[u/mrichter/AliRoot.git] / TPC / AliTPCRecoParam.h

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

///////////////////////////////////////////////////////////////////////////////
//                                                                           //
// Class with TPC reconstruction parameters                                  //
//                                                                           //
///////////////////////////////////////////////////////////////////////////////


#include "AliDetectorRecoParam.h"

class AliTPCRecoParam : public AliDetectorRecoParam
{
 public: 
  AliTPCRecoParam();
  virtual ~AliTPCRecoParam();
  virtual void Print(const Option_t* option="") const;
  static   Bool_t  GetUseTimeCalibration();
  static   void    SetUseTimeCalibration(Bool_t useTimeCalibration);

  void     SetUseHLTClusters(Int_t useHLTClusters){fUseHLTClusters=useHLTClusters;}
  Int_t    GetUseHLTClusters() const {return fUseHLTClusters;}
  void     SetUseHLTPreSeeding(Int_t useHLTPreSeeding){fUseHLTPreSeeding=useHLTPreSeeding;}
  Int_t    GetUseHLTPreSeeding() const {return fUseHLTPreSeeding;}
  void     SetClusterSharing(Bool_t sharing){fBClusterSharing=sharing;}
  Bool_t   GetClusterSharing() const {return fBClusterSharing;}
  Double_t GetCtgRange() const     { return fCtgRange;}
  Double_t GetMaxSnpTracker() const{ return fMaxSnpTracker;}
  Double_t GetMaxSnpTrack() const  { return fMaxSnpTrack;}
  Bool_t   GetUseOuterDetectors() const { return fUseOuterDetectors;}
  void     SetUseOuterDetectors(Bool_t flag)  { fUseOuterDetectors=flag;}
  Double_t GetCutSharedClusters(Int_t index)const { return fCutSharedClusters[index];}
  void  SetCutSharedClusters(Int_t index, Float_t value){ fCutSharedClusters[index]=value;}
  Int_t GetClusterMaxRange(Int_t index)const { return fClusterMaxRange[index];}
  void     SetClusterMaxRange(Int_t index, Int_t value){ fClusterMaxRange[index]=value;}
  //
  Bool_t   DumpSignal()     const  { return fDumpSignal;}
  void     SetTimeInterval(Int_t first, Int_t last) { fFirstBin=first, fLastBin =last;}
  Int_t    GetFirstBin() const     { return fFirstBin;}
  Int_t    GetLastBin() const      { return fLastBin;}
  void     SetTimeBinRange(Int_t first, Int_t last){ fFirstBin = first; fLastBin = last;}
  Bool_t   GetCalcPedestal()       const  { return fBCalcPedestal;}
  Bool_t   GetDoUnfold()           const  { return fBDoUnfold;}
  void     SetDoUnfold(Bool_t unfold)     { fBDoUnfold = unfold;}
  Float_t  GetDumpAmplitudeMin()   const  { return fDumpAmplitudeMin;}
  Float_t  GetMaxNoise()           const  { return fMaxNoise;}  
  //
  Int_t    GetUseOnePadCluster()   const  { return fUseOnePadCluster;}
  Bool_t   GetUseHLTOnePadCluster()const  { return fUseHLTOnePadCluster;}
  Float_t  GetMinMaxCutAbs()       const  { return fMinMaxCutAbs; }
  Float_t  GetMinLeftRightCutAbs() const  { return fMinLeftRightCutAbs;}  // minimal amplitude left right - PRF
  Float_t  GetMinUpDownCutAbs()    const  { return fMinUpDownCutAbs;}  // minimal amplitude up-down - TRF 
  Float_t  GetMinMaxCutSigma()       const  { return fMinMaxCutSigma; }
  Float_t  GetMinLeftRightCutSigma() const  { return fMinLeftRightCutSigma;}  // minimal amplitude left right - PRF
