DataTree/interface/Track.h

//--------------------------------------------------------------------------------------------------
// $Id: Track.h,v 1.27 2008/11/03 11:21:11 bendavid Exp $
//
// Track
//
// We store the CMSSW track parameterization
// Parameters associated to the 5D curvilinear covariance matrix:
// (qoverp, lambda, phi, dxy, dsz)
// defined as:
// qoverp = q / abs(p) = signed inverse of momentum [1/GeV]
// lambda = pi/2 - polar angle at the given point
// phi = azimuth angle at the given point
// dxy = -vx*sin(phi) + vy*cos(phi) [cm]
// dsz = vz*cos(lambda) - (vx*cos(phi)+vy*sin(phi))*sin(lambda) [cm]
// (See http://cmslxr.fnal.gov/lxr/source/DataFormats/TrackReco/interface/TrackBase.h)
//
// Format for fHits: (We do not use anything resembling reco::HitPattern from CMSSW because that
// data format requires 800 bits per track!)
// There is a one to one mapping between bits and tracker layers, where layers are enumerated
// seperately in the PXB, PXF, TIB, TID, TOB, TEC and r-phi and stereo modules are treated as
// seperate layers in those detectors which have them
// (TIB L1,L2, TID L1,L2,L3, TOB L1,L2, TEC L1,L2,L3,L4,L5,L6,L7,L8,L9).
// 
// A bit value of 1 indicates a hit in the corresponding layer, and 0 indicates no hit.
//
// Note that currently this only stores information about hits in the Tracker,
// but muon chamber information will likely be added as well.
//
// Bit-Layer assignments (starting from bit 0):
// Bit  0: PXB L1
// Bit  1: PXB L2
// Bit  2: PXB L3
// Bit  3: PXF L1
// Bit  4: PXF L2
// Bit  5: TIB L1 r-phi
// Bit  6: TIB L1 stereo
// Bit  7: TIB L2 r-phi
// Bit  8: TIB L2 stereo
// Bit  9: TIB L3 r-phi
// Bit 10: TIB L4 r-phi
// Bit 11: TID L1 r-phi
// Bit 12: TID L1 stereo
// Bit 13: TID L2 r-phi
// Bit 14: TID L2 stereo
// Bit 15: TID L3 r-phi
// Bit 16: TID L3 stereo
// Bit 17: TOB L1 r-phi
// Bit 18: TOB L1 stereo
// Bit 19: TOB L2 r-phi
// Bit 20: TOB L2 stereo
// Bit 21: TOB L3 r-phi
// Bit 22: TOB L4 r-phi
// Bit 23: TOB L5 r-phi
// Bit 24: TOB L6 r-phi
// Bit 25: TEC L1 r-phi
// Bit 26: TEC L1 stereo
// Bit 27: TEC L2 r-phi
// Bit 28: TEC L2 stereo
// Bit 29: TEC L3 r-phi
// Bit 30: TEC L3 stereo
// Bit 31: TEC L4 r-phi
// Bit 32: TEC L4 stereo
// Bit 33: TEC L5 r-phi
// Bit 34: TEC L5 stereo
// Bit 35: TEC L6 r-phi
// Bit 36: TEC L6 stereo
// Bit 37: TEC L7 r-phi
// Bit 38: TEC L7 stereo
// Bit 39: TEC L8 r-phi
// Bit 40: TEC L8 stereo
// Bit 41: TEC L9 r-phi
// Bit 42: TEC L9 stereo
//
// Authors: C.Loizides, J.Bendavid, C.Paus
//--------------------------------------------------------------------------------------------------

#ifndef MITANA_DATATREE_TRACK_H
#define MITANA_DATATREE_TRACK_H
 
#include "MitAna/DataTree/interface/DataObject.h"
#include "MitAna/DataTree/interface/SuperCluster.h"
#include "MitAna/DataTree/interface/MCParticle.h"
#include "MitAna/DataTree/interface/BitMask.h"
#include "MitAna/DataTree/interface/BaseVertex.h"
#include "MitAna/DataTree/interface/Types.h"

