* See cxx source for full Copyright notice */
/* $Id$ */
+// Revision of includes 07/05/2004
+
+/// \ingroup base
+/// \class AliMUONRawCluster
+/// \brief MUON raw cluster
+///
+/// Class for the MUON RecPoint
+/// It contains the propeorties of the physics cluters found in the tracking chambers
+/// RawCluster contains also the information from the both cathode of the chambers.
-class TArrayF;
#include <TObject.h>
#include <TMath.h> // because of inline funtion GetRadius
-
+#include <TArrayF.h>
class AliMUONRawCluster : public TObject {
+
public:
+ AliMUONRawCluster();
+ virtual ~AliMUONRawCluster() { }
+ Float_t GetRadius(Int_t i) {return TMath::Sqrt(fX[i]*fX[i]+fY[i]*fY[i]);}
+ Bool_t IsSortable() const {return kTRUE;}
+ Int_t Compare(const TObject *obj) const;
+ Int_t PhysicsContribution() const;
+ static Int_t BinarySearch(Float_t r, TArrayF ccord, Int_t from, Int_t upto);
+ static void SortMin(Int_t *idx,Float_t *xdarray, Float_t *xarray, Float_t *yarray, Float_t *qarray,Int_t ntr);
+ void DumpIndex();
- Int_t fTracks[3]; //labels of overlapped tracks
+ Int_t AddCharge(Int_t i, Int_t Q);
+ Int_t AddX(Int_t i, Float_t X);
+ Int_t AddY(Int_t i, Float_t Y);
+ Int_t AddZ(Int_t i, Float_t Z);
+
+ Int_t GetCharge(Int_t i) const;
+ Float_t GetX(Int_t i) const;
+ Float_t GetY(Int_t i) const;
+ Float_t GetZ(Int_t i) const;
+ Int_t GetTrack(Int_t i) const;
+ Int_t GetPeakSignal(Int_t i) const;
+ Int_t GetMultiplicity(Int_t i) const;
+ Int_t GetClusterType() const;
+ Int_t GetGhost() const;
+ Int_t GetNcluster(Int_t i) const;
+ Float_t GetChi2(Int_t i) const;
+ Int_t GetIndex(Int_t i, Int_t j) const;
+ Int_t GetOffset(Int_t i, Int_t j) const;
+ Float_t GetContrib(Int_t i, Int_t j) const;
+ Int_t GetPhysics(Int_t i) const;
+ Int_t GetDetElemId() const ;
+ Float_t GetError(Int_t iXY) const;
+ Float_t GetErrX() const;
+ Float_t GetErrY() const;
+
+ Int_t SetCharge(Int_t i,Int_t Q);
+ Int_t SetX(Int_t i, Float_t X);
+ Int_t SetY(Int_t i, Float_t Y);
+ Int_t SetZ(Int_t i, Float_t Z);
+ void SetDetElemId(Int_t Id);
+ Int_t SetTrack(Int_t i, Int_t track);
+ Int_t SetPeakSignal(Int_t i, Int_t peaksignal);
+ Int_t SetMultiplicity(Int_t i, Int_t mul);
+ Int_t SetClusterType(Int_t type);
+ Int_t SetGhost(Int_t ghost);
+ Int_t SetNcluster(Int_t i, Int_t ncluster);
+ Int_t SetChi2(Int_t i, Float_t chi2);
+ void SetIndex(Int_t i, Int_t j, Int_t index);
+ void SetOffset(Int_t i, Int_t j, Int_t offset);
+ void SetContrib(Int_t i, Int_t j, Float_t contrib);
+ void SetPhysics(Int_t i, Int_t physics);
+ void SetError(Int_t iXY, Float_t err);
+ void SetErrX(Float_t err);
+ void SetErrY(Float_t err);
+
+private:
+ Int_t fIndexMap[50][2]; // indeces of digits
+ Int_t fOffsetMap[50][2]; // Emmanuel special
+ Float_t fContMap[50][2]; // Contribution from digit
+ Int_t fPhysicsMap[50]; // Distinguish signal and background contr.