  Float_t  GetMinUpDownCutSigma()    const  { return fMinUpDownCutSigma;}  // minimal amplitude up-down - TRF 
  //
  void SetUseOnePadCluster(Int_t use)      {   fUseOnePadCluster = use;}
  void SetUseHLTOnePadCluster(Bool_t use)  {   fUseHLTOnePadCluster = use;}
  void SetMinMaxCutAbs(Float_t th)         {   fMinMaxCutAbs=th; }
  void SetMinLeftRightCutAbs(Float_t th)   {   fMinLeftRightCutAbs=th;}  // minimal amplitude left right - PRF
  void SetMinUpDownCutAbs(Float_t th)      {   fMinUpDownCutAbs=th;}  // minimal amplitude up-down - TRF 
  void SetMinMaxCutSigma(Float_t th)       {   fMinMaxCutSigma=th; }
  void SetMinLeftRightCutSigma(Float_t th) {   fMinLeftRightCutSigma=th;}  // minimal amplitude left right - PRF
  void SetMinUpDownCutSigma(Float_t th)    {   fMinUpDownCutSigma=th;}  // minimal amplitude up-down - TRF 
  void  SetUseTotCharge(Bool_t flag) {fUseTotCharge = flag;}
  void  SetCtgRange(Double_t ctgRange) {fCtgRange = ctgRange;}
  void  SetUseMultiplicityCorrectionDedx(Bool_t flag) {fUseMultiplicityCorrectionDedx = flag;}
  void  SetUseAlignmentTime(Bool_t flag) {fUseAlignmentTime = flag;}
  void  SetNeighborRowsDedx(Int_t nRows) {fNeighborRowsDedx = nRows;}
  //
  Int_t    GetLastSeedRowSec()       const  { return fLastSeedRowSec;} 
  Int_t    GetSeedGapPrim()        const  { return fSeedGapPrim;} 
  Int_t    GetSeedGapSec()         const  { return fSeedGapSec;} 
  void     SetDoKinks(Bool_t on)   { fBKinkFinder=on; }
  Bool_t   GetDoKinks() const      { return fBKinkFinder;}
  Double_t GetKinkAngleCutChi2(Int_t index) const {return fKinkAngleCutChi2[index];}
  void     SetKinkAngleCutChi2(Int_t index,Double_t value) {fKinkAngleCutChi2[index]=value;}
  void     SetSeedGapPrim(Int_t seedGapPrim)         { fSeedGapPrim = seedGapPrim;} 
  void     SetSeedGapSec(Int_t seedGapSec)          { fSeedGapSec  = seedGapSec;} 
  Float_t  GetMaxC()    const      { return fMaxC;}
  Bool_t   GetSpecialSeeding() const { return fBSpecialSeeding;}
  //
  //

  //
  // Correction setup
  //
  void  SetUseFieldCorrection(Int_t flag){fUseFieldCorrection=flag;}
  void  SetUseComposedCorrection(Bool_t flag){fUseComposedCorrection=flag;}
  void  SetUseRPHICorrection(Int_t flag){fUseRPHICorrection=flag;}
  void  SetUseRadialCorrection(Int_t flag){fUseRadialCorrection=flag;}
  void  SetUseQuadrantAlignment(Int_t flag){fUseQuadrantAlignment=flag;}
  void  SetUseSectorAlignment(Int_t flag){fUseSectorAlignment=flag;}
  void  SetUseDriftCorrectionTime(Int_t flag){fUseDriftCorrectionTime=flag;}
  void  SetUseDriftCorrectionGY(Int_t flag){fUseDriftCorrectionGY=flag;}
  void  SetUseGainCorrectionTime(Int_t flag){fUseGainCorrectionTime=flag;}
  void  SetUseExBCorrection(Int_t flag){fUseExBCorrection=flag;}
  void  SetUseTOFCorrection(Bool_t flag) {fUseTOFCorrection = flag;}
  void  SetUseIonTailCorrection(Int_t flag) {fUseIonTailCorrection = flag;}
  //
  Int_t GetUseFieldCorrection() const {return fUseFieldCorrection;}
  Int_t GetUseComposedCorrection() const {return fUseComposedCorrection;}
  Int_t GetUseRPHICorrection() const {return fUseRPHICorrection;}
  Int_t GetUseRadialCorrection() const {return fUseRadialCorrection;}
