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 //_________________________________________________________________________
18 // Class that contains the algorithm for the reconstruction of jet, cone around leading particle
19 // The seed is a backward particle (direct photon)
20 // 1) Take the trigger particle stored in AliAODPWG4ParticleCorrelation,
21 // 2) Search for the highest pt leading particle opposite to the photon within a phi, pt window
22 // 3) Take all particles around leading in a cone R with pt larger than threshold and construct the jet
24 // Class created from old AliPHOSGammaJet
25 // (see AliRoot versions previous Release 4-09)
27 //*-- Author: Gustavo Conesa (LNF-INFN)
28 //////////////////////////////////////////////////////////////////////////////
31 // --- ROOT system ---
33 #include "TClonesArray.h"
35 //#include "Riostream.h"
37 //---- Analysis system ----
38 #include "AliVTrack.h"
39 #include "AliVCluster.h"
40 #include "AliCaloTrackReader.h"
41 #include "AliNeutralMesonSelection.h"
42 #include "AliAnaParticleJetLeadingConeCorrelation.h"
43 #include "AliCaloPID.h"
44 #include "AliAODPWG4ParticleCorrelation.h"
45 #include "AliFiducialCut.h"
47 ClassImp(AliAnaParticleJetLeadingConeCorrelation)
50 //____________________________________________________________________________
51 AliAnaParticleJetLeadingConeCorrelation::AliAnaParticleJetLeadingConeCorrelation() :
52 AliAnaPartCorrBaseClass(), fJetsOnlyInCTS(kFALSE), fPbPb(kFALSE),
53 fSeveralConeAndPtCuts(0), fReMakeJet(0),
54 fDeltaPhiMaxCut(0.), fDeltaPhiMinCut(0.),
55 fLeadingRatioMaxCut(0.), fLeadingRatioMinCut(0.),
56 fJetCTSRatioMaxCut(0.), fJetCTSRatioMinCut(0.),
57 fJetRatioMaxCut(0.), fJetRatioMinCut(0.),
58 fJetNCone(0),fJetNPt(0), fJetCone(0),
59 fJetPtThreshold(0),fJetPtThresPbPb(0),
60 fPtTriggerSelectionCut(0.0), fSelect(0),
65 fhChargedLeadingPt(0),fhChargedLeadingPhi(0),fhChargedLeadingEta(0),
66 fhChargedLeadingDeltaPt(0),fhChargedLeadingDeltaPhi(0),fhChargedLeadingDeltaEta(0),
67 fhChargedLeadingRatioPt(0),
68 fhNeutralLeadingPt(0),fhNeutralLeadingPhi(0),fhNeutralLeadingEta(0),
69 fhNeutralLeadingDeltaPt(0),fhNeutralLeadingDeltaPhi(0),fhNeutralLeadingDeltaEta(0),
70 fhNeutralLeadingRatioPt(0),fhChargedLeadingXi(0), fhNeutralLeadingXi(0),
71 fhChargedLeadingDeltaPhiRatioPt30(0), fhNeutralLeadingDeltaPhiRatioPt30(0),
72 fhChargedLeadingDeltaPhiRatioPt50(0), fhNeutralLeadingDeltaPhiRatioPt50(0),
74 fhJetPt(0),fhJetRatioPt(0),fhJetDeltaPhi(0), fhJetDeltaEta(0),
75 fhJetLeadingRatioPt(0),fhJetLeadingDeltaPhi(0),fhJetLeadingDeltaEta(0),
76 fhJetFFz(0),fhJetFFxi(0),fhJetFFpt(0),fhJetNTracksInCone(0),
77 fhBkgPt(0),fhBkgRatioPt(0),fhBkgDeltaPhi(0), fhBkgDeltaEta(0),
78 fhBkgLeadingRatioPt(0),fhBkgLeadingDeltaPhi(0),fhBkgLeadingDeltaEta(0),
79 fhBkgFFz(0),fhBkgFFxi(0),fhBkgFFpt(0),fhBkgNTracksInCone(0),
80 //Several cones and thres histograms
81 fhJetPts(),fhJetRatioPts(),fhJetDeltaPhis(), fhJetDeltaEtas(),
82 fhJetLeadingRatioPts(),fhJetLeadingDeltaPhis(),fhJetLeadingDeltaEtas(),
83 fhJetFFzs(),fhJetFFxis(),fhJetFFpts(),fhJetNTracksInCones(),
84 fhBkgPts(),fhBkgRatioPts(),fhBkgDeltaPhis(), fhBkgDeltaEtas(),
85 fhBkgLeadingRatioPts(),fhBkgLeadingDeltaPhis(),fhBkgLeadingDeltaEtas(),
86 fhBkgFFzs(),fhBkgFFxis(),fhBkgFFpts(),fhBkgNTracksInCones()
90 //Initialize parameters
92 for(Int_t i = 0; i<6; i++){
102 fJetSigma1[i] = 0.0 ;
103 fJetSigma2[i] = 0.0 ;
107 //Several cones and thres histograms
108 for(Int_t i = 0; i<5; i++){
110 fJetNameCones[i] = "" ;
111 fJetPtThres[i] = 0.0 ;
112 fJetNamePtThres[i] = "" ;
113 for(Int_t j = 0; j<5; j++){
115 fhJetRatioPts[i][j]=0 ;
116 fhJetDeltaPhis[i][j]=0 ;
117 fhJetDeltaEtas[i][j]=0 ;
118 fhJetLeadingRatioPts[i][j]=0 ;
119 fhJetLeadingDeltaPhis[i][j]=0 ;
120 fhJetLeadingDeltaEtas[i][j]=0 ;
124 fhJetNTracksInCones[i][j]=0 ;
126 fhBkgRatioPts[i][j]=0 ;
127 fhBkgDeltaPhis[i][j]=0 ;
128 fhBkgDeltaEtas[i][j]=0 ;
129 fhBkgLeadingRatioPts[i][j]=0 ;
130 fhBkgLeadingDeltaPhis[i][j]=0 ;
131 fhBkgLeadingDeltaEtas[i][j]=0 ;
135 fhBkgNTracksInCones[i][j]=0 ;
143 //____________________________________________________________________________
144 AliAnaParticleJetLeadingConeCorrelation::AliAnaParticleJetLeadingConeCorrelation(const AliAnaParticleJetLeadingConeCorrelation & jetlc) :
145 AliAnaPartCorrBaseClass(jetlc), fJetsOnlyInCTS(jetlc.fJetsOnlyInCTS), fPbPb(jetlc.fPbPb),
146 fSeveralConeAndPtCuts(jetlc.fSeveralConeAndPtCuts), fReMakeJet(jetlc. fReMakeJet),
147 fDeltaPhiMaxCut(jetlc. fDeltaPhiMaxCut), fDeltaPhiMinCut(jetlc.fDeltaPhiMinCut),
148 fLeadingRatioMaxCut(jetlc.fLeadingRatioMaxCut), fLeadingRatioMinCut(jetlc.fLeadingRatioMinCut),
149 fJetCTSRatioMaxCut(jetlc.fJetCTSRatioMaxCut),
150 fJetCTSRatioMinCut(jetlc.fJetCTSRatioMinCut), fJetRatioMaxCut(jetlc.fJetRatioMaxCut),
151 fJetRatioMinCut(jetlc.fJetRatioMinCut), fJetNCone(jetlc.fJetNCone),
152 fJetNPt(jetlc.fJetNPt), fJetCone(jetlc.fJetCone),
153 fJetPtThreshold(jetlc.fJetPtThreshold),fJetPtThresPbPb(jetlc.fJetPtThresPbPb),
154 fPtTriggerSelectionCut(jetlc.fPtTriggerSelectionCut), fSelect(jetlc.fSelect),
155 fSelectIsolated(jetlc.fSelectIsolated),
157 fOutCont(jetlc. fOutCont),
159 fhChargedLeadingPt(jetlc.fhChargedLeadingPt), fhChargedLeadingPhi(jetlc.fhChargedLeadingPhi),
160 fhChargedLeadingEta(jetlc.fhChargedLeadingEta), fhChargedLeadingDeltaPt(jetlc.fhChargedLeadingDeltaPt),
161 fhChargedLeadingDeltaPhi(jetlc.fhChargedLeadingDeltaPhi),fhChargedLeadingDeltaEta(jetlc.fhChargedLeadingDeltaEta),
162 fhChargedLeadingRatioPt(jetlc.fhChargedLeadingRatioPt),
163 fhNeutralLeadingPt(jetlc.fhNeutralLeadingPt),fhNeutralLeadingPhi(jetlc.fhNeutralLeadingPhi),
164 fhNeutralLeadingEta(jetlc.fhNeutralLeadingEta), fhNeutralLeadingDeltaPt(jetlc.fhNeutralLeadingDeltaPt),
165 fhNeutralLeadingDeltaPhi(jetlc.fhNeutralLeadingDeltaPhi),fhNeutralLeadingDeltaEta(jetlc.fhNeutralLeadingDeltaEta),
166 fhNeutralLeadingRatioPt(jetlc.fhNeutralLeadingRatioPt),
167 fhChargedLeadingXi(jetlc.fhChargedLeadingXi), fhNeutralLeadingXi(jetlc.fhNeutralLeadingXi),
168 fhChargedLeadingDeltaPhiRatioPt30(jetlc.fhChargedLeadingDeltaPhiRatioPt30), fhNeutralLeadingDeltaPhiRatioPt30(jetlc.fhNeutralLeadingDeltaPhiRatioPt30),
169 fhChargedLeadingDeltaPhiRatioPt50(jetlc.fhChargedLeadingDeltaPhiRatioPt50), fhNeutralLeadingDeltaPhiRatioPt50(jetlc.fhNeutralLeadingDeltaPhiRatioPt50),
171 fhJetPt(jetlc.fhJetPt),fhJetRatioPt(jetlc.fhJetRatioPt),fhJetDeltaPhi(jetlc.fhJetDeltaPhi),
172 fhJetDeltaEta(jetlc.fhJetDeltaEta), fhJetLeadingRatioPt(jetlc.fhJetLeadingRatioPt),
173 fhJetLeadingDeltaPhi(jetlc.fhJetLeadingDeltaPhi),fhJetLeadingDeltaEta(jetlc.fhJetLeadingDeltaEta),
174 fhJetFFz(jetlc.fhJetFFz),fhJetFFxi(jetlc.fhJetFFxi),fhJetFFpt(jetlc.fhJetFFpt),
175 fhJetNTracksInCone(jetlc.fhJetNTracksInCone),
176 fhBkgPt(jetlc.fhBkgPt),fhBkgRatioPt(jetlc.fhBkgRatioPt),fhBkgDeltaPhi(jetlc.fhBkgDeltaPhi),
177 fhBkgDeltaEta(jetlc.fhBkgDeltaEta), fhBkgLeadingRatioPt(jetlc.fhBkgLeadingRatioPt),
178 fhBkgLeadingDeltaPhi(jetlc.fhBkgLeadingDeltaPhi),fhBkgLeadingDeltaEta(jetlc.fhBkgLeadingDeltaEta),
179 fhBkgFFz(jetlc.fhBkgFFz),fhBkgFFxi(jetlc.fhBkgFFxi),fhBkgFFpt(jetlc.fhBkgFFpt),
180 fhBkgNTracksInCone(jetlc.fhBkgNTracksInCone),
181 //Several cones and thres histograms
182 fhJetPts(),fhJetRatioPts(),fhJetDeltaPhis(), fhJetDeltaEtas(),
183 fhJetLeadingRatioPts(),fhJetLeadingDeltaPhis(),fhJetLeadingDeltaEtas(),
184 fhJetFFzs(),fhJetFFxis(),fhJetFFpts(),fhJetNTracksInCones(),
185 fhBkgPts(),fhBkgRatioPts(),fhBkgDeltaPhis(), fhBkgDeltaEtas(),
186 fhBkgLeadingRatioPts(),fhBkgLeadingDeltaPhis(),fhBkgLeadingDeltaEtas(),
