#ifndef ALIITSRESPONSE_H
#define ALIITSRESPONSE_H
+/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
+ * See cxx source for full Copyright notice */
-#include <TObject.h>
+/* $Id$ */
-#include "AliITSsegmentation.h"
+#include <TObject.h>
+#include <TString.h>
+class AliITSsegmentation;
class TF1;
-class TString;
class AliITSgeom;
//----------------------------------------------
//
// Set Electronics
- virtual void SetElectronics(Int_t) {}
+ virtual void SetElectronics(Int_t) = 0;
// Get Electronics
- virtual Int_t Electronics() {return 0;}
+ virtual Int_t Electronics() const = 0;
// Set maximum Adc-count value
- virtual void SetMaxAdc(Float_t) {}
+ virtual void SetMaxAdc(Float_t) = 0;
// Get maximum Adc-count value
- virtual Float_t MaxAdc() {return 0.;}
+ virtual Float_t MaxAdc() const = 0;
// Set maximum Adc-top value
- virtual void SetDynamicRange(Float_t) {}
+ virtual void SetDynamicRange(Float_t) = 0;
// Get maximum Adc-top value
- virtual Float_t DynamicRange() {return 0.0;}
+ virtual Float_t DynamicRange() const = 0;
// Set Charge Loss Linear Coefficient
- virtual void SetChargeLoss(Float_t) {}
+ virtual void SetChargeLoss(Float_t) = 0;
// Get Charge Loss Linear Coefficient
- virtual Float_t ChargeLoss() {return 0.0;}
+ virtual Float_t ChargeLoss() const = 0;
+
+ // Set GeVcharge value
+ virtual void SetGeVToCharge(Float_t gc=2.778E+8){fGeVcharge = gc;}
+ // Returns the value fGeVcharge
+ virtual Float_t GetGeVToCharge() const {return fGeVcharge;}
+ // Converts deposited energy to number of electrons liberated
+ virtual Float_t GeVToCharge(Float_t gev) const {return gev*fGeVcharge;}
// Diffusion coefficient
- virtual void SetDiffCoeff(Float_t, Float_t) {}
+ virtual void SetDiffCoeff(Float_t, Float_t) = 0;
// Get diffusion coefficients
- virtual void DiffCoeff(Float_t &,Float_t &) {}
+ virtual void DiffCoeff(Float_t &,Float_t &) const = 0;
// Temperature in [degree K]
virtual void SetTemperature(Float_t t=300.0) {fT = t;}
// Get temperature [degree K]
- virtual Float_t Temperature() {return fT;}
+ virtual Float_t Temperature() const {return fT;}
// Type of data - real or simulated
- virtual void SetDataType(const char *) {}
+ virtual void SetDataType(const char *data="simulated") {fDataType=data;}
// Set the impurity concentrations in [#/cm^3]
virtual void SetImpurity(Double_t n=0.0){fN = n;}
// Returns the impurity consentration in [#/cm^3]
- virtual Double_t Impurity(){return fN;}
+ virtual Double_t Impurity() const {return fN;}
// Sets the applied ratio distance/voltage [cm/volt]
virtual void SetDistanceOverVoltage(Double_t d,Double_t v){fdv = d/v;}
// Sets the applied ration distance/voltage [cm/volt]. Default value
// is 300E-4cm/80 volts = 0.000375 cm/volts
virtual void SetDistanceOverVoltage(Double_t dv=0.000375){fdv = dv;}
// Returns the ration distance/voltage
- virtual Double_t DistanceOverVoltage(){return fdv;}
+ virtual Double_t DistanceOverVoltage() const {return fdv;}
// Get data type
- virtual const char *DataType() const {return "";}
+ virtual const char *DataType() const {return fDataType.Data();}
// Set parameters options: "same" or read from "file" or "SetInvalid" or...
- virtual void SetParamOptions(const char*,const char*) {}
+ virtual void SetParamOptions(const char*,const char*) = 0;
// Set noise parameters
- virtual void SetNoiseParam(Float_t, Float_t) {}
+ virtual void SetNoiseParam(Float_t, Float_t) = 0;
// Number of parameters to be set
- virtual void SetNDetParam(Int_t) {}
+ virtual void SetNDetParam(Int_t) = 0;
// Set detector parameters: gain, coupling ...
