/* j0.c
*
* Bessel function of order zero
*
*
*
* SYNOPSIS:
*
* double x, y, j0();
*
* y = j0( x );
*
*
*
* DESCRIPTION:
*
* Returns Bessel function of order zero of the argument.
*
* The domain is divided into the intervals [0, 5] and
* (5, infinity). In the first interval the following rational
* approximation is used:
*
*
* 2 2
* (w - r ) (w - r ) P (w) / Q (w)
* 1 2 3 8
*
* 2
* where w = x and the two r's are zeros of the function.
*
* In the second interval, the Hankel asymptotic expansion
* is employed with two rational functions of degree 6/6
* and 7/7.
*
*
*
* ACCURACY:
*
* Absolute error:
* arithmetic domain # trials peak rms
* DEC 0, 30 10000 4.4e-17 6.3e-18
* IEEE 0, 30 60000 4.2e-16 1.1e-16
*
*/
�/* y0.c
*
* Bessel function of the second kind, order zero
*
*
*
* SYNOPSIS:
*
* double x, y, y0();
*
* y = y0( x );
*
*
*
* DESCRIPTION:
*
* Returns Bessel function of the second kind, of order
* zero, of the argument.
*
* The domain is divided into the intervals [0, 5] and
* (5, infinity). In the first interval a rational approximation
* R(x) is employed to compute
* y0(x) = R(x) + 2 * log(x) * j0(x) / PI.
* Thus a call to j0() is required.
*
* In the second interval, the Hankel asymptotic expansion
* is employed with two rational functions of degree 6/6
* and 7/7.
*
*
*
* ACCURACY:
*
* Absolute error, when y0(x) < 1; else relative error:
*
* arithmetic domain # trials peak rms
* DEC 0, 30 9400 7.0e-17 7.9e-18
* IEEE 0, 30 30000 1.3e-15 1.6e-16
*
*/
�
/*
Cephes Math Library Release 2.1: January, 1989
Copyright 1984, 1987, 1989 by Stephen L. Moshier
Direct inquiries to 30 Frost Street, Cambridge, MA 02140
*/
/* Note: all coefficients satisfy the relative error criterion
* except YP, YQ which are designed for absolute error. */
#include "mconf.h"
static double PP[7] = {
7.96936729297347051624E-4,
8.28352392107440799803E-2,
1.23953371646414299388E0,
5.44725003058768775090E0,
8.74716500199817011941E0,
5.30324038235394892183E0,
9.99999999999999997821E-1,
};
static double PQ[7] = {
9.24408810558863637013E-4,
8.56288474354474431428E-2,
1.25352743901058953537E0,
5.47097740330417105182E0,
8.76190883237069594232E0,
5.30605288235394617618E0,
1.00000000000000000218E0,
};
static double QP[8] = {
-1.13663838898469149931E-2,
-1.28252718670509318512E0,
-1.95539544257735972385E1,
-9.32060152123768231369E1,
-1.77681167980488050595E2,
-1.47077505154951170175E2,
-5.14105326766599330220E1,
-6.05014350600728481186E0,
};
static double QQ[7] = {
/* 1.00000000000000000000E0,*/
6.43178256118178023184E1,
8.56430025976980587198E2,
3.88240183605401609683E3,
7.24046774195652478189E3,
5.93072701187316984827E3,
2.06209331660327847417E3,
2.42005740240291393179E2,
};
static double YP[8] = {
1.55924367855235737965E4,
-1.46639295903971606143E7,
5.43526477051876500413E9,
-9.82136065717911466409E11,
8.75906394395366999549E13,
-3.46628303384729719441E15,
4.42733268572569800351E16,
-1.84950800436986690637E16,
};
static double YQ[7] = {
/* 1.00000000000000000000E0,*/
1.04128353664259848412E3,
6.26107330137134956842E5,
2.68919633393814121987E8,
8.64002487103935000337E10,
2.02979612750105546709E13,
3.17157752842975028269E15,
2.50596256172653059228E17,
};
/* 5.783185962946784521175995758455807035071 */
static double DR1 = 5.78318596294678452118E0;
/* 30.47126234366208639907816317502275584842 */
static double DR2 = 3.04712623436620863991E1;
static double RP[4] = {
-4.79443220978201773821E9,
1.95617491946556577543E12,
-2.49248344360967716204E14,
9.70862251047306323952E15,
};
static double RQ[8] = {
/* 1.00000000000000000000E0,*/
4.99563147152651017219E2,
1.73785401676374683123E5,
4.84409658339962045305E7,
1.11855537045356834862E10,
2.11277520115489217587E12,
3.10518229857422583814E14,
3.18121955943204943306E16,
1.71086294081043136091E18,
};
double j0(x)
double x;
{
double polevl(), p1evl();
double w, z, p, q, xn;
double sin(), cos(), sqrt();
extern double PIO4, SQ2OPI;
if( x < 0 )
x = -x;
if( x <= 5.0 )
{
z = x * x;
if( x < 1.0e-5 )
return( 1.0 - z/4.0 );
p = (z - DR1) * (z - DR2);
p = p * polevl( z, RP, 3)/p1evl( z, RQ, 8 );
return( p );
}
w = 5.0/x;
q = 25.0/(x*x);
p = polevl( q, PP, 6)/polevl( q, PQ, 6 );
q = polevl( q, QP, 7)/p1evl( q, QQ, 7 );
xn = x - PIO4;
p = p * cos(xn) - w * q * sin(xn);
return( p * SQ2OPI / sqrt(x) );
}
�
/* y0() 2 */
/* Bessel function of second kind, order zero */
/* Rational approximation coefficients YP[], YQ[] are used here.
* The function computed is y0(x) - 2 * log(x) * j0(x) / PI,
* whose value at x = 0 is 2 * ( log(0.5) + EUL ) / PI
* = 0.073804295108687225.
*/
/*
#define PIO4 .78539816339744830962
#define SQ2OPI .79788456080286535588
*/
extern double MAXNUM;
#ifdef MY_FIXY0
double fixy0(x)
#else
double y0(x)
#endif
double x;
{
double polevl(), p1evl();
double w, z, p, q, xn;
double j0(), log(), sin(), cos(), sqrt();
extern double TWOOPI, SQ2OPI, PIO4;
if( x <= 5.0 )
{
if( x <= 0.0 )
{
mtherr( "y0", DOMAIN );
return( -MAXNUM );
}
z = x * x;
w = polevl( z, YP, 7) / p1evl( z, YQ, 7 );
w += TWOOPI * log(x) * j0(x);
return( w );
}
w = 5.0/x;
z = 25.0 / (x * x);
p = polevl( z, PP, 6)/polevl( z, PQ, 6 );
q = polevl( z, QP, 7)/p1evl( z, QQ, 7 );
xn = x - PIO4;
p = p * sin(xn) + w * q * cos(xn);
return( p * SQ2OPI / sqrt(x) );
}