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992b14a7 | 1 | #ifndef ALIANAINSIDECLUSTERINVARIANTMASS_H |
2 | #define ALIANAINSIDECLUSTERINVARIANTMASS_H | |
3 | /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * | |
4 | * See cxx source for full Copyright notice */ | |
992b14a7 | 5 | |
6 | //_________________________________________________________________________ | |
7 | // | |
8 | // Split clusters with some criteria and calculate invariant mass | |
9 | // to identify them as pi0 or conversion | |
10 | // | |
11 | // | |
83351853 | 12 | //-- Author: Gustavo Conesa (LPSC-Grenoble) |
992b14a7 | 13 | //_________________________________________________________________________ |
14 | ||
15 | ||
16 | // --- ROOT system --- | |
17 | class TList ; | |
18 | class TObjString; | |
19 | class TLorentzVector; | |
20 | ||
21 | // --- ANALYSIS system --- | |
5c46c992 | 22 | class AliAODCaloCluster; |
23 | ||
745913ae | 24 | #include "AliAnaCaloTrackCorrBaseClass.h" |
992b14a7 | 25 | |
745913ae | 26 | class AliAnaInsideClusterInvariantMass : public AliAnaCaloTrackCorrBaseClass { |
992b14a7 | 27 | |
28 | public: | |
3c1d9afb | 29 | |
992b14a7 | 30 | AliAnaInsideClusterInvariantMass() ; // default ctor |
31 | virtual ~AliAnaInsideClusterInvariantMass() { ; } //virtual dtor | |
992b14a7 | 32 | |
36769d30 | 33 | void CheckLocalMaximaMCOrigin(AliVCluster* cluster, const Int_t mcindex, const Int_t noverlaps); |
4914e781 | 34 | //Float_t mass, Float_t m02, TLorentzVector l1, TLorentzVector l2); |
b2e375c7 | 35 | |
992b14a7 | 36 | TObjString * GetAnalysisCuts(); |
37 | ||
38 | TList * GetCreateOutputObjects(); | |
dbe09c26 | 39 | |
4914e781 | 40 | void GetMCIndex(AliVCluster * cluster, Int_t & mcindex, Int_t & mcTag); |
b2e375c7 | 41 | |
4914e781 | 42 | void GetMCPrimaryKine(AliVCluster* cluster, const Int_t mcindex, const Int_t mcTag, const Bool_t matched, |
b2e375c7 | 43 | Float_t & eprim, Float_t & asymGen, Int_t & noverlaps ); |
44 | ||
45 | void FillAngleHistograms(const Int_t nMax, const Bool_t matched, | |
46 | const Float_t en, const Float_t angle, const Float_t mass); | |
47 | ||
48 | void FillEBinHistograms(const Int_t ebin, const Int_t nMax, const Int_t mcindex, const Float_t splitFrac, | |
49 | const Float_t mass, const Float_t asym, const Float_t l0); | |
50 | ||
51 | void FillMCHistograms(const Float_t en, const Float_t e1 , const Float_t e2, | |
4914e781 | 52 | const Int_t ebin, const Int_t mcindex,const Int_t noverlaps, |
b2e375c7 | 53 | const Float_t l0, const Float_t mass, |
54 | const Int_t nMax, const Bool_t matched, | |
55 | const Float_t splitFrac, const Float_t asym, | |
56 | const Float_t eprim, const Float_t asymGen); | |
57 | ||
4914e781 | 58 | void FillMCOverlapHistograms(const Float_t en, const Float_t enprim, |
59 | const Float_t mass, const Float_t l0, | |
60 | const Float_t asym, const Float_t splitFrac, | |
b2e375c7 | 61 | const Int_t nlm, const Int_t ebin, const Bool_t matched, |
62 | const Int_t mcindex, const Int_t noverlaps); | |
63 | ||
64 | void FillSSWeightHistograms(AliVCluster *cluster, const Int_t nlm, const Int_t absId1, const Int_t absId2); | |
65 | ||
66 | void FillSSExtraHistograms(AliVCluster *cluster, const Int_t nMax, | |
67 | const Bool_t matched, const Int_t mcindex, | |
68 | const Float_t mass , const Int_t ebin); | |
4914e781 | 69 | |
70 | void FillNCellHistograms(const Int_t ncells, const Float_t energy, const Int_t nMax, | |
71 | const Bool_t matched, const Int_t mcindex, | |
72 | const Float_t mass , const Float_t l0); | |
b2e375c7 | 73 | |
74 | void FillTrackMatchingHistograms(AliVCluster * cluster,const Int_t nMax, const Int_t mcindex); | |
dbe09c26 | 75 | |
992b14a7 | 76 | void Init(); |
77 | ||
78 | void InitParameters(); | |
79 | ||
80 | void MakeAnalysisFillHistograms() ; | |
992b14a7 | 81 | |
71e3889f | 82 | void Print(const Option_t * opt) const; |
992b14a7 | 83 | |
71e3889f | 84 | void SetCalorimeter(TString & det) { fCalorimeter = det ; } |
85 | ||
86 | void SetM02Cut(Float_t min=0, Float_t max=10) { fM02MinCut = min ; fM02MaxCut = max ; } | |
992b14a7 | 87 | |
71e3889f | 88 | void SetMinNCells(Int_t cut) { fMinNCells = cut ; } |
2cb134fb | 89 | |
90 | void SetMinBadChannelDistance(Float_t cut) { fMinBadDist = cut ; } | |
992b14a7 | 91 | |
8edbd100 | 92 | void SetWCorrectionParameter(Float_t p = 0.07) { fWSimu = p ; } |
93 | ||
883411b2 | 94 | void SwitchOnFillAngleHistograms() { fFillAngleHisto = kTRUE ; } |
95 | void SwitchOffFillAngleHistograms() { fFillAngleHisto = kFALSE ; } | |
96 | ||
97 | void SwitchOnFillExtraSSHistograms() { fFillSSExtraHisto = kTRUE ; } | |
98 | void SwitchOffFillExtraSSHistograms() { fFillSSExtraHisto = kFALSE ; } | |
8e81c2cf | 99 | |
8edbd100 | 100 | void SwitchOnFillTMHistograms() { fFillTMHisto = kTRUE ; } |
101 | void SwitchOffFillTMHistograms() { fFillTMHisto = kFALSE ; } | |
102 | ||
8e81c2cf | 103 | void SwitchOnFillTMResidualHistograms() { fFillTMResidualHisto = kTRUE ; } |
104 | void SwitchOffFillTMResidualHistograms() { fFillTMResidualHisto = kFALSE ; } | |
105 | ||
b2e375c7 | 106 | void SwitchOnFillMCPrimaryHistograms() { fFillMCHisto = kTRUE ; } |
107 | void SwitchOffFillMCPrimaryHistograms() { fFillMCHisto = kFALSE ; } | |
2a77f6f4 | 108 | |
19391b8c | 109 | void SwitchOnFillSSWeightHistograms() { fFillSSWeightHisto = kTRUE ; } |
110 | void SwitchOffFillSSWeightHistograms() { fFillSSWeightHisto = kFALSE ; } | |
111 | ||
112 | void SwitchOnFillEbinHistograms() { fFillEbinHisto = kTRUE ; } | |
113 | void SwitchOffFillEbinHistograms() { fFillEbinHisto = kFALSE ; } | |
dbe09c26 | 114 | |
b2e375c7 | 115 | void SwitchOnFillMCOverlapHistograms() { fFillMCOverlapHisto = kTRUE ; } |
116 | void SwitchOffFillMCOverlapHistograms() { fFillMCOverlapHisto = kFALSE ; } | |
