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root/cvsroot/UserCode/MitAna/DataTree/interface/Electron.h
Revision: 1.20
Committed: Thu Nov 27 16:14:37 2008 UTC (16 years, 5 months ago) by loizides
Content type: text/plain
Branch: MAIN
Changes since 1.19: +3 -4 lines
Log Message: 
Fix name of accessor.

File Contents

# User Rev Content
1 bendavid 1.1 //--------------------------------------------------------------------------------------------------
2 loizides 1.20 // $Id: Electron.h,v 1.19 2008/11/12 18:56:24 peveraer Exp $
3 bendavid 1.1 //
4 paus 1.3 // Electron
5 bendavid 1.1 //
6     // Details to be worked out...
7     //
8 sixie 1.13 // Authors: C.Loizides, J.Bendavid, S.Xie
9 bendavid 1.1 //--------------------------------------------------------------------------------------------------
10    
11 loizides 1.6 #ifndef DATATREE_ELECTRON_H
12     #define DATATREE_ELECTRON_H
13    
14 sixie 1.13 #include "MitAna/DataTree/interface/SuperCluster.h"
15 bendavid 1.11 #include "MitAna/DataTree/interface/ChargedParticle.h"
16 loizides 1.6
17 bendavid 1.1 namespace mithep
18     {
19 bendavid 1.11 class Electron : public ChargedParticle
20 bendavid 1.1 {
21     public:
22     Electron() {}
23     ~Electron() {}
24    
25 sixie 1.14 const Track *BestTrk() const;
26     const Track *GsfTrk() const;
27     const Track *TrackerTrk() const;
28     const SuperCluster *SCluster() const;
29     FourVector Mom() const;
30     const Track *Trk() const { return BestTrk(); }
31 bendavid 1.18 Double_t E() const;
32     Double_t P() const;
33     Double_t Pt() const;
34     Double_t Px() const;
35     Double_t Py() const;
36     Double_t Pz() const;
37 sixie 1.14
38 sixie 1.13 Double_t Mass() const { return 0.51099892e-3; }
39     Double_t ESuperClusterOverP() const { return fESuperClusterOverP; }
40     Double_t ESeedClusterOverPout() const { return fESeedClusterOverPout; }
41 sixie 1.15 Double_t ESeedClusterOverPIn() const;
42     Double_t PIn() const { return fPIn; }
43     Double_t POut() const { return fPOut; }
44 sixie 1.13 Double_t DeltaEtaSuperClusterTrackAtVtx() const { return fDeltaEtaSuperClTrkAtVtx; }
45     Double_t DeltaEtaSeedClusterTrackAtCalo() const { return fDeltaEtaSeedClTrkAtCalo; }
46     Double_t DeltaPhiSuperClusterTrackAtVtx() const { return fDeltaPhiSuperClTrkAtVtx; }
47     Double_t DeltaPhiSeedClusterTrackAtCalo() const { return fDeltaPhiSeedClTrkAtCalo; }
48     Double_t HadronicOverEm() const { return fHadronicOverEm; }
49     Double_t IsEnergyScaleCorrected() const { return fIsEnergyScaleCorrected; }
50     Double_t IsMomentumCorrected() const { return fIsMomentumCorrected; }
51     Double_t NumberOfClusters() const { return fNumberOfClusters; }
52     Double_t Classification() const { return fClassification; }
53     Double_t E33() const { return fE33; }
54     Double_t E55() const { return fE55; }
55     Double_t CovEtaEta() const { return fCovEtaEta; }
56     Double_t CovEtaPhi() const { return fCovEtaPhi; }
57     Double_t CovPhiPhi() const { return fCovPhiPhi; }
58 peveraer 1.19 Double_t CoviEtaiEta() const { return fCoviEtaiEta; }
59 sixie 1.13 Double_t CaloIsolation() const { return fCaloIsolation; }
60 sixie 1.16 Double_t CaloTowerIsolation() const { return fCaloTowerIsolation; }
61 sixie 1.13 Double_t TrackIsolation() const { return fTrackIsolation; }
62 sixie 1.17 Double_t EcalJurassicIsolation() const { return fEcalJurassicIsolation; }
63 loizides 1.20 Double_t HcalIsolation() const { return fHcalJurassicIsolation; }
64 sixie 1.15 Double_t PassLooseID() const { return fPassLooseID; }
65     Double_t PassTightID() const { return fPassTightID; }
66     Double_t IDLikelihood() const { return fIDLikelihood; }
67 sixie 1.13
68     void SetGsfTrk(Track* t) { fGsfTrackRef = t; }
69     void SetTrackerTrk(Track* t) { fTrackerTrackRef = t; }
