/************************************************************************** * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * * * Author: The ALICE Off-line Project. * * Contributors are mentioned in the code where appropriate. * * * * Permission to use, copy, modify and distribute this software and its * * documentation strictly for non-commercial purposes is hereby granted * * without fee, provided that the above copyright notice appears in all * * copies and that both the copyright notice and this permission notice * * appear in the supporting documentation. The authors make no claims * * about the suitability of this software for any purpose. It is * * provided "as is" without express or implied warranty. * **************************************************************************/ //_________________________________________________________________________ // Class for the analysis of high pT pi0 event by event // Pi0/Eta identified by one of the following: // -Invariant mass of 2 cluster in calorimeter // -Shower shape analysis in calorimeter // -Invariant mass of one cluster in calorimeter and one photon reconstructed in CTS // // -- Author: Gustavo Conesa (LNF-INFN) & Raphaelle Ichou (SUBATECH) ////////////////////////////////////////////////////////////////////////////// // --- ROOT system --- #include #include #include // --- Analysis system --- #include "AliAnaPi0EbE.h" #include "AliCaloTrackReader.h" #include "AliIsolationCut.h" #include "AliNeutralMesonSelection.h" #include "AliCaloPID.h" #include "AliMCAnalysisUtils.h" #include "AliStack.h" #include "AliFiducialCut.h" #include "TParticle.h" #include "AliVCluster.h" #include "AliAODEvent.h" #include "AliAODMCParticle.h" ClassImp(AliAnaPi0EbE) //____________________________ AliAnaPi0EbE::AliAnaPi0EbE() : AliAnaCaloTrackCorrBaseClass(),fAnaType(kIMCalo), fCalorimeter(""), fMinDist(0.),fMinDist2(0.), fMinDist3(0.), fFillWeightHistograms(kFALSE), fFillTMHisto(0), fFillSelectClHisto(0), fInputAODGammaConvName(""), // Histograms fhPt(0), fhE(0), fhEEta(0), fhEPhi(0), fhEtaPhi(0), fhPtDecay(0), fhEDecay(0), // Shower shape histos fhEDispersion(0), fhELambda0(0), fhELambda1(0), fhELambda0NoTRD(0), fhELambda0FracMaxCellCut(0), fhEFracMaxCell(0), fhEFracMaxCellNoTRD(0), fhENCells(0), fhETime(0), fhEPairDiffTime(0), // MC histos fhPtMCNo(0), fhPhiMCNo(0), fhEtaMCNo(0), fhPtMC(0), fhPhiMC(0), fhEtaMC(0), fhMassPairMCPi0(0), fhMassPairMCEta(0), fhAnglePairMCPi0(0), fhAnglePairMCEta(0), // Weight studies fhECellClusterRatio(0), fhECellClusterLogRatio(0), fhEMaxCellClusterRatio(0), fhEMaxCellClusterLogRatio(0), fhTrackMatchedDEta(0), fhTrackMatchedDPhi(0), fhTrackMatchedDEtaDPhi(0), fhTrackMatchedMCParticle(0), fhdEdx(0), fhEOverP(0), fhEOverPNoTRD(0), // Number of local maxima in cluster fhNLocMax(0), fhELambda0LocMax1(0), fhELambda1LocMax1(0), fhELambda0LocMax2(0), fhELambda1LocMax2(0), fhELambda0LocMaxN(0), fhELambda1LocMaxN(0) { //default ctor for(Int_t i = 0; i < 6; i++){ fhEMCLambda0[i] = 0; fhEMCLambda0NoTRD[i]= 0; fhEMCLambda0FracMaxCellCut[i]= 0; fhEMCFracMaxCell[i] = 0; fhEMCLambda1[i] = 0; fhEMCDispersion[i] = 0; } //Weight studies for(Int_t i =0; i < 14; i++){ fhLambda0ForW0[i] = 0; //fhLambda1ForW0[i] = 0; if(i<8)fhMassPairLocMax[i] = 0; } //Initialize parameters InitParameters(); } //_____________________________________________________________________________________ void AliAnaPi0EbE::FillSelectedClusterHistograms(AliVCluster* cluster, const Int_t nMaxima, const Int_t tag) { // Fill shower shape, timing and other histograms for selected clusters from decay Float_t e = cluster->E(); Float_t disp = cluster->GetDispersion()*cluster->GetDispersion(); Float_t l0 = cluster->GetM02(); Float_t l1 = cluster->GetM20(); Int_t nSM = GetModuleNumber(cluster); AliVCaloCells * cell = 0x0; if(fCalorimeter == "PHOS") cell = GetPHOSCells(); else cell = GetEMCALCells(); Float_t maxCellFraction = 0; GetCaloUtils()->GetMaxEnergyCell(cell, cluster, maxCellFraction); fhEFracMaxCell->Fill(e,maxCellFraction); FillWeightHistograms(cluster); fhEDispersion->Fill(e, disp); fhELambda0 ->Fill(e, l0 ); fhELambda1 ->Fill(e, l1 ); fhNLocMax->Fill(e,nMaxima); if (nMaxima==1) { fhELambda0LocMax1->Fill(e,l0); fhELambda1LocMax1->Fill(e,l1); } else if(nMaxima==2) { fhELambda0LocMax2->Fill(e,l0); fhELambda1LocMax2->Fill(e,l1); } else { fhELambda0LocMaxN->Fill(e,l0); fhELambda1LocMaxN->Fill(e,l1); } if(fCalorimeter=="EMCAL" && nSM < 6) { fhELambda0NoTRD->Fill(e, l0 ); fhEFracMaxCellNoTRD->Fill(e,maxCellFraction); } if(maxCellFraction < 0.5) fhELambda0FracMaxCellCut->Fill(e, l0 ); fhETime ->Fill(e, cluster->GetTOF()*1.e9); fhENCells->Fill(e, cluster->GetNCells()); // Fill Track matching control histograms if(fFillTMHisto) { Float_t dZ = cluster->GetTrackDz(); Float_t dR = cluster->GetTrackDx(); if(cluster->IsEMCAL() && GetCaloUtils()->IsRecalculationOfClusterTrackMatchingOn()) { dR = 2000., dZ = 2000.; GetCaloUtils()->GetEMCALRecoUtils()->GetMatchedResiduals(cluster->GetID(),dZ,dR); } //printf("Pi0EbE: dPhi %f, dEta %f\n",dR,dZ); if(fhTrackMatchedDEta && TMath::Abs(dR) < 999) { fhTrackMatchedDEta->Fill(e,dZ); fhTrackMatchedDPhi->Fill(e,dR); if(e > 0.5) fhTrackMatchedDEtaDPhi->Fill(dZ,dR); } // Check dEdx and E/p of matched clusters if(TMath::Abs(dZ) < 0.05 && TMath::Abs(dR) < 0.05) { AliVTrack *track = GetCaloUtils()->GetMatchedTrack(cluster, GetReader()->GetInputEvent()); if(track) { Float_t dEdx = track->GetTPCsignal(); fhdEdx->Fill(e, dEdx); Float_t eOverp = e/track->P(); fhEOverP->Fill(e, eOverp); if(fCalorimeter=="EMCAL" && nSM < 6) fhEOverPNoTRD->Fill(e, eOverp); } //else // printf("AliAnaPi0EbE::FillSelectedClusterHistograms() - Residual OK but (dR, dZ)= (%2.4f,%2.4f) no track associated WHAT? \n", dR,dZ); if(IsDataMC()) { if ( !GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCConversion) ) { if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPi0) || GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCEta) ) fhTrackMatchedMCParticle->Fill(e, 2.5 ); else if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPhoton) ) fhTrackMatchedMCParticle->Fill(e, 0.5 ); else if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCElectron) ) fhTrackMatchedMCParticle->Fill(e, 1.5 ); else fhTrackMatchedMCParticle->Fill(e, 3.5 ); } else { if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPi0) || GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCEta) ) fhTrackMatchedMCParticle->Fill(e, 6.5 ); else