  Int_t GetUseQuadrantAlignment() const {return fUseQuadrantAlignment;}
  Int_t GetUseSectorAlignment() const {return fUseSectorAlignment;}
  Int_t GetUseDriftCorrectionTime() const {return fUseDriftCorrectionTime;}
  Int_t GetUseDriftCorrectionGY() const {return fUseDriftCorrectionGY;}
  Int_t GetUseGainCorrectionTime() const {return fUseGainCorrectionTime;}
  Int_t GetUseExBCorrection() const {return fUseExBCorrection;}
  Bool_t GetUseTOFCorrection() {return fUseTOFCorrection;}
  Int_t GetUseIonTailCorrection() const {return fUseIonTailCorrection;}

  Bool_t GetUseMultiplicityCorrectionDedx() const {return fUseMultiplicityCorrectionDedx;}
  Bool_t GetUseAlignmentTime() const {return fUseAlignmentTime;}
  //
  Bool_t   GetUseTotCharge() const {return fUseTotCharge;}          // switch use total or max charge
  Float_t  GetMinFraction() const {return fMinFraction;}           // truncated mean - lower threshold
  Float_t  GetMaxFraction() const {return fMaxFaction;}            // truncated mean - upper threshold
  Int_t    GetNeighborRowsDedx() const {return fNeighborRowsDedx;} 

  //
  void     SetSystematicError(Double_t *systematic){ for (Int_t i=0; i<5;i++) fSystematicErrors[i]=systematic[i];}
  const Double_t * GetSystematicError() const { return fSystematicErrors;}
  const Double_t * GetSystematicErrorClusterInner() const { return fSystematicErrorClusterInner;}

  void    SetUseSystematicCorrelation(Bool_t useCorrelation)  {fUseSystematicCorrelation=useCorrelation;}
  Bool_t  GetUseSystematicCorrelation() const { return fUseSystematicCorrelation;}

  static   AliTPCRecoParam *GetLowFluxParam();        // make reco parameters for low  flux env.
  static   AliTPCRecoParam *GetHighFluxParam();       // make reco parameters for high flux env. 
  static   AliTPCRecoParam *GetHLTParam(); // special setting for HLT  
  static   AliTPCRecoParam *GetLaserTestParam(Bool_t bPedestal);  // special setting for laser 
  static   AliTPCRecoParam *GetCosmicTestParam(Bool_t bPedestal); // special setting for cosmic  
  //
 protected:

  Int_t    fUseHLTClusters;  // allows usage of HLT clusters instead of RAW data
  Int_t    fUseHLTPreSeeding; // Usage of HLT pre-seeding 
  Bool_t   fBClusterSharing; // allows or disable cluster sharing during tracking 
  Double_t fCtgRange;        // +-fCtgRange is the ctg(Theta) window used for clusterization and tracking (MI) 
  Double_t fMaxSnpTracker;   // max sin of local angle  - for TPC tracker
  Double_t fMaxSnpTrack;     // max sin of local angle  - for track 
  Bool_t   fUseOuterDetectors; // switch - to use the outer detectors
  //
  //
  Double_t fCutSharedClusters[2]; // cut value - maximal amount  of shared clusters  
  Int_t fClusterMaxRange[2];   // neighborhood  - to define local maxima for cluster  
  //
  //   clusterer parameters
  //
  Bool_t   fDumpSignal;      // Dump Signal information flag
  Int_t    fFirstBin;        // first time bin used by cluster finder
  Int_t    fLastBin;         // last time bin  used by cluster finder 
  Bool_t   fBCalcPedestal;   // calculate Pedestal
  Bool_t   fBDoUnfold;       // do unfolding of clusters
  Float_t  fDumpAmplitudeMin; // minimal amplitude of signal to be dumped 
