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a3aebfff | 1 | /************************************************************************** |
1c5acb87 | 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 hereby granted * | |
cadbb0f3 | 9 | * without fee, provided that the above copyright notice appears in all * |
1c5acb87 | 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 | **************************************************************************/ | |
1c5acb87 | 15 | |
16 | //_________________________________________________________________________ | |
17 | // | |
18 | // Class for the photon identification. | |
19 | // Clusters from calorimeters are identified as photons | |
20 | // and kept in the AOD. Few histograms produced. | |
6175da48 | 21 | // Produces input for other analysis classes like AliAnaPi0, |
22 | // AliAnaParticleHadronCorrelation ... | |
1c5acb87 | 23 | // |
24 | // -- Author: Gustavo Conesa (LNF-INFN) | |
25 | ////////////////////////////////////////////////////////////////////////////// | |
26 | ||
27 | ||
28 | // --- ROOT system --- | |
29 | #include <TH2F.h> | |
2244659d | 30 | #include <TH3D.h> |
477d6cee | 31 | #include <TClonesArray.h> |
0c1383b5 | 32 | #include <TObjString.h> |
123fc3bd | 33 | #include "TParticle.h" |
6175da48 | 34 | #include "TDatabasePDG.h" |
1c5acb87 | 35 | |
36 | // --- Analysis system --- | |
37 | #include "AliAnaPhoton.h" | |
38 | #include "AliCaloTrackReader.h" | |
123fc3bd | 39 | #include "AliStack.h" |
1c5acb87 | 40 | #include "AliCaloPID.h" |
6639984f | 41 | #include "AliMCAnalysisUtils.h" |
ff45398a | 42 | #include "AliFiducialCut.h" |
0ae57829 | 43 | #include "AliVCluster.h" |
591cc579 | 44 | #include "AliAODMCParticle.h" |
c8fe2783 | 45 | #include "AliMixedEvent.h" |
fc195fd0 | 46 | #include "AliAODEvent.h" |
2ad19c3d | 47 | #include "AliESDEvent.h" |
c8fe2783 | 48 | |
c5693f62 | 49 | // --- Detectors --- |
50 | #include "AliPHOSGeoUtils.h" | |
51 | #include "AliEMCALGeometry.h" | |
1c5acb87 | 52 | |
53 | ClassImp(AliAnaPhoton) | |
54 | ||
5812a064 | 55 | //____________________________ |
521636d2 | 56 | AliAnaPhoton::AliAnaPhoton() : |
09273901 | 57 | AliAnaCaloTrackCorrBaseClass(), fCalorimeter(""), |
521636d2 | 58 | fMinDist(0.), fMinDist2(0.), fMinDist3(0.), |
09273901 | 59 | fRejectTrackMatch(0), fFillTMHisto(kFALSE), |
60 | fTimeCutMin(-10000), fTimeCutMax(10000), | |
9e51e29a | 61 | fNCellsCut(0), |
62 | fNLMCutMin(-1), fNLMCutMax(10), | |
63 | fFillSSHistograms(kFALSE), fFillOnlySimpleSSHisto(1), | |
f66d95af | 64 | fNOriginHistograms(8), fNPrimaryHistograms(4), |
2ad19c3d | 65 | fFillPileUpHistograms(0), |
c4a7d28a | 66 | // Histograms |
5c46c992 | 67 | fhNCellsE(0), fhCellsE(0), // Control histograms |
68 | fhMaxCellDiffClusterE(0), fhTimeE(0), // Control histograms | |
f66d95af | 69 | fhEPhoton(0), fhPtPhoton(0), |
521636d2 | 70 | fhPhiPhoton(0), fhEtaPhoton(0), |
71 | fhEtaPhiPhoton(0), fhEtaPhi05Photon(0), | |
72 | ||
4c8f7c2e | 73 | // Shower shape histograms |
9e51e29a | 74 | fhNLocMax(0), |
521636d2 | 75 | fhDispE(0), fhLam0E(0), fhLam1E(0), |
521636d2 | 76 | fhDispETRD(0), fhLam0ETRD(0), fhLam1ETRD(0), |
b5dbb99b | 77 | fhDispETM(0), fhLam0ETM(0), fhLam1ETM(0), |
78 | fhDispETMTRD(0), fhLam0ETMTRD(0), fhLam1ETMTRD(0), | |
521636d2 | 79 | |
80 | fhNCellsLam0LowE(0), fhNCellsLam1LowE(0), fhNCellsDispLowE(0), | |
81 | fhNCellsLam0HighE(0), fhNCellsLam1HighE(0), fhNCellsDispHighE(0), | |
521636d2 | 82 | |
83 | fhEtaLam0LowE(0), fhPhiLam0LowE(0), | |
84 | fhEtaLam0HighE(0), fhPhiLam0HighE(0), | |
85 | fhLam0DispLowE(0), fhLam0DispHighE(0), | |
86 | fhLam1Lam0LowE(0), fhLam1Lam0HighE(0), | |
87 | fhDispLam1LowE(0), fhDispLam1HighE(0), | |
34c16486 | 88 | fhDispEtaE(0), fhDispPhiE(0), |
89 | fhSumEtaE(0), fhSumPhiE(0), fhSumEtaPhiE(0), | |
90 | fhDispEtaPhiDiffE(0), fhSphericityE(0), | |
91 | fhDispSumEtaDiffE(0), fhDispSumPhiDiffE(0), | |
521636d2 | 92 | |
4c8f7c2e | 93 | // MC histograms |
8d6b7f60 | 94 | fhMCPhotonELambda0NoOverlap(0), fhMCPhotonELambda0TwoOverlap(0), fhMCPhotonELambda0NOverlap(0), |
b5dbb99b | 95 | // Embedding |
7c65ad18 | 96 | fhEmbeddedSignalFractionEnergy(0), |
8d6b7f60 | 97 | fhEmbedPhotonELambda0FullSignal(0), fhEmbedPhotonELambda0MostlySignal(0), |
98 | fhEmbedPhotonELambda0MostlyBkg(0), fhEmbedPhotonELambda0FullBkg(0), | |
99 | fhEmbedPi0ELambda0FullSignal(0), fhEmbedPi0ELambda0MostlySignal(0), | |
2ad19c3d | 100 | fhEmbedPi0ELambda0MostlyBkg(0), fhEmbedPi0ELambda0FullBkg(0), |
101 | // PileUp | |
102 | fhTimeENoCut(0), fhTimeESPD(0), fhTimeESPDMulti(0), | |
103 | fhTimeNPileUpVertSPD(0), fhTimeNPileUpVertTrack(0), | |
104 | fhTimeNPileUpVertContributors(0), | |
acd56ca4 | 105 | fhTimePileUpMainVertexZDistance(0), fhTimePileUpMainVertexZDiamond(0), |
106 | fhClusterMultSPDPileUp(), fhClusterMultNoPileUp() | |
4bfeae64 | 107 | { |
1c5acb87 | 108 | //default ctor |
109 | ||
4bfeae64 | 110 | for(Int_t i = 0; i < 14; i++) |
111 | { | |
4c8f7c2e | 112 | fhMCPt [i] = 0; |
113 | fhMCE [i] = 0; | |
114 | fhMCPhi [i] = 0; | |
115 | fhMCEta [i] = 0; | |
116 | fhMCDeltaE [i] = 0; | |
117 | fhMCDeltaPt[i] = 0; | |
4c8f7c2e | 118 | fhMC2E [i] = 0; |
119 | fhMC2Pt [i] = 0; | |
521636d2 | 120 | } |
121 | ||
4bfeae64 | 122 | for(Int_t i = 0; i < 7; i++) |
123 | { | |
3d5d5078 | 124 | fhPtPrimMC [i] = 0; |
125 | fhEPrimMC [i] = 0; | |
126 | fhPhiPrimMC[i] = 0; | |
127 | fhYPrimMC [i] = 0; | |
128 | ||
129 | fhPtPrimMCAcc [i] = 0; | |
130 | fhEPrimMCAcc [i] = 0; | |
131 | fhPhiPrimMCAcc[i] = 0; | |
132 | fhYPrimMCAcc [i] = 0; | |
d2655d46 | 133 | |
134 | fhDispEtaDispPhi[i] = 0; | |
135 | fhLambda0DispPhi[i] = 0; | |
136 | fhLambda0DispEta[i] = 0; | |
137 | for(Int_t j = 0; j < 6; j++) | |
138 | { | |
139 | fhMCDispEtaDispPhi[i][j] = 0; | |
140 | fhMCLambda0DispEta[i][j] = 0; | |
141 | fhMCLambda0DispPhi[i][j] = 0; | |
142 | } | |
3d5d5078 | 143 | } |
144 | ||
4bfeae64 | 145 | for(Int_t i = 0; i < 6; i++) |
146 | { | |
f66d95af | 147 | fhMCELambda0 [i] = 0; |
148 | fhMCELambda1 [i] = 0; | |
149 | fhMCEDispersion [i] = 0; | |
f66d95af | 150 | fhMCNCellsE [i] = 0; |
151 | fhMCMaxCellDiffClusterE[i] = 0; | |
bfdcf7fb | 152 | fhLambda0DispEta[i] = 0; |
153 | fhLambda0DispPhi[i] = 0; | |
154 | ||
f66d95af | 155 | fhMCLambda0vsClusterMaxCellDiffE0[i] = 0; |
156 | fhMCLambda0vsClusterMaxCellDiffE2[i] = 0; | |
157 | fhMCLambda0vsClusterMaxCellDiffE6[i] = 0; | |
158 | fhMCNCellsvsClusterMaxCellDiffE0 [i] = 0; | |
159 | fhMCNCellsvsClusterMaxCellDiffE2 [i] = 0; | |
160 | fhMCNCellsvsClusterMaxCellDiffE6 [i] = 0; | |
34c16486 | 161 | |
162 | fhMCEDispEta [i] = 0; | |
163 | fhMCEDispPhi [i] = 0; | |
164 | fhMCESumEtaPhi [i] = 0; | |
165 | fhMCEDispEtaPhiDiff[i] = 0; | |
166 | fhMCESphericity [i] = 0; | |
521636d2 | 167 | } |
168 | ||
34c16486 | 169 | for(Int_t i = 0; i < 5; i++) |
170 | { | |
acd56ca4 | 171 | fhClusterCuts[i] = 0; |
34c16486 | 172 | } |
fc195fd0 | 173 | |
4bfeae64 | 174 | // Track matching residuals |
175 | for(Int_t i = 0; i < 2; i++) | |
176 | { | |
177 | fhTrackMatchedDEta[i] = 0; fhTrackMatchedDPhi[i] = 0; fhTrackMatchedDEtaDPhi[i] = 0; | |
178 | fhTrackMatchedDEtaTRD[i] = 0; fhTrackMatchedDPhiTRD[i] = 0; | |
179 | fhTrackMatchedDEtaMCOverlap[i] = 0; fhTrackMatchedDPhiMCOverlap[i] = 0; | |
180 | fhTrackMatchedDEtaMCNoOverlap[i] = 0; fhTrackMatchedDPhiMCNoOverlap[i] = 0; | |
181 | fhTrackMatchedDEtaMCConversion[i] = 0; fhTrackMatchedDPhiMCConversion[i] = 0; | |
182 | fhTrackMatchedMCParticle[i] = 0; fhTrackMatchedMCParticle[i] = 0; | |
183 | fhdEdx[i] = 0; fhEOverP[i] = 0; | |
184 | fhEOverPTRD[i] = 0; | |
185 | } | |
186 | ||
acd56ca4 | 187 | for(Int_t i = 0; i < 4; i++) |
188 | { | |
189 | fhClusterMultSPDPileUp[i] = 0; | |
190 | fhClusterMultNoPileUp [i] = 0; | |
191 | } | |
192 | ||
1c5acb87 | 193 | //Initialize parameters |
194 | InitParameters(); | |
195 | ||
1c5acb87 | 196 | } |
197 | ||
9e51e29a | 198 | //_____________________________________________________________________________________________________ |
199 | Bool_t AliAnaPhoton::ClusterSelected(AliVCluster* calo, const TLorentzVector mom, const Int_t nMaxima) | |
c4a7d28a | 200 | { |
201 | //Select clusters if they pass different cuts | |
202 | if(GetDebug() > 2) | |
203 | printf("AliAnaPhoton::ClusterSelected() Current Event %d; Before selection : E %2.2f, pT %2.2f, Ecl %2.2f, phi %2.2f, eta %2.2f\n", | |
204 | GetReader()->GetEventNumber(), | |
fc195fd0 | 205 | calo->E(), mom.Pt(),calo->E(),mom.Phi()*TMath::RadToDeg(),mom.Eta()); |
206 | ||
207 | fhClusterCuts[1]->Fill(calo->E()); | |
c4a7d28a | 208 | |
209 | //....................................... | |
210 | //If too small or big energy, skip it | |
fc195fd0 | 211 | if(calo->E() < GetMinEnergy() || calo->E() > GetMaxEnergy() ) return kFALSE ; |
09273901 | 212 | |
c4a7d28a | 213 | if(GetDebug() > 2) printf("\t Cluster %d Pass E Cut \n",calo->GetID()); |
09273901 | 214 | |
fc195fd0 | 215 | fhClusterCuts[2]->Fill(calo->E()); |
216 | ||
c4a7d28a | 217 | //....................................... |
218 | // TOF cut, BE CAREFUL WITH THIS CUT | |
219 | Double_t tof = calo->GetTOF()*1e9; | |
220 | if(tof < fTimeCutMin || tof > fTimeCutMax) return kFALSE; | |
09273901 | 221 | |
c4a7d28a | 222 | if(GetDebug() > 2) printf("\t Cluster %d Pass Time Cut \n",calo->GetID()); |
09273901 | 223 | |
fc195fd0 | 224 | fhClusterCuts[3]->Fill(calo->E()); |
225 | ||
c4a7d28a | 226 | //....................................... |
227 | if(calo->GetNCells() <= fNCellsCut && GetReader()->GetDataType() != AliCaloTrackReader::kMC) return kFALSE; | |
09273901 | 228 | |
c4a7d28a | 229 | if(GetDebug() > 2) printf("\t Cluster %d Pass NCell Cut \n",calo->GetID()); |
09273901 | 230 | |
fc195fd0 | 231 | fhClusterCuts[4]->Fill(calo->E()); |
232 | ||
9e51e29a | 233 | if(nMaxima < fNLMCutMin || nMaxima > fNLMCutMax) return kFALSE ; |
234 | if(GetDebug() > 2) printf(" \t Cluster %d pass NLM %d of out of range \n",calo->GetID(), nMaxima); | |
235 | ||
236 | fhClusterCuts[5]->Fill(calo->E()); | |
237 | ||
c4a7d28a | 238 | //....................................... |
239 | //Check acceptance selection | |
34c16486 | 240 | if(IsFiducialCutOn()) |
241 | { | |
c4a7d28a | 242 | Bool_t in = GetFiducialCut()->IsInFiducialCut(mom,fCalorimeter) ; |
243 | if(! in ) return kFALSE ; | |
244 | } | |
09273901 | 245 | |
c4a7d28a | 246 | if(GetDebug() > 2) printf("Fiducial cut passed \n"); |
09273901 | 247 | |
9e51e29a | 248 | fhClusterCuts[6]->Fill(calo->E()); |
fc195fd0 | 249 | |
c4a7d28a | 250 | //....................................... |
251 | //Skip matched clusters with tracks | |
09273901 | 252 | |
4bfeae64 | 253 | // Fill matching residual histograms before PID cuts |
254 | if(fFillTMHisto) FillTrackMatchingResidualHistograms(calo,0); | |
09273901 | 255 | |
34c16486 | 256 | if(fRejectTrackMatch) |
257 | { | |
258 | if(IsTrackMatched(calo,GetReader()->GetInputEvent())) | |
259 | { | |
c4a7d28a | 260 | if(GetDebug() > 2) printf("\t Reject track-matched clusters\n"); |
261 | return kFALSE ; | |
262 | } | |
263 | else | |
264 | if(GetDebug() > 2) printf(" Track-matching cut passed \n"); | |
265 | }// reject matched clusters | |
09273901 | 266 | |
9e51e29a | 267 | fhClusterCuts[7]->Fill(calo->E()); |
fc195fd0 | 268 | |
c4a7d28a | 269 | //....................................... |
270 | //Check Distance to Bad channel, set bit. | |
271 | Double_t distBad=calo->GetDistanceToBadChannel() ; //Distance to bad channel | |
272 | if(distBad < 0.) distBad=9999. ; //workout strange convension dist = -1. ; | |
34c16486 | 273 | if(distBad < fMinDist) |
274 | {//In bad channel (PHOS cristal size 2.2x2.2 cm), EMCAL ( cell units ) | |
c4a7d28a | 275 | return kFALSE ; |
276 | } | |
277 | else if(GetDebug() > 2) printf("\t Bad channel cut passed %4.2f > %2.2f \n",distBad, fMinDist); | |
fc195fd0 | 278 | |
9e51e29a | 279 | fhClusterCuts[8]->Fill(calo->E()); |
09273901 | 280 | |
c4a7d28a | 281 | if(GetDebug() > 0) |
282 | printf("AliAnaPhoton::ClusterSelected() Current Event %d; After selection : E %2.2f, pT %2.2f, Ecl %2.2f, phi %2.2f, eta %2.2f\n", | |
283 | GetReader()->GetEventNumber(), | |
fc195fd0 | 284 | calo->E(), mom.Pt(),calo->E(),mom.Phi()*TMath::RadToDeg(),mom.Eta()); |
c4a7d28a | 285 | |
286 | //All checks passed, cluster selected | |
287 | return kTRUE; | |
288 | ||
289 | } | |
290 | ||
34c16486 | 291 | //___________________________________________ |
292 | void AliAnaPhoton::FillAcceptanceHistograms() | |
293 | { | |
3d5d5078 | 294 | //Fill acceptance histograms if MC data is available |
295 | ||
34c16486 | 296 | Double_t photonY = -100 ; |
297 | Double_t photonE = -1 ; | |
298 | Double_t photonPt = -1 ; | |
299 | Double_t photonPhi = 100 ; | |
300 | Double_t photonEta = -1 ; | |
301 | ||
302 | Int_t pdg = 0 ; | |
303 | Int_t tag = 0 ; | |
304 | Int_t mcIndex = 0 ; | |
305 | Bool_t inacceptance = kFALSE; | |
306 | ||
307 | if(GetReader()->ReadStack()) | |
308 | { | |
3d5d5078 | 309 | AliStack * stack = GetMCStack(); |
34c16486 | 310 | if(stack) |
311 | { | |
312 | for(Int_t i=0 ; i<stack->GetNtrack(); i++) | |
313 | { | |
3d5d5078 | 314 | TParticle * prim = stack->Particle(i) ; |
34c16486 | 315 | pdg = prim->GetPdgCode(); |
3d5d5078 | 316 | //printf("i %d, %s %d %s %d \n",i, stack->Particle(i)->GetName(), stack->Particle(i)->GetPdgCode(), |
317 | // prim->GetName(), prim->GetPdgCode()); | |
318 | ||
34c16486 | 319 | if(pdg == 22) |
320 | { | |
3d5d5078 | 321 | // Get tag of this particle photon from fragmentation, decay, prompt ... |
34c16486 | 322 | tag = GetMCAnalysisUtils()->CheckOrigin(i,GetReader(), 0); |
323 | if(!GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPhoton)) | |
324 | { | |
3d5d5078 | 325 | //A conversion photon from a hadron, skip this kind of photon |
34c16486 | 326 | // printf("AliAnaPhoton::FillAcceptanceHistograms() - not a photon, weird!\n "); |
327 | // GetMCAnalysisUtils()->PrintMCTag(tag); | |
3d5d5078 | 328 | |
329 | return; | |
330 | } | |
331 | ||
332 | //Get photon kinematics | |
333 | if(prim->Energy() == TMath::Abs(prim->Pz())) continue ; //Protection against floating point exception | |
334 | ||
34c16486 | 335 | photonY = 0.5*TMath::Log((prim->Energy()-prim->Pz())/(prim->Energy()+prim->Pz())) ; |
336 | photonE = prim->Energy() ; | |
337 | photonPt = prim->Pt() ; | |
338 | photonPhi = TMath::RadToDeg()*prim->Phi() ; | |
3d5d5078 | 339 | if(photonPhi < 0) photonPhi+=TMath::TwoPi(); |
34c16486 | 340 | photonEta = prim->Eta() ; |
3d5d5078 | 341 | |
342 | //Check if photons hit the Calorimeter | |
343 | TLorentzVector lv; | |
344 | prim->Momentum(lv); | |
34c16486 | 345 | inacceptance = kFALSE; |
346 | if (fCalorimeter == "PHOS") | |
347 | { | |
348 | if(GetPHOSGeometry() && GetCaloUtils()->IsPHOSGeoMatrixSet()) | |
349 | { | |
3d5d5078 | 350 | Int_t mod ; |
351 | Double_t x,z ; | |
352 | if(GetPHOSGeometry()->ImpactOnEmc(prim,mod,z,x)) | |
353 | inacceptance = kTRUE; | |
354 | if(GetDebug() > 2) printf("In %s Real acceptance? %d\n",fCalorimeter.Data(),inacceptance); | |
355 | } | |
34c16486 | 356 | else |
357 | { | |
3d5d5078 | 358 | if(GetFiducialCut()->IsInFiducialCut(lv,fCalorimeter)) |
359 | inacceptance = kTRUE ; | |
360 | if(GetDebug() > 2) printf("In %s fiducial cut acceptance? %d\n",fCalorimeter.Data(),inacceptance); | |
361 | } | |
362 | } | |
34c16486 | 363 | else if(fCalorimeter == "EMCAL" && GetCaloUtils()->IsEMCALGeoMatrixSet()) |
364 | { | |
365 | if(GetEMCALGeometry()) | |
366 | { | |
3d5d5078 | 367 | Int_t absID=0; |
368 | ||
369 | GetEMCALGeometry()->GetAbsCellIdFromEtaPhi(prim->Eta(),prim->Phi(),absID); | |
370 | ||
371 | if( absID >= 0) | |
372 | inacceptance = kTRUE; | |
373 | ||
374 | // if(GetEMCALGeometry()->Impact(phot1) && GetEMCALGeometry()->Impact(phot2)) | |
375 | // inacceptance = kTRUE; | |
376 | if(GetDebug() > 2) printf("In %s Real acceptance? %d\n",fCalorimeter.Data(),inacceptance); | |
377 | } | |
34c16486 | 378 | else |
379 | { | |
3d5d5078 | 380 | if(GetFiducialCut()->IsInFiducialCut(lv,fCalorimeter)) |
381 | inacceptance = kTRUE ; | |
382 | if(GetDebug() > 2) printf("In %s fiducial cut acceptance? %d\n",fCalorimeter.Data(),inacceptance); | |
383 | } | |
384 | } //In EMCAL | |
385 | ||
386 | //Fill histograms | |
c5693f62 | 387 | fhYPrimMC[kmcPPhoton]->Fill(photonPt, photonY) ; |
3d5d5078 | 388 | if(TMath::Abs(photonY) < 1.0) |
389 | { | |
c5693f62 | 390 | fhEPrimMC [kmcPPhoton]->Fill(photonE ) ; |
391 | fhPtPrimMC [kmcPPhoton]->Fill(photonPt) ; | |
392 | fhPhiPrimMC[kmcPPhoton]->Fill(photonE , photonPhi) ; | |
34c16486 | 393 | fhYPrimMC [kmcPPhoton]->Fill(photonE , photonEta) ; |
3d5d5078 | 394 | } |
34c16486 | 395 | if(inacceptance) |
396 | { | |
397 | fhEPrimMCAcc [kmcPPhoton]->Fill(photonE ) ; | |
398 | fhPtPrimMCAcc [kmcPPhoton]->Fill(photonPt) ; | |
c5693f62 | 399 | fhPhiPrimMCAcc[kmcPPhoton]->Fill(photonE , photonPhi) ; |
34c16486 | 400 | fhYPrimMCAcc [kmcPPhoton]->Fill(photonE , photonY) ; |
3d5d5078 | 401 | }//Accepted |
402 | ||
403 | //Origin of photon | |
c5693f62 | 404 | if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPrompt) && fhEPrimMC[kmcPPrompt]) |
3d5d5078 | 405 | { |
