//////////////////////////////////////////////////////
#include <TClonesArray.h>
+#include <TCanvas.h>
#include <TObjArray.h>
#include <TPad.h>
#include <TLegend.h>
+#include <TLatex.h>
+#include <TLine.h>
#include <TF1.h>
+#include <TH1D.h>
+#include <TH2D.h>
+#include <TH3D.h>
#include <TH2I.h>
+#include <TH2F.h>
#include <TH3S.h>
+#include <TH3F.h>
+#include <TProfile2D.h>
+#include <TProfile.h>
#include <TGraphErrors.h>
#include <TGraphAsymmErrors.h>
#include <TFile.h>
#include <TROOT.h>
#include <TChain.h>
#include <TParticle.h>
+#include <TTimeStamp.h>
+#include <TRandom.h>
#include "AliLog.h"
#include "AliAnalysisManager.h"
+#include "AliAnalysisCuts.h"
#include "AliESDEvent.h"
#include "AliESDkink.h"
#include "AliMCEvent.h"
#include "AliESDInputHandler.h"
#include "AliMCEventHandler.h"
+#include "AliESDpid.h"
#include "AliESDtrack.h"
#include "AliMCParticle.h"
#include "AliPID.h"
#include "AliStack.h"
#include "AliTrackReference.h"
+//#include "AliESDCentrality.h"
+#include "AliMultiplicity.h"
+#include "AliCFContainer.h"
#include "AliTRDcheckESD.h"
+#include <iostream>
+using namespace std;
ClassImp(AliTRDcheckESD)
const Float_t AliTRDcheckESD::fgkxTPC = 290.;
const Float_t AliTRDcheckESD::fgkxTOF = 365.;
-const UChar_t AliTRDcheckESD::fgkNgraph[kNrefs] ={
-0, 4, 2, 10};
+const UChar_t AliTRDcheckESD::fgkNgraph[AliTRDcheckESD::kNrefs] ={
+8, 4, 2, 20};
FILE* AliTRDcheckESD::fgFile = NULL;
+const Float_t AliTRDcheckESD::fgkEvVertexZ = 15.;
+const Int_t AliTRDcheckESD::fgkEvVertexN = 1;
+const Float_t AliTRDcheckESD::fgkTrkDCAxy = 40.;
+const Float_t AliTRDcheckESD::fgkTrkDCAz = 15.;
+const Int_t AliTRDcheckESD::fgkNclTPC = 100;
+const Float_t AliTRDcheckESD::fgkPt = 0.2;
+const Float_t AliTRDcheckESD::fgkEta = 0.9;
+const Float_t AliTRDcheckESD::fgkQs = 0.002;
+
//____________________________________________________________________
AliTRDcheckESD::AliTRDcheckESD():
AliAnalysisTaskSE()
,fNRefFigures(0)
,fESD(NULL)
,fMC(NULL)
+ ,fESDpid(new AliESDpid)
,fHistos(NULL)
,fResults(NULL)
+ ,fCfContainer(NULL)
+ ,fReferenceTrackFilter(NULL)
{
//
// Default constructor
//
- SetNameTitle("checkESD", "Check TRD @ ESD level");
+ SetNameTitle("TRDcheckESD", "Check TRD @ ESD level");
SetMC(kTRUE);
}
,fNRefFigures(0)
,fESD(NULL)
,fMC(NULL)
+ ,fESDpid(new AliESDpid)
,fHistos(NULL)
,fResults(NULL)
+ ,fCfContainer(NULL)
+ ,fReferenceTrackFilter(NULL)
{
//
// Default constructor
//
// Create Output Containers (TObjectArray containing 1D histograms)
//
- //OpenFile(0, "RECREATE");
-
Histos();
+ PostData(1, fHistos);
+}
+
+//____________________________________________________________________
+void AliTRDcheckESD::MakeSummaryFromCF(Double_t* trendValues, Bool_t useIsolatedBC, Bool_t cutTOFbc){
+ //
+ // Draw summary plots for the ESDcheck task using the CF container
+ //
+
+ cout << "Make summary from CF" << endl;
+ TCanvas *cOut=0x0;
+ if(gROOT->FindObject("trackingSummary")) delete gROOT->FindObject("trackingSummary");
+ cOut = new TCanvas("trackingSummary", "Tracking summary for the ESD task", 1600, 1200);
+ cOut->cd();
+ PlotTrackingSummaryFromCF(0, trendValues, useIsolatedBC, cutTOFbc);
+ cOut->SaveAs("trackingSummary.gif");
+
+ if(gROOT->FindObject("pidSummary")) delete gROOT->FindObject("pidSummary");
+ cOut = new TCanvas("pidSummary", "PID summary for the ESD task", 1600, 1200);
+ cOut->cd();
+ //GetRefFigure(6);
+ PlotPidSummaryFromCF(0, trendValues, useIsolatedBC, cutTOFbc);
+ cOut->SaveAs("pidSummary.gif");
+
+ if(gROOT->FindObject("centSummary")) delete gROOT->FindObject("centSummary");
+ cOut = new TCanvas("centSummary", "Centrality summary for the ESD task", 1600, 1200);
+ cOut->cd();
+ //GetRefFigure(7);
+ PlotCentSummaryFromCF(trendValues, useIsolatedBC, cutTOFbc);
+ cOut->SaveAs("centSummary.gif");
+
}
+//____________________________________________________________________
+void AliTRDcheckESD::MakeSummary(Double_t* trendValues){
+ //
+ // Draw summary plots for the ESDcheck task
+ //
+ // Old method to draw summary pictures from histograms. Use the MakeSummaryFromCF() when CF container is present
+
+ cout << "Make summary" << endl;
+ TCanvas *cTracking=0x0;
+ if(gROOT->FindObject("trackingSummary")) delete gROOT->FindObject("trackingSummary");
+ cTracking = new TCanvas("trackingSummary", "Tracking summary for the ESD task", 1600, 1200);
+ cTracking->cd();
+ //GetRefFigure(5);
+ if(PlotTrackingSummary(0, trendValues))
+ cTracking->SaveAs("trackingSummary.gif");
+
+ TCanvas* cPid = 0x0;
+ if(gROOT->FindObject("pidSummary")) delete gROOT->FindObject("pidSummary");
+ cPid = new TCanvas("pidSummary", "PID summary for the ESD task", 1600, 1200);
+ cPid->cd();
+ //GetRefFigure(6);
+ if(PlotPidSummary(0, trendValues))
+ cPid->SaveAs("pidSummary.gif");
+
+ TCanvas* cCent=0x0;
+ if(gROOT->FindObject("centSummary")) delete gROOT->FindObject("centSummary");
+ cCent = new TCanvas("centSummary", "Centrality summary for the ESD task", 1600, 1200);
+ cCent->cd();
+ //GetRefFigure(7);
+ if(PlotCentSummary(trendValues))
+ cCent->SaveAs("centSummary.gif");
+}
+
//____________________________________________________________________
Bool_t AliTRDcheckESD::GetRefFigure(Int_t ifig)
{
+ //
+ // Produce reference Plots during PostProcessing
+ //
if(ifig>=fNRefFigures){
AliWarning(Form("Ref plot %d not available. Valid only up to %d", ifig, fNRefFigures));
return kFALSE;
if(!gPad){
AliWarning("Please provide a canvas to draw results.");
return kFALSE;
+ } else {
+ gPad->SetLogx(0);gPad->SetLogy(0);
+ gPad->SetMargin(0.125, 0.015, 0.1, 0.015);
}
const Char_t *title[20];
TH1 *hF(NULL);
if((hF=(TH1S*)gROOT->FindObject("hFcheckESD"))) delete hF;
TLegend *leg(NULL);
+ TList *l(NULL); TVirtualPad *pad(NULL);
TGraphErrors *g(NULL);TGraphAsymmErrors *ga(NULL);
TObjArray *arr(NULL);
+ TLatex *lat=new TLatex();
+ lat->SetTextSize(0.07);
+ lat->SetTextColor(2);
+ TLine line;
+ TTimeStamp now;
switch(ifig){
case kNCl: // number of clusters/track
- ((TH1I*)fResults->At(kNCl))->Draw("c");
+ if(!(arr = (TObjArray*)fResults->At(kNCl))) return kFALSE;
+
+ leg = new TLegend(.83, .7, .99, .96);
+ leg->SetHeader("Species");
+ leg->SetBorderSize(0); leg->SetFillStyle(0);
+ for(Int_t ig(0); ig<fgkNgraph[kNCl-1]; ig++){
+ if(!(g = (TGraphErrors*)arr->At(ig))) return kFALSE;
+ if(!g->GetN()) continue;
+ g->Draw(ig?"pc":"apc"); leg->AddEntry(g, g->GetTitle(), "pl");
+ if(ig) continue;
+ hF=g->GetHistogram();
+ hF->SetXTitle("no of clusters");
+ hF->SetYTitle("entries");
+ hF->GetYaxis()->CenterTitle(1);
+ hF->GetYaxis()->SetTitleOffset(1.2);
+ hF->SetMinimum(5);
+ }
+ leg->Draw(); gPad->SetLogy();
break;
case kTRDstat: // Efficiency
if(!(arr = (TObjArray*)fResults->At(kTRDstat))) return kFALSE;
- leg = new TLegend(.65, .7, .95, .99);
+ leg = new TLegend(.62, .77, .98, .98);
leg->SetHeader("TRD Efficiency");
- leg->SetBorderSize(1); leg->SetFillColor(0);
+ leg->SetBorderSize(0); leg->SetFillStyle(0);
title[0] = "Geometrical (TRDin/TPCout)";
title[1] = "Tracking (TRDout/TRDin)";
title[2] = "PID (TRDpid/TRDin)";
title[3] = "Refit (TRDrefit/TRDin)";
hF = new TH1S("hFcheckESD", ";p [GeV/c];Efficiency", 10, 0.1, 10.);
- hF->SetMaximum(1.3);
+ hF->SetMaximum(1.4);
hF->GetXaxis()->SetMoreLogLabels();
+ hF->GetYaxis()->CenterTitle(1);
hF->Draw("p");
- for(Int_t ig(0); ig<fgkNgraph[kTRDstat]; ig++){
+ for(Int_t ig(0); ig<fgkNgraph[kTRDstat-1]; ig++){
if(!(g = (TGraphErrors*)arr->At(ig))) return kFALSE;
g->Draw("pl"); leg->AddEntry(g, title[ig], "pl");
//PutTrendValue(name[id], g->GetMean(2));
hF = new TH1S("hFcheckESD", ";layer;#Delta E", 6, -0.5, 5.5);
hF->SetMaximum(1.3);hF->SetMinimum(-.3);
hF->Draw("p");
- for(Int_t ig(0); ig<fgkNgraph[kTRDmom]; ig++){
+ for(Int_t ig(0); ig<fgkNgraph[kTRDmom-1]; ig++){
if(!(ga = (TGraphAsymmErrors*)arr->At(ig))) return kFALSE;
ga->Draw("pl"); leg->AddEntry(ga, title[ig], "pl");
//PutTrendValue(name[id], g->GetMean(2));
break;
case kPtRes: // Pt resolution @ vertex
if(!(arr = (TObjArray*)fResults->At(kPtRes))) return kFALSE;
- gPad->SetMargin(0.1, 0.22, 0.1, 0.023);
- leg = new TLegend(.78, .1, .99, .98);
- leg->SetHeader("P_{t} @ DCA");
- leg->SetBorderSize(1); leg->SetFillColor(0);
- leg->SetTextAlign(22);
- leg->SetTextFont(12);
- leg->SetTextSize(0.03813559);
- hF = new TH1S("hFcheckESD", ";p_{t} [GeV/c];#Delta p_{t} / p_{t} [%]", 10, 0.2, 10.);
+ gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
+ pad = ((TVirtualPad*)l->At(0)); pad->cd(); pad->SetLogx();
+ pad->SetMargin(0.1, 0.022, 0.1, 0.023);
+ hF = new TH1S("hFcheckESD", "ITS+TPC+TRD;p_{t} [GeV/c];#Delta p_{t} / p_{t} [%]", 10, 0.2, 10.);
hF->SetMaximum(10.);hF->SetMinimum(-3.);
hF->GetXaxis()->SetMoreLogLabels();
hF->GetXaxis()->SetTitleOffset(1.2);
hF->GetYaxis()->CenterTitle();
hF->Draw("p");
- for(Int_t ig(0); ig<fgkNgraph[kPtRes]; ig++){
- if(!(g = (TGraphErrors*)arr->At(ig))) continue;//return kFALSE;
+ //for(Int_t ig(0); ig<fgkNgraph[kPtRes-1]/2; ig++){
+ for(Int_t ig(2); ig<6; ig++){
+ if(!(g = (TGraphErrors*)arr->At(ig))) continue;
if(!g->GetN()) continue;
- g->Draw("pl"); leg->AddEntry(g, g->GetTitle(), "pl");
+ g->Draw("pl");
//PutTrendValue(name[id], g->GetMean(2));
//PutTrendValue(Form("%sRMS", name[id]), g->GetRMS(2));
}
- leg->Draw();gPad->SetLogx();
+ pad = ((TVirtualPad*)l->At(1)); pad->cd(); pad->SetLogx();
+ pad->SetMargin(0.1, 0.22, 0.1, 0.023);
+ hF = (TH1*)hF->Clone("hFcheckESD1");
+ hF->SetTitle("ITS+TPC");
+ hF->SetMaximum(10.);hF->SetMinimum(-3.);
+ hF->Draw("p");
+ leg = new TLegend(.78, .1, .99, .98);
+ leg->SetHeader("P_{t} @ DCA");
+ leg->SetBorderSize(1); leg->SetFillColor(0);
+ leg->SetTextAlign(22);
+ leg->SetTextFont(12);
+ leg->SetTextSize(0.03813559);
+ {
+ Int_t nPlots(0);
+ //for(Int_t ig(fgkNgraph[kPtRes-1]/2); ig<fgkNgraph[kPtRes-1]; ig++){
+ for(Int_t ig(12); ig<16; ig++){
+ if(!(g = (TGraphErrors*)arr->At(ig))) continue;
+ if(!g->GetN()) continue;
+ nPlots++;
+ g->Draw("pl"); leg->AddEntry(g, g->GetTitle(), "pl");
+ //PutTrendValue(name[id], g->GetMean(2));
+ //PutTrendValue(Form("%sRMS", name[id]), g->GetRMS(2));
+ }
+ if(nPlots) leg->Draw();
+ }
+ break;
+ case 5: // plot a 3x3 canvas with tracking related histograms
+ PlotTrackingSummary(0);
break;
+
+ case 6: // plot a 3x3 canvas with PID related histograms
+ PlotPidSummary(0);
+ break;
+
+ case 7: // plot a 3x3 canvas with centrality dependence histograms
+ PlotCentSummary();
+ break;
+
}
return kTRUE;
}
//
fESD = dynamic_cast<AliESDEvent*>(InputEvent());
fMC = MCEvent();
-
+
if(!fESD){
AliError("ESD event missing.");
return;
}
}
}
- TH2 *h(NULL);
+ TH1 *h(NULL);
+ Double_t values[kNTrdCfVariables]; // array where the CF container variables are stored
+ values[kEventVtxZ] = fESD->GetPrimaryVertex()->GetZv();
+ values[kEventBC] = fESD->GetBunchCrossNumber();
+
+ const AliMultiplicity* mult=fESD->GetMultiplicity();
+ Double_t itsNTracklets = mult->GetNumberOfTracklets();
+ if(itsNTracklets<1) return;
+ Int_t multLimits[6] = {0, 700, 1400, 2100, 2800, 3500};
+ Int_t centralityClass = 0;
+ for(Int_t iCent=0; iCent<5; ++iCent) {
+ if(itsNTracklets>=multLimits[iCent] && itsNTracklets<multLimits[iCent+1])
+ centralityClass=iCent+1;
+ }
+ values[kEventMult] = itsNTracklets;
+ if(centralityClass == 0) return;
+
AliESDtrack *esdTrack(NULL);
for(Int_t itrk = 0; itrk < fESD->GetNumberOfTracks(); itrk++){
esdTrack = fESD->GetTrack(itrk);
-
- // track status
+ if(!fReferenceTrackFilter->IsSelected(esdTrack)) continue;
+
ULong_t status = esdTrack->GetStatus(); //PrintStatus(status);
- if(!Bool_t(status & AliESDtrack::kTPCout)) continue;
- if(esdTrack->GetKinkIndex(0) > 0) continue;
-
- //Int_t nTPC(esdTrack->GetNcls(1));
- Int_t nTRD(esdTrack->GetNcls(2));
- Double_t pt(esdTrack->Pt());
- //Double_t eta(esdTrack->Eta());
- //Double_t phi(esdTrack->Phi());
- Double_t p[AliPID::kSPECIES]; esdTrack->GetTRDpid(p);
+
// pid quality
- //esdTrack->GetTRDntrackletsPID();
Bool_t kBarrel = Bool_t(status & AliESDtrack::kTRDin);
+ // find position and momentum of the track at entrance in TRD
+ Double_t localCoord[3] = {0., 0., 0.};
+ Bool_t localCoordGood = esdTrack->GetXYZAt(298., fESD->GetMagneticField(), localCoord);
+ Double_t localMom[3] = {0., 0., 0.};
+ Bool_t localMomGood = esdTrack->GetPxPyPzAt(298., fESD->GetMagneticField(), localMom);
+ //Double_t localPhi = (localMomGood ? TMath::ATan2(localMom[1], localMom[0]) : 0.0);
+ Double_t localSagitaPhi = (localCoordGood ? TMath::ATan2(localCoord[1], localCoord[0]) : 0.0);
+
+ values[kTrackTOFdeltaBC] = esdTrack->GetTOFDeltaBC();
+ values[kTrackTOFBC] = esdTrack->GetTOFBunchCrossing(fESD->GetMagneticField());
+ Float_t dcaXY=0.0; Float_t dcaZ=0.0;
+ esdTrack->GetImpactParameters(dcaXY, dcaZ);
+ values[kTrackDCAxy] = dcaXY;
+ values[kTrackDCAz] = dcaZ;
+ values[kTrackCharge] = esdTrack->Charge();
+ values[kTrackPhi] = localSagitaPhi;
+ values[kTrackEta] = esdTrack->Eta();
+ values[kTrackPt] = esdTrack->Pt();
+ values[kTrackP] = esdTrack->P();
+ values[kTrackTrdTracklets] = esdTrack->GetTRDntracklets();
+ values[kTrackTrdClusters] = esdTrack->GetTRDncls();
+ for(Int_t i=0; i<6; ++i) values[kTrackQtot+i] = 0.0;
+
+ if(localCoordGood && localMomGood) fCfContainer->Fill(values, 0); // fill the TPC reference step
+
+ // TRD reference tracks
+ if(esdTrack->GetTRDntracklets()>=1) {
+ // (slicePH,sliceNo) distribution and Qtot from slices
+ for(Int_t iPlane=0; iPlane<6; iPlane++) {
+ Float_t qtot=esdTrack->GetTRDslice(iPlane, 0);
+ for(Int_t iSlice=0; iSlice<8; iSlice++) {
+ if(esdTrack->GetTRDslice(iPlane, iSlice)>20.) {
+ h = (TH2F*)fHistos->At(kPHSlice); h->Fill(iSlice, esdTrack->GetTRDslice(iPlane, iSlice));
+ h = (TH2F*)fHistos->At(kPHSlice+centralityClass); h->Fill(iSlice, esdTrack->GetTRDslice(iPlane, iSlice));
+ }
+ }
+ values[kTrackQtot+iPlane] = fgkQs*qtot;
+ }
+
+ if(localCoordGood && localMomGood) {
+ fCfContainer->Fill(values, 1);
+ if(Bool_t(status & AliESDtrack::kTOFpid)) fCfContainer->Fill(values, 2);
+ }
+ } // end if nTRDtrkl>=1
+
// look at external track param
const AliExternalTrackParam *op = esdTrack->GetOuterParam();
const AliExternalTrackParam *ip = esdTrack->GetInnerParam();
- Double_t pt0(0.), eta0(0.), phi0(0.), ptTRD(0.);
+ Double_t pt(0.), pt0(0.), ptTRD(0.);
// read MC info if available
Bool_t kFOUND(kFALSE), kPhysPrim(kFALSE);
AliMCParticle *mcParticle(NULL);
AliTrackReference *ref(NULL);
Int_t fLabel(esdTrack->GetLabel());
Int_t fIdx(TMath::Abs(fLabel));
- if(fIdx > fStack->GetNtrack()) continue;
+ if(!fStack || fIdx > fStack->GetNtrack()) continue;
// read MC particle
if(!(mcParticle = (AliMCParticle*) fMC->GetTrack(fIdx))) {
AliWarning(Form("MC particle missing. Label[ %d].", fLabel));
continue;
}
+
+ pt = esdTrack->Pt();
pt0 = mcParticle->Pt();
- eta0 = mcParticle->Eta();
- phi0 = mcParticle->Phi();
+ //Double_t eta0 = mcParticle->Eta();
+ //Double_t phi0 = mcParticle->Phi();
kPhysPrim = fMC->IsPhysicalPrimary(fIdx);
// read track references
ptTRD=ip->Pt();
kFOUND=kTRUE;
}
- }
+ } // end if(HasMC())
if(kFOUND){
h = (TH2I*)fHistos->At(kTRDstat);
if(status & AliESDtrack::kTPCout) h->Fill(ptTRD, kTPCout);
if(status & AliESDtrack::kTRDin) h->Fill(ptTRD, kTRDin);
- if(kBarrel && (status & AliESDtrack::kTRDout)){
- ((TH1*)fHistos->At(kNCl))->Fill(nTRD);
- h->Fill(ptTRD, kTRDout);
- }
+ if(kBarrel && (status & AliESDtrack::kTRDout)) h->Fill(ptTRD, kTRDout);
if(kBarrel && (status & AliESDtrack::kTRDpid)) h->Fill(ptTRD, kTRDpid);
if(kBarrel && (status & AliESDtrack::kTRDrefit)) h->Fill(ptTRD, kTRDref);
}
- if(HasMC() && kBarrel && (status & AliESDtrack::kTRDout)) {
+ Int_t idx(HasMC() ? Pdg2Idx(TMath::Abs(mcParticle->PdgCode())): 0)
+ ,sgn(esdTrack->Charge()<0?0:1);
+ if(kBarrel && kPhysPrim) {
TH3 *h3 = (TH3S*)fHistos->At(kPtRes);
- Int_t sgn = mcParticle->Charge()>0?1:-1;
- h3->Fill(pt0, 1.e2*pt/pt0-1.e2, sgn*Pdg2Idx(TMath::Abs(mcParticle->PdgCode())));
+ Int_t offset = (status & AliESDtrack::kTRDrefit) ? 0 : 10;
+ h3->Fill(pt0, 1.e2*(pt/pt0-1.),
+ offset + 2*idx + sgn);
}
+ ((TH1*)fHistos->At(kNCl))->Fill(esdTrack->GetTRDncls(), 2*idx + sgn);
if(ip){
h = (TH2I*)fHistos->At(kTRDmom);
Float_t pTRD(0.);
h->Fill(ip->GetP()-pTRD, ily);
}
}
- }
+ } // end loop over tracks
+
+ // fill the number of tracks histograms
+ //h = (TH1I*)fHistos->At(kNTracksAcc);
+ //h->Fill(nTracksAcc);
+ //h = (TH1I*)fHistos->At(kNTracksTPC);
+ //h->Fill(nTracksTPC);
PostData(1, fHistos);
}
if(fHistos) return fHistos;
- fHistos = new TObjArray(kNhistos);
- //fHistos->SetOwner(kTRUE);
+ fHistos = new TObjArray(kNhistos+1);
+ fHistos->SetOwner(kTRUE);
TH1 *h = NULL;
- // clusters per tracklet
- if(!(h = (TH1I*)gROOT->FindObject("hNCl"))){
- h = new TH1I("hNCl", "Clusters per TRD track;N_{cl}^{TRD};entries", 100, 0., 200.);
+ // clusters per track
+ const Int_t kNpt(30);
+ Float_t pt(0.2);
+ Float_t binsPt[kNpt+1];
+ for(Int_t i=0;i<kNpt+1; i++,pt+=(TMath::Exp(i*i*.001)-1.)) binsPt[i]=pt;
+ if(!(h = (TH2I*)gROOT->FindObject("hNCl"))){
+ h = new TH2I("hNCl", "Clusters per TRD track;N_{cl}^{TRD};SPECIES;entries", 60, 0., 180., 10, -0.5, 9.5);
+ TAxis *ay(h->GetYaxis());
+ ay->SetLabelOffset(0.015);
+ for(Int_t i(0); i<AliPID::kSPECIES; i++){
+ ay->SetBinLabel(2*i+1, Form("%s^{-}", AliPID::ParticleLatexName(i)));
+ ay->SetBinLabel(2*i+2, Form("%s^{+}", AliPID::ParticleLatexName(i)));
+ }
} else h->Reset();
fHistos->AddAt(h, kNCl); fNRefFigures++;
// status bits histogram
- const Int_t kNpt(10), kNbits(5);
- Float_t Pt(0.1), Bits(.5);
- Float_t binsPt[kNpt+1], binsBits[kNbits+1];
- for(Int_t i=0;i<kNpt+1; i++,Pt+=(TMath::Exp(i*i*.015)-1.)) binsPt[i]=Pt;
- for(Int_t i=0; i<kNbits+1; i++,Bits+=1.) binsBits[i]=Bits;
+ const Int_t kNbits(5);
+ Float_t bits(.5);
+ Float_t binsBits[kNbits+1];
+ for(Int_t i=0; i<kNbits+1; i++,bits+=1.) binsBits[i]=bits;
if(!(h = (TH2I*)gROOT->FindObject("hTRDstat"))){
