[u/mrichter/AliRoot.git] / TRD / AliTRDfeeParam.h

#ifndef ALITRDFEEPARAM_H
#define ALITRDFEEPARAM_H
/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 * See cxx source for full Copyright notice                               */

/* $Id$ */

////////////////////////////////////////////////////////////////////////////
//                                                                        //
//  TRD front end electronics parameters class                            //
//  Contains all FEE (MCM, TRAP, PASA) related                            //
//  parameters, constants, and mapping.                                   //
//                                                                        //
//  Author:                                                               //
//    Ken Oyama (oyama@physi.uni-heidelberg.de)                           //
//                                                                        //
////////////////////////////////////////////////////////////////////////////

#include <TObject.h>

class TRootIoCtor;

class AliTRDCommonParam;
class AliTRDpadPlane;
class AliTRDgeometry;

//_____________________________________________________________________________
class AliTRDfeeParam : public TObject
{

 public:

  AliTRDfeeParam(TRootIoCtor *);
  AliTRDfeeParam(const AliTRDfeeParam &p);
  virtual           ~AliTRDfeeParam();
  AliTRDfeeParam    &operator=(const AliTRDfeeParam &p);
  virtual void       Copy(TObject &p) const;

  static AliTRDfeeParam *Instance();  // Singleton
  static void            Terminate();

  // Translation from MCM to Pad and vice versa
  virtual Int_t    GetPadRowFromMCM(Int_t irob, Int_t imcm) const;
  virtual Int_t    GetPadColFromADC(Int_t irob, Int_t imcm, Int_t iadc) const;
  virtual Int_t    GetMCMfromPad(Int_t irow, Int_t icol) const;
  virtual Int_t    GetROBfromPad(Int_t irow, Int_t icol) const;
  virtual Int_t    GetRobSide(Int_t irob) const;
  virtual Int_t    GetColSide(Int_t icol) const;

  static  Float_t  GetSamplingFrequency() { return (Float_t)fgkLHCfrequency / 4000000.0; }
  static  Int_t    GetNmcmRob()           { return fgkNmcmRob;      }
  static  Int_t    GetNmcmRobInRow()      { return fgkNmcmRobInRow; }
  static  Int_t    GetNmcmRobInCol()      { return fgkNmcmRobInCol; }
  static  Int_t    GetNrobC0()            { return fgkNrobC0;       }
  static  Int_t    GetNrobC1()            { return fgkNrobC1;       }
  static  Int_t    GetNadcMcm()           { return fgkNadcMcm;      }
  // static  Int_t    GetNtimebin()       { return fgkNtimebin;     }
  static  Int_t    GetNcol()              { return fgkNcol;         }
  static  Int_t    GetNcolMcm()           { return fgkNcolMcm;      }
  static  Int_t    GetNrowC0()            { return fgkNrowC0;       }
  static  Int_t    GetNrowC1()            { return fgkNrowC1;       }

  // static  Int_t    GetADCpedestal()    { return fgkADCpedestal;  }
  // static  Int_t    GetADCnoise()       { return fgkADCnoise;     }
  static  Int_t    GetADCDAC()            { return fgkADCDAC;       }

  static  Bool_t   IsPFon()               { return fgkPFon;         }
  static  Bool_t   IsGFon()               { return fgkGFon;         }
  static  Bool_t   IsTFon()               { return fgkTFon;         }

  static  Int_t    GetPFtimeConstant()    { return fgkPFtimeConstant;   }
  static  Int_t    GetPFeffectPedestal()  { return fgkPFeffectPedestal; }

  //new
  static  Int_t    GetQacc0Start()        {  return fgkPREPqAcc0Start; }
  static  Int_t    GetQacc0End()          {  return fgkPREPqAcc0End; }
  static  Int_t    GetQacc1Start()        {  return fgkPREPqAcc1Start; }
  static  Int_t    GetQacc1End()          {  return fgkPREPqAcc1End; }
          Float_t  GetMinClusterCharge() const {  return fgkMinClusterCharge; }
  static  Int_t    GetLinearFitStart()    {  return fgkPREPLinearFitStart; }
  static  Int_t    GetLinearFitEnd()      {  return fgkPREPLinearFitEnd;  }