34c16486 | 406 | mcIndex = kmcPPrompt; |
3d5d5078 | 407 | } |
c5693f62 | 408 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCFragmentation) && fhEPrimMC[kmcPFragmentation]) |
3d5d5078 | 409 | { |
34c16486 | 410 | mcIndex = kmcPFragmentation ; |
3d5d5078 | 411 | } |
c5693f62 | 412 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCISR) && fhEPrimMC[kmcPISR]) |
3d5d5078 | 413 | { |
34c16486 | 414 | mcIndex = kmcPISR; |
3d5d5078 | 415 | } |
c5693f62 | 416 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPi0Decay)&& fhEPrimMC[kmcPPi0Decay]) |
3d5d5078 | 417 | { |
34c16486 | 418 | mcIndex = kmcPPi0Decay; |
3d5d5078 | 419 | } |
f586f4aa | 420 | else if( (GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCEtaDecay) || |
c5693f62 | 421 | GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCOtherDecay)) && fhEPrimMC[kmcPOtherDecay]) |
3d5d5078 | 422 | { |
34c16486 | 423 | mcIndex = kmcPOtherDecay; |
3d5d5078 | 424 | } |
c5693f62 | 425 | else if(fhEPrimMC[kmcPOther]) |
3d5d5078 | 426 | { |
34c16486 | 427 | mcIndex = kmcPOther; |
3d5d5078 | 428 | }//Other origin |
34c16486 | 429 | |
430 | fhYPrimMC[mcIndex]->Fill(photonPt, photonY) ; | |
431 | if(TMath::Abs(photonY) < 1.0) | |
432 | { | |
433 | fhEPrimMC [mcIndex]->Fill(photonE ) ; | |
434 | fhPtPrimMC [mcIndex]->Fill(photonPt) ; | |
435 | fhPhiPrimMC[mcIndex]->Fill(photonE , photonPhi) ; | |
436 | fhYPrimMC [mcIndex]->Fill(photonE , photonEta) ; | |
437 | } | |
438 | if(inacceptance) | |
439 | { | |
440 | fhEPrimMCAcc [mcIndex]->Fill(photonE ) ; | |
441 | fhPtPrimMCAcc [mcIndex]->Fill(photonPt) ; | |
442 | fhPhiPrimMCAcc[mcIndex]->Fill(photonE , photonPhi) ; | |
443 | fhYPrimMCAcc [mcIndex]->Fill(photonE , photonY) ; | |
444 | }//Accepted | |
445 | ||
3d5d5078 | 446 | }// Primary photon |
447 | }//loop on primaries | |
448 | }//stack exists and data is MC | |
449 | }//read stack | |
34c16486 | 450 | else if(GetReader()->ReadAODMCParticles()) |
451 | { | |
3d5d5078 | 452 | TClonesArray * mcparticles = GetReader()->GetAODMCParticles(0); |
34c16486 | 453 | if(mcparticles) |
454 | { | |
3d5d5078 | 455 | Int_t nprim = mcparticles->GetEntriesFast(); |
456 | ||
457 | for(Int_t i=0; i < nprim; i++) | |
458 | { | |
459 | AliAODMCParticle * prim = (AliAODMCParticle *) mcparticles->At(i); | |
460 | ||
34c16486 | 461 | pdg = prim->GetPdgCode(); |
3d5d5078 | 462 | |
34c16486 | 463 | if(pdg == 22) |
464 | { | |
3d5d5078 | 465 | // Get tag of this particle photon from fragmentation, decay, prompt ... |
34c16486 | 466 | tag = GetMCAnalysisUtils()->CheckOrigin(i,GetReader(), 0); |
467 | if(!GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPhoton)) | |
468 | { | |
3d5d5078 | 469 | //A conversion photon from a hadron, skip this kind of photon |
34c16486 | 470 | // printf("AliAnaPhoton::FillAcceptanceHistograms() - not a photon, weird!\n "); |
471 | // GetMCAnalysisUtils()->PrintMCTag(tag); | |
3d5d5078 | 472 | |
473 | return; | |
474 | } | |
475 | ||
476 | //Get photon kinematics | |
477 | if(prim->E() == TMath::Abs(prim->Pz())) continue ; //Protection against floating point exception | |
478 | ||
34c16486 | 479 | photonY = 0.5*TMath::Log((prim->E()-prim->Pz())/(prim->E()+prim->Pz())) ; |
480 | photonE = prim->E() ; | |
481 | photonPt = prim->Pt() ; | |
03734799 | 482 | photonPhi = prim->Phi() ; |
3d5d5078 | 483 | if(photonPhi < 0) photonPhi+=TMath::TwoPi(); |
34c16486 | 484 | photonEta = prim->Eta() ; |
3d5d5078 | 485 | |
486 | //Check if photons hit the Calorimeter | |
487 | TLorentzVector lv; | |
488 | lv.SetPxPyPzE(prim->Px(),prim->Py(),prim->Pz(),prim->E()); | |
34c16486 | 489 | inacceptance = kFALSE; |
490 | if (fCalorimeter == "PHOS") | |
491 | { | |
492 | if(GetPHOSGeometry() && GetCaloUtils()->IsPHOSGeoMatrixSet()) | |
493 | { | |
3d5d5078 | 494 | Int_t mod ; |
495 | Double_t x,z ; | |
496 | Double_t vtx[]={prim->Xv(),prim->Yv(),prim->Zv()}; | |
497 | if(GetPHOSGeometry()->ImpactOnEmc(vtx, prim->Theta(),prim->Phi(),mod,z,x)) | |
498 | inacceptance = kTRUE; | |
499 | if(GetDebug() > 2) printf("In %s Real acceptance? %d\n",fCalorimeter.Data(),inacceptance); | |
500 | } | |
34c16486 | 501 | else |
502 | { | |
3d5d5078 | 503 | if(GetFiducialCut()->IsInFiducialCut(lv,fCalorimeter)) |
504 | inacceptance = kTRUE ; | |
505 | if(GetDebug() > 2) printf("In %s fiducial cut acceptance? %d\n",fCalorimeter.Data(),inacceptance); | |
506 | } | |
507 | } | |
34c16486 | 508 | else if(fCalorimeter == "EMCAL" && GetCaloUtils()->IsEMCALGeoMatrixSet()) |
509 | { | |
510 | if(GetEMCALGeometry()) | |
511 | { | |
3d5d5078 | 512 | Int_t absID=0; |
513 | ||
514 | GetEMCALGeometry()->GetAbsCellIdFromEtaPhi(prim->Eta(),prim->Phi(),absID); | |
515 | ||
516 | if( absID >= 0) | |
517 | inacceptance = kTRUE; | |
518 | ||
519 | if(GetDebug() > 2) printf("In %s Real acceptance? %d\n",fCalorimeter.Data(),inacceptance); | |
520 | } | |
34c16486 | 521 | else |
522 | { | |
3d5d5078 | 523 | if(GetFiducialCut()->IsInFiducialCut(lv,fCalorimeter)) |
524 | inacceptance = kTRUE ; | |
525 | if(GetDebug() > 2) printf("In %s fiducial cut acceptance? %d\n",fCalorimeter.Data(),inacceptance); | |
526 | } | |
527 | } //In EMCAL | |
528 | ||
529 | //Fill histograms | |
530 | ||
c5693f62 | 531 | fhYPrimMC[kmcPPhoton]->Fill(photonPt, photonY) ; |
3d5d5078 | 532 | if(TMath::Abs(photonY) < 1.0) |
533 | { | |
c5693f62 | 534 | fhEPrimMC [kmcPPhoton]->Fill(photonE ) ; |
535 | fhPtPrimMC [kmcPPhoton]->Fill(photonPt) ; | |
536 | fhPhiPrimMC[kmcPPhoton]->Fill(photonE , photonPhi) ; | |
537 | fhYPrimMC[kmcPPhoton]->Fill(photonE , photonEta) ; | |
3d5d5078 | 538 | } |
34c16486 | 539 | |
540 | if(inacceptance) | |
541 | { | |
c5693f62 | 542 | fhEPrimMCAcc[kmcPPhoton] ->Fill(photonE ) ; |
543 | fhPtPrimMCAcc[kmcPPhoton] ->Fill(photonPt) ; | |
544 | fhPhiPrimMCAcc[kmcPPhoton]->Fill(photonE , photonPhi) ; | |
545 | fhYPrimMCAcc[kmcPPhoton] ->Fill(photonE , photonY) ; | |
3d5d5078 | 546 | }//Accepted |
547 | ||
3d5d5078 | 548 | //Origin of photon |
c5693f62 | 549 | if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPrompt) && fhEPrimMC[kmcPPrompt]) |
3d5d5078 | 550 | { |
34c16486 | 551 | mcIndex = kmcPPrompt; |
3d5d5078 | 552 | } |
34c16486 | 553 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCFragmentation) && fhEPrimMC[kmcPFragmentation]) |
3d5d5078 | 554 | { |
34c16486 | 555 | mcIndex = kmcPFragmentation ; |
3d5d5078 | 556 | } |
c5693f62 | 557 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCISR) && fhEPrimMC[kmcPISR]) |
3d5d5078 | 558 | { |
34c16486 | 559 | mcIndex = kmcPISR; |
3d5d5078 | 560 | } |
c5693f62 | 561 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPi0Decay)&& fhEPrimMC[kmcPPi0Decay]) |
3d5d5078 | 562 | { |
34c16486 | 563 | mcIndex = kmcPPi0Decay; |
3d5d5078 | 564 | } |
34c16486 | 565 | else if( (GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCEtaDecay) || |
566 | GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCOtherDecay)) && fhEPrimMC[kmcPOtherDecay]) | |
3d5d5078 | 567 | { |
34c16486 | 568 | mcIndex = kmcPOtherDecay; |
3d5d5078 | 569 | } |
c5693f62 | 570 | else if(fhEPrimMC[kmcPOther]) |
3d5d5078 | 571 | { |
34c16486 | 572 | mcIndex = kmcPOther; |
3d5d5078 | 573 | }//Other origin |
34c16486 | 574 | |
575 | fhYPrimMC[mcIndex]->Fill(photonPt, photonY) ; | |
576 | if(TMath::Abs(photonY) < 1.0) | |
577 | { | |
578 | fhEPrimMC [mcIndex]->Fill(photonE ) ; | |
579 | fhPtPrimMC [mcIndex]->Fill(photonPt) ; | |
580 | fhPhiPrimMC[mcIndex]->Fill(photonE , photonPhi) ; | |
581 | fhYPrimMC [mcIndex]->Fill(photonE , photonEta) ; | |
582 | } | |
583 | if(inacceptance) | |
584 | { | |
585 | fhEPrimMCAcc [mcIndex]->Fill(photonE ) ; | |
586 | fhPtPrimMCAcc [mcIndex]->Fill(photonPt) ; | |
587 | fhPhiPrimMCAcc[mcIndex]->Fill(photonE , photonPhi) ; | |
588 | fhYPrimMCAcc [mcIndex]->Fill(photonE , photonY) ; | |
589 | }//Accepted | |
590 | ||
3d5d5078 | 591 | }// Primary photon |
592 | }//loop on primaries | |
593 | ||
c5693f62 | 594 | }//kmc array exists and data is MC |
3d5d5078 | 595 | } // read AOD MC |
596 | } | |
521636d2 | 597 | |
2ad19c3d | 598 | //___________________________________________________________________ |
acd56ca4 | 599 | void AliAnaPhoton::FillPileUpHistogramsPerEvent(TObjArray * clusters) |
600 | { | |
601 | // Fill some histograms per event to understand pile-up | |
6227a9fd | 602 | // Open the time cut in the reader to be more meaningful |
603 | ||
acd56ca4 | 604 | if(!fFillPileUpHistograms) return; |
605 | ||
606 | // Loop on clusters, get the maximum energy cluster as reference | |
607 | Int_t nclusters = clusters->GetEntriesFast(); | |
608 | Int_t idMax = 0; | |
609 | Float_t eMax = 0; | |
610 | Float_t tMax = 0; | |
611 | for(Int_t iclus = 0; iclus < nclusters ; iclus++) | |
612 | { | |
613 | AliVCluster * clus = (AliVCluster*) (clusters->At(iclus)); | |
6227a9fd | 614 | if(clus->E() > eMax && TMath::Abs(clus->GetTOF()*1e9) < 20) |
acd56ca4 | 615 | { |
616 | eMax = clus->E(); | |
617 | tMax = clus->GetTOF()*1e9; | |
618 | idMax = iclus; | |
619 | } | |
620 | } | |
621 | ||
6227a9fd | 622 | if(eMax < 5) return; |
acd56ca4 | 623 | |
624 | // Loop again on clusters to compare this max cluster t and the rest of the clusters, if E > 0.3 | |
625 | Int_t n20 = 0; | |
626 | Int_t n40 = 0; | |
627 | Int_t n = 0; | |
628 | Int_t nOK = 0; | |
629 | ||
630 | for(Int_t iclus = 0; iclus < nclusters ; iclus++) | |
631 | { | |
632 | AliVCluster * clus = (AliVCluster*) (clusters->At(iclus)); | |
633 | ||
634 | if(clus->E() < 0.3 || iclus==idMax) continue; | |
635 | ||
636 | Float_t tdiff = TMath::Abs(tMax-clus->GetTOF()*1e9); | |
637 | n++; | |
638 | if(tdiff < 20) nOK++; | |
639 | else | |
640 | { | |
641 | n20++; | |
642 | if(tdiff > 40 ) n40++; | |
643 | } | |
644 | } | |
645 | ||
646 | // Check pile-up and fill histograms depending on the different cluster multiplicities | |
647 | if(GetReader()->IsPileUpFromSPD()) | |
648 | { | |
649 | fhClusterMultSPDPileUp[0]->Fill(eMax,n ); | |
650 | fhClusterMultSPDPileUp[1]->Fill(eMax,nOK); | |
651 | fhClusterMultSPDPileUp[2]->Fill(eMax,n20); | |
652 | fhClusterMultSPDPileUp[3]->Fill(eMax,n40); | |
653 | } | |
654 | else | |
655 | { | |
656 | fhClusterMultNoPileUp[0]->Fill(eMax,n ); | |
657 | fhClusterMultNoPileUp[1]->Fill(eMax,nOK); | |
658 | fhClusterMultNoPileUp[2]->Fill(eMax,n20); | |
659 | fhClusterMultNoPileUp[3]->Fill(eMax,n40); | |
660 | } | |
661 | ||
662 | } | |
663 | ||
664 | ||
665 | //___________________________________________________________________ | |
666 | void AliAnaPhoton::FillPileUpHistograms(const Float_t energy, const Float_t time) | |
2ad19c3d | 667 | { |
668 | // Fill some histograms to understand pile-up | |
669 | if(!fFillPileUpHistograms) return; | |
670 | ||
671 | //printf("E %f, time %f\n",energy,time); | |
672 | AliVEvent * event = GetReader()->GetInputEvent(); | |
673 | ||
674 | fhTimeENoCut->Fill(energy,time); | |
675 | if(GetReader()->IsPileUpFromSPD()) fhTimeESPD ->Fill(energy,time); | |
676 | if(event->IsPileupFromSPDInMultBins()) fhTimeESPDMulti->Fill(energy,time); | |
677 | ||
de101942 | 678 | if(energy < 8) return; // Fill time figures for high energy clusters not too close to trigger threshold |
2ad19c3d | 679 | |
680 | AliESDEvent* esdEv = dynamic_cast<AliESDEvent*> (event); | |
681 | AliAODEvent* aodEv = dynamic_cast<AliAODEvent*> (event); | |
682 | ||
683 | // N pile up vertices | |
684 | Int_t nVerticesSPD = -1; | |
685 | Int_t nVerticesTracks = -1; | |
686 | ||
687 | if (esdEv) | |
688 | { | |
689 | nVerticesSPD = esdEv->GetNumberOfPileupVerticesSPD(); | |
690 | nVerticesTracks = esdEv->GetNumberOfPileupVerticesTracks(); | |
691 | ||
692 | }//ESD | |
693 | else if (aodEv) | |
694 | { | |
695 | nVerticesSPD = aodEv->GetNumberOfPileupVerticesSPD(); | |
696 | nVerticesTracks = aodEv->GetNumberOfPileupVerticesTracks(); | |
697 | }//AOD | |
698 | ||
699 | fhTimeNPileUpVertSPD ->Fill(time,nVerticesSPD); | |
700 | fhTimeNPileUpVertTrack->Fill(time,nVerticesTracks); | |
701 | ||
702 | //printf("Is SPD %d, Is SPD Multi %d, n spd %d, n track %d\n", | |
703 | // GetReader()->IsPileUpFromSPD(),event->IsPileupFromSPDInMultBins(),nVerticesSPD,nVerticesTracks); | |
704 | ||
705 | Int_t ncont = -1; | |
5559f30a | 706 | Float_t z1 = -1, z2 = -1; |
2ad19c3d | 707 | Float_t diamZ = -1; |
708 | for(Int_t iVert=0; iVert<nVerticesSPD;iVert++) | |
709 | { | |
710 | if (esdEv) | |
711 | { | |
712 | const AliESDVertex* pv=esdEv->GetPileupVertexSPD(iVert); | |
713 | ncont=pv->GetNContributors(); | |
714 | z1 = esdEv->GetPrimaryVertexSPD()->GetZ(); | |
715 | z2 = pv->GetZ(); | |
716 | diamZ = esdEv->GetDiamondZ(); | |
717 | }//ESD | |
718 | else if (aodEv) | |
719 | { | |
720 | AliAODVertex *pv=aodEv->GetVertex(iVert); | |
721 | if(pv->GetType()!=AliAODVertex::kPileupSPD) continue; | |
722 | ncont=pv->GetNContributors(); | |
723 | z1=aodEv->GetPrimaryVertexSPD()->GetZ(); | |
724 | z2=pv->GetZ(); | |
725 | diamZ = aodEv->GetDiamondZ(); | |
726 | }// AOD | |
727 | ||
728 | Double_t distZ = TMath::Abs(z2-z1); | |
729 | diamZ = TMath::Abs(z2-diamZ); | |
730 | ||
731 | fhTimeNPileUpVertContributors ->Fill(time,ncont); | |
732 | fhTimePileUpMainVertexZDistance->Fill(time,distZ); | |
733 | fhTimePileUpMainVertexZDiamond ->Fill(time,diamZ); | |
734 | ||
735 | }// loop | |
736 | } | |
737 | ||
34c16486 | 738 | //____________________________________________________________________________________ |
739 | void AliAnaPhoton::FillShowerShapeHistograms(AliVCluster* cluster, const Int_t mcTag) | |
740 | { | |
741 | //Fill cluster Shower Shape histograms | |
521636d2 | 742 | |
743 | if(!fFillSSHistograms || GetMixedEvent()) return; | |
8d6b7f60 | 744 | |
521636d2 | 745 | Float_t energy = cluster->E(); |
746 | Int_t ncells = cluster->GetNCells(); | |
521636d2 | 747 | Float_t lambda0 = cluster->GetM02(); |
748 | Float_t lambda1 = cluster->GetM20(); | |
749 | Float_t disp = cluster->GetDispersion()*cluster->GetDispersion(); | |
750 | ||
751 | TLorentzVector mom; | |
34c16486 | 752 | if(GetReader()->GetDataType() != AliCaloTrackReader::kMC) |
753 | { | |
754 | cluster->GetMomentum(mom,GetVertex(0)) ; | |
755 | }//Assume that come from vertex in straight line | |
756 | else | |
757 | { | |
521636d2 | 758 | Double_t vertex[]={0,0,0}; |
759 | cluster->GetMomentum(mom,vertex) ; | |
760 | } | |
761 | ||
762 | Float_t eta = mom.Eta(); | |
763 | Float_t phi = mom.Phi(); | |
764 | if(phi < 0) phi+=TMath::TwoPi(); | |
765 | ||
766 | fhLam0E ->Fill(energy,lambda0); | |
767 | fhLam1E ->Fill(energy,lambda1); | |
768 | fhDispE ->Fill(energy,disp); | |
b5dbb99b | 769 | |
34c16486 | 770 | if(fCalorimeter == "EMCAL" && GetModuleNumber(cluster) > 5) |
771 | { | |
521636d2 | 772 | fhLam0ETRD->Fill(energy,lambda0); |
773 | fhLam1ETRD->Fill(energy,lambda1); | |
774 | fhDispETRD->Fill(energy,disp); | |
521636d2 | 775 | } |
776 | ||
34c16486 | 777 | Float_t l0 = 0., l1 = 0.; |
778 | Float_t dispp= 0., dEta = 0., dPhi = 0.; | |
779 | Float_t sEta = 0., sPhi = 0., sEtaPhi = 0.; | |
764ab1f4 | 780 | if(fCalorimeter == "EMCAL" && !fFillOnlySimpleSSHisto) |
34c16486 | 781 | { |
782 | GetCaloUtils()->GetEMCALRecoUtils()->RecalculateClusterShowerShapeParameters(GetEMCALGeometry(), GetReader()->GetInputEvent()->GetEMCALCells(), cluster, | |
783 | l0, l1, dispp, dEta, dPhi, sEta, sPhi, sEtaPhi); | |
784 | //printf("AliAnaPhoton::FillShowerShapeHistogram - l0 %2.6f, l1 %2.6f, disp %2.6f, dEta %2.6f, dPhi %2.6f, sEta %2.6f, sPhi %2.6f, sEtaPhi %2.6f \n", | |
785 | // l0, l1, dispp, dEta, dPhi, sEta, sPhi, sEtaPhi ); | |
786 | //printf("AliAnaPhoton::FillShowerShapeHistogram - dispersion %f, dispersion eta+phi %f \n", | |
787 | // disp, dPhi+dEta ); | |
788 | fhDispEtaE -> Fill(energy,dEta); | |
789 | fhDispPhiE -> Fill(energy,dPhi); | |
790 | fhSumEtaE -> Fill(energy,sEta); | |
791 | fhSumPhiE -> Fill(energy,sPhi); | |
792 | fhSumEtaPhiE -> Fill(energy,sEtaPhi); | |
793 | fhDispEtaPhiDiffE -> Fill(energy,dPhi-dEta); | |
794 | if(dEta+dPhi>0)fhSphericityE -> Fill(energy,(dPhi-dEta)/(dEta+dPhi)); | |
795 | if(dEta+sEta>0)fhDispSumEtaDiffE -> Fill(energy,(dEta-sEta)/((dEta+sEta)/2.)); | |
796 | if(dPhi+sPhi>0)fhDispSumPhiDiffE -> Fill(energy,(dPhi-sPhi)/((dPhi+sPhi)/2.)); | |
797 | ||
bfdcf7fb | 798 | Int_t ebin = -1; |
799 | if (energy < 2 ) ebin = 0; | |
800 | else if (energy < 4 ) ebin = 1; | |
801 | else if (energy < 6 ) ebin = 2; | |
802 | else if (energy < 10) ebin = 3; | |
d2655d46 | 803 | else if (energy < 15) ebin = 4; |
804 | else if (energy < 20) ebin = 5; | |
805 | else ebin = 6; | |
bfdcf7fb | 806 | |
807 | fhDispEtaDispPhi[ebin]->Fill(dEta ,dPhi); | |
808 | fhLambda0DispEta[ebin]->Fill(lambda0,dEta); | |
809 | fhLambda0DispPhi[ebin]->Fill(lambda0,dPhi); | |
810 | ||
34c16486 | 811 | } |
812 | ||
b5dbb99b | 813 | // if track-matching was of, check effect of track-matching residual cut |
814 | ||
815 | if(!fRejectTrackMatch) | |
816 | { | |
817 | Float_t dZ = cluster->GetTrackDz(); | |
818 | Float_t dR = cluster->GetTrackDx(); | |
34c16486 | 819 | if(cluster->IsEMCAL() && GetCaloUtils()->IsRecalculationOfClusterTrackMatchingOn()) |
820 | { | |
b5dbb99b | 821 | dR = 2000., dZ = 2000.; |