4914e781 | 117 | |
118 | void SwitchOnFillNCellHistograms() { fFillNCellHisto = kTRUE ; } | |
119 | void SwitchOffFillNCellHistograms() { fFillNCellHisto = kFALSE ; } | |
b2e375c7 | 120 | |
19391b8c | 121 | void SetNWeightForShowerShape(Int_t n) { fSSWeightN = n ; } |
dbe09c26 | 122 | void SetWeightForShowerShape(Int_t i, Float_t v) { if (i < 10) fSSWeight[i] = v ; } |
123 | ||
19391b8c | 124 | void SetNECellCutForShowerShape(Int_t n) { fSSECellCutN = n ; } |
125 | void SetECellCutForShowerShape(Int_t i, Float_t v) { if (i < 10) fSSECellCut[i] = v ; } | |
126 | ||
127 | ||
128 | void RecalculateClusterShowerShapeParametersWithCellCut(const AliEMCALGeometry * geom, AliVCaloCells* cells, AliVCluster * cluster, | |
129 | Float_t & l0, Float_t & l1, | |
130 | Float_t & disp, Float_t & dEta, Float_t & dPhi, | |
131 | Float_t & sEta, Float_t & sPhi, Float_t & sEtaPhi,Float_t eCellMin = 0.); | |
132 | ||
2a77f6f4 | 133 | |
992b14a7 | 134 | //For histograms |
c5693f62 | 135 | enum mcTypes { kmcPhoton = 1, kmcConversion = 2, kmcPi0 = 3, |
de7d73e6 | 136 | kmcEta = 4, kmcElectron = 5, kmcHadron = 6, kmcPi0Conv = 7 }; |
992b14a7 | 137 | |
138 | private: | |
139 | ||
5c46c992 | 140 | TString fCalorimeter ; // Calorimeter where the gamma is searched |
3c1d9afb | 141 | Float_t fM02MaxCut ; // Study clusters with l0 smaller than cut |
142 | Float_t fM02MinCut ; // Study clusters with l0 larger than cut | |
143 | Int_t fMinNCells ; // Study clusters with ncells larger than cut | |
144 | Float_t fMinBadDist ; // Minimal distance to bad channel to accept cluster | |
b2e375c7 | 145 | Float_t fHistoECut ; // Fixed E cut for some histograms |
243c2909 | 146 | |
883411b2 | 147 | Bool_t fFillAngleHisto; // Fill splitted clusters angle histograms |
8edbd100 | 148 | Bool_t fFillTMHisto ; // Fill track matching histos, |
8e81c2cf | 149 | Bool_t fFillTMResidualHisto ; // Fill track matching histos, residuals |
150 | Bool_t fFillSSExtraHisto ; // Fill shower shape extra histos | |
b2e375c7 | 151 | Bool_t fFillMCHisto ; // Fill MC energy fraction histos |
dbe09c26 | 152 | Bool_t fFillSSWeightHisto ; // Fill weigth histograms |
19391b8c | 153 | Bool_t fFillEbinHisto ; // Fill E bin histograms |
b2e375c7 | 154 | Bool_t fFillMCOverlapHisto ; // Fill MC particles overlap histograms |
4914e781 | 155 | Bool_t fFillNCellHisto ; // Fill n cells in cluster dependent histograms |
8edbd100 | 156 | |
dbe09c26 | 157 | Float_t fSSWeight[10]; // List of weights to test |
19391b8c | 158 | Int_t fSSWeightN; // Total number of weights to test |
159 | ||
160 | Float_t fSSECellCut[10]; // List of cell min energy cuts to test | |
161 | Int_t fSSECellCutN; // Total number of cell min energy cuts to test | |
dbe09c26 | 162 | |
8edbd100 | 163 | Float_t fWSimu; // Slope of the linear correction factor for the shower |
164 | // shape weight in simulation, about 0.07 | |
165 | ||
992b14a7 | 166 | //Histograms |
167 | ||
de7d73e6 | 168 | TH2F * fhMassNLocMax1[8][2] ; //! Mass of 2 highest energy cells when 1 local max vs E, 1-6 for different MC particle types |
169 | TH2F * fhMassNLocMax2[8][2] ; //! Mass of 2 cells local maxima vs E, 1-6 for different MC particle types | |
170 | TH2F * fhMassNLocMaxN[8][2] ; //! Mass of >2 cells local maxima vs E, 1-6 for different MC particle types | |
5c46c992 | 171 | |
de7d73e6 | 172 | TH2F * fhAsymNLocMax1[8][2] ; //! Asymmetry of 2 highest energy cells when 1 local max vs E, 1-6 for different MC particle types |
173 | TH2F * fhAsymNLocMax2[8][2] ; //! Asymmetry of 2 cells local maxima vs E, 1-6 for different MC particle types | |
174 | TH2F * fhAsymNLocMaxN[8][2] ; //! Asymmetry of >2 cells local maxima vs E, 1-6 for different MC particle types | |
2a77f6f4 | 175 | |
e671adc2 | 176 | TH2F * fhSplitEFractionvsAsyNLocMax1[2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima = 1 vs |A| |
177 | TH2F * fhSplitEFractionvsAsyNLocMax2[2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima = 2 vs |A| | |
178 | TH2F * fhSplitEFractionvsAsyNLocMaxN[2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima > 2 vs |A| | |
179 | ||
77cadd95 | 180 | TH2F * fhMassM02CutNLocMax1 ; //! M02(E) selection, not matched, Mass of split clusters, NLM = 1 |
181 | TH2F * fhMassM02CutNLocMax2 ; //! M02(E) selection, not matched, Mass of split clusters, NLM = 1 | |
182 | TH2F * fhMassM02CutNLocMaxN ; //! M02(E) selection, not matched, Mass of split clusters, NLM > 2 | |
2a77f6f4 | 183 | |
77cadd95 | 184 | TH2F * fhAsymM02CutNLocMax1 ; //! M02(E) selection, not matched, energy asymmetry of split clusters, NLM = 1 |
185 | TH2F * fhAsymM02CutNLocMax2 ; //! M02(E) selection, not matched, energy asymmetry of split clusters, NLM = 2 | |
186 | TH2F * fhAsymM02CutNLocMaxN ; //! M02(E) selection, not matched, energy asymmetry of split clusters, NLM > 2 | |
e671adc2 | 187 | |
77cadd95 | 188 | TH2F * fhMassSplitECutNLocMax1 ; //! 85% of split energy, not matched, Mass of split clusters, NLM = 1 |
189 | TH2F * fhMassSplitECutNLocMax2 ; //! 85% of split energy, not matched, Mass of split clusters, NLM = 1 | |
190 | TH2F * fhMassSplitECutNLocMaxN ; //! 85% of split energy, not matched, Mass of split clusters, NLM > 2 | |
667432ef | 191 | |
de7d73e6 | 192 | TH2F * fhMassM02NLocMax1[8][2] ; //! Mass of splitted clusters when 1 local max vs M02, for E > 8 GeV, 1-6 for different MC particle types |
193 | TH2F * fhMassM02NLocMax2[8][2] ; //! Mass of splitted clusters when 2 local max vs M02, for E > 8 GeV, 1-6 for different MC particle types | |
194 | TH2F * fhMassM02NLocMaxN[8][2] ; //! Mass of splitted clusters when >2 local max vs M02, for E > 8 GeV, 1-6 for different MC particle types | |
0137016b | 195 | |
b8eb40fc | 196 | TH2F * fhMassM02NLocMax1Ebin[4] ; //! Mass of splitted clusters when 1 local max vs M02, 4 E bins, neutral clusters |
