 / v;
T g = f + g_prefix * q;
T h = p;
T c_mult = -x * x / 4;
T y(c * g), y1(c * h);
for(int k = 1; k < policies::get_max_series_iterations<Policy>(); ++k)
{
f = (k * f + p + q) / (k*k - v*v);
p /= k - v;
q /= k + v;
c *= c_mult / k;
T c1 = pow(-x * x / 4, k) / factorial<T>(k, pol);
g = f + g_prefix * q;
h = -k * g + p;
y += c * g;
y1 += c * h;
if(c * g / tools::epsilon<T>() < y)
break;
}
*Y = -y;
*Y1 = (-2 / x) * y1;
}
template <class T, class Policy>
T asymptotic_bessel_i_large_x(T v, T x, const Policy& pol)
{
BOOST_MATH_STD_USING // ADL of std names
T s = 1;
T mu = 4 * v * v;
T ex = 8 * x;
T num = mu - 1;
T denom = ex;
s -= num / denom;
num *= mu - 9;
denom *= ex * 2;
s += num / denom;
num *= mu - 25;
denom *= ex * 3;
s -= num / denom;
// Try and avoid overflow to the last minute:
T e = exp(x/2);
s = e * (e * s / sqrt(2 * x * constants::pi<T>()));
return (boost::math::isfinite)(s) ?
s : policies::raise_overflow_error<T>("boost::math::asymptotic_bessel_i_large_x<%1%>(%1%,%1%)", 0, pol);
}
}}} // namespaces
#endif