private:
- Int_t SetupRun(const AliESDEvent* const esd);
+ Int_t SetupRun(const AliVEvent* const esd);
Bool_t IsOutlierV0MSPD(Float_t spd, Float_t v0, Int_t cent) const;
Bool_t IsOutlierV0MTPC(Int_t tracks, Float_t v0, Int_t cent) const;
Bool_t IsOutlierV0MZDC(Float_t zdc, Float_t v0) const;
Float_t fV0MZDCEcalOutlierPar1; // outliers parameter
AliESDtrackCuts* fTrackCuts; //! optional track cuts
+ AliESDtrackCuts* fEsdTrackCuts; //! optional track cuts
+ AliESDtrackCuts* fEsdTrackCutsExtra1; //! optional track cuts
+ AliESDtrackCuts* fEsdTrackCutsExtra2; //! optional track cuts
Float_t fZVCut; //! z-vertex cut (in cm)
Float_t fOutliersCut; //! outliers cut (in n-sigma)
Float_t fCentV0M; // percentile centrality from V0
Float_t fCentV0A; // percentile centrality from V0A
+ Float_t fCentV0A123; // percentile centrality from V0A-123
Float_t fCentV0C; // percentile centrality from V0C
+ Float_t fCentV0MEq; // percentile centrality from V0 equalized channel
+ Float_t fCentV0AEq; // percentile centrality from V0A equalized channel
+ Float_t fCentV0CEq; // percentile centrality from V0C equalized channel
Float_t fCentFMD; // percentile centrality from FMD
Float_t fCentTRK; // percentile centrality from tracks
Float_t fCentTKL; // percentile centrality from tracklets
Float_t fCentCL0; // percentile centrality from clusters in layer 0
Float_t fCentCL1; // percentile centrality from clusters in layer 1
Float_t fCentCND; // percentile centrality from candle
- Float_t fCentNPA; // percentile centrality from Npart (MC)
Float_t fCentZNA; // percentile centrality from ZNA
+ Float_t fCentZNC; // percentile centrality from ZNC
+ Float_t fCentZPA; // percentile centrality from ZPA
+ Float_t fCentZPC; // percentile centrality from ZPC
+ Float_t fCentNPA; // percentile centrality from Npart (MC)
Float_t fCentV0MvsFMD; // percentile centrality from V0 vs FMD
Float_t fCentTKLvsV0M; // percentile centrality from tracklets vs V0
Float_t fCentZEMvsZDC; // percentile centrality from ZEM vs ZDC
+ Float_t fCentV0Mtrue; // percentile centrality from true (sim) V0A+V0C
+ Float_t fCentV0Atrue; // percentile centrality from true (sim) V0A
+ Float_t fCentV0Ctrue; // percentile centrality from true (sim) V0C
+ Float_t fCentV0MEqtrue; // percentile centrality from true (sim) V0A+V0C equalized channel
+ Float_t fCentV0AEqtrue; // percentile centrality from true (sim) V0A equalized channel
+ Float_t fCentV0CEqtrue; // percentile centrality from true (sim) V0C equalized channel
+ Float_t fCentFMDtrue; // percentile centrality from true (sim) FMD
+ Float_t fCentTRKtrue; // percentile centrality from true (sim) tracks
+ Float_t fCentTKLtrue; // percentile centrality from true (sim) tracklets
+ Float_t fCentCL0true; // percentile centrality from true (sim) Clusters in layer 0
+ Float_t fCentCL1true; // percentile centrality from true (sim) Clusters in layer 1
+ Float_t fCentCNDtrue; // percentile centrality from true (sim) tracks (candle condition)
+ Float_t fCentZNAtrue; // percentile centrality from true (sim) ZNA
+ Float_t fCentZNCtrue; // percentile centrality from true (sim) ZNC
+ Float_t fCentZPAtrue; // percentile centrality from true (sim) ZPA
+ Float_t fCentZPCtrue; // percentile centrality from true (sim) ZPC