h = new TH2I("hTRDstat", "TRD status bits;p_{t} @ TRD [GeV/c];status;entries", kNpt, binsPt, kNbits, binsBits);
TAxis *ay(h->GetYaxis());
h = new TH2I("hTRDmom", "TRD energy loss;p_{inner} - p_{ly} [GeV/c];ly;entries", 100, -1., 2., 6, -0.5, 5.5);
} else h->Reset();
fHistos->AddAt(h, kTRDmom);
- if(!HasMC()) return fHistos;
+ //if(!HasMC()) return fHistos;
// pt resolution
- const Int_t kNdpt(100), kNspec(2*AliPID::kSPECIES+1);
- Float_t DPt(-3.), Spec(-AliPID::kSPECIES-0.5);
+ const Int_t kNdpt(100), kNspec(4*AliPID::kSPECIES);
+ Float_t dpt(-3.), spec(-0.5);
Float_t binsDPt[kNdpt+1], binsSpec[kNspec+1];
- for(Int_t i=0; i<kNdpt+1; i++,DPt+=6.e-2) binsDPt[i]=DPt;
- for(Int_t i=0; i<kNspec+1; i++,Spec+=1.) binsSpec[i]=Spec;
+ for(Int_t i=0; i<kNdpt+1; i++,dpt+=6.e-2) binsDPt[i]=dpt;
+ for(Int_t i=0; i<kNspec+1; i++,spec+=1.) binsSpec[i]=spec;
if(!(h = (TH3S*)gROOT->FindObject("hPtRes"))){
h = new TH3S("hPtRes", "P_{t} resolution @ DCA;p_{t}^{MC} [GeV/c];#Delta p_{t}/p_{t}^{MC} [%];SPECIES", kNpt, binsPt, kNdpt, binsDPt, kNspec, binsSpec);
TAxis *az(h->GetZaxis());
+ az->SetLabelOffset(0.015);
for(Int_t i(0); i<AliPID::kSPECIES; i++){
- az->SetBinLabel(5-i, AliPID::ParticleLatexName(i));
- az->SetBinLabel(7+i, AliPID::ParticleLatexName(i));
+ az->SetBinLabel(2*i+1, Form("%s^{-}", AliPID::ParticleLatexName(i)));
+ az->SetBinLabel(2*i+2, Form("%s^{+}", AliPID::ParticleLatexName(i)));
+ az->SetBinLabel(10+2*i+1, Form("%s^{-}", AliPID::ParticleLatexName(i)));
+ az->SetBinLabel(10+2*i+2, Form("%s^{+}", AliPID::ParticleLatexName(i)));
}
} else h->Reset();
fHistos->AddAt(h, kPtRes);
+ // TPC event vertex distribution
+ if(!(h = (TH1F*)gROOT->FindObject("hTPCVertex"))){
+ h = new TH1F("hTPCVertex", "Event vertex Z coord. from TPC tracks", 100, -25., 25.);
+ } else h->Reset();
+ fHistos->AddAt(h, kTPCVertex);
+
+ // Event vertex
+ if(!(h = (TH1F*)gROOT->FindObject("hEventVertex"))){
+ h = new TH1F("hEventVertex", "Event vertex Z coord.", 100, -25., 25.);
+ } else h->Reset();
+ fHistos->AddAt(h, kEventVertex);
+
+ // Number of all tracks
+ if(!(h = (TH1I*)gROOT->FindObject("hNTracksAll"))){
+ h = new TH1I("hNTracksAll", "Number of tracks per event, event vertex cuts", 5000, 0, 5000);
+ } else h->Reset();
+ fHistos->AddAt(h, kNTracksAll);
+
+ // Number of tracks in acceptance and DCA cut
+ if(!(h = (TH1I*)gROOT->FindObject("hNTracksAcc"))){
+ h = new TH1I("hNTracksAcc", Form("Number of tracks per event, |#eta|<%.1f, |DCAxy|<%.1f, |DCAz|<%.1f",
+ fgkEta, fgkTrkDCAxy, fgkTrkDCAz), 5000, 0, 5000);
+ } else h->Reset();
+ fHistos->AddAt(h, kNTracksAcc);
+
+ // Number of tracks in TPC (Ncls>10)
+ if(!(h = (TH1I*)gROOT->FindObject("hNTracksTPC"))){
+ h = new TH1I("hNTracksTPC", Form("Number of tracks per event, |#eta|<%.1f, pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 5000, 0, 5000);
+ } else h->Reset();
+ fHistos->AddAt(h, kNTracksTPC);
+
+ // Distribution of DCA-xy
+ if(!(h = (TH1F*)gROOT->FindObject("hDCAxy"))){
+ h = new TH1F("hDCAxy", "Distribution of transverse DCA", 100, -100., 100.);
+ } else h->Reset();
+ fHistos->AddAt(h, kDCAxy);
+
+ // Distribution of DCA-z
+ if(!(h = (TH1F*)gROOT->FindObject("hDCAz"))){
+ h = new TH1F("hDCAz", "Distribution of longitudinal DCA", 100, -100., 100.);
+ } else h->Reset();
+ fHistos->AddAt(h, kDCAz);
+
+ Double_t binPtLimits[33] = {0.0, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9,
+ 1.0, 1.1, 1.2, 1.3, 1.4,
+ 1.6, 1.8, 2.0, 2.2, 2.4, 2.6, 2.8, 3.0,
+ 3.4, 3.8, 4.2, 4.6, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0};
+ // Pt distributions
+ if(!(h = (TH1F*)gROOT->FindObject("hPt1"))){
+ h = new TH1F("hPt1", Form("dN/dpt, |#eta|<%.1f and pt>%.1f", fgkEta, fgkPt), 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kPt1);
+
+ if(!(h = (TH1F*)gROOT->FindObject("hPt2"))){
+ h = new TH1F("hPt2", Form("dN/dpt, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz), 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kPt2);
+
+ if(!(h = (TH1F*)gROOT->FindObject("hPt3pos"))){
+ h = new TH1F("hPt3pos", Form("dN/dpt (positives), |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kPt3pos);
+
+ if(!(h = (TH1F*)gROOT->FindObject("hPt3neg"))){
+ h = new TH1F("hPt3neg", Form("dN/dpt (negatives), |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kPt3neg);
+
+ if(!(h = (TH1F*)gROOT->FindObject("hPt4pos"))){
+ h = new TH1F("hPt4pos", Form("dN/dpt (positives), |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq 1",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kPt4pos);
+
+ if(!(h = (TH1F*)gROOT->FindObject("hPt4neg"))){
+ h = new TH1F("hPt4pos", Form("dN/dpt (negatives), |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq 1",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kPt4neg);
+
+ // theta distribution of TRD tracks
+ if(!(h = (TH1F*)gROOT->FindObject("hTheta"))){
+ h = new TH1F("hTheta", Form("dN/d#theta, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq 1",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 220,.5,2.7);
+ } else h->Reset();
+ fHistos->AddAt(h, kTheta);
+
+ // phi distribution of TRD tracks
+ if(!(h = (TH1F*)gROOT->FindObject("hPhi"))){
+ h = new TH1F("hPhi", Form("dN/d#varphi, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq 1",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 157,0,6.28);
+ } else h->Reset();
+ fHistos->AddAt(h, kPhi);
+
+ // TPC cluster distribution
+ if(!(h = (TH1F*)gROOT->FindObject("hNTPCCl"))){
+ h = new TH1I("hNTPCCl", Form("Number of TPC clusters/track, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz), 160, 0, 160);
+ } else h->Reset();
+ fHistos->AddAt(h, kNTPCCl);
+
+ if(!(h = (TH1I*)gROOT->FindObject("hNTPCCl2"))){
+ h = new TH1F("hNTPCCl2", Form("Number of TPC clusters/track, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, pt>1.0 GeV/c",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz), 160, 0, 160);
+ } else h->Reset();
+ fHistos->AddAt(h, kNTPCCl2);
+
+ // dE/dx vs P for TPC reference tracks
+ if(!(h = (TH2F*)gROOT->FindObject("hTPCDedx"))){
+ h = new TH2F("hTPCDedx", Form("TPC dE/dx vs P, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, 0.1,10.1, 150, 0, 150.);
+ } else h->Reset();
+ fHistos->AddAt(h, kTPCDedx);
+
+ // eta,phi distribution of TPC reference tracks
+ if(!(h = (TH2F*)gROOT->FindObject("hEtaPhi"))){
+ h = new TH2F("hEtaPhi", Form("TPC (#eta,#varphi), |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 50, -1, 1, 157, 0, 6.28);
+ } else h->Reset();
+ fHistos->AddAt(h, kEtaPhi);
+
+ // Nclusters vs eta distribution for TPC tracks
+ if(!(h = (TH2F*)gROOT->FindObject("hEtaNclsTPC"))){
+ h = new TH2F("hEtaNclsTPC", Form("TPC Nclusters vs. #eta, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz), 50, -1, 1, 160, 0, 160.);
+ } else h->Reset();
+ fHistos->AddAt(h, kEtaNclsTPC);
+
+ // Nclusters vs phi distribution for TPC reference tracks
+ if(!(h = (TH2F*)gROOT->FindObject("hPhiNclsTPC"))){
+ h = new TH2F("hPhiNclsTPC", Form("TPC Nclusters vs. #varphi, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz), 157, 0, 6.28, 160, 0, 160.);
+ } else h->Reset();
+ fHistos->AddAt(h, kPhiNclsTPC);
+
+ // SPD multiplicity distribution
+ if(!(h = (TH1F*)gROOT->FindObject("hSPDMult"))){
+ h = new TH1F("hSPDMult", "SPD multiplicity", 10000, -0.5, 9999.5);
+ } else h->Reset();
+ fHistos->AddAt(h, kSPDMult);
+
+ // Ntracklets/track vs P for TRD reference tracks
+ Double_t binsP[19] = {0.0, 0.2, 0.4, 0.6, 0.8, 1.0, 1.2, 1.4, 1.7, 2.0,
+ 2.5, 3.0, 3.5, 4.0, 5.0, 6.0, 7.0, 9.0, 12.0};
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH2F*)gROOT->FindObject(Form("hNTrackletsTRD_cent%d",iCent+1)))){
+ h = new TH2F(Form("hNTrackletsTRD_cent%d",iCent+1), Form("TRD Ntracklets/track vs. P, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 18, binsP, 7, -0.5, 6.5);
+ } else h->Reset();
+ fHistos->AddAt(h, kNTrackletsTRD+iCent);
+ }
+
+ // Nclusters/track vs P for TRD reference tracks
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH2F*)gROOT->FindObject(Form("hNClsTrackTRD_cent%d",iCent+1)))){
+ h = new TH2F(Form("hNClsTrackTRD_cent%d",iCent+1), Form("TRD Nclusters/track vs. P, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 18, binsP, 300, 0., 300.);
+ } else h->Reset();
+ fHistos->AddAt(h, kNClsTrackTRD+iCent);
+ }
+
+ // <PH> vs slice number for TRD reference tracklets
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH2F*)gROOT->FindObject(Form("hPHSlice_cent%d",iCent+1)))){
+ h = new TH2F(Form("hPHSlice_cent%d",iCent+1), Form("<PH> vs sliceNo, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 8, -0.5, 7.5, 200, 0., 2000.);
+ } else h->Reset();
+ fHistos->AddAt(h, kPHSlice+iCent);
+ }
+
+ // <PH> vs slice number for TRD reference tracklets, from TPC pions
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH2F*)gROOT->FindObject(Form("hPHSliceTPCpions_cent%d",iCent+1)))){
+ h = new TH2F(Form("hPHSliceTPCpions_cent%d",iCent+1), Form("<PH> vs sliceNo, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, TPC pions",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 8, -0.5, 7.5, 100, 0., 2000.);
+ } else h->Reset();
+ fHistos->AddAt(h, kPHSliceTPCpions+iCent);
+ }
+
+ // TPC dE/dx vs P for TRD reference tracks, pions
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH2F*)gROOT->FindObject(Form("hTPCdedxPions_cent%d",iCent+1)))){
+ h = new TH2F(Form("hTPCdedxPions_cent%d",iCent+1), Form("TPC dE/dx vs P, TPC pions, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, 0.1,10.1, 100, 0,100.);
+ } else h->Reset();
+ fHistos->AddAt(h, kTPCdedxPions+iCent);
+ }
+
+ // <PH> vs slice number for TRD reference tracklets, from TPC electrons
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH2F*)gROOT->FindObject(Form("hPHSliceTPCelectrons_cent%d",iCent+1)))){
+ h = new TH2F(Form("hPHSliceTPCelectrons_cent%d",iCent+1), Form("<PH> vs sliceNo, centrality %d,|#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, TPC electrons",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 8, -0.5, 7.5, 100, 0., 2000.);
+ } else h->Reset();
+ fHistos->AddAt(h, kPHSliceTPCelectrons+iCent);
+ }
+
+ // TPC dE/dx vs P for TRD reference tracks, electrons
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH2F*)gROOT->FindObject(Form("hTPCdedxElectrons_cent%d",iCent+1)))){
+ h = new TH2F(Form("hTPCdedxElectrons_cent%d",iCent+1), Form("TPC dE/dx vs P, TPC electrons, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, 0.1,10.1, 100, 0,100.);
+ } else h->Reset();
+ fHistos->AddAt(h, kTPCdedxElectrons+iCent);
+ }
+
+ // Qtot vs P for TRD reference tracklets
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH2F*)gROOT->FindObject(Form("hQtotP_cent%d",iCent+1)))){
+ h = new TH2F(Form("hQtotP_cent%d",iCent+1), Form("Qtot(from slices) vs P, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 18, binsP, 400, 0., 20);
+ } else h->Reset();
+ fHistos->AddAt(h, kQtotP+iCent);
+ }
+
+ // (X,Y,momentum) distribution after AliESDtrack::PropagateTo(r=300.)
+ if(!(h = (TH3F*)gROOT->FindObject("hPropagXYvsP"))){
+ h = new TH3F("hPropagXYvsP", Form("(x,y) vs P after AliESDtrack::PropagateTo(r=300.), |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100,-500,500, 100,-500,500, 10, 0.,10.);
+ } else h->Reset();
+ fHistos->AddAt(h, kPropagXYvsP);
+
+ // (R,Z,momentum) distribution after AliESDtrack::PropagateTo(r=300.)
+ if(!(h = (TH3F*)gROOT->FindObject("hPropagRZvsP"))){
+ h = new TH3F("hPropagRZvsP", Form("(r,z) vs P after AliESDtrack::PropagateTo(r=300.), |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100,-350., 350., 100,0.,500., 10, 0.,10.);
+ } else h->Reset();
+ fHistos->AddAt(h, kPropagRZvsP);
+
+ Double_t etaBinLimits[101];
+ for(Int_t i=0; i<101; i++) etaBinLimits[i] = -1.0 + i*2.0/100.;
+ Double_t phiBinLimits[151];
+ for(Int_t i=0; i<151; i++) phiBinLimits[i] = -1.1*TMath::Pi() + i*2.2*TMath::Pi()/150.;
+ // (eta,detector phi,P) distribution of reference TPC positive tracks
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH3F*)gROOT->FindObject(Form("hTPCRefTracksPos_cent%d",iCent+1)))){
+ h = new TH3F(Form("hTPCRefTracksPos_cent%d",iCent+1), Form("(#eta,detector #varphi,p) for TPC positive reference tracks, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, etaBinLimits, 150, phiBinLimits, 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kTPCRefTracksPos+iCent);
+ }
+
+ // (eta,detector phi,P) distribution of reference TPC negative tracks
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH3F*)gROOT->FindObject(Form("hTPCRefTracksNeg_cent%d",iCent+1)))){
+ h = new TH3F(Form("hTPCRefTracksNeg_cent%d",iCent+1), Form("(#eta,detector #varphi,p) for TPC negative reference tracks, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, etaBinLimits, 150, phiBinLimits, 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kTPCRefTracksNeg+iCent);
+ }
+
+ // (eta,detector phi,P) distribution of reference TRD positive tracks
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH3F*)gROOT->FindObject(Form("hTRDRefTracksPos_cent%d",iCent+1)))){
+ h = new TH3F(Form("hTRDRefTracksPos_cent%d",iCent+1), Form("(#eta,detector #varphi,p) for TRD positive reference tracks, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq1",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, etaBinLimits, 150, phiBinLimits, 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kTRDRefTracksPos+iCent);
+ }
+
+ // (eta,detector phi,P) distribution of reference TRD negative tracks
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH3F*)gROOT->FindObject(Form("hTRDRefTracksNeg_cent%d",iCent+1)))){
+ h = new TH3F(Form("hTRDRefTracksNeg_cent%d",iCent+1), Form("(#eta,detector #varphi,p) for TRD negative reference tracks, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq1",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, etaBinLimits, 150, phiBinLimits, 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kTRDRefTracksNeg+iCent);
+ }
+
+ // (eta,detector phi,P) distribution of reference TRD positive tracks with 4 tracklets
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH3F*)gROOT->FindObject(Form("hTRDRefTracksPos4_cent%d",iCent+1)))){
+ h = new TH3F(Form("hTRDRefTracksPos4_cent%d",iCent+1), Form("(#eta,detector #varphi,p) for TRD positive reference tracks, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq1",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, etaBinLimits, 150, phiBinLimits, 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kTRDRefTracksPos4+iCent);
+ }
+
+ // (eta,detector phi,P) distribution of reference TRD positive tracks with 5 tracklets
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH3F*)gROOT->FindObject(Form("hTRDRefTracksPos5_cent%d",iCent+1)))){
+ h = new TH3F(Form("hTRDRefTracksPos5_cent%d",iCent+1), Form("(#eta,detector #varphi,p) for TRD positive reference tracks, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq1",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, etaBinLimits, 150, phiBinLimits, 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kTRDRefTracksPos5+iCent);
+ }
+
+ // (eta,detector phi,P) distribution of reference TRD positive tracks with 6 tracklets
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH3F*)gROOT->FindObject(Form("hTRDRefTracksPos6_cent%d",iCent+1)))){
+ h = new TH3F(Form("hTRDRefTracksPos6_cent%d",iCent+1), Form("(#eta,detector #varphi,p) for TRD positive reference tracks, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq1",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, etaBinLimits, 150, phiBinLimits, 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kTRDRefTracksPos6+iCent);
+ }
+
+ // (eta,detector phi,P) distribution of reference TRD negative tracks with 4 tracklets
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH3F*)gROOT->FindObject(Form("hTRDRefTracksNeg4_cent%d",iCent+1)))){
+ h = new TH3F(Form("hTRDRefTracksNeg4_cent%d",iCent+1), Form("(#eta,detector #varphi,p) for TRD negative reference tracks, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq1",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, etaBinLimits, 150, phiBinLimits, 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kTRDRefTracksNeg4+iCent);
+ }
+
+ // (eta,detector phi,P) distribution of reference TRD negative tracks with 5 tracklets
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH3F*)gROOT->FindObject(Form("hTRDRefTracksNeg5_cent%d",iCent+1)))){
+ h = new TH3F(Form("hTRDRefTracksNeg5_cent%d",iCent+1), Form("(#eta,detector #varphi,p) for TRD negative reference tracks, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq1",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, etaBinLimits, 150, phiBinLimits, 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kTRDRefTracksNeg5+iCent);
+ }
+
+ // (eta,detector phi,P) distribution of reference TRD negative tracks with 6 tracklets
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TH3F*)gROOT->FindObject(Form("hTRDRefTracksNeg6_cent%d",iCent+1)))){
+ h = new TH3F(Form("hTRDRefTracksNeg6_cent%d",iCent+1), Form("(#eta,detector #varphi,p) for TRD negative reference tracks, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq1",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, etaBinLimits, 150, phiBinLimits, 32, binPtLimits);
+ } else h->Reset();
+ fHistos->AddAt(h, kTRDRefTracksNeg6+iCent);
+ }
+
+
+ // (eta,detector phi) profile of average number of TRD tracklets/track
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TProfile2D*)gROOT->FindObject(Form("hTRDEtaPhiAvNtrkl_cent%d",iCent+1)))){
+ h = new TProfile2D(Form("hTRDEtaPhiAvNtrkl_cent%d",iCent+1), Form("<Ntracklets/track> vs (#eta,detector #varphi) for TRD reference tracks, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq1",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, -1.0, 1.0, 150, -1.1*TMath::Pi(), 1.1*TMath::Pi());
