DataTree/interface/Electron.h

//--------------------------------------------------------------------------------------------------
// $Id: Electron.h,v 1.23 2009/01/22 14:21:32 loizides Exp $
//
// Electron
//
// Details to be worked out... TODO: Needs description ala Muon class
//
// Authors: C.Loizides, J.Bendavid, S.Xie
//--------------------------------------------------------------------------------------------------

#ifndef MITANA_DATATREE_ELECTRON_H
#define MITANA_DATATREE_ELECTRON_H
 
#include "MitAna/DataTree/interface/SuperCluster.h"
#include "MitAna/DataTree/interface/ChargedParticle.h"
#include "MitAna/DataCont/interface/Ref.h"

namespace mithep 
{
  class Electron : public ChargedParticle
  {
    public:
      Electron() : fESuperClusterOverP(0), fESeedClusterOverPout(0), fDeltaEtaSuperClTrkAtVtx(0),
                   fDeltaEtaSeedClTrkAtCalo(0), fDeltaPhiSuperClTrkAtVtx(0), 
                   fDeltaPhiSeedClTrkAtCalo(0), fHadronicOverEm(0), fIsEnergyScaleCorrected(0),
                   fIsMomentumCorrected(0), fNumberOfClusters(0), fClassification(0), fE33(0),
                   fE55(0), fCovEtaEta(0), fCoviEtaiEta(0), fCovEtaPhi(0), fCovPhiPhi(0),
                   fCaloIsolation(0), fCaloTowerIsolation(0), fTrackIsolation(0), 
                   fEcalJurassicIsolation(0), fHcalJurassicIsolation(0), fPassLooseID(0),
                   fPassTightID(0), fIDLikelihood(0), fPIn(0), fPOut(0) {}
      ~Electron() {}
      
