/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
* See cxx source for full Copyright notice */
-/* $Id $ */
-/* $Log $ */
+/* $Id$ */
//____________________________________________________________
// Class for trigger analysis.
+//
+// -- Author: Gustavo Conesa & Yves Schutz (IFIC, SUBATECH, CERN)
// Digits are grouped in TRU's (Trigger Units). A TRU consist of 16x28
-// crystals ordered fNTRUPhi x fNTRUZ. The algorithm searches all possible
-// 4x4 crystal combinations per each TRU, adding the digits amplitude and
-// finding the maximum. Maximums are transformed in ADC time samples.
-// Each time bin is compared to the trigger threshold until it is larger
-// and then, triggers are set. Thresholds need to be fixed.
+// crystals ordered fNTRUPhi x fNTRUZ matrix. The algorithm searches all possible
+// 2x2 and nxn (n multiple of 4) crystal combinations per each TRU, adding the
+// digits amplitude and finding the maximum. Iti is found is maximum is isolated.
+// Maxima are transformed in ADC time samples. Each time bin is compared to the trigger
+// threshold until it is larger and then, triggers are set. Thresholds need to be fixed.
// Usage:
//
// //Inside the event loop
-// AliPHOSTrigger *tr = new AliPHOSTrigger();//Init Trigger
+// AliEMCALTrigger *tr = new AliEMCALTrigger();//Init Trigger
// tr->SetL0Threshold(100);
// tr->SetL1JetLowPtThreshold(1000);
+// tr->SetL1JetMediumPtThreshold(10000);
// tr->SetL1JetHighPtThreshold(20000);
+// ....
// tr->Trigger(); //Execute Trigger
-// tr->Print(""); //Print results
-//
-//*-- Author: Gustavo Conesa & Yves Schutz (IFIC, SUBATECH, CERN)
-
+// tr->Print(""); //Print data members after calculation.
+//
// --- ROOT system ---
class TClonesArray ;
AliPHOSTrigger() ; // ctor
AliPHOSTrigger(const AliPHOSTrigger & trig) ; // cpy ctor
- virtual ~AliPHOSTrigger() {}; //virtual dtor
+ virtual ~AliPHOSTrigger();
+
virtual void CreateInputs(); //Define trigger inputs for Central Trigger Processor
void Print(const Option_t * opt ="") const ;
- virtual void Trigger(); //Make PHOS trigger
+ virtual void Trigger() {} //Make PHOS trigger
+ void Trigger(TClonesArray *digits); //Make PHOS trigger
//Getters
- Float_t Get2x2MaxAmplitude() const {return f4x4MaxAmp ; }
- Float_t Get4x4MaxAmplitude() const {return f4x4MaxAmp ; }
+ Float_t Get2x2MaxAmplitude() const {return f2x2MaxAmp ; }
+ Float_t GetnxnMaxAmplitude() const {return fnxnMaxAmp ; }
Int_t Get2x2CrystalPhi() const {return f2x2CrystalPhi ; }
- Int_t Get4x4CrystalPhi() const {return f4x4CrystalPhi ; }
+ Int_t GetnxnCrystalPhi() const {return fnxnCrystalPhi ; }
Int_t Get2x2CrystalEta() const {return f2x2CrystalEta ; }
- Int_t Get4x4CrystalEta() const {return f4x4CrystalEta ; }
+ Int_t GetnxnCrystalEta() const {return fnxnCrystalEta ; }
Int_t Get2x2SuperModule() const {return f2x2SM ; }
- Int_t Get4x4SuperModule() const {return f4x4SM ; }
+ Int_t GetnxnSuperModule() const {return fnxnSM ; }
Int_t * GetADCValuesLowGainMax2x2Sum() {return fADCValuesLow2x2; }