822 | GetCaloUtils()->GetEMCALRecoUtils()->GetMatchedResiduals(cluster->GetID(),dZ,dR); | |
823 | } | |
824 | ||
825 | if(TMath::Abs(dZ) < 0.05 && TMath::Abs(dR) < 0.05) | |
826 | { | |
827 | fhLam0ETM ->Fill(energy,lambda0); | |
828 | fhLam1ETM ->Fill(energy,lambda1); | |
829 | fhDispETM ->Fill(energy,disp); | |
830 | ||
34c16486 | 831 | if(fCalorimeter == "EMCAL" && GetModuleNumber(cluster) > 5) |
832 | { | |
b5dbb99b | 833 | fhLam0ETMTRD->Fill(energy,lambda0); |
834 | fhLam1ETMTRD->Fill(energy,lambda1); | |
835 | fhDispETMTRD->Fill(energy,disp); | |
836 | } | |
837 | } | |
838 | }// if track-matching was of, check effect of matching residual cut | |
839 | ||
764ab1f4 | 840 | |
841 | if(!fFillOnlySimpleSSHisto){ | |
842 | if(energy < 2) | |
843 | { | |
844 | fhNCellsLam0LowE ->Fill(ncells,lambda0); | |
845 | fhNCellsLam1LowE ->Fill(ncells,lambda1); | |
846 | fhNCellsDispLowE ->Fill(ncells,disp); | |
847 | ||
848 | fhLam1Lam0LowE ->Fill(lambda1,lambda0); | |
849 | fhLam0DispLowE ->Fill(lambda0,disp); | |
850 | fhDispLam1LowE ->Fill(disp,lambda1); | |
851 | fhEtaLam0LowE ->Fill(eta,lambda0); | |
852 | fhPhiLam0LowE ->Fill(phi,lambda0); | |
853 | } | |
854 | else | |
855 | { | |
856 | fhNCellsLam0HighE ->Fill(ncells,lambda0); | |
857 | fhNCellsLam1HighE ->Fill(ncells,lambda1); | |
858 | fhNCellsDispHighE ->Fill(ncells,disp); | |
859 | ||
860 | fhLam1Lam0HighE ->Fill(lambda1,lambda0); | |
861 | fhLam0DispHighE ->Fill(lambda0,disp); | |
862 | fhDispLam1HighE ->Fill(disp,lambda1); | |
863 | fhEtaLam0HighE ->Fill(eta, lambda0); | |
864 | fhPhiLam0HighE ->Fill(phi, lambda0); | |
865 | } | |
521636d2 | 866 | } |
867 | ||
34c16486 | 868 | if(IsDataMC()) |
869 | { | |
f66d95af | 870 | AliVCaloCells* cells = 0; |
871 | if(fCalorimeter == "EMCAL") cells = GetEMCALCells(); | |
872 | else cells = GetPHOSCells(); | |
3d5d5078 | 873 | |
874 | //Fill histograms to check shape of embedded clusters | |
875 | Float_t fraction = 0; | |
34c16486 | 876 | if(GetReader()->IsEmbeddedClusterSelectionOn()) |
877 | {//Only working for EMCAL | |
3d5d5078 | 878 | Float_t clusterE = 0; // recalculate in case corrections applied. |
879 | Float_t cellE = 0; | |
34c16486 | 880 | for(Int_t icell = 0; icell < cluster->GetNCells(); icell++) |
881 | { | |
3d5d5078 | 882 | cellE = cells->GetCellAmplitude(cluster->GetCellAbsId(icell)); |
883 | clusterE+=cellE; | |
884 | fraction+=cellE*cluster->GetCellAmplitudeFraction(icell); | |
885 | } | |
886 | ||
887 | //Fraction of total energy due to the embedded signal | |
888 | fraction/=clusterE; | |
889 | ||
8d6b7f60 | 890 | if(GetDebug() > 1 ) |
891 | printf("AliAnaPhoton::FillShowerShapeHistogram() - Energy fraction of embedded signal %2.3f, Energy %2.3f\n",fraction, clusterE); | |
3d5d5078 | 892 | |
893 | fhEmbeddedSignalFractionEnergy->Fill(clusterE,fraction); | |
894 | ||
895 | } // embedded fraction | |
896 | ||
f66d95af | 897 | // Get the fraction of the cluster energy that carries the cell with highest energy |
34c16486 | 898 | Int_t absID =-1 ; |
f66d95af | 899 | Float_t maxCellFraction = 0.; |
900 | ||
901 | absID = GetCaloUtils()->GetMaxEnergyCell(cells, cluster,maxCellFraction); | |
902 | ||
903 | // Check the origin and fill histograms | |
34c16486 | 904 | |
905 | Int_t mcIndex = -1; | |
906 | ||
907 | if( GetMCAnalysisUtils()->CheckTagBit(mcTag,AliMCAnalysisUtils::kMCPhoton) && | |
3d5d5078 | 908 | !GetMCAnalysisUtils()->CheckTagBit(mcTag,AliMCAnalysisUtils::kMCConversion) && |
34c16486 | 909 | !GetMCAnalysisUtils()->CheckTagBit(mcTag,AliMCAnalysisUtils::kMCPi0) && |
910 | !GetMCAnalysisUtils()->CheckTagBit(mcTag,AliMCAnalysisUtils::kMCEta)) | |
911 | { | |
912 | mcIndex = kmcssPhoton ; | |
913 | ||
914 | if(!GetReader()->IsEmbeddedClusterSelectionOn()) | |
915 | { | |
3d5d5078 | 916 | //Check particle overlaps in cluster |
917 | ||
8d6b7f60 | 918 | // Compare the primary depositing more energy with the rest, |
919 | // if no photon/electron as comon ancestor (conversions), count as other particle | |
3d5d5078 | 920 | Int_t ancPDG = 0, ancStatus = -1; |
921 | TLorentzVector momentum; TVector3 prodVertex; | |
922 | Int_t ancLabel = 0; | |
923 | Int_t noverlaps = 1; | |
34c16486 | 924 | for (UInt_t ilab = 0; ilab < cluster->GetNLabels(); ilab++ ) |
925 | { | |
926 | ancLabel = GetMCAnalysisUtils()->CheckCommonAncestor(cluster->GetLabels()[0],cluster->GetLabels()[ilab], | |
927 | GetReader(),ancPDG,ancStatus,momentum,prodVertex); | |
3d5d5078 | 928 | if(ancPDG!=22 && TMath::Abs(ancPDG)!=11) noverlaps++; |
929 | } | |
8d6b7f60 | 930 | //printf("N overlaps %d \n",noverlaps); |
3d5d5078 | 931 | |
34c16486 | 932 | if(noverlaps == 1) |
933 | { | |
3d5d5078 | 934 | fhMCPhotonELambda0NoOverlap ->Fill(energy, lambda0); |
3d5d5078 | 935 | } |
34c16486 | 936 | else if(noverlaps == 2) |
937 | { | |
3d5d5078 | 938 | fhMCPhotonELambda0TwoOverlap ->Fill(energy, lambda0); |
3d5d5078 | 939 | } |
34c16486 | 940 | else if(noverlaps > 2) |
941 | { | |
3d5d5078 | 942 | fhMCPhotonELambda0NOverlap ->Fill(energy, lambda0); |
3d5d5078 | 943 | } |
34c16486 | 944 | else |
945 | { | |
3d5d5078 | 946 | printf("AliAnaPhoton::FillShowerShapeHistogram() - n overlaps = %d!!", noverlaps); |
947 | } | |
948 | }//No embedding | |
949 | ||
950 | //Fill histograms to check shape of embedded clusters | |
34c16486 | 951 | if(GetReader()->IsEmbeddedClusterSelectionOn()) |
952 | { | |
3d5d5078 | 953 | if (fraction > 0.9) |
954 | { | |
955 | fhEmbedPhotonELambda0FullSignal ->Fill(energy, lambda0); | |
3d5d5078 | 956 | } |
957 | else if(fraction > 0.5) | |
958 | { | |
959 | fhEmbedPhotonELambda0MostlySignal ->Fill(energy, lambda0); | |
3d5d5078 | 960 | } |
961 | else if(fraction > 0.1) | |
962 | { | |
963 | fhEmbedPhotonELambda0MostlyBkg ->Fill(energy, lambda0); | |
3d5d5078 | 964 | } |
965 | else | |
966 | { | |
967 | fhEmbedPhotonELambda0FullBkg ->Fill(energy, lambda0); | |
3d5d5078 | 968 | } |
969 | } // embedded | |
970 | ||
521636d2 | 971 | }//photon no conversion |
34c16486 | 972 | else if ( GetMCAnalysisUtils()->CheckTagBit(mcTag,AliMCAnalysisUtils::kMCElectron)) |
973 | { | |
974 | mcIndex = kmcssElectron ; | |
521636d2 | 975 | }//electron |
3d5d5078 | 976 | else if ( GetMCAnalysisUtils()->CheckTagBit(mcTag,AliMCAnalysisUtils::kMCPhoton) && |
34c16486 | 977 | GetMCAnalysisUtils()->CheckTagBit(mcTag,AliMCAnalysisUtils::kMCConversion) ) |
978 | { | |
979 | mcIndex = kmcssConversion ; | |
521636d2 | 980 | }//conversion photon |
34c16486 | 981 | else if ( GetMCAnalysisUtils()->CheckTagBit(mcTag,AliMCAnalysisUtils::kMCPi0) ) |
982 | { | |
983 | mcIndex = kmcssPi0 ; | |
3d5d5078 | 984 | |
985 | //Fill histograms to check shape of embedded clusters | |
34c16486 | 986 | if(GetReader()->IsEmbeddedClusterSelectionOn()) |
987 | { | |
3d5d5078 | 988 | if (fraction > 0.9) |
989 | { | |
990 | fhEmbedPi0ELambda0FullSignal ->Fill(energy, lambda0); | |
3d5d5078 | 991 | } |
992 | else if(fraction > 0.5) | |
993 | { | |
994 | fhEmbedPi0ELambda0MostlySignal ->Fill(energy, lambda0); | |
3d5d5078 | 995 | } |
996 | else if(fraction > 0.1) | |
997 | { | |
998 | fhEmbedPi0ELambda0MostlyBkg ->Fill(energy, lambda0); | |
3d5d5078 | 999 | } |
1000 | else | |
1001 | { | |
1002 | fhEmbedPi0ELambda0FullBkg ->Fill(energy, lambda0); | |
3d5d5078 | 1003 | } |
1004 | } // embedded | |
1005 | ||
521636d2 | 1006 | }//pi0 |
34c16486 | 1007 | else if ( GetMCAnalysisUtils()->CheckTagBit(mcTag,AliMCAnalysisUtils::kMCEta) ) |
1008 | { | |
1009 | mcIndex = kmcssEta ; | |
3d5d5078 | 1010 | }//eta |
34c16486 | 1011 | else |
1012 | { | |
1013 | mcIndex = kmcssOther ; | |
521636d2 | 1014 | }//other particles |
1015 | ||
34c16486 | 1016 | fhMCELambda0 [mcIndex]->Fill(energy, lambda0); |
1017 | fhMCELambda1 [mcIndex]->Fill(energy, lambda1); | |
1018 | fhMCEDispersion [mcIndex]->Fill(energy, disp); | |
1019 | fhMCNCellsE [mcIndex]->Fill(energy, ncells); | |
1020 | fhMCMaxCellDiffClusterE[mcIndex]->Fill(energy, maxCellFraction); | |
1021 | ||
764ab1f4 | 1022 | if(!fFillOnlySimpleSSHisto) |
34c16486 | 1023 | { |
764ab1f4 | 1024 | if (energy < 2.) |
1025 | { | |
1026 | fhMCLambda0vsClusterMaxCellDiffE0[mcIndex]->Fill(lambda0, maxCellFraction); | |
1027 | fhMCNCellsvsClusterMaxCellDiffE0 [mcIndex]->Fill(ncells, maxCellFraction); | |
1028 | } | |
1029 | else if(energy < 6.) | |
1030 | { | |
1031 | fhMCLambda0vsClusterMaxCellDiffE2[mcIndex]->Fill(lambda0, maxCellFraction); | |
1032 | fhMCNCellsvsClusterMaxCellDiffE2 [mcIndex]->Fill(ncells, maxCellFraction); | |
1033 | } | |
1034 | else | |
1035 | { | |
1036 | fhMCLambda0vsClusterMaxCellDiffE6[mcIndex]->Fill(lambda0, maxCellFraction); | |
1037 | fhMCNCellsvsClusterMaxCellDiffE6 [mcIndex]->Fill(ncells, maxCellFraction); | |
1038 | } | |
1039 | ||
1040 | if(fCalorimeter == "EMCAL") | |
1041 | { | |
1042 | fhMCEDispEta [mcIndex]-> Fill(energy,dEta); | |
1043 | fhMCEDispPhi [mcIndex]-> Fill(energy,dPhi); | |
1044 | fhMCESumEtaPhi [mcIndex]-> Fill(energy,sEtaPhi); | |
1045 | fhMCEDispEtaPhiDiff [mcIndex]-> Fill(energy,dPhi-dEta); | |
1046 | if(dEta+dPhi>0)fhMCESphericity[mcIndex]-> Fill(energy,(dPhi-dEta)/(dEta+dPhi)); | |
1047 | ||
1048 | Int_t ebin = -1; | |
1049 | if (energy < 2 ) ebin = 0; | |
1050 | else if (energy < 4 ) ebin = 1; | |
1051 | else if (energy < 6 ) ebin = 2; | |
1052 | else if (energy < 10) ebin = 3; | |
1053 | else if (energy < 15) ebin = 4; | |
1054 | else if (energy < 20) ebin = 5; | |
1055 | else ebin = 6; | |
1056 | ||
1057 | fhMCDispEtaDispPhi[ebin][mcIndex]->Fill(dEta ,dPhi); | |
1058 | fhMCLambda0DispEta[ebin][mcIndex]->Fill(lambda0,dEta); | |
1059 | fhMCLambda0DispPhi[ebin][mcIndex]->Fill(lambda0,dPhi); | |
1060 | } | |
34c16486 | 1061 | } |
521636d2 | 1062 | }//MC data |
1063 | ||
1064 | } | |
1065 | ||
4bfeae64 | 1066 | //__________________________________________________________________________ |
1067 | void AliAnaPhoton::FillTrackMatchingResidualHistograms(AliVCluster* cluster, | |
1068 | const Int_t cut) | |
1069 | { | |
1070 | // If selected, fill histograms with residuals of matched clusters, help to define track matching cut | |
1071 | // Residual filled for different cuts 0 (No cut), after 1 PID cut | |
1072 | ||
1073 | Float_t dZ = cluster->GetTrackDz(); | |
1074 | Float_t dR = cluster->GetTrackDx(); | |
1075 | ||
1076 | if(cluster->IsEMCAL() && GetCaloUtils()->IsRecalculationOfClusterTrackMatchingOn()) | |
1077 | { | |
1078 | dR = 2000., dZ = 2000.; | |
1079 | GetCaloUtils()->GetEMCALRecoUtils()->GetMatchedResiduals(cluster->GetID(),dZ,dR); | |
1080 | } | |
1081 | ||
1082 | if(fhTrackMatchedDEta[cut] && TMath::Abs(dR) < 999) | |
1083 | { | |
1084 | fhTrackMatchedDEta[cut]->Fill(cluster->E(),dZ); | |
1085 | fhTrackMatchedDPhi[cut]->Fill(cluster->E(),dR); | |
1086 | ||
1087 | if(cluster->E() > 0.5) fhTrackMatchedDEtaDPhi[cut]->Fill(dZ,dR); | |
1088 | ||
1089 | Int_t nSMod = GetModuleNumber(cluster); | |
1090 | ||
1091 | if(fCalorimeter=="EMCAL" && nSMod > 5) | |
1092 | { | |
1093 | fhTrackMatchedDEtaTRD[cut]->Fill(cluster->E(),dZ); | |
1094 | fhTrackMatchedDPhiTRD[cut]->Fill(cluster->E(),dR); | |
1095 | } | |
1096 | ||
1097 | // Check dEdx and E/p of matched clusters | |
1098 | ||
1099 | if(TMath::Abs(dZ) < 0.05 && TMath::Abs(dR) < 0.05) | |
1100 | { | |
1101 | ||
1102 | AliVTrack *track = GetCaloUtils()->GetMatchedTrack(cluster, GetReader()->GetInputEvent()); | |
1103 | ||
1104 | if(track) | |
1105 | { | |
1106 | ||
1107 | Float_t dEdx = track->GetTPCsignal(); | |
1108 | Float_t eOverp = cluster->E()/track->P(); | |
1109 | ||
1110 | fhdEdx[cut] ->Fill(cluster->E(), dEdx); | |
1111 | fhEOverP[cut]->Fill(cluster->E(), eOverp); | |
1112 | ||
1113 | if(fCalorimeter=="EMCAL" && nSMod > 5) | |
1114 | fhEOverPTRD[cut]->Fill(cluster->E(), eOverp); | |
1115 | ||
1116 | ||
1117 | } | |
1118 | else | |
1119 | printf("AliAnaPhoton::FillTrackMatchingResidualHistograms() - Residual OK but (dR, dZ)= (%2.4f,%2.4f) no track associated WHAT? \n", dR,dZ); | |
1120 | ||
1121 | ||
1122 | ||
1123 | if(IsDataMC()) | |
1124 | { | |
1125 | ||
1126 | Int_t tag = GetMCAnalysisUtils()->CheckOrigin(cluster->GetLabels(),cluster->GetNLabels(),GetReader(), 0); | |
1127 | ||
1128 | if ( !GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCConversion) ) | |
1129 | { | |
1130 | if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPi0) || | |
1131 | GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCEta) ) fhTrackMatchedMCParticle[cut]->Fill(cluster->E(), 2.5 ); | |
1132 | else if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPhoton) ) fhTrackMatchedMCParticle[cut]->Fill(cluster->E(), 0.5 ); | |
1133 | else if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCElectron) ) fhTrackMatchedMCParticle[cut]->Fill(cluster->E(), 1.5 ); | |
1134 | else fhTrackMatchedMCParticle[cut]->Fill(cluster->E(), 3.5 ); | |
1135 | ||
1136 | // Check if several particles contributed to cluster and discard overlapped mesons | |
1137 | if(!GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPi0) || | |
34c16486 | 1138 | !GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCEta)) |
1139 | { | |
4bfeae64 | 1140 | if(cluster->GetNLabels()==1) |
1141 | { | |
1142 | fhTrackMatchedDEtaMCNoOverlap[cut]->Fill(cluster->E(),dZ); | |
1143 | fhTrackMatchedDPhiMCNoOverlap[cut]->Fill(cluster->E(),dR); | |
1144 | } | |
1145 | else | |
1146 | { | |
1147 | fhTrackMatchedDEtaMCOverlap[cut]->Fill(cluster->E(),dZ); | |
1148 | fhTrackMatchedDPhiMCOverlap[cut]->Fill(cluster->E(),dR); | |
1149 | } | |
1150 | ||
1151 | }// Check overlaps | |
1152 | ||
1153 | } | |
1154 | else | |
1155 | { | |
1156 | if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPi0) || | |
1157 | GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCEta) ) fhTrackMatchedMCParticle[cut]->Fill(cluster->E(), 6.5 ); | |
1158 | else if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPhoton) ) fhTrackMatchedMCParticle[cut]->Fill(cluster->E(), 4.5 ); | |
1159 | else if ( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCElectron) ) fhTrackMatchedMCParticle[cut]->Fill(cluster->E(), 5.5 ); | |
1160 | else fhTrackMatchedMCParticle[cut]->Fill(cluster->E(), 7.5 ); | |
1161 | ||
1162 | // Check if several particles contributed to cluster | |
1163 | if(!GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPi0) || | |
34c16486 | 1164 | !GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCEta)) |
1165 | { | |
4bfeae64 | 1166 | fhTrackMatchedDEtaMCConversion[cut]->Fill(cluster->E(),dZ); |
1167 | fhTrackMatchedDPhiMCConversion[cut]->Fill(cluster->E(),dR); | |
1168 | ||
1169 | }// Check overlaps | |
1170 | ||
1171 | } | |
1172 | ||
1173 | } // MC | |
1174 | ||
1175 | } // residuals window | |
1176 | ||
1177 | } // Small residual | |
1178 | ||
1179 | } | |
1180 | ||
1181 | //___________________________________________ | |
0c1383b5 | 1182 | TObjString * AliAnaPhoton::GetAnalysisCuts() |
1183 | { | |
1184 | //Save parameters used for analysis | |
1185 | TString parList ; //this will be list of parameters used for this analysis. | |
5ae09196 | 1186 | const Int_t buffersize = 255; |
1187 | char onePar[buffersize] ; | |
0c1383b5 | 1188 | |
5ae09196 | 1189 | snprintf(onePar,buffersize,"--- AliAnaPhoton ---\n") ; |
0c1383b5 | 1190 | parList+=onePar ; |
5ae09196 | 1191 | snprintf(onePar,buffersize,"Calorimeter: %s\n",fCalorimeter.Data()) ; |
0c1383b5 | 1192 | parList+=onePar ; |
5ae09196 | 1193 | snprintf(onePar,buffersize,"fMinDist =%2.2f (Minimal distance to bad channel to accept cluster) \n",fMinDist) ; |
0c1383b5 | 1194 | parList+=onePar ; |
5ae09196 | 1195 | snprintf(onePar,buffersize,"fMinDist2=%2.2f (Cuts on Minimal distance to study acceptance evaluation) \n",fMinDist2) ; |
0c1383b5 | 1196 | parList+=onePar ; |
5ae09196 | 1197 | snprintf(onePar,buffersize,"fMinDist3=%2.2f (One more cut on distance used for acceptance-efficiency study) \n",fMinDist3) ; |
0c1383b5 | 1198 | parList+=onePar ; |
5ae09196 | 1199 | snprintf(onePar,buffersize,"fRejectTrackMatch: %d\n",fRejectTrackMatch) ; |
0c1383b5 | 1200 | parList+=onePar ; |
1201 | ||
1202 | //Get parameters set in base class. | |
1203 | parList += GetBaseParametersList() ; | |
1204 | ||
1205 | //Get parameters set in PID class. | |
1206 | parList += GetCaloPID()->GetPIDParametersList() ; | |
1207 | ||
1208 | //Get parameters set in FiducialCut class (not available yet) | |
1209 | //parlist += GetFidCut()->GetFidCutParametersList() | |
1210 | ||
1211 | return new TObjString(parList) ; | |
1212 | } | |
1213 | ||
1c5acb87 | 1214 | //________________________________________________________________________ |
1215 | TList * AliAnaPhoton::GetCreateOutputObjects() | |
1216 | { | |
477d6cee | 1217 | // Create histograms to be saved in output file and |
1218 | // store them in outputContainer | |
1219 | TList * outputContainer = new TList() ; | |
1220 | outputContainer->SetName("PhotonHistos") ; | |
4a745797 | 1221 | |
745913ae | 1222 | Int_t nptbins = GetHistogramRanges()->GetHistoPtBins(); Float_t ptmax = GetHistogramRanges()->GetHistoPtMax(); Float_t ptmin = GetHistogramRanges()->GetHistoPtMin(); |
