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author | Eugeniy Mikhailov <evgmik@gmail.com> | 2011-11-16 14:49:14 -0500 |
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committer | Eugeniy E. Mikhailov <evgmik@gmail.com> | 2020-09-21 16:29:52 -0400 |
commit | 46ed078564656957a69e52b69922bfa6a52488ad (patch) | |
tree | ffa5538adc6b2cfc9d8bff7602c8583e9c307f96 /faraday | |
parent | 4c4d562bc5c87deb828ede01a27b3fa9132f580e (diff) | |
download | multi_mode_eit-46ed078564656957a69e52b69922bfa6a52488ad.tar.gz multi_mode_eit-46ed078564656957a69e52b69922bfa6a52488ad.zip |
faraday works now
Diffstat (limited to 'faraday')
-rw-r--r-- | faraday/faraday_vs_B.m | 23 | ||||
-rw-r--r-- | faraday/output_faraday_results_vs_B.m | 16 | ||||
-rw-r--r-- | faraday/run_me.m | 25 |
3 files changed, 47 insertions, 17 deletions
diff --git a/faraday/faraday_vs_B.m b/faraday/faraday_vs_B.m index 11ba11b..733657e 100644 --- a/faraday/faraday_vs_B.m +++ b/faraday/faraday_vs_B.m @@ -14,6 +14,9 @@ detuning_p=0; N_steps=length(B_fields) kappa_p =zeros(1,N_steps+1); kappa_m =zeros(1,N_steps+1); +xi_linear=zeros(1,N_steps); +xi_left =zeros(1,N_steps); +xi_right =zeros(1,N_steps); % load useful functions; useful_functions; @@ -26,7 +29,7 @@ basis_transformation; % load subroutines fprintf (stderr, "tuning laser in forloop to set conditions vs detuning\n"); fflush (stderr); for B_field_cntr=1:N_steps; - B_field=B_fields(B_field_cntr); + B_field=B_fields(B_field_cntr) % load atom energy levels and decay description rb87_D1_line; @@ -121,18 +124,20 @@ for B_field_cntr=1:N_steps; atom_field_problem.modulation_freq = modulation_freq; atom_field_problem.freq_index = freq_index; - problems_cell_array{B_field_cntr}=atom_field_problem; - -endfor - + problems_cell_array=atom_field_problem; + save '/tmp/problem_definition.mat' problems_cell_array atom_properties detuning_freq ; fprintf (stderr, "now really hard calculations begin\n"); fflush (stderr); -% once we define all problems the main job is done here -[xi_linear, xi_left, xi_right]=parcellfun(2, @susceptibility_steady_state_at_freq, problems_cell_array); -%[xi_linear, xi_left, xi_right]=cellfun( @susceptibility_steady_state_at_freq, problems_cell_array); + [xi_linear_i, xi_left_i, xi_right_i]=susceptibility_steady_state_at_freq( problems_cell_array); + %[xi_linear, xi_left, xi_right]=cellfun( @susceptibility_steady_state_at_freq, problems_cell_array); + xi_left(B_field_cntr)=xi_left_i; + xi_right(B_field_cntr)=xi_right_i; + xi_linear(B_field_cntr)=xi_linear_i; + +endfor -save '/tmp/xi_vs_B.mat' detuning_freq xi_linear xi_left xi_right E_field_pos_freq E_field_probe B_field psi_el; +save '/tmp/xi_vs_B.mat' detuning_freq xi_linear xi_left xi_right E_field_pos_freq E_field_probe B_fields psi_el; psr_rad=output_faraday_results_vs_B; diff --git a/faraday/output_faraday_results_vs_B.m b/faraday/output_faraday_results_vs_B.m index 96e0a5e..8387a92 100644 --- a/faraday/output_faraday_results_vs_B.m +++ b/faraday/output_faraday_results_vs_B.m @@ -19,25 +19,25 @@ Ineg=(abs(Ex).