if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPhoton) ) fhTrackMatchedMCParticle->Fill(e, 4.5 ); else if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCElectron) ) fhTrackMatchedMCParticle->Fill(e, 5.5 ); else fhTrackMatchedMCParticle->Fill(e, 7.5 ); } } // MC } }// Track matching histograms if(IsDataMC()) { //Photon1 if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPi0) ) { fhEMCLambda0[kmcPi0] ->Fill(e, l0); fhEMCLambda1[kmcPi0] ->Fill(e, l1); fhEMCDispersion[kmcPi0] ->Fill(e, disp); fhEMCFracMaxCell[kmcPi0]->Fill(e,maxCellFraction); if(fCalorimeter=="EMCAL" && nSM < 6) fhEMCLambda0NoTRD[kmcPi0]->Fill(e, l0 ); if(maxCellFraction < 0.5) fhEMCLambda0FracMaxCellCut[kmcPi0]->Fill(e, l0 ); }//pi0 else if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCEta) ) { fhEMCLambda0[kmcEta] ->Fill(e, l0); fhEMCLambda1[kmcEta] ->Fill(e, l1); fhEMCDispersion[kmcEta] ->Fill(e, disp); fhEMCFracMaxCell[kmcEta]->Fill(e,maxCellFraction); if(fCalorimeter=="EMCAL" && nSM < 6) fhEMCLambda0NoTRD[kmcEta]->Fill(e, l0 ); if(maxCellFraction < 0.5) fhEMCLambda0FracMaxCellCut[kmcEta]->Fill(e, l0 ); }//eta else if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPhoton) && GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCConversion) ) { fhEMCLambda0[kmcConversion] ->Fill(e, l0); fhEMCLambda1[kmcConversion] ->Fill(e, l1); fhEMCDispersion[kmcConversion] ->Fill(e, disp); fhEMCFracMaxCell[kmcConversion]->Fill(e,maxCellFraction); if(fCalorimeter=="EMCAL" && nSM < 6) fhEMCLambda0NoTRD[kmcConversion]->Fill(e, l0 ); if(maxCellFraction < 0.5) fhEMCLambda0FracMaxCellCut[kmcConversion]->Fill(e, l0 ); }//conversion photon else if( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPhoton) ) { fhEMCLambda0[kmcPhoton] ->Fill(e, l0); fhEMCLambda1[kmcPhoton] ->Fill(e, l1); fhEMCDispersion[kmcPhoton] ->Fill(e, disp); fhEMCFracMaxCell[kmcPhoton]->Fill(e,maxCellFraction); if(fCalorimeter=="EMCAL" && nSM < 6) fhEMCLambda0NoTRD[kmcPhoton]->Fill(e, l0 ); if(maxCellFraction < 0.5) fhEMCLambda0FracMaxCellCut[kmcPhoton]->Fill(e, l0 ); }//photon no conversion else if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCElectron)) { fhEMCLambda0[kmcElectron] ->Fill(e, l0); fhEMCLambda1[kmcElectron] ->Fill(e, l1); fhEMCDispersion[kmcElectron] ->Fill(e, disp); fhEMCFracMaxCell[kmcElectron]->Fill(e,maxCellFraction); if(fCalorimeter=="EMCAL" && nSM < 6) fhEMCLambda0NoTRD[kmcElectron]->Fill(e, l0 ); if(maxCellFraction < 0.5) fhEMCLambda0FracMaxCellCut[kmcElectron]->Fill(e, l0 ); }//electron else { fhEMCLambda0[kmcHadron] ->Fill(e, l0); fhEMCLambda1[kmcHadron] ->Fill(e, l1); fhEMCDispersion[kmcHadron] ->Fill(e, disp); fhEMCFracMaxCell[kmcHadron]->Fill(e,maxCellFraction); if(fCalorimeter=="EMCAL" && nSM < 6) fhEMCLambda0NoTRD[kmcHadron]->Fill(e, l0 ); if(maxCellFraction < 0.5) fhEMCLambda0FracMaxCellCut[kmcHadron]->Fill(e, l0 ); }//other particles }//MC } //________________________________________________________ void AliAnaPi0EbE::FillWeightHistograms(AliVCluster *clus) { // Calculate weights and fill histograms if(!fFillWeightHistograms || GetMixedEvent()) return; AliVCaloCells* cells = 0; if(fCalorimeter == "EMCAL") cells = GetEMCALCells(); else cells = GetPHOSCells(); // First recalculate energy in case non linearity was applied Float_t energy = 0; Float_t ampMax = 0; for (Int_t ipos = 0; ipos < clus->GetNCells(); ipos++) { Int_t id = clus->GetCellsAbsId()[ipos]; //Recalibrate cell energy if needed Float_t amp = cells->GetCellAmplitude(id); GetCaloUtils()->RecalibrateCellAmplitude(amp,fCalorimeter, id); energy += amp; if(amp> ampMax) ampMax = amp; } // energy loop if(energy <=0 ) { printf("AliAnaPi0EbE::WeightHistograms()- Wrong calculated energy %f\n",energy); return; } fhEMaxCellClusterRatio ->Fill(energy,ampMax/energy); fhEMaxCellClusterLogRatio->Fill(energy,TMath::Log(ampMax/energy)); //Get the ratio and log ratio to all cells in cluster for (Int_t ipos = 0; ipos < clus->GetNCells(); ipos++) { Int_t id = clus->GetCellsAbsId()[ipos]; //Recalibrate cell energy if needed Float_t amp = cells->GetCellAmplitude(id); GetCaloUtils()->RecalibrateCellAmplitude(amp,fCalorimeter, id); fhECellClusterRatio ->Fill(energy,amp/energy); fhECellClusterLogRatio->Fill(energy,TMath::Log(amp/energy)); } //Recalculate shower shape for different W0 if(fCalorimeter=="EMCAL"){ Float_t l0org = clus->GetM02(); Float_t l1org = clus->GetM20(); Float_t dorg = clus->GetDispersion(); for(Int_t iw = 0; iw < 14; iw++) { GetCaloUtils()->GetEMCALRecoUtils()->SetW0(1+iw*0.5); GetCaloUtils()->GetEMCALRecoUtils()->RecalculateClusterShowerShapeParameters(GetEMCALGeometry(), cells, clus); fhLambda0ForW0[iw]->Fill(energy,clus->GetM02()); //fhLambda1ForW0[iw]->Fill(energy,clus->GetM20()); } // w0 loop // Set the original values back clus->SetM02(l0org); clus->SetM20(l1org); clus->SetDispersion(dorg); }// EMCAL } //__________________________________________ TObjString * AliAnaPi0EbE::GetAnalysisCuts() { //Save parameters used for analysis TString parList ; //this will be list of parameters used for this analysis. const Int_t buffersize = 255; char onePar[buffersize] ; snprintf(onePar,buffersize,"--- AliAnaPi0EbE ---\n") ; parList+=onePar ; snprintf(onePar,buffersize,"fAnaType=%d (Pi0 selection type) \n",fAnaType) ; parList+=onePar ; if(fAnaType == kSSCalo) { snprintf(onePar,buffersize,"Calorimeter: %s\n",fCalorimeter.Data()) ; parList+=onePar ; snprintf(onePar,buffersize,"fMinDist =%2.2f (Minimal distance to bad channel to accept cluster) \n",fMinDist) ; parList+=onePar ; snprintf(onePar,buffersize,"fMinDist2=%2.2f (Cuts on Minimal distance to study acceptance evaluation) \n",fMinDist2) ; parList+=onePar ; snprintf(onePar,buffersize,"fMinDist3=%2.2f (One more cut on distance used for acceptance-efficiency study) \n",fMinDist3) ; parList+=onePar ; } //Get parameters set in base class. parList += GetBaseParametersList() ; //Get parameters set in PID class. if(fAnaType == kSSCalo) parList += GetCaloPID()->GetPIDParametersList() ; return new TObjString(parList) ; } //__________________________________________________________________ void AliAnaPi0EbE::HasPairSameMCMother(AliAODPWG4Particle * photon1, AliAODPWG4Particle * photon2, Int_t & label, Int_t & tag) { // Check the labels of pare in case mother was same pi0 or eta // Set the new AOD accordingly Int_t label1 = photon1->GetLabel(); Int_t label2 = photon2->GetLabel(); if(label1 < 0 || label2 < 0 ) return ; //Int_t tag1 = GetMCAnalysisUtils()->CheckOrigin(label1, GetReader(), photon1->GetInputFileIndex()); //Int_t