namespace mithep 
{
  class Track : public DataObject
  {
    public:
      enum EHitLayer { 
        PXB1, 
        PXB2,
        PXB3,
        PXF1,
        PXF2,
        TIB1,
        TIB1S,
        TIB2,
        TIB2S,
        TIB3,
        TIB4,
        TID1,
        TID1S,
        TID2,
        TID2S,
        TID3,
        TID3S,
        TOB1,
        TOB1S,
        TOB2,
        TOB2S,
        TOB3,
        TOB4,
        TOB5,
        TOB6,
        TEC1,
        TEC1S,
        TEC2,
        TEC2S,
        TEC3,
        TEC3S,
        TEC4,
        TEC4S,
        TEC5,
        TEC5S,
        TEC6,
        TEC6S,
        TEC7,
        TEC7S,
        TEC8,
        TEC8S,
        TEC9,
        TEC9S
      };

      Track() : fQOverP(0), fQOverPErr(0), fLambda(0), fLambdaErr(0),
                fPhi0(0), fPhi0Err(0), fDxy(0), fDxyErr(0), fDsz(0), fDszErr(0),
                fChi2(0), fNdof(0), fEtaEcal(0), fPhiEcal(0) {}
      Track(Double_t qOverP, Double_t lambda, Double_t phi0, Double_t dxy, Double_t dsz) :
                fQOverP(qOverP), fQOverPErr(0), fLambda(lambda), fLambdaErr(0),
                fPhi0(phi0), fPhi0Err(0), fDxy(dxy), fDxyErr(0), fDsz(dsz), fDszErr(0),
                fChi2(0), fNdof(0), fEtaEcal(0), fPhiEcal(0) {}
      ~Track() {}

      Int_t              Charge()         const { return (fQOverP>0) ? 1 : -1; }
      Double_t           Chi2()           const { return fChi2; }
      Double_t           RChi2()          const { return fChi2/(Double_t)fNdof; }
      void               ClearHit(EHitLayer l)  { fHits.ClearBit(l); } 
      Double_t           D0()             const { return -fDxy; }
      Double_t           D0Corrected(const BaseVertex *iVertex) const;
      Double_t           D0Err()          const { return fDxyErr; }
      Double_t           Dsz()            const { return fDsz; }
      Double_t           DszErr()         const { return fDszErr; }
      Double_t           Dxy()            const { return fDxy; }
      Double_t           DxyErr()         const { return fDxyErr; }
      Double_t           E(Double_t m)    const { return TMath::Sqrt(E2(m)); }
      Double_t           E2(Double_t m)   const { return P2()+m*m; }
      Double_t           Eta()            const { return Mom().Eta(); }
      Double_t           EtaEcal()        const { return fEtaEcal; }
      Bool_t             Hit(EHitLayer l) const { return fHits.TestBit(l); }
      const BitMask48   &Hits()           const { return fHits; }
      Double_t           Lambda()         const { return fLambda; }
      Double_t           LambdaErr()      const { return fLambdaErr; }
      const MCParticle  *MCPart()         const;
      ThreeVector        Mom()            const { return ThreeVector(Px(),Py(),Pz()); }
      FourVector         Mom4(Double_t m) const { return FourVector(Px(),Py(),Pz(),E(m)); }
      UInt_t             Ndof()           const { return fNdof; }
      UInt_t             NHits()          const { return fHits.NBitsSet(); }
      UInt_t             NStereoHits()    const { return StereoHits().NBitsSet(); }
      Double_t           P2()             const { return P()*P(); }
      Double_t           P()              const { return TMath::Abs(1./fQOverP); }
      Double_t           Phi()            const { return fPhi0; }
      Double_t           Phi0()           const { return fPhi0; }
      Double_t           Phi0Err()        const { return fPhi0Err; }
      Double_t           PhiEcal()        const { return fPhiEcal; }
      Double_t           Prob()           const { return TMath::Prob(fChi2,fNdof); }
      Double_t           Pt()             const { return TMath::Abs(TMath::Cos(fLambda)/fQOverP); }
      Double_t           Px()             const { return Pt()*TMath::Cos(fPhi0); }      
      Double_t           Py()             const { return Pt()*TMath::Sin(fPhi0); }
      Double_t           Pz()             const { return P()*TMath::Sin(fLambda); }
      Double_t           QOverP()         const { return fQOverP; }
      Double_t           QOverPErr()      const { return fQOverPErr; }
      Double_t           Theta()          const { return (TMath::PiOver2() - fLambda); }
      Double_t           Z0()             const { return fDsz/TMath::Cos(fLambda); }
      void               SetChi2(Double_t chi2) { fChi2 = chi2; }
      void               SetErrors(Double_t qOverPErr, Double_t lambdaErr, Double_t phi0Err, 
                                   Double_t dXyErr, Double_t dSzErr);
      void               SetEtaEcal(Double_t eta) { fEtaEcal = eta; }
      void               SetHelix (Double_t qOverP, Double_t lambda, Double_t phi0, 
                                   Double_t dXy, Double_t dSz);
      void               SetHit(EHitLayer l)      { fHits.SetBit(l); }
      void               SetHits(const BitMask48 &hits) { fHits = hits; }
      void               SetNdof(UInt_t dof)      { fNdof = dof; }
      void               SetMCPart(MCParticle *p) { fMCParticleRef = p; }
      void               SetPhiEcal(Double_t phi) { fPhiEcal = phi; }
      void               SetSCluster(SuperCluster* sc) { fSuperClusterRef = sc; }
      const SuperCluster *SCluster()      const;
      const  BitMask48   StereoHits()     const { return (fHits & StereoLayers()); }
      static const BitMask48 StereoLayers();