70     void SetSuperCluster(SuperCluster* sc) { fSuperClusterRef = sc; }
71     void SetESuperClusterOverP(Double_t x) { fESuperClusterOverP = x; }
72     void SetESeedClusterOverPout(Double_t x) { fESeedClusterOverPout = x; }
73 sixie 1.15 void SetPIn(Double_t PIn) { fPIn = PIn; }
74     void SetPOut(Double_t POut) { fPOut = POut; }
75 sixie 1.13 void SetDeltaEtaSuperClusterTrackAtVtx(Double_t x) { fDeltaEtaSuperClTrkAtVtx = x; }
76     void SetDeltaEtaSeedClusterTrackAtCalo(Double_t x) { fDeltaEtaSeedClTrkAtCalo = x; }
77     void SetDeltaPhiSuperClusterTrackAtVtx(Double_t x) { fDeltaPhiSuperClTrkAtVtx = x; }
78     void SetDeltaPhiSeedClusterTrackAtCalo(Double_t x) { fDeltaPhiSeedClTrkAtCalo = x; }
79     void SetHadronicOverEm(Double_t x) { fHadronicOverEm = x; }
80     void SetIsEnergyScaleCorrected(Double_t x) { fIsEnergyScaleCorrected = x; }
81     void SetIsMomentumCorrected(Double_t x) { fIsMomentumCorrected = x; }
82     void SetNumberOfClusters(Double_t x) { fNumberOfClusters = x; }
83     void SetClassification(Double_t x) { fClassification = x; }
84     void SetE33(Double_t E33) { fE33 = E33; }
85     void SetE55(Double_t E55) { fE55 = E55; }
86     void SetCovEtaEta(Double_t CovEtaEta) { fCovEtaEta = CovEtaEta; }
87     void SetCovEtaPhi(Double_t CovEtaPhi) { fCovEtaPhi = CovEtaPhi; }
88     void SetCovPhiPhi(Double_t CovPhiPhi) { fCovPhiPhi = CovPhiPhi; }
89 peveraer 1.19 void SetCoviEtaiEta(Double_t CoviEtaiEta) { fCoviEtaiEta = CoviEtaiEta; }
90 sixie 1.13 void SetCaloIsolation(Double_t CaloIsolation) { fCaloIsolation = CaloIsolation; }
91 sixie 1.16 void SetCaloTowerIsolation(Double_t TowerIso) { fCaloTowerIsolation = TowerIso; }
92 sixie 1.13 void SetTrackIsolation(Double_t TrackIsolation) { fTrackIsolation = TrackIsolation;}
93 sixie 1.17 void SetEcalJurassicIsolation(Double_t iso ) { fEcalJurassicIsolation = iso; }
94 loizides 1.20 void SetHcalIsolation(Double_t iso ) { fHcalJurassicIsolation = iso; }
95 sixie 1.15 void SetPassLooseID(Double_t passLooseID) { fPassLooseID = passLooseID; }
96     void SetPassTightID(Double_t passTightID) { fPassTightID = passTightID; }
97     void SetIDLikelihood(Double_t likelihood) { fIDLikelihood = likelihood; }
98 sixie 1.13
99 loizides 1.8 protected:
100 loizides 1.9 TRef fGsfTrackRef; //global combined track reference
101     TRef fTrackerTrackRef; //tracker track reference
102 sixie 1.13 TRef fSuperClusterRef; //superCluster
103    
104     Double_t fESuperClusterOverP;
105     Double_t fESeedClusterOverPout;
106     Double_t fDeltaEtaSuperClTrkAtVtx;
107     Double_t fDeltaEtaSeedClTrkAtCalo;
108     Double_t fDeltaPhiSuperClTrkAtVtx;
109     Double_t fDeltaPhiSeedClTrkAtCalo;
110     Double_t fHadronicOverEm;
111     Double_t fIsEnergyScaleCorrected;
112     Double_t fIsMomentumCorrected;
113     Double_t fNumberOfClusters;
114     Double_t fClassification;
115     Double_t fE33;
116     Double_t fE55;
117     Double_t fCovEtaEta;
118 peveraer 1.19 Double_t fCoviEtaiEta;
119 sixie 1.13 Double_t fCovEtaPhi;
120     Double_t fCovPhiPhi;
121     Double_t fCaloIsolation;
122 sixie 1.16 Double_t fCaloTowerIsolation;
123 sixie 1.13 Double_t fTrackIsolation;
124 sixie 1.17 Double_t fEcalJurassicIsolation;
125     Double_t fHcalJurassicIsolation;
126 sixie 1.15 Double_t fPassLooseID;
127     Double_t fPassTightID;
128     Double_t fIDLikelihood;
129     Double_t fPIn;
130     Double_t fPOut;
131 sixie 1.13
132 loizides 1.7 ClassDef(Electron, 1) // Electron class
133 bendavid 1.1 };
134 loizides 1.4 }
135 loizides 1.8
136 loizides 1.9 //--------------------------------------------------------------------------------------------------
137 loizides 1.10 inline const mithep::Track *mithep::Electron::BestTrk() const
138 loizides 1.9 {
139 loizides 1.10 // Return "best" track.
