def doFit(ws,options): rap_bins = range(1,len(jpsi.pTRange)) pt_bins = None if options.testBin is not None: rap_bins = [int(options.testBin.split(',')[0])] pt_bins = [int(options.testBin.split(',')[1])-1] for rap_bin in rap_bins: if options.testBin is None: pt_bins = range(len(jpsi.pTRange[rap_bin])) for pt_bin in pt_bins: sigMaxMass = jpsi.polMassJpsi[rap_bin] + jpsi.nSigMass*jpsi.sigmaMassJpsi[rap_bin] sigMinMass = jpsi.polMassJpsi[rap_bin] - jpsi.nSigMass*jpsi.sigmaMassJpsi[rap_bin] sbHighMass = jpsi.polMassJpsi[rap_bin] + jpsi.nSigBkgHigh*jpsi.sigmaMassJpsi[rap_bin] sbLowMass = jpsi.polMassJpsi[rap_bin] - jpsi.nSigBkgLow*jpsi.sigmaMassJpsi[rap_bin] jPsiMass = ws.var('JpsiMass') jPsicTau = ws.var('Jpsict') jPsiMass.setRange('mlfit_prompt',2.7,3.5) jPsiMass.setRange('mlfit_nonPrompt',2.7,3.5) jPsiMass.setRange('NormalizationRangeFormlfit_prompt',2.7,3.5) jPsiMass.setRange('NormalizationRangeFormlfit_nonPrompt',2.7,3.5) jPsicTau.setRange('mlfit_signal',-1,2.5) jPsicTau.setRange('mlfit_leftMassSideBand',-1,2.5) jPsicTau.setRange('mlfit_rightMassSideBand',-1,2.5) jPsicTau.setRange('NormalizationRangeFormlfit_signal',-1,2.5) jPsicTau.setRange('NormalizationRangeFormlfit_leftMassSideBand',-1,2.5) jPsicTau.setRange('NormalizationRangeFormlfit_rightMassSideBand',-1,2.5) #jPsicTau.setRange('NormalizationRangeFormlfit_promptSignal',-1,.1) #jPsicTau.setRange('NormalizationRangeFormlfit_nonPromptSignal',.1,2.5) #jPsicTau.setRange('NormalizationRangeFormlfit_leftMassSideBand',-1,2.5) #jPsicTau.setRange('NormalizationRangeFormlfit_rightMassSideBand',-1,2.5) #jPsicTau.setRange('mlfit_promptSignal',-1,.1) #jPsicTau.setRange('mlfit_nonPromptSignal',.1,2.5) #jPsicTau.setRange('mlfit_leftMassSideBand',-1,2.5) #jPsicTau.setRange('mlfit_rightMassSideBand',-1,2.5) #reset parameters ws.var('CBn').setVal(.5) ws.var('CBalpha').setVal(.5) ws.var('CBmass').setVal(3.1) ws.var('CBsigma').setVal(.02) ws.var('bkgLambda').setVal(0) ws.var('bkgTauSSDL').setVal(.5) #ws.var('bkgTauFDL').setVal(.5) ws.var('bkgTauDSDL').setVal(.5) ws.var('fBkgSSDL').setVal(.5) ws.var('fBkgLR').setVal(.5) ws.var('bkgTauSSDR').setVal(.5) #ws.var('bkgTauFDR').setVal(.5) ws.var('bkgTauDSDR').setVal(.5) ws.var('fBkgSSDR').setVal(.5) #ws.var('fBkgFDR').setVal(.25) #ws.var('nPrompt').setVal(5000) #ws.var('nNonPrompt').setVal(500) #ws.var('nBackground').setVal(100) #ws.var('nBackgroundL').setVal(50) #ws.var('nBackgroundR').setVal(50) ws.var('nonPromptTau').setVal(.5) ws.var('promptMean').setVal(0) ws.var('ctResolution').setVal(1) LPdf = ws.pdf('LPdf') MPdf = ws.pdf('MPdf') data = ws.data('data_rap'+str(rap_bin)+'_pt'+str(pt_bin+1)) NLLs = RooArgSet() MassNLL = MPdf.createNLL(data, ROOT.RooFit.Range('mlfit'), ROOT.RooFit.SplitRange(True), ROOT.RooFit.ConditionalObservables(RooArgSet(ws.var('JpsictErr'))), ROOT.RooFit.NumCPU(2)) CTauNLL = LPdf.createNLL(data, ROOT.RooFit.Range('mlfit'), ROOT.RooFit.SplitRange(True), ROOT.RooFit.ConditionalObservables(RooArgSet(ws.var('JpsictErr'))), ROOT.RooFit.NumCPU(2)) NLLs.add(MassNLL) NLLs.add(CTauNLL) simNLL = RooAddition('add','add',NLLs) minuit = RooMinuit(simNLL) minuit.setStrategy(2) minuit.setPrintEvalErrors(-1) minuit.simplex() minuit.migrad() minuit.migrad() minuit.hesse() fitresult = minuit.save('polfitresult_rap'+str(rap_bin)+'_pt'+str(pt_bin+1)) getattr(ws,'import')(fitresult) ws.saveSnapshot('snapshot_rap'+str(rap_bin)+'_pt'+str(pt_bin+1),ws.allVars())
