#ifndef __MFadc__ #define __MFadc__ // // class MFadc // // implemented by Harald Kornmayer // // This is a class to simulate the FADC. // It assumes a special response of the PMT for one single Photo-electron. // // // #include #include #include "TObject.h" #include "TRandom.h" #include "Mdefine.h" #include "MTriggerDefine.h" #include "MFadcDefine.h" class MMcEvt ; //========== // MFadc // // The simulation of the Flash ADC system for the MAGIC teleskop is done with // this class. // So all methods concerning the FADC System should be done inside this // class. // // The Idea is to (in)put the data of the photo electrons into the class and // generate the response (output) of the FADC to that input. Response means // in this sense the ADC values of the different time slices for all pixels // // The pixelisation is done by the camera program of Jose Carlos. // // This class is closly connected to the MTrigger classs. So some of the // values defined in MTriggerDefine.h are also used by this class. // // But a lot of other stuff is defined in MFadcDefine.h. // // class MFadc { private: // // then for all pixels the shape of all the analog signals // Bool_t used[CAMERA_PIXELS] ; // a boolean to indicated if the pixels is used in this event Float_t pedestal[CAMERA_PIXELS] ; // Pedestal of FADCs Float_t sig[CAMERA_PIXELS][(Int_t) SLICES_MFADC] ; // the analog signal for pixels Float_t noise[CAMERA_PIXELS*(Int_t) SLICES_MFADC*101]; UChar_t output[CAMERA_PIXELS][FADC_SLICES]; // the analog signal for pixels that is read after a trigger occurs (high gain). UChar_t output_lowgain[CAMERA_PIXELS][FADC_SLICES]; // analog signal, low gain. // // first the data for the response function // Float_t fwhm_resp ; // fwhm of the phe_response function (in ns) Float_t ampl_resp ; // area below curve of the phe_response function (in counts * ns) Float_t sing_resp[ RESPONSE_SLICES_MFADC ] ; // the shape of the phe_response function // // We may end up with a different reponse for the outer pixels // Float_t fwhm_resp_outer ; // fwhm of the phe_response function (in ns) Float_t ampl_resp_outer ; // area below curve of the phe_response function (in counts * ns) Float_t sing_resp_outer[ RESPONSE_SLICES_MFADC ] ; // the shape of the phe_response function // // RandomGenerator for the Electonic Noise // TRandom *GenElec ; public: MFadc(Float_t ampl=MFADC_RESPONSE_AMPLITUDE, Float_t fwhm=MFADC_RESPONSE_FWHM, Float_t amplout=MFADC_RESPONSE_AMPLITUDE, Float_t fwhmout=MFADC_RESPONSE_FWHM) ; void Reset() ; void Fill( Int_t, Float_t, Float_t, Int_t ) ; void Fill( Int_t, Float_t, Float_t ) ; void FillOuter( Int_t, Float_t, Float_t ) ; void Set( Int_t iPix, Float_t res[(Int_t) SLICES_MFADC]); void AddSignal( Int_t iPix, Float_t res[(Int_t) SLICES_MFADC]); void SetPedestals( Int_t ped); void SetPedestals( Float_t ped[CAMERA_PIXELS]); void SetFwhm( Float_t fwhm){ fwhm_resp=fwhm; } void SetAmpl( Float_t ampl){ ampl_resp=ampl; } void SetFwhmOuter( Float_t fwhm){ fwhm_resp_outer=fwhm; } void SetAmplOuter( Float_t ampl){ ampl_resp_outer=ampl; } void Baseline(); void Pedestals(); void Offset( Float_t, Int_t ); void SetElecNoise(Float_t value=2.0); void ElecNoise(Float_t value=2.0) ; void Scan() ; void Scan(Float_t time) ; void GetResponse( Float_t *resp ) ; void GetPedestals( Float_t *offset); void TriggeredFadc(Float_t time); void ShowSignal ( MMcEvt *McEvt , Float_t ) ; UChar_t GetFadcSignal(Int_t pixel, Int_t slice); UChar_t GetFadcLowGainSignal(Int_t pixel, Int_t slice); Float_t GetAmplitude() { return ampl_resp ; } Float_t GetFwhm() { return fwhm_resp ; } Float_t GetAmplitudeOuter() { return ampl_resp_outer ; } Float_t GetFwhmOuter() { return fwhm_resp_outer ; } } ; #endif