      const Track         *BestTrk()               const;
      const Track         *GsfTrk()                const { return fGsfTrackRef.Obj();       }
      const Track         *TrackerTrk()            const { return fTrackerTrackRef.Obj();   }
      const SuperCluster  *SCluster()              const { return fSuperClusterRef.Obj();   }
      FourVector           Mom()                   const;
      const Track         *Trk()                   const { return BestTrk();                }
      Double_t    CaloIsolation()                  const { return fCaloIsolation;           }
      Double_t    CaloTowerIsolation()             const { return fCaloTowerIsolation;      }
      Double_t    Classification()                 const { return fClassification;          }
      Double_t    CovEtaEta()                      const { return fCovEtaEta;               }
      Double_t    CovEtaPhi()                      const { return fCovEtaPhi;               }
      Double_t    CovPhiPhi()                      const { return fCovPhiPhi;               }
      Double_t    CoviEtaiEta()                    const { return fCoviEtaiEta;             }
      Double_t    DeltaEtaSuperClusterTrackAtVtx() const { return fDeltaEtaSuperClTrkAtVtx; }
      Double_t    DeltaEtaSeedClusterTrackAtCalo() const { return fDeltaEtaSeedClTrkAtCalo; }
      Double_t    DeltaPhiSuperClusterTrackAtVtx() const { return fDeltaPhiSuperClTrkAtVtx; }
      Double_t    DeltaPhiSeedClusterTrackAtCalo() const { return fDeltaPhiSeedClTrkAtCalo; }
      Double_t    E()                              const;
      Double_t    E33()                            const { return fE33;                     }
      Double_t    E55()                            const { return fE55;                     }
      Double_t    EcalJurassicIsolation()          const { return fEcalJurassicIsolation;   }
      Double_t    ESuperClusterOverP()             const { return fESuperClusterOverP;      }
      Double_t    ESeedClusterOverPout()           const { return fESeedClusterOverPout;    }
      Double_t    ESeedClusterOverPIn()            const;
      Double_t    IDLikelihood()                   const { return fIDLikelihood;            }
      Double_t    IsEnergyScaleCorrected()         const { return fIsEnergyScaleCorrected;  }
      Double_t    IsMomentumCorrected()            const { return fIsMomentumCorrected;     }
      Double_t    HadronicOverEm()                 const { return fHadronicOverEm;          }
      Bool_t      HasGsfTrk()                      const { return fGsfTrackRef.IsValid();   }
      Bool_t      HasTrackerTrk()                  const { return fTrackerTrackRef.IsValid(); }
      Bool_t      HasSuperCluster()                const { return fSuperClusterRef.IsValid(); }
      Double_t    HcalIsolation()                  const { return fHcalJurassicIsolation;   }
      Double_t    Mass()                           const { return 0.51099892e-3;            }
      Double_t    NumberOfClusters()               const { return fNumberOfClusters;        }
      EObjType    ObjType()                        const { return kElectron;                }      
      Double_t    PassLooseID()                    const { return fPassLooseID;             }
      Double_t    PassTightID()                    const { return fPassTightID;             }
      Double_t    PIn()                            const { return fPIn;                     }
      Double_t    POut()                           const { return fPOut;                    }
      Double_t    P()                              const;
      Double_t    Pt()                             const;
      Double_t    Px()                             const;
      Double_t    Py()                             const;
      Double_t    Pz()                             const;
      Double_t    TrackIsolation()                 const { return fTrackIsolation;          }
      void        SetGsfTrk(const Track* t)              { fGsfTrackRef = t;                }
      void        SetTrackerTrk(const Track* t)          { fTrackerTrackRef = t;            }
      void        SetSuperCluster(const SuperCluster* sc) { fSuperClusterRef = sc;          }
      void        SetCaloIsolation(Double_t CaloIsolation)      { fCaloIsolation = CaloIsolation;  }
      void        SetCaloTowerIsolation(Double_t TowerIso)      { fCaloTowerIsolation = TowerIso;  }
      void        SetClassification(Double_t x)                 { fClassification = x;             }
      void        SetCovEtaEta(Double_t CovEtaEta)              { fCovEtaEta = CovEtaEta;          }
      void        SetCovEtaPhi(Double_t CovEtaPhi)              { fCovEtaPhi = CovEtaPhi;          }
      void        SetCovPhiPhi(Double_t CovPhiPhi)              { fCovPhiPhi = CovPhiPhi;          }
      void        SetCoviEtaiEta(Double_t CoviEtaiEta)          { fCoviEtaiEta = CoviEtaiEta;      }
      void        SetDeltaEtaSuperClusterTrackAtVtx(Double_t x) { fDeltaEtaSuperClTrkAtVtx = x;    }
      void        SetDeltaEtaSeedClusterTrackAtCalo(Double_t x) { fDeltaEtaSeedClTrkAtCalo = x;    }
      void        SetDeltaPhiSuperClusterTrackAtVtx(Double_t x) { fDeltaPhiSuperClTrkAtVtx = x;    }
      void        SetDeltaPhiSeedClusterTrackAtCalo(Double_t x) { fDeltaPhiSeedClTrkAtCalo = x;    }
      void        SetE33(Double_t E33)                          { fE33 = E33;                      }
      void        SetE55(Double_t E55)                          { fE55 = E55;                      }
      void        SetEcalJurassicIsolation(Double_t iso )       { fEcalJurassicIsolation = iso;    }
      void        SetESuperClusterOverP(Double_t x)             { fESuperClusterOverP = x;         }
      void        SetESeedClusterOverPout(Double_t x)           { fESeedClusterOverPout = x;       }
      void        SetHadronicOverEm(Double_t x)                 { fHadronicOverEm = x;             }
      void        SetIDLikelihood(Double_t likelihood)          { fIDLikelihood = likelihood;      }
      void        SetIsEnergyScaleCorrected(Double_t x)         { fIsEnergyScaleCorrected = x;     }
      void        SetIsMomentumCorrected(Double_t x)            { fIsMomentumCorrected = x;        }
      void        SetHcalIsolation(Double_t iso )               { fHcalJurassicIsolation = iso;    }
      void        SetNumberOfClusters(Double_t x)               { fNumberOfClusters = x;           }
      void        SetPassLooseID(Double_t passLooseID)          { fPassLooseID = passLooseID;      }
      void        SetPassTightID(Double_t passTightID)          { fPassTightID = passTightID;      }
      void        SetPIn(Double_t PIn)                          { fPIn = PIn;                      }
      void        SetPOut(Double_t POut)                        { fPOut = POut;                    }
      void        SetTrackIsolation(Double_t TrackIsolation)    { fTrackIsolation = TrackIsolation;}

