#include <AliVCluster.h>
#include <TClonesArray.h>
#include <TMath.h>
+#include <TArrayD.h>
#include <TRandom3.h>
+#include <AliJetContainer.h>
+#include <AliParticleContainer.h>
class TF1;
class THF1;
class THF2;
class TProfile;
+class AliLocalRhoParameter;
-class AliAnalysisTaskRhoVnModulation : public AliAnalysisTaskEmcalJet
-{
+class AliAnalysisTaskRhoVnModulation : public AliAnalysisTaskEmcalJet {
public:
// enumerators
enum fitModulationType { kNoFit, kV2, kV3, kCombined, kFourierSeries, kIntegratedFlow, kQC2, kQC4 }; // fit type
+ enum fitGoodnessTest { kChi2ROOT, kChi2Poisson, kKolmogorov, kKolmogorovTOY, kLinearFit };
+ enum collisionType { kPbPb, kPythia }; // collision type
+ enum qcRecovery { kFixedRho, kNegativeVn, kTryFit }; // how to deal with negative cn value for qcn value
enum runModeType { kLocal, kGrid }; // run mode type
enum dataType { kESD, kAOD, kESDMC, kAODMC }; // data type
- enum detectorType { kTPC, kVZEROA, kVZEROC}; // detector that was used
+ enum detectorType { kTPC, kVZEROA, kVZEROC, kVZEROComb}; // detector that was used
// constructors, destructor
AliAnalysisTaskRhoVnModulation();
AliAnalysisTaskRhoVnModulation(const char *name, runModeType type);
virtual ~AliAnalysisTaskRhoVnModulation();
-
// setting up the task and technical aspects
+ void ExecOnce();
Bool_t InitializeAnalysis();
virtual void UserCreateOutputObjects();
virtual Bool_t Run();
return -999; }
// note that the cdf of the chisquare distribution is the normalized lower incomplete gamma function
/* inline */ Double_t ChiSquareCDF(Int_t ndf, Double_t x) const { return TMath::Gamma(ndf/2., x/2.); }
- /* inline */ Double_t RhoVal() const { return (fRho) ? fRho->GetVal(): -999.;}
- /* inline */ Double_t RhoVal(Double_t phi, Double_t r, Double_t n) const {
- if(!fFitModulation) return RhoVal(); // coverity
- switch (fFitModulationType) {
- case kNoFit : return RhoVal();
- default : {
- Double_t denom(2*r*fFitModulation->GetParameter(0));
- return (denom <= 0.) ? RhoVal() : n*(fFitModulation->Integral(phi-r, phi+r)/denom);
- }
+ /* inline */ Double_t ChiSquare(TH1& histo, TF1* func) const {
+ // evaluate the chi2 using a poissonian error estimate on bins
+ Double_t chi2(0.);
+ for(Int_t i(0); i < histo.GetXaxis()->GetNbins(); i++) {
+ if(histo.GetBinContent(i+1) <= 0.) continue;
+ chi2 += TMath::Power((histo.GetBinContent(i+1)-func->Eval(histo.GetXaxis()->GetBinCenter(1+i))), 2)/histo.GetBinContent(i+1);
}
+ return chi2;
+ }
+ /* inline*/ Double_t KolmogorovTest(TH1F& histo, TF1* func) const {
+ // return the probability from a Kolmogorov test
+ TH1F test(histo); // stack copy of test statistic
+ for(Int_t i(0); i < test.GetXaxis()->GetNbins(); i++) test.SetBinContent(i+1, func->Eval(test.GetXaxis()->GetBinCenter(1+i)));
+ if(fFitGoodnessTest == kKolmogorovTOY) return histo.TH1::KolmogorovTest((&test), "X");
+ return histo.TH1::KolmogorovTest((&test));
}
+
// setters - analysis setup
void SetDebugMode(Int_t d) {fDebug = d;}
+ void SetRunToyMC(Bool_t t) {fRunToyMC = t; }
+ void SetAttachToEvent(Bool_t b) {fAttachToEvent = b;}
+ void SetSemiCentralInclusive(Bool_t b) {fSemiCentralInclusive = b;}
+ void SetFillHistograms(Bool_t b) {fFillHistograms = b;}