tag2 = GetMCAnalysisUtils()->CheckOrigin(label2, GetReader(), photon2->GetInputFileIndex()); Int_t tag1 = photon1->GetTag(); Int_t tag2 = photon2->GetTag(); if(GetDebug() > 0) printf("AliAnaPi0EbE::MakeInvMassInCalorimeter() - Origin of: photon1 %d; photon2 %d \n",tag1, tag2); if( (GetMCAnalysisUtils()->CheckTagBit(tag1,AliMCAnalysisUtils::kMCPi0Decay) && GetMCAnalysisUtils()->CheckTagBit(tag2,AliMCAnalysisUtils::kMCPi0Decay) ) || (GetMCAnalysisUtils()->CheckTagBit(tag1,AliMCAnalysisUtils::kMCEtaDecay) && GetMCAnalysisUtils()->CheckTagBit(tag2,AliMCAnalysisUtils::kMCEtaDecay) ) ) { //Check if pi0/eta mother is the same if(GetReader()->ReadStack()) { if(label1>=0) { TParticle * mother1 = GetMCStack()->Particle(label1);//photon in kine tree label1 = mother1->GetFirstMother(); //mother1 = GetMCStack()->Particle(label1);//pi0 } if(label2>=0) { TParticle * mother2 = GetMCStack()->Particle(label2);//photon in kine tree label2 = mother2->GetFirstMother(); //mother2 = GetMCStack()->Particle(label2);//pi0 } } // STACK else if(GetReader()->ReadAODMCParticles()) {//&& (input > -1)){ if(label1>=0) { AliAODMCParticle * mother1 = (AliAODMCParticle *) (GetReader()->GetAODMCParticles(photon1->GetInputFileIndex()))->At(label1);//photon in kine tree label1 = mother1->GetMother(); //mother1 = GetMCStack()->Particle(label1);//pi0 } if(label2>=0) { AliAODMCParticle * mother2 = (AliAODMCParticle *) (GetReader()->GetAODMCParticles(photon2->GetInputFileIndex()))->At(label2);//photon in kine tree label2 = mother2->GetMother(); //mother2 = GetMCStack()->Particle(label2);//pi0 } }// AOD //printf("mother1 %d, mother2 %d\n",label1,label2); if( label1 == label2 && label1>=0 ) { label = label1; TLorentzVector mom1 = *(photon1->Momentum()); TLorentzVector mom2 = *(photon2->Momentum()); Double_t angle = mom2.Angle(mom1.Vect()); Double_t mass = (mom1+mom2).M(); Double_t epair = (mom1+mom2).E(); if(GetMCAnalysisUtils()->CheckTagBit(tag1,AliMCAnalysisUtils::kMCPi0Decay)) { fhMassPairMCPi0 ->Fill(epair,mass); fhAnglePairMCPi0->Fill(epair,angle); GetMCAnalysisUtils()->SetTagBit(tag,AliMCAnalysisUtils::kMCPi0); } else { fhMassPairMCEta ->Fill(epair,mass); fhAnglePairMCEta->Fill(epair,angle); GetMCAnalysisUtils()->SetTagBit(tag,AliMCAnalysisUtils::kMCEta); } } // same label } // both from eta or pi0 decay } //_____________________________________________ TList * AliAnaPi0EbE::GetCreateOutputObjects() { // Create histograms to be saved in output file and // store them in outputContainer TList * outputContainer = new TList() ; outputContainer->SetName("Pi0EbEHistos") ; Int_t nptbins = GetHistogramRanges()->GetHistoPtBins(); Float_t ptmax = GetHistogramRanges()->GetHistoPtMax(); Float_t ptmin = GetHistogramRanges()->GetHistoPtMin(); Int_t nphibins = GetHistogramRanges()->GetHistoPhiBins(); Float_t phimax = GetHistogramRanges()->GetHistoPhiMax(); Float_t phimin = GetHistogramRanges()->GetHistoPhiMin(); Int_t netabins = GetHistogramRanges()->GetHistoEtaBins(); Float_t etamax = GetHistogramRanges()->GetHistoEtaMax(); Float_t etamin = GetHistogramRanges()->GetHistoEtaMin(); Int_t ssbins = GetHistogramRanges()->GetHistoShowerShapeBins(); Float_t ssmax = GetHistogramRanges()->GetHistoShowerShapeMax(); Float_t ssmin = GetHistogramRanges()->GetHistoShowerShapeMin(); Int_t tdbins = GetHistogramRanges()->GetHistoDiffTimeBins() ; Float_t tdmax = GetHistogramRanges()->GetHistoDiffTimeMax(); Float_t tdmin = GetHistogramRanges()->GetHistoDiffTimeMin(); Int_t tbins = GetHistogramRanges()->GetHistoTimeBins() ; Float_t tmax = GetHistogramRanges()->GetHistoTimeMax(); Float_t tmin = GetHistogramRanges()->GetHistoTimeMin(); Int_t nbins = GetHistogramRanges()->GetHistoNClusterCellBins(); Int_t nmax = GetHistogramRanges()->GetHistoNClusterCellMax(); Int_t nmin = GetHistogramRanges()->GetHistoNClusterCellMin(); Int_t nmassbins = GetHistogramRanges()->GetHistoMassBins(); Float_t massmin = GetHistogramRanges()->GetHistoMassMin(); Float_t massmax = GetHistogramRanges()->GetHistoMassMax(); Int_t nresetabins = GetHistogramRanges()->GetHistoTrackResidualEtaBins(); Float_t resetamax = GetHistogramRanges()->GetHistoTrackResidualEtaMax(); Float_t resetamin = GetHistogramRanges()->GetHistoTrackResidualEtaMin(); Int_t nresphibins = GetHistogramRanges()->GetHistoTrackResidualPhiBins(); Float_t resphimax = GetHistogramRanges()->GetHistoTrackResidualPhiMax(); Float_t resphimin = GetHistogramRanges()->GetHistoTrackResidualPhiMin(); Int_t ndedxbins = GetHistogramRanges()->GetHistodEdxBins(); Float_t dedxmax = GetHistogramRanges()->GetHistodEdxMax(); Float_t dedxmin = GetHistogramRanges()->GetHistodEdxMin(); Int_t nPoverEbins = GetHistogramRanges()->GetHistoPOverEBins(); Float_t pOverEmax = GetHistogramRanges()->GetHistoPOverEMax(); Float_t pOverEmin = GetHistogramRanges()->GetHistoPOverEMin(); fhPt = new TH1F("hPt","Number of identified #pi^{0} (#eta) decay",nptbins,ptmin,ptmax); fhPt->SetYTitle("N"); fhPt->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhPt) ; fhE = new TH1F("hE","Number of identified #pi^{0} (#eta) decay pairs",nptbins,ptmin,ptmax); fhE->SetYTitle("N"); fhE->SetXTitle("E (GeV)"); outputContainer->Add(fhE) ; fhEPhi = new TH2F ("hEPhi","Selected #pi^{0} (#eta) pairs: E vs #phi",nptbins,ptmin,ptmax, nphibins,phimin,phimax); fhEPhi->SetYTitle("#phi (rad)"); fhEPhi->SetXTitle("E (GeV)"); outputContainer->Add(fhEPhi) ; fhEEta = new TH2F ("hEEta","Selected #pi^{0} (#eta) pairs: E vs #eta",nptbins,ptmin,ptmax,netabins,etamin,etamax); fhEEta->SetYTitle("#eta"); fhEEta->SetXTitle("E (GeV)"); outputContainer->Add(fhEEta) ; fhEtaPhi = new TH2F ("hEtaPhi","Selected #pi^{0} (#eta) pairs: #eta vs #phi",netabins,etamin,etamax, nphibins,phimin,phimax); fhEtaPhi->SetYTitle("#phi (rad)"); fhEtaPhi->SetXTitle("#eta"); outputContainer->Add(fhEtaPhi) ; fhPtDecay = new TH1F("hPtDecay","Number of identified #pi^{0} (#eta) decay photons",nptbins,ptmin,ptmax); fhPtDecay->SetYTitle("N"); fhPtDecay->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhPtDecay) ; fhEDecay = new TH1F("hEDecay","Number of identified #pi^{0} (#eta) decay photons",nptbins,ptmin,ptmax); fhEDecay->SetYTitle("N"); fhEDecay->SetXTitle("E (GeV)"); outputContainer->Add(fhEDecay) ; //////// if( fFillSelectClHisto && (fAnaType == kIMCalo || fAnaType == kIMCaloTracks) ) { fhEDispersion = new TH2F ("hEDispersion","Selected #pi^{0} (#eta) pairs: E vs dispersion",nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhEDispersion->SetYTitle("D^{2}"); fhEDispersion->SetXTitle("E (GeV)"); outputContainer->Add(fhEDispersion) ; fhELambda0 = new TH2F ("hELambda0","Selected #pi^{0} (#eta) pairs: E vs #lambda_{0}",nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhELambda0->SetYTitle("#lambda_{0}^{2}"); fhELambda0->SetXTitle("E (GeV)"); outputContainer->Add(fhELambda0) ; fhELambda1 = new TH2F ("hELambda1","Selected #pi^{0} (#eta) pairs: E vs #lambda_{1}",nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhELambda1->SetYTitle("#lambda_{1}^{2}"); fhELambda1->SetXTitle("E (GeV)"); outputContainer->Add(fhELambda1) ; fhELambda0FracMaxCellCut = new TH2F ("hELambda0FracMaxCellCut","Selected #pi^{0} (#eta) pairs: E vs #lambda_{0}, Max cell fraction of energy < 0.5",nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhELambda0FracMaxCellCut->SetYTitle("#lambda_{0}^{2}"); fhELambda0FracMaxCellCut->SetXTitle("E (GeV)"); outputContainer->Add(fhELambda0FracMaxCellCut) ; fhEFracMaxCell = new TH2F ("hEFracMaxCell","Selected #pi^{0} (#eta) pairs: E vs #lambda_{0}, Max cell fraction of energy",nptbins,ptmin,ptmax,100,0,1); fhEFracMaxCell->SetYTitle("Fraction"); fhEFracMaxCell->SetXTitle("E (GeV)"); outputContainer->Add(fhEFracMaxCell) ; fhNLocMax = new TH2F("hNLocMax","Number of local maxima in cluster", nptbins,ptmin,ptmax,10,0,10); fhNLocMax ->SetYTitle("N maxima"); fhNLocMax ->SetXTitle("E (GeV)"); outputContainer->Add(fhNLocMax) ; fhELambda0LocMax1 = new TH2F ("hELambda0LocMax1","Selected #pi^{0} (#eta) pairs: E vs #lambda_{0}, 1 Local maxima",nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhELambda0LocMax1->SetYTitle("#lambda_{0}^{2}"); fhELambda0LocMax1->SetXTitle("E (GeV)"); outputContainer->Add(fhELambda0LocMax1) ; fhELambda1LocMax1 = new TH2F ("hELambda1LocMax1","Selected #pi^{0} (#eta) pairs: E vs #lambda_{1}, 1 Local maxima",nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhELambda1LocMax1->SetYTitle("#lambda_{1}^{2}"); fhELambda1LocMax1->SetXTitle("E (GeV)"); outputContainer->Add(fhELambda1LocMax1) ; fhELambda0LocMax2 = new TH2F ("hELambda0LocMax2","Selected #pi^{0} (#eta) pairs: E vs #lambda_{0}, 2 Local maxima",nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhELambda0LocMax2->SetYTitle("#lambda_{0}^{2}"); fhELambda0LocMax2->SetXTitle("E (GeV)"); outputContainer->Add(fhELambda0LocMax2) ; fhELambda1LocMax2 = new TH2F ("hELambda1LocMax2","Selected #pi^{0} (#eta) pairs: E vs #lambda_{1}, 2 Local maxima",nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhELambda1LocMax2->SetYTitle("#lambda_{1}^{2}"); fhELambda1LocMax2->SetXTitle("E (GeV)"); outputContainer->Add(fhELambda1LocMax2) ; fhELambda0LocMaxN = new TH2F ("hELambda0LocMaxN","Selected #pi^{0} (#eta) pairs: E vs #lambda_{0}, N>2 Local maxima",nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhELambda0LocMaxN->SetYTitle("#lambda_{0}^{2}"); fhELambda0LocMaxN->SetXTitle("E (GeV)"); outputContainer->Add(fhELambda0LocMaxN) ; fhELambda1LocMaxN = new TH2F ("hELambda1LocMaxN","Selected #pi^{0} (#eta) pairs: E vs #lambda_{1}, N>2 Local maxima",nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhELambda1LocMaxN->SetYTitle("#lambda_{1}^{2}"); fhELambda1LocMaxN->SetXTitle("E (GeV)"); outputContainer->Add(fhELambda1LocMaxN) ; if(fCalorimeter=="EMCAL") { fhELambda0NoTRD = new TH2F ("hELambda0NoTRD","Selected #pi^{0} (#eta) pairs: E vs #lambda_{0}, not behind TRD",nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhELambda0NoTRD->SetYTitle("#lambda_{0}^{2}"); fhELambda0NoTRD->SetXTitle("E (GeV)"); outputContainer->Add(fhELambda0NoTRD) ; fhEFracMaxCellNoTRD = new TH2F ("hEFracMaxCellNoTRD","Selected #pi^{0} (#eta) pairs: E vs #lambda_{0}, Max cell fraction of energy, not behind TRD",nptbins,ptmin,ptmax,100,0,1); fhEFracMaxCellNoTRD->SetYTitle("Fraction"); fhEFracMaxCellNoTRD->SetXTitle("E (GeV)"); outputContainer->Add(fhEFracMaxCellNoTRD) ; } fhENCells = new TH2F ("hENCells","N cells in cluster vs E ", nptbins,ptmin,ptmax, nbins,nmin,nmax); fhENCells->SetXTitle("E (GeV)"); fhENCells->SetYTitle("# of cells in cluster"); outputContainer->Add(fhENCells); fhETime = new TH2F("hETime","cluster time vs pair E",nptbins,ptmin,ptmax, tbins,tmin,tmax); fhETime->SetXTitle("E (GeV)"); fhETime->SetYTitle("t (ns)"); outputContainer->Add(fhETime); }// Invariant mass analysis in calorimeters and calorimeter + conversion photons if(fAnaType == kIMCalo) { fhEPairDiffTime = new TH2F("hEPairDiffTime","cluster pair time difference vs E",nptbins,ptmin,ptmax, tdbins,tdmin,tdmax); fhEPairDiffTime->SetXTitle("E_{pair} (GeV)"); fhEPairDiffTime->SetYTitle("#Delta t (ns)"); outputContainer->Add(fhEPairDiffTime); TString combiName [] = {"1LocMax","2LocMax","NLocMax","1LocMax2LocMax","1LocMaxNLocMax","2LocMaxNLocMax","1LocMaxSSBad","NLocMaxSSGood"}; TString combiTitle[] = {"1 Local Maxima in both clusters","2 Local Maxima in both clusters","more than 2 Local Maxima in both clusters", "1 Local Maxima paired with 2 Local Maxima","1 Local Maxima paired with more than 2 Local Maxima", "2 Local Maxima paired with more than 2 Local Maxima", "1 Local Maxima paired with #lambda_{0}^{2}>0.3","N Local Maxima paired with 0.1<#lambda_{0}^{2}<0.3"}; for (Int_t i = 0; i < 8 ; i++) { if (fAnaType == kIMCaloTracks && i > 2 ) continue ; fhMassPairLocMax[i] = new TH2F (Form("MassPairLocMax%s",combiName[i].Data()), Form("Mass for decay #gamma pair vs E_{pair}, origin #pi^{0}, %s", combiTitle[i].Data()), nptbins,ptmin,ptmax,nmassbins,massmin,massmax); fhMassPairLocMax[i]->SetYTitle("Mass (MeV/c^{2})"); fhMassPairLocMax[i]->SetXTitle("E_{pair} (GeV)"); outputContainer->Add(fhMassPairLocMax[i]) ; } } if(fFillTMHisto) { fhTrackMatchedDEta = new TH2F ("hTrackMatchedDEta", "d#eta of cluster-track vs cluster energy", nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); fhTrackMatchedDEta->SetYTitle("d#eta"); fhTrackMatchedDEta->SetXTitle("E_{cluster} (GeV)"); fhTrackMatchedDPhi = new TH2F ("hTrackMatchedDPhi", "d#phi of cluster-track vs cluster energy", nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); fhTrackMatchedDPhi->SetYTitle("d#phi (rad)"); fhTrackMatchedDPhi->SetXTitle("E_{cluster} (GeV)"); fhTrackMatchedDEtaDPhi = new TH2F ("hTrackMatchedDEtaDPhi", "d#eta vs d#phi of cluster-track vs cluster energy", nresetabins,resetamin,resetamax,nresphibins,resphimin,resphimax); fhTrackMatchedDEtaDPhi->SetYTitle("d#phi (rad)"); fhTrackMatchedDEtaDPhi->SetXTitle("d#eta"); outputContainer->Add(fhTrackMatchedDEta) ; outputContainer->Add(fhTrackMatchedDPhi) ; outputContainer->Add(fhTrackMatchedDEtaDPhi) ; fhdEdx = new TH2F ("hdEdx","matched track vs cluster E ", nptbins,ptmin,ptmax,ndedxbins, dedxmin, dedxmax); fhdEdx->SetXTitle("E (GeV)"); fhdEdx->SetYTitle(""); outputContainer->Add(fhdEdx); fhEOverP = new TH2F ("hEOverP","matched track E/p vs cluster E ", nptbins,ptmin,ptmax,nPoverEbins,pOverEmin,pOverEmax); fhEOverP->SetXTitle("E (GeV)"); fhEOverP->SetYTitle("E/p"); outputContainer->Add(fhEOverP); if(fCalorimeter=="EMCAL") { fhEOverPNoTRD = new TH2F ("hEOverPNoTRD","matched track E/p vs cluster E, SM not behind TRD ", nptbins,ptmin,ptmax,nPoverEbins,pOverEmin,pOverEmax); fhEOverPNoTRD->SetXTitle("E (GeV)"); fhEOverPNoTRD->SetYTitle("E/p"); outputContainer->Add(fhEOverPNoTRD); } if(IsDataMC()) { fhTrackMatchedMCParticle = new TH2F ("hTrackMatchedMCParticle", "Origin of particle vs energy", nptbins,ptmin,ptmax,8,0,8); fhTrackMatchedMCParticle->SetXTitle("E (GeV)"); //fhTrackMatchedMCParticle->SetYTitle("Particle type"); fhTrackMatchedMCParticle->GetYaxis()->SetBinLabel(1 ,"Photon"); fhTrackMatchedMCParticle->GetYaxis()->SetBinLabel(2 ,"Electron"); fhTrackMatchedMCParticle->GetYaxis()->SetBinLabel(3 ,"Meson Merged"); fhTrackMatchedMCParticle->GetYaxis()->SetBinLabel(4 ,"Rest"); fhTrackMatchedMCParticle->GetYaxis()->SetBinLabel(5 ,"Conv. Photon"); fhTrackMatchedMCParticle->GetYaxis()->SetBinLabel(6 ,"Conv. Electron"); fhTrackMatchedMCParticle->GetYaxis()->SetBinLabel(7 ,"Conv. Merged"); fhTrackMatchedMCParticle->GetYaxis()->SetBinLabel(8 ,"Conv. Rest"); outputContainer->Add(fhTrackMatchedMCParticle); } } if(fFillWeightHistograms) { fhECellClusterRatio = new TH2F ("hECellClusterRatio"," cell energy / cluster energy vs cluster energy, for selected decay photons from neutral meson", nptbins,ptmin,ptmax, 100,0,1.); fhECellClusterRatio->SetXTitle("E_{cluster} (GeV) "); fhECellClusterRatio->SetYTitle("E_{cell i}/E_{cluster}"); outputContainer->Add(fhECellClusterRatio); fhECellClusterLogRatio = new TH2F ("hECellClusterLogRatio"," Log(cell energy / cluster energy) vs cluster energy, for selected decay photons from neutral meson", nptbins,ptmin,ptmax, 100,-10,0); fhECellClusterLogRatio->SetXTitle("E_{cluster} (GeV) "); fhECellClusterLogRatio->SetYTitle("Log (E_{max cell}/E_{cluster})"); outputContainer->Add(fhECellClusterLogRatio); fhEMaxCellClusterRatio = new TH2F ("hEMaxCellClusterRatio"," max cell energy / cluster energy vs cluster energy, for selected decay photons from neutral meson", nptbins,ptmin,ptmax, 100,0,1.); fhEMaxCellClusterRatio->SetXTitle("E_{cluster} (GeV) "); fhEMaxCellClusterRatio->SetYTitle("E_{max cell}/E_{cluster}"); outputContainer->Add(fhEMaxCellClusterRatio); fhEMaxCellClusterLogRatio = new TH2F ("hEMaxCellClusterLogRatio"," Log(max cell energy / cluster energy) vs cluster energy, for selected decay photons from neutral meson", nptbins,ptmin,ptmax, 100,-10,0); fhEMaxCellClusterLogRatio->SetXTitle("E_{cluster} (GeV) "); fhEMaxCellClusterLogRatio->SetYTitle("Log (E_{max cell}/E_{cluster})"); outputContainer->Add(fhEMaxCellClusterLogRatio); for(Int_t iw = 0; iw < 14; iw++) { fhLambda0ForW0[iw] = new TH2F (Form("hLambda0ForW0%d",iw),Form("shower shape, #lambda^{2}_{0} vs E, w0 = %1.1f, for selected decay photons from neutral meson",1+0.5*iw), nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhLambda0ForW0[iw]->SetXTitle("E_{cluster}"); fhLambda0ForW0[iw]->SetYTitle("#lambda^{2}_{0}"); outputContainer->Add(fhLambda0ForW0[iw]); // fhLambda1ForW0[iw] = new TH2F (Form("hLambda1ForW0%d",iw),Form("shower shape, #lambda^{2}_{1} vs E, w0 = %1.1f, for selected decay photons from neutral meson",0.5+0.5*iw), // nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); // fhLambda1ForW0[iw]->SetXTitle("E_{cluster}"); // fhLambda1ForW0[iw]->SetYTitle("#lambda^{2}_{1}"); // outputContainer->Add(fhLambda1ForW0[iw]); } } if(IsDataMC()) { if((GetReader()->GetDataType() == AliCaloTrackReader::kMC && fAnaType!=kSSCalo) || GetReader()->GetDataType() != AliCaloTrackReader::kMC) { fhPtMC = new TH1F("hPtMC","Identified #pi^{0} (#eta) from #pi^{0} (#eta)",nptbins,ptmin,ptmax); fhPtMC->SetYTitle("N"); fhPtMC->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhPtMC) ; fhPhiMC = new TH2F ("hPhiMC","Identified #pi^{0} (#eta) from #pi^{0} (#eta)",nptbins,ptmin,ptmax,nphibins,phimin,phimax); fhPhiMC->SetYTitle("#phi"); fhPhiMC->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhPhiMC) ; fhEtaMC = new TH2F ("hEtaMC","Identified #pi^{0} (#eta) from #pi^{0} (#eta)",nptbins,ptmin,ptmax,netabins,etamin,etamax); fhEtaMC->SetYTitle("#eta"); fhEtaMC->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhEtaMC) ; fhPtMCNo = new TH1F("hPtMCNo","Identified #pi^{0} (#eta) not from #pi^{0} (#eta)",nptbins,ptmin,ptmax); fhPtMCNo->SetYTitle("N"); fhPtMCNo->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhPtMCNo) ; fhPhiMCNo = new TH2F ("hPhiMCNo","Identified #pi^{0} (#eta) not from #pi^{0} (#eta)",nptbins,ptmin,ptmax,nphibins,phimin,phimax); fhPhiMCNo->SetYTitle("#phi"); fhPhiMCNo->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhPhiMCNo) ; fhEtaMCNo = new TH2F ("hEtaMCNo","Identified #pi^{0} (#eta) not from #pi^{0} (#eta)",nptbins,ptmin,ptmax,netabins,etamin,etamax); fhEtaMCNo->SetYTitle("#eta"); fhEtaMCNo->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhEtaMCNo) ; fhAnglePairMCPi0 = new TH2F ("AnglePairMCPi0", "Angle between decay #gamma pair vs E_{pair}, origin #pi^{0}",nptbins,ptmin,ptmax,250,0,0.5); fhAnglePairMCPi0->SetYTitle("#alpha (rad)"); fhAnglePairMCPi0->SetXTitle("E_{pair} (GeV)"); outputContainer->Add(fhAnglePairMCPi0) ; fhAnglePairMCEta = new TH2F ("AnglePairMCEta", "Angle between decay #gamma pair vs E_{pair}, origin #eta",nptbins,ptmin,ptmax,250,0,0.5); fhAnglePairMCEta->SetYTitle("#alpha (rad)"); fhAnglePairMCEta->SetXTitle("E_{pair} (GeV)"); outputContainer->Add(fhAnglePairMCEta) ; fhMassPairMCPi0 = new TH2F ("MassPairMCPi0", "Mass for decay #gamma pair vs E_{pair}, origin #pi^{0}",nptbins,ptmin,ptmax,nmassbins,massmin,massmax); fhMassPairMCPi0->SetYTitle("Mass (MeV/c^{2})"); fhMassPairMCPi0->SetXTitle("E_{pair} (GeV)"); outputContainer->Add(fhMassPairMCPi0) ; fhMassPairMCEta = new TH2F ("MassPairMCEta", "Mass for decay #gamma pair vs E_{pair}, origin #eta",nptbins,ptmin,ptmax,nmassbins,massmin,massmax); fhMassPairMCEta->SetYTitle("Mass (MeV/c^{2})"); fhMassPairMCEta->SetXTitle("E_{pair} (GeV)"); outputContainer->Add(fhMassPairMCEta) ; if(fAnaType == kIMCalo){ TString ptype[] ={"#gamma","#gamma->e^{#pm}","#pi^{0}","#eta","e^{#pm}", "hadron"}; TString