    protected:
      Ref<Track>  fGsfTrackRef;               //gsf track reference
      Ref<Track>  fTrackerTrackRef;           //tracker track reference
      Ref<SuperCluster> fSuperClusterRef;     //reference to SuperCluster
      Double_t    fESuperClusterOverP;        //
      Double_t    fESeedClusterOverPout;      //
      Double_t    fDeltaEtaSuperClTrkAtVtx;   //
      Double_t    fDeltaEtaSeedClTrkAtCalo;   //
      Double_t    fDeltaPhiSuperClTrkAtVtx;   //
      Double_t    fDeltaPhiSeedClTrkAtCalo;   //
      Double_t    fHadronicOverEm;            //
      Double_t    fIsEnergyScaleCorrected;    //
      Double_t    fIsMomentumCorrected;       //
      Double_t    fNumberOfClusters;          //
      Double_t    fClassification;            //
      Double_t    fE33;                       //
      Double_t    fE55;                       //
      Double_t    fCovEtaEta;                 //
      Double_t    fCoviEtaiEta;               //
      Double_t    fCovEtaPhi;                 //
      Double_t    fCovPhiPhi;                 //
      Double_t    fCaloIsolation;             //
      Double_t    fCaloTowerIsolation;        //
      Double_t    fTrackIsolation;            //
      Double_t    fEcalJurassicIsolation;     //
      Double_t    fHcalJurassicIsolation;     // 
      Double_t    fPassLooseID;               //
      Double_t    fPassTightID;               //
      Double_t    fIDLikelihood;              //
      Double_t    fPIn;                       //
      Double_t    fPOut;                      //

    ClassDef(Electron, 1) // Electron class
  };
}

//--------------------------------------------------------------------------------------------------
inline const mithep::Track *mithep::Electron::BestTrk() const
{
  // Return "best" track.

  if (HasGsfTrk())
    return GsfTrk();
  else if (HasTrackerTrk())
    return TrackerTrk();

  return 0;
}

//-------------------------------------------------------------------------------------------------
inline mithep::FourVector mithep::Electron::Mom() const
{
  // Return momentum of the electron. We use the direction of the
  // track and the energy of the SuperCluster.

  return FourVector(Px(), Py(), Pz(), E());
}

//-------------------------------------------------------------------------------------------------
inline Double_t mithep::Electron::ESeedClusterOverPIn() const
{
  // Return energy of the SuperCluster seed divided by the magnitude 
  // of the track momentum at the vertex.
  
  return SCluster()->Seed()->Energy() / PIn();
}

//-------------------------------------------------------------------------------------------------
inline Double_t mithep::Electron::E() const
{
  // Return energy of the SuperCluster if present
  // or else return energy derived from the track.
  
  const mithep::SuperCluster *sc = SCluster();
  if (sc)
    return sc->Energy();
  else
    return TMath::Sqrt(Trk()->P()*Trk()->P() + Mass()*Mass());
}

//-------------------------------------------------------------------------------------------------
inline Double_t mithep::Electron::P() const
{
  // Return momentum derived from the SuperCluster if present
  // or else return momentum from the track.
  
