void SetSPDSigmaDiffusionAsymmetry(Double_t ecc) {fSPDEccDiff=ecc;}
void GetSPDSigmaDiffusionAsymmetry(Double_t &ecc) const {ecc=fSPDEccDiff;}
+
+ void SetSPDAddNoisyFlag(Bool_t value) {fSPDAddNoisyFlag = value;}
+ Bool_t GetSPDAddNoisyFlag() {return fSPDAddNoisyFlag;}
+ void SetSPDRemoveDeadFlag(Bool_t value) {fSPDRemoveDeadFlag = value;}
+ Bool_t GetSPDRemoveDeadFlag() {return fSPDRemoveDeadFlag;}
+
void SetSDDElectronics(Int_t p1=1) {fSDDElectronics=p1; }
Int_t GetSDDElectronics() const {return fSDDElectronics;}
Double_t fSPDCouplCol; // SPD Coupling parameter along the cols
Double_t fSPDCouplRow; // SPD Coupling parameter along the rows
Float_t fSPDEccDiff; // Eccentricity (i.e. asymmetry parameter) in the
- // Gaussian diffusion for SPD
+ // Gaussian diffusion for SPD
+ Bool_t fSPDAddNoisyFlag; // Flag saying whether noisy pixels should be added to digits
+ Bool_t fSPDRemoveDeadFlag; // Flag saying whether dead pixels should be removed from digits
Int_t fSDDElectronics; // SDD Electronics Pascal (1) or OLA (2)
Float_t fSDDDiffCoeff; // SDD Diffusion Coefficient (scaling the time)
Double_t fN; // the impurity concentration of the material in #/cm^3 (NOT USED!)
Float_t fT; // The temperature of the Si in Degree K.
- ClassDef(AliITSSimuParam,2);
+ ClassDef(AliITSSimuParam,3);
};
#endif