// 2.) method Make() and methods called within Make():
virtual void Make(AliFlowEventSimple *anEvent);
// 2a.) common:
+ virtual void CheckPointersUsedInMake();
virtual void FillAverageMultiplicities(Int_t nRP);
virtual void FillCommonControlHistograms(AliFlowEventSimple *anEvent);
virtual void ResetEventByEventQuantities();
virtual void StoreDistributionsOfCorrelations();
// 3.) method Finish() and methods called within Finish():
virtual void Finish();
+ virtual void CheckPointersUsedInFinish();
// 3a.) integrated flow:
virtual void FinalizeCorrelationsIntFlow();
virtual void FinalizeCorrectionTermsForNUAIntFlow();
//virtual void CalculateCorrectionsForNUAForIntQcumulants();
virtual void CalculateQcumulantsCorrectedForNUAIntFlow();
virtual void CalculateIntFlowCorrectedForNUA();
+ virtual void CalculateDetectorEffectsForTrueCorrelations();
//virtual void ApplyCorrectionForNonUniformAcceptanceToCumulantsForIntFlow(Bool_t useParticleWeights, TString eventWeights);
//virtual void PrintQuantifyingCorrectionsForNonUniformAcceptance(Bool_t useParticleWeights, TString eventWeights);
virtual void PrintFinalResultsForIntegratedFlow(TString type);
// 2b.) event weights:
void SetMultiplicityWeight(const char *multiplicityWeight) {*this->fMultiplicityWeight = multiplicityWeight;};
- // 3.) integrated flow:
- // flags:
+ // 3.) Reference flow:
+ // Flags:
void SetIntFlowFlags(TProfile* const intFlowFlags) {this->fIntFlowFlags = intFlowFlags;};
TProfile* GetIntFlowFlags() const {return this->fIntFlowFlags;};
void SetApplyCorrectionForNUA(Bool_t const applyCorrectionForNUA) {this->fApplyCorrectionForNUA = applyCorrectionForNUA;};
Bool_t GetApplyCorrectionForNUA() const {return this->fApplyCorrectionForNUA;};
- // integrated flow profiles:
+ void SetApplyCorrectionForNUAVsM(Bool_t const applyCorrectionForNUAVsM) {this->fApplyCorrectionForNUAVsM = applyCorrectionForNUAVsM;};
+ Bool_t GetApplyCorrectionForNUAVsM() const {return this->fApplyCorrectionForNUAVsM;};
+ void SetnBinsMult(Int_t const nbm) {this->fnBinsMult = nbm;};
+ Int_t GetnBinsMult() const {return this->fnBinsMult;};
+ void SetMinMult(Double_t const minm) {this->fMinMult = minm;};
+ Double_t GetMinMult() const {return this->fMinMult;};
+ void SetMaxMult(Double_t const maxm) {this->fMaxMult = maxm;};
+ Double_t GetMaxMult() const {return this->fMaxMult;};
+ void SetPropagateErrorFromCorrelations(Bool_t const pefc) {this->fPropagateErrorFromCorrelations = pefc;};
+ Bool_t GetPropagateErrorFromCorrelations() const {return this->fPropagateErrorFromCorrelations;};
+ void SetCalculateCumulantsVsM(Bool_t const ccvm) {this->fCalculateCumulantsVsM = ccvm;};
+ Bool_t GetCalculateCumulantsVsM() const {return this->fCalculateCumulantsVsM;};
+ void SetMinimumBiasReferenceFlow(Bool_t const mmrf) {this->fMinimumBiasReferenceFlow = mmrf;};
+ Bool_t GetMinimumBiasReferenceFlow() const {return this->fMinimumBiasReferenceFlow;};
+ // Reference flow profiles:
void SetAvMultiplicity(TProfile* const avMultiplicity) {this->fAvMultiplicity = avMultiplicity;};
TProfile* GetAvMultiplicity() const {return this->fAvMultiplicity;};
void SetIntFlowCorrelationsPro(TProfile* const intFlowCorrelationsPro) {this->fIntFlowCorrelationsPro = intFlowCorrelationsPro;};
void SetIntFlowProductOfCorrectionTermsForNUAPro(TProfile* const ifpoctfNUA) {this->fIntFlowProductOfCorrectionTermsForNUAPro = ifpoctfNUA;};
TProfile* GetIntFlowProductOfCorrectionTermsForNUAPro() const {return this->fIntFlowProductOfCorrectionTermsForNUAPro;};
void SetIntFlowCorrectionTermsForNUAPro(TProfile* const ifctfnp, Int_t const sc) {this->fIntFlowCorrectionTermsForNUAPro[sc] = ifctfnp;};
