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near2far.cpp
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near2far.cpp
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/* Copyright (C) 2005-2021 Massachusetts Institute of Technology.
*
* 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 2 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
/* Near-to-far field transformation: compute DFT of tangential fields on
a "near" surface, and use these (via the equivalence principle) to
compute the fields on a "far" surface via the homogeneous-medium Green's
function in 2d or 3d. */
#include "meep_internals.hpp"
#include <assert.h>
#include "config.h"
#include <math.h>
using namespace std;
namespace meep {
dft_near2far::dft_near2far(dft_chunk *F_, double fmin, double fmax, int Nf, double eps_, double mu_,
const volume &where_, const direction periodic_d_[2],
const int periodic_n_[2], const double periodic_k_[2],
const double period_[2])
: F(F_), eps(eps_), mu(mu_), where(where_) {
freq = meep::linspace(fmin, fmax, Nf);
for (int i = 0; i < 2; ++i) {
periodic_d[i] = periodic_d_[i];
periodic_n[i] = periodic_n_[i];
periodic_k[i] = periodic_k_[i];
period[i] = period_[i];
}
}
dft_near2far::dft_near2far(dft_chunk *F_, const std::vector<double> freq_, double eps_, double mu_,
const volume &where_, const direction periodic_d_[2],
const int periodic_n_[2], const double periodic_k_[2],
const double period_[2])
: F(F_), eps(eps_), mu(mu_), where(where_) {
freq = freq_;
for (int i = 0; i < 2; ++i) {
periodic_d[i] = periodic_d_[i];
periodic_n[i] = periodic_n_[i];
periodic_k[i] = periodic_k_[i];
period[i] = period_[i];
}
}
dft_near2far::dft_near2far(dft_chunk *F_, const double *freq_, size_t Nfreq, double eps_,
double mu_, const volume &where_, const direction periodic_d_[2],
const int periodic_n_[2], const double periodic_k_[2],
const double period_[2])
: F(F_), eps(eps_), mu(mu_), where(where_) {
freq.resize(Nfreq);
for (size_t i = 0; i < Nfreq; ++i)
freq[i] = freq_[i];
for (int i = 0; i < 2; ++i) {
periodic_d[i] = periodic_d_[i];
periodic_n[i] = periodic_n_[i];
periodic_k[i] = periodic_k_[i];
period[i] = period_[i];
}
}
dft_near2far::dft_near2far(const dft_near2far &f) : F(f.F), eps(f.eps), mu(f.mu), where(f.where) {
freq = f.freq;
for (int i = 0; i < 2; ++i) {
periodic_d[i] = f.periodic_d[i];
periodic_n[i] = f.periodic_n[i];
periodic_k[i] = f.periodic_k[i];
period[i] = f.period[i];
}
}
void dft_near2far::remove() {
while (F) {
dft_chunk *nxt = F->next_in_dft;
delete F;
F = nxt;
}
}
void dft_near2far::operator-=(const dft_near2far &st) {
if (F && st.F) *F -= *st.F;
}
void dft_near2far::save_hdf5(h5file *file, const char *dprefix) {
save_dft_hdf5(F, "F", file, dprefix);
}
void dft_near2far::load_hdf5(h5file *file, const char *dprefix) {
load_dft_hdf5(F, "F", file, dprefix);
}
void dft_near2far::save_hdf5(fields &f, const char *fname, const char *dprefix,
const char *prefix) {
h5file *ff = f.open_h5file(fname, h5file::WRITE, prefix);
save_hdf5(ff, dprefix);
delete ff;
}
void dft_near2far::load_hdf5(fields &f, const char *fname, const char *dprefix,
const char *prefix) {
h5file *ff = f.open_h5file(fname, h5file::READONLY, prefix);
load_hdf5(ff, dprefix);
delete ff;
}
void dft_near2far::scale_dfts(complex<double> scale) {
if (F) F->scale_dft(scale);
}
typedef void (*greenfunc)(std::complex<double> *EH, const vec &x, double freq, double eps,
double mu, const vec &x0, component c0, std::complex<double> f0);
/* Given the field f0 correponding to current-source component c0 at
x0, compute the E/H fields EH[6] (6 components) at x for a frequency
freq in the homogeneous 3d medium eps and mu.
