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example_script_opg.m
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130 lines (122 loc) · 6.18 KB
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clear inputs
inputs.opg_2d_wavelengths = [1200,2400,800]; % wavelengths [nm]
inputs.opg_2d_ref_inds = [2.14,2.11,2.17];% ref ind
inputs.opg_2d_gvi = [2.16,2.17,2.18]; % gvi
inputs.opg_2d_gdd = [0,0,0]; % gdd
inputs.opg_2d_phase = [0,0,0]; % phases
inputs.opg_2d_input_refl = [0,0,0]; % input reflectiviy
inputs.opg_2d_output_refl = [0,0,0]; % output reflectivity
inputs.opg_2d_crystal_losses=[0,0,0]; % crystal loss
inputs.opg_2d_n2_red1 = [0,0,0]; % n2 (red1)
inputs.opg_2d_n2_red2 = [0,0,0]; % n2 (red2)
inputs.opg_2d_n2_blue = [0,0,0]; % n2 (blue)
inputs.opg_2d_beta_red1 = [0,0,0]; % beta (red1)
inputs.opg_2d_beta_red2 = [0,0,0]; % beta (red2)
inputs.opg_2d_beta_blue = [0,0,0]; % beta (blue)
inputs.opg_2d_pulseenergy = [0,1e-17,1e-6]; % pulse energies
inputs.opg_2d_pulse_durations = [1,1,1;3,3,1].'; % pulse durations
inputs.opg_2d_pulse_delays =[0,0]; % pulse delays
inputs.opg_2d_pulse_chirps =[0,0,0]; % pulse chirps
inputs.opg_2d_beam_diameters = [0.0963,0.137,0.0781;0.0963,0.137,0.0781].';% beam diam
inputs.opg_2d_supergaussian_coeff = [1,1,1];% supergaussian coeff
inputs.opg_2d_wo_angles = [0,0,0]; % wo angles
inputs.opg_2d_offset_wodir =[0,0,0]; % offset in wo dir
inputs.opg_2d_rad_curv = [34.8,35.8,34.6;34.8,35.8,34.6].'; % rad curv
inputs.opg_2d_nz = 300; % nz
inputs.opg_2d_nxny = [128,128]; % nx_ny
inputs.opg_2d_grid_duration = 6; % grid duration [ps]
inputs.opg_2d_crystal_length = 30; % crystal length
inputs.opg_2d_lx_ly = [0.8,0.8]; % Lx, Ly
inputs.opg_2d_deff = 15; % deff
inputs.opg_2d_deltak = 0; % deltak
inputs.opg_2d_dist_to_image = 0; % dist to image
inputs.opg_2d_nt = 256; % nt
% blue_energy_vec = (5:5:20)*1e-7;
blue_energy_vec = (4:2:20)*1e-9;
n_runs_per_energy = 5;
% max_tilt = 6.5e4;
clear problem
red1_spectra = cell(length(blue_energy_vec),n_runs_per_energy);
red2_spectra = cell(length(blue_energy_vec),n_runs_per_energy);
blue_spectra = cell(length(blue_energy_vec),n_runs_per_energy);
output_energies = zeros(length(blue_energy_vec),3,n_runs_per_energy);
red1_spectral_widths = zeros(length(blue_energy_vec),n_runs_per_energy);
red1_spectral_centroid = zeros(length(blue_energy_vec),n_runs_per_energy);
red2_spectral_widths = zeros(length(blue_energy_vec),n_runs_per_energy);
red2_spectral_centroid = zeros(length(blue_energy_vec),n_runs_per_energy);
blue_spectral_widths = zeros(length(blue_energy_vec),n_runs_per_energy);
blue_spectral_centroid = zeros(length(blue_energy_vec),n_runs_per_energy);
avg_m2 = zeros(3,2,length(blue_energy_vec),n_runs_per_energy);
efficiencies = zeros(length(blue_energy_vec),n_runs_per_energy);
% low_tilt_spectra = cell(length(blue_energy_vec),n_runs_per_energy);