  //        Float_t  GetClusThr()           { return fClusThr; };
  //        Float_t  GetPadThr() const { return fPadThr; };
  //        Int_t    GetTailCancelation() const { return fTCOn; };
  //        Int_t    GetNexponential() const { return fTCnexp; };
  //virtual void     GetFilterParam(Float_t &r1, Float_t &r2, Float_t &c1, Float_t &c2, Float_t &ped) const;
  //        Int_t    GetFilterType() const { return fFilterType; };

  static  Int_t    GetTFtype()            { return fgkTFtype;       }
  //static  Int_t    GetTFnExp()            { return fgkTFnExp;       }
          Int_t    GetTFnExp()            { return fTFnExp;         }
          Float_t  GetTFr1()        const { return fTFr1;           }
          Float_t  GetTFr2()        const { return fTFr2;           }
          Float_t  GetTFc1()        const { return fTFc1;           }
          Float_t  GetTFc2()        const { return fTFc2;           }

 // for tracklets
	  Bool_t   GetTracklet()         const { return fgTracklet; } 
  static  void     SetTracklet(Bool_t trackletSim = kTRUE) { fgTracklet = trackletSim; }
          Int_t    GetMaxNrOfTracklets() const { return fgkMaxNrOfTracklets; } 
	  Bool_t    GetMCTrackletOutput() const { return fgkMCTrackletOutput; }

  static  Float_t  GetTFattPar()          { return ((Float_t) fgkTFattPar1) / ((Float_t) fgkTFattPar2); }
          Float_t  GetTFf0()        const { return 1.0 + fgkTFon*(-1.0+GetTFattPar()); }   // 1 if TC off

          void     SetEBsglIndThr(Int_t val);  
          Int_t    GetEBsglIndThr() const { return fEBsglIndThr;    }

          void     SetEBsumIndThr(Int_t val);
          Int_t    GetEBsumIndThr() const { return fEBsumIndThr;    }

          void     SetEBindLUT(Int_t val);
          Int_t    GetEBindLUT()    const { return fEBindLUT;       }

          void     SetEBignoreNeighbour(Int_t val);
          Int_t    GetEBignoreNeighbour() const             { return fEBignoreNeighbour; }

  // Concerning raw data format
          Int_t    GetRAWversion() const                    { return fRAWversion;        }
          void     SetRAWversion( Int_t rawver );
          Bool_t   GetRAWstoreRaw() const                   { return fRAWstoreRaw;       }
          void     SetRAWstoreRaw( Bool_t storeraw )        { fRAWstoreRaw = storeraw;   }

          void     SetXenon();
          void     SetArgon();

 protected:

  static AliTRDfeeParam *fgInstance;         // Singleton instance
  static Bool_t          fgTerminated;       // Defines if this class has already been terminated

  AliTRDCommonParam     *fCP;                // TRD common parameters class

  // Remark: ISO C++ allows initialization of static const values only for integer.

  // Basic Geometrical numbers
  static const Int_t    fgkLHCfrequency      = 40079000 ; // [Hz] LHC clock (should be moved to STEER?)
  static const Int_t    fgkNmcmRob           = 16;        // Number of MCMs per ROB         (old fgkMCMmax)
  static const Int_t    fgkNmcmRobInRow      = 4;         // Number of MCMs per ROB in row dir. (old fgkMCMrow)
  static const Int_t    fgkNmcmRobInCol      = 4;         // Number of MCMs per ROB in col dir. (old fgkMCMrow)
  static const Int_t    fgkNrobC0            = 6;         // Number of ROBs per C0 chamber  (old fgkROBmaxC0)
  static const Int_t    fgkNrobC1            = 8;         // Number of ROBs per C1 chamber  (old fgkROBmaxC1)
  static const Int_t    fgkNadcMcm           = 21;        // Number of ADC channels per MCM (old fgkADCmax)
  // static const Int_t    fgkNtimebin       = 24;        // Number of Time bins should come from calibDB
  static const Int_t    fgkNcol              = 144;       // Number of pads per padplane row(old fgkColmax)
  static const Int_t    fgkNcolMcm           = 18;        // Number of pads per MCM         (old fgkPadmax)
  static const Int_t    fgkNrowC0            = 12;        // Number of Rows per C0 chamber  (old fgkRowmaxC0)
  static const Int_t    fgkNrowC1            = 16;        // Number of Rows per C1 chamber  (old fgkRowmaxC1)

