]>
Commit | Line | Data |
---|---|---|
9725fd2a | 1 | /************************************************************************** |
2 | * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * | |
3 | * * | |
4 | * Author: The ALICE Off-line Project. * | |
5 | * Contributors are mentioned in the code where appropriate. * | |
6 | * * | |
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 | **************************************************************************/ | |
9725fd2a | 15 | |
a6f26052 | 16 | //_________________________________________________________________________ |
17 | // Class to check results from simulations or reconstructed real data. | |
18 | // Fill few histograms and do some checking plots | |
19 | // | |
20 | //-- Author: Gustavo Conesa (INFN-LNF) | |
21 | //_________________________________________________________________________ | |
9725fd2a | 22 | |
23 | ||
a6f26052 | 24 | // --- ROOT system --- |
d55bb5e1 | 25 | #include <TObjArray.h> |
26 | #include <TParticle.h> | |
27 | #include <TDatabasePDG.h> | |
28 | #include <TH3F.h> | |
0c1383b5 | 29 | #include <TObjString.h> |
9725fd2a | 30 | |
a6f26052 | 31 | //---- AliRoot system ---- |
9725fd2a | 32 | #include "AliAnaCalorimeterQA.h" |
33 | #include "AliCaloTrackReader.h" | |
34 | #include "AliStack.h" | |
c8fe2783 | 35 | #include "AliVCaloCells.h" |
ff45398a | 36 | #include "AliFiducialCut.h" |
c8fe2783 | 37 | #include "AliVCluster.h" |
d55bb5e1 | 38 | #include "AliVTrack.h" |
c8fe2783 | 39 | #include "AliVEvent.h" |
902aa95c | 40 | #include "AliVEventHandler.h" |
902aa95c | 41 | #include "AliAODMCParticle.h" |
42 | #include "AliMCAnalysisUtils.h" | |
9725fd2a | 43 | |
c5693f62 | 44 | // --- Detectors --- |
45 | #include "AliPHOSGeoUtils.h" | |
46 | #include "AliEMCALGeometry.h" | |
47 | ||
9725fd2a | 48 | ClassImp(AliAnaCalorimeterQA) |
c8fe2783 | 49 | |
649b825d | 50 | //________________________________________ |
c8fe2783 | 51 | AliAnaCalorimeterQA::AliAnaCalorimeterQA() : |
765206a5 | 52 | AliAnaCaloTrackCorrBaseClass(), fCalorimeter(""), |
649b825d | 53 | |
54 | //Switches | |
e6fec6f5 | 55 | fFillAllCellTimeHisto(kTRUE), |
45769d5b | 56 | fFillAllPosHisto(kFALSE), fFillAllPosHisto2(kTRUE), |
57 | fFillAllTH3(kFALSE), | |
35c71d5c | 58 | fFillAllTMHisto(kTRUE), fFillAllPi0Histo(kTRUE), |
649b825d | 59 | fCorrelate(kTRUE), fStudyBadClusters(kFALSE), |
f1538a5f | 60 | fStudyClustersAsymmetry(kFALSE), fStudyExotic(kFALSE), |
61 | fStudyWeight(kFALSE), | |
649b825d | 62 | |
63 | //Parameters and cuts | |
35c71d5c | 64 | fNModules(12), fNRCU(2), |
65 | fNMaxCols(48), fNMaxRows(24), | |
f15c25da | 66 | fTimeCutMin(-10000), fTimeCutMax(10000), |
07e4c878 | 67 | fCellAmpMin(0), fEMCALCellAmpMin(0), |
68 | fPHOSCellAmpMin(0), fMinInvMassECut(0), | |
649b825d | 69 | |
f1538a5f | 70 | // Exotic |
71 | fExoNECrossCuts(0), fExoECrossCuts(), | |
72 | fExoNDTimeCuts(0), fExoDTimeCuts(), | |
73 | ||
649b825d | 74 | //Histograms |
9e9f04cb | 75 | fhE(0), fhPt(0), |
76 | fhPhi(0), fhEta(0), fhEtaPhiE(0), | |
77 | fhECharged(0), fhPtCharged(0), | |
78 | fhPhiCharged(0), fhEtaCharged(0), fhEtaPhiECharged(0), | |
521636d2 | 79 | |
80 | //Invariant mass | |
9e9f04cb | 81 | fhIM(0 ), fhAsym(0), |
a82b4462 | 82 | |
83 | fhNCellsPerCluster(0), fhNCellsPerClusterNoCut(0), fhNClusters(0), | |
3129a79e | 84 | |
e1e62b89 | 85 | //Timing |
9e9f04cb | 86 | fhClusterTimeEnergy(0), fhCellTimeSpreadRespectToCellMax(0), |
9e9f04cb | 87 | fhCellIdCellLargeTimeSpread(0), fhClusterPairDiffTimeE(0), |
9e9f04cb | 88 | fhClusterMaxCellCloseCellRatio(0), fhClusterMaxCellCloseCellDiff(0), |
89 | fhClusterMaxCellDiff(0), fhClusterMaxCellDiffNoCut(0), | |
a82b4462 | 90 | fhClusterMaxCellDiffAverageTime(0), fhClusterMaxCellDiffWeightedTime(0), |
1a72f6c5 | 91 | fhClusterMaxCellECross(0), |
649b825d | 92 | fhLambda0(0), fhLambda1(0), fhDispersion(0), |
715fd81f | 93 | |
649b825d | 94 | //bad clusters |
95 | fhBadClusterEnergy(0), fhBadClusterTimeEnergy(0), | |
96 | fhBadClusterPairDiffTimeE(0), fhBadCellTimeSpreadRespectToCellMax(0), | |
9e9f04cb | 97 | fhBadClusterMaxCellCloseCellRatio(0), fhBadClusterMaxCellCloseCellDiff(0), fhBadClusterMaxCellDiff(0), |
a82b4462 | 98 | fhBadClusterMaxCellDiffAverageTime(0), fhBadClusterMaxCellDiffWeightedTime(0), |
1a72f6c5 | 99 | fhBadClusterMaxCellECross(0), |
1a83b960 | 100 | fhBadClusterDeltaIEtaDeltaIPhiE0(0), fhBadClusterDeltaIEtaDeltaIPhiE2(0), |
101 | fhBadClusterDeltaIEtaDeltaIPhiE6(0), fhBadClusterDeltaIA(0), | |
9e9f04cb | 102 | |
521636d2 | 103 | //Position |
9e9f04cb | 104 | fhRNCells(0), fhXNCells(0), |
105 | fhYNCells(0), fhZNCells(0), | |
106 | fhRE(0), fhXE(0), | |
107 | fhYE(0), fhZE(0), | |
521636d2 | 108 | fhXYZ(0), |
9e9f04cb | 109 | fhRCellE(0), fhXCellE(0), |
110 | fhYCellE(0), fhZCellE(0), | |
521636d2 | 111 | fhXYZCell(0), |
9e9f04cb | 112 | fhDeltaCellClusterRNCells(0), fhDeltaCellClusterXNCells(0), |
113 | fhDeltaCellClusterYNCells(0), fhDeltaCellClusterZNCells(0), | |
114 | fhDeltaCellClusterRE(0), fhDeltaCellClusterXE(0), | |
115 | fhDeltaCellClusterYE(0), fhDeltaCellClusterZE(0), | |
649b825d | 116 | |
521636d2 | 117 | // Cells |
701cbf54 | 118 | fhNCells(0), fhNCellsCutAmpMin(0), |
119 | fhAmplitude(0), fhAmpId(0), fhEtaPhiAmp(0), | |
1a72f6c5 | 120 | fhTime(0), fhTimeVz(0), |
121 | fhTimeId(0), fhTimeAmp(0), | |
638916c4 | 122 | fhAmpIdLowGain(0), fhTimeIdLowGain(0), fhTimeAmpLowGain(0), |
123 | ||
1a72f6c5 | 124 | fhCellECross(0), |
9e9f04cb | 125 | fhCaloCorrNClusters(0), fhCaloCorrEClusters(0), |
126 | fhCaloCorrNCells(0), fhCaloCorrECells(0), | |
127 | fhCaloV0SCorrNClusters(0), fhCaloV0SCorrEClusters(0), | |
128 | fhCaloV0SCorrNCells(0), fhCaloV0SCorrECells(0), | |
129 | fhCaloV0MCorrNClusters(0), fhCaloV0MCorrEClusters(0), | |
130 | fhCaloV0MCorrNCells(0), fhCaloV0MCorrECells(0), | |
131 | fhCaloTrackMCorrNClusters(0), fhCaloTrackMCorrEClusters(0), | |
132 | fhCaloTrackMCorrNCells(0), fhCaloTrackMCorrECells(0), | |
653aed3c | 133 | fhCaloCenNClusters(0), fhCaloCenEClusters(0), |
134 | fhCaloCenNCells(0), fhCaloCenECells(0), | |
135 | fhCaloEvPNClusters(0), fhCaloEvPEClusters(0), | |
136 | fhCaloEvPNCells(0), fhCaloEvPECells(0), | |
521636d2 | 137 | //Super-Module dependent histgrams |
649b825d | 138 | fhEMod(0), fhAmpMod(0), fhTimeMod(0), |
139 | fhNClustersMod(0), fhNCellsMod(0), | |
140 | fhNCellsPerClusterMod(0), fhNCellsPerClusterModNoCut(0), | |
141 | ||
638916c4 | 142 | fhGridCells(0), fhGridCellsE(0), fhGridCellsTime(0), |
143 | fhGridCellsLowGain(0), fhGridCellsELowGain(0), fhGridCellsTimeLowGain(0), | |
144 | fhTimeAmpPerRCU(0), fhIMMod(0), | |
649b825d | 145 | |
146 | // Weight studies | |
147 | fhECellClusterRatio(0), fhECellClusterLogRatio(0), | |
148 | fhEMaxCellClusterRatio(0), fhEMaxCellClusterLogRatio(0), | |
701cbf54 | 149 | fhECellTotalRatio(0), fhECellTotalLogRatio(0), |
150 | fhECellTotalRatioMod(0), fhECellTotalLogRatioMod(0), | |
715fd81f | 151 | |
765206a5 | 152 | fhExoL0ECross(0), fhExoL1ECross(0), |
153 | ||
715fd81f | 154 | // MC and reco |
649b825d | 155 | fhRecoMCE(), fhRecoMCPhi(), fhRecoMCEta(), |
156 | fhRecoMCDeltaE(), fhRecoMCRatioE(), | |
157 | fhRecoMCDeltaPhi(), fhRecoMCDeltaEta(), | |
715fd81f | 158 | |
521636d2 | 159 | // MC only |
95aee5e1 | 160 | fhGenMCE(), fhGenMCPt(), fhGenMCEtaPhi(), |
161 | fhGenMCAccE(), fhGenMCAccPt(), fhGenMCAccEtaPhi(), | |
35c71d5c | 162 | |
163 | //matched MC | |
649b825d | 164 | fhEMVxyz(0), fhEMR(0), |
165 | fhHaVxyz(0), fhHaR(0), | |
d55bb5e1 | 166 | fh1EOverP(0), fh2dR(0), |
649b825d | 167 | fh2EledEdx(0), fh2MatchdEdx(0), |
d55bb5e1 | 168 | fhMCEle1EOverP(0), fhMCEle1dR(0), fhMCEle2MatchdEdx(0), |
169 | fhMCChHad1EOverP(0), fhMCChHad1dR(0), fhMCChHad2MatchdEdx(0), | |
a054a582 | 170 | fhMCNeutral1EOverP(0), fhMCNeutral1dR(0), fhMCNeutral2MatchdEdx(0), fh1EOverPR02(0), |
171 | fhMCEle1EOverPR02(0), fhMCChHad1EOverPR02(0), fhMCNeutral1EOverPR02(0), | |
653aed3c | 172 | fh1EleEOverP(0), fhMCEle1EleEOverP(0), |
173 | fhMCChHad1EleEOverP(0), fhMCNeutral1EleEOverP(0), | |
174 | fhTrackMatchedDEta(0), fhTrackMatchedDPhi(0), fhTrackMatchedDEtaDPhi(0), | |
175 | fhTrackMatchedDEtaPos(0), fhTrackMatchedDPhiPos(0), fhTrackMatchedDEtaDPhiPos(0) | |
9725fd2a | 176 | { |
a6f26052 | 177 | //Default Ctor |
afabc52f | 178 | |
649b825d | 179 | //Weight studies |
701cbf54 | 180 | for(Int_t i =0; i < 12; i++){ |
649b825d | 181 | fhLambda0ForW0[i] = 0; |
1a72f6c5 | 182 | //fhLambda1ForW0[i] = 0; |
649b825d | 183 | |
184 | for(Int_t j = 0; j < 5; j++){ | |
185 | fhLambda0ForW0MC[i][j] = 0; | |
1a72f6c5 | 186 | //fhLambda1ForW0MC[i][j] = 0; |
649b825d | 187 | } |
188 | ||
189 | } | |
c8fe2783 | 190 | |
649b825d | 191 | //Cluster size |
192 | fhDeltaIEtaDeltaIPhiE0[0] = 0 ; fhDeltaIEtaDeltaIPhiE2[0] = 0; fhDeltaIEtaDeltaIPhiE6[0] = 0; | |
193 | fhDeltaIEtaDeltaIPhiE0[1] = 0 ; fhDeltaIEtaDeltaIPhiE2[1] = 0; fhDeltaIEtaDeltaIPhiE6[1] = 0; | |
194 | fhDeltaIA[0] = 0 ; fhDeltaIAL0[0] = 0; fhDeltaIAL1[0] = 0; | |
195 | fhDeltaIA[1] = 0 ; fhDeltaIAL0[1] = 0; fhDeltaIAL1[1] = 0; | |
196 | fhDeltaIANCells[0] = 0 ; fhDeltaIANCells[1] = 0; | |
197 | fhDeltaIAMC[0] = 0 ; fhDeltaIAMC[1] = 0; | |
198 | fhDeltaIAMC[2] = 0 ; fhDeltaIAMC[3] = 0; | |
2302a644 | 199 | |
f1538a5f | 200 | // Exotic |
201 | for (Int_t ie = 0; ie < 10 ; ie++) | |
202 | { | |
203 | fhExoDTime[ie] = 0; | |
204 | for (Int_t idt = 0; idt < 5 ; idt++) | |
205 | { | |
206 | fhExoNCell [ie][idt] = 0; | |
207 | fhExoL0 [ie][idt] = 0; | |
765206a5 | 208 | fhExoL1 [ie][idt] = 0; |
f1538a5f | 209 | fhExoECross [ie][idt] = 0; |
210 | fhExoTime [ie][idt] = 0; | |
765206a5 | 211 | fhExoL0NCell [ie][idt] = 0; |
212 | fhExoL1NCell [ie][idt] = 0; | |
f1538a5f | 213 | } |
214 | } | |
215 | ||
649b825d | 216 | // MC |
c8fe2783 | 217 | |
6aba6683 | 218 | for(Int_t i = 0; i < 7; i++) |
45769d5b | 219 | { |
649b825d | 220 | fhRecoMCE[i][0] = 0; fhRecoMCE[i][1] = 0; |
221 | fhRecoMCPhi[i][0] = 0; fhRecoMCPhi[i][1] = 0; | |
222 | fhRecoMCEta[i][0] = 0; fhRecoMCEta[i][1] = 0; | |
223 | fhRecoMCDeltaE[i][0] = 0; fhRecoMCDeltaE[i][1] = 0; | |
224 | fhRecoMCRatioE[i][0] = 0; fhRecoMCRatioE[i][1] = 0; | |
225 | fhRecoMCDeltaPhi[i][0] = 0; fhRecoMCDeltaPhi[i][1] = 0; | |
45769d5b | 226 | fhRecoMCDeltaEta[i][0] = 0; fhRecoMCDeltaEta[i][1] = 0; |
649b825d | 227 | } |
2302a644 | 228 | |
95aee5e1 | 229 | for(Int_t i = 0; i < 4; i++) |
230 | { | |
231 | fhGenMCE[i] = 0; | |
232 | fhGenMCPt[i] = 0; | |
233 | fhGenMCEtaPhi[i] = 0; | |
234 | fhGenMCAccE[i] = 0; | |
235 | fhGenMCAccPt[i] = 0; | |
236 | fhGenMCAccEtaPhi[i] = 0; | |
237 | } | |
238 | ||
649b825d | 239 | //Initialize parameters |
240 | InitParameters(); | |
241 | } | |
3f5990d6 | 242 | |
b94e038e | 243 | //______________________________________________________________________________________________________________________ |
c5693f62 | 244 | void AliAnaCalorimeterQA::BadClusterHistograms(AliVCluster* clus, const TObjArray *caloClusters, AliVCaloCells * cells, |
b94e038e | 245 | Int_t absIdMax, Double_t maxCellFraction, Float_t eCrossFrac, |
45769d5b | 246 | Double_t tmax) |
649b825d | 247 | { |
248 | //Bad cluster histograms | |
b0114dba | 249 | |
250 | // printf("AliAnaCalorimeterQA::BadClusterHistograms() - Event %d - Calorimeter %s \n \t E %f, n cells %d, max cell absId %d, maxCellFrac %f\n", | |
251 | // GetReader()->GetEventNumber(), fCalorimeter.Data(), | |
252 | // clus->E(),clus->GetNCells(),absIdMax,maxCellFraction); | |
1a72f6c5 | 253 | |
649b825d | 254 | fhBadClusterEnergy ->Fill(clus->E()); |
255 | Double_t tof = clus->GetTOF()*1.e9; | |
1a83b960 | 256 | fhBadClusterTimeEnergy ->Fill(clus->E(),tof); |
257 | fhBadClusterMaxCellDiff ->Fill(clus->E(),maxCellFraction); | |
258 | fhBadClusterMaxCellECross->Fill(clus->E(),eCrossFrac); | |
259 | ||
260 | if(fStudyClustersAsymmetry) ClusterAsymmetryHistograms(clus,absIdMax,kFALSE); | |
1a72f6c5 | 261 | |
a82b4462 | 262 | //Clusters in event time differencem bad minus good |
2302a644 | 263 | |
45769d5b | 264 | for(Int_t iclus2 = 0; iclus2 < caloClusters->GetEntriesFast(); iclus2++ ) |
265 | { | |
649b825d | 266 | AliVCluster* clus2 = (AliVCluster*)caloClusters->At(iclus2); |
a6f26052 | 267 | |
649b825d | 268 | if(clus->GetID()==clus2->GetID()) continue; |
715fd81f | 269 | |
a82b4462 | 270 | Float_t maxCellFraction2 = 0.; |
271 | Int_t absIdMax2 = GetCaloUtils()->GetMaxEnergyCell(cells, clus2,maxCellFraction2); | |
45769d5b | 272 | if(IsGoodCluster(absIdMax2,cells)) |
273 | { | |
a82b4462 | 274 | Double_t tof2 = clus2->GetTOF()*1.e9; |
649b825d | 275 | fhBadClusterPairDiffTimeE ->Fill(clus->E(), (tof-tof2)); |
649b825d | 276 | } |
a82b4462 | 277 | |
649b825d | 278 | } // loop |
924e319f | 279 | |
649b825d | 280 | // Max cell compared to other cells in cluster |
e6fec6f5 | 281 | if(fFillAllCellTimeHisto) |
2747966a | 282 | { |
45769d5b | 283 | // Get some time averages |
284 | Double_t timeAverages[2] = {0.,0.}; | |
285 | CalculateAverageTime(clus, cells, timeAverages); | |
286 | ||
649b825d | 287 | fhBadClusterMaxCellDiffAverageTime ->Fill(clus->E(),tmax-timeAverages[0]); |
649b825d | 288 | fhBadClusterMaxCellDiffWeightedTime ->Fill(clus->E(),tmax-timeAverages[1]); |
649b825d | 289 | } |
715fd81f | 290 | |
2747966a | 291 | for (Int_t ipos = 0; ipos < clus->GetNCells(); ipos++) |
292 | { | |
649b825d | 293 | Int_t absId = clus->GetCellsAbsId()[ipos]; |
2747966a | 294 | if(absId!=absIdMax && cells->GetCellAmplitude(absIdMax) > 0.01) |
295 | { | |
649b825d | 296 | Float_t frac = cells->GetCellAmplitude(absId)/cells->GetCellAmplitude(absIdMax); |
297 | ||
298 | fhBadClusterMaxCellCloseCellRatio->Fill(clus->E(),frac); | |
299 | fhBadClusterMaxCellCloseCellDiff ->Fill(clus->E(),cells->GetCellAmplitude(absIdMax)-cells->GetCellAmplitude(absId)); | |
300 | ||
e6fec6f5 | 301 | if(fFillAllCellTimeHisto) |
dbba06ca | 302 | { |
649b825d | 303 | Double_t time = cells->GetCellTime(absId); |
dbba06ca | 304 | GetCaloUtils()->RecalibrateCellTime(time, fCalorimeter, absId,GetReader()->GetInputEvent()->GetBunchCrossNumber()); |
305 | ||
649b825d | 306 | Float_t diff = (tmax-time*1e9); |
307 | fhBadCellTimeSpreadRespectToCellMax->Fill(clus->E(), diff); | |
308 | ||
e6fec6f5 | 309 | } |
649b825d | 310 | }// Not max |
311 | }//loop | |
715fd81f | 312 | |
649b825d | 313 | } |
715fd81f | 314 | |
dbf54f1e | 315 | //______________________________________________________________________ |
316 | void AliAnaCalorimeterQA::CalculateAverageTime(AliVCluster *clus, | |
317 | AliVCaloCells* cells, | |
318 | Double_t timeAverages[2]) | |
649b825d | 319 | { |
320 | // Calculate time averages and weights | |
a95eac90 | 321 | |
649b825d | 322 | // First recalculate energy in case non linearity was applied |
323 | Float_t energy = 0; | |
324 | Float_t ampMax = 0, amp = 0; | |
ecdde216 | 325 | // Int_t absIdMax =-1; |
2747966a | 326 | for (Int_t ipos = 0; ipos < clus->GetNCells(); ipos++) |
327 | { | |
649b825d | 328 | Int_t id = clus->GetCellsAbsId()[ipos]; |
e1e62b89 | 329 | |
649b825d | 330 | //Recalibrate cell energy if needed |
331 | amp = cells->GetCellAmplitude(id); | |
dbba06ca | 332 | GetCaloUtils()->RecalibrateCellAmplitude(amp,fCalorimeter, id); |
4c8f7c2e | 333 | |
649b825d | 334 | energy += amp; |
e1e62b89 | 335 | |
2747966a | 336 | if(amp> ampMax) |
337 | { | |
649b825d | 338 | ampMax = amp; |
ecdde216 | 339 | // absIdMax = id; |
649b825d | 340 | } |
649b825d | 341 | } // energy loop |
342 | ||
343 | // Calculate average time of cells in cluster and weighted average | |
dbf54f1e | 344 | Double_t aTime = 0; |
345 | Double_t wTime = 0; | |
346 | Float_t wTot = 0; | |
347 | Double_t time = 0; | |
348 | Int_t id =-1; | |
349 | Double_t w = 0; | |
350 | Int_t ncells = clus->GetNCells(); | |
45769d5b | 351 | |
2747966a | 352 | for (Int_t ipos = 0; ipos < ncells; ipos++) |
353 | { | |
dbf54f1e | 354 | id = clus ->GetCellsAbsId()[ipos]; |
355 | amp = cells->GetCellAmplitude(id); | |
356 | time = cells->GetCellTime(id); | |
649b825d | 357 | |
358 | //Recalibrate energy and time | |
dbba06ca | 359 | GetCaloUtils()->RecalibrateCellAmplitude(amp , fCalorimeter, id); |
360 | GetCaloUtils()->RecalibrateCellTime (time, fCalorimeter, id, GetReader()->GetInputEvent()->GetBunchCrossNumber()); | |
361 | ||
dbf54f1e | 362 | w = GetCaloUtils()->GetEMCALRecoUtils()->GetCellWeight(cells->GetCellAmplitude(id),energy); |
649b825d | 363 | aTime += time*1e9; |
364 | wTime += time*1e9 * w; | |
365 | wTot += w; | |
35c71d5c | 366 | |
649b825d | 367 | } |
f3138ecf | 368 | |
dbf54f1e | 369 | if(ncells > 0) aTime /= ncells; |
370 | else aTime = 0; | |
649b825d | 371 | |
dbf54f1e | 372 | if(wTot > 0) wTime /= wTot; |
f3138ecf | 373 | else wTime = 0; |
374 | ||
dbf54f1e | 375 | timeAverages[0] = aTime; |
376 | timeAverages[1] = wTime; | |
39de6caa | 377 | |
649b825d | 378 | } |
379 | ||
380 | //____________________________________________________________ | |
381 | void AliAnaCalorimeterQA::CellHistograms(AliVCaloCells *cells) | |
382 | { | |
383 | // Plot histograms related to cells only | |
9e9f04cb | 384 | |
649b825d | 385 | Int_t ncells = cells->GetNumberOfCells(); |
701cbf54 | 386 | if( ncells > 0 ) fhNCells->Fill(ncells) ; |
387 | ||
388 | Int_t ncellsCut = 0; | |
389 | Float_t ecellsCut = 0; | |
39de6caa | 390 | |
701cbf54 | 391 | if( GetDebug() > 0 ) |
649b825d | 392 | printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - %s cell entries %d\n", fCalorimeter.Data(), ncells ); |
393 | ||
394 | //Init arrays and used variables | |
701cbf54 | 395 | Int_t *nCellsInModule = new Int_t [fNModules]; |
396 | Float_t *eCellsInModule = new Float_t[fNModules]; | |
397 | ||
398 | for(Int_t imod = 0; imod < fNModules; imod++ ) | |
399 | { | |
400 | nCellsInModule[imod] = 0 ; | |
401 | eCellsInModule[imod] = 0.; | |
402 | } | |
a82b4462 | 403 | |
649b825d | 404 | Int_t icol = -1; |
405 | Int_t irow = -1; | |
406 | Int_t iRCU = -1; | |
407 | Float_t amp = 0.; | |
408 | Double_t time = 0.; | |
409 | Int_t id = -1; | |
638916c4 | 410 | Bool_t highG = kFALSE; |
649b825d | 411 | Float_t recalF = 1.; |
a82b4462 | 412 | Int_t bc = GetReader()->GetInputEvent()->GetBunchCrossNumber(); |
649b825d | 413 | |
45769d5b | 414 | for (Int_t iCell = 0; iCell < cells->GetNumberOfCells(); iCell++) |
415 | { | |
649b825d | 416 | if(GetDebug() > 2) |
417 | printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - Cell : amp %f, absId %d \n", cells->GetAmplitude(iCell), cells->GetCellNumber(iCell)); | |
45769d5b | 418 | |
649b825d | 419 | Int_t nModule = GetModuleNumberCellIndexes(cells->GetCellNumber(iCell),fCalorimeter, icol, irow, iRCU); |
420 | if(GetDebug() > 2) | |
421 | printf("\t module %d, column %d, row %d \n", nModule,icol,irow); | |
422 | ||
f1538a5f | 423 | if(nModule < fNModules) |
424 | { | |
649b825d | 425 | //Check if the cell is a bad channel |
45769d5b | 426 | if(GetCaloUtils()->IsBadChannelsRemovalSwitchedOn()) |
427 | { | |
ae2c2bc4 | 428 | if(fCalorimeter=="EMCAL") |
429 | { | |
649b825d | 430 | if(GetCaloUtils()->GetEMCALChannelStatus(nModule,icol,irow)) continue; |
431 | } | |
ae2c2bc4 | 432 | else |
433 | { | |
434 | if(GetCaloUtils()->GetPHOSChannelStatus(nModule,icol,irow) ) continue; | |
649b825d | 435 | } |
436 | } // use bad channel map | |
437 | ||
438 | amp = cells->GetAmplitude(iCell)*recalF; | |
439 | time = cells->GetTime(iCell); | |
440 | id = cells->GetCellNumber(iCell); | |
638916c4 | 441 | highG = cells->GetCellHighGain(id); |
649b825d | 442 | |
443 | // Amplitude recalibration if set | |
dbba06ca | 444 | GetCaloUtils()->RecalibrateCellAmplitude(amp, fCalorimeter, id); |
649b825d | 445 | |
446 | // Time recalibration if set | |
dbba06ca | 447 | GetCaloUtils()->RecalibrateCellTime (time, fCalorimeter, id, GetReader()->GetInputEvent()->GetBunchCrossNumber()); |
649b825d | 448 | |
449 | //Transform time to ns | |
450 | time *= 1.0e9; | |
f15c25da | 451 | |
e6fec6f5 | 452 | if(time < fTimeCutMin || time > fTimeCutMax) |
a87e069d | 453 | { |
822cc7aa | 454 | if(GetDebug() > 0 ) |
f1538a5f | 455 | printf("AliAnaCalorimeterQA - Remove cell with Time %f\n",time); |
649b825d | 456 | continue; |
e6fec6f5 | 457 | } |
06f1b12a | 458 | |
459 | // Remove exotic cells, defined only for EMCAL | |
460 | if(fCalorimeter=="EMCAL" && | |
461 | GetCaloUtils()->GetEMCALRecoUtils()->IsExoticCell(id, cells, bc)) continue; | |
462 | ||
649b825d | 463 | fhAmplitude->Fill(amp); |
464 | fhAmpId ->Fill(amp,id); | |
465 | fhAmpMod ->Fill(amp,nModule); | |
638916c4 | 466 | if(!highG) fhAmpIdLowGain->Fill(amp,id); |
701cbf54 | 467 | //E cross for exotic cells |
468 | if(amp > 0.05) | |
2747966a | 469 | { |
701cbf54 | 470 | fhCellECross->Fill(amp,1-GetECross(id,cells)/amp); |
471 | ecellsCut+=amp ; | |
472 | eCellsInModule[nModule]+=amp ; | |
473 | } | |
474 | ||
475 | if ( amp > fCellAmpMin ) | |
476 | { | |
477 | ncellsCut++ ; | |
478 | nCellsInModule[nModule]++ ; | |
06f1b12a | 479 | |
649b825d | 480 | Int_t icols = icol; |
481 | Int_t irows = irow; | |
57d8227a | 482 | |
483 | if(fCalorimeter=="EMCAL") | |
484 | { | |
649b825d | 485 | icols = (nModule % 2) ? icol + fNMaxCols : icol; |
57d8227a | 486 | if(nModule < 10 ) |
487 | irows = irow + fNMaxRows * Int_t(nModule / 2); | |
488 | else // 1/3 SM | |
489 | irows = irow + (fNMaxRows / 3) * Int_t(nModule / 2); | |
649b825d | 490 | } |
57d8227a | 491 | else |
492 | { | |
06f1b12a | 493 | irows = irow + fNMaxRows * nModule; |
649b825d | 494 | } |
06f1b12a | 495 | |
649b825d | 496 | fhGridCells ->Fill(icols,irows); |
497 | fhGridCellsE->Fill(icols,irows,amp); | |
498 | ||
638916c4 | 499 | if(!highG) |
500 | { | |
501 | fhGridCellsLowGain ->Fill(icols,irows); | |
502 | fhGridCellsELowGain->Fill(icols,irows,amp); | |
503 | } | |
504 | ||
e6fec6f5 | 505 | if(fFillAllCellTimeHisto) |
a87e069d | 506 | { |
649b825d | 507 | //printf("%s: time %g\n",fCalorimeter.Data(), time); |
1a72f6c5 | 508 | |
509 | Double_t v[3] = {0,0,0}; //vertex ; | |
510 | GetReader()->GetVertex(v); | |
511 | if(amp > 0.5) fhTimeVz ->Fill(TMath::Abs(v[2]),time); | |
512 | ||
649b825d | 513 | fhTime ->Fill(time); |
514 | fhTimeId ->Fill(time,id); | |
515 | fhTimeAmp ->Fill(amp,time); | |
516 | fhGridCellsTime->Fill(icols,irows,time); | |
638916c4 | 517 | if(!highG) fhGridCellsTimeLowGain->Fill(icols,irows,time); |
649b825d | 518 | fhTimeMod ->Fill(time,nModule); |
519 | fhTimeAmpPerRCU [nModule*fNRCU+iRCU]->Fill(amp, time); | |
520 | ||
638916c4 | 521 | if(!highG) |
522 | { | |
523 | fhTimeIdLowGain ->Fill(time,id); | |
524 | fhTimeAmpLowGain->Fill(amp,time); | |
525 | } | |
526 | ||
649b825d | 527 | } |
528 | } | |
529 | ||
530 | //Get Eta-Phi position of Cell | |
531 | if(fFillAllPosHisto) | |
532 | { | |
533 | if(fCalorimeter=="EMCAL" && GetCaloUtils()->IsEMCALGeoMatrixSet()){ | |
534 | Float_t celleta = 0.; | |
535 | Float_t cellphi = 0.; | |
536 | GetEMCALGeometry()->EtaPhiFromIndex(id, celleta, cellphi); | |
537 | ||
538 | fhEtaPhiAmp->Fill(celleta,cellphi,amp); | |
539 | Double_t cellpos[] = {0, 0, 0}; | |
540 | GetEMCALGeometry()->GetGlobal(id, cellpos); | |
541 | fhXCellE->Fill(cellpos[0],amp) ; | |
542 | fhYCellE->Fill(cellpos[1],amp) ; | |
543 | fhZCellE->Fill(cellpos[2],amp) ; | |
544 | Float_t rcell = TMath::Sqrt(cellpos[0]*cellpos[0]+cellpos[1]*cellpos[1]);//+cellpos[2]*cellpos[2]); | |
545 | fhRCellE->Fill(rcell,amp) ; | |
546 | fhXYZCell->Fill(cellpos[0],cellpos[1],cellpos[2]) ; | |
547 | }//EMCAL Cells | |
548 | else if(fCalorimeter=="PHOS" && GetCaloUtils()->IsPHOSGeoMatrixSet()){ | |
549 | TVector3 xyz; | |
550 | Int_t relId[4], module; | |
551 | Float_t xCell, zCell; | |
552 | ||