187 fhBkgFFzs(),fhBkgFFxis(),fhBkgFFpts(),fhBkgNTracksInCones()
191 for(Int_t i = 0; i<6; i++){
192 fJetXMin1[i] = jetlc.fJetXMin1[i] ;
193 fJetXMin2[i] = jetlc.fJetXMin2[i] ;
194 fJetXMax1[i] = jetlc.fJetXMax1[i] ;
195 fJetXMax2[i] = jetlc.fJetXMax2[i] ;
196 fBkgMean[i] = jetlc.fBkgMean[i] ;
197 fBkgRMS[i] = jetlc.fBkgRMS[i] ;
199 fJetE1[i] = jetlc.fJetE1[i] ;
200 fJetE2[i] = jetlc.fJetE2[i] ;
201 fJetSigma1[i] = jetlc.fJetSigma1[i] ;
202 fJetSigma2[i] = jetlc.fJetSigma2[i] ;
206 //Several cones and thres histograms
207 for(Int_t i = 0; i<5; i++){
208 fJetCones[i] = jetlc.fJetCones[i] ;
209 fJetNameCones[i] = jetlc.fJetNameCones[i] ;
210 fJetPtThres[i] = jetlc.fJetPtThres[i] ;
211 fJetNamePtThres[i] = jetlc.fJetNamePtThres[i] ;
212 for(Int_t j = 0; j<5; j++){
213 fhJetPts[i][j] = jetlc.fhJetPts[i][j] ;
214 fhJetRatioPts[i][j] = jetlc.fhJetRatioPts[i][j] ;
215 fhJetDeltaPhis[i][j] = jetlc.fhJetDeltaPhis[i][j] ;
216 fhJetDeltaEtas[i][j] = jetlc.fhJetDeltaEtas[i][j] ;
217 fhJetLeadingRatioPts[i][j] = jetlc.fhJetLeadingRatioPts[i][j] ;
218 fhJetLeadingDeltaPhis[i][j] = jetlc.fhJetLeadingDeltaPhis[i][j] ;
219 fhJetLeadingDeltaEtas[i][j] = jetlc.fhJetLeadingDeltaEtas[i][j] ;
220 fhJetFFzs[i][j] = jetlc.fhJetFFzs[i][j] ;
221 fhJetFFxis[i][j] = jetlc.fhJetFFxis[i][j] ;
222 fhJetFFpts[i][j] = jetlc.fhJetFFpts[i][j] ;
223 fhJetNTracksInCones[i][j] = fhJetNTracksInCones[i][j] ;
224 fhBkgPts[i][j] = jetlc.fhBkgPts[i][j] ;
225 fhBkgRatioPts[i][j] = jetlc.fhBkgRatioPts[i][j] ;
226 fhBkgDeltaPhis[i][j] = jetlc.fhBkgDeltaPhis[i][j] ;
227 fhBkgDeltaEtas[i][j] = jetlc.fhBkgDeltaEtas[i][j] ;
228 fhBkgLeadingRatioPts[i][j] = jetlc.fhBkgLeadingRatioPts[i][j] ;
229 fhBkgLeadingDeltaPhis[i][j] = jetlc.fhBkgLeadingDeltaPhis[i][j] ;
230 fhBkgLeadingDeltaEtas[i][j] = jetlc.fhBkgLeadingDeltaEtas[i][j] ;
231 fhBkgFFzs[i][j] = jetlc.fhBkgFFzs[i][j] ;
232 fhBkgFFxis[i][j] = jetlc.fhBkgFFxis[i][j] ;
233 fhBkgFFpts[i][j] = jetlc.fhBkgFFpts[i][j] ;
234 fhBkgNTracksInCones[i][j] = jetlc.fhBkgNTracksInCones[i][j] ;
239 //_________________________________________________________________________
240 AliAnaParticleJetLeadingConeCorrelation & AliAnaParticleJetLeadingConeCorrelation::operator = (const AliAnaParticleJetLeadingConeCorrelation & jetlc)
242 // assignment operator
244 if(this == &jetlc)return *this;
245 ((AliAnaPartCorrBaseClass *)this)->operator=(jetlc);
247 fSeveralConeAndPtCuts = jetlc.fSeveralConeAndPtCuts ;
248 fPbPb = jetlc.fPbPb ;
249 fReMakeJet = jetlc.fReMakeJet ;
250 fJetsOnlyInCTS = jetlc.fJetsOnlyInCTS;
252 fDeltaPhiMaxCut = jetlc.fDeltaPhiMaxCut ;
253 fDeltaPhiMinCut = jetlc.fDeltaPhiMinCut ;
254 fLeadingRatioMaxCut = jetlc.fLeadingRatioMaxCut ;
255 fLeadingRatioMinCut = jetlc.fLeadingRatioMinCut ;
257 fJetCTSRatioMaxCut = jetlc.fJetCTSRatioMaxCut ;
258 fJetCTSRatioMinCut = jetlc.fJetCTSRatioMinCut ;
259 fJetRatioMaxCut = jetlc.fJetRatioMaxCut ;
260 fJetRatioMinCut = jetlc.fJetRatioMinCut ;
262 fJetNCone = jetlc.fJetNCone ;
263 fJetNPt = jetlc.fJetNPt ; fJetCone = jetlc.fJetCone ;
264 fJetPtThreshold = jetlc.fJetPtThreshold ;
265 fJetPtThresPbPb = jetlc.fJetPtThresPbPb ;
266 fPtTriggerSelectionCut = jetlc.fPtTriggerSelectionCut ;
267 fSelect = jetlc.fSelect ;
268 fSelectIsolated = jetlc.fSelectIsolated ;
270 for(Int_t i = 0; i<6; i++){
271 fJetXMin1[i] = jetlc.fJetXMin1[i] ;
272 fJetXMin2[i] = jetlc.fJetXMin2[i] ;
273 fJetXMax1[i] = jetlc.fJetXMax1[i] ;
274 fJetXMax2[i] = jetlc.fJetXMax2[i] ;
275 fBkgMean[i] = jetlc.fBkgMean[i] ;
276 fBkgRMS[i] = jetlc.fBkgRMS[i] ;
278 fJetE1[i] = jetlc.fJetE1[i] ;
279 fJetE2[i] = jetlc.fJetE2[i] ;
280 fJetSigma1[i] = jetlc.fJetSigma1[i] ;
281 fJetSigma2[i] = jetlc.fJetSigma2[i] ;
286 fOutCont = jetlc. fOutCont ;
287 fhChargedLeadingPt = jetlc.fhChargedLeadingPt; fhChargedLeadingPhi = jetlc.fhChargedLeadingPhi;
288 fhChargedLeadingEta = jetlc.fhChargedLeadingEta; fhChargedLeadingDeltaPt = jetlc.fhChargedLeadingDeltaPt;
289 fhChargedLeadingDeltaPhi = jetlc.fhChargedLeadingDeltaPhi;fhChargedLeadingDeltaEta = jetlc.fhChargedLeadingDeltaEta;
290 fhChargedLeadingRatioPt = jetlc.fhChargedLeadingRatioPt;
291 fhNeutralLeadingPt = jetlc.fhNeutralLeadingPt;fhNeutralLeadingPhi = jetlc.fhNeutralLeadingPhi;
292 fhNeutralLeadingEta = jetlc.fhNeutralLeadingEta; fhNeutralLeadingDeltaPt = jetlc.fhNeutralLeadingDeltaPt;
293 fhNeutralLeadingDeltaPhi = jetlc.fhNeutralLeadingDeltaPhi;fhNeutralLeadingDeltaEta = jetlc.fhNeutralLeadingDeltaEta;
294 fhNeutralLeadingRatioPt = jetlc.fhNeutralLeadingRatioPt;
295 fhChargedLeadingXi = jetlc.fhChargedLeadingXi;
296 fhNeutralLeadingXi = jetlc.fhNeutralLeadingXi;
298 fhChargedLeadingDeltaPhiRatioPt30 = jetlc.fhChargedLeadingDeltaPhiRatioPt30;
299 fhNeutralLeadingDeltaPhiRatioPt30 = jetlc.fhNeutralLeadingDeltaPhiRatioPt30;
300 fhChargedLeadingDeltaPhiRatioPt50 = jetlc.fhChargedLeadingDeltaPhiRatioPt50;
301 fhNeutralLeadingDeltaPhiRatioPt50 = jetlc.fhNeutralLeadingDeltaPhiRatioPt50;
303 fhJetPt = jetlc.fhJetPt;fhJetRatioPt = jetlc.fhJetRatioPt;fhJetDeltaPhi = jetlc.fhJetDeltaPhi;
304 fhJetDeltaEta = jetlc.fhJetDeltaEta; fhJetLeadingRatioPt = jetlc.fhJetLeadingRatioPt;
305 fhJetLeadingDeltaPhi = jetlc.fhJetLeadingDeltaPhi;fhJetLeadingDeltaEta = jetlc.fhJetLeadingDeltaEta;
306 fhJetFFz = jetlc.fhJetFFz;fhJetFFxi = jetlc.fhJetFFxi;fhJetFFpt = jetlc.fhJetFFpt;
307 fhJetNTracksInCone = jetlc.fhJetNTracksInCone;
308 fhBkgPt = jetlc.fhBkgPt;fhBkgRatioPt = jetlc.fhBkgRatioPt;fhBkgDeltaPhi = jetlc.fhBkgDeltaPhi;
309 fhBkgDeltaEta = jetlc.fhBkgDeltaEta; fhBkgLeadingRatioPt = jetlc.fhBkgLeadingRatioPt;
310 fhBkgLeadingDeltaPhi = jetlc.fhBkgLeadingDeltaPhi;fhBkgLeadingDeltaEta = jetlc.fhBkgLeadingDeltaEta;
311 fhBkgFFz = jetlc.fhBkgFFz;fhBkgFFxi = jetlc.fhBkgFFxi;fhBkgFFpt = jetlc.fhBkgFFpt;
312 fhBkgNTracksInCone = jetlc.fhBkgNTracksInCone;
315 //Several cones and thres histograms
316 for(Int_t i = 0; i<5; i++){
317 fJetCones[i] = jetlc.fJetCones[i] ;
318 fJetNameCones[i] = jetlc.fJetNameCones[i] ;
319 fJetPtThres[i] = jetlc.fJetPtThres[i] ;
320 fJetNamePtThres[i] = jetlc.fJetNamePtThres[i] ;
322 for(Int_t j = 0; j<5; j++){
323 fhJetPts[i][j] = jetlc.fhJetPts[i][j] ;
324 fhJetRatioPts[i][j] = jetlc.fhJetRatioPts[i][j] ;
325 fhJetDeltaPhis[i][j] = jetlc.fhJetDeltaPhis[i][j] ;
326 fhJetDeltaEtas[i][j] = jetlc.fhJetDeltaEtas[i][j] ;
327 fhJetLeadingRatioPts[i][j] = jetlc.fhJetLeadingRatioPts[i][j] ;
328 fhJetLeadingDeltaPhis[i][j] = jetlc.fhJetLeadingDeltaPhis[i][j] ;
329 fhJetLeadingDeltaEtas[i][j] = jetlc.fhJetLeadingDeltaEtas[i][j] ;
330 fhJetFFzs[i][j] = jetlc.fhJetFFzs[i][j] ;
331 fhJetFFxis[i][j] = jetlc.fhJetFFxis[i][j] ;
332 fhJetFFpts[i][j] = jetlc.fhJetFFpts[i][j] ;
333 fhJetNTracksInCones[i][j] = fhJetNTracksInCones[i][j] ;
334 fhBkgPts[i][j] = jetlc.fhBkgPts[i][j] ;
335 fhBkgRatioPts[i][j] = jetlc.fhBkgRatioPts[i][j] ;
336 fhBkgDeltaPhis[i][j] = jetlc.fhBkgDeltaPhis[i][j] ;
337 fhBkgDeltaEtas[i][j] = jetlc.fhBkgDeltaEtas[i][j] ;
338 fhBkgLeadingRatioPts[i][j] = jetlc.fhBkgLeadingRatioPts[i][j] ;
339 fhBkgLeadingDeltaPhis[i][j] = jetlc.fhBkgLeadingDeltaPhis[i][j] ;
340 fhBkgLeadingDeltaEtas[i][j] = jetlc.fhBkgLeadingDeltaEtas[i][j] ;
341 fhBkgFFzs[i][j] = jetlc.fhBkgFFzs[i][j] ;
342 fhBkgFFxis[i][j] = jetlc.fhBkgFFxis[i][j] ;
343 fhBkgFFpts[i][j] = jetlc.fhBkgFFpts[i][j] ;
344 fhBkgNTracksInCones[i][j] = jetlc.fhBkgNTracksInCones[i][j] ;
352 //____________________________________________________________________________
353 AliAnaParticleJetLeadingConeCorrelation::~AliAnaParticleJetLeadingConeCorrelation()
355 // Remove all pointers except analysis output pointers.