+ } else h->Reset();
+ fHistos->AddAt(h, kTRDEtaPhiAvNtrkl+iCent);
+ }
+
+ // (eta,delta phi) profile of average number of TRD tracklets/track
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ if(!(h = (TProfile2D*)gROOT->FindObject(Form("hTRDEtaDeltaPhiAvNtrkl_cent%d",iCent+1)))){
+ h = new TProfile2D(Form("hTRDEtaDeltaPhiAvNtrkl_cent%d",iCent+1), Form("<Ntracklets/track> vs (#eta, #Delta#varphi) for TRD reference tracks, centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq1",
+ iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, -1.0, 1.0, 50, -0.4*TMath::Pi(), 0.4*TMath::Pi());
+ } else h->Reset();
+ fHistos->AddAt(h, kTRDEtaDeltaPhiAvNtrkl+iCent);
+ }
+
+ // (eta, detector phi) profile of average tracklet Qtot from slices
+ for(Int_t iCent=0; iCent<=5; ++iCent) {
+ for(Int_t iLayer=0;iLayer<6;iLayer++) {
+ if(!(h = (TProfile2D*)gROOT->FindObject(Form("hTRDEtaPhiAvQtot_Layer%d_cent%d",iLayer,iCent+1)))) {
+ h = new TProfile2D(Form("hTRDEtaPhiAvQtot_Layer%d_cent%d",iLayer,iCent+1),
+ Form("<Q_{tot}> vs (#eta, detector #varphi) for TRD reference tracks (layer %d), centrality %d, |#eta|<%.1f and pt>%.1f, |DCAxy|<%.1f, |DCAz|<%.1f, TPC nclusters>%d, nTRDtracklets#geq1",
+ iLayer, iCent+1, fgkEta, fgkPt, fgkTrkDCAxy, fgkTrkDCAz, fgkNclTPC), 100, -1.0, 1.0, 150, -1.1*TMath::Pi(), 1.1*TMath::Pi());
+ } else h->Reset();
+ fHistos->AddAt(h, kTRDEtaPhiAvQtot+iCent*6+iLayer);
+ }
+ }
+
+ // create a CF container and add it to the list of histograms
+ Int_t nbinsCf[kNTrdCfVariables];
+ for(Int_t i=0;i<kNTrdCfVariables;++i) nbinsCf[i]=0;
+ nbinsCf[kEventVtxZ] = 12;
+ nbinsCf[kEventMult] = 5;
+ nbinsCf[kEventBC] = 3500;
+ nbinsCf[kTrackTOFdeltaBC] = 2001;
+ nbinsCf[kTrackTOFBC] = 201;
+ nbinsCf[kTrackDCAxy] = 26;
+ nbinsCf[kTrackDCAz] = 101;
+ nbinsCf[kTrackCharge] = 2;
+ nbinsCf[kTrackPhi] = 150;
+ nbinsCf[kTrackEta] = 100;
+ nbinsCf[kTrackPt] = 32;
+ nbinsCf[kTrackP] = 18;
+ nbinsCf[kTrackTrdTracklets] = 7;
+ nbinsCf[kTrackTrdClusters] = 200;
+ for(Int_t i=0;i<6;++i) nbinsCf[kTrackQtot+i] = 100;
+ Double_t evVtxLims[2] = {-12.,+12.};
+ Double_t evMultLims[6] = {0.0, 700., 1400., 2100., 2800., 3500.};
+ Double_t evBCLims[2] = {-0.5, +3499.5};
+ Double_t trkTOFdeltaBClims[2] = {-1000.5, 1000.5};
+ Double_t trkTOFBClims[2] = {-100.5, 100.5};
+ Double_t trkDCAxyLims[27] = {-50.0, -40.0, -30.0, -25.0, -20.0,
+ -15.0, -10.0, -8.0, -6.0, -4.0,
+ -3.0, -2.0, -1.0, 0.0, +1.0,
+ +2.0, +3.0, +4.0, +6.0, +8.0,
+ +10.0, +15.0, +20.0, +25.0, +30.0,
+ +40.0, +50.0};
+ Double_t trkDCAzLims[2] = {-50.5, +50.5};
+ Double_t trkChargeLims[2] = {-1.5, +1.5};
+ Double_t trkPhiLims[2] = {-1.1*TMath::Pi(), +1.1*TMath::Pi()};
+ Double_t trkEtaLims[2] = {-1.0, +1.0};
+ Double_t trkPtLims[33] = {0.0, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9,
+ 1.0, 1.1, 1.2, 1.3, 1.4, 1.6, 1.8, 2.0, 2.2, 2.4,
+ 2.6, 2.8, 3.0, 3.4, 3.8, 4.2, 4.6, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0};
+ Double_t trkPLims[19] = {0.0, 0.2, 0.4, 0.6, 0.8, 1.0, 1.2, 1.4, 1.7, 2.0,
+ 2.5, 3.0, 3.5, 4.0, 5.0, 6.0, 7.0, 9.0, 12.0};
+ Double_t trkTrdNLims[2] = {-0.5, 6.5};
+ Double_t trkTrdNclsLims[2] = {-0.5, 199.5};
+ Double_t trkQtotLims[2] = {0.0, 20.};
+ fCfContainer = new AliCFContainer("TrdCfContainer", "TRD ESD CF container", 3, kNTrdCfVariables, nbinsCf);
+ fCfContainer->SetBinLimits(kEventVtxZ, evVtxLims[0], evVtxLims[1]);
+ fCfContainer->SetBinLimits(kEventMult, evMultLims);
+ fCfContainer->SetBinLimits(kEventBC, evBCLims[0], evBCLims[1]);
+ fCfContainer->SetBinLimits(kTrackTOFdeltaBC, trkTOFdeltaBClims[0], trkTOFdeltaBClims[1]);
+ fCfContainer->SetBinLimits(kTrackTOFBC, trkTOFBClims[0], trkTOFBClims[1]);
+ fCfContainer->SetBinLimits(kTrackDCAxy, trkDCAxyLims);
+ fCfContainer->SetBinLimits(kTrackDCAz, trkDCAzLims[0], trkDCAzLims[1]);
+ fCfContainer->SetBinLimits(kTrackCharge, trkChargeLims[0], trkChargeLims[1]);
+ fCfContainer->SetBinLimits(kTrackPhi, trkPhiLims[0], trkPhiLims[1]);
+ fCfContainer->SetBinLimits(kTrackEta, trkEtaLims[0], trkEtaLims[1]);
+ fCfContainer->SetBinLimits(kTrackPt, trkPtLims);
+ fCfContainer->SetBinLimits(kTrackP, trkPLims);
+ fCfContainer->SetBinLimits(kTrackTrdTracklets, trkTrdNLims[0], trkTrdNLims[1]);
+ fCfContainer->SetBinLimits(kTrackTrdClusters, trkTrdNclsLims[0], trkTrdNclsLims[1]);
+ for(Int_t i=0; i<6; ++i) fCfContainer->SetBinLimits(kTrackQtot+i, trkQtotLims[0], trkQtotLims[1]);
+ fCfContainer->SetVarTitle(kEventVtxZ, "vtxZ");
+ fCfContainer->SetVarTitle(kEventMult, "multiplicity");
+ fCfContainer->SetVarTitle(kEventBC, "BC");
+ fCfContainer->SetVarTitle(kTrackTOFdeltaBC, "TOFdeltaBC");
+ fCfContainer->SetVarTitle(kTrackTOFBC, "TOFBC");
+ fCfContainer->SetVarTitle(kTrackDCAxy, "DCAxy");
+ fCfContainer->SetVarTitle(kTrackDCAz, "DCAz");
+ fCfContainer->SetVarTitle(kTrackCharge, "charge");
+ fCfContainer->SetVarTitle(kTrackPhi, "phi");
+ fCfContainer->SetVarTitle(kTrackEta, "eta");
+ fCfContainer->SetVarTitle(kTrackPt, "pt");
+ fCfContainer->SetVarTitle(kTrackP, "P");
+ fCfContainer->SetVarTitle(kTrackTrdTracklets, "tracklets");
+ fCfContainer->SetVarTitle(kTrackTrdClusters, "clusters");
+ for(Int_t i=0; i<6; ++i) fCfContainer->SetVarTitle(kTrackQtot+i, Form("Qtot%d",i));
+
+ fCfContainer->SetStepTitle(0, "TPC reference");
+ fCfContainer->SetStepTitle(1, "TRD");
+ fCfContainer->SetStepTitle(2, "TOF");
+
+ // fHistos->AddAt(fCfContainer, kNhistos);
+ fHistos->AddAt(fCfContainer, 0);
+
return fHistos;
}
//____________________________________________________________________
-Bool_t AliTRDcheckESD::Load(const Char_t *filename, const Char_t *name)
+Bool_t AliTRDcheckESD::Load(const Char_t *file, const Char_t *dir, const Char_t *name)
{
// Load data from performance file
- if(!TFile::Open(filename)){
- AliWarning(Form("Couldn't open file %s.", filename));
+ if(!TFile::Open(file)){
+ AliWarning(Form("Couldn't open file %s.", file));
return kFALSE;
}
- TObjArray *o = NULL;
- if(!(o = (TObjArray*)gFile->Get(name ? name : GetName()))){
- AliWarning("Missing histogram container.");
+ if(dir){
+ if(!gFile->cd(dir)){
+ AliWarning(Form("Couldn't cd to %s in %s.", dir, file));
+ return kFALSE;
+ }
+ }
+ TObjArray *o(NULL);
+ const Char_t *tn=(name ? name : GetName());
+ if(!(o = (TObjArray*)gDirectory->Get(tn))){
+ AliWarning(Form("Missing histogram container %s.", tn));
return kFALSE;
}
fHistos = (TObjArray*)o->Clone(GetName());
+ fCfContainer = (AliCFContainer*)fHistos->At(0);
gFile->Close();
- SETBIT(fStatus, kLoad);
return kTRUE;
}
//____________________________________________________________________
void AliTRDcheckESD::Terminate(Option_t *)
{
-// Steer post-processing
- if(!IsLoad()){
+ // Steer post-processing
+ if(!fHistos){
fHistos = dynamic_cast<TObjArray *>(GetOutputData(1));
if(!fHistos){
AliError("Histogram container not found in output");
}
}
+ // fNRefFigures = 15;
+ // return;
+
const Char_t *name[kNrefs] = {
"Ncl", "Eff", "Eloss", "PtResDCA"
};
+
TObjArray *arr(NULL); TGraph *g(NULL);
if(!fResults){
fResults = new TObjArray(kNrefs);
for(Int_t iref(0); iref<kNrefs; iref++){
fResults->AddAt(arr = new TObjArray(fgkNgraph[iref]), iref);
arr->SetName(name[iref]); arr->SetOwner();
- switch(iref){
+ switch(iref+1){
+ case kNCl:
+ for(Int_t ig(0); ig<fgkNgraph[iref]; ig++){
+ arr->AddAt(g = new TGraphErrors(), ig);
+ g->SetLineColor(ig+1);
+ g->SetMarkerColor(ig+1);
+ g->SetMarkerStyle(ig+20);
+ g->SetName(Form("s%d", ig));
+ switch(ig){
+ case 0: g->SetTitle("ALL"); break;
+ case 1: g->SetTitle("NEG"); break;
+ case 2: g->SetTitle("POS"); break;
+ default: g->SetTitle(AliPID::ParticleLatexName(ig-3)); break;
+ };
+ }
+ break;
case kTRDmom:
- for(Int_t ig(0); ig<fgkNgraph[iref]; ig++){
+ for(Int_t ig(0); ig<fgkNgraph[iref]; ig++){
arr->AddAt(g = new TGraphAsymmErrors(), ig);
g->SetLineColor(ig+1);
g->SetMarkerColor(ig+1);
}
break;
case kPtRes:
- for(Int_t im(fgkNgraph[iref]/2), ig(im), idx(0); ig--; idx+=ig){
- arr->AddAt(g = new TGraphErrors(), ig);
+ for(Int_t idx(0); idx<AliPID::kSPECIES; idx++){
+ Int_t ig(2*idx);
+ arr->AddAt(g = new TGraphErrors(), ig);
+ g->SetLineColor(kRed-idx);
+ g->SetMarkerColor(kRed-idx);
+ g->SetMarkerStyle(20+idx);
+ g->SetNameTitle(Form("s%d", ig), Form("res %s", AliPID::ParticleLatexName(idx)));
+ arr->AddAt(g = new TGraphErrors(), ig+1);
+ g->SetLineColor(kBlue-idx);
+ g->SetMarkerColor(kBlue-idx);
+ g->SetMarkerStyle(20+idx);
+ g->SetNameTitle(Form("m%d", ig+1), Form("sys %s", AliPID::ParticleLatexName(idx)));
+
+ ig+=10;
+ arr->AddAt(g = new TGraphErrors(), ig);
g->SetLineColor(kRed-idx);
g->SetMarkerColor(kRed-idx);
- g->SetMarkerStyle(20+ig);
- g->SetNameTitle(Form("s%d", ig), Form("res %s", AliPID::ParticleLatexName(ig)));
- arr->AddAt(g = new TGraphErrors(), im+ig);
+ g->SetMarkerStyle(20+idx);
+ g->SetNameTitle(Form("s%d", ig), Form("sigma %s", AliPID::ParticleLatexName(idx)));
+ arr->AddAt(g = new TGraphErrors(), ig+1);
g->SetLineColor(kBlue-idx);
g->SetMarkerColor(kBlue-idx);
- g->SetMarkerStyle(20+ig);
- g->SetNameTitle(Form("m%d", ig), Form("sys %s", AliPID::ParticleLatexName(ig)));
+ g->SetMarkerStyle(20+idx);
+ g->SetNameTitle(Form("m%d", ig+1), Form("mean %s", AliPID::ParticleLatexName(idx)));
}
break;
default:
- for(Int_t ig(0); ig<fgkNgraph[iref]; ig++){
+ for(Int_t ig(0); ig<fgkNgraph[iref]; ig++){
arr->AddAt(g = new TGraphErrors(), ig);
g->SetLineColor(ig+1);
g->SetMarkerColor(ig+1);
}
}
}
+ TH1 *h1[2] = {NULL, NULL};
+ TH2I *h2(NULL);
+ TAxis *ax(NULL);
+
+ // No of clusters
+ if(!(h2 = (TH2I*)fHistos->At(kNCl))) return;
+ ax = h2->GetXaxis();
+ arr = (TObjArray*)fResults->At(kNCl);
+
+ // All tracks
+ h1[0] = h2->ProjectionX("Ncl_px");
+ TGraphErrors *ge=(TGraphErrors*)arr->At(0);
+ for(Int_t ib=2; ib<=ax->GetNbins(); ib++){
+ ge->SetPoint(ib-2, ax->GetBinCenter(ib), h1[0]->GetBinContent(ib));
+ }
+
+ // All charged tracks
+ TH1 *hNclCh[2] = {(TH1D*)h1[0]->Clone("NEG"), (TH1D*)h1[0]->Clone("POS")};
+ hNclCh[0]->Reset();hNclCh[1]->Reset();
+ for(Int_t is(1); is<=AliPID::kSPECIES; is++){
+ hNclCh[0]->Add(h2->ProjectionX("Ncl_px", 2*is-1, 2*is-1)); // neg
+ hNclCh[1]->Add(h2->ProjectionX("Ncl_px", 2*is, 2*is)); // pos
+ }
+ if(Int_t(hNclCh[0]->GetEntries())){
+ ge=(TGraphErrors*)arr->At(1);
+ for(Int_t ib=2; ib<=ax->GetNbins(); ib++){
+ ge->SetPoint(ib-2, ax->GetBinCenter(ib), hNclCh[0]->GetBinContent(ib));
+ }
+ }
+
+ if(Int_t(hNclCh[1]->GetEntries())){
+ ge=(TGraphErrors*)arr->At(2);
+ for(Int_t ib=2; ib<=ax->GetNbins(); ib++){
+ ge->SetPoint(ib-2, ax->GetBinCenter(ib), hNclCh[1]->GetBinContent(ib));
+ }
+ }
+ // Species wise
+ for(Int_t is(1); is<=AliPID::kSPECIES; is++){
+ h1[0] = h2->ProjectionX("Ncl_px", 2*is-1, 2*is);
+ if(!Int_t(h1[0]->GetEntries())) continue;
+ ge=(TGraphErrors*)arr->At(2+is);
+ for(Int_t ib=2; ib<=ax->GetNbins(); ib++){
+ ge->SetPoint(ib-2, ax->GetBinCenter(ib), h1[0]->GetBinContent(ib));
+ }
+ }
+
fNRefFigures = 1;
// EFFICIENCY
// geometrical efficiency
- TH2I *h2(NULL);
if(!(h2 = (TH2I*)fHistos->At(kTRDstat))) return;
- arr = (TObjArray*)fResults->At(kTRDstat);
- TH1 *h1[2] = {NULL, NULL};
+ arr = (TObjArray*)fResults->At(kTRDstat-1);
h1[0] = h2->ProjectionX("checkESDx0", kTPCout, kTPCout);
h1[1] = h2->ProjectionX("checkESDx1", kTRDin, kTRDin);
Process(h1, (TGraphErrors*)arr->At(0));
// ENERGY LOSS
if(!(h2 = dynamic_cast<TH2I*>(fHistos->At(kTRDmom)))) return;
- arr = (TObjArray*)fResults->At(kTRDmom);
+ arr = (TObjArray*)fResults->At(kTRDmom-1);
TGraphAsymmErrors *g06 = (TGraphAsymmErrors*)arr->At(0), *g09 = (TGraphAsymmErrors*)arr->At(1);
- TAxis *ax=h2->GetXaxis();
+ ax=h2->GetXaxis();
const Int_t nq(4);
const Double_t xq[nq] = {0.05, 0.2, 0.8, 0.95};
Double_t yq[nq];
delete h1[0];
}
fNRefFigures++;
- if(!HasMC()) return;
+// if(!HasMC()) return;
// Pt RESOLUTION @ DCA
TH3S* h3(NULL); TGraphErrors *gg[2] = {NULL,NULL};
if(!(h3 = dynamic_cast<TH3S*>(fHistos->At(kPtRes)))) return;
- arr = (TObjArray*)fResults->At(kPtRes);
+ arr = (TObjArray*)fResults->At(kPtRes-1);
TAxis *az(h3->GetZaxis());
for(Int_t i(0); i<AliPID::kSPECIES; i++){
- az->SetRange(5-i, 5-i);
- gg[1] = (TGraphErrors*)arr->At(4-i);
- gg[0] = (TGraphErrors*)arr->At(9-i);
+ Int_t idx(2*i);
+ az->SetRange(idx+1, idx+2);
+ gg[1] = (TGraphErrors*)arr->At(idx);
+ gg[0] = (TGraphErrors*)arr->At(idx+1);
+ Process2D((TH2*)h3->Project3D("yx"), gg);
+
+ idx+=10;
+ az->SetRange(idx+1, idx+2);
+ gg[1] = (TGraphErrors*)arr->At(idx);
+ gg[0] = (TGraphErrors*)arr->At(idx+1);
Process2D((TH2*)h3->Project3D("yx"), gg);
- //az->SetRange(7+i, 7+i);
- //Process2D((TH2*)h3->Project3D("yx"), gg);
}
fNRefFigures++;
+
+ fNRefFigures++;
+ // 3x3 tracking summary canvases for every centrality class
+ fNRefFigures++;
+ // 3x3 PID summary canvases for every centrality class
+ fNRefFigures++;
+ // 3x3 for centrality dependent pictures
+ fNRefFigures++;
+
+ //DoTrending();
}
//____________________________________________________________________
-Int_t AliTRDcheckESD::Pdg2Idx(Int_t pdg)
+Int_t AliTRDcheckESD::Pdg2Idx(Int_t pdg) const
{
+ //
+ // Helper function converting PDG code into AliPID index
+ //
switch(pdg){
- case kElectron: return AliPID::kElectron+1;
- case kMuonMinus: return AliPID::kMuon+1;
- case kPiPlus: return AliPID::kPion+1;
- case kKPlus: return AliPID::kKaon+1;
- case kProton: return AliPID::kProton+1;
+ case kElectron:
+ case kPositron: return AliPID::kElectron;
+ case kMuonPlus:
+ case kMuonMinus: return AliPID::kMuon;
+ case kPiPlus:
+ case kPiMinus: return AliPID::kPion;
+ case kKPlus:
+ case kKMinus: return AliPID::kKaon;
+ case kProton:
+ case kProtonBar: return AliPID::kProton;
}
- return 0;
+ return -1;
}
//____________________________________________________________________
);
}
+//____________________________________________________________________
+TH1D* AliTRDcheckESD::Proj2D(TH2* hist) {
+ //
+ // project the PH vs Slice 2D-histo into a 1D histo
+ //
+ /*TH1D* hProjection = new TH1F("hProjection","", hist->GetXaxis()->GetXbins()->GetSize()-1,
+ hist->GetXaxis()->GetXbins()->GetArray());*/
+ TH1D* hProjection = (TH1D*)hist->ProjectionX(Form("hProjection_%f", gRandom->Rndm()));
+ hProjection->Reset();
+ //cout << "Proj2D: nbins = " << hist->GetXaxis()->GetXbins()->GetSize()-1 << endl;
+ TF1* fitLandau = new TF1("landauFunc","landau",0.,2000.);
+ TH1D *hD;
+ for(Int_t iBin=1;iBin<=hist->GetXaxis()->GetNbins();iBin++) {
+ if(gROOT->FindObject("projection"))
+ delete gROOT->FindObject("projection");
+ hD = (TH1D*)hist->ProjectionY("projection",iBin,iBin);
+ hD->Rebin(4);
+ if(hD->Integral()>10) {
+ fitLandau->SetParameter(1, hD->GetBinCenter(hD->GetMaximumBin()));
+ fitLandau->SetParLimits(1, 0.2*hD->GetBinCenter(hD->GetMaximumBin()), 3.0*hD->GetBinCenter(hD->GetMaximumBin()));
+ fitLandau->SetParameter(0, 1000.);
+ fitLandau->SetParLimits(0, 1., 10000000.);
+ fitLandau->SetParameter(2, 0.5*hD->GetBinCenter(hD->GetMaximumBin()));
+ fitLandau->SetParLimits(2, 0.01*hD->GetBinCenter(hD->GetMaximumBin()), 1.0*hD->GetBinCenter(hD->GetMaximumBin()));
+ hD->Fit(fitLandau, "Q0", "", hD->GetXaxis()->GetXmin(), hD->GetXaxis()->GetXmax());
+ hD->Fit(fitLandau, "Q0", "", hD->GetXaxis()->GetXmin(), hD->GetXaxis()->GetXmax());
+ hProjection->SetBinContent(iBin, fitLandau->GetParameter(1));
+ hProjection->SetBinError(iBin, fitLandau->GetParameter(2));
+ }
+ else{
+ hProjection->SetBinContent(iBin, 0);
+ hProjection->SetBinError(iBin, 0);
+ }
+ }
+ return hProjection;
+}
+
+//____________________________________________________________________
+TH2F* AliTRDcheckESD::Proj3D(TH3* hist, TH2* accMap, Int_t zbinLow, Int_t zbinHigh, Float_t &entries) {
+ //
+ // Project a 3D histogram to a 2D histogram in the Z axis interval [zbinLow,zbinHigh]
+ // Return the 2D histogram and also the number of entries into this projection (entries)
+
+ Int_t nBinsX = hist->GetXaxis()->GetNbins(); // X and Y axis bins are assumed to be all equal
+ Float_t minX = hist->GetXaxis()->GetXmin();
+ Float_t maxX = hist->GetXaxis()->GetXmax();
+ Int_t nBinsY = hist->GetYaxis()->GetNbins();
+ Float_t minY = hist->GetYaxis()->GetXmin();
+ Float_t maxY = hist->GetYaxis()->GetXmax();
+ Int_t nBinsZ = hist->GetZaxis()->GetNbins(); // Z axis bins (pt) might have different widths
+
+ TH2F* projHisto = (TH2F*)gROOT->FindObject("projHisto");
+ if(projHisto)
+ projHisto->Reset();
+ else
+ projHisto = new TH2F("projHisto", "projection", nBinsX, minX, maxX, nBinsY, minY, maxY);
+
+ for(Int_t iZ=1; iZ<=nBinsZ; iZ++) {
+ if(iZ<zbinLow) continue;
+ if(iZ>zbinHigh) continue;
+ for(Int_t iX=1; iX<=nBinsX; iX++) {
+ for(Int_t iY=1; iY<=nBinsY; iY++) {
+ if(accMap) {
+ if(accMap->GetBinContent(iX,iY)>0.1)
+ projHisto->SetBinContent(iX, iY, projHisto->GetBinContent(iX, iY)+hist->GetBinContent(iX,iY,iZ));
+ }
+ else // no acc. cut
+ projHisto->SetBinContent(iX, iY, projHisto->GetBinContent(iX, iY)+hist->GetBinContent(iX,iY,iZ));
+ // count only the entries which are inside the acceptance map
+ if(accMap) {
+ if(accMap->GetBinContent(iX,iY)>0.1)
+ entries+=hist->GetBinContent(iX,iY,iZ);
+ }
+ else // no acc. cut
+ entries+=hist->GetBinContent(iX,iY,iZ);
+ }
+ }
+ }
+ return projHisto;
+}
+
+//____________________________________________________________________
+void AliTRDcheckESD::CheckActiveSM(TH1D* phiProj, Bool_t activeSM[18]) {
+ //
+ // Check the active super-modules
+ //
+ Double_t entries[18] = {0.0};
+ Double_t smPhiLimits[19];
+ for(Int_t ism=0; ism<=18; ++ism) smPhiLimits[ism] = -TMath::Pi() + (2.0*TMath::Pi()/18.0)*ism;
+ for(Int_t phiBin=1; phiBin<=phiProj->GetXaxis()->GetNbins(); ++phiBin) {
+ Double_t phi = phiProj->GetBinCenter(phiBin);
+ Int_t sm = -1;
+ for(Int_t ism=0; ism<18; ++ism)
+ if(phi>=smPhiLimits[ism] && phi<smPhiLimits[ism+1]) sm = ism;
+ if(sm==-1) continue;
+ entries[sm] += phiProj->GetBinContent(phiBin);
+ }
+ Double_t avEntries = Double_t(phiProj->Integral())/18.0;
