static AliMUONRecoParam *GetLowFluxParam();
static AliMUONRecoParam *GetHighFluxParam();
+ static AliMUONRecoParam *GetCosmicParam();
+ /// set the calibration mode (see GetCalibrationMode() for possible modes)
+ void SetCalibrationMode(Option_t* mode) { fCalibrationMode = mode; fCalibrationMode.ToUpper();}
+
+ Option_t* GetCalibrationMode() const;
+
/// set the clustering (pre-clustering) mode
- void SetClusteringMode(Option_t* mode) {fClusteringMode = mode;}
+ void SetClusteringMode(Option_t* mode) {fClusteringMode = mode; fClusteringMode.ToUpper();}
/// get the clustering (pre-clustering) mode
Option_t* GetClusteringMode() const {return fClusteringMode.Data();}
/// set the tracking mode
- void SetTrackingMode(Option_t* mode) {fTrackingMode = mode;}
+ void SetTrackingMode(Option_t* mode) {fTrackingMode = mode; fTrackingMode.ToUpper();}
/// get the tracking mode
Option_t* GetTrackingMode() const {return fTrackingMode.Data();}
/// return the percentage of events for which all cluster info are stored in ESD
Double_t GetPercentOfFullClusterInESD() const {return fPercentOfFullClusterInESD;}
+ /// set the most probable value (GeV/c) of momentum in bending plane
+ /// needed to get some "reasonable" corrections for MCS and E loss even if B = 0
+ void SetMostProbBendingMomentum(Double_t val) {fMostProbBendingMomentum = val;}
+ /// return the most probable value (GeV/c) of momentum in bending plane
+ Double_t GetMostProbBendingMomentum() const {return fMostProbBendingMomentum;}
+
/// set the minimum value (GeV/c) of momentum in bending plane
void SetMinBendingMomentum(Double_t val) {fMinBendingMomentum = val;}
/// return the minimum value (GeV/c) of momentum in bending plane
void SetMaxBendingMomentum(Double_t val) {fMaxBendingMomentum = val;}
/// return the maximum value (GeV/c) of momentum in bending plane
Double_t GetMaxBendingMomentum() const {return fMaxBendingMomentum;}
+ /// set the maximum value of the non bending slope
+ void SetMaxNonBendingSlope(Double_t val) {fMaxNonBendingSlope = val;}
+ /// return the maximum value of the non bending slope
+ Double_t GetMaxNonBendingSlope() const {return fMaxNonBendingSlope;}
/// set the vertex dispersion (cm) in non bending plane (used for original tracking only)
void SetNonBendingVertexDispersion(Double_t val) {fNonBendingVertexDispersion = val;}
/// return kTRUE/kFALSE if the fast building of track candidates is switched on/off
Bool_t MakeTrackCandidatesFast() const {return fMakeTrackCandidatesFast;}
+ /// switch on/off the building of track candidates starting from 1 cluster in each of the stations 4 and 5
+ void MakeMoreTrackCandidates(Bool_t flag) {fMakeMoreTrackCandidates = flag;}
+ /// return kTRUE/kFALSE if the building of extra track candidates is switched on/off
+ Bool_t MakeMoreTrackCandidates() const {return fMakeMoreTrackCandidates;}
+
/// switch on/off the completion of reconstructed track
void ComplementTracks(Bool_t flag) {fComplementTracks = flag;}
/// return kTRUE/kFALSE if completion of the reconstructed track is switched on/off
/// return kTRUE/kFALSE if the use of the smoother is switched on/off
Bool_t UseSmoother() const {return fUseSmoother;}
- virtual void Print(Option_t *option = "") const;
+ /// switch on/off a chamber in the reconstruction
+ void UseChamber(Int_t iCh, Bool_t flag) {if (iCh >= 0 && iCh < 10) fUseChamber[iCh] = flag;}
+ /// return kTRUE/kFALSE whether the chamber must be used or not
+ Bool_t UseChamber(Int_t iCh) const {return (iCh >= 0 && iCh < 10) ? fUseChamber[iCh] : kFALSE;}
+
+ /// request or not at least one cluster in the station to validate the track
+ void RequestStation(Int_t iSt, Bool_t flag) {if (iSt >= 0 && iSt < 5) fRequestStation[iSt] = flag;}
+ /// return kTRUE/kFALSE whether at least one cluster is requested in the station to validate the track
+ Bool_t RequestStation(Int_t iSt) const {return (iSt >= 0 && iSt < 5) ? fRequestStation[iSt] : kFALSE;}
+
+ /// set the bypassSt45 value
+ void BypassSt45(Bool_t value) { fBypassSt45 = value; }
+ /// return kTRUE if we should replace clusters in St 4 and 5 by generated clusters from trigger tracks
+ Bool_t BypassSt45() const { return fBypassSt45; }
+
+ virtual void Print(Option_t *option = "") const;
private:
/// tracking mode: ORIGINAL, KALMAN
TString fTrackingMode; ///< \brief name of the tracking mode
+ Double32_t fMostProbBendingMomentum; ///< most probable value (GeV/c) of muon momentum in bending plane (used when B = 0)
+
Double32_t fMinBendingMomentum; ///< minimum value (GeV/c) of momentum in bending plane
Double32_t fMaxBendingMomentum; ///< maximum value (GeV/c) of momentum in bending plane
+ Double32_t fMaxNonBendingSlope; ///< maximum value of the non bending slope
Double32_t fNonBendingVertexDispersion; ///< vertex dispersion (cm) in non bending plane (used for original tracking only)
Double32_t fBendingVertexDispersion; ///< vertex dispersion (cm) in bending plane (used for original tracking only)
Bool_t fMakeTrackCandidatesFast; ///< kTRUE to make candidate tracks assuming linear propagation between stations 4 and 5
+ Bool_t fMakeMoreTrackCandidates; ///< kTRUE to make candidate tracks starting from 1 cluster in each of the stations 4 and 5
+
Bool_t fComplementTracks; ///< kTRUE to try to complete the reconstructed tracks by adding missing clusters
Bool_t fImproveTracks; ///< kTRUE to try to improve the reconstructed tracks by removing bad clusters
Bool_t fSaveFullClusterInESD; ///< kTRUE to save all cluster info (including pads) in ESD
+ /// calibration mode: GAIN, NOGAIN, GAINCONSTANTCAPA
+ TString fCalibrationMode; ///<\brief calibration mode
+
+ Bool_t fBypassSt45; ///< kTRUE to use trigger tracks to generate "fake" clusters in St 4 and 5
+
+ Bool_t fUseChamber[10]; ///< kTRUE to use the chamber i in the tracking algorithm
+
+ Bool_t fRequestStation[5]; ///< kTRUE to request at least one cluster in station i to validate the track
+
// functions
void SetLowFluxParam();
void SetHighFluxParam();
+ void SetCosmicParam();
- ClassDef(AliMUONRecoParam,1) // MUON reco parameters
+ ClassDef(AliMUONRecoParam,4) // MUON reco parameters
};
#endif