+ TH1D *fPed[kDET]; // reconstructed pedestals distribution (on hist per chamber)
+ TH1D *fNoise[kDET]; // reconstructed noise distribution (on hist per chamber)
+ TH1D *fChPP[kDET]; // peak to peak for each chamber
+ TH1D *fNPointDist[kDET]; // distributin of the number of points
+ TH2D *fChPed[kDET]; // Some histograms
+ TH2D *fChNoise[kDET]; // Some histograms
+ TH2D *fNPoint[kDET]; // number of data points
+ TH3F *fData[kDET]; // Some histograms
+ TH1D *fSignal[kDET]; // Some histograms
+ TH2D *fnEntriesRM[kDET]; // number of entries for ROB - MCM
+ TH1D *fnEntriesRMDist[kDET]; // distribtion of number of entries per ROB-MCM
+
+ // after reference subtraction
+ TH2D *fChPedRes[kDET]; // histograms after reference subtraction
+ TH2D *fChNoiseRes[kDET]; // histograms after reference subtraction
+
+ TH2D *fTBEvent; // coherent noise
+
+ TH2D *fRefHistPed; // reference distributions
+ TH2D *fRefHistNoise; // reference distributions
+
+ TH2S *fFullSignal[kDET*kROB*kMCM]; // one histogram per MCM
+ Short_t fFullCounter[kDET*kROB*kMCM]; // counts a number of entries with high signal
+
+ // error codes
+ TH1D *fErrorHC; // number of errors HC
+ TH1D *fErrorMCM; // number of errors MCM
+ TH1D *fErrorADC; // number of errors ADC
+
+ TH1D *fErrorSMHC; // number of errors in HC per SM
+ TH1D *fErrorSMMCM; // number of errors in MCM per SM
+ TH1D *fErrorSMADC; // number of errors in ADC per SM