553 | GetPHOSGeometry()->AbsToRelNumbering(id,relId); | |
554 | module = relId[0]; | |
555 | GetPHOSGeometry()->RelPosInModule(relId,xCell,zCell); | |
556 | GetPHOSGeometry()->Local2Global(module,xCell,zCell,xyz); | |
557 | Float_t rcell = TMath::Sqrt(xyz.X()*xyz.X()+xyz.Y()*xyz.Y()); | |
558 | fhXCellE ->Fill(xyz.X(),amp) ; | |
559 | fhYCellE ->Fill(xyz.Y(),amp) ; | |
560 | fhZCellE ->Fill(xyz.Z(),amp) ; | |
561 | fhRCellE ->Fill(rcell ,amp) ; | |
562 | fhXYZCell->Fill(xyz.X(),xyz.Y(),xyz.Z()) ; | |
563 | }//PHOS cells | |
564 | }//fill cell position histograms | |
565 | ||
649b825d | 566 | }//nmodules |
567 | }//cell loop | |
568 | ||
701cbf54 | 569 | if( ncellsCut > 0 ) fhNCellsCutAmpMin->Fill(ncellsCut) ; //fill the cells after the cut on min amplitude and bad/exotic channels |
649b825d | 570 | |
571 | //Number of cells per module | |
45769d5b | 572 | for(Int_t imod = 0; imod < fNModules; imod++ ) |
573 | { | |
649b825d | 574 | if(GetDebug() > 1) |
575 | printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - module %d calo %s cells %d\n", imod, fCalorimeter.Data(), nCellsInModule[imod]); | |
576 | ||
577 | fhNCellsMod->Fill(nCellsInModule[imod],imod) ; | |
649b825d | 578 | } |
579 | ||
701cbf54 | 580 | // Check energy distribution in calorimeter for selected cells |
581 | if(fStudyWeight) | |
582 | { | |
583 | for (Int_t iCell = 0; iCell < cells->GetNumberOfCells(); iCell++) | |
584 | { | |
585 | if(GetDebug() > 2) | |
586 | printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - Cell : amp %f, absId %d \n", cells->GetAmplitude(iCell), cells->GetCellNumber(iCell)); | |
587 | ||
588 | Int_t nModule = GetModuleNumberCellIndexes(cells->GetCellNumber(iCell),fCalorimeter, icol, irow, iRCU); | |
589 | if(GetDebug() > 2) | |
590 | printf("\t module %d, column %d, row %d \n", nModule,icol,irow); | |
591 | ||
592 | if(nModule < fNModules) | |
593 | { | |
594 | //Check if the cell is a bad channel | |
595 | if(GetCaloUtils()->IsBadChannelsRemovalSwitchedOn()) | |
596 | { | |
597 | if(fCalorimeter=="EMCAL") | |
598 | { | |
599 | if(GetCaloUtils()->GetEMCALChannelStatus(nModule,icol,irow)) continue; | |
600 | } | |
601 | else | |
602 | { | |
603 | if(GetCaloUtils()->GetPHOSChannelStatus(nModule,icol,irow) ) continue; | |
604 | } | |
605 | } // use bad channel map | |
606 | ||
607 | amp = cells->GetAmplitude(iCell)*recalF; | |
608 | time = cells->GetTime(iCell); | |
609 | id = cells->GetCellNumber(iCell); | |
610 | ||
611 | // Amplitude recalibration if set | |
612 | GetCaloUtils()->RecalibrateCellAmplitude(amp, fCalorimeter, id); | |
613 | ||
614 | // Time recalibration if set | |
615 | GetCaloUtils()->RecalibrateCellTime (time, fCalorimeter, id, GetReader()->GetInputEvent()->GetBunchCrossNumber()); | |
616 | ||
617 | //Transform time to ns | |
618 | time *= 1.0e9; | |
619 | ||
620 | if(time < fTimeCutMin || time > fTimeCutMax) | |
621 | { | |
622 | if(GetDebug() > 0 ) | |
623 | printf("AliAnaCalorimeterQA - Remove cell with Time %f\n",time); | |
624 | continue; | |
625 | } | |
626 | ||
627 | // Remove exotic cells, defined only for EMCAL | |
628 | if(fCalorimeter=="EMCAL" && | |
629 | GetCaloUtils()->GetEMCALRecoUtils()->IsExoticCell(id, cells, bc)) continue; | |
630 | ||
631 | //E cross for exotic cells | |
632 | if(amp > 0.05) | |
633 | { | |
634 | if(ecellsCut > 0) | |
635 | { | |
636 | Float_t ratio = amp/ecellsCut; | |
637 | fhECellTotalRatio ->Fill(ecellsCut, ratio ); | |
638 | fhECellTotalLogRatio ->Fill(ecellsCut,TMath::Log(ratio)); | |
639 | } | |
640 | ||
641 | if(eCellsInModule[nModule] > 0) | |
642 | { | |
643 | Float_t ratioMod = amp/eCellsInModule[nModule]; | |
644 | fhECellTotalRatioMod [nModule]->Fill(eCellsInModule[nModule], ratioMod ); | |
645 | fhECellTotalLogRatioMod[nModule]->Fill(eCellsInModule[nModule],TMath::Log(ratioMod)); | |
646 | } | |
647 | }// amp > 0.5 | |
648 | }// nMod > 0 < Max | |
649 | } // cell loop | |
650 | } // weight studies | |
651 | ||
649b825d | 652 | delete [] nCellsInModule; |
701cbf54 | 653 | delete [] eCellsInModule; |
649b825d | 654 | |
655 | } | |
656 | ||
657 | //__________________________________________________________________________ | |
658 | void AliAnaCalorimeterQA::CellInClusterPositionHistograms(AliVCluster* clus) | |
659 | { | |
660 | // Fill histograms releated to cell position | |
661 | ||
649b825d | 662 | Int_t nCaloCellsPerCluster = clus->GetNCells(); |
663 | UShort_t * indexList = clus->GetCellsAbsId(); | |
664 | Float_t pos[3]; | |
665 | clus->GetPosition(pos); | |
666 | Float_t clEnergy = clus->E(); | |
667 | ||
668 | //Loop on cluster cells | |
45769d5b | 669 | for (Int_t ipos = 0; ipos < nCaloCellsPerCluster; ipos++) |
670 | { | |
649b825d | 671 | // printf("Index %d\n",ipos); |
672 | Int_t absId = indexList[ipos]; | |
673 | ||
674 | //Get position of cell compare to cluster | |
675 | ||
676 | if(fCalorimeter=="EMCAL" && GetCaloUtils()->IsEMCALGeoMatrixSet()){ | |
677 | ||
678 | Double_t cellpos[] = {0, 0, 0}; | |
679 | GetEMCALGeometry()->GetGlobal(absId, cellpos); | |
680 | ||
681 | fhDeltaCellClusterXNCells->Fill(pos[0]-cellpos[0],nCaloCellsPerCluster) ; | |
682 | fhDeltaCellClusterYNCells->Fill(pos[1]-cellpos[1],nCaloCellsPerCluster) ; | |
683 | fhDeltaCellClusterZNCells->Fill(pos[2]-cellpos[2],nCaloCellsPerCluster) ; | |
684 | ||
685 | fhDeltaCellClusterXE->Fill(pos[0]-cellpos[0],clEnergy) ; | |
686 | fhDeltaCellClusterYE->Fill(pos[1]-cellpos[1],clEnergy) ; | |
687 | fhDeltaCellClusterZE->Fill(pos[2]-cellpos[2],clEnergy) ; | |
688 | ||
689 | Float_t r = TMath::Sqrt(pos[0] *pos[0] + pos[1] * pos[1] ); | |
690 | Float_t rcell = TMath::Sqrt(cellpos[0]*cellpos[0] + cellpos[1]* cellpos[1]); | |
691 | ||
692 | fhDeltaCellClusterRNCells->Fill(r-rcell, nCaloCellsPerCluster) ; | |
693 | fhDeltaCellClusterRE ->Fill(r-rcell, clEnergy) ; | |
694 | ||
695 | }//EMCAL and its matrices are available | |
45769d5b | 696 | else if(fCalorimeter=="PHOS" && GetCaloUtils()->IsPHOSGeoMatrixSet()) |
697 | { | |
649b825d | 698 | TVector3 xyz; |
699 | Int_t relId[4], module; | |
700 | Float_t xCell, zCell; | |
701 | ||
702 | GetPHOSGeometry()->AbsToRelNumbering(absId,relId); | |
703 | module = relId[0]; | |
704 | GetPHOSGeometry()->RelPosInModule(relId,xCell,zCell); | |
705 | GetPHOSGeometry()->Local2Global(module,xCell,zCell,xyz); | |
706 | ||
707 | fhDeltaCellClusterXNCells->Fill(pos[0]-xyz.X(),nCaloCellsPerCluster) ; | |
708 | fhDeltaCellClusterYNCells->Fill(pos[1]-xyz.Y(),nCaloCellsPerCluster) ; | |
709 | fhDeltaCellClusterZNCells->Fill(pos[2]-xyz.Z(),nCaloCellsPerCluster) ; | |
710 | ||
711 | fhDeltaCellClusterXE->Fill(pos[0]-xyz.X(),clEnergy) ; | |
712 | fhDeltaCellClusterYE->Fill(pos[1]-xyz.Y(),clEnergy) ; | |
713 | fhDeltaCellClusterZE->Fill(pos[2]-xyz.Z(),clEnergy) ; | |
714 | ||
715 | Float_t r = TMath::Sqrt(pos[0] * pos[0] + pos[1] * pos[1] ); | |
716 | Float_t rcell = TMath::Sqrt(xyz.X() * xyz.X() + xyz.Y() * xyz.Y()); | |
717 | ||
718 | fhDeltaCellClusterRNCells->Fill(r-rcell, nCaloCellsPerCluster) ; | |
719 | fhDeltaCellClusterRE ->Fill(r-rcell, clEnergy) ; | |
720 | ||
721 | }//PHOS and its matrices are available | |
722 | }// cluster cell loop | |
723 | } | |
724 | ||
725 | //___________________________________________________________________________________________ | |
b94e038e | 726 | void AliAnaCalorimeterQA::ClusterAsymmetryHistograms(AliVCluster* clus, Int_t absIdMax, |
727 | Bool_t goodCluster) | |
649b825d | 728 | { |
729 | // Study the shape of the cluster in cell units terms | |
730 | ||
731 | //No use to study clusters with less than 4 cells | |
45769d5b | 732 | if( clus->GetNCells() <= 3 ) return; |
649b825d | 733 | |
734 | Int_t dIeta = 0; | |
735 | Int_t dIphi = 0; | |
736 | ||
737 | Int_t ietaMax=-1; Int_t iphiMax = 0; Int_t rcuMax = 0; | |
738 | Int_t smMax = GetModuleNumberCellIndexes(absIdMax,fCalorimeter, ietaMax, iphiMax, rcuMax); | |
739 | ||
6aba6683 | 740 | for (Int_t ipos = 0; ipos < clus->GetNCells(); ipos++) |
741 | { | |
649b825d | 742 | Int_t absId = clus->GetCellsAbsId()[ipos]; |
743 | ||
744 | Int_t ieta=-1; Int_t iphi = 0; Int_t rcu = 0; | |
745 | Int_t sm = GetModuleNumberCellIndexes(absId,fCalorimeter, ieta, iphi, rcu); | |
746 | ||
747 | if(dIphi < TMath::Abs(iphi-iphiMax)) dIphi = TMath::Abs(iphi-iphiMax); | |
748 | ||
45769d5b | 749 | if(smMax==sm) |
750 | { | |
649b825d | 751 | if(dIeta < TMath::Abs(ieta-ietaMax)) dIeta = TMath::Abs(ieta-ietaMax); |
752 | } | |
45769d5b | 753 | else |
754 | { | |
649b825d | 755 | Int_t ietaShift = ieta; |
756 | Int_t ietaMaxShift = ietaMax; | |
757 | if (ieta > ietaMax) ietaMaxShift+=48; | |
758 | else ietaShift +=48; | |
759 | if(dIeta < TMath::Abs(ietaShift-ietaMaxShift)) dIeta = TMath::Abs(ietaShift-ietaMaxShift); | |
760 | } | |
761 | ||
649b825d | 762 | }// fill cell-cluster histogram loop |
763 | ||
649b825d | 764 | |
1a83b960 | 765 | Float_t dIA = 1.*(dIphi-dIeta)/(dIeta+dIphi); |
766 | ||
767 | if(goodCluster) | |
768 | { | |
1a83b960 | 769 | // Was cluster matched? |
770 | Bool_t matched = GetCaloPID()->IsTrackMatched(clus,GetCaloUtils(),GetReader()->GetInputEvent()); | |
649b825d | 771 | |
1a83b960 | 772 | if (clus->E() < 2 ) fhDeltaIEtaDeltaIPhiE0[matched]->Fill(dIeta,dIphi); |
773 | else if(clus->E() < 6 ) fhDeltaIEtaDeltaIPhiE2[matched]->Fill(dIeta,dIphi); | |
774 | else fhDeltaIEtaDeltaIPhiE6[matched]->Fill(dIeta,dIphi); | |
775 | ||
776 | fhDeltaIA[matched]->Fill(clus->E(),dIA); | |
777 | ||
6aba6683 | 778 | if(clus->E() > 0.5) |
779 | { | |
1a83b960 | 780 | fhDeltaIAL0[matched] ->Fill(clus->GetM02(),dIA); |
781 | fhDeltaIAL1[matched] ->Fill(clus->GetM20(),dIA); | |
782 | fhDeltaIANCells[matched]->Fill(clus->GetNCells(),dIA); | |
649b825d | 783 | } |
784 | ||
1a83b960 | 785 | // Origin of clusters |
786 | Int_t nLabel = clus->GetNLabels(); | |
787 | Int_t* labels = clus->GetLabels(); | |
6aba6683 | 788 | |
45769d5b | 789 | if(IsDataMC()) |
790 | { | |
2644ead9 | 791 | Int_t tag = GetMCAnalysisUtils()->CheckOrigin(labels,nLabel, GetReader()); |
1a83b960 | 792 | if( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPhoton) && |
793 | !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPi0) && | |
794 | !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCEta) && | |
795 | !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCConversion) ){ | |
796 | fhDeltaIAMC[0]->Fill(clus->E(),dIA);//Pure Photon | |
797 | } | |
798 | else if ( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCElectron) && | |
799 | !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCConversion) ){ | |
800 | fhDeltaIAMC[1]->Fill(clus->E(),dIA);//Pure electron | |
801 | } | |
802 | else if ( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPhoton) && | |
803 | GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCConversion) ){ | |
804 | fhDeltaIAMC[2]->Fill(clus->E(),dIA);//Converted cluster | |
805 | } | |
806 | else if(!GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPhoton)){ | |
807 | fhDeltaIAMC[3]->Fill(clus->E(),dIA);//Hadrons | |
808 | } | |
809 | ||
810 | } // MC | |
811 | } // good cluster | |
812 | else | |
813 | { | |
814 | if (clus->E() < 2 ) fhBadClusterDeltaIEtaDeltaIPhiE0->Fill(dIeta,dIphi); | |
815 | else if(clus->E() < 6 ) fhBadClusterDeltaIEtaDeltaIPhiE2->Fill(dIeta,dIphi); | |
816 | else fhBadClusterDeltaIEtaDeltaIPhiE6->Fill(dIeta,dIphi); | |
817 | ||
818 | fhBadClusterDeltaIA->Fill(clus->E(),dIA); | |
1a83b960 | 819 | } |
649b825d | 820 | } |
821 | ||
b94e038e | 822 | //__________________________________________________________________________________________________________________ |
823 | void AliAnaCalorimeterQA::ClusterHistograms(AliVCluster* clus, const TObjArray *caloClusters, AliVCaloCells * cells, | |
824 | Int_t absIdMax, Double_t maxCellFraction, Float_t eCrossFrac, | |
45769d5b | 825 | Double_t tmax) |
649b825d | 826 | { |
827 | //Fill CaloCluster related histograms | |
828 | ||
1a83b960 | 829 | Double_t tof = clus->GetTOF()*1.e9; |
649b825d | 830 | |
1a83b960 | 831 | fhLambda0 ->Fill(clus->E(),clus->GetM02()); |
832 | fhLambda1 ->Fill(clus->E(),clus->GetM20()); | |
833 | fhDispersion ->Fill(clus->E(),clus->GetDispersion()); | |
649b825d | 834 | |
a82b4462 | 835 | fhClusterMaxCellDiff ->Fill(clus->E(),maxCellFraction); |
836 | fhClusterMaxCellECross->Fill(clus->E(),eCrossFrac); | |
837 | fhClusterTimeEnergy ->Fill(clus->E(),tof); | |
649b825d | 838 | |
1a83b960 | 839 | if(fStudyClustersAsymmetry) ClusterAsymmetryHistograms(clus,absIdMax,kTRUE); |
840 | ||
649b825d | 841 | //Clusters in event time difference |
45769d5b | 842 | for(Int_t iclus2 = 0; iclus2 < caloClusters->GetEntriesFast(); iclus2++ ) |
843 | { | |
649b825d | 844 | AliVCluster* clus2 = (AliVCluster*) caloClusters->At(iclus2); |
845 | ||
45769d5b | 846 | if( clus->GetID() == clus2->GetID() ) continue; |
649b825d | 847 | |
45769d5b | 848 | if( clus->GetM02() > 0.01 && clus2->GetM02() > 0.01 ) |
a87e069d | 849 | { |
a82b4462 | 850 | Double_t tof2 = clus2->GetTOF()*1.e9; |
649b825d | 851 | fhClusterPairDiffTimeE ->Fill(clus->E(), tof-tof2); |
852 | } | |
853 | } | |
854 | ||
1a83b960 | 855 | Int_t nModule = GetModuleNumber(clus); |
856 | Int_t nCaloCellsPerCluster = clus->GetNCells(); | |
857 | ||
45769d5b | 858 | if(nCaloCellsPerCluster > 1) |
859 | { | |
649b825d | 860 | // check time of cells respect to max energy cell |
861 | ||
e6fec6f5 | 862 | if(fFillAllCellTimeHisto) |
a87e069d | 863 | { |
45769d5b | 864 | // Get some time averages |
865 | Double_t timeAverages[2] = {0.,0.}; | |
866 | CalculateAverageTime(clus, cells, timeAverages); | |
867 | ||
649b825d | 868 | fhClusterMaxCellDiffAverageTime ->Fill(clus->E(),tmax-timeAverages[0]); |
649b825d | 869 | fhClusterMaxCellDiffWeightedTime ->Fill(clus->E(),tmax-timeAverages[1]); |
649b825d | 870 | } |
871 | ||
dbba06ca | 872 | for (Int_t ipos = 0; ipos < nCaloCellsPerCluster; ipos++) |
873 | { | |
649b825d | 874 | Int_t absId = clus->GetCellsAbsId()[ipos]; |
45769d5b | 875 | if( absId == absIdMax || cells->GetCellAmplitude(absIdMax) < 0.01 ) continue; |
649b825d | 876 | |
877 | Float_t frac = cells->GetCellAmplitude(absId)/cells->GetCellAmplitude(absIdMax); | |
878 | fhClusterMaxCellCloseCellRatio->Fill(clus->E(),frac); | |
879 | fhClusterMaxCellCloseCellDiff ->Fill(clus->E(),cells->GetCellAmplitude(absIdMax)-cells->GetCellAmplitude(absId)); | |
880 | ||
e6fec6f5 | 881 | if(fFillAllCellTimeHisto) |
dbba06ca | 882 | { |
649b825d | 883 | Double_t time = cells->GetCellTime(absId); |
dbba06ca | 884 | GetCaloUtils()->RecalibrateCellTime(time, fCalorimeter, absId,GetReader()->GetInputEvent()->GetBunchCrossNumber()); |
649b825d | 885 | |
886 | Float_t diff = (tmax-time*1.0e9); | |
887 | fhCellTimeSpreadRespectToCellMax->Fill(clus->E(), diff); | |
888 | if(TMath::Abs(TMath::Abs(diff) > 100) && clus->E() > 1 ) fhCellIdCellLargeTimeSpread->Fill(absId); | |
889 | } | |
890 | ||
891 | }// fill cell-cluster histogram loop | |
892 | ||
893 | }//check time and energy of cells respect to max energy cell if cluster of more than 1 cell | |
894 | ||
649b825d | 895 | // Get vertex for photon momentum calculation and event selection |
896 | Double_t v[3] = {0,0,0}; //vertex ; | |
1a83b960 | 897 | //GetReader()->GetVertex(v); // |
649b825d | 898 | |
899 | TLorentzVector mom ; | |
1a83b960 | 900 | clus->GetMomentum(mom,v); |
649b825d | 901 | |
902 | Float_t e = mom.E(); | |
903 | Float_t pt = mom.Pt(); | |
904 | Float_t eta = mom.Eta(); | |
905 | Float_t phi = mom.Phi(); | |
906 | if(phi < 0) phi +=TMath::TwoPi(); | |
907 | ||
908 | if(GetDebug() > 0) { | |
909 | printf("AliAnaCalorimeterQA::ClusterHistograms() - cluster: E %2.3f, pT %2.3f, eta %2.3f, phi %2.3f \n",e,pt,eta,phi*TMath::RadToDeg()); | |
910 | } | |
911 | ||
912 | fhE ->Fill(e); | |
913 | if(nModule >=0 && nModule < fNModules) fhEMod->Fill(e,nModule); | |
45769d5b | 914 | |
915 | fhPt ->Fill(pt); | |
916 | fhPhi ->Fill(phi); | |
917 | fhEta ->Fill(eta); | |
649b825d | 918 | |
919 | if(fFillAllTH3) | |
920 | fhEtaPhiE->Fill(eta,phi,e); | |
921 | ||
922 | //Cells per cluster | |
923 | fhNCellsPerCluster ->Fill(e, nCaloCellsPerCluster); | |
a82b4462 | 924 | |
649b825d | 925 | //Position |
45769d5b | 926 | if(fFillAllPosHisto2) |
927 | { | |
649b825d | 928 | Float_t pos[3] ; |
929 | clus->GetPosition(pos); | |
930 | ||
931 | fhXE ->Fill(pos[0],e); | |
932 | fhYE ->Fill(pos[1],e); | |
933 | fhZE ->Fill(pos[2],e); | |
934 | if(fFillAllTH3) | |
935 | fhXYZ ->Fill(pos[0], pos[1],pos[2]); | |
936 | ||
937 | fhXNCells->Fill(pos[0],nCaloCellsPerCluster); | |
938 | fhYNCells->Fill(pos[1],nCaloCellsPerCluster); | |
939 | fhZNCells->Fill(pos[2],nCaloCellsPerCluster); | |
940 | Float_t rxyz = TMath::Sqrt(pos[0]*pos[0]+pos[1]*pos[1]);//+pos[2]*pos[2]); | |
941 | fhRE ->Fill(rxyz,e); | |
942 | fhRNCells->Fill(rxyz ,nCaloCellsPerCluster); | |
943 | } | |
944 | ||
45769d5b | 945 | if( nModule >= 0 && nModule < fNModules ) fhNCellsPerClusterMod[nModule]->Fill(e, nCaloCellsPerCluster); |
649b825d | 946 | |
947 | } | |
948 | ||
f3138ecf | 949 | //____________________________________________________________________________ |
950 | void AliAnaCalorimeterQA::ClusterLoopHistograms(const TObjArray *caloClusters, | |
951 | AliVCaloCells* cells) | |
649b825d | 952 | { |
953 | // Fill clusters related histograms | |
649b825d | 954 | TLorentzVector mom ; |
955 | Int_t nLabel = 0 ; | |
956 | Int_t *labels = 0x0; | |
957 | Int_t nCaloClusters = caloClusters->GetEntriesFast() ; | |
958 | Int_t nCaloClustersAccepted = 0 ; | |
959 | Int_t nCaloCellsPerCluster = 0 ; | |
960 | Bool_t matched = kFALSE; | |
961 | Int_t nModule =-1 ; | |
962 | ||
963 | // Get vertex for photon momentum calculation and event selection | |
964 | Double_t v[3] = {0,0,0}; //vertex ; | |
1a83b960 | 965 | //GetReader()->GetVertex(v); |
95aee5e1 | 966 | |
649b825d | 967 | Int_t *nClustersInModule = new Int_t[fNModules]; |
968 | for(Int_t imod = 0; imod < fNModules; imod++ ) nClustersInModule[imod] = 0; | |
969 | ||
970 | if(GetDebug() > 0) | |
971 | printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - In %s there are %d clusters \n", fCalorimeter.Data(), nCaloClusters); | |
972 | ||
973 | // Loop over CaloClusters | |
45769d5b | 974 | for(Int_t iclus = 0; iclus < nCaloClusters; iclus++) |
975 | { | |
1a72f6c5 | 976 | if(GetDebug() > 0) |
977 | printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - cluster: %d/%d, data %d \n", | |
f3138ecf | 978 | iclus+1,nCaloClusters,GetReader()->GetDataType()); |
649b825d | 979 | |
6aba6683 | 980 | AliVCluster* clus = (AliVCluster*) caloClusters->At(iclus); |
649b825d | 981 | |
982 | // Get the fraction of the cluster energy that carries the cell with highest energy and its absId | |
983 | Float_t maxCellFraction = 0.; | |
984 | Int_t absIdMax = GetCaloUtils()->GetMaxEnergyCell(cells, clus,maxCellFraction); | |
985 | ||
986 | //Cut on time of clusters | |
987 | Double_t tof = clus->GetTOF()*1.e9; | |
45769d5b | 988 | if( tof < fTimeCutMin || tof > fTimeCutMax ) |
e6fec6f5 | 989 | { |
649b825d | 990 | if(GetDebug() > 0 )printf("AliAnaCalorimeterQA - Remove cluster with TOF %f\n",tof); |
991 | continue; | |
992 | } | |
993 | ||
994 | // Get cluster kinematics | |
1a83b960 | 995 | clus->GetMomentum(mom,v); |
649b825d | 996 | |
997 | // Check only certain regions | |
998 | Bool_t in = kTRUE; | |
999 | if(IsFiducialCutOn()) in = GetFiducialCut()->IsInFiducialCut(mom,fCalorimeter) ; | |
1000 | if(!in) continue; | |
1001 | ||
1a83b960 | 1002 | // MC labels |
649b825d | 1003 | nLabel = clus->GetNLabels(); |
1004 | labels = clus->GetLabels(); | |
1005 | ||
1a83b960 | 1006 | // SuperModule number of cluster |
1007 | nModule = GetModuleNumber(clus); | |
1008 | ||
649b825d | 1009 | // Cells per cluster |
1010 | nCaloCellsPerCluster = clus->GetNCells(); | |
1011 | ||
1012 | // Cluster mathed with track? | |
49b5c49b | 1013 | matched = GetCaloPID()->IsTrackMatched(clus,GetCaloUtils(), GetReader()->GetInputEvent()); |
649b825d | 1014 | |
649b825d | 1015 | //Get time of max cell |
1016 | Double_t tmax = cells->GetCellTime(absIdMax); | |
dbba06ca | 1017 | GetCaloUtils()->RecalibrateCellTime(tmax, fCalorimeter, absIdMax,GetReader()->GetInputEvent()->GetBunchCrossNumber()); |
649b825d | 1018 | tmax*=1.e9; |
1019 | ||
1a83b960 | 1020 | // Fill histograms related to single cluster |
1021 | ||
1a83b960 | 1022 | // Fill some histograms before applying the exotic cell / bad map cut |
1023 | fhNCellsPerClusterNoCut ->Fill(clus->E(), nCaloCellsPerCluster); | |
1024 | if(nModule >=0 && nModule < fNModules) fhNCellsPerClusterModNoCut[nModule]->Fill(clus->E(), nCaloCellsPerCluster); | |
1025 | ||
1026 | fhClusterMaxCellDiffNoCut->Fill(clus->E(),maxCellFraction); | |
1027 | ||
1028 | Float_t ampMax = cells->GetCellAmplitude(absIdMax); | |
dbba06ca | 1029 | GetCaloUtils()->RecalibrateCellAmplitude(ampMax,fCalorimeter, absIdMax); |
1a83b960 | 1030 | |
f1538a5f | 1031 | if(fStudyExotic) ExoticHistograms(absIdMax, ampMax, clus, cells); |
1032 | ||
649b825d | 1033 | //Check bad clusters if requested and rejection was not on |
a82b4462 | 1034 | Bool_t goodCluster = IsGoodCluster(absIdMax, cells); |
f1538a5f | 1035 | |
2747966a | 1036 | Float_t eCrossFrac = 0; |
1037 | if(ampMax > 0.01) eCrossFrac = 1-GetECross(absIdMax,cells)/ampMax; | |
649b825d | 1038 | |
649b825d | 1039 | if(!goodCluster) |
1a83b960 | 1040 | { |
649b825d | 1041 | BadClusterHistograms(clus, caloClusters, cells, absIdMax, |
45769d5b | 1042 | maxCellFraction, eCrossFrac, tmax); |
1a83b960 | 1043 | continue; |
1044 | } | |
649b825d | 1045 | |
1046 | ClusterHistograms(clus, caloClusters, cells, absIdMax, | |
45769d5b | 1047 | maxCellFraction, eCrossFrac, tmax); |
649b825d | 1048 | |
1049 | nCaloClustersAccepted++; | |
49214ef9 | 1050 | nModule = GetModuleNumber(clus); |
701cbf54 | 1051 | if(nModule >=0 && nModule < fNModules && mom.E() > 2*fCellAmpMin) |
1052 | nClustersInModule[nModule]++; | |
1a83b960 | 1053 | |
649b825d | 1054 | // Cluster weights |
1055 | if(fStudyWeight) WeightHistograms(clus, cells); | |
1056 | ||
1057 | // Cells in cluster position | |
1058 | if(fFillAllPosHisto) CellInClusterPositionHistograms(clus); | |
1059 | ||
1060 | // Fill histograms related to single cluster, mc vs data | |
1061 | Int_t mcOK = kFALSE; | |
1062 | Int_t pdg = -1; | |
1063 | if(IsDataMC() && nLabel > 0 && labels) | |
1064 | mcOK = ClusterMCHistograms(mom, matched, labels, nLabel, pdg); | |
008693e5 | 1065 | |
649b825d | 1066 | // Matched clusters with tracks, also do some MC comparison, needs input from ClusterMCHistograms |
1067 | if( matched && fFillAllTMHisto) | |
1068 | ClusterMatchedWithTrackHistograms(clus,mom,mcOK,pdg); | |
1069 | ||
1070 | // Invariant mass | |
d07278cf | 1071 | // Try to reduce background with a mild shower shape cut and no more than 1 maxima |
1072 | // in cluster and remove low energy clusters | |
1073 | if(fFillAllPi0Histo && nCaloClusters > 1 && nCaloCellsPerCluster > 1 && | |
1074 | GetCaloUtils()->GetNumberOfLocalMaxima(clus,cells) == 1 && | |
07e4c878 | 1075 | clus->GetM02() < 0.5 && clus->E() > fMinInvMassECut) |
a82b4462 | 1076 | InvariantMassHistograms(iclus, mom, nModule, caloClusters,cells); |
649b825d | 1077 | |
1078 | }//cluster loop | |
1079 | ||
1080 | // Number of clusters histograms | |
1081 | if(nCaloClustersAccepted > 0) fhNClusters->Fill(nCaloClustersAccepted); | |
1082 | ||
1083 | // Number of clusters per module | |
2747966a | 1084 | for(Int_t imod = 0; imod < fNModules; imod++ ) |
1085 | { | |
649b825d | 1086 | if(GetDebug() > 1) |
1087 | printf("AliAnaCalorimeterQA::ClusterLoopHistograms() - module %d calo %s clusters %d\n", imod, fCalorimeter.Data(), nClustersInModule[imod]); | |