+ for(Int_t ism=0; ism<18; ++ism)
+ if(entries[ism]>0.5*avEntries) activeSM[ism] = kTRUE;
+}
+
+//____________________________________________________________________
+TH1F* AliTRDcheckESD::EfficiencyTRD(TH3* tpc3D, TH3* trd3D, Bool_t useAcceptance) {
+ //
+ // Calculate the TRD-TPC matching efficiency as function of pt
+ //
+
+ if(!tpc3D || !trd3D) return NULL;
+ Int_t nBinsZ = trd3D->GetZaxis()->GetNbins();
+ // project everything on the eta-phi map to obtain an acceptance map
+ Float_t nada = 0.;
+ TH2F *trdAcc = (useAcceptance ? (TH2F*)Proj3D(trd3D, 0x0, 1, nBinsZ, nada)->Clone(Form("trdAcc%f", gRandom->Rndm())) : 0x0);
+ TH1D *phiProj = (trdAcc ? trdAcc->ProjectionY(Form("phiProj%f", gRandom->Rndm())) : 0x0);
+
+ // prepare the acceptance map
+ Bool_t activeSM[18] = {kFALSE};
+ Double_t smPhiLimits[19];
+ for(Int_t ism=0; ism<=18; ++ism) smPhiLimits[ism] = -TMath::Pi() + (2.0*TMath::Pi()/18.0)*ism;
+ if(phiProj) {
+ CheckActiveSM(phiProj, activeSM); // get the active SMs
+ trdAcc->Reset();
+ // Put 1 entry in every bin which belongs to an active SM
+ for(Int_t iY=1; iY<=trdAcc->GetYaxis()->GetNbins(); ++iY) {
+ Double_t phi = trdAcc->GetYaxis()->GetBinCenter(iY);
+ Bool_t isActive = kFALSE;
+ for(Int_t ism=0; ism<18; ++ism) {
+ if(phi>=smPhiLimits[ism] && phi<smPhiLimits[ism+1] && activeSM[ism]) {
+ isActive = kTRUE;
+ }
+ }
+ if(!isActive) continue;
+ for(Int_t iX=1; iX<=trdAcc->GetXaxis()->GetNbins(); ++iX)
+ if(trdAcc->GetXaxis()->GetBinCenter(iX)>=-0.85 && trdAcc->GetXaxis()->GetBinCenter(iX)<=0.85) trdAcc->SetBinContent(iX, iY, 1.0);
+ } // end for over Y(phi) bins
+ } // end if phiProj
+
+ // get the bin limits from the Z axis of 3D histos
+ Float_t *ptBinLimits = new Float_t[nBinsZ+1];
+ for(Int_t i=1; i<=nBinsZ; i++) {
+ ptBinLimits[i-1] = trd3D->GetZaxis()->GetBinLowEdge(i);
+ }
+ ptBinLimits[nBinsZ] = trd3D->GetZaxis()->GetBinUpEdge(nBinsZ);
+
+ TH1F *efficiency = new TH1F(Form("eff%d", Int_t(1000000.0*gRandom->Rndm())), "TRD-TPC matching efficiency", nBinsZ, ptBinLimits);
+
+ // loop over Z bins
+ Bool_t effGood = kFALSE;
+ for(Int_t i=1; i<=nBinsZ; i++) {
+ Float_t tpcEntries = 0.0; Float_t trdEntries = 0.0;
+ Proj3D(tpc3D, trdAcc, i, i, tpcEntries);
+ Proj3D(trd3D, trdAcc, i, i, trdEntries);
+ Float_t ratio = 0;
+ if(tpcEntries>0) ratio = trdEntries/tpcEntries;
+ Float_t error = 0;
+ if(tpcEntries>0 && trdEntries>0 && (tpcEntries-trdEntries)>=0.0)
+ error = TMath::Sqrt(trdEntries*(tpcEntries-trdEntries)/tpcEntries/tpcEntries/tpcEntries);
+ if(ratio>0.001) {
+ efficiency->SetBinContent(i,ratio);
+ efficiency->SetBinError(i,error);
+ effGood = kTRUE;
+ }
+ } // end loop over Z bins
+ if(!effGood) return 0x0;
+
+ return efficiency;
+}
+
+//__________________________________________________________________________________________________
+void AliTRDcheckESD::PlotCentSummaryFromCF(Double_t* trendValues, Bool_t useIsolatedBC, Bool_t cutTOFbc) {
+ //
+ // Make the centrality summary figure from the CF container
+ //
+ if(!fCfContainer) return;
+
+ trendValues = trendValues;
+
+ TLatex* lat=new TLatex();
+ lat->SetTextSize(0.06);
+ lat->SetTextColor(2);
+
+ gPad->SetTopMargin(0.05); gPad->SetBottomMargin(0.001); gPad->SetLeftMargin(0.001); gPad->SetRightMargin(0.001);
+ gPad->Divide(3,3,0.,0.);
+ TList* l=gPad->GetListOfPrimitives();
+ TVirtualPad* pad=0x0;
+
+ fCfContainer->SetRangeUser(kTrackDCAxy, -0.999, +0.999);
+ fCfContainer->SetRangeUser(kTrackDCAz, -3.0, +3.0);
+ if(cutTOFbc) fCfContainer->SetRangeUser(kTrackTOFBC, 0.0, 0.0);
+
+ // find all the isolated bunch crossings with entries
+ Bool_t isIsolated[3500];
+ TH1D* tempTH1D = (TH1D*)fCfContainer->Project(0, kEventBC);
+ FindIsolatedBCs(tempTH1D, isIsolated); delete tempTH1D;
+ Int_t nIsolatedBC = 0;
+ for(Int_t ibc=0; ibc<3500; ++ibc)
+ if(isIsolated[ibc]) nIsolatedBC++;
+
+ if(gROOT->FindObject("rangeEffPt")) delete gROOT->FindObject("rangeEffPt");
+ TH2F* rangeEffPt=new TH2F("rangeEffPt", "",10,0.,10.,10,0.,1.3);
+ rangeEffPt->SetStats(kFALSE);
+ SetStyle(rangeEffPt->GetXaxis(), "p_{T} [GeV/c]", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeEffPt->GetYaxis(), "efficiency", 0.07, 0.8, kTRUE, 0.05);
+
+ Int_t padsForEffs[5] = {0,3,6,1,4};
+ for(Int_t iCent=1; iCent<6; ++iCent) {
+ pad = ((TVirtualPad*)l->At(padsForEffs[iCent-1])); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.02); pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEffPt->Draw();
+ TLine line;
+ line.SetLineStyle(2);
+ line.SetLineWidth(2);
+ line.DrawLine(rangeEffPt->GetXaxis()->GetXmin(), 0.7, rangeEffPt->GetXaxis()->GetXmax(), 0.7);
+ line.DrawLine(rangeEffPt->GetXaxis()->GetXmin(), 0.9, rangeEffPt->GetXaxis()->GetXmax(), 0.9);
+
+ fCfContainer->SetRangeUser(kEventMult, Double_t(iCent), Double_t(iCent), kTRUE);
+ fCfContainer->SetRangeUser(kTrackCharge, +1.0, +1.0); // positive charges
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+
+ TH3D* h3PosTPC = (TH3D*)fCfContainer->Project(0, kTrackEta, kTrackPhi, kTrackPt);
+ if(h3PosTPC->GetEntries()<10) {
+ delete h3PosTPC;
+ continue;
+ }
+ TH3D* h3PosTRDall = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 4.0, 4.0); // >= 4 TRD tracklets
+ TH3D* h3PosTRDtrk4 = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 5.0, 5.0); // >= 5 TRD tracklets
+ TH3D* h3PosTRDtrk5 = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 6.0, 6.0); // >= 6 TRD tracklets
+ TH3D* h3PosTRDtrk6 = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+
+ fCfContainer->SetRangeUser(kTrackCharge, -1.0, -1.0); // negative charges
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0); // >= 0 TRD tracklets
+ TH3D* h3NegTPC = (TH3D*)fCfContainer->Project(0, kTrackEta, kTrackPhi, kTrackPt);
+ TH3D* h3NegTRDall = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 4.0, 4.0); // 4 TRD tracklets
+ TH3D* h3NegTRDtrk4 = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 5.0, 5.0); // 5 TRD tracklets
+ TH3D* h3NegTRDtrk5 = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 6.0, 6.0); // 6 TRD tracklets
+ TH3D* h3NegTRDtrk6 = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+
+ TH1F* hEffPosAll = EfficiencyTRD(h3PosTPC, h3PosTRDall, kTRUE);
+ TH1F* hEffPosTrk4 = EfficiencyTRD(h3PosTPC, h3PosTRDtrk4, kTRUE);
+ TH1F* hEffPosTrk5 = EfficiencyTRD(h3PosTPC, h3PosTRDtrk5, kTRUE);
+ TH1F* hEffPosTrk6 = EfficiencyTRD(h3PosTPC, h3PosTRDtrk6, kTRUE);
+ TH1F* hEffNegAll = EfficiencyTRD(h3NegTPC, h3NegTRDall, kTRUE);
+ TH1F* hEffNegTrk4 = EfficiencyTRD(h3NegTPC, h3NegTRDtrk4, kTRUE);
+ TH1F* hEffNegTrk5 = EfficiencyTRD(h3NegTPC, h3NegTRDtrk5, kTRUE);
+ TH1F* hEffNegTrk6 = EfficiencyTRD(h3NegTPC, h3NegTRDtrk6, kTRUE);
+
+ delete h3PosTPC; delete h3NegTPC;
+ delete h3PosTRDall; delete h3PosTRDtrk4; delete h3PosTRDtrk5; delete h3PosTRDtrk6;
+ delete h3NegTRDall; delete h3NegTRDtrk4; delete h3NegTRDtrk5; delete h3NegTRDtrk6;
+
+ // get matching efficiencies for isolated bunches
+ TH3D* h3TPCrefPos_IsolatedBC=0x0; TH3D* h3TPCrefNeg_IsolatedBC=0x0;
+ TH3D* h3TRDrefPosAll_IsolatedBC=0x0; TH3D* h3TRDrefPosTrk4_IsolatedBC=0x0; TH3D* h3TRDrefPosTrk5_IsolatedBC=0x0; TH3D* h3TRDrefPosTrk6_IsolatedBC=0x0;
+ TH3D* h3TRDrefNegAll_IsolatedBC=0x0; TH3D* h3TRDrefNegTrk4_IsolatedBC=0x0; TH3D* h3TRDrefNegTrk5_IsolatedBC=0x0; TH3D* h3TRDrefNegTrk6_IsolatedBC=0x0;
+ for(Int_t ibc=0; ibc<3500; ++ibc) {
+ if(!isIsolated[ibc]) continue;
+ fCfContainer->SetRangeUser(kEventBC, Double_t(ibc), Double_t(ibc));
+
+ TH3D* tempTH3D;
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+ fCfContainer->SetRangeUser(kTrackCharge, +1.0, +1.0); // positive charges
+ tempTH3D = (TH3D*)fCfContainer->Project(0, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TPCrefPos_IsolatedBC) h3TPCrefPos_IsolatedBC = tempTH3D;
+ else {h3TPCrefPos_IsolatedBC->Add(tempTH3D); delete tempTH3D;};
+ tempTH3D = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefPosAll_IsolatedBC) h3TRDrefPosAll_IsolatedBC = tempTH3D;
+ else {h3TRDrefPosAll_IsolatedBC->Add(tempTH3D); delete tempTH3D;}
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 4.0, 4.0);
+ tempTH3D = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefPosTrk4_IsolatedBC) h3TRDrefPosTrk4_IsolatedBC = tempTH3D;
+ else {h3TRDrefPosTrk4_IsolatedBC->Add(tempTH3D); delete tempTH3D;}
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 5.0, 5.0);
+ tempTH3D = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefPosTrk5_IsolatedBC) h3TRDrefPosTrk5_IsolatedBC = tempTH3D;
+ else {h3TRDrefPosTrk5_IsolatedBC->Add(tempTH3D); delete tempTH3D;}
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 6.0, 6.0);
+ tempTH3D = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefPosTrk6_IsolatedBC) h3TRDrefPosTrk6_IsolatedBC = tempTH3D;
+ else {h3TRDrefPosTrk6_IsolatedBC->Add(tempTH3D); delete tempTH3D;}
+
+ fCfContainer->SetRangeUser(kTrackCharge, -1.0, -1.0); // negative charges
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+ tempTH3D = (TH3D*)fCfContainer->Project(0, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TPCrefNeg_IsolatedBC) h3TPCrefNeg_IsolatedBC = tempTH3D;
+ else {h3TPCrefNeg_IsolatedBC->Add(tempTH3D); delete tempTH3D;}
+ tempTH3D = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefNegAll_IsolatedBC) h3TRDrefNegAll_IsolatedBC = tempTH3D;
+ else {h3TRDrefNegAll_IsolatedBC->Add(tempTH3D); delete tempTH3D;}
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 4.0, 4.0);
+ tempTH3D = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefNegTrk4_IsolatedBC) h3TRDrefNegTrk4_IsolatedBC = tempTH3D;
+ else {h3TRDrefNegTrk4_IsolatedBC->Add(tempTH3D); delete tempTH3D;}
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 5.0, 5.0);
+ tempTH3D = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefNegTrk5_IsolatedBC) h3TRDrefNegTrk5_IsolatedBC = tempTH3D;
+ else {h3TRDrefNegTrk5_IsolatedBC->Add(tempTH3D); delete tempTH3D;}
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 6.0, 6.0);
+ tempTH3D = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefNegTrk6_IsolatedBC) h3TRDrefNegTrk6_IsolatedBC = tempTH3D;
+ else {h3TRDrefNegTrk6_IsolatedBC->Add(tempTH3D); delete tempTH3D;}
+ }
+ fCfContainer->SetRangeUser(kEventBC, 0.0, 3500.0);
+ fCfContainer->SetRangeUser(kTrackCharge, -1.0, +1.0);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+
+ TH1F* hEffPosAll_IsolatedBC = EfficiencyTRD(h3TPCrefPos_IsolatedBC, h3TRDrefPosAll_IsolatedBC, kTRUE);
+ TH1F* hEffPosTrk4_IsolatedBC = EfficiencyTRD(h3TPCrefPos_IsolatedBC, h3TRDrefPosTrk4_IsolatedBC, kTRUE);
+ TH1F* hEffPosTrk5_IsolatedBC = EfficiencyTRD(h3TPCrefPos_IsolatedBC, h3TRDrefPosTrk5_IsolatedBC, kTRUE);
+ TH1F* hEffPosTrk6_IsolatedBC = EfficiencyTRD(h3TPCrefPos_IsolatedBC, h3TRDrefPosTrk6_IsolatedBC, kTRUE);
+ TH1F* hEffNegAll_IsolatedBC = EfficiencyTRD(h3TPCrefNeg_IsolatedBC, h3TRDrefNegAll_IsolatedBC, kTRUE);
+ TH1F* hEffNegTrk4_IsolatedBC = EfficiencyTRD(h3TPCrefNeg_IsolatedBC, h3TRDrefNegTrk4_IsolatedBC, kTRUE);
+ TH1F* hEffNegTrk5_IsolatedBC = EfficiencyTRD(h3TPCrefNeg_IsolatedBC, h3TRDrefNegTrk5_IsolatedBC, kTRUE);
+ TH1F* hEffNegTrk6_IsolatedBC = EfficiencyTRD(h3TPCrefNeg_IsolatedBC, h3TRDrefNegTrk6_IsolatedBC, kTRUE);
+
+ if(h3TPCrefPos_IsolatedBC) delete h3TPCrefPos_IsolatedBC;
+ if(h3TPCrefNeg_IsolatedBC) delete h3TPCrefNeg_IsolatedBC;
+ if(h3TRDrefPosAll_IsolatedBC) delete h3TRDrefPosAll_IsolatedBC;
+ if(h3TRDrefPosTrk4_IsolatedBC) delete h3TRDrefPosTrk4_IsolatedBC;
+ if(h3TRDrefPosTrk5_IsolatedBC) delete h3TRDrefPosTrk5_IsolatedBC;
+ if(h3TRDrefPosTrk6_IsolatedBC) delete h3TRDrefPosTrk6_IsolatedBC;
+ if(h3TRDrefNegAll_IsolatedBC) delete h3TRDrefNegAll_IsolatedBC;
+ if(h3TRDrefNegTrk4_IsolatedBC) delete h3TRDrefNegTrk4_IsolatedBC;
+ if(h3TRDrefNegTrk5_IsolatedBC) delete h3TRDrefNegTrk5_IsolatedBC;
+ if(h3TRDrefNegTrk6_IsolatedBC) delete h3TRDrefNegTrk6_IsolatedBC;
+
+ if(!useIsolatedBC) {
+ SetStyle(hEffPosAll, 1, kRed, 1, 24, kRed, 1);
+ SetStyle(hEffPosTrk4, 1, kRed, 1, 25, kRed, 1);
+ SetStyle(hEffPosTrk5, 1, kRed, 1, 26, kRed, 1);
+ SetStyle(hEffPosTrk6, 1, kRed, 1, 27, kRed, 1);
+ SetStyle(hEffNegAll, 1, kBlue, 1, 24, kBlue, 1);
+ SetStyle(hEffNegTrk4, 1, kBlue, 1, 25, kBlue, 1);
+ SetStyle(hEffNegTrk5, 1, kBlue, 1, 26, kBlue, 1);
+ SetStyle(hEffNegTrk6, 1, kBlue, 1, 27, kBlue, 1);
+ hEffPosAll->Draw("same");
+ hEffNegAll->Draw("same");
+ hEffPosTrk4->Draw("same");
+ hEffNegTrk4->Draw("same");
+ hEffPosTrk5->Draw("same");
+ hEffNegTrk5->Draw("same");
+ hEffPosTrk6->Draw("same");
+ hEffNegTrk6->Draw("same");
+ }
+ else {
+ if(nIsolatedBC>0) {
+ SetStyle(hEffPosAll_IsolatedBC, 1, kRed, 1, 24, kRed, 1);
+ SetStyle(hEffPosTrk4_IsolatedBC, 1, kRed, 1, 25, kRed, 1);
+ SetStyle(hEffPosTrk5_IsolatedBC, 1, kRed, 1, 26, kRed, 1);
+ SetStyle(hEffPosTrk6_IsolatedBC, 1, kRed, 1, 27, kRed, 1);
+ SetStyle(hEffNegAll_IsolatedBC, 1, kBlue, 1, 24, kBlue, 1);
+ SetStyle(hEffNegTrk4_IsolatedBC, 1, kBlue, 1, 25, kBlue, 1);
+ SetStyle(hEffNegTrk5_IsolatedBC, 1, kBlue, 1, 26, kBlue, 1);
+ SetStyle(hEffNegTrk6_IsolatedBC, 1, kBlue, 1, 27, kBlue, 1);
+ hEffPosAll_IsolatedBC->Draw("same");
+ hEffNegAll_IsolatedBC->Draw("same");
+ hEffPosTrk4_IsolatedBC->Draw("same");
+ hEffNegTrk4_IsolatedBC->Draw("same");
+ hEffPosTrk5_IsolatedBC->Draw("same");
+ hEffNegTrk5_IsolatedBC->Draw("same");
+ hEffPosTrk6_IsolatedBC->Draw("same");
+ hEffNegTrk6_IsolatedBC->Draw("same");
+ }
+ }
+
+ TLegend* leg=new TLegend(0.18, 0.7, 0.77, 0.89);
+ if(iCent==1) {
+ leg->SetFillColor(0);
+ leg->SetNColumns(2);
+ leg->SetMargin(0.1);
+ leg->SetBorderSize(0);
+ if(useIsolatedBC) {
+ leg->SetHeader("Isolated bunch crossings");
+ if(nIsolatedBC) {
+ leg->AddEntry(hEffPosAll_IsolatedBC, "pos. (#geq 1 tracklet)", "p");
+ leg->AddEntry(hEffNegAll_IsolatedBC, "neg. (#geq 1 tracklet)", "p");
+ leg->AddEntry(hEffPosTrk4_IsolatedBC, "pos. (4 tracklets)", "p");
+ leg->AddEntry(hEffNegTrk4_IsolatedBC, "neg. (4 tracklets)", "p");
+ leg->AddEntry(hEffPosTrk5_IsolatedBC, "pos. (5 tracklets)", "p");
+ leg->AddEntry(hEffNegTrk5_IsolatedBC, "neg. (5 tracklets)", "p");
+ leg->AddEntry(hEffPosTrk6_IsolatedBC, "pos. (6 tracklets)", "p");
+ leg->AddEntry(hEffNegTrk6_IsolatedBC, "neg. (6 tracklets)", "p");
+ }
+ }
+ else {
+ leg->SetHeader("All bunch crossings");
+ leg->AddEntry(hEffPosAll, "pos. (#geq 1 tracklet)", "p");
+ leg->AddEntry(hEffNegAll, "neg. (#geq 1 tracklet)", "p");
+ leg->AddEntry(hEffPosTrk4, "pos. (4 tracklets)", "p");
+ leg->AddEntry(hEffNegTrk4, "neg. (4 tracklets)", "p");
+ leg->AddEntry(hEffPosTrk5, "pos. (5 tracklets)", "p");
+ leg->AddEntry(hEffNegTrk5, "neg. (5 tracklets)", "p");
+ leg->AddEntry(hEffPosTrk6, "pos. (6 tracklets)", "p");
+ leg->AddEntry(hEffNegTrk6, "neg. (6 tracklets)", "p");
+ }
+ leg->Draw();
+ }
+ lat->DrawLatex(0.2, 1.32, Form("Centrality class %d", iCent));
+ } // end for loop over multiplicity classes
+
+ // Reset the modified user ranges of the CF container
+ fCfContainer->SetRangeUser(kEventMult, 0, 6, kTRUE);
+ fCfContainer->SetRangeUser(kTrackCharge, -1.0, +1.0);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+
+ // Cluster distributions in all multiplicity classes
+ pad = ((TVirtualPad*)l->At(2)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.02);
+ pad->SetTopMargin(0.02); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ if(gROOT->FindObject("rangeNcls")) delete gROOT->FindObject("rangeNcls");
+ TH2F* rangeNcls = new TH2F("rangeNcls", "", 10, 0.0, 199.9, 10, 0.0, 1.199);
+ SetStyle(rangeNcls->GetXaxis(), "# TRD clusters", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeNcls->GetYaxis(), "entries (a.u.)", 0.07, 0.8, kTRUE, 0.05);
+ rangeNcls->SetStats(kFALSE);
+ rangeNcls->Draw();
+
+ TH1D* hNcls[6]={0x0};
+ TLegend* legCls=new TLegend(0.7, 0.75, 0.97, 0.97);
+ legCls->SetBorderSize(0);
+ legCls->SetFillColor(0);
+ legCls->SetMargin(0.15);
+ for(Int_t iCent=0; iCent<6; ++iCent) {
+ if(iCent>0)
+ fCfContainer->SetRangeUser(kEventMult, Double_t(iCent), Double_t(iCent), kTRUE);
+ if(!useIsolatedBC) hNcls[iCent] = (TH1D*)fCfContainer->Project(1, kTrackTrdClusters);
+ else{
+ for(Int_t ibc=0; ibc<3500; ++ibc) {
+ if(!isIsolated[ibc]) continue;
+ fCfContainer->SetRangeUser(kEventBC, Double_t(ibc), Double_t(ibc));
+ tempTH1D = (TH1D*)fCfContainer->Project(1, kTrackTrdClusters);
+ if(!hNcls[iCent]) hNcls[iCent] = tempTH1D;
+ else {hNcls[iCent]->Add(tempTH1D); delete tempTH1D;}
+ }
+ fCfContainer->SetRangeUser(kEventBC, 0.0, 3500.0);
+ }
+ if(!hNcls[iCent]) continue;
+ hNcls[iCent]->SetLineColor(iCent<4 ? iCent+1 : iCent+2);
+ Double_t maximum = hNcls[iCent]->GetMaximum();
+ if(maximum>1.0)
+ hNcls[iCent]->Scale(1.0/maximum);
+ hNcls[iCent]->SetStats(kFALSE);
+ hNcls[iCent]->SetTitle("");
+ hNcls[iCent]->SetLineWidth(2);
+
+ if(hNcls[iCent]->Integral()>0.01) {
+ hNcls[iCent]->Draw("same");
+ legCls->AddEntry(hNcls[iCent], (iCent==0 ? "all centralities" : Form("centrality class %d", iCent)), "l");
+ }
+ }
+ if(useIsolatedBC) legCls->SetHeader("Isolated bunch crossings");
+ else legCls->SetHeader("All bunch crossings");
+ legCls->Draw();
+ fCfContainer->SetRangeUser(kEventMult, 0.0, 6.0, kTRUE);
+
+ // Qtot vs P
+ pad = ((TVirtualPad*)l->At(5)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.02);
+ pad->SetTopMargin(0.02); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ if(gROOT->FindObject("rangeQtot")) delete gROOT->FindObject("rangeQtot");
+ TH2F* rangeQtot = new TH2F("rangeQtot", "", 10, 0.0, 9.999, 10, 0.0, 1.199);
+ SetStyle(rangeQtot->GetXaxis(), "Q_{tot} (a.u.)", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeQtot->GetYaxis(), "entries (a.u.)", 0.07, 0.8, kTRUE, 0.05);
+ rangeQtot->SetStats(kFALSE);
+ rangeQtot->Draw();
+
+ TH1D* hQtot[6]={0x0};
+ TLegend* leg2=new TLegend(0.6, 0.7, 0.9, 0.97);
+ leg2->SetFillColor(0);
+ leg2->SetBorderSize(0);
+ for(Int_t iCent=0; iCent<6; ++iCent) {