140    
141     if (GsfTrk())
142     return GsfTrk();
143     else if (TrackerTrk())
144     return TrackerTrk();
145 loizides 1.9
146 loizides 1.10 return 0;
147 loizides 1.9 }
148    
149     //--------------------------------------------------------------------------------------------------
150 loizides 1.10 inline const mithep::Track *mithep::Electron::GsfTrk() const
151 loizides 1.9 {
152 loizides 1.10 // Return global combined track.
153 loizides 1.9
154 loizides 1.10 return static_cast<const Track*>(fGsfTrackRef.GetObject());
155 loizides 1.9 }
156    
157     //--------------------------------------------------------------------------------------------------
158 loizides 1.10 inline const mithep::Track *mithep::Electron::TrackerTrk() const
159 loizides 1.9 {
160 loizides 1.10 // Return tracker track.
161 loizides 1.9
162 loizides 1.10 return static_cast<const Track*>(fTrackerTrackRef.GetObject());
163 loizides 1.9 }
164 sixie 1.13 //--------------------------------------------------------------------------------------------------
165     inline const mithep::SuperCluster *mithep::Electron::SCluster() const
166     {
167     // Return Super cluster
168    
169     return static_cast<const SuperCluster*>(fSuperClusterRef.GetObject());
170     }
171 sixie 1.14
172     //-------------------------------------------------------------------------------------------------
173     inline mithep::FourVector mithep::Electron::Mom() const
174     {
175     // Return Momentum of the electron. We use the direction of the
176     // Track and the Energy of the Super Cluster
177    
178 bendavid 1.18 return FourVector(Px(), Py(), Pz(), E());
179 sixie 1.14 }
180 sixie 1.15
181 bendavid 1.18 //-------------------------------------------------------------------------------------------------
182 sixie 1.15 inline Double_t mithep::Electron::ESeedClusterOverPIn() const
183     {
184     // Return Energy of the SuperCluster Seed Divided by the magnitude
185     // of the track momentum at the vertex
186    
187     return SCluster()->Seed()->Energy() / PIn();
188     }
189    
190 bendavid 1.18 //-------------------------------------------------------------------------------------------------
191     inline Double_t mithep::Electron::E() const
192     {
193     // Return Energy of the SuperCluster if present
194     // or else return energy derived from the track
195    
196     const mithep::SuperCluster *sc = SCluster();
197     if (sc)
198     return sc->Energy();
199     else
200     return TMath::Sqrt(Trk()->P()*Trk()->P() + Mass()*Mass());
201     }
202    
203     //-------------------------------------------------------------------------------------------------
204     inline Double_t mithep::Electron::P() const
205     {
206     // Return momentum derived from the SuperCluster if present
207     // or else return momentum from the track
208    
209     const mithep::SuperCluster *sc = SCluster();
210     if (sc)
211     return TMath::Sqrt(sc->Energy()*sc->Energy() - Mass()*Mass());
212     else
213     return Trk()->P();
214     }
215    
216     //-------------------------------------------------------------------------------------------------
217     inline Double_t mithep::Electron::Px() const
218     {
219     return Pt()*TMath::Cos(Trk()->Phi());
220     }
221    
222     //-------------------------------------------------------------------------------------------------
223     inline Double_t mithep::Electron::Py() const
224     {
225     return Pt()*TMath::Sin(Trk()->Phi());
226     }
227 sixie 1.15
228 bendavid 1.18 //-------------------------------------------------------------------------------------------------
229     inline Double_t mithep::Electron::Pz() const
230     {
231     return P()*TMath::Sin(Trk()->Lambda());
232     }
233    
234     //-------------------------------------------------------------------------------------------------
235     inline Double_t mithep::Electron::Pt() const
236     {
237     return TMath::Abs(P()*TMath::Cos(Trk()->Lambda()));
238     }
239 loizides 1.8 #endif