+
Int_t fQ[2] ; // Q of cluster (in ADC counts)
Float_t fX[2] ; // X of cluster
Float_t fY[2] ; // Y of cluster
Float_t fZ[2] ; // Z of cluster
+ Int_t fTracks[3]; //labels of overlapped tracks
Int_t fPeakSignal[2]; // Peak signal
- Int_t fIndexMap[50][2]; // indeces of digits
- Int_t fOffsetMap[50][2]; // Emmanuel special
- Float_t fContMap[50][2]; // Contribution from digit
- Int_t fPhysicsMap[50]; // Distinguish signal and background contr.
Int_t fMultiplicity[2]; // Cluster multiplicity
- Int_t fNcluster[2]; // Number of clusters
Int_t fClusterType; // Cluster type
+ Int_t fGhost; // 0 if not a ghost or ghost problem solved
+ // >0 if ghost problem remains because
+ // 1 both (true and ghost) satify
+ // charge chi2 compatibility
+ // 2 none give satisfactory chi2
+ Int_t fNcluster[2]; // Number of clusters
Float_t fChi2[2]; // Chi**2 of fit
-
- public:
- AliMUONRawCluster();
- virtual ~AliMUONRawCluster() {}
- Float_t GetRadius(Int_t i) {return TMath::Sqrt(fX[i]*fX[i]+fY[i]*fY[i]);}
- Bool_t IsSortable() const {return kTRUE;}
- Int_t Compare(const TObject *obj) const;
- Int_t PhysicsContribution();
- static Int_t BinarySearch(Float_t r, TArrayF ccord, Int_t from, Int_t upto);
- static void SortMin(Int_t *idx,Float_t *xdarray, Float_t *xarray,
- Float_t *yarray, Float_t *qarray,Int_t ntr);
+ Int_t fDetElemId; // ID number of the detection element (slat) on which the cluster is found.
+ Float_t fErrXY[2]; // coordinate errors
ClassDef(AliMUONRawCluster,1) //Cluster class for MUON
};
+
+// inline functions
+
+inline Int_t AliMUONRawCluster::GetIndex(Int_t i, Int_t j) const
+{ return fIndexMap[i][j]; }
+
+inline Int_t AliMUONRawCluster::GetOffset(Int_t i, Int_t j) const
+{ return fOffsetMap[i][j]; }
+
+inline Float_t AliMUONRawCluster::GetContrib(Int_t i, Int_t j) const
+{ return fContMap[i][j]; }
+
+inline Int_t AliMUONRawCluster::GetPhysics(Int_t i) const
+{ return fPhysicsMap[i]; }
+
+inline void AliMUONRawCluster::SetIndex(Int_t i, Int_t j, Int_t index)
+{ fIndexMap[i][j] = index; }
+
+inline void AliMUONRawCluster::SetOffset(Int_t i, Int_t j, Int_t offset)
+{ fOffsetMap[i][j] = offset; }
+
+inline void AliMUONRawCluster::SetContrib(Int_t i, Int_t j, Float_t contrib)
+{ fContMap[i][j] = contrib; }
+
+inline void AliMUONRawCluster::SetPhysics(Int_t i, Int_t physics)
+{ fPhysicsMap[i] = physics; }
+
+inline void AliMUONRawCluster::SetDetElemId(Int_t Id)
+{ fDetElemId = Id; }
+
+inline Int_t AliMUONRawCluster::GetDetElemId() const
+{ return fDetElemId;}
+
+inline void AliMUONRawCluster::SetError(Int_t iXY, Float_t err)
+{ fErrXY[iXY] = err; }
+
+inline void AliMUONRawCluster::SetErrX(Float_t err)
+{ SetError(0, err); }
+
+inline void AliMUONRawCluster::SetErrY(Float_t err)
+{ SetError(1, err); }
+
+inline Float_t AliMUONRawCluster::GetError(Int_t iXY) const
+{ return fErrXY[iXY]; }
+
+inline Float_t AliMUONRawCluster::GetErrX() const
+{ return GetError(0); }
+
+inline Float_t AliMUONRawCluster::GetErrY() const
+{ return GetError(1); }
+
#endif