AliT0RecoParam(const AliT0RecoParam &p); //copy constructor
AliT0RecoParam& operator=(const AliT0RecoParam &p);
virtual ~AliT0RecoParam();
-
- static AliT0RecoParam *GetLowFluxParam(); // make reco parameters for low flux env
+ static AliT0RecoParam *GetLowFluxParam(); // make reco parameters for low flux env
static AliT0RecoParam *GetHighFluxParam(); // make reco parameters for high flux env
static AliT0RecoParam *GetLaserTestParam(); // special setting for laser SetLaserTestParam
-
+ //for monitoring
+ // static AliT0RecoParam *GetHistRange(); // limit of monitoring histograms
+
+ //old staff
Float_t GetRefAmp() const {return fRefAmp;}
void SetRefAmp(Float_t amp) { fRefAmp = amp;}
+ //now number of bad channel
Int_t GetRefPoint() const {return fRefPoint;}
void SetRefPoint(Int_t ref) {fRefPoint = ref;}
-
- void PrintParameters() const;
-
- protected:
- Float_t fRefAmp;
- Int_t fRefPoint;
-
+
+ //now low and high limit for multi-bunch recontruction
+ Float_t GetLow(Int_t numhist) const {return fLow[numhist];}
+ // Float_t GetLow() {return *fLow;}
+ void SetLow(Int_t numhist, Float_t low) {fLow[numhist] = low;}
+
+ Float_t GetHigh(Int_t numhist) const {return fHigh[numhist];}
+ // Float_t GetHigh() {return *fHigh;}
+ void SetHigh(Int_t numhist, Float_t high) {fHigh[numhist] = high;}
+ Float_t GetLatencyL1() const {return fLatencyL1;}
+ void SetLatencyL1(Float_t lat) {fLatencyL1 = lat;}
+ Float_t GetLatencyL1A() const {return fLatencyL1A;}
+ void SetLatencyL1A(Float_t lat) {fLatencyL1A = lat;}
+ Float_t GetLatencyL1C() const {return fLatencyL1C;}
+ void SetLatencyL1C(Float_t lat) {fLatencyL1C = lat;}
+ Float_t GetLatencyHPTDC() const {return fLatencyHPTDC;}
+ void SetLatencyHPTDC(Float_t lat) {fLatencyHPTDC = lat;}
+ Float_t GetVertexShift() const {return fVertexShift;}
+ void SetVertexShift(Float_t sh) {fVertexShift = sh;}
+ Int_t GetCorridor() const {return Int_t (fLow[300]); }
+ void SetCorridor(Int_t cor) { fLow[300] = Float_t(cor);}
- ClassDef(AliT0RecoParam, 1);
+ //new staff
+ Int_t GetBadChannels(Int_t i) const {return fBadChannels[i];}
+ void SetBadChannels(Int_t i, Int_t value) {fBadChannels[i] = value;}
+ Float_t GetAmpLowThreshold() const {return fLow[200];}
+ Float_t GetAmpHighThreshold() const {return fHigh[200];}
+
+ void SetSatelliteThresholds(Float_t low, Float_t high)
+ {fSatelliteThresholds[0]=low; fSatelliteThresholds[1]=high;}
+ Float_t GetLowSatelliteThreshold() const {return fSatelliteThresholds[0];}
+ Float_t GetHighSatelliteThreshold() const {return fSatelliteThresholds[1];}
+ void SetEq (Int_t eq) {fEqualised = eq; };
+ Int_t GetEq () const { return fEqualised;}
+ void PrintParameters() const;
+
+ protected:
+ Float_t fRefAmp; // for slewing correcton
+ Int_t fRefPoint; // #channel for RefPoint
+ Float_t fLow[500]; //low limit of monitoring histograms
+ Float_t fHigh[500]; //high limit of monitoring histograms
+ Float_t fLatencyL1; //Latency L1
+ Float_t fLatencyL1A; //Latency L1 for OrA
+ Float_t fLatencyL1C; //Latency L1 for orC
+ Float_t fLatencyHPTDC; //Latency HPTDC
+ Float_t fVertexShift; // for slewing correcton
+ Int_t fBadChannels[24]; // bad channels map
+ Float_t fSatelliteThresholds[2]; // what we call satellite
+ Int_t fEqualised; // do we write pure CFD or equalized
+
+ ClassDef(AliT0RecoParam, 6);
+
};
#endif
git://git.uio.no / u / mrichter / AliRoot.git / blobdiff