void SetFillQAHistograms(Bool_t qa) {fFillQAHistograms = qa;}
- void SetCentralityClasses(TArrayI* c) {fCentralityClasses = c;}
+ void SetReduceBinsXYByFactor(Float_t x, Float_t y) {fReduceBinsXByFactor = x;
+ fReduceBinsYByFactor = y;}
+ void SetNoEventWeightsForQC(Bool_t e) {fNoEventWeightsForQC = e;}
+ void SetCentralityClasses(TArrayD* c) {fCentralityClasses = c;}
+ void SetPtBinsHybrids(TArrayD* p) {fPtBinsHybrids = p;}
+ void SetPtBinsJets(TArrayD* p) {fPtBinsJets = p;}
+ void SetExpectedRuns(TArrayI* r) {fExpectedRuns = r;}
+ void SetExpectedSemiGoodRuns(TArrayI* r) {fExpectedSemiGoodRuns = r;}
void SetIntegratedFlow(TH1F* i, TH1F* j) {fUserSuppliedV2 = i;
fUserSuppliedV3 = j; }
void SetOnTheFlyResCorrection(TH1F* r2, TH1F* r3) {fUserSuppliedR2 = r2;
void SetNameJetClones(const char* name) {fNameJetClones = name; }
void SetNamePicoTrackClones(const char* name) {fNamePicoTrackClones = name; }
void SetNameRho(const char* name) {fNameRho = name; }
+ void SetNameRhoSmall(TString name) {fNameSmallRho = name; }
+ void SetUseScaledRho(Bool_t s) {fUseScaledRho = s; }
void SetRandomSeed(TRandom3* r) {if (fRandom) delete fRandom; fRandom = r; }
- void SetModulationFit(TF1* fit) {if (fFitModulation) delete fFitModulation;
- fFitModulation = fit; }
+ void SetModulationFit(TF1* fit);
+ void SetUseControlFit(Bool_t c);
void SetModulationFitMinMaxP(Float_t m, Float_t n) {fMinPvalue = m; fMaxPvalue = n; }
void SetModulationFitType(fitModulationType type) {fFitModulationType = type; }
+ void SetGoodnessTest(fitGoodnessTest test) {fFitGoodnessTest = test; }
+ void SetQCnRecoveryType(qcRecovery type) {fQCRecovery = type; }
void SetModulationFitOptions(TString opt) {fFitModulationOptions = opt; }
void SetReferenceDetector(detectorType type) {fDetectorType = type; }
- void SetUsePtWeight(Bool_t w) {fUsePtWeight = w; }
+ void SetCollisionType(collisionType type) {fCollisionType = type; }
+ void SetUsePtWeight(Bool_t w) {
+ fUsePtWeight = w;
+ if(!fUsePtWeight) fUsePtWeightErrorPropagation = kFALSE; }
+ void SetUsePtWeightErrorPropagation(Bool_t w) {fUsePtWeightErrorPropagation = w; }
void SetRunModeType(runModeType type) {fRunModeType = type; }
void SetAbsVertexZ(Float_t v) {fAbsVertexZ = v; }
void SetMinDistanceRctoLJ(Float_t m) {fMinDisanceRCtoLJ = m; }
void SetRandomConeRadius(Float_t r) {fRandomConeRadius = r; }
+ void SetMaxNoRandomCones(Int_t m) {fMaxCones = m; }
void SetMinLeadingHadronPt(Double_t m) {fMinLeadingHadronPt = m; }
+ void SetSetPtSub(Bool_t s) {fSubtractJetPt = s;}
void SetForceAbsVnHarmonics(Bool_t f) {fAbsVnHarmonics = f; }
void SetExcludeLeadingJetsFromFit(Float_t n) {fExcludeLeadingJetsFromFit = n; }
void SetRebinSwapHistoOnTheFly(Bool_t r) {fRebinSwapHistoOnTheFly = r; }
void SetSaveThisPercentageOfFits(Float_t p) {fPercentageOfFits = p; }
void SetUseV0EventPlaneFromHeader(Bool_t h) {fUseV0EventPlaneFromHeader = h;}
- void SetSetPtSub(Bool_t s) {fSetPtSub = s; }
void SetExplicitOutlierCutForYear(Int_t y) {fExplicitOutlierCut = y;}
// getters - these are used as well by AliAnalyisTaskJetFlow, so be careful when changing them
- TString GetJetsName() const {return fJetsName; }
