#ifndef ALIANAINSIDECLUSTERINVARIANTMASS_H #define ALIANAINSIDECLUSTERINVARIANTMASS_H /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * See cxx source for full Copyright notice */ //_________________________________________________________________________ // // Split clusters with some criteria and calculate invariant mass // to identify them as pi0 or conversion // // //-- Author: Gustavo Conesa (LPSC-Grenoble) //_________________________________________________________________________ // --- ROOT system --- class TList ; class TObjString; class TLorentzVector; // --- ANALYSIS system --- class AliAODCaloCluster; #include "AliAnaCaloTrackCorrBaseClass.h" class AliAnaInsideClusterInvariantMass : public AliAnaCaloTrackCorrBaseClass { public: AliAnaInsideClusterInvariantMass() ; // default ctor virtual ~AliAnaInsideClusterInvariantMass() { ; } //virtual dtor void CheckLocalMaximaMCOrigin(AliVCluster* cluster, Int_t mcindex, Int_t noverlaps, Float_t e1, Float_t e2, Float_t mass); //, Float_t m02, TLorentzVector l1, TLorentzVector l2); TObjString * GetAnalysisCuts(); TList * GetCreateOutputObjects(); void GetMCIndex(AliVCluster * cluster, Int_t & mcindex, Int_t & mcTag); void GetMCPrimaryKine(AliVCluster* cluster, Int_t mcindex, Int_t mcTag, Bool_t matched, Float_t & eprim, Float_t & asymGen, Float_t & angleGen, Int_t & noverlaps ); void FillAngleHistograms(Int_t nMax, Bool_t matched, Int_t mcindex, Float_t en, Float_t e1 , Float_t e2, Float_t angle, Float_t mass, Float_t anglePrim, Float_t m02, Float_t asym, Int_t pid, Int_t noverlaps); void FillArmenterosHistograms(Int_t nMax, Int_t ebin, Int_t mcindex, Float_t pi0E, Float_t m02, Int_t pid); void FillThetaStarHistograms(Int_t nMax, Bool_t matched, Int_t mcindex, Float_t pi0E, Float_t m02, Int_t pid); void FillEBinHistograms(Int_t ebin, Int_t nMax, Int_t mcindex, Float_t splitFrac, Float_t mass, Float_t asym, Float_t l0); void FillMCHistograms(Float_t en, Float_t e1 , Float_t e2, Int_t ebin, Int_t mcindex,Int_t noverlaps, Float_t l0, Float_t mass, Int_t nMax, Bool_t matched, Float_t splitFrac, Float_t asym, Float_t eprim, Float_t asymGen); void FillMCOverlapHistograms(Float_t en, Float_t enprim, Int_t nc, Float_t mass, Float_t l0, Float_t asym, Float_t splitFrac, Int_t nlm, Int_t ebin, Bool_t matched, Int_t mcindex, Int_t noverlaps); void FillSSWeightHistograms(AliVCluster *cluster, Int_t nlm, Int_t absId1, Int_t absId2); void FillSSExtraHistograms(AliVCluster *cluster, Int_t nMax, Bool_t matched, Int_t mcindex, Float_t mass , Int_t ebin); void FillNLMDiffCutHistograms(AliVCluster *cluster, AliVCaloCells *cells, Bool_t matched); void FillNCellHistograms(Int_t ncells, Float_t energy, Int_t nMax, Bool_t matched, Int_t mcindex, Float_t mass , Float_t l0); void FillTrackMatchingHistograms(AliVCluster * cluster,Int_t nMax, Int_t mcindex); void FillHistograms1(Float_t en, Float_t e1, Float_t e2, Int_t nMax, Float_t mass, Float_t l0, Float_t eta, Float_t phi, Bool_t matched, Int_t mcindex); void FillHistograms2(Float_t en, Float_t eprim, Float_t e1, Float_t e2, Int_t nMax, Float_t mass, Float_t l0, Bool_t matched, Int_t mcindex); void FillIdPi0Histograms(Float_t en, Float_t e1, Float_t e2, Int_t nc, Int_t nMax, Float_t t12diff, Float_t mass, Float_t l0, Float_t eta, Float_t phi, Bool_t matched, Int_t mcindex); void FillIdEtaHistograms(Float_t en, Float_t e1, Float_t e2, Int_t nc, Int_t nMax, Float_t t12diff, Float_t mass, Float_t l0, Float_t eta, Float_t phi, Bool_t matched, Int_t mcindex); void FillIdConvHistograms(Float_t en, Int_t nMax, Float_t asym, Float_t mass, Float_t l0, Bool_t matched, Int_t mcindex); void Init(); void InitParameters(); void MakeAnalysisFillHistograms() ; void Print(const Option_t * opt) const; void SetMinNCells(Int_t cut) { fMinNCells = cut ; } void SetMinBadChannelDistance(Float_t cut) { fMinBadDist = cut ; } void SetWCorrectionParameter(Int_t i, Float_t p = 0.07) { if( i<2 ) fWSimu[i] = p; } void SwitchOnFillAngleHistograms() { fFillAngleHisto = kTRUE ; } void SwitchOffFillAngleHistograms() { fFillAngleHisto = kFALSE ; } void SwitchOnFillArmenterosHistograms() { fFillArmenterosHisto = kTRUE ; } void SwitchOffFillArmenterosHistograms() { fFillArmenterosHisto = kFALSE ; } void SwitchOnFillThetaStarHistograms() { fFillThetaStarHisto = kTRUE ; } void SwitchOffFillThetaStarHistograms() { fFillThetaStarHisto = kFALSE ; } void SwitchOnFillExtraSSHistograms() { fFillSSExtraHisto = kTRUE ; } void SwitchOffFillExtraSSHistograms() { fFillSSExtraHisto = kFALSE ; } void SwitchOnFillHighMultHistograms() { fFillHighMultHisto = kTRUE ; } void SwitchOffFillHighMultHistograms() { fFillHighMultHisto = kFALSE ; } void SwitchOnFillIdConvHistograms() { fFillIdConvHisto = kTRUE ; } void SwitchOffFillIdConvHistograms() { fFillIdConvHisto = kFALSE ; } void SwitchOnFillIdEtaHistograms() { fFillIdEtaHisto = kTRUE ; } void SwitchOffFillIdEtaHistograms() { fFillIdEtaHisto = kFALSE ; } void SwitchOnFillTMHistograms() { fFillTMHisto = kTRUE ; } void SwitchOffFillTMHistograms() { fFillTMHisto = kFALSE ; } void SwitchOnFillTMResidualHistograms() { fFillTMResidualHisto = kTRUE ; } void SwitchOffFillTMResidualHistograms() { fFillTMResidualHisto = kFALSE ; } void SwitchOnFillMCPrimaryHistograms() { fFillMCHisto = kTRUE ; } void SwitchOffFillMCPrimaryHistograms() { fFillMCHisto = kFALSE ; } void SwitchOnFillSSWeightHistograms() { fFillSSWeightHisto = kTRUE ; } void SwitchOffFillSSWeightHistograms() { fFillSSWeightHisto = kFALSE ; } void SwitchOnFillNLMDiffCutsHistograms() { fFillNLMDiffCutHisto = kTRUE ; } void SwitchOffFillNLMDiffCutsHistograms() { fFillNLMDiffCutHisto = kFALSE ; } void SwitchOnFillEbinHistograms() { fFillEbinHisto = kTRUE ; } void SwitchOffFillEbinHistograms() { fFillEbinHisto = kFALSE ; } void SwitchOnFillMCOverlapHistograms() { fFillMCOverlapHisto = kTRUE ; } void SwitchOffFillMCOverlapHistograms() { fFillMCOverlapHisto = kFALSE ; } void SwitchOnFillNCellHistograms() { fFillNCellHisto = kTRUE ; } void SwitchOffFillNCellHistograms() { fFillNCellHisto = kFALSE ; } void SwitchOnSplitClusterDistToBad() { fCheckSplitDistToBad = kTRUE ; } void SwitchOffSplitClusterDistToBad() { fCheckSplitDistToBad = kFALSE ; } void SetNWeightForShowerShape(Int_t n) { fSSWeightN = n ; } void SetWeightForShowerShape(Int_t i, Float_t v) { if (i < 20) fSSWeight[i] = v ; } void SetNumberOfNLocMaxSettings(Int_t n) { fNLMSettingN = n ; } void SetNLocMaxMinE (Int_t i, Float_t v) { if (i < 5) fNLMMinE [i] = v ; } void SetNLocMaxMinDiff(Int_t i, Float_t v) { if (i < 5) fNLMMinDiff[i] = v ; } void SetNECellCutForShowerShape(Int_t n) { fSSECellCutN = n ; } void SetECellCutForShowerShape(Int_t i, Float_t v) { if (i < 20) fSSECellCut[i] = v ; } void RecalculateClusterShowerShapeParametersWithCellCut(const AliEMCALGeometry * geom, AliVCaloCells* cells, AliVCluster * cluster, Float_t & l0, Float_t & l1, Float_t & disp, Float_t & dEta, Float_t & dPhi, Float_t & sEta, Float_t & sPhi, Float_t & sEtaPhi,Float_t eCellMin = 0.); //For histograms enum mcTypes { kmcPhoton = 1, kmcConversion = 2, kmcPi0 = 3, kmcPi0Conv = 4, kmcEta = 5, kmcHadron = 6 }; private: Int_t fMinNCells ; // Study clusters with ncells larger than cut Float_t fMinBadDist ; // Minimal distance to bad channel to accept cluster Float_t fHistoECut ; // Fixed E cut for some histograms Bool_t fCheckSplitDistToBad; // Check the distance to bad channel and to EMCal borders of split clusters Bool_t fFillAngleHisto; // Fill splitted clusters angle histograms