SetInjLineRange(2,170,240);
SetTimeStep(25.);
}
- void SetPolOrder(Int_t n){fPolOrder=n;}
+ void SetPolDegree(Int_t n){fPolDegree=n;}
void SetMinDriftSpeed(Float_t vmin){fMinDriftSpeed=vmin;}
void SetMaxDriftSpeed(Float_t vmax){fMaxDriftSpeed=vmax;}
void SetMaxDriftSpeedErr(Float_t maxval){
fFirstPadForFit=firstpad;
fLastPadForFit=lastpad;
}
- void SetPadStatusCutForFit(Int_t cutval=1){
+ void SetPadStatusCutForFit(Int_t cutval=4){
fPadStatusCutForFit=cutval;
}
void SetDefaults();
void CalcDriftSpeed(Int_t jpad);
void CalcTimeBinZero();
void FitDriftSpeedVsAnode();
+ void PolyFit(Int_t degree=3);
Double_t GetMeanDriftSpeed(Int_t ipad) const{
- if(fNEvents==0) return 0.;
- return fSumDriftSpeed[ipad]/(Double_t)fNEvents;
+ if(fNEventsInPad[ipad]==0) return 0.;
+ return fSumDriftSpeed[ipad]/(Double_t)fNEventsInPad[ipad];
}
Double_t GetRMSDriftSpeed(Int_t ipad) const;
+ Double_t GetMeanPadStatusCut(Int_t ipad) const{
+ if(fNEventsInPad[ipad]==0) return 0.;
+ return (Double_t)fSumPadStatusCut[ipad]/(Double_t)fNEventsInPad[ipad];
+ }
+ Double_t GetMeanPadStatus(Int_t ipad) const{
+ if(fNEvents==0) return 0.;
+ return (Double_t)fSumPadStatus[ipad]/(Double_t)fNEvents;
+ }
+
void FitMeanDriftSpeedVsAnode();
protected:
static const Float_t fgkDefaultMinSpeed; // Default for fMinDriftSpeed
static const Float_t fgkDefaultMaxSpeed; // Default for fMaxDriftSpeed
static const Float_t fgkDefaultMaxErr; // Default for fMaxDriftSpeedErr
- static const Int_t fgkDefaultPolOrder; // Default for fPolOrder
+ static const Int_t fgkDefaultPolDegree; // Default for fPolDegree
static const Float_t fgkDefaultTimeStep; // Default for fTimeStep
static const UShort_t fgkDefaultTbMin[kInjLines]; // Defaults for fTbMin
static const UShort_t fgkDefaultTbMax[kInjLines]; // Defaults for fTbMax
Double_t fTbZero; // Time zero for injector event
Double_t fRMSTbZero; // Error on time zero
Double_t fPosition[kInjLines]; // Coordinates of injector lines
- UShort_t fTbMin[kInjLines]; // Minimum time bin for each line
- UShort_t fTbMax[kInjLines]; // Maximum time bin for each line
- Bool_t fGoodInj[kInjPads][kInjLines]; // array of good injectors
+ UShort_t fTbMin[kInjLines]; // Minimum time bin for each line
+ UShort_t fTbMax[kInjLines]; // Maximum time bin for each line
+ Bool_t fGoodInj[kInjPads][kInjLines]; // array of good injectors
Double_t fCentroid[kInjPads][kInjLines]; // array of time bin centroids
Double_t fRMSCentroid[kInjPads][kInjLines]; // array of time rms of injectors
Double_t fDriftSpeed[kInjPads]; // drift speed
Double_t fDriftSpeedErr[kInjPads]; // error on drift speed
- Int_t fNEvents; // number of events
+ Int_t fNEvents; // number of events
+ Int_t fNEventsInPad[kInjPads]; // number of events per pad
Double_t fSumDriftSpeed[kInjPads]; // drift speed summed over events
Double_t fSumSqDriftSpeed[kInjPads]; // drift speed^2 sum
+ Int_t fSumPadStatus[kInjPads]; // pad status sum
+ Int_t fSumPadStatusCut[kInjPads]; // pad status (> cut) sum
- Double_t *fParam; // parameters of polinomial fit to
+ Double_t *fParam; // parameters of polinomial fit to
// drift speed vs. anode number
- Int_t fPolOrder; // order of polinomial fit
+ Int_t fPolDegree; // Degree of polynomial fit
+ Int_t fActualPolDegree; // Degree actually used (<=fPolDegree)
Float_t fMinDriftSpeed; // Minimum value for drift speed
Float_t fMaxDriftSpeed; // Maximum value for drift speed
Float_t fMaxDriftSpeedErr; // Maximum value for error on drift speed
Bool_t fUseTimeZeroSignal; // flag for usage of time zero signal
// in drift speed calculation
- ClassDef(AliITSOnlineSDDInjectors,7)
+ ClassDef(AliITSOnlineSDDInjectors,8)
};
#endif