1223 | Int_t nphibins = GetHistogramRanges()->GetHistoPhiBins(); Float_t phimax = GetHistogramRanges()->GetHistoPhiMax(); Float_t phimin = GetHistogramRanges()->GetHistoPhiMin(); | |
1224 | Int_t netabins = GetHistogramRanges()->GetHistoEtaBins(); Float_t etamax = GetHistogramRanges()->GetHistoEtaMax(); Float_t etamin = GetHistogramRanges()->GetHistoEtaMin(); | |
1225 | Int_t ssbins = GetHistogramRanges()->GetHistoShowerShapeBins(); Float_t ssmax = GetHistogramRanges()->GetHistoShowerShapeMax(); Float_t ssmin = GetHistogramRanges()->GetHistoShowerShapeMin(); | |
1226 | Int_t nbins = GetHistogramRanges()->GetHistoNClusterCellBins(); Int_t nmax = GetHistogramRanges()->GetHistoNClusterCellMax(); Int_t nmin = GetHistogramRanges()->GetHistoNClusterCellMin(); | |
1227 | Int_t ntimebins= GetHistogramRanges()->GetHistoTimeBins(); Float_t timemax = GetHistogramRanges()->GetHistoTimeMax(); Float_t timemin = GetHistogramRanges()->GetHistoTimeMin(); | |
521636d2 | 1228 | |
09273901 | 1229 | Int_t nresetabins = GetHistogramRanges()->GetHistoTrackResidualEtaBins(); |
1230 | Float_t resetamax = GetHistogramRanges()->GetHistoTrackResidualEtaMax(); | |
1231 | Float_t resetamin = GetHistogramRanges()->GetHistoTrackResidualEtaMin(); | |
1232 | Int_t nresphibins = GetHistogramRanges()->GetHistoTrackResidualPhiBins(); | |
1233 | Float_t resphimax = GetHistogramRanges()->GetHistoTrackResidualPhiMax(); | |
1234 | Float_t resphimin = GetHistogramRanges()->GetHistoTrackResidualPhiMin(); | |
1235 | ||
31ae6d59 | 1236 | Int_t ndedxbins = GetHistogramRanges()->GetHistodEdxBins(); |
1237 | Float_t dedxmax = GetHistogramRanges()->GetHistodEdxMax(); | |
1238 | Float_t dedxmin = GetHistogramRanges()->GetHistodEdxMin(); | |
1239 | Int_t nPoverEbins = GetHistogramRanges()->GetHistoPOverEBins(); | |
1240 | Float_t pOverEmax = GetHistogramRanges()->GetHistoPOverEMax(); | |
1241 | Float_t pOverEmin = GetHistogramRanges()->GetHistoPOverEMin(); | |
09273901 | 1242 | |
d2655d46 | 1243 | Int_t bin[] = {0,2,4,6,10,15,20,100}; // energy bins for SS studies |
1244 | ||
9e51e29a | 1245 | TString cut[] = {"Open","Reader","E","Time","NCells","NLM","Fidutial","Matching","Bad","PID"}; |
1246 | for (Int_t i = 0; i < 10 ; i++) | |
fc195fd0 | 1247 | { |
1248 | fhClusterCuts[i] = new TH1F(Form("hCut_%d_%s", i, cut[i].Data()), | |
1249 | Form("Number of clusters that pass cuts <= %d, %s", i, cut[i].Data()), | |
1250 | nptbins,ptmin,ptmax); | |
1251 | fhClusterCuts[i]->SetYTitle("dN/dE "); | |
1252 | fhClusterCuts[i]->SetXTitle("E (GeV)"); | |
1253 | outputContainer->Add(fhClusterCuts[i]) ; | |
1254 | } | |
1255 | ||
e1e62b89 | 1256 | fhNCellsE = new TH2F ("hNCellsE","# of cells in cluster vs E of clusters", nptbins,ptmin,ptmax, nbins,nmin,nmax); |
c4a7d28a | 1257 | fhNCellsE->SetXTitle("E (GeV)"); |
1258 | fhNCellsE->SetYTitle("# of cells in cluster"); | |
f15c25da | 1259 | outputContainer->Add(fhNCellsE); |
1260 | ||
5c46c992 | 1261 | fhCellsE = new TH2F ("hCellsE","energy of cells in cluster vs E of clusters", nptbins,ptmin,ptmax, nptbins*2,ptmin,ptmax); |
1262 | fhCellsE->SetXTitle("E_{cluster} (GeV)"); | |
1263 | fhCellsE->SetYTitle("E_{cell} (GeV)"); | |
1264 | outputContainer->Add(fhCellsE); | |
1265 | ||
f15c25da | 1266 | fhTimeE = new TH2F ("hTimeE","time of cluster vs E of clusters", nptbins,ptmin,ptmax, ntimebins,timemin,timemax); |
1267 | fhTimeE->SetXTitle("E (GeV)"); | |
1268 | fhTimeE->SetYTitle("time (ns)"); | |
1269 | outputContainer->Add(fhTimeE); | |
6175da48 | 1270 | |
f66d95af | 1271 | fhMaxCellDiffClusterE = new TH2F ("hMaxCellDiffClusterE","energy vs difference of cluster energy - max cell energy / cluster energy, good clusters", |
1272 | nptbins,ptmin,ptmax, 500,0,1.); | |
1273 | fhMaxCellDiffClusterE->SetXTitle("E_{cluster} (GeV) "); | |
1274 | fhMaxCellDiffClusterE->SetYTitle("(E_{cluster} - E_{cell max})/ E_{cluster}"); | |
1275 | outputContainer->Add(fhMaxCellDiffClusterE); | |
1276 | ||
20218aea | 1277 | fhEPhoton = new TH1F("hEPhoton","Number of #gamma over calorimeter vs energy",nptbins,ptmin,ptmax); |
1278 | fhEPhoton->SetYTitle("N"); | |
1279 | fhEPhoton->SetXTitle("E_{#gamma}(GeV)"); | |
1280 | outputContainer->Add(fhEPhoton) ; | |
1281 | ||
1282 | fhPtPhoton = new TH1F("hPtPhoton","Number of #gamma over calorimeter vs p_{T}",nptbins,ptmin,ptmax); | |
477d6cee | 1283 | fhPtPhoton->SetYTitle("N"); |
1284 | fhPtPhoton->SetXTitle("p_{T #gamma}(GeV/c)"); | |
1285 | outputContainer->Add(fhPtPhoton) ; | |
1286 | ||
1287 | fhPhiPhoton = new TH2F | |
20218aea | 1288 | ("hPhiPhoton","#phi_{#gamma} vs p_{T}",nptbins,ptmin,ptmax,nphibins,phimin,phimax); |
6175da48 | 1289 | fhPhiPhoton->SetYTitle("#phi (rad)"); |
477d6cee | 1290 | fhPhiPhoton->SetXTitle("p_{T #gamma} (GeV/c)"); |
1291 | outputContainer->Add(fhPhiPhoton) ; | |
1292 | ||
1293 | fhEtaPhoton = new TH2F | |
20218aea | 1294 | ("hEtaPhoton","#eta_{#gamma} vs p_{T}",nptbins,ptmin,ptmax,netabins,etamin,etamax); |
477d6cee | 1295 | fhEtaPhoton->SetYTitle("#eta"); |
1296 | fhEtaPhoton->SetXTitle("p_{T #gamma} (GeV/c)"); | |
1297 | outputContainer->Add(fhEtaPhoton) ; | |
1298 | ||
6175da48 | 1299 | fhEtaPhiPhoton = new TH2F |
1300 | ("hEtaPhiPhoton","#eta vs #phi",netabins,etamin,etamax,nphibins,phimin,phimax); | |
1301 | fhEtaPhiPhoton->SetYTitle("#phi (rad)"); | |
1302 | fhEtaPhiPhoton->SetXTitle("#eta"); | |
1303 | outputContainer->Add(fhEtaPhiPhoton) ; | |
34c16486 | 1304 | if(GetMinPt() < 0.5) |
1305 | { | |
20218aea | 1306 | fhEtaPhi05Photon = new TH2F |
1307 | ("hEtaPhi05Photon","#eta vs #phi, E > 0.5",netabins,etamin,etamax,nphibins,phimin,phimax); | |
1308 | fhEtaPhi05Photon->SetYTitle("#phi (rad)"); | |
1309 | fhEtaPhi05Photon->SetXTitle("#eta"); | |
1310 | outputContainer->Add(fhEtaPhi05Photon) ; | |
1311 | } | |
6175da48 | 1312 | |
9e51e29a | 1313 | fhNLocMax = new TH2F("hNLocMax","Number of local maxima in cluster", |
1314 | nptbins,ptmin,ptmax,10,0,10); | |
1315 | fhNLocMax ->SetYTitle("N maxima"); | |
1316 | fhNLocMax ->SetXTitle("E (GeV)"); | |
1317 | outputContainer->Add(fhNLocMax) ; | |
1318 | ||
521636d2 | 1319 | //Shower shape |
34c16486 | 1320 | if(fFillSSHistograms) |
1321 | { | |
521636d2 | 1322 | fhLam0E = new TH2F ("hLam0E","#lambda_{0}^{2} vs E", nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); |
1323 | fhLam0E->SetYTitle("#lambda_{0}^{2}"); | |
1324 | fhLam0E->SetXTitle("E (GeV)"); | |
1325 | outputContainer->Add(fhLam0E); | |
1326 | ||
1327 | fhLam1E = new TH2F ("hLam1E","#lambda_{1}^{2} vs E", nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
1328 | fhLam1E->SetYTitle("#lambda_{1}^{2}"); | |
1329 | fhLam1E->SetXTitle("E (GeV)"); | |
1330 | outputContainer->Add(fhLam1E); | |
1331 | ||
1332 | fhDispE = new TH2F ("hDispE"," dispersion^{2} vs E", nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
1333 | fhDispE->SetYTitle("D^{2}"); | |
1334 | fhDispE->SetXTitle("E (GeV) "); | |
1335 | outputContainer->Add(fhDispE); | |
b5dbb99b | 1336 | |
1337 | if(!fRejectTrackMatch) | |
1338 | { | |
1339 | fhLam0ETM = new TH2F ("hLam0ETM","#lambda_{0}^{2} vs E, cut on track-matching residual |#Delta #eta| < 0.05, |#Delta #phi| < 0.05", nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
1340 | fhLam0ETM->SetYTitle("#lambda_{0}^{2}"); | |
1341 | fhLam0ETM->SetXTitle("E (GeV)"); | |
1342 | outputContainer->Add(fhLam0ETM); | |
1343 | ||
1344 | fhLam1ETM = new TH2F ("hLam1ETM","#lambda_{1}^{2} vs E, cut on track-matching residual |#Delta #eta| < 0.05, |#Delta #phi| < 0.05", nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
1345 | fhLam1ETM->SetYTitle("#lambda_{1}^{2}"); | |
1346 | fhLam1ETM->SetXTitle("E (GeV)"); | |
1347 | outputContainer->Add(fhLam1ETM); | |
1348 | ||
1349 | fhDispETM = new TH2F ("hDispETM"," dispersion^{2} vs E, cut on track-matching residual |#Delta #eta| < 0.05, |#Delta #phi| < 0.05", nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
1350 | fhDispETM->SetYTitle("D^{2}"); | |
1351 | fhDispETM->SetXTitle("E (GeV) "); | |
1352 | outputContainer->Add(fhDispETM); | |
1353 | } | |
521636d2 | 1354 | |
b5dbb99b | 1355 | if(fCalorimeter == "EMCAL") |
1356 | { | |
521636d2 | 1357 | fhLam0ETRD = new TH2F ("hLam0ETRD","#lambda_{0}^{2} vs E, EMCAL SM covered by TRD", nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); |
1358 | fhLam0ETRD->SetYTitle("#lambda_{0}^{2}"); | |
1359 | fhLam0ETRD->SetXTitle("E (GeV)"); | |
1360 | outputContainer->Add(fhLam0ETRD); | |
1361 | ||
1362 | fhLam1ETRD = new TH2F ("hLam1ETRD","#lambda_{1}^{2} vs E, EMCAL SM covered by TRD", nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
1363 | fhLam1ETRD->SetYTitle("#lambda_{1}^{2}"); | |
1364 | fhLam1ETRD->SetXTitle("E (GeV)"); | |
1365 | outputContainer->Add(fhLam1ETRD); | |
1366 | ||
1367 | fhDispETRD = new TH2F ("hDispETRD"," dispersion^{2} vs E, EMCAL SM covered by TRD", nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
1368 | fhDispETRD->SetYTitle("Dispersion^{2}"); | |
1369 | fhDispETRD->SetXTitle("E (GeV) "); | |
b5dbb99b | 1370 | outputContainer->Add(fhDispETRD); |
1371 | ||
1372 | if(!fRejectTrackMatch) | |
1373 | { | |
1374 | fhLam0ETMTRD = new TH2F ("hLam0ETMTRD","#lambda_{0}^{2} vs E, EMCAL SM covered by TRD, cut on track-matching residual |#Delta #eta| < 0.05, |#Delta #phi| < 0.05", nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
1375 | fhLam0ETMTRD->SetYTitle("#lambda_{0}^{2}"); | |
1376 | fhLam0ETMTRD->SetXTitle("E (GeV)"); | |
1377 | outputContainer->Add(fhLam0ETMTRD); | |
1378 | ||
1379 | fhLam1ETMTRD = new TH2F ("hLam1ETMTRD","#lambda_{1}^{2} vs E, EMCAL SM covered by TRD, cut on track-matching residual |#Delta #eta| < 0.05, |#Delta #phi| < 0.05", nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
1380 | fhLam1ETMTRD->SetYTitle("#lambda_{1}^{2}"); | |
1381 | fhLam1ETMTRD->SetXTitle("E (GeV)"); | |
1382 | outputContainer->Add(fhLam1ETMTRD); | |
1383 | ||
1384 | fhDispETMTRD = new TH2F ("hDispETMTRD"," dispersion^{2} vs E, EMCAL SM covered by TRD, cut on track-matching residual |#Delta #eta| < 0.05, |#Delta #phi| < 0.05", nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
1385 | fhDispETMTRD->SetYTitle("Dispersion^{2}"); | |
1386 | fhDispETMTRD->SetXTitle("E (GeV) "); | |
1387 | outputContainer->Add(fhDispETMTRD); | |
1388 | } | |
521636d2 | 1389 | } |
1390 | ||
764ab1f4 | 1391 | if(!fFillOnlySimpleSSHisto) |
34c16486 | 1392 | { |
764ab1f4 | 1393 | fhNCellsLam0LowE = new TH2F ("hNCellsLam0LowE","N_{cells} in cluster vs #lambda_{0}^{2}, E < 2 GeV", nbins,nmin, nmax, ssbins,ssmin,ssmax); |
1394 | fhNCellsLam0LowE->SetXTitle("N_{cells}"); | |
1395 | fhNCellsLam0LowE->SetYTitle("#lambda_{0}^{2}"); | |
1396 | outputContainer->Add(fhNCellsLam0LowE); | |
1397 | ||
1398 | fhNCellsLam0HighE = new TH2F ("hNCellsLam0HighE","N_{cells} in cluster vs #lambda_{0}^{2}, E > 2 GeV", nbins,nmin, nmax, ssbins,ssmin,ssmax); | |
1399 | fhNCellsLam0HighE->SetXTitle("N_{cells}"); | |
1400 | fhNCellsLam0HighE->SetYTitle("#lambda_{0}^{2}"); | |
1401 | outputContainer->Add(fhNCellsLam0HighE); | |
1402 | ||
1403 | fhNCellsLam1LowE = new TH2F ("hNCellsLam1LowE","N_{cells} in cluster vs #lambda_{1}^{2}, E < 2 GeV", nbins,nmin, nmax, ssbins,ssmin,ssmax); | |
1404 | fhNCellsLam1LowE->SetXTitle("N_{cells}"); | |
1405 | fhNCellsLam1LowE->SetYTitle("#lambda_{0}^{2}"); | |
1406 | outputContainer->Add(fhNCellsLam1LowE); | |
1407 | ||
1408 | fhNCellsLam1HighE = new TH2F ("hNCellsLam1HighE","N_{cells} in cluster vs #lambda_{1}^{2}, E > 2 GeV", nbins,nmin, nmax, ssbins,ssmin,ssmax); | |
1409 | fhNCellsLam1HighE->SetXTitle("N_{cells}"); | |
1410 | fhNCellsLam1HighE->SetYTitle("#lambda_{0}^{2}"); | |
1411 | outputContainer->Add(fhNCellsLam1HighE); | |
1412 | ||
1413 | fhNCellsDispLowE = new TH2F ("hNCellsDispLowE","N_{cells} in cluster vs dispersion^{2}, E < 2 GeV", nbins,nmin, nmax, ssbins,ssmin,ssmax); | |
1414 | fhNCellsDispLowE->SetXTitle("N_{cells}"); | |
1415 | fhNCellsDispLowE->SetYTitle("D^{2}"); | |
1416 | outputContainer->Add(fhNCellsDispLowE); | |
1417 | ||
1418 | fhNCellsDispHighE = new TH2F ("hNCellsDispHighE","N_{cells} in cluster vs dispersion^{2}, E < 2 GeV", nbins,nmin, nmax, ssbins,ssmin,ssmax); | |
1419 | fhNCellsDispHighE->SetXTitle("N_{cells}"); | |
1420 | fhNCellsDispHighE->SetYTitle("D^{2}"); | |
1421 | outputContainer->Add(fhNCellsDispHighE); | |
1422 | ||
1423 | fhEtaLam0LowE = new TH2F ("hEtaLam0LowE","#eta vs #lambda_{0}^{2}, E < 2 GeV", netabins,etamin,etamax, ssbins,ssmin,ssmax); | |
1424 | fhEtaLam0LowE->SetYTitle("#lambda_{0}^{2}"); | |
1425 | fhEtaLam0LowE->SetXTitle("#eta"); | |
1426 | outputContainer->Add(fhEtaLam0LowE); | |
1427 | ||
1428 | fhPhiLam0LowE = new TH2F ("hPhiLam0LowE","#phi vs #lambda_{0}^{2}, E < 2 GeV", nphibins,phimin,phimax, ssbins,ssmin,ssmax); | |
1429 | fhPhiLam0LowE->SetYTitle("#lambda_{0}^{2}"); | |
1430 | fhPhiLam0LowE->SetXTitle("#phi"); | |
1431 | outputContainer->Add(fhPhiLam0LowE); | |
1432 | ||
1433 | fhEtaLam0HighE = new TH2F ("hEtaLam0HighE","#eta vs #lambda_{0}^{2}, E > 2 GeV", netabins,etamin,etamax, ssbins,ssmin,ssmax); | |
1434 | fhEtaLam0HighE->SetYTitle("#lambda_{0}^{2}"); | |
1435 | fhEtaLam0HighE->SetXTitle("#eta"); | |
1436 | outputContainer->Add(fhEtaLam0HighE); | |
1437 | ||
1438 | fhPhiLam0HighE = new TH2F ("hPhiLam0HighE","#phi vs #lambda_{0}^{2}, E > 2 GeV", nphibins,phimin,phimax, ssbins,ssmin,ssmax); | |
1439 | fhPhiLam0HighE->SetYTitle("#lambda_{0}^{2}"); | |
1440 | fhPhiLam0HighE->SetXTitle("#phi"); | |
1441 | outputContainer->Add(fhPhiLam0HighE); | |
1442 | ||
1443 | fhLam1Lam0LowE = new TH2F ("hLam1Lam0LowE","#lambda_{0}^{2} vs #lambda_{1}^{2} in cluster of E < 2 GeV", ssbins,ssmin,ssmax, ssbins,ssmin,ssmax); | |
1444 | fhLam1Lam0LowE->SetYTitle("#lambda_{0}^{2}"); | |
1445 | fhLam1Lam0LowE->SetXTitle("#lambda_{1}^{2}"); | |
1446 | outputContainer->Add(fhLam1Lam0LowE); | |
1447 | ||
1448 | fhLam1Lam0HighE = new TH2F ("hLam1Lam0HighE","#lambda_{0}^{2} vs #lambda_{1}^{2} in cluster of E > 2 GeV", ssbins,ssmin,ssmax, ssbins,ssmin,ssmax); | |
1449 | fhLam1Lam0HighE->SetYTitle("#lambda_{0}^{2}"); | |
1450 | fhLam1Lam0HighE->SetXTitle("#lambda_{1}^{2}"); | |
1451 | outputContainer->Add(fhLam1Lam0HighE); | |
1452 | ||
1453 | fhLam0DispLowE = new TH2F ("hLam0DispLowE","#lambda_{0}^{2} vs dispersion^{2} in cluster of E < 2 GeV", ssbins,ssmin,ssmax, ssbins,ssmin,ssmax); | |
1454 | fhLam0DispLowE->SetXTitle("#lambda_{0}^{2}"); | |
1455 | fhLam0DispLowE->SetYTitle("D^{2}"); | |
1456 | outputContainer->Add(fhLam0DispLowE); | |
1457 | ||
1458 | fhLam0DispHighE = new TH2F ("hLam0DispHighE","#lambda_{0}^{2} vs dispersion^{2} in cluster of E > 2 GeV", ssbins,ssmin,ssmax, ssbins,ssmin,ssmax); | |
1459 | fhLam0DispHighE->SetXTitle("#lambda_{0}^{2}"); | |
1460 | fhLam0DispHighE->SetYTitle("D^{2}"); | |
1461 | outputContainer->Add(fhLam0DispHighE); | |
1462 | ||
1463 | fhDispLam1LowE = new TH2F ("hDispLam1LowE","Dispersion^{2} vs #lambda_{1}^{2} in cluster of E < 2 GeV", ssbins,ssmin,ssmax, ssbins,ssmin,ssmax); | |
1464 | fhDispLam1LowE->SetXTitle("D^{2}"); | |
1465 | fhDispLam1LowE->SetYTitle("#lambda_{1}^{2}"); | |
1466 | outputContainer->Add(fhDispLam1LowE); | |
1467 | ||
1468 | fhDispLam1HighE = new TH2F ("hDispLam1HighE","Dispersion^{2} vs #lambda_{1^{2}} in cluster of E > 2 GeV", ssbins,ssmin,ssmax, ssbins,ssmin,ssmax); | |
1469 | fhDispLam1HighE->SetXTitle("D^{2}"); | |
1470 | fhDispLam1HighE->SetYTitle("#lambda_{1}^{2}"); | |
1471 | outputContainer->Add(fhDispLam1HighE); | |
1472 | ||
1473 | if(fCalorimeter == "EMCAL") | |
34c16486 | 1474 | { |
764ab1f4 | 1475 | fhDispEtaE = new TH2F ("hDispEtaE","#sigma^{2}_{#eta #eta} = #Sigma w_{i}(#eta_{i} - <#eta>)^{2}/ #Sigma w_{i} vs E", nptbins,ptmin,ptmax, ssbins,ssmin,ssmax); |
1476 | fhDispEtaE->SetXTitle("E (GeV)"); | |
1477 | fhDispEtaE->SetYTitle("#sigma^{2}_{#eta #eta}"); | |
1478 | outputContainer->Add(fhDispEtaE); | |
1479 | ||
1480 | fhDispPhiE = new TH2F ("hDispPhiE","#sigma^{2}_{#phi #phi} = #Sigma w_{i}(#phi_{i} - <#phi>)^{2} / #Sigma w_{i} vs E", nptbins,ptmin,ptmax, ssbins,ssmin,ssmax); | |
1481 | fhDispPhiE->SetXTitle("E (GeV)"); | |
1482 | fhDispPhiE->SetYTitle("#sigma^{2}_{#phi #phi}"); | |
1483 | outputContainer->Add(fhDispPhiE); | |
1484 | ||
1485 | fhSumEtaE = new TH2F ("hSumEtaE","#delta^{2}_{#eta #eta} = #Sigma w_{i}(#eta_{i})^{2} / #Sigma w_{i} - <#eta>^{2} vs E", nptbins,ptmin,ptmax, ssbins,ssmin,ssmax); | |
1486 | fhSumEtaE->SetXTitle("E (GeV)"); | |
1487 | fhSumEtaE->SetYTitle("#delta^{2}_{#eta #eta}"); | |
1488 | outputContainer->Add(fhSumEtaE); | |
1489 | ||
1490 | fhSumPhiE = new TH2F ("hSumPhiE","#delta^{2}_{#phi #phi} = #Sigma w_{i}(#phi_{i})^{2}/ #Sigma w_{i} - <#phi>^{2} vs E", | |
1491 | nptbins,ptmin,ptmax, ssbins,ssmin,ssmax); | |
1492 | fhSumPhiE->SetXTitle("E (GeV)"); | |
1493 | fhSumPhiE->SetYTitle("#delta^{2}_{#phi #phi}"); | |
1494 | outputContainer->Add(fhSumPhiE); | |
1495 | ||
1496 | fhSumEtaPhiE = new TH2F ("hSumEtaPhiE","#delta^{2}_{#eta #phi} = #Sigma w_{i}(#phi_{i} #eta_{i} ) / #Sigma w_{i} - <#phi><#eta> vs E", | |
1497 | nptbins,ptmin,ptmax, 2*ssbins,-ssmax,ssmax); | |
1498 | fhSumEtaPhiE->SetXTitle("E (GeV)"); | |
1499 | fhSumEtaPhiE->SetYTitle("#delta^{2}_{#eta #phi}"); | |
