287 lines
12 KiB
Python
287 lines
12 KiB
Python
import numpy as np
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import matplotlib.pyplot as plt
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import copy
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import argparse
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import collections
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import dispersiveXanes_alignment as alignment
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import dispersiveXanes_utils as utils
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import xanes_analyzeRun
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parser = argparse.ArgumentParser(description='Process argv')
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parser.add_argument('--run', type=int,default=82,help='which run to analyze')
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parser.add_argument('--force', action="store_true",help='force calculation')
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args = parser.parse_args()
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profile_ret = collections.namedtuple("profile_ret",["run","p1","p2","calibs"])
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nice_colors = ["#1b9e77", "#d95f02", "#7570b3"]
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gradual_colors = ['#014636', '#016c59', '#02818a', '#3690c0', '#67a9cf', '#a6bddb', '#d0d1e6']#, '#ece2f0']
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def calcSpectraForRun(run=82,calibs="all",realign=False,init="auto",alignCalib=0,force=False):
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""" Calculate spectra (spec1, spec2) for run based on alignment.
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Alignment can be 'forced' with realign=True.
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In such a case
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init = run for initial alignment
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alignCalib = calibcycle for alignment
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"""
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if init=="auto": init=run
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if isinstance(run,int):
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r = xanes_analyzeRun.AnalyzeRun(run,initAlign=init)
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else:
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r = run
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if realign:
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r.doShots(slice(20),calib=refCalib,doFit=True)
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r.saveTransform()
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# next line is used to force calculations in case of realignment
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fname = 'auto' if not realign else "thisfiledoesnotexists"
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if force: fname = "thisfiledoesnotexists"
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if len(r.results) == 0:
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try:
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r.load(fname)
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print("Loading previously saved results")
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except FileNotFoundError:
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r.analyzeScan(calibs=calibs,nImagesToFit=0,nSaveImg=4)
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r.save(overwrite=True)
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# cannot take the output from r.results because it might have been calculated for
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# a bigger range than asked for.
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if isinstance(calibs,int):
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calibsForOut = (calibs,)
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elif isinstance(calibs,slice):
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calibsForOut = list(range(r.nCalib))[calibs]
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elif calibs == "all":
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calibsForOut = r.results.keys()
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else:
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calibsForOut = calibs
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# focused data have one single calibcycle ...
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if len(r.results) > 1:
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p1 = [r.results[calib].p1 for calib in calibsForOut]
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p2 = [r.results[calib].p2 for calib in calibsForOut]
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else:
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idx = r.results[None].fom < 0.5
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p1 = [ r.results[None].p1[idx], r.results[None].p1[~idx] ]
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p2 = [ r.results[None].p2[idx], r.results[None].p2[~idx] ]
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return profile_ret( run =r, p1 =p1, p2=p2,calibs=calibsForOut)
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def calcSpectraForRefAndSample(run=82,refCalibs=slice(None,None,2),forceSpectraCalculation=False):
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""" Function to calculate the Spectra with and without (ref) the sample.
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It can analyze two kinds of runs:
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* Single run with that alternates IN and OUT (like run 82)
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in this case use something like:
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calcSpectraForRefAndSample(82,refCalibs=slice(None,None,2)
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or
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calcSpectraForRefAndSample(82,refCalibs=(0,2,4,6))
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* Multiple runs (one with reference and one with sample) like run 155 and 156
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in this case use something like:
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calcSpectraForRefAndSample( run=(155,156) )
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where the first is the reference run and the second the one with the sample.
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in this second case the refCalibs does not play a role
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use forceSpectraCalculation = True, to re-read the images
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"""
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if isinstance(run,int):
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run = xanes_analyzeRun.AnalyzeRun(run)
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if isinstance(refCalibs,slice): refCalibs = list(range(run.nCalib))[refCalibs]
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if isinstance(refCalibs,int): refCalibs = [refCalibs,]
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sampleCalibs = [c+1 for c in refCalibs]
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# need a single call (for sample and ref) to save all calibcycles
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data= calcSpectraForRun(run,calibs=refCalibs+sampleCalibs,\
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force=forceSpectraCalculation);
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# for focused runs
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if len(data.run.results) == 1:
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ref = profile_ret(run=data.run,p1=[data.p1[0],],p2=[data.p2[0],],calibs=[0,])
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sample = profile_ret(run=data.run,p1=[data.p1[1],],p2=[data.p2[1],],calibs=[0,])