Bool_t fFillTMHisto ; // Fill track matching histos, Bool_t fFillTMResidualHisto ; // Fill track matching histos, residuals Bool_t fFillSSExtraHisto ; // Fill shower shape extra histos Bool_t fFillMCHisto ; // Fill MC energy fraction histos Bool_t fFillSSWeightHisto ; // Fill weigth histograms Bool_t fFillNLMDiffCutHisto ; // Fill NLM histograms for different settings Bool_t fFillEbinHisto ; // Fill E bin histograms Bool_t fFillMCOverlapHisto ; // Fill MC particles overlap histograms Bool_t fFillNCellHisto ; // Fill n cells in cluster dependent histograms Bool_t fFillIdConvHisto ; // Fill histograms for clusters identified as conversion Bool_t fFillIdEtaHisto ; // Fill histograms for clusters identified as Eta Bool_t fFillHighMultHisto; // Fill centrality/event plane histograms Bool_t fFillArmenterosHisto; // Fill armenteros type histo Bool_t fFillThetaStarHisto; // Fill cosThetaStar histos Float_t fSSWeight[20]; // List of weights to test Int_t fSSWeightN; // Total number of weights to test Float_t fSSECellCut[20]; // List of cell min energy cuts to test Int_t fSSECellCutN; // Total number of cell min energy cuts to test Float_t fNLMMinE [5]; // List of local maxima min energy Float_t fNLMMinDiff[5]; // List of local maxima min difference cell energy Int_t fNLMSettingN; // Total number of NLM settings to test Float_t fWSimu[2]; // Constant and slope of the linear correction factor for the shower // shape weight in simulation, about 1-0.07*w TLorentzVector fClusterMomentum; //! Cluster momentum TLorentzVector fSubClusterMom1; //! Sub-Cluster momentum TLorentzVector fSubClusterMom2; //! Sub-Cluster momentum TLorentzVector fSubClusterMomSum; //! Sub-Cluster momentum sum, armenteros TLorentzVector fSubClusterMomBoost; //! Sub-Cluster momentum boosted, armenteros TLorentzVector fPrimaryMom; //! Primary momentum TLorentzVector fGrandMotherMom; //! Primary momentum TLorentzVector fMCDaughMom1; //! Primary momentum TLorentzVector fMCDaughMom2; //! Primary momentum TVector3 fProdVertex; //! primary production vertex //Histograms TH2F * fhMassNLocMax1[7][2] ; //! Split Inv Mass vs cluster E, NLM=1, different MC particle types, track matching on/off TH2F * fhMassNLocMax2[7][2] ; //! Split Inv Mass vs cluster E, NLM=2, different MC particle types, track matching on/off TH2F * fhMassNLocMaxN[7][2] ; //! Split Inv Mass vs cluster E, NLM>2, different MC particle types, track matching on/off TH2F * fhMassSplitENLocMax1[7][2] ; //! Split Inv Mass vs E1+E2, NLM=1, different MC particle types, track matching on/off TH2F * fhMassSplitENLocMax2[7][2] ; //! Split Inv Mass vs E1+E2, NLM=2, different MC particle types, track matching on/off TH2F * fhMassSplitENLocMaxN[7][2] ; //! Split Inv Mass vs E1+E2, NLM>2, different MC particle types, track matching on/off TH2F * fhAsymNLocMax1[7][2] ; //! Asymmetry of 2 highest energy cells when 1 local max vs E, 1-6 for different MC particle types TH2F * fhAsymNLocMax2[7][2] ; //! Asymmetry of 2 cells local maxima vs E, 1-6 for different MC particle types TH2F * fhAsymNLocMaxN[7][2] ; //! Asymmetry of >2 cells local maxima vs E, 1-6 for different MC particle types TH2F * fhSplitEFractionvsAsyNLocMax1[2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima = 1 vs |A| TH2F * fhSplitEFractionvsAsyNLocMax2[2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima = 2 vs |A| TH2F * fhSplitEFractionvsAsyNLocMaxN[2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima > 2 vs |A| TH2F * fhMassAsyCutNLocMax1 ; //! Mass(E) asym selection, not matched, Mass of split clusters, NLM = 1 TH2F * fhMassAsyCutNLocMax2 ; //! Mass(E) asym selection, not matched, Mass of split clusters, NLM = 1 TH2F * fhMassAsyCutNLocMaxN ; //! Mass(E) asym selection, not matched, Mass of split clusters, NLM > 2 TH2F * fhM02AsyCutNLocMax1 ; //! M02(E) asym selection, not matched, M02, NLM = 1 TH2F * fhM02AsyCutNLocMax2 ; //! M02(E) asym selection, not matched, M02, NLM = 2 TH2F * fhM02AsyCutNLocMaxN ; //! M02(E) asym selection, not matched, M02, NLM > 2 TH2F * fhMassM02CutNLocMax1 ; //! Mass(E) M02 selection, not matched, Mass of split clusters, NLM = 1 TH2F * fhMassM02CutNLocMax2 ; //! Mass(E) M02 selection, not matched, Mass of split clusters, NLM = 1 TH2F * fhMassM02CutNLocMaxN ; //! Mass(E) M02 selection, not matched, Mass of split clusters, NLM > 2 TH2F * fhAsymM02CutNLocMax1 ; //! Asym(E) M02 selection, not matched, energy asymmetry of split clusters, NLM = 1 TH2F * fhAsymM02CutNLocMax2 ; //! Asym(E) M02 selection, not matched, energy asymmetry of split clusters, NLM = 2 TH2F * fhAsymM02CutNLocMaxN ; //! Asym(E) M02 selection, not matched, energy asymmetry of split clusters, NLM > 2 TH2F * fhMassEnCutNLocMax1 ; //! Mass(E) E sub-cluster cut selection, not matched, Mass of split clusters, NLM = 1 TH2F * fhMassEnCutNLocMax2 ; //! Mass(E) E sub-cluster cut selection, not matched, Mass of split clusters, NLM = 1 TH2F * fhMassEnCutNLocMaxN ; //! Mass(E) E sub-cluster cut selection, not matched, Mass of split clusters, NLM > 2 TH2F * fhM02EnCutNLocMax1 ; //! M02(E) E sub-cluster cut selection, not matched, Mass of split clusters, NLM = 1 TH2F * fhM02EnCutNLocMax2 ; //! M02(E) E sub-cluster cut selection, not matched, Mass of split clusters, NLM = 1 TH2F * fhM02EnCutNLocMaxN ; //! M02(E) E sub-cluster cut selection, not matched, Mass of split clusters, NLM > 2 TH2F * fhAsymEnCutNLocMax1 ; //! Asym(E) E sub-cluster cut selection, not matched, Mass of split clusters, NLM = 1 TH2F * fhAsymEnCutNLocMax2 ; //! Asym(E) E sub-cluster cut selection, not matched, Mass of split clusters, NLM = 1 TH2F * fhAsymEnCutNLocMaxN ; //! Asym(E) E sub-cluster cut selection, not matched, Mass of split clusters, NLM > 2 TH2F * fhSplitEFracEnCutNLocMax1 ; //! Split E fraction (E) E sub-cluster cut selection, not matched, Mass of split clusters, NLM = 1 TH2F * fhSplitEFracEnCutNLocMax2 ; //! Split E fraction (E) E sub-cluster cut selection, not matched, Mass of split clusters, NLM = 1 TH2F * fhSplitEFracEnCutNLocMaxN ; //! Split E fraction (E) E sub-cluster cut selection, not matched, Mass of split clusters, NLM > 2 TH2F * fhMassSplitECutNLocMax1 ; //! 85% of split energy, not matched, Mass of split clusters, NLM = 1 TH2F * fhMassSplitECutNLocMax2 ; //! 85% of split energy, not matched, Mass of split clusters, NLM = 1 TH2F * fhMassSplitECutNLocMaxN ; //! 85% of split energy, not matched, Mass of split clusters, NLM > 2 TH2F * fhMassM02NLocMax1[7][2] ; //! Mass of splitted clusters when 1 local max vs M02, for E > 8 GeV, 1-6 for different MC particle types TH2F * fhMassM02NLocMax2[7][2] ; //! Mass of splitted clusters when 2 local max vs M02, for E > 8 GeV, 1-6 for different MC particle types TH2F * fhMassM02NLocMaxN[7][2] ; //! Mass of splitted clusters when >2 local max vs M02, for E > 8 GeV, 1-6 for different MC particle types TH2F * fhMassM02NLocMax1Ebin[4] ; //! Mass of splitted clusters when 1 local max vs M02, 4 E bins, neutral clusters TH2F * fhMassM02NLocMax2Ebin[4] ; //! Mass of splitted clusters when 2 local max vs M02, 4 E bins, neutral clusters TH2F * fhMassM02NLocMaxNEbin[4] ; //! Mass of splitted clusters when >2 local max vs M02, 4 E bins, neutral clusters TH2F * fhMassAsyNLocMax1Ebin[4] ; //! Mass of Mass of splitted clusters when 1 local max vs asymmetry, 4 E bins, neutral clusters TH2F * fhMassAsyNLocMax2Ebin[4] ; //! Mass of Mass of splitted clusters when 2 local max vs asymmetry, 4 E bins, neutral clusters TH2F * fhMassAsyNLocMaxNEbin[4] ; //! Mass of Mass