1500 | outputContainer->Add(fhSumEtaPhiE); | |
1501 | ||
1502 | fhDispEtaPhiDiffE = new TH2F ("hDispEtaPhiDiffE","#sigma^{2}_{#phi #phi} - #sigma^{2}_{#eta #eta} vs E", | |
1503 | nptbins,ptmin,ptmax,200, -10,10); | |
1504 | fhDispEtaPhiDiffE->SetXTitle("E (GeV)"); | |
1505 | fhDispEtaPhiDiffE->SetYTitle("#sigma^{2}_{#phi #phi}-#sigma^{2}_{#eta #eta}"); | |
1506 | outputContainer->Add(fhDispEtaPhiDiffE); | |
bfdcf7fb | 1507 | |
764ab1f4 | 1508 | fhSphericityE = new TH2F ("hSphericityE","(#sigma^{2}_{#phi #phi} - #sigma^{2}_{#eta #eta}) / (#sigma^{2}_{#eta #eta} + #sigma^{2}_{#phi #phi}) vs E", |
1509 | nptbins,ptmin,ptmax, 200, -1,1); | |
1510 | fhSphericityE->SetXTitle("E (GeV)"); | |
1511 | fhSphericityE->SetYTitle("s = (#sigma^{2}_{#phi #phi} - #sigma^{2}_{#eta #eta}) / (#sigma^{2}_{#eta #eta} + #sigma^{2}_{#phi #phi})"); | |
1512 | outputContainer->Add(fhSphericityE); | |
bfdcf7fb | 1513 | |
764ab1f4 | 1514 | fhDispSumEtaDiffE = new TH2F ("hDispSumEtaDiffE","#sigma^{2}_{#eta #eta} - #delta^{2}_{#eta #eta} / average vs E", nptbins,ptmin,ptmax, 200,-0.01,0.01); |
1515 | fhDispSumEtaDiffE->SetXTitle("E (GeV)"); | |
1516 | fhDispSumEtaDiffE->SetYTitle("#sigma^{2}_{#eta #eta} - #delta^{2}_{#eta #eta} / average"); | |
1517 | outputContainer->Add(fhDispSumEtaDiffE); | |
1518 | ||
1519 | fhDispSumPhiDiffE = new TH2F ("hDispSumPhiDiffE","#sigma^{2}_{#phi #phi} - #delta^{2}_{#phi #phi} / average vs E", nptbins,ptmin,ptmax, 200,-0.01,0.01); | |
1520 | fhDispSumPhiDiffE->SetXTitle("E (GeV)"); | |
1521 | fhDispSumPhiDiffE->SetYTitle("#sigma^{2}_{#phi #phi} - #delta^{2}_{#phi #phi} / average"); | |
1522 | outputContainer->Add(fhDispSumPhiDiffE); | |
1523 | ||
1524 | for(Int_t i = 0; i < 7; i++) | |
1525 | { | |
1526 | fhDispEtaDispPhi[i] = new TH2F (Form("hDispEtaDispPhi_EBin%d",i),Form("#sigma^{2}_{#phi #phi} vs #sigma^{2}_{#eta #eta} for %d < E < %d GeV",bin[i],bin[i+1]), | |
1527 | ssbins,ssmin,ssmax , ssbins,ssmin,ssmax); | |
1528 | fhDispEtaDispPhi[i]->SetXTitle("#sigma^{2}_{#eta #eta}"); | |
1529 | fhDispEtaDispPhi[i]->SetYTitle("#sigma^{2}_{#phi #phi}"); | |
1530 | outputContainer->Add(fhDispEtaDispPhi[i]); | |
1531 | ||
1532 | fhLambda0DispEta[i] = new TH2F (Form("hLambda0DispEta_EBin%d",i),Form("#lambda^{2}_{0} vs #sigma^{2}_{#eta #eta} for %d < E < %d GeV",bin[i],bin[i+1]), | |
1533 | ssbins,ssmin,ssmax , ssbins,ssmin,ssmax); | |
1534 | fhLambda0DispEta[i]->SetXTitle("#lambda^{2}_{0}"); | |
1535 | fhLambda0DispEta[i]->SetYTitle("#sigma^{2}_{#eta #eta}"); | |
1536 | outputContainer->Add(fhLambda0DispEta[i]); | |
1537 | ||
1538 | fhLambda0DispPhi[i] = new TH2F (Form("hLambda0DispPhi_EBin%d",i),Form("#lambda^{2}_{0}} vs #sigma^{2}_{#phi #phi} for %d < E < %d GeV",bin[i],bin[i+1]), | |
1539 | ssbins,ssmin,ssmax , ssbins,ssmin,ssmax); | |
1540 | fhLambda0DispPhi[i]->SetXTitle("#lambda^{2}_{0}"); | |
1541 | fhLambda0DispPhi[i]->SetYTitle("#sigma^{2}_{#phi #phi}"); | |
1542 | outputContainer->Add(fhLambda0DispPhi[i]); | |
1543 | } | |
34c16486 | 1544 | } |
1545 | } | |
521636d2 | 1546 | } // Shower shape |
1547 | ||
09273901 | 1548 | // Track Matching |
1549 | ||
b5dbb99b | 1550 | if(fFillTMHisto) |
1551 | { | |
4bfeae64 | 1552 | fhTrackMatchedDEta[0] = new TH2F |
1553 | ("hTrackMatchedDEtaNoCut", | |
1554 | "d#eta of cluster-track vs cluster energy, no photon cuts", | |
09273901 | 1555 | nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); |
4bfeae64 | 1556 | fhTrackMatchedDEta[0]->SetYTitle("d#eta"); |
1557 | fhTrackMatchedDEta[0]->SetXTitle("E_{cluster} (GeV)"); | |
09273901 | 1558 | |
4bfeae64 | 1559 | fhTrackMatchedDPhi[0] = new TH2F |
1560 | ("hTrackMatchedDPhiNoCut", | |
1561 | "d#phi of cluster-track vs cluster energy, no photon cuts", | |
09273901 | 1562 | nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); |
4bfeae64 | 1563 | fhTrackMatchedDPhi[0]->SetYTitle("d#phi (rad)"); |
1564 | fhTrackMatchedDPhi[0]->SetXTitle("E_{cluster} (GeV)"); | |
09273901 | 1565 | |
4bfeae64 | 1566 | fhTrackMatchedDEtaDPhi[0] = new TH2F |
1567 | ("hTrackMatchedDEtaDPhiNoCut", | |
1568 | "d#eta vs d#phi of cluster-track vs cluster energy, no photon cuts", | |
09273901 | 1569 | nresetabins,resetamin,resetamax,nresphibins,resphimin,resphimax); |
4bfeae64 | 1570 | fhTrackMatchedDEtaDPhi[0]->SetYTitle("d#phi (rad)"); |
1571 | fhTrackMatchedDEtaDPhi[0]->SetXTitle("d#eta"); | |
b5dbb99b | 1572 | |
4bfeae64 | 1573 | fhdEdx[0] = new TH2F ("hdEdxNoCut","matched track <dE/dx> vs cluster E, no photon cuts ", |
1574 | nptbins,ptmin,ptmax,ndedxbins, dedxmin, dedxmax); | |
1575 | fhdEdx[0]->SetXTitle("E (GeV)"); | |
1576 | fhdEdx[0]->SetYTitle("<dE/dx>"); | |
1577 | ||
1578 | fhEOverP[0] = new TH2F ("hEOverPNoCut","matched track E/p vs cluster E, no photon cuts ", | |
1579 | nptbins,ptmin,ptmax,nPoverEbins,pOverEmin,pOverEmax); | |
1580 | fhEOverP[0]->SetXTitle("E (GeV)"); | |
1581 | fhEOverP[0]->SetYTitle("E/p"); | |
1582 | ||
1583 | outputContainer->Add(fhTrackMatchedDEta[0]) ; | |
1584 | outputContainer->Add(fhTrackMatchedDPhi[0]) ; | |
1585 | outputContainer->Add(fhTrackMatchedDEtaDPhi[0]) ; | |
1586 | outputContainer->Add(fhdEdx[0]); | |
1587 | outputContainer->Add(fhEOverP[0]); | |
1588 | ||
1589 | fhTrackMatchedDEta[1] = new TH2F | |
1590 | ("hTrackMatchedDEta", | |
09273901 | 1591 | "d#eta of cluster-track vs cluster energy, no photon cuts", |
1592 | nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); | |
4bfeae64 | 1593 | fhTrackMatchedDEta[1]->SetYTitle("d#eta"); |
1594 | fhTrackMatchedDEta[1]->SetXTitle("E_{cluster} (GeV)"); | |
09273901 | 1595 | |
4bfeae64 | 1596 | fhTrackMatchedDPhi[1] = new TH2F |
1597 | ("hTrackMatchedDPhi", | |
09273901 | 1598 | "d#phi of cluster-track vs cluster energy, no photon cuts", |
1599 | nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); | |
4bfeae64 | 1600 | fhTrackMatchedDPhi[1]->SetYTitle("d#phi (rad)"); |
1601 | fhTrackMatchedDPhi[1]->SetXTitle("E_{cluster} (GeV)"); | |
09273901 | 1602 | |
4bfeae64 | 1603 | fhTrackMatchedDEtaDPhi[1] = new TH2F |
1604 | ("hTrackMatchedDEtaDPhi", | |
09273901 | 1605 | "d#eta vs d#phi of cluster-track vs cluster energy, no photon cuts", |
1606 | nresetabins,resetamin,resetamax,nresphibins,resphimin,resphimax); | |
4bfeae64 | 1607 | fhTrackMatchedDEtaDPhi[1]->SetYTitle("d#phi (rad)"); |
1608 | fhTrackMatchedDEtaDPhi[1]->SetXTitle("d#eta"); | |
09273901 | 1609 | |
4bfeae64 | 1610 | fhdEdx[1] = new TH2F ("hdEdx","matched track <dE/dx> vs cluster E ", |
1611 | nptbins,ptmin,ptmax,ndedxbins, dedxmin, dedxmax); | |
1612 | fhdEdx[1]->SetXTitle("E (GeV)"); | |
1613 | fhdEdx[1]->SetYTitle("<dE/dx>"); | |
1614 | ||
1615 | fhEOverP[1] = new TH2F ("hEOverP","matched track E/p vs cluster E ", | |
1616 | nptbins,ptmin,ptmax,nPoverEbins,pOverEmin,pOverEmax); | |
1617 | fhEOverP[1]->SetXTitle("E (GeV)"); | |
1618 | fhEOverP[1]->SetYTitle("E/p"); | |
1619 | ||
1620 | outputContainer->Add(fhTrackMatchedDEta[1]) ; | |
1621 | outputContainer->Add(fhTrackMatchedDPhi[1]) ; | |
1622 | outputContainer->Add(fhTrackMatchedDEtaDPhi[1]) ; | |
1623 | outputContainer->Add(fhdEdx[1]); | |
1624 | outputContainer->Add(fhEOverP[1]); | |
31ae6d59 | 1625 | |
b5dbb99b | 1626 | if(fCalorimeter=="EMCAL") |
1627 | { | |
4bfeae64 | 1628 | fhTrackMatchedDEtaTRD[0] = new TH2F |
b5dbb99b | 1629 | ("hTrackMatchedDEtaTRDNoCut", |
1630 | "d#eta of cluster-track vs cluster energy, SM behind TRD, no photon cuts", | |
1631 | nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); | |
4bfeae64 | 1632 | fhTrackMatchedDEtaTRD[0]->SetYTitle("d#eta"); |
1633 | fhTrackMatchedDEtaTRD[0]->SetXTitle("E_{cluster} (GeV)"); | |
b5dbb99b | 1634 | |
4bfeae64 | 1635 | fhTrackMatchedDPhiTRD[0] = new TH2F |
b5dbb99b | 1636 | ("hTrackMatchedDPhiTRDNoCut", |
1637 | "d#phi of cluster-track vs cluster energy, SM behing TRD, no photon cuts", | |
1638 | nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); | |
4bfeae64 | 1639 | fhTrackMatchedDPhiTRD[0]->SetYTitle("d#phi (rad)"); |
1640 | fhTrackMatchedDPhiTRD[0]->SetXTitle("E_{cluster} (GeV)"); | |
b5dbb99b | 1641 | |
4bfeae64 | 1642 | fhEOverPTRD[0] = new TH2F ("hEOverPTRDNoCut","matched track E/p vs cluster E, behind TRD, no photon cuts ", |
1643 | nptbins,ptmin,ptmax,nPoverEbins,pOverEmin,pOverEmax); | |
1644 | fhEOverPTRD[0]->SetXTitle("E (GeV)"); | |
1645 | fhEOverPTRD[0]->SetYTitle("E/p"); | |
1646 | ||
1647 | outputContainer->Add(fhTrackMatchedDEtaTRD[0]) ; | |
1648 | outputContainer->Add(fhTrackMatchedDPhiTRD[0]) ; | |
1649 | outputContainer->Add(fhEOverPTRD[0]); | |
b5dbb99b | 1650 | |
4bfeae64 | 1651 | fhTrackMatchedDEtaTRD[1] = new TH2F |
1652 | ("hTrackMatchedDEtaTRD", | |
1653 | "d#eta of cluster-track vs cluster energy, SM behind TRD", | |
1654 | nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); | |
1655 | fhTrackMatchedDEtaTRD[1]->SetYTitle("d#eta"); | |
1656 | fhTrackMatchedDEtaTRD[1]->SetXTitle("E_{cluster} (GeV)"); | |
1657 | ||
1658 | fhTrackMatchedDPhiTRD[1] = new TH2F | |
1659 | ("hTrackMatchedDPhiTRD", | |
1660 | "d#phi of cluster-track vs cluster energy, SM behing TRD", | |
1661 | nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); | |
1662 | fhTrackMatchedDPhiTRD[1]->SetYTitle("d#phi (rad)"); | |
1663 | fhTrackMatchedDPhiTRD[1]->SetXTitle("E_{cluster} (GeV)"); | |
1664 | ||
1665 | fhEOverPTRD[1] = new TH2F ("hEOverPTRD","matched track E/p vs cluster E, behind TRD ", | |
1666 | nptbins,ptmin,ptmax,nPoverEbins,pOverEmin,pOverEmax); | |
1667 | fhEOverPTRD[1]->SetXTitle("E (GeV)"); | |
1668 | fhEOverPTRD[1]->SetYTitle("E/p"); | |
1669 | ||
1670 | outputContainer->Add(fhTrackMatchedDEtaTRD[1]) ; | |
1671 | outputContainer->Add(fhTrackMatchedDPhiTRD[1]) ; | |
1672 | outputContainer->Add(fhEOverPTRD[1]); | |
b5dbb99b | 1673 | |
1674 | } | |
1675 | ||
31ae6d59 | 1676 | if(IsDataMC()) |
1677 | { | |
4bfeae64 | 1678 | fhTrackMatchedDEtaMCNoOverlap[0] = new TH2F |
1679 | ("hTrackMatchedDEtaMCNoOverlapNoCut", | |
1680 | "d#eta of cluster-track vs cluster energy, no other MC particles overlap", | |
1681 | nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); | |
1682 | fhTrackMatchedDEtaMCNoOverlap[0]->SetYTitle("d#eta"); | |
1683 | fhTrackMatchedDEtaMCNoOverlap[0]->SetXTitle("E_{cluster} (GeV)"); | |
1684 | ||
1685 | fhTrackMatchedDPhiMCNoOverlap[0] = new TH2F | |
1686 | ("hTrackMatchedDPhiMCNoOverlapNoCut", | |
1687 | "d#phi of cluster-track vs cluster energy, no other MC particles overlap", | |
1688 | nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); | |
1689 | fhTrackMatchedDPhiMCNoOverlap[0]->SetYTitle("d#phi (rad)"); | |
1690 | fhTrackMatchedDPhiMCNoOverlap[0]->SetXTitle("E_{cluster} (GeV)"); | |
1691 | ||
1692 | outputContainer->Add(fhTrackMatchedDEtaMCNoOverlap[0]) ; | |
1693 | outputContainer->Add(fhTrackMatchedDPhiMCNoOverlap[0]) ; | |
1694 | ||
1695 | fhTrackMatchedDEtaMCNoOverlap[1] = new TH2F | |
8d6b7f60 | 1696 | ("hTrackMatchedDEtaMCNoOverlap", |
1697 | "d#eta of cluster-track vs cluster energy, no other MC particles overlap", | |
1698 | nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); | |
4bfeae64 | 1699 | fhTrackMatchedDEtaMCNoOverlap[1]->SetYTitle("d#eta"); |
1700 | fhTrackMatchedDEtaMCNoOverlap[1]->SetXTitle("E_{cluster} (GeV)"); | |
8d6b7f60 | 1701 | |
4bfeae64 | 1702 | fhTrackMatchedDPhiMCNoOverlap[1] = new TH2F |
8d6b7f60 | 1703 | ("hTrackMatchedDPhiMCNoOverlap", |
1704 | "d#phi of cluster-track vs cluster energy, no other MC particles overlap", | |
1705 | nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); | |
4bfeae64 | 1706 | fhTrackMatchedDPhiMCNoOverlap[1]->SetYTitle("d#phi (rad)"); |
1707 | fhTrackMatchedDPhiMCNoOverlap[1]->SetXTitle("E_{cluster} (GeV)"); | |
1708 | ||
1709 | outputContainer->Add(fhTrackMatchedDEtaMCNoOverlap[1]) ; | |
1710 | outputContainer->Add(fhTrackMatchedDPhiMCNoOverlap[1]) ; | |
1711 | ||
1712 | fhTrackMatchedDEtaMCOverlap[0] = new TH2F | |
1713 | ("hTrackMatchedDEtaMCOverlapNoCut", | |
1714 | "d#eta of cluster-track vs cluster energy, several MC particles overlap", | |
1715 | nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); | |
1716 | fhTrackMatchedDEtaMCOverlap[0]->SetYTitle("d#eta"); | |
1717 | fhTrackMatchedDEtaMCOverlap[0]->SetXTitle("E_{cluster} (GeV)"); | |
1718 | ||
1719 | fhTrackMatchedDPhiMCOverlap[0] = new TH2F | |
1720 | ("hTrackMatchedDPhiMCOverlapNoCut", | |
1721 | "d#phi of cluster-track vs cluster energy, several MC particles overlap", | |
1722 | nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); | |
1723 | fhTrackMatchedDPhiMCOverlap[0]->SetYTitle("d#phi (rad)"); | |
1724 | fhTrackMatchedDPhiMCOverlap[0]->SetXTitle("E_{cluster} (GeV)"); | |
8d6b7f60 | 1725 | |
4bfeae64 | 1726 | outputContainer->Add(fhTrackMatchedDEtaMCOverlap[0]) ; |
1727 | outputContainer->Add(fhTrackMatchedDPhiMCOverlap[0]) ; | |
8d6b7f60 | 1728 | |
4bfeae64 | 1729 | fhTrackMatchedDEtaMCOverlap[1] = new TH2F |
8d6b7f60 | 1730 | ("hTrackMatchedDEtaMCOverlap", |
1731 | "d#eta of cluster-track vs cluster energy, several MC particles overlap", | |
1732 | nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); | |
4bfeae64 | 1733 | fhTrackMatchedDEtaMCOverlap[1]->SetYTitle("d#eta"); |
1734 | fhTrackMatchedDEtaMCOverlap[1]->SetXTitle("E_{cluster} (GeV)"); | |
8d6b7f60 | 1735 | |
4bfeae64 | 1736 | fhTrackMatchedDPhiMCOverlap[1] = new TH2F |
8d6b7f60 | 1737 | ("hTrackMatchedDPhiMCOverlap", |
1738 | "d#phi of cluster-track vs cluster energy, several MC particles overlap", | |
1739 | nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); | |
4bfeae64 | 1740 | fhTrackMatchedDPhiMCOverlap[1]->SetYTitle("d#phi (rad)"); |
1741 | fhTrackMatchedDPhiMCOverlap[1]->SetXTitle("E_{cluster} (GeV)"); | |
1742 | ||
1743 | outputContainer->Add(fhTrackMatchedDEtaMCOverlap[1]) ; | |
1744 | outputContainer->Add(fhTrackMatchedDPhiMCOverlap[1]) ; | |
1745 | ||
1746 | fhTrackMatchedDEtaMCConversion[0] = new TH2F | |
1747 | ("hTrackMatchedDEtaMCConversionNoCut", | |
1748 | "d#eta of cluster-track vs cluster energy, no other MC particles overlap appart from conversions", | |
1749 | nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); | |
1750 | fhTrackMatchedDEtaMCConversion[0]->SetYTitle("d#eta"); | |
1751 | fhTrackMatchedDEtaMCConversion[0]->SetXTitle("E_{cluster} (GeV)"); | |
8d6b7f60 | 1752 | |
4bfeae64 | 1753 | fhTrackMatchedDPhiMCConversion[0] = new TH2F |
1754 | ("hTrackMatchedDPhiMCConversionNoCut", | |
1755 | "d#phi of cluster-track vs cluster energy, no other MC particles overlap appart from conversions", | |
1756 | nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); | |
1757 | fhTrackMatchedDPhiMCConversion[0]->SetYTitle("d#phi (rad)"); | |
1758 | fhTrackMatchedDPhiMCConversion[0]->SetXTitle("E_{cluster} (GeV)"); | |
8d6b7f60 | 1759 | |
4bfeae64 | 1760 | outputContainer->Add(fhTrackMatchedDEtaMCConversion[0]) ; |
1761 | outputContainer->Add(fhTrackMatchedDPhiMCConversion[0]) ; | |
1762 | ||
8d6b7f60 | 1763 | |
4bfeae64 | 1764 | fhTrackMatchedDEtaMCConversion[1] = new TH2F |
b5dbb99b | 1765 | ("hTrackMatchedDEtaMCConversion", |
4bfeae64 | 1766 | "d#eta of cluster-track vs cluster energy, no other MC particles overlap appart from conversions", |
8d6b7f60 | 1767 | nptbins,ptmin,ptmax,nresetabins,resetamin,resetamax); |
4bfeae64 | 1768 | fhTrackMatchedDEtaMCConversion[1]->SetYTitle("d#eta"); |
1769 | fhTrackMatchedDEtaMCConversion[1]->SetXTitle("E_{cluster} (GeV)"); | |
8d6b7f60 | 1770 | |
4bfeae64 | 1771 | fhTrackMatchedDPhiMCConversion[1] = new TH2F |
b5dbb99b | 1772 | ("hTrackMatchedDPhiMCConversion", |
8d6b7f60 | 1773 | "d#phi of cluster-track vs cluster energy, no other MC particles overlap appart from conversions", |
1774 | nptbins,ptmin,ptmax,nresphibins,resphimin,resphimax); | |
4bfeae64 | 1775 | fhTrackMatchedDPhiMCConversion[1]->SetYTitle("d#phi (rad)"); |
1776 | fhTrackMatchedDPhiMCConversion[1]->SetXTitle("E_{cluster} (GeV)"); | |
8d6b7f60 | 1777 | |
4bfeae64 | 1778 | outputContainer->Add(fhTrackMatchedDEtaMCConversion[1]) ; |
1779 | outputContainer->Add(fhTrackMatchedDPhiMCConversion[1]) ; | |
8d6b7f60 | 1780 | |
31ae6d59 | 1781 | |
4bfeae64 | 1782 | fhTrackMatchedMCParticle[0] = new TH2F |
31ae6d59 | 1783 | ("hTrackMatchedMCParticleNoCut", |
1784 | "Origin of particle vs energy", | |
1785 | nptbins,ptmin,ptmax,8,0,8); | |
4bfeae64 | 1786 | fhTrackMatchedMCParticle[0]->SetXTitle("E (GeV)"); |
1787 | //fhTrackMatchedMCParticle[0]->SetYTitle("Particle type"); | |
1788 | ||
1789 | fhTrackMatchedMCParticle[0]->GetYaxis()->SetBinLabel(1 ,"Photon"); | |
1790 | fhTrackMatchedMCParticle[0]->GetYaxis()->SetBinLabel(2 ,"Electron"); | |
1791 | fhTrackMatchedMCParticle[0]->GetYaxis()->SetBinLabel(3 ,"Meson Merged"); | |
1792 | fhTrackMatchedMCParticle[0]->GetYaxis()->SetBinLabel(4 ,"Rest"); | |
1793 | fhTrackMatchedMCParticle[0]->GetYaxis()->SetBinLabel(5 ,"Conv. Photon"); | |
1794 | fhTrackMatchedMCParticle[0]->GetYaxis()->SetBinLabel(6 ,"Conv. Electron"); | |
1795 | fhTrackMatchedMCParticle[0]->GetYaxis()->SetBinLabel(7 ,"Conv. Merged"); | |
1796 | fhTrackMatchedMCParticle[0]->GetYaxis()->SetBinLabel(8 ,"Conv. Rest"); | |
1797 | ||
1798 | fhTrackMatchedMCParticle[1] = new TH2F | |
