/* integration/qmomof.c * * Copyright (C) 1996, 1997, 1998, 1999, 2000, 2007 Brian Gough * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or (at * your option) any later version. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include #include #include #include static void compute_moments (double par, double * cheb); static int dgtsl (size_t n, double *c, double *d, double *e, double *b); gsl_integration_qawo_table * gsl_integration_qawo_table_alloc (double omega, double L, enum gsl_integration_qawo_enum sine, size_t n) { gsl_integration_qawo_table *t; double * chebmo; if (n == 0) { GSL_ERROR_VAL ("table length n must be positive integer", GSL_EDOM, 0); } t = (gsl_integration_qawo_table *) malloc (sizeof (gsl_integration_qawo_table)); if (t == 0) { GSL_ERROR_VAL ("failed to allocate space for qawo_table struct", GSL_ENOMEM, 0); } chebmo = (double *) malloc (25 * n * sizeof (double)); if (chebmo == 0) { free (t); GSL_ERROR_VAL ("failed to allocate space for chebmo block", GSL_ENOMEM, 0); } t->n = n; t->sine = sine; t->omega = omega; t->L = L; t->par = 0.5 * omega * L; t->chebmo = chebmo; /* precompute the moments */ { size_t i; double scale = 1.0; for (i = 0 ; i < t->n; i++) { compute_moments (t->par * scale, t->chebmo + 25*i); scale *= 0.5; } } return t; } int gsl_integration_qawo_table_set (gsl_integration_qawo_table * t, double omega, double L, enum gsl_integration_qawo_enum sine) { t->omega = omega; t->sine = sine; t->L = L; t->par = 0.5 * omega * L; /* recompute the moments */ { size_t i; double scale = 1.0; for (i = 0 ; i < t->n; i++) { compute_moments (t->par * scale, t->chebmo + 25*i); scale *= 0.5; } } return GSL_SUCCESS; } int gsl_integration_qawo_table_set_length (gsl_integration_qawo_table * t, double L) { /* return immediately if the length is the same as the old length */ if (L == t->L) return GSL_SUCCESS; /* otherwise reset the table and compute the new parameters */ t->L = L; t->par = 0.5 * t->omega * L; /* recompute the moments */ { size_t i; double scale = 1.0; for (i = 0 ; i < t->n; i++) { compute_moments (t->par * scale, t->chebmo + 25*i); scale *= 0.5; } } return GSL_SUCCESS; } void gsl_integration_qawo_table_free (gsl_integration_qawo_table * t) { RETURN_IF_NULL (t); free (t->chebmo); free (t); } static void compute_moments (double par, double *chebmo) { double v[28], d[25], d1[25], d2[25]; const size_t noeq = 25; const double par2 = par * par; const double par4 = par2 * par2; const double par22 = par2 + 2.0; const double sinpar = sin (par); const double cospar = cos (par); size_t i; /* compute the chebyschev moments with respect to cosine */ double ac = 8 * cospar; double as = 24 * par * sinpar; v[0] = 2 * sinpar / par; v[1] = (8 * cospar + (2 * par2 - 8) * sinpar / par) / par2; v[2] = (32 * (par2 - 12) * cospar + (2 * ((par2 - 80) * par2 + 192) * sinpar) / par) / par4; if (fabs (par) <= 24) { /* compute the moments as the solution of a boundary value problem using the asyptotic expansion as an endpoint */ double an2, ass, asap; double an = 6; size_t k; for (k = 0; k < noeq - 1; k++) { an2 = an * an; d[k] = -2 * (an2 - 4) * (par22 - 2 * an2); d2[k] = (an - 1) * (an - 2) * par2; d1[k + 1] = (an + 3) * (an + 4) * par2; v[k + 3] = as - (an2 - 4) * ac; an = an + 2.0; } an2 = an * an; d[noeq - 1] = -2 * (an2 - 4) * (par22 - 2 * an2); v[noeq + 2] = as - (an2 - 4) * ac; v[3] = v[3] - 56 * par2 * v[2]; ass = par * sinpar; asap = (((((210 * par2 - 1) * cospar - (105 * par2 - 63) * ass) / an2 - (1 - 15 * par2) * cospar + 15 * ass) / an2 - cospar + 3 * ass) / an2 - cospar) / an2; v[noeq + 2] = v[noeq + 2] - 2 * asap * par2 * (an - 1) * (an - 2); dgtsl (noeq, d1, d, d2, v + 3); } else { /* compute the moments by forward recursion */ size_t k; double an = 4; for (k = 3; k < 13; k++) { double an2 = an * an; v[k] = ((an2 - 4) * (2 * (par22 - 2 * an2) * v[k - 1] - ac) + as - par2 * (an + 1) * (an + 2) * v[k - 2]) / (par2 * (an - 1) * (an - 2)); an = an + 2.0; } } for (i = 0; i < 13; i++) { chebmo[2 * i] = v[i]; } /* compute the chebyschev moments with respect to sine */ v[0] = 2 * (sinpar - par * cospar) / par2; v[1] = (18 - 48 / par2) * sinpar / par2 + (-2 + 48 / par2) * cospar / par; ac = -24 * par * cospar; as = -8 * sinpar; if (fabs (par) <= 24) { /* compute the moments as the solution of a boundary value problem using the asyptotic expansion as an endpoint */ size_t k; double an2, ass, asap; double an = 5; for (k = 0; k < noeq - 1; k++) { an2 = an * an; d[k] = -2 * (an2 - 4) * (par22 - 2 * an2); d2[k] = (an - 1) * (an - 2) * par2; d1[k + 1] = (an + 3) * (an + 4) * par2; v[k + 2] = ac + (an2 - 4) * as; an = an + 2.0; } an2 = an * an; d[noeq - 1] = -2 * (an2 - 4) * (par22 - 2 * an2); v[noeq + 1] = ac + (an2 - 4) * as; v[2] = v[2] - 42 * par2 * v[1]; ass = par * cospar; asap = (((((105 * par2 - 63) * ass - (210 * par2 - 1) * sinpar) / an2 + (15 * par2 - 1) * sinpar - 15 * ass) / an2 - sinpar - 3 * ass) / an2 - sinpar) / an2; v[noeq + 1] = v[noeq + 1] - 2 * asap * par2 * (an - 1) * (an - 2); dgtsl (noeq, d1, d, d2, v + 2); } else { /* compute the moments by forward recursion */ size_t k; double an = 3; for (k = 2; k < 12; k++) { double an2 = an * an; v[k] = ((an2 - 4) * (2 * (par22 - 2 * an2) * v[k - 1] + as) + ac - par2 * (an + 1) * (an + 2) * v[k - 2]) / (par2 * (an - 1) * (an - 2)); an = an + 2.0; } } for (i = 0; i < 12; i++) { chebmo[2 * i + 1] = v[i]; } } static int dgtsl (size_t n, double *c, double *d, double *e, double *b) { /* solves a tridiagonal matrix A x = b c[1 .. n - 1] subdiagonal of the matrix A d[0 .. n - 1] diagonal of the matrix A e[0 .. n - 2] superdiagonal of the matrix A b[0 .. n - 1] right hand side, replaced by the solution vector x */ size_t k; c[0] = d[0]; if (n == 0) { return GSL_SUCCESS; } if (n == 1) { b[0] = b[0] / d[0] ; return GSL_SUCCESS; } d[0] = e[0]; e[0] = 0; e[n - 1] = 0; for (k = 0; k < n - 1; k++) { size_t k1 = k + 1; if (fabs (c[k1]) >= fabs (c[k])) { { double t = c[k1]; c[k1] = c[k]; c[k] = t; }; { double t = d[k1]; d[k1] = d[k]; d[k] = t; }; { double t = e[k1]; e[k1] = e[k]; e[k] = t; }; { double t = b[k1]; b[k1] = b[k]; b[k] = t; }; } if (c[k] == 0) { return GSL_FAILURE ; } { double t = -c[k1] / c[k]; c[k1] = d[k1] + t * d[k]; d[k1] = e[k1] + t * e[k]; e[k1] = 0; b[k1] = b[k1] + t * b[k]; } } if (c[n - 1] == 0) { return GSL_FAILURE; } b[n - 1] = b[n - 1] / c[n - 1]; b[n - 2] = (b[n - 2] - d[n - 2] * b[n - 1]) / c[n - 2]; for (k = n ; k > 2; k--) { size_t kb = k - 3; b[kb] = (b[kb] - d[kb] * b[kb + 1] - e[kb] * b[kb + 2]) / c[kb]; } return GSL_SUCCESS; }