+ if(iCent>0)
+ fCfContainer->SetRangeUser(kEventMult, Double_t(iCent), Double_t(iCent), kTRUE);
+ if(useIsolatedBC) {
+ for(Int_t ibc=0; ibc<3500; ++ibc) {
+ if(!isIsolated[ibc]) continue;
+ fCfContainer->SetRangeUser(kEventBC, Double_t(ibc), Double_t(ibc));
+ for(Int_t il=0; il<6; ++il) {
+ tempTH1D = (TH1D*)fCfContainer->Project(1, kTrackQtot+il);
+ if(!hQtot[iCent] && il==0) hQtot[iCent] = tempTH1D;
+ else {hQtot[iCent]->Add(tempTH1D); delete tempTH1D;}
+ }
+ }
+ fCfContainer->SetRangeUser(kEventBC, 0.0, 3500.0);
+ }
+ else {
+ for(Int_t il=0; il<6; ++il) {
+ tempTH1D = (TH1D*)fCfContainer->Project(1, kTrackQtot+il);
+ if(il==0) hQtot[iCent] = tempTH1D;
+ else hQtot[iCent]->Add(tempTH1D);
+ }
+ } // end if(useIsolatedBC)
+
+ if(!hQtot[iCent]) continue;
+ hQtot[iCent]->SetBinContent(1, 0);
+ Double_t maximum = hQtot[iCent]->GetMaximum();
+ if(maximum>1.0)
+ hQtot[iCent]->Scale(1.0/maximum);
+ hQtot[iCent]->SetLineColor(iCent<4 ? iCent+1 : iCent+2);
+ hQtot[iCent]->SetStats(kFALSE);
+ hQtot[iCent]->SetTitle("");
+ hQtot[iCent]->SetLineWidth(2);
+ if(hQtot[iCent]->Integral()>0.01) {
+ hQtot[iCent]->Draw(iCent==0 ? "" : "same");
+ leg2->AddEntry(hQtot[iCent], (iCent==0 ? "all centralities" : Form("centrality class %d", iCent)), "l");
+ }
+ }
+ if(useIsolatedBC) leg2->SetHeader("Isolated bunch crossings");
+ else leg2->SetHeader("All bunch crossings");
+ leg2->Draw();
+ fCfContainer->SetRangeUser(kEventMult, 0.0, 5.0, kTRUE);
+ if(cutTOFbc) fCfContainer->SetRangeUser(kTrackTOFBC, -1000.0, +1000.0); // reset the cut on TOFbc
+}
+
+
+//_________________________________________________________________
+void AliTRDcheckESD::PlotTrackingSummaryFromCF(Int_t centralityClass, Double_t* trendValues, Bool_t useIsolatedBC, Bool_t cutTOFbc) {
+
+ if(!fCfContainer) return;
+
+ TLatex *lat=new TLatex();
+ lat->SetTextSize(0.06);
+ lat->SetTextColor(2);
+
+ gPad->SetTopMargin(0.05); gPad->SetBottomMargin(0.001);
+ gPad->SetLeftMargin(0.001); gPad->SetRightMargin(0.001);
+ gPad->Divide(3,3,0.,0.);
+ TList* l=gPad->GetListOfPrimitives();
+
+ // eta-phi distr. for positive TPC tracks
+ TVirtualPad* pad = ((TVirtualPad*)l->At(0)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+
+ fCfContainer->SetRangeUser(kTrackDCAxy, -0.999, +0.999);
+ fCfContainer->SetRangeUser(kTrackDCAz, -3.0, +3.0);
+ if(cutTOFbc) fCfContainer->SetRangeUser(kTrackTOFBC, 0.0, 0.0);
+
+ // find all the isolated bunch crossings with entries
+ Bool_t isIsolated[3500];
+ TH1D* tempTH1D = (TH1D*)fCfContainer->Project(0, kEventBC);
+ FindIsolatedBCs(tempTH1D, isIsolated); delete tempTH1D;
+ Int_t nIsolatedBC = 0;
+ for(Int_t ibc=0; ibc<3500; ++ibc)
+ if(isIsolated[ibc]) nIsolatedBC++;
+
+ if(centralityClass>0) // select the multiplicity class
+ fCfContainer->SetRangeUser(kEventMult, Double_t(centralityClass), Double_t(centralityClass), kTRUE);
+
+ TH2D* hTPCrefPos = 0x0; TH2D* hTRDrefPos = 0x0; TH2D* hTOFrefPos = 0x0;
+ TH2D* hTPCrefNeg = 0x0; TH2D* hTRDrefNeg = 0x0; TH2D* hTOFrefNeg = 0x0;
+ if(!useIsolatedBC) {
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+ fCfContainer->SetRangeUser(kTrackCharge, +1.0, +1.0); // positive charges
+ hTPCrefPos = (TH2D*)fCfContainer->Project(0, kTrackEta, kTrackPhi);
+ hTRDrefPos = (TH2D*)fCfContainer->Project(1, kTrackEta, kTrackPhi);
+ hTOFrefPos = (TH2D*)fCfContainer->Project(2, kTrackEta, kTrackPhi);
+ fCfContainer->SetRangeUser(kTrackCharge, -1.0, -1.0); // negative charges
+ hTPCrefNeg = (TH2D*)fCfContainer->Project(0, kTrackEta, kTrackPhi);
+ hTRDrefNeg = (TH2D*)fCfContainer->Project(1, kTrackEta, kTrackPhi);
+ hTOFrefNeg = (TH2D*)fCfContainer->Project(2, kTrackEta, kTrackPhi);
+ fCfContainer->SetRangeUser(kTrackCharge, -1.0, +1.0); // reset charge cut
+ }
+
+ TH2D* hTPCrefPos_IsolatedBC=0x0; TH2D* hTPCrefNeg_IsolatedBC=0x0;
+ TH2D* hTRDrefPos_IsolatedBC=0x0; TH2D* hTRDrefNeg_IsolatedBC=0x0;
+ TH2D* hTOFrefPos_IsolatedBC=0x0; TH2D* hTOFrefNeg_IsolatedBC=0x0;
+ if(useIsolatedBC) {
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+ for(Int_t ibc=0; ibc<3500; ++ibc) {
+ if(!isIsolated[ibc]) continue;
+ fCfContainer->SetRangeUser(kEventBC, Double_t(ibc), Double_t(ibc));
+ fCfContainer->SetRangeUser(kTrackCharge, +1.0, +1.0); // positive charges
+ TH2D* tempTH2D;
+ tempTH2D = (TH2D*)fCfContainer->Project(0, kTrackEta, kTrackPhi);
+ if(!hTPCrefPos_IsolatedBC) hTPCrefPos_IsolatedBC = tempTH2D;
+ else {hTPCrefPos_IsolatedBC->Add(tempTH2D); delete tempTH2D;}
+ tempTH2D = (TH2D*)fCfContainer->Project(1, kTrackEta, kTrackPhi);
+ if(!hTRDrefPos_IsolatedBC) hTRDrefPos_IsolatedBC = tempTH2D;
+ else {hTRDrefPos_IsolatedBC->Add(tempTH2D); delete tempTH2D;}
+ tempTH2D = (TH2D*)fCfContainer->Project(2, kTrackEta, kTrackPhi);
+ if(!hTOFrefPos_IsolatedBC) hTOFrefPos_IsolatedBC = tempTH2D;
+ else {hTOFrefPos_IsolatedBC->Add(tempTH2D); delete tempTH2D;}
+ fCfContainer->SetRangeUser(kTrackCharge, -1.0, -1.0); // negative charges
+ tempTH2D = (TH2D*)fCfContainer->Project(0, kTrackEta, kTrackPhi);
+ if(!hTPCrefNeg_IsolatedBC) hTPCrefNeg_IsolatedBC = tempTH2D;
+ else {hTPCrefNeg_IsolatedBC->Add(tempTH2D); delete tempTH2D;}
+ tempTH2D = (TH2D*)fCfContainer->Project(1, kTrackEta, kTrackPhi);
+ if(!hTRDrefNeg_IsolatedBC) hTRDrefNeg_IsolatedBC = tempTH2D;
+ else {hTRDrefNeg_IsolatedBC->Add(tempTH2D); delete tempTH2D;}
+ tempTH2D = (TH2D*)fCfContainer->Project(2, kTrackEta, kTrackPhi);
+ if(!hTOFrefNeg_IsolatedBC) hTOFrefNeg_IsolatedBC = tempTH2D;
+ else {hTOFrefNeg_IsolatedBC->Add(tempTH2D); delete tempTH2D;}
+ }
+ fCfContainer->SetRangeUser(kEventBC, 0.0, 3500.); // reset the BC range
+ fCfContainer->SetRangeUser(kTrackCharge, -1.0, +1.0); // reset charge cut
+ }
+
+ if(gROOT->FindObject("rangeEtaPhi")) delete gROOT->FindObject("rangeEtaPhi");
+ TH2F* rangeEtaPhi = new TH2F("rangeEtaPhi", "", 10, -0.99, +0.99, 10, -3.4, +3.4);
+ SetStyle(rangeEtaPhi->GetXaxis(), "#eta", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeEtaPhi->GetYaxis(), "detector #varphi", 0.07, 0.8, kTRUE, 0.05);
+ rangeEtaPhi->SetStats(kFALSE);
+
+ //----------------------------------------------
+ // eta-phi efficiency for positive TRD tracks
+ pad = ((TVirtualPad*)l->At(0)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEtaPhi->Draw();
+
+ if(useIsolatedBC) {
+ if(nIsolatedBC>0) {
+ TH2D* hTRDeffPos_IsolatedBC = (TH2D*)hTRDrefPos_IsolatedBC->Clone("hTRDeffPos_IsolatedBC");
+ hTRDeffPos_IsolatedBC->Reset();
+ hTRDeffPos_IsolatedBC->SetStats(kFALSE);
+ hTRDeffPos_IsolatedBC->Divide(hTRDrefPos_IsolatedBC, hTPCrefPos_IsolatedBC);
+ hTRDeffPos_IsolatedBC->SetMaximum(1.0);
+ hTRDeffPos_IsolatedBC->Draw("samecolz");
+ }
+ }
+ else {
+ TH2D* hTRDeffPos = (TH2D*)hTRDrefPos->Clone("hTRDeffPos");
+ hTRDeffPos->Reset();
+ hTRDeffPos->SetStats(kFALSE);
+ hTRDeffPos->Divide(hTRDrefPos, hTPCrefPos);
+ hTRDeffPos->SetMaximum(1.0);
+ hTRDeffPos->Draw("samecolz");
+ }
+ lat->DrawLatex(-0.9, 3.6, "TPC-TRD matching for positive tracks");
+ DrawTRDGrid();
+
+ //----------------------------------------------
+ // eta-phi efficiency for negative TRD tracks
+ pad = ((TVirtualPad*)l->At(3)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEtaPhi->Draw();
+
+ if(useIsolatedBC) {
+ if(nIsolatedBC>0) {
+ TH2D* hTRDeffNeg_IsolatedBC = (TH2D*)hTRDrefNeg_IsolatedBC->Clone("hTRDeffNeg_IsolatedBC");
+ hTRDeffNeg_IsolatedBC->Reset();
+ hTRDeffNeg_IsolatedBC->SetStats(kFALSE);
+ hTRDeffNeg_IsolatedBC->Divide(hTRDrefNeg_IsolatedBC, hTPCrefNeg_IsolatedBC);
+ hTRDeffNeg_IsolatedBC->SetMaximum(1.0);
+ hTRDeffNeg_IsolatedBC->Draw("samecolz");
+ }
+ }
+ else {
+ TH2D* hTRDeffNeg = (TH2D*)hTRDrefNeg->Clone("hTRDeffNeg");
+ hTRDeffNeg->Reset();
+ hTRDeffNeg->SetStats(kFALSE);
+ hTRDeffNeg->Divide(hTRDrefNeg, hTPCrefNeg);
+ hTRDeffNeg->SetMaximum(1.0);
+ hTRDeffNeg->Draw("samecolz");
+ }
+ lat->DrawLatex(-0.9, 3.6, "TPC-TRD matching for negative tracks");
+ DrawTRDGrid();
+
+ //----------------------------------------------
+ // eta-phi TRD-TOF matching efficiency for positive tracks
+ pad = ((TVirtualPad*)l->At(1)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEtaPhi->Draw();
+
+ if(useIsolatedBC) {
+ if(nIsolatedBC>0) {
+ TH2D* hTOFeffPos_IsolatedBC = (TH2D*)hTOFrefPos_IsolatedBC->Clone("hTOFeffPos_IsolatedBC");
+ hTOFeffPos_IsolatedBC->Reset();
+ hTOFeffPos_IsolatedBC->SetStats(kFALSE);
+ hTOFeffPos_IsolatedBC->Divide(hTOFrefPos_IsolatedBC, hTRDrefPos_IsolatedBC);
+ hTOFeffPos_IsolatedBC->SetMaximum(1.0);
+ hTOFeffPos_IsolatedBC->Draw("samecolz");
+ }
+ }
+ else {
+ TH2D* hTOFeffPos = (TH2D*)hTOFrefPos->Clone("hTOFeffPos");
+ hTOFeffPos->Reset();
+ hTOFeffPos->SetStats(kFALSE);
+ hTOFeffPos->Divide(hTOFrefPos, hTRDrefPos);
+ hTOFeffPos->SetMaximum(1.0);
+ hTOFeffPos->Draw("samecolz");
+ }
+ lat->DrawLatex(-0.9, 3.6, "TRD-TOF matching for positive tracks");
+ DrawTRDGrid();
+
+ //----------------------------------------------
+ // eta-phi TRD-TOF matching efficiency for negative tracks
+ pad = ((TVirtualPad*)l->At(4)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEtaPhi->Draw();
+
+ if(useIsolatedBC) {
+ if(nIsolatedBC) {
+ TH2D* hTOFeffNeg_IsolatedBC = (TH2D*)hTOFrefNeg_IsolatedBC->Clone("hTOFeffNeg_IsolatedBC");
+ hTOFeffNeg_IsolatedBC->Reset();
+ hTOFeffNeg_IsolatedBC->SetStats(kFALSE);
+ hTOFeffNeg_IsolatedBC->Divide(hTOFrefNeg_IsolatedBC, hTRDrefNeg_IsolatedBC);
+ hTOFeffNeg_IsolatedBC->SetMaximum(1.0);
+ hTOFeffNeg_IsolatedBC->Draw("samecolz");
+ }
+ }
+ else {
+ TH2D* hTOFeffNeg = (TH2D*)hTOFrefNeg->Clone("hTOFeffNeg");
+ hTOFeffNeg->Reset();
+ hTOFeffNeg->SetStats(kFALSE);
+ hTOFeffNeg->Divide(hTOFrefNeg, hTRDrefNeg);
+ hTOFeffNeg->SetMaximum(1.0);
+ hTOFeffNeg->Draw("samecolz");
+ }
+ lat->DrawLatex(-0.9, 3.6, "TRD-TOF matching for negative tracks");
+ DrawTRDGrid();
+
+ if(hTRDrefPos) delete hTRDrefPos; if(hTPCrefPos) delete hTPCrefPos; if(hTOFrefPos) delete hTOFrefPos;
+ if(hTRDrefNeg) delete hTRDrefNeg; if(hTPCrefNeg) delete hTPCrefNeg; if(hTOFrefNeg) delete hTOFrefNeg;
+ if(hTRDrefPos_IsolatedBC) delete hTRDrefPos_IsolatedBC; if(hTPCrefPos_IsolatedBC) delete hTPCrefPos_IsolatedBC; if(hTOFrefPos_IsolatedBC) delete hTOFrefPos_IsolatedBC;
+ if(hTRDrefNeg_IsolatedBC) delete hTRDrefNeg_IsolatedBC; if(hTPCrefNeg_IsolatedBC) delete hTPCrefNeg_IsolatedBC; if(hTOFrefNeg_IsolatedBC) delete hTOFrefNeg_IsolatedBC;
+
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+ fCfContainer->SetRangeUser(kTrackCharge, +1.0, +1.0); // positive charges
+ TH3D* h3TPCrefPos = (TH3D*)fCfContainer->Project(0, kTrackEta, kTrackPhi, kTrackPt);
+ TH3D* h3TRDrefPosAll = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ TH3D* h3TOFrefPosAll = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 4.0, 4.0);
+ TH3D* h3TRDrefPosTrk4 = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ TH3D* h3TOFrefPosTrk4 = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 5.0, 5.0);
+ TH3D* h3TRDrefPosTrk5 = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ TH3D* h3TOFrefPosTrk5 = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 6.0, 6.0);
+ TH3D* h3TRDrefPosTrk6 = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ TH3D* h3TOFrefPosTrk6 = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+
+ fCfContainer->SetRangeUser(kTrackCharge, -1.0, -1.0); // negative charges
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+ TH3D* h3TPCrefNeg = (TH3D*)fCfContainer->Project(0, kTrackEta, kTrackPhi, kTrackPt);
+ TH3D* h3TRDrefNegAll = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ TH3D* h3TOFrefNegAll = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 4.0, 4.0);
+ TH3D* h3TRDrefNegTrk4 = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ TH3D* h3TOFrefNegTrk4 = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 5.0, 5.0);
+ TH3D* h3TRDrefNegTrk5 = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ TH3D* h3TOFrefNegTrk5 = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 6.0, 6.0);
+ TH3D* h3TRDrefNegTrk6 = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ TH3D* h3TOFrefNegTrk6 = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ fCfContainer->SetRangeUser(kTrackCharge, -1.0, +1.0);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+
+ TH1F* hTRDEffPtPosAll = EfficiencyTRD(h3TPCrefPos, h3TRDrefPosAll, kTRUE);
+ TH1F* hTRDEffPtNegAll = EfficiencyTRD(h3TPCrefNeg, h3TRDrefNegAll, kTRUE);
+ TH1F* hTRDEffPtPosTrk4 = EfficiencyTRD(h3TPCrefPos, h3TRDrefPosTrk4, kTRUE);
+ TH1F* hTRDEffPtNegTrk4 = EfficiencyTRD(h3TPCrefNeg, h3TRDrefNegTrk4, kTRUE);
+ TH1F* hTRDEffPtPosTrk5 = EfficiencyTRD(h3TPCrefPos, h3TRDrefPosTrk5, kTRUE);
+ TH1F* hTRDEffPtNegTrk5 = EfficiencyTRD(h3TPCrefNeg, h3TRDrefNegTrk5, kTRUE);
+ TH1F* hTRDEffPtPosTrk6 = EfficiencyTRD(h3TPCrefPos, h3TRDrefPosTrk6, kTRUE);
+ TH1F* hTRDEffPtNegTrk6 = EfficiencyTRD(h3TPCrefNeg, h3TRDrefNegTrk6, kTRUE);
+
+ TH1F* hTOFEffPtPosAll = EfficiencyTRD(h3TRDrefPosAll, h3TOFrefPosAll, kFALSE);
+ TH1F* hTOFEffPtNegAll = EfficiencyTRD(h3TRDrefNegAll, h3TOFrefNegAll, kFALSE);
+ TH1F* hTOFEffPtPosTrk4 = EfficiencyTRD(h3TRDrefPosTrk4, h3TOFrefPosTrk4, kFALSE);
+ TH1F* hTOFEffPtNegTrk4 = EfficiencyTRD(h3TRDrefNegTrk4, h3TOFrefNegTrk4, kFALSE);
+ TH1F* hTOFEffPtPosTrk5 = EfficiencyTRD(h3TRDrefPosTrk5, h3TOFrefPosTrk5, kFALSE);
+ TH1F* hTOFEffPtNegTrk5 = EfficiencyTRD(h3TRDrefNegTrk5, h3TOFrefNegTrk5, kFALSE);
+ TH1F* hTOFEffPtPosTrk6 = EfficiencyTRD(h3TRDrefPosTrk6, h3TOFrefPosTrk6, kFALSE);
+ TH1F* hTOFEffPtNegTrk6 = EfficiencyTRD(h3TRDrefNegTrk6, h3TOFrefNegTrk6, kFALSE);
+
+ delete h3TPCrefPos; delete h3TPCrefNeg;
+ delete h3TRDrefPosAll; delete h3TRDrefPosTrk4; delete h3TRDrefPosTrk5; delete h3TRDrefPosTrk6;
+ delete h3TRDrefNegAll; delete h3TRDrefNegTrk4; delete h3TRDrefNegTrk5; delete h3TRDrefNegTrk6;
+ delete h3TOFrefPosAll; delete h3TOFrefPosTrk4; delete h3TOFrefPosTrk5; delete h3TOFrefPosTrk6;
+ delete h3TOFrefNegAll; delete h3TOFrefNegTrk4; delete h3TOFrefNegTrk5; delete h3TOFrefNegTrk6;
+
+ TF1* funcConst = new TF1("constFunc", "[0]", 1.0, 3.0);
+ if(trendValues && hTRDEffPtPosAll){
+ if(hTRDEffPtPosAll->Integral()>0.1) {
+ hTRDEffPtPosAll->Fit(funcConst, "Q0ME", "goff", 1.0, 3.0);
+ trendValues[0] = funcConst->GetParameter(0);
+ trendValues[1] = funcConst->GetParError(0);
+ }
+ }
+ if(trendValues && hTRDEffPtNegAll){
+ if(hTRDEffPtNegAll->Integral()>0.1) {
+ hTRDEffPtNegAll->Fit(funcConst, "Q0ME", "goff", 1.0, 3.0);
+ trendValues[2] = funcConst->GetParameter(0);
+ trendValues[3] = funcConst->GetParError(0);
+ }
+ }
+ if(trendValues && hTOFEffPtPosAll){
+ if(hTOFEffPtPosAll->Integral()>0.1) {
+ hTOFEffPtPosAll->Fit(funcConst, "Q0ME", "goff", 1.0, 3.0);
+ trendValues[4] = funcConst->GetParameter(0);
+ trendValues[5] = funcConst->GetParError(0);
+ }
+ }
+ if(trendValues && hTOFEffPtNegAll){
+ if(hTOFEffPtNegAll->Integral()>0.1) {
+ hTOFEffPtNegAll->Fit(funcConst, "Q0ME", "goff", 1.0, 3.0);
+ trendValues[6] = funcConst->GetParameter(0);
+ trendValues[7] = funcConst->GetParError(0);
+ }
+ }
+ // get matching efficiencies for isolated bunches
+ TH3D* h3TPCrefPos_IsolatedBC=0x0; TH3D* h3TPCrefNeg_IsolatedBC=0x0;
+ TH3D* h3TRDrefPosAll_IsolatedBC=0x0; TH3D* h3TRDrefPosTrk4_IsolatedBC=0x0; TH3D* h3TRDrefPosTrk5_IsolatedBC=0x0; TH3D* h3TRDrefPosTrk6_IsolatedBC=0x0;
+ TH3D* h3TRDrefNegAll_IsolatedBC=0x0; TH3D* h3TRDrefNegTrk4_IsolatedBC=0x0; TH3D* h3TRDrefNegTrk5_IsolatedBC=0x0; TH3D* h3TRDrefNegTrk6_IsolatedBC=0x0;
+ TH3D* h3TOFrefPosAll_IsolatedBC=0x0; TH3D* h3TOFrefPosTrk4_IsolatedBC=0x0; TH3D* h3TOFrefPosTrk5_IsolatedBC=0x0; TH3D* h3TOFrefPosTrk6_IsolatedBC=0x0;
+ TH3D* h3TOFrefNegAll_IsolatedBC=0x0; TH3D* h3TOFrefNegTrk4_IsolatedBC=0x0; TH3D* h3TOFrefNegTrk5_IsolatedBC=0x0; TH3D* h3TOFrefNegTrk6_IsolatedBC=0x0;
+ for(Int_t ibc=0; ibc<3500; ++ibc) {
+ if(!isIsolated[ibc]) continue;
+ fCfContainer->SetRangeUser(kEventBC, Double_t(ibc), Double_t(ibc));
+
+ TH3D* temp;
+ fCfContainer->SetRangeUser(kTrackCharge, +1.0, +1.0); // positive charges
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+ temp = (TH3D*)fCfContainer->Project(0, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TPCrefPos_IsolatedBC) h3TPCrefPos_IsolatedBC = temp;
+ else {h3TPCrefPos_IsolatedBC->Add(temp); delete temp;}
+ temp = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefPosAll_IsolatedBC) h3TRDrefPosAll_IsolatedBC = temp;
+ else {h3TRDrefPosAll_IsolatedBC->Add(temp); delete temp;}
+ temp = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TOFrefPosAll_IsolatedBC) h3TOFrefPosAll_IsolatedBC = temp;
+ else {h3TOFrefPosAll_IsolatedBC->Add(temp); delete temp;}
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 4.0, 4.0);
+ temp = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefPosTrk4_IsolatedBC) h3TRDrefPosTrk4_IsolatedBC = temp;
+ else {h3TRDrefPosTrk4_IsolatedBC->Add(temp); delete temp;}
+ temp = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TOFrefPosTrk4_IsolatedBC) h3TOFrefPosTrk4_IsolatedBC = temp;
+ else {h3TOFrefPosTrk4_IsolatedBC->Add(temp); delete temp;}
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 5.0, 5.0);
+ temp = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefPosTrk5_IsolatedBC) h3TRDrefPosTrk5_IsolatedBC = temp;
+ else {h3TRDrefPosTrk5_IsolatedBC->Add(temp); delete temp;}
+ temp = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TOFrefPosTrk5_IsolatedBC) h3TOFrefPosTrk5_IsolatedBC = temp;
+ else {h3TOFrefPosTrk5_IsolatedBC->Add(temp); delete temp;}
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 6.0, 6.0);
+ temp = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefPosTrk6_IsolatedBC) h3TRDrefPosTrk6_IsolatedBC = temp;
+ else {h3TRDrefPosTrk6_IsolatedBC->Add(temp); delete temp;}
+ temp = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TOFrefPosTrk6_IsolatedBC) h3TOFrefPosTrk6_IsolatedBC = temp;
+ else {h3TOFrefPosTrk6_IsolatedBC->Add(temp); delete temp;}