  Float_t  fMaxNoise;        // maximal noise sigma on pad to be used in cluster finder
  Int_t    fUseOnePadCluster; // flag - use one pad cluster -0 not use >0 use
  Bool_t   fUseHLTOnePadCluster; // flag - use one HLT pad cluster for tracking
  Float_t  fMinMaxCutAbs;    // minimal amplitude at cluster maxima
  Float_t  fMinLeftRightCutAbs;  // minimal amplitude left right - PRF
  Float_t  fMinUpDownCutAbs;  // minimal amplitude up-down - TRF 
  Float_t  fMinMaxCutSigma;    // minimal amplitude at cluster maxima
  Float_t  fMinLeftRightCutSigma;  // minimal amplitude left right - PRF
  Float_t  fMinUpDownCutSigma;  // minimal amplitude up-down - TRF 
  //
  //
  Float_t  fMaxC;            // maximal curvature for tracking
  Bool_t   fBSpecialSeeding; // special seeding with big inclination angles allowed (for Cosmic and laser)
  Bool_t   fBKinkFinder;       // do kink finder reconstruction
  Double_t fKinkAngleCutChi2[2];   // angular cut for kinks
  Int_t    fLastSeedRowSec;     // Most Inner Row to make seeding for secondaries
  Int_t    fSeedGapPrim;   // seeding gap for primary tracks
  Int_t    fSeedGapSec;   // seeding gap for secondary tracks

  //
  // Correction switches
  //
  Int_t fUseFieldCorrection;     // use field correction
  Bool_t fUseComposedCorrection; // flag to use composed correction
  Int_t fUseRPHICorrection;      // use rphi correction
  Int_t fUseRadialCorrection;    // use radial correction
  Int_t fUseQuadrantAlignment;   // use quadrant alignment
  Int_t fUseSectorAlignment;     // use sector alignment
  Int_t fUseDriftCorrectionTime; // use drift correction time
  Int_t fUseDriftCorrectionGY;   // use drif correction global y
  Int_t fUseGainCorrectionTime;  // use gain correction time
  Int_t fUseExBCorrection;       // use ExB correction
  Bool_t fUseMultiplicityCorrectionDedx; // use Dedx multiplicity correction
  Bool_t fUseAlignmentTime;              // use time dependent alignment correction
  Int_t fUseIonTailCorrection;   // use ion tail correction
  //
  // dEdx switches
  //
  Bool_t   fUseTotCharge;          // switch use total or max charge
  Float_t fMinFraction;           // truncated mean - lower threshold
  Float_t fMaxFaction;            // truncated mean - upper threshold
  Int_t   fNeighborRowsDedx;      // number of neighboring rows to identify cluster below thres in dEdx calculation 0 -> switch off

  Bool_t fUseTOFCorrection;  // switch - kTRUE use TOF correction kFALSE - do not use
  //
  //  misscalibration 
  //
  Double_t fSystematicErrors[5];  //systematic errors in the track parameters - to be added to TPC covariance matrix 
  Double_t fSystematicErrorClusterInner[2];  // systematic error of the cluster - used to downscale the information
  Bool_t fUseSystematicCorrelation;         // switch to use the correlation for the sys
public:   
  static Bool_t fgUseTimeCalibration; // flag usage the time dependent calibration
                                      // to be switched off for pass 0 reconstruction
                                      // Use static function, other option will be to use 
                                      // additional specific storage ?