def main(infiles=None): infile = infiles[0] var = "leadmupt" bounds = [25, 300] c1 = ROOT.TCanvas("NLL", "NLL", 1000, 1000) x = ROOT.RooRealVar(var, var, bounds[0], bounds[1]) aset = ROOT.RooArgSet(x, "aset") frame = x.frame() f = ROOT.TFile.Open(infile) tree = f.Get(f.GetListOfKeys().At(0).GetName()) tree.Print() nentries = tree.GetEntries() y = [] dh2 = ROOT.TH1F() data = ROOT.RooDataSet("Data", "Data", aset) for n in range(nentries): tree.GetEntry(n) y.append(getattr(tree, var)) if y[n] <= bounds[1] and y[n] >= bounds[0]: x.setVal(y[n]) data.add(aset) dh2.Fill(y[n]) data.plotOn(frame) dh = RooDataHist("dh", "dh", RooArgSet(x), data) nbins = dh2.GetNbinsX() nbinsy = dh2.GetNbinsX() print("nbins: ", nbins) print("nbinsy: ", nbinsy) for i in range(nbins): if dh2.GetBinContent(dh2.GetBin(i)) == 0: print("bin: ", i) #dh2.SetBinError(bin,0.01) ## CREATE GAUSSIAN MODEL mx = RooRealVar("mx", "mx", 10, 0, 350) sx = RooRealVar("sx", "sx", 3, 0, 10) gx = RooGaussian("gx", "gx", x, mx, sx) ## CREATE EXPONENTIAL MODEL lambda1 = RooRealVar("lambda1", "slope1", -100, 100) expo1 = RooExponential("expo1", "exponential PDF 1", x, lambda1) lambda2 = RooRealVar("lambda2", "slope2", -.03, -1000, 1000) expo2 = RooExponential("expo2", "exponential PDF 2", x, lambda2) l1 = RooRealVar("l1", "yield1", 100, 0, 10000) l2 = RooRealVar("l2", "yield2", 100, 0, 10000) #sum = RooAddPdf("sum","exp and gauss",RooArgList(expo1,gx),RooArgList(l1,l2)) sum = RooAddPdf("sum", "2 exps", RooArgList(expo1, expo2), RooArgList(l1, l2)) ## Construct binned likelihood nll = RooNLLVar("nll", "nll", expo1, data, ROOT.RooFit.Extended(True)) ## Start Minuit session on NLL m = RooMinuit(nll) m.migrad() m.hesse() r1 = m.save() #sum.plotOn(frame,ROOT.RooFit.LineColor(1)) #sum.plotOn(frame,ROOT.RooFit.Components("expo1"),ROOT.RooFit.LineColor(2)) #sum.plotOn(frame,ROOT.RooFit.Components("expo2"),ROOT.RooFit.LineColor(3)) expo1.plotOn(frame) ## Construct Chi2 chi2 = RooChi2Var("chi2", "chi2", expo2, dh) ## Start Minuit session on Chi2 m2 = RooMinuit(chi2) m2.migrad() m2.hesse() r2 = m2.save() frame.Draw() c2 = ROOT.TCanvas("Chi2", "Chi2", 1000, 1000) frame2 = x.frame() data.plotOn(frame2) expo2.plotOn(frame2) #sum.plotOn(frame2,ROOT.RooFit.LineColor(4)) #sum.plotOn(frame2,ROOT.RooFit.Components("expo1"),ROOT.RooFit.LineColor(5)) #sum.plotOn(frame2,ROOT.RooFit.Components("expo2"),ROOT.RooFit.LineColor(6)) ## Print results print("result of likelihood fit") r1.Print("v") print("result of chi2 fit") r2.Print("v") frame2.Draw() c1.Draw() c2.Draw() rep = '' while not rep in ['q', 'Q']: rep = input('enter "q" to quit: ') if 1 < len(rep): rep = rep[0]
