1 /**************************************************************************
2 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
7 * Permission to use, copy, modify and distribute this software and its *
8 * documentation strictly for non-commercial purposes is hereby granted *
9 * without fee, provided that the above copyright notice appears in all *
10 * copies and that both the copyright notice and this permission notice *
11 * appear in the supporting documentation. The authors make no claims *
12 * about the suitability of this software for any purpose. It is *
13 * provided "as is" without express or implied warranty. *
14 **************************************************************************/
17 * analysis task for jet flow preparation
19 * this task is part of the emcal jet framework and should be run in the emcaljet train
20 * the following extensions to an accepted AliVEvent are expected:
22 * - background estimate rho
24 * aod's and esd's are handled transparently
25 * the task will attempt to estimate a phi-dependent background density rho
26 * by fitting vn harmonics to the dpt/dphi distribution
28 * author: Redmer Alexander Bertens, Utrecht Univeristy, Utrecht, Netherlands
29 * rbertens@cern.ch, rbertens@nikhef.nl, r.a.bertens@uu.nl
43 #include <AliAnalysisTask.h>
44 #include <AliAnalysisManager.h>
45 #include <AliCentrality.h>
46 #include <AliVVertex.h>
47 #include <AliESDEvent.h>
48 #include <AliAODEvent.h>
49 #include <AliAODTrack.h>
50 // emcal jet framework includes
51 #include <AliPicoTrack.h>
52 #include <AliEmcalJet.h>
53 #include <AliRhoParameter.h>
54 #include <AliLocalRhoParameter.h>
55 #include <AliAnalysisTaskRhoVnModulation.h>
57 class AliAnalysisTaskRhoVnModulation;
60 ClassImp(AliAnalysisTaskRhoVnModulation)
62 AliAnalysisTaskRhoVnModulation::AliAnalysisTaskRhoVnModulation() : AliAnalysisTaskEmcalJet("AliAnalysisTaskRhoVnModulation", kTRUE),
63 fDebug(0), fLocalInit(0), fAttachToEvent(kTRUE), fSemiCentralInclusive(kFALSE), fFillHistograms(kTRUE), fFillQAHistograms(kTRUE), fReduceBinsXByFactor(-1.), fReduceBinsYByFactor(-1.), fNoEventWeightsForQC(kTRUE), fCentralityClasses(0), fPtBinsHybrids(0), fPtBinsJets(0), fUserSuppliedV2(0), fUserSuppliedV3(0), fUserSuppliedR2(0), fUserSuppliedR3(0), fTracksCont(0), fJetsCont(0), fUseScaledRho(0), fNAcceptedTracks(0), fNAcceptedTracksQCn(0), fFitModulationType(kNoFit), fQCRecovery(kTryFit), fUsePtWeight(kTRUE), fUsePtWeightErrorPropagation(kTRUE), fDetectorType(kTPC), fFitModulationOptions("QWLI"), fRunModeType(kGrid), fDataType(kESD), fCollisionType(kPbPb), fRandom(0), fRunNumber(-1), fMappedRunNumber(0), fInCentralitySelection(-1), fFitModulation(0), fFitControl(0), fMinPvalue(0.01), fMaxPvalue(1), fNameJetClones(0), fNamePicoTrackClones(0), fNameRho(0), fLocalJetMinEta(-10), fLocalJetMaxEta(-10), fLocalJetMinPhi(-10), fLocalJetMaxPhi(-10), fSoftTrackMinPt(0.15), fSoftTrackMaxPt(5.), fSemiGoodJetMinPhi(0.), fSemiGoodJetMaxPhi(4.), fSemiGoodTrackMinPhi(0.), fSemiGoodTrackMaxPhi(4.), fAbsVertexZ(10), fHistCentrality(0), fHistVertexz(0), fHistRunnumbersPhi(0), fHistRunnumbersEta(0), fHistPvaluePDF(0), fHistPvalueCDF(0), fHistRhoStatusCent(0), fMinDisanceRCtoLJ(0), fRandomConeRadius(-1.), fMaxCones(-1), fAbsVnHarmonics(kTRUE), fExcludeLeadingJetsFromFit(1.), fRebinSwapHistoOnTheFly(kTRUE), fPercentageOfFits(10.), fUseV0EventPlaneFromHeader(kTRUE), fExplicitOutlierCut(-1), fMinLeadingHadronPt(0), fSubtractJetPt(kFALSE), fOutputList(0), fOutputListGood(0), fOutputListBad(0), fHistAnalysisSummary(0), fHistSwap(0), fProfV2(0), fProfV2Cumulant(0), fProfV3(0), fProfV3Cumulant(0), fHistPsiControl(0), fHistPsiSpread(0), fHistPsiVZEROA(0), fHistPsiVZEROC(0), fHistPsiVZERO(0), fHistPsiTPC(0), fHistPsiVZEROAV0M(0), fHistPsiVZEROCV0M(0), fHistPsiVZEROVV0M(0), fHistPsiTPCiV0M(0), fHistPsiVZEROATRK(0), fHistPsiVZEROCTRK(0), fHistPsiVZEROTRK(0), fHistPsiTPCTRK(0), fHistRhoVsMult(0), fHistRhoVsCent(0), fHistRhoAVsMult(0), fHistRhoAVsCent(0) {
64 for(Int_t i(0); i < 10; i++) {
65 fProfV2Resolution[i] = 0;
66 fProfV3Resolution[i] = 0;
67 fHistPicoTrackPt[i] = 0;
68 fHistPicoTrackMult[i] = 0;
72 /* fHistClusterPt[i] = 0; */
73 /* fHistClusterPhi[i] = 0; */
74 /* fHistClusterEta[i] = 0; */
75 /* fHistClusterCorrPt[i] = 0; */
76 /* fHistClusterCorrPhi[i] = 0; */
77 /* fHistClusterCorrEta[i] = 0; */
78 fHistRhoPackage[i] = 0;
81 fHistRhoVsRCPt[i] = 0;
83 fHistDeltaPtDeltaPhi2[i] = 0;
84 fHistDeltaPtDeltaPhi3[i] = 0;
85 fHistRCPhiEtaExLJ[i] = 0;
86 fHistRhoVsRCPtExLJ[i] = 0;
88 fHistDeltaPtDeltaPhi2ExLJ[i] = 0;
89 fHistDeltaPtDeltaPhi3ExLJ[i] = 0;
90 /* fHistRCPhiEtaRand[i] = 0; */
91 /* fHistRhoVsRCPtRand[i] = 0; */
92 /* fHistRCPtRand[i] = 0; */
93 /* fHistDeltaPtDeltaPhi2Rand[i] = 0; */
94 /* fHistDeltaPtDeltaPhi3Rand[i] = 0; */
97 fHistJetEtaPhi[i] = 0;
98 fHistJetPtArea[i] = 0;
99 fHistJetPtConstituents[i] = 0;
100 fHistJetEtaRho[i] = 0;
101 fHistJetPsi2Pt[i] = 0;
102 fHistJetPsi3Pt[i] = 0;
104 // default constructor
106 //_____________________________________________________________________________
107 AliAnalysisTaskRhoVnModulation::AliAnalysisTaskRhoVnModulation(const char* name, runModeType type) : AliAnalysisTaskEmcalJet(name, kTRUE),
108 fDebug(0), fLocalInit(0), fAttachToEvent(kTRUE), fSemiCentralInclusive(kFALSE), fFillHistograms(kTRUE), fFillQAHistograms(kTRUE), fReduceBinsXByFactor(-1.), fReduceBinsYByFactor(-1.), fNoEventWeightsForQC(kTRUE), fCentralityClasses(0), fPtBinsHybrids(0), fPtBinsJets(0), fUserSuppliedV2(0), fUserSuppliedV3(0), fUserSuppliedR2(0), fUserSuppliedR3(0), fTracksCont(0), fJetsCont(0), fUseScaledRho(0), fNAcceptedTracks(0), fNAcceptedTracksQCn(0), fFitModulationType(kNoFit), fQCRecovery(kTryFit), fUsePtWeight(kTRUE), fUsePtWeightErrorPropagation(kTRUE), fDetectorType(kTPC), fFitModulationOptions("QWLI"), fRunModeType(type), fDataType(kESD), fCollisionType(kPbPb), fRandom(0), fRunNumber(-1), fMappedRunNumber(0), fInCentralitySelection(-1), fFitModulation(0), fFitControl(0), fMinPvalue(0.01), fMaxPvalue(1), fNameJetClones(0), fNamePicoTrackClones(0), fNameRho(0), fLocalJetMinEta(-10), fLocalJetMaxEta(-10), fLocalJetMinPhi(-10), fLocalJetMaxPhi(-10), fSoftTrackMinPt(0.15), fSoftTrackMaxPt(5.), fSemiGoodJetMinPhi(0.), fSemiGoodJetMaxPhi(4.), fSemiGoodTrackMinPhi(0.), fSemiGoodTrackMaxPhi(4.), fAbsVertexZ(10), fHistCentrality(0), fHistVertexz(0), fHistRunnumbersPhi(0), fHistRunnumbersEta(0), fHistPvaluePDF(0), fHistPvalueCDF(0), fHistRhoStatusCent(0), fMinDisanceRCtoLJ(0), fRandomConeRadius(-1.), fMaxCones(-1), fAbsVnHarmonics(kTRUE), fExcludeLeadingJetsFromFit(1.), fRebinSwapHistoOnTheFly(kTRUE), fPercentageOfFits(10.), fUseV0EventPlaneFromHeader(kTRUE), fExplicitOutlierCut(-1), fMinLeadingHadronPt(0), fSubtractJetPt(kFALSE), fOutputList(0), fOutputListGood(0), fOutputListBad(0), fHistAnalysisSummary(0), fHistSwap(0), fProfV2(0), fProfV2Cumulant(0), fProfV3(0), fProfV3Cumulant(0), fHistPsiControl(0), fHistPsiSpread(0), fHistPsiVZEROA(0), fHistPsiVZEROC(0), fHistPsiVZERO(0), fHistPsiTPC(0), fHistPsiVZEROAV0M(0), fHistPsiVZEROCV0M(0), fHistPsiVZEROVV0M(0), fHistPsiTPCiV0M(0), fHistPsiVZEROATRK(0), fHistPsiVZEROCTRK(0), fHistPsiVZEROTRK(0), fHistPsiTPCTRK(0), fHistRhoVsMult(0), fHistRhoVsCent(0), fHistRhoAVsMult(0), fHistRhoAVsCent(0) {
109 for(Int_t i(0); i < 10; i++) {
110 fProfV2Resolution[i] = 0;
111 fProfV3Resolution[i] = 0;
112 fHistPicoTrackPt[i] = 0;
113 fHistPicoTrackMult[i] = 0;
114 fHistPicoCat1[i] = 0;
115 fHistPicoCat2[i] = 0;
116 fHistPicoCat3[i] = 0;
117 /* fHistClusterPt[i] = 0; */
118 /* fHistClusterPhi[i] = 0; */
119 /* fHistClusterEta[i] = 0; */
120 /* fHistClusterCorrPt[i] = 0; */
121 /* fHistClusterCorrPhi[i] = 0; */
122 /* fHistClusterCorrEta[i] = 0; */
123 fHistRhoPackage[i] = 0;
125 fHistRCPhiEta[i] = 0;
126 fHistRhoVsRCPt[i] = 0;
128 fHistDeltaPtDeltaPhi2[i] = 0;
129 fHistDeltaPtDeltaPhi3[i] = 0;
130 fHistRCPhiEtaExLJ[i] = 0;
131 fHistRhoVsRCPtExLJ[i] = 0;
132 fHistRCPtExLJ[i] = 0;
133 fHistDeltaPtDeltaPhi2ExLJ[i] = 0;
134 fHistDeltaPtDeltaPhi3ExLJ[i] = 0;
135 /* fHistRCPhiEtaRand[i] = 0; */
136 /* fHistRhoVsRCPtRand[i] = 0; */
137 /* fHistRCPtRand[i] = 0; */
138 /* fHistDeltaPtDeltaPhi2Rand[i] = 0; */
139 /* fHistDeltaPtDeltaPhi3Rand[i] = 0; */
140 fHistJetPtRaw[i] = 0;
142 fHistJetEtaPhi[i] = 0;
143 fHistJetPtArea[i] = 0;
144 fHistJetPtConstituents[i] = 0;
145 fHistJetEtaRho[i] = 0;
146 fHistJetPsi2Pt[i] = 0;
147 fHistJetPsi3Pt[i] = 0;
150 DefineInput(0, TChain::Class());
151 DefineOutput(1, TList::Class());
152 switch (fRunModeType) {
154 gStyle->SetOptFit(1);
155 DefineOutput(2, TList::Class());
156 DefineOutput(3, TList::Class());
158 default: fDebug = -1; // suppress debug info explicitely when not running locally
160 switch (fCollisionType) {
162 fFitModulationType = kNoFit;
166 if(fLocalRhoName=="") fLocalRhoName = Form("LocalRhoFrom_%s", GetName());
168 //_____________________________________________________________________________
169 AliAnalysisTaskRhoVnModulation::~AliAnalysisTaskRhoVnModulation()
172 if(fOutputList) delete fOutputList;
173 if(fOutputListGood) delete fOutputListGood;
174 if(fOutputListBad) delete fOutputListBad;
175 if(fFitModulation) delete fFitModulation;
176 if(fHistSwap) delete fHistSwap;
177 if(fCentralityClasses) delete fCentralityClasses;
178 if(fFitControl) delete fFitControl;
180 //_____________________________________________________________________________
181 void AliAnalysisTaskRhoVnModulation::ExecOnce()
184 fLocalRho = new AliLocalRhoParameter(fLocalRhoName.Data(), 0);
186 if(!(InputEvent()->FindListObject(fLocalRho->GetName()))) {
187 InputEvent()->AddObject(fLocalRho);
189 AliFatal(Form("%s: Container with name %s already present. Aborting", GetName(), fLocalRho->GetName()));
192 AliAnalysisTaskEmcalJet::ExecOnce(); // init the base class
193 AliAnalysisTaskEmcalJet::SetVzRange(-1.*fAbsVertexZ, fAbsVertexZ);
195 // unscaled rho has been retrieved by the parent class, now we retrieve rho scaled
196 fRho = dynamic_cast<AliRhoParameter*>(InputEvent()->FindListObject(Form("%s_Scaled", fRho->GetName())));
198 AliFatal(Form("%s: Couldn't find container for scaled rho. Aborting !", GetName()));
201 if(!GetJetContainer()) AliFatal(Form("%s: Couldn't find jet container. Aborting !", GetName()));
203 //_____________________________________________________________________________
204 Bool_t AliAnalysisTaskRhoVnModulation::InitializeAnalysis()
206 // initialize the anaysis
207 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
208 if(fRandomConeRadius <= 0) fRandomConeRadius = GetJetContainer()->GetJetRadius();
209 if(fMaxCones <= 0) fMaxCones = TMath::Nint(1.8*TMath::TwoPi()/(TMath::Pi()*fRandomConeRadius*fRandomConeRadius));
210 if(fLocalJetMinEta > -10 && fLocalJetMaxEta > -10) GetJetContainer()->SetJetEtaLimits(fLocalJetMinEta, fLocalJetMaxEta);
211 if(fLocalJetMinPhi > -10 && fLocalJetMaxPhi > -10) GetJetContainer()->SetJetPhiLimits(fLocalJetMinPhi, fLocalJetMaxPhi);
212 if(fMinDisanceRCtoLJ==0) fMinDisanceRCtoLJ = .5*GetJetRadius();
213 if(dynamic_cast<AliAODEvent*>(InputEvent())) fDataType = kAOD; // determine the datatype
214 else if(dynamic_cast<AliESDEvent*>(InputEvent())) fDataType = kESD;
215 fHistAnalysisSummary->SetBinContent(36, (int)fDataType);
216 if(!fRandom) fRandom = new TRandom3(0); // get a randomized if one hasn't been user-supplied
217 switch (fFitModulationType) {
218 case kNoFit : { SetModulationFit(new TF1("fix_kNoFit", "[0]", 0, TMath::TwoPi())); } break;
220 SetModulationFit(new TF1("fit_kV2", "[0]*([1]+[2]*[3]*TMath::Cos([2]*(x-[4])))", 0, TMath::TwoPi()));