- TString GetTracksName() const {return fTracksName; }
- TArrayI* GetCentralityClasses() const {return fCentralityClasses;}
+ TString GetJetsName() const {return GetJetContainer()->GetArrayName(); }
+ TString GetTracksName() const {return GetParticleContainer()->GetArrayName(); }
+ TString GetLocalRhoName() const {return fLocalRhoName; }
+ TArrayD* GetCentralityClasses() const {return fCentralityClasses;}
+ TArrayD* GetPtBinsHybrids() const {return fPtBinsHybrids; }
+ TArrayD* GetPtBinsJets() const {return fPtBinsJets; }
+ TProfile* GetResolutionParameters(Int_t h, Int_t c) const {return (h==2) ? fProfV2Resolution[c] : fProfV3Resolution[c];}
+ TList* GetOutputList() const {return fOutputList;}
+ AliLocalRhoParameter* GetLocalRhoParameter() const {return fLocalRho;}
+ Double_t GetJetRadius() const {return GetJetContainer()->GetJetRadius();}
+ /* inline */ AliEmcalJet* GetLeadingJet() {
+ // return pointer to the highest pt jet (before background subtraction) within acceptance
+ // only rudimentary cuts are applied on this level, hence the implementation outside of
+ // the framework
+ Int_t iJets(fJets->GetEntriesFast());
+ Double_t pt(0);
+ AliEmcalJet* leadingJet(0x0);
+ for(Int_t i(0); i < iJets; i++) {
+ AliEmcalJet* jet = static_cast<AliEmcalJet*>(fJets->At(i));
+ if(!PassesSimpleCuts(jet)) continue;
+ if(jet->Pt() > pt) {
+ leadingJet = jet;
+ pt = leadingJet->Pt();
+ }
+ }
+ return leadingJet;
+ }
void ExecMe() {ExecOnce();}
+ AliAnalysisTaskRhoVnModulation* ReturnMe() {return this;}
// local cuts
void SetLocalJetMinMaxEta(Float_t min, Float_t max) {fLocalJetMinEta = min; fLocalJetMaxEta = max;}
void SetLocalJetMinMaxEta(Float_t R) {fLocalJetMinEta = - 0.9 + R; fLocalJetMaxEta = 0.9 - R; }
void SetLocalJetMinMaxPhi(Float_t min, Float_t max) {fLocalJetMinPhi = min; fLocalJetMaxEta = max;}
void SetSoftTrackMinMaxPt(Float_t min, Float_t max) {fSoftTrackMinPt = min; fSoftTrackMaxPt = max;}
+ void SetSemiGoodJetMinMaxPhi(Double_t a, Double_t b) {fSemiGoodJetMinPhi = a; fSemiGoodJetMaxPhi = b;}
+ void SetSemiGoodTrackMinMaxPhi(Double_t a, Double_t b) {fSemiGoodTrackMinPhi = a; fSemiGoodTrackMaxPhi = b;}
// numerical evaluations
void CalculateEventPlaneVZERO(Double_t vzero[2][2]) const;
void CalculateEventPlaneTPC(Double_t* tpc);
- void CalculateEventPlaneResolution(Double_t vzero[2][2], Double_t* tpc) const;
- void CalculateRandomCone(Float_t &pt, Float_t &eta, Float_t &phi, AliEmcalJet* jet = 0x0, Bool_t randomize = 0) const;
+ void CalculateEventPlaneCombinedVZERO(Double_t* comb) const;
+ void CalculateEventPlaneResolution(Double_t vzero[2][2], Double_t* vzeroComb, Double_t* tpc);
+ Double_t CalculateEventPlaneChi(Double_t resEP) const;
+ void CalculateRandomCone(Float_t &pt, Float_t &eta, Float_t &phi, AliEmcalJet* jet = 0x0) const;
Double_t CalculateQC2(Int_t harm);
Double_t CalculateQC4(Int_t harm);
- // helper calculations for the q-cumulant analysis
+ // helper calculations for the q-cumulant analysis, also used by AliAnalyisTaskJetFlow
void QCnQnk(Int_t n, Int_t k, Double_t &reQ, Double_t &imQ);
+ void QCnDiffentialFlowVectors(
+ TClonesArray* pois, TArrayD* ptBins, Bool_t vpart, Double_t* repn, Double_t* impn,