+
+ fCfContainer->SetRangeUser(kTrackCharge, -1.0, -1.0); // negative charges
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+ temp = (TH3D*)fCfContainer->Project(0, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TPCrefNeg_IsolatedBC) h3TPCrefNeg_IsolatedBC = temp;
+ else {h3TPCrefNeg_IsolatedBC->Add(temp); delete temp;}
+ temp = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefNegAll_IsolatedBC) h3TRDrefNegAll_IsolatedBC = temp;
+ else {h3TRDrefNegAll_IsolatedBC->Add(temp); delete temp;}
+ temp = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TOFrefNegAll_IsolatedBC) h3TOFrefNegAll_IsolatedBC = temp;
+ else {h3TOFrefNegAll_IsolatedBC->Add(temp); delete temp;}
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 4.0, 4.0);
+ temp = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefNegTrk4_IsolatedBC) h3TRDrefNegTrk4_IsolatedBC = temp;
+ else {h3TRDrefNegTrk4_IsolatedBC->Add(temp); delete temp;}
+ temp = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TOFrefNegTrk4_IsolatedBC) h3TOFrefNegTrk4_IsolatedBC = temp;
+ else {h3TOFrefNegTrk4_IsolatedBC->Add(temp); delete temp;}
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 5.0, 5.0);
+ temp = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefNegTrk5_IsolatedBC) h3TRDrefNegTrk5_IsolatedBC = temp;
+ else {h3TRDrefNegTrk5_IsolatedBC->Add(temp); delete temp;}
+ temp = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TOFrefNegTrk5_IsolatedBC) h3TOFrefNegTrk5_IsolatedBC = temp;
+ else {h3TOFrefNegTrk5_IsolatedBC->Add(temp); delete temp;}
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 6.0, 6.0);
+ temp = (TH3D*)fCfContainer->Project(1, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TRDrefNegTrk6_IsolatedBC) h3TRDrefNegTrk6_IsolatedBC = temp;
+ else {h3TRDrefNegTrk6_IsolatedBC->Add(temp); delete temp;}
+ temp = (TH3D*)fCfContainer->Project(2, kTrackEta, kTrackPhi, kTrackPt);
+ if(!h3TOFrefNegTrk6_IsolatedBC) h3TOFrefNegTrk6_IsolatedBC = temp;
+ else {h3TOFrefNegTrk6_IsolatedBC->Add(temp); delete temp;}
+ }
+ fCfContainer->SetRangeUser(kEventBC, 0.0, 3500.0);
+ fCfContainer->SetRangeUser(kTrackCharge, -1.0, +1.0);
+ fCfContainer->SetRangeUser(kTrackTrdTracklets, 0.0, 6.0);
+
+ TH1F* hTRDEffPtPosAll_IsolatedBC = EfficiencyTRD(h3TPCrefPos_IsolatedBC, h3TRDrefPosAll_IsolatedBC, kTRUE);
+ TH1F* hTRDEffPtNegAll_IsolatedBC = EfficiencyTRD(h3TPCrefNeg_IsolatedBC, h3TRDrefNegAll_IsolatedBC, kTRUE);
+ TH1F* hTRDEffPtPosTrk4_IsolatedBC = EfficiencyTRD(h3TPCrefPos_IsolatedBC, h3TRDrefPosTrk4_IsolatedBC, kTRUE);
+ TH1F* hTRDEffPtNegTrk4_IsolatedBC = EfficiencyTRD(h3TPCrefNeg_IsolatedBC, h3TRDrefNegTrk4_IsolatedBC, kTRUE);
+ TH1F* hTRDEffPtPosTrk5_IsolatedBC = EfficiencyTRD(h3TPCrefPos_IsolatedBC, h3TRDrefPosTrk5_IsolatedBC, kTRUE);
+ TH1F* hTRDEffPtNegTrk5_IsolatedBC = EfficiencyTRD(h3TPCrefNeg_IsolatedBC, h3TRDrefNegTrk5_IsolatedBC, kTRUE);
+ TH1F* hTRDEffPtPosTrk6_IsolatedBC = EfficiencyTRD(h3TPCrefPos_IsolatedBC, h3TRDrefPosTrk6_IsolatedBC, kTRUE);
+ TH1F* hTRDEffPtNegTrk6_IsolatedBC = EfficiencyTRD(h3TPCrefNeg_IsolatedBC, h3TRDrefNegTrk6_IsolatedBC, kTRUE);
+
+ TH1F* hTOFEffPtPosAll_IsolatedBC = EfficiencyTRD(h3TRDrefPosAll_IsolatedBC, h3TOFrefPosAll_IsolatedBC, kFALSE);
+ TH1F* hTOFEffPtNegAll_IsolatedBC = EfficiencyTRD(h3TRDrefNegAll_IsolatedBC, h3TOFrefNegAll_IsolatedBC, kFALSE);
+ TH1F* hTOFEffPtPosTrk4_IsolatedBC = EfficiencyTRD(h3TRDrefPosTrk4_IsolatedBC, h3TOFrefPosTrk4_IsolatedBC, kFALSE);
+ TH1F* hTOFEffPtNegTrk4_IsolatedBC = EfficiencyTRD(h3TRDrefNegTrk4_IsolatedBC, h3TOFrefNegTrk4_IsolatedBC, kFALSE);
+ TH1F* hTOFEffPtPosTrk5_IsolatedBC = EfficiencyTRD(h3TRDrefPosTrk5_IsolatedBC, h3TOFrefPosTrk5_IsolatedBC, kFALSE);
+ TH1F* hTOFEffPtNegTrk5_IsolatedBC = EfficiencyTRD(h3TRDrefNegTrk5_IsolatedBC, h3TOFrefNegTrk5_IsolatedBC, kFALSE);
+ TH1F* hTOFEffPtPosTrk6_IsolatedBC = EfficiencyTRD(h3TRDrefPosTrk6_IsolatedBC, h3TOFrefPosTrk6_IsolatedBC, kFALSE);
+ TH1F* hTOFEffPtNegTrk6_IsolatedBC = EfficiencyTRD(h3TRDrefNegTrk6_IsolatedBC, h3TOFrefNegTrk6_IsolatedBC, kFALSE);
+
+ if(h3TPCrefPos_IsolatedBC) delete h3TPCrefPos_IsolatedBC; if(h3TPCrefNeg_IsolatedBC) delete h3TPCrefNeg_IsolatedBC;
+ if(h3TRDrefPosAll_IsolatedBC) delete h3TRDrefPosAll_IsolatedBC; if(h3TRDrefPosTrk4_IsolatedBC) delete h3TRDrefPosTrk4_IsolatedBC;
+ if(h3TRDrefPosTrk5_IsolatedBC) delete h3TRDrefPosTrk5_IsolatedBC; if(h3TRDrefPosTrk6_IsolatedBC) delete h3TRDrefPosTrk6_IsolatedBC;
+ if(h3TRDrefNegAll_IsolatedBC) delete h3TRDrefNegAll_IsolatedBC; if(h3TRDrefNegTrk4_IsolatedBC) delete h3TRDrefNegTrk4_IsolatedBC;
+ if(h3TRDrefNegTrk5_IsolatedBC) delete h3TRDrefNegTrk5_IsolatedBC; if(h3TRDrefNegTrk6_IsolatedBC) delete h3TRDrefNegTrk6_IsolatedBC;
+ if(h3TOFrefPosAll_IsolatedBC) delete h3TOFrefPosAll_IsolatedBC; if(h3TOFrefPosTrk4_IsolatedBC) delete h3TOFrefPosTrk4_IsolatedBC;
+ if(h3TOFrefPosTrk5_IsolatedBC) delete h3TOFrefPosTrk5_IsolatedBC; if(h3TOFrefPosTrk6_IsolatedBC) delete h3TOFrefPosTrk6_IsolatedBC;
+ if(h3TOFrefNegAll_IsolatedBC) delete h3TOFrefNegAll_IsolatedBC; if(h3TOFrefNegTrk4_IsolatedBC) delete h3TOFrefNegTrk4_IsolatedBC;
+ if(h3TOFrefNegTrk5_IsolatedBC) delete h3TOFrefNegTrk5_IsolatedBC; if(h3TOFrefNegTrk6_IsolatedBC) delete h3TOFrefNegTrk6_IsolatedBC;
+
+ if(trendValues && hTRDEffPtPosAll_IsolatedBC && hTRDEffPtPosAll_IsolatedBC->Integral()>0.1) {
+ hTRDEffPtPosAll_IsolatedBC->Fit(funcConst, "Q0ME", "goff", 1.0, 3.0);
+ trendValues[18] = funcConst->GetParameter(0);
+ trendValues[19] = funcConst->GetParError(0);
+ }
+ if(trendValues && hTRDEffPtNegAll_IsolatedBC && hTRDEffPtNegAll_IsolatedBC->Integral()>0.1) {
+ hTRDEffPtNegAll_IsolatedBC->Fit(funcConst, "Q0ME", "goff", 1.0, 3.0);
+ trendValues[20] = funcConst->GetParameter(0);
+ trendValues[21] = funcConst->GetParError(0);
+ }
+ if(trendValues && hTOFEffPtPosAll_IsolatedBC && hTOFEffPtPosAll_IsolatedBC->Integral()>0.1) {
+ hTOFEffPtPosAll_IsolatedBC->Fit(funcConst, "Q0ME", "goff", 1.0, 3.0);
+ trendValues[22] = funcConst->GetParameter(0);
+ trendValues[23] = funcConst->GetParError(0);
+ }
+ if(trendValues && hTOFEffPtNegAll_IsolatedBC && hTOFEffPtNegAll_IsolatedBC->Integral()>0.1) {
+ hTOFEffPtNegAll_IsolatedBC->Fit(funcConst, "Q0ME", "goff", 1.0, 3.0);
+ trendValues[24] = funcConst->GetParameter(0);
+ trendValues[25] = funcConst->GetParError(0);
+ }
+
+ //---------------------------------------------------------
+ // TPC-TRD matching efficiency vs pt
+ pad = ((TVirtualPad*)l->At(6)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.02);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+
+ if(gROOT->FindObject("rangeEffPt2")) delete gROOT->FindObject("rangeEffPt2");
+ TH2F* rangeEffPt=new TH2F("rangeEffPt2", "",10,0.,10.,10,0.,1.4);
+ rangeEffPt->SetStats(kFALSE);
+ SetStyle(rangeEffPt->GetXaxis(), "p_{T} [GeV/c]", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeEffPt->GetYaxis(), "efficiency", 0.07, 0.8, kTRUE, 0.05);
+ rangeEffPt->Draw();
+ lat->DrawLatex(0.2, 1.42, "TPC-TRD matching efficiency");
+ //++++++++++++++++++
+ TLine line;
+ line.SetLineStyle(2);
+ line.SetLineWidth(2);
+ line.DrawLine(rangeEffPt->GetXaxis()->GetXmin(), 0.7, rangeEffPt->GetXaxis()->GetXmax(), 0.7);
+ line.DrawLine(rangeEffPt->GetXaxis()->GetXmin(), 0.9, rangeEffPt->GetXaxis()->GetXmax(), 0.9);
+ TLegend* leg=new TLegend(0.2, 0.7, 0.7, 0.89);
+ leg->SetNColumns(2);
+ leg->SetMargin(0.15);
+ leg->SetBorderSize(0);
+ leg->SetFillColor(0);
+
+ if(!useIsolatedBC) {
+ SetStyle(hTRDEffPtPosAll, 1, kRed, 1, 24, kRed, 1);
+ SetStyle(hTRDEffPtNegAll, 1, kBlue, 1, 24, kBlue, 1);
+ SetStyle(hTRDEffPtPosTrk4, 1, kRed, 1, 25, kRed, 1);
+ SetStyle(hTRDEffPtNegTrk4, 1, kBlue, 1, 25, kBlue, 1);
+ SetStyle(hTRDEffPtPosTrk5, 1, kRed, 1, 26, kRed, 1);
+ SetStyle(hTRDEffPtNegTrk5, 1, kBlue, 1, 26, kBlue, 1);
+ SetStyle(hTRDEffPtPosTrk6, 1, kRed, 1, 27, kRed, 1);
+ SetStyle(hTRDEffPtNegTrk6, 1, kBlue, 1, 27, kBlue, 1);
+ leg->SetHeader("All bunch crossings");
+ hTRDEffPtPosAll->Draw("same"); leg->AddEntry(hTRDEffPtPosAll, "pos. (#geq 1 tracklet)", "p");
+ hTRDEffPtNegAll->Draw("same"); leg->AddEntry(hTRDEffPtNegAll, "neg. (#geq 1 tracklet)", "p");
+ hTRDEffPtPosTrk4->Draw("same"); leg->AddEntry(hTRDEffPtPosTrk4, "pos. (4 tracklets)", "p");
+ hTRDEffPtNegTrk4->Draw("same"); leg->AddEntry(hTRDEffPtNegTrk4, "neg. (4 tracklets)", "p");
+ hTRDEffPtPosTrk5->Draw("same"); leg->AddEntry(hTRDEffPtPosTrk5, "pos. (5 tracklets)", "p");
+ hTRDEffPtNegTrk5->Draw("same"); leg->AddEntry(hTRDEffPtNegTrk5, "neg. (5 tracklets)", "p");
+ hTRDEffPtPosTrk6->Draw("same"); leg->AddEntry(hTRDEffPtPosTrk6, "pos. (6 tracklets)", "p");
+ hTRDEffPtNegTrk6->Draw("same"); leg->AddEntry(hTRDEffPtNegTrk6, "neg. (6 tracklets)", "p");
+ }
+ else {
+ if(nIsolatedBC>0) {
+ SetStyle(hTRDEffPtPosAll_IsolatedBC, 1, kRed, 1, 24, kRed, 1);
+ SetStyle(hTRDEffPtNegAll_IsolatedBC, 1, kBlue, 1, 24, kBlue, 1);
+ SetStyle(hTRDEffPtPosTrk4_IsolatedBC, 1, kRed, 1, 25, kRed, 1);
+ SetStyle(hTRDEffPtNegTrk4_IsolatedBC, 1, kBlue, 1, 25, kBlue, 1);
+ SetStyle(hTRDEffPtPosTrk5_IsolatedBC, 1, kRed, 1, 26, kRed, 1);
+ SetStyle(hTRDEffPtNegTrk5_IsolatedBC, 1, kBlue, 1, 26, kBlue, 1);
+ SetStyle(hTRDEffPtPosTrk6_IsolatedBC, 1, kRed, 1, 27, kRed, 1);
+ SetStyle(hTRDEffPtNegTrk6_IsolatedBC, 1, kBlue, 1, 27, kBlue, 1);
+ leg->SetHeader("Isolated bunch crossings");
+ hTRDEffPtPosAll_IsolatedBC->Draw("same"); leg->AddEntry(hTRDEffPtPosAll_IsolatedBC, "pos. (#geq 1 tracklet)", "p");
+ hTRDEffPtNegAll_IsolatedBC->Draw("same"); leg->AddEntry(hTRDEffPtNegAll_IsolatedBC, "neg. (#geq 1 tracklet)", "p");
+ hTRDEffPtPosTrk4_IsolatedBC->Draw("same"); leg->AddEntry(hTRDEffPtPosTrk4_IsolatedBC, "pos. (4 tracklets)", "p");
+ hTRDEffPtNegTrk4_IsolatedBC->Draw("same"); leg->AddEntry(hTRDEffPtNegTrk4_IsolatedBC, "neg. (4 tracklets)", "p");
+ hTRDEffPtPosTrk5_IsolatedBC->Draw("same"); leg->AddEntry(hTRDEffPtPosTrk5_IsolatedBC, "pos. (5 tracklets)", "p");
+ hTRDEffPtNegTrk5_IsolatedBC->Draw("same"); leg->AddEntry(hTRDEffPtNegTrk5_IsolatedBC, "neg. (5 tracklets)", "p");
+ hTRDEffPtPosTrk6_IsolatedBC->Draw("same"); leg->AddEntry(hTRDEffPtPosTrk6_IsolatedBC, "pos. (6 tracklets)", "p");
+ hTRDEffPtNegTrk6_IsolatedBC->Draw("same"); leg->AddEntry(hTRDEffPtNegTrk6_IsolatedBC, "neg. (6 tracklets)", "p");
+ }
+ }
+
+ leg->Draw();
+
+ //---------------------------------------------------------
+ // TRD-TOF matching efficiency vs pt
+ pad = ((TVirtualPad*)l->At(7)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.02);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+
+ rangeEffPt->Draw();
+ lat->DrawLatex(0.2, 1.42, "TRD-TOF matching efficiency");
+
+ if(!useIsolatedBC) {
+ SetStyle(hTOFEffPtPosAll, 1, kRed, 1, 24, kRed, 1);
+ SetStyle(hTOFEffPtPosTrk4, 1, kRed, 1, 25, kRed, 1);
+ SetStyle(hTOFEffPtPosTrk5, 1, kRed, 1, 26, kRed, 1);
+ SetStyle(hTOFEffPtPosTrk6, 1, kRed, 1, 27, kRed, 1);
+ SetStyle(hTOFEffPtNegAll, 1, kBlue, 1, 24, kBlue, 1);
+ SetStyle(hTOFEffPtNegTrk4, 1, kBlue, 1, 25, kBlue, 1);
+ SetStyle(hTOFEffPtNegTrk5, 1, kBlue, 1, 26, kBlue, 1);
+ SetStyle(hTOFEffPtNegTrk6, 1, kBlue, 1, 27, kBlue, 1);
+ hTOFEffPtPosAll->Draw("same");
+ hTOFEffPtPosTrk4->Draw("same");
+ hTOFEffPtPosTrk5->Draw("same");
+ hTOFEffPtPosTrk6->Draw("same");
+ hTOFEffPtNegAll->Draw("same");
+ hTOFEffPtNegTrk4->Draw("same");
+ hTOFEffPtNegTrk5->Draw("same");
+ hTOFEffPtNegTrk6->Draw("same");
+ }
+ else {
+ if(nIsolatedBC>0) {
+ SetStyle(hTOFEffPtPosAll_IsolatedBC, 1, kRed, 1, 24, kRed, 1);
+ SetStyle(hTOFEffPtPosTrk4_IsolatedBC, 1, kRed, 1, 25, kRed, 1);
+ SetStyle(hTOFEffPtPosTrk5_IsolatedBC, 1, kRed, 1, 26, kRed, 1);
+ SetStyle(hTOFEffPtPosTrk6_IsolatedBC, 1, kRed, 1, 27, kRed, 1);
+ SetStyle(hTOFEffPtNegAll_IsolatedBC, 1, kBlue, 1, 24, kBlue, 1);
+ SetStyle(hTOFEffPtNegTrk4_IsolatedBC, 1, kBlue, 1, 25, kBlue, 1);
+ SetStyle(hTOFEffPtNegTrk5_IsolatedBC, 1, kBlue, 1, 26, kBlue, 1);
+ SetStyle(hTOFEffPtNegTrk6_IsolatedBC, 1, kBlue, 1, 27, kBlue, 1);
+ hTOFEffPtPosAll_IsolatedBC->Draw("same");
+ hTOFEffPtPosTrk4_IsolatedBC->Draw("same");
+ hTOFEffPtPosTrk5_IsolatedBC->Draw("same");
+ hTOFEffPtPosTrk6_IsolatedBC->Draw("same");
+ hTOFEffPtNegAll_IsolatedBC->Draw("same");
+ hTOFEffPtNegTrk4_IsolatedBC->Draw("same");
+ hTOFEffPtNegTrk5_IsolatedBC->Draw("same");
+ hTOFEffPtNegTrk6_IsolatedBC->Draw("same");
+ }
+ }
+
+ //-----------------------------------------------------
+ // <ntracklets> vs (phi,eta)
+ pad = ((TVirtualPad*)l->At(2)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+
+ rangeEtaPhi->Draw();
+ lat->DrawLatex(-0.9, 3.6, "TRD <N_{tracklets}>");
+
+ TH3D* hNtracklets = (TH3D*)fCfContainer->Project(1, kTrackPhi, kTrackEta, kTrackTrdTracklets);
+ TH3D* hNtracklets_IsolatedBC=0x0;
+ for(Int_t ibc=0; ibc<3500; ++ibc) {
+ if(!isIsolated[ibc]) continue;
+ fCfContainer->SetRangeUser(kEventBC, Double_t(ibc), Double_t(ibc));
+ TH3D* temp = (TH3D*)fCfContainer->Project(1, kTrackPhi, kTrackEta, kTrackTrdTracklets);
+ if(!hNtracklets_IsolatedBC) hNtracklets_IsolatedBC = temp;
+ else {hNtracklets_IsolatedBC->Add(temp); delete temp;}
+ }
+ fCfContainer->SetRangeUser(kEventBC, 0.0, 3500.0); // reset the BC range
+
+ TProfile2D* hNtrackletsProf=0x0;
+ if(useIsolatedBC) {
+ if(nIsolatedBC>0)
+ hNtrackletsProf = hNtracklets_IsolatedBC->Project3DProfile();
+ }
+ else hNtrackletsProf = hNtracklets->Project3DProfile();
+ delete hNtracklets; if(hNtracklets_IsolatedBC) delete hNtracklets_IsolatedBC;
+ if(hNtrackletsProf) {
+ hNtrackletsProf->SetStats(kFALSE);
+ hNtrackletsProf->SetMinimum(0.);
+ hNtrackletsProf->SetMaximum(6.);
+ hNtrackletsProf->Draw("samecolz");
+ DrawTRDGrid();
+ }
+
+ // calculate the trend value for tracklets/track
+ TH2D* hNtrackletsVsP = (TH2D*)fCfContainer->Project(1, kTrackP, kTrackTrdTracklets);
+ if(trendValues && hNtrackletsVsP && hNtrackletsVsP->GetEntries()>0.1) {
+ TProfile* hNtrackletsVsPprof = hNtrackletsVsP->ProfileX("hNtrackletsVsPprof");
+ hNtrackletsVsPprof->Fit(funcConst, "QME0", "goff", 1.0, 3.0);
+ trendValues[8] = funcConst->GetParameter(0);
+ trendValues[9] = funcConst->GetParError(0);
+ delete hNtrackletsVsP;
+ }
+ TH2D* hNtrackletsVsP_IsolatedBC=0x0;
+ for(Int_t ibc=0; ibc<3500; ++ibc) {
+ if(!isIsolated[ibc]) continue;
+ fCfContainer->SetRangeUser(kEventBC, Double_t(ibc), Double_t(ibc));
+ TH2D* temp = (TH2D*)fCfContainer->Project(1, kTrackP, kTrackTrdTracklets);
+ if(!hNtrackletsVsP_IsolatedBC) hNtrackletsVsP_IsolatedBC = temp;
+ else {hNtrackletsVsP_IsolatedBC->Add(temp); delete temp;}
+ }
+ fCfContainer->SetRangeUser(kEventBC, 0.0, 3500.0); // reset the BC range
+ if(trendValues && hNtrackletsVsP_IsolatedBC && hNtrackletsVsP_IsolatedBC->GetEntries()>0.1) {
+ TProfile* hNtrackletsVsPprof_IsolatedBC = hNtrackletsVsP_IsolatedBC->ProfileX("hNtrackletsVsPprof_IsolatedBC");
+ hNtrackletsVsPprof_IsolatedBC->Fit(funcConst, "QME0", "goff", 1.0, 3.0);
+ trendValues[26] = funcConst->GetParameter(0);
+ trendValues[27] = funcConst->GetParError(0);
+ delete hNtrackletsVsPprof_IsolatedBC;
+ }
+
+ //--------------------------------------------------------------
+ // Nclusters per TRD track vs momentum
+ pad = ((TVirtualPad*)l->At(5)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.12);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ pad->SetLogz();
+
+ if(gROOT->FindObject("rangeNclsP")) delete gROOT->FindObject("rangeNclsP");
+ TH2F* rangeNclsP = new TH2F("rangeNclsP", "", 10, 0.0, 11.99, 10, 0.0, 199.0);
+ SetStyle(rangeNclsP->GetXaxis(), "p [GeV/c]", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeNclsP->GetYaxis(), "#clusters", 0.07, 0.8, kTRUE, 0.05);
+ rangeNclsP->SetStats(kFALSE);
+ rangeNclsP->Draw();
+ lat->DrawLatex(1.0, 205., "TRD Clusters / track");
+
+ TH2D* hNclsVsP = (TH2D*)fCfContainer->Project(1, kTrackP, kTrackTrdClusters);
+ TH2D* hNclsVsP_IsolatedBC=0x0;
+ for(Int_t ibc=0; ibc<3500; ++ibc) {
+ if(!isIsolated[ibc]) continue;
+ fCfContainer->SetRangeUser(kEventBC, Double_t(ibc), Double_t(ibc));
+ TH2D* temp = (TH2D*)fCfContainer->Project(1, kTrackP, kTrackTrdClusters);
+ if(!hNclsVsP_IsolatedBC) hNclsVsP_IsolatedBC = temp;
+ else {hNclsVsP_IsolatedBC->Add(temp); delete temp;}
+ }
+ fCfContainer->SetRangeUser(kEventBC, 0.0, 3500.0); // reset the BC range
+
+ if(useIsolatedBC && hNclsVsP_IsolatedBC) {
+ hNclsVsP_IsolatedBC->SetStats(kFALSE);
+ hNclsVsP_IsolatedBC->Draw("samecolz");
+ }
+ if(!useIsolatedBC && hNclsVsP) {
+ hNclsVsP->SetStats(kFALSE);
+ hNclsVsP->Draw("samecolz");
+ }
+
+ if(trendValues && hNclsVsP && hNclsVsP->GetEntries()>10) {
+ TProfile* hNclsVsPprof = hNclsVsP->ProfileX("hNclsVsPprof");
+ hNclsVsPprof->Fit(funcConst, "QME0", "goff", 1.0, 3.0);
+ trendValues[10] = funcConst->GetParameter(0);
+ trendValues[11] = funcConst->GetParError(0);
+ }
+ if(trendValues && hNclsVsP_IsolatedBC && hNclsVsP_IsolatedBC->GetEntries()>10) {
+ TProfile* hNclsVsPprof_IsolatedBC = hNclsVsP_IsolatedBC->ProfileX("hNclsVsPprof_IsolateBC");
+ hNclsVsPprof_IsolatedBC->Fit(funcConst, "QME0", "goff", 1.0, 3.0);
+ trendValues[28] = funcConst->GetParameter(0);
+ trendValues[29] = funcConst->GetParError(0);
+ }
+
+ //--------------------------------------------------------------
+ // TRD-TPC and TOF-TRD matching efficiency vs bunch crossing
+ pad = ((TVirtualPad*)l->At(8)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.02);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+
+ TH1D* phiProj = (TH1D*)fCfContainer->Project(1, kTrackPhi);
+ Double_t smPhiLimits[19];
+ Bool_t activeSM[18] = {kFALSE};
+ for(Int_t ism=0; ism<=18; ++ism) smPhiLimits[ism] = -TMath::Pi() + (2.0*TMath::Pi()/18.0)*ism;
+ CheckActiveSM(phiProj, activeSM);
+ for(Int_t ism=0; ism<18; ++ism) cout << "sm " << ism << " is active : " << (activeSM[ism] ? "yes" : "no") << endl;
+
+ fCfContainer->SetRangeUser(kTrackPt, 1.01, 2.99); // 1.0 < pt < 3.0 GeV/c