197 | TH2F * fhMassM02NLocMax2Ebin[4] ; //! Mass of splitted clusters when 2 local max vs M02, 4 E bins, neutral clusters | |
198 | TH2F * fhMassM02NLocMaxNEbin[4] ; //! Mass of splitted clusters when >2 local max vs M02, 4 E bins, neutral clusters | |
199 | ||
200 | TH2F * fhMassAsyNLocMax1Ebin[4] ; //! Mass of Mass of splitted clusters when 1 local max vs asymmetry, 4 E bins, neutral clusters | |
201 | TH2F * fhMassAsyNLocMax2Ebin[4] ; //! Mass of Mass of splitted clusters when 2 local max vs asymmetry, 4 E bins, neutral clusters | |
202 | TH2F * fhMassAsyNLocMaxNEbin[4] ; //! Mass of Mass of splitted clusters when >2 local max vs asymmetry, 4 E bins, neutral clusters | |
203 | ||
204 | TH2F * fhAsyMCGenRecoNLocMax1EbinPi0[4] ; //! Generated vs reconstructed asymmetry of splitted clusters from pi0 when 1 local max, 4 E bins, neutral clusters | |
205 | TH2F * fhAsyMCGenRecoNLocMax2EbinPi0[4] ; //! Generated vs reconstructed asymmetry of splitted clusters from pi0 when 2 local max, 4 E bins, neutral clusters | |
206 | TH2F * fhAsyMCGenRecoNLocMaxNEbinPi0[4] ; //! Generated vs reconstructed asymmetry of splitted clusters from pi0 when >2 local max, 4 E bins, neutral clusters | |
7b686344 | 207 | |
de7d73e6 | 208 | TH2F * fhMassDispEtaNLocMax1[8][2] ; //! Mass of 2 highest energy cells when 1 local max, vs M02, for E > 8 GeV, 1-6 for different MC particle types |
209 | TH2F * fhMassDispEtaNLocMax2[8][2] ; //! Mass of 2 cells local maxima, vs M02, for E > 8 GeV, 1-6 for different MC particle types | |
210 | TH2F * fhMassDispEtaNLocMaxN[8][2] ; //! Mass of >2 cells local maxima, vs M02, for E > 8 GeV, 1-6 for different MC particle types | |
d2655d46 | 211 | |
e671adc2 | 212 | TH2F * fhMassDispEtaNLocMax1Ebin[4] ; //! Mass of 2 highest energy cells when 1 local max, vs M02, 4 E bins, neutral clusters |
213 | TH2F * fhMassDispEtaNLocMax2Ebin[4] ; //! Mass of 2 cells local maxima, vs M02, 4 E bins, neutral clusters | |
214 | TH2F * fhMassDispEtaNLocMaxNEbin[4] ; //! Mass of >2 cells local maxima, vs M02, 4 E bins, neutral clusters | |
d2655d46 | 215 | |
de7d73e6 | 216 | TH2F * fhMassDispPhiNLocMax1[8][2] ; //! Mass of 2 highest energy cells when 1 local max, vs M02, for E > 8 GeV, 1-6 for different MC particle types |
217 | TH2F * fhMassDispPhiNLocMax2[8][2] ; //! Mass of 2 cells local maxima, vs M02, for E > 8 GeV, 1-6 for different MC particle types | |
218 | TH2F * fhMassDispPhiNLocMaxN[8][2] ; //! Mass of >2 cells local maxima, vs M02, for E > 8 GeV, 1-6 for different MC particle types | |
d2655d46 | 219 | |
e671adc2 | 220 | TH2F * fhMassDispPhiNLocMax1Ebin[4] ; //! Mass of 2 highest energy cells when 1 local max, vs M02, 4 E bins, neutral clusters |
221 | TH2F * fhMassDispPhiNLocMax2Ebin[4] ; //! Mass of 2 cells local maxima, vs M02, 4 E bins, neutral clusters | |
222 | TH2F * fhMassDispPhiNLocMaxNEbin[4] ; //! Mass of >2 cells local maxima, vs M02, 4 E bins, neutral clusters | |
d2655d46 | 223 | |
de7d73e6 | 224 | TH2F * fhMassDispAsyNLocMax1[8][2] ; //! Mass of 2 highest energy cells when 1 local max, vs M02, for E > 8 GeV, 1-6 for different MC particle types |
225 | TH2F * fhMassDispAsyNLocMax2[8][2] ; //! Mass of 2 cells local maxima, vs M02, for E > 8 GeV, 1-6 for different MC particle types | |
226 | TH2F * fhMassDispAsyNLocMaxN[8][2] ; //! Mass of >2 cells local maxima, vs M02, for E > 8 GeV, 1-6 for different MC particle types | |
d2655d46 | 227 | |
e671adc2 | 228 | TH2F * fhMassDispAsyNLocMax1Ebin[4] ; //! Mass of 2 highest energy cells when 1 local max, vs M02, 4 E bins, neutral clusters |
229 | TH2F * fhMassDispAsyNLocMax2Ebin[4] ; //! Mass of 2 cells local maxima, vs M02, 4 E bins, neutral clusters | |
230 | TH2F * fhMassDispAsyNLocMaxNEbin[4] ; //! Mass of >2 cells local maxima, vs M02, 4 E bins, neutral clusters | |
d2655d46 | 231 | |
de7d73e6 | 232 | TH2F * fhNLocMax [8][2] ; //! Number of maxima in cluster vs E, 1-6 for different MC particle types |
233 | TH2F * fhNLocMaxM02Cut[8][2] ; //! Number of maxima in cluster vs E, 1-6 for different MC particle types, after SS cut | |
5c46c992 | 234 | |
de7d73e6 | 235 | TH2F * fhM02NLocMax1 [8][2] ; //! M02 vs E for N max in cluster = 1, 1-6 for different MC particle types |
236 | TH2F * fhM02NLocMax2 [8][2] ; //! M02 vs E for N max in cluster = 2, 1-6 for different MC particle types | |
237 | TH2F * fhM02NLocMaxN [8][2] ; //! M02 vs E for N max in cluster > 2, 1-6 for different MC particle types | |
8e81c2cf | 238 | |
e671adc2 | 239 | TH2F * fhMCAsymM02NLocMax1MCPi0Ebin[4] ; //! M02 vs decay asymmetry for N max in cluster = 1, for 4 energy bins |
240 | TH2F * fhMCAsymM02NLocMax2MCPi0Ebin[4] ; //! M02 vs decay asymmetry for N max in cluster = 2, for 4 energy bins | |
241 | TH2F * fhMCAsymM02NLocMaxNMCPi0Ebin[4] ; //! M02 vs decay asymmetry for N max in cluster > 2, for 4 energy bins | |
8e81c2cf | 242 | |
de7d73e6 | 243 | TH2F * fhMCGenFracNLocMax1[8][2] ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types |
244 | TH2F * fhMCGenFracNLocMax2[8][2] ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types | |
245 | TH2F * fhMCGenFracNLocMaxN[8][2] ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types | |
4914e781 | 246 | |
247 | TH2F * fhMCGenFracNLocMax1NoOverlap[8][2] ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types, no overlap found | |
248 | TH2F * fhMCGenFracNLocMax2NoOverlap[8][2] ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types, no overlap found | |
249 | TH2F * fhMCGenFracNLocMaxNNoOverlap[8][2] ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types, no overlap found | |
250 | ||
b8eb40fc | 251 | TH2F * fhMCGenFracAfterCutsNLocMax1MCPi0 ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster = 1, MCPi0 after M02 and asymmetry cut |
