-
- // Geometry
- AliTRDgeometry *fGeo; //! The TRD geometry
-
- // Write
- Bool_t fWriteCoef[3]; // Do you want to write the result in a file?
- TString fWriteNameCoef; // Where the coef Det are written
-
- // Fit
- Bool_t fFitPHOn; // The fit PH On (0)
- Bool_t fFitPol2On; // The fit Pol2 On (1)
- Bool_t fFitLagrPolOn; // The fit LagrPol On (3)
- Bool_t fTakeTheMaxPH; // Take the Max for the T0 determination
- Int_t fFitPHPeriode; // Periode of the fit PH
- Int_t fFitPHNDB; // To choose which method will be used to fill the database for the PH
- Float_t fBeginFitCharge; // The fit begins at mean/fBeginFitCharge for the gain calibration
- Float_t fT0Shift; // T0 Shift with the actual method
- Float_t fRangeFitPRF; // The fit range for the PRF is -fRangeFitPRF +fRangeFitPRF
- Bool_t fFitPRFOn; // The fit PRF Gaussian On (0)
- Bool_t fRMSPRFOn; // The RMS PRF On (2)
- Int_t fFitPRFNDB; // To choose which method will be used to fill the database for the PRF
- Bool_t fMeanChargeOn; // Mean Charge on (1)
- Bool_t fFitChargeBisOn; // For an other fit function (convolution, more time consuming)(2)
- Bool_t fFitChargeOn; // For the first fit function (sum of Gaus and Landau) (0)
- Bool_t fFitMeanWOn; // For the Marian Mean W method (4)
- Int_t fFitChargeNDB; // To choose which method will be used to fill the database for the CH
- Bool_t fAccCDB; // If there is a calibration database to be compared with....
- Int_t fMinEntries; // Min Entries to fit the histo
- Short_t fRebin; // If you want to rebin the histo for the gain calibration
-
- // Statistics
- Int_t fNumberFit; // To know how many pad groups have been fitted
- Int_t fNumberFitSuccess; // To know how many pad groups have been fitted successfully
- Int_t fNumberEnt; // To know how many pad groups have entries in the histo
- Double_t fStatisticMean; // To know the mean statistic of the histos
-
- // Debug Mode
- Short_t fDebug; // For debugging 0 rien, 1 errors, 2 one fit alone, 3 one detector, 4 one detector with errors
- Int_t fDet[3]; // Detector visualised (plane,chamb,sect) si debugging == 3 or 4
- Int_t fFitVoir; // Fit visualised si debugging == 2
-
- // Calibration mode
-
- AliTRDCalibraMode *fCalibraMode; // The calibration mode
-
- // The coefficients trees
-
- TTree *fPRF; // Tree of the sigma of PRD
- TTree *fGain; // Tree of the gain factor
- TTree *fT0; // Tree of the time0
- TTree *fVdrift; // Tree of the drift velocity
-
- // "Pointer" of the branch of the tree
- Int_t fVdriftDetector; // Branch of Vdrift
- Float_t *fVdriftPad; // Branch of Vdrift
- Int_t fT0Detector; // Branch of t0
- Float_t *fT0Pad; // Branch of t0
- Int_t fPRFDetector; // Branch of PRF
- Float_t *fPRFPad; // Branch of PRF
- Float_t *fCoefCH; // Branch relative gain
-
- //
- // For debugging
- //
-
- // To build the graph with the errors of the fits
- Double_t *fCoefCharge[5]; // Coefs resulting from the fit for the gain
- Double_t *fCoefChargeE[4]; // Error of the found coefs for the gain
- Double_t *fCoefVdrift[4]; // Coefs resulting from the fit for the drift velocity
- Double_t *fCoefVdriftE[3]; // Error of the found coefs for the drift velocity
- Double_t *fCoefT0[4]; // Coefs resulting from the fit for the drift velocity