358 //____________________________________________________________________________
359 Double_t AliAnaParticleJetLeadingConeCorrelation::CalculateJetRatioLimit(const Double_t ptg, const Double_t *par, const Double_t *x) const {
360 //Calculate the ratio of the jet and trigger particle limit for the selection
361 //WARNING: need to check what it does
362 //printf("CalculateLimit: x1 %2.3f, x2%2.3f\n",x[0],x[1]);
363 Double_t ePP = par[0] + par[1] * ptg ;
364 Double_t sPP = par[2] + par[3] * ptg ;
365 Double_t f = x[0] + x[1] * ptg ;
366 Double_t ePbPb = ePP + par[4] ;
367 Double_t sPbPb = TMath::Sqrt(sPP*sPP+ par[5]*par[5]) ;
368 Double_t rat = (ePbPb - sPbPb * f) / ptg ;
369 //printf("CalculateLimit: ePP %2.3f, sPP %2.3f, f %2.3f\n", ePP, sPP, f);
370 //printf("CalculateLimit: ePbPb %2.3f, sPbPb %2.3f, rat %2.3f\n", ePbPb, sPbPb, rat);
374 //____________________________________________________________________________
375 void AliAnaParticleJetLeadingConeCorrelation::FillJetHistos(AliAODPWG4ParticleCorrelation * particle, const TLorentzVector leading, const TLorentzVector jet, const TString type, const TString lastname)
377 //Fill jet and background histograms
378 Double_t ptTrig = particle->Pt();
379 Double_t ptJet = jet.Pt();
380 Double_t ptLead = leading.Pt();
381 Double_t phiTrig = particle->Phi();
382 Double_t phiJet = jet.Phi();
383 if(phiJet < 0) phiJet+=TMath::TwoPi();
384 Double_t phiLead = leading.Phi();
385 if(phiLead < 0) phiLead+=TMath::TwoPi();
386 Double_t etaTrig = particle->Eta();
387 Double_t etaJet = jet.Eta();
388 Double_t etaLead = leading.Eta();
391 h1 = dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sPt%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())));
392 if(h1)h1->Fill(ptTrig,ptJet);
395 h2 = dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sRatioPt%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())));
396 if(h2) h2->Fill(ptTrig,ptJet/ptTrig);
399 h3 = dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sLeadingRatioPt%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())));
400 if(h3)h3->Fill(ptTrig,ptLead/ptJet);
402 // dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sPhi%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())))->
403 // Fill(ptTrig,phiJet);
405 h4 = dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sDeltaPhi%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())));
406 if(h4) h4->Fill(ptTrig,phiJet-phiTrig);
408 h5 = dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sLeadingDeltaPhi%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())));
409 if(h5) h5->Fill(ptTrig,phiJet-phiLead);
411 // dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sEta%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())))->
412 // Fill(ptTrig,etaJet);
414 h6 = dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sDeltaEta%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())));
415 if(h6) h6->Fill(ptTrig,etaJet-etaTrig);
417 h7 = dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sLeadingDeltaEta%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())));
418 if(h7) h7->Fill(ptTrig,etaJet-etaLead);
420 //Construct fragmentation function
421 TObjArray * pl = new TObjArray;
423 if(type == "Jet") pl = particle->GetObjArray(Form("%sTracks",GetAODObjArrayName().Data()));
424 else if(type == "Bkg") particle->GetObjArray(Form("%sTracksBkg",GetAODObjArrayName().Data()));
428 //Different pt cut for jet particles in different collisions systems
429 //Only needed when jet is recalculated from AODs
430 Float_t ptcut = fJetPtThreshold;
431 if(fPbPb && !fSeveralConeAndPtCuts && ptTrig > fPtTriggerSelectionCut) ptcut = fJetPtThresPbPb ;
434 Int_t nTracksInCone = 0;
436 for(Int_t ipr = 0;ipr < pl->GetEntriesFast() ; ipr ++ ){
437 AliVTrack* track = dynamic_cast<AliVTrack *>(pl->At(ipr)) ;
438 if(track)p3.SetXYZ(track->Px(),track->Py(),track->Pz());
439 else printf("AliAnaParticleJetLeadingConeCorrelation::FillJetHistos() - Track not available\n");
441 //Recheck if particle is in jet cone
442 if(fReMakeJet || fSeveralConeAndPtCuts)
443 if(!IsParticleInJetCone(p3.Eta(), p3.Phi(), leading.Eta(), leading.Phi()) ) continue ;
447 TH2F *ha =dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sFFz%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())));
448 if(ha) ha->Fill(ptTrig,p3.Pt()/ptTrig);
449 TH2F *hb =dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sFFxi%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())));
450 if(hb) hb->Fill(ptTrig,TMath::Log(ptTrig/p3.Pt()));
451 TH2F *hc =dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sFFpt%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())));
452 if(hc) hc->Fill(ptTrig,p3.Pt());
456 if(nTracksInCone > 0) {
457 TH2F *hd = dynamic_cast<TH2F*>(GetOutputContainer()->FindObject(Form("%s%sNTracksInCone%s",GetAddedHistogramsStringToName().Data(),type.Data(),lastname.Data())));
458 if(hd)hd->Fill(ptTrig, nTracksInCone);
463 //________________________________________________________________________
464 TList * AliAnaParticleJetLeadingConeCorrelation::GetCreateOutputObjects()
466 // Create histograms to be saved in output file and
467 // store them in fOutCont
469 if(GetDebug()>1) printf("AliAnaParticleJetLeadingConeCorrelation::GetCreateOutputObjects() - Init histograms \n");
471 fOutCont = new TList() ;
472 fOutCont->SetName("ParticleJetLeadingInConeCorrelationHistograms") ;
474 Int_t nptbins = GetHistoPtBins();
475 Int_t nphibins = GetHistoPhiBins();
476 Int_t netabins = GetHistoEtaBins();
477 Float_t ptmax = GetHistoPtMax();
478 Float_t phimax = GetHistoPhiMax();
479 Float_t etamax = GetHistoEtaMax();
480 Float_t ptmin = GetHistoPtMin();
481 Float_t phimin = GetHistoPhiMin();
482 Float_t etamin = GetHistoEtaMin();
484 fhChargedLeadingPt = new TH2F("ChargedLeadingPt","p_{T leading charge} vs p_{T trigger}",nptbins,ptmin,ptmax,nptbins,ptmin,ptmax);
485 fhChargedLeadingPt->SetYTitle("p_{T leading charge}");
486 fhChargedLeadingPt->SetXTitle("p_{T trigger} (GeV/c)");
488 fhChargedLeadingPhi = new TH2F("ChargedLeadingPhi","#phi_{h^{#pm}} vs p_{T trigger}", nptbins,ptmin,ptmax,nphibins,phimin,phimax);
489 fhChargedLeadingPhi->SetYTitle("#phi_{h^{#pm}} (rad)");
490 fhChargedLeadingPhi->SetXTitle("p_{T trigger} (GeV/c)");
492 fhChargedLeadingEta = new TH2F("ChargedLeadingEta","#eta_{h^{#pm}} vs p_{T trigger}",nptbins,ptmin,ptmax,netabins,etamin,etamax);
493 fhChargedLeadingEta->SetYTitle("#eta_{h^{#pm}} ");
494 fhChargedLeadingEta->SetXTitle("p_{T trigger} (GeV/c)");
496 fhChargedLeadingDeltaPt = new TH2F("ChargedLeadingDeltaPt","p_{T trigger} - p_{T h^{#pm}} vs p_{T trigger}",nptbins,ptmin,ptmax,nptbins,ptmin,ptmax);
497 fhChargedLeadingDeltaPt->SetYTitle("#Delta p_{T} (GeV/c)");
498 fhChargedLeadingDeltaPt->SetXTitle("p_{T trigger} (GeV/c)");
500 fhChargedLeadingDeltaPhi = new TH2F("ChargedLeadingDeltaPhi","#phi_{trigger} - #phi_{h^{#pm}} vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,TMath::TwoPi());
501 fhChargedLeadingDeltaPhi->SetYTitle("#Delta #phi (rad)");
502 fhChargedLeadingDeltaPhi->SetXTitle("p_{T trigger} (GeV/c)");
504 fhChargedLeadingDeltaEta = new TH2F("ChargedLeadingDeltaEta","#eta_{trigger} - #eta_{h^{#pm}} vs p_{T trigger}",nptbins,ptmin,ptmax,120,-2,2);
505 fhChargedLeadingDeltaEta->SetYTitle("#Delta #eta");
506 fhChargedLeadingDeltaEta->SetXTitle("p_{T trigger} (GeV/c)");
508 fhChargedLeadingRatioPt = new TH2F("ChargedLeadingRatioPt","p_{T leading charge} /p_{T trigger} vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,2);
509 fhChargedLeadingRatioPt->SetYTitle("p_{T lead charge} /p_{T trigger}");
510 fhChargedLeadingRatioPt->SetXTitle("p_{T trigger} (GeV/c)");
512 fhChargedLeadingXi = new TH2F("ChargedLeadingXi","ln(p_{T trigger} / p_{T leading charge} ) vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,10);
513 fhChargedLeadingXi->SetYTitle("#xi");
514 fhChargedLeadingXi->SetXTitle("p_{T trigger} (GeV/c)");
516 fOutCont->Add(fhChargedLeadingPt) ;
517 fOutCont->Add(fhChargedLeadingPhi) ;
518 fOutCont->Add(fhChargedLeadingEta) ;
519 fOutCont->Add(fhChargedLeadingDeltaPt) ;
520 fOutCont->Add(fhChargedLeadingDeltaPhi) ;
521 fOutCont->Add(fhChargedLeadingDeltaEta) ;
522 fOutCont->Add(fhChargedLeadingRatioPt) ;
523 fOutCont->Add(fhChargedLeadingXi) ;
525 fhChargedLeadingDeltaPhiRatioPt30 = new TH2F("ChargedLeadingDeltaPhiRatioPt30","#phi_{trigger} - #phi_{#pi^{0}} vs p_{T leading}/p_{T trigger}, charged leading, p_{T trigger} > 30 GeV/c",120,0,TMath::TwoPi(),nptbins,0,1);
526 fhChargedLeadingDeltaPhiRatioPt30->SetXTitle("#Delta #phi (rad)");
527 fhChargedLeadingDeltaPhiRatioPt30->SetYTitle("p_{T leading} / p_{T trigger}");
529 fhChargedLeadingDeltaPhiRatioPt50 = new TH2F("ChargedLeadingDeltaPhiRatioPt50","#phi_{trigger} - #phi_{#pi^{0}} vs p_{T leading}/p_{T trigger}, charged leading, p_{T trigger} > 50 GeV/c",120,0,TMath::TwoPi(),nptbins,0,1);
530 fhChargedLeadingDeltaPhiRatioPt50->SetXTitle("#Delta #phi (rad)");
531 fhChargedLeadingDeltaPhiRatioPt50->SetYTitle("p_{T leading} / p_{T trigger}");
533 fOutCont->Add(fhChargedLeadingDeltaPhiRatioPt30) ;
534 fOutCont->Add(fhChargedLeadingDeltaPhiRatioPt50) ;
538 fhNeutralLeadingPt = new TH2F("NeutralLeadingPt","p_{T leading #pi^{0}} vs p_{T trigger}",nptbins,ptmin,ptmax,nptbins,ptmin,ptmax);
539 fhNeutralLeadingPt->SetYTitle("p_{T leading #pi^{0}}");
540 fhNeutralLeadingPt->SetXTitle("p_{T trigger} (GeV/c)");
542 fhNeutralLeadingPhi = new TH2F("NeutralLeadingPhi","#phi_{#pi^{0}} vs p_{T trigger}",nptbins,ptmin,ptmax,nphibins,phimin,phimax);
543 fhNeutralLeadingPhi->SetYTitle("#phi_{#pi^{0}} (rad)");
544 fhNeutralLeadingPhi->SetXTitle("p_{T trigger} (GeV/c)");
546 fhNeutralLeadingEta = new TH2F("NeutralLeadingEta","#eta_{#pi^{0}} vs p_{T trigger}",nptbins,ptmin,ptmax,netabins,etamin,etamax);
547 fhNeutralLeadingEta->SetYTitle("#eta_{#pi^{0}} ");
548 fhNeutralLeadingEta->SetXTitle("p_{T trigger} (GeV/c)");
550 fhNeutralLeadingDeltaPt = new TH2F("NeutralLeadingDeltaPt","p_{T trigger} - p_{T #pi^{0}} vs p_{T trigger}",nptbins,ptmin,ptmax,nptbins,ptmin,ptmax);
551 fhNeutralLeadingDeltaPt->SetYTitle("#Delta p_{T} (GeV/c)");
552 fhNeutralLeadingDeltaPt->SetXTitle("p_{T trigger} (GeV/c)");
554 fhNeutralLeadingDeltaPhi = new TH2F("NeutralLeadingDeltaPhi","#phi_{trigger} - #phi_{#pi^{0}} vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,TMath::TwoPi());
555 fhNeutralLeadingDeltaPhi->SetYTitle("#Delta #phi (rad)");
556 fhNeutralLeadingDeltaPhi->SetXTitle("p_{T trigger} (GeV/c)");