  const mithep::SuperCluster *sc = SCluster();
  if (sc)
    return TMath::Sqrt(sc->Energy()*sc->Energy() - Mass()*Mass());
  else
    return Trk()->P();
}

//-------------------------------------------------------------------------------------------------
inline Double_t mithep::Electron::Px() const
{
  // Return px.

  return Pt()*TMath::Cos(Trk()->Phi());
}

//-------------------------------------------------------------------------------------------------
inline Double_t mithep::Electron::Py() const
{
  // Return py.

  return Pt()*TMath::Sin(Trk()->Phi());
}

//-------------------------------------------------------------------------------------------------
inline Double_t mithep::Electron::Pz() const
{
  // Return pz.

  return P()*TMath::Sin(Trk()->Lambda());
}

//-------------------------------------------------------------------------------------------------
inline Double_t mithep::Electron::Pt() const
{
  // Return pt.

  return TMath::Abs(P()*TMath::Cos(Trk()->Lambda()));
}
#endif
Revision:	1.24
Committed:	Tue Feb 17 15:09:45 2009 UTC (16 years, 2 months ago) by bendavid
Content type:	text/plain
Branch:	MAIN
Changes since 1.23:	+16 -38 lines
Log Message:	Switched to templated Ref class
#	User	Rev	Content
1	bendavid	1.1	//--------------------------------------------------------------------------------------------------
2	bendavid	1.24	// $Id: Electron.h,v 1.23 2009/01/22 14:21:32 loizides Exp $
3	bendavid	1.1	//
4	paus	1.3	// Electron
5	bendavid	1.1	//
6	loizides	1.22	// Details to be worked out... TODO: Needs description ala Muon class
7	bendavid	1.1	//
8	sixie	1.13	// Authors: C.Loizides, J.Bendavid, S.Xie
9	bendavid	1.1	//--------------------------------------------------------------------------------------------------
10
11	loizides	1.23	#ifndef MITANA_DATATREE_ELECTRON_H
12			#define MITANA_DATATREE_ELECTRON_H
13	loizides	1.6
14	sixie	1.13	#include "MitAna/DataTree/interface/SuperCluster.h"
15	bendavid	1.11	#include "MitAna/DataTree/interface/ChargedParticle.h"
16	bendavid	1.24	#include "MitAna/DataCont/interface/Ref.h"
17	loizides	1.6
18	bendavid	1.1	namespace mithep
19			{
20	bendavid	1.11	class Electron : public ChargedParticle
21	bendavid	1.1	{
22			public:
23	loizides	1.22	Electron() : fESuperClusterOverP(0), fESeedClusterOverPout(0), fDeltaEtaSuperClTrkAtVtx(0),
24			fDeltaEtaSeedClTrkAtCalo(0), fDeltaPhiSuperClTrkAtVtx(0),
25			fDeltaPhiSeedClTrkAtCalo(0), fHadronicOverEm(0), fIsEnergyScaleCorrected(0),
26			fIsMomentumCorrected(0), fNumberOfClusters(0), fClassification(0), fE33(0),
27			fE55(0), fCovEtaEta(0), fCoviEtaiEta(0), fCovEtaPhi(0), fCovPhiPhi(0),
28			fCaloIsolation(0), fCaloTowerIsolation(0), fTrackIsolation(0),
29			fEcalJurassicIsolation(0), fHcalJurassicIsolation(0), fPassLooseID(0),
30			fPassTightID(0), fIDLikelihood(0), fPIn(0), fPOut(0) {}
31	bendavid	1.1	~Electron() {}
32
33	sixie	1.14	const Track *BestTrk() const;
34	bendavid	1.24	const Track *GsfTrk() const { return fGsfTrackRef.Obj(); }
35			const Track *TrackerTrk() const { return fTrackerTrackRef.Obj(); }
36			const SuperCluster *SCluster() const { return fSuperClusterRef.Obj(); }
37	sixie	1.14	FourVector Mom() const;