Adapted from code by M. T. Homer Reid in his SCUFF-EM package
(file scuff-em/src/libs/libIncField/PointSource.cc), which is GPL v2+. */
void green3d(std::complex<double> *EH, const vec &x, double freq, double eps, double mu,
const vec &x0, component c0, std::complex<double> f0) {
vec rhat = x - x0;
double r = abs(rhat);
rhat = rhat / r;
if (rhat.dim != D3) abort("wrong dimensionality in green3d");
double n = sqrt(eps * mu);
double k = 2 * pi * freq * n;
std::complex<double> ikr = std::complex<double>(0.0, k * r);
double ikr2 = -(k * r) * (k * r);
/* note that SCUFF-EM computes the fields from the dipole moment p,
whereas we need it from the current J = -i*omega*p, so our result
is divided by -i*omega compared to SCUFF */
std::complex<double> expfac = f0 * polar(k * n / (4 * pi * r), k * r + pi * 0.5);
double Z = sqrt(mu / eps);
vec p = zero_vec(rhat.dim);
p.set_direction(component_direction(c0), 1);
double pdotrhat = p & rhat;
vec rhatcrossp = vec(rhat.y() * p.z() - rhat.z() * p.y(),
rhat.z() * p.x() - rhat.x() * p.z(),
rhat.x() * p.y() - rhat.y() * p.x());
/* compute the various scalar quantities in the point source formulae */
std::complex<double> term1 = 1.0 - 1.0 / ikr + 1.0 / ikr2;
std::complex<double> term2 = (-1.0 + 3.0 / ikr - 3.0 / ikr2) * pdotrhat;
std::complex<double> term3 = (1.0 - 1.0 / ikr);
/* now assemble everything based on source type */
if (is_electric(c0)) {
expfac /= eps;
EH[0] = expfac * (term1 * p.x() + term2 * rhat.x());
EH[1] = expfac * (term1 * p.y() + term2 * rhat.y());
EH[2] = expfac * (term1 * p.z() + term2 * rhat.z());
EH[3] = expfac * term3 * rhatcrossp.x() / Z;
EH[4] = expfac * term3 * rhatcrossp.y() / Z;
EH[5] = expfac * term3 * rhatcrossp.z() / Z;
}
else if (is_magnetic(c0)) {
expfac /= mu;
EH[0] = -expfac * term3 * rhatcrossp.x() * Z;
EH[1] = -expfac * term3 * rhatcrossp.y() * Z;
EH[2] = -expfac * term3 * rhatcrossp.z() * Z;
EH[3] = expfac * (term1 * p.x() + term2 * rhat.x());
EH[4] = expfac * (term1 * p.y() + term2 * rhat.y());
EH[5] = expfac * (term1 * p.z() + term2 * rhat.z());
}
else
abort("unrecognized source type");
}
// hankel function J + iY
#if defined(HAVE_JN)
static std::complex<double> hankel(int n, double x) {
return std::complex<double>(jn(n, x), yn(n, x));
}
#elif defined(HAVE_LIBGSL)
#include <gsl/gsl_sf_bessel.h>
static std::complex<double> hankel(int n, double x) {
return std::complex<double>(gsl_sf_bessel_Jn(n, x), gsl_sf_bessel_Yn(n, x));
}
#else /* !HAVE_LIBGSL */
static std::complex<double> hankel(int n, double x) {
(void)n;
(void)x; // unused
abort("GNU GSL library is required for Hankel functions");
}
#endif /* !HAVE_LIBGSL */
/* like green3d, but 2d Green's functions */
void green2d(std::complex<double> *EH, const vec &x, double freq, double eps, double mu,
const vec &x0, component c0, std::complex<double> f0) {
vec rhat = x - x0;
double r = abs(rhat);
rhat = rhat / r;
if (rhat.dim != D2) abort("wrong dimensionality in green2d");
double omega = 2 * pi * freq;
double k = omega * sqrt(eps * mu);
std::complex<double> ik = std::complex<double>(0.0, k);
double kr = k * r;
double Z = sqrt(mu / eps);
