-#ifndef ALITOFSDigitizer_H
-#define ALITOFSDigitizer_H
+#ifndef ALITOFSDIGITIZER_H
+#define ALITOFSDIGITIZER_H
+
/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
* See cxx source for full Copyright notice */
+//__________________________________________//
+// //
+// Class for making SDigits in TOF //
+// //
+//-- Authors: F. Pierella, A. De Caro //
+// //
+//__________________________________________//
+
+/* $Id$ */
-//_________________________________________________________________________
-// Task Class for making SDigits in TOF
-//
-//-- Author: F. Pierella
+#include "TNamed.h"
+class TF1;
+class TString;
-#include "TTask.h"
-#include "TString.h"
-#include "AliTOF.h"
-#include "AliDetector.h"
+class AliLoader;
+class AliRunLoader;
-class AliTOFSDigitizer: public TTask {
+class AliTOFcalib;
+
+class AliTOFSDigitizer: public TNamed {
public:
AliTOFSDigitizer() ; // ctor
- AliTOFSDigitizer(char* HeaderFile, char *SdigitsFile = 0) ;
+ //AliTOFSDigitizer(const char* HeaderFile) ; // par ctor
+ AliTOFSDigitizer(const char* HeaderFile, Int_t evNumber1=-1, Int_t nEvents=0) ; // par ctor
- virtual ~AliTOFSDigitizer() ; // dtor
- // Int_t Digitize(Float_t Energy);
+ AliTOFSDigitizer(const AliTOFSDigitizer &source); // copy constructor
+ AliTOFSDigitizer& operator=(const AliTOFSDigitizer &/*source*/); // ass. op.
-// char *GetSDigitsFile() const {return const_cast<char*>(fSDigitsFile.Data());}
- const char *GetSDigitsFile() const {return fSDigitsFile.Data();}
- virtual void Exec(Option_t *option);
- void SetNEvents(Int_t Nevents) {fNevents = Nevents;}
- Int_t GetNEvents() const {return fNevents;}
- void SetSDigitsFile(char * file ) ;
- virtual void Print(Option_t* option) const ;
- TClonesArray *SDigits() const {return fSDigits;}
- TClonesArray *Hits() const {return fHits;}
+ virtual ~AliTOFSDigitizer() ; // dtor
+ //static Float_t WidthTdcBin() {return fgkTdcBin;};
+
+ virtual void Digitize(Option_t *verboseOption);
+ void SetSDigitsFile(char * /*file*/ ) const {;}
+
+ void InitParameters();
+ virtual void PrintParameters() const ;
+ virtual void SimulateDetectorResponse(Float_t z0, Float_t x0, Float_t geantTime, Int_t& nActivatedPads, Int_t& nFiredPads, Bool_t* isFired, Int_t* nPlace, Float_t* qInduced, Float_t* tofTime, Float_t& averageTime);
+ virtual void SimulateDetectorResponseOLD(Float_t z0, Float_t x0, Float_t geantTime, Int_t& nActivatedPads, Int_t& nFiredPads, Bool_t* isFired, Int_t* nPlace, Float_t* qInduced, Float_t* tofTime, Float_t& averageTime);
+ virtual void Print(Option_t* opt) const ;
+ void SetFirstEvent(Int_t event1) {fEvent1 = event1;}
+ void SetSecondEvent(Int_t event2) {fEvent2 = event2;}
+ Int_t GetFirstEvent() const {return fEvent1;}
+ Int_t GetSecondEvent() const {return fEvent2;}
+ Int_t GetNEvents() const {return (fEvent2-fEvent1);}
+ void SelectSectorAndPlate(Int_t sector, Int_t plate);
+
+ // setters and getters for detector simulation
+ // it summarizes all it is known about TOF strip
+ void SetPadefficiency(Float_t padefficiency) {fpadefficiency=padefficiency;}
+ void SetEdgeEffect(Int_t edgeEffect) {fEdgeEffect=edgeEffect;}
+ void SetEdgeTails(Int_t edgeTails) {fEdgeTails=edgeTails;}
+ void SetHparameter(Float_t hparameter) {fHparameter=hparameter;}
+ void SetH2parameter(Float_t h2parameter) {fH2parameter=h2parameter;}
+ void SetKparameter(Float_t kparameter) {fKparameter=kparameter;}