558 fhNeutralLeadingDeltaEta = new TH2F("NeutralLeadingDeltaEta","#eta_{trigger} - #eta_{#pi^{0}} vs p_{T trigger}",nptbins,ptmin,ptmax,120,-2,2);
559 fhNeutralLeadingDeltaEta->SetYTitle("#Delta #eta");
560 fhNeutralLeadingDeltaEta->SetXTitle("p_{T trigger} (GeV/c)");
562 fhNeutralLeadingRatioPt = new TH2F("NeutralLeadingRatioPt","p_{T leading #pi^{0}} /p_{T trigger} vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,2);
563 fhNeutralLeadingRatioPt->SetYTitle("p_{T lead #pi^{0}} /p_{T trigger}");
564 fhNeutralLeadingRatioPt->SetXTitle("p_{T trigger} (GeV/c)");
566 fhNeutralLeadingXi = new TH2F("NeutralLeadingXi","ln(p_{T trigger} / p_{T leading #pi^{0}} ) vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,10);
567 fhNeutralLeadingXi->SetYTitle("#xi");
568 fhNeutralLeadingXi->SetXTitle("p_{T trigger} (GeV/c)");
570 fOutCont->Add(fhNeutralLeadingPt) ;
571 fOutCont->Add(fhNeutralLeadingPhi) ;
572 fOutCont->Add(fhNeutralLeadingEta) ;
573 fOutCont->Add(fhNeutralLeadingDeltaPt) ;
574 fOutCont->Add(fhNeutralLeadingDeltaPhi) ;
575 fOutCont->Add(fhNeutralLeadingDeltaEta) ;
576 fOutCont->Add(fhNeutralLeadingRatioPt) ;
577 fOutCont->Add(fhNeutralLeadingXi) ;
579 fhNeutralLeadingDeltaPhiRatioPt30 = new TH2F("NeutralLeadingDeltaPhiRatioPt30","#phi_{trigger} - #phi_{#pi^{0}} vs p_{T leading}/p_{T trigger}, neutral leading, p_{T trigger} > 30 GeV/c",120,0,TMath::TwoPi(),nptbins,0,1);
580 fhNeutralLeadingDeltaPhiRatioPt30->SetXTitle("#Delta #phi (rad)");
581 fhNeutralLeadingDeltaPhiRatioPt30->SetYTitle("p_{T leading} / p_{T trigger}");
583 fhNeutralLeadingDeltaPhiRatioPt50 = new TH2F("NeutralLeadingDeltaPhiRatioPt50","#phi_{trigger} - #phi_{#pi^{0}} vs p_{T leading}/p_{T trigger}, neutral leading, p_{T trigger} > 50 GeV/c",120,0,TMath::TwoPi(),nptbins,0,1);
584 fhNeutralLeadingDeltaPhiRatioPt50->SetXTitle("#Delta #phi (rad)");
585 fhNeutralLeadingDeltaPhiRatioPt50->SetYTitle("p_{T leading} / p_{T trigger}");
586 fOutCont->Add(fhNeutralLeadingDeltaPhiRatioPt30) ;
587 fOutCont->Add(fhNeutralLeadingDeltaPhiRatioPt50) ;
591 if(!fSeveralConeAndPtCuts){// not several cones
594 fhJetPt = new TH2F("JetPt","p_{T jet} vs p_{T trigger}",nptbins,ptmin,ptmax,nptbins,ptmin,ptmax);
595 fhJetPt->SetYTitle("p_{T jet}");
596 fhJetPt->SetXTitle("p_{T trigger} (GeV/c)");
598 fhJetRatioPt = new TH2F("JetRatioPt","p_{T jet}/p_{T trigger} vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,2);
599 fhJetRatioPt->SetYTitle("p_{T jet}/p_{T trigger}");
600 fhJetRatioPt->SetXTitle("p_{T trigger} (GeV/c)");
602 fhJetDeltaPhi = new TH2F("JetDeltaPhi","#phi_{jet} - #phi_{trigger} vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,TMath::TwoPi());
603 fhJetDeltaPhi->SetYTitle("#Delta #phi (rad)");
604 fhJetDeltaPhi->SetXTitle("p_{T trigger} (GeV/c)");
606 fhJetDeltaEta = new TH2F("JetDeltaEta","#eta_{jet} - #eta_{trigger} vs p_{T trigger}",nptbins,ptmin,ptmax,120,-2,2);
607 fhJetDeltaEta->SetYTitle("#Delta #eta");
608 fhJetDeltaEta->SetXTitle("p_{T trigger} (GeV/c)");
610 fhJetLeadingRatioPt = new TH2F("JetLeadingRatioPt","p_{T jet} vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,2);
611 fhJetLeadingRatioPt->SetYTitle("p_{T leading}/p_{T jet}");
612 fhJetLeadingRatioPt->SetXTitle("p_{T trigger} (GeV/c)");
614 fhJetLeadingDeltaPhi = new TH2F("JetLeadingDeltaPhi","#phi_{jet} - #phi_{leading} vs p_{T trigger}",nptbins,ptmin,ptmax,120,-TMath::Pi(),TMath::Pi());
615 fhJetLeadingDeltaPhi->SetYTitle("#Delta #phi (rad)");
616 fhJetLeadingDeltaPhi->SetXTitle("p_{T trigger} (GeV/c)");
618 fhJetLeadingDeltaEta = new TH2F("JetLeadingDeltaEta","#eta_{jet} - #eta_{leading} vs p_{T trigger}",nptbins,ptmin,ptmax,120,-2,2);
619 fhJetLeadingDeltaEta->SetYTitle("#Delta #eta");
620 fhJetLeadingDeltaEta->SetXTitle("p_{T trigger} (GeV/c)");
622 fhJetFFz = new TH2F("JetFFz","z = p_{T i charged}/p_{T trigger} vs p_{T trigger}",nptbins,ptmin,ptmax,200,0.,2);
623 fhJetFFz->SetYTitle("z");
624 fhJetFFz->SetXTitle("p_{T trigger}");
626 fhJetFFxi = new TH2F("JetFFxi","#xi = ln(p_{T trigger}/p_{T i charged}) vs p_{T trigger}",nptbins,ptmin,ptmax,100,0.,10.);
627 fhJetFFxi->SetYTitle("#xi");
628 fhJetFFxi->SetXTitle("p_{T trigger}");
630 fhJetFFpt = new TH2F("JetFFpt","#xi = p_{T i charged}) vs p_{T trigger}",nptbins,ptmin,ptmax,200,0.,50.);
631 fhJetFFpt->SetYTitle("p_{T charged hadron}");
632 fhJetFFpt->SetXTitle("p_{T trigger}");
634 fhJetNTracksInCone = new TH2F("JetNTracksInCone","N particles in cone vs p_{T trigger}",nptbins,ptmin,ptmax,5000,0, 5000);
635 fhJetNTracksInCone->SetYTitle("N tracks in jet cone");
636 fhJetNTracksInCone->SetXTitle("p_{T trigger} (GeV/c)");
638 fOutCont->Add(fhJetPt) ;
639 fOutCont->Add(fhJetRatioPt) ;
640 fOutCont->Add(fhJetDeltaPhi) ;
641 fOutCont->Add(fhJetDeltaEta) ;
642 fOutCont->Add(fhJetLeadingRatioPt) ;
643 fOutCont->Add(fhJetLeadingDeltaPhi) ;
644 fOutCont->Add(fhJetLeadingDeltaEta) ;
645 fOutCont->Add(fhJetFFz) ;
646 fOutCont->Add(fhJetFFxi) ;
647 fOutCont->Add(fhJetFFpt) ;
648 fOutCont->Add(fhJetNTracksInCone) ;
651 fhBkgPt = new TH2F("BkgPt","p_{T bkg} vs p_{T trigger}",nptbins,ptmin,ptmax,nptbins,ptmin,ptmax);
652 fhBkgPt->SetYTitle("p_{T bkg}");
653 fhBkgPt->SetXTitle("p_{T trigger} (GeV/c)");
655 fhBkgRatioPt = new TH2F("BkgRatioPt","p_{T bkg}/p_{T trigger} vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,2);
656 fhBkgRatioPt->SetYTitle("p_{T bkg}/p_{T trigger}");
657 fhBkgRatioPt->SetXTitle("p_{T trigger} (GeV/c)");
659 fhBkgDeltaPhi = new TH2F("BkgDeltaPhi","#phi_{bkg} - #phi_{trigger} vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,TMath::TwoPi());
660 fhBkgDeltaPhi->SetYTitle("#Delta #phi (rad)");
661 fhBkgDeltaPhi->SetXTitle("p_{T trigger} (GeV/c)");
663 fhBkgDeltaEta = new TH2F("BkgDeltaEta","#eta_{bkg} - #eta_{trigger} vs p_{T trigger}",nptbins,ptmin,ptmax,120,-2,2);
664 fhBkgDeltaEta->SetYTitle("#Delta #eta");
665 fhBkgDeltaEta->SetXTitle("p_{T trigger} (GeV/c)");
667 fhBkgLeadingRatioPt = new TH2F("BkgLeadingRatioPt","p_{T bkg} vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,2);
668 fhBkgLeadingRatioPt->SetYTitle("p_{T leading}/p_{T bkg}");
669 fhBkgLeadingRatioPt->SetXTitle("p_{T trigger} (GeV/c)");
671 fhBkgLeadingDeltaPhi = new TH2F("BkgLeadingDeltaPhi","#phi_{bkg} - #phi_{leading} vs p_{T trigger}",nptbins,ptmin,ptmax,120,0,TMath::TwoPi());
672 fhBkgLeadingDeltaPhi->SetYTitle("#Delta #phi (rad)");
673 fhBkgLeadingDeltaPhi->SetXTitle("p_{T trigger} (GeV/c)");
675 fhBkgLeadingDeltaEta = new TH2F("BkgLeadingDeltaEta","#eta_{bkg} - #eta_{leading} vs p_{T trigger}",nptbins,ptmin,ptmax,120,-2,2);
676 fhBkgLeadingDeltaEta->SetYTitle("#Delta #eta");
677 fhBkgLeadingDeltaEta->SetXTitle("p_{T trigger} (GeV/c)");
679 fhBkgFFz = new TH2F("BkgFFz","z = p_{T i charged}/p_{T trigger} vs p_{T trigger}", nptbins,ptmin,ptmax,200,0.,2);
680 fhBkgFFz->SetYTitle("z");
681 fhBkgFFz->SetXTitle("p_{T trigger}");
683 fhBkgFFxi = new TH2F("BkgFFxi","#xi = ln(p_{T trigger}/p_{T i charged}) vs p_{T trigger}", nptbins,ptmin,ptmax,100,0.,10.);
684 fhBkgFFxi->SetYTitle("#xi");
685 fhBkgFFxi->SetXTitle("p_{T trigger}");
687 fhBkgFFpt = new TH2F("BkgFFpt","p_{T charged hadron } vs p_{T trigger}", nptbins,ptmin,ptmax,200,0.,50.);
688 fhBkgFFpt->SetYTitle("p_{T charged} hadron");
689 fhBkgFFpt->SetXTitle("p_{T trigger}");
691 fhBkgNTracksInCone = new TH2F("BkgNTracksInCone","N particles in cone vs p_{T trigger}",nptbins,ptmin,ptmax,5000,0, 5000);
692 fhBkgNTracksInCone->SetYTitle("N tracks in bkg cone");
693 fhBkgNTracksInCone->SetXTitle("p_{T trigger} (GeV/c)");
695 fOutCont->Add(fhBkgPt) ;
696 fOutCont->Add(fhBkgRatioPt) ;
697 fOutCont->Add(fhBkgDeltaPhi) ;
698 fOutCont->Add(fhBkgDeltaEta) ;
699 fOutCont->Add(fhBkgLeadingRatioPt) ;
700 fOutCont->Add(fhBkgLeadingDeltaPhi) ;
701 fOutCont->Add(fhBkgLeadingDeltaEta) ;
702 fOutCont->Add(fhBkgFFz) ;
703 fOutCont->Add(fhBkgFFxi) ;
704 fOutCont->Add(fhBkgFFpt) ;
705 fOutCont->Add(fhBkgNTracksInCone) ;
708 else{ //If we want to study the jet for different cones and pt
709 for(Int_t icone = 0; icone<fJetNCone; icone++){//icone
710 for(Int_t ipt = 0; ipt<fJetNPt;ipt++){ //ipt
712 TString lastnamehist ="Cone"+ fJetNameCones[icone]+"Pt"+ fJetNamePtThres[ipt];
713 TString lastnametitle =", cone ="+fJetNameCones[icone]+", pt > " +fJetNamePtThres[ipt]+" GeV/c";
716 fhJetPts[icone][ipt] = new TH2F(Form("JetPt%s",lastnamehist.Data()),Form("p_{T jet} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,nptbins,ptmin,ptmax);
717 fhJetPts[icone][ipt]->SetYTitle("p_{T jet}");
718 fhJetPts[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
720 fhJetRatioPts[icone][ipt] = new TH2F(Form("JetRatioPt%s",lastnamehist.Data()),Form("p_{T jet}/p_{T trigger} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,120,0,2);
721 fhJetRatioPts[icone][ipt]->SetYTitle("p_{T jet}/p_{T trigger}");
722 fhJetRatioPts[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
724 fhJetDeltaPhis[icone][ipt] = new TH2F(Form("JetDeltaPhi%s",lastnamehist.Data()),Form("#phi_{jet} - #phi_{trigger} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,120,0,TMath::TwoPi());
725 fhJetDeltaPhis[icone][ipt]->SetYTitle("#Delta #phi (rad)");
726 fhJetDeltaPhis[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
728 fhJetDeltaEtas[icone][ipt] = new TH2F(Form("JetDeltaEta%s",lastnamehist.Data()),Form("#eta_{jet} - #eta_{trigger} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,120,-2,2);
729 fhJetDeltaEtas[icone][ipt]->SetYTitle("#Delta #eta");
730 fhJetDeltaEtas[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
732 fhJetLeadingRatioPts[icone][ipt] = new TH2F(Form("JetLeadingRatioPt%s",lastnamehist.Data()),Form("p_{T jet} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,120,0,2);
733 fhJetLeadingRatioPts[icone][ipt]->SetYTitle("p_{T leading}/p_{T jet}");
734 fhJetLeadingRatioPts[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
736 fhJetLeadingDeltaPhis[icone][ipt] = new TH2F(Form("JetLeadingDeltaPhi%s",lastnamehist.Data()),Form("#phi_{jet} - #phi_{leading} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,120,0,TMath::TwoPi());
737 fhJetLeadingDeltaPhis[icone][ipt]->SetYTitle("#Delta #phi (rad)");
738 fhJetLeadingDeltaPhis[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
740 fhJetLeadingDeltaEtas[icone][ipt] = new TH2F(Form("JetLeadingDeltaEta%s",lastnamehist.Data()),Form("#eta_{jet} - #eta_{leading} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,120,-2,2);
741 fhJetLeadingDeltaEtas[icone][ipt]->SetYTitle("#Delta #eta");
742 fhJetLeadingDeltaEtas[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