  ClassDef(AliTPCRecoParam, 17)
};


#endif
Commit	Line	Data
	1	#ifndef ALITPCRECOPARAM_H
	2	#define ALITPCRECOPARAM_H
	3	/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	4	* See cxx source for full Copyright notice */
	5
	6	///////////////////////////////////////////////////////////////////////////////
	7	// //
	8	// Class with TPC reconstruction parameters //
	9	// //
	10	///////////////////////////////////////////////////////////////////////////////
	11
	12
	13	#include "AliDetectorRecoParam.h"
	14
	15	class AliTPCRecoParam : public AliDetectorRecoParam
	16	{
	17	public:
	18	AliTPCRecoParam();
	19	virtual ~AliTPCRecoParam();
	20	virtual void Print(const Option_t* option="") const;
	21	static Bool_t GetUseTimeCalibration();
	22	static void SetUseTimeCalibration(Bool_t useTimeCalibration);
	23
	24	void SetUseHLTClusters(Int_t useHLTClusters){fUseHLTClusters=useHLTClusters;}
	25	Int_t GetUseHLTClusters() const {return fUseHLTClusters;}
	26	void SetUseHLTPreSeeding(Int_t useHLTPreSeeding){fUseHLTPreSeeding=useHLTPreSeeding;}
	27	Int_t GetUseHLTPreSeeding() const {return fUseHLTPreSeeding;}
	28	void SetClusterSharing(Bool_t sharing){fBClusterSharing=sharing;}
	29	Bool_t GetClusterSharing() const {return fBClusterSharing;}
	30	Double_t GetCtgRange() const { return fCtgRange;}
	31	Double_t GetMaxSnpTracker() const{ return fMaxSnpTracker;}
	32	Double_t GetMaxSnpTrack() const { return fMaxSnpTrack;}
	33	Bool_t GetUseOuterDetectors() const { return fUseOuterDetectors;}
	34	void SetUseOuterDetectors(Bool_t flag) { fUseOuterDetectors=flag;}
	35	Double_t GetCutSharedClusters(Int_t index)const { return fCutSharedClusters[index];}
	36	void SetCutSharedClusters(Int_t index, Float_t value){ fCutSharedClusters[index]=value;}
	37	Int_t GetClusterMaxRange(Int_t index)const { return fClusterMaxRange[index];}
	38	void SetClusterMaxRange(Int_t index, Int_t value){ fClusterMaxRange[index]=value;}
	39	//
	40	Bool_t DumpSignal() const { return fDumpSignal;}
	41	void SetTimeInterval(Int_t first, Int_t last) { fFirstBin=first, fLastBin =last;}
	42	Int_t GetFirstBin() const { return fFirstBin;}
	43	Int_t GetLastBin() const { return fLastBin;}
	44	void SetTimeBinRange(Int_t first, Int_t last){ fFirstBin = first; fLastBin = last;}
	45	Bool_t GetCalcPedestal() const { return fBCalcPedestal;}
	46	Bool_t GetDoUnfold() const { return fBDoUnfold;}
	47	void SetDoUnfold(Bool_t unfold) { fBDoUnfold = unfold;}
	48	Float_t GetDumpAmplitudeMin() const { return fDumpAmplitudeMin;}
	49	Float_t GetMaxNoise() const { return fMaxNoise;}
	50	//
	51	Int_t GetUseOnePadCluster() const { return fUseOnePadCluster;}
	52	Bool_t GetUseHLTOnePadCluster()const { return fUseHLTOnePadCluster;}
	53	Float_t GetMinMaxCutAbs() const { return fMinMaxCutAbs; }
	54	Float_t GetMinLeftRightCutAbs() const { return fMinLeftRightCutAbs;} // minimal amplitude left right - PRF
	55	Float_t GetMinUpDownCutAbs() const { return fMinUpDownCutAbs;} // minimal amplitude up-down - TRF
	56	Float_t GetMinMaxCutSigma() const { return fMinMaxCutSigma; }
	57	Float_t GetMinLeftRightCutSigma() const { return fMinLeftRightCutSigma;} // minimal amplitude left right - PRF