+ void SetK2parameter(Float_t k2parameter) {fK2parameter=k2parameter;}
+ void SetEffCenter(Float_t effCenter) {fEffCenter=effCenter;}
+ void SetEffBoundary(Float_t effBoundary) {fEffBoundary=effBoundary;}
+ void SetEff2Boundary(Float_t eff2Boundary) {fEff2Boundary=eff2Boundary;}
+ void SetEff3Boundary(Float_t eff3Boundary) {fEff3Boundary=eff3Boundary;}
+ void SetAddTRes(Float_t addTRes) {fAddTRes=addTRes;}
+ void SetResCenter (Float_t resCenter) {fResCenter=resCenter;}
+ void SetResBoundary(Float_t resBoundary) {fResBoundary=resBoundary;}
+ void SetResSlope(Float_t resSlope) {fResSlope=resSlope;}
+ void SetTimeWalkCenter(Float_t timeWalkCenter) {fTimeWalkCenter=timeWalkCenter;}
+ void SetTimeWalkBoundary(Float_t timeWalkBoundary){fTimeWalkBoundary=timeWalkBoundary;}
+ void SetTimeWalkSlope(Float_t timeWalkSlope) {fTimeWalkSlope=timeWalkSlope;}
+
+ void SetTimeDelayFlag(Int_t timeDelayFlag) {fTimeDelayFlag=timeDelayFlag;}
+ void SetPulseHeightSlope(Float_t pulseHeightSlope){fPulseHeightSlope=pulseHeightSlope;}
+ void SetTimeDelaySlope(Float_t timeDelaySlope) {fTimeDelaySlope=timeDelaySlope;}
+ void SetMinimumCharge(Float_t minimumCharge) {fMinimumCharge=minimumCharge;}
+ void SetChargeSmearing(Float_t chargeSmearing) {fChargeSmearing=chargeSmearing;}
+ void SetLogChargeSmearing(Float_t logChargeSmearing){fLogChargeSmearing=logChargeSmearing;}
+ void SetTimeSmearing(Float_t timeSmearing) {fTimeSmearing=timeSmearing;}
+ void SetAverageTimeFlag(Int_t averageTimeFlag) {fAverageTimeFlag=averageTimeFlag;}
+
+ void SetAdcBin(Float_t adcBin) {fAdcBin=adcBin;}
+ void SetAdcMean(Float_t adcMean) {fAdcMean=adcMean;}
+ void SetAdcRms(Float_t adcRms) {fAdcRms=adcRms;}
+
+ void SetTimeResolution(Float_t time) {fTimeResolution=time;}
+
+ Float_t GetPadefficiency() const {return fpadefficiency;}
+ Int_t GetEdgeEffect() const {return fEdgeEffect;}
+ Int_t GetEdgeTails() const {return fEdgeTails;}
+ Float_t GetHparameter() const {return fHparameter;}
+ Float_t GetH2parameter() const {return fH2parameter;}
+ Float_t GetKparameter() const {return fKparameter;}
+ Float_t GetK2parameter() const {return fK2parameter;}
+ Float_t GetEffCenter() const {return fEffCenter;}
+ Float_t GetEffBoundary() const {return fEffBoundary;}
+ Float_t GetEff2Boundary() const {return fEff2Boundary;}
+ Float_t GetEff3Boundary() const {return fEff3Boundary;}
+ Float_t GetAddTRes () const {return fAddTRes;}
+ Float_t GetResCenter () const {return fResCenter;}
+ Float_t GetResBoundary() const {return fResBoundary;}
+ Float_t GetResSlope() const {return fResSlope;}
+ Float_t GetTimeWalkCenter() const {return fTimeWalkCenter;}
+ Float_t GetTimeWalkBoundary() const {return fTimeWalkBoundary;}
+ Float_t GetTimeWalkSlope() const {return fTimeWalkSlope;}
+ Int_t GetTimeDelayFlag() const {return fTimeDelayFlag;}
+ Float_t GetPulseHeightSlope() const {return fPulseHeightSlope;}
+ Float_t GetTimeDelaySlope() const {return fTimeDelaySlope;}
+ Float_t GetMinimumCharge() const {return fMinimumCharge;}
+ Float_t GetChargeSmearing() const {return fChargeSmearing;}
+ Float_t GetLogChargeSmearing()const {return fLogChargeSmearing;}
+ Float_t GetTimeSmearing() const {return fTimeSmearing;}
+ Int_t GetAverageTimeFlag() const {return fAverageTimeFlag;}
+
+ Float_t GetAdcBin() const {return fAdcBin;}
+ Float_t GetAdcMean() const {return fAdcMean;}
+ Float_t GetAdcRms() const {return fAdcRms;}