std::complex<double> H0 = hankel(0, kr) * f0;
std::complex<double> H1 = hankel(1, kr) * f0;
std::complex<double> ikH1 = 0.25 * ik * H1;
if (component_direction(c0) == meep::Z) {
if (is_electric(c0)) { // Ez source
EH[0] = EH[1] = 0.0;
EH[2] = (-0.25 * omega * mu) * H0;
EH[3] = -rhat.y() * ikH1;
EH[4] = rhat.x() * ikH1;
EH[5] = 0.0;
}
else /* (is_magnetic(c0)) */ { // Hz source
EH[0] = rhat.y() * ikH1;
EH[1] = -rhat.x() * ikH1;
EH[2] = 0.0;
EH[3] = EH[4] = 0.0;
EH[5] = (-0.25 * omega * eps) * H0;
}
}
else { /* in-plane source */
std::complex<double> H2 = hankel(2, kr) * f0;
vec p = zero_vec(rhat.dim);
p.set_direction(component_direction(c0), 1);
double pdotrhat = p & rhat;
double rhatcrossp = rhat.x() * p.y() - rhat.y() * p.x();
if (is_electric(c0)) { // Exy source
EH[0] = -(rhat.x() * (pdotrhat / r * 0.25 * Z)) * H1 +
(rhat.y() * (rhatcrossp * omega * mu * 0.125)) * (H0 - H2);
EH[1] = -(rhat.y() * (pdotrhat / r * 0.25 * Z)) * H1 -
(rhat.x() * (rhatcrossp * omega * mu * 0.125)) * (H0 - H2);
EH[2] = 0.0;
EH[3] = EH[4] = 0.0;
EH[5] = -rhatcrossp * ikH1;
}
else /* (is_magnetic(c0)) */ { // Hxy source
EH[0] = EH[1] = 0.0;
EH[2] = rhatcrossp * ikH1;
EH[3] = -(rhat.x() * (pdotrhat / r * 0.25 / Z)) * H1 +
(rhat.y() * (rhatcrossp * omega * eps * 0.125)) * (H0 - H2);
EH[4] = -(rhat.y() * (pdotrhat / r * 0.25 / Z)) * H1 -
(rhat.x() * (rhatcrossp * omega * eps * 0.125)) * (H0 - H2);
EH[5] = 0.0;
}
}
}
// cylindrical Green's function constructed by integrating green3d as the source
// term rotates around the z axis with exp(im*phi) dependence, integrated to a tolerance tol.
// (note: this is the Green's function divided by 2pi*x0.r(), to compensate for a 2piR factor
// in the near2far add_dft weight.)
void greencyl(std::complex<double> *EH, const vec &x, double freq, double eps, double mu,
const vec &x0, component c0, std::complex<double> f0, double m, double tol) {
if (x0.dim != Dcyl) abort("wrong dimensionality in greencyl");
vec x_3d(x.dim == Dcyl ? x.r() : x.x(), x.y(), x.z());
direction d = component_direction(c0);
component cx = direction_component(c0, X), cy = direction_component(c0, Y);
for (int j = 0; j < 6; ++j)
EH[j] = 0;
/* Perform phi integral. Since phi integrand is smooth, quadrature with equally spaced points
should converge exponentially fast with the number N of quadrature points. We
repeatedly double N until convergence to tol is achieved, re-using previous points. */
const int N0 = 4;
double dphi = 2.0 / N0; // factor of 2*pi*r is already included in add_dft weight
for (int N = N0; N <= 65536; N *= 2) {
std::complex<double> EH_sum[6];
dphi *= 0.5; // delta phi is halved because N doubles
double dphi2pi = dphi * 2 * pi;
for (int j = 0; j < 6; ++j)
EH_sum[j] = EH[j] * 0.5; // re-use previous quadrature points (with halved dphi)
/* N-point quadrature points i = 0..N-1. After the first iteration (N==N0), we
only need to sum over odd i, since the even i were summed for the previous N. */
for (int i = (N > N0); i < N; i += 1 + (N > N0)) {
double phi = i * dphi2pi, c = cos(phi), s = sin(phi);
vec x0_phi(x0.r() * c, x0.r() * s, x0.z()); // source point rotated by phi