    protected:
      BitMask48          fHits;                //storage for mostly hit information
      Double_t           fQOverP;              //signed inverse of momentum [1/GeV]
      Double_t           fQOverPErr;           //error of q/p
      Double_t           fLambda;              //pi/2 - polar angle at the reference point
      Double_t           fLambdaErr;           //error of lambda
      Double_t           fPhi0;                //azimuth angle at the given point
      Double_t           fPhi0Err;             //error of azimuthal angle
      Double_t           fDxy;                 //transverse distance to reference point [cm]
      Double_t           fDxyErr;              //error of transverse distance
      Double_t           fDsz;                 //longitudinal distance to reference point [cm]
      Double_t           fDszErr;              //error of longitudinal distance
      Double_t           fChi2;                //chi squared of track fit
      UInt_t             fNdof;                //degree-of-freedom of track fit
      Double32_t         fEtaEcal;             //Eta of track at Ecal front face
      Double32_t         fPhiEcal;             //phi of track at Ecal front face
      TRef               fSuperClusterRef;     //superCluster crossed by track
      TRef               fMCParticleRef;       //reference to sim particle (for monte carlo)
              
    ClassDef(Track, 2) // Track class
  };
}

//--------------------------------------------------------------------------------------------------
inline Double_t mithep::Track::D0Corrected(const BaseVertex *iVertex) const
{
  // Return corrected d0 with respect to primary vertex or beamspot

  Double_t lXM =  -TMath::Sin(Phi()) * D0();
  Double_t lYM =   TMath::Cos(Phi()) * D0();
  Double_t lDX = (lXM + iVertex->X());
  Double_t lDY = (lYM + iVertex->Y());
  Double_t d0Corr = (Px()*lDY - Py()*lDX)/Pt();
  
  return d0Corr;
  
}

//--------------------------------------------------------------------------------------------------
inline
void mithep::Track::SetHelix(Double_t qOverP, Double_t lambda, Double_t phi0, 
                                   Double_t dxy, Double_t dsz)
{
  // Set helix parameters.

  fQOverP = qOverP;
  fLambda = lambda;
  fPhi0   = phi0;
  fDxy    = dxy;
  fDsz    = dsz;
}

//--------------------------------------------------------------------------------------------------
inline
void mithep::Track::SetErrors(Double_t qOverPErr, Double_t lambdaErr, Double_t phi0Err, 
                                   Double_t dxyErr, Double_t dszErr)
{
  // Set helix errors.

  fQOverPErr = qOverPErr;
  fLambdaErr = lambdaErr;
  fPhi0Err   = phi0Err;
  fDxyErr    = dxyErr;
  fDszErr    = dszErr;
}

//--------------------------------------------------------------------------------------------------
inline
const mithep::MCParticle *mithep::Track::MCPart() const 
{ 
  // Get reference to simulated particle.