- TProfile* GetIntFlowCorrectionTermsForNUAPro(Int_t sc) const {return this->fIntFlowCorrectionTermsForNUAPro[sc];};
+ TProfile* GetIntFlowCorrectionTermsForNUAPro(Int_t sc) const {return this->fIntFlowCorrectionTermsForNUAPro[sc];};
+ void SetIntFlowCorrectionTermsForNUAVsMPro(TProfile* const ifctfnpvm, Int_t const sc, Int_t const ci) {this->fIntFlowCorrectionTermsForNUAVsMPro[sc][ci] = ifctfnpvm;};
+ TProfile* GetIntFlowCorrectionTermsForNUAVsMPro(Int_t sc, Int_t ci) const {return this->fIntFlowCorrectionTermsForNUAVsMPro[sc][ci];};
// integrated flow histograms holding all results:
void SetIntFlowCorrelationsHist(TH1D* const intFlowCorrelationsHist) {this->fIntFlowCorrelationsHist = intFlowCorrelationsHist;};
TH1D* GetIntFlowCorrelationsHist() const {return this->fIntFlowCorrelationsHist;};
void SetIntFlowQcumulants(TH1D* const intFlowQcumulants) {this->fIntFlowQcumulants = intFlowQcumulants;};
TH1D* GetIntFlowQcumulants() const {return this->fIntFlowQcumulants;};
void SetIntFlowQcumulantsVsM(TH1D* const intFlowQcumulantsVsM, Int_t co) {this->fIntFlowQcumulantsVsM[co] = intFlowQcumulantsVsM;};
- TH1D* GetIntFlowQcumulantsVsM(Int_t co) const {return this->fIntFlowQcumulantsVsM[co];};
+ TH1D* GetIntFlowQcumulantsVsM(Int_t co) const {return this->fIntFlowQcumulantsVsM[co];};
+ void SetIntFlowQcumulantsRebinnedInM(TH1D* const ifqcrim) {this->fIntFlowQcumulantsRebinnedInM = ifqcrim;};
+ TH1D* GetIntFlowQcumulantsRebinnedInM() const {return this->fIntFlowQcumulantsRebinnedInM;};
void SetIntFlow(TH1D* const intFlow) {this->fIntFlow = intFlow;};
TH1D* GetIntFlow() const {return this->fIntFlow;};
void SetIntFlowVsM(TH1D* const intFlowVsM, Int_t co) {this->fIntFlowVsM[co] = intFlowVsM;};
- TH1D* GetIntFlowVsM(Int_t co) const {return this->fIntFlowVsM[co];};
+ TH1D* GetIntFlowVsM(Int_t co) const {return this->fIntFlowVsM[co];};
+ void SetIntFlowRebinnedInM(TH1D* const ifrim) {this->fIntFlowRebinnedInM = ifrim;};
+ TH1D* GetIntFlowRebinnedInM() const {return this->fIntFlowRebinnedInM;};
+ void SetIntFlowDetectorBias(TH1D* const ifdb) {this->fIntFlowDetectorBias = ifdb;};
+ TH1D* GetIntFlowDetectorBias() const {return this->fIntFlowDetectorBias;};
+ void SetIntFlowDetectorBiasVsM(TH1D* const ifdbvm, Int_t ci) {this->fIntFlowDetectorBiasVsM[ci] = ifdbvm;};
+ TH1D* GetIntFlowDetectorBiasVsM(Int_t ci) const {return this->fIntFlowDetectorBiasVsM[ci];};
// 4.) differential flow:
// flags:
void SetDiffFlowFlags(TProfile* const diffFlowFlags) {this->fDiffFlowFlags = diffFlowFlags;};
Double_t fEtaBinWidth; // bin width for eta histograms
Int_t fHarmonic; // harmonic
TString *fAnalysisLabel; // analysis label (all histograms and output file will have this label)
- Bool_t fPrintFinalResults[3]; // print on the screen the final results (0=NONAME, 1=RP, 2=POI)
+ Bool_t fPrintFinalResults[4]; // print on the screen the final results (0=RF, 1=RP, 2=POI, 3=RF rebinned in M)
// 2a.) particle weights:
TList *fWeightsList; // list to hold all histograms with particle weights: fUseParticleWeights, fPhiWeights, fPtWeights and fEtaWeights
TList *fIntFlowResults; // list to hold all histograms with final results relevant for integrated flow
// 3b.) flags:
TProfile *fIntFlowFlags; // profile to hold all flags for integrated flow
- Bool_t fApplyCorrectionForNUA; // apply correction for non-uniform acceptance
+ Bool_t fApplyCorrectionForNUA; // apply correction for non-uniform acceptance
+ Bool_t fApplyCorrectionForNUAVsM; // apply correction for non-uniform acceptance versus M
+ Int_t fnBinsMult; // number of multiplicity bins for flow analysis versus multiplicity
+ Double_t fMinMult; // minimal multiplicity for flow analysis versus multiplicity