252 | TH2F * fhMCGenFracAfterCutsNLocMax2MCPi0 ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster = 2, MCPi0, after M02 and asymmetry cut | |
253 | TH2F * fhMCGenFracAfterCutsNLocMaxNMCPi0 ; //! E generated particle / E reconstructed vs E reconstructed for N max in cluster > 2, MCPi0, after M02 and asymmetry cut | |
667432ef | 254 | |
de7d73e6 | 255 | TH2F * fhMCGenSplitEFracNLocMax1[8][2] ; //! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types |
256 | TH2F * fhMCGenSplitEFracNLocMax2[8][2] ; //! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types | |
257 | TH2F * fhMCGenSplitEFracNLocMaxN[8][2] ; //! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types | |
667432ef | 258 | |
4914e781 | 259 | TH2F * fhMCGenSplitEFracNLocMax1NoOverlap[8][2];//! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types, no overlap |
260 | TH2F * fhMCGenSplitEFracNLocMax2NoOverlap[8][2];//! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types, no overlap | |
261 | TH2F * fhMCGenSplitEFracNLocMaxNNoOverlap[8][2];//! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types, no overlap | |
262 | ||
667432ef | 263 | TH2F * fhMCGenSplitEFracAfterCutsNLocMax1MCPi0; //! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types |
264 | TH2F * fhMCGenSplitEFracAfterCutsNLocMax2MCPi0; //! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types | |
265 | TH2F * fhMCGenSplitEFracAfterCutsNLocMaxNMCPi0; //! E generated particle / E1+E2 reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types | |
bb2d339b | 266 | |
de7d73e6 | 267 | TH2F * fhMCGenEFracvsSplitEFracNLocMax1[8][2] ; //! E generated particle / E reconstructed vs E1+E2 reconstructed / E reconstructed for N max in cluster = 1, MC pi0 |
268 | TH2F * fhMCGenEFracvsSplitEFracNLocMax2[8][2] ; //! E generated particle / E reconstructed vs E1+E2 reconstructed / E reconstructed for N max in cluster = 2, MC pi0 | |
269 | TH2F * fhMCGenEFracvsSplitEFracNLocMaxN[8][2] ; //! E generated particle / E reconstructed vs E1+E2 reconstructed / E reconstructed for N max in cluster > 2, MC pi0 | |
bb2d339b | 270 | |
de7d73e6 | 271 | TH2F * fhMCGenEvsSplitENLocMax1[8][2] ; //! E generated particle vs E1+E2 for N max in cluster = 1, 1-6 for different MC particle types |
272 | TH2F * fhMCGenEvsSplitENLocMax2[8][2] ; //! E generated particle vs E1+E2 for N max in cluster = 2, 1-6 for different MC particle types | |
273 | TH2F * fhMCGenEvsSplitENLocMaxN[8][2] ; //! E generated particle vs E1+E2 for N max in cluster > 2, 1-6 for different MC particle types | |
bb2d339b | 274 | |
de7d73e6 | 275 | TH2F * fhMCGenFracNLocMaxEbin[8][4] ; //! NLM vs E generated particle / E reconstructed vs E reconstructed 1-6 for different MC particle types, not matched to track |
276 | TH2F * fhMCGenFracNLocMaxEbinMatched[8][4] ; //! NLM vs E generated particle / E reconstructed vs E reconstructed 1-6 for different MC particle types, matched to track | |
53f2c382 | 277 | |
de7d73e6 | 278 | TH2F * fhM02MCGenFracNLocMax1Ebin[8][4] ; //! M02 vs E generated particle / E reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types, not track matched |
279 | TH2F * fhM02MCGenFracNLocMax2Ebin[8][4] ; //! M02 vs E generated particle / E reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types, not track matched | |
280 | TH2F * fhM02MCGenFracNLocMaxNEbin[8][4] ; //! M02 vs E generated particle / E reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types, not track matched | |
8e81c2cf | 281 | |
de7d73e6 | 282 | TH2F * fhMassMCGenFracNLocMax1Ebin[8][4] ; //! Mass vs E generated particle / E reconstructed vs E reconstructed for N max in cluster = 1, 1-6 for different MC particle types, not track matched |
283 | TH2F * fhMassMCGenFracNLocMax2Ebin[8][4] ; //! Mass vs E generated particle / E reconstructed vs E reconstructed for N max in cluster = 2, 1-6 for different MC particle types, not track matched | |
284 | TH2F * fhMassMCGenFracNLocMaxNEbin[8][4] ; //! Mass vs E generated particle / E reconstructed vs E reconstructed for N max in cluster > 2, 1-6 for different MC particle types, not track matched | |
8e81c2cf | 285 | |
de7d73e6 | 286 | TH2F * fhNCellNLocMax1[8][2] ; //! n cells in cluster vs E for N max in cluster = 1, 1-6 for different MC particle types |
287 | TH2F * fhNCellNLocMax2[8][2] ; //! n cells in cluster vs E for N max in cluster = 2, 1-6 for different MC particle types | |
288 | TH2F * fhNCellNLocMaxN[8][2] ; //! n cells in cluster vs E for N max in cluster > 2, 1-6 for different MC particle types | |
992b14a7 | 289 | |
4914e781 | 290 | TH2F * fhNCellMassEHighNLocMax1MCPi0 ; //! n cells in cluster vs mass for high energy clusters, for N max in cluster = 1, for MC pi0 |
291 | TH2F * fhNCellM02EHighNLocMax1MCPi0 ; //! n cells in cluster vs m02 for high energy clusters, for N max in cluster = 1, for MC pi0 | |
292 | TH2F * fhNCellMassELowNLocMax1MCPi0 ; //! n cells in cluster vs mass for low energy clusters, for N max in cluster = 1, for MC pi0 | |
293 | TH2F * fhNCellM02ELowNLocMax1MCPi0 ; //! n cells in cluster vs m02 for low energy clusters, for N max in cluster = 1, for MC pi0 | |
294 | ||
295 | TH2F * fhNCellMassEHighNLocMax2MCPi0 ; //! n cells in cluster vs mass for high energy clusters, for N max in cluster = 2, for MC pi0 | |
296 | TH2F * fhNCellM02EHighNLocMax2MCPi0 ; //! n cells in cluster vs m02 for high energy clusters, for N max in cluster = 2, for MC pi0 | |
297 | TH2F * fhNCellMassELowNLocMax2MCPi0 ; //! n cells in cluster vs mass for low energy clusters, for N max in cluster = 2, for MC pi0 | |
298 | TH2F * fhNCellM02ELowNLocMax2MCPi0 ; //! n cells in cluster vs m02 for low energy clusters, for N max in cluster = 2, for MC pi0 | |
299 | ||