- virtual void SetDetParam(Float_t *) {}
+ virtual void SetDetParam(Float_t *) = 0;
// Parameters options
- virtual void ParamOptions(char *,char*) {}
- virtual Int_t NDetParam() {return 0;}
- virtual void GetDetParam(Float_t *) {}
- virtual void GetNoiseParam(Float_t&, Float_t&) {}
+ virtual void ParamOptions(char *,char*) const = 0;
+ virtual Int_t NDetParam() const = 0;
+ virtual void GetDetParam(Float_t *) const = 0;
+ virtual void GetNoiseParam(Float_t&, Float_t&) const = 0;
// Zero-suppression option - could be 1D, 2D or non-ZeroSuppressed
- virtual void SetZeroSupp(const char*) {}
+ virtual void SetZeroSupp(const char*) = 0;
// Get zero-suppression option
- virtual const char *ZeroSuppOption() const {return "";}
+ virtual const char *ZeroSuppOption() const = 0;
// Set thresholds
- virtual void SetThresholds(Float_t, Float_t) {}
- virtual void Thresholds(Float_t &, Float_t &) {}
- // Set min val
- virtual void SetMinVal(Int_t) {};
- virtual Int_t MinVal() {return 0;};
+ virtual void SetThresholds(Float_t, Float_t) = 0;
+ virtual void Thresholds(Float_t &, Float_t &) const = 0;
// Set filenames
- virtual void SetFilenames(const char *,const char *,const char *) {}
+ virtual void SetFilenames(const char *f1="",const char *f2="",const char *f3=""){
+ // Set filenames - input, output, parameters ....
+ fFileName1=f1; fFileName2=f2; fFileName3=f3;}
// Filenames
- virtual void Filenames(char*,char*,char*) {}
-
- virtual Float_t DriftSpeed() {return 0.;}
- virtual Bool_t OutputOption() {return kFALSE;}
- virtual Bool_t Do10to8() {return kTRUE;}
- virtual void GiveCompressParam(Int_t *) {}
-
+ virtual void Filenames(char* input,char* baseline,char* param) {
+ strcpy(input,fFileName1.Data()); strcpy(baseline,fFileName2.Data());
+ strcpy(param,fFileName3.Data());}
+
+ virtual void SetDriftSpeed(Float_t p1) = 0;
+ virtual Float_t DriftSpeed() const = 0;
+ virtual void SetOutputOption(Bool_t write=kFALSE) {// set output option
+ fWrite = write;}
+ virtual Bool_t OutputOption() const {return fWrite;}
+ virtual Bool_t Do10to8() const {return kTRUE;}
+ virtual void GiveCompressParam(Int_t *) const =0;
//
// Detector type response methods
// Set number of sigmas over which cluster disintegration is performed
- virtual void SetNSigmaIntegration(Float_t) {}
+ virtual void SetNSigmaIntegration(Float_t) = 0;
// Get number of sigmas over which cluster disintegration is performed
- virtual Float_t NSigmaIntegration() {return 0.;}
+ virtual Float_t NSigmaIntegration() const = 0;
// Set number of bins for the gaussian lookup table
- virtual void SetNLookUp(Int_t) {}
+ virtual void SetNLookUp(Int_t) = 0;
// Get number of bins for the gaussian lookup table
- virtual Int_t GausNLookUp() {return 0;}
+ virtual Int_t GausNLookUp() const {return 0;}
// Get scaling factor for bin i-th from the gaussian lookup table
- virtual Float_t GausLookUp(Int_t) {return 0.;}
+ virtual Float_t GausLookUp(Int_t) const {return 0.;}
// Set sigmas of the charge spread function
- virtual void SetSigmaSpread(Float_t, Float_t) {}
+ virtual void SetSigmaSpread(Float_t, Float_t) = 0;
// Get sigmas for the charge spread
- virtual void SigmaSpread(Float_t &,Float_t &) {}
-
+ virtual void SigmaSpread(Float_t &,Float_t &) const = 0;
// Pulse height from scored quantity (eloss)
- virtual Float_t IntPH(Float_t) {return 0.;}
+ virtual Float_t IntPH(Float_t) const {return 0.;}
// Charge disintegration
- virtual Float_t IntXZ(AliITSsegmentation *) {return 0.;}