- Double_t *fCoefT0E[3]; // Error of the found coefs for the drift velocity
- Double_t *fCoefPRF[3]; // Coefs resulting from the fit for the PRF
- Double_t *fCoefPRFE[2]; // Error of the found coefs for the PRF
- TH2F *fCoefChargeDB[4]; // Visualisation of the coef of the detecteur fDet for the gain
- TH2F *fCoefVdriftDB[3]; // Visualisation of the coef of the detecteur fDet for the drift velocity
- TH2F *fCoefT0DB[3]; // Visualisation of the coef of the detecteur fDet for time 0
- TH2F *fCoefPRFDB[2]; // Visualisation of the coef of the detecteur fDet for the pad response function
-
- // Variables in the loop for the coef or more general
- Float_t fChargeCoef[5]; // 4 Marian Mean W, 3 database value, 0 fit, 1 mean, 2 fit time consuming
- Float_t fVdriftCoef[4]; // 3 lagrangepoly, 2 database value, 1 slope method, 0 fit
- Float_t fPRFCoef[3]; // 2 Rms, 1 database, 0 fit
- Float_t fT0Coef[4]; // 3 lagrangepoly, 2 database, 1 slope method, 0 fit
- Float_t fPhd[3]; // Begin AR and DR
- Int_t fDect1[3]; // First calibration group that will be called to be maybe fitted
- Int_t fDect2[3]; // Last calibration group that will be called to be maybe fitted
- Double_t fScaleFitFactor; // Scale factor of the fit results for the gain
- Int_t fEntriesCurrent; // Entries in the current histo
- Int_t fCountDet[3]; // Current detector
- Int_t fCount[3]; // When the next detector comes
-
- // Vector method
-
- AliTRDCalibraVector *fCalibraVector; // The vector object
-
- class AliTRDFitCHInfo : public TObject {
-
- public:
-
- AliTRDFitCHInfo()
- :TObject()
- ,fCoef(0x0)
- ,fDetector(-1) { }
- AliTRDFitCHInfo(const AliTRDFitCHInfo &i)
- :TObject(i)
- ,fCoef(0x0)
- ,fDetector(-1) { }
- AliTRDFitCHInfo &operator=(const AliTRDFitCHInfo&) { return *this; }
- virtual ~AliTRDFitCHInfo() { }
-
- void SetCoef(Float_t *coef) { fCoef = coef; }
- void SetDetector(Int_t detector) { fDetector = detector; }
-
- Float_t *GetCoef() const { return fCoef; }
- Int_t GetDetector() const { return fDetector; }
-
- protected:
-
- Float_t *fCoef; // Relative gain coefficient for each group of the detector
- Int_t fDetector; // Detector number
-
- };
-
- TObjArray *fVectorFitCH; // Vectors to fit
-
- //
- // A lot of internal functions......
- //
-
- // Init AliTRDCalibraFit
- void Init();
-
- //
- // Fit
- //
-
- // Create histos if fDebug == 1 or fDebug >=3
- void CreateFitHistoPHDB(Int_t rowMax, Int_t colMax);
- void CreateFitHistoT0DB(Int_t rowMax, Int_t colMax);
- void CreateFitHistoCHDB(Int_t rowMax, Int_t colMax);
- void CreateFitHistoPRFDB(Int_t rowMax, Int_t colMax);
- void InitArrayFitCH();
- void InitArrayFitPH();
- void InitArrayFitT0();
- void InitArrayFitPRF();
-
- // CHFit functions
- Bool_t FillVectorFitCH(Int_t countdet);
- Bool_t InitFit(Int_t nbins, Int_t i);
- void InitfCountDetAndfCount(Int_t i);
- void UpdatefCountDetAndfCount(Int_t idect, Int_t i);
- void ReconstructFitRowMinRowMax(Int_t idect, Int_t i);
- Bool_t NotEnoughStatistic(Int_t idect, Int_t i);
- Bool_t FillInfosFit(Int_t idect, Int_t i);
- Bool_t WriteFitInfos(Int_t i);
- void NormierungCharge();
-
- // Fill histos DB from the Coef histos
- void FillCoefChargeDB();
- void FillCoefVdriftDB();
- void FillCoefT0DB();
- void FillCoefPRFDB();
-
- // Plot histos CoefPRF Coef....