1799 | ("hTrackMatchedMCParticle", | |
1800 | "Origin of particle vs energy", | |
1801 | nptbins,ptmin,ptmax,8,0,8); | |
1802 | fhTrackMatchedMCParticle[1]->SetXTitle("E (GeV)"); | |
1803 | //fhTrackMatchedMCParticle[1]->SetYTitle("Particle type"); | |
31ae6d59 | 1804 | |
4bfeae64 | 1805 | fhTrackMatchedMCParticle[1]->GetYaxis()->SetBinLabel(1 ,"Photon"); |
1806 | fhTrackMatchedMCParticle[1]->GetYaxis()->SetBinLabel(2 ,"Electron"); | |
1807 | fhTrackMatchedMCParticle[1]->GetYaxis()->SetBinLabel(3 ,"Meson Merged"); | |
1808 | fhTrackMatchedMCParticle[1]->GetYaxis()->SetBinLabel(4 ,"Rest"); | |
1809 | fhTrackMatchedMCParticle[1]->GetYaxis()->SetBinLabel(5 ,"Conv. Photon"); | |
1810 | fhTrackMatchedMCParticle[1]->GetYaxis()->SetBinLabel(6 ,"Conv. Electron"); | |
1811 | fhTrackMatchedMCParticle[1]->GetYaxis()->SetBinLabel(7 ,"Conv. Merged"); | |
1812 | fhTrackMatchedMCParticle[1]->GetYaxis()->SetBinLabel(8 ,"Conv. Rest"); | |
31ae6d59 | 1813 | |
4bfeae64 | 1814 | outputContainer->Add(fhTrackMatchedMCParticle[0]); |
1815 | outputContainer->Add(fhTrackMatchedMCParticle[1]); | |
8d6b7f60 | 1816 | |
31ae6d59 | 1817 | } |
09273901 | 1818 | } |
1819 | ||
2ad19c3d | 1820 | if(fFillPileUpHistograms) |
1821 | { | |
1822 | fhTimeENoCut = new TH2F ("hTimeE_NoCut","time of cluster vs E of clusters, no cut", nptbins,ptmin,ptmax, ntimebins,timemin,timemax); | |
1823 | fhTimeENoCut->SetXTitle("E (GeV)"); | |
1824 | fhTimeENoCut->SetYTitle("time (ns)"); | |
1825 | outputContainer->Add(fhTimeENoCut); | |
1826 | ||
1827 | fhTimeESPD = new TH2F ("hTimeE_SPD","time of cluster vs E of clusters, SPD cut", nptbins,ptmin,ptmax, ntimebins,timemin,timemax); | |
1828 | fhTimeESPD->SetXTitle("E (GeV)"); | |
1829 | fhTimeESPD->SetYTitle("time (ns)"); | |
1830 | outputContainer->Add(fhTimeESPD); | |
1831 | ||
1832 | fhTimeESPDMulti = new TH2F ("hTimeE_SPDMulti","time of cluster vs E of clusters, SPD multi cut", nptbins,ptmin,ptmax, ntimebins,timemin,timemax); | |
1833 | fhTimeESPDMulti->SetXTitle("E (GeV)"); | |
1834 | fhTimeESPDMulti->SetYTitle("time (ns)"); | |
1835 | outputContainer->Add(fhTimeESPDMulti); | |
1836 | ||
1837 | fhTimeNPileUpVertSPD = new TH2F ("hTime_NPileUpVertSPD","time of cluster vs N pile-up SPD vertex", ntimebins,timemin,timemax,50,0,50); | |
1838 | fhTimeNPileUpVertSPD->SetYTitle("# vertex "); | |
1839 | fhTimeNPileUpVertSPD->SetXTitle("time (ns)"); | |
1840 | outputContainer->Add(fhTimeNPileUpVertSPD); | |
1841 | ||
1842 | fhTimeNPileUpVertTrack = new TH2F ("hTime_NPileUpVertTracks","time of cluster vs N pile-up Tracks vertex", ntimebins,timemin,timemax, 50,0,50 ); | |
1843 | fhTimeNPileUpVertTrack->SetYTitle("# vertex "); | |
1844 | fhTimeNPileUpVertTrack->SetXTitle("time (ns)"); | |
1845 | outputContainer->Add(fhTimeNPileUpVertTrack); | |
1846 | ||
1847 | fhTimeNPileUpVertContributors = new TH2F ("hTime_NPileUpVertContributors","time of cluster vs N constributors to pile-up SPD vertex", ntimebins,timemin,timemax,50,0,50); | |
1848 | fhTimeNPileUpVertContributors->SetYTitle("# vertex "); | |
1849 | fhTimeNPileUpVertContributors->SetXTitle("time (ns)"); | |
1850 | outputContainer->Add(fhTimeNPileUpVertContributors); | |
1851 | ||
1852 | fhTimePileUpMainVertexZDistance = new TH2F ("hTime_PileUpMainVertexZDistance","time of cluster vs distance in Z pile-up SPD vertex - main SPD vertex",ntimebins,timemin,timemax,100,0,50); | |
1853 | fhTimePileUpMainVertexZDistance->SetYTitle("distance Z (cm) "); | |
1854 | fhTimePileUpMainVertexZDistance->SetXTitle("time (ns)"); | |
1855 | outputContainer->Add(fhTimePileUpMainVertexZDistance); | |
1856 | ||
1857 | fhTimePileUpMainVertexZDiamond = new TH2F ("hTime_PileUpMainVertexZDiamond","time of cluster vs distance in Z pile-up SPD vertex - z diamond",ntimebins,timemin,timemax,100,0,50); | |
1858 | fhTimePileUpMainVertexZDiamond->SetYTitle("diamond distance Z (cm) "); | |
1859 | fhTimePileUpMainVertexZDiamond->SetXTitle("time (ns)"); | |
acd56ca4 | 1860 | outputContainer->Add(fhTimePileUpMainVertexZDiamond); |
1861 | ||
1862 | TString title[] = {"no |t diff| cut","|t diff|<20 ns","|t diff|>20 ns","|t diff|>40 ns"}; | |
1863 | TString name [] = {"TDiffNoCut","TDiffSmaller20ns","TDiffLarger20ns","TDiffLarger40ns"}; | |
1864 | for(Int_t i = 0; i < 4; i++) | |
1865 | { | |
1866 | fhClusterMultSPDPileUp[i] = new TH2F(Form("fhClusterMultSPDPileUp_%s", name[i].Data()), | |
1867 | Form("Number of clusters per pile up event with E > 0.5 and %s respect cluster max vs cluster max E ",title[i].Data()), | |
1868 | nptbins,ptmin,ptmax,100,0,100); | |
1869 | fhClusterMultSPDPileUp[i]->SetYTitle("n clusters "); | |
1870 | fhClusterMultSPDPileUp[i]->SetXTitle("E_{cluster max} (GeV)"); | |
1871 | outputContainer->Add(fhClusterMultSPDPileUp[i]) ; | |
1872 | ||
1873 | fhClusterMultNoPileUp[i] = new TH2F(Form("fhClusterMultNoPileUp_%s", name[i].Data()), | |
1874 | Form("Number of clusters per non pile up event with E > 0.5 and %s respect cluster max vs cluster max E ",title[i].Data()), | |
1875 | nptbins,ptmin,ptmax,100,0,100); | |
1876 | fhClusterMultNoPileUp[i]->SetYTitle("n clusters "); | |
1877 | fhClusterMultNoPileUp[i]->SetXTitle("E_{cluster max} (GeV)"); | |
1878 | outputContainer->Add(fhClusterMultNoPileUp[i]) ; | |
1879 | } | |
2ad19c3d | 1880 | |
1881 | } | |
1882 | ||
34c16486 | 1883 | if(IsDataMC()) |
1884 | { | |
f66d95af | 1885 | TString ptype[] = { "#gamma", "#gamma_{#pi decay}","#gamma_{other decay}", "#pi^{0}","#eta", |
1886 | "e^{#pm}","#gamma->e^{#pm}","hadron?","Anti-N","Anti-P", | |
1887 | "#gamma_{prompt}","#gamma_{fragmentation}","#gamma_{ISR}","String" } ; | |
3d5d5078 | 1888 | |
f66d95af | 1889 | TString pname[] = { "Photon","PhotonPi0Decay","PhotonOtherDecay","Pi0","Eta","Electron", |
1890 | "Conversion", "Hadron", "AntiNeutron","AntiProton", | |
1891 | "PhotonPrompt","PhotonFragmentation","PhotonISR","String" } ; | |
521636d2 | 1892 | |
34c16486 | 1893 | for(Int_t i = 0; i < fNOriginHistograms; i++) |
1894 | { | |
3d5d5078 | 1895 | fhMCE[i] = new TH1F(Form("hE_MC%s",pname[i].Data()), |
521636d2 | 1896 | Form("cluster from %s : E ",ptype[i].Data()), |
1897 | nptbins,ptmin,ptmax); | |
3d5d5078 | 1898 | fhMCE[i]->SetXTitle("E (GeV)"); |
1899 | outputContainer->Add(fhMCE[i]) ; | |
521636d2 | 1900 | |
4c8f7c2e | 1901 | fhMCPt[i] = new TH1F(Form("hPt_MC%s",pname[i].Data()), |
521636d2 | 1902 | Form("cluster from %s : p_{T} ",ptype[i].Data()), |
1903 | nptbins,ptmin,ptmax); | |
4c8f7c2e | 1904 | fhMCPt[i]->SetXTitle("p_{T} (GeV/c)"); |
1905 | outputContainer->Add(fhMCPt[i]) ; | |
521636d2 | 1906 | |
4c8f7c2e | 1907 | fhMCEta[i] = new TH2F(Form("hEta_MC%s",pname[i].Data()), |
521636d2 | 1908 | Form("cluster from %s : #eta ",ptype[i].Data()), |
1909 | nptbins,ptmin,ptmax,netabins,etamin,etamax); | |
4c8f7c2e | 1910 | fhMCEta[i]->SetYTitle("#eta"); |
1911 | fhMCEta[i]->SetXTitle("E (GeV)"); | |
1912 | outputContainer->Add(fhMCEta[i]) ; | |
521636d2 | 1913 | |
4c8f7c2e | 1914 | fhMCPhi[i] = new TH2F(Form("hPhi_MC%s",pname[i].Data()), |
521636d2 | 1915 | Form("cluster from %s : #phi ",ptype[i].Data()), |
1916 | nptbins,ptmin,ptmax,nphibins,phimin,phimax); | |
4c8f7c2e | 1917 | fhMCPhi[i]->SetYTitle("#phi (rad)"); |
1918 | fhMCPhi[i]->SetXTitle("E (GeV)"); | |
1919 | outputContainer->Add(fhMCPhi[i]) ; | |
1920 | ||
1921 | ||
d9105d92 | 1922 | fhMCDeltaE[i] = new TH2F (Form("hDeltaE_MC%s",pname[i].Data()), |
1923 | Form("MC - Reco E from %s",pname[i].Data()), | |
1924 | nptbins,ptmin,ptmax, 200,-50,50); | |
4c8f7c2e | 1925 | fhMCDeltaE[i]->SetXTitle("#Delta E (GeV)"); |
1926 | outputContainer->Add(fhMCDeltaE[i]); | |
1927 | ||
d9105d92 | 1928 | fhMCDeltaPt[i] = new TH2F (Form("hDeltaPt_MC%s",pname[i].Data()), |
1929 | Form("MC - Reco p_{T} from %s",pname[i].Data()), | |
1930 | nptbins,ptmin,ptmax, 200,-50,50); | |
4c8f7c2e | 1931 | fhMCDeltaPt[i]->SetXTitle("#Delta p_{T} (GeV/c)"); |
1932 | outputContainer->Add(fhMCDeltaPt[i]); | |
d9105d92 | 1933 | |
4c8f7c2e | 1934 | fhMC2E[i] = new TH2F (Form("h2E_MC%s",pname[i].Data()), |
1935 | Form("E distribution, reconstructed vs generated from %s",pname[i].Data()), | |
1936 | nptbins,ptmin,ptmax,nptbins,ptmin,ptmax); | |
1937 | fhMC2E[i]->SetXTitle("E_{rec} (GeV)"); | |
1938 | fhMC2E[i]->SetYTitle("E_{gen} (GeV)"); | |
1939 | outputContainer->Add(fhMC2E[i]); | |
1940 | ||
1941 | fhMC2Pt[i] = new TH2F (Form("h2Pt_MC%s",pname[i].Data()), | |
1942 | Form("p_T distribution, reconstructed vs generated from %s",pname[i].Data()), | |
1943 | nptbins,ptmin,ptmax,nptbins,ptmin,ptmax); | |
1944 | fhMC2Pt[i]->SetXTitle("p_{T,rec} (GeV/c)"); | |
1945 | fhMC2Pt[i]->SetYTitle("p_{T,gen} (GeV/c)"); | |
1946 | outputContainer->Add(fhMC2Pt[i]); | |
1947 | ||
521636d2 | 1948 | |
1949 | } | |
3d5d5078 | 1950 | |
f66d95af | 1951 | TString pptype[] = { "#gamma", "#gamma_{#pi decay}","#gamma_{other decay}","hadron?", |
1952 | "#gamma_{prompt}","#gamma_{fragmentation}","#gamma_{ISR}"} ; | |
1953 | ||
1954 | TString ppname[] = { "Photon","PhotonPi0Decay","PhotonOtherDecay","Hadron", | |
1955 | "PhotonPrompt","PhotonFragmentation","PhotonISR"} ; | |
1956 | ||
34c16486 | 1957 | for(Int_t i = 0; i < fNPrimaryHistograms; i++) |
1958 | { | |
f66d95af | 1959 | fhEPrimMC[i] = new TH1F(Form("hEPrim_MC%s",ppname[i].Data()), |
1960 | Form("primary photon %s : E ",pptype[i].Data()), | |
3d5d5078 | 1961 | nptbins,ptmin,ptmax); |
1962 | fhEPrimMC[i]->SetXTitle("E (GeV)"); | |
1963 | outputContainer->Add(fhEPrimMC[i]) ; | |
1964 | ||
f66d95af | 1965 | fhPtPrimMC[i] = new TH1F(Form("hPtPrim_MC%s",ppname[i].Data()), |
1966 | Form("primary photon %s : p_{T} ",pptype[i].Data()), | |
3d5d5078 | 1967 | nptbins,ptmin,ptmax); |
1968 | fhPtPrimMC[i]->SetXTitle("p_{T} (GeV/c)"); | |
1969 | outputContainer->Add(fhPtPrimMC[i]) ; | |
1970 | ||
f66d95af | 1971 | fhYPrimMC[i] = new TH2F(Form("hYPrim_MC%s",ppname[i].Data()), |
1972 | Form("primary photon %s : Rapidity ",pptype[i].Data()), | |
3d5d5078 | 1973 | nptbins,ptmin,ptmax,800,-8,8); |
1974 | fhYPrimMC[i]->SetYTitle("Rapidity"); | |
1975 | fhYPrimMC[i]->SetXTitle("E (GeV)"); | |
1976 | outputContainer->Add(fhYPrimMC[i]) ; | |
1977 | ||
f66d95af | 1978 | fhPhiPrimMC[i] = new TH2F(Form("hPhiPrim_MC%s",ppname[i].Data()), |
1979 | Form("primary photon %s : #phi ",pptype[i].Data()), | |
3d5d5078 | 1980 | nptbins,ptmin,ptmax,nphibins,phimin,phimax); |
1981 | fhPhiPrimMC[i]->SetYTitle("#phi (rad)"); | |
1982 | fhPhiPrimMC[i]->SetXTitle("E (GeV)"); | |
1983 | outputContainer->Add(fhPhiPrimMC[i]) ; | |
1984 | ||
1985 | ||
f66d95af | 1986 | fhEPrimMCAcc[i] = new TH1F(Form("hEPrimAcc_MC%s",ppname[i].Data()), |
1987 | Form("primary photon %s in acceptance: E ",pptype[i].Data()), | |
3d5d5078 | 1988 | nptbins,ptmin,ptmax); |
1989 | fhEPrimMCAcc[i]->SetXTitle("E (GeV)"); | |
1990 | outputContainer->Add(fhEPrimMCAcc[i]) ; | |
1991 | ||
f66d95af | 1992 | fhPtPrimMCAcc[i] = new TH1F(Form("hPtPrimAcc_MC%s",ppname[i].Data()), |
1993 | Form("primary photon %s in acceptance: p_{T} ",pptype[i].Data()), | |
3d5d5078 | 1994 | nptbins,ptmin,ptmax); |
1995 | fhPtPrimMCAcc[i]->SetXTitle("p_{T} (GeV/c)"); | |
1996 | outputContainer->Add(fhPtPrimMCAcc[i]) ; | |
1997 | ||
f66d95af | 1998 | fhYPrimMCAcc[i] = new TH2F(Form("hYPrimAcc_MC%s",ppname[i].Data()), |
1999 | Form("primary photon %s in acceptance: Rapidity ",pptype[i].Data()), | |
3d5d5078 | 2000 | nptbins,ptmin,ptmax,100,-1,1); |
2001 | fhYPrimMCAcc[i]->SetYTitle("Rapidity"); | |
2002 | fhYPrimMCAcc[i]->SetXTitle("E (GeV)"); | |
2003 | outputContainer->Add(fhYPrimMCAcc[i]) ; | |
2004 | ||
f66d95af | 2005 | fhPhiPrimMCAcc[i] = new TH2F(Form("hPhiPrimAcc_MC%s",ppname[i].Data()), |
2006 | Form("primary photon %s in acceptance: #phi ",pptype[i].Data()), | |
3d5d5078 | 2007 | nptbins,ptmin,ptmax,nphibins,phimin,phimax); |
2008 | fhPhiPrimMCAcc[i]->SetYTitle("#phi (rad)"); | |
2009 | fhPhiPrimMCAcc[i]->SetXTitle("E (GeV)"); | |
2010 | outputContainer->Add(fhPhiPrimMCAcc[i]) ; | |
2011 | ||
2012 | } | |
2013 | ||
34c16486 | 2014 | if(fFillSSHistograms) |
2015 | { | |
3d5d5078 | 2016 | TString ptypess[] = { "#gamma","hadron?","#pi^{0}","#eta","#gamma->e^{#pm}","e^{#pm}"} ; |
2017 | ||
2018 | TString pnamess[] = { "Photon","Hadron","Pi0","Eta","Conversion","Electron"} ; | |
2019 | ||
34c16486 | 2020 | for(Int_t i = 0; i < 6; i++) |
2021 | { | |
3d5d5078 | 2022 | fhMCELambda0[i] = new TH2F(Form("hELambda0_MC%s",pnamess[i].Data()), |
2023 | Form("cluster from %s : E vs #lambda_{0}^{2}",ptypess[i].Data()), | |
521636d2 | 2024 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); |
3d5d5078 | 2025 | fhMCELambda0[i]->SetYTitle("#lambda_{0}^{2}"); |
2026 | fhMCELambda0[i]->SetXTitle("E (GeV)"); | |
2027 | outputContainer->Add(fhMCELambda0[i]) ; | |
521636d2 | 2028 | |
3d5d5078 | 2029 | fhMCELambda1[i] = new TH2F(Form("hELambda1_MC%s",pnamess[i].Data()), |
2030 | Form("cluster from %s : E vs #lambda_{1}^{2}",ptypess[i].Data()), | |
521636d2 | 2031 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); |
3d5d5078 | 2032 | fhMCELambda1[i]->SetYTitle("#lambda_{1}^{2}"); |
2033 | fhMCELambda1[i]->SetXTitle("E (GeV)"); | |
2034 | outputContainer->Add(fhMCELambda1[i]) ; | |
34c16486 | 2035 | |
3d5d5078 | 2036 | fhMCEDispersion[i] = new TH2F(Form("hEDispersion_MC%s",pnamess[i].Data()), |
2037 | Form("cluster from %s : E vs dispersion^{2}",ptypess[i].Data()), | |
521636d2 | 2038 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); |
3d5d5078 | 2039 | fhMCEDispersion[i]->SetYTitle("D^{2}"); |
2040 | fhMCEDispersion[i]->SetXTitle("E (GeV)"); | |
2041 | outputContainer->Add(fhMCEDispersion[i]) ; | |
34c16486 | 2042 | |
f66d95af | 2043 | fhMCNCellsE[i] = new TH2F (Form("hNCellsE_MC%s",pnamess[i].Data()), |
34c16486 | 2044 | Form("# of cells in cluster from %s vs E of clusters",ptypess[i].Data()), |
f66d95af | 2045 | nptbins,ptmin,ptmax, nbins,nmin,nmax); |
2046 | fhMCNCellsE[i]->SetXTitle("E (GeV)"); | |
2047 | fhMCNCellsE[i]->SetYTitle("# of cells in cluster"); | |
2048 | outputContainer->Add(fhMCNCellsE[i]); | |
2049 | ||
2050 | fhMCMaxCellDiffClusterE[i] = new TH2F (Form("hMaxCellDiffClusterE_MC%s",pnamess[i].Data()), | |
34c16486 | 2051 | Form("energy vs difference of cluster energy from %s - max cell energy / cluster energy, good clusters",ptypess[i].Data()), |
2052 | nptbins,ptmin,ptmax, 500,0,1.); | |
f66d95af | 2053 | fhMCMaxCellDiffClusterE[i]->SetXTitle("E_{cluster} (GeV) "); |
2054 | fhMCMaxCellDiffClusterE[i]->SetYTitle("(E_{cluster} - E_{cell max})/ E_{cluster}"); | |
2055 | outputContainer->Add(fhMCMaxCellDiffClusterE[i]); | |
2056 | ||
764ab1f4 | 2057 | if(!fFillOnlySimpleSSHisto) |
34c16486 | 2058 | { |
764ab1f4 | 2059 | fhMCLambda0vsClusterMaxCellDiffE0[i] = new TH2F(Form("hLambda0vsClusterMaxCellDiffE0_MC%s",pnamess[i].Data()), |
2060 | Form("cluster from %s : #lambda^{2}_{0} vs fraction of energy carried by max cell, E < 2 GeV",ptypess[i].Data()), | |
2061 | ssbins,ssmin,ssmax,500,0,1.); | |
2062 | fhMCLambda0vsClusterMaxCellDiffE0[i]->SetXTitle("#lambda_{0}^{2}"); | |
2063 | fhMCLambda0vsClusterMaxCellDiffE0[i]->SetYTitle("(E_{cluster} - E_{cell max})/ E_{cluster}"); | |
2064 | outputContainer->Add(fhMCLambda0vsClusterMaxCellDiffE0[i]) ; | |
2065 | ||
2066 | fhMCLambda0vsClusterMaxCellDiffE2[i] = new TH2F(Form("hLambda0vsClusterMaxCellDiffE2_MC%s",pnamess[i].Data()), | |
2067 | Form("cluster from %s : #lambda^{2}_{0} vs fraction of energy carried by max cell, 2< E < 6 GeV",ptypess[i].Data()), | |
2068 | ssbins,ssmin,ssmax,500,0,1.); | |
2069 | fhMCLambda0vsClusterMaxCellDiffE2[i]->SetXTitle("#lambda_{0}^{2}"); | |
2070 | fhMCLambda0vsClusterMaxCellDiffE2[i]->SetYTitle("(E_{cluster} - E_{cell max})/ E_{cluster}"); | |
2071 | outputContainer->Add(fhMCLambda0vsClusterMaxCellDiffE2[i]) ; | |
34c16486 | 2072 | |
764ab1f4 | 2073 | fhMCLambda0vsClusterMaxCellDiffE6[i] = new TH2F(Form("hLambda0vsClusterMaxCellDiffE6_MC%s",pnamess[i].Data()), |
2074 | Form("cluster from %s : #lambda^{2}_{0} vs fraction of energy carried by max cell, E > 6 GeV",ptypess[i].Data()), | |
2075 | ssbins,ssmin,ssmax,500,0,1.); | |
2076 | fhMCLambda0vsClusterMaxCellDiffE6[i]->SetXTitle("#lambda_{0}^{2}"); | |
2077 | fhMCLambda0vsClusterMaxCellDiffE6[i]->SetYTitle("(E_{cluster} - E_{cell max})/ E_{cluster}"); | |
2078 | outputContainer->Add(fhMCLambda0vsClusterMaxCellDiffE6[i]) ; | |
34c16486 | 2079 | |
764ab1f4 | 2080 | fhMCNCellsvsClusterMaxCellDiffE0[i] = new TH2F(Form("hNCellsvsClusterMaxCellDiffE0_MC%s",pnamess[i].Data()), |
2081 | Form("cluster from %s : N cells in cluster vs fraction of energy carried by max cell, E < 2 GeV",ptypess[i].Data()), | |
2082 | nbins/5,nmin,nmax/5,500,0,1.); | |
2083 | fhMCNCellsvsClusterMaxCellDiffE0[i]->SetXTitle("N cells in cluster"); | |
2084 | fhMCNCellsvsClusterMaxCellDiffE0[i]->SetYTitle("(E_{cluster} - E_{cell max})/ E_{cluster}"); | |
2085 | outputContainer->Add(fhMCNCellsvsClusterMaxCellDiffE0[i]) ; | |
34c16486 | 2086 | |
764ab1f4 | 2087 | fhMCNCellsvsClusterMaxCellDiffE2[i] = new TH2F(Form("hNCellsvsClusterMaxCellDiffE2_MC%s",pnamess[i].Data()), |
2088 | Form("cluster from %s : N cells in cluster vs fraction of energy carried by max cell, 2< E < 6 GeV",ptypess[i].Data()), | |