  // ADC intrinsic parameters
  static const Int_t    fgkADCDAC            = 0;         // 5 bit ADC gain parameter

  // TRAP filter global setup
  static const Bool_t   fgkPFon              = kTRUE;     // Pedestal Filter enable/disable flag.
  static const Bool_t   fgkGFon              = kFALSE;    // Gain correction Filter enable/disable flag
  static const Bool_t   fgkTFon              = kTRUE;     // Tail cancelation Filter enable/disable flag (old name fTCOn)

  // PF setup
  static const Int_t    fgkPFtimeConstant    =  0;        // 0 for fastest, 3 for slowest (no effect, probably)
  static const Int_t    fgkPFeffectPedestal  = 10;        // [in ADC units] the desired baseline (Additive)

  // GF setup
  static const Int_t    fgkGFnoise           =  0;        // Noise level increased by gain filter x 100 [in ADC] (to be measured)

  // TF setup
  static const Int_t    fgkTFtype            = 1;         // TC type (0=analog, 1=digital, 2=MI, 3=close to electronics) (old name fFilterType)

  // OLD TF setup (calculated from above)  (valid only for fgkTFsimType = 0 or 1)
  //static const Int_t    fgkTFnExp          = 1;           // Number of exponential for simType 0 and 1
               Int_t    fTFnExp;                            // Number of exponential for simType 0 and 1

 // Tracklet  processing on/off 
  static       Bool_t   fgTracklet; // tracklet processing

  // max. nr of tracklet words for one mcm
  static const Int_t    fgkMaxNrOfTracklets = 4; 

  // additional tracklet folder structure output, containing all necessary Monte Carlo information; maybe this should go somewhere else;
  static const Bool_t   fgkMCTrackletOutput = kTRUE; // default should be kTRUE

  // following need Instance because initialized in constructor
               Float_t  fTFr1;                            // Time constant [us] long (old name fR1)
               Float_t  fTFr2;                            // Time constant [us] short(old name fR2)
               Float_t  fTFc1;                            // Weight long  (old name fC1)
               Float_t  fTFc2;                            // Weight short (old name fC2)

  // here is for TRAP simulation (not yet used)
  static const Int_t    fgkTFdecayWeightL     = 270;      // 0 to 1024 corresponds to 0 to 0.5
  static const Int_t    fgkTFdecayParL        = 348;      // 0 to 511 corresponds to 0.75 to 1
  static const Int_t    fgkTFdecayParS        = 449;      // 0 to 511 correponds to 0.25 to 0.5
  static const Int_t    fgkTFattPar1          = 45;       // attenuationParameter = fgkTFattenuationParameter1/fgkTFattenuationParameter2
  static const Int_t    fgkTFattPar2          = 14;       //                      = -alphaL/ln(lambdaL)-(1-alphaL)/ln(lambdaS)

  // ZS parameters
               Int_t    fEBsglIndThr;                     // EBIS in ADC units
               Int_t    fEBsumIndThr;                     // EBIT in ADC units
               Int_t    fEBindLUT;                        // EBIL lookup table
               Int_t    fEBignoreNeighbour;               // EBIN 0:include neighbor