+ Double_t *mp, Double_t *reqn, Double_t *imqn, Double_t* mq, Int_t n);
Double_t QCnS(Int_t i, Int_t j);
Double_t QCnM();
Double_t QCnM11();
Double_t QCnM1111();
+ Bool_t QCnRecovery(Double_t psi2, Double_t psi3);
// analysis details
Bool_t CorrectRho(Double_t psi2, Double_t psi3);
- // event and track selection
- /* inline */ Bool_t PassesCuts(const AliVTrack* track) const {
- if(!track) return kFALSE;
- return (track->Pt() < fTrackPtCut || track->Eta() < fTrackMinEta || track->Eta() > fTrackMaxEta || track->Phi() < fTrackMinPhi || track->Phi() > fTrackMaxPhi) ? kFALSE : kTRUE; }
- /* inline */ Bool_t PassesCuts(AliEmcalJet* jet) const {
- if(!jet || fJetRadius <= 0) return kFALSE;
- return (GetLeadingHadronPt(jet) < fMinLeadingHadronPt || jet->Pt() < fJetPtCut || jet->Area()/(fJetRadius*fJetRadius*TMath::Pi()) < fPercAreaCut || jet->Eta() < fJetMinEta || jet->Eta() > fJetMaxEta || jet->Phi() < fJetMinPhi || jet->Phi() > fJetMaxPhi) ? kFALSE : kTRUE; }
+ // event and track selection, also used by AliAnalyisTaskJetFlow
+ /* inline */ Bool_t PassesCuts(AliVTrack* track) const { return AcceptTrack(track, 0); }
+ /* inline */ Bool_t PassesCuts(AliEmcalJet* jet) { return AcceptJet(jet, 0); }
+ /* inline */ Bool_t PassesSimpleCuts(AliEmcalJet* jet) {
+ Float_t minPhi(GetJetContainer()->GetJetPhiMin()), maxPhi(GetJetContainer()->GetJetPhiMax());
+ return (jet && jet->Pt() > 1 && jet->Eta() < .9-GetJetRadius() && jet->Eta() > -.9+GetJetRadius() && jet->Phi() > minPhi && jet->Phi() < maxPhi && jet->Area() > .557*GetJetRadius()*GetJetRadius()*TMath::Pi());
+ }
Bool_t PassesCuts(AliVEvent* event);
Bool_t PassesCuts(Int_t year);
Bool_t PassesCuts(const AliVCluster* track) const;
// filling histograms
- void FillHistogramsAfterSubtraction(Double_t vzero[2][2], Double_t* tpc) const;
+ void FillHistogramsAfterSubtraction(Double_t psi2, Double_t psi3, Double_t vzero[2][2], Double_t* vzeroComb, Double_t* tpc);
void FillTrackHistograms() const;
void FillClusterHistograms() const;
void FillCorrectedClusterHistograms() const;
- void FillEventPlaneHistograms(Double_t vzero[2][2], Double_t* tpc) const;
- void FillRhoHistograms() const;
+ void FillEventPlaneHistograms(Double_t vzero[2][2], Double_t* vzeroComb, Double_t* tpc) const;
+ void FillRhoHistograms();
void FillDeltaPtHistograms(Double_t psi2, Double_t psi3) const;
- void FillJetHistograms(Double_t vzero[2][2], Double_t* psi) const;
- void FillDeltaPhiHistograms(Double_t vzero[2][2], Double_t* tpc) const;
+ void FillJetHistograms(Double_t psi2, Double_t psi3);
void FillQAHistograms(AliVTrack* vtrack) const;
void FillQAHistograms(AliVEvent* vevent);
void FillAnalysisSummaryHistogram() const;
TH1F* GetResolutionFromOuptutFile(detectorType detector, Int_t h = 2, TArrayD* c = 0x0);
TH1F* CorrectForResolutionDiff(TH1F* v, detectorType detector, TArrayD* cen, Int_t c, Int_t h = 2);
TH1F* CorrectForResolutionInt(TH1F* v, detectorType detector, TArrayD* cen, Int_t h = 2);
+ TH1F* GetDifferentialQC(TProfile* refCumulants, TProfile* diffCumlants, TArrayD* ptBins, Int_t h);
private:
// analysis flags and settings
Int_t fDebug; // debug level (0 none, 1 fcn calls, 2 verbose)
- Bool_t fInitialized; //! is the analysis initialized?