221 fFitModulation->SetParameter(0, 0.); // normalization
222 fFitModulation->SetParameter(3, 0.2); // v2
223 fFitModulation->FixParameter(1, 1.); // constant
224 fFitModulation->FixParameter(2, 2.); // constant
227 SetModulationFit(new TF1("fit_kV3", "[0]*([1]+[2]*[3]*TMath::Cos([2]*(x-[4])))", 0, TMath::TwoPi()));
228 fFitModulation->SetParameter(0, 0.); // normalization
229 fFitModulation->SetParameter(3, 0.2); // v3
230 fFitModulation->FixParameter(1, 1.); // constant
231 fFitModulation->FixParameter(2, 3.); // constant
233 default : { // for the combined fit, the 'direct fourier series' or the user supplied vn values we use v2 and v3
234 SetModulationFit(new TF1("fit_kCombined", "[0]*([1]+[2]*([3]*TMath::Cos([2]*(x-[4]))+[7]*TMath::Cos([5]*(x-[6]))))", 0, TMath::TwoPi()));
235 fFitModulation->SetParameter(0, 0.); // normalization
236 fFitModulation->SetParameter(3, 0.2); // v2
237 fFitModulation->FixParameter(1, 1.); // constant
238 fFitModulation->FixParameter(2, 2.); // constant
239 fFitModulation->FixParameter(5, 3.); // constant
240 fFitModulation->SetParameter(7, 0.2); // v3
243 switch (fRunModeType) {
244 case kGrid : { fFitModulationOptions += "N0"; } break;
247 FillAnalysisSummaryHistogram();
250 //_____________________________________________________________________________
251 TH1F* AliAnalysisTaskRhoVnModulation::BookTH1F(const char* name, const char* x, Int_t bins, Double_t min, Double_t max, Int_t c, Bool_t append)
253 // book a TH1F and connect it to the output container
254 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
255 if(fReduceBinsXByFactor > 0 ) bins = TMath::Nint(bins/fReduceBinsXByFactor);
256 if(!fOutputList) return 0x0;
258 if(c!=-1) { // format centrality dependent histograms accordingly
259 name = Form("%s_%i", name, c);
260 title += Form("_%i-%i", (int)(fCentralityClasses->At(c)), (int)(fCentralityClasses->At((1+c))));
262 title += Form(";%s;[counts]", x);
263 TH1F* histogram = new TH1F(name, title.Data(), bins, min, max);
265 if(append) fOutputList->Add(histogram);
268 //_____________________________________________________________________________
269 TH2F* AliAnalysisTaskRhoVnModulation::BookTH2F(const char* name, const char* x, const char*y, Int_t binsx, Double_t minx, Double_t maxx, Int_t binsy, Double_t miny, Double_t maxy, Int_t c, Bool_t append)
271 // book a TH2F and connect it to the output container
272 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
273 if(fReduceBinsXByFactor > 0 ) binsx = TMath::Nint(binsx/fReduceBinsXByFactor);
274 if(fReduceBinsYByFactor > 0 ) binsy = TMath::Nint(binsy/fReduceBinsYByFactor);
275 if(!fOutputList) return 0x0;
277 if(c!=-1) { // format centrality dependent histograms accordingly
278 name = Form("%s_%i", name, c);
279 title += Form("_%i-%i", (int)fCentralityClasses->At(c), (int)(fCentralityClasses->At((1+c))));
281 title += Form(";%s;%s", x, y);
282 TH2F* histogram = new TH2F(name, title.Data(), binsx, minx, maxx, binsy, miny, maxy);
284 if(append) fOutputList->Add(histogram);
287 //_____________________________________________________________________________
288 void AliAnalysisTaskRhoVnModulation::UserCreateOutputObjects()
290 // create output objects
291 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
292 fOutputList = new TList();
293 fOutputList->SetOwner(kTRUE);
294 if(!fCentralityClasses) { // classes must be defined at this point
295 Double_t c[] = {0., 20., 40., 60., 80., 100.};
296 fCentralityClasses = new TArrayD(sizeof(c)/sizeof(c[0]), c);
299 fHistCentrality = BookTH1F("fHistCentrality", "centrality", 102, -2, 100);
300 fHistVertexz = BookTH1F("fHistVertexz", "vertex z (cm)", 100, -12, 12);
302 // pico track kinematics
303 for(Int_t i(0); i < fCentralityClasses->GetSize()-1; i++) {
304 fHistPicoTrackPt[i] = BookTH1F("fHistPicoTrackPt", "p_{t} [GeV/c]", 100, 0, 50, i);
305 fHistPicoTrackMult[i] = BookTH1F("fHistPicoTrackMult", "multiplicity", 100, 0, 5000, i);
306 if(fFillQAHistograms) {
307 fHistPicoCat1[i] = BookTH2F("fHistPicoCat1", "#eta", "#phi", 50, -1, 1, 50, 0, TMath::TwoPi(), i);
308 fHistPicoCat2[i] = BookTH2F("fHistPicoCat2", "#eta", "#phi", 50, -1, 1, 50, 0, TMath::TwoPi(), i);
309 fHistPicoCat3[i] = BookTH2F("fHistPicoCat3", "#eta", "#phi", 50, -1, 1, 50, 0, TMath::TwoPi(), i);
312 /* fHistClusterPt[i] = BookTH1F("fHistClusterPt", "p_{t} [GeV/c]", 100, 0, 100, i); */
313 /* fHistClusterPhi[i] = BookTH1F("fHistClusterPhi", "#phi", 100, 0, TMath::TwoPi(), i); */
314 /* fHistClusterEta[i] = BookTH1F("fHistClusterEta", "#eta", 100, -5, 5); */
316 // emcal kinematics after hadronic correction
317 /* fHistClusterCorrPt[i] = BookTH1F("fHistClusterCorrPt", "p_{t} [GeV/c]", 100, 0, 100, i); */
318 /* fHistClusterCorrPhi[i] = BookTH1F("fHistClusterCorrPhi", "#phi", 100, 0, TMath::TwoPi(), i); */
319 /* fHistClusterCorrEta[i] = BookTH1F("fHistClusterCorrEta", "#eta", 100, -5, 5, i); */
322 if(fFillQAHistograms) {
323 // event plane estimates and quality
324 fHistPsiControl = new TProfile("fHistPsiControl", "fHistPsiControl", 10, 0, 10);
325 fHistPsiControl->Sumw2();
326 fHistPsiSpread = new TProfile("fHistPsiSpread", "fHistPsiSpread", 4, 0, 4);
327 fHistPsiSpread->Sumw2();
328 fHistPsiControl->GetXaxis()->SetBinLabel(1, "<#Psi_{2, VZEROA}>");
329 fHistPsiControl->GetXaxis()->SetBinLabel(2, "<#Psi_{2, VZEROC}>");
330 fHistPsiControl->GetXaxis()->SetBinLabel(3, "<#Psi_{2, TPC}>");
331 fHistPsiControl->GetXaxis()->SetBinLabel(4, "<#Psi_{2, TPC, #eta < 0}>");
332 fHistPsiControl->GetXaxis()->SetBinLabel(5, "<#Psi_{2, TPC, #eta > 0}>");
333 fHistPsiControl->GetXaxis()->SetBinLabel(6, "<#Psi_{3, VZEROA}>");
334 fHistPsiControl->GetXaxis()->SetBinLabel(7, "<#Psi_{3, VZEROC}>");
335 fHistPsiControl->GetXaxis()->SetBinLabel(8, "<#Psi_{3, TPC}>");
336 fHistPsiControl->GetXaxis()->SetBinLabel(9, "<#Psi_{3, TPC, #eta < 0}>");
337 fHistPsiControl->GetXaxis()->SetBinLabel(10, "<#Psi_{3, TPC, #eta > 0}>");
338 fHistPsiSpread->GetXaxis()->SetBinLabel(1, "<#Psi_{2, VZEROA} - #Psi_{2, VZEROC}>");
339 fHistPsiSpread->GetXaxis()->SetBinLabel(2, "<#Psi_{2, VZEROC} - #Psi_{2, TPC}>");
340 fHistPsiSpread->GetXaxis()->SetBinLabel(3, "<#Psi_{2, VZEROC} - #Psi_{2, TPC}>");
341 fHistPsiSpread->GetXaxis()->SetBinLabel(4, "<#Psi_{2, TPC, #eta < 0} - #Psi_{2, TPC, #eta > 0}>");
342 fOutputList->Add(fHistPsiControl);
343 fOutputList->Add(fHistPsiSpread);
344 fHistPsiVZEROA = BookTH1F("fHistPsiVZEROA", "#Psi_{VZEROA}", 40, -.5*TMath::Pi(), .5*TMath::Pi());
345 fHistPsiVZEROC = BookTH1F("fHistPsiVZEROC", "#Psi_{VZEROC}", 40, -.5*TMath::Pi(), .5*TMath::Pi());
346 fHistPsiVZERO = BookTH1F("fHistPsiVZERO", "#Psi_{VZERO}", 40, -.5*TMath::Pi(), .5*TMath::Pi());
347 fHistPsiTPC = BookTH1F("fHistPsiTPC", "#Psi_{TPC}", 40, -.5*TMath::Pi(), .5*TMath::Pi());
348 fHistPsiVZEROAV0M = BookTH2F("fHistPsiVZEROAV0M", "V0M", "#Psi_{2, VZEROA}", 60, 0, 60, 40, -.5*TMath::Pi(), .5*TMath::Pi());
349 fHistPsiVZEROCV0M = BookTH2F("fHistPsiVZEROCV0M", "V0M", "#Psi_{2, VZEROC}", 60, 0, 60, 40, -.5*TMath::Pi(), .5*TMath::Pi());
350 fHistPsiVZEROVV0M = BookTH2F("fHistPsiVZEROV0M", "V0M", "#Psi_{2, VZERO}", 60, 0, 60, 40, -.5*TMath::Pi(), .5*TMath::Pi());
351 fHistPsiTPCiV0M = BookTH2F("fHistPsiTPCV0M", "V0M", "#Psi_{2, TRK}", 60, 0, 60, 40, -.5*TMath::Pi(), .5*TMath::Pi());
352 fHistPsiVZEROATRK = BookTH2F("fHistPsiVZEROATRK", "TRK", "#Psi_{2, VZEROA}", 60, 0, 60, 40, -.5*TMath::Pi(), .5*TMath::Pi());
353 fHistPsiVZEROCTRK = BookTH2F("fHistPsiVZEROCTRK", "TRK", "#Psi_{2, VZEROC}", 60, 0, 60, 40, -.5*TMath::Pi(), .5*TMath::Pi());
354 fHistPsiVZEROTRK = BookTH2F("fHistPsiVZEROTRK", "TRK", "#Psi_{2, VZERO}", 60, 0, 60, 40, -.5*TMath::Pi(), .5*TMath::Pi());
355 fHistPsiTPCTRK = BookTH2F("fHistPsiTPCTRK", "TRK", "#Psi_{2, TRK}", 60, 0, 60, 40, -.5*TMath::Pi(), .5*TMath::Pi());
358 for(Int_t i(0); i < fCentralityClasses->GetSize()-1; i ++) {
359 fHistRhoPackage[i] = BookTH1F("fHistRhoPackage", "#rho [GeV/c]", 100, 0, 150, i);
360 fHistRho[i] = BookTH1F("fHistRho", "#rho [GeV/c]", 100, 0, 150, i);
362 fHistRhoVsMult = BookTH2F("fHistRhoVsMult", "multiplicity", "#rho [GeV/c]", 100, 0, 4000, 100, 0, 250);
363 fHistRhoVsCent = BookTH2F("fHistRhoVsCent", "centrality", "#rho [GeV/c]", 100, 0, 100, 100, 0, 250);
364 fHistRhoAVsMult = BookTH2F("fHistRhoAVsMult", "multiplicity", "#rho * A (jet) [GeV/c]", 100, 0, 4000, 100, 0, 50);
365 fHistRhoAVsCent = BookTH2F("fHistRhoAVsCent", "centrality", "#rho * A (jet) [GeV/c]", 100, 0, 100, 100, 0, 50);
367 TString detector("");
368 switch (fDetectorType) {
369 case kTPC : detector+="TPC";
371 case kVZEROA : detector+="VZEROA";
373 case kVZEROC : detector+="VZEROC";
375 case kVZEROComb : detector+="VZEROComb";
379 // delta pt distributions
380 for(Int_t i(0); i < fCentralityClasses->GetSize()-1; i ++) {
381 if(fFillQAHistograms) fHistRCPhiEta[i] = BookTH2F("fHistRCPhiEta", "#phi (RC)", "#eta (RC)", 40, 0, TMath::TwoPi(), 40, -1, 1, i);
382 fHistRhoVsRCPt[i] = BookTH2F("fHistRhoVsRCPt", "p_{t} (RC) [GeV/c]", "#rho * A (RC) [GeV/c]", 100, 0, 300, 100, 0, 350, i);
383 fHistRCPt[i] = BookTH1F("fHistRCPt", "p_{t} (RC) [GeV/c]", 130, -20, 150, i);
384 if(fFillQAHistograms) fHistRCPhiEtaExLJ[i] = BookTH2F("fHistRCPhiEtaExLJ", "#phi (RC)", "#eta (RC)", 40, 0, TMath::TwoPi(), 40, -1, 1, i);
385 fHistDeltaPtDeltaPhi2[i] = BookTH2F("fHistDeltaPtDeltaPhi2", Form("#phi - #Psi_{2, %s}", detector.Data()), "#delta p_{t} [GeV/c]", 40, 0, TMath::Pi(), 400, -70, 130, i);
386 fHistDeltaPtDeltaPhi3[i] = BookTH2F("fHistDeltaPtDeltaPhi3", Form("#phi - #Psi_{3, %s}", detector.Data()), "#delta p_{t} [GeV/c]", 40, 0, TMath::TwoPi()/3., 400, -70, 130, i);
387 fHistRhoVsRCPtExLJ[i] = BookTH2F("fHistRhoVsRCPtExLJ", "p_{t} (RC) [GeV/c]", "#rho * A (RC) [GeV/c]", 100, 0, 300, 100, 0, 350, i);
388 fHistRCPtExLJ[i] = BookTH1F("fHistRCPtExLJ", "p_{t} (RC) [GeV/c]", 130, -20, 150, i);
389 /* fHistRCPhiEtaRand[i] = BookTH2F("fHistRCPhiEtaRand", "#phi (RC)", "#eta (RC)", 100, 0, TMath::TwoPi(), 100, -1, 1, i); */
390 fHistDeltaPtDeltaPhi2ExLJ[i] = BookTH2F("fHistDeltaPtDeltaPhi2ExLJ", Form("#phi - #Psi_{2, %s}", detector.Data()), "#delta p_{t} [GeV/c]", 40, 0, TMath::Pi(), 400, -70, 130, i);
391 fHistDeltaPtDeltaPhi3ExLJ[i] = BookTH2F("fHistDeltaPtDeltaPhi3ExLJ", Form("#phi - #Psi_{3, %s}", detector.Data()), "#delta p_{t} [GeV/c]", 40, 0, TMath::TwoPi()/3., 400, -70, 130, i);
392 /* fHistRhoVsRCPtRand[i] = BookTH2F("fHistRhoVsRCPtRand", "p_{t} (RC) [GeV/c]", "#rho * A (RC) [GeV/c]", 100, 0, 300, 100, 0, 350, i); */
393 /* fHistRCPtRand[i] = BookTH1F("fHistRCPtRand", "p_{t} (RC) [GeV/c]", 130, -20, 150, i); */
394 /* fHistDeltaPtDeltaPhi2Rand[i] = BookTH2F("fHistDeltaPtDeltaPhi2Rand", "#phi - #Psi_{TPC}", "#delta p_{t} [GeV/c]", 50, 0, TMath::Pi(), 100, -50, 100, i); */
395 /* fHistDeltaPtDeltaPhi3Rand[i] = BookTH2F("fHistDeltaPtDeltaPhi3Rand", "#phi - #Psi_{TPC}", "#delta p_{t} [GeV/c]", 50, 0, TMath::TwoPi()/3., 100, -50, 100, i); */
396 // jet histograms (after kinematic cuts)
397 fHistJetPtRaw[i] = BookTH1F("fHistJetPtRaw", "p_{t, jet} RAW [GeV/c]", 200, -50, 150, i);
398 fHistJetPt[i] = BookTH1F("fHistJetPt", "p_{t, jet} [GeV/c]", 350, -100, 250, i);
399 if(fFillQAHistograms) fHistJetEtaPhi[i] = BookTH2F("fHistJetEtaPhi", "#eta", "#phi", 100, -1, 1, 100, 0, TMath::TwoPi(), i);
400 fHistJetPtArea[i] = BookTH2F("fHistJetPtArea", "p_{t, jet} [GeV/c]", "Area", 175, -100, 250, 30, 0, 0.9, i);
401 fHistJetPtConstituents[i] = BookTH2F("fHistJetPtConstituents", "p_{t, jet} [GeV/c]", "Area", 350, -100, 250, 60, 0, 150, i);