1088 | fhNClustersMod->Fill(nClustersInModule[imod],imod); | |
1089 | } | |
1090 | ||
1091 | delete [] nClustersInModule; | |
1092 | ||
1093 | } | |
1094 | ||
b94e038e | 1095 | //__________________________________________________________________________________________ |
1096 | Bool_t AliAnaCalorimeterQA::ClusterMCHistograms(TLorentzVector mom, Bool_t matched, | |
1097 | const Int_t * labels, Int_t nLabels, Int_t & pdg ) | |
649b825d | 1098 | { |
1099 | ||
1100 | //Fill histograms only possible when simulation | |
1101 | ||
2747966a | 1102 | if(!labels || nLabels<=0) |
1103 | { | |
42d47cb7 | 1104 | if(GetDebug() > 1) printf("AliAnaCalorimeterQA::ClusterMCHistograms() - Strange, labels array %p, n labels %d \n", labels,nLabels); |
1105 | return kFALSE; | |
1106 | } | |
1107 | ||
6aba6683 | 1108 | if(GetDebug() > 1) |
2747966a | 1109 | { |
42d47cb7 | 1110 | printf("AliAnaCalorimeterQA::ClusterMCHistograms() - Primaries: nlabels %d\n",nLabels); |
649b825d | 1111 | } |
1112 | ||
1113 | Float_t e = mom.E(); | |
1114 | Float_t eta = mom.Eta(); | |
1115 | Float_t phi = mom.Phi(); | |
1116 | if(phi < 0) phi +=TMath::TwoPi(); | |
1117 | ||
1118 | AliAODMCParticle * aodprimary = 0x0; | |
1119 | TParticle * primary = 0x0; | |
1120 | ||
1121 | //Play with the MC stack if available | |
1122 | Int_t label = labels[0]; | |
1123 | ||
2747966a | 1124 | if(label < 0) |
1125 | { | |
008693e5 | 1126 | if(GetDebug() >= 0) printf("AliAnaCalorimeterQA::ClusterMCHistograms() *** bad label ***: label %d \n", label); |
649b825d | 1127 | return kFALSE; |
1128 | } | |
1129 | ||
45769d5b | 1130 | Int_t pdg0 =-1; Int_t status = -1; Int_t iMother = -1; Int_t iParent = -1; |
1131 | Float_t vxMC = 0; Float_t vyMC = 0; | |
1132 | Float_t eMC = 0; //Float_t ptMC= 0; | |
1133 | Float_t phiMC = 0; Float_t etaMC = 0; | |
1134 | Int_t charge = 0; | |
649b825d | 1135 | |
1136 | //Check the origin. | |
2644ead9 | 1137 | Int_t tag = GetMCAnalysisUtils()->CheckOrigin(labels,nLabels, GetReader()); |
649b825d | 1138 | |
d07278cf | 1139 | if ( GetReader()->ReadStack() && |
1140 | !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCUnknown)) | |
1141 | { //it MC stack and known tag | |
649b825d | 1142 | |
d07278cf | 1143 | if( label >= GetMCStack()->GetNtrack()) |
1144 | { | |
008693e5 | 1145 | if(GetDebug() >= 0) printf("AliAnaCalorimeterQA::ClusterMCHistograms() *** large label ***: label %d, n tracks %d \n", label, GetMCStack()->GetNtrack()); |
649b825d | 1146 | return kFALSE; |
1147 | } | |
1148 | ||
1149 | primary = GetMCStack()->Particle(label); | |
1150 | iMother = label; | |
1151 | pdg0 = TMath::Abs(primary->GetPdgCode()); | |
1152 | pdg = pdg0; | |
1153 | status = primary->GetStatusCode(); | |
1154 | vxMC = primary->Vx(); | |
1155 | vyMC = primary->Vy(); | |
1156 | iParent = primary->GetFirstMother(); | |
1157 | ||
d07278cf | 1158 | if(GetDebug() > 1 ) |
1159 | { | |
008693e5 | 1160 | printf("AliAnaCalorimeterQA::ClusterMCHistograms() - Cluster most contributing mother: \n"); |
649b825d | 1161 | printf("\t Mother label %d, pdg %d, %s, status %d, parent %d \n",iMother, pdg0, primary->GetName(),status, iParent); |
1162 | } | |
1163 | ||
1164 | //Get final particle, no conversion products | |
d07278cf | 1165 | if(GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCConversion)) |
1166 | { | |
649b825d | 1167 | //Get the parent |
1168 | primary = GetMCStack()->Particle(iParent); | |
1169 | pdg = TMath::Abs(primary->GetPdgCode()); | |
008693e5 | 1170 | |
1171 | if(GetDebug() > 1 ) printf("AliAnaCalorimeterQA::ClusterMCHistograms() - Converted cluster!. Find before conversion: \n"); | |
1172 | ||
d07278cf | 1173 | while((pdg == 22 || pdg == 11) && status != 1) |
1174 | { | |
008693e5 | 1175 | Int_t iMotherOrg = iMother; |
649b825d | 1176 | iMother = iParent; |
1177 | primary = GetMCStack()->Particle(iMother); | |
1178 | status = primary->GetStatusCode(); | |
649b825d | 1179 | pdg = TMath::Abs(primary->GetPdgCode()); |
008693e5 | 1180 | iParent = primary->GetFirstMother(); |
1181 | ||
1182 | // If gone too back and non stable, assign the decay photon/electron | |
1183 | // there are other possible decays, ignore them for the moment | |
1184 | if(pdg==111 || pdg==221) | |
1185 | { | |
1186 | primary = GetMCStack()->Particle(iMotherOrg); | |
1187 | break; | |
1188 | } | |
1189 | ||
1190 | if( iParent < 0 ) | |
1191 | { | |
1192 | iParent = iMother; | |
008693e5 | 1193 | break; |
1194 | } | |
1195 | ||
649b825d | 1196 | if(GetDebug() > 1 )printf("\t pdg %d, index %d, %s, status %d \n",pdg, iMother, primary->GetName(),status); |
1197 | } | |
008693e5 | 1198 | |
d07278cf | 1199 | if(GetDebug() > 1 ) |
1200 | { | |
649b825d | 1201 | printf("AliAnaCalorimeterQA::ClusterHistograms() - Converted Cluster mother before conversion: \n"); |
1202 | printf("\t Mother label %d, pdg %d, %s, status %d, parent %d \n",iMother, pdg, primary->GetName(), status, iParent); | |
1203 | } | |
1204 | ||
1205 | } | |
1206 | ||
1207 | //Overlapped pi0 (or eta, there will be very few), get the meson | |
1208 | if(GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPi0) || | |
d07278cf | 1209 | GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCEta)) |
1210 | { | |
649b825d | 1211 | if(GetDebug() > 1 ) printf("AliAnaCalorimeterQA::ClusterHistograms() - Overlapped Meson decay!, Find it: \n"); |
008693e5 | 1212 | |
d07278cf | 1213 | while(pdg != 111 && pdg != 221) |
008693e5 | 1214 | { |
1215 | //printf("iMother %d, pdg %d, iParent %d, pdg %d\n",iMother,pdg,iParent,GetMCStack()->Particle(iParent)->GetPdgCode()); | |
649b825d | 1216 | iMother = iParent; |
1217 | primary = GetMCStack()->Particle(iMother); | |
1218 | status = primary->GetStatusCode(); | |
649b825d | 1219 | pdg = TMath::Abs(primary->GetPdgCode()); |
008693e5 | 1220 | iParent = primary->GetFirstMother(); |
1221 | ||
1222 | if( iParent < 0 )break; | |
1223 | ||
649b825d | 1224 | if(GetDebug() > 1 ) printf("\t pdg %d, %s, index %d\n",pdg, primary->GetName(),iMother); |
008693e5 | 1225 | |
d07278cf | 1226 | if(iMother==-1) |
1227 | { | |
649b825d | 1228 | printf("AliAnaCalorimeterQA::ClusterHistograms() - Tagged as Overlapped photon but meson not found, why?\n"); |
1229 | //break; | |
1230 | } | |
1231 | } | |
008693e5 | 1232 | |
649b825d | 1233 | if(GetDebug() > 2 ) printf("AliAnaCalorimeterQA::ClusterHistograms() - Overlapped %s decay, label %d \n", |
1234 | primary->GetName(),iMother); | |
1235 | } | |
1236 | ||
1237 | eMC = primary->Energy(); | |
ecdde216 | 1238 | //ptMC = primary->Pt(); |
649b825d | 1239 | phiMC = primary->Phi(); |
1240 | etaMC = primary->Eta(); | |
1241 | pdg = TMath::Abs(primary->GetPdgCode()); | |
1242 | charge = (Int_t) TDatabasePDG::Instance()->GetParticle(pdg)->Charge(); | |
1243 | ||
1244 | } | |
d07278cf | 1245 | else if( GetReader()->ReadAODMCParticles() && |
1246 | !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCUnknown)) | |
1247 | {//it MC AOD and known tag | |
649b825d | 1248 | //Get the list of MC particles |
2644ead9 | 1249 | if(!GetReader()->GetAODMCParticles()) |
649b825d | 1250 | AliFatal("MCParticles not available!"); |
1251 | ||
2644ead9 | 1252 | aodprimary = (AliAODMCParticle*) (GetReader()->GetAODMCParticles())->At(label); |
649b825d | 1253 | iMother = label; |
1254 | pdg0 = TMath::Abs(aodprimary->GetPdgCode()); | |
1255 | pdg = pdg0; | |
1256 | status = aodprimary->IsPrimary(); | |
1257 | vxMC = aodprimary->Xv(); | |
1258 | vyMC = aodprimary->Yv(); | |
1259 | iParent = aodprimary->GetMother(); | |
1260 | ||
45769d5b | 1261 | if( GetDebug() > 1 ) |
d07278cf | 1262 | { |
649b825d | 1263 | printf("AliAnaCalorimeterQA::ClusterHistograms() - Cluster most contributing mother: \n"); |
1264 | printf("\t Mother label %d, pdg %d, Primary? %d, Physical Primary? %d, parent %d \n", | |
1265 | iMother, pdg0, aodprimary->IsPrimary(), aodprimary->IsPhysicalPrimary(), iParent); | |
1266 | } | |
1267 | ||
1268 | //Get final particle, no conversion products | |
45769d5b | 1269 | if( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCConversion) ) |
008693e5 | 1270 | { |
45769d5b | 1271 | if( GetDebug() > 1 ) |
649b825d | 1272 | printf("AliAnaCalorimeterQA::ClusterHistograms() - Converted cluster!. Find before conversion: \n"); |
1273 | //Get the parent | |
2644ead9 | 1274 | aodprimary = (AliAODMCParticle*)(GetReader()->GetAODMCParticles())->At(iParent); |
649b825d | 1275 | pdg = TMath::Abs(aodprimary->GetPdgCode()); |
d07278cf | 1276 | while ((pdg == 22 || pdg == 11) && !aodprimary->IsPhysicalPrimary()) |
1277 | { | |
008693e5 | 1278 | Int_t iMotherOrg = iMother; |
649b825d | 1279 | iMother = iParent; |
2644ead9 | 1280 | aodprimary = (AliAODMCParticle*)(GetReader()->GetAODMCParticles())->At(iMother); |
649b825d | 1281 | status = aodprimary->IsPrimary(); |
1282 | iParent = aodprimary->GetMother(); | |
1283 | pdg = TMath::Abs(aodprimary->GetPdgCode()); | |
008693e5 | 1284 | |
1285 | // If gone too back and non stable, assign the decay photon/electron | |
1286 | // there are other possible decays, ignore them for the moment | |
45769d5b | 1287 | if( pdg == 111 || pdg == 221 ) |
008693e5 | 1288 | { |
2644ead9 | 1289 | aodprimary = (AliAODMCParticle*)(GetReader()->GetAODMCParticles())->At(iMotherOrg); |
008693e5 | 1290 | break; |
1291 | } | |
1292 | ||
45769d5b | 1293 | if( iParent < 0 ) |
008693e5 | 1294 | { |
1295 | iParent = iMother; | |
1296 | break; | |
1297 | } | |
1298 | ||
45769d5b | 1299 | if( GetDebug() > 1 ) |
649b825d | 1300 | printf("\t pdg %d, index %d, Primary? %d, Physical Primary? %d \n", |
1301 | pdg, iMother, aodprimary->IsPrimary(), aodprimary->IsPhysicalPrimary()); | |
1302 | } | |
1303 | ||
45769d5b | 1304 | if( GetDebug() > 1 ) |
d07278cf | 1305 | { |
649b825d | 1306 | printf("AliAnaCalorimeterQA::ClusterHistograms() - Converted Cluster mother before conversion: \n"); |
1307 | printf("\t Mother label %d, pdg %d, parent %d, Primary? %d, Physical Primary? %d \n", | |
1308 | iMother, pdg, iParent, aodprimary->IsPrimary(), aodprimary->IsPhysicalPrimary()); | |
1309 | } | |
649b825d | 1310 | } |
1311 | ||
1312 | //Overlapped pi0 (or eta, there will be very few), get the meson | |
1313 | if(GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPi0) || | |
2747966a | 1314 | GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCEta)) |
1315 | { | |
649b825d | 1316 | if(GetDebug() > 1 ) printf("AliAnaCalorimeterQA::ClusterHistograms() - Overlapped Meson decay!, Find it: PDG %d, mom %d \n",pdg, iMother); |
45769d5b | 1317 | |
008693e5 | 1318 | while(pdg != 111 && pdg != 221) |
1319 | { | |
649b825d | 1320 | iMother = iParent; |
2644ead9 | 1321 | aodprimary = (AliAODMCParticle*)(GetReader()->GetAODMCParticles())->At(iMother); |
649b825d | 1322 | status = aodprimary->IsPrimary(); |
1323 | iParent = aodprimary->GetMother(); | |
1324 | pdg = TMath::Abs(aodprimary->GetPdgCode()); | |
008693e5 | 1325 | |
45769d5b | 1326 | if( iParent < 0 ) break; |
649b825d | 1327 | |
45769d5b | 1328 | if( GetDebug() > 1 ) printf("\t pdg %d, index %d\n",pdg, iMother); |
649b825d | 1329 | |
2747966a | 1330 | if(iMother==-1) |
1331 | { | |
649b825d | 1332 | printf("AliAnaCalorimeterQA::ClusterHistograms() - Tagged as Overlapped photon but meson not found, why?\n"); |
1333 | //break; | |
1334 | } | |
1335 | } | |
1336 | ||
1337 | if(GetDebug() > 2 ) printf("AliAnaCalorimeterQA::ClusterHistograms() - Overlapped %s decay, label %d \n", | |
1338 | aodprimary->GetName(),iMother); | |
1339 | } | |
1340 | ||
1341 | status = aodprimary->IsPrimary(); | |
1342 | eMC = aodprimary->E(); | |
ecdde216 | 1343 | //ptMC = aodprimary->Pt(); |
649b825d | 1344 | phiMC = aodprimary->Phi(); |
1345 | etaMC = aodprimary->Eta(); | |
1346 | pdg = TMath::Abs(aodprimary->GetPdgCode()); | |
1347 | charge = aodprimary->Charge(); | |
1348 | ||
1349 | } | |
1350 | ||
1351 | //Float_t vz = primary->Vz(); | |
1352 | Float_t rVMC = TMath::Sqrt(vxMC*vxMC + vyMC*vyMC); | |
45769d5b | 1353 | if( ( pdg == 22 || TMath::Abs(pdg) == 11 ) && status != 1 ) |
2747966a | 1354 | { |
649b825d | 1355 | fhEMVxyz ->Fill(vxMC,vyMC);//,vz); |
1356 | fhEMR ->Fill(e,rVMC); | |
1357 | } | |
1358 | ||
1359 | //printf("reco e %f, pt %f, phi %f, eta %f \n", e, pt, phi, eta); | |
1360 | //printf("prim e %f, pt %f, phi %f, eta %f \n", eMC,ptMC,phiMC ,etaMC ); | |
1361 | //printf("vertex: vx %f, vy %f, vz %f, r %f \n", vxMC, vyMC, vz, r); | |
1362 | ||
1363 | //Overlapped pi0 (or eta, there will be very few) | |
6aba6683 | 1364 | Int_t mcIndex = -1; |
1365 | if ( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPi0 ) ) | |
2747966a | 1366 | { |
6aba6683 | 1367 | mcIndex = kmcPi0; |
649b825d | 1368 | }//Overlapped pizero decay |
6aba6683 | 1369 | else if( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCEta ) ) |
2747966a | 1370 | { |
6aba6683 | 1371 | mcIndex = kmcEta; |
649b825d | 1372 | }//Overlapped eta decay |
6aba6683 | 1373 | else if( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPhoton ) ) |
2747966a | 1374 | { |
6aba6683 | 1375 | if( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCConversion)) |
1376 | mcIndex = kmcPhotonConv ; | |
1377 | else | |
1378 | mcIndex = kmcPhoton ; | |
649b825d | 1379 | }//photon |
6aba6683 | 1380 | else if( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCElectron) ) |
2747966a | 1381 | { |
6aba6683 | 1382 | mcIndex = kmcElectron; |
1383 | fhEMVxyz ->Fill(vxMC,vyMC);//,vz); | |
1384 | fhEMR ->Fill(e,rVMC); | |
649b825d | 1385 | } |
2747966a | 1386 | else if(charge == 0) |
1387 | { | |
6aba6683 | 1388 | mcIndex = kmcNeHadron; |
649b825d | 1389 | fhHaVxyz ->Fill(vxMC,vyMC);//,vz); |
1390 | fhHaR ->Fill(e,rVMC); | |
1391 | } | |
2747966a | 1392 | else if(charge!=0) |
1393 | { | |
6aba6683 | 1394 | mcIndex = kmcChHadron; |
1395 | fhHaVxyz ->Fill(vxMC,vyMC);//,vz); | |
1396 | fhHaR ->Fill(e,rVMC); | |
1397 | } | |
1398 | ||
1399 | //printf("mc index %d\n",mcIndex); | |
1400 | ||
1401 | if( mcIndex >= 0 && mcIndex < 7 ) | |
1402 | { | |
1403 | fhRecoMCE [mcIndex][(matched)] ->Fill(e,eMC); | |
1404 | if(e > 0.5 && eMC > 0.5) fhRecoMCEta[mcIndex][(matched)]->Fill(eta,etaMC); | |
1405 | if(e > 0.5 && eMC > 0.5) fhRecoMCPhi[mcIndex][(matched)]->Fill(phi,phiMC); | |
1406 | if(eMC > 0) fhRecoMCRatioE [mcIndex][(matched)]->Fill(e,e/eMC); | |
1407 | fhRecoMCDeltaE [mcIndex][(matched)]->Fill(e,eMC-e); | |
1408 | fhRecoMCDeltaPhi[mcIndex][(matched)]->Fill(e,phiMC-phi); | |
1409 | fhRecoMCDeltaEta[mcIndex][(matched)]->Fill(e,etaMC-eta); | |
649b825d | 1410 | } |
1411 | ||
45769d5b | 1412 | if( primary || aodprimary ) return kTRUE ; |
1413 | else return kFALSE; | |
649b825d | 1414 | |
1415 | } | |
1416 | ||
1417 | //________________________________________________________________________________________________ | |
1418 | void AliAnaCalorimeterQA::ClusterMatchedWithTrackHistograms(AliVCluster *clus, TLorentzVector mom, | |
b94e038e | 1419 | Bool_t okPrimary, Int_t pdg) |
649b825d | 1420 | { |
1421 | //Histograms for clusters matched with tracks | |
42d47cb7 | 1422 | |
649b825d | 1423 | Float_t e = mom.E(); |
1424 | Float_t pt = mom.Pt(); | |
1425 | Float_t eta = mom.Eta(); | |
1426 | Float_t phi = mom.Phi(); | |
1427 | if(phi < 0) phi +=TMath::TwoPi(); | |
45769d5b | 1428 | |
1429 | fhECharged ->Fill(e); | |
1430 | fhPtCharged ->Fill(pt); | |
1431 | fhPhiCharged ->Fill(phi); | |
1432 | fhEtaCharged ->Fill(eta); | |
a82b4462 | 1433 | |
42d47cb7 | 1434 | //Study the track and matched cluster if track exists. |
1435 | ||
4bfeae64 | 1436 | AliVTrack *track = GetCaloUtils()->GetMatchedTrack(clus, GetReader()->GetInputEvent()); |
649b825d | 1437 | |
1438 | if(!track) return ; | |
649b825d | 1439 | |
a87e069d | 1440 | Double_t tpt = track->Pt(); |
1441 | Double_t tmom = track->P(); | |
1442 | Double_t dedx = track->GetTPCsignal(); | |
1443 | Int_t nITS = track->GetNcls(0); | |
1444 | Int_t nTPC = track->GetNcls(1); | |
653aed3c | 1445 | Bool_t positive = kFALSE; |
1446 | if(track) positive = (track->Charge()>0); | |
a87e069d | 1447 | |
1448 | // Residuals | |
1449 | Float_t deta = clus->GetTrackDz(); | |
1450 | Float_t dphi = clus->GetTrackDx(); | |
1451 | Double_t dR = TMath::Sqrt(dphi*dphi + deta*deta); | |
1452 | ||
653aed3c | 1453 | if(TMath::Abs(dphi) < 999) |
1454 | { | |
1455 | fhTrackMatchedDEta->Fill(e,deta); | |
1456 | fhTrackMatchedDPhi->Fill(e,dphi); | |
1457 | if(e > 0.5) fhTrackMatchedDEtaDPhi->Fill(deta,dphi); | |
1458 | ||
1459 | if(track && positive) | |
1460 | { | |
653aed3c | 1461 | fhTrackMatchedDEtaPos->Fill(e,deta); |
1462 | fhTrackMatchedDPhiPos->Fill(e,dphi); | |
1463 | if(e > 0.5) fhTrackMatchedDEtaDPhiPos->Fill(deta,dphi); | |
1464 | } | |
1465 | } | |
a87e069d | 1466 | |
653aed3c | 1467 | Double_t eOverP = e/tmom; |
d55bb5e1 | 1468 | fh1EOverP->Fill(tpt, eOverP); |
653aed3c | 1469 | if(dR < 0.02) |
1470 | { | |
a054a582 | 1471 | fh1EOverPR02->Fill(tpt,eOverP); |
1472 | if(dedx > 60 && dedx < 100) fh1EleEOverP->Fill(tpt,eOverP); | |
1473 | } | |
a87e069d | 1474 | |
1475 | fh2dR->Fill(e,dR); | |
1476 | fh2MatchdEdx->Fill(tmom,dedx); | |
1477 | ||
1478 | if(IsDataMC() && okPrimary) | |
1479 | { | |
1480 | Double_t charge = TDatabasePDG::Instance()->GetParticle(pdg)->Charge(); | |
649b825d | 1481 | |
a87e069d | 1482 | if(TMath::Abs(pdg) == 11) |
1483 | { | |
d55bb5e1 | 1484 | fhMCEle1EOverP->Fill(tpt,eOverP); |
a87e069d | 1485 | fhMCEle1dR->Fill(dR); |
1486 | fhMCEle2MatchdEdx->Fill(tmom,dedx); | |
653aed3c | 1487 | if(dR < 0.02) |
1488 | { | |
1489 | fhMCEle1EOverPR02->Fill(tpt,eOverP); | |
1490 | if(dedx > 60 && dedx < 100) fhMCEle1EleEOverP->Fill(tpt,eOverP); | |
a054a582 | 1491 | } |
a87e069d | 1492 | } |
1493 | else if(charge!=0) | |
1494 | { | |
d55bb5e1 | 1495 | fhMCChHad1EOverP->Fill(tpt,eOverP); |
a87e069d | 1496 | fhMCChHad1dR->Fill(dR); |
1497 | fhMCChHad2MatchdEdx->Fill(tmom,dedx); | |
653aed3c | 1498 | if(dR < 0.02) |
1499 | { | |
1500 | fhMCChHad1EOverPR02->Fill(tpt,eOverP); | |
1501 | if(dedx > 60 && dedx < 100) fhMCChHad1EleEOverP->Fill(tpt,eOverP); | |
a054a582 | 1502 | } |
a87e069d | 1503 | } |
1504 | else if(charge == 0) | |
1505 | { | |
d55bb5e1 | 1506 | fhMCNeutral1EOverP->Fill(tpt,eOverP); |
a87e069d | 1507 | fhMCNeutral1dR->Fill(dR); |
1508 | fhMCNeutral2MatchdEdx->Fill(tmom,dedx); | |
653aed3c | 1509 | if(dR < 0.02) |
1510 | { | |
1511 | fhMCNeutral1EOverPR02->Fill(tpt,eOverP); | |
1512 | if(dedx > 60 && dedx < 100) fhMCNeutral1EleEOverP->Fill(tpt,eOverP); | |
a054a582 | 1513 | } |
649b825d | 1514 | } |
a87e069d | 1515 | }//DataMC |
1516 | ||
45769d5b | 1517 | if(dR < 0.02 && eOverP > 0.6 && eOverP < 1.2 |
a87e069d | 1518 | && clus->GetNCells() > 1 && nITS > 3 && nTPC > 20) |
1519 | { | |
1520 | fh2EledEdx->Fill(tmom,dedx); | |
649b825d | 1521 | } |
a87e069d | 1522 | |
649b825d | 1523 | } |
1524 | ||
1525 | //___________________________________ | |
1526 | void AliAnaCalorimeterQA::Correlate() | |
1527 | { | |
1528 | // Correlate information from PHOS and EMCAL and with V0 and track multiplicity | |
1529 | ||
95aee5e1 | 1530 | //Clusters arrays |
649b825d | 1531 | TObjArray * caloClustersEMCAL = GetEMCALClusters(); |
1532 | TObjArray * caloClustersPHOS = GetPHOSClusters(); | |
1533 | ||
95aee5e1 | 1534 | if(!caloClustersEMCAL || !caloClustersPHOS) |
1535 | { | |
1536 | if( GetDebug() > 0 ) printf("AliAnaCalorimeterQA::Correlate() - PHOS (%p) or EMCAL (%p) clusters array not available, do not correlate\n", | |
1537 | caloClustersPHOS,caloClustersEMCAL); | |
1538 | return ; | |
1539 | } | |
1540 | ||
1541 | //Cells arrays | |
1542 | AliVCaloCells * cellsEMCAL = GetEMCALCells(); | |
1543 | AliVCaloCells * cellsPHOS = GetPHOSCells(); | |
1544 | ||
1545 | if(!cellsEMCAL || !cellsPHOS) | |
1546 | { | |
1547 | if( GetDebug() > 0 ) printf("AliAnaCalorimeterQA::Correlate() - PHOS (%p) or EMCAL (%p) cells array ot available, do not correlate\n", | |
1548 | cellsPHOS,cellsEMCAL); | |
1549 | return ; | |
1550 | } | |
1551 | ||
1552 | // Clusters parameters | |
649b825d | 1553 | Int_t nclEMCAL = caloClustersEMCAL->GetEntriesFast(); |
1554 | Int_t nclPHOS = caloClustersPHOS ->GetEntriesFast(); | |
1555 | ||
653aed3c | 1556 | Float_t cen = GetEventCentrality(); |
1557 | Float_t ep = GetEventPlaneAngle(); | |
1558 | ||
649b825d | 1559 | Float_t sumClusterEnergyEMCAL = 0; |
1560 | Float_t sumClusterEnergyPHOS = 0; | |
1561 | Int_t iclus = 0; | |
1562 | for(iclus = 0 ; iclus < caloClustersEMCAL->GetEntriesFast() ; iclus++) | |
1563 | sumClusterEnergyEMCAL += ((AliVCluster*)caloClustersEMCAL->At(iclus))->E(); | |
1564 | for(iclus = 0 ; iclus < caloClustersPHOS->GetEntriesFast(); iclus++) | |
1565 | sumClusterEnergyPHOS += ((AliVCluster*)caloClustersPHOS->At(iclus))->E(); | |
1566 | ||
95aee5e1 | 1567 | //Cells parameters |
649b825d | 1568 | Int_t ncellsEMCAL = cellsEMCAL->GetNumberOfCells(); |
1569 | Int_t ncellsPHOS = cellsPHOS ->GetNumberOfCells(); | |
1570 | ||
1571 | Float_t sumCellEnergyEMCAL = 0; | |
1572 | Float_t sumCellEnergyPHOS = 0; | |
1573 | Int_t icell = 0; | |
1574 | for(icell = 0 ; icell < cellsEMCAL->GetNumberOfCells() ; icell++) | |
1575 | sumCellEnergyEMCAL += cellsEMCAL->GetAmplitude(icell); | |
1576 | for(icell = 0 ; icell < cellsPHOS->GetNumberOfCells(); icell++) | |
1577 | sumCellEnergyPHOS += cellsPHOS->GetAmplitude(icell); | |
1578 | ||
1579 | ||
1580 | //Fill Histograms | |
1581 | fhCaloCorrNClusters->Fill(nclEMCAL,nclPHOS); | |
1582 | fhCaloCorrEClusters->Fill(sumClusterEnergyEMCAL,sumClusterEnergyPHOS); | |
1583 | fhCaloCorrNCells ->Fill(ncellsEMCAL,ncellsPHOS); | |
1584 | fhCaloCorrECells ->Fill(sumCellEnergyEMCAL,sumCellEnergyPHOS); | |
1585 | ||
1586 | Int_t v0S = GetV0Signal(0)+GetV0Signal(1); | |
1587 | Int_t v0M = GetV0Multiplicity(0)+GetV0Multiplicity(1); | |
1588 | Int_t trM = GetTrackMultiplicity(); | |
653aed3c | 1589 | if(fCalorimeter=="PHOS") |
1590 | { | |
649b825d | 1591 | fhCaloV0MCorrNClusters ->Fill(v0M,nclPHOS); |
1592 | fhCaloV0MCorrEClusters ->Fill(v0M,sumClusterEnergyPHOS); | |
1593 | fhCaloV0MCorrNCells ->Fill(v0M,ncellsPHOS); | |
1594 | fhCaloV0MCorrECells ->Fill(v0M,sumCellEnergyPHOS); | |
1595 | ||
1596 | fhCaloV0SCorrNClusters ->Fill(v0S,nclPHOS); | |
1597 | fhCaloV0SCorrEClusters ->Fill(v0S,sumClusterEnergyPHOS); | |
1598 | fhCaloV0SCorrNCells ->Fill(v0S,ncellsPHOS); | |
1599 | fhCaloV0SCorrECells ->Fill(v0S,sumCellEnergyPHOS); | |
1600 | ||
1601 | fhCaloTrackMCorrNClusters->Fill(trM,nclPHOS); | |
1602 | fhCaloTrackMCorrEClusters->Fill(trM,sumClusterEnergyPHOS); | |
1603 | fhCaloTrackMCorrNCells ->Fill(trM,ncellsPHOS); | |
1604 | fhCaloTrackMCorrECells ->Fill(trM,sumCellEnergyPHOS); | |
653aed3c | 1605 | |
1606 | fhCaloCenNClusters ->Fill(cen,nclPHOS); | |
1607 | fhCaloCenEClusters ->Fill(cen,sumClusterEnergyPHOS); | |
1608 | fhCaloCenNCells ->Fill(cen,ncellsPHOS); | |
1609 | fhCaloCenECells ->Fill(cen,sumCellEnergyPHOS); | |
1610 | ||
1611 | fhCaloEvPNClusters ->Fill(ep ,nclPHOS); | |
1612 | fhCaloEvPEClusters ->Fill(ep ,sumClusterEnergyPHOS); | |
1613 | fhCaloEvPNCells ->Fill(ep ,ncellsPHOS); | |
1614 | fhCaloEvPECells ->Fill(ep ,sumCellEnergyPHOS); | |
649b825d | 1615 | } |
653aed3c | 1616 | else |
1617 | { | |
649b825d | 1618 | fhCaloV0MCorrNClusters ->Fill(v0M,nclEMCAL); |
1619 | fhCaloV0MCorrEClusters ->Fill(v0M,sumClusterEnergyEMCAL); | |
1620 | fhCaloV0MCorrNCells ->Fill(v0M,ncellsEMCAL); | |
1621 | fhCaloV0MCorrECells ->Fill(v0M,sumCellEnergyEMCAL); | |
1622 | ||
1623 | fhCaloV0SCorrNClusters ->Fill(v0S,nclEMCAL); | |
1624 | fhCaloV0SCorrEClusters ->Fill(v0S,sumClusterEnergyEMCAL); | |
