class TRandom3;
class TRefArray;
class TClonesArray;
+class TF1;
class AliAnalysisTaskJetCluster : public AliAnalysisTaskSE
{
virtual ~AliAnalysisTaskJetCluster();
// Implementation of interface methods
virtual void UserCreateOutputObjects();
- virtual void Init();
- virtual void LocalInit() { Init(); }
+ virtual void LocalInit();
virtual void UserExec(Option_t *option);
virtual void Terminate(Option_t *option);
virtual Bool_t Notify();
-
- virtual void SetUseGlobalSelection(Bool_t b){fUseGlobalSelection = b;}
virtual void SetAODTrackInput(Bool_t b){fUseAODTrackInput = b;}
virtual void SetAODMCInput(Bool_t b){fUseAODMCInput = b;}
+ virtual void SetEventSelection(Bool_t b){fEventSelection = b;}
virtual void SetRecEtaWindow(Float_t f){fRecEtaWindow = f;}
+ virtual void SetTrackEtaWindow(Float_t f){fTrackEtaWindow = f;}
virtual void SetTrackTypeGen(Int_t i){fTrackTypeGen = i;}
virtual void SetTrackTypeRec(Int_t i){fTrackTypeRec = i;}
virtual void SetTrackPtCut(Float_t x){fTrackPtCut = x;}
virtual void SetCentralityCut(Float_t xLo,Float_t xUp){fCentCutLo = xLo; fCentCutUp = xUp;}
- virtual void SetFilterMask(UInt_t i){fFilterMask = i;}
+ virtual void SetFilterMask(UInt_t i,Int_t iType = 0){fFilterMask = i;
+ fFilterType = iType;}
+ virtual void SetFilterMaskBestPt(UInt_t i){fFilterMaskBestPt = i;}
+
+ virtual void SetJetTypes(UInt_t i){fJetTypes = i;}
virtual void SetJetTriggerPtCut(Float_t x){fJetTriggerPtCut = x;}
+ virtual void SetVtxCuts(Float_t z,Float_t r = 1){fVtxZCut = z; fVtxR2Cut = r *r;}
virtual void SetBackgroundBranch(const char* c){fBackgroundBranch = c;}
virtual const char* GetBackgroundBranch(){return fBackgroundBranch.Data();}
virtual void SetNSkipLeadingRan(Int_t x){fNSkipLeadingRan = x;}
+ virtual void SetNSkipLeadingCone(Int_t x){fNSkipLeadingCone = x;}
virtual void SetNRandomCones(Int_t x){fNRandomCones = x;}
virtual void SetJetOutputBranch(const char *c){fNonStdBranch = c;}
virtual const char* GetJetOutputBranch(){return fNonStdBranch.Data();}
virtual void SetJetOutputFile(const char *c){fNonStdFile = c;}
virtual const char* GetJetOutputFile(){return fNonStdFile.Data();}
+ 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="$ALICE_ROOT/OADB/PWGJE/Resolution/PtResol_LHCh_Cent0-10_v1.root") {fUseTrPtResolutionFromOADB = b; fPathTrPtResolution=path;}
+ virtual void SetUseTrEfficiencyFromOADB(Bool_t b=kTRUE, TString path="$ALICE_ROOT/OADB/PWGJE/Efficiency/Efficiency_LHC11a2aj_Cent0_v1.root") {fUseTrEfficiencyFromOADB = b; fPathTrEfficiency=path;}
+ virtual void LoadTrEfficiencyRootFileFromOADB();
+ virtual void LoadTrPtResolutionRootFileFromOADB();
+ virtual void SetChangeEfficiencyFraction(Double_t p) {fChangeEfficiencyFraction = p;}
+ virtual void SetSmearResolution(Bool_t b){fUseTrPtResolutionSmearing = b;}
+ virtual void SetDiceEfficiency(Bool_t b){fUseDiceEfficiency = b;}
+ virtual void SetDiceEfficiencyMinPt(Double_t pt) {fDiceEfficiencyMinPt = pt;}
+ virtual void SetMomentumResolutionHybrid(TProfile *p1, TProfile *p2, TProfile *p3);
+ virtual void SetEfficiencyHybrid(TH1 *h1, TH1 *h2, TH1 *h3);
+ virtual void SetFixedEfficiency(Double_t eff) {fEfficiencyFixed = eff;}
+ virtual void SetRequireT0vtx(Bool_t b = true){fRequireTZEROvtx = b;}
+ virtual void SetRequireV0AC(Bool_t b = true){fRequireVZEROAC = b;}
+
+ Double_t GetMomentumSmearing(Int_t cat, Double_t pt);
+ void FitMomentumResolution();
+
// for Fast Jet
fastjet::JetAlgorithm GetAlgorithm() const {return fAlgorithm;}
enum {kMaxCorrelation = 3};
enum {kMaxRadius = 5};
enum {kMaxCent = 4};
+ enum {kJet = 1<<0,
+ kJetRan = 1<<1,
+ kRC = 1<<2,
+ kRCRan = 1<<3
+ };
private:
TRefArray *fRef; // ! trefarray for track references within the jet
Bool_t fUseAODTrackInput; // take track from input AOD not from ouptu AOD
Bool_t fUseAODMCInput; // take MC from input AOD not from ouptu AOD
- Bool_t fUseGlobalSelection; // Limit the eta of the generated jets
Bool_t fUseBackgroundCalc; // switches on background calculations
+ Bool_t fEventSelection; // use the event selection of this task, otherwise analyse all
+ Bool_t fRequireVZEROAC; // switch to require V0 AC
+ Bool_t fRequireTZEROvtx; // switch to require T0 vtx
UInt_t fFilterMask; // filter bit for slecected tracks
+ UInt_t fFilterMaskBestPt; // filter bit to mark jets with high quality leading tracks
+
+ UInt_t fFilterType; // filter type 0 = all, 1 = ITSTPC, 2 = TPC
+ UInt_t fJetTypes; // 1<<0 regular jets, 1<<1 << randomized event 1<<2 random cones 1<<3 random cones randomiuzed event
Int_t fTrackTypeRec; // type of tracks used for FF
Int_t fTrackTypeGen; // type of tracks used for FF
- Int_t fNSkipLeadingRan; // number of leading tracks to be skipped in the randomized event
+ Int_t fNSkipLeadingRan; // number of leading tracks to be skipped in the randomized event
+ Int_t fNSkipLeadingCone; // number of leading jets to be for the random cones
Int_t fNRandomCones; // number of generated random cones
Float_t fAvgTrials; // Average nimber of trials
Float_t fExternalWeight; // external weight
+ Float_t fTrackEtaWindow; // eta window used for corraltion plots between rec and gen
Float_t fRecEtaWindow; // eta window used for corraltion plots between rec and gen
Float_t fTrackPtCut; // minimum track pt to be accepted
Float_t fJetOutputMinPt; // minimum p_t for jets to be written out
+ Float_t fMaxTrackPtInJet; // maximum track pt within a jet for flagging...