402 fHistJetEtaRho[i] = BookTH2F("fHistJetEtaRho", "#eta", "#rho", 100, -1, 1, 100, 0, 300, i);
403 // in plane and out of plane spectra
404 fHistJetPsi2Pt[i] = BookTH2F("fHistJetPsi2Pt", Form("#phi_{jet} - #Psi_{2, %s}", detector.Data()), "p_{t, jet} [GeV/c]", 40, 0., TMath::Pi(), 350, -100, 250, i);
405 fHistJetPsi3Pt[i] = BookTH2F("fHistJetPsi3Pt", Form("#phi_{jet} - #Psi_{3, %s}", detector.Data()), "p_{t, jet} [GeV/c]", 40, 0., TMath::TwoPi()/3., 350, -100, 250, i);
406 // profiles for all correlator permutations which are necessary to calculate each second and third order event plane resolution
407 fProfV2Resolution[i] = new TProfile(Form("fProfV2Resolution_%i", i), Form("fProfV2Resolution_%i", i), 11, -0.5, 10.5);
408 fProfV2Resolution[i]->GetXaxis()->SetBinLabel(3, "<cos(2(#Psi_{VZEROA} - #Psi_{VZEROC}))>");
409 fProfV2Resolution[i]->GetXaxis()->SetBinLabel(4, "<cos(2(#Psi_{VZEROC} - #Psi_{VZEROA}))>");
410 fProfV2Resolution[i]->GetXaxis()->SetBinLabel(5, "<cos(2(#Psi_{VZEROA} - #Psi_{TPC}))>");
411 fProfV2Resolution[i]->GetXaxis()->SetBinLabel(6, "<cos(2(#Psi_{TPC} - #Psi_{VZEROA}))>");
412 fProfV2Resolution[i]->GetXaxis()->SetBinLabel(7, "<cos(2(#Psi_{VZEROC} - #Psi_{TPC}))>");
413 fProfV2Resolution[i]->GetXaxis()->SetBinLabel(8, "<cos(2(#Psi_{TPC} - #Psi_{VZEROC}))>");
414 fProfV2Resolution[i]->GetXaxis()->SetBinLabel(9, "<cos(2(#Psi_{VZERO} - #Psi_{TPC_A}))>");
415 fProfV2Resolution[i]->GetXaxis()->SetBinLabel(10, "<cos(2(#Psi_{VZERO} - #Psi_{TPC_B}))>");
416 fProfV2Resolution[i]->GetXaxis()->SetBinLabel(11, "<cos(2(#Psi_{TPC_A} - #Psi_{TPC_B}))>");
417 fOutputList->Add(fProfV2Resolution[i]);
418 fProfV3Resolution[i] = new TProfile(Form("fProfV3Resolution_%i", i), Form("fProfV3Resolution_%i", i), 11, -0.5, 10.5);
419 fProfV3Resolution[i]->GetXaxis()->SetBinLabel(3, "<cos(3(#Psi_{VZEROA} - #Psi_{VZEROC}))>");
420 fProfV3Resolution[i]->GetXaxis()->SetBinLabel(4, "<cos(3(#Psi_{VZEROC} - #Psi_{VZEROA}))>");
421 fProfV3Resolution[i]->GetXaxis()->SetBinLabel(5, "<cos(3(#Psi_{VZEROA} - #Psi_{TPC}))>");
422 fProfV3Resolution[i]->GetXaxis()->SetBinLabel(6, "<cos(3(#Psi_{TPC} - #Psi_{VZEROA}))>");
423 fProfV3Resolution[i]->GetXaxis()->SetBinLabel(7, "<cos(3(#Psi_{VZEROC} - #Psi_{TPC}))>");
424 fProfV3Resolution[i]->GetXaxis()->SetBinLabel(8, "<cos(3(#Psi_{TPC} - #Psi_{VZEROC}))>");
425 fProfV3Resolution[i]->GetXaxis()->SetBinLabel(9, "<cos(3(#Psi_{VZERO} - #Psi_{TPC_A}))>");
426 fProfV3Resolution[i]->GetXaxis()->SetBinLabel(10, "<cos(3(#Psi_{VZERO} - #Psi_{TPC_B}))>");
427 fProfV3Resolution[i]->GetXaxis()->SetBinLabel(11, "<cos(3(#Psi_{TPC_A} - #Psi_{TPC_B}))>");
428 fOutputList->Add(fProfV3Resolution[i]);
430 // cdf and pdf of chisquare distribution
431 fHistPvaluePDF = BookTH1F("fHistPvaluePDF", "PDF #chi^{2}", 500, 0, 1);
432 fHistPvalueCDF = BookTH1F("fHistPvalueCDF", "CDF #chi^{2}", 500, 0, 1);
433 fHistRhoStatusCent = BookTH2F("fHistRhoStatusCent", "centrality", "status [-1=lin was better, 0=ok, 1 = failed]", 101, -1, 100, 3, -1.5, 1.5);
435 Float_t temp[fCentralityClasses->GetSize()];
436 for(Int_t i(0); i < fCentralityClasses->GetSize(); i++) temp[i] = fCentralityClasses->At(i);
437 fProfV2 = new TProfile("fProfV2", "fProfV2", fCentralityClasses->GetSize()-1, temp);
438 fProfV3 = new TProfile("fProfV3", "fProfV3", fCentralityClasses->GetSize()-1, temp);
439 fOutputList->Add(fProfV2);
440 fOutputList->Add(fProfV3);
441 switch (fFitModulationType) {
443 fProfV2Cumulant = new TProfile("fProfV2Cumulant", "fProfV2Cumulant", fCentralityClasses->GetSize()-1, temp);
444 fProfV3Cumulant = new TProfile("fProfV3Cumulant", "fProfV3Cumulant", fCentralityClasses->GetSize()-1, temp);
445 fOutputList->Add(fProfV2Cumulant);
446 fOutputList->Add(fProfV3Cumulant);
449 fProfV2Cumulant = new TProfile("fProfV2Cumulant", "fProfV2Cumulant", fCentralityClasses->GetSize()-1, temp);
450 fProfV3Cumulant = new TProfile("fProfV3Cumulant", "fProfV3Cumulant", fCentralityClasses->GetSize()-1, temp);
451 fOutputList->Add(fProfV2Cumulant);
452 fOutputList->Add(fProfV3Cumulant);
456 // for the histograms initialized below, binning is fixed to runnumbers or flags
457 fReduceBinsXByFactor = 1;
458 fReduceBinsYByFactor = 1;
459 if(fFillQAHistograms) {
460 fHistRunnumbersEta = new TH2F("fHistRunnumbersEta", "fHistRunnumbersEta", 100, -.5, 99.5, 100, -1.1, 1.1);
461 fHistRunnumbersEta->Sumw2();
462 fOutputList->Add(fHistRunnumbersEta);
463 fHistRunnumbersPhi = new TH2F("fHistRunnumbersPhi", "fHistRunnumbersPhi", 100, -.5, 99.5, 100, -0.2, TMath::TwoPi()+0.2);
464 fHistRunnumbersPhi->Sumw2();
465 fOutputList->Add(fHistRunnumbersPhi);
467 fHistAnalysisSummary = BookTH1F("fHistAnalysisSummary", "flag", 52, -0.5, 52.5);
468 fHistSwap = new TH1F("fHistSwap", "fHistSwap", 20, 0, TMath::TwoPi());
469 if(fUsePtWeight) fHistSwap->Sumw2();
471 if(fUserSuppliedV2) fOutputList->Add(fUserSuppliedV2);
472 if(fUserSuppliedV3) fOutputList->Add(fUserSuppliedV3);
473 if(fUserSuppliedR2) fOutputList->Add(fUserSuppliedR2);
474 if(fUserSuppliedR3) fOutputList->Add(fUserSuppliedR3);
475 // increase readability of output list
477 PostData(1, fOutputList);
479 switch (fRunModeType) {
481 fOutputListGood = new TList();
482 fOutputListGood->SetOwner(kTRUE);
483 fOutputListBad = new TList();
484 fOutputListBad->SetOwner(kTRUE);
485 PostData(2, fOutputListGood);
486 PostData(3, fOutputListBad);
491 // get the containers
492 fTracksCont = GetParticleContainer("Tracks");
493 fJetsCont = GetJetContainer("Jets");
495 //_____________________________________________________________________________
496 Bool_t AliAnalysisTaskRhoVnModulation::Run()
498 // user exec: execute once for each event
499 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
500 if(!fTracks||!fJets||!fRho) return kFALSE;
501 if(!fLocalInit) fLocalInit = InitializeAnalysis();
502 // reject the event if expected data is missing
503 if(!PassesCuts(InputEvent())) return kFALSE;
504 if(!fCaloClusters && fDebug > 0) printf(" > Warning: couldn't retreive calo clusters! < \n");
506 fLocalRho->SetVal(fRho->GetVal());
507 // [0][0] psi2a [1,0] psi2c
508 // [0][1] psi3a [1,1] psi3c
509 Double_t vzero[2][2];
510 CalculateEventPlaneVZERO(vzero);
511 /* for the combined vzero event plane
513 * not fully implmemented yet, use with caution ! */
514 Double_t vzeroComb[2];
515 CalculateEventPlaneCombinedVZERO(vzeroComb);
518 CalculateEventPlaneTPC(tpc);
519 Double_t psi2(-1), psi3(-1);
520 // arrays which will hold the fit parameters
521 switch (fDetectorType) { // determine the detector type for the rho fit
522 case kTPC : { psi2 = tpc[0]; psi3 = tpc[1]; } break;
523 case kVZEROA : { psi2 = vzero[0][0]; psi3 = vzero[0][1]; } break;
524 case kVZEROC : { psi2 = vzero[1][0]; psi3 = vzero[1][1]; } break;
525 case kVZEROComb : { psi2 = vzeroComb[0]; psi3 = vzeroComb[1];} break;
528 switch (fFitModulationType) { // do the fits
530 switch (fCollisionType) {
531 case kPythia : { // background is zero for pp jets
532 fFitModulation->FixParameter(0, 0);
533 fLocalRho->SetVal(0);
536 fFitModulation->FixParameter(0, fLocalRho->GetVal());
540 case kV2 : { // only v2
541 if(CorrectRho(psi2, psi3)) {
542 fProfV2->Fill(fCent, fFitModulation->GetParameter(3));
543 if(fUserSuppliedR2) {
544 Double_t r(fUserSuppliedR2->GetBinContent(fUserSuppliedR2->GetXaxis()->FindBin(fCent)));
545 if(r > 0) fFitModulation->SetParameter(3, fFitModulation->GetParameter(3)/r);
547 CalculateEventPlaneResolution(vzero, vzeroComb, tpc);
550 case kV3 : { // only v3
551 if(CorrectRho(psi2, psi3)) {
552 if(fUserSuppliedR3) {
553 Double_t r(fUserSuppliedR3->GetBinContent(fUserSuppliedR3->GetXaxis()->FindBin(fCent)));
554 if(r > 0) fFitModulation->SetParameter(3, fFitModulation->GetParameter(3)/r);
556 fProfV3->Fill(fCent, fFitModulation->GetParameter(3));
557 CalculateEventPlaneResolution(vzero, vzeroComb, tpc);
560 case kQC2 : { // qc2 analysis
561 if(CorrectRho(psi2, psi3)) {
562 if(fUserSuppliedR2 && fUserSuppliedR3) {
563 // note for the qc method, resolution is REVERSED to go back to v2obs
564 Double_t r2(fUserSuppliedR2->GetBinContent(fUserSuppliedR2->GetXaxis()->FindBin(fCent)));
565 Double_t r3(fUserSuppliedR3->GetBinContent(fUserSuppliedR3->GetXaxis()->FindBin(fCent)));
566 if(r2 > 0) fFitModulation->SetParameter(3, fFitModulation->GetParameter(3)*r2);
567 if(r3 > 0) fFitModulation->SetParameter(7, fFitModulation->GetParameter(7)*r3);
569 if (fUsePtWeight) { // use weighted weights
570 Double_t dQCnM11 = (fNoEventWeightsForQC) ? 1. : QCnM11();
571 fProfV2->Fill(fCent, fFitModulation->GetParameter(3), dQCnM11);
572 fProfV3->Fill(fCent, fFitModulation->GetParameter(7), dQCnM11);
574 Double_t dQCnM = (fNoEventWeightsForQC) ? 2. : QCnM();
575 fProfV2->Fill(fCent, fFitModulation->GetParameter(3), dQCnM*(dQCnM-1));
576 fProfV3->Fill(fCent, fFitModulation->GetParameter(7), dQCnM*(dQCnM-1));
578 CalculateEventPlaneResolution(vzero, vzeroComb, tpc);
582 if(CorrectRho(psi2, psi3)) {
583 if(fUserSuppliedR2 && fUserSuppliedR3) {
584 // note for the qc method, resolution is REVERSED to go back to v2obs
585 Double_t r2(fUserSuppliedR2->GetBinContent(fUserSuppliedR2->GetXaxis()->FindBin(fCent)));
586 Double_t r3(fUserSuppliedR3->GetBinContent(fUserSuppliedR3->GetXaxis()->FindBin(fCent)));
587 if(r2 > 0) fFitModulation->SetParameter(3, fFitModulation->GetParameter(3)*r2);
588 if(r3 > 0) fFitModulation->SetParameter(7, fFitModulation->GetParameter(7)*r3);
590 if (fUsePtWeight) { // use weighted weights
591 fProfV2->Fill(fCent, TMath::Power(fFitModulation->GetParameter(3),0.5)/*, QCnM1111()*/);
592 fProfV3->Fill(fCent, TMath::Power(fFitModulation->GetParameter(7),0.5)/*, QCnM1111()*/);
594 fProfV2->Fill(fCent, TMath::Power(fFitModulation->GetParameter(3),0.5)/*, QCnM()*(QCnM()-1)*(QCnM()-2)*(QCnM()-3)*/);
595 fProfV3->Fill(fCent, TMath::Power(fFitModulation->GetParameter(7),0.5)/*, QCnM()*(QCnM()-1)*(QCnM()-2)*(QCnM()-3)*/);
598 CalculateEventPlaneResolution(vzero, vzeroComb, tpc);
601 if(CorrectRho(psi2, psi3)) {
602 if(fUserSuppliedR2 && fUserSuppliedR3) {
603 Double_t r2(fUserSuppliedR2->GetBinContent(fUserSuppliedR2->GetXaxis()->FindBin(fCent)));
604 Double_t r3(fUserSuppliedR3->GetBinContent(fUserSuppliedR3->GetXaxis()->FindBin(fCent)));
605 if(r2 > 0) fFitModulation->SetParameter(3, fFitModulation->GetParameter(3)/r2);
606 if(r3 > 0) fFitModulation->SetParameter(7, fFitModulation->GetParameter(7)/r3);
608 fProfV2->Fill(fCent, fFitModulation->GetParameter(3));
609 fProfV3->Fill(fCent, fFitModulation->GetParameter(7));
610 CalculateEventPlaneResolution(vzero, vzeroComb, tpc);
614 // if all went well, update the local rho parameter
615 fLocalRho->SetLocalRho(fFitModulation);
616 // fill a number of histograms
617 if(fFillHistograms) FillHistogramsAfterSubtraction(psi2, psi3, vzero, vzeroComb, tpc);
618 if(fFillQAHistograms) FillQAHistograms(InputEvent());
619 // send the output to the connected output container
620 PostData(1, fOutputList);
621 switch (fRunModeType) {
623 PostData(2, fOutputListGood);
624 PostData(3, fOutputListBad);
631 //_____________________________________________________________________________
632 void AliAnalysisTaskRhoVnModulation::CalculateEventPlaneVZERO(Double_t vzero[2][2]) const
634 // get the vzero event plane
635 if(fUseV0EventPlaneFromHeader) { // use the vzero from the header
636 Double_t a(0), b(0), c(0), d(0), e(0), f(0), g(0), h(0);
637 vzero[0][0] = InputEvent()->GetEventplane()->CalculateVZEROEventPlane(InputEvent(), 8, 2, a, b);