1625 | fhCaloV0SCorrNCells ->Fill(v0S,ncellsEMCAL); | |
1626 | fhCaloV0SCorrECells ->Fill(v0S,sumCellEnergyEMCAL); | |
1627 | ||
1628 | fhCaloTrackMCorrNClusters->Fill(trM,nclEMCAL); | |
1629 | fhCaloTrackMCorrEClusters->Fill(trM,sumClusterEnergyEMCAL); | |
1630 | fhCaloTrackMCorrNCells ->Fill(trM,ncellsEMCAL); | |
1631 | fhCaloTrackMCorrECells ->Fill(trM,sumCellEnergyEMCAL); | |
653aed3c | 1632 | |
1633 | fhCaloCenNClusters ->Fill(cen,nclEMCAL); | |
1634 | fhCaloCenEClusters ->Fill(cen,sumClusterEnergyEMCAL); | |
1635 | fhCaloCenNCells ->Fill(cen,ncellsEMCAL); | |
1636 | fhCaloCenECells ->Fill(cen,sumCellEnergyEMCAL); | |
1637 | ||
1638 | fhCaloEvPNClusters ->Fill(ep ,nclEMCAL); | |
1639 | fhCaloEvPEClusters ->Fill(ep ,sumClusterEnergyEMCAL); | |
1640 | fhCaloEvPNCells ->Fill(ep ,ncellsEMCAL); | |
1641 | fhCaloEvPECells ->Fill(ep ,sumCellEnergyEMCAL); | |
649b825d | 1642 | } |
1643 | ||
1644 | if(GetDebug() > 0 ) | |
1645 | { | |
1646 | printf("AliAnaCalorimeterQA::Correlate(): \n"); | |
1647 | printf("\t EMCAL: N cells %d, N clusters %d, summed E cells %f, summed E clusters %f \n", | |
1648 | ncellsEMCAL,nclEMCAL, sumCellEnergyEMCAL,sumClusterEnergyEMCAL); | |
1649 | printf("\t PHOS : N cells %d, N clusters %d, summed E cells %f, summed E clusters %f \n", | |
1650 | ncellsPHOS,nclPHOS,sumCellEnergyPHOS,sumClusterEnergyPHOS); | |
1651 | printf("\t V0 : Signal %d, Multiplicity %d, Track Multiplicity %d \n", v0S,v0M,trM); | |
653aed3c | 1652 | printf("\t centrality : %f, Event plane angle %f \n", cen,ep); |
649b825d | 1653 | } |
1654 | ||
1655 | } | |
1656 | ||
1657 | //__________________________________________________ | |
1658 | TObjString * AliAnaCalorimeterQA::GetAnalysisCuts() | |
1659 | { | |
1660 | //Save parameters used for analysis | |
1661 | TString parList ; //this will be list of parameters used for this analysis. | |
1662 | const Int_t buffersize = 255; | |
1663 | char onePar[buffersize] ; | |
1664 | ||
1665 | snprintf(onePar,buffersize,"--- AliAnaCalorimeterQA ---\n") ; | |
1666 | parList+=onePar ; | |
1667 | snprintf(onePar,buffersize,"Calorimeter: %s\n",fCalorimeter.Data()) ; | |
1668 | parList+=onePar ; | |
1669 | snprintf(onePar,buffersize,"Time Cut : %2.2f < T < %2.2f ns \n",fTimeCutMin, fTimeCutMax) ; | |
1670 | parList+=onePar ; | |
1671 | snprintf(onePar,buffersize,"PHOS Cell Amplitude > %2.2f GeV, EMCAL Cell Amplitude > %2.2f GeV \n",fPHOSCellAmpMin, fEMCALCellAmpMin) ; | |
1672 | parList+=onePar ; | |
07e4c878 | 1673 | snprintf(onePar,buffersize,"Inv. Mass E1, E2 > %2.2f GeV \n",fMinInvMassECut) ; |
1674 | parList+=onePar ; | |
1675 | ||
649b825d | 1676 | //Get parameters set in base class. |
1677 | //parList += GetBaseParametersList() ; | |
1678 | ||
1679 | //Get parameters set in FiducialCut class (not available yet) | |
1680 | //parlist += GetFidCut()->GetFidCutParametersList() | |
1681 | ||
1682 | return new TObjString(parList) ; | |
1683 | } | |
1684 | ||
b94e038e | 1685 | //_________________________________________________________________________________ |
1686 | void AliAnaCalorimeterQA::ExoticHistograms(Int_t absIdMax, Float_t ampMax, | |
f1538a5f | 1687 | AliVCluster *clus, AliVCaloCells* cells) |
1688 | { | |
1689 | // Calculate weights | |
1690 | ||
1691 | if(ampMax < 0.01) | |
1692 | { | |
1693 | printf("AliAnaCalorimeterQA::ExoticHistograms()- Low amplitude energy %f\n",ampMax); | |
1694 | return; | |
1695 | } | |
1696 | ||
cc11121e | 1697 | Float_t l0 = clus->GetM02(); |
765206a5 | 1698 | Float_t l1 = clus->GetM20(); |
cc11121e | 1699 | Float_t en = clus->E(); |
1700 | Int_t nc = clus->GetNCells(); | |
765206a5 | 1701 | Double_t tmax = clus->GetTOF()*1.e9; // recalibrated elsewhere |
1702 | ||
1703 | Float_t eCrossFrac = 1-GetECross(absIdMax,cells, 10000000)/ampMax; | |
1704 | ||
1705 | if(en > 5) | |
1706 | { | |
1707 | fhExoL0ECross->Fill(eCrossFrac,l0); | |
1708 | fhExoL1ECross->Fill(eCrossFrac,l1); | |
1709 | } | |
f1538a5f | 1710 | |
1711 | for(Int_t ie = 0; ie < fExoNECrossCuts; ie++) | |
1712 | { | |
1713 | for(Int_t idt = 0; idt < fExoNDTimeCuts; idt++) | |
1714 | { | |
765206a5 | 1715 | eCrossFrac = 1-GetECross(absIdMax,cells, fExoDTimeCuts[idt])/ampMax; |
f1538a5f | 1716 | |
1717 | if(eCrossFrac > fExoECrossCuts[ie]) | |
1718 | { | |
1719 | //Exotic | |
1720 | fhExoL0 [ie][idt]->Fill(en,l0 ); | |
765206a5 | 1721 | fhExoL1 [ie][idt]->Fill(en,l1 ); |
1722 | fhExoTime [ie][idt]->Fill(en,tmax); | |
1723 | ||
1724 | if(en > 5) | |
1725 | { | |
1726 | fhExoL0NCell[ie][idt]->Fill(nc,l0); | |
1727 | fhExoL1NCell[ie][idt]->Fill(nc,l1); | |
1728 | } | |
f1538a5f | 1729 | |
1730 | // Diff time, do for one cut in e cross | |
1731 | if(ie == 0) | |
1732 | { | |
1733 | for (Int_t icell = 0; icell < clus->GetNCells(); icell++) | |
1734 | { | |
1735 | Int_t absId = clus->GetCellsAbsId()[icell]; | |
1736 | Double_t time = cells->GetCellTime(absId); | |
1737 | GetCaloUtils()->RecalibrateCellTime(time, fCalorimeter, absId,GetReader()->GetInputEvent()->GetBunchCrossNumber()); | |
1738 | ||
1739 | Float_t diff = (tmax-time)*1e9; | |
1740 | fhExoDTime[idt]->Fill(en, diff); | |
1741 | } | |
1742 | } | |
1743 | } | |
1744 | else | |
1745 | { | |
1746 | fhExoECross[ie][idt]->Fill(en,eCrossFrac); | |
cc11121e | 1747 | fhExoNCell [ie][idt]->Fill(en,nc); |
f1538a5f | 1748 | } |
1749 | } // D time cut loop | |
1750 | } // e cross cut loop | |
1751 | } | |
1752 | ||
649b825d | 1753 | //____________________________________________________ |
1754 | TList * AliAnaCalorimeterQA::GetCreateOutputObjects() | |
1755 | { | |
1756 | // Create histograms to be saved in output file and | |
1757 | // store them in outputContainer | |
1758 | ||
1759 | TList * outputContainer = new TList() ; | |
1760 | outputContainer->SetName("QAHistos") ; | |
1761 | ||
9f48b3f0 | 1762 | // Init the number of modules, set in the class AliCalorimeterUtils |
1763 | fNModules = GetCaloUtils()->GetNumberOfSuperModulesUsed(); | |
1764 | if(fCalorimeter=="PHOS" && fNModules > 4) fNModules = 4; | |
1765 | ||
649b825d | 1766 | //Histograms |
745913ae | 1767 | Int_t nptbins = GetHistogramRanges()->GetHistoPtBins(); Float_t ptmax = GetHistogramRanges()->GetHistoPtMax(); Float_t ptmin = GetHistogramRanges()->GetHistoPtMin(); |
1768 | Int_t nfineptbins = GetHistogramRanges()->GetHistoFinePtBins(); Float_t ptfinemax = GetHistogramRanges()->GetHistoFinePtMax(); Float_t ptfinemin = GetHistogramRanges()->GetHistoFinePtMin(); | |
1769 | Int_t nphibins = GetHistogramRanges()->GetHistoPhiBins(); Float_t phimax = GetHistogramRanges()->GetHistoPhiMax(); Float_t phimin = GetHistogramRanges()->GetHistoPhiMin(); | |
1770 | Int_t netabins = GetHistogramRanges()->GetHistoEtaBins(); Float_t etamax = GetHistogramRanges()->GetHistoEtaMax(); Float_t etamin = GetHistogramRanges()->GetHistoEtaMin(); | |
1771 | Int_t nmassbins = GetHistogramRanges()->GetHistoMassBins(); Float_t massmax = GetHistogramRanges()->GetHistoMassMax(); Float_t massmin = GetHistogramRanges()->GetHistoMassMin(); | |
1772 | Int_t nasymbins = GetHistogramRanges()->GetHistoAsymmetryBins(); Float_t asymmax = GetHistogramRanges()->GetHistoAsymmetryMax(); Float_t asymmin = GetHistogramRanges()->GetHistoAsymmetryMin(); | |
ec58c056 | 1773 | Int_t nPoverEbins = GetHistogramRanges()->GetHistoPOverEBins(); Float_t eOverPmax = GetHistogramRanges()->GetHistoPOverEMax(); Float_t eOverPmin = GetHistogramRanges()->GetHistoPOverEMin(); |
745913ae | 1774 | Int_t ndedxbins = GetHistogramRanges()->GetHistodEdxBins(); Float_t dedxmax = GetHistogramRanges()->GetHistodEdxMax(); Float_t dedxmin = GetHistogramRanges()->GetHistodEdxMin(); |
1775 | Int_t ndRbins = GetHistogramRanges()->GetHistodRBins(); Float_t dRmax = GetHistogramRanges()->GetHistodRMax(); Float_t dRmin = GetHistogramRanges()->GetHistodRMin(); | |
1776 | Int_t ntimebins = GetHistogramRanges()->GetHistoTimeBins(); Float_t timemax = GetHistogramRanges()->GetHistoTimeMax(); Float_t timemin = GetHistogramRanges()->GetHistoTimeMin(); | |
1777 | Int_t nclbins = GetHistogramRanges()->GetHistoNClustersBins(); Int_t nclmax = GetHistogramRanges()->GetHistoNClustersMax(); Int_t nclmin = GetHistogramRanges()->GetHistoNClustersMin(); | |
1778 | Int_t ncebins = GetHistogramRanges()->GetHistoNCellsBins(); Int_t ncemax = GetHistogramRanges()->GetHistoNCellsMax(); Int_t ncemin = GetHistogramRanges()->GetHistoNCellsMin(); | |
1779 | Int_t nceclbins = GetHistogramRanges()->GetHistoNClusterCellBins(); Int_t nceclmax = GetHistogramRanges()->GetHistoNClusterCellMax(); Int_t nceclmin = GetHistogramRanges()->GetHistoNClusterCellMin(); | |
1780 | Int_t nvdistbins = GetHistogramRanges()->GetHistoVertexDistBins(); Float_t vdistmax = GetHistogramRanges()->GetHistoVertexDistMax(); Float_t vdistmin = GetHistogramRanges()->GetHistoVertexDistMin(); | |
1781 | Int_t rbins = GetHistogramRanges()->GetHistoRBins(); Float_t rmax = GetHistogramRanges()->GetHistoRMax(); Float_t rmin = GetHistogramRanges()->GetHistoRMin(); | |
1782 | Int_t xbins = GetHistogramRanges()->GetHistoXBins(); Float_t xmax = GetHistogramRanges()->GetHistoXMax(); Float_t xmin = GetHistogramRanges()->GetHistoXMin(); | |
1783 | Int_t ybins = GetHistogramRanges()->GetHistoYBins(); Float_t ymax = GetHistogramRanges()->GetHistoYMax(); Float_t ymin = GetHistogramRanges()->GetHistoYMin(); | |
1784 | Int_t zbins = GetHistogramRanges()->GetHistoZBins(); Float_t zmax = GetHistogramRanges()->GetHistoZMax(); Float_t zmin = GetHistogramRanges()->GetHistoZMin(); | |
1785 | Int_t ssbins = GetHistogramRanges()->GetHistoShowerShapeBins(); Float_t ssmax = GetHistogramRanges()->GetHistoShowerShapeMax(); Float_t ssmin = GetHistogramRanges()->GetHistoShowerShapeMin(); | |
1786 | Int_t tdbins = GetHistogramRanges()->GetHistoDiffTimeBins() ; Float_t tdmax = GetHistogramRanges()->GetHistoDiffTimeMax(); Float_t tdmin = GetHistogramRanges()->GetHistoDiffTimeMin(); | |
1787 | ||
1788 | Int_t nv0sbins = GetHistogramRanges()->GetHistoV0SignalBins(); Int_t nv0smax = GetHistogramRanges()->GetHistoV0SignalMax(); Int_t nv0smin = GetHistogramRanges()->GetHistoV0SignalMin(); | |
1789 | Int_t nv0mbins = GetHistogramRanges()->GetHistoV0MultiplicityBins(); Int_t nv0mmax = GetHistogramRanges()->GetHistoV0MultiplicityMax(); Int_t nv0mmin = GetHistogramRanges()->GetHistoV0MultiplicityMin(); | |
1790 | Int_t ntrmbins = GetHistogramRanges()->GetHistoTrackMultiplicityBins(); Int_t ntrmmax = GetHistogramRanges()->GetHistoTrackMultiplicityMax(); Int_t ntrmmin = GetHistogramRanges()->GetHistoTrackMultiplicityMin(); | |
649b825d | 1791 | |
1792 | //EMCAL | |
1793 | fNMaxCols = 48; | |
1794 | fNMaxRows = 24; | |
1795 | fNRCU = 2 ; | |
1796 | //PHOS | |
f1538a5f | 1797 | if(fCalorimeter=="PHOS") |
1798 | { | |
649b825d | 1799 | fNMaxCols = 56; |
1800 | fNMaxRows = 64; | |
1801 | fNRCU = 4 ; | |
1802 | } | |
1803 | ||
78451bcd | 1804 | fhE = new TH1F ("hE","#it{E} reconstructed clusters ", nptbins*5,ptmin,ptmax*5); |
1805 | fhE->SetXTitle("#it{E} (GeV)"); | |
649b825d | 1806 | outputContainer->Add(fhE); |
1807 | ||
78451bcd | 1808 | fhPt = new TH1F ("hPt","#it{p}_{T} reconstructed clusters", nptbins,ptmin,ptmax); |
1809 | fhPt->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
45769d5b | 1810 | outputContainer->Add(fhPt); |
1811 | ||
1812 | fhPhi = new TH1F ("hPhi","#phi reconstructed clusters ",nphibins,phimin,phimax); | |
1813 | fhPhi->SetXTitle("#phi (rad)"); | |
1814 | outputContainer->Add(fhPhi); | |
1815 | ||
1816 | fhEta = new TH1F ("hEta","#eta reconstructed clusters ",netabins,etamin,etamax); | |
1817 | fhEta->SetXTitle("#eta "); | |
1818 | outputContainer->Add(fhEta); | |
1819 | ||
649b825d | 1820 | |
f1538a5f | 1821 | if(fFillAllTH3) |
1822 | { | |
649b825d | 1823 | fhEtaPhiE = new TH3F ("hEtaPhiE","#eta vs #phi vs energy, reconstructed clusters", |
1824 | netabins,etamin,etamax,nphibins,phimin,phimax,nptbins,ptmin,ptmax); | |
1825 | fhEtaPhiE->SetXTitle("#eta "); | |
1826 | fhEtaPhiE->SetYTitle("#phi (rad)"); | |
78451bcd | 1827 | fhEtaPhiE->SetZTitle("#it{E} (GeV) "); |
649b825d | 1828 | outputContainer->Add(fhEtaPhiE); |
1829 | } | |
1830 | ||
1831 | fhClusterTimeEnergy = new TH2F ("hClusterTimeEnergy","energy vs TOF, reconstructed clusters", | |
1832 | nptbins,ptmin,ptmax, ntimebins,timemin,timemax); | |
78451bcd | 1833 | fhClusterTimeEnergy->SetXTitle("#it{E} (GeV) "); |
649b825d | 1834 | fhClusterTimeEnergy->SetYTitle("TOF (ns)"); |
1835 | outputContainer->Add(fhClusterTimeEnergy); | |
1836 | ||
1837 | fhClusterPairDiffTimeE = new TH2F("hClusterPairDiffTimeE","cluster pair time difference vs E, only good clusters", | |
1838 | nptbins,ptmin,ptmax, tdbins,tdmin,tdmax); | |
78451bcd | 1839 | fhClusterPairDiffTimeE->SetXTitle("#it{E}_{cluster} (GeV)"); |
1840 | fhClusterPairDiffTimeE->SetYTitle("#Delta #it{t} (ns)"); | |
649b825d | 1841 | outputContainer->Add(fhClusterPairDiffTimeE); |
1842 | ||
1843 | fhLambda0 = new TH2F ("hLambda0","shower shape, #lambda^{2}_{0} vs E", | |
1844 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
78451bcd | 1845 | fhLambda0->SetXTitle("#it{E}_{cluster}"); |
649b825d | 1846 | fhLambda0->SetYTitle("#lambda^{2}_{0}"); |
1847 | outputContainer->Add(fhLambda0); | |
1848 | ||
1849 | fhLambda1 = new TH2F ("hLambda1","shower shape, #lambda^{2}_{1} vs E for bad cluster ", | |
1850 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
78451bcd | 1851 | fhLambda1->SetXTitle("#it{E}_{cluster}"); |
649b825d | 1852 | fhLambda1->SetYTitle("#lambda^{2}_{1}"); |
1853 | outputContainer->Add(fhLambda1); | |
1854 | ||
1855 | fhDispersion = new TH2F ("hDispersion","shower shape, Dispersion^{2} vs E for bad cluster ", | |
1856 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
78451bcd | 1857 | fhDispersion->SetXTitle("#it{E}_{cluster}"); |
649b825d | 1858 | fhDispersion->SetYTitle("Dispersion"); |
1859 | outputContainer->Add(fhDispersion); | |
1860 | ||
1861 | fhClusterMaxCellCloseCellRatio = new TH2F ("hClusterMaxCellCloseCellRatio","energy vs ratio of max cell / neighbour cell, reconstructed clusters", | |
1862 | nptbins,ptmin,ptmax, 100,0,1.); | |
78451bcd | 1863 | fhClusterMaxCellCloseCellRatio->SetXTitle("#it{E}_{cluster} (GeV) "); |
1864 | fhClusterMaxCellCloseCellRatio->SetYTitle("#it{E}_{cell i}/#it{E}_{cell max}"); | |
649b825d | 1865 | outputContainer->Add(fhClusterMaxCellCloseCellRatio); |
1866 | ||
1867 | fhClusterMaxCellCloseCellDiff = new TH2F ("hClusterMaxCellCloseCellDiff","energy vs ratio of max cell / neighbour cell, reconstructed clusters", | |
1868 | nptbins,ptmin,ptmax, 500,0,100.); | |
78451bcd | 1869 | fhClusterMaxCellCloseCellDiff->SetXTitle("#it{E}_{cluster} (GeV) "); |
1870 | fhClusterMaxCellCloseCellDiff->SetYTitle("#it{E}_{cell max}-#it{E}_{cell i} (GeV)"); | |
649b825d | 1871 | outputContainer->Add(fhClusterMaxCellCloseCellDiff); |
1872 | ||
1873 | fhClusterMaxCellDiff = new TH2F ("hClusterMaxCellDiff","energy vs difference of cluster energy - max cell energy / cluster energy, good clusters", | |
1874 | nptbins,ptmin,ptmax, 500,0,1.); | |
78451bcd | 1875 | fhClusterMaxCellDiff->SetXTitle("#it{E}_{cluster} (GeV) "); |
1876 | fhClusterMaxCellDiff->SetYTitle("(#it{E}_{cluster} - #it{E}_{cell max})/ #it{E}_{cluster}"); | |
649b825d | 1877 | outputContainer->Add(fhClusterMaxCellDiff); |
1878 | ||
1879 | fhClusterMaxCellDiffNoCut = new TH2F ("hClusterMaxCellDiffNoCut","energy vs difference of cluster energy - max cell energy / cluster energy", | |
1880 | nptbins,ptmin,ptmax, 500,0,1.); | |
78451bcd | 1881 | fhClusterMaxCellDiffNoCut->SetXTitle("#it{E}_{cluster} (GeV) "); |
1882 | fhClusterMaxCellDiffNoCut->SetYTitle("(#it{E}_{cluster} - #it{E}_{cell max})/ #it{E}_{cluster}"); | |
649b825d | 1883 | outputContainer->Add(fhClusterMaxCellDiffNoCut); |
1884 | ||
1a72f6c5 | 1885 | fhClusterMaxCellECross = new TH2F ("hClusterMaxCellECross","1 - Energy in cross around max energy cell / max energy cell vs cluster energy, good clusters", |
1886 | nptbins,ptmin,ptmax, 400,-1,1.); | |
78451bcd | 1887 | fhClusterMaxCellECross->SetXTitle("#it{E}_{cluster} (GeV) "); |
1888 | fhClusterMaxCellECross->SetYTitle("1- #it{E}_{cross}/#it{E}_{cell max}"); | |
1a72f6c5 | 1889 | outputContainer->Add(fhClusterMaxCellECross); |
1890 | ||
f1538a5f | 1891 | fhNCellsPerClusterNoCut = new TH2F ("hNCellsPerClusterNoCut","# cells per cluster vs energy, no bad clusters cut", |
1892 | nptbins,ptmin,ptmax, nceclbins,nceclmin,nceclmax); | |
78451bcd | 1893 | fhNCellsPerClusterNoCut->SetXTitle("#it{E} (GeV)"); |
1894 | fhNCellsPerClusterNoCut->SetYTitle("#it{n}_{cells}"); | |
f1538a5f | 1895 | outputContainer->Add(fhNCellsPerClusterNoCut); |
1896 | ||
1897 | fhNCellsPerCluster = new TH2F ("hNCellsPerCluster","# cells per cluster vs energy",nptbins,ptmin,ptmax, nceclbins,nceclmin,nceclmax); | |
78451bcd | 1898 | fhNCellsPerCluster->SetXTitle("#it{E} (GeV)"); |
1899 | fhNCellsPerCluster->SetYTitle("#it{n}_{cells}"); | |
f1538a5f | 1900 | outputContainer->Add(fhNCellsPerCluster); |
1901 | ||
1902 | fhNClusters = new TH1F ("hNClusters","# clusters", nclbins,nclmin,nclmax); | |
78451bcd | 1903 | fhNClusters->SetXTitle("#it{n}_{clusters}"); |
f1538a5f | 1904 | outputContainer->Add(fhNClusters); |
1905 | ||
1a83b960 | 1906 | if(fStudyBadClusters) |
1907 | { | |
649b825d | 1908 | fhBadClusterEnergy = new TH1F ("hBadClusterEnergy","Bad cluster energy", nptbins,ptmin,ptmax); |
78451bcd | 1909 | fhBadClusterEnergy->SetXTitle("#it{E}_{cluster} (GeV) "); |
649b825d | 1910 | outputContainer->Add(fhBadClusterEnergy); |
1911 | ||
1912 | fhBadClusterMaxCellCloseCellRatio = new TH2F ("hBadClusterMaxCellCloseCellRatio","energy vs ratio of max cell / neighbour cell constributing cell, reconstructed bad clusters", | |
1913 | nptbins,ptmin,ptmax, 100,0,1.); | |
78451bcd | 1914 | fhBadClusterMaxCellCloseCellRatio->SetXTitle("#it{E}_{cluster} (GeV) "); |
649b825d | 1915 | fhBadClusterMaxCellCloseCellRatio->SetYTitle("ratio"); |
1916 | outputContainer->Add(fhBadClusterMaxCellCloseCellRatio); | |
1917 | ||
1918 | fhBadClusterMaxCellCloseCellDiff = new TH2F ("hBadClusterMaxCellCloseCellDiff","energy vs ratio of max cell - neighbour cell constributing cell, reconstructed bad clusters", | |
1919 | nptbins,ptmin,ptmax, 500,0,100); | |
78451bcd | 1920 | fhBadClusterMaxCellCloseCellDiff->SetXTitle("#it{E}_{cluster} (GeV) "); |
1921 | fhBadClusterMaxCellCloseCellDiff->SetYTitle("#it{E}_{cell max} - #it{E}_{cell i} (GeV)"); | |
649b825d | 1922 | outputContainer->Add(fhBadClusterMaxCellCloseCellDiff); |
1923 | ||
1924 | fhBadClusterMaxCellDiff = new TH2F ("hBadClusterMaxCellDiff","energy vs difference of cluster energy - max cell energy / cluster energy for bad clusters", | |
1925 | nptbins,ptmin,ptmax, 500,0,1.); | |
78451bcd | 1926 | fhBadClusterMaxCellDiff->SetXTitle("#it{E}_{cluster} (GeV) "); |
1927 | fhBadClusterMaxCellDiff->SetYTitle("(#it{E}_{cluster} - #it{E}_{cell max}) / #it{E}_{cluster}"); | |
649b825d | 1928 | outputContainer->Add(fhBadClusterMaxCellDiff); |
1929 | ||
1930 | fhBadClusterTimeEnergy = new TH2F ("hBadClusterTimeEnergy","energy vs TOF of reconstructed bad clusters", | |
1931 | nptbins,ptmin,ptmax, ntimebins,timemin,timemax); | |
78451bcd | 1932 | fhBadClusterTimeEnergy->SetXTitle("#it{E}_{cluster} (GeV) "); |
1933 | fhBadClusterTimeEnergy->SetYTitle("#it{t} (ns)"); | |
649b825d | 1934 | outputContainer->Add(fhBadClusterTimeEnergy); |
1935 | ||
1936 | fhBadClusterPairDiffTimeE = new TH2F("hBadClusterPairDiffTimeE","cluster pair time difference (bad - good) vs E from bad cluster",nptbins,ptmin,ptmax, tdbins,tdmin,tdmax); | |
78451bcd | 1937 | fhBadClusterPairDiffTimeE->SetXTitle("#it{E}_{bad cluster} (GeV)"); |
1938 | fhBadClusterPairDiffTimeE->SetYTitle("#Delta #it{t} (ns)"); | |
649b825d | 1939 | outputContainer->Add(fhBadClusterPairDiffTimeE); |
1940 | ||
78451bcd | 1941 | fhBadClusterMaxCellECross = new TH2F ("hBadClusterMaxCellECross","1 - #it{E}_{+} around max energy cell / max energy cell vs cluster energy, bad clusters", |
1a72f6c5 | 1942 | nptbins,ptmin,ptmax, 400,-1,1.); |
78451bcd | 1943 | fhBadClusterMaxCellECross->SetXTitle("#it{E}_{cluster} (GeV) "); |
1944 | fhBadClusterMaxCellECross->SetYTitle("1- #it{E}_{cross}/#it{E}_{cell max}"); | |
1a72f6c5 | 1945 | outputContainer->Add(fhBadClusterMaxCellECross); |
1946 | ||
e6fec6f5 | 1947 | if(fFillAllCellTimeHisto) |
1948 | { | |
78451bcd | 1949 | fhBadCellTimeSpreadRespectToCellMax = new TH2F ("hBadCellTimeSpreadRespectToCellMax","#it{t}_{cell max}-#it{t}_{cell i} from bad cluster", nptbins,ptmin,ptmax, tdbins,tdmin,tdmax); |
1950 | fhBadCellTimeSpreadRespectToCellMax->SetXTitle("#it{E} (GeV)"); | |
1951 | fhBadCellTimeSpreadRespectToCellMax->SetYTitle("#Delta #it{t}_{cell max - i} (ns)"); | |
649b825d | 1952 | outputContainer->Add(fhBadCellTimeSpreadRespectToCellMax); |
1953 | ||
78451bcd | 1954 | fhBadClusterMaxCellDiffAverageTime = new TH2F ("hBadClusterMaxCellDiffAverageTime","#it{t}_{cell max}-#it{t}_{average} from bad cluster", nptbins,ptmin,ptmax, tdbins,tdmin,tdmax); |
1955 | fhBadClusterMaxCellDiffAverageTime->SetXTitle("#it{E} (GeV)"); | |
1956 | fhBadClusterMaxCellDiffAverageTime->SetYTitle("#Delta #it{t}_{cell max - average} (ns)"); | |
649b825d | 1957 | outputContainer->Add(fhBadClusterMaxCellDiffAverageTime); |
a82b4462 | 1958 | |
78451bcd | 1959 | fhBadClusterMaxCellDiffWeightedTime = new TH2F ("hBadClusterMaxCellDiffWeightedTime","#it{t}_{cell max}-#it{t}_{weighted} from bad cluster", nptbins,ptmin,ptmax, tdbins,tdmin,tdmax); |
1960 | fhBadClusterMaxCellDiffWeightedTime->SetXTitle("#it{E} (GeV)"); | |
1961 | fhBadClusterMaxCellDiffWeightedTime->SetYTitle("#Delta #it{t}_{cell max - weighted} (ns)"); | |
649b825d | 1962 | outputContainer->Add(fhBadClusterMaxCellDiffWeightedTime); |
1963 | ||
649b825d | 1964 | } |
1965 | ||
1966 | } | |
1967 | ||
f1538a5f | 1968 | if(fStudyExotic) |
1969 | { | |
765206a5 | 1970 | fhExoL0ECross = new TH2F("hExoL0_ECross", |
78451bcd | 1971 | "#lambda^{2}_{0} vs 1-#it{E}_{+}/#it{E}_{max} for E > 5 GeV", |
e49010f3 | 1972 | 400,0,1,ssbins,ssmin,ssmax); |
78451bcd | 1973 | fhExoL0ECross ->SetXTitle("1-#it{E}_{+}/#it{E}_{cell max}"); |
cdacd584 | 1974 | fhExoL0ECross ->SetYTitle("#lambda^{2}_{0}"); |
765206a5 | 1975 | outputContainer->Add(fhExoL0ECross) ; |
1976 | ||
1977 | fhExoL1ECross = new TH2F("hExoL1_ECross", | |
78451bcd | 1978 | "#lambda^{2}_{1} vs 1-#it{E}_{+}/#it{E}_{max} for E > 5 GeV", |
e49010f3 | 1979 | 400,0,1,ssbins,ssmin,ssmax); |
78451bcd | 1980 | fhExoL1ECross ->SetXTitle("1-#it{E}_{+}/#it{E}_{cell max}"); |
cdacd584 | 1981 | fhExoL1ECross ->SetYTitle("#lambda^{2}_{1}"); |
765206a5 | 1982 | outputContainer->Add(fhExoL1ECross) ; |
1983 | ||
f1538a5f | 1984 | for(Int_t ie = 0; ie <fExoNECrossCuts; ie++) |
1985 | { | |
1986 | ||
1987 | fhExoDTime[ie] = new TH2F(Form("hExoDTime_ECross%d",ie), | |
78451bcd | 1988 | Form("#Delta time = t_{max}-t_{cells} vs #it{E}_{cluster} for exotic, 1-#it{E}_{+}/#it{E}_{max} < %2.2f",fExoECrossCuts[ie]), |
f1538a5f | 1989 | nptbins,ptmin,ptmax,tdbins,tdmin,tdmax); |
78451bcd | 1990 | fhExoDTime[ie] ->SetYTitle("#Delta #it{t} (ns)"); |
1991 | fhExoDTime[ie] ->SetXTitle("#it{E} (GeV)"); | |
f1538a5f | 1992 | outputContainer->Add(fhExoDTime[ie]) ; |
1993 | ||
1994 | for(Int_t idt = 0; idt < fExoNDTimeCuts; idt++) | |
1995 | { | |
1996 | fhExoNCell[ie][idt] = new TH2F(Form("hExoNCell_ECross%d_DT%d",ie,idt), | |
78451bcd | 1997 | Form("N cells per cluster vs E cluster, 1-#it{E}_{+}/#it{E}_{max} < %2.2f, #Delta t < %2.0f",fExoECrossCuts[ie],fExoDTimeCuts[idt]), |
f1538a5f | 1998 | nptbins,ptmin,ptmax,nceclbins,nceclmin,nceclmax); |
78451bcd | 1999 | fhExoNCell[ie][idt] ->SetYTitle("#it{n}_cells"); |