+
+
TH1F *fHtempV0M; // histogram with centrality vs multiplicity using V0
TH1F *fHtempV0A; // histogram with centrality vs multiplicity using V0A
+ TH1F *fHtempV0A123; // histogram with centrality vs multiplicity using V0A-123
TH1F *fHtempV0C; // histogram with centrality vs multiplicity using V0C
+ TH1F *fHtempV0MEq; // histogram with centrality vs multiplicity using V0 equalized channel
+ TH1F *fHtempV0AEq; // histogram with centrality vs multiplicity using V0A equalized channel
+ TH1F *fHtempV0CEq; // histogram with centrality vs multiplicity using V0C equalized channel
TH1F *fHtempFMD; // histogram with centrality vs multiplicity using FMD
TH1F *fHtempTRK; // histogram with centrality vs multiplicity using tracks
TH1F *fHtempTKL; // histogram with centrality vs multiplicity using tracklets
TH1F *fHtempCL0; // histogram with centrality vs multiplicity using clusters in layer 0
TH1F *fHtempCL1; // histogram with centrality vs multiplicity using clusters in layer 1
TH1F *fHtempCND; // histogram with centrality vs multiplicity using candle
- TH1F *fHtempNPA; // histogram with centrality vs multiplicity using Npart
TH1F *fHtempZNA; // histogram with centrality vs multiplicity using ZNA
+ TH1F *fHtempZNC; // histogram with centrality vs multiplicity using ZNC
+ TH1F *fHtempZPA; // histogram with centrality vs multiplicity using ZPA
+ TH1F *fHtempZPC; // histogram with centrality vs multiplicity using ZPC
TH1F *fHtempV0MvsFMD; // histogram with centrality vs multiplicity using V0 vs FMD
TH1F *fHtempTKLvsV0M; // histogram with centrality vs multiplicity using tracklets vs V0
TH2F *fHtempZEMvsZDC; // histogram with centrality vs multiplicity using ZEM vs ZDC
+ TH1F *fHtempNPA; // histogram with centrality vs multiplicity using Npart
+
+ TH1F *fHtempV0Mtrue; // histogram with centrality true (sim) vs multiplicity using V0
+ TH1F *fHtempV0Atrue; // histogram with centrality true (sim) vs multiplicity using V0A
+ TH1F *fHtempV0Ctrue; // histogram with centrality true (sim) vs multiplicity using V0C
+ TH1F *fHtempV0MEqtrue; // histogram with centrality true (sim) vs multiplicity using V0 equalized channel
+ TH1F *fHtempV0AEqtrue; // histogram with centrality true (sim) vs multiplicity using V0A equalized channel
+ TH1F *fHtempV0CEqtrue; // histogram with centrality true (sim) vs multiplicity using V0C equalized channel
+ TH1F *fHtempFMDtrue; // histogram with centrality true (sim) vs multiplicity using FMD
+ TH1F *fHtempTRKtrue; // histogram with centrality true (sim) vs multiplicity using tracks
+ TH1F *fHtempTKLtrue; // histogram with centrality true (sim) vs multiplicity using tracklets
+ TH1F *fHtempCL0true; // histogram with centrality true (sim) vs multiplicity using clusters in layer 0
+ TH1F *fHtempCL1true; // histogram with centrality true (sim) vs multiplicity using clusters in layer 1
+ TH1F *fHtempCNDtrue; // histogram with centrality true (sim) vs multiplicity using candle
+ TH1F *fHtempZNAtrue; // histogram with centrality true (sim) vs multiplicity using ZNA
+ TH1F *fHtempZNCtrue; // histogram with centrality true (sim) vs multiplicity using ZNC
+ TH1F *fHtempZPAtrue; // histogram with centrality true (sim) vs multiplicity using ZPA