638 vzero[1][0] = InputEvent()->GetEventplane()->CalculateVZEROEventPlane(InputEvent(), 9, 2, c, d);
639 vzero[0][1] = InputEvent()->GetEventplane()->CalculateVZEROEventPlane(InputEvent(), 8, 3, e, f);
640 vzero[1][1] = InputEvent()->GetEventplane()->CalculateVZEROEventPlane(InputEvent(), 9, 3, g, h);
643 // grab the vzero event plane without recentering
644 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
645 Double_t qxa2(0), qya2(0), qxc2(0), qyc2(0); // for psi2
646 Double_t qxa3(0), qya3(0), qxc3(0), qyc3(0); // for psi3
647 for(Int_t iVZERO(0); iVZERO < 64; iVZERO++) {
648 Double_t phi(TMath::PiOver4()*(.5+iVZERO%8)), /* eta(0), */ weight(InputEvent()->GetVZEROEqMultiplicity(iVZERO));
649 // (iVZERO<32) ? eta = -3.45+.5*(iVZERO/8) : eta = 4.8-.6*((iVZERO/8)-4);
651 qxa2 += weight*TMath::Cos(2.*phi);
652 qya2 += weight*TMath::Sin(2.*phi);
653 qxa3 += weight*TMath::Cos(3.*phi);
654 qya3 += weight*TMath::Sin(3.*phi);
657 qxc2 += weight*TMath::Cos(2.*phi);
658 qyc2 += weight*TMath::Sin(2.*phi);
659 qxc3 += weight*TMath::Cos(3.*phi);
660 qyc3 += weight*TMath::Sin(3.*phi);
663 vzero[0][0] = .5*TMath::ATan2(qya2, qxa2);
664 vzero[1][0] = .5*TMath::ATan2(qyc2, qxc2);
665 vzero[0][1] = (1./3.)*TMath::ATan2(qya3, qxa3);
666 vzero[1][1] = (1./3.)*TMath::ATan2(qyc3, qxc3);
668 //_____________________________________________________________________________
669 void AliAnalysisTaskRhoVnModulation::CalculateEventPlaneTPC(Double_t* tpc)
671 // grab the TPC event plane
672 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
673 fNAcceptedTracks = 0; // reset the track counter
674 Double_t qx2(0), qy2(0); // for psi2
675 Double_t qx3(0), qy3(0); // for psi3
677 Float_t excludeInEta = -999;
678 if(fExcludeLeadingJetsFromFit > 0 ) { // remove the leading jet from ep estimate
679 AliEmcalJet* leadingJet(GetJetContainer()->GetLeadingJet());
680 if(leadingJet) excludeInEta = leadingJet->Eta();
682 Int_t iTracks(fTracks->GetEntriesFast());
683 for(Int_t iTPC(0); iTPC < iTracks; iTPC++) {
684 AliVTrack* track = static_cast<AliVTrack*>(fTracks->At(iTPC));
685 if(!PassesCuts(track) || track->Pt() < fSoftTrackMinPt || track->Pt() > fSoftTrackMaxPt) continue;
686 if(fExcludeLeadingJetsFromFit > 0 &&( (TMath::Abs(track->Eta() - excludeInEta) < GetJetContainer()->GetJetRadius()*fExcludeLeadingJetsFromFit ) || (TMath::Abs(track->Eta()) - GetJetContainer()->GetJetRadius() - GetJetContainer()->GetJetEtaMax() ) > 0 )) continue;
688 qx2+= TMath::Cos(2.*track->Phi());
689 qy2+= TMath::Sin(2.*track->Phi());
690 qx3+= TMath::Cos(3.*track->Phi());
691 qy3+= TMath::Sin(3.*track->Phi());
694 tpc[0] = .5*TMath::ATan2(qy2, qx2);
695 tpc[1] = (1./3.)*TMath::ATan2(qy3, qx3);
697 //_____________________________________________________________________________
698 void AliAnalysisTaskRhoVnModulation::CalculateEventPlaneCombinedVZERO(Double_t* comb) const
700 // grab the combined vzero event plane
701 // if(fUseV0EventPlaneFromHeader) { // use the vzero from the header
702 Double_t a(0), b(0), c(0), d(0);
703 comb[0] = InputEvent()->GetEventplane()->CalculateVZEROEventPlane(InputEvent(), 10, 2, a, b);
704 comb[1] = InputEvent()->GetEventplane()->CalculateVZEROEventPlane(InputEvent(), 10, 3, c, d);
706 // Double_t qx2a(0), qy2a(0), qx2c(0), qy2c(0), qx3a(0), qy3a(0), qx3c(0), qy3c(0);
707 // InputEvent()->GetEventplane()->CalculateVZEROEventPlane(InputEvent(), 8, 2, qx2a, qy2a);
708 // InputEvent()->GetEventplane()->CalculateVZEROEventPlane(InputEvent(), 9, 2, qx2c, qy2c);
709 // InputEvent()->GetEventplane()->CalculateVZEROEventPlane(InputEvent(), 8, 3, qx3a, qy3a);
710 // InputEvent()->GetEventplane()->CalculateVZEROEventPlane(InputEvent(), 9, 3, qx3c, qy3c);
711 // FIXME the rest of this function isn't impelmented yet (as of 01-07-2013)
712 // Double_t chi2A(-1), chi2C(-1), chi3A(-1), chi3C(-1); // get chi from the resolution
713 // Double_t qx2(chi2A*chi2A*qx2a+chi2C*chi2C*qx2c);
714 // Double_t qy2(chi2A*chi2A*qy2a+chi2C*chi2C*qy2c);
715 // Double_t qx3(chi3A*chi3A*qx3a+chi3C*chi3C*qx3c);
716 // Double_t qy3(chi3A*chi3A*qy3a+chi3C*chi3C*qy3c);
717 // comb[0] = .5*TMath::ATan2(qy2, qx2);
718 // comb[1] = (1./3.)*TMath::ATan2(qy3, qx3);
721 //_____________________________________________________________________________
722 void AliAnalysisTaskRhoVnModulation::CalculateEventPlaneResolution(Double_t vzero[2][2], Double_t* vzeroComb, Double_t* tpc)
724 // fill the profiles for the resolution parameters
725 if(fDebug > 1) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
726 fProfV2Resolution[fInCentralitySelection]->Fill(2., TMath::Cos(2.*(vzero[0][0] - vzero[1][0])));
727 fProfV2Resolution[fInCentralitySelection]->Fill(3., TMath::Cos(2.*(vzero[1][0] - vzero[0][0])));
728 fProfV2Resolution[fInCentralitySelection]->Fill(4., TMath::Cos(2.*(vzero[0][0] - tpc[0])));
729 fProfV2Resolution[fInCentralitySelection]->Fill(5., TMath::Cos(2.*(tpc[0] - vzero[0][0])));
730 fProfV2Resolution[fInCentralitySelection]->Fill(6., TMath::Cos(2.*(vzero[1][0] - tpc[0])));
731 fProfV2Resolution[fInCentralitySelection]->Fill(7., TMath::Cos(2.*(tpc[0] - vzero[1][0])));
732 fProfV3Resolution[fInCentralitySelection]->Fill(2., TMath::Cos(3.*(vzero[0][0] - vzero[1][0])));
733 fProfV3Resolution[fInCentralitySelection]->Fill(3., TMath::Cos(3.*(vzero[1][0] - vzero[0][0])));
734 fProfV3Resolution[fInCentralitySelection]->Fill(4., TMath::Cos(3.*(vzero[0][0] - tpc[0])));
735 fProfV3Resolution[fInCentralitySelection]->Fill(5., TMath::Cos(3.*(tpc[0] - vzero[0][0])));
736 fProfV3Resolution[fInCentralitySelection]->Fill(6., TMath::Cos(3.*(vzero[1][0] - tpc[0])));
737 fProfV3Resolution[fInCentralitySelection]->Fill(7., TMath::Cos(3.*(tpc[0] - vzero[1][0])));
738 // for the resolution of the combined vzero event plane, use two tpc halves as uncorrelated subdetectors
739 Double_t qx2a(0), qy2a(0); // for psi2a, negative eta
740 Double_t qx3a(0), qy3a(0); // for psi3a, negative eta
741 Double_t qx2b(0), qy2b(0); // for psi2a, positive eta
742 Double_t qx3b(0), qy3b(0); // for psi3a, positive eta
744 Int_t iTracks(fTracks->GetEntriesFast());
745 for(Int_t iTPC(0); iTPC < iTracks; iTPC++) {
746 AliVTrack* track = static_cast<AliVTrack*>(fTracks->At(iTPC));
747 if(!PassesCuts(track) || track->Pt() < fSoftTrackMinPt || track->Pt() > fSoftTrackMaxPt) continue;
748 if(track->Eta() < 0 ) {
749 qx2a+= TMath::Cos(2.*track->Phi());
750 qy2a+= TMath::Sin(2.*track->Phi());
751 qx3a+= TMath::Cos(3.*track->Phi());
752 qy3a+= TMath::Sin(3.*track->Phi());
753 } else if (track->Eta() > 0) {
754 qx2b+= TMath::Cos(2.*track->Phi());
755 qy2b+= TMath::Sin(2.*track->Phi());
756 qx3b+= TMath::Cos(3.*track->Phi());
757 qy3b+= TMath::Sin(3.*track->Phi());
761 Double_t tpca2(.5*TMath::ATan2(qy2a, qx2a));
762 Double_t tpca3((1./3.)*TMath::ATan2(qy3a, qx3a));
763 Double_t tpcb2(.5*TMath::ATan2(qy2b, qx2b));
764 Double_t tpcb3((1./3.)*TMath::ATan2(qy3b, qx3b));
765 fProfV2Resolution[fInCentralitySelection]->Fill(8., TMath::Cos(2.*(vzeroComb[0] - tpca2)));
766 fProfV2Resolution[fInCentralitySelection]->Fill(9., TMath::Cos(2.*(vzeroComb[0] - tpcb2)));
767 fProfV2Resolution[fInCentralitySelection]->Fill(10., TMath::Cos(2.*(tpca2 - tpcb2)));
768 fProfV3Resolution[fInCentralitySelection]->Fill(8., TMath::Cos(3.*(vzeroComb[1] - tpca3)));
769 fProfV3Resolution[fInCentralitySelection]->Fill(9., TMath::Cos(3.*(vzeroComb[1] - tpcb3)));
770 fProfV3Resolution[fInCentralitySelection]->Fill(10., TMath::Cos(3.*(tpca3 - tpcb3)));
772 //_____________________________________________________________________________
773 Double_t AliAnalysisTaskRhoVnModulation::CalculateEventPlaneChi(Double_t resEP) const
775 // Get Chi from EP resolution (PRC 58 1671)
776 Double_t chi(2.), delta (1.);
777 for (Int_t i(0); i < 15; i++) {
778 chi = ((TMath::Sqrt(TMath::Pi()/2.)/2.)*chi*exp(-chi*chi/4.)*(TMath::BesselI0(chi*chi/4.)+TMath::BesselI1(chi* chi/4.)) < resEP) ? chi+delta : chi-delta;
783 //_____________________________________________________________________________
784 void AliAnalysisTaskRhoVnModulation::CalculateRandomCone(Float_t &pt, Float_t &eta, Float_t &phi,
785 AliEmcalJet* jet) const
788 if(fDebug > 1) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
789 pt = 0; eta = 0; phi = 0;
790 Float_t etaJet(999), phiJet(999), dJet(999); // no jet: same as jet very far away
791 if(jet) { // if a leading jet is given, use its kinematic properties
795 // the random cone acceptance has to equal the jet acceptance
796 // this also insures safety when runnnig on the semi-good tpc runs for 11h data,
797 // where jet acceptance is adjusted to reduced acceptance - hence random cone acceptance as well
798 Float_t minPhi(GetJetContainer()->GetJetPhiMin()), maxPhi(GetJetContainer()->GetJetPhiMax());
799 if(maxPhi > TMath::TwoPi()) maxPhi = TMath::TwoPi();
800 if(minPhi < 0 ) minPhi = 0;
801 Float_t diffRcRJR(TMath::Abs(fRandomConeRadius-GetJetContainer()->GetJetRadius()));
802 // construct a random cone and see if it's far away enough from the leading jet
803 Int_t attempts(1000);
806 eta = gRandom->Uniform(GetJetContainer()->GetJetEtaMin()+diffRcRJR, GetJetContainer()->GetJetEtaMax()-diffRcRJR);
807 phi = gRandom->Uniform(minPhi, maxPhi);
809 dJet = TMath::Sqrt((etaJet-eta)*(etaJet-eta)+(phiJet-phi)*(phiJet-phi));
810 if(dJet > fMinDisanceRCtoLJ) break;
811 else if (attempts == 0) {
812 printf(" > No random cone after 1000 tries, giving up ... !\n");
817 AliVParticle* track = fTracksCont->GetNextAcceptParticle(0);
819 Float_t etaTrack(track->Eta()), phiTrack(track->Phi()), ptTrack(track->Pt());
820 // get distance from cone
821 if(TMath::Abs(phiTrack-phi) > TMath::Abs(phiTrack - phi + TMath::TwoPi())) phiTrack+=TMath::TwoPi();
822 if(TMath::Abs(phiTrack-phi) > TMath::Abs(phiTrack - phi - TMath::TwoPi())) phiTrack-=TMath::TwoPi();
823 if(TMath::Sqrt(TMath::Abs((etaTrack-eta)*(etaTrack-eta)+(phiTrack-phi)*(phiTrack-phi))) <= fRandomConeRadius) pt+=ptTrack;
824 track = fTracksCont->GetNextAcceptParticle();
828 //_____________________________________________________________________________
829 Double_t AliAnalysisTaskRhoVnModulation::CalculateQC2(Int_t harm) {
830 // get the second order q-cumulant, a -999 return will be caught in the qa routine of CorrectRho
831 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
832 Double_t reQ(0), imQ(0), modQ(0), M11(0), M(0);
833 if(fUsePtWeight) { // for the weighted 2-nd order q-cumulant
834 QCnQnk(harm, 1, reQ, imQ); // get the weighted 2-nd order q-vectors
835 modQ = reQ*reQ+imQ*imQ; // get abs Q-squared
836 M11 = QCnM11(); // equals S2,1 - S1,2
837 return (M11 > 0) ? ((modQ - QCnS(1,2))/M11) : -999;
838 } // else return the non-weighted 2-nd order q-cumulant
839 QCnQnk(harm, 0, reQ, imQ); // get the non-weighted 2-nd order q-vectors
840 modQ = reQ*reQ+imQ*imQ; // get abs Q-squared
842 return (M > 1) ? (modQ - M)/(M*(M-1)) : -999;
844 //_____________________________________________________________________________
845 Double_t AliAnalysisTaskRhoVnModulation::CalculateQC4(Int_t harm) {
846 // get the fourth order q-cumulant, a -999 return will be caught in the qa routine of CorrectRho
847 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
848 Double_t reQn1(0), imQn1(0), reQ2n2(0), imQ2n2(0), reQn3(0), imQn3(0), M1111(0), M(0);
849 Double_t a(0), b(0), c(0), d(0), e(0), f(0), g(0); // terms of the calculation
850 if(fUsePtWeight) { // for the weighted 4-th order q-cumulant
851 QCnQnk(harm, 1, reQn1, imQn1);
852 QCnQnk(harm*2, 2, reQ2n2, imQ2n2);
853 QCnQnk(harm, 3, reQn3, imQn3);
854 // fill in the terms ...
