#ifndef ALITRDDIGITIZER_H #define ALITRDDIGITIZER_H /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * See cxx source for full Copyright notice */ /* $Id$ */ #include "AliDigitizer.h" class TFile; class TF1; class AliRunDigitizer; class AliTRD; class AliTRDdigitsManager; class AliTRDgeometry; /////////////////////////////////////////////////////// // Produces digits from the hits information // /////////////////////////////////////////////////////// class AliTRDdigitizer : public AliDigitizer { public: AliTRDdigitizer(); AliTRDdigitizer(const Text_t* name, const Text_t* title); AliTRDdigitizer(AliRunDigitizer *manager, const Text_t* name, const Text_t* title); AliTRDdigitizer(AliRunDigitizer *manager); AliTRDdigitizer(const AliTRDdigitizer &d); virtual ~AliTRDdigitizer(); AliTRDdigitizer &operator=(const AliTRDdigitizer &d); virtual void Copy(TObject &d); virtual Bool_t Init(); virtual Bool_t InitDetector(); virtual Bool_t ReInit(); virtual void Exec(Option_t* option = 0); virtual Bool_t Open(const Char_t *file, Int_t nEvent = 0); virtual Bool_t MakeBranch(const Char_t *file = 0); virtual Bool_t MakeDigits(); virtual void AddSDigitsManager(AliTRDdigitsManager *manager); virtual void DeleteSDigitsManager(); virtual Bool_t ConvertSDigits(); virtual Bool_t MergeSDigits(); virtual Bool_t SDigits2Digits(); virtual Bool_t WriteDigits(); virtual void SetGasGain(Float_t gasgain) { fGasGain = gasgain; }; virtual void SetNoise(Float_t noise) { fNoise = noise; }; virtual void SetChipGain(Float_t chipgain) { fChipGain = chipgain; }; virtual void SetADCoutRange(Float_t range) { fADCoutRange = range; }; virtual void SetADCinRange(Float_t range) { fADCinRange = range; }; virtual void SetADCthreshold(Int_t thresh) { fADCthreshold = thresh; }; virtual void SetDiffusion(Int_t diffOn = 1) { fDiffusionOn = diffOn; }; virtual void SetElAttach(Int_t elOn = 1) { fElAttachOn = elOn; }; virtual void SetElAttachProp(Float_t prop) { fElAttachProp = prop; }; virtual void SetExB(Int_t exbOn = 1) { fExBOn = exbOn; }; virtual void SetPadResponse(Int_t prfOn = 1) { fPRFOn = prfOn; }; virtual void SetTimeResponse(Int_t trfOn = 1) { fTRFOn = trfOn; ReInit(); }; virtual void SetCrossTalk(Int_t ctOn = 1) { fCTOn = ctOn; ReInit(); }; virtual void SetTailCancelation(Int_t tcOn = 1) { fTCOn = tcOn; }; virtual void SetNexponential(Int_t nexp) { fTCnexp = nexp; }; virtual void SetDriftVelocity(Float_t v) { fDriftVelocity = v; ReInit(); }; virtual void SetPadCoupling(Float_t v) { fPadCoupling = v; }; virtual void SetTimeCoupling(Float_t v) { fTimeCoupling = v; }; virtual void SetTiltingAngle(Float_t v); virtual void SetCompress(Int_t c = 1) { fCompress = c; }; virtual void SetDebug(Int_t v = 1) { fDebug = v; }; virtual void SetSDigits(Int_t v = 1) { fSDigits = v; }; virtual void SetSDigitsScale(Float_t s) { fSDigitsScale = s; }; virtual void SetEvent(Int_t v = 0) { fEvent = v; }; virtual void SetManager(AliTRDdigitsManager *man) { fDigitsManager = man; }; AliTRDdigitsManager *Digits() const { return fDigitsManager; }; Float_t GetGasGain() const { return fGasGain; }; Float_t GetNoise() const { return fNoise; }; Float_t GetChipGain() const { return fChipGain; }; Float_t GetADCoutRange() const { return fADCoutRange; }; Float_t GetADCinRange() const { return fADCinRange; }; Int_t GetADCthreshold() const { return fADCthreshold; }; Float_t GetDiffusionT() const { return fDiffusionT; }; Float_t GetDiffusionL() const { return fDiffusionL; }; Float_t GetElAttachProp() const { return fElAttachProp; }; Int_t GetExB() const { return fExBOn; }; Float_t GetOmegaTau() const { return fOmegaTau; }; Float_t GetDriftVelocity() const { return fDriftVelocity; }; Float_t GetPadCoupling() const { return fPadCoupling; }; Float_t GetTimeCoupling() const { return fTimeCoupling; }; Bool_t GetCompress() const { return fCompress; }; Bool_t GetSDigits() const { return fSDigits; }; Float_t GetSDigitsScale() const { return fSDigitsScale; }; Float_t GetTimeBinWidth() const { return fTimeBinWidth; }; Float_t GetTiltingAngle() const; virtual Float_t GetDiffusionL(Float_t vd, Float_t b); virtual Float_t GetDiffusionT(Float_t vd, Float_t b); virtual Float_t GetOmegaTau(Float_t vd, Float_t b); protected: TFile *fInputFile; //! ALIROOT-file AliTRDdigitsManager *fDigitsManager; //! Manager for the output digits AliTRDdigitsManager *fSDigitsManager; //! Manager for the summed input s-digits TList *fSDigitsManagerList; //! List of managers of input s-digits AliTRD *fTRD; //! TRD detector class AliTRDgeometry *fGeo; //! TRD geometry Int_t fEvent; //! Event number Int_t *fMasks; //! Masks for the merging Float_t fField; // Magnetic field Float_t fGasGain; // Gas gain Float_t fNoise; // Electronics noise Float_t fChipGain; // Electronics gain Float_t fADCoutRange; // ADC output range (number of channels) Float_t fADCinRange; // ADC input range (input charge) Int_t fADCthreshold; // ADC threshold in ADC channel Int_t fDiffusionOn; // Switch for the diffusion Float_t fDiffusionT; // Diffusion in transverse direction Float_t fDiffusionL; // Diffusion in longitudinal direction Int_t fElAttachOn; // Switch for the electron attachment Float_t fElAttachProp; // Propability for electron attachment (for 1m) Int_t fExBOn; // Switch for the ExB effects Float_t fOmegaTau; // Tangens of the Lorentz angle Float_t fLorentzFactor; // Factor due to Lorentz force Int_t fPRFOn; // Switch for the pad response Float_t *fPRFsmp; //! Sampled pad response Int_t fPRFbin; // Number of bins for the PRF Float_t fPRFlo; // Lower boundary of the PRF Float_t fPRFhi; // Higher boundary of the PRF Float_t fPRFwid; // Bin width of the sampled PRF Int_t fPRFpad; // Distance to next pad in PRF Int_t fTRFOn; // Switch for the time response Float_t *fTRFsmp; //! Integrated time response Int_t fTRFbin; // Number of bins for the TRF Float_t fTRFlo; // Lower boundary of the TRF Float_t fTRFhi; // Higher boundary of the TRF Float_t fTRFwid; // Bin width of the integrated TRF Int_t fCTOn; // Switch for cross talk Float_t *fCTsmp; //! Integrated cross talk Int_t fTCOn; // Switch for the tail cancelation Int_t fTCnexp; // Number of exponential of the digital filter Float_t fDriftVelocity; // Drift velocity (cm / mus) Float_t fTimeBinWidth; // Time bin width in ns Float_t fPadCoupling; // Pad coupling factor Float_t fTimeCoupling; // Time coupling factor (image charge of moving ions) Float_t fTiltingAngle; // Tilting angle of the readout pads Bool_t fCompress; // Switch to keep only compressed data in memory Int_t fDebug; // Sets the debug level Bool_t fSDigits; // Switch for the summable digits Float_t fSDigitsScale; // Scale factor for the summable digits private: virtual Float_t Col0Tilted(Float_t col0, Float_t rowOffset, Int_t plane); virtual Float_t CrossTalk(Float_t time); virtual Int_t Diffusion(Float_t driftlength, Float_t *xyz); virtual Int_t ExB(Float_t driftlength, Float_t *xyz); virtual Int_t PadResponse(Float_t signal, Float_t dist, Int_t plane, Float_t *pad); virtual Float_t TimeResponse(Float_t time); virtual void DeConvExp(Double_t *source, Double_t *target, Int_t n, Int_t nexp); virtual Bool_t CheckDetector(Int_t plane, Int_t chamber, Int_t sector); virtual void SamplePRF(); virtual void SampleTRF(); ClassDef(AliTRDdigitizer,6) // Produces TRD-Digits }; #endif