### Test Script for a file found in the SDprox2 results from initial Parallel Simulations from __future__ import division import numpy import matplotlib from matplotlib import pyplot from mpl_toolkits.mplot3d import Axes3D import scipy from scipy import signal from scipy import stats Case = 'SDprox2_E_COM_I_COM' EXCSLM = 1 EXCSR = 1 Inh90SR = 1 Inh180SR = 1 Inh270SR = 1 Inh90SLM = 1 Inh180SLM = 1 Inh270SLM = 1 EXC = 1 INH = 1 numExcThetaSyns = 27 # i.e. 3 connections so 9 synapses per connection numInhThetaSyns = 8 # i.e. 2 connections so 4 synapses per connection SaveExample = 1 randseed1 = 10 # if using fixed random seeds randseed2 = 15 # HC Treshold Measurement Values tstop = 10 # seconds font_size = 13 Examples = numpy.load('NPYfiles/' + Case + '_ExampleHCModelParams.npy') ExampleStrings = numpy.load('NPYfiles/' + Case + '_ExampleHCModelStrings.npy') thetaSynMultiplier = numpy.array([0, 1, 2, 3]) prethetanoise = numpy.arange(0.00,0.11,0.01) tstop = h.tstop/1000 dt = h.dt for x2 in range(0,1): if Examples[0][x2] == 0: print(ExampleStrings[x2].decode("utf-8") + ' is empty') continue for n in prethetanoise: for y in range(0,4): print('Simulating... ' + str(ExampleStrings[x2]) + ' #' + str(y+1)) ExampleString = ExampleStrings[x2].decode("utf-8") HCNumber = x2 # Run Simulation of Example h.randomize_syns(5,2) # i.e. same random seeds when comparing runs h.f(Examples[0][x2],Examples[1][x2],Examples[2][x2],Examples[3][x2],SaveExample,randseed1,randseed2,1,INH*numInhThetaSyns*thetaSynMultiplier[y],EXC*numExcThetaSyns*thetaSynMultiplier[y],EXCSLM,EXCSR,Inh90SR,Inh180SR,Inh270SR,Inh90SLM,Inh180SLM,Inh270SLM,n) # i.e. same random seeds when comparing runs HC_Trace = numpy.fromfile("%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s" % ('model_',str(Examples[0][x2]),'_NumInh_',str(Examples[1][x2]),'_NumExc_',str(Examples[2][x2]),'_InhSpikes_',str(Examples[3][x2]),'_ExcSRSpikes_',str(Examples[3][x2]),'_ExcSLMSpikes_',str(9),'_NumExcCommon_',str(4),'_NumInhCommon_X',str(thetaSynMultiplier[y]),'_ThetaMultiplier_',str('%0.2f' %h.prethetanoise),'_prethetanoise.dat'),dtype=float) voltvec = HC_Trace[1:len(HC_Trace)] if y == 0: HC_Trace_Baseline = HC_Trace[10000:100001] HC_SpikeTimes_Baseline = numpy.zeros((len(HC_Trace),), dtype=numpy.float) for i in range(0,len(h.apctimes)): HC_SpikeTimes_Baseline[int(h.apctimes.x[i]/dt)] = h.apctimes.x[i] HC_SpikeTimes_Baseline = HC_SpikeTimes_Baseline[10000:100001] HC_SpikeTimes_Baseline2 = numpy.array(h.apctimes,dtype=numpy.float) elif y == 1: HC_Trace_Rhythm = HC_Trace[10000:100001] HC_SpikeTimes_Rhythm = numpy.zeros((len(HC_Trace),), dtype=numpy.float) for i in range(0,len(h.apctimes)): HC_SpikeTimes_Rhythm[int(h.apctimes.x[i]/dt)] = h.apctimes.x[i] HC_SpikeTimes_Rhythm = HC_SpikeTimes_Rhythm[10000:100001] HC_SpikeTimes_Rhythm2 = numpy.array(h.apctimes,dtype=numpy.float) elif y == 2: HC_Trace_X2Rhythm = HC_Trace[10000:100001] HC_SpikeTimes_X2Rhythm = numpy.zeros((len(HC_Trace),), dtype=numpy.float) for i in range(0,len(h.apctimes)): HC_SpikeTimes_X2Rhythm[int(h.apctimes.x[i]/dt)] = h.apctimes.x[i] HC_SpikeTimes_X2Rhythm = HC_SpikeTimes_X2Rhythm[10000:100001] HC_SpikeTimes_X2Rhythm2 = numpy.array(h.apctimes,dtype=numpy.float) elif y == 3: HC_Trace_X3Rhythm = HC_Trace[10000:100001] HC_SpikeTimes_X3Rhythm = numpy.zeros((len(HC_Trace),), dtype=numpy.float) for i in range(0,len(h.apctimes)): HC_SpikeTimes_X3Rhythm[int(h.apctimes.x[i]/dt)] = h.apctimes.x[i] HC_SpikeTimes_X3Rhythm = HC_SpikeTimes_X3Rhythm[10000:100001] HC_SpikeTimes_X3Rhythm2 = numpy.array(h.apctimes,dtype=numpy.float) timevec = numpy.arange(0,10000.1,0.1) if y == 0: f, axarr = matplotlib.pyplot.subplots(4, sharex=True) axarr[0].plot(timevec,voltvec,'b') axarr[0].set_title('Baseline High-Conductance',fontsize = font_size-2) # axarr[0].set_title("%s%s%s%s%s%s%s%s%s" % ('InhSyns: ',str(Examples[0][x]),', ExcSyns: ',str(Examples[1][x]),',\nInhSpikes: ',str(Examples[2][x]/tstop),'Hz, ExcSpikes: ',str(Examples[3][x]/tstop),'Hz')) axarr[0].set_ylim(-85,30) axarr[0].set_xlim(8000,10000) axarr[0].spines['right'].set_visible(False) axarr[0].spines['top'].set_visible(False) axarr[0].spines['bottom'].set_visible(False) for tic in axarr[0].xaxis.get_major_ticks(): tic.tick1line.set_visible = tic.tick2line.set_visible = False if y == 1: axarr[1].plot(timevec,voltvec,'r') axarr[1].set_title('Theta Input X1',fontsize=font_size-2) axarr[1].set_ylim(-85,30) axarr[1].set_ylabel('Voltage (mV) ',fontsize=font_size-2) axarr[1].set_xlim(8000,10000) axarr[1].spines['right'].set_visible(False) axarr[1].spines['top'].set_visible(False) axarr[1].spines['bottom'].set_visible(False) for tic in axarr[1].xaxis.get_major_ticks(): tic.tick1line.set_visible = tic.tick2line.set_visible = False if y == 2: axarr[2].plot(timevec,voltvec,'g') axarr[2].set_title('Theta Input X2',fontsize=font_size-2) axarr[2].set_ylim(-85,30) axarr[2].set_xlim(8000,10000) axarr[2].spines['right'].set_visible(False) axarr[2].spines['top'].set_visible(False) axarr[2].spines['bottom'].set_visible(False) for tic in axarr[2].xaxis.get_major_ticks(): tic.tick1line.set_visible = tic.tick2line.set_visible = False if y == 3: axarr[3].plot(timevec,voltvec,'c') axarr[3].set_title('Theta Input X3',fontsize=font_size-2) axarr[3].set_ylim(-85,30) axarr[3].set_xlim(8000,10000) axarr[3].set_xlabel('Time (ms)',fontsize=font_size-2) axarr[3].spines['right'].set_visible(False) axarr[3].spines['top'].set_visible(False) pyplot.savefig('PLOTfiles/' + Case + '_Trace_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.pdf', bbox_inches='tight') pyplot.savefig('PLOTfiles/' + Case + '_Trace_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.png', bbox_inches='tight') pyplot.gcf().clear() pyplot.cla() pyplot.clf() pyplot.close() if thetaSynMultiplier[y]>0: f2, axarr2 = matplotlib.pyplot.subplots(1) for j in range(0,int(h.excthetacount)): randind = int(h.EXCrandSRtheta.x[j]) if randind == -1: randind = 0 ThetaVec = numpy.array([],dtype=numpy.float) for q in range(0,len(h.ThetaSRexcprespiketrains[randind])): ThetaVec = numpy.append(ThetaVec,h.ThetaSRexcprespiketrains[randind].x[q]) ThetaVec = numpy.array(ThetaVec,dtype=numpy.float) axarr2.vlines(ThetaVec,j+0.75,j+1.25,'g') for k in range(0,int(h.excthetacount)): randind = int(h.EXCrandSLMtheta.x[k]) if randind == -1: randind = 0 ThetaVec = numpy.array([],dtype=numpy.float) for q in range(0,len(h.ThetaSLMexcprespiketrains[randind])): ThetaVec = numpy.append(ThetaVec,h.ThetaSLMexcprespiketrains[randind].x[q]) ThetaVec = numpy.array(ThetaVec,dtype=numpy.float) axarr2.vlines(ThetaVec,j+k+1.75,j+k+2.25,'c') for l in range(0,int(h.inhthetacount)): randind = int(h.randSRinhtheta90.x[l]) if randind == -1: randind = 0 ThetaVec = numpy.array([],dtype=numpy.float) for q in range(0,len(h.ThetaSRInh90prespiketrains[randind])): ThetaVec = numpy.append(ThetaVec,h.ThetaSRInh90prespiketrains[randind].x[q]) ThetaVec = numpy.array(ThetaVec,dtype=numpy.float) axarr2.vlines(ThetaVec,l+j+k+2.75,l+j+k+3.25,'m') for m in range(0,int(h.inhthetacount)): randind = int(h.randSLMinhtheta90.x[m]) if randind == -1: randind = 0 ThetaVec = numpy.array([],dtype=numpy.float) for q in range(0,len(h.ThetaSLMInh90prespiketrains[randind])): ThetaVec = numpy.append(ThetaVec,h.ThetaSLMInh90prespiketrains[randind].x[q]) ThetaVec = numpy.array(ThetaVec,dtype=numpy.float) axarr2.vlines(ThetaVec,m+l+j+k+3.75,m+l+j+k+4.25,'y') for n2 in range(0,int(h.inhthetacount)): randind = int(h.randSRinhtheta180.x[n2]) if randind == -1: randind = 0 ThetaVec = numpy.array([],dtype=numpy.float) for q in range(0,len(h.ThetaSRInh180prespiketrains[randind])): ThetaVec = numpy.append(ThetaVec,h.ThetaSRInh180prespiketrains[randind].x[q]) ThetaVec = numpy.array(ThetaVec,dtype=numpy.float) axarr2.vlines(ThetaVec,n2+m+l+j+k+4.75,n2+m+l+j+k+5.25,'b') for o in range(0,int(h.inhthetacount)): randind = int(h.randSLMinhtheta180.x[o]) if randind == -1: randind = 0 ThetaVec = numpy.array([],dtype=numpy.float) for q in range(0,len(h.ThetaSLMInh180prespiketrains[randind])): ThetaVec = numpy.append(ThetaVec,h.ThetaSLMInh180prespiketrains[randind].x[q]) ThetaVec = numpy.array(ThetaVec,dtype=numpy.float) axarr2.vlines(ThetaVec,o+n2+m+l+j+k+5.75,o+n2+m+l+j+k+6.25,'k') for p in range(0,int(h.inhthetacount)): randind = int(h.randSRinhtheta270.x[p]) if randind == -1: randind = 0 ThetaVec = numpy.array([],dtype=numpy.float) for q in range(0,len(h.ThetaSRInh270prespiketrains[randind])): ThetaVec = numpy.append(ThetaVec,h.ThetaSRInh270prespiketrains[randind].x[q]) ThetaVec = numpy.array(ThetaVec,dtype=numpy.float) axarr2.vlines(ThetaVec,p+o+n2+m+l+j+k+6.75,p+o+n2+m+l+j+k+7.25,color='orange') for