2000 | fhExoNCell[ie][idt] ->SetXTitle("#it{E} (GeV)"); | |
f1538a5f | 2001 | outputContainer->Add(fhExoNCell[ie][idt]) ; |
2002 | ||
2003 | fhExoL0 [ie][idt] = new TH2F(Form("hExoL0_ECross%d_DT%d",ie,idt), | |
78451bcd | 2004 | Form("#lambda^{2}_{0} vs E cluster for exotic, 1-#it{E}_{+}/#it{E}_{max} < %2.2f, #Delta t = %2.0f",fExoECrossCuts[ie],fExoDTimeCuts[idt]), |
f1538a5f | 2005 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); |
2006 | fhExoL0 [ie][idt] ->SetYTitle("#lambda^{2}_{0}"); | |
78451bcd | 2007 | fhExoL0 [ie][idt] ->SetXTitle("#it{E} (GeV)"); |
f1538a5f | 2008 | outputContainer->Add(fhExoL0[ie][idt]) ; |
765206a5 | 2009 | |
2010 | fhExoL1 [ie][idt] = new TH2F(Form("hExoL1_ECross%d_DT%d",ie,idt), | |
78451bcd | 2011 | Form("#lambda^{2}_{1} vs E cluster for exotic, 1-#it{E}_{+}/#it{E}_{max} < %2.2f, #Delta t = %2.0f",fExoECrossCuts[ie],fExoDTimeCuts[idt]), |
765206a5 | 2012 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); |
2013 | fhExoL1 [ie][idt] ->SetYTitle("#lambda^{2}_{1}"); | |
78451bcd | 2014 | fhExoL1 [ie][idt] ->SetXTitle("#it{E} (GeV)"); |
765206a5 | 2015 | outputContainer->Add(fhExoL1[ie][idt]) ; |
f1538a5f | 2016 | |
2017 | fhExoECross[ie][idt] = new TH2F(Form("hExoECross_ECross%d_DT%d",ie,idt), | |
78451bcd | 2018 | Form("#it{E} cross for cells vs E cell, 1-#it{E}_{+}/#it{E}_{max} < %2.2f, #Delta t < %2.0f",fExoECrossCuts[ie],fExoDTimeCuts[idt]), |
f1538a5f | 2019 | nptbins,ptmin,ptmax,400,0,1); |
78451bcd | 2020 | fhExoECross[ie][idt] ->SetYTitle("1-#it{E}_{+}/#it{E}_{cell max}"); |
2021 | fhExoECross[ie][idt] ->SetXTitle("#it{E}_{cell} (GeV)"); | |
f1538a5f | 2022 | outputContainer->Add(fhExoECross[ie][idt]) ; |
2023 | ||
2024 | fhExoTime [ie][idt] = new TH2F(Form("hExoTime_ECross%d_DT%d",ie,idt), | |
78451bcd | 2025 | Form("Time of cluster (max cell) vs E cluster for exotic, 1-#it{E}_{+}/#it{E}_{max} < %2.2f, #Delta t = %2.0f",fExoECrossCuts[ie],fExoDTimeCuts[idt]), |
f1538a5f | 2026 | nptbins,ptmin,ptmax,ntimebins,timemin,timemax); |
78451bcd | 2027 | fhExoTime [ie][idt] ->SetYTitle("#it{t}_{max} (ns)"); |
2028 | fhExoTime [ie][idt] ->SetXTitle("#it{E} (GeV)"); | |
f1538a5f | 2029 | outputContainer->Add(fhExoTime[ie][idt]) ; |
2030 | ||
765206a5 | 2031 | fhExoL0NCell[ie][idt] = new TH2F(Form("hExoL0_NCell%d_DT%d",ie,idt), |
78451bcd | 2032 | Form("#lambda^{2}_{0} vs N cells per clusters for E > 5 GeV, 1-#it{E}_{+}/#it{E}_{max} < %2.2f, #Delta t = %2.0f",fExoECrossCuts[ie],fExoDTimeCuts[idt]), |
765206a5 | 2033 | nptbins,ptmin,ptmax,ntimebins,timemin,timemax); |
78451bcd | 2034 | fhExoL0NCell[ie][idt] ->SetYTitle("#it{n}_{cells}"); |
765206a5 | 2035 | fhExoL0NCell[ie][idt] ->SetXTitle("#lambda^{2}_{0}"); |
2036 | outputContainer->Add(fhExoL0NCell[ie][idt]) ; | |
2037 | ||
2038 | fhExoL1NCell[ie][idt] = new TH2F(Form("hExoL1_NCell%d_DT%d",ie,idt), | |
78451bcd | 2039 | Form("#lambda^{2}_{1} vs N cells per clusters for E > 5 GeV, 1-#it{E}_{+}/#it{E}_{max} < %2.2f, #Delta t = %2.0f",fExoECrossCuts[ie],fExoDTimeCuts[idt]), |
765206a5 | 2040 | nptbins,ptmin,ptmax,ntimebins,timemin,timemax); |
78451bcd | 2041 | fhExoL1NCell[ie][idt] ->SetYTitle("#it{n}_{cells}"); |
765206a5 | 2042 | fhExoL1NCell[ie][idt] ->SetXTitle("#lambda^{2}_{1}"); |
2043 | outputContainer->Add(fhExoL1NCell[ie][idt]) ; | |
2044 | ||
f1538a5f | 2045 | } |
2046 | } | |
2047 | } | |
2048 | ||
649b825d | 2049 | // Cluster size in terms of cells |
f1538a5f | 2050 | if(fStudyClustersAsymmetry) |
2051 | { | |
78451bcd | 2052 | fhDeltaIEtaDeltaIPhiE0[0] = new TH2F ("hDeltaIEtaDeltaIPhiE0"," Cluster size in columns vs rows for E < 2 GeV, #it{n}_{cells} > 3", |
649b825d | 2053 | 50,0,50,50,0,50); |
2054 | fhDeltaIEtaDeltaIPhiE0[0]->SetXTitle("#Delta Column"); | |
2055 | fhDeltaIEtaDeltaIPhiE0[0]->SetYTitle("#Delta Row"); | |
2056 | outputContainer->Add(fhDeltaIEtaDeltaIPhiE0[0]); | |
2057 | ||
78451bcd | 2058 | fhDeltaIEtaDeltaIPhiE2[0] = new TH2F ("hDeltaIEtaDeltaIPhiE2"," Cluster size in columns vs rows for 2 <E < 6 GeV, #it{n}_{cells} > 3", |
649b825d | 2059 | 50,0,50,50,0,50); |
2060 | fhDeltaIEtaDeltaIPhiE2[0]->SetXTitle("#Delta Column"); | |
2061 | fhDeltaIEtaDeltaIPhiE2[0]->SetYTitle("#Delta Row"); | |
2062 | outputContainer->Add(fhDeltaIEtaDeltaIPhiE2[0]); | |
2063 | ||
78451bcd | 2064 | fhDeltaIEtaDeltaIPhiE6[0] = new TH2F ("hDeltaIEtaDeltaIPhiE6"," Cluster size in columns vs rows for E > 6 GeV, #it{n}_{cells} > 3", |
649b825d | 2065 | 50,0,50,50,0,50); |
2066 | fhDeltaIEtaDeltaIPhiE6[0]->SetXTitle("#Delta Column"); | |
2067 | fhDeltaIEtaDeltaIPhiE6[0]->SetYTitle("#Delta Row"); | |
2068 | outputContainer->Add(fhDeltaIEtaDeltaIPhiE6[0]); | |
2069 | ||
2070 | fhDeltaIA[0] = new TH2F ("hDeltaIA"," Cluster *asymmetry* in cell units vs E", | |
2071 | nptbins,ptmin,ptmax,21,-1.05,1.05); | |
78451bcd | 2072 | fhDeltaIA[0]->SetXTitle("#it{E}_{cluster}"); |
2073 | fhDeltaIA[0]->SetYTitle("#it{A}_{cell in cluster}"); | |
649b825d | 2074 | outputContainer->Add(fhDeltaIA[0]); |
2075 | ||
2076 | fhDeltaIAL0[0] = new TH2F ("hDeltaIAL0"," Cluster *asymmetry* in cell units vs #lambda^{2}_{0}", | |
2077 | ssbins,ssmin,ssmax,21,-1.05,1.05); | |
2078 | fhDeltaIAL0[0]->SetXTitle("#lambda^{2}_{0}"); | |
78451bcd | 2079 | fhDeltaIAL0[0]->SetYTitle("#it{A}_{cell in cluster}"); |
649b825d | 2080 | outputContainer->Add(fhDeltaIAL0[0]); |
2081 | ||
2082 | fhDeltaIAL1[0] = new TH2F ("hDeltaIAL1"," Cluster *asymmetry* in cell units vs #lambda^{2}_{1}", | |
2083 | ssbins,ssmin,ssmax,21,-1.05,1.05); | |
2084 | fhDeltaIAL1[0]->SetXTitle("#lambda^{2}_{1}"); | |
78451bcd | 2085 | fhDeltaIAL1[0]->SetYTitle("#it{A}_{cell in cluster}"); |
649b825d | 2086 | outputContainer->Add(fhDeltaIAL1[0]); |
2087 | ||
2088 | fhDeltaIANCells[0] = new TH2F ("hDeltaIANCells"," Cluster *asymmetry* in cell units vs N cells in cluster", | |
2089 | nceclbins,nceclmin,nceclmax,21,-1.05,1.05); | |
78451bcd | 2090 | fhDeltaIANCells[0]->SetXTitle("#it{n}_{cell in cluster}"); |
2091 | fhDeltaIANCells[0]->SetYTitle("#it{A}_{cell in cluster}"); | |
649b825d | 2092 | outputContainer->Add(fhDeltaIANCells[0]); |
2093 | ||
2094 | ||
78451bcd | 2095 | fhDeltaIEtaDeltaIPhiE0[1] = new TH2F ("hDeltaIEtaDeltaIPhiE0Charged"," Cluster size in columns vs rows for E < 2 GeV, #it{n}_{cells} > 3, matched with track", |
649b825d | 2096 | 50,0,50,50,0,50); |
2097 | fhDeltaIEtaDeltaIPhiE0[1]->SetXTitle("#Delta Column"); | |
2098 | fhDeltaIEtaDeltaIPhiE0[1]->SetYTitle("#Delta Row"); | |
2099 | outputContainer->Add(fhDeltaIEtaDeltaIPhiE0[1]); | |
2100 | ||
78451bcd | 2101 | fhDeltaIEtaDeltaIPhiE2[1] = new TH2F ("hDeltaIEtaDeltaIPhiE2Charged"," Cluster size in columns vs rows for 2 <E < 6 GeV, #it{n}_{cells} > 3, matched with track", |
649b825d | 2102 | 50,0,50,50,0,50); |
2103 | fhDeltaIEtaDeltaIPhiE2[1]->SetXTitle("#Delta Column"); | |
2104 | fhDeltaIEtaDeltaIPhiE2[1]->SetYTitle("#Delta Row"); | |
2105 | outputContainer->Add(fhDeltaIEtaDeltaIPhiE2[1]); | |
2106 | ||
78451bcd | 2107 | fhDeltaIEtaDeltaIPhiE6[1] = new TH2F ("hDeltaIEtaDeltaIPhiE6Charged"," Cluster size in columns vs rows for E > 6 GeV, #it{n}_{cells} > 3, matched with track", |
649b825d | 2108 | 50,0,50,50,0,50); |
2109 | fhDeltaIEtaDeltaIPhiE6[1]->SetXTitle("#Delta Column"); | |
2110 | fhDeltaIEtaDeltaIPhiE6[1]->SetYTitle("#Delta Row"); | |
2111 | outputContainer->Add(fhDeltaIEtaDeltaIPhiE6[1]); | |
2112 | ||
2113 | fhDeltaIA[1] = new TH2F ("hDeltaIACharged"," Cluster *asymmetry* in cell units vs E, matched with track", | |
2114 | nptbins,ptmin,ptmax,21,-1.05,1.05); | |
78451bcd | 2115 | fhDeltaIA[1]->SetXTitle("#it{E}_{cluster}"); |
2116 | fhDeltaIA[1]->SetYTitle("#it{A}_{cell in cluster}"); | |
649b825d | 2117 | outputContainer->Add(fhDeltaIA[1]); |
2118 | ||
2119 | fhDeltaIAL0[1] = new TH2F ("hDeltaIAL0Charged"," Cluster *asymmetry* in cell units vs #lambda^{2}_{0}, matched with track", | |
2120 | ssbins,ssmin,ssmax,21,-1.05,1.05); | |
2121 | fhDeltaIAL0[1]->SetXTitle("#lambda^{2}_{0}"); | |
78451bcd | 2122 | fhDeltaIAL0[1]->SetYTitle("#it{A}_{cell in cluster}"); |
649b825d | 2123 | outputContainer->Add(fhDeltaIAL0[1]); |
2124 | ||
2125 | fhDeltaIAL1[1] = new TH2F ("hDeltaIAL1Charged"," Cluster *asymmetry* in cell units vs #lambda^{2}_{1}, matched with track", | |
2126 | ssbins,ssmin,ssmax,21,-1.05,1.05); | |
2127 | fhDeltaIAL1[1]->SetXTitle("#lambda^{2}_{1}"); | |
78451bcd | 2128 | fhDeltaIAL1[1]->SetYTitle("#it{A}_{cell in cluster}"); |
649b825d | 2129 | outputContainer->Add(fhDeltaIAL1[1]); |
2130 | ||
2131 | fhDeltaIANCells[1] = new TH2F ("hDeltaIANCellsCharged"," Cluster *asymmetry* in cell units vs N cells in cluster, matched with track", | |
2132 | nceclbins,nceclmin,nceclmax,21,-1.05,1.05); | |
78451bcd | 2133 | fhDeltaIANCells[1]->SetXTitle("#it{n}_{cell in cluster}"); |
2134 | fhDeltaIANCells[1]->SetYTitle("#it{A}_{cell in cluster}"); | |
649b825d | 2135 | outputContainer->Add(fhDeltaIANCells[1]); |
2136 | ||
2137 | if(IsDataMC()){ | |
2138 | TString particle[]={"Photon","Electron","Conversion","Hadron"}; | |
2139 | for (Int_t iPart = 0; iPart < 4; iPart++) { | |
2140 | ||
2141 | fhDeltaIAMC[iPart] = new TH2F (Form("hDeltaIA_MC%s",particle[iPart].Data()),Form(" Cluster *asymmetry* in cell units vs E, from %s",particle[iPart].Data()), | |
2142 | nptbins,ptmin,ptmax,21,-1.05,1.05); | |
78451bcd | 2143 | fhDeltaIAMC[iPart]->SetXTitle("#it{E}_{cluster}"); |
2144 | fhDeltaIAMC[iPart]->SetYTitle("#it{A}_{cell in cluster}"); | |
649b825d | 2145 | outputContainer->Add(fhDeltaIAMC[iPart]); |
2146 | } | |
2147 | } | |
f1538a5f | 2148 | |
1a83b960 | 2149 | if(fStudyBadClusters) |
2150 | { | |
78451bcd | 2151 | fhBadClusterDeltaIEtaDeltaIPhiE0 = new TH2F ("hBadClusterDeltaIEtaDeltaIPhiE0"," Cluster size in columns vs rows for E < 2 GeV, #it{n}_{cells} > 3", |
1a83b960 | 2152 | 50,0,50,50,0,50); |
2153 | fhBadClusterDeltaIEtaDeltaIPhiE0->SetXTitle("#Delta Column"); | |
2154 | fhBadClusterDeltaIEtaDeltaIPhiE0->SetYTitle("#Delta Row"); | |
2155 | outputContainer->Add(fhBadClusterDeltaIEtaDeltaIPhiE0); | |
2156 | ||
78451bcd | 2157 | fhBadClusterDeltaIEtaDeltaIPhiE2 = new TH2F ("hBadClusterDeltaIEtaDeltaIPhiE2"," Cluster size in columns vs rows for 2 <E < 6 GeV, #it{n}_{cells} > 3", |
1a83b960 | 2158 | 50,0,50,50,0,50); |
2159 | fhBadClusterDeltaIEtaDeltaIPhiE2->SetXTitle("#Delta Column"); | |
2160 | fhBadClusterDeltaIEtaDeltaIPhiE2->SetYTitle("#Delta Row"); | |
2161 | outputContainer->Add(fhBadClusterDeltaIEtaDeltaIPhiE2); | |
2162 | ||
78451bcd | 2163 | fhBadClusterDeltaIEtaDeltaIPhiE6 = new TH2F ("hBadClusterDeltaIEtaDeltaIPhiE6"," Cluster size in columns vs rows for E > 6 GeV, #it{n}_{cells} > 3", |
1a83b960 | 2164 | 50,0,50,50,0,50); |
2165 | fhBadClusterDeltaIEtaDeltaIPhiE6->SetXTitle("#Delta Column"); | |
2166 | fhBadClusterDeltaIEtaDeltaIPhiE6->SetYTitle("#Delta Row"); | |
2167 | outputContainer->Add(fhBadClusterDeltaIEtaDeltaIPhiE6); | |
2168 | ||
2169 | fhBadClusterDeltaIA = new TH2F ("hBadClusterDeltaIA"," Cluster *asymmetry* in cell units vs E", | |
2170 | nptbins,ptmin,ptmax,21,-1.05,1.05); | |
78451bcd | 2171 | fhBadClusterDeltaIA->SetXTitle("#it{E}_{cluster}"); |
2172 | fhBadClusterDeltaIA->SetYTitle("#it{A}_{cell in cluster}"); | |
1a83b960 | 2173 | outputContainer->Add(fhBadClusterDeltaIA); |
2174 | } | |
649b825d | 2175 | } |
2176 | ||
f1538a5f | 2177 | if(fStudyWeight) |
2178 | { | |
649b825d | 2179 | fhECellClusterRatio = new TH2F ("hECellClusterRatio"," cell energy / cluster energy vs cluster energy", |
2180 | nptbins,ptmin,ptmax, 100,0,1.); | |
78451bcd | 2181 | fhECellClusterRatio->SetXTitle("#it{E}_{cluster} (GeV) "); |
2182 | fhECellClusterRatio->SetYTitle("#it{E}_{cell i}/#it{E}_{cluster}"); | |
649b825d | 2183 | outputContainer->Add(fhECellClusterRatio); |
2184 | ||
2185 | fhECellClusterLogRatio = new TH2F ("hECellClusterLogRatio"," Log(cell energy / cluster energy) vs cluster energy", | |
1a72f6c5 | 2186 | nptbins,ptmin,ptmax, 100,-10,0); |
78451bcd | 2187 | fhECellClusterLogRatio->SetXTitle("#it{E}_{cluster} (GeV) "); |
2188 | fhECellClusterLogRatio->SetYTitle("Log(#it{E}_{cell i}/#it{E}_{cluster})"); | |
649b825d | 2189 | outputContainer->Add(fhECellClusterLogRatio); |
2190 | ||
2191 | fhEMaxCellClusterRatio = new TH2F ("hEMaxCellClusterRatio"," max cell energy / cluster energy vs cluster energy", | |
2192 | nptbins,ptmin,ptmax, 100,0,1.); | |
78451bcd | 2193 | fhEMaxCellClusterRatio->SetXTitle("#it{E}_{cluster} (GeV) "); |
2194 | fhEMaxCellClusterRatio->SetYTitle("#it{E}_{max cell}/#it{E}_{cluster}"); | |
649b825d | 2195 | outputContainer->Add(fhEMaxCellClusterRatio); |
2196 | ||
2197 | fhEMaxCellClusterLogRatio = new TH2F ("hEMaxCellClusterLogRatio"," Log(max cell energy / cluster energy) vs cluster energy", | |
1a72f6c5 | 2198 | nptbins,ptmin,ptmax, 100,-10,0); |
78451bcd | 2199 | fhEMaxCellClusterLogRatio->SetXTitle("#it{E}_{cluster} (GeV) "); |
2200 | fhEMaxCellClusterLogRatio->SetYTitle("Log (#it{E}_{max cell}/#it{E}_{cluster})"); | |
649b825d | 2201 | outputContainer->Add(fhEMaxCellClusterLogRatio); |
2202 | ||
701cbf54 | 2203 | fhECellTotalRatio = new TH2F ("hECellTotalRatio"," cell energy / sum all energy vs all energy", |
2204 | nptbins*2,ptmin,ptmax*2, 100,0,1.); | |
78451bcd | 2205 | fhECellTotalRatio->SetXTitle("#it{E}_{total} (GeV) "); |
2206 | fhECellTotalRatio->SetYTitle("#it{E}_{cell i}/#it{E}_{total}"); | |
701cbf54 | 2207 | outputContainer->Add(fhECellTotalRatio); |
2208 | ||
2209 | fhECellTotalLogRatio = new TH2F ("hECellTotalLogRatio"," Log(cell energy / sum all energy) vs all energy", | |
2210 | nptbins*2,ptmin,ptmax*2, 100,-10,0); | |
78451bcd | 2211 | fhECellTotalLogRatio->SetXTitle("#it{E}_{total} (GeV) "); |
2212 | fhECellTotalLogRatio->SetYTitle("Log(#it{E}_{cell i}/#it{E}_{total})"); | |
701cbf54 | 2213 | outputContainer->Add(fhECellTotalLogRatio); |
2214 | ||
2215 | fhECellTotalRatioMod = new TH2F*[fNModules]; | |
2216 | fhECellTotalLogRatioMod = new TH2F*[fNModules]; | |
2217 | ||
2218 | for(Int_t imod = 0; imod < fNModules; imod++) | |
2219 | { | |
2220 | fhECellTotalRatioMod[imod] = new TH2F (Form("hECellTotalRatio_Mod%d",imod), | |
2221 | Form("#cell energy / sum all energy vs all energy in Module %d",imod), | |
2222 | nptbins*2,ptmin,ptmax*2, 100,0,1.); | |
78451bcd | 2223 | fhECellTotalRatioMod[imod]->SetXTitle("#it{E} (GeV)"); |
2224 | fhECellTotalRatioMod[imod]->SetYTitle("#it{n}_{cells}"); | |
701cbf54 | 2225 | outputContainer->Add(fhECellTotalRatioMod[imod]); |
2226 | ||
2227 | fhECellTotalLogRatioMod[imod] = new TH2F (Form("hECellTotalLogRatio_Mod%d",imod), | |
2228 | Form("Log(cell energy / sum all energy) vs all energy in Module %d",imod), | |
2229 | nptbins*2,ptmin,ptmax*2, 100,-10,0); | |
78451bcd | 2230 | fhECellTotalLogRatioMod[imod]->SetXTitle("#it{E} (GeV)"); |
2231 | fhECellTotalLogRatioMod[imod]->SetYTitle("#it{n}_{cells}"); | |
701cbf54 | 2232 | outputContainer->Add(fhECellTotalLogRatioMod[imod]); |
2233 | ||
2234 | } | |
2235 | ||
2236 | for(Int_t iw = 0; iw < 12; iw++) | |
2237 | { | |
2238 | Float_t w0 = 3+0.25*iw; | |
2239 | fhLambda0ForW0[iw] = new TH2F (Form("hLambda0ForW0%d",iw),Form("shower shape, #lambda^{2}_{0} vs E, w0 = %1.1f",w0), | |
649b825d | 2240 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); |
78451bcd | 2241 | fhLambda0ForW0[iw]->SetXTitle("#it{E}_{cluster}"); |
649b825d | 2242 | fhLambda0ForW0[iw]->SetYTitle("#lambda^{2}_{0}"); |
2243 | outputContainer->Add(fhLambda0ForW0[iw]); | |
2244 | ||
701cbf54 | 2245 | // fhLambda1ForW0[iw] = new TH2F (Form("hLambda1ForW0%d",iw),Form("shower shape, #lambda^{2}_{1} vs E, w0 = %1.1f",w0), |
1a72f6c5 | 2246 | // nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); |
78451bcd | 2247 | // fhLambda1ForW0[iw]->SetXTitle("#it{E}_{cluster}"); |
1a72f6c5 | 2248 | // fhLambda1ForW0[iw]->SetYTitle("#lambda^{2}_{1}"); |
2249 | // outputContainer->Add(fhLambda1ForW0[iw]); | |
649b825d | 2250 | |
2251 | if(IsDataMC()){ | |
2252 | TString mcnames[] = {"Photon", "Electron","Conversion","Pi0","Hadron"}; | |
2253 | for(Int_t imc = 0; imc < 5; imc++){ | |
2254 | fhLambda0ForW0MC[iw][imc] = new TH2F (Form("hLambda0ForW0%d_MC%s",iw,mcnames[imc].Data()), | |
701cbf54 | 2255 | Form("shower shape, #lambda^{2}_{0} vs E, w0 = %1.1f, for MC %s",w0,mcnames[imc].Data()), |
649b825d | 2256 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); |
78451bcd | 2257 | fhLambda0ForW0MC[iw][imc]->SetXTitle("#it{E}_{cluster}"); |
649b825d | 2258 | fhLambda0ForW0MC[iw][imc]->SetYTitle("#lambda^{2}_{0}"); |
2259 | outputContainer->Add(fhLambda0ForW0MC[iw][imc]); | |
2260 | ||
1a72f6c5 | 2261 | // fhLambda1ForW0MC[iw][imc] = new TH2F (Form("hLambda1ForW0%d_MC%s",iw,mcnames[imc].Data()), |
701cbf54 | 2262 | // Form("shower shape, #lambda^{2}_{1} vs E, w0 = %1.1f, for MC %s",w0,mcnames[imc].Data()), |
1a72f6c5 | 2263 | // nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); |
78451bcd | 2264 | // fhLambda1ForW0MC[iw][imc]->SetXTitle("#it{E}_{cluster}"); |
1a72f6c5 | 2265 | // fhLambda1ForW0MC[iw][imc]->SetYTitle("#lambda^{2}_{1}"); |
2266 | // outputContainer->Add(fhLambda1ForW0MC[iw][imc]); | |
649b825d | 2267 | } |
2268 | } | |
f1538a5f | 2269 | } |
649b825d | 2270 | } |
2271 | ||
2272 | //Track Matching | |
f1538a5f | 2273 | if(fFillAllTMHisto) |
2274 | { | |
653aed3c | 2275 | Int_t nresetabins = GetHistogramRanges()->GetHistoTrackResidualEtaBins(); |
2276 | Float_t resetamax = GetHistogramRanges()->GetHistoTrackResidualEtaMax(); | |
2277 | Float_t resetamin = GetHistogramRanges()->GetHistoTrackResidualEtaMin(); | |
2278 | Int_t nresphibins = GetHistogramRanges()->GetHistoTrackResidualPhiBins(); | |
2279 | Float_t resphimax = GetHistogramRanges()->GetHistoTrackResidualPhiMax(); | |
2280 | Float_t resphimin = GetHistogramRanges()->GetHistoTrackResidualPhiMin(); | |
2281 | ||
2282 | fhTrackMatchedDEta = new TH2F("hTrackMatchedDEta","d#eta of cluster-track vs cluster energy", | |
2283 | nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); | |
2284 | fhTrackMatchedDEta->SetYTitle("d#eta"); | |
78451bcd | 2285 | fhTrackMatchedDEta->SetXTitle("#it{E}_{cluster} (GeV)"); |
653aed3c | 2286 | |
2287 | fhTrackMatchedDPhi = new TH2F("hTrackMatchedDPhi","d#phi of cluster-track vs cluster energy", | |
2288 | nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); | |
2289 | fhTrackMatchedDPhi->SetYTitle("d#phi (rad)"); | |
78451bcd | 2290 | fhTrackMatchedDPhi->SetXTitle("#it{E}_{cluster} (GeV)"); |
653aed3c | 2291 | |
2292 | fhTrackMatchedDEtaDPhi = new TH2F("hTrackMatchedDEtaDPhi","d#eta vs d#phi of cluster-track vs cluster energy", | |
2293 | nresetabins,resetamin,resetamax,nresphibins,resphimin,resphimax); | |
2294 | fhTrackMatchedDEtaDPhi->SetYTitle("d#phi (rad)"); | |
2295 | fhTrackMatchedDEtaDPhi->SetXTitle("d#eta"); | |
2296 | ||
2297 | fhTrackMatchedDEtaPos = new TH2F("hTrackMatchedDEtaPos","d#eta of cluster-track vs cluster energy", | |
2298 | nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); | |
2299 | fhTrackMatchedDEtaPos->SetYTitle("d#eta"); | |
78451bcd | 2300 | fhTrackMatchedDEtaPos->SetXTitle("#it{E}_{cluster} (GeV)"); |
653aed3c | 2301 | |
2302 | fhTrackMatchedDPhiPos = new TH2F("hTrackMatchedDPhiPos","d#phi of cluster-track vs cluster energy", | |
2303 | nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); | |
2304 | fhTrackMatchedDPhiPos->SetYTitle("d#phi (rad)"); | |
78451bcd | 2305 | fhTrackMatchedDPhiPos->SetXTitle("#it{E}_{cluster} (GeV)"); |
653aed3c | 2306 | |
2307 | fhTrackMatchedDEtaDPhiPos = new TH2F("hTrackMatchedDEtaDPhiPos","d#eta vs d#phi of cluster-track vs cluster energy", | |
2308 | nresetabins,resetamin,resetamax,nresphibins,resphimin,resphimax); | |
2309 | fhTrackMatchedDEtaDPhiPos->SetYTitle("d#phi (rad)"); | |
2310 | fhTrackMatchedDEtaDPhiPos->SetXTitle("d#eta"); | |
2311 | ||
2312 | outputContainer->Add(fhTrackMatchedDEta) ; | |
2313 | outputContainer->Add(fhTrackMatchedDPhi) ; | |
2314 | outputContainer->Add(fhTrackMatchedDEtaDPhi) ; | |
2315 | outputContainer->Add(fhTrackMatchedDEtaPos) ; | |
2316 | outputContainer->Add(fhTrackMatchedDPhiPos) ; | |
2317 | outputContainer->Add(fhTrackMatchedDEtaDPhiPos) ; | |
2318 | ||
78451bcd | 2319 | fhECharged = new TH1F ("hECharged","#it{E} reconstructed clusters, matched with track", nptbins,ptmin,ptmax); |
2320 | fhECharged->SetXTitle("#it{E} (GeV)"); | |
45769d5b | 2321 | outputContainer->Add(fhECharged); |
2322 | ||
78451bcd | 2323 | fhPtCharged = new TH1F ("hPtCharged","#it{p}_{T} reconstructed clusters, matched with track", nptbins,ptmin,ptmax); |
2324 | fhPtCharged->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
45769d5b | 2325 | outputContainer->Add(fhPtCharged); |
2326 | ||
2327 | fhPhiCharged = new TH1F ("hPhiCharged","#phi reconstructed clusters, matched with track",nphibins,phimin,phimax); | |
2328 | fhPhiCharged->SetXTitle("#phi (rad)"); | |
2329 | outputContainer->Add(fhPhiCharged); | |
2330 | ||
2331 | fhEtaCharged = new TH1F ("hEtaCharged","#eta reconstructed clusters, matched with track",netabins,etamin,etamax); | |
2332 | fhEtaCharged->SetXTitle("#eta "); | |
2333 | outputContainer->Add(fhEtaCharged); | |
2334 | ||
2335 | if(fFillAllTH3) | |
f1538a5f | 2336 | { |
3748ffb5 | 2337 | fhEtaPhiECharged = new TH3F ("hEtaPhiECharged","#eta vs #phi, reconstructed clusters, matched with track", |
521636d2 | 2338 | netabins,etamin,etamax,nphibins,phimin,phimax,nptbins,ptmin,ptmax); |
3748ffb5 | 2339 | fhEtaPhiECharged->SetXTitle("#eta "); |
2340 | fhEtaPhiECharged->SetYTitle("#phi "); | |
78451bcd | 2341 | fhEtaPhiECharged->SetZTitle("#it{E} (GeV) "); |
3748ffb5 | 2342 | outputContainer->Add(fhEtaPhiECharged); |
2343 | } | |
55c05f8c | 2344 | |
78451bcd | 2345 | fh1EOverP = new TH2F("h1EOverP","TRACK matches #it{E}/#it{p}",nptbins,ptmin,ptmax, nPoverEbins,eOverPmin,eOverPmax); |
2346 | fh1EOverP->SetYTitle("#it{E}/#it{p}"); | |
2347 | fh1EOverP->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
d55bb5e1 | 2348 | outputContainer->Add(fh1EOverP); |
3bfc4732 | 2349 | |
78451bcd | 2350 | fh2dR = new TH2F("h2dR","TRACK matches #Delta #it{R}",nptbins,ptmin,ptmax,ndRbins,dRmin,dRmax); |
2351 | fh2dR->SetXTitle("#Delta #it{R} (rad)"); | |
2352 | fh2dR->SetXTitle("#it{E} cluster (GeV)"); | |
a87e069d | 2353 | outputContainer->Add(fh2dR) ; |
3bfc4732 | 2354 | |
78451bcd | 2355 | fh2MatchdEdx = new TH2F("h2MatchdEdx","#it{dE/dx} vs. #it{p} for all matches",nptbins,ptmin,ptmax,ndedxbins,dedxmin,dedxmax); |
2356 | fh2MatchdEdx->SetXTitle("p (GeV/#it{c})"); | |
2357 | fh2MatchdEdx->SetYTitle("#it{dE/dx}>"); | |
3bfc4732 | 2358 | outputContainer->Add(fh2MatchdEdx); |
2359 | ||
78451bcd | 2360 | fh2EledEdx = new TH2F("h2EledEdx","#it{dE/dx} vs. #it{p} for electrons",nptbins,ptmin,ptmax,ndedxbins,dedxmin,dedxmax); |
2361 | fh2EledEdx->SetXTitle("p (GeV/#it{c})"); | |
2362 | fh2EledEdx->SetYTitle("<#it{dE/dx}>"); | |
3bfc4732 | 2363 | outputContainer->Add(fh2EledEdx) ; |
2364 | ||
78451bcd | 2365 | fh1EOverPR02 = new TH2F("h1EOverPR02","TRACK matches #it{E}/#it{p}, all",nptbins,ptmin,ptmax, nPoverEbins,eOverPmin,eOverPmax); |
2366 | fh1EOverPR02->SetYTitle("#it{E}/#it{p}"); | |
2367 | fh1EOverPR02->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
d55bb5e1 | 2368 | outputContainer->Add(fh1EOverPR02); |
a054a582 | 2369 | |
78451bcd | 2370 | fh1EleEOverP = new TH2F("h1EleEOverP","Electron candidates #it{E}/#it{p} (60<#it{dE/dx}<100)",nptbins,ptmin,ptmax, nPoverEbins,eOverPmin,eOverPmax); |
2371 | fh1EleEOverP->SetYTitle("#it{E}/#it{p}"); | |
2372 | fh1EleEOverP->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
a054a582 | 2373 | outputContainer->Add(fh1EleEOverP); |