of splitted clusters when >2 local max vs asymmetry, 4 E bins, neutral clusters TH2F * fhAsyMCGenRecoNLocMax1EbinPi0[4] ; //! Generated vs reconstructed asymmetry of splitted clusters from pi0 when 1 local max, 4 E bins, neutral clusters TH2F * fhAsyMCGenRecoNLocMax2EbinPi0[4] ; //! Generated vs reconstructed asymmetry of splitted clusters from pi0 when 2 local max, 4 E bins, neutral clusters TH2F * fhAsyMCGenRecoNLocMaxNEbinPi0[4] ; //! Generated vs reconstructed asymmetry of splitted clusters from pi0 when >2 local max, 4 E bins, neutral clusters TH2F * fhAsyMCGenRecoDiffMCPi0[3]; //! reconstructed-generated asymmetry of splitted clusters vs E from pi0, for 3 NLM cases TH2F * fhAsyMCGenRecoDiffMCPi0Conv[3]; //! reconstructed-generated asymmetry of splitted clusters vs E from converted pi0, for 3 NLM cases TH2F * fhMassDispEtaNLocMax1[7][2] ; //! Mass of 2 highest energy cells when 1 local max, vs M02, for E > 8 GeV, 1-6 for different MC particle types TH2F * fhMassDispEtaNLocMax2[7][2] ; //! Mass of 2 cells local maxima, vs M02, for E > 8 GeV, 1-6 for different MC particle types TH2F * fhMassDispEtaNLocMaxN[7][2] ; //! Mass of >2 cells local maxima, vs M02, for E > 8 GeV, 1-6 for different MC particle types TH2F * fhMassDispEtaNLocMax1Ebin[4] ; //! Mass of 2 highest energy cells when 1 local max, vs M02, 4 E bins, neutral clusters TH2F * fhMassDispEtaNLocMax2Ebin[4] ; //! Mass of 2 cells local maxima, vs M02, 4 E bins, neutral clusters TH2F * fhMassDispEtaNLocMaxNEbin[4] ; //! Mass of >2 cells local maxima, vs M02, 4 E bins, neutral clusters TH2F * fhMassDispPhiNLocMax1[7][2] ; //! Mass of 2 highest energy cells when 1 local max, vs M02, for E > 8 GeV, 1-6 for different MC particle types TH2F * fhMassDispPhiNLocMax2[7][2] ; //! Mass of 2 cells local maxima, vs M02, for E > 8 GeV, 1-6 for different MC particle types TH2F * fhMassDispPhiNLocMaxN[7][2] ; //! Mass of >2 cells local maxima, vs M02, for E > 8 GeV, 1-6 for different MC particle types TH2F * fhMassDispPhiNLocMax1Ebin[4] ; //! Mass of 2 highest energy cells when 1 local max, vs M02, 4 E bins, neutral clusters TH2F * fhMassDispPhiNLocMax2Ebin[4] ; //! Mass of 2 cells local maxima, vs M02, 4 E bins, neutral clusters TH2F * fhMassDispPhiNLocMaxNEbin[4] ; //! Mass of >2 cells local maxima, vs M02, 4 E bins, neutral clusters TH2F * fhMassDispAsyNLocMax1[7][2] ; //! Mass of 2 highest energy cells when 1 local max, vs M02, for E > 8 GeV, 1-6 for different MC particle types TH2F * fhMassDispAsyNLocMax2[7][2] ; //! Mass of 2 cells local maxima, vs M02, for E > 8 GeV, 1-6 for different MC particle types TH2F * fhMassDispAsyNLocMaxN[7][2] ; //! Mass of >2 cells local maxima, vs M02, for E > 8 GeV, 1-6 for different MC particle types TH2F * fhMassDispAsyNLocMax1Ebin[4] ; //! Mass of 2 highest energy cells when 1 local max, vs M02, 4 E bins, neutral clusters TH2F * fhMassDispAsyNLocMax2Ebin[4] ; //! Mass of 2 cells local maxima, vs M02, 4 E bins, neutral clusters TH2F * fhMassDispAsyNLocMaxNEbin[4] ; //! Mass of >2 cells local maxima, vs M02, 4 E bins, neutral clusters TH2F * fhNLocMax [7][2] ; //! Number of maxima in cluster vs E, 1-6 for different MC particle types TH2F * fhNLocMaxM02Cut[7][2] ; //! Number of maxima in cluster vs E, 1-6 for different MC particle types, after SS cut TH2F * fhNLocMaxIdPi0 [7][2] ; //! Number of maxima in cluster vs E, 1-6 for different MC particle types, after pi0 selection TH2F * fhSplitClusterENLocMax[7][2] ; //! Number of maxima in cluster vs E of splitted clusters, 1-6 for different MC particle types TH2F * fhSplitClusterEPi0NLocMax[7][2] ; //! Number of maxima in cluster vs E of splitted clusters when cluster id as pi0, 1-6 for different MC particle types TH2F * fhLM1NLocMax [7][2] ; //! Split cluster 1 E distribution vs Number of maxima in cluster vs E, 1-6 for different MC particle types TH2F * fhLM1NLocMaxM02Cut[7][2] ; //! Split cluster 1 E distribution vs Number of maxima in cluster vs E, 1-6 for different MC particle types, after SS cut TH2F * fhLM1NLocMaxIdPi0 [7][2] ; //! Split cluster 1 E distribution vs Number of maxima in cluster vs E, 1-6 for different MC particle types, pi0 selection TH2F * fhLM2NLocMax [7][2] ; //! Split cluster 2 E distribution vs Number of maxima in cluster vs E, 1-6 for different MC particle types TH2F * fhLM2NLocMaxM02Cut[7][2] ; //! Split cluster 2 E distribution vs Number of maxima in cluster vs E, 1-6 for different MC particle types, after SS cut TH2F * fhLM2NLocMaxIdPi0 [7][2] ; //! Split cluster 2 E distribution vs Number of maxima in cluster vs E, 1-6 for different MC particle types, pi0 selection TH2F * fhM02NLocMax1 [7][2] ; //! M02 vs E for N max in cluster = 1, 1-6 for different MC particle types TH2F * fhM02NLocMax2 [7][2] ; //! M02 vs E for N max in cluster = 2, 1-6 for different MC particle types TH2F * fhM02NLocMaxN [7][2] ; //! M02 vs E for N max in cluster > 2, 1-6 for different MC particle types TH2F * fhMCAsymM02NLocMax1MCPi0Ebin[4] ; //! M02 vs decay asymmetry for N max in cluster = 1, for 4 energy bins TH2F * fhMCAsymM02NLocMax2MCPi0Ebin[4] ; //! M02 vs decay asymmetry for N max in cluster = 2, for 4 energy bins TH2F * fhMCAsymM02NLocMaxNMCPi0Ebin[4] ; //! M02 vs decay asymmetry for N max in cluster > 2, for 4 energy bins TH2F * fhMCGenFracNLocMax1[7][2] ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types TH2F * fhMCGenFracNLocMax2[7][2] ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types TH2F * fhMCGenFracNLocMaxN[7][2] ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types TH2F * fhMCGenFracNLocMax1NoOverlap[7][2] ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types, no overlap found TH2F * fhMCGenFracNLocMax2NoOverlap[7][2] ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types, no overlap found TH2F * fhMCGenFracNLocMaxNNoOverlap[7][2] ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types, no overlap found TH2F * fhMCGenFracAfterCutsNLocMax1MCPi0 ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster = 1, MCPi0 after M02 and asymmetry cut TH2F * fhMCGenFracAfterCutsNLocMax2MCPi0 ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster = 2, MCPi0, after M02 and asymmetry cut TH2F * fhMCGenFracAfterCutsNLocMaxNMCPi0 ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster > 2, MCPi0, after M02 and asymmetry cut TH2F * fhMCGenSplitEFracNLocMax1[7][2] ; //! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types TH2F * fhMCGenSplitEFracNLocMax2[7][2] ; //! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types TH2F * fhMCGenSplitEFracNLocMaxN[7][2] ; //! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types TH2F * fhMCGenSplitEFracNLocMax1NoOverlap[7][2];//! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types, no overlap TH2F * fhMCGenSplitEFracNLocMax2NoOverlap[7][2];//! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types, no overlap TH2F * fhMCGenSplitEFracNLocMaxNNoOverlap[7][2];//! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types, no overlap TH2F * fhMCGenSplitEFracAfterCutsNLocMax1MCPi0; //! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types TH2F * fhMCGenSplitEFracAfterCutsNLocMax2MCPi0; //! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types TH2F * fhMCGenSplitEFracAfterCutsNLocMaxNMCPi0; //! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types TH2F * fhMCGenEFracvsSplitEFracNLocMax1[7][2] ; //! E generated particle / E reconstructed vs E1+E2 reconstructed / E reconstructed for N max in cluster = 1, MC pi0 TH2F * fhMCGenEFracvsSplitEFracNLocMax2[7][2] ; //! E generated particle / E reconstructed vs E1+E2 reconstructed / E reconstructed for N max in cluster = 2, MC pi0 TH2F * fhMCGenEFracvsSplitEFracNLocMaxN[7][2] ; //! E generated particle / E reconstructed vs E1+E2 reconstructed / E reconstructed for N max in cluster > 2, MC pi0 TH2F * fhMCGenEvsSplitENLocMax1[7][2] ; //! E generated particle vs E1+E2 for N max in cluster = 1, 1-6 for different MC particle types TH2F * fhMCGenEvsSplitENLocMax2[7][2] ; //! E generated particle vs E1+E2 for N max in cluster = 2, 1-6 for different MC particle types TH2F * fhMCGenEvsSplitENLocMaxN[7][2] ; //! E generated particle vs E1+E2 for N max in cluster > 2, 1-6 for different MC particle types TH2F * fhMCGenFracNLocMaxEbin[7][4] ; //! NLM vs E generated particle / E reconstructed vs E reconstructed 1-6 for different MC particle types, not matched to track TH2F * fhMCGenFracNLocMaxEbinMatched[7][4] ; //! NLM vs E generated particle / E reconstructed vs E reconstructed 1-6 for different MC particle types, matched to track TH2F * fhM02MCGenFracNLocMax1Ebin[7][4] ; //! M02 vs E generated particle / E reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types, not track matched TH2F * fhM02MCGenFracNLocMax2Ebin[7][4] ; //! M02 vs E generated particle / E reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types, not track matched TH2F * fhM02MCGenFracNLocMaxNEbin[7][4] ; //! M02 vs E generated particle / E reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types, not track matched TH2F * fhMassMCGenFracNLocMax1Ebin[7][4] ; //! Mass vs E generated particle / E reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types, not track matched TH2F * fhMassMCGenFracNLocMax2Ebin[7][4] ; //! Mass vs E generated particle / E reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types, not track matched TH2F * fhMassMCGenFracNLocMaxNEbin[7][4] ; //! Mass vs E generated particle / E reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types, not track matched TH2F * fhNCellNLocMax1[7][2] ; //! n cells in cluster vs E for N max in cluster = 1, 1-6 for different MC particle types TH2F * fhNCellNLocMax2[7][2] ; //! n cells in cluster vs E for N max in cluster = 2, 1-6 for different MC particle types TH2F * fhNCellNLocMaxN[7][2] ; //! n cells in cluster vs E for N max in cluster > 2, 1-6 for different MC particle types TH2F * fhNCellMassEHighNLocMax1MCPi0 ; //! n cells in cluster vs mass for high energy clusters, for N max in cluster = 1, for MC pi0 TH2F * fhNCellM02EHighNLocMax1MCPi0 ; //! n cells in cluster vs m02 for high energy clusters, for N max in cluster = 1, for MC pi0 TH2F * fhNCellMassELowNLocMax1MCPi0 ; //! n cells in cluster vs mass for low energy clusters, for N max in cluster = 1, for MC pi0 TH2F * fhNCellM02ELowNLocMax1MCPi0 ; //! n cells in cluster vs m02 for low energy clusters, for N max in cluster = 1, for MC pi0 TH2F * fhNCellMassEHighNLocMax2MCPi0 ; //! n cells in cluster vs mass for high energy clusters, for N max in cluster = 2, for MC pi0 TH2F * fhNCellM02EHighNLocMax2MCPi0 ; //! n cells in cluster vs m02 for high energy clusters, for N max in cluster = 2, for MC pi0 TH2F * fhNCellMassELowNLocMax2MCPi0 ; //! n cells in cluster vs mass for low energy clusters, for N max in cluster = 2, for MC pi0 TH2F * fhNCellM02ELowNLocMax2MCPi0 ; //! n cells in cluster vs m02 for low energy clusters, for N max in cluster = 2, for MC pi0 TH2F * fhNCellMassEHighNLocMaxNMCPi0 ; //! n cells in cluster vs mass for high energy clusters, for N max in cluster > 2, for MC pi0 TH2F * fhNCellM02EHighNLocMaxNMCPi0 ; //! n cells in cluster vs m02 for high energy clusters, for N max in cluster > 2, for MC pi0 TH2F * fhNCellMassELowNLocMaxNMCPi0 ; //! n cells in cluster vs mass for low energy clusters, for N max in cluster > 2, for MC pi0 TH2F * fhNCellM02ELowNLocMaxNMCPi0 ; //! n cells in cluster vs m02 for low energy clusters, for N max in cluster > 2, for MC pi0 TH2F * fhM02Pi0NLocMax1[7][2] ; //! M02 for Mass around pi0, N Local Maxima = 1 TH2F * fhM02EtaNLocMax1[7][2] ; //! M02 for Mass around eta, N Local Maxima = 1 TH2F * fhM02ConNLocMax1[7][2] ; //! M02 for Mass around close to 0, N Local Maxima = 1 TH2F * fhM02Pi0NLocMax2[7][2] ; //! M02 for Mass around pi0, N Local Maxima = 2 TH2F * fhM02EtaNLocMax2[7][2] ; //! M02 for Mass around eta, N Local Maxima = 2 TH2F * fhM02ConNLocMax2[7][2] ; //! M02 for Mass around close to 0, N Local Maxima = 2 TH2F * fhM02Pi0NLocMaxN[7][2] ; //! M02 for Mass around pi0, N Local Maxima > 2 TH2F * fhM02EtaNLocMaxN[7][2] ; //! M02 for Mass around eta, N Local Maxima > 2 TH2F * fhM02ConNLocMaxN[7][2] ; //! M02 for Mass around close to 0, N Local Maxima > 2 TH2F * fhMassPi0NLocMax1[7][2] ; //! Mass for selected pi0, N Local Maxima = 1 TH2F * fhMassEtaNLocMax1[7][2] ; //! Mass for selected around eta, N Local Maxima = 1 TH2F * fhMassConNLocMax1[7][2] ; //! Mass for selected around close to 0, N Local Maxima = 1 TH2F * fhMassPi0NLocMax2[7][2] ; //! Mass for selected around pi0, N Local Maxima = 2 TH2F * fhMassEtaNLocMax2[7][2] ; //! Mass for selected around eta, N Local Maxima = 2 TH2F * fhMassConNLocMax2[7][2] ; //! Mass for selected around close to 0, N Local Maxima = 2 TH2F * fhMassPi0NLocMaxN[7][2] ; //! Mass for selected around pi0, N Local Maxima > 2 TH2F * fhMassEtaNLocMaxN[7][2] ; //! Mass for selected around eta, N Local Maxima > 2 TH2F * fhMassConNLocMaxN[7][2] ; //! Mass for selected around close to 0, N Local Maxima > 2 TH2F * fhNCellPi0NLocMax1[7][2] ; //! n cells for selected around pi0, N Local Maxima = 1 TH2F * fhNCellEtaNLocMax1[7][2] ; //! n cells for selected around eta, N Local Maxima = 1 TH2F * fhNCellPi0NLocMax2[7][2] ; //! n cells for selected around pi0, N Local Maxima = 2 TH2F * fhNCellEtaNLocMax2[7][2] ; //! n cells for selected around eta, N Local Maxima = 2 TH2F * fhNCellPi0NLocMaxN[7][2] ; //! n cells for selected around pi0, N Local Maxima > 2 TH2F * fhNCellEtaNLocMaxN[7][2] ; //! n cells for selected around eta, N Local Maxima > 2 TH2F * fhMassAfterCutsNLocMax1[7][2] ; //! Mass after M02, asymmetry cuts for MC part, N Local Maxima = 1 TH2F * fhMassAfterCutsNLocMax2[7][2] ; //! Mass after M02, asymmetry cuts for MC part, N Local Maxima = 2 TH2F * fhMassAfterCutsNLocMaxN[7][2] ; //! Mass after M02, asymmetry cuts for MC part, N Local Maxima > 2 TH2F * fhMassSplitEAfterCutsNLocMax1[7][2] ; //! Split Inv Mass vs E1+E2, NLM=1, after M02, asymmetry cuts, different MC particle types, track matching on/off TH2F * fhMassSplitEAfterCutsNLocMax2[7][2] ; //! Split Inv Mass vs E1+E2, NLM=2, after M02, asymmetry cuts, different MC particle types, track matching on/off TH2F * fhMassSplitEAfterCutsNLocMaxN[7][2] ; //! Split Inv Mass vs E1+E2, NLM>2, after M02, asymmetry cuts, different MC particle types, track matching on/off TH2F * fhMassSplitEPi0NLocMax1[7][2] ; //! Split Inv Mass vs E1+E2, NLM=1, after pi0 selection, different MC particle types, track matching on/off TH2F * fhMassSplitEPi0NLocMax2[7][2] ; //! Split Inv Mass vs E1+E2, NLM=2, after pi0 selection, different MC particle types, track matching on/off TH2F * fhMassSplitEPi0NLocMaxN[7][2] ; //! Split Inv Mass vs E1+E2, NLM>2, after pi0 selection, different MC particle types, track matching on/off TH2F * fhAsyPi0NLocMax1[7][2] ; //! Asy for Mass around pi0, N Local Maxima = 1 TH2F * fhAsyEtaNLocMax1[7][2] ; //! Asy for Mass around eta, N Local Maxima = 1 TH2F * fhAsyConNLocMax1[7][2] ; //! Asy for Mass