Merge branch 'master' of https://code.df.uba.ar/nnunez/artiq_experiments

b98e7aea · Nicolas Nunez Barreto · c43bb634 · 01187785 · b98e7aea · b98e7aea
Commit b98e7aea authored Aug 11, 2023 by Nicolas Nunez Barreto
9 changed files
--- a/analisis/plots/20230804_RotationalDopplerShift/Data/000013968-IR_Scan_withcal_optimized.h5
+++ b/analisis/plots/20230804_RotationalDopplerShift/Data/000013968-IR_Scan_withcal_optimized.h5
--- a/analisis/plots/20230804_RotationalDopplerShift/Data/000013970-IR_Scan_withcal_optimized.h5
+++ b/analisis/plots/20230804_RotationalDopplerShift/Data/000013970-IR_Scan_withcal_optimized.h5
--- a/analisis/plots/20230804_RotationalDopplerShift/Data/000013971-IR_Scan_withcal_optimized.h5
+++ b/analisis/plots/20230804_RotationalDopplerShift/Data/000013971-IR_Scan_withcal_optimized.h5
--- a/analisis/plots/20230804_RotationalDopplerShift/Data/000013974-IR_Scan_withcal_optimized.h5
+++ b/analisis/plots/20230804_RotationalDopplerShift/Data/000013974-IR_Scan_withcal_optimized.h5
--- a/analisis/plots/20230804_RotationalDopplerShift/Data/000013975-IR_Scan_withcal_optimized.h5
+++ b/analisis/plots/20230804_RotationalDopplerShift/Data/000013975-IR_Scan_withcal_optimized.h5
--- a/analisis/plots/20230804_RotationalDopplerShift/Data/EITfit/threeLevel_2repumps_AnalysisFunctions.py
+++ b/analisis/plots/20230804_RotationalDopplerShift/Data/EITfit/threeLevel_2repumps_AnalysisFunctions.py
--- a/analisis/plots/20230804_RotationalDopplerShift/Data/EITfit/threeLevel_2repumps_CPTPlotter.py
+++ b/analisis/plots/20230804_RotationalDopplerShift/Data/EITfit/threeLevel_2repumps_CPTPlotter.py
+#!/usr/bin/env python3
+# -*- coding: utf-8 -*-
+"""
+Created on Tue Sep  1 17:58:39 2020
+@author: oem
+"""
+import os
+import numpy as np
+#os.chdir('/home/oem/Nextcloud/G_liaf/liaf-TrampaAnular/Código General/EIT-CPT/Buenos Aires/Experiment Simulations/CPT scripts/Eight Level 2 repumps')
+from threeLevel_2repumps_AnalysisFunctions import CalculoTeoricoDarkResonances_8levels, GetMinimaInfo, GetPlotsofFluovsAngle_8levels, PerformExperiment_8levels, FindDRFrequencies, FindRelativeFluorescencesOfDR, GenerateNoisyCPT, SmoothNoisyCPT, GetFinalMaps, GenerateNoisyCPT_fixedRabi, GenerateNoisyCPT_fit
+import matplotlib.pyplot as plt
+import time
+from threeLevel_2repumps_AnalysisFunctions import MeasureRelativeFluorescenceFromCPT, IdentifyPolarizationCoincidences, RetrieveAbsoluteCoincidencesBetweenMaps, GetClosestIndex
+#C:\Users\Usuario\Nextcloud\G_liaf\liaf-TrampaAnular\Código General\EIT-CPT\Buenos Aires\Experiment Simulations\CPT scripts\Eight Level 2 repumps
+ub = 9.27e-24
+h = 6.63e-34
+c = (ub/h)*1e-4 #en unidades de MHz/G
+#u = 1e6
+u = 33.5e6
+B = (u/(2*np.pi))/c
+#sg, sp = 0.6, 5  #parámetros de control, saturación del doppler y repump
+#rabG, rabP = sg*gPS, sp*gPD #frecuencias de rabi
+gPS, gPD, = 2*np.pi*21.58e6, 2*np.pi*1.35e6 #anchos de linea de las transiciones
+lw = 0.1
+DopplerLaserLinewidth, RepumpLaserLinewidth, ProbeLaserLinewidth = lw, lw, lw #ancho de linea de los laseres
+DetDoppler = -36 #42
+DetRepumpVec = [DetDoppler+29.6]
+Tvec = [0.7] #temperatura en mK
+alpha = 0*(np.pi/180) #angulo entre los láseres
+phidoppler, titadoppler = 0, 90
+phirepump, titarepump = 0,  0
+phiprobe = 0
+titaprobe = 90
+#Calculo las resonancias oscuras teóricas
+#ResonanciasTeoricas, DRPositivas = CalculoTeoricoDarkResonances_8levels(u/(2*np.pi*1e6), titadoppler, DetDoppler, DetRepump)
+#Parametros de la simulacion cpt
+center = -45
+span = 80
+freqMin = center-span*0.5
+freqMax = center+span*0.5
