1 #ifndef ALIMUONRAWCLUSTER_H
2 #define ALIMUONRAWCLUSTER_H
4 /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
5 * See cxx source for full Copyright notice */
8 // Revision of includes 07/05/2004
11 /// \class AliMUONRawCluster
12 /// \brief MUON raw cluster
14 /// Class for the MUON RecPoint
15 /// It contains the properties of the physics cluters found in the tracking chambers
16 /// RawCluster contains also the information from the both cathode of the chambers.
19 #include "AliMUONVCluster.h"
20 #include <TMath.h> // because of inline funtion GetRadius
23 class AliMUONRawCluster : public AliMUONVCluster {
27 virtual ~AliMUONRawCluster();
29 /// Clear method (used by TClonesArray)
30 virtual void Clear(Option_t* = "") {}
32 /// Create a copy of the current cluster
33 virtual AliMUONRawCluster* Clone(const char* = "") const {return new AliMUONRawCluster(*this);}
35 /// Set coordinates (cm)
36 virtual void SetXYZ(Double_t x, Double_t y, Double_t z) {fX[0] = x; fY[0] = y; fZ[0] = z;}
37 /// Return coordinate X (cm)
38 virtual Double_t GetX() const {return fX[0];}
39 /// Return coordinate Y (cm)
40 virtual Double_t GetY() const {return fY[0];}
41 /// Return coordinate Z (cm)
42 virtual Double_t GetZ() const {return fZ[0];}
44 /// Set resolution (cm) on coordinates (X,Y)
45 virtual void SetErrXY(Double_t errX, Double_t errY) {fErrXY[0] = errX; fErrXY[1] = errY;}
46 /// Return resolution (cm) on coordinate X
47 virtual Double_t GetErrX() const {return fErrXY[0];}
48 /// Return resolution**2 (cm**2) on coordinate X
49 virtual Double_t GetErrX2() const {return fErrXY[0] * fErrXY[0];}
50 /// Return resolution (cm) on coordinate Y
51 virtual Double_t GetErrY() const {return fErrXY[1];}
52 /// Return resolution**2 (cm**2) on coordinate Y
53 virtual Double_t GetErrY2() const {return fErrXY[1] * fErrXY[1];}
55 /// Set the cluster charge
56 virtual void SetCharge(Double_t q) {fQ[0] = q;}
57 /// Set the cluster charge
58 virtual Double_t GetCharge() const {return fQ[0];}
61 virtual Int_t GetChamberId() const {return fDetElemId/100 - 1;}
62 /// Set detection element Id
63 void SetDetElemId(Int_t id) {fDetElemId = id;}
64 /// Return detection element Id
65 virtual Int_t GetDetElemId() const {return fDetElemId;}
67 virtual void SetDigitsId(Int_t nDigits, const UInt_t *digitsId);
68 /// Add a digit Id to the array of associated digits
69 virtual void AddDigitId(UInt_t id) {fIndexMap[fMultiplicity[0]++][0] = id;}
71 /// Return number of associated digits
72 virtual Int_t GetNDigits() const {return fMultiplicity[0];}
73 /// Return Id of digits i
74 virtual UInt_t GetDigitId(Int_t i) const {return (i < fMultiplicity[0] && i < 50) ? (UInt_t)fIndexMap[i][0] : 0;}
76 /// Set chi2 of cluster
77 virtual void SetChi2( Double_t chi2) {fChi2[0] = chi2;}
78 /// Return chi2 of cluster
79 virtual Double_t GetChi2() const {return fChi2[0];}
82 Float_t GetRadius(Int_t i) {return TMath::Sqrt(fX[i]*fX[i]+fY[i]*fY[i]);}
83 /// Return true as the function Compare() is implemented
84 Bool_t IsSortable() const {return kTRUE;}
85 Int_t Compare(const TObject *obj) const;
86 Int_t PhysicsContribution() const;
87 virtual void Print(Option_t* opt="") const;
88 static Int_t BinarySearch(Float_t r, TArrayF ccord, Int_t from, Int_t upto);
89 static void SortMin(Int_t *idx,Float_t *xdarray, Float_t *xarray, Float_t *yarray, Float_t *qarray,Int_t ntr);
92 Int_t AddCharge(Int_t i, Float_t Q);
93 Int_t AddX(Int_t i, Float_t X);
94 Int_t AddY(Int_t i, Float_t Y);
95 Int_t AddZ(Int_t i, Float_t Z);