  return static_cast<const MCParticle*>(fMCParticleRef.GetObject()); 
}

//--------------------------------------------------------------------------------------------------
inline const mithep::SuperCluster *mithep::Track::SCluster() const
{
  // Return Super cluster

  return static_cast<const SuperCluster*>(fSuperClusterRef.GetObject());
}

//--------------------------------------------------------------------------------------------------
inline
const mithep::BitMask48 mithep::Track::StereoLayers()
{ 
  // Build and return BitMask of stereo layers

  mithep::BitMask48 stereoLayers;
  
  stereoLayers.SetBit(mithep::Track::TIB1S);
  stereoLayers.SetBit(mithep::Track::TIB2S);
  stereoLayers.SetBit(mithep::Track::TID1S);
  stereoLayers.SetBit(mithep::Track::TID2S);
  stereoLayers.SetBit(mithep::Track::TID3S);
  stereoLayers.SetBit(mithep::Track::TOB1S);
  stereoLayers.SetBit(mithep::Track::TOB2S);
  stereoLayers.SetBit(mithep::Track::TEC1S);
  stereoLayers.SetBit(mithep::Track::TEC2S);
  stereoLayers.SetBit(mithep::Track::TEC3S);
  stereoLayers.SetBit(mithep::Track::TEC4S);
  stereoLayers.SetBit(mithep::Track::TEC5S);
  stereoLayers.SetBit(mithep::Track::TEC6S);
  stereoLayers.SetBit(mithep::Track::TEC7S);
  stereoLayers.SetBit(mithep::Track::TEC8S);
  stereoLayers.SetBit(mithep::Track::TEC9S);
  
