#include <TH1F.h>
#include <TH2I.h>
+#include <TProfile.h>
#include "AliITSPlaneEff.h"
-#include "AliCDBId.h"
+
+class AliCDBId;
///////////////////////////////////////////
// //
AliITSPlaneEffSPD(const AliITSPlaneEffSPD &source);
// ass. operator
AliITSPlaneEffSPD& operator=(const AliITSPlaneEffSPD &s);
- AliITSPlaneEff& operator=(const AliITSPlaneEff &source);
// Simple way to add another class (i.e. statistics).
AliITSPlaneEffSPD& operator +=( const AliITSPlaneEffSPD &add);
// Getters for average Plane efficiency (including dead/noisy)
- Double_t PlaneEff(const UInt_t mod, const UInt_t chip) const;
- Double_t ErrPlaneEff(const UInt_t mod, const UInt_t chip) const;
+ Double_t PlaneEff(const UInt_t mod, const UInt_t chip, Bool_t FO=kFALSE, const UInt_t BCm4=0) const;
+ Double_t ErrPlaneEff(const UInt_t mod, const UInt_t chip, Bool_t FO=kFALSE, const UInt_t BCm4=0) const;
Double_t PlaneEff(const UInt_t key) const
- {return PlaneEff(GetModFromKey(key),GetChipFromKey(key));};
+ {return PlaneEff(GetModFromKey(key),GetChipFromKey(key),IsForFO(key),GetBCm4FromKey(key));};
Double_t ErrPlaneEff(const UInt_t key) const
- {return ErrPlaneEff(GetModFromKey(key),GetChipFromKey(key));};
+ {return ErrPlaneEff(GetModFromKey(key),GetChipFromKey(key),IsForFO(key),GetBCm4FromKey(key));};
// Getters for fFound[] and fTried[]
Int_t GetFound(const UInt_t key) const;
Int_t GetTried(const UInt_t key) const;
// Methods to update the Plane efficiency (specific of the SPD segmentation)
- Bool_t UpDatePlaneEff(const Bool_t Kfound, const UInt_t mod, const UInt_t chip);
+ Bool_t UpDatePlaneEff(const Bool_t Kfound, const UInt_t mod, const UInt_t chip, Bool_t FO=kFALSE, const UInt_t BCm4=0);
Bool_t UpDatePlaneEff(const Bool_t Kfound, const UInt_t key)
- {return UpDatePlaneEff(Kfound,GetModFromKey(key),GetChipFromKey(key));};
+ {return UpDatePlaneEff(Kfound,GetModFromKey(key),GetChipFromKey(key),IsForFO(key),GetBCm4FromKey(key));};
//
enum {kNModule = 240}; // The number of modules
+ enum {kNModuleLy1 = 80}; // The number of modules in Inner Layer
enum {kNChip = 5}; // The number of chips per module
enum {kNCol = 32}; // The number of columns per chip
enum {kNRow = 256}; // The number of rows per chip (and per module)
+ enum {kNClockPhase = 4}; // The number of clock phases between LHC (40 MHz clock) and SPD (10 MHz clock), for FO studies
virtual Double_t LivePlaneEff(UInt_t key) const;
Double_t LivePlaneEff(const UInt_t mod, const UInt_t chip) const
// method to locate a basic block from Detector Local coordinate (to be used in tracking)
// see file cxx for numbering convention.
// here idet runs from 0 to 79 for layer 0 and from 0 to 159 for layer 1
- UInt_t GetKey(const UInt_t mod, const UInt_t chip) const; // unique key to locate the basic
- // block of the SPD
+ UInt_t GetKey(const UInt_t mod, const UInt_t chip, const Bool_t FO=kFALSE, const UInt_t BCm4=0) const; // unique key to locate the basic
+ // block of the SPD for detector and FO efficiency
+ UInt_t SwitchChipKeyNumbering(UInt_t key) const; // method to switch from offline chip key numbering to online Raw Stream chip numbering
+ // and viceversa. Used for Fast-Or studies.
UInt_t GetKeyFromDetLocCoord(Int_t ilay,Int_t idet, Float_t, Float_t locz) const;
UInt_t Nblock() const; // return the number of basic blocks
// compute the geometrical limit of a basic block (chip) in detector local coordinate system
virtual void SetCreateHistos(Bool_t his=kFALSE)
//{fHis=his; if(fHis) InitHistos(); else DeleteHistos(); return; }
{fHis=his; if(fHis) {DeleteHistos(); InitHistos();} else DeleteHistos(); return; }
- //Bool_t FillHistos(UInt_t key, Bool_t found, Float_t trackXZ[2], Float_t clusterXZ[2], Int_t ctXZ[2]);
- virtual Bool_t FillHistos(UInt_t key, Bool_t found, Float_t *track, Float_t *cluster, Int_t *ctype);
+ virtual Bool_t FillHistos(UInt_t key, Bool_t found, Float_t *track, Float_t *cluster, Int_t *ctype, Float_t *angtrkmod);
virtual Bool_t WriteHistosToFile(TString filename="PlaneEffSPDHistos.root",Option_t* option = "RECREATE");
virtual Bool_t ReadHistosFromFile(TString filename="PlaneEffSPDHistos.root"); // histos must exist already !