	58	Float_t GetMinUpDownCutSigma() const { return fMinUpDownCutSigma;} // minimal amplitude up-down - TRF
	59	//
	60	void SetUseOnePadCluster(Int_t use) { fUseOnePadCluster = use;}
	61	void SetUseHLTOnePadCluster(Bool_t use) { fUseHLTOnePadCluster = use;}
	62	void SetMinMaxCutAbs(Float_t th) { fMinMaxCutAbs=th; }
	63	void SetMinLeftRightCutAbs(Float_t th) { fMinLeftRightCutAbs=th;} // minimal amplitude left right - PRF
	64	void SetMinUpDownCutAbs(Float_t th) { fMinUpDownCutAbs=th;} // minimal amplitude up-down - TRF
	65	void SetMinMaxCutSigma(Float_t th) { fMinMaxCutSigma=th; }
	66	void SetMinLeftRightCutSigma(Float_t th) { fMinLeftRightCutSigma=th;} // minimal amplitude left right - PRF
	67	void SetMinUpDownCutSigma(Float_t th) { fMinUpDownCutSigma=th;} // minimal amplitude up-down - TRF
	68	void SetUseTotCharge(Bool_t flag) {fUseTotCharge = flag;}
	69	void SetCtgRange(Double_t ctgRange) {fCtgRange = ctgRange;}
	70	void SetUseMultiplicityCorrectionDedx(Bool_t flag) {fUseMultiplicityCorrectionDedx = flag;}
	71	void SetUseAlignmentTime(Bool_t flag) {fUseAlignmentTime = flag;}
	72	void SetNeighborRowsDedx(Int_t nRows) {fNeighborRowsDedx = nRows;}
	73	//
	74	Int_t GetLastSeedRowSec() const { return fLastSeedRowSec;}
	75	Int_t GetSeedGapPrim() const { return fSeedGapPrim;}
	76	Int_t GetSeedGapSec() const { return fSeedGapSec;}
	77	void SetDoKinks(Bool_t on) { fBKinkFinder=on; }
	78	Bool_t GetDoKinks() const { return fBKinkFinder;}
	79	Double_t GetKinkAngleCutChi2(Int_t index) const {return fKinkAngleCutChi2[index];}
	80	void SetKinkAngleCutChi2(Int_t index,Double_t value) {fKinkAngleCutChi2[index]=value;}
	81	void SetSeedGapPrim(Int_t seedGapPrim) { fSeedGapPrim = seedGapPrim;}
	82	void SetSeedGapSec(Int_t seedGapSec) { fSeedGapSec = seedGapSec;}
	83	Float_t GetMaxC() const { return fMaxC;}
	84	Bool_t GetSpecialSeeding() const { return fBSpecialSeeding;}
	85	//
	86	//
	87
	88	//
	89	// Correction setup
	90	//
	91	void SetUseFieldCorrection(Int_t flag){fUseFieldCorrection=flag;}
	92	void SetUseComposedCorrection(Bool_t flag){fUseComposedCorrection=flag;}
	93	void SetUseRPHICorrection(Int_t flag){fUseRPHICorrection=flag;}
	94	void SetUseRadialCorrection(Int_t flag){fUseRadialCorrection=flag;}
	95	void SetUseQuadrantAlignment(Int_t flag){fUseQuadrantAlignment=flag;}
	96	void SetUseSectorAlignment(Int_t flag){fUseSectorAlignment=flag;}
	97	void SetUseDriftCorrectionTime(Int_t flag){fUseDriftCorrectionTime=flag;}
	98	void SetUseDriftCorrectionGY(Int_t flag){fUseDriftCorrectionGY=flag;}
	99	void SetUseGainCorrectionTime(Int_t flag){fUseGainCorrectionTime=flag;}
	100	void SetUseExBCorrection(Int_t flag){fUseExBCorrection=flag;}
	101	void SetUseTOFCorrection(Bool_t flag) {fUseTOFCorrection = flag;}
	102	void SetUseIonTailCorrection(Int_t flag) {fUseIonTailCorrection = flag;}
	103	//
	104	Int_t GetUseFieldCorrection() const {return fUseFieldCorrection;}
	105	Int_t GetUseComposedCorrection() const {return fUseComposedCorrection;}
	106	Int_t GetUseRPHICorrection() const {return fUseRPHICorrection;}
	107	Int_t GetUseRadialCorrection() const {return fUseRadialCorrection;}
	108	Int_t GetUseQuadrantAlignment() const {return fUseQuadrantAlignment;}
