/* j1.c * * Bessel function of order one * * * * SYNOPSIS: * * double x, y, j1(); * * y = j1( x ); * * * * DESCRIPTION: * * Returns Bessel function of order one of the argument. * * The domain is divided into the intervals [0, 8] and * (8, infinity). In the first interval a 24 term Chebyshev * expansion is used. In the second, the asymptotic * trigonometric representation is employed using two * rational functions of degree 5/5. * * * * ACCURACY: * * Absolute error: * arithmetic domain # trials peak rms * DEC 0, 30 10000 4.0e-17 1.1e-17 * IEEE 0, 30 30000 2.6e-16 1.1e-16 * * */ /* y1.c * * Bessel function of second kind of order one * * * * SYNOPSIS: * * double x, y, y1(); * * y = y1( x ); * * * * DESCRIPTION: * * Returns Bessel function of the second kind of order one * of the argument. * * The domain is divided into the intervals [0, 8] and * (8, infinity). In the first interval a 25 term Chebyshev * expansion is used, and a call to j1() is required. * In the second, the asymptotic trigonometric representation * is employed using two rational functions of degree 5/5. * * * * ACCURACY: * * Absolute error: * arithmetic domain # trials peak rms * DEC 0, 30 10000 8.6e-17 1.3e-17 * IEEE 0, 30 30000 1.0e-15 1.3e-16 * * (error criterion relative when |y1| > 1). * */ /* Cephes Math Library Release 2.8: June, 2000 Copyright 1984, 1987, 1989, 2000 by Stephen L. Moshier */ double j1(double ); double j1(double x) { double w, z, p, q, xn; const double DR1 = 5.78318596294678452118E0; const double DR2 = 3.04712623436620863991E1; const double Z1 = 1.46819706421238932572E1; const double Z2 = 4.92184563216946036703E1; const double THPIO4 = 2.35619449019234492885; const double SQ2OPI = 0.79788456080286535588; double RP[8] = { -8.99971225705559398224E8, 4.52228297998194034323E11, -7.27494245221818276015E13, 3.68295732863852883286E15, 0.0, 0.0, 0.0, 0.0 }; double RQ[8] = { /* 1.00000000000000000000E0,*/ 6.20836478118054335476E2, 2.56987256757748830383E5, 8.35146791431949253037E7, 2.21511595479792499675E10, 4.74914122079991414898E12, 7.84369607876235854894E14, 8.95222336184627338078E16, 5.32278620332680085395E18, }; double PP[8] = { 7.62125616208173112003E-4, 7.31397056940917570436E-2, 1.12719608129684925192E0, 5.11207951146807644818E0, 8.42404590141772420927E0, 5.21451598682361504063E0, 1.00000000000000000254E0, 0.0, }; double PQ[8] = { 5.71323128072548699714E-4, 6.88455908754495404082E-2, 1.10514232634061696926E0, 5.07386386128601488557E0, 8.39985554327604159757E0, 5.20982848682361821619E0, 9.99999999999999997461E-1, 0.0, }; double QP[8] = { 5.10862594750176621635E-2, 4.98213872951233449420E0, 7.58238284132545283818E1, 3.66779609360150777800E2, 7.10856304998926107277E2, 5.97489612400613639965E2, 2.11688757100572135698E2, 2.52070205858023719784E1, }; double QQ[8] = { /* 1.00000000000000000000E0,*/ 7.42373277035675149943E1, 1.05644886038262816351E3, 4.98641058337653607651E3, 9.56231892404756170795E3, 7.99704160447350683650E3, 2.82619278517639096600E3, 3.36093607810698293419E2, 0.0, }; //const double Z1 = 1.46819706421238932572E1; //const double Z2 = 4.92184563216946036703E1; w = x; if( x < 0 ) w = -x; if( w <= 5.0 ) { z = x * x; w = polevl( z, RP, 3 ) / p1evl( z, RQ, 8 ); w = w * x * (z - Z1) * (z - Z2); return( w ); } w = 5.0/x; z = w * w; p = polevl( z, PP, 6)/polevl( z, PQ, 6 ); q = polevl( z, QP, 7)/p1evl( z, QQ, 7 ); xn = x - THPIO4; double sn, cn; SINCOS(xn, sn, cn); p = p * cn - w * q * sn; return( p * SQ2OPI / sqrt(x) ); }