// This method increases the
Int_t GetMissingTracksForGivenEff(Double_t eff, Double_t RelErr, UInt_t im, UInt_t ic) const;
UInt_t GetModFromKey(const UInt_t key) const;
UInt_t GetChipFromKey(const UInt_t key) const;
+ Bool_t IsForFO(const UInt_t key) const;
+ UInt_t GetBCm4FromKey(const UInt_t key) const; // return the "Bunch Crossing modulo 4" (for Fast Or studies)
UInt_t GetChipFromCol(const UInt_t col) const; // get the chip number (from 0 to kNChip)
UInt_t GetColFromLocZ(Float_t zloc) const; // get the Column from the local z
Float_t GetLocZFromCol(const UInt_t col) const; // get the local Z from the column number,
void GetModAndChipFromKey(const UInt_t key, UInt_t& mod, UInt_t& chip) const;
void GetDeadAndNoisyInChip(const UInt_t key, UInt_t& dead, UInt_t& noisy) const;
//
- Int_t fFound[kNModule*kNChip]; // number of associated clusters in a given chip
- Int_t fTried[kNModule*kNChip]; // number of tracks used for chip efficiency evaluation
+ Int_t fFound[kNModule*kNChip*(kNClockPhase+1)]; // if(<kNModule*kNChip) is the number of associated clusters in a given chip
+ Int_t fTried[kNModule*kNChip*(kNClockPhase+1)]; // if(<kNModule*kNChip) is the number of tracks used for chip efficiency evaluation
+ // if(>=kNModule*kNChip) Same tale but for Fast-Or
+ // studies (in the 4 phase relationship between LHC and SPD clocks)
+ Bool_t FillHistosStd(UInt_t key, Bool_t found, Float_t *track, Float_t *cluster, Int_t *ctype, Float_t *angtrkmod);
+ Bool_t FillHistosFO(UInt_t key, Bool_t found, Float_t *track);
private:
enum {kNHisto = kNModule}; // The number of histograms: module by module.
TH1F ***fHisResZclu; //! histos with residual distribution along local Z for cluster type
TH1F ***fHisResXchip; //! histos with residual distribution along local X (r-phi) chip by chip
TH1F ***fHisResZchip; //! histos with residual distribution along local Z chip by chip
- //TProfile **fProfResXvsLPhi; //! TProfile of X Residuals vs. impact Angle phi (of the track w.r.t. module)
- //TProfile **fProfResZvsLPhi; //! TProfile of Z Residuals vs. impact Angle phi (of the track w.r.t. module)
- //TProfile **fProfResXvsLDip; //! TProfile of X Residuals vs. impact dip Angle (of the track w.r.t. module)
- //TProfile **fProfResZvsLDip; //! TProfile of Z Residuals vs. impact dip Angle (of the track w.r.t. module)
+ TProfile **fProfResXvsPhi; //! TProfile of X Residuals vs. impact Angle phi (of the track w.r.t. module)
+ //TProfile **fProfResZvsPhi; //! TProfile of Z Residuals vs. impact Angle phi (of the track w.r.t. module)
+ //TProfile **fProfResXvsDip; //! TProfile of X Residuals vs. impact dip Angle (of the track w.r.t. module)
+ TProfile **fProfResZvsDip; //! TProfile of Z Residuals vs. impact dip Angle (of the track w.r.t. module)
+ TProfile ***fProfResXvsPhiclu; //! TProfile of X Residuals vs. impact Angle phi (of the track w.r.t. module) for different clu. type
+ TProfile ***fProfResZvsDipclu; //! TProfile of Z Residuals vs. impact dip Angle (of the track w.r.t. module) for different clu. type
TH1F **fHisTrackErrX; //! histos with track prediction error on Local X
TH1F **fHisTrackErrZ; //! histos with track prediction error on Local Z
TH1F **fHisClusErrX; //! histos with Local_X cluster error
TH1F **fHisClusErrZ; //! histos with Local_Z cluster error
-
- ClassDef(AliITSPlaneEffSPD,2) // SPD Plane Efficiency class
+ TH1F ***fHisTrackXFOtrue; //! histos with track prediction along local X (r-phi) if FastOr bit is found
+ TH1F ***fHisTrackZFOtrue; //! histos with track prediction along local Z if FastOr bit is found
+ TH1F ***fHisTrackXFOfalse; //! histos with track prediction along local X (r-phi) if FastOr bit is not found
+ TH1F ***fHisTrackZFOfalse; //! histos with track prediction along local Z if FastOr bit is not found
+ TH2F ***fHisTrackXZFOtrue; //! histos with track prediction along local X (r-phi) and Z if FastOr bit is found
+ TH2F ***fHisTrackXZFOfalse; //! histos with track prediction along local X (r-phi) and Z if FastOr bit is not found
+
+ ClassDef(AliITSPlaneEffSPD,4) // SPD Plane Efficiency class
};
//
inline UInt_t AliITSPlaneEffSPD::Nblock() const {return kNModule*kNChip;}
inline Int_t AliITSPlaneEffSPD::GetFound(const UInt_t key) const {
- if(key>=kNModule*kNChip) {AliWarning("GetFound: you asked for a non existing key"); return -1;}
+ if(key>=kNModule*kNChip*(kNClockPhase+1)) {AliWarning("GetFound: you asked for a non existing key"); return -1;}
+ if(key>=kNModule*kNChip)AliWarning("GetFound: you asked for FO efficiency studies");
return fFound[key];
}
inline Int_t AliITSPlaneEffSPD::GetTried(const UInt_t key) const {
- if(key>=kNModule*kNChip) {AliWarning("GetTried: you asked for a non existing key"); return -1;}
+ if(key>=kNModule*kNChip*(kNClockPhase+1)) {AliWarning("GetTried: you asked for a non existing key"); return -1;}
+ if(key>=kNModule*kNChip)AliWarning("GetTried: you asked for FO efficiency studies");
return fTried[key];
}
//