std::complex<double> EH_phi[6], f0_exp_imphi = f0 * std::polar(1.0, m * phi) * dphi;
/* if the source direction is in the r or phi directions, then we must rotate
the direction of the source current in the xy plane as well */
if (d == Z) { // source currents in z direction don't rotate
green3d(EH_phi, x_3d, freq, eps, mu, x0_phi, c0, f0_exp_imphi);
for (int j = 0; j < 6; ++j)
EH_sum[j] += EH_phi[j];
}
else if (d == R) { // r_hat = c x_hat + s y_hat
green3d(EH_phi, x_3d, freq, eps, mu, x0_phi, cx, f0_exp_imphi * c);
for (int j = 0; j < 6; ++j)
EH_sum[j] += EH_phi[j];
green3d(EH_phi, x_3d, freq, eps, mu, x0_phi, cy, f0_exp_imphi * s);
for (int j = 0; j < 6; ++j)
EH_sum[j] += EH_phi[j];
}
else { // (d == P): phi_hat = c y_hat - s x_hat
green3d(EH_phi, x_3d, freq, eps, mu, x0_phi, cx, f0_exp_imphi * (-s));
for (int j = 0; j < 6; ++j)
EH_sum[j] += EH_phi[j];
green3d(EH_phi, x_3d, freq, eps, mu, x0_phi, cy, f0_exp_imphi * c);
for (int j = 0; j < 6; ++j)
EH_sum[j] += EH_phi[j];
}
}
// accumulate the new and old sums and check how much the integral has changed in L1 norm
double sumdiff = 0, sumabs = 0;
for (int j = 0; j < 6; ++j) {
sumdiff += abs(EH[j] - EH_sum[j]);
sumabs += abs(EH_sum[j]);
EH[j] = EH_sum[j];
}
if (sumdiff <= sumabs * tol) break; // doubling N changed sum by less than tol
}
}
void dft_near2far::farfield_lowlevel(std::complex<double> *EH, const vec &x) {
if (x.dim != D3 && x.dim != D2 && x.dim != Dcyl)
abort("only 2d or 3d or cylindrical far-field computation is supported");
greenfunc green = x.dim == D2 ? green2d : green3d;
const size_t Nfreq = freq.size();
for (size_t i = 0; i < 6 * Nfreq; ++i)
EH[i] = 0.0;
for (dft_chunk *f = F; f; f = f->next_in_dft) {
assert(Nfreq == f->omega.size());
component c0 = component(f->vc); /* equivalent source component */
vec rshift(f->shift * (0.5 * f->fc->gv.inva));
#ifdef HAVE_OPENMP
#pragma omp parallel for
#endif
for (size_t i = 0; i < Nfreq; ++i) {
std::complex<double> EH6[6];
size_t idx_dft = 0;
LOOP_OVER_IVECS(f->fc->gv, f->is, f->ie, idx) {
IVEC_LOOP_LOC(f->fc->gv, x0);
x0 = f->S.transform(x0, f->sn) + rshift;
vec xs(x0);
for (int i0 = -periodic_n[0]; i0 <= periodic_n[0]; ++i0) {
if (periodic_d[0] != NO_DIRECTION)
xs.set_direction(periodic_d[0], x0.in_direction(periodic_d[0]) + i0 * period[0]);
double phase0 = i0 * periodic_k[0];
for (int i1 = -periodic_n[1]; i1 <= periodic_n[1]; ++i1) {
if (periodic_d[1] != NO_DIRECTION)
xs.set_direction(periodic_d[1], x0.in_direction(periodic_d[1]) + i1 * period[1]);
double phase = phase0 + i1 * periodic_k[1];
std::complex<double> cphase = std::polar(1.0, phase);
if (x.dim == Dcyl)
greencyl(EH6, x, freq[i], eps, mu, xs, c0, f->dft[Nfreq * idx_dft + i], f->fc->m,
1e-3);
else
green(EH6, x, freq[i], eps, mu, xs, c0, f->dft[Nfreq * idx_dft + i]);
for (int j = 0; j < 6; ++j)
EH[i * 6 + j] += EH6[j] * cphase;
}
}
idx_dft++;
}
}
}
}
std::complex<double> *dft_near2far::farfield(const vec &x) {
std::complex<double> *EH, *EH_local;
const size_t Nfreq = freq.size();
EH_local = new std::complex<double>[6 * Nfreq];
farfield_lowlevel(EH_local, x);
EH = new std::complex<double>[6 * Nfreq];