around close to 0, N Local Maxima = 1 TH2F * fhAsyPi0NLocMax2[7][2] ; //! Asy for Mass around pi0, N Local Maxima = 2 TH2F * fhAsyEtaNLocMax2[7][2] ; //! Asy for Mass around eta, N Local Maxima = 2 TH2F * fhAsyConNLocMax2[7][2] ; //! Asy for Mass around close to 0, N Local Maxima = 2 TH2F * fhAsyPi0NLocMaxN[7][2] ; //! Asy for Mass around pi0, N Local Maxima > 2 TH2F * fhAsyEtaNLocMaxN[7][2] ; //! Asy for Mass around eta, N Local Maxima > 2 TH2F * fhAsyConNLocMaxN[7][2] ; //! Asy for Mass around close to 0, N Local Maxima > 2 TH2F * fhSplitEFractionNLocMax1[7][2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima = 1 TH2F * fhSplitEFractionNLocMax2[7][2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima = 2 TH2F * fhSplitEFractionNLocMaxN[7][2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima > 2 TH2F * fhSplitEFractionAfterCutsNLocMax1[7][2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima = 1, after M02 and asymmetry cut TH2F * fhSplitEFractionAfterCutsNLocMax2[7][2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima = 2, after M02 and asymmetry cut TH2F * fhSplitEFractionAfterCutsNLocMaxN[7][2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima > 2, after M02 and asymmetry cut TH2F * fhMassSplitEFractionNLocMax1Ebin[7][4] ; //! Mass vs sum of splitted cluster energy / cluster energy for N max in cluster = 1, 1-6 for different MC particle types, not track matched TH2F * fhMassSplitEFractionNLocMax2Ebin[7][4] ; //! Mass vs sum of splitted cluster energy / cluster energy for N max in cluster = 2, 1-6 for different MC particle types, not track matched TH2F * fhMassSplitEFractionNLocMaxNEbin[7][4] ; //! Mass vs sum of splitted cluster energy / cluster energy for N max in cluster > 2, 1-6 for different MC particle types, not track matched TH2F * fhAnglePairNLocMax1[7][2] ; //! pair opening angle vs E TH2F * fhAnglePairNLocMax2[7][2] ; //! pair opening angle vs E TH2F * fhAnglePairNLocMaxN[7][2] ; //! pair opening angle vs E TH2F * fhAnglePairAfterCutsNLocMax1[7][2] ; //! pair opening angle vs E TH2F * fhAnglePairAfterCutsNLocMax2[7][2] ; //! pair opening angle vs E TH2F * fhAnglePairAfterCutsNLocMaxN[7][2] ; //! pair opening angle vs E TH2F * fhAnglePairPi0NLocMax1[7][2] ; //! pair opening angle vs E TH2F * fhAnglePairPi0NLocMax2[7][2] ; //! pair opening angle vs E TH2F * fhAnglePairPi0NLocMaxN[7][2] ; //! pair opening angle vs E TH2F * fhAnglePairMassNLocMax1[7][2] ; //! pair opening angle vs Mass for E > 7 GeV TH2F * fhAnglePairMassNLocMax2[7][2] ; //! pair opening angle vs Mass for E > 7 GeV TH2F * fhAnglePairMassNLocMaxN[7][2] ; //! pair opening angle vs Mass for E > 7 GeV TH2F * fhAnglePairM02NLocMax1[7][2] ; //! pair opening angle vs M02 for E > 7 GeV TH2F * fhAnglePairM02NLocMax2[7][2] ; //! pair opening angle vs M02 for E > 7 GeV TH2F * fhAnglePairM02NLocMaxN[7][2] ; //! pair opening angle vs M02 for E > 7 GeV TH2F * fhAnglePairPrimPi0RecoNLocMax1; //! pair opening angle pi0 generated/reconstructed vs E TH2F * fhAnglePairPrimPi0RecoNLocMax2; //! pair opening angle pi0 generated/reconstructed vs E TH2F * fhAnglePairPrimPi0RecoNLocMaxN; //! pair opening angle pi0 generated/reconstructed vs E TH2F * fhAnglePairPrimPi0vsRecoNLocMax1; //! pair opening angle pi0 generated vs reconstructed TH2F * fhAnglePairPrimPi0vsRecoNLocMax2; //! pair opening angle pi0 generated vs reconstructed TH2F * fhAnglePairPrimPi0vsRecoNLocMaxN; //! pair opening angle pi0 generated vs reconstructed TH2F * fhAnglePairOverM02NLocMax1[7][2]; //! pair opening angle / m02 vs E, NLM=1 TH2F * fhAnglePairOverM02NLocMax2[7][2]; //! pair opening angle / m02 vs E, NLM=2 TH2F * fhAnglePairOverM02NLocMaxN[7][2]; //! pair opening angle / m02 vs E, NLM=N TH2F * fhAnglePairOverM02NLocMax1Overlap0[7][2];//! pair opening angle / m02 vs E, NLM=1 TH2F * fhAnglePairOverM02NLocMax2Overlap0[7][2];//! pair opening angle / m02 vs E, NLM=2 TH2F * fhAnglePairOverM02NLocMaxNOverlap0[7][2];//! pair opening angle / m02 vs E, NLM=N TH2F * fhAnglePairPrimPi0OverM02NLocMax1; //! pair opening angle / m02 vs E, NLM=1, prim pi0 TH2F * fhAnglePairPrimPi0OverM02NLocMax2; //! pair opening angle / m02 vs E, NLM=2, prim pi0 TH2F * fhAnglePairPrimPi0OverM02NLocMaxN; //! pair opening angle / m02 vs E, NLM=N, prim pi0 TH2F * fhArmNLocMax1[7][4] ; //! Armenteros of 2 highest energy cells when 1 local max vs E, 1-6 for different MC particle types TH2F * fhArmNLocMax2[7][4] ; //! Armenteros of 2 cells local maxima vs E, 1-6 for different MC particle types TH2F * fhArmNLocMaxN[7][4] ; //! Armenteros of >2 cells local maxima vs E, 1-6 for different MC particle types TH2F * fhArmAfterCutsNLocMax1[7][4] ; //! Armenteros after M02, asymmetry cuts for pi0, N Local Maxima = 1 TH2F * fhArmAfterCutsNLocMax2[7][4] ; //! Armenteros after M02, asymmetry cuts for pi0, N Local Maxima = 2 TH2F * fhArmAfterCutsNLocMaxN[7][4] ; //! Armenteros after M02, asymmetry cuts for pi0, N Local Maxima > 2 TH2F * fhArmPi0NLocMax1[7][4] ; //! Armenteros for selected pi0, N Local Maxima = 1 TH2F * fhArmPi0NLocMax2[7][4] ; //! Armenteros for selected pi0, N Local Maxima = 2 TH2F * fhArmPi0NLocMaxN[7][4] ; //! Armenteros for selected pi0, N Local Maxima > 2 TH2F * fhCosThStarNLocMax1[7][2] ; //! cos(theta^star) vs E, NLM=1 TH2F * fhCosThStarNLocMax2[7][2] ; //! cos(theta^star) vs E, NLM=2 TH2F * fhCosThStarNLocMaxN[7][2] ; //! cos(theta^star) vs E, NLM>2 TH2F * fhCosThStarAfterCutsNLocMax1[7][2] ; //! cos(theta^star) vs E, after M02, asymmetry cuts, NLM=1 TH2F * fhCosThStarAfterCutsNLocMax2[7][2] ; //! cos(theta^star) vs E, after M02, asymmetry cuts, NLM=2 TH2F * fhCosThStarAfterCutsNLocMaxN[7][2] ; //! cos(theta^star) vs E, after M02, asymmetry cuts, NLM>2 TH2F * fhCosThStarPi0NLocMax1[7][2] ; //! cos(theta^star) vs E, after M02, asymmetry and pi0 mass cuts, NLM=1 TH2F * fhCosThStarPi0NLocMax2[7][2] ; //! cos(theta^star) vs E, after M02, asymmetry and pi0 mass cuts, NLM=2 TH2F * fhCosThStarPi0NLocMaxN[7][2] ; //! cos(theta^star) vs E, after M02, asymmetry and pi0 mass cuts, NLM>2 TH2F * fhTrackMatchedDEtaNLocMax1[7] ; //! Eta distance between track and cluster vs cluster E, 1 local maximum TH2F * fhTrackMatchedDPhiNLocMax1[7] ; //! Phi distance between track and cluster vs cluster E, 1 local maximum TH2F * fhTrackMatchedDEtaNLocMax2[7] ; //! Eta distance between track and cluster vs cluster E, 2 local maximum TH2F * fhTrackMatchedDPhiNLocMax2[7] ; //! Phi distance between track and cluster vs cluster E, 2 local maximum TH2F * fhTrackMatchedDEtaNLocMaxN[7] ; //! Eta distance between track and cluster vs cluster E, more than 2 local maximum TH2F * fhTrackMatchedDPhiNLocMaxN[7] ; //! Phi distance between track and cluster vs cluster E, more than 2 local maximum TH2F * fhTrackMatchedDEtaNLocMax1Pos[7] ; //! Eta distance between track and cluster vs cluster E, 1 local maximum TH2F * fhTrackMatchedDPhiNLocMax1Pos[7] ; //! Phi distance between track and cluster vs cluster E, 1 local maximum TH2F * fhTrackMatchedDEtaNLocMax2Pos[7] ; //! Eta distance between track and cluster vs cluster E, 2 local maximum TH2F * fhTrackMatchedDPhiNLocMax2Pos[7] ; //! Phi distance between track and cluster vs cluster E, 2 local maximum TH2F * fhTrackMatchedDEtaNLocMaxNPos[7] ; //! Eta distance between track and cluster vs cluster E, more than 2 local maximum TH2F * fhTrackMatchedDPhiNLocMaxNPos[7] ; //! Phi distance between track and cluster vs cluster E, more than 2 local maximum TH2F * fhTrackMatchedDEtaNLocMax1Neg[7] ; //! Eta