+""" parametros para tener espectros coherentes
+freqMin = -56
+freqMax = 14
+"""
+freqStep = 1e-1
+noiseamplitude = 0
+RelMinMedido0Vector = []
+RelMinMedido1Vector = []
+RelMinMedido2Vector = []
+RelMinMedido3Vector = []
+RelMinMedido4Vector = []
+#Sr = np.arange(0, 10, 0.2)
+#Sg = np.arange(0.01, 1, 0.05)
+#Sp = np.arange(0.1, 6.1, 1)
+#Sg = [0.6**2]
+#Sp = [2.3**2]
+Sg = [1.4]
+Sp = [6]
+Sr = [11]
+i = 0
+save = False
+showFigures = True
+if not showFigures:
+    plt.ioff()
+else:
+    plt.ion()
+fig1, ax1 = plt.subplots()
+offsetx = 464
+ax1.plot([f-offsetx for f in FreqsDR], CountsDR, 'o')
+run = True
+Scale = 730
+Offset = 600 #600 para 20k cuentas aprox
+MaxCoherenceValue = []
+for sg in Sg:
+    for sp in Sp:
+        rabG, rabP = sg*gPS, sp*gPD
+        for Ti in Tvec:
+            T = Ti*1e-3
+            for DetRepump in DetRepumpVec:
+                print(T)
+                for sr in Sr:
+                    rabR = sr*gPD
+                    #MeasuredFreq, MeasuredFluo = GenerateNoisyCPT(rabG, rabR, rabP, gPS, gPD, DetDoppler, DetRepump, u, DopplerLaserLinewidth, RepumpLaserLinewidth, ProbeLaserLinewidth, T, alpha, phidoppler, titadoppler, phiprobe, [titaprobe], phirepump, titarepump, freqMin, freqMax, freqStep, plot=False, solvemode=1, detpvec=None, noiseamplitude=noiseamplitude)
+                    if run:
+                        MeasuredFreq4, MeasuredFluo4 = GenerateNoisyCPT_fixedRabi(sg, sr, sp, gPS, gPD, DetDoppler, DetRepump, u, DopplerLaserLinewidth, RepumpLaserLinewidth, ProbeLaserLinewidth, T, alpha, phidoppler, titadoppler, phiprobe, [titaprobe], phirepump, titarepump, freqMin, freqMax, freqStep, plot=False, solvemode=1, detpvec=None, noiseamplitude=noiseamplitude)
+                    #SmoothFluo = SmoothNoisyCPT(MeasuredFluo, window=9, poly=2)
+                    SmoothFluo4 = MeasuredFluo4
+                    #Scale = max(BestC)/max([100*s for s in SmoothFluo4])
+                    ax1.plot(MeasuredFreq4, [Scale*100*f + Offset for f in SmoothFluo4], label=f'Sr = {sr}')
+                    ax1.axvline(DetDoppler, linestyle='--', linewidth=1)
+                    #if sr != 0:
+                        #ax1.axvline(DetRepump, linestyle='--', linewidth=1)
+                    MaxCoherenceValue.append(np.max(SmoothFluo4))
+                    #print(titaprobe)
+                    ax1.set_xlabel('Detuning Rebombeo (MHz)')
+                    ax1.set_ylabel('Fluorescencia (AU)')
+                    ax1.set_title(f'B: {round(B, 2)} G, Sdop: {round(sg, 2)}, Sp: {round(sp, 2)}, Sr: {round(sr, 2)}, lw: {lw} MHz, T: {Ti} mK')
+                    #ax1.set_ylim(0, 8)
+                    #ax1.axvline(DetDoppler, linestyle='dashed', color='red', linewidth=1)
+                    #ax1.axvline(DetRepump, linestyle='dashed', color='black', linewidth=1)
+                    #ax1.set_title('Pol Doppler y Repump: Sigma+ Sigma-, Pol Probe: PI')
+                    #ax1.legend()
+                    ax1.grid()
+                    print (f'{i+1}/{len(Sg)*len(Sp)}')
+                    i = i + 1
+                    if save:
+                        plt.savefig(f'Mapa_plots_100k_1mk/CPT_SMSM_sdop{round(sg, 2)}_sp{round(sp, 2)}_sr{round(sr, 2)}.jpg')
+                    ax1.legend()
+"""
+plt.figure()
+plt.plot(Sr, MaxCoherenceValue, 'o')
+plt.xlabel('Sr')
+plt.ylabel('Coherence')
+"""
+"""
+plt.figure()
+plt.plot(MeasuredFreq, [100*f for f in SmoothFluo], color='darkred')
+plt.xlabel('Desintonía 866 (MHz)')
+plt.ylabel('Fluorescencia (A.U.)')