q2 in range(0,int(h.inhthetacount)): randind = int(h.randSLMinhtheta270.x[q2]) if randind == -1: randind = 0 ThetaVec = numpy.array([],dtype=numpy.float) for q in range(0,len(h.ThetaSLMInh270prespiketrains[randind])): ThetaVec = numpy.append(ThetaVec,h.ThetaSLMInh270prespiketrains[randind].x[q]) ThetaVec = numpy.array(ThetaVec,dtype=numpy.float) axarr2.vlines(ThetaVec,q2+p+o+n2+m+l+j+k+6.75,q2+p+o+n2+m+l+j+k+7.25,color='r') axarr2.set_xlim(8000,10000) axarr2.set_ylim(0,q2+p+o+n2+m+l+j+k+8) axarr2.set_xlabel('Time (ms)',fontsize=font_size-4) axarr2.set_ylabel('CA3 EC3 Inhibition ',fontsize=font_size-4) pyplot.savefig('PLOTfiles/' + Case + '_ThetaPresynapticSpikes_' + ExampleString + '_X' + str(y) + '_ThetaMultiplier_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.pdf', bbox_inches='tight') pyplot.savefig('PLOTfiles/' + Case + '_ThetaPresynapticSpikes_' + ExampleString + '_X' + str(y) + '_ThetaMultiplier_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.png', bbox_inches='tight') pyplot.gcf().clear() pyplot.cla() pyplot.clf() pyplot.close() f, axarr = matplotlib.pyplot.subplots(2, sharex=False) f1, Pxx_den1 = signal.welch(HC_SpikeTimes_Baseline, 1/(dt/1000), nperseg=25000) f2, Pxx_den2 = signal.welch(HC_SpikeTimes_Rhythm, 1/(dt/1000), nperseg=25000) f3, Pxx_den3 = signal.welch(HC_SpikeTimes_X2Rhythm, 1/(dt/1000), nperseg=25000) f4, Pxx_den4 = signal.welch(HC_SpikeTimes_X3Rhythm, 1/(dt/1000), nperseg=25000) numpy.save('NPYfiles/' + Case + '_SpikeTimesBaseline_' + str(HCNumber) + '_HCNumber_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.npy',HC_SpikeTimes_Baseline2) numpy.save('NPYfiles/' + Case + '_SpikeTimesRhythm_' + str(HCNumber) + '_HCNumber_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.npy',HC_SpikeTimes_Rhythm2) numpy.save('NPYfiles/' + Case + '_SpikeTimesX2Rhythm_' + str(HCNumber) + '_HCNumber_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.npy',HC_SpikeTimes_X2Rhythm2) numpy.save('NPYfiles/' + Case + '_SpikeTimesX3Rhythm_' + str(HCNumber) + '_HCNumber_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.npy',HC_SpikeTimes_X3Rhythm2) axarr[0].loglog(f1, Pxx_den1,'b') axarr[0].loglog(f2, Pxx_den2,'r') axarr[0].loglog(f3, Pxx_den3,'g') axarr[0].loglog(f4, Pxx_den4,'c') axarr[0].hlines(numpy.amax(Pxx_den4)+500,5,12,'k',linestyles='solid') axarr[0].text(5.05,numpy.amax(Pxx_den4)+1000,'Theta (5-12Hz)') axarr[0].axvline(numpy.array([5]),ymin=0,ymax=0.95,color='k',linestyle='solid') axarr[0].axvline(numpy.array([12]),ymin=0,ymax=0.95,color='k',linestyle='solid') axarr[0].axvline(numpy.array([8]),ymin=0,ymax=0.95,color='k',linestyle='dashed') axarr[0].set_xlim(0,100) axarr[0].set_xlabel('frequency (Hz)') axarr[0].set_ylabel(r'$PSD (Spikes^2 / Hz)$') axarr[0].spines['right'].set_visible(False) axarr[0].spines['top'].set_visible(False) ind = numpy.arange(8) width = 0.4 Area1 = numpy.trapz(Pxx_den1[(f1>5) & (f1<12)],x=f1[(f1>5) & (f1<12)]) Area2 = numpy.trapz(Pxx_den2[(f2>5) & (f2<12)],x=f2[(f2>5) & (f2<12)]) Area3 = numpy.trapz(Pxx_den3[(f3>5) & (f3<12)],x=f3[(f3>5) & (f3<12)]) Area4 = numpy.trapz(Pxx_den4[(f4>5) & (f4<12)],x=f4[(f4>5) & (f4<12)]) e8Hz1 = Pxx_den1[f1==8] e8Hz2 = Pxx_den2[f2==8] e8Hz3 = Pxx_den3[f3==8] e8Hz4 = Pxx_den4[f4==8] axarr[1].bar(ind+width, [Area1, Area2, Area3, Area4, e8Hz1[0], e8Hz2[0], e8Hz3[0], e8Hz4[0]], width, color='k') axarr[1].set_xticks(ind+width) axarr[1].set_xticklabels(('Base\n(5-12Hz)','ThetaX1\n(5-12Hz)', 'ThetaX2\n(5-12Hz)', 'ThetaX3\n(5-12Hz)', 'Base\n(8Hz)','ThetaX1\n(8Hz)','ThetaX2\n(8Hz)','ThetaX3\n(8Hz)'),fontsize=font_size-3, fontweight='bold', rotation=45) axarr[1].set_ylabel('PSD Magnitude') axarr[1].set_xlim(0,8+width) axarr[1].spines['right'].set_visible(False) axarr[1].spines['top'].set_visible(False) pyplot.tight_layout() pyplot.savefig('PLOTfiles/' + Case + '_PSD_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.pdf', bbox_inches='tight') pyplot.savefig('PLOTfiles/' + Case + '_PSD_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.png', bbox_inches='tight') pyplot.gcf().clear() pyplot.cla() pyplot.clf() pyplot.close() # Instantaneous Frequency Analyses (Note this is converting the ISIs into seconds and then instantaneous frequencies) IF_Baseline = numpy.concatenate([numpy.array([0],dtype=numpy.float),1000/numpy.diff(HC_SpikeTimes_Baseline2)]) IF_ThetaX1 = numpy.concatenate([numpy.array([0],dtype=numpy.float),1000/numpy.diff(HC_SpikeTimes_Rhythm2)]) IF_ThetaX2 = numpy.concatenate([numpy.array([0],dtype=numpy.float),1000/numpy.diff(HC_SpikeTimes_X2Rhythm2)]) IF_ThetaX3 = numpy.concatenate([numpy.array([0],dtype=numpy.float),1000/numpy.diff(HC_SpikeTimes_X3Rhythm2)]) range_if = (0,100) heights1,bins1 = numpy.histogram(IF_Baseline,bins=100,range=range_if) heights2,bins2 = numpy.histogram(IF_ThetaX1,bins=100,range=range_if) heights3,bins3 = numpy.histogram(IF_ThetaX2,bins=100,range=range_if) heights4,bins4 = numpy.histogram(IF_ThetaX3,bins=100,range=range_if) # Normalize heights1 = heights1/float(sum(heights1)) heights2 = heights2/float(sum(heights2)) heights3 = heights3/float(sum(heights3)) heights4 = heights4/float(sum(heights4)) bin1=bins1[:-1]+numpy.diff(bins1)/2. bin2=bins2[:-1]+numpy.diff(bins2)/2. bin3=bins3[:-1]+numpy.diff(bins3)/2. bin4=bins4[:-1]+numpy.diff(bins4)/2. binMids1 = bin1[~numpy.isnan(bin1)] binMids2 = bin2[~numpy.isnan(bin2)] binMids3 = bin3[~numpy.isnan(bin3)] binMids4 = bin4[~numpy.isnan(bin4)] heights1 = heights1[~numpy.isnan(bin1)] heights2 = heights2[~numpy.isnan(bin2)] heights3 = heights3[~numpy.isnan(bin3)] heights4 = heights4[~numpy.isnan(bin4)] f, axarr = matplotlib.pyplot.subplots(2, sharex=False) axarr[0].semilogx(binMids1,heights1,'b') axarr[0].semilogx(binMids2,heights2,'r') axarr[0].semilogx(binMids3,heights3,'g') axarr[0].semilogx(binMids4,heights4,'c') axarr[0].vlines(numpy.array([4,12]),0,numpy.amax(heights4)+0.01,'k',linestyles='solid') axarr[0].vlines(numpy.array([8]),0,numpy.amax(heights4)+0.01,'k',linestyles='dashed') axarr[0].hlines(numpy.amax(heights4)+0.01,4,12,'k',linestyles='solid') axarr[0].text(4.3,numpy.amax(heights4)+0.02,'Theta (4-12Hz)') axarr[0].set_xlabel('Frequency (Hz)') axarr[0].set_ylabel('Probability') axarr[0].set_xlim(0,130) axarr[0].set_ylim(0,0.19) axarr[0].spines['right'].set_visible(False) axarr[0].spines['top'].set_visible(False) ind = numpy.arange(8) width = 0.4 Area11 = numpy.trapz(heights1[(binMids1>4) & (binMids1<8)],x=binMids1[(binMids1>4) & (binMids1<8)]) Area22 = numpy.trapz(heights2[(binMids2>4) & (binMids2<8)],x=binMids2[(binMids2>4) & (binMids2<8)]) Area33 = numpy.trapz(heights3[(binMids3>4) & (binMids3<8)],x=binMids3[(binMids3>4) & (binMids3<8)]) Area44 = numpy.trapz(heights4[(binMids4>4) & (binMids4<8)],x=binMids4[(binMids4>4) & (binMids4<8)]) e8Hz11 = numpy.trapz(heights1[(binMids1>8) & (binMids1<12)],x=binMids1[(binMids1>8) & (binMids1<12)]) #IF NOT THIS TRY NUMPY.AMAX BETWEEN 7 AND 9 e8Hz22 = numpy.trapz(heights2[(binMids2>8) & (binMids2<12)],x=binMids2[(binMids2>8) & (binMids2<12)]) e8Hz33 = numpy.trapz(heights3[(binMids3>8) & (binMids3<12)],x=binMids3[(binMids3>8) & (binMids3<12)]) e8Hz44 = numpy.trapz(heights4[(binMids4>8) & (binMids4<12)],x=binMids4[(binMids4>8) & (binMids4<12)]) axarr[1].bar(ind+width, [Area11, Area22, Area33, Area44, e8Hz11, e8Hz22, e8Hz33, e8Hz44], width, color='k') axarr[1].set_xticks(ind+width) axarr[1].set_xticklabels(('Base\n(4-8Hz)','ThetaX1\n(4-8Hz)', 'ThetaX2\n(4-8Hz)', 'ThetaX3\n(4-8Hz)', 'Base\n(8-12Hz)','ThetaX1\n(8-12Hz)','ThetaX2\n(8-12Hz)','ThetaX3\n(8-12Hz)'),fontsize=font_size-3, fontweight='bold', rotation=45) axarr[1].set_ylabel('Probability') axarr[1].set_xlim(0,8+width) axarr[1].spines['right'].set_visible(False) axarr[1].spines['top'].set_visible(False) pyplot.tight_layout() pyplot.savefig('PLOTfiles/' + Case + '_IFDistribution_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.pdf', bbox_inches='tight') pyplot.savefig('PLOTfiles/' + Case + '_IFDistribution_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.png', bbox_inches='tight') pyplot.gcf().clear() pyplot.cla() pyplot.clf() pyplot.close() # Polar Distribution Plots STX0 = HC_SpikeTimes_Baseline2/125 STX1 = HC_SpikeTimes_Rhythm2/125 STX2 = HC_SpikeTimes_X2Rhythm2/125 STX3 = HC_SpikeTimes_X3Rhythm2/125 Rads_Baseline = 2*numpy.pi*(STX0-STX0.astype(int)) Rads_1XRhythm = 2*numpy.pi*(STX1-STX1.astype(int)) Rads_2XRhythm = 2*numpy.pi*(STX2-STX2.astype(int)) Rads_3XRhythm = 2*numpy.pi*(STX3-STX3.astype(int)) Rads_Baseline_Sorted = sorted(Rads_Baseline) Rads_1XRhythm_Sorted = sorted(Rads_1XRhythm) Rads_2XRhythm_Sorted = sorted(Rads_2XRhythm) Rads_3XRhythm_Sorted = sorted(Rads_3XRhythm) IF_Baseline_Sorted = [x for i, x in sorted(zip(Rads_Baseline,IF_Baseline))] IF_ThetaX1_Sorted = [x for i, x in sorted(zip(Rads_1XRhythm,IF_ThetaX1))] IF_ThetaX2_Sorted = [x for i, x in sorted(zip(Rads_2XRhythm,IF_ThetaX2))] IF_ThetaX3_Sorted = [x for i, x in sorted(zip(Rads_3XRhythm,IF_ThetaX3))] bin_size = 25 range_if = (0,100) range_rads = (0,2*numpy.pi) heights11,be11 = numpy.histogram(Rads_Baseline,bins=bin_size,range=range_rads) bins11 = be11[:-1]+numpy.diff(be11)/2. PrefPhase_Baseline = bins11[heights11 == numpy.amax(heights11)] heights22,be22 = numpy.histogram(Rads_1XRhythm,bins=bin_size,range=range_rads) bins22 = be22[:-1]+numpy.diff(be22)/2. PrefPhase_ThetaX1 = bins22[heights22 == numpy.amax(heights22)] heights33,be33 = numpy.histogram(Rads_2XRhythm,bins=bin_size,range=range_rads) bins33 = be33[:-1]+numpy.diff(be33)/2. PrefPhase_ThetaX2 = bins33[heights33 == numpy.amax(heights33)] heights44,be44 = numpy.histogram(Rads_3XRhythm,bins=bin_size,range=range_rads) bins44 = be44[:-1]+numpy.diff(be44)/2. PrefPhase_ThetaX3 = bins44[heights44 == numpy.amax(heights44)] Rads_Baseline_MeanBins,be11,bn11 = scipy.stats.binned_statistic(Rads_Baseline_Sorted,Rads_Baseline_Sorted,statistic='mean',bins=bin_size,range=range_rads) _BMeans = Rads_Baseline_MeanBins Rads_Baseline_MeanBins = Rads_Baseline_MeanBins[~numpy.isnan(Rads_Baseline_MeanBins)] Rads_Baseline_MeanBins = numpy.append(Rads_Baseline_MeanBins,Rads_Baseline_MeanBins[0]) Rads_1XRhythm_MeanBins,be21,bn21 = scipy.stats.binned_statistic(Rads_1XRhythm_Sorted,Rads_1XRhythm_Sorted,statistic='mean',bins=bin_size,range=range_rads) _1Means = Rads_1XRhythm_MeanBins Rads_1XRhythm_MeanBins = Rads_1XRhythm_MeanBins[~numpy.isnan(Rads_1XRhythm_MeanBins)] Rads_1XRhythm_MeanBins = numpy.append(Rads_1XRhythm_MeanBins,Rads_1XRhythm_MeanBins[0]) Rads_2XRhythm_MeanBins,be31,bn31 = scipy.stats.binned_statistic(Rads_2XRhythm_Sorted,Rads_2XRhythm_Sorted,statistic='mean',bins=bin_size,range=range_rads) _2Means = Rads_2XRhythm_MeanBins Rads_2XRhythm_MeanBins = Rads_2XRhythm_MeanBins[~numpy.isnan(Rads_2XRhythm_MeanBins)] Rads_2XRhythm_MeanBins = numpy.append(Rads_2XRhythm_MeanBins,Rads_2XRhythm_MeanBins[0]) Rads_3XRhythm_MeanBins,be41,bn41 = scipy.stats.binned_statistic(Rads_3XRhythm_Sorted,Rads_3XRhythm_Sorted,statistic='mean',bins=bin_size,range=range_rads) _3Means = Rads_3XRhythm_MeanBins Rads_3XRhythm_MeanBins = Rads_3XRhythm_MeanBins[~numpy.isnan(Rads_3XRhythm_MeanBins)] Rads_3XRhythm_MeanBins = numpy.append(Rads_3XRhythm_MeanBins,Rads_3XRhythm_MeanBins[0]) IF_Baseline_MeanBins,be12,bn12 = scipy.stats.binned_statistic(Rads_Baseline_Sorted,IF_Baseline_Sorted,statistic='mean',bins=bin_size,range=range_rads) IF_Baseline_MeanBins = IF_Baseline_MeanBins[~numpy.isnan(_BMeans)] IF_Baseline_MeanBins = numpy.append(IF_Baseline_MeanBins,IF_Baseline_MeanBins[0]) IF_1XRhythm_MeanBins,be22,bn22 = scipy.stats.binned_statistic(Rads_1XRhythm_Sorted,IF_ThetaX1_Sorted,statistic='mean',bins=bin_size,range=range_rads) IF_1XRhythm_MeanBins = IF_1XRhythm_MeanBins[~numpy.isnan(_1Means)] IF_1XRhythm_MeanBins = numpy.append(IF_1XRhythm_MeanBins,IF_1XRhythm_MeanBins[0]) IF_2XRhythm_MeanBins,be32,bn32 = scipy.stats.binned_statistic(Rads_2XRhythm_Sorted,IF_ThetaX2_Sorted,statistic='mean',bins=bin_size,range=range_rads) IF_2XRhythm_MeanBins = IF_2XRhythm_MeanBins[~numpy.isnan(_2Means)] IF_2XRhythm_MeanBins = numpy.append(IF_2XRhythm_MeanBins,IF_2XRhythm_MeanBins[0]) IF_3XRhythm_MeanBins,be42,bn42 = scipy.stats.binned_statistic(Rads_3XRhythm_Sorted,IF_ThetaX3_Sorted,statistic='mean',bins=bin_size,range=range_rads) IF_3XRhythm_MeanBins = IF_3XRhythm_MeanBins[~numpy.isnan(_3Means)] IF_3XRhythm_MeanBins = numpy.append(IF_3XRhythm_MeanBins,IF_3XRhythm_MeanBins[0]) IF_Baseline_MinsBins,be111,bn111 = scipy.stats.binned_statistic(Rads_Baseline_Sorted,IF_Baseline_Sorted,statistic='min',bins=bin_size,range=range_rads) IF_Baseline_MinsBins = IF_Baseline_MinsBins[~numpy.isnan(_BMeans)] IF_Baseline_MinsBins = numpy.append(IF_Baseline_MinsBins,IF_Baseline_MinsBins[0]) IF_1XRhythm_MinsBins,be211,bn211 = scipy.stats.binned_statistic(Rads_1XRhythm_Sorted,IF_ThetaX1_Sorted,statistic='min',bins=bin_size,range=range_rads) IF_1XRhythm_MinsBins = IF_1XRhythm_MinsBins[~numpy.isnan(_1Means)] IF_1XRhythm_MinsBins = numpy.append(IF_1XRhythm_MinsBins,IF_1XRhythm_MinsBins[0]) IF_2XRhythm_MinsBins,be311,bn311 = scipy.stats.binned_statistic(Rads_2XRhythm_Sorted,IF_ThetaX2_Sorted,statistic='min',bins=bin_size,range=range_rads) IF_2XRhythm_MinsBins = IF_2XRhythm_MinsBins[~numpy.isnan(_2Means)] IF_2XRhythm_MinsBins = numpy.append(IF_2XRhythm_MinsBins,IF_2XRhythm_MinsBins[0]) IF_3XRhythm_MinsBins,be411,bn411 = scipy.stats.binned_statistic(Rads_3XRhythm_Sorted,IF_ThetaX3_Sorted,statistic='min',bins=bin_size,range=range_rads) IF_3XRhythm_MinsBins = IF_3XRhythm_MinsBins[~numpy.isnan(_3Means)] IF_3XRhythm_MinsBins = numpy.append(IF_3XRhythm_MinsBins,IF_3XRhythm_MinsBins[0]) IF_Baseline_MaxBins,be111,bn111 = scipy.stats.binned_statistic(Rads_Baseline_Sorted,IF_Baseline_Sorted,statistic='max',bins=bin_size,range=range_rads) IF_Baseline_MaxBins = IF_Baseline_MaxBins[~numpy.isnan(_BMeans)] IF_Baseline_MaxBins = numpy.append(IF_Baseline_MaxBins,IF_Baseline_MaxBins[0]) IF_1XRhythm_MaxBins,be211,bn211 = scipy.stats.binned_statistic(Rads_1XRhythm_Sorted,IF_ThetaX1_Sorted,statistic='max',bins=bin_size,range=range_rads) IF_1XRhythm_MaxBins = IF_1XRhythm_MaxBins[~numpy.isnan(_1Means)] IF_1XRhythm_MaxBins = numpy.append(IF_1XRhythm_MaxBins,IF_1XRhythm_MaxBins[0]) IF_2XRhythm_MaxBins,be311,bn311 = scipy.stats.binned_statistic(Rads_2XRhythm_Sorted,IF_ThetaX2_Sorted,statistic='max',bins=bin_size,range=range_rads) IF_2XRhythm_MaxBins = IF_2XRhythm_MaxBins[~numpy.isnan(_2Means)] IF_2XRhythm_MaxBins = numpy.append(IF_2XRhythm_MaxBins,IF_2XRhythm_MaxBins[0]) IF_3XRhythm_MaxBins,be411,bn411 = scipy.stats.binned_statistic(Rads_3XRhythm_Sorted,IF_ThetaX3_Sorted,statistic='max',bins=bin_size,range=range_rads) IF_3XRhythm_MaxBins = IF_3XRhythm_MaxBins[~numpy.isnan(_3Means)] IF_3XRhythm_MaxBins = numpy.append(IF_3XRhythm_MaxBins,IF_3XRhythm_MaxBins[0]) IF_Baseline_StdBins,be111,bn111 = scipy.stats.binned_statistic(Rads_Baseline_Sorted,IF_Baseline_Sorted,statistic='std',bins=bin_size,range=range_rads) IF_Baseline_StdBins = IF_Baseline_StdBins[~numpy.isnan(_BMeans)] IF_Baseline_StdBins = numpy.append(IF_Baseline_StdBins,IF_Baseline_StdBins[0]) IF_1XRhythm_StdBins,be211,bn211 = scipy.stats.binned_statistic(Rads_1XRhythm_Sorted,IF_ThetaX1_Sorted,statistic='std',bins=bin_size,range=range_rads) IF_1XRhythm_StdBins = IF_1XRhythm_StdBins[~numpy.isnan(_1Means)] IF_1XRhythm_StdBins = numpy.append(IF_1XRhythm_StdBins,IF_1XRhythm_StdBins[0]) IF_2XRhythm_StdBins,be311,bn311 = scipy.stats.binned_statistic(Rads_2XRhythm_Sorted,IF_ThetaX2_Sorted,statistic='std',bins=bin_size,range=range_rads) IF_2XRhythm_StdBins = IF_2XRhythm_StdBins[~numpy.isnan(_2Means)] IF_2XRhythm_StdBins = numpy.append(IF_2XRhythm_StdBins,IF_2XRhythm_StdBins[0]) IF_3XRhythm_StdBins,be411,bn411 = scipy.stats.binned_statistic(Rads_3XRhythm_Sorted,IF_ThetaX3_Sorted,statistic='std',bins=bin_size,range=range_rads) IF_3XRhythm_StdBins = IF_3XRhythm_StdBins[~numpy.isnan(_3Means)] IF_3XRhythm_StdBins = numpy.append(IF_3XRhythm_StdBins,IF_3XRhythm_StdBins[0]) axarr = pyplot.subplot(111, projection='polar') axarr.plot(Rads_Baseline_Sorted,IF_Baseline_Sorted,'b',label='Baseline') axarr.plot(Rads_1XRhythm_Sorted,IF_ThetaX1_Sorted,'r',label='ThetaX1') axarr.plot(Rads_2XRhythm_Sorted,IF_ThetaX2_Sorted,'g',label='ThetaX2') axarr.plot(Rads_3XRhythm_Sorted,IF_ThetaX3_Sorted,'c',label='ThetaX3') position = 292.5 axarr._r_label_position._t = (position, 0) axarr._r_label_position.invalidate() axarr.set_xticklabels(['0$^\circ$', '45$^\circ$', '90$^\circ$\nPeak', '135$^\circ$', '180$^\circ$', '225$^\circ$', '270$^\circ$\nTrough', '315$^\circ$']) # axarr.legend(loc=1) pyplot.tight_layout() pyplot.savefig('PLOTfiles/' + Case + '_PolarPlot_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.pdf', bbox_inches='tight') pyplot.savefig('PLOTfiles/' + Case + '_PolarPlot_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.png', bbox_inches='tight') pyplot.gcf().clear() pyplot.cla() pyplot.clf() pyplot.close() axarr = pyplot.subplot(111, projection='polar') axarr.plot(Rads_Baseline_MeanBins,IF_Baseline_MeanBins,'b',label='Baseline') # axarr.fill_between(Rads_Baseline_MeanBins,IF_Baseline_MinsBins,IF_Baseline_MaxBins,alpha=0.5, edgecolor='b', facecolor='b') axarr.fill_between(Rads_Baseline_MeanBins,numpy.clip(IF_Baseline_MeanBins-IF_Baseline_StdBins,0,1000),numpy.clip(IF_Baseline_MeanBins+IF_Baseline_StdBins,0,1000),alpha=0.5, edgecolor='b', facecolor='b') axarr.plot(Rads_1XRhythm_MeanBins,IF_1XRhythm_MeanBins,'r',label='ThetaX1') # axarr.fill_between(Rads_1XRhythm_MeanBins,IF_1XRhythm_MinsBins,IF_1XRhythm_MaxBins,alpha=0.5, edgecolor='r', facecolor='r') axarr.fill_between(Rads_1XRhythm_MeanBins,numpy.clip(IF_1XRhythm_MeanBins-IF_1XRhythm_StdBins,0,1000),numpy.clip(IF_1XRhythm_MeanBins+IF_1XRhythm_StdBins,0,1000),alpha=0.5, edgecolor='r', facecolor='r') axarr.plot(Rads_2XRhythm_MeanBins,IF_2XRhythm_MeanBins,'g',label='ThetaX2') # axarr.fill_between(Rads_2XRhythm_MeanBins,IF_2XRhythm_MinsBins,IF_2XRhythm_MaxBins,alpha=0.5, edgecolor='g', facecolor='g') axarr.fill_between(Rads_2XRhythm_MeanBins,numpy.clip(IF_2XRhythm_MeanBins-IF_2XRhythm_StdBins,0,1000),numpy.clip(IF_2XRhythm_MeanBins+IF_2XRhythm_StdBins,0,1000),alpha=0.5, edgecolor='g', facecolor='g') axarr.plot(Rads_3XRhythm_MeanBins,IF_3XRhythm_MeanBins,'c',label='ThetaX3') # axarr.fill_between(Rads_3XRhythm_MeanBins,IF_3XRhythm_MinsBins,IF_3XRhythm_MaxBins,alpha=0.5, edgecolor='c', facecolor='c') axarr.fill_between(Rads_3XRhythm_MeanBins,numpy.clip(IF_3XRhythm_MeanBins-IF_3XRhythm_StdBins,0,1000),numpy.clip(IF_3XRhythm_MeanBins+IF_3XRhythm_StdBins,0,1000),alpha=0.5, edgecolor='c', facecolor='c') position = 292.5 axarr._r_label_position._t = (position, 0) axarr._r_label_position.invalidate() axarr.set_xticklabels(['0$^\circ$', '45$^\circ$', '90$^\circ$\nPeak', '135$^\circ$', '180$^\circ$', '225$^\circ$', '270$^\circ$\nTrough', '315$^\circ$']) # axarr.legend(loc=1) pyplot.tight_layout() pyplot.savefig('PLOTfiles/' + Case + '_PolarPlotBinned_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.pdf', bbox_inches='tight') pyplot.savefig('PLOTfiles/' + Case + '_PolarPlotBinned_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.png', bbox_inches='tight') pyplot.gcf().clear() pyplot.cla() pyplot.clf() pyplot.close() axarr = pyplot.subplot(111, projection='polar') axarr.plot(Rads_Baseline_MeanBins,IF_Baseline_MeanBins,'b',label='Baseline') # axarr.fill_between(Rads_Baseline_MeanBins,IF_Baseline_MinsBins,IF_Baseline_MaxBins,alpha=0.5, edgecolor='b', facecolor='b') axarr.fill_between(Rads_Baseline_MeanBins,numpy.clip(IF_Baseline_MeanBins-IF_Baseline_StdBins,0,1000),numpy.clip(IF_Baseline_MeanBins+IF_Baseline_StdBins,0,1000),alpha=0.5, edgecolor='b', facecolor='b') position = 292.5 bottom = numpy.amax(numpy.clip(IF_Baseline_MeanBins+IF_Baseline_StdBins,0,1000))+5 width = range_rads[1]/(bin_size+1) axarr.bar(_BMeans, heights11, width=width, bottom=bottom,color='b') # for ph in range(0,len(PrefPhase_Baseline)): # axarr.annotate(' ', xy=(PrefPhase_Baseline[ph], numpy.amax(numpy.clip(IF_Baseline_MeanBins+IF_Baseline_StdBins,0,1000))), xytext=(0, 0),arrowprops=dict(facecolor='black', shrink=0.05),) axarr._r_label_position._t = (position, 0) axarr._r_label_position.invalidate() axarr.set_xticklabels(['0$^\circ$', '45$^\circ$', '90$^\circ$\nPeak', '135$^\circ$', '180$^\circ$', '225$^\circ$', '270$^\circ$\nTrough', '315$^\circ$']) # axarr.legend(loc=1) pyplot.tight_layout() pyplot.savefig('PLOTfiles/' + Case + '_PolarPlotBinnedBaseline_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.pdf', bbox_inches='tight') pyplot.savefig('PLOTfiles/' + Case + '_PolarPlotBinnedBaseline_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.png', bbox_inches='tight') pyplot.gcf().clear() pyplot.cla() pyplot.clf() pyplot.close() axarr = pyplot.subplot(111, projection='polar') axarr.plot(Rads_1XRhythm_MeanBins,IF_1XRhythm_MeanBins,'r',label='ThetaX1') # axarr.fill_between(Rads_1XRhythm_MeanBins,IF_1XRhythm_MinsBins,IF_1XRhythm_MaxBins,alpha=0.5, edgecolor='r', facecolor='r') axarr.fill_between(Rads_1XRhythm_MeanBins,numpy.clip(IF_1XRhythm_MeanBins-IF_1XRhythm_StdBins,0,1000),numpy.clip(IF_1XRhythm_MeanBins+IF_1XRhythm_StdBins,0,1000),alpha=0.5, edgecolor='r', facecolor='r') position = 292.5 bottom = numpy.amax(numpy.clip(IF_1XRhythm_MeanBins+IF_1XRhythm_StdBins,0,1000))+5 width = range_rads[1]/(bin_size+1) axarr.bar(_1Means, heights22, width=width, bottom=bottom,color='r') # for ph in range(0,len(PrefPhase_ThetaX1)): # axarr.annotate(' ', xy=(PrefPhase_ThetaX1[ph], numpy.amax(numpy.clip(IF_1XRhythm_MeanBins+IF_1XRhythm_StdBins,0,1000))), xytext=(0, 