#ifndef MARS_MHCalibrationBlindPixel #define MARS_MHCalibrationBlindPixel #ifndef MARS_MH #include "MH.h" #endif #ifndef MARS_MHCalibrationConfig #include "MHCalibrationConfig.h" #endif #ifndef ROOT_TH1 #include "TH1.h" #endif #ifndef ROOT_TH1F #include "TH1F.h" #endif #ifndef ROOT_TF1 #include "TF1.h" #endif #ifndef ROOT_TPaveText #include "TPaveText.h" #endif class TMath; class MParList; class MHCalibrationBlindPixel : public MH { private: TH1F* fHBlindPixelCharge; //-> Histogram with the single Phe spectrum TH1I* fHBlindPixelTime; //-> Variance of summed FADC slices TH1I* fHBlindPixelChargevsN; //-> Summed Charge vs. Event Nr. TF1 *fSinglePheFit; TF1 *fTimeGausFit; TF1 *fSinglePhePedFit; Axis_t fBlindPixelChargefirst; Axis_t fBlindPixelChargelast; Int_t fBlindPixelChargenbins; void ResetBin(Int_t i); void DrawLegend(); TPaveText *fFitLegend; Bool_t fFitOK; BlindPixelFitFunc fgSinglePheFitFunc; // In the beginning, Int_t fgSinglePheFitNPar; // we want to be flexible using different functions Double_t fLambda; Double_t fMu0; Double_t fMu1; Double_t fSigma0; Double_t fSigma1; Double_t fLambdaErr; Double_t fMu0Err; Double_t fMu1Err; Double_t fSigma0Err; Double_t fSigma1Err; Double_t fChisquare; Double_t fProb; Int_t fNdf; Double_t fMeanTime; Double_t fMeanTimeErr; Double_t fSigmaTime; Double_t fSigmaTimeErr; Double_t fLambdaCheck; Double_t fLambdaCheckErr; public: MHCalibrationBlindPixel(const char *name=NULL, const char *title=NULL); ~MHCalibrationBlindPixel(); Bool_t FillBlindPixelCharge(Float_t q) { return fHBlindPixelCharge->Fill(q) > -1; } Bool_t FillBlindPixelTime(Int_t t) { return fHBlindPixelTime->Fill(t) > -1; } Bool_t FillBlindPixelChargevsN(Stat_t rq, Int_t t) { return fHBlindPixelChargevsN->Fill(t,rq) > -1; } const Double_t GetLambda() const { return fLambda; } const Double_t GetLambdaCheck() const { return fLambdaCheck; } const Double_t GetMu0() const { return fMu0; } const Double_t GetMu1() const { return fMu1; } const Double_t GetSigma0() const { return fSigma0; } const Double_t GetSigma1() const { return fSigma1; } const Double_t GetLambdaErr() const { return fLambdaErr; } const Double_t GetLambdaCheckErr() const { return fLambdaCheckErr; } const Double_t GetMu0Err() const { return fMu0Err; } const Double_t GetMu1Err() const { return fMu1Err; } const Double_t GetSigma0Err() const { return fSigma0Err; } const Double_t GetSigma1Err() const { return fSigma1Err; } const Double_t GetChiSquare() const { return fChisquare; } const Double_t GetProb() const { return fProb; } const Int_t GetNdf() const { return fNdf; } const Double_t GetMeanTime() const { return fMeanTime; } const Double_t GetMeanTimeErr() const { return fMeanTimeErr; } const Double_t GetSigmaTime() const { return fSigmaTime; } const Double_t GetSigmaTimeErr() const { return fSigmaTimeErr; } Bool_t SimulateSinglePhe(Double_t lambda, Double_t mu0, Double_t mu1, Double_t sigma0, Double_t sigma1); Bool_t FitSinglePhe(Axis_t rmin=0, Axis_t rmax=0, Option_t *opt="RL0+Q"); Bool_t FitTime(Axis_t rmin=0., Axis_t rmax=0.,Option_t *opt="R0+Q"); void ChangeFitFunc(BlindPixelFitFunc fitfunc, Int_t par=5); void CutAllEdges(); void Draw(Option_t *option=""); Bool_t IsFitOK() { return fFitOK; } ClassDef(MHCalibrationBlindPixel, 1) }; #endif /* MARS_MHCalibrationBlindPixel */