38			const Track *Trk() const { return BestTrk(); }
39	loizides	1.22	Double_t CaloIsolation() const { return fCaloIsolation; }
40			Double_t CaloTowerIsolation() const { return fCaloTowerIsolation; }
41			Double_t Classification() const { return fClassification; }
42			Double_t CovEtaEta() const { return fCovEtaEta; }
43			Double_t CovEtaPhi() const { return fCovEtaPhi; }
44			Double_t CovPhiPhi() const { return fCovPhiPhi; }
45			Double_t CoviEtaiEta() const { return fCoviEtaiEta; }
46	sixie	1.13	Double_t DeltaEtaSuperClusterTrackAtVtx() const { return fDeltaEtaSuperClTrkAtVtx; }
47			Double_t DeltaEtaSeedClusterTrackAtCalo() const { return fDeltaEtaSeedClTrkAtCalo; }
48			Double_t DeltaPhiSuperClusterTrackAtVtx() const { return fDeltaPhiSuperClTrkAtVtx; }
49			Double_t DeltaPhiSeedClusterTrackAtCalo() const { return fDeltaPhiSeedClTrkAtCalo; }
50	loizides	1.22	Double_t E() const;
51	sixie	1.13	Double_t E33() const { return fE33; }
52			Double_t E55() const { return fE55; }
53	sixie	1.17	Double_t EcalJurassicIsolation() const { return fEcalJurassicIsolation; }
54	loizides	1.22	Double_t ESuperClusterOverP() const { return fESuperClusterOverP; }
55			Double_t ESeedClusterOverPout() const { return fESeedClusterOverPout; }
56			Double_t ESeedClusterOverPIn() const;
57			Double_t IDLikelihood() const { return fIDLikelihood; }
58			Double_t IsEnergyScaleCorrected() const { return fIsEnergyScaleCorrected; }
59			Double_t IsMomentumCorrected() const { return fIsMomentumCorrected; }
60			Double_t HadronicOverEm() const { return fHadronicOverEm; }
61	bendavid	1.24	Bool_t HasGsfTrk() const { return fGsfTrackRef.IsValid(); }
62			Bool_t HasTrackerTrk() const { return fTrackerTrackRef.IsValid(); }
63			Bool_t HasSuperCluster() const { return fSuperClusterRef.IsValid(); }
64	loizides	1.20	Double_t HcalIsolation() const { return fHcalJurassicIsolation; }
65	loizides	1.22	Double_t Mass() const { return 0.51099892e-3; }
66			Double_t NumberOfClusters() const { return fNumberOfClusters; }
67			EObjType ObjType() const { return kElectron; }
68	sixie	1.15	Double_t PassLooseID() const { return fPassLooseID; }
69			Double_t PassTightID() const { return fPassTightID; }
70	loizides	1.22	Double_t PIn() const { return fPIn; }
71			Double_t POut() const { return fPOut; }
72			Double_t P() const;
73			Double_t Pt() const;
74			Double_t Px() const;
75			Double_t Py() const;
76			Double_t Pz() const;
77			Double_t TrackIsolation() const { return fTrackIsolation; }
78	bendavid	1.24	void SetGsfTrk(const Track* t) { fGsfTrackRef = t; }
79			void SetTrackerTrk(const Track* t) { fTrackerTrackRef = t; }
80			void SetSuperCluster(const SuperCluster* sc) { fSuperClusterRef = sc; }
81	loizides	1.22	void SetCaloIsolation(Double_t CaloIsolation) { fCaloIsolation = CaloIsolation; }
82			void SetCaloTowerIsolation(Double_t TowerIso) { fCaloTowerIsolation = TowerIso; }
83			void SetClassification(Double_t x) { fClassification = x; }
84			void SetCovEtaEta(Double_t CovEtaEta) { fCovEtaEta = CovEtaEta; }
85			void SetCovEtaPhi(Double_t CovEtaPhi) { fCovEtaPhi = CovEtaPhi; }
86			void SetCovPhiPhi(Double_t CovPhiPhi) { fCovPhiPhi = CovPhiPhi; }
87			void SetCoviEtaiEta(Double_t CoviEtaiEta) { fCoviEtaiEta = CoviEtaiEta; }