pname[] ={"Photon","Conversion", "Pi0", "Eta", "Electron","Hadron"}; for(Int_t i = 0; i < 6; i++){ fhEMCLambda0[i] = new TH2F(Form("hELambda0_MC%s",pname[i].Data()), Form("Selected pair, cluster from %s : E vs #lambda_{0}^{2}",ptype[i].Data()), nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhEMCLambda0[i]->SetYTitle("#lambda_{0}^{2}"); fhEMCLambda0[i]->SetXTitle("E (GeV)"); outputContainer->Add(fhEMCLambda0[i]) ; if(fCalorimeter=="EMCAL"){ fhEMCLambda0NoTRD[i] = new TH2F(Form("hELambda0NoTRD_MC%s",pname[i].Data()), Form("Selected pair, cluster from %s : E vs #lambda_{0}^{2}, NoTRD",ptype[i].Data()), nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhEMCLambda0NoTRD[i]->SetYTitle("#lambda_{0}^{2}"); fhEMCLambda0NoTRD[i]->SetXTitle("E (GeV)"); outputContainer->Add(fhEMCLambda0NoTRD[i]) ; } fhEMCLambda0FracMaxCellCut[i] = new TH2F(Form("hELambda0FracMaxCellCut_MC%s",pname[i].Data()), Form("Selected pair, cluster from %s : E vs #lambda_{0}^{2}, Max cell fraction of energy < 0.5 ",ptype[i].Data()), nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhEMCLambda0FracMaxCellCut[i]->SetYTitle("#lambda_{0}^{2}"); fhEMCLambda0FracMaxCellCut[i]->SetXTitle("E (GeV)"); outputContainer->Add(fhEMCLambda0FracMaxCellCut[i]) ; fhEMCFracMaxCell[i] = new TH2F(Form("hEFracMaxCell_MC%s",pname[i].Data()), Form("Selected pair, cluster from %s : E vs Max cell fraction of energy",ptype[i].Data()), nptbins,ptmin,ptmax,100,0,1); fhEMCFracMaxCell[i]->SetYTitle("Fraction"); fhEMCFracMaxCell[i]->SetXTitle("E (GeV)"); outputContainer->Add(fhEMCFracMaxCell[i]) ; fhEMCLambda1[i] = new TH2F(Form("hELambda1_MC%s",pname[i].Data()), Form("Selected pair, cluster from %s : E vs #lambda_{1}^{2}",ptype[i].Data()), nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhEMCLambda1[i]->SetYTitle("#lambda_{1}^{2}"); fhEMCLambda1[i]->SetXTitle("E (GeV)"); outputContainer->Add(fhEMCLambda1[i]) ; fhEMCDispersion[i] = new TH2F(Form("hEDispersion_MC%s",pname[i].Data()), Form("Selected pair, cluster from %s : E vs dispersion^{2}",ptype[i].Data()), nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); fhEMCDispersion[i]->SetYTitle("D^{2}"); fhEMCDispersion[i]->SetXTitle("E (GeV)"); outputContainer->Add(fhEMCDispersion[i]) ; }// }//kIMCalo } //Not MC reader }//Histos with MC //Keep neutral meson selection histograms if requiered //Setting done in AliNeutralMesonSelection if(fAnaType!=kSSCalo && GetNeutralMesonSelection()){ TList * nmsHistos = GetNeutralMesonSelection()->GetCreateOutputObjects() ; if(GetNeutralMesonSelection()->AreNeutralMesonSelectionHistosKept()) for(Int_t i = 0; i < nmsHistos->GetEntries(); i++) outputContainer->Add(nmsHistos->At(i)) ; delete nmsHistos; } return outputContainer ; } //____________________________________________________________________________ void AliAnaPi0EbE::Init() { //Init //Do some checks if(fCalorimeter == "PHOS" && !GetReader()->IsPHOSSwitchedOn() && NewOutputAOD()){ printf("AliAnaPi0EbE::Init() - !!STOP: You want to use PHOS in analysis but it is not read!! \n!!Check the configuration file!!\n"); abort(); } else if(fCalorimeter == "EMCAL" && !GetReader()->IsEMCALSwitchedOn() && NewOutputAOD()){ printf("AliAnaPi0EbE::Init() - !!STOP: You want to use EMCAL in analysis but it is not read!! \n!!Check the configuration file!!\n"); abort(); } } //____________________________________________________________________________ void AliAnaPi0EbE::InitParameters() { //Initialize the parameters of the analysis. AddToHistogramsName("AnaPi0EbE_"); fInputAODGammaConvName = "PhotonsCTS" ; fAnaType = kIMCalo ; fCalorimeter = "EMCAL" ; fMinDist = 2.; fMinDist2 = 4.; fMinDist3 = 5.; } //__________________________________________________________________ void AliAnaPi0EbE::MakeAnalysisFillAOD() { //Do analysis and fill aods switch(fAnaType) { case kIMCalo: MakeInvMassInCalorimeter(); break; case kSSCalo: MakeShowerShapeIdentification(); break; case kIMCaloTracks: MakeInvMassInCalorimeterAndCTS(); break; } } //____________________________________________ void AliAnaPi0EbE::MakeInvMassInCalorimeter() { //Do analysis and fill aods //Search for the photon decay in calorimeters //Read photon list from AOD, produced in class AliAnaPhoton //Check if 2 photons have the mass of the pi0. TLorentzVector mom1; TLorentzVector mom2; TLorentzVector mom ; Int_t tag = 0; Int_t label = 0; if(!GetInputAODBranch()){ printf("AliAnaPi0EbE::MakeInvMassInCalorimeter() - No input calo photons in AOD with name branch < %s >, STOP \n",GetInputAODName().Data()); abort(); } //Get shower shape information of clusters TObjArray *clusters = 0; if (fCalorimeter=="EMCAL") clusters = GetEMCALClusters(); else if(fCalorimeter=="PHOS") clusters = GetPHOSClusters() ; for(Int_t iphoton = 0; iphoton < GetInputAODBranch()->GetEntriesFast()-1; iphoton++){ AliAODPWG4Particle * photon1 = (AliAODPWG4Particle*) (GetInputAODBranch()->At(iphoton)); //Vertex cut in case of mixed events Int_t evtIndex1 = 0 ; if(GetMixedEvent()) evtIndex1 = GetMixedEvent()->EventIndexForCaloCluster(photon1->GetCaloLabel(0)) ; if(TMath::Abs(GetVertex(evtIndex1)[2]) > GetZvertexCut()) continue ; //vertex cut mom1 = *(photon1->Momentum()); //Get original cluster, to recover some information Int_t iclus = -1; AliVCluster *cluster1 = FindCluster(clusters,photon1->GetCaloLabel(0),iclus); if(!cluster1){ printf("AliAnaPi0EbE::MakeInvMassInCalorimeter() - First cluster not found\n"); return; } for(Int_t jphoton = iphoton+1; jphoton < GetInputAODBranch()->GetEntriesFast(); jphoton++) { AliAODPWG4Particle * photon2 = (AliAODPWG4Particle*) (GetInputAODBranch()->At(jphoton)); Int_t evtIndex2 = 0 ; if(GetMixedEvent()) evtIndex2 = GetMixedEvent()->EventIndexForCaloCluster(photon2->GetCaloLabel(0)) ; if(GetMixedEvent() && (evtIndex1 == evtIndex2)) continue ; if(TMath::Abs(GetVertex(evtIndex2)[2]) > GetZvertexCut()) continue ; //vertex cut mom2 = *(photon2->Momentum()); //Get original cluster, to recover some information Int_t iclus2; AliVCluster *cluster2 = FindCluster(clusters,photon2->GetCaloLabel(0),iclus2,iclus+1); if(!cluster2) { printf("AliAnaPi0EbE::MakeInvMassInCalorimeter() - Second cluster not found\n"); return; } Float_t e1 = photon1->E(); Float_t e2 = photon2->E(); //Select clusters with good time window difference Float_t tof1 = cluster1->GetTOF()*1e9;; Float_t tof2 = cluster2->GetTOF()*1e9;; Double_t t12diff = tof1-tof2; fhEPairDiffTime->Fill(e1+e2, t12diff); if(TMath::Abs(t12diff) > GetPairTimeCut()) continue; //Play with the MC stack if available