+ Double_t fMaxMult; // maximal multiplicity for flow analysis versus multiplicity
+ Bool_t fPropagateErrorFromCorrelations; // propagate error for v_n from correlations (kTRUE) or from cumulants (kFALSE) (used only for debugging/cross-checking)
+ Bool_t fCalculateCumulantsVsM; // calculate cumulants versus multiplicity
+ Bool_t fMinimumBiasReferenceFlow; // store as reference flow in AliFlowCommonHistResults the minimum bias result (kFALSE by default)
// 3c.) event-by-event quantities:
TMatrixD *fReQ; // fReQ[m][k] = sum_{i=1}^{M} w_{i}^{k} cos(m*phi_{i})
TMatrixD *fImQ; // fImQ[m][k] = sum_{i=1}^{M} w_{i}^{k} sin(m*phi_{i})
TH1D *fIntFlowEventWeightsForCorrelationsEBE; // 1st bin: eW_<2>, 2nd bin: eW_<4>, 3rd bin: eW_<6>, 4th bin: eW_<8>
TH1D *fIntFlowCorrelationsAllEBE; // to be improved (add comment)
TH1D *fIntFlowCorrectionTermsForNUAEBE[2]; // [0=sin terms,1=cos terms], NUA = non-uniform acceptance
- TH1D *fIntFlowEventWeightForCorrectionTermsForNUAEBE[2]; // [0=sin terms,1=cos terms], NUA = non-uniform acceptance
+ TH1D *fIntFlowEventWeightForCorrectionTermsForNUAEBE[2]; // [0=sin terms,1=cos terms], NUA = non-uniform acceptance
// 3d.) profiles:
TProfile *fAvMultiplicity; // profile to hold average multiplicities and number of events for events with nRP>=0, nRP>=1, ... , and nRP>=8
TProfile *fIntFlowCorrelationsPro; // average correlations <<2>>, <<4>>, <<6>> and <<8>> (with wrong errors!)
// [0=<<2><4>>,1=<<2><6>>,2=<<2><8>>,3=<<4><6>>,4=<<4><8>>,5=<<6><8>>]
TProfile *fIntFlowProductOfCorrectionTermsForNUAPro; // average product of correction terms for NUA
TProfile *fIntFlowCorrectionTermsForNUAPro[2]; // average correction terms for non-uniform acceptance (with wrong errors!) [0=sin terms,1=cos terms]
+ TProfile *fIntFlowCorrectionTermsForNUAVsMPro[2][4]; // average correction terms for non-uniform acceptance (with wrong errors!) [0=sin terms,1=cos terms][correction term index] vs multiplicity
// 3e.) histograms with final results:
TH1D *fIntFlowCorrelationsHist; // final results for average correlations <<2>>, <<4>>, <<6>> and <<8>> (with correct errors!)
TH1D *fIntFlowCorrelationsVsMHist[4]; // average correlations <<2>>, <<4>>, <<6>> and <<8>> versus multiplicity (error is correct here!)
TH1D *fIntFlowSumOfProductOfEventWeightsNUA; // sum of products of event weights for NUA terms
TH1D *fIntFlowQcumulants; // final results for integrated Q-cumulants QC{2}, QC{4}, QC{6} and QC{8}
TH1D *fIntFlowQcumulantsVsM[4]; // final results for integrated Q-cumulants QC{2}, QC{4}, QC{6} and QC{8} versus multiplicity
+ TH1D *fIntFlowQcumulantsRebinnedInM; // final results for reference Q-cumulants QC{2}, QC{4}, QC{6} and QC{8} rebinned in M
TH1D *fIntFlow; // final results for integrated flow estimates v_n{2,QC}, v_n{4,QC}, v_n{6,QC} and v_n{8,QC}
- TH1D *fIntFlowVsM[4]; // final results for integrated flow estimates v_n{2,QC}, v_n{4,QC}, v_n{6,QC} and v_n{8,QC} versus multiplicity
+ TH1D *fIntFlowVsM[4]; // final results for integrated flow estimates v_n{2,QC}, v_n{4,QC}, v_n{6,QC} and v_n{8,QC} versus multiplicity
+ TH1D *fIntFlowRebinnedInM; // final results for ref. flow estimates v_n{2,QC}, v_n{4,QC}, v_n{6,QC} and v_n{8,QC} rebinned in M
+ TH1D *fIntFlowDetectorBias; // bias coming from detector inefficiencies to <<2>>, <<4>>, <<6>> and <<8>> (corrected/measured)
+ TH1D *fIntFlowDetectorBiasVsM[4]; // bias coming from detector inefficiencies to <<2>>, <<4>>, <<6>> and <<8>> vs M (corrected/measured)
// 4.) differential flow
// 4a.) lists:
TList *fDiffFlowList; // list to hold list with all histograms (fDiffFlowResults) and list with profiles (fDiffFlowProfiles) relevant for differential flow