88	sixie	1.13	void SetDeltaEtaSuperClusterTrackAtVtx(Double_t x) { fDeltaEtaSuperClTrkAtVtx = x; }
89			void SetDeltaEtaSeedClusterTrackAtCalo(Double_t x) { fDeltaEtaSeedClTrkAtCalo = x; }
90			void SetDeltaPhiSuperClusterTrackAtVtx(Double_t x) { fDeltaPhiSuperClTrkAtVtx = x; }
91			void SetDeltaPhiSeedClusterTrackAtCalo(Double_t x) { fDeltaPhiSeedClTrkAtCalo = x; }
92	loizides	1.22	void SetE33(Double_t E33) { fE33 = E33; }
93			void SetE55(Double_t E55) { fE55 = E55; }
94			void SetEcalJurassicIsolation(Double_t iso ) { fEcalJurassicIsolation = iso; }
95			void SetESuperClusterOverP(Double_t x) { fESuperClusterOverP = x; }
96			void SetESeedClusterOverPout(Double_t x) { fESeedClusterOverPout = x; }
97	sixie	1.13	void SetHadronicOverEm(Double_t x) { fHadronicOverEm = x; }
98	loizides	1.22	void SetIDLikelihood(Double_t likelihood) { fIDLikelihood = likelihood; }
99	sixie	1.13	void SetIsEnergyScaleCorrected(Double_t x) { fIsEnergyScaleCorrected = x; }
100			void SetIsMomentumCorrected(Double_t x) { fIsMomentumCorrected = x; }
101	loizides	1.22	void SetHcalIsolation(Double_t iso ) { fHcalJurassicIsolation = iso; }
102	sixie	1.13	void SetNumberOfClusters(Double_t x) { fNumberOfClusters = x; }
103	sixie	1.15	void SetPassLooseID(Double_t passLooseID) { fPassLooseID = passLooseID; }
104			void SetPassTightID(Double_t passTightID) { fPassTightID = passTightID; }
105	loizides	1.22	void SetPIn(Double_t PIn) { fPIn = PIn; }
106			void SetPOut(Double_t POut) { fPOut = POut; }
107			void SetTrackIsolation(Double_t TrackIsolation) { fTrackIsolation = TrackIsolation;}
108	sixie	1.13
109	loizides	1.8	protected:
110	bendavid	1.24	Ref<Track> fGsfTrackRef; //gsf track reference
111			Ref<Track> fTrackerTrackRef; //tracker track reference
112			Ref<SuperCluster> fSuperClusterRef; //reference to SuperCluster
113	loizides	1.22	Double_t fESuperClusterOverP; //
114			Double_t fESeedClusterOverPout; //
115			Double_t fDeltaEtaSuperClTrkAtVtx; //
116			Double_t fDeltaEtaSeedClTrkAtCalo; //
117			Double_t fDeltaPhiSuperClTrkAtVtx; //
118			Double_t fDeltaPhiSeedClTrkAtCalo; //
119			Double_t fHadronicOverEm; //
120			Double_t fIsEnergyScaleCorrected; //
121			Double_t fIsMomentumCorrected; //
122			Double_t fNumberOfClusters; //
123			Double_t fClassification; //
124			Double_t fE33; //
125			Double_t fE55; //
126			Double_t fCovEtaEta; //
127			Double_t fCoviEtaiEta; //
128			Double_t fCovEtaPhi; //
129			Double_t fCovPhiPhi; //
130			Double_t fCaloIsolation; //
131			Double_t fCaloTowerIsolation; //
132			Double_t fTrackIsolation; //
133			Double_t fEcalJurassicIsolation; //
134			Double_t fHcalJurassicIsolation; //
135			Double_t fPassLooseID; //
136			Double_t fPassTightID; //
137			Double_t fIDLikelihood; //
138			Double_t fPIn; //
139			Double_t fPOut; //
140	sixie	1.13
141	loizides	1.7	ClassDef(Electron, 1) // Electron class
142	bendavid	1.1	};
143	loizides	1.4	}
144	loizides	1.8
145	loizides	1.9	//--------------------------------------------------------------------------------------------------
146	loizides	1.10	inline const mithep::Track *mithep::Electron::BestTrk() const
147	loizides	1.9	{
148	loizides	1.10	// Return "best" track.