if(IsDataMC()) HasPairSameMCMother(photon1, photon2, label, tag) ; // Check the invariant mass for different selection on the local maxima // Name of AOD method TO BE FIXED Int_t nMaxima1 = photon1->GetFiducialArea(); Int_t nMaxima2 = photon2->GetFiducialArea(); Double_t mass = (mom1+mom2).M(); Double_t epair = (mom1+mom2).E(); if(nMaxima1==nMaxima2) { if (nMaxima1==1) fhMassPairLocMax[0]->Fill(epair,mass); else if(nMaxima1==2) fhMassPairLocMax[1]->Fill(epair,mass); else fhMassPairLocMax[2]->Fill(epair,mass); } else if(nMaxima1==1 || nMaxima2==1) { if (nMaxima1==2 || nMaxima2==2) fhMassPairLocMax[3]->Fill(epair,mass); else fhMassPairLocMax[4]->Fill(epair,mass); } else fhMassPairLocMax[5]->Fill(epair,mass); // combinations with SS axis cut and NLM cut if(nMaxima1 == 1 && cluster2->GetM02() > 0.3) fhMassPairLocMax[6]->Fill(epair,mass); if(nMaxima2 == 1 && cluster1->GetM02() > 0.3) fhMassPairLocMax[6]->Fill(epair,mass); if(nMaxima1 > 1 && cluster2->GetM02() < 0.3 && cluster2->GetM02()> 0.1 ) fhMassPairLocMax[7]->Fill(epair,mass); if(nMaxima2 > 1 && cluster1->GetM02() < 0.3 && cluster1->GetM02()> 0.1 ) fhMassPairLocMax[7]->Fill(epair,mass); //Select good pair (good phi, pt cuts, aperture and invariant mass) if(GetNeutralMesonSelection()->SelectPair(mom1, mom2,fCalorimeter)) { if(GetDebug()>1) printf("AliAnaPi0EbE::MakeInvMassInCalorimeter() - Selected gamma pair: pt %f, phi %f, eta%f \n",(mom1+mom2).Pt(), (mom1+mom2).Phi()*180./3.1416, (mom1+mom2).Eta()); //Fill some histograms about shower shape if(fFillSelectClHisto && clusters && GetReader()->GetDataType()!=AliCaloTrackReader::kMC) { FillSelectedClusterHistograms(cluster1, nMaxima1, photon1->GetTag()); FillSelectedClusterHistograms(cluster2, nMaxima2, photon2->GetTag()); } // Tag both photons as decay photon1->SetTagged(kTRUE); photon2->SetTagged(kTRUE); fhPtDecay->Fill(photon1->Pt()); fhEDecay ->Fill(photon1->E() ); fhPtDecay->Fill(photon2->Pt()); fhEDecay ->Fill(photon2->E() ); //Create AOD for analysis mom = mom1+mom2; AliAODPWG4Particle pi0 = AliAODPWG4Particle(mom); pi0.SetIdentifiedParticleType(AliCaloPID::kPi0); pi0.SetDetector(photon1->GetDetector()); // MC pi0.SetLabel(label); pi0.SetTag(tag); //Set the indeces of the original caloclusters pi0.SetCaloLabel(photon1->GetCaloLabel(0), photon2->GetCaloLabel(0)); //pi0.SetInputFileIndex(input); AddAODParticle(pi0); }//pi0 }//2n photon loop }//1st photon loop if(GetDebug() > 1) printf("AliAnaPi0EbE::MakeInvMassInCalorimeter() - End fill AODs \n"); } //__________________________________________________ void AliAnaPi0EbE::MakeInvMassInCalorimeterAndCTS() { //Do analysis and fill aods //Search for the photon decay in calorimeters //Read photon list from AOD, produced in class AliAnaPhoton and AliGammaConversion //Check if 2 photons have the mass of the pi0. TLorentzVector mom1; TLorentzVector mom2; TLorentzVector mom ; Int_t tag = 0; Int_t label = 0; Int_t evtIndex = 0; // Check calorimeter input if(!GetInputAODBranch()){ printf("AliAnaPi0EbE::MakeInvMassInCalorimeterAndCTS() - No input calo photons in AOD branch with name < %s > , STOP\n",GetInputAODName().Data()); abort(); } // Get the array with conversion photons TClonesArray * inputAODGammaConv = (TClonesArray *) GetReader()->GetOutputEvent()->FindListObject(fInputAODGammaConvName); if(!inputAODGammaConv) { inputAODGammaConv = (TClonesArray *) GetReader()->GetInputEvent()->FindListObject(fInputAODGammaConvName); if(!inputAODGammaConv) { printf("AliAnaPi0EbE::MakeInvMassInCalorimeterAndCTS() - No input gamma conversions in AOD branch with name < %s >\n",fInputAODGammaConvName.Data()); return; } } //Get shower shape information of clusters TObjArray *clusters = 0; if (fCalorimeter=="EMCAL") clusters = GetEMCALClusters(); else if(fCalorimeter=="PHOS") clusters = GetPHOSClusters() ; Int_t nCTS = inputAODGammaConv->GetEntriesFast(); Int_t nCalo = GetInputAODBranch()->GetEntriesFast(); if(nCTS<=0 || nCalo <=0) { if(GetDebug() > 1) printf("AliAnaPi0EbE::MakeInvMassInCalorimeterAndCTS() - nCalo %d, nCTS %d, cannot loop\n",nCalo,nCTS); return; } if(GetDebug() > 1) printf("AliAnaPi0EbE::MakeInvMassInCalorimeterAndCTS() - Number of conversion photons %d\n",nCTS); // Do the loop, first calo, second CTS for(Int_t iphoton = 0; iphoton < GetInputAODBranch()->GetEntriesFast(); iphoton++){ AliAODPWG4Particle * photon1 = (AliAODPWG4Particle*) (GetInputAODBranch()->At(iphoton)); mom1 = *(photon1->Momentum()); //Get original cluster, to recover some information Int_t iclus = -1; AliVCluster *cluster = FindCluster(clusters,photon1->GetCaloLabel(0),iclus); for(Int_t jphoton = 0; jphoton < nCTS; jphoton++){ AliAODPWG4Particle * photon2 = (AliAODPWG4Particle*) (inputAODGammaConv->At(jphoton)); if(GetMixedEvent()) evtIndex = GetMixedEvent()->EventIndexForCaloCluster(photon2->GetCaloLabel(0)) ; if(TMath::Abs(GetVertex(evtIndex)[2]) > GetZvertexCut()) continue ; //vertex cut mom2 = *(photon2->Momentum()); Double_t mass = (mom1+mom2).M(); Double_t epair = (mom1+mom2).E(); Int_t nMaxima = photon1->GetFiducialArea(); if (nMaxima==1) fhMassPairLocMax[0]->Fill(epair,mass); else if(nMaxima==2) fhMassPairLocMax[1]->Fill(epair,mass); else fhMassPairLocMax[2]->Fill(epair,mass); //Play with the MC stack if available if(IsDataMC()) { Int_t label2 = photon2->GetLabel(); if(label2 >= 0 )photon2->SetTag(GetMCAnalysisUtils()->CheckOrigin(label2, GetReader(), photon2->GetInputFileIndex())); HasPairSameMCMother(photon1, photon2, label, tag) ; } //Select good pair (good phi, pt cuts, aperture and invariant mass) if(GetNeutralMesonSelection()->SelectPair(mom1, mom2,fCalorimeter)) { if(GetDebug() > 1) printf("AliAnaPi0EbE::MakeInvMassInCalorimeterAndCTS() - Selected gamma pair: pt %f, phi %f, eta%f\n",(mom1+mom2).Pt(), (mom1+mom2).Phi()*180./3.1416, (mom1+mom2).Eta()); //Fill some histograms about shower shape if(fFillSelectClHisto && cluster && GetReader()->GetDataType()!