  return stereoLayers;
}
#endif
Revision:	1.28
Committed:	Mon Nov 17 18:56:07 2008 UTC (16 years, 5 months ago) by bendavid
Content type:	text/plain
Branch:	MAIN
CVS Tags:	Mit_006
Changes since 1.27:	+18 -1 lines
Log Message:	Added D0Corrected accessor for impact parameter wrt primary vertex or beamspot
#	Content
1	//--------------------------------------------------------------------------------------------------
2	// $Id: Track.h,v 1.27 2008/11/03 11:21:11 bendavid Exp $
3	//
4	// Track
5	//
6	// We store the CMSSW track parameterization
7	// Parameters associated to the 5D curvilinear covariance matrix:
8	// (qoverp, lambda, phi, dxy, dsz)
9	// defined as:
10	// qoverp = q / abs(p) = signed inverse of momentum [1/GeV]
11	// lambda = pi/2 - polar angle at the given point
12	// phi = azimuth angle at the given point
13	// dxy = -vxsin(phi) + vycos(phi) [cm]
14	// dsz = vzcos(lambda) - (vxcos(phi)+vysin(phi))sin(lambda) [cm]
15	// (See http://cmslxr.fnal.gov/lxr/source/DataFormats/TrackReco/interface/TrackBase.h)
16	//
17	// Format for fHits: (We do not use anything resembling reco::HitPattern from CMSSW because that
18	// data format requires 800 bits per track!)
19	// There is a one to one mapping between bits and tracker layers, where layers are enumerated
20	// seperately in the PXB, PXF, TIB, TID, TOB, TEC and r-phi and stereo modules are treated as
21	// seperate layers in those detectors which have them
22	// (TIB L1,L2, TID L1,L2,L3, TOB L1,L2, TEC L1,L2,L3,L4,L5,L6,L7,L8,L9).
23	//
24	// A bit value of 1 indicates a hit in the corresponding layer, and 0 indicates no hit.
25	//
26	// Note that currently this only stores information about hits in the Tracker,
27	// but muon chamber information will likely be added as well.
28	//
29	// Bit-Layer assignments (starting from bit 0):
30	// Bit 0: PXB L1
31	// Bit 1: PXB L2
32	// Bit 2: PXB L3
33	// Bit 3: PXF L1
34	// Bit 4: PXF L2
35	// Bit 5: TIB L1 r-phi
36	// Bit 6: TIB L1 stereo
37	// Bit 7: TIB L2 r-phi
38	// Bit 8: TIB L2 stereo
39	// Bit 9: TIB L3 r-phi
40	// Bit 10: TIB L4 r-phi
41	// Bit 11: TID L1 r-phi
42	// Bit 12: TID L1 stereo
43	// Bit 13: TID L2 r-phi
44	// Bit 14: TID L2 stereo
45	// Bit 15: TID L3 r-phi
46	// Bit 16: TID L3 stereo
47	// Bit 17: TOB L1 r-phi
48	// Bit 18: TOB L1 stereo
49	// Bit 19: TOB L2 r-phi
50	// Bit 20: TOB L2 stereo
51	// Bit 21: TOB L3 r-phi
52	// Bit 22: TOB L4 r-phi
53	// Bit 23: TOB L5 r-phi
54	// Bit 24: TOB L6 r-phi
55	// Bit 25: TEC L1 r-phi
56	// Bit 26: TEC L1 stereo
57	// Bit 27: TEC L2 r-phi
58	// Bit 28: TEC L2 stereo
59	// Bit 29: TEC L3 r-phi
60	// Bit 30: TEC L3 stereo
61	// Bit 31: TEC L4 r-phi
62	// Bit 32: TEC L4 stereo
63	// Bit 33: TEC L5 r-phi
64	// Bit 34: TEC L5 stereo
65	// Bit 35: TEC L6 r-phi
66	// Bit 36: TEC L6 stereo
67	// Bit 37: TEC L7 r-phi
68	// Bit 38: TEC L7 stereo
69	// Bit 39: TEC L8 r-phi
70	// Bit 40: TEC L8 stereo
71	// Bit 41: TEC L9 r-phi
72	// Bit 42: TEC L9 stereo
73	//
74	// Authors: C.Loizides, J.Bendavid, C.Paus
75	//--------------------------------------------------------------------------------------------------
76
77	#ifndef MITANA_DATATREE_TRACK_H
78	#define MITANA_DATATREE_TRACK_H
79
80	#include "MitAna/DataTree/interface/DataObject.h"
81	#include "MitAna/DataTree/interface/SuperCluster.h"
82	#include "MitAna/DataTree/interface/MCParticle.h"
83	#include "MitAna/DataTree/interface/BitMask.h"
84	#include "MitAna/DataTree/interface/BaseVertex.h"
85	#include "MitAna/DataTree/interface/Types.h"
86
87	namespace mithep
88	{
89	class Track : public DataObject
90	{
91	public:
92	enum EHitLayer {
93	PXB1,
94	PXB2,
95	PXB3,
96	PXF1,
97	PXF2,
98	TIB1,
99	TIB1S,
100	TIB2,
101	TIB2S,
102	TIB3,
103	TIB4,
104	TID1,
105	TID1S,
106	TID2,
107	TID2S,
108	TID3,
109	TID3S,
110	TOB1,
111	TOB1S,
112	TOB2,
113	TOB2S,
114	TOB3,
115	TOB4,
116	TOB5,
117	TOB6,
