virtual void SetMaxTrackPtInJet(Float_t x){fMaxTrackPtInJet = x;}
virtual void SetJetOutputMinPt(Float_t x){fJetOutputMinPt = x;}
virtual void SetBackgroundCalc(Bool_t b){fUseBackgroundCalc = b;}
+ virtual void SetStoreRhoLeadingTrackCorr(Bool_t b) {fStoreRhoLeadingTrackCorr=b;}
//Setters for detector level effects
virtual void SetUseTrResolutionFromOADB(Bool_t b=kTRUE, TString path="$ALICE_ROOT/OADB/PWGJE/Resolution/PtResol_LHCh_Cent0-10_v1.root") {fUseTrPtResolutionFromOADB = b; fPathTrPtResolution=path;}
Float_t fVtxR2Cut; // R vtx cut (squared)
Float_t fCentCutUp; // upper limit on centrality
Float_t fCentCutLo; // lower limit on centrality
+
+ Bool_t fStoreRhoLeadingTrackCorr; //store histos with rho correlation to leading track in event
+
// output configurartion
TString fNonStdBranch; // the name of the non-std branch name, if empty no branch is filled
TString fBackgroundBranch; // name of the branch used for background subtraction
TProfile *fMomResH1; // Momentum resolution from TrackQA Hybrid Category 1
TProfile *fMomResH2; // Momentum resolution from TrackQA Hybrid Category 2
TProfile *fMomResH3; // Momentum resolution from TrackQA Hybrid Category 3
- TF1 *fMomResH1Fit; //fit
- TF1 *fMomResH2Fit; //fit
- TF1 *fMomResH3Fit; //fit
+ TF1 *fMomResH1Fit; //fit
+ TF1 *fMomResH2Fit; //fit
+ TF1 *fMomResH3Fit; //fit
TH1 *fhEffH1; // Efficiency for Spectra Hybrid Category 1
TH1 *fhEffH2; // Efficiency for Spectra Hybrid Category 2
TH2F* fh2TracksLeadingJetPhiPtC[kMaxCent]; //! track correlation with leading Jet
TH2F* fh2TracksLeadingJetPhiPtWC[kMaxCent]; //! track correlation with leading Jet
+ TH2F* fh2CentvsRho; //! centrality vs background density full event
+ TH2F* fh2CentvsSigma; //! centrality vs sigma full event
+ TH2F* fh2MultvsRho; //! multiplicity vs background density full event
+ TH2F* fh2MultvsSigma; //! multiplicity vs sigma full event
+
+ TH3F* fh3CentvsRhoLeadingTrackPtQ1; //! centrality vs background density vs pt leading track near side
+ TH3F* fh3CentvsRhoLeadingTrackPtQ2; //! centrality vs background density vs pt leading track perpendicular (+0.5*\pi)
+ TH3F* fh3CentvsRhoLeadingTrackPtQ3; //! centrality vs background density vs pt leading track away side
+ TH3F* fh3CentvsRhoLeadingTrackPtQ4; //! centrality vs background density vs pt leading track perpendicular (-0.5*\pi)
+
+ TH3F* fh3CentvsSigmaLeadingTrackPtQ1; //! centrality vs sigma vs pt leading track near side
+ TH3F* fh3CentvsSigmaLeadingTrackPtQ2; //! centrality vs sigma vs pt leading track perpendicular (+0.5*\pi)
+ TH3F* fh3CentvsSigmaLeadingTrackPtQ3; //! centrality vs sigma vs pt leading track away side
+ TH3F* fh3CentvsSigmaLeadingTrackPtQ4; //! centrality vs sigma vs pt leading track perpendicular (-0.5*\pi)
+
+ TH3F* fh3MultvsRhoLeadingTrackPtQ1; //! multiplicity vs background density vs pt leading track near side
+ TH3F* fh3MultvsRhoLeadingTrackPtQ2; //! multiplicity vs background density vs pt leading track perpendicular (+0.5*\pi)
+ TH3F* fh3MultvsRhoLeadingTrackPtQ3; //! multiplicity vs background density vs pt leading track away side
+ TH3F* fh3MultvsRhoLeadingTrackPtQ4; //! multiplicity vs background density vs pt leading track perpendicular (-0.5*\pi)
+
+ TH3F* fh3MultvsSigmaLeadingTrackPtQ1; //! multiplicity vs sigma vs pt leading track near side
+ TH3F* fh3MultvsSigmaLeadingTrackPtQ2; //! multiplicity vs sigma vs pt leading track perpendicular (+0.5*\pi)
+ TH3F* fh3MultvsSigmaLeadingTrackPtQ3; //! multiplicity vs sigma vs pt leading track away side
+ TH3F* fh3MultvsSigmaLeadingTrackPtQ4; //! multiplicity vs sigma vs pt leading track perpendicular (-0.5*\pi)
+
//Histos for detector level effects from toy model
TH2F *fh2PtGenPtSmeared; //! Control histo smeared momentum
TProfile *fp1Efficiency; //! Control profile efficiency