def doFit(ws,options): rap_bins = range(1,len(jpsi.pTRange)) pt_bins = None if options.testBin is not None: rap_bins = [int(options.testBin.split(',')[0])] pt_bins = [int(options.testBin.split(',')[1])-1] for rap_bin in rap_bins: if options.testBin is None: pt_bins = range(len(jpsi.pTRange[rap_bin])) for pt_bin in pt_bins: sigMaxMass = jpsi.polMassJpsi[rap_bin] + jpsi.nSigMass*jpsi.sigmaMassJpsi[rap_bin] sigMinMass = jpsi.polMassJpsi[rap_bin] - jpsi.nSigMass*jpsi.sigmaMassJpsi[rap_bin] sbHighMass = jpsi.polMassJpsi[rap_bin] + jpsi.nSigBkgHigh*jpsi.sigmaMassJpsi[rap_bin] sbLowMass = jpsi.polMassJpsi[rap_bin] - jpsi.nSigBkgLow*jpsi.sigmaMassJpsi[rap_bin] jPsiMass = ws.var('JpsiMass') jPsicTau = ws.var('Jpsict') jPsiMass.setRange('mlfit_prompt',2.7,3.5) jPsiMass.setRange('mlfit_nonPrompt',2.7,3.5) jPsiMass.setRange('NormalizationRangeFormlfit_prompt',2.7,3.5) jPsiMass.setRange('NormalizationRangeFormlfit_nonPrompt',2.7,3.5) jPsicTau.setRange('mlfit_signal',-1,2.5) jPsicTau.setRange('mlfit_leftMassSideBand',-1,2.5) jPsicTau.setRange('mlfit_rightMassSideBand',-1,2.5) jPsicTau.setRange('NormalizationRangeFormlfit_signal',-1,2.5) jPsicTau.setRange('NormalizationRangeFormlfit_leftMassSideBand',-1,2.5) jPsicTau.setRange('NormalizationRangeFormlfit_rightMassSideBand',-1,2.5) #jPsicTau.setRange('NormalizationRangeFormlfit_promptSignal',-1,.1) #jPsicTau.setRange('NormalizationRangeFormlfit_nonPromptSignal',.1,2.5) #jPsicTau.setRange('NormalizationRangeFormlfit_leftMassSideBand',-1,2.5) #jPsicTau.setRange('NormalizationRangeFormlfit_rightMassSideBand',-1,2.5) #jPsicTau.setRange('mlfit_promptSignal',-1,.1) #jPsicTau.setRange('mlfit_nonPromptSignal',.1,2.5) #jPsicTau.setRange('mlfit_leftMassSideBand',-1,2.5) #jPsicTau.setRange('mlfit_rightMassSideBand',-1,2.5) #reset parameters ws.var('CBn').setVal(.5) ws.var('CBalpha').setVal(.5) ws.var('CBmass').setVal(3.1) ws.var('CBsigma').setVal(.02) ws.var('bkgLambda').setVal(0) ws.var('bkgTauSSDL').setVal(.5) #ws.var('bkgTauFDL').setVal(.5) ws.var('bkgTauDSDL').setVal(.5) ws.var('fBkgSSDL').setVal(.5) ws.var('fBkgLR').setVal(.5) ws.var('bkgTauSSDR').setVal(.5) #ws.var('bkgTauFDR').setVal(.5) ws.var('bkgTauDSDR').setVal(.5) ws.var('fBkgSSDR').setVal(.5) #ws.var('fBkgFDR').setVal(.25) #ws.var('nPrompt').setVal(5000) #ws.var('nNonPrompt').setVal(500) #ws.var('nBackground').setVal(100) #ws.var('nBackgroundL').setVal(50) #ws.var('nBackgroundR').setVal(50) ws.var('nonPromptTau').setVal(.5) ws.var('promptMean').setVal(0) ws.var('ctResolution').setVal(1) if options.fixBfrac: cutStringM1 = '('+jPsiMass.GetName()+' > '+str(sigMinMass)+' && '+jPsiMass.GetName()+' < '+str(sigMaxMass)+')' data2 = ws.data('data_rap'+str(rap_bin)+'_pt'+str(pt_bin+1)) dataSizeBfrac1 = data2.numEntries() print dataSizeBfrac1 bfracVars = RooArgSet(jPsiMass) bfracData = data2.reduce(ROOT.RooFit.SelectVars(bfracVars), ROOT.RooFit.Cut(cutStringM1), ROOT.RooFit.Name('data_for_normalizing_bfrac'), ROOT.RooFit.Title('data_for_normalizing_bfrac')) print rap_bin print pt_bin bfrac = jpsi.Bfrac[rap_bin-1][pt_bin] print bfrac dataSizeBfrac = bfracData.numEntries() factPrompt = 1-bfrac dataSizePrompt = dataSizeBfrac*factPrompt