+
+ Float_t GetTimeResolution() const {return fTimeResolution;}
+
+
+protected:
private:
- Int_t fNevents; // Number of events to digitize
- TString fSDigitsFile; // output file
- TClonesArray *fSDigits; // array of summable digits
- TClonesArray *fHits; // array of summable digits
+ Int_t fEvent1; // lower bound for events to sdigitize
+ Int_t fEvent2; // upper bound for events to sdigitize
+ TF1 *ftail; // pointer to formula for time with tail
TString fHeadersFile; // input file
-
- protected:
-
-
- ClassDef(AliTOFSDigitizer,1) // creates TOF SDigits
+ AliRunLoader* fRunLoader; //! Run Loader
+ AliLoader* fTOFLoader; //! Loader
+
+ Int_t fSelectedSector; // sector number for sdigitization
+ Int_t fSelectedPlate ; // plate number for sdigitization
+
+ // detector response simulation
+ // Intrisic MRPC time resolution and pad (edge effect) parameters
+ Float_t fTimeResolution; // time resolution (ps)
+ Float_t fpadefficiency; // intrinsic pad efficiency, used if fEdgeEffect==0
+ Int_t fEdgeEffect; // edge effects option
+ Int_t fEdgeTails; // edge tails option
+ Float_t fHparameter; // sensitive edge (to produce hits on the neighbouring pads)
+ // 0.7 cm (old); 0.4 cm (new)
+ Float_t fH2parameter; // parameter to fit the efficiency
+ Float_t fKparameter; // sensitive edge (going ahead towards the center
+ // no delay effects are suffered) 1.0 cm (old); 0.5 cm (new)
+ Float_t fK2parameter; // parameter to fit the efficiency
+ // Pad Efficiency and Resolution parameters
+ Float_t fEffCenter; // efficiency in the central region of the pad
+ Float_t fEffBoundary; // efficiency at the boundary of the pad
+ Float_t fEff2Boundary; // efficiency value at H2parameter
+ Float_t fEff3Boundary; // efficiency value at K2parameter
+ Float_t fAddTRes; // additional contribution to
+ // the intrinsic MRPC time resolution (ps)
+ Float_t fResCenter; // resolution (ps) in the central region of the pad
+ Float_t fResBoundary; // resolution (ps) at the boundary of the pad
+ Float_t fResSlope; // slope (ps/K) for neighbouring pad
+ // Time Walk parameters
+ Float_t fTimeWalkCenter; // time walk (ps) in the central region of the pad
+ Float_t fTimeWalkBoundary;// time walk (ps) at the boundary of the pad
+ Float_t fTimeWalkSlope; // slope (ps/K) for neighbouring pad
+ Int_t fTimeDelayFlag; // flag for delay due to the PulseHeightEffect
+ Float_t fPulseHeightSlope;// It determines the charge amount induced
+ // due to edge effect, using the formula
+ // qInduced=exp(-PulseHeightSlope*x)
+ Float_t fTimeDelaySlope; // It determines the time delay. This is the slope
+ // in the T1-T2 vs log(q1/q2) plot
+ // ADC-TDC correlation parameters
+ Float_t fMinimumCharge; // Minimum charge amount which could be induced
+ Float_t fChargeSmearing; // Smearing in charge in (q1/q2) vs x plot
+ Float_t fLogChargeSmearing;// Smearing in log of charge ratio
+ Float_t fTimeSmearing; // Smearing in time in time vs log(q1/q2) plot
+ Int_t fAverageTimeFlag; // flag (see the setter for details)
+
+ Float_t fAdcBin; // charge-window for the ADC bins [pC]
+ Float_t fAdcMean; // mean value for the ADC spectrum [bins]
+ Float_t fAdcRms; // rms value for the ADC spectrum [bins]
+
+ AliTOFcalib * fCalib; //! calibration object
+
+ ClassDef(AliTOFSDigitizer,5) // creates TOF SDigits
};
-#endif // AliTOFSDigitizer_H
+#endif // AliTOFSDIGITIZER_H