300 | TH2F * fhNCellMassEHighNLocMaxNMCPi0 ; //! n cells in cluster vs mass for high energy clusters, for N max in cluster > 2, for MC pi0 | |
301 | TH2F * fhNCellM02EHighNLocMaxNMCPi0 ; //! n cells in cluster vs m02 for high energy clusters, for N max in cluster > 2, for MC pi0 | |
302 | TH2F * fhNCellMassELowNLocMaxNMCPi0 ; //! n cells in cluster vs mass for low energy clusters, for N max in cluster > 2, for MC pi0 | |
303 | TH2F * fhNCellM02ELowNLocMaxNMCPi0 ; //! n cells in cluster vs m02 for low energy clusters, for N max in cluster > 2, for MC pi0 | |
304 | ||
c8710850 | 305 | TH2F * fhM02Pi0NLocMax1[8][2] ; //! M02 for Mass around pi0, N Local Maxima = 1 |
306 | TH2F * fhM02EtaNLocMax1[8][2] ; //! M02 for Mass around eta, N Local Maxima = 1 | |
307 | TH2F * fhM02ConNLocMax1[8][2] ; //! M02 for Mass around close to 0, N Local Maxima = 1 | |
308 | ||
309 | TH2F * fhM02Pi0NLocMax2[8][2] ; //! M02 for Mass around pi0, N Local Maxima = 2 | |
310 | TH2F * fhM02EtaNLocMax2[8][2] ; //! M02 for Mass around eta, N Local Maxima = 2 | |
311 | TH2F * fhM02ConNLocMax2[8][2] ; //! M02 for Mass around close to 0, N Local Maxima = 2 | |
5c46c992 | 312 | |
c8710850 | 313 | TH2F * fhM02Pi0NLocMaxN[8][2] ; //! M02 for Mass around pi0, N Local Maxima > 2 |
314 | TH2F * fhM02EtaNLocMaxN[8][2] ; //! M02 for Mass around eta, N Local Maxima > 2 | |
315 | TH2F * fhM02ConNLocMaxN[8][2] ; //! M02 for Mass around close to 0, N Local Maxima > 2 | |
fc01318e | 316 | |
c8710850 | 317 | TH2F * fhMassPi0NLocMax1[8][2] ; //! Mass for selected pi0, N Local Maxima = 1 |
318 | TH2F * fhMassEtaNLocMax1[8][2] ; //! Mass for selected around eta, N Local Maxima = 1 | |
319 | TH2F * fhMassConNLocMax1[8][2] ; //! Mass for selected around close to 0, N Local Maxima = 1 | |
e671adc2 | 320 | |
c8710850 | 321 | TH2F * fhMassPi0NLocMax2[8][2] ; //! Mass for selected around pi0, N Local Maxima = 2 |
322 | TH2F * fhMassEtaNLocMax2[8][2] ; //! Mass for selected around eta, N Local Maxima = 2 | |
323 | TH2F * fhMassConNLocMax2[8][2] ; //! Mass for selected around close to 0, N Local Maxima = 2 | |
bb2d339b | 324 | |
c8710850 | 325 | TH2F * fhMassPi0NLocMaxN[8][2] ; //! Mass for selected around pi0, N Local Maxima > 2 |
326 | TH2F * fhMassEtaNLocMaxN[8][2] ; //! Mass for selected around eta, N Local Maxima > 2 | |
327 | TH2F * fhMassConNLocMaxN[8][2] ; //! Mass for selected around close to 0, N Local Maxima > 2 | |
bb2d339b | 328 | |
74858845 | 329 | TH2F * fhMassAfterCutsNLocMax1[8][2] ; //! Mass after M02, asymmetry cuts for pi0, N Local Maxima = 1 |
330 | TH2F * fhMassAfterCutsNLocMax2[8][2] ; //! Mass after M02, asymmetry cuts for pi0, N Local Maxima = 2 | |
331 | TH2F * fhMassAfterCutsNLocMaxN[8][2] ; //! Mass after M02, asymmetry cuts for pi0, N Local Maxima > 2 | |
167f2534 | 332 | |
c8710850 | 333 | TH2F * fhAsyPi0NLocMax1[8][2] ; //! Asy for Mass around pi0, N Local Maxima = 1 |
334 | TH2F * fhAsyEtaNLocMax1[8][2] ; //! Asy for Mass around eta, N Local Maxima = 1 | |
335 | TH2F * fhAsyConNLocMax1[8][2] ; //! Asy for Mass around close to 0, N Local Maxima = 1 | |
bb2d339b | 336 | |
c8710850 | 337 | TH2F * fhAsyPi0NLocMax2[8][2] ; //! Asy for Mass around pi0, N Local Maxima = 2 |
338 | TH2F * fhAsyEtaNLocMax2[8][2] ; //! Asy for Mass around eta, N Local Maxima = 2 | |
339 | TH2F * fhAsyConNLocMax2[8][2] ; //! Asy for Mass around close to 0, N Local Maxima = 2 | |
fc01318e | 340 | |
c8710850 | 341 | TH2F * fhAsyPi0NLocMaxN[8][2] ; //! Asy for Mass around pi0, N Local Maxima > 2 |
342 | TH2F * fhAsyEtaNLocMaxN[8][2] ; //! Asy for Mass around eta, N Local Maxima > 2 | |
343 | TH2F * fhAsyConNLocMaxN[8][2] ; //! Asy for Mass around close to 0, N Local Maxima > 2 | |
e671adc2 | 344 | |
de7d73e6 | 345 | TH2F * fhSplitEFractionNLocMax1[8][2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima = 1 |
346 | TH2F * fhSplitEFractionNLocMax2[8][2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima = 2 | |
347 | TH2F * fhSplitEFractionNLocMaxN[8][2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima > 2 | |
667432ef | 348 | |
74858845 | 349 | TH2F * fhSplitEFractionAfterCutsNLocMax1[8][2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima = 1, after M02 and asymmetry cut |
350 | TH2F * fhSplitEFractionAfterCutsNLocMax2[8][2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima = 2, after M02 and asymmetry cut | |
351 | TH2F * fhSplitEFractionAfterCutsNLocMaxN[8][2] ; //! sum of splitted cluster energy / cluster energy for N Local Maxima > 2, after M02 and asymmetry cut | |
667432ef | 352 | |
de7d73e6 | 353 | TH2F * fhMassSplitEFractionNLocMax1Ebin[8][4] ; //! Mass vs sum of splitted cluster energy / cluster energy for N max in cluster = 1, 1-6 for different MC particle types, not track matched |
354 | TH2F * fhMassSplitEFractionNLocMax2Ebin[8][4] ; //! Mass vs sum of splitted cluster energy / cluster energy for N max in cluster = 2, 1-6 for different MC particle types, not track matched | |
355 | TH2F * fhMassSplitEFractionNLocMaxNEbin[8][4] ; //! Mass vs sum of splitted cluster energy / cluster energy for N max in cluster > 2, 1-6 for different MC particle types, not track matched | |
5094c724 | 356 | |
c8710850 | 357 | TH2F * fhAnglePairNLocMax1[2] ; //! pair opening angle vs E |
358 | TH2F * fhAnglePairNLocMax2[2] ; //! pair opening angle vs E | |
359 | TH2F * fhAnglePairNLocMaxN[2] ; //! pair opening angle vs E | |
360 | ||
361 | TH2F * fhAnglePairMassNLocMax1[2] ; //! pair opening angle vs Mass for E > 7 GeV | |
362 | TH2F * fhAnglePairMassNLocMax2[2] ; //! pair opening angle vs Mass for E > 7 GeV | |
363 | TH2F * fhAnglePairMassNLocMaxN[2] ; //! pair opening angle vs Mass for E > 7 GeV | |
364 | ||
365 | TH2F * fhTrackMatchedDEtaNLocMax1[8] ; //! Eta distance between track and cluster vs cluster E, 1 local maximum | |