- void PlotWritePH();
- void PlotWriteT0();
- void PlotWriteCH();
- void PlotWritePRF();
-
- // Plot histos DB
- void PlotPHDB();
- void PlotT0DB();
- void PlotCHDB();
- void PlotPRFDB();
-
- // Write the DB histos
- void WritePHDB(TFile *fout);
- void WriteT0DB(TFile *fout);
- void WriteCHDB(TFile *fout);
- void WritePRFDB(TFile *fout);
-
- // Calculate the mean coefs from the database
- Bool_t CalculVdriftCoefMean(Int_t fect, Int_t idect);
- Bool_t CalculChargeCoefMean(Int_t fect, Int_t idect, Bool_t vrai);
- Bool_t CalculPRFCoefMean(Int_t fect, Int_t idect);
- Bool_t CalculT0CoefMean(Int_t fect, Int_t idect);
- Float_t GetPRFDefault(Int_t plane) const;
-
- // Fit methods
- void FitBisCH(TH1 *projch, Int_t idect);
- void FitCH(TH1 *projch, Int_t idect);
- void FitMeanW(TH1 *projch, Int_t idect);
- void FitMean(TH1 *projch, Int_t idect, Double_t nentries);
- void FitPH(TH1 *projPH, Int_t idect);
- void FitPRF(TH1 *projPRF, Int_t idect);
- void RmsPRF(TH1 *projPRF, Int_t idect);
- void FitPente(TH1 *projPH, Int_t idect);
- void FitLagrangePoly(TH1* projPH, Int_t idect);
- TH1I *ReBin(TH1I *hist) const;
- TH1F *ReBin(TH1F *hist) const;
-
- // Clear
- void ClearTree();
-
- // Some basic geometry function
- virtual Int_t GetPlane(Int_t d) const;
- virtual Int_t GetChamber(Int_t d) const;
- virtual Int_t GetSector(Int_t d) const;
-
- // Init, Fill and Reset the variables to default value tree Gain, PRF, Vdrift and T0
- void InitTreePH();
- void FillTreeVdrift(Int_t countdet);
- void InitTreeT0();
- void FillTreeT0(Int_t countdet);
- void InitTreePRF();
- void FillTreePRF(Int_t countdet);
- void ConvertVectorFitCHTree();
-
- // Instance of this class and so on
- static AliTRDCalibraFit *fgInstance; // Instance
- static Bool_t fgTerminated; // If terminated
-
+
+ // Geometry
+ AliTRDgeometry *fGeo; //! The TRD geometry
+
+
+ Int_t fNumberOfBinsExpected; // Number of bins expected
+
+ // Fit
+ Short_t fMethod; // Method
+ Float_t fBeginFitCharge; // The fit begins at mean/fBeginFitCharge for the gain calibration
+ Int_t fFitPHPeriode; // Periode of the fit PH
+ Bool_t fTakeTheMaxPH; // Take the Max for the T0 determination
+ Float_t fT0Shift0; // T0 Shift with the maximum positive slope
+ Float_t fT0Shift1; // T0 Shift with the maximum of the amplification region
+ Float_t fRangeFitPRF; // The fit range for the PRF is -fRangeFitPRF +fRangeFitPRF
+ Bool_t fAccCDB; // If there is a calibration database to be compared with....
+ Int_t fMinEntries; // Min Entries to fit the histo
+ Short_t fRebin; // If you want to rebin the histo for the gain calibration
+
+ // Statistics
+ Int_t fNumberFit; // To know how many pad groups have been fitted
+ Int_t fNumberFitSuccess; // To know how many pad groups have been fitted successfully
+ Int_t fNumberEnt; // To know how many pad groups have entries in the histo
+ Double_t fStatisticMean; // To know the mean statistic of the histos
+
+
+ // Debug Modes
+ TTreeSRedirector *fDebugStreamer; //!Debug streamer
+ Short_t fDebugLevel; // Flag for debugging
+ Int_t fDet[3]; // Detector visualised (layer,stack,sector) si debugging == 3 or 4
+ Int_t fFitVoir; // Fit visualised si debugging == 2
+
+ // Magnetic field lorentz angle
+ Float_t fMagneticField; // Magnetic field lorentz angle
+
+ // Calibra objects
+
+ AliTRDCalibraMode *fCalibraMode; // The calibration mode
+
+ // Current values of the coefficients found and ect...
+ Float_t fCurrentCoef[2]; // Current coefs
+ Float_t fCurrentCoefE; // Current coefs error
+ Float_t fCurrentCoef2[2]; // Current coefs
+ Float_t fCurrentCoefE2; // Current coefs error
+ Float_t fPhd[3]; // Begin AR and DR
+ Int_t fDect1; // First calibration group that will be called to be maybe fitted
+ Int_t fDect2; // Last calibration group that will be called to be maybe fitted
+ Double_t fScaleFitFactor; // Scale factor of the fit results for the gain
+ Int_t fEntriesCurrent; // Entries in the current histo
+ Int_t fCountDet; // Current detector (or first in the group)
+ Int_t fCount; // When the next detector comes
+ Int_t fNbDet; // Number of detector in the group
+
+ // Current calib object
+ AliTRDCalDet *fCalDet; // Current calib object
+ AliTRDCalROC *fCalROC; // Current calib object
+ AliTRDCalDet *fCalDet2; // Current calib object
+ AliTRDCalROC *fCalROC2; // Current calib object
+
+ // Current values detector
+
+ Float_t *fCurrentCoefDetector; // Current values for the detector
+ Float_t *fCurrentCoefDetector2; // Current values for the detector
+
+ TObjArray fVectorFit; // Vectors to fit
+ TObjArray fVectorFit2; // Vectors to fit
+
+ //
+ // A lot of internal functions......