855 a = (reQn1*reQn1+imQn1*imQn1)*(reQn1*reQn1+imQn1*imQn1);
856 b = reQ2n2*reQ2n2 + imQ2n2*imQ2n2;
857 c = -2.*(reQ2n2*reQn1*reQn1-reQ2n2*imQn1*imQn1+2.*imQ2n2*reQn1*imQn1);
858 d = 8.*(reQn3*reQn1+imQn3*imQn1);
859 e = -4.*QCnS(1,2)*(reQn1*reQn1+imQn1*imQn1);
863 return (M1111 > 0) ? (a+b+c+d+e+f+g)/M1111 : -999;
864 } // else return the unweighted case
865 Double_t reQn(0), imQn(0), reQ2n(0), imQ2n(0);
866 QCnQnk(harm, 0, reQn, imQn);
867 QCnQnk(harm*2, 0, reQ2n, imQ2n);
868 // fill in the terms ...
870 if(M < 4) return -999;
871 a = (reQn*reQn+imQn*imQn)*(reQn*reQn+imQn*imQn);
872 b = reQ2n*reQ2n + imQ2n*imQ2n;
873 c = -2.*(reQ2n*reQn*reQn-reQ2n*imQn*imQn+2.*imQ2n*reQn*imQn);
874 e = -4.*(M-2)*(reQn*reQn+imQn*imQn);
876 return (a+b+c+e+f)/(M*(M-1)*(M-2)*(M-3));
878 //_____________________________________________________________________________
879 void AliAnalysisTaskRhoVnModulation::QCnQnk(Int_t n, Int_t k, Double_t &reQ, Double_t &imQ) {
880 // get the weighted n-th order q-vector, pass real and imaginary part as reference
881 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
883 fNAcceptedTracksQCn = 0;
884 Int_t iTracks(fTracks->GetEntriesFast());
885 for(Int_t iTPC(0); iTPC < iTracks; iTPC++) {
886 AliVTrack* track = static_cast<AliVTrack*>(fTracks->At(iTPC));
887 if(!PassesCuts(track) || track->Pt() < fSoftTrackMinPt || track->Pt() > fSoftTrackMaxPt) continue;
888 fNAcceptedTracksQCn++;
889 // for the unweighted case, k equals zero and the weight doesn't contribute to the equation below
890 reQ += TMath::Power(track->Pt(), k) * TMath::Cos(((double)n)*track->Phi());
891 imQ += TMath::Power(track->Pt(), k) * TMath::Sin(((double)n)*track->Phi());
894 //_____________________________________________________________________________
895 void AliAnalysisTaskRhoVnModulation::QCnDiffentialFlowVectors(
896 TClonesArray* pois, TArrayD* ptBins, Bool_t vpart, Double_t* repn, Double_t* impn,
897 Double_t *mp, Double_t *reqn, Double_t *imqn, Double_t* mq, Int_t n)
899 // get unweighted differential flow vectors
900 Int_t iPois(pois->GetEntriesFast());
902 for(Int_t i(0); i < iPois; i++) {
903 for(Int_t ptBin(0); ptBin < ptBins->GetSize()-1; ptBin++) {
904 AliVTrack* poi = static_cast<AliVTrack*>(pois->At(i));
905 if(PassesCuts(poi)) {
906 if(poi->Pt() >= ptBins->At(ptBin) && poi->Pt() < ptBins->At(ptBin+1)) {
907 // fill the flow vectors assuming that all poi's are in the rp selection (true by design)
908 repn[ptBin]+=TMath::Cos(((double)n)*poi->Phi());
909 impn[ptBin]+=TMath::Sin(((double)n)*poi->Phi());
911 reqn[ptBin]+=TMath::Cos(((double)n)*poi->Phi());
912 imqn[ptBin]+=TMath::Sin(((double)n)*poi->Phi());
919 for(Int_t i(0); i < iPois; i++) {
920 for(Int_t ptBin(0); ptBin < ptBins->GetSize()-1; ptBin++) {
921 AliEmcalJet* poi = static_cast<AliEmcalJet*>(pois->At(i));
922 if(PassesCuts(poi)) {
923 Double_t pt(poi->Pt()-poi->Area()*fLocalRho->GetLocalVal(poi->Phi(), GetJetContainer()->GetJetRadius(), fLocalRho->GetVal()));
924 if(pt >= ptBins->At(ptBin) && pt < ptBins->At(ptBin+1)) {
925 repn[ptBin]+=TMath::Cos(((double)n)*poi->Phi());
926 impn[ptBin]+=TMath::Sin(((double)n)*poi->Phi());
927 mp[ptBin]++; // qn isn't filled, no overlap between poi's and rp's
934 //_____________________________________________________________________________
935 Double_t AliAnalysisTaskRhoVnModulation::QCnS(Int_t i, Int_t j) {
936 // get the weighted ij-th order autocorrelation correction
937 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
938 if(!fTracks || i <= 0 || j <= 0) return -999;
939 Int_t iTracks(fTracks->GetEntriesFast());
941 for(Int_t iTPC(0); iTPC < iTracks; iTPC++) {
942 AliVTrack* track = static_cast<AliVTrack*>(fTracks->At(iTPC));
943 if(!PassesCuts(track) || track->Pt() < fSoftTrackMinPt || track->Pt() > fSoftTrackMaxPt) continue;
944 Sij+=TMath::Power(track->Pt(), j);
946 return TMath::Power(Sij, i);
948 //_____________________________________________________________________________
949 Double_t AliAnalysisTaskRhoVnModulation::QCnM() {
950 // get multiplicity for unweighted q-cumulants. function QCnQnk should be called first
951 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
952 return (Double_t) fNAcceptedTracksQCn;
954 //_____________________________________________________________________________
955 Double_t AliAnalysisTaskRhoVnModulation::QCnM11() {
956 // get multiplicity weights for the weighted two particle cumulant
957 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
958 return (QCnS(2,1) - QCnS(1,2));
960 //_____________________________________________________________________________
961 Double_t AliAnalysisTaskRhoVnModulation::QCnM1111() {
962 // get multiplicity weights for the weighted four particle cumulant
963 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
964 return (QCnS(4,1)-6*QCnS(1,2)*QCnS(2,1)+8*QCnS(1,3)*QCnS(1,1)+3*QCnS(2,2)-6*QCnS(1,4));
966 //_____________________________________________________________________________
967 Bool_t AliAnalysisTaskRhoVnModulation::QCnRecovery(Double_t psi2, Double_t psi3) {
968 // decides how to deal with the situation where c2 or c3 is negative
969 // returns kTRUE depending on whether or not a modulated rho is used for the jet background
970 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
971 if(TMath::AreEqualAbs(fFitModulation->GetParameter(3), .0, 1e-10) && TMath::AreEqualAbs(fFitModulation->GetParameter(7), .0,1e-10)) {
972 fFitModulation->SetParameter(7, 0);
973 fFitModulation->SetParameter(3, 0);
974 fFitModulation->SetParameter(0, fLocalRho->GetVal());
975 return kTRUE; // v2 and v3 have physical null values
977 switch (fQCRecovery) {
978 case kFixedRho : { // roll back to the original rho
979 fFitModulation->SetParameter(7, 0);
980 fFitModulation->SetParameter(3, 0);
981 fFitModulation->SetParameter(0, fLocalRho->GetVal());
982 return kFALSE; // rho is forced to be fixed
985 Double_t c2(fFitModulation->GetParameter(3));
986 Double_t c3(fFitModulation->GetParameter(7));
987 if( c2 < 0 ) c2 = -1.*TMath::Sqrt(-1.*c2);
988 if( c3 < 0 ) c3 = -1.*TMath::Sqrt(-1.*c3);
989 fFitModulation->SetParameter(3, c2);
990 fFitModulation->SetParameter(7, c3);
991 return kTRUE; // is this a physical quantity ?
994 fitModulationType tempType(fFitModulationType); // store temporarily
995 fFitModulationType = kCombined;
996 fFitModulation->SetParameter(7, 0);
997 fFitModulation->SetParameter(3, 0);
998 Bool_t pass(CorrectRho(psi2, psi3)); // do the fit and all quality checks
999 fFitModulationType = tempType; // roll back for next event
1002 default : return kFALSE;
1006 //_____________________________________________________________________________
1007 Bool_t AliAnalysisTaskRhoVnModulation::CorrectRho(Double_t psi2, Double_t psi3)
1009 // get rho' -> rho(phi)
1010 // two routines are available, both can be used with or without pt weights
1011 // [1] get vn from q-cumulants or as an integrated value from a user supplied histogram
1012 // in case of cumulants, both cumulants and vn values are stored. in both cases, v2 and v3
1013 // are expected. a check is performed to see if rho has no negative local minimum
1014 // for full description, see Phys. Rev. C 83, 044913
1015 // since the cn distribution has negative values, vn = sqrt(cn) can be imaginary sometimes
1016 // in this case one can either roll back to the 'original' rixed rho, do a fit for vn or take use
1017 // vn = - sqrt(|cn|)
1018 // [2] fitting a fourier expansion to the de/dphi distribution
1019 // the fit can be done with either v2, v3 or a combination.
1020 // in all cases, a cut can be made on the p-value of the chi-squared value of the fit
1021 // and a check can be performed to see if rho has no negative local minimum
1022 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1023 switch (fFitModulationType) { // for approaches where no fitting is required
1025 fFitModulation->FixParameter(4, psi2);
1026 fFitModulation->FixParameter(6, psi3);
1027 fFitModulation->FixParameter(3, CalculateQC2(2)); // set here with cn, vn = sqrt(cn)
1028 fFitModulation->FixParameter(7, CalculateQC2(3));
1029 // first fill the histos of the raw cumulant distribution
1030 if (fUsePtWeight) { // use weighted weights
1031 Double_t dQCnM11 = (fNoEventWeightsForQC) ? 1. : QCnM11();
1032 fProfV2Cumulant->Fill(fCent, fFitModulation->GetParameter(3), dQCnM11);
1033 fProfV3Cumulant->Fill(fCent, fFitModulation->GetParameter(7), dQCnM11);
1035 Double_t dQCnM = (fNoEventWeightsForQC) ? 2. : QCnM();
1036 fProfV2Cumulant->Fill(fCent, fFitModulation->GetParameter(3), dQCnM*(dQCnM-1));
1037 fProfV3Cumulant->Fill(fCent, fFitModulation->GetParameter(7), dQCnM*(dQCnM-1));
1039 // then see if one of the cn value is larger than zero and vn is readily available
1040 if(fFitModulation->GetParameter(3) > 0 && fFitModulation->GetParameter(7) > 0) {
1041 fFitModulation->FixParameter(3, TMath::Sqrt(fFitModulation->GetParameter(3)));
1042 fFitModulation->FixParameter(7, TMath::Sqrt(fFitModulation->GetParameter(7)));
1043 } else if (!QCnRecovery(psi2, psi3)) return kFALSE; // try to recover the cumulant, this will set v2 and v3
1044 if(fAbsVnHarmonics && fFitModulation->GetMinimum(0, TMath::TwoPi()) < 0) { // general check
1045 fFitModulation->SetParameter(7, 0);
1046 fFitModulation->SetParameter(3, 0);
1047 fFitModulation->SetParameter(0, fLocalRho->GetVal());
1053 fFitModulation->FixParameter(4, psi2);
1054 fFitModulation->FixParameter(6, psi3);
1055 fFitModulation->FixParameter(3, CalculateQC4(2)); // set here with cn, vn = sqrt(cn)
1056 fFitModulation->FixParameter(7, CalculateQC4(3));
1057 // first fill the histos of the raw cumulant distribution
1058 if (fUsePtWeight) { // use weighted weights
1059 fProfV2Cumulant->Fill(fCent, fFitModulation->GetParameter(3)/*, QCnM1111()*/);
1060 fProfV3Cumulant->Fill(fCent, fFitModulation->GetParameter(7)/*, QCnM1111()*/);
1062 fProfV2Cumulant->Fill(fCent, fFitModulation->GetParameter(3)/*, QCnM1111()*/);
1063 fProfV3Cumulant->Fill(fCent, fFitModulation->GetParameter(7)/*, QCnM1111()*/);
1065 // then see if one of the cn value is larger than zero and vn is readily available
1066 if(fFitModulation->GetParameter(3) > 0 && fFitModulation->GetParameter(7) > 0) {
1067 fFitModulation->FixParameter(3, TMath::Sqrt(fFitModulation->GetParameter(3)));
1068 fFitModulation->FixParameter(7, TMath::Sqrt(fFitModulation->GetParameter(7)));
1069 } else if (!QCnRecovery(psi2, psi3)) return kFALSE; // try to recover the cumulant, this will set v2 and v3
1070 if(fAbsVnHarmonics && fFitModulation->GetMinimum(0, TMath::TwoPi()) < 0) { // general check
1071 fFitModulation->SetParameter(7, 0);
1072 fFitModulation->SetParameter(3, 0);
1073 fFitModulation->SetParameter(0, fLocalRho->GetVal());
1077 case kIntegratedFlow : {
1078 // use v2 and v3 values from an earlier iteration over the data
1079 fFitModulation->FixParameter(3, fUserSuppliedV2->GetBinContent(fUserSuppliedV2->GetXaxis()->FindBin(fCent)));
1080 fFitModulation->FixParameter(4, psi2);
1081 fFitModulation->FixParameter(6, psi3);
1082 fFitModulation->FixParameter(7, fUserSuppliedV3->GetBinContent(fUserSuppliedV3->GetXaxis()->FindBin(fCent)));
1083 if(fAbsVnHarmonics && fFitModulation->GetMinimum(0, TMath::TwoPi()) < 0) {
1084 fFitModulation->SetParameter(7, 0);
1085 fFitModulation->SetParameter(3, 0);
1086 fFitModulation->SetParameter(0, fLocalRho->GetVal());
1093 TString detector("");
1094 switch (fDetectorType) {
1095 case kTPC : detector+="TPC";
1097 case kVZEROA : detector+="VZEROA";
1099 case kVZEROC : detector+="VZEROC";
1101 case kVZEROComb : detector+="VZEROComb";
1105 Int_t iTracks(fTracks->GetEntriesFast());
1106 Double_t excludeInEta = -999;
1107 Double_t excludeInPhi = -999;
1108 Double_t excludeInPt = -999;
1109 if(iTracks <= 0 || fLocalRho->GetVal() <= 0 ) return kFALSE; // no use fitting an empty event ...