366 | TH2F * fhTrackMatchedDPhiNLocMax1[8] ; //! Phi distance between track and cluster vs cluster E, 1 local maximum | |
367 | TH2F * fhTrackMatchedDEtaNLocMax2[8] ; //! Eta distance between track and cluster vs cluster E, 2 local maximum | |
368 | TH2F * fhTrackMatchedDPhiNLocMax2[8] ; //! Phi distance between track and cluster vs cluster E, 2 local maximum | |
369 | TH2F * fhTrackMatchedDEtaNLocMaxN[8] ; //! Eta distance between track and cluster vs cluster E, more than 2 local maximum | |
370 | TH2F * fhTrackMatchedDPhiNLocMaxN[8] ; //! Phi distance between track and cluster vs cluster E, more than 2 local maximum | |
b2e375c7 | 371 | |
372 | TH2F * fhTrackMatchedDEtaNLocMax1Pos[8] ; //! Eta distance between track and cluster vs cluster E, 1 local maximum | |
373 | TH2F * fhTrackMatchedDPhiNLocMax1Pos[8] ; //! Phi distance between track and cluster vs cluster E, 1 local maximum | |
374 | TH2F * fhTrackMatchedDEtaNLocMax2Pos[8] ; //! Eta distance between track and cluster vs cluster E, 2 local maximum | |
375 | TH2F * fhTrackMatchedDPhiNLocMax2Pos[8] ; //! Phi distance between track and cluster vs cluster E, 2 local maximum | |
376 | TH2F * fhTrackMatchedDEtaNLocMaxNPos[8] ; //! Eta distance between track and cluster vs cluster E, more than 2 local maximum | |
377 | TH2F * fhTrackMatchedDPhiNLocMaxNPos[8] ; //! Phi distance between track and cluster vs cluster E, more than 2 local maximum | |
378 | ||
379 | TH2F * fhTrackMatchedDEtaNLocMax1Neg[8] ; //! Eta distance between track and cluster vs cluster E, 1 local maximum | |
380 | TH2F * fhTrackMatchedDPhiNLocMax1Neg[8] ; //! Phi distance between track and cluster vs cluster E, 1 local maximum | |
381 | TH2F * fhTrackMatchedDEtaNLocMax2Neg[8] ; //! Eta distance between track and cluster vs cluster E, 2 local maximum | |
382 | TH2F * fhTrackMatchedDPhiNLocMax2Neg[8] ; //! Phi distance between track and cluster vs cluster E, 2 local maximum | |
383 | TH2F * fhTrackMatchedDEtaNLocMaxNNeg[8] ; //! Eta distance between track and cluster vs cluster E, more than 2 local maximum | |
384 | TH2F * fhTrackMatchedDPhiNLocMaxNNeg[8] ; //! Phi distance between track and cluster vs cluster E, more than 2 local maximum | |
385 | ||
17f5b4b6 | 386 | TH2F * fhCentralityPi0NLocMax1[8][2] ; //! Centrality for selected pi0, N Local Maxima = 1 |
387 | TH2F * fhCentralityEtaNLocMax1[8][2] ; //! Centrality for selected eta, N Local Maxima = 1 | |
388 | TH2F * fhCentralityPi0NLocMax2[8][2] ; //! Centrality for selected pi0, N Local Maxima = 2 | |
389 | TH2F * fhCentralityEtaNLocMax2[8][2] ; //! Centrality for selected eta, N Local Maxima = 2 | |
390 | TH2F * fhCentralityPi0NLocMaxN[8][2] ; //! Centrality for selected pi0, N Local Maxima > 2 | |
391 | TH2F * fhCentralityEtaNLocMaxN[8][2] ; //! Centrality for selected eta, N Local Maxima > 2 | |
c8710850 | 392 | |
393 | TH2F * fhEventPlanePi0NLocMax1 ; //! Event plane for selected pi0, N Local Maxima = 1 | |
394 | TH2F * fhEventPlaneEtaNLocMax1 ; //! Event plane for selected eta, N Local Maxima = 1 | |
395 | TH2F * fhEventPlanePi0NLocMax2 ; //! Event plane for selected pi0, N Local Maxima = 2 | |
396 | TH2F * fhEventPlaneEtaNLocMax2 ; //! Event plane for selected eta, N Local Maxima = 2 | |
397 | TH2F * fhEventPlanePi0NLocMaxN ; //! Event plane for selected pi0, N Local Maxima > 2 | |
398 | TH2F * fhEventPlaneEtaNLocMaxN ; //! Event plane for selected eta, N Local Maxima > 2 | |
399 | ||
9554fc65 | 400 | TH2F * fhClusterEtaPhiNLocMax1 ; //! Eta vs Phi of clusters with N Local Maxima = 1, E > 8 GeV |
401 | TH2F * fhClusterEtaPhiNLocMax2 ; //! Eta vs Phi of clusters with N Local Maxima = 2, E > 8 GeV | |
402 | TH2F * fhClusterEtaPhiNLocMaxN ; //! Eta vs Phi of clusters with N Local Maxima > 2, E > 8 GeV | |
403 | TH2F * fhPi0EtaPhiNLocMax1 ; //! Eta vs Phi of pi0's with N Local Maxima = 1, E > 8 GeV | |
404 | TH2F * fhPi0EtaPhiNLocMax2 ; //! Eta vs Phi of pi0's with N Local Maxima = 2, E > 8 GeV | |
405 | TH2F * fhPi0EtaPhiNLocMaxN ; //! Eta vs Phi of pi0's with N Local Maxima > N, E > 8 GeV | |
406 | TH2F * fhEtaEtaPhiNLocMax1 ; //! Eta vs Phi of eta's with N Local Maxima = 1, E > 8 GeV | |
407 | TH2F * fhEtaEtaPhiNLocMax2 ; //! Eta vs Phi of eta's with N Local Maxima = 2, E > 8 GeV | |
408 | TH2F * fhEtaEtaPhiNLocMaxN ; //! Eta vs Phi of eta's with N Local Maxima > N, E > 8 GeV | |
409 | ||
dbe09c26 | 410 | TH2F * fhPi0CellE[3] ; //! pi0's energy vs cluster cell energy with NLM = 1, = 2, > 2 |
411 | TH2F * fhPi0CellEFrac[3] ; //! pi0's energy vs cluster cell energy fraction with NLM = 1, = 2, > 2 | |
412 | TH2F * fhPi0CellLogEFrac[3] ; //! pi0's energy vs cluster log cell energy fraction with NLM = 1, = 2, > 2 | |
19391b8c | 413 | TH2F * fhPi0CellEMaxEMax2Frac [3]; //! pi0's energy vs fraction of 2 main maxima energy with NLM = 1, = 2, > 2 |
414 | TH2F * fhPi0CellEMaxClusterFrac [3]; //! pi0's energy vs energy fraction of main LM and cluster energy with NLM = 1, = 2, > 2 | |
415 | TH2F * fhPi0CellEMax2ClusterFrac[3]; //! pi0's energy vs energy fraction of second LM and cluster energy with NLM = 1, = 2, > 2 | |
416 | TH2F * fhPi0CellEMaxFrac [3]; //! pi0's energy vs energy fraction of main LM and cluster cell energy with NLM = 1, = 2, > 2 | |
417 | TH2F * fhPi0CellEMax2Frac [3]; //! pi0's energy vs energy fraction of second LM and cluster cell energy with NLM = 1, = 2, > 2 | |
418 | ||
dbe09c26 | 419 | TH2F * fhM02WeightPi0[3][10] ; //! M02 for selected pi0 with different weight, with NLM = 1, = 2, > 2 |
19391b8c | 420 | TH2F * fhM02ECellCutPi0[3][10] ; //! M02 for selected pi0 with different cut on cell energy, with NLM = 1, = 2, > 2 |
dbe09c26 | 421 | |
a1fd1b69 | 422 | TH2F * fhPi0EPairDiffTimeNLM1; //! E vs Pair of clusters time difference vs E, for selected pi0, NLM=1 |