55c05f8c | 2374 | } |
2375 | ||
f1538a5f | 2376 | if(fFillAllPi0Histo) |
2377 | { | |
9e9f04cb | 2378 | fhIM = new TH2F ("hIM","Cluster pairs Invariant mass vs reconstructed pair energy, ncell > 1",nptbins,ptmin,ptmax,nmassbins,massmin,massmax); |
78451bcd | 2379 | fhIM->SetXTitle("#it{p}_{T, cluster pairs} (GeV) "); |
2380 | fhIM->SetYTitle("M_{cluster pairs} (GeV/#it{c}^{2})"); | |
55c05f8c | 2381 | outputContainer->Add(fhIM); |
a6f26052 | 2382 | |
55c05f8c | 2383 | fhAsym = new TH2F ("hAssym","Cluster pairs Asymmetry vs reconstructed pair energy",nptbins,ptmin,ptmax,nasymbins,asymmin,asymmax); |
78451bcd | 2384 | fhAsym->SetXTitle("#it{p}_{T, cluster pairs} (GeV) "); |
2385 | fhAsym->SetYTitle("#it{Asymmetry}"); | |
55c05f8c | 2386 | outputContainer->Add(fhAsym); |
a6f26052 | 2387 | } |
649b825d | 2388 | |
c8fe2783 | 2389 | |
f1538a5f | 2390 | if(fFillAllPosHisto2) |
2391 | { | |
2392 | if(fFillAllTH3) | |
2393 | { | |
78451bcd | 2394 | fhXYZ = new TH3F ("hXYZ","Cluster: #it{x} vs #it{y} vs #it{z}",xbins,xmin,xmax,ybins,ymin,ymax,zbins,zmin,zmax); |
2395 | fhXYZ->SetXTitle("#it{x} (cm)"); | |
2396 | fhXYZ->SetYTitle("#it{y} (cm)"); | |
2397 | fhXYZ->SetZTitle("#it{z} (cm) "); | |
55c05f8c | 2398 | outputContainer->Add(fhXYZ); |
2399 | } | |
2400 | ||
35c71d5c | 2401 | fhXNCells = new TH2F ("hXNCells","Cluster X position vs N Cells per Cluster",xbins,xmin,xmax,nceclbins,nceclmin,nceclmax); |
78451bcd | 2402 | fhXNCells->SetXTitle("#it{x} (cm)"); |
55c05f8c | 2403 | fhXNCells->SetYTitle("N cells per cluster"); |
2404 | outputContainer->Add(fhXNCells); | |
2405 | ||
35c71d5c | 2406 | fhZNCells = new TH2F ("hZNCells","Cluster Z position vs N Cells per Cluster",zbins,zmin,zmax,nceclbins,nceclmin,nceclmax); |
78451bcd | 2407 | fhZNCells->SetXTitle("#it{z} (cm)"); |
55c05f8c | 2408 | fhZNCells->SetYTitle("N cells per cluster"); |
2409 | outputContainer->Add(fhZNCells); | |
2410 | ||
2411 | fhXE = new TH2F ("hXE","Cluster X position vs cluster energy",xbins,xmin,xmax,nptbins,ptmin,ptmax); | |
78451bcd | 2412 | fhXE->SetXTitle("#it{x} (cm)"); |
2413 | fhXE->SetYTitle("#it{E} (GeV)"); | |
55c05f8c | 2414 | outputContainer->Add(fhXE); |
2415 | ||
2416 | fhZE = new TH2F ("hZE","Cluster Z position vs cluster energy",zbins,zmin,zmax,nptbins,ptmin,ptmax); | |
78451bcd | 2417 | fhZE->SetXTitle("#it{z} (cm)"); |
2418 | fhZE->SetYTitle("#it{E} (GeV)"); | |
55c05f8c | 2419 | outputContainer->Add(fhZE); |
2420 | ||
35c71d5c | 2421 | fhRNCells = new TH2F ("hRNCells","Cluster R position vs N Cells per Cluster",rbins,rmin,rmax,nceclbins,nceclmin,nceclmax); |
55c05f8c | 2422 | fhRNCells->SetXTitle("r = #sqrt{x^{2}+y^{2}} (cm)"); |
2423 | fhRNCells->SetYTitle("N cells per cluster"); | |
2424 | outputContainer->Add(fhRNCells); | |
2425 | ||
2426 | ||
35c71d5c | 2427 | fhYNCells = new TH2F ("hYNCells","Cluster Y position vs N Cells per Cluster",ybins,ymin,ymax,nceclbins,nceclmin,nceclmax); |
78451bcd | 2428 | fhYNCells->SetXTitle("#it{y} (cm)"); |
55c05f8c | 2429 | fhYNCells->SetYTitle("N cells per cluster"); |
2430 | outputContainer->Add(fhYNCells); | |
2431 | ||
2432 | fhRE = new TH2F ("hRE","Cluster R position vs cluster energy",rbins,rmin,rmax,nptbins,ptmin,ptmax); | |
2433 | fhRE->SetXTitle("r = #sqrt{x^{2}+y^{2}} (cm)"); | |
78451bcd | 2434 | fhRE->SetYTitle("#it{E} (GeV)"); |
55c05f8c | 2435 | outputContainer->Add(fhRE); |
2436 | ||
2437 | fhYE = new TH2F ("hYE","Cluster Y position vs cluster energy",ybins,ymin,ymax,nptbins,ptmin,ptmax); | |
78451bcd | 2438 | fhYE->SetXTitle("#it{y} (cm)"); |
2439 | fhYE->SetYTitle("#it{E} (GeV)"); | |
55c05f8c | 2440 | outputContainer->Add(fhYE); |
2441 | } | |
f1538a5f | 2442 | |
2443 | if(fFillAllPosHisto) | |
2444 | { | |
a6f26052 | 2445 | fhRCellE = new TH2F ("hRCellE","Cell R position vs cell energy",rbins,rmin,rmax,nptbins,ptmin,ptmax); |
2446 | fhRCellE->SetXTitle("r = #sqrt{x^{2}+y^{2}} (cm)"); | |
78451bcd | 2447 | fhRCellE->SetYTitle("#it{E} (GeV)"); |
a6f26052 | 2448 | outputContainer->Add(fhRCellE); |
2449 | ||
2450 | fhXCellE = new TH2F ("hXCellE","Cell X position vs cell energy",xbins,xmin,xmax,nptbins,ptmin,ptmax); | |
78451bcd | 2451 | fhXCellE->SetXTitle("#it{x} (cm)"); |
2452 | fhXCellE->SetYTitle("#it{E} (GeV)"); | |
a6f26052 | 2453 | outputContainer->Add(fhXCellE); |
2454 | ||
2455 | fhYCellE = new TH2F ("hYCellE","Cell Y position vs cell energy",ybins,ymin,ymax,nptbins,ptmin,ptmax); | |
78451bcd | 2456 | fhYCellE->SetXTitle("#it{y} (cm)"); |
2457 | fhYCellE->SetYTitle("#it{E} (GeV)"); | |
a6f26052 | 2458 | outputContainer->Add(fhYCellE); |
2459 | ||
2460 | fhZCellE = new TH2F ("hZCellE","Cell Z position vs cell energy",zbins,zmin,zmax,nptbins,ptmin,ptmax); | |
78451bcd | 2461 | fhZCellE->SetXTitle("#it{z} (cm)"); |
2462 | fhZCellE->SetYTitle("#it{E} (GeV)"); | |
a6f26052 | 2463 | outputContainer->Add(fhZCellE); |
2464 | ||
78451bcd | 2465 | fhXYZCell = new TH3F ("hXYZCell","Cell : #it{x} vs #it{y} vs #it{z}",xbins,xmin,xmax,ybins,ymin,ymax,zbins,zmin,zmax); |
2466 | fhXYZCell->SetXTitle("#it{x} (cm)"); | |
2467 | fhXYZCell->SetYTitle("#it{y} (cm)"); | |
2468 | fhXYZCell->SetZTitle("#it{z} (cm)"); | |
a6f26052 | 2469 | outputContainer->Add(fhXYZCell); |
2470 | ||
2471 | ||
2472 | Float_t dx = TMath::Abs(xmin)+TMath::Abs(xmax); | |
2473 | Float_t dy = TMath::Abs(ymin)+TMath::Abs(ymax); | |
2474 | Float_t dz = TMath::Abs(zmin)+TMath::Abs(zmax); | |
2475 | Float_t dr = TMath::Abs(rmin)+TMath::Abs(rmax); | |
2476 | ||
35c71d5c | 2477 | fhDeltaCellClusterRNCells = new TH2F ("hDeltaCellClusterRNCells","Cluster-Cell R position vs N Cells per Cluster",rbins*2,-dr,dr,nceclbins,nceclmin,nceclmax); |
a6f26052 | 2478 | fhDeltaCellClusterRNCells->SetXTitle("r = #sqrt{x^{2}+y^{2}} (cm)"); |
78451bcd | 2479 | fhDeltaCellClusterRNCells->SetYTitle("#it{n}_{cells per cluster}"); |
a6f26052 | 2480 | outputContainer->Add(fhDeltaCellClusterRNCells); |
2481 | ||
35c71d5c | 2482 | fhDeltaCellClusterXNCells = new TH2F ("hDeltaCellClusterXNCells","Cluster-Cell X position vs N Cells per Cluster",xbins*2,-dx,dx,nceclbins,nceclmin,nceclmax); |
78451bcd | 2483 | fhDeltaCellClusterXNCells->SetXTitle("#it{x} (cm)"); |
2484 | fhDeltaCellClusterXNCells->SetYTitle("#it{n}_{cells per cluster}"); | |
a6f26052 | 2485 | outputContainer->Add(fhDeltaCellClusterXNCells); |
2486 | ||
35c71d5c | 2487 | fhDeltaCellClusterYNCells = new TH2F ("hDeltaCellClusterYNCells","Cluster-Cell Y position vs N Cells per Cluster",ybins*2,-dy,dy,nceclbins,nceclmin,nceclmax); |
78451bcd | 2488 | fhDeltaCellClusterYNCells->SetXTitle("#it{y} (cm)"); |
a6f26052 | 2489 | fhDeltaCellClusterYNCells->SetYTitle("N cells per cluster"); |
2490 | outputContainer->Add(fhDeltaCellClusterYNCells); | |
2491 | ||
35c71d5c | 2492 | fhDeltaCellClusterZNCells = new TH2F ("hDeltaCellClusterZNCells","Cluster-Cell Z position vs N Cells per Cluster",zbins*2,-dz,dz,nceclbins,nceclmin,nceclmax); |
78451bcd | 2493 | fhDeltaCellClusterZNCells->SetXTitle("#it{z} (cm)"); |
2494 | fhDeltaCellClusterZNCells->SetYTitle("#it{n}_{cells per cluster}"); | |
a6f26052 | 2495 | outputContainer->Add(fhDeltaCellClusterZNCells); |
2496 | ||
2497 | fhDeltaCellClusterRE = new TH2F ("hDeltaCellClusterRE","Cluster-Cell R position vs cluster energy",rbins*2,-dr,dr,nptbins,ptmin,ptmax); | |
2498 | fhDeltaCellClusterRE->SetXTitle("r = #sqrt{x^{2}+y^{2}} (cm)"); | |
78451bcd | 2499 | fhDeltaCellClusterRE->SetYTitle("#it{E} (GeV)"); |
a6f26052 | 2500 | outputContainer->Add(fhDeltaCellClusterRE); |
2501 | ||
2502 | fhDeltaCellClusterXE = new TH2F ("hDeltaCellClusterXE","Cluster-Cell X position vs cluster energy",xbins*2,-dx,dx,nptbins,ptmin,ptmax); | |
78451bcd | 2503 | fhDeltaCellClusterXE->SetXTitle("#it{x} (cm)"); |
2504 | fhDeltaCellClusterXE->SetYTitle("#it{E} (GeV)"); | |
a6f26052 | 2505 | outputContainer->Add(fhDeltaCellClusterXE); |
2506 | ||
2507 | fhDeltaCellClusterYE = new TH2F ("hDeltaCellClusterYE","Cluster-Cell Y position vs cluster energy",ybins*2,-dy,dy,nptbins,ptmin,ptmax); | |
78451bcd | 2508 | fhDeltaCellClusterYE->SetXTitle("#it{y} (cm)"); |
2509 | fhDeltaCellClusterYE->SetYTitle("#it{E} (GeV)"); | |
a6f26052 | 2510 | outputContainer->Add(fhDeltaCellClusterYE); |
2511 | ||
2512 | fhDeltaCellClusterZE = new TH2F ("hDeltaCellClusterZE","Cluster-Cell Z position vs cluster energy",zbins*2,-dz,dz,nptbins,ptmin,ptmax); | |
78451bcd | 2513 | fhDeltaCellClusterZE->SetXTitle("#it{z} (cm)"); |
2514 | fhDeltaCellClusterZE->SetYTitle("#it{E} (GeV)"); | |
a6f26052 | 2515 | outputContainer->Add(fhDeltaCellClusterZE); |
2516 | ||
2517 | fhEtaPhiAmp = new TH3F ("hEtaPhiAmp","Cell #eta vs cell #phi vs cell energy",netabins,etamin,etamax,nphibins,phimin,phimax,nptbins,ptmin,ptmax); | |
2518 | fhEtaPhiAmp->SetXTitle("#eta "); | |
2519 | fhEtaPhiAmp->SetYTitle("#phi (rad)"); | |
78451bcd | 2520 | fhEtaPhiAmp->SetZTitle("#it{E} (GeV) "); |
a6f26052 | 2521 | outputContainer->Add(fhEtaPhiAmp); |
2522 | ||
2302a644 | 2523 | } |
c8fe2783 | 2524 | |
a6f26052 | 2525 | //Calo cells |
e3300002 | 2526 | fhNCells = new TH1F ("hNCells","# cells", ncebins,ncemin+0.5,ncemax); |
78451bcd | 2527 | fhNCells->SetXTitle("#it{n}_{cells}"); |
2302a644 | 2528 | outputContainer->Add(fhNCells); |
701cbf54 | 2529 | |
2530 | fhNCellsCutAmpMin = new TH1F ("hNCellsCutAmpMin",Form("# cells amp > %1.2f-%1.2f",fEMCALCellAmpMin,fPHOSCellAmpMin), ncebins,ncemin+0.5,ncemax); | |
78451bcd | 2531 | fhNCellsCutAmpMin->SetXTitle("#it{n}_{cells}"); |
701cbf54 | 2532 | outputContainer->Add(fhNCellsCutAmpMin); |
2302a644 | 2533 | |
78451bcd | 2534 | fhAmplitude = new TH1F ("hAmplitude","#it{E}_{cell}", nptbins*2,ptmin,ptmax); |
2535 | fhAmplitude->SetXTitle("#it{E}_{cell} (GeV)"); | |
2302a644 | 2536 | outputContainer->Add(fhAmplitude); |
2537 | ||
78451bcd | 2538 | fhAmpId = new TH2F ("hAmpId","#it{E}_{cell}", nfineptbins,ptfinemin,ptfinemax,fNMaxRows*fNMaxCols*fNModules,0,fNMaxRows*fNMaxCols*fNModules); |
2539 | fhAmpId->SetXTitle("#it{E}_{cell} (GeV)"); | |
2302a644 | 2540 | outputContainer->Add(fhAmpId); |
638916c4 | 2541 | |
2542 | fhAmpIdLowGain = new TH2F ("hAmpIdLG","Low gain: #it{E}_{cell}", nfineptbins,ptfinemin,ptfinemax,fNMaxRows*fNMaxCols*fNModules,0,fNMaxRows*fNMaxCols*fNModules); | |
2543 | fhAmpIdLowGain->SetXTitle("#it{E}_{cell} (GeV)"); | |
2544 | outputContainer->Add(fhAmpIdLowGain); | |
2302a644 | 2545 | |
638916c4 | 2546 | if(fFillAllCellTimeHisto) |
e6fec6f5 | 2547 | { |
649b825d | 2548 | fhCellTimeSpreadRespectToCellMax = new TH2F ("hCellTimeSpreadRespectToCellMax","t_{cell max}-t_{cell i} per cluster", nptbins,ptmin,ptmax,tdbins,tdmin,tdmax); |
78451bcd | 2549 | fhCellTimeSpreadRespectToCellMax->SetXTitle("#it{E} (GeV)"); |
2550 | fhCellTimeSpreadRespectToCellMax->SetYTitle("#Delta #it{t}_{cell max-i} (ns)"); | |
2302a644 | 2551 | outputContainer->Add(fhCellTimeSpreadRespectToCellMax); |
2552 | ||
649b825d | 2553 | fhClusterMaxCellDiffAverageTime = new TH2F ("hClusterMaxCellDiffAverageTime","t_{cell max}-t_{average} per cluster", nptbins,ptmin,ptmax, tdbins,tdmin,tdmax); |
78451bcd | 2554 | fhClusterMaxCellDiffAverageTime->SetXTitle("#it{E} (GeV)"); |
2555 | fhClusterMaxCellDiffAverageTime->SetYTitle("#Delta #it{t}_{cell max - average} (ns)"); | |
9e9f04cb | 2556 | outputContainer->Add(fhClusterMaxCellDiffAverageTime); |
a82b4462 | 2557 | |
649b825d | 2558 | fhClusterMaxCellDiffWeightedTime = new TH2F ("hClusterMaxCellDiffWeightedTime","t_{cell max}-t_{weighted} per cluster", nptbins,ptmin,ptmax, tdbins,tdmin,tdmax); |
78451bcd | 2559 | fhClusterMaxCellDiffWeightedTime->SetXTitle("#it{E} (GeV)"); |
2560 | fhClusterMaxCellDiffWeightedTime->SetYTitle("#Delta #it{t}_{cell max - weighted} (ns)"); | |
649b825d | 2561 | outputContainer->Add(fhClusterMaxCellDiffWeightedTime); |
35c71d5c | 2562 | |
924e319f | 2563 | fhCellIdCellLargeTimeSpread= new TH1F ("hCellIdCellLargeTimeSpread","Cells with time 100 ns larger than cell max in cluster ", |
35c71d5c | 2564 | fNMaxCols*fNMaxRows*fNModules,0,fNMaxCols*fNMaxRows*fNModules); |
2302a644 | 2565 | fhCellIdCellLargeTimeSpread->SetXTitle("Absolute Cell Id"); |
2566 | outputContainer->Add(fhCellIdCellLargeTimeSpread); | |
521636d2 | 2567 | |
78451bcd | 2568 | fhTime = new TH1F ("hTime","#it{t}_{cell}",ntimebins,timemin,timemax); |
2569 | fhTime->SetXTitle("#it{t}_{cell} (ns)"); | |
2302a644 | 2570 | outputContainer->Add(fhTime); |
2571 | ||
78451bcd | 2572 | fhTimeVz = new TH2F ("hTimeVz","#it{t}_{cell} vs vertex, amplitude > 0.5 GeV",100, 0, 50,ntimebins,timemin,timemax); |
1a72f6c5 | 2573 | fhTimeVz->SetXTitle("|v_{z}| (cm)"); |
78451bcd | 2574 | fhTimeVz->SetYTitle("#it{t}_{cell} (ns)"); |
1a72f6c5 | 2575 | outputContainer->Add(fhTimeVz); |
2576 | ||
78451bcd | 2577 | fhTimeId = new TH2F ("hTimeId","#it{t}_{cell} vs Absolute Id", |
35c71d5c | 2578 | ntimebins,timemin,timemax,fNMaxRows*fNMaxCols*fNModules,0,fNMaxRows*fNMaxCols*fNModules); |
78451bcd | 2579 | fhTimeId->SetXTitle("#it{t}_{cell} (ns)"); |
2302a644 | 2580 | fhTimeId->SetYTitle("Cell Absolute Id"); |
2581 | outputContainer->Add(fhTimeId); | |
2582 | ||
78451bcd | 2583 | fhTimeAmp = new TH2F ("hTimeAmp","#it{t}_{cell} vs #it{E}_{cell}",nptbins*2,ptmin,ptmax,ntimebins,timemin,timemax); |
2584 | fhTimeAmp->SetYTitle("#it{t}_{cell} (ns)"); | |
2585 | fhTimeAmp->SetXTitle("#it{E}_{cell} (GeV)"); | |
2302a644 | 2586 | outputContainer->Add(fhTimeAmp); |
2587 | ||
638916c4 | 2588 | fhTimeIdLowGain = new TH2F ("hTimeIdLG","Low gain: #it{t}_{cell} vs Absolute Id", |
2589 | ntimebins,timemin,timemax,fNMaxRows*fNMaxCols*fNModules,0,fNMaxRows*fNMaxCols*fNModules); | |
2590 | fhTimeIdLowGain->SetXTitle("#it{t}_{cell} (ns)"); | |
2591 | fhTimeIdLowGain->SetYTitle("Cell Absolute Id"); | |
2592 | outputContainer->Add(fhTimeIdLowGain); | |
2593 | ||
2594 | fhTimeAmpLowGain = new TH2F ("hTimeAmpLG","Low gain: #it{t}_{cell} vs #it{E}_{cell}",nptbins*2,ptmin,ptmax,ntimebins,timemin,timemax); | |
2595 | fhTimeAmpLowGain->SetYTitle("#it{t}_{cell} (ns)"); | |
2596 | fhTimeAmpLowGain->SetXTitle("#it{E}_{cell} (GeV)"); | |
2597 | outputContainer->Add(fhTimeAmpLowGain); | |
2598 | ||
2302a644 | 2599 | } |
06f1b12a | 2600 | |
2601 | fhCellECross = new TH2F ("hCellECross","1 - Energy in cross around cell / cell energy", | |
2602 | nptbins,ptmin,ptmax, 400,-1,1.); | |
78451bcd | 2603 | fhCellECross->SetXTitle("#it{E}_{cell} (GeV) "); |
2604 | fhCellECross->SetYTitle("1- #it{E}_{cross}/#it{E}_{cell}"); | |
06f1b12a | 2605 | outputContainer->Add(fhCellECross); |
2606 | ||
1a72f6c5 | 2607 | |
f1538a5f | 2608 | if(fCorrelate) |
2609 | { | |
798a9b04 | 2610 | //PHOS vs EMCAL |
35c71d5c | 2611 | fhCaloCorrNClusters = new TH2F ("hCaloCorrNClusters","# clusters in EMCAL vs PHOS", nclbins,nclmin,nclmax,nclbins,nclmin,nclmax); |
2302a644 | 2612 | fhCaloCorrNClusters->SetXTitle("number of clusters in EMCAL"); |
2613 | fhCaloCorrNClusters->SetYTitle("number of clusters in PHOS"); | |
2614 | outputContainer->Add(fhCaloCorrNClusters); | |
2615 | ||
653aed3c | 2616 | fhCaloCorrEClusters = new TH2F ("hCaloCorrEClusters","summed energy of clusters in EMCAL vs PHOS", nptbins,ptmin,ptmax*2,nptbins,ptmin,ptmax*2); |
78451bcd | 2617 | fhCaloCorrEClusters->SetXTitle("#Sigma #it{E} of clusters in EMCAL (GeV)"); |
2618 | fhCaloCorrEClusters->SetYTitle("#Sigma #it{E} of clusters in PHOS (GeV)"); | |
2302a644 | 2619 | outputContainer->Add(fhCaloCorrEClusters); |
2620 | ||
35c71d5c | 2621 | fhCaloCorrNCells = new TH2F ("hCaloCorrNCells","# Cells in EMCAL vs PHOS", ncebins,ncemin,ncemax, ncebins,ncemin,ncemax); |
649b825d | 2622 | fhCaloCorrNCells->SetXTitle("number of Cells in EMCAL"); |
2623 | fhCaloCorrNCells->SetYTitle("number of Cells in PHOS"); | |
2624 | outputContainer->Add(fhCaloCorrNCells); | |
2302a644 | 2625 | |
653aed3c | 2626 | fhCaloCorrECells = new TH2F ("hCaloCorrECells","summed energy of Cells in EMCAL vs PHOS", nptbins*2,ptmin,ptmax*4,nptbins*2,ptmin,ptmax*4); |
78451bcd | 2627 | fhCaloCorrECells->SetXTitle("#Sigma #it{E} of Cells in EMCAL (GeV)"); |
2628 | fhCaloCorrECells->SetYTitle("#Sigma #it{E} of Cells in PHOS (GeV)"); | |
649b825d | 2629 | outputContainer->Add(fhCaloCorrECells); |
2302a644 | 2630 | |
649b825d | 2631 | //Calorimeter VS V0 signal |
2632 | fhCaloV0SCorrNClusters = new TH2F ("hCaloV0SNClusters",Form("# clusters in %s vs V0 signal",fCalorimeter.Data()), nv0sbins,nv0smin,nv0smax,nclbins,nclmin,nclmax); | |
2633 | fhCaloV0SCorrNClusters->SetXTitle("V0 signal"); | |
2634 | fhCaloV0SCorrNClusters->SetYTitle(Form("number of clusters in %s",fCalorimeter.Data())); | |
2635 | outputContainer->Add(fhCaloV0SCorrNClusters); | |
2302a644 | 2636 | |
653aed3c | 2637 | fhCaloV0SCorrEClusters = new TH2F ("hCaloV0SEClusters",Form("summed energy of clusters in %s vs V0 signal",fCalorimeter.Data()), nv0sbins,nv0smin,nv0smax,nptbins,ptmin,ptmax*2); |
649b825d | 2638 | fhCaloV0SCorrEClusters->SetXTitle("V0 signal"); |
78451bcd | 2639 | fhCaloV0SCorrEClusters->SetYTitle(Form("#Sigma #it{E} of clusters in %s (GeV)",fCalorimeter.Data())); |
649b825d | 2640 | outputContainer->Add(fhCaloV0SCorrEClusters); |
2302a644 | 2641 | |
649b825d | 2642 | fhCaloV0SCorrNCells = new TH2F ("hCaloV0SNCells",Form("# Cells in %s vs V0 signal",fCalorimeter.Data()), nv0sbins,nv0smin,nv0smax, ncebins,ncemin,ncemax); |
2643 | fhCaloV0SCorrNCells->SetXTitle("V0 signal"); | |
2644 | fhCaloV0SCorrNCells->SetYTitle(Form("number of Cells in %s",fCalorimeter.Data())); | |
2645 | outputContainer->Add(fhCaloV0SCorrNCells); | |
3bfc4732 | 2646 | |
653aed3c | 2647 | fhCaloV0SCorrECells = new TH2F ("hCaloV0SECells",Form("summed energy of Cells in %s vs V0 signal",fCalorimeter.Data()), nv0sbins,nv0smin,nv0smax,nptbins,ptmin,ptmax*2); |
649b825d | 2648 | fhCaloV0SCorrECells->SetXTitle("V0 signal"); |
78451bcd | 2649 | fhCaloV0SCorrECells->SetYTitle(Form("#Sigma #it{E} of Cells in %s (GeV)",fCalorimeter.Data())); |
649b825d | 2650 | outputContainer->Add(fhCaloV0SCorrECells); |
3bfc4732 | 2651 | |
649b825d | 2652 | //Calorimeter VS V0 multiplicity |
2653 | fhCaloV0MCorrNClusters = new TH2F ("hCaloV0MNClusters",Form("# clusters in %s vs V0 signal",fCalorimeter.Data()), nv0mbins,nv0mmin,nv0mmax,nclbins,nclmin,nclmax); | |
2654 | fhCaloV0MCorrNClusters->SetXTitle("V0 signal"); | |
2655 | fhCaloV0MCorrNClusters->SetYTitle(Form("number of clusters in %s",fCalorimeter.Data())); | |
2656 | outputContainer->Add(fhCaloV0MCorrNClusters); | |
3bfc4732 | 2657 | |
653aed3c | 2658 | fhCaloV0MCorrEClusters = new TH2F ("hCaloV0MEClusters",Form("summed energy of clusters in %s vs V0 signal",fCalorimeter.Data()), nv0mbins,nv0mmin,nv0mmax,nptbins,ptmin,ptmax*2); |
649b825d | 2659 | fhCaloV0MCorrEClusters->SetXTitle("V0 signal"); |
78451bcd | 2660 | fhCaloV0MCorrEClusters->SetYTitle(Form("#Sigma #it{E} of clusters in %s (GeV)",fCalorimeter.Data())); |
649b825d | 2661 | outputContainer->Add(fhCaloV0MCorrEClusters); |
3bfc4732 | 2662 | |
649b825d | 2663 | fhCaloV0MCorrNCells = new TH2F ("hCaloV0MNCells",Form("# Cells in %s vs V0 signal",fCalorimeter.Data()), nv0mbins,nv0mmin,nv0mmax, ncebins,ncemin,ncemax); |
2664 | fhCaloV0MCorrNCells->SetXTitle("V0 signal"); | |
2665 | fhCaloV0MCorrNCells->SetYTitle(Form("number of Cells in %s",fCalorimeter.Data())); | |
2666 | outputContainer->Add(fhCaloV0MCorrNCells); | |
3bfc4732 | 2667 | |
653aed3c | 2668 | fhCaloV0MCorrECells = new TH2F ("hCaloV0MECells",Form("summed energy of Cells in %s vs V0 signal",fCalorimeter.Data()), nv0mbins,nv0mmin,nv0mmax,nptbins,ptmin,ptmax*2); |
649b825d | 2669 | fhCaloV0MCorrECells->SetXTitle("V0 signal"); |
78451bcd | 2670 | fhCaloV0MCorrECells->SetYTitle(Form("#Sigma #it{E} of Cells in %s (GeV)",fCalorimeter.Data())); |
649b825d | 2671 | outputContainer->Add(fhCaloV0MCorrECells); |
3bfc4732 | 2672 | |
649b825d | 2673 | //Calorimeter VS Track multiplicity |
2674 | fhCaloTrackMCorrNClusters = new TH2F ("hCaloTrackMNClusters",Form("# clusters in %s vs # tracks",fCalorimeter.Data()), ntrmbins,ntrmmin,ntrmmax,nclbins,nclmin,nclmax); | |
2675 | fhCaloTrackMCorrNClusters->SetXTitle("# tracks"); | |
2676 | fhCaloTrackMCorrNClusters->SetYTitle(Form("number of clusters in %s",fCalorimeter.Data())); | |
2677 | outputContainer->Add(fhCaloTrackMCorrNClusters); | |
3bfc4732 | 2678 | |
653aed3c | 2679 | fhCaloTrackMCorrEClusters = new TH2F ("hCaloTrackMEClusters",Form("summed energy of clusters in %s vs # tracks",fCalorimeter.Data()), ntrmbins,ntrmmin,ntrmmax,nptbins,ptmin,ptmax*2); |
649b825d | 2680 | fhCaloTrackMCorrEClusters->SetXTitle("# tracks"); |
78451bcd | 2681 | fhCaloTrackMCorrEClusters->SetYTitle(Form("#Sigma #it{E} of clusters in %s (GeV)",fCalorimeter.Data())); |
649b825d | 2682 | outputContainer->Add(fhCaloTrackMCorrEClusters); |
3bfc4732 | 2683 | |
649b825d | 2684 | fhCaloTrackMCorrNCells = new TH2F ("hCaloTrackMNCells",Form("# Cells in %s vs # tracks",fCalorimeter.Data()), ntrmbins,ntrmmin,ntrmmax, ncebins,ncemin,ncemax); |
2685 | fhCaloTrackMCorrNCells->SetXTitle("# tracks"); | |
2686 | fhCaloTrackMCorrNCells->SetYTitle(Form("number of Cells in %s",fCalorimeter.Data())); | |
2687 | outputContainer->Add(fhCaloTrackMCorrNCells); | |
3bfc4732 | 2688 | |
653aed3c | 2689 | fhCaloTrackMCorrECells = new TH2F ("hCaloTrackMECells",Form("summed energy of Cells in %s vs # tracks",fCalorimeter.Data()), ntrmbins,ntrmmin,ntrmmax,nptbins,ptmin,ptmax*2); |
649b825d | 2690 | fhCaloTrackMCorrECells->SetXTitle("# tracks"); |
78451bcd | 2691 | fhCaloTrackMCorrECells->SetYTitle(Form("#Sigma #it{E} of Cells in %s (GeV)",fCalorimeter.Data())); |
649b825d | 2692 | outputContainer->Add(fhCaloTrackMCorrECells); |
3bfc4732 | 2693 | |
653aed3c | 2694 | fhCaloCenNClusters = new TH2F ("hCaloCenNClusters","# clusters in calorimeter vs centrality",100,0,100,nclbins,nclmin,nclmax); |
2695 | fhCaloCenNClusters->SetYTitle("number of clusters in calorimeter"); | |
2696 | fhCaloCenNClusters->SetXTitle("Centrality"); | |
2697 | outputContainer->Add(fhCaloCenNClusters); | |
2698 | ||
2699 | fhCaloCenEClusters = new TH2F ("hCaloCenEClusters","summed energy of clusters in calorimeter vs centrality",100,0,100,nptbins,ptmin,ptmax*2); | |
78451bcd | 2700 | fhCaloCenEClusters->SetYTitle("#Sigma #it{E} of clusters in calorimeter (GeV)"); |
653aed3c | 2701 | fhCaloCenEClusters->SetXTitle("Centrality"); |
2702 | outputContainer->Add(fhCaloCenEClusters); | |
2703 | ||
2704 | fhCaloCenNCells = new TH2F ("hCaloCenNCells","# Cells in calorimeter vs centrality",100,0,100,ncebins,ncemin,ncemax); | |
2705 | fhCaloCenNCells->SetYTitle("number of Cells in calorimeter"); | |
2706 | fhCaloCenNCells->SetXTitle("Centrality"); | |
2707 | outputContainer->Add(fhCaloCenNCells); | |
2708 | ||
2709 | fhCaloCenECells = new TH2F ("hCaloCenECells","summed energy of Cells in calorimeter vs centrality",100,0,100,nptbins*2,ptmin,ptmax*4); | |
78451bcd | 2710 | fhCaloCenECells->SetYTitle("#Sigma #it{E} of Cells in calorimeter (GeV)"); |
653aed3c | 2711 | fhCaloCenECells->SetXTitle("Centrality"); |
2712 | outputContainer->Add(fhCaloCenECells); | |
2713 | ||
2714 | fhCaloEvPNClusters = new TH2F ("hCaloEvPNClusters","# clusters in calorimeter vs event plane angle",100,0,TMath::Pi(),nclbins,nclmin,nclmax); | |
2715 | fhCaloEvPNClusters->SetYTitle("number of clusters in calorimeter"); | |
2716 | fhCaloEvPNClusters->SetXTitle("Event plane angle (rad)"); | |
2717 | outputContainer->Add(fhCaloEvPNClusters); | |
2718 | ||
2719 | fhCaloEvPEClusters = new TH2F ("hCaloEvPEClusters","summed energy of clusters in calorimeter vs event plane angle",100,0,TMath::Pi(),nptbins,ptmin,ptmax*2); | |