^2)/2; figure(1); hold off; -plot(detuning_freq, real(xi_left-xi_right), '-'); +plot(B_fields, real(xi_left-xi_right), '-'); title("differential real xi"); xlabel("two photon detuning (MHz)"); figure(2); hold off; -plot(detuning_freq, imag(xi_left-xi_right), '-'); +plot(B_fields, imag(xi_left-xi_right), '-'); title("differential imag xi"); xlabel("two photon detuning (MHz)"); figure(3); hold off; -plot(detuning_freq, real(xi_left), '-', detuning_freq, real(xi_right), '-'); +plot(B_fields, real(xi_left), '-', detuning_freq, real(xi_right), '-'); title("real xi"); xlabel("two photon detuning (MHz)"); figure(4); hold off; -plot(detuning_freq, imag(xi_left), '-', detuning_freq, imag(xi_right), '-'); +plot(B_fields, imag(xi_left), '-', detuning_freq, imag(xi_right), '-'); title("imag xi"); xlabel("two photon detuning (MHz)"); @@ -45,15 +45,15 @@ figure(5); hold off; I_probe=E_field_probe^2; psr_rad=(Ipos-Ineg)/(2*I_probe); -plot(detuning_freq, psr_rad, '-'); -subt_str=sprintf("Laser Rabi freq normalized to upper state decay %.3f, ellipticity %.1f degree, \n B field ground level splitting %.3f Gauss", I_probe, psi_el*180/pi, B_field); +plot(B_fields, psr_rad, '-'); +subt_str=sprintf("Laser Rabi freq normalized to upper state decay %.3f, ellipticity %.1f degree, \n B field ground level splitting %.3f Gauss", I_probe, psi_el*180/pi, detuning_freq); title(cstrcat("BPD normilized PSR signal at F_g=2 to F_e=1,2.\n ",subt_str) ); xlabel("two photon detuning (MHz)"); ylabel("PSR (radians)"); print("psr_vs_detuning.ps"); -fname= sprintf("psr_vs_detuning_Fg=2toFe=1,2_Ip=%.3f_el_%.1f_B=%.3fG.mat", I_probe, psi_el*180/pi,B_field); -save(fname,'detuning_freq', 'psr_rad'); +fname= sprintf("psr_vs_B_Fg=2toFe=1,2_Ip=%.3f_el_%.1f_detun=%.3fMHz.mat", I_probe, psi_el*180/pi,detuning_freq); +save(fname,'B_fields', 'psr_rad', 'xi_left', 'xi_right', 'xi_linear'); return; diff --git a/faraday/run_me.m b/faraday/run_me.m new file mode 100644 index 0000000..8a29973 --- /dev/null +++ b/faraday/run_me.m @@ -0,0 +1,25 @@ +data_dir='results/'; +output_dir='results/'; +detuning_freq=0; + +gmg=.7; % gyro magnetic ration for ground level +zeeman_splitting=+0.1; +Nsteps=100; +B_fields=linspace(-zeeman_splitting/gmg, zeeman_splitting/gmg, Nsteps); + +%[psr_rad]=psr_vs_detuning(Ep, psi_el, B_field, theta, phi) + +% phi is angle between linear polarization and axis x +%phi=pi/4; +phi=0; +% theta is angle between lab z axis (light propagation direction) and magnetic field axis (z') +theta=0; +% psi_el is the ellipticity parameter (phase difference between left and right polarization) +psi_el=-30/180*pi*e-8; + +Ep=sqrt(0.1); + +%[psr_rad_smEp_pos_el]=psr_vs_detuning(detuning_freq, Ep, psi_el, B_field, theta, phi) ; +[psr_rad_smEp_pos_el]=faraday_vs_B(detuning_freq, Ep, psi_el, B_fields, theta, phi) ; + +plot(B_fields, psr_rad_smEp_pos_el) |