+ virtual Float_t IntXZ(AliITSsegmentation *) const {return 0.;}
// Electron mobility in Si. [cm^2/(Volt Sec)]. T in degree K, N in #/cm^3
- virtual Double_t MobilityElectronSiEmp();
+ virtual Double_t MobilityElectronSiEmp() const ;
// Hole mobility in Si. [cm^2/(Volt Sec)] T in degree K, N in #/cm^3
- virtual Double_t MobilityHoleSiEmp();
+ virtual Double_t MobilityHoleSiEmp() const ;
// Einstein relation for Diffusion Coefficient of Electrons. [cm^2/sec]
// T in degree K, N in #/cm^3
- virtual Double_t DiffusionCoefficientElectron();
+ virtual Double_t DiffusionCoefficientElectron() const ;
// Einstein relation for Diffusion Coefficient of Holes. [cm^2/sec]
// T in [degree K], N in [#/cm^3]
- virtual Double_t DiffusionCoefficientHole();
+ virtual Double_t DiffusionCoefficientHole() const ;
// Electron <speed> under an applied electric field E=Volts/cm. [cm/sec]
// d distance-thickness in [cm], v in [volts], T in [degree K],
// N in [#/cm^3]
- virtual Double_t SpeedElectron();
+ virtual Double_t SpeedElectron() const ;
// Holes <speed> under an applied electric field E=Volts/cm. [cm/sec]
// d distance-thickness in [cm], v in [volts], T in [degree K],
// N in [#/cm^3]
- virtual Double_t SpeedHole();
+ virtual Double_t SpeedHole() const ;
// Returns the Gaussian sigma == <x^2+z^2> [cm^2] due to the defusion of
// electrons or holes through a distance l [cm] caused by an applied
// voltage v [volt] through a distance d [cm] in any material at a
// temperature T [degree K].
- virtual Double_t SigmaDiffusion3D(Double_t);
+ virtual Double_t SigmaDiffusion3D(Double_t l) const ;
// Returns the Gaussian sigma == <x^2 +y^2+z^2> [cm^2] due to the
// defusion of electrons or holes through a distance l [cm] caused by an
// applied voltage v [volt] through a distance d [cm] in any material at a
// temperature T [degree K].
- virtual Double_t SigmaDiffusion2D(Double_t);
+ virtual Double_t SigmaDiffusion2D(Double_t l) const ;
// Returns the Gaussian sigma == <x^2+z^2> [cm^2] due to the defusion of
// electrons or holes through a distance l [cm] caused by an applied
// voltage v [volt] through a distance d [cm] in any material at a
// temperature T [degree K].
- virtual Double_t SigmaDiffusion1D(Double_t);
+ virtual Double_t SigmaDiffusion1D(Double_t l) const ;
+ // Prints out the content of this class in ASCII format.
+ virtual void Print(ostream *os) const;
+ // Reads in the content of this class in the format of Print
+ virtual void Read(istream *is);
+ protected:
+ void NotImplemented(const char *method) const {if(gDebug>0)
+ Warning(method,"This method is not implemented for this sub-class");}
+
+ TString fDataType; // data type - real or simulated
private:
Double_t fdv; // The parameter d/v where d is the disance over which the
// the potential v is applied d/v [cm/volts]
Double_t fN; // the impurity consentration of the material in #/cm^3
Double_t fT; // The temperature of the Si in Degree K.
+ Double_t fGeVcharge; // Energy to ionize (free an electron).
+ TString fFileName1; // input keys : run, module #
+ TString fFileName2; // baseline & noise val or output code
+ // signal or monitored bgr.
+ TString fFileName3; // param values or output coded signal
+ Bool_t fWrite; // Write option for the compression algorithms
ClassDef(AliITSresponse,2) // Detector type response virtual base class
};
+// Input and output function for standard C++ input/output.
+ostream& operator<<(ostream &os,AliITSresponse &source);
+istream& operator>>(istream &os,AliITSresponse &source);
#endif