118	TEC1,
119	TEC1S,
120	TEC2,
121	TEC2S,
122	TEC3,
123	TEC3S,
124	TEC4,
125	TEC4S,
126	TEC5,
127	TEC5S,
128	TEC6,
129	TEC6S,
130	TEC7,
131	TEC7S,
132	TEC8,
133	TEC8S,
134	TEC9,
135	TEC9S
136	};
137
138	Track() : fQOverP(0), fQOverPErr(0), fLambda(0), fLambdaErr(0),
139	fPhi0(0), fPhi0Err(0), fDxy(0), fDxyErr(0), fDsz(0), fDszErr(0),
140	fChi2(0), fNdof(0), fEtaEcal(0), fPhiEcal(0) {}
141	Track(Double_t qOverP, Double_t lambda, Double_t phi0, Double_t dxy, Double_t dsz) :
142	fQOverP(qOverP), fQOverPErr(0), fLambda(lambda), fLambdaErr(0),
143	fPhi0(phi0), fPhi0Err(0), fDxy(dxy), fDxyErr(0), fDsz(dsz), fDszErr(0),
144	fChi2(0), fNdof(0), fEtaEcal(0), fPhiEcal(0) {}
145	~Track() {}
146
147	Int_t Charge() const { return (fQOverP>0) ? 1 : -1; }
148	Double_t Chi2() const { return fChi2; }
149	Double_t RChi2() const { return fChi2/(Double_t)fNdof; }
150	void ClearHit(EHitLayer l) { fHits.ClearBit(l); }
151	Double_t D0() const { return -fDxy; }
152	Double_t D0Corrected(const BaseVertex *iVertex) const;
153	Double_t D0Err() const { return fDxyErr; }
154	Double_t Dsz() const { return fDsz; }
155	Double_t DszErr() const { return fDszErr; }
156	Double_t Dxy() const { return fDxy; }
157	Double_t DxyErr() const { return fDxyErr; }
158	Double_t E(Double_t m) const { return TMath::Sqrt(E2(m)); }
159	Double_t E2(Double_t m) const { return P2()+m*m; }
160	Double_t Eta() const { return Mom().Eta(); }
161	Double_t EtaEcal() const { return fEtaEcal; }
162	Bool_t Hit(EHitLayer l) const { return fHits.TestBit(l); }
163	const BitMask48 &Hits() const { return fHits; }
164	Double_t Lambda() const { return fLambda; }
165	Double_t LambdaErr() const { return fLambdaErr; }
166	const MCParticle *MCPart() const;
167	ThreeVector Mom() const { return ThreeVector(Px(),Py(),Pz()); }
168	FourVector Mom4(Double_t m) const { return FourVector(Px(),Py(),Pz(),E(m)); }
169	UInt_t Ndof() const { return fNdof; }
170	UInt_t NHits() const { return fHits.NBitsSet(); }
171	UInt_t NStereoHits() const { return StereoHits().NBitsSet(); }
172	Double_t P2() const { return P()*P(); }
173	Double_t P() const { return TMath::Abs(1./fQOverP); }
174	Double_t Phi() const { return fPhi0; }
175	Double_t Phi0() const { return fPhi0; }
176	Double_t Phi0Err() const { return fPhi0Err; }
177	Double_t PhiEcal() const { return fPhiEcal; }
178	Double_t Prob() const { return TMath::Prob(fChi2,fNdof); }
179	Double_t Pt() const { return TMath::Abs(TMath::Cos(fLambda)/fQOverP); }
180	Double_t Px() const { return Pt()*TMath::Cos(fPhi0); }
181	Double_t Py() const { return Pt()*TMath::Sin(fPhi0); }
182	Double_t Pz() const { return P()*TMath::Sin(fLambda); }
183	Double_t QOverP() const { return fQOverP; }
184	Double_t QOverPErr() const { return fQOverPErr; }
185	Double_t Theta() const { return (TMath::PiOver2() - fLambda); }
186	Double_t Z0() const { return fDsz/TMath::Cos(fLambda); }
187	void SetChi2(Double_t chi2) { fChi2 = chi2; }
188	void SetErrors(Double_t qOverPErr, Double_t lambdaErr, Double_t phi0Err,
189	Double_t dXyErr, Double_t dSzErr);
190	void SetEtaEcal(Double_t eta) { fEtaEcal = eta; }
191	void SetHelix (Double_t qOverP, Double_t lambda, Double_t phi0,
192	Double_t dXy, Double_t dSz);
193	void SetHit(EHitLayer l) { fHits.SetBit(l); }
194	void SetHits(const BitMask48 &hits) { fHits = hits; }
195	void SetNdof(UInt_t dof) { fNdof = dof; }
196	void SetMCPart(MCParticle *p) { fMCParticleRef = p; }
197	void SetPhiEcal(Double_t phi) { fPhiEcal = phi; }
198	void SetSCluster(SuperCluster* sc) { fSuperClusterRef = sc; }
199	const SuperCluster *SCluster() const;
200	const BitMask48 StereoHits() const { return (fHits & StereoLayers()); }
201	static const BitMask48 StereoLayers();
202
203	protected:
204	BitMask48 fHits; //storage for mostly hit information
205	Double_t fQOverP; //signed inverse of momentum [1/GeV]
206	Double_t fQOverPErr; //error of q/p