dataSizeNonPrompt = dataSizeBfrac*bfrac print factPrompt print dataSizeBfrac print dataSizePrompt print dataSizeNonPrompt ws.var('nPromptSignal').setVal(dataSizePrompt) ws.var('nNonPromptSignal').setVal(dataSizeNonPrompt) ws.var('nPromptSignal').setConstant() ws.var('nNonPromptSignal').setConstant() LPdf = ws.pdf('LPdf') MPdf = ws.pdf('MPdf') data = ws.data('data_rap'+str(rap_bin)+'_pt'+str(pt_bin+1)) NLLs = RooArgSet() MassNLL = MPdf.createNLL(data, ROOT.RooFit.Range('mlfit'), ROOT.RooFit.SplitRange(True), ROOT.RooFit.ConditionalObservables(RooArgSet(ws.var('JpsictErr'))), ROOT.RooFit.NumCPU(2)) CTauNLL = LPdf.createNLL(data, ROOT.RooFit.Range('mlfit'), ROOT.RooFit.SplitRange(True), ROOT.RooFit.ConditionalObservables(RooArgSet(ws.var('JpsictErr'))), ROOT.RooFit.NumCPU(2)) NLLs.add(MassNLL) NLLs.add(CTauNLL) simNLL = RooAddition('add','add',NLLs) minuit = RooMinuit(simNLL) minuit.setStrategy(2) minuit.setPrintEvalErrors(-1) if options.do_fit: minuit.simplex() minuit.migrad() minuit.migrad() minuit.hesse() fitresult = minuit.save('polfitresult_rap'+str(rap_bin)+'_pt'+str(pt_bin+1)) getattr(ws,'import')(fitresult) ws.saveSnapshot('snapshot_rap'+str(rap_bin)+'_pt'+str(pt_bin+1),ws.allVars()) fitresult.Print()
def rooFit601(): print ">>> setup pdf and likelihood..." x = RooRealVar("x", "x", -20, 20) mean = RooRealVar("mean", "mean of g1 and g2", 0) sigma1 = RooRealVar("sigma1", "width of g1", 3) sigma2 = RooRealVar("sigma2", "width of g2", 4, 3.0, 6.0) # intentional strong correlations gauss1 = RooGaussian("gauss1", "gauss1", x, mean, sigma1) gauss2 = RooGaussian("gauss2", "gauss2", x, mean, sigma2) frac = RooRealVar("frac", "frac", 0.5, 0.0, 1.0) model = RooAddPdf("model", "model", RooArgList(gauss1, gauss2), RooArgList(frac)) print ">>> generate to data..." data = model.generate(RooArgSet(x), 1000) # RooDataSet print ">>> construct unbinned likelihood of model wrt data..." nll = model.createNLL(data) # RooAbsReal print ">>> interactive minimization and error analysis with MINUIT interface object..." minuit = RooMinuit(nll) print ">>> set avtive verbosity for logging of MINUIT parameter space stepping..." minuit.setVerbose(kTRUE) print ">>> call MIGRAD to minimize the likelihood..." minuit.migrad() print "\n>>> parameter values and error estimates that are back propagated from MINUIT:" model.getParameters(RooArgSet(x)).Print("s") print "\n>>> disable verbose logging..." minuit.setVerbose(kFALSE) print ">>> run HESSE to calculate errors from d2L/dp2..." minuit.hesse() print ">>> value of and error on sigma2 (back propagated from MINUIT):" sigma2.Print() print "\n>>> run MINOS on sigma2 parameter only..." minuit.minos(RooArgSet(sigma2)) print "\n>>> value of and error on sigma2 (back propagated from MINUIT after running MINOS):" sigma2.Print() print "\n>>> saving results, contour plots..." # Save a snapshot of the fit result. This object contains the initial # fit parameters, the final fit parameters, the complete correlation # matrix, the EDM, the minimized FCN , the last MINUIT status code and # the