openEMS/matlab/private/ReadNF2FF.m

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Matlab
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function nf2ff = ReadNF2FF(nf2ff)
% function nf2ff = ReadNF2FF(nf2ff)
%
% internal function to read calculated nf2ff data, use CalcNF2FF to read
% existing nf2ff data
%
% See also: CalcNF2FF, CreateNF2FFBox
%
% openEMS matlab interface
% -----------------------
% author: Thorsten Liebig, 2012
file = nf2ff.hdf5;
hdf_mesh = ReadHDF5Mesh(file);
nf2ff.r = double(hdf_mesh.lines{1});
nf2ff.theta = double(hdf_mesh.lines{2});
nf2ff.phi = double(hdf_mesh.lines{3});
% read attributes
nf2ff.freq = ReadHDF5Attribute(file,'/nf2ff','Frequency');
nf2ff.Prad = ReadHDF5Attribute(file,'/nf2ff','Prad');
nf2ff.Dmax = ReadHDF5Attribute(file,'/nf2ff','Dmax');
try
nf2ff.Eps_r = ReadHDF5Attribute(file,'/nf2ff','Eps_r');
catch
nf2ff.Eps_r = ones(size(nf2ff.freq));
end
try
nf2ff.Mue_r = ReadHDF5Attribute(file,'/nf2ff','Mue_r');
catch
nf2ff.Mue_r = ones(size(nf2ff.freq));
end
if isOctave
hdf = load( '-hdf5', file );
for n=1:numel(nf2ff.freq)
nf2ff.E_theta{n} = double(hdf.nf2ff.E_theta.FD.(['f' int2str(n-1) '_real']) +1i*hdf.nf2ff.E_theta.FD.(['f' int2str(n-1) '_imag']) );
nf2ff.E_phi{n} = double(hdf.nf2ff.E_phi.FD.(['f' int2str(n-1) '_real']) +1i*hdf.nf2ff.E_phi.FD.(['f' int2str(n-1) '_imag']) );
nf2ff.E_norm{n} = double(sqrt(abs(nf2ff.E_theta{n}).^2+abs(nf2ff.E_phi{n}).^2));
nf2ff.P_rad{n} = double(hdf.nf2ff.P_rad.FD.(['f' int2str(n-1)]));
end
else
% matlab compatibility to older versions
if verLessThan('matlab','7.12')
% read data
for n=1:numel(nf2ff.freq)
nf2ff.E_theta{n} = double(hdf5read(file,['/nf2ff/E_theta/FD/f' int2str(n-1) '_real']) + 1i*hdf5read(file,['/nf2ff/E_theta/FD/f' int2str(n-1) '_imag']));
nf2ff.E_phi{n} = double(hdf5read(file,['/nf2ff/E_phi/FD/f' int2str(n-1) '_real']) + 1i*hdf5read(file,['/nf2ff/E_phi/FD/f' int2str(n-1) '_imag']));
nf2ff.E_norm{n} = double(sqrt(abs(nf2ff.E_theta{n}).^2+abs(nf2ff.E_phi{n}).^2));
nf2ff.P_rad{n} = double(hdf5read(file,['/nf2ff/P_rad/FD/f' int2str(n-1)]));
end
else
% read data
for n=1:numel(nf2ff.freq)
nf2ff.E_theta{n} = double(h5read(file,['/nf2ff/E_theta/FD/f' int2str(n-1) '_real']) + 1i*h5read(file,['/nf2ff/E_theta/FD/f' int2str(n-1) '_imag']));
nf2ff.E_phi{n} = double(h5read(file,['/nf2ff/E_phi/FD/f' int2str(n-1) '_real']) + 1i*h5read(file,['/nf2ff/E_phi/FD/f' int2str(n-1) '_imag']));
nf2ff.E_norm{n} = double(sqrt(abs(nf2ff.E_theta{n}).^2+abs(nf2ff.E_phi{n}).^2));
nf2ff.P_rad{n} = double(h5read(file,['/nf2ff/P_rad/FD/f' int2str(n-1)]));
end
end
end
% Calculation of right- and left-handed circular polarization
% adopted from
% 2012, Tim Pegg <teepegg@gmail.com>
% cleanup (if exist)
nf2ff.E_cprh = [];
nf2ff.E_cplh = [];
% Setup vectors for converting to LHCP and RHCP polarization senses
[THETHA PHI] = ndgrid(nf2ff.theta,nf2ff.phi);
cosphi = cos(PHI);
sinphi = sin(PHI);
for f=1:numel(nf2ff.freq)
nf2ff.E_cprh{f} = (cosphi+1i*sinphi) .* (nf2ff.E_theta{f}+1i*nf2ff.E_phi{f})/sqrt(2);
nf2ff.E_cplh{f} = (cosphi-1i*sinphi) .* (nf2ff.E_theta{f}-1i*nf2ff.E_phi{f})/sqrt(2);
end