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else:
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ref = calcSpectraForRun(run,calibs=refCalibs)
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sample = calcSpectraForRun(run,calibs=sampleCalibs)
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elif isinstance(run,(list,tuple)):
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refRun = xanes_analyzeRun.AnalyzeRun(run[0])
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sampleRun = xanes_analyzeRun.AnalyzeRun(run[1],initAlign=run[0])
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refCalibs = [0,]
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sampleCalibs = [0,]
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ref = calcSpectraForRun(refRun,calibs=refCalibs,\
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force=forceSpectraCalculation)
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sample = calcSpectraForRun(sampleRun,calibs=sampleCalibs,\
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force=forceSpectraCalculation)
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return ref,sample
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def calcRef(r1,r2,calibs=None,threshold=0.05):
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""" r1 and r2 are list of 2d arrays (nShots,nPixels) for each calibcycle """
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if calibs is None: calibs = list(range(len(r1)))
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out = collections.OrderedDict()
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out["ratioOfAverage"] = dict()
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out["medianOfRatios"] = dict()
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for p1,p2,n in zip(r1,r2,calibs):
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out["ratioOfAverage"][n] = utils.ratioOfAverage(p1,p2,threshold=threshold)
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out["medianOfRatios"][n] = utils.medianRatio(p1,p2,threshold=threshold)
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# add curves with all calib together
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p1 = np.vstack(r1)
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p2 = np.vstack(r2)
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n = ",".join(map(str,calibs))
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ref1 = utils.ratioOfAverage(p1,p2,threshold=threshold)
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ref2 = utils.medianRatio(p1,p2,threshold=threshold)
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out["ratioOfAverage"][n] = utils.ratioOfAverage(p1,p2,threshold=threshold)
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out["medianOfRatios"][n] = utils.medianRatio(p1,p2,threshold=threshold)
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out["ratioOfAverage"]['all'] = out["ratioOfAverage"][n]
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out["medianOfRatios"]['all'] = out["medianOfRatios"][n]
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return out
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def showDifferentRefs(run=82,refCalibs=slice(None,None,2),threshold=0.05):
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""" example plots showing how stable are the different ways of taking spectra """
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prof = calcSpectraForRun(run,calibs=refCalibs)
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refs = calcRef(prof.p1,prof.p2,calibs=prof.calibs)
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kind_of_av = list(refs.keys())
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fig,ax=plt.subplots(len(kind_of_av)+1,1,sharex=True,sharey=True)
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E = prof.run.E
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calibs = list(refs[kind_of_av[0]].keys())
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for ikind,kind in enumerate(kind_of_av):
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for calib in calibs:
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if isinstance(calib,int):
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ax[ikind].plot(E,refs[kind][calib],label="calib %s"%calib)
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else:
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if calibs == 'all': continue
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ax[ikind].plot(E,refs[kind][calib],label="calib %s"%calib,lw=2,color='k',alpha=0.7)
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ax[-1].plot(E,refs[kind][calib],label="calib all, %s"%kind,lw=1.5,color=nice_colors[ikind],alpha=0.8)
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for ikind,kind in enumerate(kind_of_av): ax[ikind].set_title("Run %d, %s"%(run,kind))
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ax[0].set_ylim(0.88,1.12)
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ax[0].set_ylim(0.88,1.12)
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ax[-2].legend()
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ax[-1].legend()
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for a in ax: a.grid()
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def calcSampleAbs(run=82,refCalibs=slice(None,None,2),threshold=0.05,refKind="medianOfRatios",forceSpectraCalculation=False):
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""" example of use
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ratio = calcSampleAbs(82)
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ratio = calcSampleAbs( (155,156) )
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"""
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ref,sample = calcSpectraForRefAndSample(run,refCalibs=refCalibs,forceSpectraCalculation=forceSpectraCalculation)
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temp = calcRef(ref.p1,ref.p2,calibs=ref.calibs,threshold=threshold)
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ref = temp[refKind]['all']
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p1 = np.vstack( sample.p1 )
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p2 = np.vstack( sample.p2 )
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print(p1.shape)
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p1,p2 = utils.maskLowIntensity(p1,p2,threshold=threshold)
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ratio = p2/p1
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ratio = ratio/ref
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return p1,p2,-np.log10(ratio)
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def showSpectra(run=82,shots=slice(5),calibs=0,averageEachCalib=False,
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normalization="auto",shifty=1,xlim=(7060,7180),showAv=True):
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""" averageEachCalib: if True, plot only one (averaged) spectrum per calibcycle
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normalization: if "auto", the max of the spectra that will be plotted will be used
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"""
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r = xanes_analyzeRun.AnalyzeRun(run=run)
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r.load()
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calibsSaved = list(r.results.keys()); calibsSaved.sort()
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res = [ r.results[c].p2 for c in calibsSaved ]
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if isinstance(calibs,slice): res=res[calibs]
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if isinstance(calibs,int): res=[res[calibs],]
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avCalibs = [ np.nanmedian(spectra,axis=0) for spectra in res ]
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if averageEachCalib:
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res = avCalibs
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showAv = False; # it does not make sense to plot it twice !