for K = 1:length(blue_energy_vec)
%generate inputs
problem(K) = inputs;
problem(K).opg_2d_pulseenergy(3) = blue_energy_vec(K);
for J = 1:n_runs_per_energy
fcn_handles = snlo_opg_func(problem(K));
% keyboard;
run_handle = fcn_handles{1};
accept_handle = fcn_handles{2};
spectra_handle = fcn_handles{3};
analyze_handle = fcn_handles{4};
% k_perp_filter_handle = fcn_handles{5};
% k_perp_filter_accept_handle = fcn_handles{6};
close_handle = fcn_handles{end};
% keyboard;
accept_handle();
run_handle();
spectra_handle();
analyze_handle();
% k_perp_filter_handle(max_tilt);
% pause(1);
% k_perp_filter_accept_handle();
% k_perp_filter_accept_handle(max_tilt);
output = load('opg_2d_output.mat');
output_energies(K,1,J) = trapz(output.power(:,1),output.power(:,2));
output_energies(K,2,J) = trapz(output.power(:,1),output.power(:,3));
output_energies(K,3,J) = trapz(output.power(:,1),output.power(:,4));
red1_spectrum = load('OPG_BEAM_3WS.DAT');
red1_spectra{K,J} = red1_spectrum;
red1_spectrum = red1_spectrum(:,1:2);
freqs = red1_spectrum(:,1);
amps = red1_spectrum(:,2);
y = cumsum(amps)./sum(amps);
ind1 = find(y>=0.1,1,'first');
ind2 = find(y>=0.9,1,'first');
red1_spectral_widths(K,J) = freqs(ind2) - freqs(ind1);
red1_spectral_centroid(K,J) = trapz(freqs,freqs.*amps)./trapz(freqs,amps);
red2_spectrum = load('OPG_BEAM_3WI.DAT');
red2_spectra{K,J} = red2_spectrum;
red2_spectrum = red2_spectrum(:,1:2);
freqs = red2_spectrum(:,1);
amps = red2_spectrum(:,2);
y = cumsum(amps)./sum(amps);
ind1 = find(y>=0.1,1,'first');
ind2 = find(y>=0.9,1,'first');
red2_spectral_widths(K,J) = freqs(ind2) - freqs(ind1);
red2_spectral_centroid(K,J) = trapz(freqs,freqs.*amps)./trapz(freqs,amps);
blue_spectrum = load('OPG_BEAM_3WP.DAT');
blue_spectra{K,J} = blue_spectrum;
blue_spectrum = blue_spectrum(:,1:2);
freqs = blue_spectrum(:,1);
amps = blue_spectrum(:,2);
y = cumsum(amps)./sum(amps);
ind1 = find(y>=0.1,1,'first');
ind2 = find(y>=0.9,1,'first');
blue_spectral_widths(K,J) = freqs(ind2) - freqs(ind1);
blue_spectral_centroid(K,J) = trapz(freqs,freqs.*amps)./trapz(freqs,amps);
m2s = load('opg_2d_beam_analysis.mat','avg_msquared');
avg_m2(:,:,K,J) = m2s.avg_msquared;
% (input_energy - data.output_energies(:,3).')./input_energy;
efficiencies(K,J) = (blue_energy_vec(K) - output_energies(K,3,J))./blue_energy_vec(K);
% low_tilt_spectra{K,J} = load('low_tilt_spectra.mat');
end
% run opg model
% load output (specifically output energies)
save('opg_batch.mat','inputs','problem','blue_energy_vec','output_energies',...
'avg_m2','red1_spectral_widths','red1_spectral_centroid',...
'red2_spectral_widths','red2_spectral_centroid',...
'blue_spectral_widths','blue_spectral_centroid','red1_spectra','red2_spectra','efficiencies');
% 'blue_spectral_widths','blue_spectral_centroid','red1_spectra','red2_spectra','low_tilt_spectra');
end