744 fhJetFFzs[icone][ipt] = new TH2F(Form("JetFFz%s",lastnamehist.Data()),"z = p_{T i charged}/p_{T trigger} vs p_{T trigger}", 120,0.,120.,200,0.,2);
745 fhJetFFzs[icone][ipt]->SetYTitle("z");
746 fhJetFFzs[icone][ipt]->SetXTitle("p_{T trigger}");
748 fhJetFFxis[icone][ipt] = new TH2F(Form("JetFFxi%s",lastnamehist.Data()),"#xi = ln(p_{T trigger}/p_{T i charged}) vs p_{T trigger}", 120,0.,120.,100,0.,10.);
749 fhJetFFxis[icone][ipt]->SetYTitle("#xi");
750 fhJetFFxis[icone][ipt]->SetXTitle("p_{T trigger}");
752 fhJetFFpts[icone][ipt] = new TH2F(Form("JetFFpt%s",lastnamehist.Data()),"p_{T charged hadron } in jet vs p_{T trigger}", 120,0.,120.,200,0.,50.);
753 fhJetFFpts[icone][ipt]->SetYTitle("p_{T charged hadron}");
754 fhJetFFpts[icone][ipt]->SetXTitle("p_{T trigger}");
756 fhJetNTracksInCones[icone][ipt] = new TH2F(Form("JetNTracksInCone%s",lastnamehist.Data()),Form("N particles in cone vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,5000,0, 5000);
757 fhJetNTracksInCones[icone][ipt]->SetYTitle("N tracks in jet cone");
758 fhJetNTracksInCones[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
760 fOutCont->Add(fhJetPts[icone][ipt]) ;
761 fOutCont->Add(fhJetRatioPts[icone][ipt]) ;
762 fOutCont->Add(fhJetDeltaPhis[icone][ipt]) ;
763 fOutCont->Add(fhJetDeltaEtas[icone][ipt]) ;
764 fOutCont->Add(fhJetLeadingRatioPts[icone][ipt]) ;
765 fOutCont->Add(fhJetLeadingDeltaPhis[icone][ipt]) ;
766 fOutCont->Add(fhJetLeadingDeltaEtas[icone][ipt]) ;
767 fOutCont->Add(fhJetFFzs[icone][ipt]) ;
768 fOutCont->Add(fhJetFFxis[icone][ipt]) ;
769 fOutCont->Add(fhJetFFpts[icone][ipt]) ;
770 fOutCont->Add(fhJetNTracksInCones[icone][ipt]) ;
773 fhBkgPts[icone][ipt] = new TH2F(Form("BkgPt%s",lastnamehist.Data()),Form("p_{T bkg} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,nptbins,ptmin,ptmax);
774 fhBkgPts[icone][ipt]->SetYTitle("p_{T bkg}");
775 fhBkgPts[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
777 fhBkgRatioPts[icone][ipt] = new TH2F(Form("BkgRatioPt%s",lastnamehist.Data()),Form("p_{T bkg}/p_{T trigger} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,120,0,2);
778 fhBkgRatioPts[icone][ipt]->SetYTitle("p_{T bkg}/p_{T trigger}");
779 fhBkgRatioPts[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
781 fhBkgDeltaPhis[icone][ipt] = new TH2F(Form("BkgDeltaPhi%s",lastnamehist.Data()),Form("#phi_{bkg} - #phi_{trigger} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,120,0,TMath::TwoPi());
782 fhBkgDeltaPhis[icone][ipt]->SetYTitle("#Delta #phi (rad)");
783 fhBkgDeltaPhis[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
785 fhBkgDeltaEtas[icone][ipt] = new TH2F(Form("BkgDeltaEta%s",lastnamehist.Data()),Form("#eta_{bkg} - #eta_{trigger} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,120,-2,2);
786 fhBkgDeltaEtas[icone][ipt]->SetYTitle("#Delta #eta");
787 fhBkgDeltaEtas[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
789 fhBkgLeadingRatioPts[icone][ipt] = new TH2F(Form("BkgLeadingRatioPt%s",lastnamehist.Data()),Form("p_{T bkg} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,120,0,2);
790 fhBkgLeadingRatioPts[icone][ipt]->SetYTitle("p_{T leading}/p_{T bkg}");
791 fhBkgLeadingRatioPts[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
793 fhBkgLeadingDeltaPhis[icone][ipt] = new TH2F(Form("BkgLeadingDeltaPhi%s",lastnamehist.Data()),Form("#phi_{bkg} - #phi_{leading} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,120,0,TMath::TwoPi());
794 fhBkgLeadingDeltaPhis[icone][ipt]->SetYTitle("#Delta #phi (rad)");
795 fhBkgLeadingDeltaPhis[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
797 fhBkgLeadingDeltaEtas[icone][ipt] = new TH2F(Form("BkgLeadingDeltaEta%s",lastnamehist.Data()),Form("#eta_{bkg} - #eta_{leading} vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,120,-2,2);
798 fhBkgLeadingDeltaEtas[icone][ipt]->SetYTitle("#Delta #eta");
799 fhBkgLeadingDeltaEtas[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
801 fhBkgFFzs[icone][ipt] = new TH2F(Form("BkgFFz%s",lastnamehist.Data()),"z = p_{T i charged}/p_{T trigger} vs p_{T trigger}", 120,0.,120.,200,0.,2);
802 fhBkgFFzs[icone][ipt]->SetYTitle("z");
803 fhBkgFFzs[icone][ipt]->SetXTitle("p_{T trigger}");
805 fhBkgFFxis[icone][ipt] = new TH2F(Form("BkgFFxi%s",lastnamehist.Data()),"#xi = ln(p_{T trigger}/p_{T i charged}) vs p_{T trigger}", 120,0.,120.,100,0.,10.);
806 fhBkgFFxis[icone][ipt]->SetYTitle("#xi");
807 fhBkgFFxis[icone][ipt]->SetXTitle("p_{T trigger}");
809 fhBkgFFpts[icone][ipt] = new TH2F(Form("BkgFFpt%s",lastnamehist.Data()),"p_{T charged hadron} in jet vs p_{T trigger}", 120,0.,120.,200,0.,50.);
810 fhBkgFFpts[icone][ipt]->SetYTitle("p_{T charged hadron}");
811 fhBkgFFpts[icone][ipt]->SetXTitle("p_{T trigger}");
813 fhBkgNTracksInCones[icone][ipt] = new TH2F(Form("BkgNTracksInCone%s",lastnamehist.Data()),Form("N particles in cone vs p_{T trigger} %s",lastnametitle.Data()),nptbins,ptmin,ptmax,5000,0, 5000);
814 fhBkgNTracksInCones[icone][ipt]->SetYTitle("N tracks in bkg cone");
815 fhBkgNTracksInCones[icone][ipt]->SetXTitle("p_{T trigger} (GeV/c)");
817 fOutCont->Add(fhBkgPts[icone][ipt]) ;
818 fOutCont->Add(fhBkgRatioPts[icone][ipt]) ;
819 fOutCont->Add(fhBkgDeltaPhis[icone][ipt]) ;
820 fOutCont->Add(fhBkgDeltaEtas[icone][ipt]) ;
821 fOutCont->Add(fhBkgLeadingRatioPts[icone][ipt]) ;
822 fOutCont->Add(fhBkgLeadingDeltaPhis[icone][ipt]) ;
823 fOutCont->Add(fhBkgLeadingDeltaEtas[icone][ipt]) ;
824 fOutCont->Add(fhBkgFFzs[icone][ipt]) ;
825 fOutCont->Add(fhBkgFFxis[icone][ipt]) ;
826 fOutCont->Add(fhBkgFFpts[icone][ipt]) ;
827 fOutCont->Add(fhBkgNTracksInCones[icone][ipt]) ;
831 }//If we want to study any cone or pt threshold
833 //Keep neutral meson selection histograms if requiered
834 //Setting done in AliNeutralMesonSelection
835 if(GetNeutralMesonSelection()){
836 TList * nmsHistos = GetNeutralMesonSelection()->GetCreateOutputObjects() ;
837 if(GetNeutralMesonSelection()->AreNeutralMesonSelectionHistosKept())
838 for(Int_t i = 0; i < nmsHistos->GetEntries(); i++) fOutCont->Add(nmsHistos->At(i)) ;
844 printf("AliAnaParticleJetLeadingConeCorrelation::GetCreateOutputObjects() - All histograms names : \n");
845 for(Int_t i = 0 ; i< fOutCont->GetEntries(); i++)
846 printf("Histo i %d name %s\n",i,((fOutCont->At(i))->GetName()));
847 //cout<< (fOutCont->At(i))->GetName()<<endl;
854 //____________________________________________________________________________
855 Bool_t AliAnaParticleJetLeadingConeCorrelation::GetLeadingParticle(AliAODPWG4ParticleCorrelation *particle, TLorentzVector & pLeading)
857 //Search Charged or Neutral leading particle, select the highest one and fill AOD
859 TLorentzVector pLeadingCh(0,0,0,0) ;
860 TLorentzVector pLeadingPi0(0,0,0,0) ;
862 GetLeadingCharge(particle, pLeadingCh) ;
863 if(!fJetsOnlyInCTS) GetLeadingPi0(particle, pLeadingPi0) ;
865 Double_t ptch = pLeadingCh.Pt();
866 Double_t ptpi = pLeadingPi0.Pt();
867 if (ptch > 0 || ptpi > 0){
869 if(GetDebug() > 1)printf("AliAnaParticleJetLeadingConeCorrelation::GetLeadingParticle() - Leading found in CTS \n");
870 pLeading = pLeadingCh;
871 if(GetDebug() > 1) printf("AliAnaParticleJetLeadingConeCorrelation::GetLeadingParticle() - Found Leading: pt %2.3f, phi %2.3f deg, eta %2.3f\n",
872 pLeading.Pt(),pLeading.Phi()*TMath::RadToDeg(),pLeading.Eta()) ;
874 particle->SetLeading(pLeadingCh);
875 particle->SetLeadingDetector("CTS");
880 printf("AliAnaParticleJetLeadingConeCorrelation::GetLeadingParticle() - Leading found in EMCAL \n");
881 pLeading = pLeadingPi0;
882 if(GetDebug() > 1) printf("AliAnaParticleJetLeadingConeCorrelation::GetLeadingParticle() - Found Leading: pt %2.3f, phi %2.3f, eta %2.3f\n",
883 pLeading.Pt(),pLeading.Phi()*TMath::RadToDeg(),pLeading.Eta()) ;
885 particle->SetLeading(pLeadingPi0);
886 particle->SetLeadingDetector("EMCAL");
891 if(GetDebug() > 1)printf ("AliAnaParticleJetLeadingConeCorrelation::GetLeadingParticle() - NO LEADING PARTICLE FOUND \n");
897 //____________________________________________________________________________
898 void AliAnaParticleJetLeadingConeCorrelation::GetLeadingCharge(AliAODPWG4ParticleCorrelation* const particle, TLorentzVector & pLeading) const
900 //Search for the charged particle with highest pt and with
901 //Phi=Phi_trigger-Pi and pT=0.1E_gamma
904 Double_t ptTrig = particle->Pt();
905 Double_t phiTrig = particle->Phi();
906 Double_t rat = -100 ;
907 Double_t ptl = -100 ;
908 Double_t phil = -100 ;
910 Double_t phi = -100.;
913 for(Int_t ipr = 0;ipr < GetCTSTracks()->GetEntriesFast() ; ipr ++ ){
914 AliVTrack* track = (AliVTrack *)(GetCTSTracks()->At(ipr)) ;
915 p3.SetXYZ(track->Px(),track->Py(),track->Pz());
918 if(phi < 0) phi+=TMath::TwoPi();
920 //printf("AliAnaParticleJetLeadingConeCorrelation::GetLeadingCharge() - Tracks: pt %2.3f eta %2.3f phi %2.3f pt/ptTrig %2.3f \n",
921 // pt, p3.Eta(), phi,pt/ptTrig) ;
922 Float_t deltaphi = TMath::Abs(phiTrig-phi);
923 if((deltaphi > fDeltaPhiMinCut) && (deltaphi < fDeltaPhiMaxCut) &&
924 (rat > fLeadingRatioMinCut) && (rat < fLeadingRatioMaxCut) && (pt > ptl)) {
927 pLeading.SetVect(p3);
931 if(GetDebug() > 1 && ptl > 0 ) printf("AliAnaParticleJetLeadingConeCorrelation::GetLeadingCharge() - Leading in CTS: pt %2.3f eta %2.3f phi %2.3f pt/ptTrig %2.3f, |phiTrig-phi| %2.3f \n",
932 ptl, pLeading.Eta(), phil,ptl/ptTrig, TMath::Abs(phiTrig-phil)) ;
937 //____________________________________________________________________________
938 void AliAnaParticleJetLeadingConeCorrelation::GetLeadingPi0(AliAODPWG4ParticleCorrelation* const particle, TLorentzVector & pLeading)
940 //Search for the neutral pion with highest pt and with
941 //Phi=Phi_trigger-Pi and pT=0.1E_gamma
943 if(GetEMCALClusters()){
944 Double_t ptTrig = particle->Pt();
945 Double_t phiTrig = particle->Phi();
946 Double_t rat = -100 ;
947 Double_t ptl = -100 ;
948 Double_t phil = -100 ;
950 Double_t phi = -100.;
952 TLorentzVector gammai;
953 TLorentzVector gammaj;
955 //Get vertex for photon momentum calculation
956 Double_t vertex [] = {0,0,0} ; //vertex
957 //Double_t vertex2[] = {0,0,0} ; //vertex of second input AOD
958 if(GetReader()->GetDataType() != AliCaloTrackReader::kMC)
961 //if(GetReader()->GetSecondInputAODTree()) GetReader()->GetSecondInputAODVertex(vertex2);
964 //Cluster loop, select pairs with good pt, phi and fill AODs or histograms
965 for(Int_t iclus = 0;iclus < GetEMCALClusters()->GetEntriesFast() ; iclus ++ ){
966 AliVCluster * calo = (AliVCluster *)(GetEMCALClusters()->At(iclus)) ;
968 //Input from second AOD?