Float_t fJetTriggerPtCut; // minimum jwt pT for AOD to be written
+ Float_t fVtxZCut; // zvtx cut
+ 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
- TString fNonStdFile; // The optional name of the output file the non-std brnach is written to
-
+ TString fNonStdFile; // The optional name of the output file the non-std branch is written to
+
+ //Detector level effects
+ 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
+
+ TH1 *fhEffH1; // Efficiency for Spectra Hybrid Category 1
+ TH1 *fhEffH2; // Efficiency for Spectra Hybrid Category 2
+ TH1 *fhEffH3; // Efficiency for Spectra Hybrid Category 3
+ Bool_t fUseTrPtResolutionSmearing; // Apply momentum smearing on track level
+ Bool_t fUseDiceEfficiency; // Apply efficiency on track level by dicing
+ Double_t fDiceEfficiencyMinPt; // Only do efficiency dicing for tracks above this pt
+ Bool_t fUseTrPtResolutionFromOADB; // Load track pt resolution root file from OADB path
+ Bool_t fUseTrEfficiencyFromOADB; // Load tracking efficiency root file from OADB path
+ TString fPathTrPtResolution; // OADB path to root file
+ TString fPathTrEfficiency; // OADB path to root file
+ Double_t fChangeEfficiencyFraction; // change efficiency by fraction
+ Double_t fEfficiencyFixed; // fixed efficiency for all pT and all types of tracks
+
// Fast jet
- Double_t fRparam;
+ Double_t fRparam; // fastjet distance parameter
fastjet::JetAlgorithm fAlgorithm; //fastjet::kt_algorithm
fastjet::Strategy fStrategy; //= fastjet::Best;
fastjet::RecombinationScheme fRecombScheme; // = fastjet::BIpt_scheme;
- fastjet::AreaType fAreaType;
- Double_t fGhostArea;
- Int_t fActiveAreaRepeats;
- Double_t fGhostEtamax;
-
- TClonesArray *fTCAJetsOut; //! TCA of output jets
- TClonesArray *fTCAJetsOutRan; //! TCA of output jets in randomized event
- TClonesArray *fTCARandomConesOut; //! TCA of output jets in randomized event
+ fastjet::AreaType fAreaType; // fastjet area type
+ Double_t fGhostArea; // fasjet ghost area
+ Int_t fActiveAreaRepeats; // fast jet active area repeats
+ Double_t fGhostEtamax; // fast jet ghost area
+
+ TClonesArray *fTCAJetsOut; //! TCA of output jets
+ TClonesArray *fTCAJetsOutRan; //! TCA of output jets in randomized event
+ TClonesArray *fTCARandomConesOut; //! TCA of output jets in randomized event
TClonesArray *fTCARandomConesOutRan; //! TCA of output jets in randomized event
AliAODJetEventBackground *fAODJetBackgroundOut; //! jet background to be written out
TH2F* fh2TracksLeadingJetPhiPtC[kMaxCent]; //! track correlation with leading Jet
TH2F* fh2TracksLeadingJetPhiPtWC[kMaxCent]; //! track correlation with leading Jet
+ TH3F* fh3CentvsRhoLeadingTrackPt; //! centrality vs background density full event
+ TH3F* fh3CentvsSigmaLeadingTrackPt; //! centrality vs sigma full event
+ TH3F* fh3MultvsRhoLeadingTrackPt; //! multiplicity vs background density full event
+ TH3F* fh3MultvsSigmaLeadingTrackPt; //! 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)
+
+ TH3F* fh3CentvsDeltaRhoLeadingTrackPtQ1; //! centrality vs delta background density vs pt leading track near side
+ TH3F* fh3CentvsDeltaRhoLeadingTrackPtQ2; //! centrality vs delta background density vs pt leading track perpendicular (+0.5*\pi)
+ TH3F* fh3CentvsDeltaRhoLeadingTrackPtQ3; //! centrality vs delta background density vs pt leading track away side
+ TH3F* fh3CentvsDeltaRhoLeadingTrackPtQ4; //! centrality vs delta background density 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
+ TProfile *fp1PtResolution; //! Control profile for pT resolution
+
TList *fHistList; //!leading tracks to be skipped in the randomized event Output list
- ClassDef(AliAnalysisTaskJetCluster, 14)
+ ClassDef(AliAnalysisTaskJetCluster, 22)
};
#endif