+ Bool_t fRunToyMC; // run toy mc for fit routine
+ Bool_t fLocalInit; //! is the analysis initialized?
+ Bool_t fAttachToEvent; // attach local rho to the event
+ Bool_t fSemiCentralInclusive; // semi central inclusive event selection
+ Bool_t fFillHistograms; // fill histograms
Bool_t fFillQAHistograms; // fill qa histograms
- TArrayI* fCentralityClasses; //-> centrality classes (maximum 10)
+ Float_t fReduceBinsXByFactor; // reduce the bins on x-axis of histo's by this much
+ Float_t fReduceBinsYByFactor; // reduce the bins on y-axis of histo's by this much
+ Bool_t fNoEventWeightsForQC; // don't store event weights for qc analysis
+ TArrayD* fCentralityClasses; //-> centrality classes (maximum 10)
+ TArrayD* fPtBinsHybrids; //-> pt bins for hybrid track vn anaysis
+ TArrayD* fPtBinsJets; //-> pt bins for jet vn analysis
+ TArrayI* fExpectedRuns; //-> array of expected run numbers, used for QA
+ TArrayI* fExpectedSemiGoodRuns; //-> array of expected semi-good runs, used for cuts and QA
TH1F* fUserSuppliedV2; // histo with integrated v2
TH1F* fUserSuppliedV3; // histo with integrated v3
TH1F* fUserSuppliedR2; // correct the extracted v2 with this r
TH1F* fUserSuppliedR3; // correct the extracted v3 with this r
+ AliParticleContainer* fTracksCont; //!tracks
+ AliJetContainer* fJetsCont; //!jets
+ AliEmcalJet* fLeadingJet; //! leading jet
// members
+ Bool_t fUseScaledRho; // use scaled rho
Int_t fNAcceptedTracks; //! number of accepted tracks
Int_t fNAcceptedTracksQCn; //! accepted tracks for QCn
fitModulationType fFitModulationType; // fit modulation type
+ fitGoodnessTest fFitGoodnessTest; // fit goodness test type
+ qcRecovery fQCRecovery; // recovery type for e-by-e qc method
Bool_t fUsePtWeight; // use dptdphi instead of dndphi
+ Bool_t fUsePtWeightErrorPropagation; // recalculate the bin errors in case of pt weighting
detectorType fDetectorType; // type of detector used for modulation fit
TString fFitModulationOptions; // fit options for modulation fit
runModeType fRunModeType; // run mode type
dataType fDataType; // datatype
+ collisionType fCollisionType; // collision type
TRandom3* fRandom; //-> dont use gRandom to not interfere with other tasks
+ Int_t fRunNumber; //! current runnumber (for QA and jet, track selection)
Int_t fMappedRunNumber; //! mapped runnumer (for QA)
Int_t fInCentralitySelection; //! centrality bin
TF1* fFitModulation; //-> modulation fit for rho
+ TF1* fFitControl; //-> control fit
Float_t fMinPvalue; // minimum value of p
Float_t fMaxPvalue; // maximum value of p
const char* fNameJetClones; //! collection of tclones array with jets
const char* fNamePicoTrackClones; //! collection of tclones with pico tracks
const char* fNameRho; //! name of rho
+ TString fNameSmallRho; // name of small rho
+ AliRhoParameter* fCachedRho; //! temp cache for rho pointer
// additional jet cuts (most are inherited)