  // Charge accumulators
  static const Int_t    fgkPREPqAcc0Start     =  5;       // Preprocessor Charge Accumulator 0 Start
  static const Int_t    fgkPREPqAcc0End       = 10;       // Preprocessor Charge Accumulator 0 End
  static const Int_t    fgkPREPqAcc1Start     = 11;       // Preprocessor Charge Accumulator 1 Start
  static const Int_t    fgkPREPqAcc1End       = 20;       // Preprocessor Charge Accumulator 1 End
  static const Int_t    fgkMinClusterCharge   = 20;       // Hit detection [in ADC units]

  //new
  //time constants for linear fit
  static const Int_t    fgkPREPLinearFitStart = 5;
  static const Int_t    fgkPREPLinearFitEnd   = 20;


  // OLD TRAP processing parameters calculated from above
  //static const Float_t  fClusThr;                       // Cluster threshold
  //static const Float_t  fPadThr;                        // Pad threshold

  // For raw production
               Int_t    fRAWversion;                      // Raw data production version
  static const Int_t    fgkMaxRAWversion      = 3;        // Maximum raw version number supported
               Bool_t   fRAWstoreRaw;                     // Store unfiltered data for raw data stream

 private:

  AliTRDfeeParam();

  ClassDef(AliTRDfeeParam,3)                              // The TRD front end electronics parameter