+ TH1F *fHtempZPCtrue; // histogram with centrality true (sim) vs multiplicity using ZPC
TList *fOutputList; // output list
+
TH1F *fHOutCentV0M ; //control histogram for centrality
TH1F *fHOutCentV0A ; //control histogram for centrality
+ TH1F *fHOutCentV0A123 ; //control histogram for centrality
TH1F *fHOutCentV0C ; //control histogram for centrality
+ TH1F *fHOutCentV0MEq ; //control histogram for centrality
+ TH1F *fHOutCentV0AEq ; //control histogram for centrality
+ TH1F *fHOutCentV0CEq ; //control histogram for centrality
TH1F *fHOutCentV0MCVHN; //control histogram for centrality
TH1F *fHOutCentV0MCVLN; //control histogram for centrality
TH1F *fHOutCentV0MCVHNinMB; //control histogram for centrality
TH1F *fHOutCentCND ; //control histogram for centrality
TH1F *fHOutCentNPA ; //control histogram for centrality
TH1F *fHOutCentZNA ; //control histogram for centrality
+ TH1F *fHOutCentZNC ; //control histogram for centrality
+ TH1F *fHOutCentZPA ; //control histogram for centrality
+ TH1F *fHOutCentZPC ; //control histogram for centrality
TH1F *fHOutCentV0MvsFMD; //control histogram for centrality
TH1F *fHOutCentTKLvsV0M; //control histogram for centrality
TH1F *fHOutCentZEMvsZDC; //control histogram for centrality
TH2F *fHOutCentZNAvsCentTRK; //control histogram for centrality
TH2F *fHOutCentZNAvsCentCND; //control histogram for centrality
TH2F *fHOutCentZNAvsCentCL1; //control histogram for centrality
+ TH2F *fHOutCentZNAvsCentZPA; //control histogram for centrality
TH2F *fHOutMultV0AC; //control histogram for multiplicity
TH1F *fHOutMultV0M ; //control histogram for multiplicity
TH1F *fHOutMultV0A ; //control histogram for multiplicity
+ TH1F *fHOutMultV0A123 ; //control histogram for multiplicity
TH1F *fHOutMultV0C ; //control histogram for multiplicity
+ TH1F *fHOutMultV0MEq ; //control histogram for multiplicity
+ TH1F *fHOutMultV0AEq ; //control histogram for multiplicity
+ TH1F *fHOutMultV0CEq ; //control histogram for multiplicity
TH1F *fHOutMultV0Mnc ; //control histogram for multiplicity
TH1F *fHOutMultV0Anc ; //control histogram for multiplicity
TH1F *fHOutMultV0Cnc ; //control histogram for multiplicity
TH1F *fHOutMultCND ; //control histogram for multiplicity
TH1F *fHOutMultNPA ; //control histogram for multiplicity
TH1F *fHOutMultZNA ; //control histogram for multiplicity
+ TH1F *fHOutMultZNC ; //control histogram for multiplicity
+ TH1F *fHOutMultZPA ; //control histogram for multiplicity
+ TH1F *fHOutMultZPC ; //control histogram for multiplicity
TH2F *fHOutMultV0MvsZDN; //control histogram for multiplicity
TH2F *fHOutMultZEMvsZDN; //control histogram for multiplicity
TH2F *fHOutMultV0OvsCL1; //control histogram for multiplicity
TH2F *fHOutMultV0OvsTRK; //control histogram for multiplicity
TH2F *fHOutMultCL1vsTKL; //control histogram for multiplicity
+ TH2F *fHOutMultZNAvsZPA; //control histogram for multiplicity
TH1F *fHOutCentV0Mqual1 ; //control histogram for centrality quality 1
TH1F *fHOutCentTRKqual1 ; //control histogram for centrality quality 1
TH1F *fHOutVertex ; //control histogram for vertex SPD
TH1F *fHOutVertexT0 ; //control histogram for vertex T0
- ClassDef(AliCentralitySelectionTask, 23);
+ ClassDef(AliCentralitySelectionTask, 29);
};
#endif