423 | TH2F * fhPi0EPairDiffTimeNLM2; //! E vs Pair of clusters time difference vs E, for selected pi0, NLM=2 | |
424 | TH2F * fhPi0EPairDiffTimeNLMN; //! E vs Pair of clusters time difference vs E, for selected pi0, NLM>2 | |
425 | TH2F * fhEtaEPairDiffTimeNLM1; //! E vs Pair of clusters time difference vs E, for selected eta, NLM=1 | |
426 | TH2F * fhEtaEPairDiffTimeNLM2; //! E vs Pair of clusters time difference vs E, for selected eta, NLM=2 | |
427 | TH2F * fhEtaEPairDiffTimeNLMN; //! E vs Pair of clusters time difference vs E, for selected eta, NLM>2 | |
428 | ||
b2e375c7 | 429 | TH2F * fhMCEM02Overlap0[3][8]; //! E vs M02 for different MC origin, no other MC particles contributes, neutral cluster |
430 | TH2F * fhMCEM02Overlap1[3][8]; //! E vs M02 for different MC origin, 1 other MC particles contributes, neutral cluster | |
431 | TH2F * fhMCEM02OverlapN[3][8]; //! E vs M02 for different MC origin, N other MC particles contributes, neutral cluster | |
432 | TH2F * fhMCEM02Overlap0Match[3][8]; //! E vs M02 for different MC origin, no other MC particles contributes, charged cluster | |
433 | TH2F * fhMCEM02Overlap1Match[3][8]; //! E vs M02 for different MC origin, 1 other MC particles contributes, charged cluster | |
434 | TH2F * fhMCEM02OverlapNMatch[3][8]; //! E vs M02 for different MC origin, N other MC particles contributes, charged cluster | |
435 | ||
436 | TH2F * fhMCEMassOverlap0[3][8]; //! E vs Mass for different MC origin, no other MC particles contributes, neutral cluster | |
437 | TH2F * fhMCEMassOverlap1[3][8]; //! E vs Mass for different MC origin, 1 other MC particles contributes, neutral cluster | |
438 | TH2F * fhMCEMassOverlapN[3][8]; //! E vs Mass for different MC origin, N other MC particles contributes, neutral cluster | |
439 | TH2F * fhMCEMassOverlap0Match[3][8]; //! E vs Mass for different MC origin, no other MC particles contributes, charged cluster | |
440 | TH2F * fhMCEMassOverlap1Match[3][8]; //! E vs Mass for different MC origin, 1 other MC particles contributes, charged cluster | |
441 | TH2F * fhMCEMassOverlapNMatch[3][8]; //! E vs Mass for different MC origin, N other MC particles contributes, charged cluster | |
442 | ||
83351853 | 443 | TH2F * fhMCESplitEFracOverlap0[3][8]; //! E vs sum of splitted cluster energy / cluster energy for different MC origin, no other MC particles contributes, neutral cluster |
444 | TH2F * fhMCESplitEFracOverlap1[3][8]; //! E vs sum of splitted cluster energy / cluster energy for different MC origin, 1 other MC particles contributes, neutral cluster | |
4914e781 | 445 | TH2F * fhMCESplitEFracOverlapN[3][8]; //! E vs sum of splitted cluster energy / cluster energy for different MC origin, N other MC particles contributes, neutral cluster |
83351853 | 446 | TH2F * fhMCESplitEFracOverlap0Match[3][8]; //! E vs sum of splitted cluster energy / cluster energy for different MC origin, no other MC particles contributes, charged cluster |
447 | TH2F * fhMCESplitEFracOverlap1Match[3][8]; //! E vs sum of splitted cluster energy / cluster energy for different MC origin, 1 other MC particles contributes, charged cluster | |
4914e781 | 448 | TH2F * fhMCESplitEFracOverlapNMatch[3][8]; //! E vs sum of splitted cluster energy / cluster energy for different MC origin, N other MC particles contributes, charged cluster |
449 | ||
450 | TH2F * fhMCEAsymOverlap0[3][8]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, no other MC particles contributes, neutral cluster | |
451 | TH2F * fhMCEAsymOverlap1[3][8]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, 1 other MC particles contributes, neutral cluster | |
452 | TH2F * fhMCEAsymOverlapN[3][8]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, N other MC particles contributes, neutral cluster | |
453 | TH2F * fhMCEAsymOverlap0Match[3][8]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, no other MC particles contributes, charged cluster | |
454 | TH2F * fhMCEAsymOverlap1Match[3][8]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, 1 other MC particles contributes, charged cluster | |
455 | TH2F * fhMCEAsymOverlapNMatch[3][8]; //! E vs sum of splitted cluster energy asymmetry for different MC origin, N other MC particles contributes, charged cluster | |
456 | ||
457 | TH2F * fhMCEEpriOverlap0[3][8]; //! E reco vs primary for different MC origin, no other MC particles contributes, neutral cluster | |
458 | TH2F * fhMCEEpriOverlap1[3][8]; //! E reco vs primary for different MC origin, 1 other MC particles contributes, neutral cluster | |
459 | TH2F * fhMCEEpriOverlapN[3][8]; //! E reco vs primary for different MC origin, N other MC particles contributes, neutral cluster | |
460 | TH2F * fhMCEEpriOverlap0Match[3][8]; //! E reco vs primary for different MC origin, no other MC particles contributes, charged cluster | |
461 | TH2F * fhMCEEpriOverlap1Match[3][8]; //! E reco vs primary for different MC origin, 1 other MC particles contributes, charged cluster | |
462 | TH2F * fhMCEEpriOverlapNMatch[3][8]; //! E reco vs primary for different MC origin, N other MC particles contributes, charged cluster | |
83351853 | 463 | |
b2e375c7 | 464 | TH2F * fhMCPi0MassM02Overlap0[3][4]; //! MC Pi0 M02 vs Mass for different MC origin, no other MC particles contributes, neutral cluster, 4 E bins |
465 | TH2F * fhMCPi0MassM02Overlap1[3][4]; //! MC Pi0 M02 vs Mass for different MC origin, 1 other MC particles contributes, neutral cluster, 4 E bins | |
466 | TH2F * fhMCPi0MassM02OverlapN[3][4]; //! MC Pi0 M02 vs Mass for different MC origin, N other MC particles contributes, neutral cluster, 4 E bins | |
467 | TH2F * fhMCPi0MassM02Overlap0Match[3][4]; //! MC Pi0 M02 vs Mass for different MC origin, no other MC particles contributes, charged cluster, 4 E bins | |
