#include <TObject.h>
-#include <TVectorD.h>
+#include <TVectorDfwd.h>
+#include <TMatrixDfwd.h>
class TTree;
class TObjArray;
+class TH1;
+class THnBase;
//_____________________________________________________________________________
class AliTPCClusterParam : public TObject {
public:
static AliTPCClusterParam* Instance();
AliTPCClusterParam();
AliTPCClusterParam(const AliTPCClusterParam& param);
- AliTPCClusterParam & operator=(const AliTPCClusterParam&);
+ AliTPCClusterParam & operator=(const AliTPCClusterParam& param);
virtual ~AliTPCClusterParam();
virtual void Print(Option_t* option = "") const;
- void SetInstance(AliTPCClusterParam*param){fgInstance = param;}
+ void SetInstance(AliTPCClusterParam *const param){fgInstance = param;}
//
// Seting functions
//
void FitData(TTree * tree);
void FitResol(TTree * tree);
void FitRMS(TTree * tree);
- void SetQnorm(Int_t ipad, Int_t itype, TVectorD * norm);
+ void SetQnorm(Int_t ipad, Int_t itype, const TVectorD *const norm);
+ void SetQnormCorr(Int_t ipad, Int_t itype, Int_t corrType, Float_t val);
+ Double_t GetQnormCorr(Int_t ipad, Int_t itype, Int_t corrType) const;
+ TMatrixD *GetQnormCorrMatrix(){return fQNormCorr;};
+ void ResetQnormCorr();
+ void SetWaveCorrectionMap( THnBase *WaveCorrectionMap);
+ void SetResolutionYMap( THnBase *ResolutionYMap);
//
// Charge parameterization
//
Float_t Qnorm(Int_t ipad, Int_t itype, Float_t dr, Float_t ty, Float_t tz);
+ Float_t QnormHis(Int_t ipad, Int_t itype, Float_t dr, Float_t ty, Float_t tz);
- Float_t QnormPos(Int_t ipad, Bool_t isMax, Float_t pad, Float_t time, Float_t z, Float_t sy2, Float_t sz2, Float_t qm, Float_t qt);
+ Float_t QnormPos(Int_t ipad, Bool_t isMax, Float_t pad, Float_t time, Float_t z, Float_t sy2, Float_t sz2, Float_t qm, Float_t qt);
+ static Float_t SQnormPos(Int_t ipad, Bool_t isMax, Float_t pad, Float_t time, Float_t z, Float_t sy2, Float_t sz2, Float_t qm, Float_t qt){ return fgInstance->QnormPos(ipad,isMax,pad,time,z,sy2,sz2,qm,qt);;}
+
+ Float_t PosCorrection(Int_t type, Int_t ipad, Float_t pad, Float_t time, Float_t z, Float_t sy2, Float_t sz2, Float_t qm);
+ static Float_t SPosCorrection(Int_t type, Int_t ipad, Float_t pad, Float_t time, Float_t z, Float_t sy2, Float_t sz2, Float_t qm){ return fgInstance->PosCorrection(type,ipad,pad,time,z,sy2,sz2,qm);}
//
// Error parameterization
//
- Float_t GetError0(Int_t dim, Int_t type, Float_t z, Float_t angle);
- Float_t GetError0Par(Int_t dim, Int_t type, Float_t z, Float_t angle);
- Float_t GetError1(Int_t dim, Int_t type, Float_t z, Float_t angle);
- Float_t GetErrorQ(Int_t dim, Int_t type, Float_t z, Float_t angle, Float_t Qmean);
- Float_t GetErrorQPar(Int_t dim, Int_t type, Float_t z, Float_t angle, Float_t Qmean);
- Float_t GetErrorQParScaled(Int_t dim, Int_t type, Float_t z, Float_t angle, Float_t Qmean);
+ Float_t GetError0(Int_t dim, Int_t type, Float_t z, Float_t angle) const;
+ Float_t GetError0Par(Int_t dim, Int_t type, Float_t z, Float_t angle) const;
+ Float_t GetError1(Int_t dim, Int_t type, Float_t z, Float_t angle) const;
+ Float_t GetErrorQ(Int_t dim, Int_t type, Float_t z, Float_t angle, Float_t Qmean) const;
+ Float_t GetErrorQPar(Int_t dim, Int_t type, Float_t z, Float_t angle, Float_t Qmean) const;
+ Float_t GetErrorQParScaled(Int_t dim, Int_t type, Float_t z, Float_t angle, Float_t Qmean) const;
//
// Shape parameterization
//
- Float_t GetRMS0(Int_t dim, Int_t type, Float_t z, Float_t angle);
- Float_t GetRMS1(Int_t dim, Int_t type, Float_t z, Float_t angle);
- Float_t GetRMSQ(Int_t dim, Int_t type, Float_t z, Float_t angle, Float_t Qmean);
- Float_t GetRMSSigma(Int_t dim, Int_t type, Float_t z, Float_t angle, Float_t Qmean);
- Float_t GetShapeFactor(Int_t dim, Int_t type, Float_t z, Float_t angle, Float_t Qmean, Float_t rmsL, Float_t rmsM);
+ Float_t GetRMS0(Int_t dim, Int_t type, Float_t z, Float_t angle) const;
+ Float_t GetRMS1(Int_t dim, Int_t type, Float_t z, Float_t angle) const;
+ Float_t GetRMSQ(Int_t dim, Int_t type, Float_t z, Float_t angle, Float_t Qmean) const;