970 // if (particle->GetDetector() == "EMCAL" && GetReader()->GetEMCALClustersNormalInputEntries() <= iclus) inputi = 1 ;
971 // else if(particle->GetDetector() == "PHOS" && GetReader()->GetPHOSClustersNormalInputEntries() <= iclus) inputi = 1;
973 //Cluster selection, not charged, with photon or pi0 id and in fiducial cut
975 //if (inputi == 0 && !SelectCluster(calo, vertex, gammai, pdgi)) continue ;
976 //else if(inputi == 1 && !SelectCluster(calo, vertex2, gammai, pdgi)) continue ;
977 if(!SelectCluster(calo, vertex, gammai, pdgi)) continue ;
979 if(GetDebug() > 2) printf("AliAnaParticleJetLeadingConeCorrelation::GetLeadingPi0() - Neutral cluster: pt %2.3f, phi %2.3f \n",
980 gammai.Pt(),gammai.Phi());
982 //2 gamma overlapped, found with PID
983 if(pdgi == AliCaloPID::kPi0){
985 if(GetDebug() > 2) printf("AliAnaParticleJetLeadingConeCorrelation::GetLeadingPi0() - Neutral cluster ID as Pi0 \n");
990 if(phi < 0) phi+=TMath::TwoPi();
992 //Selection within angular and energy limits
993 Float_t deltaphi = TMath::Abs(phiTrig-phi);
994 if(pt > ptl && rat > fLeadingRatioMinCut && rat < fLeadingRatioMaxCut &&
995 deltaphi > fDeltaPhiMinCut && deltaphi < fDeltaPhiMaxCut )
999 pLeading.SetPxPyPzE(gammai.Px(),gammai.Py(),gammai.Pz(),gammai.E());
1001 }// pdg = AliCaloPID::kPi0
1002 //Make invariant mass analysis
1003 else if(pdgi == AliCaloPID::kPhoton){
1004 //Search the photon companion in case it comes from a Pi0 decay
1005 //Apply several cuts to select the good pair
1006 for(Int_t jclus = iclus+1; jclus < GetEMCALClusters()->GetEntriesFast() ; jclus ++ ){
1007 AliVCluster * calo2 = (AliVCluster *) (GetEMCALClusters()->At(jclus)) ;
1009 //Input from second AOD?
1011 // if (particle->GetDetector() == "EMCAL" && GetReader()->GetEMCALClustersNormalInputEntries() <= jclus) inputj = 1;
1012 // else if(particle->GetDetector() == "PHOS" && GetReader()->GetPHOSClustersNormalInputEntries() <= jclus) inputj = 1;
1014 //Cluster selection, not charged with photon or pi0 id and in fiducial cut
1016 //if (inputj == 0 && !SelectCluster(calo2, vertex, gammaj, pdgj)) continue ;
1017 //else if(inputj == 1 && !SelectCluster(calo2, vertex2, gammaj, pdgj)) continue ;
1018 if (!SelectCluster(calo2, vertex, gammaj, pdgj)) continue ;
1020 if(pdgj == AliCaloPID::kPhoton ){
1022 pt = (gammai+gammaj).Pt();
1023 phi = (gammai+gammaj).Phi();
1024 if(phi < 0) phi+=TMath::TwoPi();
1027 //Selection within angular and energy limits
1028 Float_t deltaphi = TMath::Abs(phiTrig-phi);
1029 if(GetDebug() > 3 ) printf("AliAnaParticleJetLeadingConeCorrelation::GetLeadingPi0() - Neutral Hadron Correlation: gamma pair: pt %2.2f, phi %2.2f, eta %2.2f, |phiTrig-phi| %2.3f, pt/ptTrig %2.3f, M %2.3f\n",
1030 pt,phi,(gammai+gammaj).Eta(), deltaphi, rat, (gammai+gammaj).M());
1032 if(pt > ptl && rat > fLeadingRatioMinCut && rat < fLeadingRatioMaxCut &&
1033 deltaphi > fDeltaPhiMinCut && deltaphi < fDeltaPhiMaxCut ){
1034 //Select good pair (aperture and invariant mass)
1035 if(GetNeutralMesonSelection()->SelectPair(gammai, gammaj)){
1038 pLeading=(gammai+gammaj);
1040 if(GetDebug() > 3 ) printf("AliAnaParticleJetLeadingConeCorrelation::GetLeadingPi0() - Neutral Hadron Correlation: Selected gamma pair: pt %2.2f, phi %2.2f, eta %2.2f, M %2.3f\n",
1041 ptl,phil,(gammai+gammaj).Eta(), (gammai+gammaj).M());
1045 }//Pair selected as leading
1046 }//if pair of gammas
1051 if(GetDebug() > 2 && pLeading.Pt() > 0 ) printf("AliAnaParticleJetLeadingConeCorrelation::GetLeadingPi0() - Leading EMCAL: pt %2.3f eta %2.3f phi %2.3f pt/Eg %2.3f \n",
1052 pLeading.Pt(), pLeading.Eta(), phil, pLeading.Pt()/ptTrig) ;
1054 }//EMCAL list exists
1057 //____________________________________________________________________________
1058 void AliAnaParticleJetLeadingConeCorrelation::InitParameters()
1060 //Initialize the parameters of the analysis.
1061 SetInputAODName("PWG4Particle");
1062 SetAODObjArrayName("JetLeadingCone");
1063 AddToHistogramsName("AnaJetLCCorr_");
1065 fJetsOnlyInCTS = kFALSE ;
1067 fReMakeJet = kFALSE ;
1069 //Leading selection parameters
1070 fDeltaPhiMinCut = 2.9 ;
1071 fDeltaPhiMaxCut = 3.4 ;
1072 fLeadingRatioMinCut = 0.1;
1073 fLeadingRatioMaxCut = 1.5;
1075 //Jet selection parameters
1077 fJetRatioMaxCut = 1.2 ;
1078 fJetRatioMinCut = 0.3 ;
1079 fJetCTSRatioMaxCut = 1.2 ;
1080 fJetCTSRatioMinCut = 0.3 ;
1081 fSelect = 0 ; //0, Accept all jets, 1, selection depends on energy, 2 fixed selection
1083 fSelectIsolated = kFALSE;
1085 //Cut depending on gamma energy
1086 fPtTriggerSelectionCut = 10.; //For Low pt jets+BKG, another limits applied
1087 //Reconstructed jet energy dependence parameters
1088 //e_jet = a1+e_gamma b2.
1089 //Index 0-> Pt>2 GeV r = 0.3; Index 1-> Pt>0.5 GeV r = 0.3
1090 fJetE1[0] = -5.75; fJetE1[1] = -4.1;
1091 fJetE2[0] = 1.005; fJetE2[1] = 1.05;
1093 //Reconstructed sigma of jet energy dependence parameters
1094 //s_jet = a1+e_gamma b2.
1095 //Index 0-> Pt>2 GeV r = 0.3; Index 1-> Pt>0.5 GeV r = 0.3
1096 fJetSigma1[0] = 2.65; fJetSigma1[1] = 2.75;
1097 fJetSigma2[0] = 0.0018; fJetSigma2[1] = 0.033;
1099 //Background mean energy and RMS
1100 //Index 0-> No BKG; Index 1-> BKG > 2 GeV;
1101 //Index 2-> (low pt jets)BKG > 0.5 GeV;
1102 //Index > 2, same for CTS conf
1103 fBkgMean[0] = 0.; fBkgMean[1] = 8.8 ; fBkgMean[2] = 69.5;
1104 fBkgMean[3] = 0.; fBkgMean[4] = 6.4; fBkgMean[5] = 48.6;
1105 fBkgRMS[0] = 0.; fBkgRMS[1] = 7.5; fBkgRMS[2] = 22.0;
1106 fBkgRMS[3] = 0.; fBkgRMS[4] = 5.4; fBkgRMS[5] = 13.2;
1108 //Factor x of min/max = E -+ x * sigma. Obtained after selecting the
1109 //limits for monoenergetic jets.
1110 //Index 0-> No BKG; Index 1-> BKG > 2 GeV;
1111 //Index 2-> (low pt jets) BKG > 0.5 GeV;
1112 //Index > 2, same for CTS conf
1114 fJetXMin1[0] =-0.69 ; fJetXMin1[1] = 0.39 ; fJetXMin1[2] =-0.88 ;
1115 fJetXMin1[3] =-2.0 ; fJetXMin1[4] =-0.442 ; fJetXMin1[5] =-1.1 ;
1116 fJetXMin2[0] = 0.066; fJetXMin2[1] = 0.038; fJetXMin2[2] = 0.034;
1117 fJetXMin2[3] = 0.25 ; fJetXMin2[4] = 0.113; fJetXMin2[5] = 0.077 ;
1118 fJetXMax1[0] =-3.8 ; fJetXMax1[1] =-0.76 ; fJetXMax1[2] =-3.6 ;
1119 fJetXMax1[3] =-2.7 ; fJetXMax1[4] =-1.21 ; fJetXMax1[5] =-3.7 ;
1120 fJetXMax2[0] =-0.012; fJetXMax2[1] =-0.022; fJetXMax2[2] = 0.016;
1121 fJetXMax2[3] =-0.024; fJetXMax2[4] =-0.008; fJetXMax2[5] = 0.027;
1124 //Different cones and pt thresholds to construct the jet
1127 fJetPtThreshold = 0.5 ;
1128 fJetPtThresPbPb = 2. ;
1131 fJetCones[0] = 0.2 ; fJetNameCones[0] = "02" ;
1132 fJetCones[1] = 0.3 ; fJetNameCones[1] = "03" ;
1133 fJetCones[2] = 0.4 ; fJetNameCones[2] = "04" ;
1134 fJetCones[2] = 0.5 ; fJetNameCones[2] = "05" ;
1136 fJetPtThres[0] = 0.0 ; fJetNamePtThres[0] = "00" ;
1137 fJetPtThres[1] = 0.5 ; fJetNamePtThres[1] = "05" ;
1138 fJetPtThres[2] = 1.0 ; fJetNamePtThres[2] = "10" ;
1139 fJetPtThres[3] = 2.0 ; fJetNamePtThres[3] = "20" ;
1142 //__________________________________________________________________________-
1143 Bool_t AliAnaParticleJetLeadingConeCorrelation::IsJetSelected(const Double_t ptTrig, const Double_t ptjet) const {
1144 //Given the pt of the jet and the trigger particle, select the jet or not
1145 //3 options, fSelect=0 accepts all, fSelect=1 selects jets depending on a
1146 //function energy dependent and fSelect=2 selects on simple fixed cuts
1148 if(ptjet == 0) return kFALSE;
1150 Double_t rat = ptTrig / ptjet ;
1152 //###############################################################
1154 return kTRUE; //Accept all jets, no restriction
1155 //###############################################################
1156 else if(fSelect == 1){
1157 //Check if the energy of the reconstructed jet is within an energy window
1158 //WARNING: to be rechecked, don't remember what all the steps mean
1168 //Phythia alone, jets with pt_th > 0.2, r = 0.3
1169 par[0] = fJetE1[0]; par[1] = fJetE2[0];
1170 //Energy of the jet peak
1171 //e_jet = fJetE1[0]+fJetE2[0]*e_gamma, simulation fit
1172 par[2] = fJetSigma1[0]; par[3] = fJetSigma2[0];
1173 //Sigma of the jet peak
1174 //sigma_jet = fJetSigma1[0]+fJetSigma2[0]*e_gamma, simulation fit
1175 par[4] = fBkgMean[0 + iCTS]; par[5] = fBkgRMS[0 + iCTS];
1176 //Parameters reserved for PbPb bkg.
1177 xmax[0] = fJetXMax1[0 + iCTS]; xmax[1] = fJetXMax2[0 + iCTS];
1178 xmin[0] = fJetXMin1[0 + iCTS]; xmin[1] = fJetXMin2[0 + iCTS];
1179 //Factor that multiplies sigma to obtain the best limits,
1180 //by observation, of mono jet ratios (ptjet/ptTrig)
1181 //X_jet = fJetX1[0]+fJetX2[0]*e_gamma
1185 if(ptTrig > fPtTriggerSelectionCut){
1186 //Phythia +PbPb with pt_th > 2 GeV/c, r = 0.3
1187 par[0] = fJetE1[0]; par[1] = fJetE2[0];
1188 //Energy of the jet peak, same as in pp
1189 //e_jet = fJetE1[0]+fJetE2[0]*e_gamma, simulation fit
1190 par[2] = fJetSigma1[0]; par[3] = fJetSigma2[0];
1191 //Sigma of the jet peak, same as in pp
1192 //sigma_jet = fJetSigma1[0]+fJetSigma2[0]*e_gamma, simulation fit
1193 par[4] = fBkgMean[1 + iCTS]; par[5] = fBkgRMS[1 + iCTS];
1194 //Mean value and RMS of PbPb Bkg
1195 xmax[0] = fJetXMax1[1 + iCTS]; xmax[1] = fJetXMax2[1 + iCTS];
1196 xmin[0] = fJetXMin1[1 + iCTS]; xmin[1] = fJetXMin2[1 + iCTS];
1197 //Factor that multiplies sigma to obtain the best limits,
1198 //by observation, of mono jet ratios (ptjet/ptTrig) mixed with PbPb Bkg,
1199 //pt_th > 2 GeV, r = 0.3
1200 //X_jet = fJetX1[0]+fJetX2[0]*e_gamma
1204 //Phythia + PbPb with pt_th > 0.5 GeV/c, r = 0.3
1205 par[0] = fJetE1[1]; par[1] = fJetE2[1];
1206 //Energy of the jet peak, pt_th > 2 GeV/c, r = 0.3
1207 //e_jet = fJetE1[0]+fJetE2[0]*e_gamma, simulation fit
1208 par[2] = fJetSigma1[1]; par[3] = fJetSigma2[1];
1209 //Sigma of the jet peak, pt_th > 2 GeV/c, r = 0.3
1210 //sigma_jet = fJetSigma1[0]+fJetSigma2[0]*e_gamma, simulation fit
1211 par[4] = fBkgMean[2 + iCTS]; par[5] = fBkgRMS[2 + iCTS];
1212 //Mean value and RMS of PbPb Bkg in a 0.3 cone, pt > 2 GeV.