};
#endif
Commit	Line	Data
022e76c3	1	#ifndef ALITRDFEEPARAM_H
	2	#define ALITRDFEEPARAM_H
	3	/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	4	* See cxx source for full Copyright notice */
	5
bf397f30	6	/* $Id$ */
022e76c3	7
acc49af9	8	////////////////////////////////////////////////////////////////////////////
	9	// //
	10	// TRD front end electronics parameters class //
	11	// Contains all FEE (MCM, TRAP, PASA) related //
	12	// parameters, constants, and mapping. //
	13	// //
	14	// Author: //
	15	// Ken Oyama (oyama@physi.uni-heidelberg.de) //
	16	// //
	17	////////////////////////////////////////////////////////////////////////////
022e76c3	18
	19	#include <TObject.h>
	20
ba84a3e3	21	class TRootIoCtor;
ba84a3e3	22
022e76c3	23	class AliTRDCommonParam;
	24	class AliTRDpadPlane;
	25	class AliTRDgeometry;
	26
	27	//_____________________________________________________________________________
	28	class AliTRDfeeParam : public TObject
	29	{
	30
	31	public:
	32
ba84a3e3	33	AliTRDfeeParam(TRootIoCtor *);
022e76c3	34	AliTRDfeeParam(const AliTRDfeeParam &p);
	35	virtual ~AliTRDfeeParam();
	36	AliTRDfeeParam &operator=(const AliTRDfeeParam &p);
	37	virtual void Copy(TObject &p) const;
	38
	39	static AliTRDfeeParam *Instance(); // Singleton
	40	static void Terminate();
	41
	42	// Translation from MCM to Pad and vice versa
	43	virtual Int_t GetPadRowFromMCM(Int_t irob, Int_t imcm) const;
	44	virtual Int_t GetPadColFromADC(Int_t irob, Int_t imcm, Int_t iadc) const;
	45	virtual Int_t GetMCMfromPad(Int_t irow, Int_t icol) const;
	46	virtual Int_t GetROBfromPad(Int_t irow, Int_t icol) const;
	47	virtual Int_t GetRobSide(Int_t irob) const;
	48	virtual Int_t GetColSide(Int_t icol) const;
	49
	50	static Float_t GetSamplingFrequency() { return (Float_t)fgkLHCfrequency / 4000000.0; }
acc49af9	51	static Int_t GetNmcmRob() { return fgkNmcmRob; }
022e76c3	52	static Int_t GetNmcmRobInRow() { return fgkNmcmRobInRow; }
022e76c3	53	static Int_t GetNmcmRobInCol() { return fgkNmcmRobInCol; }
acc49af9	54	static Int_t GetNrobC0() { return fgkNrobC0; }
	55	static Int_t GetNrobC1() { return fgkNrobC1; }
	56	static Int_t GetNadcMcm() { return fgkNadcMcm; }
	57	// static Int_t GetNtimebin() { return fgkNtimebin; }
	58	static Int_t GetNcol() { return fgkNcol; }
	59	static Int_t GetNcolMcm() { return fgkNcolMcm; }
	60	static Int_t GetNrowC0() { return fgkNrowC0; }
	61	static Int_t GetNrowC1() { return fgkNrowC1; }
	62
	63	// static Int_t GetADCpedestal() { return fgkADCpedestal; }
	64	// static Int_t GetADCnoise() { return fgkADCnoise; }
	65	static Int_t GetADCDAC() { return fgkADCDAC; }
	66
	67	static Bool_t IsPFon() { return fgkPFon; }
	68	static Bool_t IsGFon() { return fgkGFon; }
	69	static Bool_t IsTFon() { return fgkTFon; }
	70
	71	static Int_t GetPFtimeConstant() { return fgkPFtimeConstant; }
	72	static Int_t GetPFeffectPedestal() { return fgkPFeffectPedestal; }
dfd03fc3	73
1d93b218	74	//new
	75	static Int_t GetQacc0Start() { return fgkPREPqAcc0Start; }
	76	static Int_t GetQacc0End() { return fgkPREPqAcc0End; }
	77	static Int_t GetQacc1Start() { return fgkPREPqAcc1Start; }
	78	static Int_t GetQacc1End() { return fgkPREPqAcc1End; }
	79	Float_t GetMinClusterCharge() const { return fgkMinClusterCharge; }
	80	static Int_t GetLinearFitStart() { return fgkPREPLinearFitStart; }
	81	static Int_t GetLinearFitEnd() { return fgkPREPLinearFitEnd; }
	82
ecf39416	83	// Float_t GetClusThr() { return fClusThr; };
022e76c3	84	// Float_t GetPadThr() const { return fPadThr; };
	85	// Int_t GetTailCancelation() const { return fTCOn; };
	86	// Int_t GetNexponential() const { return fTCnexp; };
	87	//virtual void GetFilterParam(Float_t &r1, Float_t &r2, Float_t &c1, Float_t &c2, Float_t &ped) const;
	88	// Int_t GetFilterType() const { return fFilterType; };