78451bcd | 2720 | fhCaloEvPEClusters->SetYTitle("#Sigma #it{E} of clusters in calorimeter (GeV)"); |
653aed3c | 2721 | fhCaloEvPEClusters->SetXTitle("Event plane angle (rad)"); |
2722 | outputContainer->Add(fhCaloEvPEClusters); | |
2723 | ||
2724 | fhCaloEvPNCells = new TH2F ("hCaloEvPNCells","# Cells in calorimeter vs event plane angle",100,0,TMath::Pi(),ncebins,ncemin,ncemax); | |
2725 | fhCaloEvPNCells->SetYTitle("number of Cells in calorimeter"); | |
2726 | fhCaloEvPNCells->SetXTitle("Event plane angle (rad)"); | |
2727 | outputContainer->Add(fhCaloEvPNCells); | |
2728 | ||
2729 | fhCaloEvPECells = new TH2F ("hCaloEvPECells","summed energy of Cells in calorimeter vs event plane angle",100,0,TMath::Pi(),nptbins*2,ptmin,ptmax*4); | |
78451bcd | 2730 | fhCaloEvPECells->SetYTitle("#Sigma #it{E} of Cells in calorimeter (GeV)"); |
653aed3c | 2731 | fhCaloEvPECells->SetXTitle("Event plane angle (rad)"); |
2732 | outputContainer->Add(fhCaloEvPECells); | |
2733 | ||
3bfc4732 | 2734 | |
649b825d | 2735 | }//correlate calorimeters |
c8fe2783 | 2736 | |
649b825d | 2737 | //Module histograms |
9725fd2a | 2738 | |
649b825d | 2739 | fhEMod = new TH2F ("hE_Mod","Cluster reconstructed Energy in each present Module",nptbins,ptmin,ptmax,fNModules,0,fNModules); |
78451bcd | 2740 | fhEMod->SetXTitle("#it{E} (GeV)"); |
649b825d | 2741 | fhEMod->SetYTitle("Module"); |
2742 | outputContainer->Add(fhEMod); | |
c8fe2783 | 2743 | |
649b825d | 2744 | fhAmpMod = new TH2F ("hAmp_Mod","Cell energy in each present Module",nptbins,ptmin,ptmax,fNModules,0,fNModules); |
78451bcd | 2745 | fhAmpMod->SetXTitle("#it{E} (GeV)"); |
649b825d | 2746 | fhAmpMod->SetYTitle("Module"); |
2747 | outputContainer->Add(fhAmpMod); | |
3bfc4732 | 2748 | |
e6fec6f5 | 2749 | if(fFillAllCellTimeHisto) |
2750 | { | |
0fb69ade | 2751 | fhTimeMod = new TH2F ("hTime_Mod","Cell time in each present Module",ntimebins,timemin,timemax,fNModules,0,fNModules); |
2752 | fhTimeMod->SetXTitle("t (ns)"); | |
2753 | fhTimeMod->SetYTitle("Module"); | |
2754 | outputContainer->Add(fhTimeMod); | |
2755 | } | |
3bfc4732 | 2756 | |
e3300002 | 2757 | fhNClustersMod = new TH2F ("hNClusters_Mod","# clusters vs Module", nclbins,nclmin+0.5,nclmax,fNModules,0,fNModules); |
649b825d | 2758 | fhNClustersMod->SetXTitle("number of clusters"); |
2759 | fhNClustersMod->SetYTitle("Module"); | |
2760 | outputContainer->Add(fhNClustersMod); | |
2302a644 | 2761 | |
e3300002 | 2762 | fhNCellsMod = new TH2F ("hNCells_Mod","# cells vs Module", ncebins,ncemin+0.5,ncemax,fNModules,0,fNModules); |
78451bcd | 2763 | fhNCellsMod->SetXTitle("#it{n}_{cells}"); |
649b825d | 2764 | fhNCellsMod->SetYTitle("Module"); |
2765 | outputContainer->Add(fhNCellsMod); | |
17708df9 | 2766 | |
649b825d | 2767 | Int_t colmaxs = fNMaxCols; |
2768 | Int_t rowmaxs = fNMaxRows; | |
e6fec6f5 | 2769 | if(fCalorimeter=="EMCAL") |
2770 | { | |
649b825d | 2771 | colmaxs=2*fNMaxCols; |
2772 | rowmaxs=Int_t(fNModules/2)*fNMaxRows; | |
2773 | } | |
e6fec6f5 | 2774 | else |
2775 | { | |
649b825d | 2776 | rowmaxs=fNModules*fNMaxRows; |
2302a644 | 2777 | } |
3bfc4732 | 2778 | |
649b825d | 2779 | fhGridCells = new TH2F ("hGridCells",Form("Entries in grid of cells"), |
2780 | colmaxs+2,-1.5,colmaxs+0.5, rowmaxs+2,-1.5,rowmaxs+0.5); | |
2781 | fhGridCells->SetYTitle("row (phi direction)"); | |
2782 | fhGridCells->SetXTitle("column (eta direction)"); | |
2783 | outputContainer->Add(fhGridCells); | |
3bfc4732 | 2784 | |
649b825d | 2785 | fhGridCellsE = new TH2F ("hGridCellsE","Accumulated energy in grid of cells", |
2786 | colmaxs+2,-1.5,colmaxs+0.5, rowmaxs+2,-1.5,rowmaxs+0.5); | |
2787 | fhGridCellsE->SetYTitle("row (phi direction)"); | |
2788 | fhGridCellsE->SetXTitle("column (eta direction)"); | |
2789 | outputContainer->Add(fhGridCellsE); | |
3bfc4732 | 2790 | |
638916c4 | 2791 | fhGridCellsLowGain = new TH2F ("hGridCellsLG",Form("Low gain: Entries in grid of cells"), |
2792 | colmaxs+2,-1.5,colmaxs+0.5, rowmaxs+2,-1.5,rowmaxs+0.5); | |
2793 | fhGridCellsLowGain->SetYTitle("row (phi direction)"); | |
2794 | fhGridCellsLowGain->SetXTitle("column (eta direction)"); | |
2795 | outputContainer->Add(fhGridCellsLowGain); | |
2796 | ||
2797 | fhGridCellsELowGain = new TH2F ("hGridCellsELG","Low gain: Accumulated energy in grid of cells", | |
2798 | colmaxs+2,-1.5,colmaxs+0.5, rowmaxs+2,-1.5,rowmaxs+0.5); | |
2799 | fhGridCellsELowGain->SetYTitle("row (phi direction)"); | |
2800 | fhGridCellsELowGain->SetXTitle("column (eta direction)"); | |
2801 | outputContainer->Add(fhGridCellsELowGain); | |
2802 | ||
2803 | ||
e6fec6f5 | 2804 | if(fFillAllCellTimeHisto) |
2805 | { | |
638916c4 | 2806 | fhGridCellsTime = new TH2F ("hGridCellsTime","Accumulated time in grid of cells", |
2807 | colmaxs+2,-1.5,colmaxs+0.5, rowmaxs+2,-1.5,rowmaxs+0.5); | |
0fb69ade | 2808 | fhGridCellsTime->SetYTitle("row (phi direction)"); |
2809 | fhGridCellsTime->SetXTitle("column (eta direction)"); | |
638916c4 | 2810 | outputContainer->Add(fhGridCellsTime); |
2811 | ||
2812 | fhGridCellsTimeLowGain = new TH2F ("hGridCellsTimeLG","Low gain: Accumulated time in grid of cells", | |
2813 | colmaxs+2,-1.5,colmaxs+0.5, rowmaxs+2,-1.5,rowmaxs+0.5); | |
2814 | fhGridCellsTimeLowGain->SetYTitle("row (phi direction)"); | |
2815 | fhGridCellsTimeLowGain->SetXTitle("column (eta direction)"); | |
2816 | outputContainer->Add(fhGridCellsTimeLowGain); | |
0fb69ade | 2817 | } |
3bfc4732 | 2818 | |
e6fec6f5 | 2819 | fhNCellsPerClusterMod = new TH2F*[fNModules]; |
649b825d | 2820 | fhNCellsPerClusterModNoCut = new TH2F*[fNModules]; |
e6fec6f5 | 2821 | fhIMMod = new TH2F*[fNModules]; |
2822 | if(fFillAllCellTimeHisto) fhTimeAmpPerRCU = new TH2F*[fNModules*fNRCU]; | |
0fb69ade | 2823 | |
e6fec6f5 | 2824 | for(Int_t imod = 0; imod < fNModules; imod++) |
2825 | { | |
649b825d | 2826 | fhNCellsPerClusterMod[imod] = new TH2F (Form("hNCellsPerCluster_Mod%d",imod), |
2827 | Form("# cells per cluster vs cluster energy in Module %d",imod), | |
2828 | nptbins,ptmin,ptmax, nceclbins,nceclmin,nceclmax); | |
78451bcd | 2829 | fhNCellsPerClusterMod[imod]->SetXTitle("#it{E} (GeV)"); |
2830 | fhNCellsPerClusterMod[imod]->SetYTitle("#it{n}_{cells}"); | |
649b825d | 2831 | outputContainer->Add(fhNCellsPerClusterMod[imod]); |
3bfc4732 | 2832 | |
649b825d | 2833 | fhNCellsPerClusterModNoCut[imod] = new TH2F (Form("hNCellsPerClusterNoCut_Mod%d",imod), |
2834 | Form("# cells per cluster vs cluster energy in Module %d, no cut",imod), | |
2835 | nptbins,ptmin,ptmax, nceclbins,nceclmin,nceclmax); | |
78451bcd | 2836 | fhNCellsPerClusterModNoCut[imod]->SetXTitle("#it{E} (GeV)"); |
2837 | fhNCellsPerClusterModNoCut[imod]->SetYTitle("#it{n}_{cells}"); | |
649b825d | 2838 | outputContainer->Add(fhNCellsPerClusterModNoCut[imod]); |
3bfc4732 | 2839 | |
e6fec6f5 | 2840 | if(fFillAllCellTimeHisto) |
2841 | { | |
2842 | for(Int_t ircu = 0; ircu < fNRCU; ircu++) | |
2843 | { | |
649b825d | 2844 | fhTimeAmpPerRCU[imod*fNRCU+ircu] = new TH2F (Form("hTimeAmp_Mod%d_RCU%d",imod,ircu), |
78451bcd | 2845 | Form("#it{E}_{cell} vs #it{t}_{cell} in Module %d, RCU %d ",imod,ircu), |
649b825d | 2846 | nptbins,ptmin,ptmax,ntimebins,timemin,timemax); |
78451bcd | 2847 | fhTimeAmpPerRCU[imod*fNRCU+ircu]->SetXTitle("#it{E} (GeV)"); |
2848 | fhTimeAmpPerRCU[imod*fNRCU+ircu]->SetYTitle("#it{t} (ns)"); | |
649b825d | 2849 | outputContainer->Add(fhTimeAmpPerRCU[imod*fNRCU+ircu]); |
3bfc4732 | 2850 | |
649b825d | 2851 | } |
3bfc4732 | 2852 | } |
2853 | ||
e6fec6f5 | 2854 | if(fFillAllPi0Histo) |
2855 | { | |
649b825d | 2856 | fhIMMod[imod] = new TH2F (Form("hIM_Mod%d",imod), |
2857 | Form("Cluster pairs Invariant mass vs reconstructed pair energy in Module %d, n cell > 1",imod), | |
2858 | nptbins,ptmin,ptmax,nmassbins,massmin,massmax); | |
78451bcd | 2859 | fhIMMod[imod]->SetXTitle("#it{p}_{T, cluster pairs} (GeV) "); |
2860 | fhIMMod[imod]->SetYTitle("#it{M}_{cluster pairs} (GeV/#it{c}^{2})"); | |
649b825d | 2861 | outputContainer->Add(fhIMMod[imod]); |
3bfc4732 | 2862 | |
649b825d | 2863 | } |
2864 | } | |
2865 | ||
a82b4462 | 2866 | // Monte Carlo Histograms |
649b825d | 2867 | |
6aba6683 | 2868 | TString particleName[] = { "Photon","PhotonConv","Pi0", "Eta", "Electron", "NeutralHadron", "ChargedHadron" }; |
649b825d | 2869 | |
f1538a5f | 2870 | if(IsDataMC()) |
2871 | { | |
6aba6683 | 2872 | for(Int_t iPart = 0; iPart < 7; iPart++) |
f1538a5f | 2873 | { |
2874 | for(Int_t iCh = 0; iCh < 2; iCh++) | |
2875 | { | |
649b825d | 2876 | fhRecoMCRatioE[iPart][iCh] = new TH2F (Form("hRecoMCRatioE_%s_Match%d",particleName[iPart].Data(),iCh), |
3fa37dff | 2877 | Form("Reconstructed/Generated E, %s, Matched %d",particleName[iPart].Data(),iCh), |
649b825d | 2878 | nptbins, ptmin, ptmax, 200,0,2); |
78451bcd | 2879 | fhRecoMCRatioE[iPart][iCh]->SetYTitle("#it{E}_{reconstructed}/#it{E}_{generated}"); |
2880 | fhRecoMCRatioE[iPart][iCh]->SetXTitle("#it{E}_{reconstructed} (GeV)"); | |
649b825d | 2881 | outputContainer->Add(fhRecoMCRatioE[iPart][iCh]); |
3bfc4732 | 2882 | |
3bfc4732 | 2883 | |
649b825d | 2884 | fhRecoMCDeltaE[iPart][iCh] = new TH2F (Form("hRecoMCDeltaE_%s_Match%d",particleName[iPart].Data(),iCh), |
3fa37dff | 2885 | Form("Generated - Reconstructed E, %s, Matched %d",particleName[iPart].Data(),iCh), |
649b825d | 2886 | nptbins, ptmin, ptmax, nptbins*2,-ptmax,ptmax); |
78451bcd | 2887 | fhRecoMCDeltaE[iPart][iCh]->SetYTitle("#Delta #it{E} (GeV)"); |
2888 | fhRecoMCDeltaE[iPart][iCh]->SetXTitle("#it{E}_{reconstructed} (GeV)"); | |
649b825d | 2889 | outputContainer->Add(fhRecoMCDeltaE[iPart][iCh]); |
3bfc4732 | 2890 | |
649b825d | 2891 | fhRecoMCDeltaPhi[iPart][iCh] = new TH2F (Form("hRecoMCDeltaPhi_%s_Match%d",particleName[iPart].Data(),iCh), |
3fa37dff | 2892 | Form("Generated - Reconstructed #phi, %s, Matched %d",particleName[iPart].Data(),iCh), |
649b825d | 2893 | nptbins, ptmin, ptmax, nphibins*2,-phimax,phimax); |
3fa37dff | 2894 | fhRecoMCDeltaPhi[iPart][iCh]->SetYTitle("#Delta #phi (rad)"); |
78451bcd | 2895 | fhRecoMCDeltaPhi[iPart][iCh]->SetXTitle("#it{E}_{reconstructed} (GeV)"); |
649b825d | 2896 | outputContainer->Add(fhRecoMCDeltaPhi[iPart][iCh]); |
3bfc4732 | 2897 | |
649b825d | 2898 | fhRecoMCDeltaEta[iPart][iCh] = new TH2F (Form("hRecoMCDeltaEta_%s_Match%d",particleName[iPart].Data(),iCh), |
3fa37dff | 2899 | Form("Generated - Reconstructed #eta, %s, Matched %d",particleName[iPart].Data(),iCh), |
649b825d | 2900 | nptbins, ptmin, ptmax,netabins*2,-etamax,etamax); |
3fa37dff | 2901 | fhRecoMCDeltaEta[iPart][iCh]->SetYTitle("#Delta #eta "); |
78451bcd | 2902 | fhRecoMCDeltaEta[iPart][iCh]->SetXTitle("#it{E}_{reconstructed} (GeV)"); |
649b825d | 2903 | outputContainer->Add(fhRecoMCDeltaEta[iPart][iCh]); |
e1e62b89 | 2904 | |
649b825d | 2905 | fhRecoMCE[iPart][iCh] = new TH2F (Form("hRecoMCE_%s_Match%d",particleName[iPart].Data(),iCh), |
78451bcd | 2906 | Form("#it{E} distribution, reconstructed vs generated, %s, Matched %d",particleName[iPart].Data(),iCh), |
649b825d | 2907 | nptbins,ptmin,ptmax,nptbins,ptmin,ptmax); |
78451bcd | 2908 | fhRecoMCE[iPart][iCh]->SetXTitle("#it{E}_{rec} (GeV)"); |
2909 | fhRecoMCE[iPart][iCh]->SetYTitle("#it{E}_{gen} (GeV)"); | |
649b825d | 2910 | outputContainer->Add(fhRecoMCE[iPart][iCh]); |
3bfc4732 | 2911 | |
649b825d | 2912 | fhRecoMCPhi[iPart][iCh] = new TH2F (Form("hRecoMCPhi_%s_Match%d",particleName[iPart].Data(),iCh), |
2913 | Form("#phi distribution, reconstructed vs generated, %s, Matched %d",particleName[iPart].Data(),iCh), | |
2914 | nphibins,phimin,phimax, nphibins,phimin,phimax); | |
3fa37dff | 2915 | fhRecoMCPhi[iPart][iCh]->SetXTitle("#phi_{reconstructed} (rad)"); |
2916 | fhRecoMCPhi[iPart][iCh]->SetYTitle("#phi_{generated} (rad)"); | |
649b825d | 2917 | outputContainer->Add(fhRecoMCPhi[iPart][iCh]); |
e1e62b89 | 2918 | |
649b825d | 2919 | fhRecoMCEta[iPart][iCh] = new TH2F (Form("hRecoMCEta_%s_Match%d",particleName[iPart].Data(),iCh), |
2920 | Form("#eta distribution, reconstructed vs generated, %s, Matched %d",particleName[iPart].Data(),iCh), | |
2921 | netabins,etamin,etamax,netabins,etamin,etamax); | |
3fa37dff | 2922 | fhRecoMCEta[iPart][iCh]->SetXTitle("#eta_{reconstructed} "); |
2923 | fhRecoMCEta[iPart][iCh]->SetYTitle("#eta_{generated} "); | |
649b825d | 2924 | outputContainer->Add(fhRecoMCEta[iPart][iCh]); |
3bfc4732 | 2925 | } |
649b825d | 2926 | } |
c8fe2783 | 2927 | |
649b825d | 2928 | //Pure MC |
f1538a5f | 2929 | for(Int_t iPart = 0; iPart < 4; iPart++) |
2930 | { | |
95aee5e1 | 2931 | fhGenMCE [iPart] = new TH1F(Form("hGenMCE_%s",particleName[iPart].Data()) , |
2932 | Form("#it{E} of generated %s",particleName[iPart].Data()), | |
2933 | nptbins,ptmin,ptmax); | |
2934 | ||
2935 | fhGenMCPt[iPart] = new TH1F(Form("hGenMCPt_%s",particleName[iPart].Data()) , | |
78451bcd | 2936 | Form("#it{p}_{T} of generated %s",particleName[iPart].Data()), |
649b825d | 2937 | nptbins,ptmin,ptmax); |
95aee5e1 | 2938 | |
649b825d | 2939 | fhGenMCEtaPhi[iPart] = new TH2F(Form("hGenMCEtaPhi_%s",particleName[iPart].Data()), |
2940 | Form("Y vs #phi of generated %s",particleName[iPart].Data()), | |
95aee5e1 | 2941 | 200,-1,1,360,0,TMath::TwoPi()); |
649b825d | 2942 | |
95aee5e1 | 2943 | fhGenMCE [iPart] ->SetXTitle("#it{E} (GeV)"); |
2944 | fhGenMCPt[iPart] ->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
649b825d | 2945 | fhGenMCEtaPhi[iPart]->SetXTitle("#eta"); |
2946 | fhGenMCEtaPhi[iPart]->SetYTitle("#phi (rad)"); | |
95aee5e1 | 2947 | |
2948 | outputContainer->Add(fhGenMCE [iPart]); | |
2949 | outputContainer->Add(fhGenMCPt [iPart]); | |
649b825d | 2950 | outputContainer->Add(fhGenMCEtaPhi[iPart]); |
521636d2 | 2951 | |
521636d2 | 2952 | |
95aee5e1 | 2953 | fhGenMCAccE [iPart] = new TH1F(Form("hGenMCAccE_%s",particleName[iPart].Data()) , |
78451bcd | 2954 | Form("#it{E} of generated %s",particleName[iPart].Data()), |
649b825d | 2955 | nptbins,ptmin,ptmax); |
95aee5e1 | 2956 | fhGenMCAccPt[iPart] = new TH1F(Form("hGenMCAccPt_%s",particleName[iPart].Data()) , |
2957 | Form("#it{p}_{T} of generated %s",particleName[iPart].Data()), | |
2958 | nptbins,ptmin,ptmax); | |
649b825d | 2959 | fhGenMCAccEtaPhi[iPart] = new TH2F(Form("hGenMCAccEtaPhi_%s",particleName[iPart].Data()), |
2960 | Form("Y vs #phi of generated %s",particleName[iPart].Data()), | |
2961 | netabins,etamin,etamax,nphibins,phimin,phimax); | |
2962 | ||
95aee5e1 | 2963 | fhGenMCAccE [iPart] ->SetXTitle("#it{E} (GeV)"); |
2964 | fhGenMCAccPt[iPart] ->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
649b825d | 2965 | fhGenMCAccEtaPhi[iPart]->SetXTitle("#eta"); |
2966 | fhGenMCAccEtaPhi[iPart]->SetYTitle("#phi (rad)"); | |
2967 | ||
95aee5e1 | 2968 | outputContainer->Add(fhGenMCAccE [iPart]); |
2969 | outputContainer->Add(fhGenMCAccPt [iPart]); | |
649b825d | 2970 | outputContainer->Add(fhGenMCAccEtaPhi[iPart]); |
2971 | ||
2972 | } | |
f5036bcb | 2973 | |
649b825d | 2974 | //Vertex of generated particles |
2975 | ||
2976 | fhEMVxyz = new TH2F ("hEMVxyz","Production vertex of reconstructed ElectroMagnetic particles",nvdistbins,vdistmin,vdistmax,nvdistbins,vdistmin,vdistmax);//,100,0,500); | |
78451bcd | 2977 | fhEMVxyz->SetXTitle("#it{v}_{x}"); |
2978 | fhEMVxyz->SetYTitle("#it{v}_{y}"); | |
649b825d | 2979 | //fhEMVxyz->SetZTitle("v_{z}"); |
2980 | outputContainer->Add(fhEMVxyz); | |
2981 | ||
2982 | fhHaVxyz = new TH2F ("hHaVxyz","Production vertex of reconstructed hadrons",nvdistbins,vdistmin,vdistmax,nvdistbins,vdistmin,vdistmax);//,100,0,500); | |
78451bcd | 2983 | fhHaVxyz->SetXTitle("#it{v}_{x}"); |
2984 | fhHaVxyz->SetYTitle("#it{v}_{y}"); | |
649b825d | 2985 | //fhHaVxyz->SetZTitle("v_{z}"); |
2986 | outputContainer->Add(fhHaVxyz); | |
2987 | ||
2988 | fhEMR = new TH2F ("hEMR","Distance to production vertex of reconstructed ElectroMagnetic particles vs E rec",nptbins,ptmin,ptmax,nvdistbins,vdistmin,vdistmax); | |
78451bcd | 2989 | fhEMR->SetXTitle("#it{E} (GeV)"); |
649b825d | 2990 | fhEMR->SetYTitle("TMath::Sqrt(v_{x}^{2}+v_{y}^{2})"); |
2991 | outputContainer->Add(fhEMR); | |
2992 | ||
2993 | fhHaR = new TH2F ("hHaR","Distance to production vertex of reconstructed Hadrons vs E rec",nptbins,ptmin,ptmax,nvdistbins,vdistmin,vdistmax); | |
78451bcd | 2994 | fhHaR->SetXTitle("#it{E} (GeV)"); |
649b825d | 2995 | fhHaR->SetYTitle("TMath::Sqrt(v_{x}^{2}+v_{y}^{2})"); |
2996 | outputContainer->Add(fhHaR); | |
2997 | ||
2998 | ||
2999 | //Track Matching | |
3000 | ||
78451bcd | 3001 | fhMCEle1EOverP = new TH2F("hMCEle1EOverP","TRACK matches #it{E}/#it{p}, MC electrons",nptbins,ptmin,ptmax, nPoverEbins,eOverPmin,eOverPmax); |
3002 | fhMCEle1EOverP->SetYTitle("#it{E}/#it{p}"); | |
3003 | fhMCEle1EOverP->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
d55bb5e1 | 3004 | outputContainer->Add(fhMCEle1EOverP); |
649b825d | 3005 | |
3006 | fhMCEle1dR = new TH1F("hMCEle1dR","TRACK matches dR, MC electrons",ndRbins,dRmin,dRmax); | |
78451bcd | 3007 | fhMCEle1dR->SetXTitle("#Delta #it{R} (rad)"); |
649b825d | 3008 | outputContainer->Add(fhMCEle1dR) ; |
3009 | ||
78451bcd | 3010 | fhMCEle2MatchdEdx = new TH2F("hMCEle2MatchdEdx","#it{dE/dx} vs. #it{p} for all matches, MC electrons",nptbins,ptmin,ptmax,ndedxbins,dedxmin,dedxmax); |
3011 | fhMCEle2MatchdEdx->SetXTitle("#it{p} (GeV/#it{c})"); | |
3012 | fhMCEle2MatchdEdx->SetYTitle("<#it{dE/dx}>"); | |
649b825d | 3013 | outputContainer->Add(fhMCEle2MatchdEdx); |
3014 | ||
78451bcd | 3015 | fhMCChHad1EOverP = new TH2F("hMCChHad1EOverP","TRACK matches #it{E}/#it{p}, MC charged hadrons",nptbins,ptmin,ptmax, nPoverEbins,eOverPmin,eOverPmax); |
3016 | fhMCChHad1EOverP->SetYTitle("#it{E}/#it{p}"); | |
3017 | fhMCChHad1EOverP->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
d55bb5e1 | 3018 | outputContainer->Add(fhMCChHad1EOverP); |
649b825d | 3019 | |
3020 | fhMCChHad1dR = new TH1F("hMCChHad1dR","TRACK matches dR, MC charged hadrons",ndRbins,dRmin,dRmax); | |
3021 | fhMCChHad1dR->SetXTitle("#Delta R (rad)"); | |
3022 | outputContainer->Add(fhMCChHad1dR) ; | |
3023 | ||
78451bcd | 3024 | fhMCChHad2MatchdEdx = new TH2F("hMCChHad2MatchdEdx","#it{dE/dx} vs. #it{p} for all matches, MC charged hadrons",nptbins,ptmin,ptmax,ndedxbins,dedxmin,dedxmax); |
3025 | fhMCChHad2MatchdEdx->SetXTitle("#it{p} (GeV/#it{c})"); | |
3026 | fhMCChHad2MatchdEdx->SetYTitle("#it{dE/dx}>"); | |
649b825d | 3027 | outputContainer->Add(fhMCChHad2MatchdEdx); |
3028 | ||
78451bcd | 3029 | fhMCNeutral1EOverP = new TH2F("hMCNeutral1EOverP","TRACK matches #it{E}/#it{p}, MC neutrals",nptbins,ptmin,ptmax, nPoverEbins,eOverPmin,eOverPmax); |
3030 | fhMCNeutral1EOverP->SetYTitle("#it{E}/#it{p}"); | |
3031 | fhMCNeutral1EOverP->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
d55bb5e1 | 3032 | outputContainer->Add(fhMCNeutral1EOverP); |
649b825d | 3033 | |
3034 | fhMCNeutral1dR = new TH1F("hMCNeutral1dR","TRACK matches dR, MC neutrals",ndRbins,dRmin,dRmax); | |
78451bcd | 3035 | fhMCNeutral1dR->SetXTitle("#Delta #it{R} (rad)"); |
649b825d | 3036 | outputContainer->Add(fhMCNeutral1dR) ; |
3037 | ||
78451bcd | 3038 | fhMCNeutral2MatchdEdx = new TH2F("hMCNeutral2MatchdEdx","#it{dE/dx} vs. #it{p} for all matches, MC neutrals",nptbins,ptmin,ptmax,ndedxbins,dedxmin,dedxmax); |
3039 | fhMCNeutral2MatchdEdx->SetXTitle("#it{p} (GeV/#it{c})"); | |
3040 | fhMCNeutral2MatchdEdx->SetYTitle("#it{dE/dx}>"); | |
649b825d | 3041 | outputContainer->Add(fhMCNeutral2MatchdEdx); |
3042 | ||
78451bcd | 3043 | fhMCEle1EOverPR02 = new TH2F("hMCEle1EOverPR02","TRACK matches #it{E}/#it{p}, MC electrons",nptbins,ptmin,ptmax, nPoverEbins,eOverPmin,eOverPmax); |
3044 | fhMCEle1EOverPR02->SetYTitle("#it{E}/#it{p}"); | |
3045 | fhMCEle1EOverPR02->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
d55bb5e1 | 3046 | outputContainer->Add(fhMCEle1EOverPR02); |
649b825d | 3047 | |
78451bcd | 3048 | fhMCChHad1EOverPR02 = new TH2F("hMCChHad1EOverPR02","TRACK matches #it{E}/#it{p}, MC charged hadrons",nptbins,ptmin,ptmax, nPoverEbins,eOverPmin,eOverPmax); |
3049 | fhMCChHad1EOverPR02->SetYTitle("#it{E}/#it{p}"); | |
3050 | fhMCChHad1EOverPR02->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
d55bb5e1 | 3051 | outputContainer->Add(fhMCChHad1EOverPR02); |
f5036bcb | 3052 | |
78451bcd | 3053 | fhMCNeutral1EOverPR02 = new TH2F("hMCNeutral1EOverPR02","TRACK matches #it{E}/#it{p}, MC neutrals",nptbins,ptmin,ptmax, nPoverEbins,eOverPmin,eOverPmax); |
3054 | fhMCNeutral1EOverPR02->SetYTitle("#it{E}/#it{p}"); | |
3055 | fhMCNeutral1EOverPR02->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
d55bb5e1 | 3056 | outputContainer->Add(fhMCNeutral1EOverPR02); |
7206b21b | 3057 | |
78451bcd | 3058 | fhMCEle1EleEOverP = new TH2F("hMCEle1EleEOverP","Electron candidates #it{E}/#it{p} (60<dEdx<100), MC electrons",nptbins,ptmin,ptmax, nPoverEbins,eOverPmin,eOverPmax); |
3059 | fhMCEle1EleEOverP->SetYTitle("#it{E}/#it{p}"); | |
3060 | fhMCEle1EleEOverP->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
7206b21b | 3061 | outputContainer->Add(fhMCEle1EleEOverP); |
3062 | ||
78451bcd | 3063 | fhMCChHad1EleEOverP = new TH2F("hMCEle1EleEOverP","Electron candidates #it{E}/#it{p} (60<dEdx<100), MC charged hadrons",nptbins,ptmin,ptmax, nPoverEbins,eOverPmin,eOverPmax); |
3064 | fhMCChHad1EleEOverP->SetYTitle("#it{E}/#it{p}"); | |
3065 | fhMCChHad1EleEOverP->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
7206b21b | 3066 | outputContainer->Add(fhMCChHad1EleEOverP); |
3067 | ||
78451bcd | 3068 | fhMCNeutral1EleEOverP = new TH2F("hMCNeutral1EleEOverP","Electron candidates #it{E}/#it{p} (60<dEdx<100), MC neutrals",nptbins,ptmin,ptmax, nPoverEbins,eOverPmin,eOverPmax); |
3069 | fhMCNeutral1EleEOverP->SetYTitle("#it{E}/#it{p}"); | |
3070 | fhMCNeutral1EleEOverP->SetXTitle("#it{p}_{T} (GeV/#it{c})"); | |
7206b21b | 3071 | outputContainer->Add(fhMCNeutral1EleEOverP); |
3072 | ||
521636d2 | 3073 | } |
f5036bcb | 3074 | |
649b825d | 3075 | // for(Int_t i = 0; i < outputContainer->GetEntries() ; i++) |
3076 | // printf("i=%d, name= %s\n",i,outputContainer->At(i)->GetName()); | |
521636d2 | 3077 | |
649b825d | 3078 | return outputContainer; |
902aa95c | 3079 | } |
3080 | ||
b94e038e | 3081 | //______________________________________________________________________________________ |
3082 | Float_t AliAnaCalorimeterQA::GetECross(Int_t absID, AliVCaloCells* cells, Float_t dtcut) | |
1a72f6c5 | 3083 | { |
3084 | // Get energy in cross axis around maximum cell, for EMCAL only | |
3085 | ||
06f1b12a | 3086 | Int_t icol =-1, irow=-1,iRCU = -1; |
3087 | Int_t imod = GetModuleNumberCellIndexes(absID, fCalorimeter, icol, irow, iRCU); | |
e3300002 | 3088 | |
57d8227a | 3089 | if(fCalorimeter=="EMCAL") |
3090 | { | |
06f1b12a | 3091 | //Get close cells index, energy and time, not in corners |
e3300002 | 3092 | |
3093 | Int_t absID1 = -1; | |
3094 | Int_t absID2 = -1; | |
3095 | ||
3096 | if( irow < AliEMCALGeoParams::fgkEMCALRows-1) absID1 = GetCaloUtils()->GetEMCALGeometry()->GetAbsCellIdFromCellIndexes(imod, irow+1, icol); | |
3097 | if( irow > 0 ) absID2 = GetCaloUtils()->GetEMCALGeometry()->GetAbsCellIdFromCellIndexes(imod, irow-1, icol); | |
2747966a | 3098 | |
3099 | // In case of cell in eta = 0 border, depending on SM shift the cross cell index | |
3100 | Int_t absID3 = -1; | |
3101 | Int_t absID4 = -1; | |
3102 | ||
3103 | if ( icol == AliEMCALGeoParams::fgkEMCALCols - 1 && !(imod%2) ) | |
3104 | { | |
e3300002 | 3105 | absID3 = GetCaloUtils()->GetEMCALGeometry()-> GetAbsCellIdFromCellIndexes(imod+1, irow, 0); |
3106 | absID4 = GetCaloUtils()->GetEMCALGeometry()-> GetAbsCellIdFromCellIndexes(imod , irow, icol-1); | |
2747966a | 3107 | } |
3108 | else if( icol == 0 && imod%2 ) | |