1110 if(fExcludeLeadingJetsFromFit > 0 ) {
1111 AliEmcalJet* leadingJet(GetJetContainer()->GetLeadingJet());
1113 excludeInEta = leadingJet->Eta();
1114 excludeInPhi = leadingJet->Phi();
1115 excludeInPt = leadingJet->Pt();
1118 // check the acceptance of the track selection that will be used
1119 // if one uses e.g. semi-good tpc tracks, accepance in phi is reduced to 0 < phi < 4
1120 // the defaults (-10 < phi < 10) which accept all, are then overwritten
1121 Double_t lowBound(0.), upBound(TMath::TwoPi()); // bounds for fit
1122 if(GetParticleContainer()->GetParticlePhiMin() > lowBound) lowBound = GetParticleContainer()->GetParticlePhiMin();
1123 if(GetParticleContainer()->GetParticlePhiMax() < upBound) upBound = GetParticleContainer()->GetParticlePhiMax();
1125 fHistSwap->Reset(); // clear the histogram
1126 TH1F _tempSwap; // on stack for quick access
1127 TH1F _tempSwapN; // on stack for quick access, bookkeeping histogram
1128 if(fRebinSwapHistoOnTheFly) {
1129 if(fNAcceptedTracks < 49) fNAcceptedTracks = 49; // avoid aliasing effects
1130 _tempSwap = TH1F("_tempSwap", "_tempSwap", TMath::CeilNint(TMath::Sqrt(fNAcceptedTracks)), lowBound, upBound);
1131 if(fUsePtWeightErrorPropagation) _tempSwapN = TH1F("_tempSwapN", "_tempSwapN", TMath::CeilNint(TMath::Sqrt(fNAcceptedTracks)), lowBound, upBound);
1132 if(fUsePtWeight) _tempSwap.Sumw2();
1134 else _tempSwap = *fHistSwap; // now _tempSwap holds the desired histo
1135 // non poissonian error when using pt weights
1136 Double_t totalpts(0.), totalptsquares(0.), totalns(0.);
1137 for(Int_t i(0); i < iTracks; i++) {
1138 AliVTrack* track = static_cast<AliVTrack*>(fTracks->At(i));
1139 if(fExcludeLeadingJetsFromFit > 0 &&( (TMath::Abs(track->Eta() - excludeInEta) < GetJetContainer()->GetJetRadius()*fExcludeLeadingJetsFromFit ) || (TMath::Abs(track->Eta()) - GetJetContainer()->GetJetRadius() - GetJetContainer()->GetJetEtaMax() ) > 0 )) continue;
1140 if(!PassesCuts(track) || track->Pt() > fSoftTrackMaxPt || track->Pt() < fSoftTrackMinPt) continue;
1142 _tempSwap.Fill(track->Phi(), track->Pt());
1143 if(fUsePtWeightErrorPropagation) {
1144 totalpts += track->Pt();
1145 totalptsquares += track->Pt()*track->Pt();
1147 _tempSwapN.Fill(track->Phi());
1150 else _tempSwap.Fill(track->Phi());
1152 if(fUsePtWeight && fUsePtWeightErrorPropagation) {
1153 // in the case of pt weights overwrite the poissonian error estimate which is assigned by root by a more sophisticated appraoch
1154 // the assumption here is that the bin error will be dominated by the uncertainty in the mean pt in a bin and in the uncertainty
1155 // of the number of tracks in a bin, the first of which will be estimated from the sample standard deviation of all tracks in the
1156 // event, for the latter use a poissonian estimate. the two contrubitions are assumed to be uncorrelated
1157 if(totalns < 1) return kFALSE; // not one track passes the cuts
1158 for(Int_t l = 0; l < _tempSwap.GetNbinsX(); l++) {
1159 if(_tempSwapN.GetBinContent(l+1) == 0) {
1160 _tempSwap.SetBinContent(l+1,0);
1161 _tempSwap.SetBinError(l+1,0);
1164 Double_t vartimesnsq = totalptsquares*totalns - totalpts*totalpts;
1165 Double_t variance = vartimesnsq/(totalns*(totalns-1.));
1166 Double_t SDOMSq = variance / _tempSwapN.GetBinContent(l+1);
1167 Double_t SDOMSqOverMeanSq = SDOMSq * _tempSwapN.GetBinContent(l+1) * _tempSwapN.GetBinContent(l+1) / (_tempSwapN.GetBinContent(l+1) * _tempSwapN.GetBinContent(l+1));
1168 Double_t poissonfrac = 1./_tempSwapN.GetBinContent(l+1);
1169 Double_t vartotalfrac = SDOMSqOverMeanSq + poissonfrac;
1170 Double_t vartotal = vartotalfrac * _tempSwap.GetBinContent(l+1) * _tempSwap.GetBinContent(l+1);
1171 if(vartotal > 0.0001) _tempSwap.SetBinError(l+1,TMath::Sqrt(vartotal));
1173 _tempSwap.SetBinContent(l+1,0);
1174 _tempSwap.SetBinError(l+1,0);
1180 fFitModulation->SetParameter(0, fLocalRho->GetVal());
1181 switch (fFitModulationType) {
1182 case kNoFit : { fFitModulation->FixParameter(0, fLocalRho->GetVal() );
1185 fFitModulation->FixParameter(4, psi2);
1188 fFitModulation->FixParameter(4, psi3);
1191 fFitModulation->FixParameter(4, psi2);
1192 fFitModulation->FixParameter(6, psi3);
1194 case kFourierSeries : {
1195 // in this approach, an explicit calculation will be made of vn = sqrt(xn^2+yn^2)
1196 // where x[y] = Integrate[r(phi)cos[sin](n phi)dphi, 0, 2pi]
1197 Double_t cos2(0), sin2(0), cos3(0), sin3(0), sumPt(0);
1198 for(Int_t i(0); i < iTracks; i++) {
1199 AliVTrack* track = static_cast<AliVTrack*>(fTracks->At(i));
1200 if(!PassesCuts(track) || track->Pt() > fSoftTrackMaxPt || track->Pt() < fSoftTrackMinPt) continue;
1201 sumPt += track->Pt();
1202 cos2 += track->Pt()*TMath::Cos(2*PhaseShift(track->Phi()-psi2));
1203 sin2 += track->Pt()*TMath::Sin(2*PhaseShift(track->Phi()-psi2));
1204 cos3 += track->Pt()*TMath::Cos(3*PhaseShift(track->Phi()-psi3));
1205 sin3 += track->Pt()*TMath::Sin(3*PhaseShift(track->Phi()-psi3));
1207 fFitModulation->SetParameter(3, TMath::Sqrt(cos2*cos2+sin2*sin2)/fLocalRho->GetVal());
1208 fFitModulation->SetParameter(4, psi2);
1209 fFitModulation->SetParameter(6, psi3);
1210 fFitModulation->SetParameter(7, TMath::Sqrt(cos3*cos3+sin3*sin3)/fLocalRho->GetVal());
1214 _tempSwap.Fit(fFitModulation, fFitModulationOptions.Data(), "", lowBound, upBound);
1215 // the quality of the fit is evaluated from 1 - the cdf of the chi square distribution
1216 Double_t CDF(1.-ChiSquareCDF(fFitModulation->GetNDF(), fFitModulation->GetChisquare()));
1217 fHistPvalueCDF->Fill(CDF);
1219 // as an additional quality check, see if fitting a control fit has a higher significance
1220 _tempSwap.Fit(fFitControl, fFitModulationOptions.Data(), "", lowBound, upBound);
1221 Double_t CDFControl(1.-ChiSquareCDF(fFitControl->GetNDF(), fFitControl->GetChisquare()));
1222 if(CDFControl > CDF) {
1223 CDF = -1.; // control fit is more significant, so throw out the 'old' fit
1224 fHistRhoStatusCent->Fill(fCent, -1);
1227 if(CDF >= fMinPvalue && CDF <= fMaxPvalue && ( fAbsVnHarmonics && fFitModulation->GetMinimum(0, TMath::TwoPi()) > 0)) { // fit quality. not that although with limited acceptance the fit is performed on just
1228 // part of phase space, the requirement that energy desntiy is larger than zero is applied
1229 // to the FULL spectrum
1230 fHistRhoStatusCent->Fill(fCent, 0.);
1231 // for LOCAL didactic purposes, save the best and the worst fits
1232 // this routine can produce a lot of output histograms (it's not memory 'safe') and will not work on GRID
1233 // since the output will become unmergeable (i.e. different nodes may produce conflicting output)
1234 switch (fRunModeType) {
1236 if(fRandom->Uniform(0, 100) > fPercentageOfFits) break;
1237 static Int_t didacticCounterBest(0);
1238 TProfile* didacticProfile = (TProfile*)_tempSwap.Clone(Form("Fit_%i_1-CDF_%.3f_cen_%i_%s", didacticCounterBest, CDF, fInCentralitySelection, detector.Data()));
1239 TF1* didacticFit = (TF1*)fFitModulation->Clone(Form("fit_%i_CDF_%.3f_cen_%i_%s", didacticCounterBest, CDF, fInCentralitySelection, detector.Data()));
1240 switch(fFitModulationType) {
1242 // to make a nice picture also plot the separate components (v2 and v3) of the fit
1243 // only done for cobined fit where there are actually components to split ...