1213 xmax[0] = fJetXMax1[2 + iCTS]; xmax[1] = fJetXMax2[2 + iCTS];
1214 xmin[0] = fJetXMin1[2 + iCTS]; xmin[1] = fJetXMin2[2 + iCTS];
1215 //Factor that multiplies sigma to obtain the best limits,
1216 //by observation, of mono jet ratios (ptjet/ptTrig) mixed with PbPb Bkg,
1217 //pt_th > 2 GeV, r = 0.3
1218 //X_jet = fJetX1[0]+fJetX2[0]*e_gamma
1220 }//If low pt jet in bkg
1223 //Calculate minimum and maximum limits of the jet ratio.
1224 Double_t min = CalculateJetRatioLimit(ptTrig, par, xmin);
1225 Double_t max = CalculateJetRatioLimit(ptTrig, par, xmax);
1227 if(GetDebug() > 3)printf("AliAnaParticleJetLeadingConeCorrelation::IsJetSelected() - Jet selection? : Limits min %2.3f, max %2.3f, pt_jet %2.3f, pt_gamma %2.3f, pt_jet / pt_gamma %2.3f\n",min,max,ptjet,ptTrig,rat);
1229 if(( min < rat ) && ( max > ptjet/rat))
1234 //###############################################################
1235 else if(fSelect == 2){
1237 if(!fJetsOnlyInCTS){
1238 if((rat < fJetRatioMaxCut) && (rat > fJetRatioMinCut )) return kTRUE;
1241 if((rat < fJetCTSRatioMaxCut) && (rat > fJetCTSRatioMinCut )) return kTRUE;
1244 //###############################################################
1246 printf("AliAnaParticleJetLeadingConeCorrelation::IsJetSelected() - Jet selection option larger than 2, DON'T SELECT JETS\n");
1254 //___________________________________________________________________
1255 Bool_t AliAnaParticleJetLeadingConeCorrelation::IsParticleInJetCone(const Double_t eta, Double_t phi, const Double_t etal, Double_t phil)
1257 //Check if the particle is inside the cone defined by the leading particle
1258 //WARNING: To be rechecked
1260 if(phi < 0) phi+=TMath::TwoPi();
1261 if(phil < 0) phil+=TMath::TwoPi();
1262 Double_t rad = 10000 + fJetCone;
1264 if(TMath::Abs(phi-phil) <= (TMath::TwoPi() - fJetCone))
1265 rad = TMath::Sqrt(TMath::Power(eta-etal,2)+TMath::Power(phi-phil,2));
1267 if(phi-phil > TMath::TwoPi() - fJetCone)
1268 rad = TMath::Sqrt(TMath::Power(eta-etal,2)+TMath::Power((phi-TMath::TwoPi())-phil,2));
1269 if(phi-phil < -(TMath::TwoPi() - fJetCone))
1270 rad = TMath::Sqrt(TMath::Power(eta-etal,2)+TMath::Power((phi+TMath::TwoPi())-phil,2));
1273 if(rad < fJetCone) return kTRUE ;
1274 else return kFALSE ;
1278 //__________________________________________________________________
1279 void AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillAOD()
1281 //Particle-Hadron Correlation Analysis, fill AODs
1283 if(!GetInputAODBranch()){
1284 printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillAOD() - No input particles in AOD with name branch < %s > \n",
1285 GetInputAODName().Data());
1289 if(strcmp(GetInputAODBranch()->GetClass()->GetName(), "AliAODPWG4ParticleCorrelation")){
1290 printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillAOD() - Wrong type of AOD object, change AOD class name in input AOD: It should be <AliAODPWG4ParticleCorrelation> and not <%s> \n",GetInputAODBranch()->GetClass()->GetName());
1295 printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillAOD() - Begin jet leading cone correlation analysis, fill AODs \n");
1296 printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillAOD() - In particle branch aod entries %d\n", GetInputAODBranch()->GetEntriesFast());
1297 printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillAOD() - In CTS aod entries %d\n", GetCTSTracks()->GetEntriesFast());
1298 printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillAOD() - In EMCAL aod entries %d\n", GetEMCALClusters()->GetEntriesFast());
1301 TLorentzVector pLeading(0,0,0,0); //It will contain the kinematics of the found leading particle
1303 //Loop on stored AOD particles, trigger
1304 Int_t naod = GetInputAODBranch()->GetEntriesFast();
1305 for(Int_t iaod = 0; iaod < naod ; iaod++){
1306 AliAODPWG4ParticleCorrelation* particle = (AliAODPWG4ParticleCorrelation*) (GetInputAODBranch()->At(iaod));
1308 // printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillAOD() - Trigger : pt %3.2f, phi %2.2f, eta %2.2f\n",particle->Pt(), particle->Phi(), particle->Eta());
1310 //Search leading particles in CTS and EMCAL
1311 if(GetLeadingParticle(particle, pLeading)){
1313 //Construct the jet around the leading, Fill AOD jet particle list, select jet
1314 //and fill AOD with jet and background
1315 MakeAODJet(particle, pLeading);
1318 }//AOD trigger particle loop
1320 if(GetDebug() >1)printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillAOD() - End of jet leading cone analysis, fill AODs \n");
1324 //__________________________________________________________________
1325 void AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillHistograms()
1328 //Particle-Hadron Correlation Analysis, fill histograms
1330 if(!GetInputAODBranch()){
1331 printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillHistograms() - No input particles in AOD with name branch < %s > \n",
1332 GetInputAODName().Data());
1336 printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillHistograms() - Begin jet leading cone correlation analysis, fill histograms \n");
1337 printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillHistograms() - In particle branch aod entries %d\n", GetInputAODBranch()->GetEntriesFast());
1338 printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillHistograms() - In CTS aod entries %d\n", GetCTSTracks()->GetEntriesFast());
1339 printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillHistograms() - In EMCAL aod entries %d\n", GetEMCALClusters()->GetEntriesFast());
1342 TLorentzVector pLeading(0,0,0,0) ;
1344 //Loop on stored AOD particles, trigger
1345 Int_t naod = GetInputAODBranch()->GetEntriesFast();
1346 for(Int_t iaod = 0; iaod < naod ; iaod++){
1347 AliAODPWG4ParticleCorrelation* particle = (AliAODPWG4ParticleCorrelation*) (GetInputAODBranch()->At(iaod));
1349 if(OnlyIsolated() && !particle->IsIsolated()) continue;
1351 Double_t pt = particle->Pt();
1352 Double_t phi = particle->Phi();
1353 Double_t eta = particle->Eta();
1355 //Get leading particle, fill histograms
1356 pLeading = particle->GetLeading();
1357 TString det = particle->GetLeadingDetector();
1359 if(det!="" && pLeading.Pt() > 0){
1360 Double_t ptL = pLeading.Pt();
1361 Double_t phiL = pLeading.Phi();
1362 if(phiL < 0 ) phiL+=TMath::TwoPi();
1363 Double_t etaL = pLeading.Eta();
1365 if(GetDebug() > 1) printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillHistograms() - Trigger with pt %3.2f, phi %2.2f, eta %2.2f\n", pt, phi, eta);
1368 fhChargedLeadingPt->Fill(pt,ptL);
1369 fhChargedLeadingPhi->Fill(pt,phiL);
1370 fhChargedLeadingEta->Fill(pt,etaL);
1371 fhChargedLeadingDeltaPt->Fill(pt,pt-ptL);
1372 fhChargedLeadingDeltaPhi->Fill(pt,TMath::Abs(phi-phiL));
1373 fhChargedLeadingDeltaEta->Fill(pt,eta-etaL);
1374 fhChargedLeadingRatioPt->Fill(pt,ptL/pt);
1375 fhChargedLeadingXi->Fill(pt,TMath::Log(pt/ptL));
1376 if(pt > 30) fhChargedLeadingDeltaPhiRatioPt30->Fill(TMath::Abs(phi-phiL),ptL/pt);
1377 if(pt > 50) fhChargedLeadingDeltaPhiRatioPt50->Fill(TMath::Abs(phi-phiL),ptL/pt);
1379 else if(det== "EMCAL"){
1380 fhNeutralLeadingPt->Fill(pt,ptL);
1381 fhNeutralLeadingPhi->Fill(pt,phiL);
1382 fhNeutralLeadingEta->Fill(pt,etaL);
1383 fhNeutralLeadingDeltaPt->Fill(pt,pt-ptL);
1384 fhNeutralLeadingDeltaPhi->Fill(pt,TMath::Abs(phi-phiL));
1385 fhNeutralLeadingDeltaEta->Fill(pt,eta-etaL);
1386 fhNeutralLeadingRatioPt->Fill(pt,ptL/pt);
1387 fhNeutralLeadingXi->Fill(pt,TMath::Log(pt/ptL));
1388 if(pt > 30) fhNeutralLeadingDeltaPhiRatioPt30->Fill(TMath::Abs(phi-phiL),ptL/pt);
1389 if(pt > 50) fhNeutralLeadingDeltaPhiRatioPt50->Fill(TMath::Abs(phi-phiL),ptL/pt);
1393 //Fill Jet histograms
1394 TLorentzVector bkg(0,0,0,0);
1395 TLorentzVector jet(0,0,0,0);
1396 if(!fSeveralConeAndPtCuts){//just fill histograms
1398 jet=particle->GetCorrelatedJet();
1399 bkg=particle->GetCorrelatedBackground();
1401 else MakeJetFromAOD(particle, pLeading, jet,bkg);
1403 if(jet.Pt() > 0){//Jet was found
1404 FillJetHistos(particle, pLeading, jet,"Jet","");
1405 FillJetHistos(particle, pLeading, bkg,"Bkg","");
1408 else if(fSeveralConeAndPtCuts){
1409 for(Int_t icone = 0; icone<fJetNCone; icone++) {
1410 fJetCone=fJetCones[icone];
1411 for(Int_t ipt = 0; ipt<fJetNPt;ipt++) {
1412 TString lastname ="Cone"+ fJetNameCones[icone]+"Pt"+ fJetNamePtThres[ipt];
1413 fJetPtThreshold=fJetPtThres[ipt];
1414 MakeJetFromAOD(particle, pLeading, jet,bkg);
1415 if(jet.Pt() > 0) {//Jet was found
1416 FillJetHistos(particle, pLeading, jet,"Jet",lastname);
1417 FillJetHistos(particle, pLeading, bkg,"Bkg",lastname);
1421 }//fSeveralConeAndPtCuts
1423 }//AOD trigger particle loop
1425 if(GetDebug() >1)printf("AliAnaParticleJetLeadingConeCorrelation::MakeAnalysisFillHistograms() - End of jet leading cone analysis, fill histograms \n");
1429 //____________________________________________________________________________
1430 void AliAnaParticleJetLeadingConeCorrelation::MakeAODJet(AliAODPWG4ParticleCorrelation *particle, const TLorentzVector pLeading)
1432 //Fill the jet with the particles around the leading particle with
1433 //R=fJetCone and pt_th = fJetPtThres. Calculate the energy of the jet and
1434 //fill aod with found information
1436 TLorentzVector bkg(0,0,0,0);
1437 TLorentzVector jet(0,0,0,0);
1438 TLorentzVector lv (0,0,0,0); //Temporal container for jet particles kinematics
1440 Double_t ptTrig = particle->Pt();
1441 Double_t phiTrig = particle->Phi();
1442 Double_t phil = pLeading.Phi();
1443 if(phil<0) phil+=TMath::TwoPi();
1444 Double_t etal = pLeading.Eta();
1446 //Different pt cut for jet particles in different collisions systems
1447 Float_t ptcut = fJetPtThreshold;
1448 if(fPbPb && !fSeveralConeAndPtCuts && ptTrig > fPtTriggerSelectionCut) ptcut = fJetPtThresPbPb ;
1450 //Add charged particles to jet if they are in cone around the leading particle
1451 if(!GetCTSTracks()) {
1452 printf("AliAnaParticleJetLeadingConeCorrelation::MakeAODJet() - Cannot construct jets without tracks, STOP analysis");
1456 //Fill jet with tracks
1458 //Initialize reference arrays that will contain jet and background tracks
1459 TObjArray * reftracks = new TObjArray;
1460 TObjArray * reftracksbkg = new TObjArray;
1462 for(Int_t ipr = 0;ipr < (GetCTSTracks())->GetEntriesFast() ; ipr ++ ){
1463 AliVTrack* track = (AliVTrack *)((GetCTSTracks())->At(ipr)) ;
1464 p3.SetXYZ(track->Px(),track->Py(),track->Pz());
1467 if(IsParticleInJetCone(p3.Eta(), p3.Phi(), etal, phil)){
1469 reftracks->Add(track);
1471 if(p3.Pt() > ptcut ){
1477 //Background around (phi_gamma-pi, eta_leading)
1478 else if(IsParticleInJetCone(p3.Eta(),p3.Phi(),etal, phiTrig)) {
1480 reftracksbkg->Add(track);
1482 if(p3.Pt() > ptcut ){
1489 //Add referenced tracks to AOD
1490 if(reftracks->GetEntriesFast() > 0 ){
1491 reftracks->SetName(Form("%sTracks",GetAODObjArrayName().Data()));
1492 particle->AddObjArray(reftracks);
1494 else if(GetDebug() > 2 ) printf("AliAnaParticleJetLeadingConeCorrelation::MakeAODJet() - No tracks in jet cone\n");
1495 if(reftracksbkg->GetEntriesFast() > 0 ){
1496 reftracksbkg->SetName(Form("%sTracksBkg",GetAODObjArrayName().Data()));
1497 particle->AddObjArray(reftracksbkg);
1499 else if(GetDebug() > 2 ) printf("AliAnaParticleJetLeadingConeCorrelation::MakeAODJet() - No background tracks in jet cone\n");
1501 //Add neutral particles to jet
1502 //Initialize reference arrays that will contain jet and background tracks
1503 TObjArray * refclusters = new TObjArray;
1504 TObjArray * refclustersbkg = new TObjArray;
1505 if(!fJetsOnlyInCTS && GetEMCALClusters()){
1507 //Get vertex for photon momentum calculation
1508 Double_t vertex[] = {0,0,0} ; //vertex
1509 //Double_t vertex2[] = {0,0,0} ; //vertex of second input aod
1510 if(GetReader()->GetDataType()!= AliCaloTrackReader::kMC)
1512 GetReader()->GetVertex(vertex);
1513 //if(GetReader()->GetSecondInputAODTree()) GetReader()->GetSecondInputAODVertex(vertex2);
1516 for(Int_t iclus = 0;iclus < (GetEMCALClusters())->GetEntriesFast() ; iclus ++ ){
1517 AliVCluster * calo = (AliVCluster *) (GetEMCALClusters()->At(iclus)) ;
1519 //Cluster selection, not charged
1520 if(IsTrackMatched(calo)) continue ;
1522 //Input from second AOD?