	89
acc49af9	90	static Int_t GetTFtype() { return fgkTFtype; }
f2979d08	91	//static Int_t GetTFnExp() { return fgkTFnExp; }
f2979d08	92	Int_t GetTFnExp() { return fTFnExp; }
acc49af9	93	Float_t GetTFr1() const { return fTFr1; }
	94	Float_t GetTFr2() const { return fTFr2; }
	95	Float_t GetTFc1() const { return fTFc1; }
	96	Float_t GetTFc2() const { return fTFc2; }
dfd03fc3	97
1d93b218	98	// for tracklets
837e440c	99	Bool_t GetTracklet() const { return fgTracklet; }
837e440c	100	static void SetTracklet(Bool_t trackletSim = kTRUE) { fgTracklet = trackletSim; }
1d93b218	101	Int_t GetMaxNrOfTracklets() const { return fgkMaxNrOfTracklets; }
96e6312d	102	Bool_t GetMCTrackletOutput() const { return fgkMCTrackletOutput; }
1d93b218	103
acc49af9	104	static Float_t GetTFattPar() { return ((Float_t) fgkTFattPar1) / ((Float_t) fgkTFattPar2); }
acc49af9	105	Float_t GetTFf0() const { return 1.0 + fgkTFon*(-1.0+GetTFattPar()); } // 1 if TC off
2ec0bacc	106
2ec0bacc	107	void SetEBsglIndThr(Int_t val);
acc49af9	108	Int_t GetEBsglIndThr() const { return fEBsglIndThr; }
2ec0bacc	109
2ec0bacc	110	void SetEBsumIndThr(Int_t val);
acc49af9	111	Int_t GetEBsumIndThr() const { return fEBsumIndThr; }
2ec0bacc	112
2ec0bacc	113	void SetEBindLUT(Int_t val);
acc49af9	114	Int_t GetEBindLUT() const { return fEBindLUT; }
2ec0bacc	115
2ec0bacc	116	void SetEBignoreNeighbour(Int_t val);
acc49af9	117	Int_t GetEBignoreNeighbour() const { return fEBignoreNeighbour; }
dfd03fc3	118
ecf39416	119	// Concerning raw data format
acc49af9	120	Int_t GetRAWversion() const { return fRAWversion; }
ecf39416	121	void SetRAWversion( Int_t rawver );
acc49af9	122	Bool_t GetRAWstoreRaw() const { return fRAWstoreRaw; }
acc49af9	123	void SetRAWstoreRaw( Bool_t storeraw ) { fRAWstoreRaw = storeraw; }
022e76c3	124
f2979d08	125	void SetXenon();
	126	void SetArgon();
	127
022e76c3	128	protected:
022e76c3	129
acc49af9	130	static AliTRDfeeParam *fgInstance; // Singleton instance
acc49af9	131	static Bool_t fgTerminated; // Defines if this class has already been terminated
022e76c3	132
acc49af9	133	AliTRDCommonParam *fCP; // TRD common parameters class
022e76c3	134
	135	// Remark: ISO C++ allows initialization of static const values only for integer.
	136
	137	// Basic Geometrical numbers
	138	static const Int_t fgkLHCfrequency = 40079000 ; // [Hz] LHC clock (should be moved to STEER?)
	139	static const Int_t fgkNmcmRob = 16; // Number of MCMs per ROB (old fgkMCMmax)
	140	static const Int_t fgkNmcmRobInRow = 4; // Number of MCMs per ROB in row dir. (old fgkMCMrow)
	141	static const Int_t fgkNmcmRobInCol = 4; // Number of MCMs per ROB in col dir. (old fgkMCMrow)
	142	static const Int_t fgkNrobC0 = 6; // Number of ROBs per C0 chamber (old fgkROBmaxC0)
	143	static const Int_t fgkNrobC1 = 8; // Number of ROBs per C1 chamber (old fgkROBmaxC1)
	144	static const Int_t fgkNadcMcm = 21; // Number of ADC channels per MCM (old fgkADCmax)
ecf39416	145	// static const Int_t fgkNtimebin = 24; // Number of Time bins should come from calibDB
022e76c3	146	static const Int_t fgkNcol = 144; // Number of pads per padplane row(old fgkColmax)
	147	static const Int_t fgkNcolMcm = 18; // Number of pads per MCM (old fgkPadmax)
	148	static const Int_t fgkNrowC0 = 12; // Number of Rows per C0 chamber (old fgkRowmaxC0)
	149	static const Int_t fgkNrowC1 = 16; // Number of Rows per C1 chamber (old fgkRowmaxC1)
	150
	151	// ADC intrinsic parameters
022e76c3	152	static const Int_t fgkADCDAC = 0; // 5 bit ADC gain parameter
	153
	154	// TRAP filter global setup
	155	static const Bool_t fgkPFon = kTRUE; // Pedestal Filter enable/disable flag.
	156	static const Bool_t fgkGFon = kFALSE; // Gain correction Filter enable/disable flag
	157	static const Bool_t fgkTFon = kTRUE; // Tail cancelation Filter enable/disable flag (old name fTCOn)