1244 TF1* v2(new TF1("dfit_kV2", "[0]*([1]+[2]*[3]*TMath::Cos([2]*(x-[4])))", 0, TMath::TwoPi()));
1245 v2->SetParameter(0, didacticFit->GetParameter(0)); // normalization
1246 v2->SetParameter(3, didacticFit->GetParameter(3)); // v2
1247 v2->FixParameter(1, 1.); // constant
1248 v2->FixParameter(2, 2.); // constant
1249 v2->SetLineColor(kGreen);
1250 didacticProfile->GetListOfFunctions()->Add(v2);
1251 TF1* v3(new TF1("dfit_kV3", "[0]*([1]+[2]*[3]*TMath::Cos([2]*(x-[4])))", 0, TMath::TwoPi()));
1252 v3->SetParameter(0, didacticFit->GetParameter(0)); // normalization
1253 v3->SetParameter(3, didacticFit->GetParameter(7)); // v3
1254 v3->FixParameter(1, 1.); // constant
1255 v3->FixParameter(2, 3.); // constant
1256 v3->SetLineColor(kYellow);
1257 didacticProfile->GetListOfFunctions()->Add(v3);
1261 didacticProfile->GetListOfFunctions()->Add(didacticFit);
1262 fOutputListGood->Add(didacticProfile);
1263 didacticCounterBest++;
1264 TH2F* didacticSurface = BookTH2F(Form("surface_%s", didacticProfile->GetName()), "#phi", "#eta", 50, 0, TMath::TwoPi(), 50, -1, 1, -1, kFALSE);
1265 for(Int_t i(0); i < iTracks; i++) {
1266 AliVTrack* track = static_cast<AliVTrack*>(fTracks->At(i));
1267 if(PassesCuts(track)) {
1268 if(fUsePtWeight) didacticSurface->Fill(track->Phi(), track->Eta(), track->Pt());
1269 else didacticSurface->Fill(track->Phi(), track->Eta());
1272 if(fExcludeLeadingJetsFromFit) { // visualize the excluded region
1273 TF2 *f2 = new TF2(Form("%s_LJ", didacticSurface->GetName()),"[0]*TMath::Gaus(x,[1],[2])*TMath::Gaus(y,[3],[4])", 0, TMath::TwoPi(), -1, 1);
1274 f2->SetParameters(excludeInPt/3.,excludeInPhi,.1,excludeInEta,.1);
1275 didacticSurface->GetListOfFunctions()->Add(f2);
1277 fOutputListGood->Add(didacticSurface);
1281 } else { // if the fit is of poor quality revert to the original rho estimate
1282 switch (fRunModeType) { // again see if we want to save the fit
1284 static Int_t didacticCounterWorst(0);
1285 if(fRandom->Uniform(0, 100) > fPercentageOfFits) break;
1286 TProfile* didacticProfile = (TProfile*)_tempSwap.Clone(Form("Fit_%i_1-CDF_%.3f_cen_%i_%s", didacticCounterWorst, CDF, fInCentralitySelection, detector.Data() ));
1287 TF1* didacticFit = (TF1*)fFitModulation->Clone(Form("fit_%i_p_%.3f_cen_%i_%s", didacticCounterWorst, CDF, fInCentralitySelection, detector.Data()));
1288 didacticProfile->GetListOfFunctions()->Add(didacticFit);
1289 fOutputListBad->Add(didacticProfile);
1290 didacticCounterWorst++;
1294 switch (fFitModulationType) {
1295 case kNoFit : break; // nothing to do
1296 case kCombined : fFitModulation->SetParameter(7, 0); // no break
1297 case kFourierSeries : fFitModulation->SetParameter(7, 0); // no break
1298 default : { // needs to be done if there was a poor fit
1299 fFitModulation->SetParameter(3, 0);
1300 fFitModulation->SetParameter(0, fLocalRho->GetVal());
1303 if(CDF > -.5) fHistRhoStatusCent->Fill(fCent, 1.);
1304 return kFALSE; // return false if the fit is rejected
1308 //_____________________________________________________________________________
1309 Bool_t AliAnalysisTaskRhoVnModulation::PassesCuts(AliVEvent* event)
1312 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1313 if(!event || !AliAnalysisTaskEmcal::IsEventSelected()) return kFALSE;
1314 if(fSemiCentralInclusive && ! (event->GetTriggerMask() & (ULong64_t(1)<<7))) return kFALSE;
1315 if(TMath::Abs(InputEvent()->GetPrimaryVertex()->GetZ()) > 10.) return kFALSE;
1316 // aod and esd specific checks
1317 switch (fDataType) {
1319 AliESDEvent* esdEvent = static_cast<AliESDEvent*>(InputEvent());
1320 if( (!esdEvent) || (TMath::Abs(esdEvent->GetPrimaryVertexSPD()->GetZ() - esdEvent->GetPrimaryVertex()->GetZ()) > .5) ) return kFALSE;
1323 AliAODEvent* aodEvent = static_cast<AliAODEvent*>(InputEvent());
1324 if( (!aodEvent) || (TMath::Abs(aodEvent->GetPrimaryVertexSPD()->GetZ() - aodEvent->GetPrimaryVertex()->GetZ()) > .5) ) return kFALSE;
1328 fCent = InputEvent()->GetCentrality()->GetCentralityPercentile("V0M");
1329 if(fCent <= fCentralityClasses->At(0) || fCent >= fCentralityClasses->At(fCentralityClasses->GetSize()-1) || TMath::Abs(fCent-InputEvent()->GetCentrality()->GetCentralityPercentile("TRK")) > 5.) return kFALSE;
1330 // determine centrality class
1331 fInCentralitySelection = -1;
1332 for(Int_t i(0); i < fCentralityClasses->GetSize()-1; i++) {
1333 if(fCent >= fCentralityClasses->At(i) && fCent <= fCentralityClasses->At(1+i)) {
1334 fInCentralitySelection = i;
1337 if(fInCentralitySelection<0) return kFALSE; // should be null op
1338 if(fExplicitOutlierCut == 2010 || fExplicitOutlierCut == 2011) {
1339 if(!PassesCuts(fExplicitOutlierCut)) return kFALSE;
1341 if(fRho->GetVal() <= 0 ) return kFALSE;
1342 if(fTracks->GetEntries() < 1) return kFALSE;
1343 if(fRunNumber != InputEvent()->GetRunNumber()) {
1344 fRunNumber = InputEvent()->GetRunNumber(); // set the current run number
1345 if(fDebug > 0 ) printf("> NEW RUNNNUMBER DETECTED: %i <\n", fRunNumber);
1346 // determine the run number to see if the track and jet cuts should be refreshed for semi-good TPC runs
1347 Int_t semiGoodTPCruns[] = {169975, 169981, 170038, 170040, 170083, 170084, 170085, 170088, 170089, 170091, 170152, 170155, 170159, 170163, 170193, 170195, 170203, 170204, 170205, 170228, 170230, 170264, 170268, 170269, 170270, 170306, 170308, 170309};
1348 for(Int_t i(0); i < (int)(sizeof(semiGoodTPCruns)/sizeof(semiGoodTPCruns[0])); i++) {
1349 if(semiGoodTPCruns[i] == fRunNumber) { // run is semi-good
1350 if(fDebug > 0) printf(" > SEMI-GOOD TPC DETECTED, adjusting acceptance accordingly ... <\n");
1351 AliAnalysisTaskEmcalJet::SetJetPhiLimits(fSemiGoodJetMinPhi, fSemiGoodJetMaxPhi);
1352 AliAnalysisTaskEmcal::SetTrackPhiLimits(fSemiGoodTrackMinPhi, fSemiGoodTrackMaxPhi);
1358 //_____________________________________________________________________________
1359 Bool_t AliAnalysisTaskRhoVnModulation::PassesCuts(Int_t year)
1361 // additional centrality cut based on relation between tpc and global multiplicity
1362 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1363 AliAODEvent* event(dynamic_cast<AliAODEvent*>(InputEvent()));
1364 if(!event) return kFALSE;
1365 Int_t multTPC(0), multGlob(0), nTracks(InputEvent()->GetNumberOfTracks());
1366 for(Int_t iTracks = 0; iTracks < nTracks; iTracks++) {
1367 AliAODTrack* track = event->GetTrack(iTracks);
1368 if(!track) continue;
1369 if (!track || track->Pt() < .2 || track->Pt() > 5.0 || TMath::Abs(track->Eta()) > .8 || track->GetTPCNcls() < 70 || !track->GetDetPid() || track->GetDetPid()->GetTPCsignal() < 10.0) continue; // general quality cut
1370 if (track->TestFilterBit(1) && track->Chi2perNDF() > 0.2) multTPC++;
1371 if (!track->TestFilterBit(16) || track->Chi2perNDF() < 0.1) continue;
1372 Double_t b[2] = {-99., -99.};
1373 Double_t bCov[3] = {-99., -99., -99.};
1374 if (track->PropagateToDCA(event->GetPrimaryVertex(), event->GetMagneticField(), 100., b, bCov) && TMath::Abs(b[0]) < 0.3 && TMath::Abs(b[1]) < 0.3) multGlob++;
1376 if(year == 2010 && multTPC > (-40.3+1.22*multGlob) && multTPC < (32.1+1.59*multGlob)) return kTRUE;
1377 if(year == 2011 && multTPC > (-36.73 + 1.48*multGlob) && multTPC < (62.87 + 1.78*multGlob)) return kTRUE;
1380 //_____________________________________________________________________________
1381 Bool_t AliAnalysisTaskRhoVnModulation::PassesCuts(const AliVCluster* cluster) const
1384 if(fDebug > 1) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1385 if(!cluster) return kFALSE;
1388 //_____________________________________________________________________________
1389 void AliAnalysisTaskRhoVnModulation::FillHistogramsAfterSubtraction(Double_t psi2, Double_t psi3, Double_t vzero[2][2], Double_t* vzeroComb, Double_t* tpc)
1392 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1393 FillTrackHistograms();
1394 /* FillClusterHistograms(); */
1395 FillJetHistograms(psi2, psi3);
1396 /* FillCorrectedClusterHistograms(); */
1397 if(fFillQAHistograms) FillEventPlaneHistograms(vzero, vzeroComb, tpc);
1398 FillRhoHistograms();
1399 FillDeltaPtHistograms(psi2, psi3);
1401 //_____________________________________________________________________________
1402 void AliAnalysisTaskRhoVnModulation::FillTrackHistograms() const
1404 // fill track histograms
1405 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1406 Int_t iTracks(fTracks->GetEntriesFast()), iAcceptedTracks(0);
1407 for(Int_t i(0); i < iTracks; i++) {
1408 AliVTrack* track = static_cast<AliVTrack*>(fTracks->At(i));
1409 if(!PassesCuts(track)) continue;
1411 fHistPicoTrackPt[fInCentralitySelection]->Fill(track->Pt());
1412 if(fFillQAHistograms) FillQAHistograms(track);
1414 fHistPicoTrackMult[fInCentralitySelection]->Fill(iAcceptedTracks);
1416 //_____________________________________________________________________________
1417 void AliAnalysisTaskRhoVnModulation::FillClusterHistograms() const
1419 // fill cluster histograms
1420 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1421 Int_t iClusters(fCaloClusters->GetEntriesFast());
1422 for(Int_t i(0); i < iClusters; i++) {
1423 AliVCluster* cluster = static_cast<AliVCluster*>(fCaloClusters->At(iClusters));
1424 if (!PassesCuts(cluster)) continue;
1425 TLorentzVector clusterLorentzVector;
1426 cluster->GetMomentum(clusterLorentzVector, const_cast<Double_t*>(fVertex));
1427 //fHistClusterPt[fInCentralitySelection]->Fill(clusterLorentzVector.Pt());
1428 //fHistClusterEta[fInCentralitySelection]->Fill(clusterLorentzVector.Eta());
1429 //fHistClusterPhi[fInCentralitySelection]->Fill(clusterLorentzVector.Phi());
1433 //_____________________________________________________________________________
1434 void AliAnalysisTaskRhoVnModulation::FillCorrectedClusterHistograms() const
1436 // fill clusters after hadronic correction FIXME implement
1437 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1439 //_____________________________________________________________________________
1440 void AliAnalysisTaskRhoVnModulation::FillEventPlaneHistograms(Double_t vzero[2][2], Double_t* vzeroComb, Double_t* tpc) const
1442 // fill event plane histograms
1443 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1444 fHistPsiControl->Fill(0.5, vzero[0][0]); // vzero a psi2
1445 fHistPsiControl->Fill(1.5, vzero[1][0]); // vzero c psi2
1446 fHistPsiControl->Fill(2.5, tpc[0]); // tpc psi 2
1447 fHistPsiControl->Fill(5.5, vzero[0][1]); // vzero a psi3
1448 fHistPsiControl->Fill(6.5, vzero[1][1]); // vzero b psi3
1449 fHistPsiControl->Fill(7.5, tpc[1]); // tpc psi 3
1450 fHistPsiVZEROA->Fill(vzero[0][0]);
1451 fHistPsiVZEROC->Fill(vzero[1][0]);
1452 fHistPsiVZERO->Fill(vzeroComb[0]);
1453 fHistPsiTPC->Fill(tpc[0]);
1454 fHistPsiSpread->Fill(0.5, TMath::Abs(vzero[0][0]-vzero[1][0]));
1455 fHistPsiSpread->Fill(1.5, TMath::Abs(vzero[0][0]-tpc[0]));
1456 fHistPsiSpread->Fill(2.5, TMath::Abs(vzero[1][0]-tpc[0]));
1457 // event plane vs centrality QA histo's to check recentering
1458 Double_t TRK(InputEvent()->GetCentrality()->GetCentralityPercentile("TRK"));
1459 Double_t V0M(InputEvent()->GetCentrality()->GetCentralityPercentile("V0M"));
1460 fHistPsiVZEROAV0M->Fill(V0M, vzero[0][0]);
1461 fHistPsiVZEROCV0M->Fill(V0M, vzero[1][0]);
1462 fHistPsiVZEROVV0M->Fill(V0M, vzeroComb[0]);
1463 fHistPsiTPCiV0M->Fill(V0M, tpc[0]);
1464 fHistPsiVZEROATRK->Fill(TRK, vzero[0][0]);
1465 fHistPsiVZEROCTRK->Fill(TRK, vzero[1][0]);
1466 fHistPsiVZEROTRK->Fill(TRK, vzeroComb[0]);
1467 fHistPsiTPCTRK->Fill(TRK, tpc[0]);
1469 //_____________________________________________________________________________
1470 void AliAnalysisTaskRhoVnModulation::FillRhoHistograms()
1472 // fill rho histograms
1473 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1474 fHistRhoPackage[fInCentralitySelection]->Fill(fLocalRho->GetVal()); // save the rho estimate from the emcal jet package
1475 // get multiplicity FIXME inefficient
1476 Int_t iJets(fJets->GetEntriesFast());
1477 Double_t rho(fLocalRho->GetLocalVal(TMath::Pi(), TMath::Pi(), fLocalRho->GetVal()));
1478 fHistRho[fInCentralitySelection]->Fill(rho);
1479 fHistRhoVsMult->Fill(fTracks->GetEntries(), rho);
1480 fHistRhoVsCent->Fill(fCent, rho);
1481 for(Int_t i(0); i < iJets; i++) {
1482 AliEmcalJet* jet = static_cast<AliEmcalJet*>(fJets->At(i));
1483 if(!PassesCuts(jet)) continue;
1484 fHistRhoAVsMult->Fill(fTracks->GetEntries(), rho * jet->Area());
1485 fHistRhoAVsCent->Fill(fCent, rho * jet->Area());
1488 //_____________________________________________________________________________
1489 void AliAnalysisTaskRhoVnModulation::FillDeltaPtHistograms(Double_t psi2, Double_t psi3) const
1491 // fill delta pt histograms
1492 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1494 AliEmcalJet* leadingJet(GetJetContainer()->GetLeadingJet());
1495 if(!leadingJet && fDebug > 0) printf(" > failed to retrieve leading jet ! < \n");
1496 const Float_t areaRC = fRandomConeRadius*fRandomConeRadius*TMath::Pi();
1497 // we're retrieved the leading jet, now get a random cone
1498 for(i = 0; i < fMaxCones; i++) {
1499 Float_t pt(0), eta(0), phi(0);
1500 // get a random cone without constraints on leading jet position
1501 CalculateRandomCone(pt, eta, phi, 0x0);
1503 if(fFillQAHistograms) fHistRCPhiEta[fInCentralitySelection]->Fill(phi, eta);
1504 fHistRhoVsRCPt[fInCentralitySelection]->Fill(pt, fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal())*areaRC);
1505 fHistRCPt[fInCentralitySelection]->Fill(pt);
1506 fHistDeltaPtDeltaPhi2[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt - areaRC*fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal()));
1507 fHistDeltaPtDeltaPhi3[fInCentralitySelection]->Fill(PhaseShift(phi-psi3, 3.), pt - areaRC*fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal()));
1509 // get a random cone excluding leading jet area
1510 CalculateRandomCone(pt, eta, phi, leadingJet);
1512 if(fFillQAHistograms) fHistRCPhiEtaExLJ[fInCentralitySelection]->Fill(phi, eta);