=AliCaloTrackReader::kMC) { FillSelectedClusterHistograms(cluster, nMaxima, photon1->GetTag()); } // Tag both photons as decay photon1->SetTagged(kTRUE); photon2->SetTagged(kTRUE); fhPtDecay->Fill(photon1->Pt()); fhEDecay ->Fill(photon1->E() ); //fhPtDecay->Fill(photon2->Pt()); //fhEDecay ->Fill(photon2->E() ); //Create AOD for analysis mom = mom1+mom2; AliAODPWG4Particle pi0 = AliAODPWG4Particle(mom); pi0.SetIdentifiedParticleType(AliCaloPID::kPi0); pi0.SetDetector(photon1->GetDetector()); // MC pi0.SetLabel(label); pi0.SetTag(tag); //Set the indeces of the original tracks or caloclusters pi0.SetCaloLabel(photon1->GetCaloLabel(0), -1); pi0.SetTrackLabel(photon2->GetTrackLabel(0), photon2->GetTrackLabel(1)); //pi0.SetInputFileIndex(input); AddAODParticle(pi0); }//pi0 }//2n photon loop }//1st photon loop if(GetDebug() > 1) printf("AliAnaPi0EbE::MakeInvMassInCalorimeterAndCTS() - End fill AODs \n"); } //_________________________________________________ void AliAnaPi0EbE::MakeShowerShapeIdentification() { //Search for pi0 in fCalorimeter with shower shape analysis TObjArray * pl = 0x0; //Select the Calorimeter of the photon if (fCalorimeter == "PHOS" ) pl = GetPHOSClusters(); else if (fCalorimeter == "EMCAL") pl = GetEMCALClusters(); if(!pl) { Info("MakeShowerShapeIdentification","TObjArray with %s clusters is NULL!\n",fCalorimeter.Data()); return; } TLorentzVector mom ; for(Int_t icalo = 0; icalo < pl->GetEntriesFast(); icalo++) { AliVCluster * calo = (AliVCluster*) (pl->At(icalo)); Int_t evtIndex = 0 ; if (GetMixedEvent()) { evtIndex=GetMixedEvent()->EventIndexForCaloCluster(calo->GetID()) ; } if(TMath::Abs(GetVertex(evtIndex)[2]) > GetZvertexCut()) continue ; //vertex cut //Get Momentum vector, if(GetReader()->GetDataType() != AliCaloTrackReader::kMC){ calo->GetMomentum(mom,GetVertex(evtIndex)) ;}//Assume that come from vertex in straight line else{ Double_t vertex[]={0,0,0}; calo->GetMomentum(mom,vertex) ; } //If too small or big pt, skip it if(mom.Pt() < GetMinPt() || mom.Pt() > GetMaxPt() ) continue ; //Check acceptance selection if(IsFiducialCutOn()) { Bool_t in = GetFiducialCut()->IsInFiducialCut(mom,fCalorimeter) ; if(! in ) continue ; } //Create AOD for analysis AliAODPWG4Particle aodpi0 = AliAODPWG4Particle(mom); aodpi0.SetLabel(calo->GetLabel()); //Set the indeces of the original caloclusters aodpi0.SetCaloLabel(calo->GetID(),-1); aodpi0.SetDetector(fCalorimeter); if(GetDebug() > 1) printf("AliAnaPi0EbE::MakeShowerShapeIdentification() - FillAOD: Min pt cut and fiducial cut passed: pt %3.2f, phi %2.2f, eta %1.2f\n",aodpi0.Pt(),aodpi0.Phi(),aodpi0.Eta()); //Check Distance to Bad channel, set bit. Double_t distBad=calo->GetDistanceToBadChannel() ; //Distance to bad channel if(distBad < 0.) distBad=9999. ; //workout strange convension dist = -1. ; if(distBad < fMinDist) //In bad channel (PHOS cristal size 2.2x2.2 cm) continue ; if(GetDebug() > 1) printf("AliAnaPi0EbE::MakeShowerShapeIdentification() - FillAOD: Bad channel cut passed %4.2f\n",distBad); if (distBad > fMinDist3) aodpi0.SetDistToBad(2) ; else if(distBad > fMinDist2) aodpi0.SetDistToBad(1) ; else aodpi0.SetDistToBad(0) ; //Check PID //PID selection or bit setting if(IsCaloPIDOn()) { //Skip matched clusters with tracks if(IsTrackMatched(calo, GetReader()->GetInputEvent())) continue ; // Get most probable PID, 2 options check bayesian PID weights or redo PID // By default, redo PID aodpi0.SetIdentifiedParticleType(GetCaloPID()->GetIdentifiedParticleType(calo));//PID recalculated if(GetDebug() > 1) printf("AliAnaPi0EbE::MakeShowerShapeIdentification() - PDG of identified particle %d\n",aodpi0.GetIdentifiedParticleType()); //If cluster does not pass pid, not pi0, skip it. if(aodpi0.GetIdentifiedParticleType() != AliCaloPID::kPi0) continue ; } else { //Set PID bits for later selection //GetPDG already called in SetPIDBits. GetCaloPID()->SetPIDBits(calo,&aodpi0, GetCaloUtils(), GetReader()->GetInputEvent()); if(GetDebug() > 1) printf("AliAnaPi0EbE::MakeShowerShapeIdentification() - PID Bits set \n"); } if(GetDebug() > 1) printf("AliAnaPi0EbE::MakeShowerShapeIdentification() - Pi0 selection cuts passed: pT %3.2f, pdg %d\n",aodpi0.Pt(), aodpi0.GetIdentifiedParticleType()); //Play with the MC stack if available //Check origin of the candidates if(IsDataMC()) { if((GetReader()->GetDataType() == AliCaloTrackReader::kMC && fAnaType!=kSSCalo) || GetReader()->GetDataType() != AliCaloTrackReader::kMC){ //aodpi0.SetInputFileIndex(input); Int_t tag =0; tag = GetMCAnalysisUtils()->CheckOrigin(calo->GetLabel(),GetReader(), aodpi0.GetInputFileIndex()); //GetMCAnalysisUtils()->CheckMultipleOrigin(calo->GetLabels(),calo->GetNLabels(), GetReader(), aodpi0.GetInputFileIndex(), tag); aodpi0.SetTag(tag); if(GetDebug() > 0) printf("AliAnaPi0EbE::MakeShowerShapeIdentification() - Origin of candidate %d\n",aodpi0.GetTag()); } }//Work with stack also //Add AOD with pi0 object to aod branch AddAODParticle(aodpi0); }//loop if(GetDebug() > 1) printf("AliAnaPi0EbE::MakeShowerShapeIdentification() - End fill AODs \n"); } //______________________________________________ void AliAnaPi0EbE::MakeAnalysisFillHistograms() { //Do analysis and fill histograms if(!GetOutputAODBranch()) { printf("AliAnaPi0EbE::MakeAnalysisFillHistograms() - No output pi0 in AOD branch with name < %s >,STOP \n",GetOutputAODName().Data()); abort(); } //Loop on stored AOD pi0 Int_t naod = GetOutputAODBranch()->GetEntriesFast(); if(GetDebug() > 0) printf("AliAnaPi0EbE::MakeAnalysisFillHistograms() - aod branch entries %d\n", naod); for(Int_t iaod = 0; iaod < naod ; iaod++) { AliAODPWG4Particle* pi0 = (AliAODPWG4Particle*) (GetOutputAODBranch()->At(iaod)); Int_t pdg = pi0->GetIdentifiedParticleType(); if(IsCaloPIDOn() && pdg != AliCaloPID::kPi0) continue; //Fill pi0 histograms Float_t ener = pi0->E(); Float_t pt = pi0->Pt(); Float_t phi = pi0->Phi(); if(phi < 0) phi+=TMath::TwoPi(); Float_t eta = pi0->Eta(); fhPt ->Fill(pt); fhE ->Fill(ener); fhEEta ->Fill(ener,eta); fhEPhi ->Fill(ener,phi); fhEtaPhi ->Fill(eta,phi); if(IsDataMC()) { if((GetReader()->GetDataType() == AliCaloTrackReader::kMC && fAnaType!=kSSCalo) || GetReader()->GetDataType() != AliCaloTrackReader::kMC){ if(GetMCAnalysisUtils()->CheckTagBit(pi0->GetTag(), AliMCAnalysisUtils::kMCPi0)) { fhPtMC ->Fill(pt); fhPhiMC ->Fill(pt,phi); fhEtaMC ->Fill(pt,eta); } else { fhPtMCNo ->Fill(pt); fhPhiMCNo ->Fill(pt,phi); fhEtaMCNo ->Fill(pt,eta); } } }//Histograms with MC }// aod loop } //__________________________________________________________________ void AliAnaPi0EbE::Print(const Option_t * opt) const { //Print some relevant parameters set for the analysis if(! opt) return; printf("**** Print %s %s ****\n", GetName(), GetTitle() ) ; AliAnaCaloTrackCorrBaseClass::Print(""); printf("Analysis Type = %d \n", fAnaType) ; if(fAnaType == kSSCalo){ printf("Calorimeter = %s\n", fCalorimeter.Data()) ; printf("Min Distance to Bad Channel = %2.1f\n",fMinDist); printf("Min Distance to Bad Channel 2 = %2.1f\n",fMinDist2); printf("Min Distance to Bad Channel 3 = %2.1f\n",fMinDist3); } printf(" \n") ; }