	158
	159	// PF setup
acc49af9	160	static const Int_t fgkPFtimeConstant = 0; // 0 for fastest, 3 for slowest (no effect, probably)
acc49af9	161	static const Int_t fgkPFeffectPedestal = 10; // [in ADC units] the desired baseline (Additive)
022e76c3	162
022e76c3	163	// GF setup
acc49af9	164	static const Int_t fgkGFnoise = 0; // Noise level increased by gain filter x 100 [in ADC] (to be measured)
022e76c3	165
022e76c3	166	// TF setup
1d93b218	167	static const Int_t fgkTFtype = 1; // TC type (0=analog, 1=digital, 2=MI, 3=close to electronics) (old name fFilterType)
dfd03fc3	168
dfd03fc3	169	// OLD TF setup (calculated from above) (valid only for fgkTFsimType = 0 or 1)
f2979d08	170	//static const Int_t fgkTFnExp = 1; // Number of exponential for simType 0 and 1
96e6312d	171	Int_t fTFnExp; // Number of exponential for simType 0 and 1
dfd03fc3	172
1d93b218	173	// Tracklet processing on/off
837e440c	174	static Bool_t fgTracklet; // tracklet processing
1d93b218	175
	176	// max. nr of tracklet words for one mcm
	177	static const Int_t fgkMaxNrOfTracklets = 4;
	178
96e6312d	179	// additional tracklet folder structure output, containing all necessary Monte Carlo information; maybe this should go somewhere else;
	180	static const Bool_t fgkMCTrackletOutput = kTRUE; // default should be kTRUE
	181
dfd03fc3	182	// following need Instance because initialized in constructor
acc49af9	183	Float_t fTFr1; // Time constant [us] long (old name fR1)
	184	Float_t fTFr2; // Time constant [us] short(old name fR2)
	185	Float_t fTFc1; // Weight long (old name fC1)
	186	Float_t fTFc2; // Weight short (old name fC2)
dfd03fc3	187
dfd03fc3	188	// here is for TRAP simulation (not yet used)
acc49af9	189	static const Int_t fgkTFdecayWeightL = 270; // 0 to 1024 corresponds to 0 to 0.5
	190	static const Int_t fgkTFdecayParL = 348; // 0 to 511 corresponds to 0.75 to 1
	191	static const Int_t fgkTFdecayParS = 449; // 0 to 511 correponds to 0.25 to 0.5
	192	static const Int_t fgkTFattPar1 = 45; // attenuationParameter = fgkTFattenuationParameter1/fgkTFattenuationParameter2
	193	static const Int_t fgkTFattPar2 = 14; // = -alphaL/ln(lambdaL)-(1-alphaL)/ln(lambdaS)
dfd03fc3	194
dfd03fc3	195	// ZS parameters
acc49af9	196	Int_t fEBsglIndThr; // EBIS in ADC units
	197	Int_t fEBsumIndThr; // EBIT in ADC units
	198	Int_t fEBindLUT; // EBIL lookup table
	199	Int_t fEBignoreNeighbour; // EBIN 0:include neighbor
022e76c3	200
022e76c3	201	// Charge accumulators
1d93b218	202	static const Int_t fgkPREPqAcc0Start = 5; // Preprocessor Charge Accumulator 0 Start
acc49af9	203	static const Int_t fgkPREPqAcc0End = 10; // Preprocessor Charge Accumulator 0 End
	204	static const Int_t fgkPREPqAcc1Start = 11; // Preprocessor Charge Accumulator 1 Start
	205	static const Int_t fgkPREPqAcc1End = 20; // Preprocessor Charge Accumulator 1 End
	206	static const Int_t fgkMinClusterCharge = 20; // Hit detection [in ADC units]
022e76c3	207
1d93b218	208	//new
	209	//time constants for linear fit
	210	static const Int_t fgkPREPLinearFitStart = 5;
	211	static const Int_t fgkPREPLinearFitEnd = 20;
	212
	213
	214
022e76c3	215	// OLD TRAP processing parameters calculated from above
acc49af9	216	//static const Float_t fClusThr; // Cluster threshold
acc49af9	217	//static const Float_t fPadThr; // Pad threshold
022e76c3	218
022e76c3	219	// For raw production
acc49af9	220	Int_t fRAWversion; // Raw data production version
	221	static const Int_t fgkMaxRAWversion = 3; // Maximum raw version number supported
	222	Bool_t fRAWstoreRaw; // Store unfiltered data for raw data stream
022e76c3	223
	224	private:
	225
	226	AliTRDfeeParam();
	227
f2979d08	228	ClassDef(AliTRDfeeParam,3) // The TRD front end electronics parameter
022e76c3	229
acc49af9	230	};
022e76c3	231	#endif