	109	Int_t GetUseSectorAlignment() const {return fUseSectorAlignment;}
	110	Int_t GetUseDriftCorrectionTime() const {return fUseDriftCorrectionTime;}
	111	Int_t GetUseDriftCorrectionGY() const {return fUseDriftCorrectionGY;}
	112	Int_t GetUseGainCorrectionTime() const {return fUseGainCorrectionTime;}
	113	Int_t GetUseExBCorrection() const {return fUseExBCorrection;}
	114	Bool_t GetUseTOFCorrection() {return fUseTOFCorrection;}
	115	Int_t GetUseIonTailCorrection() const {return fUseIonTailCorrection;}
	116
	117	Bool_t GetUseMultiplicityCorrectionDedx() const {return fUseMultiplicityCorrectionDedx;}
	118	Bool_t GetUseAlignmentTime() const {return fUseAlignmentTime;}
	119	//
	120	Bool_t GetUseTotCharge() const {return fUseTotCharge;} // switch use total or max charge
	121	Float_t GetMinFraction() const {return fMinFraction;} // truncated mean - lower threshold
	122	Float_t GetMaxFraction() const {return fMaxFaction;} // truncated mean - upper threshold
	123	Int_t GetNeighborRowsDedx() const {return fNeighborRowsDedx;}
	124
	125	//
	126	void SetSystematicError(Double_t *systematic){ for (Int_t i=0; i<5;i++) fSystematicErrors[i]=systematic[i];}
	127	const Double_t * GetSystematicError() const { return fSystematicErrors;}
	128	const Double_t * GetSystematicErrorClusterInner() const { return fSystematicErrorClusterInner;}
	129
	130	void SetUseSystematicCorrelation(Bool_t useCorrelation) {fUseSystematicCorrelation=useCorrelation;}
	131	Bool_t GetUseSystematicCorrelation() const { return fUseSystematicCorrelation;}
	132
	133	static AliTPCRecoParam *GetLowFluxParam(); // make reco parameters for low flux env.
	134	static AliTPCRecoParam *GetHighFluxParam(); // make reco parameters for high flux env.
	135	static AliTPCRecoParam *GetHLTParam(); // special setting for HLT
	136	static AliTPCRecoParam *GetLaserTestParam(Bool_t bPedestal); // special setting for laser
	137	static AliTPCRecoParam *GetCosmicTestParam(Bool_t bPedestal); // special setting for cosmic
	138	//
	139	protected:
	140
	141	Int_t fUseHLTClusters; // allows usage of HLT clusters instead of RAW data
	142	Int_t fUseHLTPreSeeding; // Usage of HLT pre-seeding
	143	Bool_t fBClusterSharing; // allows or disable cluster sharing during tracking
	144	Double_t fCtgRange; // +-fCtgRange is the ctg(Theta) window used for clusterization and tracking (MI)
	145	Double_t fMaxSnpTracker; // max sin of local angle - for TPC tracker
	146	Double_t fMaxSnpTrack; // max sin of local angle - for track
	147	Bool_t fUseOuterDetectors; // switch - to use the outer detectors
	148	//
	149	//
	150	Double_t fCutSharedClusters[2]; // cut value - maximal amount of shared clusters
	151	Int_t fClusterMaxRange[2]; // neighborhood - to define local maxima for cluster
	152	//
	153	// clusterer parameters
	154	//
	155	Bool_t fDumpSignal; // Dump Signal information flag
	156	Int_t fFirstBin; // first time bin used by cluster finder
	157	Int_t fLastBin; // last time bin used by cluster finder
	158	Bool_t fBCalcPedestal; // calculate Pedestal
	159	Bool_t fBDoUnfold; // do unfolding of clusters
	160	Float_t fDumpAmplitudeMin; // minimal amplitude of signal to be dumped