97 Float_t GetCharge(Int_t i) const;
98 Float_t GetX(Int_t i) const;
99 Float_t GetY(Int_t i) const;
100 Float_t GetZ(Int_t i) const;
101 Int_t GetTrack(Int_t i=0) const;
102 Float_t GetPeakSignal(Int_t i=0) const;
103 Int_t GetMultiplicity(Int_t i=0) const;
104 Int_t GetClusterType() const;
105 Int_t GetGhost() const;
106 Int_t GetNcluster(Int_t i=0) const;
107 Float_t GetChi2(Int_t i) const;
108 Int_t GetIndex(Int_t i, Int_t j) const;
109 Int_t GetOffset(Int_t i, Int_t j) const;
110 Float_t GetContrib(Int_t i, Int_t j) const;
111 Int_t GetPhysics(Int_t i) const;
113 Int_t SetCharge(Int_t i, Float_t Q);
114 Int_t SetX(Int_t i, Float_t X);
115 Int_t SetY(Int_t i, Float_t Y);
116 Int_t SetZ(Int_t i, Float_t Z);
117 Int_t SetTrack(Int_t i, Int_t track);
118 Int_t SetPeakSignal(Int_t i, Float_t peaksignal);
119 Int_t SetMultiplicity(Int_t i, Int_t mul);
120 Int_t SetClusterType(Int_t type);
121 Int_t SetGhost(Int_t ghost);
122 Int_t SetNcluster(Int_t i, Int_t ncluster);
123 Int_t SetChi2(Int_t i, Float_t chi2);
124 void SetIndex(Int_t i, Int_t j, Int_t index);
125 void SetOffset(Int_t i, Int_t j, Int_t offset);
126 void SetContrib(Int_t i, Int_t j, Float_t contrib);
127 void SetPhysics(Int_t i, Int_t physics);
130 Int_t fIndexMap[50][2]; ///< Indices of digits
131 Int_t fOffsetMap[50][2]; ///< Emmanuel special
132 Float_t fContMap[50][2]; ///< Contribution from digit
133 Int_t fPhysicsMap[50]; ///< Distinguish signal and background contr.
135 Float_t fQ[2] ; ///< Q of cluster (in ADC counts)
136 Float_t fX[2] ; ///< X of cluster
137 Float_t fY[2] ; ///< Y of cluster
138 Float_t fZ[2] ; ///< Z of cluster
139 Int_t fTracks[3]; ///< Labels of overlapped tracks
140 Float_t fPeakSignal[2]; ///< Peak signal
141 Int_t fMultiplicity[2]; ///< Cluster multiplicity
142 Int_t fClusterType; ///< Cluster type
143 Int_t fGhost; ///< Ghost info
144 // 0 if not a ghost or ghost problem solved
145 // >0 if ghost problem remains because
146 // 1 both (true and ghost) satify
147 // charge chi2 compatibility
148 // 2 none give satisfactory chi2
149 Int_t fNcluster[2]; ///< Number of clusters
150 Float_t fChi2[2]; ///< Chi**2 of fit
151 Int_t fDetElemId; ///< ID number of the detection element (slat) on which the cluster is found.
152 Float_t fErrXY[2]; ///< coordinate errors
154 ClassDef(AliMUONRawCluster,3) //Cluster class for MUON
159 /// Return Indices of digits
160 inline Int_t AliMUONRawCluster::GetIndex(Int_t i, Int_t j) const
161 { return fIndexMap[i][j]; }
163 /// Return Emmanuel special offset map
164 inline Int_t AliMUONRawCluster::GetOffset(Int_t i, Int_t j) const
165 { return fOffsetMap[i][j]; }
167 /// Return Contribution from digit
168 inline Float_t AliMUONRawCluster::GetContrib(Int_t i, Int_t j) const
169 { return fContMap[i][j]; }
171 /// Return Distinguish signal and background contr.
172 inline Int_t AliMUONRawCluster::GetPhysics(Int_t i) const
173 { return fPhysicsMap[i]; }
175 /// Set Indices of digits
176 inline void AliMUONRawCluster::SetIndex(Int_t i, Int_t j, Int_t index)
177 { fIndexMap[i][j] = index; }
179 /// Set Emmanuel special offset map
180 inline void AliMUONRawCluster::SetOffset(Int_t i, Int_t j, Int_t offset)
181 { fOffsetMap[i][j] = offset; }
183 /// Set Contribution from digit
184 inline void AliMUONRawCluster::SetContrib(Int_t i, Int_t j, Float_t contrib)
185 { fContMap[i][j] = contrib; }
187 /// Set Distinguish signal and background contr.
188 inline void AliMUONRawCluster::SetPhysics(Int_t i, Int_t physics)
189 { fPhysicsMap[i] = physics; }