Float_t fLocalJetMinEta; // local eta cut for jets
Float_t fLocalJetMaxEta; // local eta cut for jets
Float_t fLocalJetMaxPhi; // local phi cut for jets
Float_t fSoftTrackMinPt; // min pt for soft tracks
Float_t fSoftTrackMaxPt; // max pt for soft tracks
+ Double_t fSemiGoodJetMinPhi; // min phi for semi good tpc runs
+ Double_t fSemiGoodJetMaxPhi; // max phi for semi good tpc runs
+ Double_t fSemiGoodTrackMinPhi; // min phi for semi good tpc runs
+ Double_t fSemiGoodTrackMaxPhi; // max phi for semi good tpc runs
// event cuts
Float_t fAbsVertexZ; // cut on zvertex
// general qa histograms
TH1F* fHistVertexz; //! accepted verte
TH2F* fHistRunnumbersPhi; //! run numbers averaged phi
TH2F* fHistRunnumbersEta; //! run numbers averaged eta
- TH1F* fHistPvaluePDF; //! pdf value of chisquare p
+ TH1F* fHistPvalueCDFROOT; //! pdf value of chisquare p
+ TH2F* fHistPvalueCDFROOTCent; //! p value versus centrlaity from root
+ TH2F* fHistChi2ROOTCent; //! reduced chi2 from ROOT, centrality correlation
+ TH2F* fHistPChi2Root; //! correlation p value and reduced chi2
TH1F* fHistPvalueCDF; //! cdf value of chisquare p
+ TH2F* fHistPvalueCDFCent; //! p value vs centrality
+ TH2F* fHistChi2Cent; //! reduced chi2, centrlaity correlation
+ TH2F* fHistPChi2; //! correlation p value and reduced chi2
+ TH1F* fHistKolmogorovTest; //! KolmogorovTest value
+ TH2F* fHistKolmogorovTestCent;//! KolmogorovTest value, centrality correlation
+ TH2F* fHistPKolmogorov; //! p value vs kolmogorov value
+ TH2F* fHistRhoStatusCent; //! status of rho as function of centrality
+ TH1F* fHistUndeterminedRunQA; //! undetermined run QA
// general settings
Float_t fMinDisanceRCtoLJ; // min distance between rc and leading jet
Float_t fRandomConeRadius; // radius of random cone
+ Int_t fMaxCones; // max number of random cones
Bool_t fAbsVnHarmonics; // force postive local rho
Float_t fExcludeLeadingJetsFromFit; // exclude n leading jets from fit
Bool_t fRebinSwapHistoOnTheFly; // rebin swap histo on the fly
Float_t fPercentageOfFits; // save this percentage of fits
- Bool_t fUseV0EventPlaneFromHeader; // use the vzero event plane from the header
- Bool_t fSetPtSub; // store the subtracted pt in the jet
+ Bool_t fUseV0EventPlaneFromHeader; // use the vzero event plane from the header
Int_t fExplicitOutlierCut; // cut on correlation of tpc and global multiplicity
Double_t fMinLeadingHadronPt; // minimum pt for leading hadron
+ Bool_t fSubtractJetPt; // save subtracted jet pt by calling SetPtSub
// transient object pointers
TList* fOutputList; //! output list
TList* fOutputListGood; //! output list for local analysis
TProfile* fProfV3Resolution[10]; //! resolution parameters for v3
// qa histograms for accepted pico tracks
TH1F* fHistPicoTrackPt[10]; //! pt of all charged tracks
+ TH1F* fHistPicoTrackMult[10]; //! multiplicity of accepted pico tracks