	161	Float_t fMaxNoise; // maximal noise sigma on pad to be used in cluster finder
	162	Int_t fUseOnePadCluster; // flag - use one pad cluster -0 not use >0 use
	163	Bool_t fUseHLTOnePadCluster; // flag - use one HLT pad cluster for tracking
	164	Float_t fMinMaxCutAbs; // minimal amplitude at cluster maxima
	165	Float_t fMinLeftRightCutAbs; // minimal amplitude left right - PRF
	166	Float_t fMinUpDownCutAbs; // minimal amplitude up-down - TRF
	167	Float_t fMinMaxCutSigma; // minimal amplitude at cluster maxima
	168	Float_t fMinLeftRightCutSigma; // minimal amplitude left right - PRF
	169	Float_t fMinUpDownCutSigma; // minimal amplitude up-down - TRF
	170	//
	171	//
	172	Float_t fMaxC; // maximal curvature for tracking
	173	Bool_t fBSpecialSeeding; // special seeding with big inclination angles allowed (for Cosmic and laser)
	174	Bool_t fBKinkFinder; // do kink finder reconstruction
	175	Double_t fKinkAngleCutChi2[2]; // angular cut for kinks
	176	Int_t fLastSeedRowSec; // Most Inner Row to make seeding for secondaries
	177	Int_t fSeedGapPrim; // seeding gap for primary tracks
	178	Int_t fSeedGapSec; // seeding gap for secondary tracks
	179
	180	//
	181	// Correction switches
	182	//
	183	Int_t fUseFieldCorrection; // use field correction
	184	Bool_t fUseComposedCorrection; // flag to use composed correction
	185	Int_t fUseRPHICorrection; // use rphi correction
	186	Int_t fUseRadialCorrection; // use radial correction
	187	Int_t fUseQuadrantAlignment; // use quadrant alignment
	188	Int_t fUseSectorAlignment; // use sector alignment
	189	Int_t fUseDriftCorrectionTime; // use drift correction time
	190	Int_t fUseDriftCorrectionGY; // use drif correction global y
	191	Int_t fUseGainCorrectionTime; // use gain correction time
	192	Int_t fUseExBCorrection; // use ExB correction
	193	Bool_t fUseMultiplicityCorrectionDedx; // use Dedx multiplicity correction
	194	Bool_t fUseAlignmentTime; // use time dependent alignment correction
	195	Int_t fUseIonTailCorrection; // use ion tail correction
	196	//
	197	// dEdx switches
	198	//
	199	Bool_t fUseTotCharge; // switch use total or max charge
	200	Float_t fMinFraction; // truncated mean - lower threshold
	201	Float_t fMaxFaction; // truncated mean - upper threshold
	202	Int_t fNeighborRowsDedx; // number of neighboring rows to identify cluster below thres in dEdx calculation 0 -> switch off
	203
	204	Bool_t fUseTOFCorrection; // switch - kTRUE use TOF correction kFALSE - do not use
	205	//
	206	// misscalibration
	207	//
	208	Double_t fSystematicErrors[5]; //systematic errors in the track parameters - to be added to TPC covariance matrix
	209	Double_t fSystematicErrorClusterInner[2]; // systematic error of the cluster - used to downscale the information
	210	Bool_t fUseSystematicCorrelation; // switch to use the correlation for the sys
	211	public:
	212	static Bool_t fgUseTimeCalibration; // flag usage the time dependent calibration
	213	// to be switched off for pass 0 reconstruction
	214	// Use static function, other option will be to use
	215	// additional specific storage ?
	216	ClassDef(AliTPCRecoParam, 17)
	217	};
	218
	219
	220	#endif