number of times the RooFit function object has indicated evaluation # problems (e.g. zero probabilities during likelihood evaluation) result = minuit.save() # RooFitResult # Make contour plot of mx vs sx at 1,2,3 sigma frame1 = minuit.contour(frac, sigma2, 1, 2, 3) # RooPlot frame1.SetTitle("RooMinuit contour plot") # Print the fit result snapshot result.Print("v") print "\n>>> change value of \"mean\" parameter..." mean.setVal(0.3) # Rerun MIGRAD,HESSE print ">>> rerun MIGRAD, HESSE..." minuit.migrad() minuit.hesse() print ">>> value on and error of frac:" frac.Print() print "\n>>> fix value of \"sigma\" parameter (setConstant)..." sigma2.setConstant(kTRUE) print ">>> rerun MIGRAD, HESSE..." minuit.migrad() minuit.hesse() frac.Print()
def doFit(ws, options): rap_bins = range(1, len(jpsi.pTRange)) pt_bins = None if options.testBin is not None: rap_bins = [int(options.testBin.split(',')[0])] pt_bins = [int(options.testBin.split(',')[1]) - 1] for rap_bin in rap_bins: if options.testBin is None: pt_bins = range(len(jpsi.pTRange[rap_bin])) for pt_bin in pt_bins: sigMaxMass = jpsi.polMassJpsi[ rap_bin] + jpsi.nSigMass * jpsi.sigmaMassJpsi[rap_bin] sigMinMass = jpsi.polMassJpsi[ rap_bin] - jpsi.nSigMass * jpsi.sigmaMassJpsi[rap_bin] sbHighMass = jpsi.polMassJpsi[ rap_bin] + jpsi.nSigBkgHigh * jpsi.sigmaMassJpsi[rap_bin] sbLowMass = jpsi.polMassJpsi[ rap_bin] - jpsi.nSigBkgLow * jpsi.sigmaMassJpsi[rap_bin] jPsiMass = ws.var('JpsiMass') jPsicTau = ws.var('Jpsict') jPsiMass.setRange('mlfit_prompt', 2.7, 3.5) jPsiMass.setRange('mlfit_nonPrompt', 2.7, 3.5) jPsiMass.setRange('NormalizationRangeFormlfit_prompt', 2.7, 3.5) jPsiMass.setRange('NormalizationRangeFormlfit_nonPrompt', 2.7, 3.5) jPsicTau.setRange('mlfit_signal', -1, 2.5) jPsicTau.setRange('mlfit_leftMassSideBand', -1, 2.5) jPsicTau.setRange('mlfit_rightMassSideBand', -1, 2.5) jPsicTau.setRange('NormalizationRangeFormlfit_signal', -1, 2.5) jPsicTau.setRange('NormalizationRangeFormlfit_leftMassSideBand', -1, 2.5) jPsicTau.setRange('NormalizationRangeFormlfit_rightMassSideBand', -1, 2.5) #jPsicTau.setRange('NormalizationRangeFormlfit_promptSignal',-1,.1) #jPsicTau.setRange('NormalizationRangeFormlfit_nonPromptSignal',.1,2.5) #jPsicTau.setRange('NormalizationRangeFormlfit_leftMassSideBand',-1,2.5) #jPsicTau.setRange('NormalizationRangeFormlfit_rightMassSideBand',-1,2.5) #jPsicTau.setRange('mlfit_promptSignal',-1,.1) #jPsicTau.setRange('mlfit_nonPromptSignal',.1,2.5) #jPsicTau.setRange('mlfit_leftMassSideBand',-1,2.5) #jPsicTau.setRange('mlfit_rightMassSideBand',-1,2.5) #reset parameters ws.var('CBn').setVal(.5) ws.var('CBalpha').setVal(.5) ws.var('CBmass').setVal(3.1) ws.var('CBsigma').setVal(.02) ws.var('bkgLambda').setVal(0) ws.var('bkgTauSSDL').setVal(.5) #ws.var('bkgTauFDL').setVal(.5) ws.var('bkgTauDSDL').setVal(.5) ws.var('fBkgSSDL').setVal(.5) ws.var('fBkgLR').setVal(.5) ws.var('bkgTauSSDR').setVal(.5) #ws.var('bkgTauFDR').setVal(.5) ws.var('bkgTauDSDR').setVal(.5) ws.var('fBkgSSDR').setVal(.5) #ws.var('fBkgFDR').setVal(.25) #ws.var('nPrompt').setVal(5000) #ws.var('nNonPrompt').setVal(500) #ws.var('nBackground').setVal(100) #ws.var('nBackgroundL').setVal(50) #ws.var('nBackgroundR').setVal(50) ws.var('nonPromptTau').setVal(.5) ws.var('promptMean').setVal(0) ws.var('ctResolution').setVal(1) LPdf = ws.pdf('LPdf') MPdf = ws.pdf('MPdf') data = ws.data('data_rap' + str(rap_bin) + '_pt' + str(pt_bin + 1)) NLLs = RooArgSet() MassNLL = MPdf.createNLL( data, ROOT.RooFit.Range('mlfit'), ROOT.RooFit.SplitRange(True), ROOT.RooFit.ConditionalObservables( RooArgSet(ws.var('JpsictErr'))), ROOT.RooFit.NumCPU(2)) CTauNLL = LPdf.createNLL( data, ROOT.RooFit.Range('mlfit'), ROOT.RooFit.SplitRange(True), ROOT.RooFit.ConditionalObservables( RooArgSet(ws.var('JpsictErr'))), ROOT.RooFit.NumCPU(2)) NLLs.add(MassNLL) NLLs.add(CTauNLL) simNLL = RooAddition('add', 'add', NLLs) minuit = RooMinuit(simNLL) minuit.setStrategy(2) minuit.setPrintEvalErrors(-1) minuit.simplex() minuit.migrad() minuit.migrad() minuit.hesse() fitresult = minuit.save('polfitresult_rap' + str(rap_bin) + '_pt' + str(pt_bin + 1)) getattr(ws, 'import')(fitresult) ws.saveSnapshot( 'snapshot_rap' + str(rap_bin) + '_pt' + str(pt_bin + 1), ws.allVars())
def main(options,args): eta_bins = [[0.0,1.4442]] # try to split material dependence # [1.560,2.5]] pt_bins = [[12, 15], [15, 20]] #get input workspace input = TFile.Open(options.inputFile) ws = input.Get(options.workspaceName).Clone() input.Close() #ws.Print("v") sieie = RooRealVar(options.showerShapeName,options.showerShapeName,0) pt = RooRealVar(options.ptName,options.ptName,0) eta = RooRealVar(options.etaName,options.etaName,0) chIso = RooRealVar(options.isoName,options.isoName,0) vars = RooArgSet() vars.add(sieie) vars.add(pt) vars.add(eta) vars.add(chIso) if options.MCFakeRate: #chIso = RooRealVar(options.isoName, 'phHIso', 100, 0, 20) fake = RooRealVar('FakePho','',-0.5,1.5) vars.add(fake) data = None if options.weight is not None: weight = RooRealVar(options.weight,'',.5) vars.add(weight) data = RooDataSet('data','All Input Data', vars, RooFit.ImportFromFile(options.dataFile, options.dataTreeName), RooFit.WeightVar(options.weight) ) else: data = RooDataSet('data','All Input Data', vars, RooFit.ImportFromFile(options.dataFile, options.dataTreeName) ) data.Print("v") # put in the raw datasets, no cuts or manipulation getattr(ws,'import')(data, RooFit.RenameVariable(options.showerShapeName,'Pho_SigmaIEtaIEta'), RooFit.RenameVariable(options.ptName,'Pho_Pt'), RooFit.RenameVariable(options.etaName,'Pho_Eta')) sieie = ws.var('Pho_SigmaIEtaIEta') sieie.setRange('barrelSel',0,0.011) sieie.setRange('endcapSel',0,0.033) output = TFile.Open(options.outputFile,'RECREATE') output.cd() #histograms fakeRate = [] nFakes = [] nTot = [] fakeRateMC = [] #counters totBkg = [] #central value in each bin totBkgUp = [] #upper error totBkgLo = [] #lower error ietabin = 0 #setup histograms and counters for i in range(len(eta_bins)): fakeRate.append(TGraphAsymmErrors()) fakeRate[i].SetName('fakeRate_etabin%d'%i) nFakes.append(TGraphAsymmErrors()) nFakes[i].SetName('nFakes_etabin%d'%i) nTot.append(TGraphAsymmErrors()) nTot[i].SetName('nTot_etabin%d'%i) if