149
150	bendavid	1.24	if (HasGsfTrk())
151	loizides	1.10	return GsfTrk();
152	bendavid	1.24	else if (HasTrackerTrk())
153	loizides	1.10	return TrackerTrk();
154	loizides	1.9
155	loizides	1.10	return 0;
156	loizides	1.9	}
157
158	sixie	1.14	//-------------------------------------------------------------------------------------------------
159			inline mithep::FourVector mithep::Electron::Mom() const
160			{
161	loizides	1.22	// Return momentum of the electron. We use the direction of the
162			// track and the energy of the SuperCluster.
163	sixie	1.14
164	bendavid	1.18	return FourVector(Px(), Py(), Pz(), E());
165	sixie	1.14	}
166	sixie	1.15
167	bendavid	1.18	//-------------------------------------------------------------------------------------------------
168	sixie	1.15	inline Double_t mithep::Electron::ESeedClusterOverPIn() const
169			{
170	loizides	1.22	// Return energy of the SuperCluster seed divided by the magnitude
171			// of the track momentum at the vertex.
172	sixie	1.15
173			return SCluster()->Seed()->Energy() / PIn();
174			}
175
176	bendavid	1.18	//-------------------------------------------------------------------------------------------------
177			inline Double_t mithep::Electron::E() const
178			{
179	loizides	1.22	// Return energy of the SuperCluster if present
180			// or else return energy derived from the track.
181	bendavid	1.18
182			const mithep::SuperCluster *sc = SCluster();
183			if (sc)
184			return sc->Energy();
185			else
186			return TMath::Sqrt(Trk()->P()Trk()->P() + Mass()Mass());
187			}
188
189			//-------------------------------------------------------------------------------------------------
190			inline Double_t mithep::Electron::P() const
191			{
192			// Return momentum derived from the SuperCluster if present
193	loizides	1.22	// or else return momentum from the track.
194	bendavid	1.18
195			const mithep::SuperCluster *sc = SCluster();
196			if (sc)
197			return TMath::Sqrt(sc->Energy()sc->Energy() - Mass()Mass());
198			else
199			return Trk()->P();
200			}
201
202			//-------------------------------------------------------------------------------------------------
203			inline Double_t mithep::Electron::Px() const
204			{
205	loizides	1.22	// Return px.
206
207	bendavid	1.18	return Pt()*TMath::Cos(Trk()->Phi());
208			}
209
210			//-------------------------------------------------------------------------------------------------
211			inline Double_t mithep::Electron::Py() const
212			{
213	loizides	1.22	// Return py.
214
215	bendavid	1.18	return Pt()*TMath::Sin(Trk()->Phi());
216			}
217	sixie	1.15
218	bendavid	1.18	//-------------------------------------------------------------------------------------------------
219			inline Double_t mithep::Electron::Pz() const
220			{
221	loizides	1.22	// Return pz.
222
223	bendavid	1.18	return P()*TMath::Sin(Trk()->Lambda());
224			}
225
226			//-------------------------------------------------------------------------------------------------
227			inline Double_t mithep::Electron::Pt() const
228			{
229	loizides	1.22	// Return pt.
230
231	bendavid	1.18	return TMath::Abs(P()*TMath::Cos(Trk()->Lambda()));
232			}
233	loizides	1.8	#endif