distance between track and cluster vs cluster E, 1 local maximum TH2F * fhTrackMatchedDPhiNLocMax1Neg[7] ; //! Phi distance between track and cluster vs cluster E, 1 local maximum TH2F * fhTrackMatchedDEtaNLocMax2Neg[7] ; //! Eta distance between track and cluster vs cluster E, 2 local maximum TH2F * fhTrackMatchedDPhiNLocMax2Neg[7] ; //! Phi distance between track and cluster vs cluster E, 2 local maximum TH2F * fhTrackMatchedDEtaNLocMaxNNeg[7] ; //! Eta distance between track and cluster vs cluster E, more than 2 local maximum TH2F * fhTrackMatchedDPhiNLocMaxNNeg[7] ; //! Phi distance between track and cluster vs cluster E, more than 2 local maximum TH2F * fhCentralityPi0NLocMax1 ; //! Centrality for selected pi0, N Local Maxima = 1 TH2F * fhCentralityEtaNLocMax1 ; //! Centrality for selected eta, N Local Maxima = 1 TH2F * fhCentralityPi0NLocMax2 ; //! Centrality for selected pi0, N Local Maxima = 2 TH2F * fhCentralityEtaNLocMax2 ; //! Centrality for selected eta, N Local Maxima = 2 TH2F * fhCentralityPi0NLocMaxN ; //! Centrality for selected pi0, N Local Maxima > 2 TH2F * fhCentralityEtaNLocMaxN ; //! Centrality for selected eta, N Local Maxima > 2 TH2F * fhEventPlanePi0NLocMax1 ; //! Event plane for selected pi0, N Local Maxima = 1 TH2F * fhEventPlaneEtaNLocMax1 ; //! Event plane for selected eta, N Local Maxima = 1 TH2F * fhEventPlanePi0NLocMax2 ; //! Event plane for selected pi0, N Local Maxima = 2 TH2F * fhEventPlaneEtaNLocMax2 ; //! Event plane for selected eta, N Local Maxima = 2 TH2F * fhEventPlanePi0NLocMaxN ; //! Event plane for selected pi0, N Local Maxima > 2 TH2F * fhEventPlaneEtaNLocMaxN ; //! Event plane for selected eta, N Local Maxima > 2 TH2F * fhClusterEtaPhiNLocMax1 ; //! Eta vs Phi of clusters with N Local Maxima = 1, E > 8 GeV TH2F * fhClusterEtaPhiNLocMax2 ; //! Eta vs Phi of clusters with N Local Maxima = 2, E > 8 GeV TH2F * fhClusterEtaPhiNLocMaxN ; //! Eta vs Phi of clusters with N Local Maxima > 2, E > 8 GeV TH2F * fhPi0EtaPhiNLocMax1 ; //! Eta vs Phi of pi0's with N Local Maxima = 1, E > 8 GeV TH2F * fhPi0EtaPhiNLocMax2 ; //! Eta vs Phi of pi0's with N Local Maxima = 2, E > 8 GeV TH2F * fhPi0EtaPhiNLocMaxN ; //! Eta vs Phi of pi0's with N Local Maxima > N, E > 8 GeV TH2F * fhEtaEtaPhiNLocMax1 ; //! Eta vs Phi of eta's with N Local Maxima = 1, E > 8 GeV TH2F * fhEtaEtaPhiNLocMax2 ; //! Eta vs Phi of eta's with N Local Maxima = 2, E > 8 GeV TH2F * fhEtaEtaPhiNLocMaxN ; //! Eta vs Phi of eta's with N Local Maxima > N, E > 8 GeV TH2F * fhPi0CellE[3] ; //! pi0's energy vs cluster cell energy with NLM = 1, = 2, > 2 TH2F * fhPi0CellEFrac[3] ; //! pi0's energy vs cluster cell energy fraction with NLM = 1, = 2, > 2 TH2F * fhPi0CellLogEFrac[3] ; //! pi0's energy vs cluster log cell energy fraction with NLM = 1, = 2, > 2 TH2F * fhPi0CellEMaxEMax2Frac [3]; //! pi0's energy vs fraction of 2 main maxima energy with NLM = 1, = 2, > 2 TH2F * fhPi0CellEMaxClusterFrac [3]; //! pi0's energy vs energy fraction of main LM and cluster energy with NLM = 1, = 2, > 2 TH2F * fhPi0CellEMax2ClusterFrac[3]; //! pi0's energy vs energy fraction of second LM and cluster energy with NLM = 1, = 2, > 2 TH2F * fhPi0CellEMaxFrac [3]; //! pi0's energy vs energy fraction of main LM and cluster cell energy with NLM = 1, = 2, > 2 TH2F * fhPi0CellEMax2Frac [3]; //! pi0's energy vs energy fraction of second LM and cluster cell energy with NLM = 1, = 2, > 2 TH2F * fhM02WeightPi0[3][20] ; //! M02 for selected pi0 with different weight, with NLM = 1, = 2, > 2 TH2F * fhM02ECellCutPi0[3][20] ; //! M02 for selected pi0 with different cut on cell energy, with NLM = 1, = 2, > 2 TH2F * fhPi0EPairDiffTimeNLM1; //! E vs Pair of clusters time difference vs E, for selected pi0, NLM=1 TH2F * fhPi0EPairDiffTimeNLM2; //! E vs Pair of clusters time difference vs E, for selected pi0, NLM=2 TH2F * fhPi0EPairDiffTimeNLMN; //! E vs Pair of clusters time difference vs E, for selected pi0, NLM>2 TH2F * fhEtaEPairDiffTimeNLM1; //! E vs Pair of clusters time difference vs E, for selected eta, NLM=1 TH2F * fhEtaEPairDiffTimeNLM2; //! E vs Pair of clusters time difference vs E, for selected eta, NLM=2 TH2F * fhEtaEPairDiffTimeNLMN; //! E vs Pair of clusters time difference vs E, for selected eta, NLM>2 TH2F * fhMCEM02Overlap0[3][7]; //! E vs M02 for different MC origin, no other MC particles contributes, neutral cluster TH2F * fhMCEM02Overlap1[3][7]; //! E vs M02 for different MC origin, 1 other MC particles contributes, neutral cluster TH2F * fhMCEM02OverlapN[3][7]; //! E vs M02 for different MC origin, N other MC particles contributes, neutral cluster TH2F * fhMCEM02Overlap0Match[3][7]; //! E vs M02 for different MC origin, no other MC particles contributes, charged cluster TH2F * fhMCEM02Overlap1Match[3][7]; //! E vs M02 for different MC origin, 1 other MC particles contributes, charged cluster TH2F * fhMCEM02OverlapNMatch[3][7]; //! E vs M02 for different MC origin, N other MC particles contributes, charged cluster TH2F * fhMCEMassOverlap0[3][7]; //! E vs Mass for different MC origin, no other MC particles contributes, neutral cluster TH2F * fhMCEMassOverlap1[3][7]; //! E vs Mass for different MC origin, 1 other MC particles contributes, neutral cluster TH2F * fhMCEMassOverlapN[3][7]; //! E vs Mass for different MC origin, N other MC particles contributes, neutral cluster TH2F * fhMCEMassOverlap0Match[3][7]; //! E vs Mass for different MC origin, no other MC particles contributes, charged cluster TH2F * fhMCEMassOverlap1Match[3][7]; //! E vs Mass for different MC origin, 1 other MC particles contributes, charged cluster TH2F * fhMCEMassOverlapNMatch[3][7]; //! E vs Mass for different MC origin, N other MC particles contributes, charged cluster TH2F * fhMCESplitEFracOverlap0[3][7]; //! E vs sum of splitted cluster energy / cluster energy for different MC origin, no other MC particles contributes, neutral cluster TH2F * fhMCESplitEFracOverlap1[3][7]; //! E vs sum of splitted cluster energy / cluster energy for different MC origin, 1 other MC particles contributes, neutral cluster TH2F * fhMCESplitEFracOverlapN[3][7]; //! E vs sum of splitted cluster energy / cluster energy for different MC origin, N other MC particles contributes, neutral cluster TH2F * fhMCESplitEFracOverlap0Match[3][7]; //! E vs sum of splitted cluster energy / cluster energy for different MC origin, no other MC particles contributes, charged cluster TH2F * fhMCESplitEFracOverlap1Match[3][7]; //! E vs sum of splitted cluster energy / cluster energy for different MC origin, 1 other MC particles contributes, charged cluster TH2F * fhMCESplitEFracOverlapNMatch[3][7]; //! E vs sum of splitted cluster energy / cluster energy for different MC origin, N other MC particles contributes, charged cluster TH2F * fhMCEAsymOverlap0[3][7]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, no other MC particles contributes, neutral cluster TH2F * fhMCEAsymOverlap1[3][7]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, 1 other MC particles contributes, neutral cluster TH2F * fhMCEAsymOverlapN[3][7]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, N other MC particles contributes, neutral cluster TH2F * fhMCEAsymOverlap0Match[3][7]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, no other MC particles contributes, charged cluster TH2F * fhMCEAsymOverlap1Match[3][7]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, 1 other MC particles contributes, charged cluster TH2F * fhMCEAsymOverlapNMatch[3][7]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, N other MC particles contributes, charged cluster TH2F * fhMCENCellOverlap0[3][7]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, no other MC particles contributes, neutral cluster TH2F * fhMCENCellOverlap1[3][7]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, 1 other MC particles contributes, neutral cluster TH2F * fhMCENCellOverlapN[3][7]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, N other MC particles contributes, neutral cluster TH2F * fhMCENCellOverlap0Match[3][7]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, no other MC particles contributes, charged cluster TH2F * fhMCENCellOverlap1Match[3][7]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, 1 other MC particles contributes, charged cluster TH2F * fhMCENCellOverlapNMatch[3][7]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, N other MC particles contributes, charged cluster TH2F * fhMCEEpriOverlap0[3][7]; //! E reco vs primary for different MC origin, no other MC particles contributes, neutral cluster TH2F * fhMCEEpriOverlap1[3][7]; //! E reco vs primary for different MC origin, 1 other MC particles contributes, neutral cluster TH2F * fhMCEEpriOverlapN[3][7]; //! E reco vs primary for different MC origin, N other MC particles contributes, neutral cluster TH2F * fhMCEEpriOverlap0Match[3][7]; //! E reco vs primary for different MC origin, no other MC particles contributes, charged cluster TH2F * fhMCEEpriOverlap1Match[3][7]; //! E reco vs primary for different MC origin, 1 other MC particles contributes, charged cluster TH2F * fhMCEEpriOverlapNMatch[3][7]; //! E reco vs primary for different MC origin, N other MC particles contributes, charged cluster TH2F * fhMCEEpriOverlap0IdPi0[3][7]; //! E reco vs primary for different MC origin, no other MC particles contributes, neutral cluster, neutral clusters id as pi0 TH2F * fhMCEEpriOverlap1IdPi0[3][7]; //! E reco vs primary for different MC origin, 1 other MC particles contributes, neutral cluster, neutral clusters id as pi0 TH2F * fhMCEEpriOverlapNIdPi0[3][7]; //! E reco vs primary for different MC origin, 1 other MC particles contributes, neutral cluster, neutral clusters is as pi0 TH2F * fhMCPi0MassM02Overlap0[3][4]; //! MC Pi0 M02 vs Mass for different MC origin, no other MC particles contributes, neutral cluster, 4 E bins TH2F * fhMCPi0MassM02Overlap1[3][4]; //! MC Pi0 M02 vs Mass for different MC origin, 1 other MC particles contributes, neutral cluster, 4 E bins TH2F * fhMCPi0MassM02OverlapN[3][4]; //! MC Pi0 M02 vs Mass for different MC origin, N other MC particles contributes, neutral cluster, 4 E bins TH2F * fhMCPi0MassM02Overlap0Match[3][4]; //! MC Pi0 M02 vs Mass for different MC origin, no other MC particles contributes, charged cluster, 4 E bins TH2F * fhMCPi0MassM02Overlap1Match[3][4]; //! MC Pi0 M02 vs Mass for different MC origin, 1 other MC particles contributes, charged cluster, 4 E bins TH2F * fhMCPi0MassM02OverlapNMatch[3][4]; //! MC Pi0 M02 vs Mass for different MC origin, N other MC particles contributes, charged cluster, 4 E bins TH2F * fhMCENOverlaps[3][7]; //! E vs number of Overlaps in MC, neutral cluster TH2F * fhMCENOverlapsMatch[3][7]; //! E vs number of Overlaps in MC, charged cluster TH2F * fhMCPi0HighNLMPair; //! E vs NLM when cluster originated in pi0 merging and highest energy local maxima correspond to 2 photons TH2F * fhMCPi0LowNLMPair; //! E vs NLM when cluster originated in pi0 merging and a pair of local maxima except highest energy correspond to 2 photons TH2F * fhMCPi0AnyNLMPair; //! E vs NLM when cluster originated in pi0 merging and a both highest energy pairs and other pairs correspond to 2 photons TH2F * fhMCPi0NoneNLMPair; //! E vs NLM when cluster originated in pi0 merging and a both no NLM corresponds to the photons // No match between highest energy local maxima and highest energy MC particle TH2F * fhMCPi0HighNLMPairNoMCMatch; //! E vs NLM when cluster originated in pi0 merging and highest energy local maxima correspond to 2 photons TH2F * fhMCPi0LowNLMPairNoMCMatch; //! E vs NLM when cluster originated in pi0 merging and a pair of local maxima except highest energy correspond to 2 photons TH2F * fhMCPi0AnyNLMPairNoMCMatch; //! E vs NLM when cluster originated in pi0 merging and a both highest energy pairs and other pairs correspond to 2 photons TH2F * fhMCPi0NoneNLMPairNoMCMatch; //! E vs NLM when cluster originated in pi0 merging and a both no NLM corresponds to the photons TH2F * fhMCPi0HighNLMPairOverlap; //! E vs NLM when cluster originated in pi0 merging and highest energy local maxima correspond to 2 photons, overlap TH2F * fhMCPi0LowNLMPairOverlap; //! E vs NLM when cluster originated in pi0 merging and a pair of local maxima except highest energy correspond to 2 photons, overlap TH2F * fhMCPi0AnyNLMPairOverlap; //! E vs NLM when cluster originated in pi0 merging and a both highest energy pairs and other pairs correspond to 2 photons, overlap TH2F * fhMCPi0NoneNLMPairOverlap; //! E vs NLM when cluster originated in pi0 merging and a both no NLM corresponds to the photons, overlap // No match between highest energy local maxima and highest energy MC particle TH2F * fhMCPi0HighNLMPairNoMCMatchOverlap; //! E vs NLM when cluster originated in pi0 merging and highest energy local maxima correspond to 2 photons, overlap TH2F * fhMCPi0LowNLMPairNoMCMatchOverlap; //! E vs NLM when cluster originated in pi0 merging and a pair of local maxima except highest energy correspond to 2 photons, overlap TH2F * fhMCPi0AnyNLMPairNoMCMatchOverlap; //! E vs NLM when cluster originated in pi0 merging and a both highest energy pairs and other pairs correspond to 2 photons, overlap TH2F * fhMCPi0NoneNLMPairNoMCMatchOverlap; //! E vs NLM when cluster originated in pi0 merging and a both no NLM corresponds to the photons, overlap TH2F * fhMCPi0DecayPhotonHitHighLM; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit the cell local maxima TH2F * fhMCPi0DecayPhotonAdjHighLM; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima TH2F * fhMCPi0DecayPhotonHitOtherLM; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high TH2F * fhMCPi0DecayPhotonAdjOtherLM; //! E vs NLM when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high TH2F * fhMCPi0DecayPhotonAdjacent; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit adjacen cells, not 2 LM TH2F * fhMCPi0DecayPhotonHitNoLM; //! E vs NLM when cluster originated in pi0 merging and MC photon decay do not hit the cell local maximas TH2F * fhMCPi0DecayPhotonHitHighLMOverlap; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit the cell local maxima, overlap TH2F * fhMCPi0DecayPhotonAdjHighLMOverlap; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima, overlap TH2F * fhMCPi0DecayPhotonHitOtherLMOverlap; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high, overlap TH2F * fhMCPi0DecayPhotonAdjOtherLMOverlap; //! E vs NLM when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high, overlap TH2F * fhMCPi0DecayPhotonAdjacentOverlap; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit adjacen cells, not 2 LM, overlap TH2F * fhMCPi0DecayPhotonHitNoLMOverlap; //! E vs NLM when cluster originated in pi0 merging and MC photon decay do not hit the cell local maximas, overlap TH2F * fhMCPi0DecayPhotonHitHighLMDiffELM1[3]; //! E vs Ephoton-Esplit cluster when cluster originated in pi0 merging and MC photon decay hit the cell local maxima TH2F * fhMCPi0DecayPhotonAdjHighLMDiffELM1[3]; //! E vs Ephoton-Esplit cluster when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima TH2F * fhMCPi0DecayPhotonHitOtherLMDiffELM1[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high TH2F * fhMCPi0DecayPhotonAdjOtherLMDiffELM1[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high TH2F * fhMCPi0DecayPhotonHitHighLMOverlapDiffELM1[3]; //! E vs Ephoton-Esplit cluster when cluster originated in pi0 merging and MC photon decay hit the cell local maxima TH2F * fhMCPi0DecayPhotonAdjHighLMOverlapDiffELM1[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima, overlap TH2F * fhMCPi0DecayPhotonHitOtherLMOverlapDiffELM1[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high, overlap TH2F * fhMCPi0DecayPhotonAdjOtherLMOverlapDiffELM1[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high, overlap TH2F * fhMCPi0DecayPhotonHitHighLMDiffELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the cell local maxima TH2F * fhMCPi0DecayPhotonAdjHighLMDiffELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima TH2F * fhMCPi0DecayPhotonHitOtherLMDiffELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high TH2F * fhMCPi0DecayPhotonAdjOtherLMDiffELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high TH2F * fhMCPi0DecayPhotonHitHighLMOverlapDiffELM2[3]; //! E vs Ephoton-Esplit cluster when cluster originated in pi0 merging and MC photon decay hit the cell local maxima TH2F * fhMCPi0DecayPhotonAdjHighLMOverlapDiffELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima, overlap TH2F * fhMCPi0DecayPhotonHitOtherLMOverlapDiffELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high, overlap TH2F * fhMCPi0DecayPhotonAdjOtherLMOverlapDiffELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high, overlap TH2F * fhMCPi0DecayPhotonHitHighLMDiffELM1vsELM1[3]; //! E vs Ephoton-Esplit cluster when cluster originated in pi0 merging and MC photon decay hit the cell local maxima TH2F * fhMCPi0DecayPhotonAdjHighLMDiffELM1vsELM1[3]; //! E vs Ephoton-Esplit cluster when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima TH2F * fhMCPi0DecayPhotonHitOtherLMDiffELM1vsELM1[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high TH2F * fhMCPi0DecayPhotonAdjOtherLMDiffELM1vsELM1[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high TH2F * fhMCPi0DecayPhotonHitHighLMOverlapDiffELM1vsELM1[3]; //! E vs Ephoton-Esplit cluster when cluster originated in pi0 merging and MC photon decay hit the cell local maxima TH2F * fhMCPi0DecayPhotonAdjHighLMOverlapDiffELM1vsELM1[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima, overlap TH2F * fhMCPi0DecayPhotonHitOtherLMOverlapDiffELM1vsELM1[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high, overlap TH2F * fhMCPi0DecayPhotonAdjOtherLMOverlapDiffELM1vsELM1[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high, overlap TH2F * fhMCPi0DecayPhotonHitHighLMDiffELM2vsELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the cell local maxima TH2F * fhMCPi0DecayPhotonAdjHighLMDiffELM2vsELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima TH2F * fhMCPi0DecayPhotonHitOtherLMDiffELM2vsELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high TH2F * fhMCPi0DecayPhotonAdjOtherLMDiffELM2vsELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high TH2F * fhMCPi0DecayPhotonHitHighLMOverlapDiffELM2vsELM2[3]; //! E vs Ephoton-Esplit cluster when cluster originated in pi0 merging and MC photon decay hit the cell local maxima TH2F * fhMCPi0DecayPhotonAdjHighLMOverlapDiffELM2vsELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima, overlap TH2F * fhMCPi0DecayPhotonHitOtherLMOverlapDiffELM2vsELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high, overlap TH2F * fhMCPi0DecayPhotonAdjOtherLMOverlapDiffELM2vsELM2[3]; //! E vs Ephoton-Esplit when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high, overlap TH2F * fhMCPi0DecayPhotonHitHighLMMass[3]; //! E vs Mass when cluster originated in pi0 merging and MC photon decay hit the cell local maxima TH2F * fhMCPi0DecayPhotonAdjHighLMMass[3]; //! E vs Mass when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima TH2F * fhMCPi0DecayPhotonHitOtherLMMass[3]; //! E vs Mass when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high TH2F * fhMCPi0DecayPhotonAdjOtherLMMass[3]; //! E vs Mass when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high TH2F * fhMCPi0DecayPhotonAdjacentMass[3]; //! E vs Mass when cluster originated in pi0 merging and MC photon decay hit adjacen cells, not 2 LM TH2F * fhMCPi0DecayPhotonHitNoLMMass[3]; //! E vs Mass when cluster originated in pi0 merging and MC photon decay do not hit the cell local maximas TH2F * fhMCPi0DecayPhotonHitHighLMOverlapMass[3]; //! E vs Mass when cluster originated in pi0 merging and MC photon decay hit the cell local maxima, overlap TH2F * fhMCPi0DecayPhotonAdjHighLMOverlapMass[3]; //! E vs Mass when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima, overlap TH2F * fhMCPi0DecayPhotonHitOtherLMOverlapMass[3]; //! E vs Mass when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high, overlap TH2F * fhMCPi0DecayPhotonAdjOtherLMOverlapMass[3]; //! E vs Mass when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high, overlap TH2F * fhMCPi0DecayPhotonAdjacentOverlapMass[3]; //! E vs Mass when cluster originated in pi0 merging and MC photon decay hit adjacen cells, not 2 LM, overlap TH2F * fhMCPi0DecayPhotonHitNoLMOverlapMass[3]; //! E vs Mass when cluster originated in pi0 merging and MC photon decay do not hit the cell local maximas, overlap TH2F * fhMCEOverlapType; //! what particles overlap with pi0, neutral clusters TH2F * fhMCEOverlapTypeMatch; //! what particles overlap with pi0, charged clusters TH2F * fhMassBadDistClose[3]; //! split mass of clusters with second LM close to bad channel TH2F * fhM02BadDistClose[3]; //! m02 of clusters with second LM close to bad channel TH2F * fhMassOnBorder[3]; //! split mass of clusters with second LM on EMCAL border TH2F * fhM02OnBorder[3]; //! m02 of clusters with second LM close to EMCAL border TH2F * fhNLocMaxDiffCut [5][5] [2] ; //! Number of maxima for different values of min Loc Max value and min difference between cells, matched/unmatched with tracks TH2F * fhM02NLocMaxDiffCut[5][5][3][2] ; //! M02 for 3 kinds of number of maxima for different values of min Loc Max value and min difference between cells, matched/unmatched with tracks TH2F * fhMassNLocMaxDiffCut[5][5][3][2] ; //! Mass for 3 kinds of number of maxima for different values of min Loc Max value and min difference between cells, matched/unmatched with tracks TH2F * fhNLocMaxDiffCutPi0 [5][5] [2] ; //! Number of maxima for different values of min Loc Max value and min difference between cells, matched/unmatched with tracks, cluster selected as pi0 TH2F * fhM02NLocMaxDiffCutPi0[5][5][3][2] ; //! M02 for 3 kinds of number of maxima for different values of min Loc Max value and min difference between cells, matched/unmatched with tracks, cluster selected as pi0 TH2F * fhMassNLocMaxDiffCutPi0[5][5][3][2] ; //! M02 for 3 kinds of number of maxima for different values of min Loc Max value and min difference between cells, matched/unmatched with tracks AliAnaInsideClusterInvariantMass( const AliAnaInsideClusterInvariantMass & split) ; // cpy ctor AliAnaInsideClusterInvariantMass & operator = (const AliAnaInsideClusterInvariantMass & split) ; // cpy assignment ClassDef(AliAnaInsideClusterInvariantMass,30) } ; #endif //ALIANAINSIDECLUSTERINVARIANTMASS_H