468 | TH2F * fhMCPi0MassM02Overlap1Match[3][4]; //! MC Pi0 M02 vs Mass for different MC origin, 1 other MC particles contributes, charged cluster, 4 E bins | |
469 | TH2F * fhMCPi0MassM02OverlapNMatch[3][4]; //! MC Pi0 M02 vs Mass for different MC origin, N other MC particles contributes, charged cluster, 4 E bins | |
470 | ||
471 | TH2F * fhMCENOverlaps[3][8]; //! E vs number of Overlaps in MC, neutral cluster | |
472 | TH2F * fhMCENOverlapsMatch[3][8]; //! E vs number of Overlaps in MC, charged cluster | |
473 | ||
474 | TH2F * fhMCPi0HighNLMPair; //! E vs NLM when cluster originated in pi0 merging and highest energy local maxima correspond to 2 photons | |
475 | TH2F * fhMCPi0LowNLMPair; //! E vs NLM when cluster originated in pi0 merging and a pair of local maxima except highest energy correspond to 2 photons | |
476 | TH2F * fhMCPi0AnyNLMPair; //! E vs NLM when cluster originated in pi0 merging and a both highest energy pairs and other pairs correspond to 2 photons | |
477 | TH2F * fhMCPi0NoneNLMPair; //! E vs NLM when cluster originated in pi0 merging and a both no NLM corresponds to the photons | |
b2e375c7 | 478 | // No match between highest energy local maxima and highest energy MC particle |
479 | TH2F * fhMCPi0HighNLMPairNoMCMatch; //! E vs NLM when cluster originated in pi0 merging and highest energy local maxima correspond to 2 photons | |
480 | TH2F * fhMCPi0LowNLMPairNoMCMatch; //! E vs NLM when cluster originated in pi0 merging and a pair of local maxima except highest energy correspond to 2 photons | |
481 | TH2F * fhMCPi0AnyNLMPairNoMCMatch; //! E vs NLM when cluster originated in pi0 merging and a both highest energy pairs and other pairs correspond to 2 photons | |
482 | TH2F * fhMCPi0NoneNLMPairNoMCMatch; //! E vs NLM when cluster originated in pi0 merging and a both no NLM corresponds to the photons | |
36769d30 | 483 | |
484 | TH2F * fhMCPi0HighNLMPairOverlap; //! E vs NLM when cluster originated in pi0 merging and highest energy local maxima correspond to 2 photons, overlap | |
485 | TH2F * fhMCPi0LowNLMPairOverlap; //! E vs NLM when cluster originated in pi0 merging and a pair of local maxima except highest energy correspond to 2 photons, overlap | |
486 | TH2F * fhMCPi0AnyNLMPairOverlap; //! E vs NLM when cluster originated in pi0 merging and a both highest energy pairs and other pairs correspond to 2 photons, overlap | |
487 | TH2F * fhMCPi0NoneNLMPairOverlap; //! E vs NLM when cluster originated in pi0 merging and a both no NLM corresponds to the photons, overlap | |
488 | // No match between highest energy local maxima and highest energy MC particle | |
489 | TH2F * fhMCPi0HighNLMPairNoMCMatchOverlap; //! E vs NLM when cluster originated in pi0 merging and highest energy local maxima correspond to 2 photons, overlap | |
490 | TH2F * fhMCPi0LowNLMPairNoMCMatchOverlap; //! E vs NLM when cluster originated in pi0 merging and a pair of local maxima except highest energy correspond to 2 photons, overlap | |
491 | TH2F * fhMCPi0AnyNLMPairNoMCMatchOverlap; //! E vs NLM when cluster originated in pi0 merging and a both highest energy pairs and other pairs correspond to 2 photons, overlap | |
492 | TH2F * fhMCPi0NoneNLMPairNoMCMatchOverlap; //! E vs NLM when cluster originated in pi0 merging and a both no NLM corresponds to the photons, overlap | |
493 | ||
83351853 | 494 | TH2F * fhMCPi0DecayPhotonHitHighLM; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit the cell local maxima |
495 | TH2F * fhMCPi0DecayPhotonAdjHighLM; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima | |
496 | TH2F * fhMCPi0DecayPhotonHitOtherLM; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high | |
497 | TH2F * fhMCPi0DecayPhotonAdjOtherLM; //! E vs NLM when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high | |
36769d30 | 498 | TH2F * fhMCPi0DecayPhotonAdjacent; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit adjacen cells, not 2 LM |
83351853 | 499 | TH2F * fhMCPi0DecayPhotonHitNoLM; //! E vs NLM when cluster originated in pi0 merging and MC photon decay do not hit the cell local maximas |
b2e375c7 | 500 | |
36769d30 | 501 | TH2F * fhMCPi0DecayPhotonHitHighLMOverlap; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit the cell local maxima, overlap |
502 | TH2F * fhMCPi0DecayPhotonAdjHighLMOverlap; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit the adjacent cell local maxima, overlap | |
503 | TH2F * fhMCPi0DecayPhotonHitOtherLMOverlap; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit the cell local maximas, not high, overlap | |
504 | TH2F * fhMCPi0DecayPhotonAdjOtherLMOverlap; //! E vs NLM when cluster originated in pi0 merging and MC photon decay do not hit the adjacent cell local maximas, not high, overlap | |
505 | TH2F * fhMCPi0DecayPhotonAdjacentOverlap; //! E vs NLM when cluster originated in pi0 merging and MC photon decay hit adjacen cells, not 2 LM, overlap | |
506 | TH2F * fhMCPi0DecayPhotonHitNoLMOverlap; //! E vs NLM when cluster originated in pi0 merging and MC photon decay do not hit the cell local maximas, overlap | |
507 | ||
b2e375c7 | 508 | TH2F * fhMCEOverlapType; //! what particles overlap with pi0, neutral clusters |
509 | TH2F * fhMCEOverlapTypeMatch; //! what particles overlap with pi0, charged clusters | |
dbe09c26 | 510 | |
2a77f6f4 | 511 | AliAnaInsideClusterInvariantMass( const AliAnaInsideClusterInvariantMass & split) ; // cpy ctor |
512 | AliAnaInsideClusterInvariantMass & operator = (const AliAnaInsideClusterInvariantMass & split) ; // cpy assignment | |
992b14a7 | 513 | |
4914e781 | 514 | ClassDef(AliAnaInsideClusterInvariantMass,22) |
992b14a7 | 515 | |
516 | } ; | |
517 | ||
518 | #endif //ALIANAINSIDECLUSTERINVARIANTMASS_H | |
519 | ||
520 | ||
521 |