+ Float_t GetRMSSigma(Int_t dim, Int_t type, Float_t z, Float_t angle, Float_t Qmean) const;
+ Float_t GetShapeFactor(Int_t dim, Int_t type, Float_t z, Float_t angle, Float_t Qmean, Float_t rmsL, Float_t rmsM) const;
+ //
+ // Correction and resolution maps
+ //
+ const THnBase *GetWaveCorrectionMap() const { return fWaveCorrectionMap; }
+ const THnBase *GetResolutionYMap() const { return fResolutionYMap; }
+ Float_t GetWaveCorrection(Int_t Type, Float_t Z, Int_t QMax, Float_t Pad, Float_t angleY ) const;
+ static Float_t SGetWaveCorrection(Int_t Type, Float_t Z, Int_t QMax, Float_t Pad, Float_t angleY ){return fgInstance->SGetWaveCorrection(Type,Z,QMax,Pad,angleY);}
//
//
//
//
//
static Float_t SQnorm(Int_t ipad, Int_t itype,Float_t dr, Float_t ty, Float_t tz) {return fgInstance->Qnorm(ipad, itype, dr,ty,tz);}
+ static Float_t SQnormHis(Int_t ipad, Int_t itype,Float_t dr, Float_t ty, Float_t tz) {return fgInstance->QnormHis(ipad, itype, dr,ty,tz);}
+ //
+ // Analytical position angular correction
+ //
+ static Double_t GaussConvolution(Double_t x0, Double_t x1, Double_t k0, Double_t k1, Double_t s0, Double_t s1);
+ static Double_t GaussConvolutionTail(Double_t x0, Double_t x1, Double_t k0, Double_t k1, Double_t s0, Double_t s1, Double_t tau);
+ static Double_t GaussConvolutionGamma4(Double_t x0, Double_t x1, Double_t k0, Double_t k1, Double_t s0, Double_t s1, Double_t tau);
+ static Double_t QmaxCorrection(Int_t sector, Int_t row, Float_t cpad, Float_t ctime, Float_t ky, Float_t kz, Float_t rmsy0, Float_t rmsz0, Float_t effLength=0, Float_t effDiff=1);
+ static Double_t QtotCorrection(Int_t sector, Int_t row, Float_t cpad, Float_t ctime, Float_t ky, Float_t kz, Float_t rmsy0, Float_t rmsz0, Float_t qtot, Float_t thr, Float_t effLength=0, Float_t effDiff=1);
- public:
//
//
//
void FitRMSQ(TTree * tree, Int_t dim, Int_t type, Float_t *param0, Float_t *error);
void FitRMSSigma(TTree * tree, Int_t dim, Int_t type, Float_t *param0, Float_t *error);
//
+ TVectorD*& PosYcor(Int_t ind) {return fPosYcor[ind];}
+ TVectorD*& PosZcor(Int_t ind) {return fPosZcor[ind];}
+ Float_t ParamS0Par(Int_t i, Int_t j, Int_t k) const {return fParamS0Par[i][j][k];}
+ TVectorD* QpadTnorm() const {return fQpadTnorm;}
+ TVectorD* QpadMnorm() const {return fQpadMnorm;}
+protected:
Float_t fRatio; //ratio of values constibution to error
Float_t fParamS0[2][3][4]; //error parameterization coeficients
Float_t fErrorS0[2][3][4]; //error parameterization coeficients
// charge normalization parametrization
//
TObjArray *fQNorm; // q norm paramters
- TVectorD *fPosQTnorm[3]; // q position normalization
- TVectorD *fPosQMnorm[3]; // q position normalization
- TVectorD *fQpadTnorm; // q pad normalization - Total charge
- TVectorD *fQpadMnorm; // q pad normalization - Max charge
+ TMatrixD *fQNormCorr; // q norm correction for analytica correction
+ TObjArray *fQNormHis; // q norm correction for analytical correction
+ //
+ TVectorD *fPosQTnorm[3]; // q position normalization
+ TVectorD *fPosQMnorm[3]; // q position normalization
+ TVectorD *fQpadTnorm; // q pad normalization - Total charge
+ TVectorD *fQpadMnorm; // q pad normalization - Max charge
+ //
+ // Position corrections
+ //
+ TVectorD *fPosYcor[3]; // position correction parameterization
+ TVectorD *fPosZcor[3]; // position correction parameterization
+ //
+ // Wave Correction Map
+ //
+ THnBase* fWaveCorrectionMap; //dY with respect to the distance to the center of the pad
+ Bool_t fWaveCorrectionMirroredPad; // flag is the cog axis mirrored at 0.5
+ Bool_t fWaveCorrectionMirroredZ; // flag is the Z axis mirrored at 0
+ Bool_t fWaveCorrectionMirroredAngle; // flag is the Angle axis mirrored at 0
+ //
+ // Resolution Map
+ //
+ THnBase* fResolutionYMap; // Map of resolution in Y
//
- protected:
static AliTPCClusterParam* fgInstance; //! Instance of this class (singleton implementation)
- ClassDef(AliTPCClusterParam,2) // TPC Cluster parameter class
+ ClassDef(AliTPCClusterParam,7) // TPC Cluster parameter class
};
#endif