207	Double_t fLambda; //pi/2 - polar angle at the reference point
208	Double_t fLambdaErr; //error of lambda
209	Double_t fPhi0; //azimuth angle at the given point
210	Double_t fPhi0Err; //error of azimuthal angle
211	Double_t fDxy; //transverse distance to reference point [cm]
212	Double_t fDxyErr; //error of transverse distance
213	Double_t fDsz; //longitudinal distance to reference point [cm]
214	Double_t fDszErr; //error of longitudinal distance
215	Double_t fChi2; //chi squared of track fit
216	UInt_t fNdof; //degree-of-freedom of track fit
217	Double32_t fEtaEcal; //Eta of track at Ecal front face
218	Double32_t fPhiEcal; //phi of track at Ecal front face
219	TRef fSuperClusterRef; //superCluster crossed by track
220	TRef fMCParticleRef; //reference to sim particle (for monte carlo)
221
222	ClassDef(Track, 2) // Track class
223	};
224	}
225
226	//--------------------------------------------------------------------------------------------------
227	inline Double_t mithep::Track::D0Corrected(const BaseVertex *iVertex) const
228	{
229	// Return corrected d0 with respect to primary vertex or beamspot
230
231	Double_t lXM = -TMath::Sin(Phi()) * D0();
232	Double_t lYM = TMath::Cos(Phi()) * D0();
233	Double_t lDX = (lXM + iVertex->X());
234	Double_t lDY = (lYM + iVertex->Y());
235	Double_t d0Corr = (Px()lDY - Py()lDX)/Pt();
236
237	return d0Corr;
238
239	}
240
241	//--------------------------------------------------------------------------------------------------
242	inline
243	void mithep::Track::SetHelix(Double_t qOverP, Double_t lambda, Double_t phi0,
244	Double_t dxy, Double_t dsz)
245	{
246	// Set helix parameters.
247
248	fQOverP = qOverP;
249	fLambda = lambda;
250	fPhi0 = phi0;
251	fDxy = dxy;
252	fDsz = dsz;
253	}
254
255	//--------------------------------------------------------------------------------------------------
256	inline
257	void mithep::Track::SetErrors(Double_t qOverPErr, Double_t lambdaErr, Double_t phi0Err,
258	Double_t dxyErr, Double_t dszErr)
259	{
260	// Set helix errors.
261
262	fQOverPErr = qOverPErr;
263	fLambdaErr = lambdaErr;
264	fPhi0Err = phi0Err;
265	fDxyErr = dxyErr;
266	fDszErr = dszErr;
267	}
268
269	//--------------------------------------------------------------------------------------------------
270	inline
271	const mithep::MCParticle *mithep::Track::MCPart() const
272	{
273	// Get reference to simulated particle.
274
275	return static_cast<const MCParticle*>(fMCParticleRef.GetObject());
276	}
277
278	//--------------------------------------------------------------------------------------------------
279	inline const mithep::SuperCluster *mithep::Track::SCluster() const
280	{
281	// Return Super cluster
282
283	return static_cast<const SuperCluster*>(fSuperClusterRef.GetObject());
284	}
285
286	//--------------------------------------------------------------------------------------------------
287	inline
288	const mithep::BitMask48 mithep::Track::StereoLayers()
289	{
290	// Build and return BitMask of stereo layers
291
292	mithep::BitMask48 stereoLayers;
293
294	stereoLayers.SetBit(mithep::Track::TIB1S);
295	stereoLayers.SetBit(mithep::Track::TIB2S);
296	stereoLayers.SetBit(mithep::Track::TID1S);
297	stereoLayers.SetBit(mithep::Track::TID2S);
298	stereoLayers.SetBit(mithep::Track::TID3S);
299	stereoLayers.SetBit(mithep::Track::TOB1S);
300	stereoLayers.SetBit(mithep::Track::TOB2S);
301	stereoLayers.SetBit(mithep::Track::TEC1S);
302	stereoLayers.SetBit(mithep::Track::TEC2S);
303	stereoLayers.SetBit(mithep::Track::TEC3S);
304	stereoLayers.SetBit(mithep::Track::TEC4S);
305	stereoLayers.SetBit(mithep::Track::TEC5S);
306	stereoLayers.SetBit(mithep::Track::TEC6S);
307	stereoLayers.SetBit(mithep::Track::TEC7S);
308	stereoLayers.SetBit(mithep::Track::TEC8S);
309	stereoLayers.SetBit(mithep::Track::TEC9S);
310
311	return stereoLayers;
312	}
313	#endif