2089 | nbins/5,nmin,nmax/5,500,0,1.); | |
2090 | fhMCNCellsvsClusterMaxCellDiffE2[i]->SetXTitle("N cells in cluster"); | |
2091 | fhMCNCellsvsClusterMaxCellDiffE2[i]->SetYTitle("(E_{cluster} - E_{cell max})/ E_{cluster}"); | |
2092 | outputContainer->Add(fhMCNCellsvsClusterMaxCellDiffE2[i]) ; | |
34c16486 | 2093 | |
764ab1f4 | 2094 | fhMCNCellsvsClusterMaxCellDiffE6[i] = new TH2F(Form("hNCellsvsClusterMaxCellDiffE6_MC%s",pnamess[i].Data()), |
2095 | Form("cluster from %s : N cells in cluster vs fraction of energy carried by max cell, E > 6 GeV",ptypess[i].Data()), | |
2096 | nbins/5,nmin,nmax/5,500,0,1.); | |
2097 | fhMCNCellsvsClusterMaxCellDiffE6[i]->SetXTitle("N cells in cluster"); | |
2098 | fhMCNCellsvsClusterMaxCellDiffE6[i]->SetYTitle("E (GeV)"); | |
2099 | outputContainer->Add(fhMCNCellsvsClusterMaxCellDiffE6[i]) ; | |
34c16486 | 2100 | |
764ab1f4 | 2101 | if(fCalorimeter=="EMCAL") |
34c16486 | 2102 | { |
764ab1f4 | 2103 | fhMCEDispEta[i] = new TH2F (Form("hEDispEtaE_MC%s",pnamess[i].Data()), |
2104 | Form("cluster from %s : #sigma^{2}_{#eta #eta} = #Sigma w_{i}(#eta_{i} - <#eta>)^{2}/ #Sigma w_{i} vs E",ptypess[i].Data()), | |
2105 | nptbins,ptmin,ptmax, ssbins,ssmin,ssmax); | |
2106 | fhMCEDispEta[i]->SetXTitle("E (GeV)"); | |
2107 | fhMCEDispEta[i]->SetYTitle("#sigma^{2}_{#eta #eta}"); | |
2108 | outputContainer->Add(fhMCEDispEta[i]); | |
2109 | ||
2110 | fhMCEDispPhi[i] = new TH2F (Form("hEDispPhiE_MC%s",pnamess[i].Data()), | |
2111 | Form("cluster from %s : #sigma^{2}_{#phi #phi} = #Sigma w_{i}(#phi_{i} - <#phi>)^{2} / #Sigma w_{i} vs E",ptypess[i].Data()), | |
2112 | nptbins,ptmin,ptmax, ssbins,ssmin,ssmax); | |
2113 | fhMCEDispPhi[i]->SetXTitle("E (GeV)"); | |
2114 | fhMCEDispPhi[i]->SetYTitle("#sigma^{2}_{#phi #phi}"); | |
2115 | outputContainer->Add(fhMCEDispPhi[i]); | |
2116 | ||
2117 | fhMCESumEtaPhi[i] = new TH2F (Form("hESumEtaPhiE_MC%s",pnamess[i].Data()), | |
2118 | Form("cluster from %s : #delta^{2}_{#eta #phi} = #Sigma w_{i}(#phi_{i} #eta_{i} ) / #Sigma w_{i} - <#phi><#eta> vs E",ptypess[i].Data()), | |
2119 | nptbins,ptmin,ptmax, 2*ssbins,-ssmax,ssmax); | |
2120 | fhMCESumEtaPhi[i]->SetXTitle("E (GeV)"); | |
2121 | fhMCESumEtaPhi[i]->SetYTitle("#delta^{2}_{#eta #phi}"); | |
2122 | outputContainer->Add(fhMCESumEtaPhi[i]); | |
2123 | ||
2124 | fhMCEDispEtaPhiDiff[i] = new TH2F (Form("hEDispEtaPhiDiffE_MC%s",pnamess[i].Data()), | |
2125 | Form("cluster from %s : #sigma^{2}_{#phi #phi} - #sigma^{2}_{#eta #eta} vs E",ptypess[i].Data()), | |
2126 | nptbins,ptmin,ptmax,200,-10,10); | |
2127 | fhMCEDispEtaPhiDiff[i]->SetXTitle("E (GeV)"); | |
2128 | fhMCEDispEtaPhiDiff[i]->SetYTitle("#sigma^{2}_{#phi #phi}-#sigma^{2}_{#eta #eta}"); | |
2129 | outputContainer->Add(fhMCEDispEtaPhiDiff[i]); | |
2130 | ||
2131 | fhMCESphericity[i] = new TH2F (Form("hESphericity_MC%s",pnamess[i].Data()), | |
2132 | Form("cluster from %s : (#sigma^{2}_{#phi #phi} - #sigma^{2}_{#eta #eta}) / (#sigma^{2}_{#eta #eta} + #sigma^{2}_{#phi #phi}) vs E",ptypess[i].Data()), | |
2133 | nptbins,ptmin,ptmax, 200,-1,1); | |
2134 | fhMCESphericity[i]->SetXTitle("E (GeV)"); | |
2135 | fhMCESphericity[i]->SetYTitle("s = (#sigma^{2}_{#phi #phi} - #sigma^{2}_{#eta #eta}) / (#sigma^{2}_{#eta #eta} + #sigma^{2}_{#phi #phi})"); | |
2136 | outputContainer->Add(fhMCESphericity[i]); | |
2137 | ||
2138 | for(Int_t ie = 0; ie < 7; ie++) | |
2139 | { | |
2140 | fhMCDispEtaDispPhi[ie][i] = new TH2F (Form("hMCDispEtaDispPhi_EBin%d_MC%s",ie,pnamess[i].Data()), | |
2141 | Form("cluster from %s : #sigma^{2}_{#phi #phi} vs #sigma^{2}_{#eta #eta} for %d < E < %d GeV",pnamess[i].Data(),bin[ie],bin[ie+1]), | |
2142 | ssbins,ssmin,ssmax , ssbins,ssmin,ssmax); | |
2143 | fhMCDispEtaDispPhi[ie][i]->SetXTitle("#sigma^{2}_{#eta #eta}"); | |
2144 | fhMCDispEtaDispPhi[ie][i]->SetYTitle("#sigma^{2}_{#phi #phi}"); | |
2145 | outputContainer->Add(fhMCDispEtaDispPhi[ie][i]); | |
2146 | ||
2147 | fhMCLambda0DispEta[ie][i] = new TH2F (Form("hMCLambda0DispEta_EBin%d_MC%s",ie,pnamess[i].Data()), | |
2148 | Form("cluster from %s : #lambda^{2}_{0} vs #sigma^{2}_{#eta #eta} for %d < E < %d GeV",pnamess[i].Data(),bin[ie],bin[ie+1]), | |
2149 | ssbins,ssmin,ssmax , ssbins,ssmin,ssmax); | |
2150 | fhMCLambda0DispEta[ie][i]->SetXTitle("#lambda^{2}_{0}"); | |
2151 | fhMCLambda0DispEta[ie][i]->SetYTitle("#sigma^{2}_{#phi #phi}"); | |
2152 | outputContainer->Add(fhMCLambda0DispEta[ie][i]); | |
2153 | ||
2154 | fhMCLambda0DispPhi[ie][i] = new TH2F (Form("hMCLambda0DispPhi_EBin%d_MC%s",ie,pnamess[i].Data()), | |
2155 | Form("cluster from %s :#lambda^{2}_{0} vs #sigma^{2}_{#phi #phi} for %d < E < %d GeV",pnamess[i].Data(),bin[ie],bin[ie+1]), | |
2156 | ssbins,ssmin,ssmax , ssbins,ssmin,ssmax); | |
2157 | fhMCLambda0DispPhi[ie][i]->SetXTitle("#lambda^{2}_{0}"); | |
2158 | fhMCLambda0DispPhi[ie][i]->SetYTitle("#sigma^{2}_{#phi #phi}"); | |
2159 | outputContainer->Add(fhMCLambda0DispPhi[ie][i]); | |
2160 | } | |
34c16486 | 2161 | } |
34c16486 | 2162 | } |
2163 | }// loop | |
3d5d5078 | 2164 | |
2165 | if(!GetReader()->IsEmbeddedClusterSelectionOn()) | |
2166 | { | |
2167 | fhMCPhotonELambda0NoOverlap = new TH2F("hELambda0_MCPhoton_NoOverlap", | |
2168 | "cluster from Photon : E vs #lambda_{0}^{2}", | |
2169 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
2170 | fhMCPhotonELambda0NoOverlap->SetYTitle("#lambda_{0}^{2}"); | |
2171 | fhMCPhotonELambda0NoOverlap->SetXTitle("E (GeV)"); | |
2172 | outputContainer->Add(fhMCPhotonELambda0NoOverlap) ; | |
2173 | ||
3d5d5078 | 2174 | fhMCPhotonELambda0TwoOverlap = new TH2F("hELambda0_MCPhoton_TwoOverlap", |
2175 | "cluster from Photon : E vs #lambda_{0}^{2}", | |
2176 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
2177 | fhMCPhotonELambda0TwoOverlap->SetYTitle("#lambda_{0}^{2}"); | |
2178 | fhMCPhotonELambda0TwoOverlap->SetXTitle("E (GeV)"); | |
2179 | outputContainer->Add(fhMCPhotonELambda0TwoOverlap) ; | |
2180 | ||
3d5d5078 | 2181 | fhMCPhotonELambda0NOverlap = new TH2F("hELambda0_MCPhoton_NOverlap", |
2182 | "cluster from Photon : E vs #lambda_{0}^{2}", | |
2183 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
2184 | fhMCPhotonELambda0NOverlap->SetYTitle("#lambda_{0}^{2}"); | |
2185 | fhMCPhotonELambda0NOverlap->SetXTitle("E (GeV)"); | |
2186 | outputContainer->Add(fhMCPhotonELambda0NOverlap) ; | |
521636d2 | 2187 | |
3d5d5078 | 2188 | } //No embedding |
2189 | ||
2190 | //Fill histograms to check shape of embedded clusters | |
2191 | if(GetReader()->IsEmbeddedClusterSelectionOn()) | |
2192 | { | |
2193 | ||
2194 | fhEmbeddedSignalFractionEnergy = new TH2F("hEmbeddedSignal_FractionEnergy", | |
34c16486 | 2195 | "Energy Fraction of embedded signal versus cluster energy", |
2196 | nptbins,ptmin,ptmax,100,0.,1.); | |
3d5d5078 | 2197 | fhEmbeddedSignalFractionEnergy->SetYTitle("Fraction"); |
2198 | fhEmbeddedSignalFractionEnergy->SetXTitle("E (GeV)"); | |
2199 | outputContainer->Add(fhEmbeddedSignalFractionEnergy) ; | |
2200 | ||
2201 | fhEmbedPhotonELambda0FullSignal = new TH2F("hELambda0_EmbedPhoton_FullSignal", | |
34c16486 | 2202 | "cluster from Photon embedded with more than 90% energy in cluster : E vs #lambda_{0}^{2}", |
2203 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
3d5d5078 | 2204 | fhEmbedPhotonELambda0FullSignal->SetYTitle("#lambda_{0}^{2}"); |
2205 | fhEmbedPhotonELambda0FullSignal->SetXTitle("E (GeV)"); | |
2206 | outputContainer->Add(fhEmbedPhotonELambda0FullSignal) ; | |
34c16486 | 2207 | |
3d5d5078 | 2208 | fhEmbedPhotonELambda0MostlySignal = new TH2F("hELambda0_EmbedPhoton_MostlySignal", |
34c16486 | 2209 | "cluster from Photon embedded with 50% to 90% energy in cluster : E vs #lambda_{0}^{2}", |
2210 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
3d5d5078 | 2211 | fhEmbedPhotonELambda0MostlySignal->SetYTitle("#lambda_{0}^{2}"); |
2212 | fhEmbedPhotonELambda0MostlySignal->SetXTitle("E (GeV)"); | |
2213 | outputContainer->Add(fhEmbedPhotonELambda0MostlySignal) ; | |
2214 | ||
3d5d5078 | 2215 | fhEmbedPhotonELambda0MostlyBkg = new TH2F("hELambda0_EmbedPhoton_MostlyBkg", |
34c16486 | 2216 | "cluster from Photon embedded with 10% to 50% energy in cluster : E vs #lambda_{0}^{2}", |
2217 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
3d5d5078 | 2218 | fhEmbedPhotonELambda0MostlyBkg->SetYTitle("#lambda_{0}^{2}"); |
2219 | fhEmbedPhotonELambda0MostlyBkg->SetXTitle("E (GeV)"); | |
2220 | outputContainer->Add(fhEmbedPhotonELambda0MostlyBkg) ; | |
34c16486 | 2221 | |
3d5d5078 | 2222 | fhEmbedPhotonELambda0FullBkg = new TH2F("hELambda0_EmbedPhoton_FullBkg", |
34c16486 | 2223 | "cluster from Photonm embedded with 0% to 10% energy in cluster : E vs #lambda_{0}^{2}", |
2224 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
3d5d5078 | 2225 | fhEmbedPhotonELambda0FullBkg->SetYTitle("#lambda_{0}^{2}"); |
2226 | fhEmbedPhotonELambda0FullBkg->SetXTitle("E (GeV)"); | |
2227 | outputContainer->Add(fhEmbedPhotonELambda0FullBkg) ; | |
2228 | ||
3d5d5078 | 2229 | fhEmbedPi0ELambda0FullSignal = new TH2F("hELambda0_EmbedPi0_FullSignal", |
34c16486 | 2230 | "cluster from Pi0 embedded with more than 90% energy in cluster : E vs #lambda_{0}^{2}", |
2231 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
3d5d5078 | 2232 | fhEmbedPi0ELambda0FullSignal->SetYTitle("#lambda_{0}^{2}"); |
2233 | fhEmbedPi0ELambda0FullSignal->SetXTitle("E (GeV)"); | |
2234 | outputContainer->Add(fhEmbedPi0ELambda0FullSignal) ; | |
34c16486 | 2235 | |
3d5d5078 | 2236 | fhEmbedPi0ELambda0MostlySignal = new TH2F("hELambda0_EmbedPi0_MostlySignal", |
34c16486 | 2237 | "cluster from Pi0 embedded with 50% to 90% energy in cluster : E vs #lambda_{0}^{2}", |
2238 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
3d5d5078 | 2239 | fhEmbedPi0ELambda0MostlySignal->SetYTitle("#lambda_{0}^{2}"); |
2240 | fhEmbedPi0ELambda0MostlySignal->SetXTitle("E (GeV)"); | |
2241 | outputContainer->Add(fhEmbedPi0ELambda0MostlySignal) ; | |
2242 | ||
3d5d5078 | 2243 | fhEmbedPi0ELambda0MostlyBkg = new TH2F("hELambda0_EmbedPi0_MostlyBkg", |
34c16486 | 2244 | "cluster from Pi0 embedded with 10% to 50% energy in cluster : E vs #lambda_{0}^{2}", |
2245 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
3d5d5078 | 2246 | fhEmbedPi0ELambda0MostlyBkg->SetYTitle("#lambda_{0}^{2}"); |
2247 | fhEmbedPi0ELambda0MostlyBkg->SetXTitle("E (GeV)"); | |
2248 | outputContainer->Add(fhEmbedPi0ELambda0MostlyBkg) ; | |
2249 | ||
3d5d5078 | 2250 | fhEmbedPi0ELambda0FullBkg = new TH2F("hELambda0_EmbedPi0_FullBkg", |
34c16486 | 2251 | "cluster from Pi0 embedded with 0% to 10% energy in cluster : E vs #lambda_{0}^{2}", |
2252 | nptbins,ptmin,ptmax,ssbins,ssmin,ssmax); | |
3d5d5078 | 2253 | fhEmbedPi0ELambda0FullBkg->SetYTitle("#lambda_{0}^{2}"); |
2254 | fhEmbedPi0ELambda0FullBkg->SetXTitle("E (GeV)"); | |
2255 | outputContainer->Add(fhEmbedPi0ELambda0FullBkg) ; | |
34c16486 | 2256 | |
3d5d5078 | 2257 | }// embedded histograms |
2258 | ||
521636d2 | 2259 | |
2260 | }// Fill SS MC histograms | |
2261 | ||
477d6cee | 2262 | }//Histos with MC |
09273901 | 2263 | |
477d6cee | 2264 | return outputContainer ; |
2265 | ||
1c5acb87 | 2266 | } |
2267 | ||
34c16486 | 2268 | //_______________________ |
6639984f | 2269 | void AliAnaPhoton::Init() |
2270 | { | |
2271 | ||
2272 | //Init | |
2273 | //Do some checks | |
34c16486 | 2274 | if(fCalorimeter == "PHOS" && !GetReader()->IsPHOSSwitchedOn() && NewOutputAOD()) |
2275 | { | |
591cc579 | 2276 | printf("AliAnaPhoton::Init() - !!STOP: You want to use PHOS in analysis but it is not read!! \n!!Check the configuration file!!\n"); |
6639984f | 2277 | abort(); |
2278 | } | |
34c16486 | 2279 | else if(fCalorimeter == "EMCAL" && !GetReader()->IsEMCALSwitchedOn() && NewOutputAOD()) |
2280 | { | |
591cc579 | 2281 | printf("AliAnaPhoton::Init() - !!STOP: You want to use EMCAL in analysis but it is not read!! \n!!Check the configuration file!!\n"); |
6639984f | 2282 | abort(); |
2283 | } | |
2284 | ||
49b5c49b | 2285 | if(GetReader()->GetDataType() == AliCaloTrackReader::kMC) GetCaloPID()->SwitchOnBayesian(); |
2286 | ||
6639984f | 2287 | } |
2288 | ||
1c5acb87 | 2289 | //____________________________________________________________________________ |
2290 | void AliAnaPhoton::InitParameters() | |
2291 | { | |
2292 | ||
2293 | //Initialize the parameters of the analysis. | |
a3aebfff | 2294 | AddToHistogramsName("AnaPhoton_"); |
521636d2 | 2295 | |
6175da48 | 2296 | fCalorimeter = "EMCAL" ; |
2297 | fMinDist = 2.; | |
2298 | fMinDist2 = 4.; | |
2299 | fMinDist3 = 5.; | |
1e86c71e | 2300 | |
caa8a222 | 2301 | fTimeCutMin =-1000000; |
2302 | fTimeCutMax = 1000000; | |
6175da48 | 2303 | fNCellsCut = 0; |
2ac125bf | 2304 | |
1e86c71e | 2305 | fRejectTrackMatch = kTRUE ; |
1e86c71e | 2306 | |
1c5acb87 | 2307 | } |
2308 | ||
2309 | //__________________________________________________________________ | |
2310 | void AliAnaPhoton::MakeAnalysisFillAOD() | |
2311 | { | |
f8006433 | 2312 | //Do photon analysis and fill aods |
f37fa8d2 | 2313 | |
6175da48 | 2314 | //Get the vertex |
5025c139 | 2315 | Double_t v[3] = {0,0,0}; //vertex ; |
2316 | GetReader()->GetVertex(v); | |
f8006433 | 2317 | |
f37fa8d2 | 2318 | //Select the Calorimeter of the photon |
c8fe2783 | 2319 | TObjArray * pl = 0x0; |
71e3889f | 2320 | AliVCaloCells* cells = 0; |
2321 | if (fCalorimeter == "PHOS" ) | |
2322 | { | |
2323 | pl = GetPHOSClusters(); | |
2324 | cells = GetPHOSCells(); | |
2325 | } | |
477d6cee | 2326 | else if (fCalorimeter == "EMCAL") |
71e3889f | 2327 | { |
2328 | pl = GetEMCALClusters(); | |
2329 | cells = GetEMCALCells(); | |
2330 | } | |
5ae09196 | 2331 | |
34c16486 | 2332 | if(!pl) |
2333 | { | |
5ae09196 | 2334 | Info("MakeAnalysisFillAOD","TObjArray with %s clusters is NULL!\n",fCalorimeter.Data()); |
2335 | return; | |
2336 | } | |
521636d2 | 2337 | |
acd56ca4 | 2338 | FillPileUpHistogramsPerEvent(pl); |
2339 | ||
fc195fd0 | 2340 | // Loop on raw clusters before filtering in the reader and fill control histogram |
34c16486 | 2341 | if((GetReader()->GetEMCALClusterListName()=="" && fCalorimeter=="EMCAL") || fCalorimeter=="PHOS") |
2342 | { | |
2343 | for(Int_t iclus = 0; iclus < GetReader()->GetInputEvent()->GetNumberOfCaloClusters(); iclus++ ) | |
2344 | { | |
fc195fd0 | 2345 | AliVCluster * clus = GetReader()->GetInputEvent()->GetCaloCluster(iclus); |
2346 | if (fCalorimeter == "PHOS" && clus->IsPHOS() && clus->E() > GetReader()->GetPHOSPtMin() ) fhClusterCuts[0]->Fill(clus->E()); | |
2347 | else if(fCalorimeter == "EMCAL" && clus->IsEMCAL() && clus->E() > GetReader()->GetEMCALPtMin()) fhClusterCuts[0]->Fill(clus->E()); | |
2348 | } | |
2349 | } | |
34c16486 | 2350 | else |
2351 | { // reclusterized | |
fc195fd0 | 2352 | TClonesArray * clusterList = 0; |
7d650cb7 | 2353 | |
2354 | if(GetReader()->GetInputEvent()->FindListObject(GetReader()->GetEMCALClusterListName())) | |
2355 | clusterList = dynamic_cast<TClonesArray*> (GetReader()->GetInputEvent()->FindListObject(GetReader()->GetEMCALClusterListName())); | |
2356 | else if(GetReader()->GetOutputEvent()) | |
4a9e1073 | 2357 | clusterList = dynamic_cast<TClonesArray*> (GetReader()->GetOutputEvent()->FindListObject(GetReader()->GetEMCALClusterListName())); |
7d650cb7 | 2358 | |
34c16486 | 2359 | if(clusterList) |
2360 | { | |
fc195fd0 | 2361 | Int_t nclusters = clusterList->GetEntriesFast(); |
34c16486 | 2362 | for (Int_t iclus = 0; iclus < nclusters; iclus++) |
2363 | { | |
fc195fd0 | 2364 | AliVCluster * clus = dynamic_cast<AliVCluster*> (clusterList->At(iclus)); |
2365 | if(clus)fhClusterCuts[0]->Fill(clus->E()); | |
4a9e1073 | 2366 | } |
fc195fd0 | 2367 | } |
2368 | } | |
fc195fd0 | 2369 | |
6175da48 | 2370 | //Init arrays, variables, get number of clusters |
1e86c71e | 2371 | TLorentzVector mom, mom2 ; |
2372 | Int_t nCaloClusters = pl->GetEntriesFast(); | |
20218aea | 2373 | |
6175da48 | 2374 | if(GetDebug() > 0) printf("AliAnaPhoton::MakeAnalysisFillAOD() - input %s cluster entries %d\n", fCalorimeter.Data(), nCaloClusters); |
521636d2 | 2375 | |
6175da48 | 2376 | //---------------------------------------------------- |
2377 | // Fill AOD with PHOS/EMCAL AliAODPWG4Particle objects | |
2378 | //---------------------------------------------------- | |
2379 | // Loop on clusters | |
34c16486 | 2380 | for(Int_t icalo = 0; icalo < nCaloClusters; icalo++) |
2381 | { | |
0ae57829 | 2382 | AliVCluster * calo = (AliVCluster*) (pl->At(icalo)); |
2383 | //printf("calo %d, %f\n",icalo,calo->E()); | |
521636d2 | 2384 | |
f8006433 | 2385 | //Get the index where the cluster comes, to retrieve the corresponding vertex |
c8fe2783 | 2386 | Int_t evtIndex = 0 ; |
34c16486 | 2387 | if (GetMixedEvent()) |
2388 | { | |
c8fe2783 | 2389 | evtIndex=GetMixedEvent()->EventIndexForCaloCluster(calo->GetID()) ; |
5025c139 | 2390 | //Get the vertex and check it is not too large in z |
96539743 | 2391 | if(TMath::Abs(GetVertex(evtIndex)[2])> GetZvertexCut()) continue; |
c8fe2783 | 2392 | } |
521636d2 | 2393 | |
2394 | //Cluster selection, not charged, with photon id and in fiducial cut | |
