#include "scattering.h" #include "quantum_efficiency.h" #include #include #include #include #include "optics.h" #include "sno.h" #include /* for size_t */ #include /* for exit() */ #include /* for fprintf() */ #include /* for gsl_strerror() */ #include "pdg.h" #include #include static double xlo = -1.0; static double xhi = 1.0; static size_t nx = 200; static double ylo = 0.0; static double yhi = 1.0; static size_t ny = 1000; static double *x; static double *y; static double *z; static gsl_spline2d *spline; static gsl_interp_accel *xacc; static gsl_interp_accel *yacc; static double x2lo = 0.0; static double x2hi = 1.0; static size_t nx2 = 1000; static double *x2; static double *y2; static gsl_spline *spline2; static gsl_interp_accel *xacc2; static double prob_scatter(double wavelength, void *params) { /* Calculate the number of photons emitted per unit solid angle per cm at * an angle `theta` for a particle travelling with velocity `beta` with an * angular distribution of width `theta0`. */ double qe, delta, index; double beta_cos_theta = ((double *) params)[0]; double beta_sin_theta_theta0 = ((double *) params)[1]; qe = get_quantum_efficiency(wavelength); index = get_index_snoman_d2o(wavelength); delta = (1.0/index - beta_cos_theta)/beta_sin_theta_theta0; return qe*exp(-pow(delta,2)/2.0)/pow(wavelength,2)*1e7/sqrt(2*M_PI); } static double prob_scatter2(double wavelength, void *params) { /* Calculate the number of photons emitted per per cm for a particle * travelling with velocity `beta`. */ double qe, index; double beta = ((double *) params)[0]; qe = get_quantum_efficiency(wavelength); index = get_index_snoman_d2o(wavelength); return 2*M_PI*FINE_STRUCTURE_CONSTANT*(1-(1/(beta*beta*index*index)))*qe/pow(wavelength,2)*1e7; } void init_interpolation(void) { size_t i, j; double params[2]; double result, error; size_t nevals; int status; gsl_integration_cquad_workspace *w; gsl_function F; x = malloc(nx*sizeof(double)); y = malloc(ny*sizeof(double)); z = malloc(nx*ny*sizeof(double)); spline = gsl_spline2d_alloc(gsl_interp2d_bilinear, nx, ny); xacc = gsl_interp_accel_alloc(); yacc = gsl_interp_accel_alloc(); for (i = 0; i < nx; i++) { x[i] = xlo + (xhi-xlo)*i/(nx-1); } for (i = 0; i < ny; i++) { y[i] = ylo + (yhi-ylo)*i/(ny-1); } w = gsl_integration_cquad_workspace_alloc(100); F.function = &prob_scatter; F.params = params; for (i = 0; i < nx; i++) { for (j = 0; j < ny; j++) { params[0] = x[i]; params[1] = y[j]; status = gsl_integration_cquad(&F, 200, 800, 0, 1e-2, w, &result, &error, &nevals); if (status) { fprintf(stderr, "error integrating photon angular distribution: %s\n", gsl_strerror(status)); exit(1); } gsl_spline2d_set(spline, z, i, j, result); } } gsl_spline2d_init(spline, x, y, z, nx, ny); x2 = malloc(nx2*sizeof(double)); y2 = malloc(nx2*sizeof(double)); spline2 = gsl_spline_alloc(gsl_interp_linear, nx2); xacc2 = gsl_interp_accel_alloc(); for (i = 0; i < nx2; i++) { x2[i] = x2lo + (x2hi-x2lo)*i/(nx2-1); } F.function = &prob_scatter2; F.params = params; for (i = 0; i < nx2; i++) { params[0] = x2[i]; status = gsl_integration_cquad(&F, 200, 800, 0, 1e-2, w, &result, &error, &nevals); if (status) { fprintf(stderr, "error integrating photon angular distribution: %s\n", gsl_strerror(status)); exit(1); } y2[i] = result; } gsl_spline_init(spline2, x2, y2, nx2); gsl_integration_cquad_workspace_free(w); } double get_probability(double beta, double cos_theta, double theta0) { double sin_theta; /* Technically this isn't defined up to a sign, but it doesn't matter since * we are going to square it everywhere. */ sin_theta = fabs(sin(acos(cos_theta))); return gsl_spline2d_eval(spline, beta*cos_theta, beta*sin_theta*theta0, xacc, yacc)/(theta0*sin_theta); } double get_probability2(double beta) { return gsl_spline_eval(spline2, beta, xacc2); } void free_interpolation(void) { free(x); free(y); free(z); gsl_spline2d_free(spline); gsl_interp_accel_free(xacc); gsl_interp_accel_free(yacc); }