+ TH2D* hTPCPhiBC = (TH2D*)fCfContainer->Project(0, kEventBC, kTrackPhi);
+ TH2D* hTRDPhiBC = (TH2D*)fCfContainer->Project(1, kEventBC, kTrackPhi);
+ TH2D* hTOFPhiBC = (TH2D*)fCfContainer->Project(2, kEventBC, kTrackPhi);
+ TH1D* projectionBC = (TH1D*)fCfContainer->Project(0, kEventBC);
+ fCfContainer->SetRangeUser(kTrackPt, 0.0, 100.0); // reset the pt range
+ TH1D* hTRDEffBC = new TH1D("hTRDEffBC", "", hTPCPhiBC->GetXaxis()->GetNbins(), hTPCPhiBC->GetXaxis()->GetXmin(), hTPCPhiBC->GetXaxis()->GetXmax());
+ TH1D* hTOFEffBC = new TH1D("hTOFEffBC", "", hTPCPhiBC->GetXaxis()->GetNbins(), hTPCPhiBC->GetXaxis()->GetXmin(), hTPCPhiBC->GetXaxis()->GetXmax());
+
+ for(Int_t bcBin=1; bcBin<=hTPCPhiBC->GetXaxis()->GetNbins(); ++bcBin) {
+ if(projectionBC->GetBinContent(bcBin)<0.1) continue;
+ Double_t tpcEntries = 0.0; Double_t trdEntries = 0.0; Double_t tofEntries = 0.0;
+ for(Int_t phiBin=1; phiBin<=hTPCPhiBC->GetYaxis()->GetNbins(); ++phiBin) {
+ Double_t phi = hTPCPhiBC->GetYaxis()->GetBinCenter(phiBin);
+ for(Int_t ism=0; ism<18; ++ism) {
+ if(phi>=smPhiLimits[ism] && phi<smPhiLimits[ism+1] && activeSM[ism]) {
+ tpcEntries += hTPCPhiBC->GetBinContent(bcBin, phiBin);
+ trdEntries += hTRDPhiBC->GetBinContent(bcBin, phiBin);
+ tofEntries += hTOFPhiBC->GetBinContent(bcBin, phiBin);
+ }
+ } // end loop over super-modules
+ } // end loop over phi bins
+ hTRDEffBC->SetBinContent(bcBin, (tpcEntries>0.01 ? trdEntries/tpcEntries : 0.0));
+ if(tpcEntries>0.01 && trdEntries>0.01 && (tpcEntries-trdEntries)>=0.01)
+ hTRDEffBC->SetBinError(bcBin, TMath::Sqrt(trdEntries*(tpcEntries-trdEntries)/tpcEntries/tpcEntries/tpcEntries));
+ hTOFEffBC->SetBinContent(bcBin, (trdEntries>0.01 ? tofEntries/trdEntries : 0.0));
+ if(trdEntries>0.01 && tofEntries>0.01 && (trdEntries-tofEntries)>=0.01)
+ hTOFEffBC->SetBinError(bcBin, TMath::Sqrt(tofEntries*(trdEntries-tofEntries)/trdEntries/trdEntries/trdEntries));
+ } // end loop over BC bins
+ delete hTPCPhiBC; delete hTRDPhiBC; delete hTOFPhiBC;
+ delete projectionBC;
+
+ if(gROOT->FindObject("rangeBC")) delete gROOT->FindObject("rangeBC");
+ TH2F* rangeBC = new TH2F("rangeBC", "", 10, -0.5, 3499.5, 10, 0.0, 1.4);
+ rangeBC->SetStats(kFALSE);
+ SetStyle(rangeBC->GetXaxis(), "Bunch crossing", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeBC->GetYaxis(), "efficiency", 0.07, 0.8, kTRUE, 0.05);
+ rangeBC->Draw();
+
+ TLegend* legBC=new TLegend(0.8, 0.7, 0.95, 0.89);
+ legBC->SetBorderSize(0);
+ legBC->SetMargin(0.15);
+ legBC->SetFillColor(0);
+ if(hTRDEffBC) {
+ hTRDEffBC->SetStats(kFALSE);
+ SetStyle(hTRDEffBC, 1, kRed, 2, 24, kRed, 1); legBC->AddEntry(hTRDEffBC, "TPC-TRD", "p");
+ SetStyle(hTOFEffBC, 1, kBlue, 2, 24, kBlue, 1); legBC->AddEntry(hTOFEffBC, "TRD-TOF", "p");
+ hTRDEffBC->Draw("same");
+ hTOFEffBC->Draw("same");
+ legBC->Draw();
+ lat->DrawLatex(200., 1.42, "Matching efficiency at 1<p_{T}<3 GeV/c");
+ }
+
+ // reset the user range on the event multiplicity
+ fCfContainer->SetRangeUser(kEventMult, 0.0, 6.0, kTRUE);
+ if(cutTOFbc) fCfContainer->SetRangeUser(kTrackTOFBC, -1000.0, +1000.0); // reset the cut on TOFbc
+
+ delete funcConst;
+}
+
+
+//_________________________________________________________________
+void AliTRDcheckESD::PlotPidSummaryFromCF(Int_t centralityClass, Double_t* trendValues, Bool_t useIsolatedBC, Bool_t cutTOFbc) {
+
+ if(!fCfContainer) return;
+
+ TLatex *lat=new TLatex();
+ lat->SetTextSize(0.07);
+ lat->SetTextColor(2);
+ gPad->SetTopMargin(0.05); gPad->SetBottomMargin(0.001);
+ gPad->SetLeftMargin(0.001); gPad->SetRightMargin(0.001);
+ gPad->Divide(3,3,0.,0.);
+ TList* l=gPad->GetListOfPrimitives();
+
+ fCfContainer->SetRangeUser(kTrackDCAxy, -0.999, +0.999);
+ fCfContainer->SetRangeUser(kTrackDCAz, -3.0, +3.0);
+ if(cutTOFbc) fCfContainer->SetRangeUser(kTrackTOFBC, 0.0, 0.0);
+
+ // find all the isolated bunch crossings with entries
+ Bool_t isIsolated[3500];
+ TH1D* tempTH1D = (TH1D*)fCfContainer->Project(0, kEventBC);
+ FindIsolatedBCs(tempTH1D, isIsolated); delete tempTH1D;
+ Int_t nIsolatedBC = 0;
+ for(Int_t ibc=0; ibc<3500; ++ibc)
+ if(isIsolated[ibc]) nIsolatedBC++;
+
+ if(centralityClass>0) // select the multiplicity class
+ fCfContainer->SetRangeUser(kEventMult, Double_t(centralityClass), Double_t(centralityClass), kTRUE);
+
+ if(gROOT->FindObject("rangeEtaPhi2")) delete gROOT->FindObject("rangeEtaPhi2");
+ TH2F* rangeEtaPhi = new TH2F("rangeEtaPhi2", "", 10, -0.99, +0.99, 10, -3.4, +3.4);
+ SetStyle(rangeEtaPhi->GetXaxis(), "#eta", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeEtaPhi->GetYaxis(), "detector #varphi", 0.07, 0.8, kTRUE, 0.05);
+ rangeEtaPhi->SetStats(kFALSE);
+
+ // eta-phi distr. for <Qtot> in layer 0
+ TVirtualPad* pad;
+ TProfile2D* hProf2D;
+ for(Int_t iLayer=0; iLayer<6; ++iLayer) {
+ pad = ((TVirtualPad*)l->At((iLayer<3 ? iLayer*3 : (iLayer-3)*3+1))); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEtaPhi->Draw();
+
+ TH3D* hQtotEtaPhi=0x0;
+ if(useIsolatedBC) {
+ for(Int_t ibc=0; ibc<3500; ++ibc) {
+ if(!isIsolated[ibc]) continue;
+ fCfContainer->SetRangeUser(kEventBC, Double_t(ibc), Double_t(ibc));
+ TH3D* temp = (TH3D*)fCfContainer->Project(1, kTrackPhi, kTrackEta, kTrackQtot+iLayer);
+ if(!hQtotEtaPhi) hQtotEtaPhi = temp;
+ else {hQtotEtaPhi->Add(temp); delete temp;}
+ }
+ fCfContainer->SetRangeUser(kEventBC, 0.0, 3500.0);
+ }
+ else hQtotEtaPhi = (TH3D*)fCfContainer->Project(1, kTrackPhi, kTrackEta, kTrackQtot+iLayer);
+ hProf2D = (hQtotEtaPhi ? hQtotEtaPhi->Project3DProfile() : 0x0);
+ if(hQtotEtaPhi) delete hQtotEtaPhi;
+
+ if(hProf2D) {
+ hProf2D->SetStats(kFALSE);
+ hProf2D->SetMinimum(0.);
+ hProf2D->SetMaximum(4.);
+ hProf2D->Draw("samecolz");
+ }
+ lat->DrawLatex(-0.9, 3.6, Form("TRD <Q_{tot}> Layer %d", iLayer));
+ DrawTRDGrid();
+ }
+
+ // PH versus slice number
+ pad = ((TVirtualPad*)l->At(2)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.03); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+
+ if(gROOT->FindObject("rangePHslice")) delete gROOT->FindObject("rangePHslice");
+ TH2F* rangePHslice=new TH2F("rangePHslice", "", 8, -0.5, 7.5, 10, 0.0, 2000.);
+ rangePHslice->SetStats(kFALSE);
+ SetStyle(rangePHslice->GetXaxis(), "slice", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangePHslice->GetYaxis(), "PH", 0.07, 0.8, kTRUE, 0.05);
+ rangePHslice->Draw();
+
+ TF1* funcPol1 = new TF1("funcPol1", "[0]+[1]*x", 2.9, 6.4);
+
+ TH2F* h2F;
+ TH1D* hF;
+ if((h2F = dynamic_cast<TH2F*>(fHistos->At(kPHSlice+centralityClass)))) {
+ hF = Proj2D(h2F);
+ h2F->SetStats(kFALSE);
+ h2F->Draw("samecolz");
+ if(trendValues) {
+ hF->Fit(funcPol1, "QME0", "goff", 2.9, 6.4);
+ trendValues[12] = funcPol1->GetParameter(0); // PH plateau
+ trendValues[13] = funcPol1->GetParError(0); // PH plateau
+ trendValues[14] = funcPol1->GetParameter(1); // PH slope
+ trendValues[15] = funcPol1->GetParError(1); // PH slope
+ }
+ hF->SetLineWidth(2);
+ hF->SetLineStyle(2);
+ hF->Draw("same");
+ }
+ delete funcPol1;
+
+ // Qtot vs P
+ pad = ((TVirtualPad*)l->At(5)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.03); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ pad->SetLogz();
+
+ if(gROOT->FindObject("rangeQtotP")) delete gROOT->FindObject("rangeQtotP");
+ TH2F* rangeQtotP = new TH2F("rangeQtotP", "", 10, 0.0, 11.99, 10, 0.0, 11.99);
+ SetStyle(rangeQtotP->GetXaxis(), "P [GeV/c]", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeQtotP->GetYaxis(), "Q_{tot}", 0.07, 0.8, kTRUE, 0.05);
+ rangeQtotP->SetStats(kFALSE);
+ rangeQtotP->Draw();
+
+ TH2D* hQtotP_IsolatedBC = 0x0;
+ for(Int_t ibc=0; ibc<3500; ++ibc) {
+ if(!isIsolated[ibc]) continue;
+ fCfContainer->SetRangeUser(kEventBC, Double_t(ibc), Double_t(ibc));
+ TH2D* temp = (TH2D*)fCfContainer->Project(1, kTrackP, kTrackQtot);
+ if(!hQtotP_IsolatedBC) hQtotP_IsolatedBC = temp;
+ else {hQtotP_IsolatedBC->Add(temp); delete temp;}
+ for(Int_t il=1; il<6; ++il) {
+ temp = (TH2D*)fCfContainer->Project(1, kTrackP, kTrackQtot+il);
+ hQtotP_IsolatedBC->Add(temp); delete temp;
+ }
+ }
+ fCfContainer->SetRangeUser(kEventBC, 0.0, 3500.0);
+
+ TH2D* temp = (TH2D*)fCfContainer->Project(1, kTrackP, kTrackQtot);
+ TH2D* hQtotP = temp;
+ for(Int_t il=1; il<6; ++il) {
+ temp = (TH2D*)fCfContainer->Project(1, kTrackP, kTrackQtot+il);
+ hQtotP->Add(temp); delete temp;
+ }
+
+ if(hQtotP_IsolatedBC)
+ for(Int_t i=1; i<=hQtotP_IsolatedBC->GetXaxis()->GetNbins(); ++i)
+ hQtotP_IsolatedBC->SetBinContent(i, 1, 0.0);
+ TH1D* hQtotProj_IsolatedBC = (hQtotP_IsolatedBC ? Proj2D(hQtotP_IsolatedBC) : 0x0);
+ if(hQtotProj_IsolatedBC) SetStyle(hQtotProj_IsolatedBC, 2, kBlue, 2, 1, kBlue, 1);
+ if(trendValues && hQtotProj_IsolatedBC && hQtotProj_IsolatedBC->GetEntries()>2) {
+ trendValues[30] = hQtotProj_IsolatedBC->GetBinContent(hQtotProj_IsolatedBC->FindBin(1.0)); // Landau MPV at 1GeV/c
+ trendValues[31] = hQtotProj_IsolatedBC->GetBinError(hQtotProj_IsolatedBC->FindBin(1.0)); // Landau width at 1 GeV/c
+ }
+ if(hQtotP)
+ for(Int_t i=1; i<=hQtotP->GetXaxis()->GetNbins(); ++i)
+ hQtotP->SetBinContent(i, 1, 0.0);
+ TH1D* hQtotProj = (hQtotP ? Proj2D(hQtotP) : 0x0);
+ if(hQtotProj) SetStyle(hQtotProj, 2, kBlue, 2, 1, kBlue, 1);
+ if(trendValues && hQtotProj && hQtotProj->GetEntries()>2) {
+ trendValues[16] = hQtotProj->GetBinContent(hQtotProj->FindBin(1.0)); // Landau MPV at 1GeV/c
+ trendValues[17] = hQtotProj->GetBinError(hQtotProj->FindBin(1.0)); // Landau width at 1 GeV/c
+ }
+ if(useIsolatedBC && hQtotP_IsolatedBC) {
+ hQtotP_IsolatedBC->SetStats(kFALSE);
+ for(Int_t i=1; i<=hQtotP_IsolatedBC->GetXaxis()->GetNbins(); ++i) hQtotP_IsolatedBC->SetBinContent(i, 1, 0.0);
+ hQtotP_IsolatedBC->Draw("samecolz");
+ hQtotProj_IsolatedBC->Draw("same");
+ }
+ if(!useIsolatedBC && hQtotP) {
+ hQtotP->SetStats(kFALSE);
+ hQtotP->Draw("samecolz");
+ hQtotProj->Draw("same");
+ }
+
+ // reset the user range on the event multiplicity
+ fCfContainer->SetRangeUser(kEventMult, 0.0, 6.0, kTRUE);
+ if(cutTOFbc) fCfContainer->SetRangeUser(kTrackTOFBC, -1000.0, +1000.0); // reset the cut on TOFbc
+}
+
+
+//_________________________________________________________________
+Bool_t AliTRDcheckESD::PlotCentSummary(Double_t* trendValues) {
+
+ Bool_t isGoodForSaving=kFALSE;
+
+ trendValues = trendValues;
+
+ TLatex* lat=new TLatex();
+ lat->SetTextSize(0.06);
+ lat->SetTextColor(2);
+
+ gPad->SetTopMargin(0.05); gPad->SetBottomMargin(0.001);
+ gPad->SetLeftMargin(0.001); gPad->SetRightMargin(0.001);
+ gPad->Divide(3,3,0.,0.);
+ TList* l=gPad->GetListOfPrimitives();
+
+ TPad* pad=0x0;
+
+ if(gROOT->FindObject("rangeEffPt")) delete gROOT->FindObject("rangeEffPt");
+ TH2F* rangeEffPt=new TH2F("rangeEffPt", "",10,0.,10.,10,0.,1.4);
+ rangeEffPt->SetStats(kFALSE);
+ SetStyle(rangeEffPt->GetXaxis(), "p_{T} [GeV/c]", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeEffPt->GetYaxis(), "efficiency", 0.07, 0.8, kTRUE, 0.05);
+
+ TH3F *h3(NULL), *h3p(NULL), *h3n(NULL);
+ Int_t padsForEffs[5] = {0,3,6,1,4};
+ for(Int_t iCent=1; iCent<6; ++iCent) {
+ // TPC-TRD matching efficiencies
+ pad = ((TPad*)l->At(padsForEffs[iCent-1])); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.02); pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+
+ if(!(h3p = dynamic_cast<TH3F*>(fHistos->At(kTPCRefTracksPos+iCent)))) continue;
+ if(!(h3n = dynamic_cast<TH3F*>(fHistos->At(kTPCRefTracksNeg+iCent)))) continue;
+ // =============================================
+ if(!(h3 = dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksPos+iCent)))) continue;
+ TH1F* hFeffP = EfficiencyTRD(h3p, h3, kTRUE);
+ //
+ if(!(h3 = dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksNeg+iCent)))) continue;
+ TH1F* hFeffN = EfficiencyTRD(h3n, h3, kTRUE);
+ // =============================================
+ if(!(h3 = dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksPos4+iCent)))) continue;
+ TH1F* hFeffP4 = EfficiencyTRD(h3p, h3, kTRUE);
+ //
+ if(!(h3 = dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksNeg4+iCent)))) continue;
+ TH1F* hFeffN4 = EfficiencyTRD(h3n, h3, kTRUE);
+ // =============================================
+ if(!(h3 = dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksPos5+iCent)))) continue;
+ TH1F* hFeffP5 = EfficiencyTRD(h3p, h3, kTRUE);
+ //
+ if(!(h3 = dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksNeg5+iCent)))) continue;
+ TH1F* hFeffN5 = EfficiencyTRD(h3n, h3, kTRUE);
+ // =============================================
+ if(!(h3 = dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksPos6+iCent)))) continue;
+ TH1F* hFeffP6 = EfficiencyTRD(h3p, h3, kTRUE);
+ //
+ if(!(h3 = dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksNeg6+iCent)))) continue;
+ TH1F* hFeffN6 = EfficiencyTRD(h3n, h3, kTRUE);
+
+ rangeEffPt->Draw();
+
+ TLine line;
+ line.SetLineStyle(2);
+ line.SetLineWidth(2);
+ line.DrawLine(rangeEffPt->GetXaxis()->GetXmin(), 0.7, rangeEffPt->GetXaxis()->GetXmax(), 0.7);
+ line.DrawLine(rangeEffPt->GetXaxis()->GetXmin(), 0.9, rangeEffPt->GetXaxis()->GetXmax(), 0.9);
+ line.SetLineStyle(1);
+ line.SetLineWidth(1);
+ line.DrawLine(rangeEffPt->GetXaxis()->GetXmin(), 1.0, rangeEffPt->GetXaxis()->GetXmax(), 1.0);
+ if(hFeffP) SetStyle(hFeffP, 1, kRed, 1, 24, kRed, 1);
+ if(hFeffP4) SetStyle(hFeffP4, 1, kRed, 1, 25, kRed, 1);
+ if(hFeffP5) SetStyle(hFeffP5, 1, kRed, 1, 26, kRed, 1);
+ if(hFeffP6) SetStyle(hFeffP6, 1, kRed, 1, 27, kRed, 1);
+ if(hFeffN) SetStyle(hFeffN, 1, kBlue, 1, 24, kBlue, 1);
+ if(hFeffN4) SetStyle(hFeffN4, 1, kBlue, 1, 25, kBlue, 1);
+ if(hFeffN5) SetStyle(hFeffN5, 1, kBlue, 1, 26, kBlue, 1);
+ if(hFeffN6) SetStyle(hFeffN6, 1, kBlue, 1, 27, kBlue, 1);
+
+ TLegend* leg=new TLegend(0.16, 0.7, 0.61, 0.89);
+ leg->SetFillColor(0);
+ leg->SetNColumns(2);
+ leg->SetTextSize(0.039);
+ leg->SetMargin(0.1);
+ if(hFeffP && hFeffP->Integral()>0.001) {
+ isGoodForSaving = kTRUE;
+ hFeffP->Draw("same");
+ leg->AddEntry(hFeffP, "pos. (#geq 1 trcklt)", "p");
+ }
+ if(hFeffN && hFeffN->Integral()>0.001) {
+ isGoodForSaving = kTRUE;
+ hFeffN->Draw("same");
+ leg->AddEntry(hFeffN, "neg. (#geq 1 trcklt)", "p");
+ }
+ if(hFeffP4 && hFeffP4->Integral()>0.001) {
+ isGoodForSaving = kTRUE;
+ hFeffP4->Draw("same");
+ leg->AddEntry(hFeffP4, "pos. (4 trcklts)", "p");
+ }
+ if(hFeffN4 && hFeffN4->Integral()>0.001) {
+ isGoodForSaving = kTRUE;
+ hFeffN4->Draw("same");
+ leg->AddEntry(hFeffN4, "neg. (4 trcklts)", "p");
+ }
+ if(hFeffP5 && hFeffP5->Integral()>0.001) {
+ isGoodForSaving = kTRUE;
+ hFeffP5->Draw("same");
+ leg->AddEntry(hFeffP5, "pos. (5 trcklts)", "p");
+ }
+ if(hFeffN5 && hFeffN5->Integral()>0.001) {
+ isGoodForSaving = kTRUE;
+ hFeffN5->Draw("same");
+ leg->AddEntry(hFeffN5, "neg. (5 trcklts)", "p");
+ }
+ if(hFeffP6 && hFeffP6->Integral()>0.001) {
+ isGoodForSaving = kTRUE;
+ hFeffP6->Draw("same");
+ leg->AddEntry(hFeffP6, "pos. (6 trcklts)", "p");
+ }
+ if(hFeffN6 && hFeffN6->Integral()>0.001) {
+ isGoodForSaving = kTRUE;
+ hFeffN6->Draw("same");
+ leg->AddEntry(hFeffN6, "neg. (6 trklts)", "p");
+ }
+
+ if(isGoodForSaving) {
+ if(iCent==1) leg->Draw();
+ lat->DrawLatex(5.6, 1.3, Form("Centrality class %d", iCent));
+ lat->DrawLatex(0.5, 1.42, "TPC-TRD matching efficiency");
+ }
+ } // end loop over multiplicity intervals
+
+ // Number of clusters per TRD track
+ pad = ((TPad*)l->At(2)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.02);
+ pad->SetTopMargin(0.02); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ if(gROOT->FindObject("rangeNcls")) delete gROOT->FindObject("rangeNcls");
+ TH2F* rangeNcls = new TH2F("rangeNcls", "", 10, 0.0, 199.9, 10, 0.0, 1.199);
+ SetStyle(rangeNcls->GetXaxis(), "# TRD clusters", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeNcls->GetYaxis(), "entries (a.u.)", 0.07, 0.8, kTRUE, 0.05);
+ rangeNcls->SetStats(kFALSE);
+ rangeNcls->Draw();
+
+ TH2F* h2F[6]; TH1D* proj[6];
+ TLegend* leg=new TLegend(0.2, 0.7, 0.5, 0.95);
+ leg->SetFillColor(0);
+ Bool_t isGood=kFALSE;
+ for(Int_t iCent=0; iCent<6; ++iCent) {
+ h2F[iCent] = dynamic_cast<TH2F*>(fHistos->At(kNClsTrackTRD+iCent));
+ proj[iCent] = (h2F[iCent] && h2F[iCent]->GetEntries()>10 ? h2F[iCent]->ProjectionY(Form("projCent%d",iCent)) : 0x0);
+ if(proj[iCent]) {
+ proj[iCent]->SetLineColor(iCent<4 ? iCent+1 : iCent+2);
+ Double_t maximum = proj[iCent]->GetMaximum();
+ if(maximum>1.0)
+ proj[iCent]->Scale(1.0/maximum);
+ proj[iCent]->SetStats(kFALSE);
+ proj[iCent]->Draw("same");
+ leg->AddEntry(proj[iCent], (iCent==0 ? "all centralities" : Form("centrality class %d", iCent)), "l");
+ isGood = kTRUE;
+ }
+ }
+ if(isGood) leg->Draw();
+ isGoodForSaving = isGoodForSaving || isGood;
+
+ // Qtot vs P
+ pad = ((TPad*)l->At(5)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.02);
+ pad->SetTopMargin(0.02); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ if(gROOT->FindObject("rangeQtot")) delete gROOT->FindObject("rangeQtot");
+ TH2F* rangeQtot = new TH2F("rangeQtot", "", 10, 0.0, 9.999, 10, 0.0, 1.199);
+ SetStyle(rangeQtot->GetXaxis(), "Q_{tot} (a.u.)", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeQtot->GetYaxis(), "entries (a.u.)", 0.07, 0.8, kTRUE, 0.05);
+ rangeQtot->SetStats(kFALSE);
+ rangeQtot->Draw();
+
+ TH1D* projQ[6];
+ TLegend* leg2=new TLegend(0.6, 0.7, 0.9, 0.95);
+ leg2->SetFillColor(0);
+ isGood = kFALSE;
+ for(Int_t iCent=0; iCent<6; ++iCent) {
+ h2F[iCent] = dynamic_cast<TH2F*>(fHistos->At(kQtotP+iCent));
+ projQ[iCent] = (h2F[iCent] && h2F[iCent]->GetEntries()>10 ? h2F[iCent]->ProjectionY(Form("projQCent%d",iCent)) : 0x0);
+ if(projQ[iCent]) {
+ projQ[iCent]->SetLineColor(iCent<4 ? iCent+1 : iCent+2);
+ Double_t maximum = projQ[iCent]->GetMaximum();
+ if(maximum>1.0)
+ projQ[iCent]->Scale(1.0/maximum);
+ projQ[iCent]->SetStats(kFALSE);
+ projQ[iCent]->Draw("same");
+ leg2->AddEntry(projQ[iCent], (iCent==0 ? "all centralities" : Form("centrality class %d", iCent)), "l");