+plt.axvline(-30, color='darkblue', linewidth=1.2, linestyle='--')
+plt.yticks(np.arange(0.4, 1.8, 0.2))
+plt.ylim(0.5, 1.6)
+plt.grid()
+plt.figure()
+plt.plot(MeasuredFreq4, [100*f for f in SmoothFluo4], color='darkred')
+plt.xlabel('Desintonía 866 (MHz)')
+plt.ylabel('Fluorescencia (A.U.)')
+plt.axvline(-30, color='darkblue', linewidth=1.2, linestyle='--')
+plt.yticks(np.arange(0.8, 2.4, 0.4))
+plt.grid()
+"""
+#%%
+from scipy.optimize import curve_fit
+T = 0.5e-3
+sg = 0.7
+sp = 6
+sr = 0
+DetDoppler = -14
+DetRepump = 0
+FitsSp = []
+FitsOffset = []
+Sg = [0.87]
+def FitEIT(freqs, SP, offset):
+    MeasuredFreq, MeasuredFluo = GenerateNoisyCPT_fit(0.87, sr, SP, gPS, gPD, DetDoppler, DetRepump, u, DopplerLaserLinewidth, RepumpLaserLinewidth, ProbeLaserLinewidth, T, alpha, phidoppler, titadoppler, phiprobe, [titaprobe], phirepump, titarepump, freqs, plot=False, solvemode=1, detpvec=None, noiseamplitude=noiseamplitude)
+    FinalFluo = [f*43000 + 2685 for f in MeasuredFluo]
+    return FinalFluo
+freqs = [f-offsetx+32 for f in FreqsDR]
+freqslong = np.arange(min(freqs), max(freqs)+freqs[1]-freqs[0], 0.1*(freqs[1]-freqs[0]))
+popt, pcov = curve_fit(FitEIT, freqs, CountsDR, p0=[5, 700], bounds=(0, [10, 1e6]))
+FitsSp.append(popt[0])
+FitsOffset.append(popt[1])
+print(popt)
+FittedEIT = FitEIT(freqslong, *popt)
+plt.figure()
+plt.errorbar(freqs, CountsDR, yerr=2*np.sqrt(CountsDR), fmt='o', capsize=2, markersize=2)
+plt.plot(freqslong, FitEIT(freqslong, *popt))
+plt.title(f'Sdop: {round(popt[0], 2)}, Spr: {round(popt[1], 2)}, T: {T*1e3} mK, detDop: {DetDoppler} MHz')
+np.savetxt('CPT_measured.txt', np.transpose([freqs, CountsDR]))
+np.savetxt('CPT_fitted.txt', np.transpose([freqslong, FittedEIT]))
--- a/analisis/plots/20230804_RotationalDopplerShift/Data/EITfit/threeLevel_2repumps_linealpol_python_scripts.py
+++ b/analisis/plots/20230804_RotationalDopplerShift/Data/EITfit/threeLevel_2repumps_linealpol_python_scripts.py
--- a/analisis/plots/20230804_RotationalDopplerShift/RDS_CPT.py
+++ b/analisis/plots/20230804_RotationalDopplerShift/RDS_CPT.py
+import h5py
+import matplotlib.pyplot as plt
+import numpy as np
+import sys
+import re
+import ast
+from scipy.optimize import curve_fit
+import os
+from scipy import interpolate
+#Mediciones barriendo angulo del TISA y viendo kicking de resonancias oscuras
+#C:\Users\Usuario\Documents\artiq\artiq_experiments\analisis\plots\20220106_CPT_DosLaseres_v08_TISA_DR\Data