34c16486 | 2395 | if(GetReader()->GetDataType() != AliCaloTrackReader::kMC) |
2396 | { | |
f8006433 | 2397 | calo->GetMomentum(mom,GetVertex(evtIndex)) ;}//Assume that come from vertex in straight line |
34c16486 | 2398 | else |
2399 | { | |
f8006433 | 2400 | Double_t vertex[]={0,0,0}; |
2401 | calo->GetMomentum(mom,vertex) ; | |
2402 | } | |
2ad19c3d | 2403 | |
6175da48 | 2404 | //-------------------------------------- |
2405 | // Cluster selection | |
2406 | //-------------------------------------- | |
9e51e29a | 2407 | Int_t nMaxima = GetCaloUtils()->GetNumberOfLocalMaxima(calo, cells); // NLM |
2408 | if(!ClusterSelected(calo,mom,nMaxima)) continue; | |
2409 | ||
6175da48 | 2410 | //---------------------------- |
2411 | //Create AOD for analysis | |
2412 | //---------------------------- | |
2413 | AliAODPWG4Particle aodph = AliAODPWG4Particle(mom); | |
2414 | ||
2415 | //............................................... | |
2416 | //Set the indeces of the original caloclusters (MC, ID), and calorimeter | |
2417 | Int_t label = calo->GetLabel(); | |
2418 | aodph.SetLabel(label); | |
6175da48 | 2419 | aodph.SetCaloLabel(calo->GetID(),-1); |
2420 | aodph.SetDetector(fCalorimeter); | |
c4a7d28a | 2421 | //printf("Index %d, Id %d, iaod %d\n",icalo, calo->GetID(),GetOutputAODBranch()->GetEntriesFast()); |
521636d2 | 2422 | |
6175da48 | 2423 | //............................................... |
2424 | //Set bad channel distance bit | |
c4a7d28a | 2425 | Double_t distBad=calo->GetDistanceToBadChannel() ; //Distance to bad channel |
f37fa8d2 | 2426 | if (distBad > fMinDist3) aodph.SetDistToBad(2) ; |
477d6cee | 2427 | else if(distBad > fMinDist2) aodph.SetDistToBad(1) ; |
f37fa8d2 | 2428 | else aodph.SetDistToBad(0) ; |
af7b3903 | 2429 | //printf("DistBad %f Bit %d\n",distBad, aodph.DistToBad()); |
c8fe2783 | 2430 | |
8d6b7f60 | 2431 | //-------------------------------------------------------------------------------------- |
2432 | // Play with the MC stack if available | |
2433 | //-------------------------------------------------------------------------------------- | |
2434 | ||
2435 | //Check origin of the candidates | |
2436 | Int_t tag = -1; | |
2437 | ||
34c16486 | 2438 | if(IsDataMC()) |
2439 | { | |
8d6b7f60 | 2440 | tag = GetMCAnalysisUtils()->CheckOrigin(calo->GetLabels(),calo->GetNLabels(),GetReader(), aodph.GetInputFileIndex()); |
2441 | aodph.SetTag(tag); | |
2442 | ||
2443 | if(GetDebug() > 0) | |
2444 | printf("AliAnaPhoton::MakeAnalysisFillAOD() - Origin of candidate, bit map %d\n",aodph.GetTag()); | |
2445 | }//Work with stack also | |
2446 | ||
2447 | ||
521636d2 | 2448 | //-------------------------------------------------------------------------------------- |
2449 | //Fill some shower shape histograms before PID is applied | |
2450 | //-------------------------------------------------------------------------------------- | |
2451 | ||
8d6b7f60 | 2452 | FillShowerShapeHistograms(calo,tag); |
6175da48 | 2453 | |
2454 | //------------------------------------- | |
f37fa8d2 | 2455 | //PID selection or bit setting |
6175da48 | 2456 | //------------------------------------- |
49b5c49b | 2457 | |
6175da48 | 2458 | //............................................... |
2459 | // Data, PID check on | |
3c1d9afb | 2460 | if(IsCaloPIDOn()) |
2461 | { | |
49b5c49b | 2462 | // Get most probable PID, 2 options check bayesian PID weights or redo PID |
2463 | // By default, redo PID | |
09273901 | 2464 | |
3c1d9afb | 2465 | aodph.SetIdentifiedParticleType(GetCaloPID()->GetIdentifiedParticleType(calo)); |
477d6cee | 2466 | |
21a4b1c0 | 2467 | if(GetDebug() > 1) printf("AliAnaPhoton::MakeAnalysisFillAOD() - PDG of identified particle %d\n",aodph.GetIdentifiedParticleType()); |
477d6cee | 2468 | |
f37fa8d2 | 2469 | //If cluster does not pass pid, not photon, skip it. |
21a4b1c0 | 2470 | if(aodph.GetIdentifiedParticleType() != AliCaloPID::kPhoton) continue ; |
477d6cee | 2471 | |
2472 | } | |
8d6b7f60 | 2473 | |
6175da48 | 2474 | //............................................... |
2475 | // Data, PID check off | |
3c1d9afb | 2476 | else |
2477 | { | |
f37fa8d2 | 2478 | //Set PID bits for later selection (AliAnaPi0 for example) |
49b5c49b | 2479 | //GetIdentifiedParticleType already called in SetPIDBits. |
2480 | ||
3c1d9afb | 2481 | GetCaloPID()->SetPIDBits(calo,&aodph, GetCaloUtils(),GetReader()->GetInputEvent()); |
49b5c49b | 2482 | |
a3aebfff | 2483 | if(GetDebug() > 1) printf("AliAnaPhoton::MakeAnalysisFillAOD() - PID Bits set \n"); |
477d6cee | 2484 | } |
2485 | ||
3c1d9afb | 2486 | if(GetDebug() > 1) printf("AliAnaPhoton::MakeAnalysisFillAOD() - Photon selection cuts passed: pT %3.2f, pdg %d\n", |
2487 | aodph.Pt(), aodph.GetIdentifiedParticleType()); | |
09273901 | 2488 | |
9e51e29a | 2489 | fhClusterCuts[9]->Fill(calo->E()); |
2490 | ||
2491 | fhNLocMax->Fill(calo->E(),nMaxima); | |
2492 | ||
09273901 | 2493 | // Matching after cuts |
4bfeae64 | 2494 | if(fFillTMHisto) FillTrackMatchingResidualHistograms(calo,1); |
09273901 | 2495 | |
2ad19c3d | 2496 | // Fill histograms to undertand pile-up before other cuts applied |
2497 | // Remember to relax time cuts in the reader | |
2498 | FillPileUpHistograms(calo->E(),calo->GetTOF()*1e9); | |
2499 | ||
5c46c992 | 2500 | // Add number of local maxima to AOD, method name in AOD to be FIXED |
9e51e29a | 2501 | aodph.SetFiducialArea(nMaxima); |
5c46c992 | 2502 | |
5c46c992 | 2503 | |
f37fa8d2 | 2504 | //Add AOD with photon object to aod branch |
477d6cee | 2505 | AddAODParticle(aodph); |
2506 | ||
2507 | }//loop | |
5812a064 | 2508 | |
f37fa8d2 | 2509 | if(GetDebug() > 1) printf("AliAnaPhoton::MakeAnalysisFillAOD() End fill AODs, with %d entries \n",GetOutputAODBranch()->GetEntriesFast()); |
477d6cee | 2510 | |
1c5acb87 | 2511 | } |
2512 | ||
2513 | //__________________________________________________________________ | |
2514 | void AliAnaPhoton::MakeAnalysisFillHistograms() | |
2515 | { | |
6175da48 | 2516 | //Fill histograms |
f8006433 | 2517 | |
6175da48 | 2518 | // Get vertex |
2244659d | 2519 | Double_t v[3] = {0,0,0}; //vertex ; |
2520 | GetReader()->GetVertex(v); | |
6175da48 | 2521 | //fhVertex->Fill(v[0],v[1],v[2]); |
2522 | if(TMath::Abs(v[2]) > GetZvertexCut()) return ; // done elsewhere for Single Event analysis, but there for mixed event | |
2523 | ||
2524 | //---------------------------------- | |
577d9801 | 2525 | //Loop on stored AOD photons |
2526 | Int_t naod = GetOutputAODBranch()->GetEntriesFast(); | |
577d9801 | 2527 | if(GetDebug() > 0) printf("AliAnaPhoton::MakeAnalysisFillHistograms() - aod branch entries %d\n", naod); |
521636d2 | 2528 | |
3c1d9afb | 2529 | for(Int_t iaod = 0; iaod < naod ; iaod++) |
2530 | { | |
577d9801 | 2531 | AliAODPWG4Particle* ph = (AliAODPWG4Particle*) (GetOutputAODBranch()->At(iaod)); |
2532 | Int_t pdg = ph->GetIdentifiedParticleType(); | |
521636d2 | 2533 | |
577d9801 | 2534 | if(GetDebug() > 3) |
3c1d9afb | 2535 | printf("AliAnaPhoton::MakeAnalysisFillHistograms() - PDG %d, MC TAG %d, Calorimeter %s\n", |
2536 | ph->GetIdentifiedParticleType(),ph->GetTag(), (ph->GetDetector()).Data()) ; | |
521636d2 | 2537 | |
577d9801 | 2538 | //If PID used, fill histos with photons in Calorimeter fCalorimeter |
2539 | if(IsCaloPIDOn() && pdg != AliCaloPID::kPhoton) continue; | |
2540 | if(ph->GetDetector() != fCalorimeter) continue; | |
521636d2 | 2541 | |
577d9801 | 2542 | if(GetDebug() > 2) |
2543 | printf("AliAnaPhoton::MakeAnalysisFillHistograms() - ID Photon: pt %f, phi %f, eta %f\n", ph->Pt(),ph->Phi(),ph->Eta()) ; | |
521636d2 | 2544 | |
6175da48 | 2545 | //................................ |
577d9801 | 2546 | //Fill photon histograms |
2547 | Float_t ptcluster = ph->Pt(); | |
2548 | Float_t phicluster = ph->Phi(); | |
2549 | Float_t etacluster = ph->Eta(); | |
2550 | Float_t ecluster = ph->E(); | |
521636d2 | 2551 | |
20218aea | 2552 | fhEPhoton ->Fill(ecluster); |
577d9801 | 2553 | fhPtPhoton ->Fill(ptcluster); |
2554 | fhPhiPhoton ->Fill(ptcluster,phicluster); | |
2555 | fhEtaPhoton ->Fill(ptcluster,etacluster); | |
521636d2 | 2556 | if (ecluster > 0.5) fhEtaPhiPhoton ->Fill(etacluster, phicluster); |
20218aea | 2557 | else if(GetMinPt() < 0.5) fhEtaPhi05Photon->Fill(etacluster, phicluster); |
2558 | ||
5812a064 | 2559 | |
2560 | //Get original cluster, to recover some information | |
2561 | Int_t absID = 0; | |
2562 | Float_t maxCellFraction = 0; | |
2563 | AliVCaloCells* cells = 0; | |
2564 | TObjArray * clusters = 0; | |
34c16486 | 2565 | if(fCalorimeter == "EMCAL") |
2566 | { | |
5812a064 | 2567 | cells = GetEMCALCells(); |
2568 | clusters = GetEMCALClusters(); | |
2569 | } | |
34c16486 | 2570 | else |
2571 | { | |
5812a064 | 2572 | cells = GetPHOSCells(); |
2573 | clusters = GetPHOSClusters(); | |
6175da48 | 2574 | } |
20218aea | 2575 | |
5812a064 | 2576 | Int_t iclus = -1; |
2577 | AliVCluster *cluster = FindCluster(clusters,ph->GetCaloLabel(0),iclus); | |
5c46c992 | 2578 | if(cluster) |
2579 | { | |
06f1b12a | 2580 | absID = GetCaloUtils()->GetMaxEnergyCell(cells, cluster,maxCellFraction); |
2581 | ||
2582 | // Control histograms | |
2583 | fhMaxCellDiffClusterE->Fill(ph->E(),maxCellFraction); | |
2584 | fhNCellsE ->Fill(ph->E(),cluster->GetNCells()); | |
2585 | fhTimeE ->Fill(ph->E(),cluster->GetTOF()*1.e9); | |
5c46c992 | 2586 | if(cells) |
2587 | { | |
2588 | for(Int_t icell = 0; icell < cluster->GetNCells(); icell++) | |
2589 | fhCellsE->Fill(ph->E(),cells->GetCellAmplitude(cluster->GetCellsAbsId()[icell])); | |
2590 | } | |
06f1b12a | 2591 | } |
5812a064 | 2592 | |
6175da48 | 2593 | //....................................... |
577d9801 | 2594 | //Play with the MC data if available |
34c16486 | 2595 | if(IsDataMC()) |
2596 | { | |
51a0ace5 | 2597 | if(GetDebug()>0) |
2598 | { | |
2599 | if(GetReader()->ReadStack() && !GetMCStack()) | |
2600 | { | |
2601 | printf("AliAnaPhoton::MakeAnalysisFillHistograms() - Stack not available, is the MC handler called?\n"); | |
2602 | } | |
2603 | else if(GetReader()->ReadAODMCParticles() && !GetReader()->GetAODMCParticles(0)) | |
2604 | { | |
2605 | printf("AliAnaPhoton::MakeAnalysisFillHistograms() - Standard MCParticles not available!\n"); | |
2606 | } | |
2607 | } | |
2608 | ||
3d5d5078 | 2609 | FillAcceptanceHistograms(); |
2610 | ||
4c8f7c2e | 2611 | //.................................................................... |
2612 | // Access MC information in stack if requested, check that it exists. | |
2613 | Int_t label =ph->GetLabel(); | |
51a0ace5 | 2614 | |
34c16486 | 2615 | if(label < 0) |
2616 | { | |
4c8f7c2e | 2617 | if(GetDebug() > 1) printf("AliAnaPhoton::MakeAnalysisFillHistograms() *** bad label ***: label %d \n", label); |
2618 | continue; | |
2619 | } | |
2620 | ||
2621 | Float_t eprim = 0; | |
2622 | Float_t ptprim = 0; | |
51a0ace5 | 2623 | Bool_t ok = kFALSE; |
2624 | TLorentzVector primary = GetMCAnalysisUtils()->GetMother(label,GetReader(),ok); | |
2625 | if(ok) | |
34c16486 | 2626 | { |
51a0ace5 | 2627 | eprim = primary.Energy(); |
2628 | ptprim = primary.Pt(); | |
4c8f7c2e | 2629 | } |
2630 | ||
577d9801 | 2631 | Int_t tag =ph->GetTag(); |
51a0ace5 | 2632 | Int_t mcParticleTag = -1; |
c5693f62 | 2633 | if( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPhoton) && fhMCE[kmcPhoton]) |
3d5d5078 | 2634 | { |
8e81c2cf | 2635 | fhMCE [kmcPhoton] ->Fill(ecluster); |
2636 | fhMCPt [kmcPhoton] ->Fill(ptcluster); | |
2637 | fhMCPhi[kmcPhoton] ->Fill(ecluster,phicluster); | |
2638 | fhMCEta[kmcPhoton] ->Fill(ecluster,etacluster); | |
2639 | ||
2640 | fhMC2E [kmcPhoton] ->Fill(ecluster, eprim); | |
2641 | fhMC2Pt [kmcPhoton] ->Fill(ptcluster, ptprim); | |
2642 | fhMCDeltaE [kmcPhoton] ->Fill(ecluster,eprim-ecluster); | |
2643 | fhMCDeltaPt[kmcPhoton] ->Fill(ptcluster,ptprim-ptcluster); | |
2644 | ||
764ab1f4 | 2645 | if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCConversion) && |
2646 | GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPhoton) && | |
2647 | fhMCE[kmcConversion]) | |
3d5d5078 | 2648 | { |
8e81c2cf | 2649 | fhMCE [kmcConversion] ->Fill(ecluster); |
2650 | fhMCPt [kmcConversion] ->Fill(ptcluster); | |
2651 | fhMCPhi[kmcConversion] ->Fill(ecluster,phicluster); | |
2652 | fhMCEta[kmcConversion] ->Fill(ecluster,etacluster); | |
2653 | ||
2654 | fhMC2E [kmcConversion] ->Fill(ecluster, eprim); | |
2655 | fhMC2Pt [kmcConversion] ->Fill(ptcluster, ptprim); | |
2656 | fhMCDeltaE [kmcConversion] ->Fill(ecluster,eprim-ecluster); | |
2657 | fhMCDeltaPt[kmcConversion] ->Fill(ptcluster,ptprim-ptcluster); | |
3d5d5078 | 2658 | } |
2659 | ||
51a0ace5 | 2660 | if (GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPrompt) && fhMCE[kmcPrompt]) |
34c16486 | 2661 | { |
51a0ace5 | 2662 | mcParticleTag = kmcPrompt; |
3d5d5078 | 2663 | } |
c5693f62 | 2664 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCFragmentation)&& fhMCE[kmcFragmentation]) |
3d5d5078 | 2665 | { |
51a0ace5 | 2666 | mcParticleTag = kmcFragmentation; |
3d5d5078 | 2667 | } |
c5693f62 | 2668 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCISR)&& fhMCE[kmcISR]) |
3d5d5078 | 2669 | { |
51a0ace5 | 2670 | mcParticleTag = kmcISR; |
3d5d5078 | 2671 | } |
2672 | else if( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPi0Decay) && | |
c5693f62 | 2673 | !GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPi0) && fhMCE[kmcPi0Decay]) |
3d5d5078 | 2674 | { |
51a0ace5 | 2675 | mcParticleTag = kmcPi0Decay; |
3d5d5078 | 2676 | } |
764ab1f4 | 2677 | else if((( GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCEtaDecay) && |
2678 | !GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCEta) ) || | |
51a0ace5 | 2679 | GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCOtherDecay) ) && fhMCE[kmcOtherDecay]) |
3d5d5078 | 2680 | { |
51a0ace5 | 2681 | mcParticleTag = kmcOtherDecay; |
3d5d5078 | 2682 | } |
51a0ace5 | 2683 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCPi0) && fhMCE[kmcPi0]) |
3d5d5078 | 2684 | { |
51a0ace5 | 2685 | mcParticleTag = kmcPi0; |
f66d95af | 2686 | } |
c5693f62 | 2687 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCEta) && fhMCE[kmcEta]) |
f66d95af | 2688 | { |
51a0ace5 | 2689 | mcParticleTag = kmcEta; |
f66d95af | 2690 | } |
3d5d5078 | 2691 | } |
c5693f62 | 2692 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCAntiNeutron) && fhMCE[kmcAntiNeutron]) |
3d5d5078 | 2693 | { |
51a0ace5 | 2694 | mcParticleTag = kmcAntiNeutron; |
3d5d5078 | 2695 | } |
c5693f62 | 2696 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCAntiProton) && fhMCE[kmcAntiProton]) |
3d5d5078 | 2697 | { |
51a0ace5 | 2698 | mcParticleTag = kmcAntiProton; |
3d5d5078 | 2699 | } |
c5693f62 | 2700 | else if(GetMCAnalysisUtils()->CheckTagBit(tag,AliMCAnalysisUtils::kMCElectron) && fhMCE[kmcElectron]) |
3d5d5078 | 2701 | { |
51a0ace5 | 2702 | mcParticleTag = kmcElectron; |
3d5d5078 | 2703 | } |
34c16486 | 2704 | else if( fhMCE[kmcOther]) |
2705 | { | |
51a0ace5 | 2706 | mcParticleTag = kmcOther; |
4c8f7c2e | 2707 | |
f8006433 | 2708 | // printf(" AliAnaPhoton::MakeAnalysisFillHistograms() - Label %d, pT %2.3f Unknown, bits set: ", |
2709 | // ph->GetLabel(),ph->Pt()); | |
2710 | // for(Int_t i = 0; i < 20; i++) { | |
2711 | // if(GetMCAnalysisUtils()->CheckTagBit(tag,i)) printf(" %d, ",i); | |
2712 | // } | |
2713 | // printf("\n"); | |
2714 | ||
577d9801 | 2715 | } |
521636d2 | 2716 | |
51a0ace5 | 2717 | fhMCE [mcParticleTag] ->Fill(ecluster); |
2718 | fhMCPt [mcParticleTag] ->Fill(ptcluster); | |
2719 | fhMCPhi[mcParticleTag] ->Fill(ecluster,phicluster); | |
2720 | fhMCEta[mcParticleTag] ->Fill(ecluster,etacluster); | |
2721 | ||
2722 | fhMC2E[mcParticleTag] ->Fill(ecluster, eprim); | |
2723 | fhMC2Pt[mcParticleTag] ->Fill(ptcluster, ptprim); | |
2724 | fhMCDeltaE[mcParticleTag] ->Fill(ecluster,eprim-ecluster); | |
2725 | fhMCDeltaPt[mcParticleTag]->Fill(ptcluster,ptprim-ptcluster); | |
2726 | ||
577d9801 | 2727 | }//Histograms with MC |
521636d2 | 2728 | |
577d9801 | 2729 | }// aod loop |
521636d2 | 2730 | |
1c5acb87 | 2731 | } |
2732 | ||
2733 | ||
2734 | //__________________________________________________________________ | |
2735 | void AliAnaPhoton::Print(const Option_t * opt) const | |
2736 | { | |
477d6cee | 2737 | //Print some relevant parameters set for the analysis |
2738 | ||
2739 | if(! opt) | |
2740 | return; | |
2741 | ||
2742 | printf("**** Print %s %s ****\n", GetName(), GetTitle() ) ; | |
745913ae | 2743 | AliAnaCaloTrackCorrBaseClass::Print(" "); |
a3aebfff | 2744 | |
477d6cee | 2745 | printf("Calorimeter = %s\n", fCalorimeter.Data()) ; |
2746 | printf("Min Distance to Bad Channel = %2.1f\n",fMinDist); | |
2747 | printf("Min Distance to Bad Channel 2 = %2.1f\n",fMinDist2); | |
2748 | printf("Min Distance to Bad Channel 3 = %2.1f\n",fMinDist3); | |
a3aebfff | 2749 | printf("Reject clusters with a track matched = %d\n",fRejectTrackMatch); |
4cf55759 | 2750 | printf("Time Cut: %3.1f < TOF < %3.1f\n", fTimeCutMin, fTimeCutMax); |
2ac125bf | 2751 | printf("Number of cells in cluster is > %d \n", fNCellsCut); |
477d6cee | 2752 | printf(" \n") ; |
1c5acb87 | 2753 | |
2754 | } |