+ isGood = kTRUE;
+ }
+ }
+ if(isGood) leg2->Draw();
+ isGoodForSaving = isGoodForSaving || isGood;
+ return isGoodForSaving;
+}
+
+
+//_________________________________________________________________
+Bool_t AliTRDcheckESD::PlotTrackingSummary(Int_t centralityClass, Double_t* trendValues) {
+
+ Bool_t isGoodForSaving=kFALSE;
+
+ TLatex *lat=new TLatex();
+ lat->SetTextSize(0.07);
+ lat->SetTextColor(2);
+ gPad->SetTopMargin(0.05); gPad->SetBottomMargin(0.001);
+ gPad->SetLeftMargin(0.001); gPad->SetRightMargin(0.001);
+ gPad->Divide(3,3,0.,0.);
+ TList* l=gPad->GetListOfPrimitives();
+ // eta-phi distr. for positive TPC tracks
+ TVirtualPad* pad = ((TVirtualPad*)l->At(0)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ if(gROOT->FindObject("rangeEtaPhi")) delete gROOT->FindObject("rangeEtaPhi");
+ TH2F* rangeEtaPhi = new TH2F("rangeEtaPhi", "", 10, -0.99, +0.99, 10, -3.4, +3.4);
+ SetStyle(rangeEtaPhi->GetXaxis(), "#eta", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeEtaPhi->GetYaxis(), "detector #varphi", 0.07, 0.8, kTRUE, 0.05);
+ rangeEtaPhi->SetStats(kFALSE);
+ rangeEtaPhi->Draw();
+ lat->DrawLatex(-0.9, 3.6, "TPC positive ref. tracks");
+
+ TH3F* h3F = dynamic_cast<TH3F*>(fHistos->At(kTPCRefTracksPos+centralityClass));
+ TH2F* h2FtpcP = 0x0;
+ Float_t nada=0.0;
+ if(h3F && h3F->GetEntries()>10) {
+ h2FtpcP = (TH2F*)Proj3D((TH3F*)h3F, 0x0, 1, h3F->GetZaxis()->GetNbins(), nada)->Clone();
+ h2FtpcP->SetStats(kFALSE);
+ h2FtpcP->Draw("samecolz"); isGoodForSaving = kTRUE;
+ isGoodForSaving = kTRUE;
+ }
+ //-----------------
+ // eta-phi distr. for negative TPC tracks
+ pad = ((TVirtualPad*)l->At(1)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEtaPhi->Draw();
+ lat->DrawLatex(-0.9, 3.6, "TPC negative ref. tracks");
+
+ h3F = dynamic_cast<TH3F*>(fHistos->At(kTPCRefTracksNeg+centralityClass));
+ TH2F* h2FtpcN = 0x0;
+ if(h3F && h3F->GetEntries()>10) {
+ h2FtpcN = (TH2F*)Proj3D((TH3F*)h3F, 0x0, 1, h3F->GetZaxis()->GetNbins(), nada)->Clone();
+ h2FtpcN->SetStats(kFALSE);
+ h2FtpcN->Draw("samecolz");
+ isGoodForSaving = kTRUE;
+ }
+ //----------------------------------------------
+ // eta-phi distr. for positive TRD tracks
+ pad = ((TVirtualPad*)l->At(3)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEtaPhi->Draw();
+ lat->DrawLatex(-0.9, 3.6, "TRD positive ref. tracks");
+
+ h3F = dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksPos+centralityClass));
+ TH2F* h2FtrdP = 0x0;
+ if(h3F && h3F->GetEntries()>10) {
+ h2FtrdP = (TH2F*)Proj3D((TH3F*)h3F, 0x0, 1, h3F->GetZaxis()->GetNbins(), nada)->Clone();
+ h2FtrdP->SetStats(kFALSE);
+ h2FtrdP->SetMaximum((h2FtpcP ? h2FtpcP->GetMaximum() : h2FtrdP->GetMaximum()));
+ h2FtrdP->Draw("samecolz");
+ isGoodForSaving=kTRUE;
+ }
+ //--------------------------------------------
+ // eta-phi distr. for negative TRD tracks
+ pad = ((TVirtualPad*)l->At(4)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEtaPhi->Draw();
+ lat->DrawLatex(-0.9, 3.6, "TRD negative ref. tracks");
+
+ h3F = dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksNeg+centralityClass));
+ TH2F* h2FtrdN = 0x0;
+ if(h3F && h3F->GetEntries()>10) {
+ h2FtrdN = (TH2F*)Proj3D((TH3F*)h3F, 0x0, 1, h3F->GetZaxis()->GetNbins(), nada)->Clone();
+ h2FtrdN->SetStats(kFALSE);
+ h2FtrdN->SetMaximum(h2FtpcN ? h2FtpcN->GetMaximum() : h2FtrdN->GetMaximum());
+ h2FtrdN->Draw("samecolz");
+ isGoodForSaving=kTRUE;
+ }
+ //----------------------------------------------
+ // eta-phi efficiency for positive TRD tracks
+ pad = ((TVirtualPad*)l->At(6)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEtaPhi->Draw();
+ lat->DrawLatex(-0.9, 3.6, "Efficiency positive tracks");
+
+ TH2F* h2Feff = (h2FtrdP ? (TH2F*)h2FtrdP->Clone("h2FeffPos") : 0x0);
+ if(h2Feff) {
+ h2Feff->Reset();
+ h2Feff->SetStats(kFALSE);
+ h2Feff->Divide(h2FtrdP, h2FtpcP);
+ h2Feff->SetMaximum(1.0);
+ if(h2Feff->GetEntries()>1) { h2Feff->Draw("samecolz"); isGoodForSaving=kTRUE; }
+ }
+ //-------------------------------------------------
+ // eta-phi efficiency for negative TRD tracks
+ pad = ((TVirtualPad*)l->At(7)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEtaPhi->Draw();
+ lat->DrawLatex(-0.9, 3.6, "Efficiency negative tracks");
+
+ h2Feff = (h2FtrdN ? (TH2F*)h2FtrdN->Clone("h2FeffNeg") : 0x0);
+ if(h2Feff) {
+ h2Feff->Reset();
+ h2Feff->SetStats(kFALSE);
+ h2Feff->Divide(h2FtrdN, h2FtpcN);
+ h2Feff->SetMaximum(1.0);
+ if(h2Feff->GetEntries()>0.1) { h2Feff->Draw("samecolz"); isGoodForSaving=kTRUE; }
+ }
+ //-----------------------------------------------------
+ // <ntracklets> vs (phi,eta)
+ pad = ((TVirtualPad*)l->At(2)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEtaPhi->Draw();
+ lat->DrawLatex(-0.9, 3.6, "TRD <N_{tracklets}>");
+
+ TProfile2D* hProf2D;
+ if((hProf2D = dynamic_cast<TProfile2D*>(fHistos->At(kTRDEtaPhiAvNtrkl+centralityClass)))) {
+ if(hProf2D->GetEntries()>10) {
+ hProf2D->SetStats(kFALSE);
+ hProf2D->SetMinimum(0.);
+ hProf2D->SetMaximum(6.);
+ if(hProf2D->GetEntries()>1) { hProf2D->Draw("samecolz"); isGoodForSaving = kTRUE; }
+ }
+ }
+ //---------------------------------------------------------
+ // TPC-TRD matching efficiency vs pt
+ pad = ((TVirtualPad*)l->At(5)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.02);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ TH1F* hFeffP = EfficiencyTRD(dynamic_cast<TH3F*>(fHistos->At(kTPCRefTracksPos+centralityClass)),
+ dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksPos+centralityClass)), kTRUE);
+ TH1F* hFeffN = EfficiencyTRD(dynamic_cast<TH3F*>(fHistos->At(kTPCRefTracksNeg+centralityClass)),
+ dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksNeg+centralityClass)), kTRUE);
+ TH1F* hFeffP4 = EfficiencyTRD(dynamic_cast<TH3F*>(fHistos->At(kTPCRefTracksPos+centralityClass)),
+ dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksPos4+centralityClass)), kTRUE);
+ TH1F* hFeffN4 = EfficiencyTRD(dynamic_cast<TH3F*>(fHistos->At(kTPCRefTracksNeg+centralityClass)),
+ dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksNeg4+centralityClass)), kTRUE);
+ TH1F* hFeffP5 = EfficiencyTRD(dynamic_cast<TH3F*>(fHistos->At(kTPCRefTracksPos+centralityClass)),
+ dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksPos5+centralityClass)), kTRUE);
+ TH1F* hFeffN5 = EfficiencyTRD(dynamic_cast<TH3F*>(fHistos->At(kTPCRefTracksNeg+centralityClass)),
+ dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksNeg5+centralityClass)), kTRUE);
+ TH1F* hFeffP6 = EfficiencyTRD(dynamic_cast<TH3F*>(fHistos->At(kTPCRefTracksPos+centralityClass)),
+ dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksPos6+centralityClass)), kTRUE);
+ TH1F* hFeffN6 = EfficiencyTRD(dynamic_cast<TH3F*>(fHistos->At(kTPCRefTracksNeg+centralityClass)),
+ dynamic_cast<TH3F*>(fHistos->At(kTRDRefTracksNeg6+centralityClass)), kTRUE);
+
+ TF1* funcConst = new TF1("funcConst", "[0]", 1.0, 3.0);
+
+ if(gROOT->FindObject("rangeEffPt2")) delete gROOT->FindObject("rangeEffPt2");
+ TH2F* rangeEffPt2=new TH2F("rangeEffPt2", "",10,0.,10.,10,0.,1.4);
+ rangeEffPt2->SetStats(kFALSE);
+ SetStyle(rangeEffPt2->GetXaxis(), "p_{T} [GeV/c]", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeEffPt2->GetYaxis(), "efficiency", 0.07, 0.8, kTRUE, 0.05);
+ rangeEffPt2->Draw();
+ lat->DrawLatex(0.5, 1.42, "TRD-TPC matching efficiency");
+ //++++++++++++++++++
+ TLine line;
+ line.SetLineStyle(2);
+ line.SetLineWidth(2);
+ line.DrawLine(rangeEffPt2->GetXaxis()->GetXmin(), 0.7, rangeEffPt2->GetXaxis()->GetXmax(), 0.7);
+ line.DrawLine(rangeEffPt2->GetXaxis()->GetXmin(), 0.9, rangeEffPt2->GetXaxis()->GetXmax(), 0.9);
+ line.SetLineStyle(1);
+ line.SetLineWidth(1);
+ line.DrawLine(rangeEffPt2->GetXaxis()->GetXmin(), 1.0, rangeEffPt2->GetXaxis()->GetXmax(), 1.0);
+ TLegend* leg=new TLegend(0.2, 0.7, 0.6, 0.89);
+ leg->SetNColumns(2);
+ leg->SetFillColor(0);
+ if(hFeffP){
+ hFeffP->SetMarkerStyle(24);
+ hFeffP->SetMarkerColor(2);
+ hFeffP->SetLineColor(2);
+ if(trendValues && hFeffP->GetEntries()>1) {
+ hFeffP->Fit(funcConst, "QME0", "goff", 1.0, 3.0);
+ trendValues[0] = funcConst->GetParameter(0);
+ trendValues[1] = funcConst->GetParError(0);
+ }
+ if(hFeffP->Integral()>0.001) {
+ hFeffP->Draw("same");
+ leg->AddEntry(hFeffP, "positives (#geq 1 tracklet)", "p");
+ }
+ }
+ if(hFeffN){
+ hFeffN->SetMarkerStyle(24);
+ hFeffN->SetMarkerColor(4);
+ hFeffN->SetLineColor(4);
+ if(trendValues && hFeffN->GetEntries()>1) {
+ hFeffN->Fit(funcConst, "QME0", "goff", 1.0, 3.0);
+ trendValues[2] = funcConst->GetParameter(0);
+ trendValues[3] = funcConst->GetParError(0);
+ }
+ if(hFeffN->Integral()>0.001) {
+ hFeffN->Draw("same");
+ leg->AddEntry(hFeffN, "negatives (#geq 1 tracklet)", "p");
+ }
+ }
+ if(hFeffP4){
+ hFeffP4->SetMarkerStyle(25);
+ hFeffP4->SetMarkerColor(2);
+ hFeffP4->SetLineColor(2);
+ if(hFeffP4->Integral()>0.001) {
+ hFeffP4->Draw("same");
+ leg->AddEntry(hFeffP4, "positives (4 tracklets)", "p");
+ }
+ }
+ if(hFeffN4){
+ hFeffN4->SetMarkerStyle(25);
+ hFeffN4->SetMarkerColor(4);
+ hFeffN4->SetLineColor(4);
+ if(hFeffN4->Integral()>0.001) {
+ hFeffN4->Draw("same");
+ leg->AddEntry(hFeffN4, "negatives (4 tracklets)", "p");
+ }
+ }
+ if(hFeffP5){
+ hFeffP5->SetMarkerStyle(26);
+ hFeffP5->SetMarkerColor(2);
+ hFeffP5->SetLineColor(2);
+ if(hFeffP5->Integral()>0.001) {
+ hFeffP5->Draw("same");
+ leg->AddEntry(hFeffP5, "positives (5 tracklets)", "p");
+ }
+ }
+ if(hFeffN5){
+ hFeffN5->SetMarkerStyle(26);
+ hFeffN5->SetMarkerColor(4);
+ hFeffN5->SetLineColor(4);
+ if(hFeffN5->Integral()>0.001) {
+ hFeffN5->Draw("same");
+ leg->AddEntry(hFeffN5, "negatives (5 tracklets)", "p");
+ }
+ }
+ if(hFeffP6){
+ hFeffP6->SetMarkerStyle(27);
+ hFeffP6->SetMarkerColor(2);
+ hFeffP6->SetLineColor(2);
+ if(hFeffP6->Integral()>0.001) {
+ hFeffP6->Draw("same");
+ leg->AddEntry(hFeffP6, "positives (6 tracklets)", "p");
+ }
+ }
+ if(hFeffN6){
+ hFeffN6->SetMarkerStyle(27);
+ hFeffN6->SetMarkerColor(4);
+ hFeffN6->SetLineColor(4);
+ if(hFeffN6->Integral()>0.001) {
+ hFeffN6->Draw("same");
+ leg->AddEntry(hFeffN6, "negatives (6 tracklets)", "p");
+ }
+ }
+ leg->Draw();
+
+ //--------------------------------------------------------------
+ // Nclusters per TRD track
+ pad = ((TVirtualPad*)l->At(8)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.12);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ pad->SetLogz();
+ if(gROOT->FindObject("rangeNclsP")) delete gROOT->FindObject("rangeNclsP");
+ TH2F* rangeNclsP = new TH2F("rangeNclsP", "", 10, 0.0, 11.99, 10, 0.0, 199.0);
+ SetStyle(rangeNclsP->GetXaxis(), "p [GeV/c]", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeNclsP->GetYaxis(), "#clusters", 0.07, 0.8, kTRUE, 0.05);
+ rangeNclsP->SetStats(kFALSE);
+ rangeNclsP->Draw();
+ lat->DrawLatex(1.0, 205., "TRD Clusters / track");
+
+ TH2F* hNclsVsP=0x0;
+ if((hNclsVsP = dynamic_cast<TH2F*>(fHistos->At(kNClsTrackTRD+centralityClass)))) {
+ hNclsVsP->SetStats(kFALSE);
+ if(hNclsVsP->GetEntries()>10) {
+ hNclsVsP->Draw("samecolz"); isGoodForSaving=kTRUE;
+ if(trendValues) {
+ TProfile* h2FProf = hNclsVsP->ProfileX("nclsVsPprof");
+ h2FProf->Fit(funcConst, "QME0", "goff", 1.0, 3.0);
+ trendValues[4] = funcConst->GetParameter(0);
+ trendValues[5] = funcConst->GetParError(0);
+ }
+ }
+ }
+
+ delete funcConst;
+ return isGoodForSaving;
+}
+
+
+//_________________________________________________________________
+Bool_t AliTRDcheckESD::PlotPidSummary(Int_t centralityClass, Double_t* trendValues) {
+
+ Bool_t isGoodForSaving=kFALSE;
+
+ TLatex *lat=new TLatex();
+ lat->SetTextSize(0.07);
+ lat->SetTextColor(2);
+ gPad->SetTopMargin(0.05); gPad->SetBottomMargin(0.001);
+ gPad->SetLeftMargin(0.001); gPad->SetRightMargin(0.001);
+ gPad->Divide(3,3,0.,0.);
+ TList* l=gPad->GetListOfPrimitives();
+ // eta-phi distr. for <Qtot> in layer 0
+ TVirtualPad* pad;
+ TProfile2D* hProf2D;
+ if(gROOT->FindObject("rangeEtaPhi2")) delete gROOT->FindObject("rangeEtaPhi2");
+ TH2F* rangeEtaPhi = new TH2F("rangeEtaPhi2", "", 10, -0.99, +0.99, 10, -3.4, +3.4);
+ SetStyle(rangeEtaPhi->GetXaxis(), "#eta", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeEtaPhi->GetYaxis(), "detector #varphi", 0.07, 0.8, kTRUE, 0.05);
+ rangeEtaPhi->SetStats(kFALSE);
+
+ for(Int_t iLayer=0; iLayer<6; ++iLayer) {
+ pad = ((TVirtualPad*)l->At((iLayer<3 ? iLayer*3 : (iLayer-3)*3+1))); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ rangeEtaPhi->Draw();
+ lat->DrawLatex(-0.9, 3.6, Form("TRD <Q_{tot}> Layer %d", iLayer));
+
+ if(!(hProf2D = dynamic_cast<TProfile2D*>(fHistos->At(kTRDEtaPhiAvQtot+6*centralityClass+iLayer)))) continue;
+ if(hProf2D && hProf2D->GetEntries()>10) {
+ hProf2D->SetStats(kFALSE);
+ hProf2D->SetMinimum(0.);
+ hProf2D->SetMaximum(4.);
+ if(hProf2D->GetEntries()>10) { hProf2D->Draw("samecolz"); isGoodForSaving=kTRUE; }
+ }
+ }
+
+ // PH versus slice number
+ pad = ((TVirtualPad*)l->At(2)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ if(gROOT->FindObject("rangePHslice")) delete gROOT->FindObject("rangePHslice");
+ TH2F* rangePHslice = new TH2F("rangePHslice", "", 10, -0.5, 7.5, 10, 0.0, 2000.0);
+ SetStyle(rangePHslice->GetXaxis(), "slice", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangePHslice->GetYaxis(), "PH", 0.07, 0.8, kTRUE, 0.05);
+ rangePHslice->SetStats(kFALSE);
+ rangePHslice->Draw();
+
+ TF1* funcPol1 = new TF1("funcPol1", "[0]+[1]*x", 2.9, 6.4);
+
+ TH2F* h2F;
+ TH1D* hF;
+ if((h2F = dynamic_cast<TH2F*>(fHistos->At(kPHSlice+centralityClass)))) {
+ if(h2F && h2F->GetEntries()>10) {
+ hF = Proj2D(h2F);
+ h2F->SetStats(kFALSE);
+ h2F->Draw("samecolz");
+ isGoodForSaving=kTRUE;
+ if(trendValues) {
+ hF->Fit(funcPol1, "QME0", "goff", 2.9, 6.4);
+ trendValues[6] = funcPol1->GetParameter(0);
+ trendValues[7] = funcPol1->GetParError(0);
+ trendValues[8] = funcPol1->GetParameter(1);
+ trendValues[9] = funcPol1->GetParError(1);
+ }
+ hF->SetLineWidth(2);
+ hF->Draw("same");
+ }
+ }
+ delete funcPol1;
+
+ // Qtot vs P
+ pad = ((TVirtualPad*)l->At(5)); pad->cd();
+ pad->SetLeftMargin(0.15); pad->SetRightMargin(0.1);
+ pad->SetTopMargin(0.1); pad->SetBottomMargin(0.15);
+ pad->SetGridx(kFALSE); pad->SetGridy(kFALSE);
+ pad->SetLogz();
+ if(gROOT->FindObject("rangeQtotP")) delete gROOT->FindObject("rangeQtotP");
+ TH2F* rangeQtotP = new TH2F("rangeQtotP", "", 10, 0.0, 11.99, 10, 0.0, 11.99);
+ SetStyle(rangeQtotP->GetXaxis(), "P [GeV/c]", 0.07, 0.8, kTRUE, 0.05);
+ SetStyle(rangeQtotP->GetYaxis(), "Q_{tot}", 0.07, 0.8, kTRUE, 0.05);
+ rangeQtotP->SetStats(kFALSE);
+ rangeQtotP->Draw();
+
+ if((h2F = dynamic_cast<TH2F*>(fHistos->At(kQtotP+centralityClass)))) {
+ if(h2F && h2F->GetEntries()>10) {
+ h2F->SetStats(kFALSE);
+ h2F->Draw("samecolz");
+ isGoodForSaving=kTRUE;
+ hF = Proj2D(h2F);
+ hF->SetLineWidth(2);
+ hF->Draw("same");
+ if(trendValues) {
+ trendValues[10] = hF->GetBinContent(hF->FindBin(1.0));
+ trendValues[11] = hF->GetBinError(hF->FindBin(1.0));
+ }
+ }
+ }
+ return isGoodForSaving;
+}
+
+//__________________________________________________________________________________________________
+void AliTRDcheckESD::DrawTRDGrid() {
+ //
+ // Draw a grid of lines showing the TRD supermodule and stack structure in (eta,phi) coordinates.
+ // The canvas on which to draw must already exist.
+ //
+ TLine line;
+ line.SetLineColor(2);
+ line.SetLineWidth(1);
+ line.SetLineStyle(2);
+ for(Int_t i=0; i<=9; ++i) {
+ line.DrawLine(-1.0, 2.0*TMath::Pi()/18.0*i, +1.0, 2.0*TMath::Pi()/18.0*i);
+ line.DrawLine(-1.0, -2.0*TMath::Pi()/18.0*i, +1.0, -2.0*TMath::Pi()/18.0*i);
+ }
+ line.DrawLine(-0.85, -3.2, -0.85, +3.2);
+ line.DrawLine(-0.54, -3.2, -0.54, +3.2);
+ line.DrawLine(-0.16, -3.2, -0.16, +3.2);
+ line.DrawLine(+0.16, -3.2, +0.16, +3.2);
+ line.DrawLine(+0.54, -3.2, +0.54, +3.2);
+ line.DrawLine(+0.85, -3.2, +0.85, +3.2);
+}
+
+//_________________________________________________________________
+void AliTRDcheckESD::SetStyle(TH1* hist,
+ Int_t lineStyle, Int_t lineColor, Int_t lineWidth,
+ Int_t markerStyle, Int_t markerColor, Int_t markerSize) {
+ //
+ // Set style settings for histograms
+ //
+ hist->SetLineStyle(lineStyle);
+ hist->SetLineColor(lineColor);
+ hist->SetLineWidth(lineWidth);
+ hist->SetMarkerStyle(markerStyle);
+ hist->SetMarkerColor(markerColor);
+ hist->SetMarkerSize(markerSize);
+}
+
+//____________________________________________________________________
+void AliTRDcheckESD::SetStyle(TAxis* axis, const Char_t* title, Float_t titleSize, Float_t titleOffset, Bool_t centerTitle,
+ Float_t labelSize) {
+ //
+ // Set style settings for axes
+ //
+ axis->SetTitle(title);
+ axis->SetTitleSize(titleSize);
+ axis->SetTitleOffset(titleOffset);
+ axis->CenterTitle(centerTitle);
+ axis->SetLabelSize(labelSize);
+}
+
+//____________________________________________________________________
+void AliTRDcheckESD::FindIsolatedBCs(TH1D* bcHist, Bool_t isIsolated[3500]) {
+ //
+ // Find the isolated bunch crossings
+ //
+ Int_t isolationSize = 10; // number of free bunches in both directions
+ for(Int_t bcBin=1; bcBin<=bcHist->GetXaxis()->GetNbins(); ++bcBin) {
+ Int_t bc = TMath::Nint(bcHist->GetBinCenter(bcBin));
+ if(bc<-0.001 || bc>3499.01) {
+ isIsolated[bc] = kFALSE;
+ continue;
+ }
+ Double_t entries = bcHist->GetBinContent(bcBin);
+ if(entries<0.001) {
+ isIsolated[bc] = kFALSE;
+ continue; // no entries
+ }
+
+ // check isolation
+ isIsolated[bc] = kTRUE;
+ for(Int_t ibc = TMath::Max(1,bcBin-isolationSize); ibc <= TMath::Min(3499, bcBin+isolationSize); ++ibc) {
+ if(ibc==bcBin) continue;
+ if(bcHist->GetBinContent(ibc)>0.01) {
+ isIsolated[bc] = kFALSE;
+ break;
+ }
+ }
+ } // end loop over BC bins
+
+ cout << "Isolated bunches: " << endl;
+ for(Int_t ibc=0; ibc<3500; ++ibc)
+ if(isIsolated[ibc]) cout << "BC #" << ibc << endl;
+}