sum_to_all(EH_local, EH, 6 * Nfreq);
delete[] EH_local;
return EH;
}
double *dft_near2far::get_farfields_array(const volume &where, int &rank, size_t *dims, size_t &N,
double resolution) {
/* compute output grid size etc. */
double dx[3] = {0, 0, 0};
direction dirs[3] = {X, Y, Z};
rank = 0;
N = dims[0] = dims[1] = dims[2] = 1;
LOOP_OVER_DIRECTIONS(where.dim, d) {
dims[rank] = int(floor(where.in_direction(d) * resolution));
if (dims[rank] <= 1)
dims[rank] = 1;
else
dx[rank] = where.in_direction(d) / (dims[rank] - 1);
N *= dims[rank];
dirs[rank++] = d;
}
if (where.dim == Dcyl) dirs[2] = P; // otherwise Z is listed twice
const size_t Nfreq = freq.size();
if (N * Nfreq < 1) return NULL; /* nothing to output */
/* 6 x 2 x N x Nfreq array of fields in row-major order */
double *EH = new double[6 * 2 * N * Nfreq];
double *EH_ = new double[6 * 2 * N * Nfreq]; // temp array for sum_to_all
/* fields for farfield_lowlevel for a single output point x */
std::complex<double> *EH1 = new std::complex<double>[6 * Nfreq];
double start = wall_time();
size_t last_point = 0;
vec x(where.dim);
for (size_t i0 = 0; i0 < dims[0]; ++i0) {
x.set_direction(dirs[0], where.in_direction_min(dirs[0]) + i0 * dx[0]);
for (size_t i1 = 0; i1 < dims[1]; ++i1) {
x.set_direction(dirs[1], where.in_direction_min(dirs[1]) + i1 * dx[1]);
for (size_t i2 = 0; i2 < dims[2]; ++i2) {
x.set_direction(dirs[2], where.in_direction_min(dirs[2]) + i2 * dx[2]);
double t;
if (verbosity > 0 && (t = wall_time()) > start + MEEP_MIN_OUTPUT_TIME) {
size_t this_point = (dims[1] * i0 + i1) * dims[2] + i2 + 1;
master_printf("get_farfields_array working on point %zu of %zu (%d%% done), %g s/point\n",
this_point, N, (int)((double)this_point / N * 100),
(t - start) / (std::max(1, (int)(this_point - last_point))));
start = t;
last_point = this_point;
}
farfield_lowlevel(EH1, x);
if (verbosity > 1) all_wait(); // Allow consistent progress updates from master
ptrdiff_t idx = (i0 * dims[1] + i1) * dims[2] + i2;
for (size_t i = 0; i < Nfreq; ++i)
for (int k = 0; k < 6; ++k) {
EH_[((k * 2 + 0) * N + idx) * Nfreq + i] = real(EH1[i * 6 + k]);
EH_[((k * 2 + 1) * N + idx) * Nfreq + i] = imag(EH1[i * 6 + k]);
}
}
}
}
sum_to_all(EH_, EH, 6 * 2 * N * Nfreq);
/* collapse singleton dimensions */
int ireduced = 0;
for (int i = 0; i < rank; ++i) {
if (dims[i] > 1) dims[ireduced++] = dims[i];
}
rank = ireduced;
delete[] EH_;
delete[] EH1;
return EH;
}
void dft_near2far::save_farfields(const char *fname, const char *prefix, const volume &where,
double resolution) {
size_t dims[4] = {1, 1, 1, 1};
int rank = 0;
size_t N = 1;
double *EH = get_farfields_array(where, rank, dims, N, resolution);
if (!EH) return; /* nothing to output */
const size_t Nfreq = freq.size();
/* frequencies are the last dimension */
if (Nfreq > 1) dims[rank++] = Nfreq;
/* output to a file with one dataset per component & real/imag part */
if (am_master()) {
const int buflen = 1024;
static char filename[buflen];
snprintf(filename, buflen, "%s%s%s.h5", prefix ? prefix : "", prefix && prefix[0] ? "-" : "",
fname);
h5file ff(filename, h5file::WRITE, false);
