void GetTypeOfFit(Bool_t &background, Int_t &typeb) const {background = fWithBkg; typeb = ftypeOfFit4Bkg;}
Int_t GetReflectionSigmaFactor() const {return ffactor;}
Double_t GetMean() const {return fMass;}
+ Double_t GetMeanUncertainty() const {return fMassErr;}
Double_t GetSigma()const {return fSigmaSgn;}
+ Double_t GetSigmaUncertainty()const { return fSigmaSgnErr;}
+ Double_t GetRawYield()const {return fRawYield;}
+ Double_t GetRawYieldError()const {return fRawYieldErr;}
Double_t GetChiSquare() const;
Double_t GetReducedChiSquare() const;
void GetSideBandsBounds(Int_t& lb, Int_t& hb) const;
Int_t ffactor; // number to multiply to the sigma of the signal to obtain the reflected gaussian
TNtuple* fntuParam; // contains fit parameters
Double_t fMass; // signal gaussian mean value
+ Double_t fMassErr; // err signal gaussian mean value
Double_t fSigmaSgn; // signal gaussian sigma
+ Double_t fSigmaSgnErr; // err signal gaussian sigma
+ Double_t fRawYield; // signal gaussian integral
+ Double_t fRawYieldErr; // err on signal gaussian integral
Bool_t fSideBands; // kTRUE = only side bands considered
Bool_t* fFixPar; //[fNFinalPars] for each par if kTRUE it is fixed in fit
Int_t fSideBandl; // left side band limit (bin number)
Int_t fSideBandr; // right side band limit (bin number)
Int_t fcounter; // internal counter
TList* fContourGraph; // TList of TGraph containing contour plots
- ClassDef(AliHFMassFitter,4); // class for invariant mass fit
+
+ ClassDef(AliHFMassFitter,6); // class for invariant mass fit
};
#endif