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fig,ax = plt.subplots(len(res),1,sharex=True,sharey=True,squeeze=False)
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if normalization == "auto": normalization = np.nanmax( [temp[shots] for temp in res] )
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for (av,spectra,a) in zip(avCalibs,res,ax[:,0]):
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spectra_norm = spectra[shots]/normalization
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av_norm = av/normalization
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for i,spectrum in enumerate(spectra_norm):
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color = gradual_colors[i%len(gradual_colors)]
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a.axhline(i*shifty,ls='--',color=color)
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if showAv: a.fill_between(r.E,i*shifty,av_norm+i*shifty,color='#d95f0e',alpha=0.4)
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print(i)
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a.plot(r.E,spectrum+i*shifty,color=color,lw=2)
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ax[0][0].set_xlim(*xlim)
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ax[0][0].set_title("Run %d"%run)
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if not averageEachCalib: ax[0][0].set_ylim(0,shifty*(len(spectra_norm)))
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color_ss = '#08519c'
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color_av = '#238b45'
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color_av_all = '#d95f0e'
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def showAbs(run=82,shots=slice(5),normalization="auto",shifty=1,xlim=(7080,7180),showAv=True,showAvOverAll=True,smoothWidth=0,threshold=0.01,filterShot=0.1):
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""" normalization: if "auto", the max of the spectra that will be plotted will be used
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filterShot = means that it filters out the filterShot*100 percentile
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"""
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E = alignment.defaultE
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p1,p2,abs = calcSampleAbs(run=run,threshold=threshold)
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p1_sum = p1.sum(-1)
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if filterShot>0:
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idx = p1_sum>np.percentile(p1_sum,filterShot*100)
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p1 = p1[idx]
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p2 = p2[idx]
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abs = abs[idx]
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p1_av = np.nanmean(p1,axis=0)
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p2_av = np.nanmean(p2,axis=0)
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# somehow nanmedian screws up when array is too big ... so using nanmean
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abs_av = np.nanmean(abs,axis=0)
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p1 = p1[shots]; p2=p2[shots]; abs = abs[shots]
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if smoothWidth > 0: abs = smoothSpectra(E,abs,res=smoothWidth)
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fig,ax = plt.subplots(1,2,sharex=True,sharey=True,squeeze=False)
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ax = ax[0]
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if normalization == "auto": normalization = np.nanmax( p1 )
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for ishot,(s1,s2,a) in enumerate(zip(p1,p2,abs)):
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s1_norm = s1/normalization
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s2_norm = s2/normalization
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color = gradual_colors[ishot%len(gradual_colors)]
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ax[0].axhline(ishot*shifty,ls='--',color=color)
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ax[1].axhline(ishot*shifty,ls='--',color=color)
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if showAvOverAll:
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if ishot == 0: ax[0].fill_between(E,ishot*shifty,p1_av/normalization+ishot*shifty,color=color_av_all,alpha=0.6)
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ax[1].plot(E,abs_av+ishot*shifty,color=color_av_all,lw=2,zorder=20)
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if showAv:
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ax[1].plot(E,np.nanmedian(abs,0)+ishot*shifty,color=color_av,lw=2,zorder=10)
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ax[0].plot(E,s1_norm+ishot*shifty,ls = '-' ,color='0.8',lw=2)
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ax[0].plot(E,s2_norm+ishot*shifty,ls = '-' ,color='0.3',lw=2)
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ax[1].plot(E,a+ishot*shifty,color=color_ss,lw=2)
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ax[0].set_xlim(*xlim)
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ax[0].set_title("Run %s"%str(run))
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ax[1].set_ylabel("Sample Absorption")
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ax[0].set_ylabel("Normalized Spectra")
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ax[0].set_ylim(0,shifty*(p1.shape[0]))
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print("STD of (average over shown shots) - (average over all): %.3f"%np.nanstd(np.nanmedian(abs,0)-abs_av))
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ax[1].set_title("STD of (average_{shown}) - (average_{all}): %.3f"%np.nanstd(np.nanmedian(abs,0)-abs_av))
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def showAbsWithSweep(run=(155,156),first=0,period=150,nSpectra=10,**kwards):
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shots = slice(first,first+period,int(period/nSpectra))
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showAbs(run=run,shots=shots,**kwards)
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def smoothSpectra(E,abs_spectra,res=0.5):
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from scipy import integrate
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if abs_spectra.ndim == 1: abs_spectra=abs_spectra[np.newaxis,:]
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out = np.empty_like(abs_spectra)
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for ispectrum in range(abs_spectra.shape[0]):
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idx = np.isfinite(abs_spectra[ispectrum])
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Eclean = E[idx]
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for i in range(len(E)):
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g = 1/np.sqrt(2*np.pi)/res*np.exp(-(E-E[i])**2/2/res**2)
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tointegrate = g*abs_spectra[ispectrum]
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# filter out nans
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tointegrate = tointegrate[idx]
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out[ispectrum,i] = integrate.simps(tointegrate,x=Eclean)
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return out
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def doLongCalc():
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#calcSpectraForRefAndSample(82,forceSpectraCalculation=True)
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# scanning requires a lower level call
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r = xanes_analyzeRun.AnalyzeRun(84)
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r.analyzeScan(nShotsPerCalib="all",calibs="all",nSaveImg=2,calibsToFit='even',nImagesToFit=3)
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r.save(overwrite=True)
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#calcSpectraForRefAndSample(84,forceSpectraCalculation=False)
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calcSpectraForRefAndSample(96,forceSpectraCalculation=True)
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calcSpectraForRefAndSample((155,156),forceSpectraCalculation=True)
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#r = calcSpectra(run,refCalibs=refCalib,force=force)
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if __name__ == "__main__":
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pass
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#main(args.run,force=args.force)
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