component c[6] = {Ex, Ey, Ez, Hx, Hy, Hz};
char dataname[128];
for (int k = 0; k < 6; ++k)
for (int reim = 0; reim < 2; ++reim) {
snprintf(dataname, 128, "%s.%c", component_name(c[k]), "ri"[reim]);
ff.write(dataname, rank, dims, EH + (k * 2 + reim) * N * Nfreq);
}
}
delete[] EH;
}
double *dft_near2far::flux(direction df, const volume &where, double resolution) {
if (coordinate_mismatch(where.dim, df) || where.dim == Dcyl)
abort("cannot get flux for near2far: co-ordinate mismatch");
size_t dims[4] = {1, 1, 1, 1};
int rank = 0;
size_t N = 1;
double *EH = get_farfields_array(where, rank, dims, N, resolution);
const size_t Nfreq = freq.size();
double *F = new double[Nfreq];
std::complex<double> ff_EH[6];
std::complex<double> cE[2], cH[2];
for (size_t i = 0; i < Nfreq; ++i)
F[i] = 0;
for (size_t idx = 0; idx < N; ++idx) {
for (size_t i = 0; i < Nfreq; ++i) {
for (int k = 0; k < 6; ++k)
ff_EH[k] = std::complex<double>(*(EH + ((k * 2 + 0) * N + idx) * Nfreq + i),
*(EH + ((k * 2 + 1) * N + idx) * Nfreq + i));
switch (df) {
case X: cE[0] = ff_EH[1], cE[1] = ff_EH[2], cH[0] = ff_EH[5], cH[1] = ff_EH[4]; break;
case Y: cE[0] = ff_EH[2], cE[1] = ff_EH[0], cH[0] = ff_EH[3], cH[1] = ff_EH[5]; break;
case Z: cE[0] = ff_EH[0], cE[1] = ff_EH[1], cH[0] = ff_EH[4], cH[1] = ff_EH[3]; break;
case R:
case P:
case NO_DIRECTION: abort("invalid flux direction");
}
for (int j = 0; j < 2; ++j)
F[i] += real(cE[j] * conj(cH[j])) * (1 - 2 * j);
}
}
double dV = 1;
LOOP_OVER_DIRECTIONS(where.dim, d) {
int dim = int(floor(where.in_direction(d) * resolution));
if (dim > 1) dV *= where.in_direction(d) / (dim - 1);
}
for (size_t i = 0; i < Nfreq; ++i)
F[i] *= dV;
delete[] EH;
return F;
}
static double approxeq(double a, double b) { return fabs(a - b) < 0.5e-11 * (fabs(a) + fabs(b)); }
dft_near2far fields::add_dft_near2far(const volume_list *where, const double *freq, size_t Nfreq,
int Nperiods) {
dft_chunk *F = 0; /* E and H chunks*/
double eps = 0, mu = 0;
volume everywhere = where->v;
direction periodic_d[2] = {NO_DIRECTION, NO_DIRECTION};
int periodic_n[2] = {0, 0};
double periodic_k[2] = {0, 0}, period[2] = {0, 0};
for (const volume_list *w = where; w; w = w->next) {
everywhere = everywhere | where->v;
direction nd = component_direction(w->c);
if (nd == NO_DIRECTION) nd = normal_direction(w->v);
if (nd == NO_DIRECTION) abort("unknown dft_near2far normal");
direction fd[2];
double weps = real(get_eps(w->v.center()));
double wmu = real(get_mu(w->v.center()));
if (w != where && !(approxeq(eps, weps) && approxeq(mu, wmu)))
abort("dft_near2far requires surfaces in a homogeneous medium");
eps = weps;
mu = wmu;
/* two transverse directions to normal (in cyclic order to get
correct sign s below) */
switch (nd) {
case X:
fd[0] = Y;
fd[1] = Z;
break;
case Y:
fd[0] = Z;
fd[1] = X;
break;
case R:
fd[0] = P;
fd[1] = Z;
break;
case P:
fd[0] = Z;
fd[1] = R;
break;
case Z:
if (gv.dim == Dcyl)
fd[0] = R, fd[1] = P;
else
fd[0] = X, fd[1] = Y;
break;
default: abort("invalid normal direction in dft_near2far!");
}
if (Nperiods > 1) {
for (int i = 0; i < 2; ++i) {
double user_width = user_volume.num_direction(fd[i]) / a;