1513 fHistRhoVsRCPtExLJ[fInCentralitySelection]->Fill(pt, fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal())*areaRC);
1514 fHistRCPtExLJ[fInCentralitySelection]->Fill(pt);
1515 fHistDeltaPtDeltaPhi2ExLJ[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt - areaRC*fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal()));
1516 fHistDeltaPtDeltaPhi3ExLJ[fInCentralitySelection]->Fill(PhaseShift(phi-psi3, 3.), pt - areaRC*fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal()));
1520 //_____________________________________________________________________________
1521 void AliAnalysisTaskRhoVnModulation::FillJetHistograms(Double_t psi2, Double_t psi3)
1523 // fill jet histograms
1524 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1525 Int_t iJets(fJets->GetEntriesFast());
1526 for(Int_t i(0); i < iJets; i++) {
1527 AliEmcalJet* jet = static_cast<AliEmcalJet*>(fJets->At(i));
1528 if(PassesCuts(jet)) {
1529 Double_t pt(jet->Pt()), area(jet->Area()), eta(jet->Eta()), phi(jet->Phi());
1530 Double_t rho(fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal()));
1531 fHistJetPtRaw[fInCentralitySelection]->Fill(pt);
1532 fHistJetPt[fInCentralitySelection]->Fill(pt-area*rho);
1533 if(fFillQAHistograms) fHistJetEtaPhi[fInCentralitySelection]->Fill(eta, phi);
1534 fHistJetPtArea[fInCentralitySelection]->Fill(pt-area*rho, area);
1535 fHistJetPsi2Pt[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt-area*rho);
1536 fHistJetPsi3Pt[fInCentralitySelection]->Fill(PhaseShift(phi-psi3, 3.), pt-area*rho);
1537 fHistJetPtConstituents[fInCentralitySelection]->Fill(pt-area*rho, jet->Nch());
1538 fHistJetEtaRho[fInCentralitySelection]->Fill(eta, pt/area);
1539 if(fSubtractJetPt) jet->SetPtSub(pt-area*rho); // if requested, save the subtracted jet pt
1540 } else if(fSubtractJetPt) jet->SetPtSub(-999.);
1543 //_____________________________________________________________________________
1544 void AliAnalysisTaskRhoVnModulation::FillQAHistograms(AliVTrack* vtrack) const
1546 // fill qa histograms for pico tracks
1548 AliPicoTrack* track = static_cast<AliPicoTrack*>(vtrack);
1549 fHistRunnumbersPhi->Fill(fMappedRunNumber, track->Phi());
1550 fHistRunnumbersEta->Fill(fMappedRunNumber, track->Eta());
1551 Int_t type((int)(track->GetTrackType()));
1554 fHistPicoCat1[fInCentralitySelection]->Fill(track->Eta(), track->Phi());
1557 fHistPicoCat2[fInCentralitySelection]->Fill(track->Eta(), track->Phi());
1560 fHistPicoCat3[fInCentralitySelection]->Fill(track->Eta(), track->Phi());
1565 //_____________________________________________________________________________
1566 void AliAnalysisTaskRhoVnModulation::FillQAHistograms(AliVEvent* vevent)
1568 // fill qa histograms for events
1570 fHistVertexz->Fill(vevent->GetPrimaryVertex()->GetZ());
1571 fHistCentrality->Fill(fCent);
1572 Int_t runNumber(InputEvent()->GetRunNumber());
1573 Int_t runs[] = {167813, 167988, 168066, 168068, 168069, 168076, 168104, 168212, 168311, 168322, 168325, 168341, 168361, 168362, 168458, 168460, 168461, 168992, 169091, 169094, 169138, 169143, 169167, 169417, 169835, 169837, 169838, 169846, 169855, 169858, 169859, 169923, 169956, 170027, 170036, 170081, 169975, 169981, 170038, 170040, 170083, 170084, 170085, 170088, 170089, 170091, 170152, 170155, 170159, 170163, 170193, 170195, 170203, 170204, 170205, 170228, 170230, 170264, 170268, 170269, 170270, 170306, 170308, 170309};
1574 for(fMappedRunNumber = 0; fMappedRunNumber < 64; fMappedRunNumber++) {
1575 if(runs[fMappedRunNumber]==runNumber) break;
1578 //_____________________________________________________________________________
1579 void AliAnalysisTaskRhoVnModulation::FillAnalysisSummaryHistogram() const
1581 // fill the analysis summary histrogram, saves all relevant analysis settigns
1582 if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1583 fHistAnalysisSummary->GetXaxis()->SetBinLabel(2, "fJetRadius");
1584 fHistAnalysisSummary->SetBinContent(2, GetJetContainer()->GetJetRadius());
1585 fHistAnalysisSummary->GetXaxis()->SetBinLabel(3, "fJetEtaMin");
1586 fHistAnalysisSummary->SetBinContent(3, GetJetContainer()->GetJetEtaMin());
1587 fHistAnalysisSummary->GetXaxis()->SetBinLabel(4, "fJetEtaMax");
1588 fHistAnalysisSummary->SetBinContent(4, GetJetContainer()->GetJetEtaMax());
1589 fHistAnalysisSummary->GetXaxis()->SetBinLabel(5, "fJetPhiMin");
1590 fHistAnalysisSummary->SetBinContent(5, GetJetContainer()->GetJetPhiMin());
1591 fHistAnalysisSummary->GetXaxis()->SetBinLabel(6, "fJetPhiMax");
1592 fHistAnalysisSummary->SetBinContent(6, GetJetContainer()->GetJetPhiMin());
1593 fHistAnalysisSummary->GetXaxis()->SetBinLabel(16, "fForceBeamType");
1594 fHistAnalysisSummary->SetBinContent(16, fForceBeamType);
1595 fHistAnalysisSummary->GetXaxis()->SetBinLabel(17, "fMinCent");
1596 fHistAnalysisSummary->SetBinContent(17, fMinCent);
1597 fHistAnalysisSummary->GetXaxis()->SetBinLabel(18, "fMaxCent");
1598 fHistAnalysisSummary->SetBinContent(18, fMaxCent);
1599 fHistAnalysisSummary->GetXaxis()->SetBinLabel(19, "fMinVz");
1600 fHistAnalysisSummary->SetBinContent(19, fMinVz);
1601 fHistAnalysisSummary->GetXaxis()->SetBinLabel(20, "fMaxVz");
1602 fHistAnalysisSummary->SetBinContent(20, fMaxVz);
1603 fHistAnalysisSummary->GetXaxis()->SetBinLabel(21, "fOffTrigger");
1604 fHistAnalysisSummary->SetBinContent(21, fOffTrigger);
1605 fHistAnalysisSummary->GetXaxis()->SetBinLabel(33, "fRandomConeRadius");
1606 fHistAnalysisSummary->SetBinContent(33, fRandomConeRadius);
1607 fHistAnalysisSummary->GetXaxis()->SetBinLabel(34, "fitModulationType");
1608 fHistAnalysisSummary->SetBinContent(34, (int)fFitModulationType);
1609 fHistAnalysisSummary->GetXaxis()->SetBinLabel(35, "runModeType");
1610 fHistAnalysisSummary->SetBinContent(35, (int)fRunModeType);
1611 fHistAnalysisSummary->GetXaxis()->SetBinLabel(36, "data type");
1612 fHistAnalysisSummary->SetBinContent(36, (int)fDataType);
1613 fHistAnalysisSummary->GetXaxis()->SetBinLabel(37, "iterator");
1614 fHistAnalysisSummary->SetBinContent(37, 1.);
1615 fHistAnalysisSummary->GetXaxis()->SetBinLabel(38, "fMinPvalue");
1616 fHistAnalysisSummary->SetBinContent(38, fMinPvalue);
1617 fHistAnalysisSummary->GetXaxis()->SetBinLabel(39, "fMaxPvalue");
1618 fHistAnalysisSummary->SetBinContent(39, fMaxPvalue);
1619 fHistAnalysisSummary->GetXaxis()->SetBinLabel(40, "fExcludeLeadingJetsFromFit");
1620 fHistAnalysisSummary->SetBinContent(40, fExcludeLeadingJetsFromFit);
1621 fHistAnalysisSummary->GetXaxis()->SetBinLabel(41, "fRebinSwapHistoOnTheFly");
1622 fHistAnalysisSummary->SetBinContent(41, (int)fRebinSwapHistoOnTheFly);
1623 fHistAnalysisSummary->GetXaxis()->SetBinLabel(42, "fUsePtWeight");
1624 fHistAnalysisSummary->SetBinContent(42, (int)fUsePtWeight);
1625 fHistAnalysisSummary->GetXaxis()->SetBinLabel(43, "fMinLeadingHadronPt");
1626 fHistAnalysisSummary->SetBinContent(43, fMinLeadingHadronPt);
1627 fHistAnalysisSummary->GetXaxis()->SetBinLabel(44, "fExplicitOutlierCut");
1628 fHistAnalysisSummary->SetBinContent(44, fExplicitOutlierCut);
1629 fHistAnalysisSummary->GetXaxis()->SetBinLabel(45, "fLocalJetMinEta");
1630 fHistAnalysisSummary->SetBinContent(45,fLocalJetMinEta );
1631 fHistAnalysisSummary->GetXaxis()->SetBinLabel(46, "fLocalJetMaxEta");
1632 fHistAnalysisSummary->SetBinContent(46, fLocalJetMaxEta);
1633 fHistAnalysisSummary->GetXaxis()->SetBinLabel(47, "fLocalJetMinPhi");
1634 fHistAnalysisSummary->SetBinContent(47, fLocalJetMinPhi);
1635 fHistAnalysisSummary->GetXaxis()->SetBinLabel(48, "fLocalJetMaxPhi");
1636 fHistAnalysisSummary->SetBinContent(48, fLocalJetMaxPhi);
1637 fHistAnalysisSummary->GetXaxis()->SetBinLabel(49, "fSoftTrackMinPt");
1638 fHistAnalysisSummary->SetBinContent(49, fSoftTrackMinPt);
1639 fHistAnalysisSummary->GetXaxis()->SetBinLabel(50, "fSoftTrackMaxPt");
1640 fHistAnalysisSummary->SetBinContent(50, fSoftTrackMaxPt);
1641 fHistAnalysisSummary->GetXaxis()->SetBinLabel(51, "fMaxCones");
1642 fHistAnalysisSummary->SetBinContent(51, fMaxCones);
1643 fHistAnalysisSummary->GetXaxis()->SetBinLabel(52, "fUseScaledRho");
1644 fHistAnalysisSummary->SetBinContent(52, fUseScaledRho);
1646 //_____________________________________________________________________________
1647 void AliAnalysisTaskRhoVnModulation::Terminate(Option_t *)
1650 switch (fRunModeType) {
1652 printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
1653 if(fFillQAHistograms) {
1654 Int_t runs[] = {167813, 167988, 168066, 168068, 168069, 168076, 168104, 168212, 168311, 168322, 168325, 168341, 168361, 168362, 168458, 168460, 168461, 168992, 169091, 169094, 169138, 169143, 169167, 169417, 169835, 169837, 169838, 169846, 169855, 169858, 169859, 169923, 169956, 170027, 170036, 170081, 169975, 169981, 170038, 170040, 170083, 170084, 170085, 170088, 170089, 170091, 170152, 170155, 170159, 170163, 170193, 170195, 170203, 170204, 170205, 170228, 170230, 170264, 170268, 170269, 170270, 170306, 170308, 170309};
1655 for(Int_t i(0); i < 64; i++) {
1656 fHistRunnumbersPhi->GetXaxis()->SetBinLabel(i+1, Form("%i", runs[i]));
1657 fHistRunnumbersEta->GetXaxis()->SetBinLabel(i+1, Form("%i", runs[i]));
1659 fHistRunnumbersPhi->GetXaxis()->SetBinLabel(65, "undetermined");
1660 fHistRunnumbersEta->GetXaxis()->SetBinLabel(65, "undetermined");
1662 AliAnalysisTaskRhoVnModulation::Dump();
1663 for(Int_t i(0); i < fHistAnalysisSummary->GetXaxis()->GetNbins(); i++) printf( " > flag: %s \t content %.2f \n", fHistAnalysisSummary->GetXaxis()->GetBinLabel(1+i), fHistAnalysisSummary->GetBinContent(1+i));
1668 //_____________________________________________________________________________
1669 void AliAnalysisTaskRhoVnModulation::SetModulationFit(TF1* fit)
1671 // set modulation fit
1672 if (fFitModulation) delete fFitModulation;
1673 fFitModulation = fit;
1675 //_____________________________________________________________________________
1676 void AliAnalysisTaskRhoVnModulation::SetUseControlFit(Bool_t c)
1679 if (fFitControl) delete fFitControl;
1681 fFitControl = new TF1("controlFit", "pol0", 0, TMath::TwoPi());
1682 } else fFitControl = 0x0;
1684 //_____________________________________________________________________________
1685 TH1F* AliAnalysisTaskRhoVnModulation::GetResolutionFromOuptutFile(detectorType det, Int_t h, TArrayD* cen)
1687 // INTERFACE METHOD FOR OUTPUTFILE
1688 // get the detector resolution, user has ownership of the returned histogram
1690 printf(" > Please add fOutputList first < \n");
1694 (cen) ? r = new TH1F("R", "R", cen->GetSize()-1, cen->GetArray()) : r = new TH1F("R", "R", 10, 0, 10);
1695 if(!cen) r->GetXaxis()->SetTitle("number of centrality bin");
1696 r->GetYaxis()->SetTitle(Form("Resolution #Psi_{%i}", h));
1697 for(Int_t i(0); i < 10; i++) {
1698 TProfile* temp((TProfile*)fOutputList->FindObject(Form("fProfV%iResolution_%i", h, i)));
1700 Double_t a(temp->GetBinContent(3)), b(temp->GetBinContent(5)), c(temp->GetBinContent(7));
1701 Double_t d(temp->GetBinContent(9)), e(temp->GetBinContent(10)), f(temp->GetBinContent(11));
1702 Double_t _a(temp->GetBinError(3)), _b(temp->GetBinError(5)), _c(temp->GetBinError(7));
1703 Double_t _d(temp->GetBinError(9)), _e(temp->GetBinError(10)), _f(temp->GetBinError(11));
1704 if(a <= 0 || b <= 0 || c <= 0 || d <= 0 || e <= 0 || f <= 0) continue;
1707 r->SetBinContent(1+i, TMath::Sqrt((a*b)/c));
1708 if(i==0) r->SetNameTitle("VZEROA resolution", "VZEROA resolution");
1709 r->SetBinError(1+i, TMath::Sqrt(_a*_a+_b*_b+_c*_c));
1712 r->SetBinContent(1+i, TMath::Sqrt((a*c)/b));
1713 if(i==0) r->SetNameTitle("VZEROC resolution", "VZEROC resolution");
1714 r->SetBinError(1+i, TMath::Sqrt(_a*_a+_b*_b+_c*_c));
1717 r->SetBinContent(1+i, TMath::Sqrt((b*c)/a));
1718 if(i==0) r->SetNameTitle("TPC resolution", "TPC resolution");
1719 r->SetBinError(1+i, TMath::Sqrt(_a*_a+_b*_b+_c*_c));
1722 r->SetBinContent(1+i, TMath::Sqrt((d*e)/f));
1723 if(i==0) r->SetNameTitle("VZEROComb resolution", "VZEROComb resolution");
1724 r->SetBinError(1+i, TMath::Sqrt(_d*_d+_e*_e+_f*_f));
1731 //_____________________________________________________________________________
1732 TH1F* AliAnalysisTaskRhoVnModulation::CorrectForResolutionDiff(TH1F* v, detectorType det, TArrayD* cen, Int_t c, Int_t h)
1734 // INTERFACE METHOD FOR OUTPUT FILE
1735 // correct the supplied differential vn histogram v for detector resolution
1736 TH1F* r(GetResolutionFromOuptutFile(det, h, cen));
1738 printf(" > Couldn't find resolution < \n");
1741 Double_t res(1./r->GetBinContent(1+r->FindBin(c)));
1742 TF1* line = new TF1("line", "pol0", 0, 200);
1743 line->SetParameter(0, res);
1747 //_____________________________________________________________________________
1748 TH1F* AliAnalysisTaskRhoVnModulation::CorrectForResolutionInt(TH1F* v, detectorType det, TArrayD* cen, Int_t h)
1750 // INTERFACE METHOD FOR OUTPUT FILE
1751 // correct the supplied intetrated vn histogram v for detector resolution
1752 // integrated vn must have the same centrality binning as the resolotion correction
1753 TH1F* r(GetResolutionFromOuptutFile(det, h, cen));
1757 //_____________________________________________________________________________
1758 TH1F* AliAnalysisTaskRhoVnModulation::GetDifferentialQC(TProfile* refCumulants, TProfile* diffCumlants, TArrayD* ptBins, Int_t h)
1760 // get differential QC
1761 Double_t r(refCumulants->GetBinContent(h-1)); // v2 reference flow
1762 if(r > 0) r = TMath::Sqrt(r);
1763 TH1F* qc = new TH1F(Form("QC2v%i", h), Form("QC2v%i", h), ptBins->GetSize()-1, ptBins->GetArray());
1764 Double_t a(0), b(0), c(0); // dummy variables
1765 for(Int_t i(0); i < ptBins->GetSize(); i++) {
1767 a = diffCumlants->GetBinContent(1+i);
1768 b = diffCumlants->GetBinError(1+i);
1770 qc->SetBinContent(1+i, c);
1771 (a <= 0 || b <= 0) ? qc->SetBinError(1+i, b) : qc->SetBinError(1+i, TMath::Sqrt(c*c*b*b/(a*a)));
1777 //_____________________________________________________________________________