+ //
+
+ // Init AliTRDCalibraFit
+ Bool_t InitFit(Int_t nbins, Int_t i);
+ Bool_t InitFitCH();
+ Bool_t InitFitPH();
+ Bool_t InitFitPRF();
+ Bool_t InitFitLinearFitter();
+
+ // Not enough Statistics
+ Bool_t NotEnoughStatisticCH(Int_t idect);
+ Bool_t NotEnoughStatisticPH(Int_t idect,Double_t nentries);
+ Bool_t NotEnoughStatisticPRF(Int_t idect);
+ Bool_t NotEnoughStatisticLinearFitter();
+
+ // Fill Infos Fit
+ Bool_t FillInfosFitCH(Int_t idect);
+ Bool_t FillInfosFitPH(Int_t idect,Double_t nentries);
+ Bool_t FillInfosFitPRF(Int_t idect);
+ Bool_t FillInfosFitLinearFitter();
+
+ void FillFillCH(Int_t idect);
+ void FillFillPH(Int_t idect,Double_t nentries);
+ void FillFillPRF(Int_t idect);
+ void FillFillLinearFitter();
+
+ Bool_t FillVectorFit();
+ Bool_t FillVectorFit2();
+
+ // Functions...
+ void InitfCountDetAndfCount(Int_t i);
+ void CalculNumberOfBinsExpected(Int_t i);
+ void CalculDect1Dect2(Int_t i);
+ void UpdatefCountDetAndfCount(Int_t idect, Int_t i);
+ void ReconstructFitRowMinRowMax(Int_t idect, Int_t i);
+ Bool_t CheckFitVoir();
+ void NormierungCharge();
+ Bool_t SetNrphiFromTObject(const char *name, Int_t i);
+ Bool_t SetNzFromTObject(const char *name, Int_t i);
+ Int_t GetNumberOfGroupsPRF(const char* nametitle);
+
+ // Calculate the mean coefs from the database
+ Bool_t CalculVdriftCoefMean();
+ Bool_t CalculChargeCoefMean(Bool_t vrai);
+ Bool_t CalculPRFCoefMean();
+ Bool_t CalculT0CoefMean();
+ Bool_t CalculVdriftLorentzCoef();
+ Float_t GetPRFDefault(Int_t layer) const;
+ void SetCalROC(Int_t i);
+
+ // Fit methods
+ void FitBisCH(TH1 *projch, Double_t mean);
+ void FitCH(TH1 *projch, Double_t mean);
+ void FitMeanW(TH1 *projch, Double_t nentries);
+ void FitMeanWSm(TH1 *projch, Float_t sumAll);
+ void FitMean(TH1 *projch, Double_t nentries, Double_t mean);
+ void FitPH(TH1 *projPH, Int_t idect);
+ void FitPRF(TH1 *projPRF);
+ void RmsPRF(TH1 *projPRF);
+ Bool_t FitPRFGausMI(Double_t *arraye,Double_t *arraym,Double_t *arrayme,Int_t nBins,Float_t xMin,Float_t xMax);
+ Double_t FitGausMI(Double_t *arraye,Double_t *arraym,Double_t *arrayme,Int_t nBins, Float_t xMin,Float_t xMax,TVectorD *param, Bool_t kError= kTRUE);
+ void FitPente(TH1 *projPH);
+ void FitLagrangePoly(TH1* projPH);
+ void FitTnpRange(Double_t *arraye,Double_t *arraym,Double_t *arrayme,Int_t nbg,Int_t nybins);
+ TH1I *ReBin(const TH1I *hist) const;
+ TH1F *ReBin(const TH1F *hist) const;
+
+ // Some basic geometry function
+ virtual Int_t GetLayer(Int_t d) const;
+ virtual Int_t GetStack(Int_t d) const;
+ virtual Int_t GetSector(Int_t d) const;
+
+ // Instance of this class and so on
+ static AliTRDCalibraFit *fgInstance; // Instance
+ static Bool_t fgTerminated; // If terminated
+
+
+ private:
+
+ static Double_t PH(const Double_t *x, const Double_t *par);
+ static Double_t AsymmGauss(const Double_t *x, const Double_t *par);
+ static Double_t FuncLandauGaus(const Double_t *x, const Double_t *par);
+ static Double_t LanGauFun(const Double_t *x, const Double_t *par);
+ TF1 *LanGauFit(TH1 *his, const Double_t *fitrange, const Double_t *startvalues
+ , const Double_t *parlimitslo, const Double_t *parlimitshi, Double_t *fitparams
+ , Double_t *fiterrors, Double_t *chiSqr, Int_t *ndf) const;
+ Int_t LanGauPro(const Double_t *params, Double_t &maxx, Double_t &fwhm);
+ static Double_t GausConstant(const Double_t *x, const Double_t *par);
+
+ // This is a singleton, contructor is private!
+ AliTRDCalibraFit();
+ virtual ~AliTRDCalibraFit();
+
+