1524 // if (particle->GetDetector() == "EMCAL" && GetReader()->GetEMCALClustersNormalInputEntries() <= iclus) input = 1 ;
1525 // else if(particle->GetDetector() == "PHOS" && GetReader()->GetPHOSClustersNormalInputEntries() <= iclus) input = 1;
1527 //Get Momentum vector,
1528 if (input == 0) calo->GetMomentum(lv,vertex) ;//Assume that come from vertex in straight line
1529 //else if(input == 1) calo->GetMomentum(lv,vertex2);//Assume that come from vertex in straight line
1532 if(IsParticleInJetCone(lv.Eta(),lv.Phi(), etal, phil)){
1534 refclusters->Add(calo);
1536 if(lv.Pt() > ptcut ) jet+=lv;
1538 //Background around (phi_gamma-pi, eta_leading)
1539 else if(IsParticleInJetCone(lv.Eta(),lv.Phi(),etal, phiTrig)){
1542 refclustersbkg->Add(calo);
1544 if(lv.Pt() > ptcut ) bkg+=lv;
1547 }//jets with neutral particles
1549 //Add referenced clusters to AOD
1550 if(refclusters->GetEntriesFast() > 0 ){
1551 refclusters->SetName(Form("%sClusters",GetAODObjArrayName().Data()));
1552 particle->AddObjArray(refclusters);
1554 else if(GetDebug() > 2 ) printf("AliAnaParticleJetLeadingConeCorrelation::MakeAODJet() - No clusters in jet cone\n");
1555 if(refclustersbkg->GetEntriesFast() > 0 ){
1556 refclustersbkg->SetName(Form("%sClustersBkg",GetAODObjArrayName().Data()));
1557 particle->AddObjArray(refclustersbkg);
1559 else if(GetDebug() > 2 ) printf("AliAnaParticleJetLeadingConeCorrelation::MakeAODJet() - No background clusters in jet cone\n");
1561 //If there is any jet found, select after some criteria and
1562 //and fill AOD with corresponding TLorentzVector kinematics
1563 if(IsJetSelected(particle->Pt(), jet.Pt())) {
1564 particle->SetCorrelatedJet(jet);
1565 particle->SetCorrelatedBackground(bkg);
1566 if(GetDebug()>1) printf("AliAnaParticleJetLeadingConeCorrelation::MakeAODJet() - Found jet: Trigger pt %2.3f, Jet pt %2.3f, Bkg pt %2.3f\n",ptTrig,jet.Pt(),bkg.Pt());
1571 //____________________________________________________________________________
1572 void AliAnaParticleJetLeadingConeCorrelation::MakeJetFromAOD(AliAODPWG4ParticleCorrelation *particle, const TLorentzVector pLeading, TLorentzVector & jet, TLorentzVector & bkg)
1574 //Fill the jet with the particles around the leading particle with
1575 //R=fJetCone and pt_th = fJetPtThres. Calculate the energy of the jet and
1576 //fill aod tlorentzvectors with jet and bakcground found
1578 TLorentzVector lv (0,0,0,0); //Temporal container for jet particles kinematics
1580 Double_t ptTrig = particle->Pt();
1581 Double_t phiTrig = particle->Phi();
1582 Double_t phil = pLeading.Phi();
1583 if(phil < 0) phil+=TMath::TwoPi();
1584 Double_t etal = pLeading.Eta();
1586 TObjArray * refclusters = particle->GetObjArray(Form("Clusters%s" ,GetAODObjArrayName().Data()));
1587 TObjArray * reftracks = particle->GetObjArray(Form("Tracks%s" ,GetAODObjArrayName().Data()));
1588 TObjArray * refclustersbkg = particle->GetObjArray(Form("ClustersBkg%s",GetAODObjArrayName().Data()));
1589 TObjArray * reftracksbkg = particle->GetObjArray(Form("TracksBkg%s" ,GetAODObjArrayName().Data()));
1591 //Different pt cut for jet particles in different collisions systems
1592 Float_t ptcut = fJetPtThreshold;
1593 if(fPbPb && !fSeveralConeAndPtCuts && ptTrig > fPtTriggerSelectionCut) ptcut = fJetPtThresPbPb ;
1595 //Fill jet with tracks
1599 for(Int_t ipr = 0;ipr < reftracks->GetEntriesFast() ; ipr ++ ){
1600 AliVTrack* track = (AliVTrack *) reftracks->At(ipr) ;
1601 p3.SetXYZ(track->Px(),track->Py(),track->Pz());
1602 Float_t phi = p3.Phi();
1603 if(phi < 0) phi+=TMath::TwoPi();
1604 if(p3.Pt() > ptcut && IsParticleInJetCone(p3.Eta(), phi, etal, phil) ){
1610 //Particles in background
1612 for(Int_t ipr = 0;ipr < reftracksbkg->GetEntriesFast() ; ipr ++ ){
1613 AliVTrack* track = (AliVTrack *) reftracksbkg->At(ipr) ;
1614 p3.SetXYZ(track->Px(),track->Py(),track->Pz());
1615 if(p3.Pt() > ptcut && IsParticleInJetCone(p3.Eta(),p3.Phi(),etal, phiTrig) ) {
1619 }//background Track loop
1622 //Add neutral particles to jet
1623 if(!fJetsOnlyInCTS && refclusters){
1625 //Get vertex for photon momentum calculation
1626 Double_t vertex[] = {0,0,0} ; //vertex
1627 //Double_t vertex2[] = {0,0,0} ; //vertex of second input aod
1628 if(GetReader()->GetDataType()!= AliCaloTrackReader::kMC)
1630 GetReader()->GetVertex(vertex);
1631 //if(GetReader()->GetSecondInputAODTree()) GetReader()->GetSecondInputAODVertex(vertex2);
1634 //Loop on jet particles
1636 for(Int_t iclus = 0;iclus < refclusters->GetEntriesFast() ; iclus ++ ){
1637 AliVCluster * calo = (AliVCluster *) refclusters->At(iclus) ;
1639 //Input from second AOD?
1641 // if (particle->GetDetector() == "EMCAL" && GetReader()->GetEMCALClustersNormalInputEntries() <= iclus) input = 1 ;
1642 // else if(particle->GetDetector() == "PHOS" && GetReader()->GetPHOSClustersNormalInputEntries() <= iclus) input = 1;
1644 //Get Momentum vector,
1645 if (input == 0) calo->GetMomentum(lv,vertex) ;//Assume that come from vertex in straight line
1646 //else if(input == 1) calo->GetMomentum(lv,vertex2);//Assume that come from vertex in straight line
1648 if(lv.Pt() > ptcut && IsParticleInJetCone(lv.Eta(),lv.Phi(), etal, phil)) jet+=lv;
1652 //Loop on background particles
1654 for(Int_t iclus = 0;iclus < refclustersbkg->GetEntriesFast() ; iclus ++ ){
1655 AliVCluster * calo = (AliVCluster *) refclustersbkg->At(iclus) ;
1657 //Input from second AOD?
1659 // if (particle->GetDetector() == "EMCAL" && GetReader()->GetEMCALClustersNormalInputEntries() <= iclus) input = 1 ;
1660 // else if(particle->GetDetector() == "PHOS" && GetReader()->GetPHOSClustersNormalInputEntries() <= iclus) input = 1;
1662 //Get Momentum vector,
1663 if (input == 0) calo->GetMomentum(lv,vertex) ;//Assume that come from vertex in straight line
1664 //else if(input == 1) calo->GetMomentum(lv,vertex2);//Assume that come from vertex in straight line
1666 if( lv.Pt() > ptcut && IsParticleInJetCone(lv.Eta(),lv.Phi(),etal, phiTrig)) bkg+=lv;
1667 }//background cluster loop
1671 //If there is any jet found, leave jet and bkg as they are,
1672 //if not set them to 0.
1673 if(!IsJetSelected(particle->Pt(), jet.Pt())) {
1674 jet.SetPxPyPzE(0.,0.,0.,0.);
1675 bkg.SetPxPyPzE(0.,0.,0.,0.);
1678 if(GetDebug()>1) printf("AliAnaParticleJetLeadingConeCorrelation::MakeJetFromAOD() - Found jet: Trigger pt %2.3f, Jet pt %2.3f, Bkg pt %2.3f\n",ptTrig,jet.Pt(),bkg.Pt());
1682 //____________________________________________________________________________
1683 //Bool_t AliAnaParticleJetLeadingConeCorrelation::SelectCluster(AliVCluster * calo, Double_t *vertex, TLorentzVector & mom, Int_t & pdg) {
1684 // //Select cluster depending on its pid and acceptance selections
1686 // //Skip matched clusters with tracks
1687 // if(IsTrackMatched(calo)) return kFALSE;
1690 // calo->GetMomentum(mom,vertex);//Assume that come from vertex in straight line
1691 // pdg = AliCaloPID::kPhoton;
1692 // if(IsCaloPIDOn()){
1693 // //Get most probable PID, 2 options check PID weights (in MC this option is mandatory)
1694 // //or redo PID, recommended option for EMCal.
1695 // if(!IsCaloPIDRecalculationOn() || GetReader()->GetDataType() == AliCaloTrackReader::kMC )
1696 // pdg = GetCaloPID()->GetPdg("EMCAL",calo->GetPID(),mom.E());//PID with weights
1698 // pdg = GetCaloPID()->GetPdg("EMCAL",mom,calo);//PID recalculated
1700 // // if(GetDebug() > 3) printf("AliAnaParticleJetLeadingConeCorrelation::SelectCluster() - PDG of identified particle %d\n",pdg);
1701 // //If it does not pass pid, skip
1702 // if(pdg != AliCaloPID::kPhoton && pdg != AliCaloPID::kPi0)
1706 // //Check acceptance selection
1707 // if(IsFiducialCutOn()){
1708 // Bool_t in = GetFiducialCut()->IsInFiducialCut(mom,"EMCAL") ;
1709 // if(! in ) return kFALSE ;
1712 // //if(GetDebug() > 3) printf("AliAnaParticleJetLeadingConeCorrelation::SelectCluster() - Cluster selection cuts passed: pT %3.2f, pdg %d\n",mom.Pt(), pdg);
1718 //__________________________________________________________________
1719 void AliAnaParticleJetLeadingConeCorrelation::Print(const Option_t * opt) const
1722 //Print some relevant parameters set for the analysis
1726 printf("**** Print %s %s ****\n", GetName(), GetTitle() ) ;
1727 AliAnaPartCorrBaseClass::Print(" ");
1729 if(fJetsOnlyInCTS)printf("Jets reconstructed in CTS \n");
1730 else printf("Jets reconstructed in CTS+EMCAL \n");
1732 if(fPbPb) printf("PbPb events, pT cut in jet cone energy reconstruction %2.1f \n", fJetPtThreshold);
1733 else printf("pp events, pT cut in jet cone energy reconstruction %2.1f \n", fJetPtThresPbPb);
1735 printf("If pT of trigger < %2.3f, select jets as in pp? \n", fPtTriggerSelectionCut);
1737 printf("Phi gamma-Leading < %3.2f\n", fDeltaPhiMaxCut) ;
1738 printf("Phi gamma-Leading > %3.2f\n", fDeltaPhiMinCut) ;
1739 printf("pT Leading / pT Trigger < %3.2f\n", fLeadingRatioMaxCut) ;
1740 printf("pT Leading / pT Trigger > %3.2f\n", fLeadingRatioMinCut) ;
1743 printf("pT Jet / pT Gamma < %3.2f\n", fJetRatioMaxCut) ;
1744 printf("pT Jet / pT Gamma > %3.2f\n", fJetRatioMinCut) ;
1745 printf("pT Jet (Only CTS)/ pT Trigger < %3.2f\n", fJetCTSRatioMaxCut) ;
1746 printf("pT Jet (Only CTS)/ pT Trigger > %3.2f\n", fJetCTSRatioMinCut) ;
1748 else if(fSelect == 0)
1749 printf("Accept all reconstructed jets \n") ;
1750 else if(fSelect == 1)
1751 printf("Accept jets depending on trigger energy \n") ;
1753 printf("Wrong jet selection option: %d \n", fSelect) ;
1755 printf("Isolated Trigger? %d\n", fSelectIsolated) ;