3109 | { | |
e3300002 | 3110 | absID3 = GetCaloUtils()->GetEMCALGeometry()-> GetAbsCellIdFromCellIndexes(imod , irow, icol+1); |
3111 | absID4 = GetCaloUtils()->GetEMCALGeometry()-> GetAbsCellIdFromCellIndexes(imod-1, irow, AliEMCALGeoParams::fgkEMCALCols-1); | |
2747966a | 3112 | } |
3113 | else | |
3114 | { | |
e3300002 | 3115 | if( icol < AliEMCALGeoParams::fgkEMCALCols-1 ) |
3116 | absID3 = GetCaloUtils()->GetEMCALGeometry()-> GetAbsCellIdFromCellIndexes(imod, irow, icol+1); | |
3117 | if( icol > 0 ) | |
3118 | absID4 = GetCaloUtils()->GetEMCALGeometry()-> GetAbsCellIdFromCellIndexes(imod, irow, icol-1); | |
2747966a | 3119 | } |
06f1b12a | 3120 | |
3121 | //Recalibrate cell energy if needed | |
3122 | //Float_t ecell = cells->GetCellAmplitude(absID); | |
dbba06ca | 3123 | //GetCaloUtils()->RecalibrateCellAmplitude(ecell,fCalorimeter, absID); |
06f1b12a | 3124 | Double_t tcell = cells->GetCellTime(absID); |
dbba06ca | 3125 | GetCaloUtils()->RecalibrateCellTime(tcell, fCalorimeter, absID,GetReader()->GetInputEvent()->GetBunchCrossNumber()); |
06f1b12a | 3126 | |
3127 | Float_t ecell1 = 0, ecell2 = 0, ecell3 = 0, ecell4 = 0; | |
3128 | Double_t tcell1 = 0, tcell2 = 0, tcell3 = 0, tcell4 = 0; | |
3129 | ||
45769d5b | 3130 | if(absID1 > 0 ) |
2747966a | 3131 | { |
06f1b12a | 3132 | ecell1 = cells->GetCellAmplitude(absID1); |
dbba06ca | 3133 | GetCaloUtils()->RecalibrateCellAmplitude(ecell1, fCalorimeter, absID1); |
06f1b12a | 3134 | tcell1 = cells->GetCellTime(absID1); |
dbba06ca | 3135 | GetCaloUtils()->RecalibrateCellTime (tcell1, fCalorimeter, absID1,GetReader()->GetInputEvent()->GetBunchCrossNumber()); |
06f1b12a | 3136 | } |
45769d5b | 3137 | if(absID2 > 0 ) |
2747966a | 3138 | { |
06f1b12a | 3139 | ecell2 = cells->GetCellAmplitude(absID2); |
dbba06ca | 3140 | GetCaloUtils()->RecalibrateCellAmplitude(ecell2, fCalorimeter, absID2); |
06f1b12a | 3141 | tcell2 = cells->GetCellTime(absID2); |
dbba06ca | 3142 | GetCaloUtils()->RecalibrateCellTime (tcell2, fCalorimeter, absID2, GetReader()->GetInputEvent()->GetBunchCrossNumber()); |
06f1b12a | 3143 | } |
45769d5b | 3144 | if(absID3 > 0 ) |
2747966a | 3145 | { |
06f1b12a | 3146 | ecell3 = cells->GetCellAmplitude(absID3); |
dbba06ca | 3147 | GetCaloUtils()->RecalibrateCellAmplitude(ecell3, fCalorimeter, absID3); |
06f1b12a | 3148 | tcell3 = cells->GetCellTime(absID3); |
dbba06ca | 3149 | GetCaloUtils()->RecalibrateCellTime (tcell3, fCalorimeter, absID3, GetReader()->GetInputEvent()->GetBunchCrossNumber()); |
06f1b12a | 3150 | } |
45769d5b | 3151 | if(absID4 > 0 ) |
2747966a | 3152 | { |
06f1b12a | 3153 | ecell4 = cells->GetCellAmplitude(absID4); |
dbba06ca | 3154 | GetCaloUtils()->RecalibrateCellAmplitude(ecell4, fCalorimeter, absID4); |
06f1b12a | 3155 | tcell4 = cells->GetCellTime(absID4); |
dbba06ca | 3156 | GetCaloUtils()->RecalibrateCellTime (tcell4, fCalorimeter, absID4, GetReader()->GetInputEvent()->GetBunchCrossNumber()); |
06f1b12a | 3157 | } |
f1538a5f | 3158 | |
3159 | if(TMath::Abs(tcell-tcell1)*1.e9 > dtcut) ecell1 = 0 ; | |
3160 | if(TMath::Abs(tcell-tcell2)*1.e9 > dtcut) ecell2 = 0 ; | |
3161 | if(TMath::Abs(tcell-tcell3)*1.e9 > dtcut) ecell3 = 0 ; | |
3162 | if(TMath::Abs(tcell-tcell4)*1.e9 > dtcut) ecell4 = 0 ; | |
06f1b12a | 3163 | |
3164 | return ecell1+ecell2+ecell3+ecell4; | |
1a72f6c5 | 3165 | } |
57d8227a | 3166 | else //PHOS |
3167 | { | |
06f1b12a | 3168 | |
3169 | Int_t absId1 = -1, absId2 = -1, absId3 = -1, absId4 = -1; | |
3170 | ||
3171 | Int_t relId1[] = { imod+1, 0, irow+1, icol }; | |
3172 | Int_t relId2[] = { imod+1, 0, irow-1, icol }; | |
3173 | Int_t relId3[] = { imod+1, 0, irow , icol+1 }; | |
3174 | Int_t relId4[] = { imod+1, 0, irow , icol-1 }; | |
3175 | ||
3176 | GetCaloUtils()->GetPHOSGeometry()->RelToAbsNumbering(relId1, absId1); | |
3177 | GetCaloUtils()->GetPHOSGeometry()->RelToAbsNumbering(relId2, absId2); | |
3178 | GetCaloUtils()->GetPHOSGeometry()->RelToAbsNumbering(relId3, absId3); | |
3179 | GetCaloUtils()->GetPHOSGeometry()->RelToAbsNumbering(relId4, absId4); | |
3180 | ||
3181 | Float_t ecell1 = 0, ecell2 = 0, ecell3 = 0, ecell4 = 0; | |
3182 | ||
3183 | if(absId1 > 0 ) ecell1 = cells->GetCellAmplitude(absId1); | |
3184 | if(absId2 > 0 ) ecell2 = cells->GetCellAmplitude(absId2); | |
3185 | if(absId3 > 0 ) ecell3 = cells->GetCellAmplitude(absId3); | |
3186 | if(absId4 > 0 ) ecell4 = cells->GetCellAmplitude(absId4); | |
3187 | ||
3188 | return ecell1+ecell2+ecell3+ecell4; | |
3189 | ||
1a72f6c5 | 3190 | } |
3191 | ||
1a72f6c5 | 3192 | } |
3193 | ||
c5693f62 | 3194 | //__________________________________________________________________________________________________ |
b94e038e | 3195 | void AliAnaCalorimeterQA::InvariantMassHistograms(Int_t iclus, TLorentzVector mom, |
3196 | Int_t nModule, const TObjArray* caloClusters, | |
a82b4462 | 3197 | AliVCaloCells * cells) |
649b825d | 3198 | { |
3199 | // Fill Invariant mass histograms | |
c8fe2783 | 3200 | |
649b825d | 3201 | if(GetDebug()>1) printf("AliAnaCalorimeterQA::InvariantMassHistograms() - Start \n"); |
3748ffb5 | 3202 | |
649b825d | 3203 | //Get vertex for photon momentum calculation and event selection |
3204 | Double_t v[3] = {0,0,0}; //vertex ; | |
1a83b960 | 3205 | //GetReader()->GetVertex(v); |
a6f26052 | 3206 | |
649b825d | 3207 | Int_t nModule2 = -1; |
3208 | TLorentzVector mom2 ; | |
3209 | Int_t nCaloClusters = caloClusters->GetEntriesFast(); | |
a6f26052 | 3210 | |
d07278cf | 3211 | for(Int_t jclus = iclus + 1 ; jclus < nCaloClusters ; jclus++) |
3212 | { | |
649b825d | 3213 | AliVCluster* clus2 = (AliVCluster*)caloClusters->At(jclus); |
a82b4462 | 3214 | |
3215 | Float_t maxCellFraction = 0.; | |
45769d5b | 3216 | Int_t absIdMax = GetCaloUtils()->GetMaxEnergyCell(cells, clus2, maxCellFraction); |
55c05f8c | 3217 | |
d07278cf | 3218 | // Try to rediuce background with a mild shower shape cut and no more than 1 maxima |
3219 | // in cluster and remove low energy clusters | |
3220 | if( clus2->GetNCells() <= 1 || !IsGoodCluster(absIdMax,cells) || | |
3221 | GetCaloUtils()->GetNumberOfLocalMaxima(clus2,cells) > 1 || | |
07e4c878 | 3222 | clus2->GetM02() > 0.5 || clus2->E() < fMinInvMassECut ) continue; |
c8fe2783 | 3223 | |
649b825d | 3224 | //Get cluster kinematics |
3225 | clus2->GetMomentum(mom2,v); | |
c8fe2783 | 3226 | |
649b825d | 3227 | //Check only certain regions |
3228 | Bool_t in2 = kTRUE; | |
3229 | if(IsFiducialCutOn()) in2 = GetFiducialCut()->IsInFiducialCut(mom2,fCalorimeter) ; | |
3230 | if(!in2) continue; | |
2302a644 | 3231 | |
649b825d | 3232 | //Get module of cluster |
3233 | nModule2 = GetModuleNumber(clus2); | |
c8fe2783 | 3234 | |
649b825d | 3235 | //Fill histograms |
c8fe2783 | 3236 | |
649b825d | 3237 | //All modules |
3238 | fhIM ->Fill((mom+mom2).Pt(),(mom+mom2).M()); | |
49214ef9 | 3239 | |
649b825d | 3240 | //Single module |
45769d5b | 3241 | if(nModule == nModule2 && nModule >= 0 && nModule < fNModules) |
649b825d | 3242 | fhIMMod[nModule]->Fill((mom+mom2).Pt(),(mom+mom2).M()); |
d07278cf | 3243 | |
c8fe2783 | 3244 | |
649b825d | 3245 | //Asymetry histograms |
3246 | fhAsym->Fill((mom+mom2).Pt(),TMath::Abs((mom.E()-mom2.E())/(mom.E()+mom2.E()))); | |
3247 | ||
3248 | }// 2nd cluster loop | |
3249 | ||
3250 | } | |
3251 | ||
3252 | //______________________________ | |
3253 | void AliAnaCalorimeterQA::Init() | |
3254 | { | |
3255 | //Check if the data or settings are ok | |
c8fe2783 | 3256 | |
649b825d | 3257 | if(fCalorimeter != "PHOS" && fCalorimeter !="EMCAL") |
3258 | AliFatal(Form("Wrong calorimeter name <%s>", fCalorimeter.Data())); | |
521636d2 | 3259 | |
b6002a83 | 3260 | //if(GetReader()->GetDataType()== AliCaloTrackReader::kMC) |
3261 | // AliFatal("Analysis of reconstructed data, MC reader not aplicable"); | |
649b825d | 3262 | |
3263 | } | |
3bfc4732 | 3264 | |
649b825d | 3265 | //________________________________________ |
3266 | void AliAnaCalorimeterQA::InitParameters() | |
3267 | { | |
3268 | //Initialize the parameters of the analysis. | |
3269 | AddToHistogramsName("AnaCaloQA_"); | |
3270 | ||
3271 | fCalorimeter = "EMCAL"; //or PHOS | |
9f48b3f0 | 3272 | fNModules = 22; // set maximum to maximum number of EMCAL modules |
649b825d | 3273 | fNRCU = 2; // set maximum number of RCU in EMCAL per SM |
07e4c878 | 3274 | |
e6fec6f5 | 3275 | fTimeCutMin = -9999999; |
3276 | fTimeCutMax = 9999999; | |
07e4c878 | 3277 | |
3278 | fEMCALCellAmpMin = 0.2; // 200 MeV | |
3279 | fPHOSCellAmpMin = 0.2; // 200 MeV | |
3280 | fCellAmpMin = 0.2; // 200 MeV | |
3281 | fMinInvMassECut = 0.5; // 500 MeV | |
c8fe2783 | 3282 | |
f1538a5f | 3283 | // Exotic studies |
3284 | fExoNECrossCuts = 10 ; | |
3285 | fExoNDTimeCuts = 4 ; | |
3286 | ||
3287 | fExoDTimeCuts [0] = 1.e4 ; fExoDTimeCuts [1] = 50.0 ; fExoDTimeCuts [2] = 25.0 ; fExoDTimeCuts [3] = 10.0 ; | |
3288 | fExoECrossCuts[0] = 0.80 ; fExoECrossCuts[1] = 0.85 ; fExoECrossCuts[2] = 0.90 ; fExoECrossCuts[3] = 0.92 ; fExoECrossCuts[4] = 0.94 ; | |
3289 | fExoECrossCuts[5] = 0.95 ; fExoECrossCuts[6] = 0.96 ; fExoECrossCuts[7] = 0.97 ; fExoECrossCuts[8] = 0.98 ; fExoECrossCuts[9] = 0.99 ; | |
3290 | ||
649b825d | 3291 | } |
c8fe2783 | 3292 | |
b94e038e | 3293 | //_____________________________________________________________________________ |
3294 | Bool_t AliAnaCalorimeterQA::IsGoodCluster(Int_t absIdMax, AliVCaloCells* cells) | |
649b825d | 3295 | { |
3296 | //Identify cluster as exotic or not | |
3297 | ||
06f1b12a | 3298 | if(!fStudyBadClusters) return kTRUE; |
a82b4462 | 3299 | |
2747966a | 3300 | if(fCalorimeter=="EMCAL") |
3301 | { | |
06f1b12a | 3302 | if(!GetCaloUtils()->GetEMCALRecoUtils()->IsRejectExoticCluster()) |
2747966a | 3303 | { |
06f1b12a | 3304 | return !( GetCaloUtils()->GetEMCALRecoUtils()->IsExoticCell(absIdMax,cells,(GetReader()->GetInputEvent())->GetBunchCrossNumber()) ); |
2747966a | 3305 | } |
3306 | else | |
3307 | { | |
06f1b12a | 3308 | return kTRUE; |
2747966a | 3309 | } |
649b825d | 3310 | } |
06f1b12a | 3311 | else // PHOS |
3312 | { | |
1a83b960 | 3313 | Float_t ampMax = cells->GetCellAmplitude(absIdMax); |
dbba06ca | 3314 | GetCaloUtils()->RecalibrateCellAmplitude(ampMax, fCalorimeter, absIdMax); |
2747966a | 3315 | |
3316 | if(ampMax < 0.01) return kFALSE; | |
3317 | ||
1a83b960 | 3318 | if(1-GetECross(absIdMax,cells)/ampMax > 0.95) return kFALSE; |
3319 | else return kTRUE; | |
06f1b12a | 3320 | } |
3321 | ||
649b825d | 3322 | } |
17708df9 | 3323 | |
a82b4462 | 3324 | //_________________________________________________________ |
649b825d | 3325 | void AliAnaCalorimeterQA::Print(const Option_t * opt) const |
3326 | { | |
3327 | //Print some relevant parameters set for the analysis | |
3328 | if(! opt) | |
3329 | return; | |
521636d2 | 3330 | |
649b825d | 3331 | printf("**** Print %s %s ****\n", GetName(), GetTitle() ) ; |
745913ae | 3332 | AliAnaCaloTrackCorrBaseClass::Print(" "); |
2302a644 | 3333 | |
649b825d | 3334 | printf("Select Calorimeter %s \n",fCalorimeter.Data()); |
3335 | printf("Time Cut: %3.1f < TOF < %3.1f\n", fTimeCutMin, fTimeCutMax); | |
3336 | printf("EMCAL Min Amplitude : %2.1f GeV/c\n", fEMCALCellAmpMin) ; | |
3337 | printf("PHOS Min Amplitude : %2.1f GeV/c\n", fPHOSCellAmpMin) ; | |
07e4c878 | 3338 | printf("Inv. Mass min. E clus : %2.1f GeV/c\n", fMinInvMassECut) ; |
c8fe2783 | 3339 | |
649b825d | 3340 | } |
3341 | ||
649b825d | 3342 | //_____________________________________________________ |
3343 | void AliAnaCalorimeterQA::MakeAnalysisFillHistograms() | |
3344 | { | |
3345 | //Fill Calorimeter QA histograms | |
c8fe2783 | 3346 | |
649b825d | 3347 | //Play with the MC stack if available |
701cbf54 | 3348 | if(IsDataMC()) MCHistograms(); |
798a9b04 | 3349 | |
95aee5e1 | 3350 | // Correlate Calorimeters and V0 and track Multiplicity |
3351 | if(fCorrelate) Correlate(); | |
3352 | ||
701cbf54 | 3353 | //Get List with CaloClusters , calo Cells, init min amplitude |
3354 | TObjArray * caloClusters = NULL; | |
3355 | AliVCaloCells * cells = 0x0; | |
3356 | if (fCalorimeter == "PHOS") | |
3357 | { | |
3358 | fCellAmpMin = fPHOSCellAmpMin; | |
3359 | caloClusters = GetPHOSClusters(); | |
3360 | cells = GetPHOSCells(); | |
3361 | } | |
3362 | else if (fCalorimeter == "EMCAL") | |
3363 | { | |
3364 | fCellAmpMin = fEMCALCellAmpMin; | |
3365 | caloClusters = GetEMCALClusters(); | |
3366 | cells = GetEMCALCells(); | |
3367 | } | |
3368 | else | |
649b825d | 3369 | AliFatal(Form("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - Wrong calorimeter name <%s>, END\n", fCalorimeter.Data())); |
798a9b04 | 3370 | |
07e4c878 | 3371 | if( !caloClusters || !cells ) |
45769d5b | 3372 | { |
649b825d | 3373 | AliFatal(Form("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - No CaloClusters or CaloCells available\n")); |
3374 | return; // trick coverity | |
c8fe2783 | 3375 | } |
649b825d | 3376 | |
07e4c878 | 3377 | if(caloClusters->GetEntriesFast() == 0) return ; |
3378 | ||
1a72f6c5 | 3379 | //printf("QA: N cells %d, N clusters %d \n",cells->GetNumberOfCells(),caloClusters->GetEntriesFast()); |
3380 | ||
95aee5e1 | 3381 | // Clusters |
649b825d | 3382 | ClusterLoopHistograms(caloClusters,cells); |
3383 | ||
3384 | // Cells | |
3385 | CellHistograms(cells); | |
3386 | ||
3387 | if(GetDebug() > 0) | |
3388 | printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - End \n"); | |
3389 | ||
a0bb4dc0 | 3390 | } |
3391 | ||
649b825d | 3392 | //______________________________________ |
3393 | void AliAnaCalorimeterQA::MCHistograms() | |
3394 | { | |
3395 | //Get the MC arrays and do some checks before filling MC histograms | |
9e9f04cb | 3396 | |
95aee5e1 | 3397 | Int_t pdg = 0 ; |
3398 | Int_t status = 0 ; | |
3399 | Int_t nprim = 0 ; | |
3400 | ||
3401 | TParticle * primStack = 0; | |
3402 | AliAODMCParticle * primAOD = 0; | |
649b825d | 3403 | TLorentzVector mom ; |
3404 | ||
95aee5e1 | 3405 | // Get the ESD MC particles container |
3406 | AliStack * stack = 0; | |
3407 | if( GetReader()->ReadStack() ) | |
45769d5b | 3408 | { |
95aee5e1 | 3409 | stack = GetMCStack(); |
3410 | if(!stack ) return; | |
3411 | nprim = stack->GetNtrack(); | |
3412 | } | |
2302a644 | 3413 | |
95aee5e1 | 3414 | // Get the AOD MC particles container |
3415 | TClonesArray * mcparticles = 0; | |
3416 | if( GetReader()->ReadAODMCParticles() ) | |
3417 | { | |
3418 | mcparticles = GetReader()->GetAODMCParticles(); | |
3419 | if( !mcparticles ) return; | |
3420 | nprim = mcparticles->GetEntriesFast(); | |
3421 | } | |
35c71d5c | 3422 | |
95aee5e1 | 3423 | //printf("N primaries %d\n",nprim); |
3424 | for(Int_t i=0 ; i < nprim; i++) | |
2747966a | 3425 | { |
95aee5e1 | 3426 | if(GetReader()->AcceptOnlyHIJINGLabels() && !GetReader()->IsHIJINGLabel(i)) continue ; |
35c71d5c | 3427 | |
95aee5e1 | 3428 | // Get the generated particles, check that it is primary (not parton, resonance) |
3429 | // and get its momentum. Different way to recover from ESD or AOD | |
3430 | if(GetReader()->ReadStack()) | |
2747966a | 3431 | { |
95aee5e1 | 3432 | primStack = stack->Particle(i) ; |
3433 | if(!primStack) | |
3434 | { | |
3435 | printf("AliAnaCalorimeterQA::MCHistograms() - ESD primaries pointer not available!!\n"); | |
3436 | continue; | |
3437 | } | |
3438 | ||
3439 | pdg = primStack->GetPdgCode(); | |
3440 | status = primStack->GetStatusCode(); | |
35c71d5c | 3441 | |
95aee5e1 | 3442 | //printf("Input: i %d, %s, pdg %d, status %d \n",i, primStack->GetName(), pdg, status); |
35c71d5c | 3443 | |
95aee5e1 | 3444 | if ( status > 11 ) continue; //Working for PYTHIA and simple generators, check for HERWIG, HIJING? |
3445 | ||
3446 | if ( primStack->Energy() == TMath::Abs(primStack->Pz()) ) continue ; //Protection against floating point exception | |
3447 | ||
3448 | //printf("Take : i %d, %s, pdg %d, status %d \n",i, primStack->GetName(), pdg, status); | |
3449 | ||
3450 | //Photon kinematics | |
3451 | primStack->Momentum(mom); | |
35c71d5c | 3452 | } |
2747966a | 3453 | else |
3454 | { | |
95aee5e1 | 3455 | primAOD = (AliAODMCParticle *) mcparticles->At(i); |
3456 | if(!primAOD) | |
3457 | { | |
3458 | printf("AliAnaCalorimeterQA::MCHistograms() - AOD primaries pointer not available!!\n"); | |
3459 | continue; | |
3460 | } | |
3461 | ||
3462 | pdg = primAOD->GetPdgCode(); | |
3463 | status = primAOD->GetStatus(); | |
3464 | ||
3465 | //printf("Input: i %d, %s, pdg %d, status %d \n",i, primAOD->GetName(), pdg, status); | |
3466 | ||
3467 | if (!primAOD->IsPrimary()) continue; //accept all which is not MC transport generated. Don't know how to avoid partons | |
3468 | ||
3469 | if ( status > 11 ) continue; //Working for PYTHIA and simple generators, check for HERWIG | |
3470 | ||
3471 | if ( primAOD->E() == TMath::Abs(primAOD->Pz()) ) continue ; //Protection against floating point exception | |
3472 | ||
3473 | //printf("Take : i %d, %s, pdg %d, status %d \n",i, primAOD->GetName(), pdg, status); | |
3474 | ||
3475 | //kinematics | |
3476 | mom.SetPxPyPzE(primAOD->Px(),primAOD->Py(),primAOD->Pz(),primAOD->E()); | |
2302a644 | 3477 | } |
95aee5e1 | 3478 | |
3479 | Float_t eMC = mom.E(); | |
3480 | if(eMC < 0.2) continue; | |
3481 | Float_t ptMC = mom.E(); | |
3482 | ||
3483 | Float_t etaMC = mom.Eta(); | |
3484 | // Only particles in |eta| < 1 | |
3485 | if (TMath::Abs(etaMC) > 1) continue; | |
3486 | ||
3487 | Float_t phiMC = mom.Phi(); | |
3488 | if(phiMC < 0) | |
3489 | phiMC += TMath::TwoPi(); | |
3490 | ||
3491 | Int_t mcIndex = -1; | |
3492 | if (pdg==22) mcIndex = kmcPhoton; | |
3493 | else if (pdg==111) mcIndex = kmcPi0; | |
3494 | else if (pdg==221) mcIndex = kmcEta; | |
3495 | else if (TMath::Abs(pdg)==11) mcIndex = kmcElectron; | |
3496 | ||
3497 | if( mcIndex >=0 ) | |
2747966a | 3498 | { |
95aee5e1 | 3499 | fhGenMCE [mcIndex]->Fill( eMC); |
3500 | fhGenMCPt[mcIndex]->Fill(ptMC); | |
3501 | if(eMC > 0.5) fhGenMCEtaPhi[mcIndex]->Fill(etaMC,phiMC); | |
3502 | ||
3503 | Bool_t inacceptance = kTRUE; | |
3504 | // Check same fidutial borders as in data analysis on top of real acceptance if real was requested. | |
3505 | if( IsFiducialCutOn() && !GetFiducialCut()->IsInFiducialCut(mom,fCalorimeter) ) inacceptance = kFALSE ; | |
3506 | ||
3507 | if(IsRealCaloAcceptanceOn()) // defined on base class | |
3508 | { | |
3509 | if(GetReader()->ReadStack() && | |
3510 | !GetCaloUtils()->IsMCParticleInCalorimeterAcceptance(fCalorimeter, primStack)) inacceptance = kFALSE ; | |
3511 | if(GetReader()->ReadAODMCParticles() && | |
3512 | !GetCaloUtils()->IsMCParticleInCalorimeterAcceptance(fCalorimeter, primAOD )) inacceptance = kFALSE ; | |
3513 | } | |
3514 | ||
3515 | if(!inacceptance) continue; | |
3516 | ||
3517 | fhGenMCAccE [mcIndex]->Fill( eMC); | |
3518 | fhGenMCAccPt[mcIndex]->Fill(ptMC); | |
3519 | if(eMC > 0.5) fhGenMCAccEtaPhi[mcIndex]->Fill(etaMC,phiMC); | |
3520 | ||
2302a644 | 3521 | } |
95aee5e1 | 3522 | |
2302a644 | 3523 | } |
902aa95c | 3524 | } |
c8fe2783 | 3525 | |
649b825d | 3526 | //_________________________________________________________________________________ |
3527 | void AliAnaCalorimeterQA::WeightHistograms(AliVCluster *clus, AliVCaloCells* cells) | |
3528 | { | |
3529 | // Calculate weights | |
3530 | ||
3531 | // First recalculate energy in case non linearity was applied | |
3532 | Float_t energy = 0; | |
701cbf54 | 3533 | Float_t ampMax = 0; |
3534 | Float_t energyOrg = clus->E(); | |
3535 | ||
3536 | // Do study when there are enough cells in cluster | |
3537 | if(clus->GetNCells() < 3) return ; | |
3538 | ||
2747966a | 3539 | for (Int_t ipos = 0; ipos < clus->GetNCells(); ipos++) |
3540 | { | |
649b825d | 3541 | Int_t id = clus->GetCellsAbsId()[ipos]; |
3542 | ||
3543 | //Recalibrate cell energy if needed | |
3544 | Float_t amp = cells->GetCellAmplitude(id); | |
dbba06ca | 3545 | GetCaloUtils()->RecalibrateCellAmplitude(amp, fCalorimeter, id); |
649b825d | 3546 | |
3547 | energy += amp; | |
3548 | ||
3549 | if(amp> ampMax) | |
3550 | ampMax = amp; | |
3551 | ||
3552 | } // energy loop | |
3553 | ||
2747966a | 3554 | if(energy <=0 ) |
3555 | { | |
649b825d | 3556 | printf("AliAnaCalorimeterQA::WeightHistograms()- Wrong calculated energy %f\n",energy); |
3557 | return; | |
3558 | } | |
3559 | ||
701cbf54 | 3560 | //Remove non lin correction |
3561 | clus->SetE(energy); | |
3562 | ||
649b825d | 3563 | fhEMaxCellClusterRatio ->Fill(energy,ampMax/energy); |
3564 | fhEMaxCellClusterLogRatio->Fill(energy,TMath::Log(ampMax/energy)); | |
3565 | ||
3566 | //Get the ratio and log ratio to all cells in cluster | |
2747966a | 3567 | for (Int_t ipos = 0; ipos < clus->GetNCells(); ipos++) |
3568 | { | |
649b825d | 3569 | Int_t id = clus->GetCellsAbsId()[ipos]; |
3570 | ||
3571 | //Recalibrate cell energy if needed | |
3572 | Float_t amp = cells->GetCellAmplitude(id); | |
dbba06ca | 3573 | GetCaloUtils()->RecalibrateCellAmplitude(amp, fCalorimeter, id); |
649b825d | 3574 | |
3575 | fhECellClusterRatio ->Fill(energy,amp/energy); | |
3576 | fhECellClusterLogRatio->Fill(energy,TMath::Log(amp/energy)); | |
3577 | } | |
3578 | ||
3579 | //Recalculate shower shape for different W0 | |
2747966a | 3580 | if(fCalorimeter=="EMCAL") |
3581 | { | |
649b825d | 3582 | Float_t l0org = clus->GetM02(); |
3583 | Float_t l1org = clus->GetM20(); | |
3584 | Float_t dorg = clus->GetDispersion(); | |
701cbf54 | 3585 | |
3586 | Int_t tagMC = -1; | |
3587 | if(IsDataMC() && clus->GetNLabels() > 0) | |
45769d5b | 3588 | { |
701cbf54 | 3589 | Int_t tag = GetMCAnalysisUtils()->CheckOrigin(clus->GetLabels(),clus->GetNLabels(), GetReader()); |
3590 | ||
3591 | if( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPhoton) && | |
3592 | !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPi0) && | |
3593 | !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCEta) && | |
3594 | !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCConversion) ){ | |
3595 | tagMC = 0; | |
3596 | } // Pure Photon | |
3597 | else if( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCElectron) && | |
3598 | !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCConversion) ){ | |
3599 | tagMC = 1; | |
3600 | } // Electron | |
3601 | else if( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCConversion) ){ | |
3602 | tagMC = 2; | |
3603 | } // Conversion | |
3604 | else if( GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPi0) ){ | |
3605 | tagMC = 3; | |
3606 | }// Pi0 | |
3607 | else if(!GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCEta) && | |
3608 | !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPhoton) ){ | |
3609 | tagMC = 4; | |
3610 | }// Hadron | |
3611 | }// Is MC | |
3612 | ||
3613 | for(Int_t iw = 0; iw < 12; iw++) | |
3614 | { | |
3615 | GetCaloUtils()->GetEMCALRecoUtils()->SetW0(3+iw*0.25); | |
649b825d | 3616 | GetCaloUtils()->GetEMCALRecoUtils()->RecalculateClusterShowerShapeParameters(GetEMCALGeometry(), cells, clus); |
3617 | ||
3618 | fhLambda0ForW0[iw]->Fill(energy,clus->GetM02()); | |
1a72f6c5 | 3619 | //fhLambda1ForW0[iw]->Fill(energy,clus->GetM20()); |
649b825d | 3620 | |
701cbf54 | 3621 | if(IsDataMC() && tagMC >= 0) |
45769d5b | 3622 | { |
701cbf54 | 3623 | fhLambda0ForW0MC[iw][tagMC]->Fill(energy,clus->GetM02()); |
3624 | //fhLambda1ForW0MC[iw][tagMC]->Fill(energy,clus->GetM20()); | |
3625 | } | |
649b825d | 3626 | } // w0 loop |
3627 | ||
3628 | // Set the original values back | |
3629 | clus->SetM02(l0org); | |
3630 | clus->SetM20(l1org); | |
3631 | clus->SetDispersion(dorg); | |
3632 | ||
3633 | }// EMCAL | |
701cbf54 | 3634 | |
3635 | clus->SetE(energyOrg); | |
3636 | ||
649b825d | 3637 | } |
3638 | ||
3639 | ||
3640 |