options.MCFakeRate: fakeRateMC.append(TGraphAsymmErrors()) fakeRateMC[i].SetName('fakeRateMC_etabin%d'%i) totBkg.append(0) totBkgUp.append(0) totBkgLo.append(0) #loop through bins making all fits for etabin in eta_bins: #pt bin number for TGraphs iptbin = 0 for ptbin in pt_bins: if 'abs(Pho_Eta) < 1.4442': phoselsig = ' abs(Pho_Eta) > %f && abs(Pho_Eta) < %f && Pho_Pt > %f && Pho_Pt < %f'%(etabin[0], etabin[1], ptbin[0], ptbin[1]) # if options.MCFakeRate: phoselbkg = 'phoCHIso > 2 && phoCHIso < 6 && abs(Pho_Eta) > %f && abs(Pho_Eta) < %f && Pho_Pt > %f && Pho_Pt < %f'%(etabin[0], etabin[1], ptbin[0], ptbin[1]) phosel= phoselsig or phoselbkg #phosel = 'phoselsig || phoselbkg' #phosel = 'abs(Pho_Eta) > %f && abs(Pho_Eta) < %f && Pho_Pt > %f && Pho_Pt < %f'%(etabin[0], # etabin[1], # ptbin[0], # ptbin[1]) postfix = '_Eta_%.4f_%.4f_Pt_%.2f_%.2f'%(etabin[0],etabin[1],ptbin[0],ptbin[1]) binData = ws.data('data').reduce(RooFit.Cut(phosel), RooFit.Name('binData'+postfix), RooFit.Title('Data Events')) #save it all in the workspace getattr(ws,'import')(binData) #create the PDFs we are going to fit! options.pdfModule.makePdf(ws,etabin,postfix,options.extraInput) output.cd() ws.factory('RooExtendPdf::fullPDFExt'+postfix+'('+ 'fullPDF'+postfix+',nTot'+postfix+'[2000,1e-8,10000])') bNLL = ws.pdf('fullPDFExt'+postfix).createNLL(ws.data('binData'+postfix), RooFit.Extended(True), RooFit.NumCPU(4)) bFit = RooMinuit(bNLL) #bFit.setVerbose(True) if ws.data('binData'+postfix).sumEntries() > 0: bFit.setPrintLevel(-1) bFit.migrad() bFit.hesse() bFit.setPrintLevel(0) bFit.minos(RooArgSet(ws.var('fBkg'+postfix))) bRes = bFit.save('binFitResult'+postfix) getattr(ws,'import')(bRes) #plot fits on top of data bFrame = sieie.frame() bFrame.SetName('binFrame'+postfix) binData.plotOn(bFrame) ws.pdf('fullPDFExt'+postfix).plotOn(bFrame, RooFit.LineColor(ROOT.kYellow)) #ws.pdf('fullPDFExt'+postfix).plotOn(bFramea) ws.pdf('fullPDFExt'+postfix).plotOn(bFrame, RooFit.Components('bkgTemplatePDF'+postfix), RooFit.LineColor(ROOT.kBlue)) ws.pdf('fullPDFExt'+postfix).plotOn(bFrame, RooFit.Components('sigTemplatePDF'+postfix), RooFit.LineColor(ROOT.kRed)) ws.pdf('fullPDFExt'+postfix).plotOn(bFrame, RooFit.Components('fullPDF'+postfix), RooFit.LineColor(ROOT.kGreen)) bFrame.Write() bSigInt = None bBkgInt = None #make plot of fake rate in signal region as a function of pT #< 0.011 (EB), <0.030 (EE) if etabin[0] >= 1.560: bSigInt = ws.pdf('sigTemplatePDF'+ postfix).createIntegral(RooArgSet(sieie), RooArgSet(sieie), 'endcapSel') bBkgInt = ws.pdf('bkgTemplatePDF'+ postfix).createIntegral(RooArgSet(sieie), RooArgSet(sieie), 'endcapSel') else: bSigInt = ws.pdf('sigTemplatePDF'+ postfix).createIntegral(RooArgSet(sieie), RooArgSet(sieie), 'barrelSel') bBkgInt = ws.pdf('bkgTemplatePDF'+ postfix).createIntegral(RooArgSet(sieie), RooArgSet(sieie), 'barrelSel') nEventsB = ws.var('nTot'+postfix).getVal() nSignalB = (1.0 - ws.var('fBkg'+postfix).getVal())*nEventsB*bSigInt.getVal() nBkgB = ws.var('fBkg'+postfix).getVal()*nEventsB*bBkgInt.getVal() nBkgBUp = ws.var('fBkg'+postfix).getErrorHi()*nEventsB*bBkgInt.getVal() nBkgBLo = -ws.var('fBkg'+postfix).getErrorLo()*nEventsB*bBkgInt.getVal() print "Events Sig Bkg: %.3f + %.3f - %.3f"%(nEventsB, nSignalB, nBkgB) trash = (1.0 - ws.var('fBkg'+postfix).getVal()) trash1 = bSigInt.getVal() trash2 = bBkgInt.getVal() trash3 = ws.var('fBkg'+postfix).getVal() print nEventsB print trash print trash1 print trash2 print trash3 if nBkgBLo == 0.0: #catch cases when minos dies on lower limits parb_err = ws.var('fBkg'+postfix).getError()*nEventsB*bBkgInt.getVal() nBkgBLo = -max(nBkgB - parb_err,-nBkgB) totBkg[ietabin] += nBkgB totBkgUp[ietabin] = sqrt(nBkgBUp*nBkgBUp + totBkgUp[ietabin]*totBkgUp[ietabin]) totBkgLo[ietabin] = sqrt(nBkgBLo*nBkgBLo + totBkgLo[ietabin]*totBkgLo[ietabin]) print "Background Events: %.3f + %.3f - %.3f"%(nBkgB,nBkgBUp,nBkgBLo) fakeRate[ietabin].SetPoint(iptbin,(float(ptbin[1])+float(ptbin[0]))/2,nBkgB/(nSignalB+nBkgB)) fakeRate[ietabin].SetPointError(iptbin, (float(ptbin[1])+float(ptbin[0]))/2 - float(ptbin[0]), float(ptbin[1]) - (float(ptbin[1])+float(ptbin[0]))/2, -ws.var('fBkg'+postfix).getErrorLo(), ws.var('fBkg'+postfix).getErrorHi()) #nFakes[ietabin].SetPoint(iptbin,(float(ptbin[1])+float(ptbin[0]))/2,nBkgB/(float(ptbin[1]) - float(ptbin[0]))) nFakes[ietabin].SetPoint(iptbin,(float(ptbin[1])+float(ptbin[0]))/2,nBkgB) nFakes[ietabin].SetPointError(iptbin, (float(ptbin[1])+float(ptbin[0]))/2 - float(ptbin[0]), float(ptbin[1]) - (float(ptbin[1])+float(ptbin[0]))/2, nBkgBLo/(float(ptbin[1]) - float(ptbin[0])), nBkgBUp/(float(ptbin[1]) - float(ptbin[0]))) #nTot[ietabin].SetPoint(iptbin,(float(ptbin[1])+float(ptbin[0]))/2,nEventsB/(float(ptbin[1]) - float(ptbin[0]))) nTot[ietabin].SetPoint(iptbin,(float(ptbin[1])+float(ptbin[0]))/2,nEventsB) nTot[ietabin].SetPointError(iptbin, (float(ptbin[1])+float(ptbin[0]))/2 - float(ptbin[0]), float(ptbin[1]) - (float(ptbin[1])+float(ptbin[0]))/2, ws.var('nTot'+postfix).getError()/(float(ptbin[1]) - float(ptbin[0])), ws.var('nTot'+postfix).getError()/(float(ptbin[1]) - float(ptbin[0]))) if options.MCFakeRate: fr = 0 if etabin[0] > 1.560: fr = (ws.data('binData'+postfix).sumEntries('FakePho > 0.5 && Pho_SigmaIEtaIEta < 0.030')/ ws.data('binData'+postfix).sumEntries('FakePho > -1 && Pho_SigmaIEtaIEta < 0.030')) else: fr = (ws.data('binData'+postfix).sumEntries('FakePho > 0.5 && Pho_SigmaIEtaIEta < 0.011')/ ws.data('binData'+postfix).sumEntries('FakePho > -1 && Pho_SigmaIEtaIEta < 0.011')) fakeRateMC[ietabin].SetPoint(iptbin,(float(ptbin[1])+float(ptbin[0]))/2,fr) fakeRateMC[ietabin].SetPointError(iptbin, (float(ptbin[1])+float(ptbin[0]))/2 - float(ptbin[0]), float(ptbin[1]) - (float(ptbin[1])+float(ptbin[0]))/2, 0, 0) iptbin += 1 ietabin += 1 for i in range(len(eta_bins)): print " %.4f < |Eta| < %.4f Total Background = %.3f +/- (%.3f,%.3f)"%(eta_bins[i][0],eta_bins[i][1], totBkg[i],totBkgUp[i],totBkgLo[i]) fakeRate[i].Write() nFakes[i].Write() nTot[i].Write() if options.MCFakeRate: fakeRateMC[i].Write() ws.Write() output.Close()