+os.chdir('/home/nico/Documents/artiq_experiments/analisis/plots/20230804_RotationalDopplerShift/Data')
+MOTIONAL_FILES = """000013968-IR_Scan_withcal_optimized
+000013970-IR_Scan_withcal_optimized
+000013971-IR_Scan_withcal_optimized
+000013974-IR_Scan_withcal_optimized
+000013975-IR_Scan_withcal_optimized"""
+def SeeKeys(files):
+    for i, fname in enumerate(files.split()):
+        data = h5py.File(fname+'.h5', 'r') # Leo el h5: Recordar que nuestros datos estan en 'datasets'
+        print(fname)
+        print(list(data['datasets'].keys()))
+print(SeeKeys(MOTIONAL_FILES))
+#carpeta pc nico labo escritorio:
+#C:\Users\Usuario\Documents\artiq\artiq_experiments\analisis\plots\20211101_CPT_DosLaseres_v03\Data
+Counts = []
+IR1_Freqs    = []
+for i, fname in enumerate(MOTIONAL_FILES.split()):
+    print(str(i) + ' - ' + fname)
+    data = h5py.File(fname+'.h5', 'r')
+    #Amplitudes.append(np.array(data['datasets']['amplitudes']))
+    Counts.append(np.array(data['datasets']['counts_spectrum']))
+    IR1_Freqs.append(np.array(data['datasets']['IR1_Frequencies']))
+#%%
+"""
+Resonancias DR con poca pot de IR1
+"""
+medvec = [2,1]
+plt.figure()
+ftrap = 22.1
+DR1 = 435.8
+DR2 = 444.2
+for med in medvec:
+    plt.plot([2*f*1e-6 for f in IR1_Freqs[med][1:]], [c for c in Counts[med][1:]], '-o', markersize=2)
+    i=i+1
+plt.axvline(DR1, linestyle='--', color='red', zorder=0)
+plt.axvline(DR2, linestyle='--', color='red', zorder=0)
+plt.axvline(DR1-ftrap, linestyle='--', color='red', zorder=0)
+plt.axvline(DR1+ftrap, linestyle='--', color='red', zorder=0)
+plt.axvline(DR2-ftrap, linestyle='--', color='red', zorder=0)
+plt.axvline(DR2+ftrap, linestyle='--', color='red', zorder=0)
+plt.xlabel('Frecuencia')
+plt.ylabel('Counts')
+plt.xlim(420,449)
+plt.ylim(100,700)
+plt.grid()
+plt.legend()
+#%%
+"""
+Resonancias DR con mas pot de IR1
+"""
+medvec = [3,4]
+plt.figure()
+ftrap = 22.1
+DR1 = 435.8
+DR2 = 444.2
+for med in medvec:
+    plt.plot([2*f*1e-6 for f in IR1_Freqs[med][1:]], [c for c in Counts[med][1:]], '-o', markersize=2)
+    i=i+1
+plt.axvline(DR1, linestyle='--', color='red', zorder=0)
+plt.axvline(DR2, linestyle='--', color='red', zorder=0)
+plt.axvline(DR1-ftrap, linestyle='--', color='red', zorder=0)
+plt.axvline(DR1+ftrap, linestyle='--', color='red', zorder=0)
+plt.axvline(DR2-ftrap, linestyle='--', color='red', zorder=0)
+plt.axvline(DR2+ftrap, linestyle='--', color='red', zorder=0)
+plt.xlabel('Frecuencia')
+plt.ylabel('Counts')
+plt.xlim(433,440)
+plt.ylim(100,1000)
+plt.grid()
+plt.legend()