0),arrowprops=dict(facecolor='black', shrink=0.05),) axarr._r_label_position._t = (position, 0) axarr._r_label_position.invalidate() axarr.set_xticklabels(['0$^\circ$', '45$^\circ$', '90$^\circ$\nPeak', '135$^\circ$', '180$^\circ$', '225$^\circ$', '270$^\circ$\nTrough', '315$^\circ$']) # axarr.legend(loc=1) pyplot.tight_layout() pyplot.savefig('PLOTfiles/' + Case + '_PolarPlotBinned1XTheta_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.pdf', bbox_inches='tight') pyplot.savefig('PLOTfiles/' + Case + '_PolarPlotBinned1XTheta_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.png', bbox_inches='tight') pyplot.gcf().clear() pyplot.cla() pyplot.clf() pyplot.close() axarr = pyplot.subplot(111, projection='polar') axarr.plot(Rads_2XRhythm_MeanBins,IF_2XRhythm_MeanBins,'g',label='ThetaX2') # axarr.fill_between(Rads_2XRhythm_MeanBins,IF_2XRhythm_MinsBins,IF_2XRhythm_MaxBins,alpha=0.5, edgecolor='g', facecolor='g') axarr.fill_between(Rads_2XRhythm_MeanBins,numpy.clip(IF_2XRhythm_MeanBins-IF_2XRhythm_StdBins,0,1000),numpy.clip(IF_2XRhythm_MeanBins+IF_2XRhythm_StdBins,0,1000),alpha=0.5, edgecolor='g', facecolor='g') position = 292.5 bottom = numpy.amax(numpy.clip(IF_2XRhythm_MeanBins+IF_2XRhythm_StdBins,0,1000))+5 width = range_rads[1]/(bin_size+1) axarr.bar(_2Means, heights33, width=width, bottom=bottom,color='g') # for ph in range(0,len(PrefPhase_ThetaX2)): # axarr.annotate(' ', xy=(PrefPhase_ThetaX2[ph], numpy.amax(numpy.clip(IF_2XRhythm_MeanBins+IF_2XRhythm_StdBins,0,1000))), xytext=(0, 0),arrowprops=dict(facecolor='black', shrink=0.05),) axarr._r_label_position._t = (position, 0) axarr._r_label_position.invalidate() axarr.set_xticklabels(['0$^\circ$', '45$^\circ$', '90$^\circ$\nPeak', '135$^\circ$', '180$^\circ$', '225$^\circ$', '270$^\circ$\nTrough', '315$^\circ$']) # axarr.legend(loc=1) pyplot.tight_layout() pyplot.savefig('PLOTfiles/' + Case + '_PolarPlotBinned2XTheta_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.pdf', bbox_inches='tight') pyplot.savefig('PLOTfiles/' + Case + '_PolarPlotBinned2XTheta_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.png', bbox_inches='tight') pyplot.gcf().clear() pyplot.cla() pyplot.clf() pyplot.close() axarr = pyplot.subplot(111, projection='polar') axarr.plot(Rads_3XRhythm_MeanBins,IF_3XRhythm_MeanBins,'c',label='ThetaX3') # axarr.fill_between(Rads_3XRhythm_MeanBins,IF_3XRhythm_MinsBins,IF_3XRhythm_MaxBins,alpha=0.5, edgecolor='c', facecolor='c') axarr.fill_between(Rads_3XRhythm_MeanBins,numpy.clip(IF_3XRhythm_MeanBins-IF_3XRhythm_StdBins,0,1000),numpy.clip(IF_3XRhythm_MeanBins+IF_3XRhythm_StdBins,0,1000),alpha=0.5, edgecolor='c', facecolor='c') position = 292.5 bottom = numpy.amax(numpy.clip(IF_3XRhythm_MeanBins+IF_3XRhythm_StdBins,0,1000))+5 width = range_rads[1]/(bin_size+1) axarr.bar(_3Means, heights44, width=width, bottom=bottom,color='c') # for ph in range(0,len(PrefPhase_ThetaX3)): # axarr.annotate(' ', xy=(PrefPhase_ThetaX3[ph], numpy.amax(numpy.clip(IF_3XRhythm_MeanBins+IF_3XRhythm_StdBins,0,1000))), xytext=(0, 0),arrowprops=dict(facecolor='black', shrink=0.05),) axarr._r_label_position._t = (position, 0) axarr._r_label_position.invalidate() axarr.set_xticklabels(['0$^\circ$', '45$^\circ$', '90$^\circ$\nPeak', '135$^\circ$', '180$^\circ$', '225$^\circ$', '270$^\circ$\nTrough', '315$^\circ$']) # axarr.legend(loc=1) pyplot.tight_layout() pyplot.savefig('PLOTfiles/' + Case + '_PolarPlotBinned3XTheta_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.pdf', bbox_inches='tight') pyplot.savefig('PLOTfiles/' + Case + '_PolarPlotBinned3XTheta_' + ExampleString + '_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.png', bbox_inches='tight') pyplot.gcf().clear() pyplot.cla() pyplot.clf() pyplot.close() numpy.save('NPYfiles/' + Case + '_Areas_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.npy',numpy.array([Area1,Area2,Area3,Area4],dtype=numpy.float)) numpy.save('NPYfiles/' + Case + '_e8Hz_' + str('%0.2f' %h.prethetanoise) + '_prethetanoise.npy',numpy.array([e8Hz1,e8Hz2,e8Hz3,e8Hz4],dtype=numpy.float)) # LNI_LNE_LIS_LES # HNI_LNE_LIS_LES # LNI_HNE_LIS_LES # HNI_HNE_LIS_LES # LNI_LNE_HIS_LES # HNI_LNE_HIS_LES # LNI_HNE_HIS_LES # HNI_HNE_HIS_LES # LNI_LNE_LIS_HES # HNI_LNE_LIS_HES # LNI_HNE_LIS_HES # HNI_HNE_LIS_HES # LNI_LNE_HIS_HES # HNI_LNE_HIS_HES # LNI_HNE_HIS_HES # HNI_HNE_HIS_HES