TH2F* fHistPicoCat1[10]; //! pico tracks spd hit and refit
TH2F* fHistPicoCat2[10]; //! pico tracks wo spd hit w refit, constrained
TH2F* fHistPicoCat3[10]; //! pico tracks wo spd hit wo refit, constrained
TProfile* fHistPsiSpread; //! event plane spread histogram
TH1F* fHistPsiVZEROA; //! psi 2 from vzero a
TH1F* fHistPsiVZEROC; //! psi 2 from vzero c
+ TH1F* fHistPsiVZERO; //! psi 2 from combined vzero
TH1F* fHistPsiTPC; //! psi 2 from tpc
+ TH2F* fHistPsiVZEROAV0M; //! psi 2 from vzero a
+ TH2F* fHistPsiVZEROCV0M; //! psi 2 from vzero c
+ TH2F* fHistPsiVZEROVV0M; //! psi 2 from combined vzero
+ TH2F* fHistPsiTPCiV0M; //! psi 2 from tpc
+ TH2F* fHistPsiVZEROATRK; //! psi 2 from vzero a
+ TH2F* fHistPsiVZEROCTRK; //! psi 2 from vzero c
+ TH2F* fHistPsiVZEROTRK; //! psi 2 from combined vzero
+ TH2F* fHistPsiTPCTRK; //! psi 2 from tpc
// background
TH1F* fHistRhoPackage[10]; //! rho as estimated by emcal jet package
TH1F* fHistRho[10]; //! background
TH2F* fHistRCPhiEta[10]; //! random cone eta and phi
TH2F* fHistRhoVsRCPt[10]; //! rho * A vs rcpt
TH1F* fHistRCPt[10]; //! rcpt
- TH2F* fHistDeltaPtDeltaPhi2[10]; //! dpt vs dphi
- TH2F* fHistDeltaPtDeltaPhi3[10]; //! dpt vs dphi
+ TH2F* fHistDeltaPtDeltaPhi2[10]; //! dpt vs dphi (psi2 - phi)
+ TH2F* fHistDeltaPtDeltaPhi3[10]; //! dpt vs dphi (psi3 - phi)
TH2F* fHistRCPhiEtaExLJ[10]; //! random cone eta and phi, excl leading jet
TH2F* fHistRhoVsRCPtExLJ[10]; //! rho * A vs rcpt, excl leading jet
TH1F* fHistRCPtExLJ[10]; //! rcpt, excl leading jet
TH1F* fHistJetPt[10]; //! pt of found jets (background subtracted)
TH2F* fHistJetEtaPhi[10]; //! eta and phi correlation
TH2F* fHistJetPtArea[10]; //! jet pt versus area
+ TH2F* fHistJetPtEta[10]; //! jet pt versus eta (temp control)
TH2F* fHistJetPtConstituents[10]; //! jet pt versus number of constituents
TH2F* fHistJetEtaRho[10]; //! jet eta versus jet rho
// in plane, out of plane jet spectra
- TH2F* fHistJetPsiTPCPt[10]; //! psi tpc versus pt
- TH2F* fHistJetPsiVZEROAPt[10]; //! psi vzeroa versus pt
- TH2F* fHistJetPsiVZEROCPt[10]; //! psi vzeroc versus pt
- // phi minus psi
- TH1F* fHistDeltaPhi2VZEROA[10]; //! phi minus psi_A
- TH1F* fHistDeltaPhi2VZEROC[10]; //! phi minus psi_C
- TH1F* fHistDeltaPhi2TPC[10]; //! phi minus psi_TPC
- TH1F* fHistDeltaPhi3VZEROA[10]; //! phi minus psi_A
- TH1F* fHistDeltaPhi3VZEROC[10]; //! phi minus psi_C
- TH1F* fHistDeltaPhi3TPC[10]; //! phi minus psi_TPC
+ TH2F* fHistJetPsi2Pt[10]; //! psi tpc versus pt
+ TH2F* fHistJetPsi3Pt[10]; //! psi vzeroc versus pt
AliAnalysisTaskRhoVnModulation(const AliAnalysisTaskRhoVnModulation&); // not implemented
AliAnalysisTaskRhoVnModulation& operator=(const AliAnalysisTaskRhoVnModulation&); // not implemented
- ClassDef(AliAnalysisTaskRhoVnModulation, 12);
+ ClassDef(AliAnalysisTaskRhoVnModulation, 26);
};
#endif
git://git.uio.no / u / mrichter / AliRoot.git / blobdiff