if (has_direction(v.dim, fd[i]) && boundaries[High][fd[i]] == Periodic &&
boundaries[Low][fd[i]] == Periodic &&
float(w->v.in_direction(fd[i])) >= float(user_width)) {
periodic_d[i] = fd[i];
periodic_n[i] = Nperiods;
period[i] = user_width;
periodic_k[i] = 2 * pi * real(k[fd[i]]) * period[i];
}
}
}
for (int i = 0; i < 2; ++i) { /* E or H */
for (int j = 0; j < 2; ++j) { /* first or second component */
component c = direction_component(i == 0 ? Ex : Hx, fd[j]);
/* find equivalent source component c0 and sign s */
component c0 = direction_component(i == 0 ? Hx : Ex, fd[1 - j]);
double s = j == 0 ? 1 : -1; /* sign of n x c */
if (is_electric(c)) s = -s;
F = add_dft(c, w->v, freq, Nfreq, true, s * w->weight, F, false, 1.0, false, c0);
}
}
}
return dft_near2far(F, freq, Nfreq, eps, mu, everywhere, periodic_d, periodic_n, periodic_k,
period);
}
//Modified from farfield_lowlevel
std::vector<struct sourcedata> dft_near2far::near_sourcedata(const vec &x_0, double* farpt_list, size_t nfar_pts, std::complex<double>* dJ) {
if (x_0.dim != D3 && x_0.dim != D2 && x_0.dim != Dcyl)
abort("only 2d or 3d or cylindrical far-field computation is supported");
greenfunc green = x_0.dim == D2 ? green2d : green3d;
const size_t Nfreq = freq.size();
std::vector<struct sourcedata> temp;
for (dft_chunk *f = F; f; f = f->next_in_dft) {
assert(Nfreq == f->omega.size());
std::vector<ptrdiff_t> idx_arr;
std::vector<std::complex<double> > amp_arr;
component c0 = component(f->vc); /* equivalent source component */
vec rshift(f->shift * (0.5 * f->fc->gv.inva));
std::complex<double> EH6[6];
size_t idx_dft = 0;
sourcedata temp_struct = {component(f->c), idx_arr, f->fc->chunk_idx, amp_arr};
LOOP_OVER_IVECS(f->fc->gv, f->is, f->ie, idx) {
IVEC_LOOP_ILOC(f->fc->gv, ix0);
IVEC_LOOP_LOC(f->fc->gv, x0);
x0 = f->S.transform(x0, f->sn) + rshift;
vec xs(x0);
double w;
w = IVEC_LOOP_WEIGHT(f->s0, f->s1, f->e0, f->e1, f->dV0 + f->dV1 * loop_i2);
temp_struct.idx_arr.push_back(idx);
for (size_t i = 0; i < Nfreq; ++i) {
std::complex<double> EH0 = std::complex<double>(0,0);
for (int i0 = -periodic_n[0]; i0 <= periodic_n[0]; ++i0) {
if (periodic_d[0] != NO_DIRECTION)
xs.set_direction(periodic_d[0], x0.in_direction(periodic_d[0]) + i0 * period[0]);
double phase0 = i0 * periodic_k[0];
for (int i1 = -periodic_n[1]; i1 <= periodic_n[1]; ++i1) {
if (periodic_d[1] != NO_DIRECTION)
xs.set_direction(periodic_d[1], x0.in_direction(periodic_d[1]) + i1 * period[1]);
double phase = phase0 + i1 * periodic_k[1];
std::complex<double> cphase = std::polar(1.0, phase);
for (size_t ipt = 0; ipt < nfar_pts; ++ipt){
vec x = vec(farpt_list[3*ipt], farpt_list[3*ipt+1], farpt_list[3*ipt+2]);
if (x_0.dim == Dcyl)
greencyl(EH6, x, freq[i], eps, mu, xs, c0, w, f->fc->m, 1e-3);
else
green(EH6, x, freq[i], eps, mu, xs, c0, w);
for (int j = 0; j < 6; ++j)
EH0 += EH6[j] * cphase * (f->stored_weight) * dJ[6*Nfreq*ipt + 6*i + j];
}
}
}
idx_dft++;
if (is_electric(temp_struct.near_fd_comp))
EH0 *= -1;
EH0 /= f->S.multiplicity(ix0);
temp_struct.amp_arr.push_back(EH0);
}
}
temp.push_back(temp_struct);
}
return temp;
}
} // namespace meep