Int_t * GetADCValuesHighGainMax2x2Sum() {return fADCValuesHigh2x2; }
- Int_t * GetADCValuesLowGainMax4x4Sum() {return fADCValuesLow4x4; }
- Int_t * GetADCValuesHighGainMax4x4Sum() {return fADCValuesHigh4x4; }
+ Int_t * GetADCValuesLowGainMaxnxnSum() {return fADCValuesLownxn; }
+ Int_t * GetADCValuesHighGainMaxnxnSum() {return fADCValuesHighnxn; }
- void GetCrystalPhiEtaIndexInModuleFromTRUIndex(Int_t itru, Int_t iphitru, Int_t ietatru,Int_t &ietaMod,Int_t &iphiMod, const AliPHOSGeometry *geom) const ;
+ void GetCrystalPhiEtaIndexInModuleFromTRUIndex(Int_t itru, Int_t iphitru, Int_t ietatru,Int_t &ietaMod,Int_t &iphiMod) const ;
- Float_t GetL0Threshold() const {return fL0Threshold ; }
- Float_t GetL1JetLowPtThreshold() const {return fL1JetLowPtThreshold ; }
- Float_t GetL1JetHighPtThreshold() const {return fL1JetHighPtThreshold ; }
+ Float_t GetL0Threshold() const {return fL0Threshold ; }
+ Float_t GetL1JetLowPtThreshold() const {return fL1JetLowPtThreshold ; }
+ Float_t GetL1JetMediumPtThreshold() const {return fL1JetMediumPtThreshold ; }
+ Float_t GetL1JetHighPtThreshold() const {return fL1JetHighPtThreshold ; }
- Int_t GetNTRU() const {return fNTRU ; }
- Int_t GetNTRUZ() const {return fNTRUZ ; }
- Int_t GetNTRUPhi() const {return fNTRUPhi ; }
+ Int_t GetNTRU() const {return fNTRU ; }
+ Int_t GetNTRUZ() const {return fNTRUZ ; }
+ Int_t GetNTRUPhi() const {return fNTRUPhi ; }
+
+ Int_t GetPatchSize() const {return fPatchSize ; }
+ Int_t GetIsolPatchSize() const {return fIsolPatchSize ; }
- Bool_t IsSimulation() const {return fSimulation ; }
+ Float_t Get2x2AmpOutOfPatch() const {return f2x2AmpOutOfPatch; }
+ Float_t GetnxnAmpOutOfPatch() const {return fnxnAmpOutOfPatch; }
+ Float_t Get2x2AmpOutOfPatchThres() const {return f2x2AmpOutOfPatchThres; }
+ Float_t GetnxnAmpOutOfPatchThres() const {return fnxnAmpOutOfPatchThres; }
- //Setters
+ Bool_t Is2x2Isol() const {return fIs2x2Isol; }
+ Bool_t IsnxnIsol() const {return fIsnxnIsol; }
+ Bool_t IsSimulation() const {return fSimulation ; }
+ Bool_t IsIsolatedInModule() const {return fIsolateInModule ; }
+
+ //Setters
void SetDigitsList(TClonesArray * digits)
{fDigitsList = digits ; }
-
void SetNTRU(Int_t ntru) {fNTRU = ntru ; }
void SetNTRUZ(Int_t ntru) {fNTRUZ = ntru ; }
void SetNTRUPhi(Int_t ntru) {fNTRUPhi = ntru ; }
{fL0Threshold = amp ; }
void SetL1JetLowPtThreshold(Int_t amp)
{fL1JetLowPtThreshold = amp ; }
+ void SetL1JetMediumPtThreshold(Int_t amp)
+ {fL1JetMediumPtThreshold = amp; }
void SetL1JetHighPtThreshold(Int_t amp)
{fL1JetHighPtThreshold = amp ; }
- void SetSimulation(Bool_t sim ) {fSimulation = sim ; }
+ void SetPatchSize(Int_t ps) { fPatchSize = ps ; }
+ void SetIsolPatchSize(Int_t ps) { fIsolPatchSize = ps ; }
+ void Set2x2AmpOutOfPatchThres(Float_t th) { f2x2AmpOutOfPatchThres = th; }
+ void SetnxnAmpOutOfPatchThres(Float_t th) { fnxnAmpOutOfPatchThres = th; }
+ void SetSimulation(Bool_t sim ) { fSimulation = sim ; }
+ void SetIsolateInModule(Bool_t isol ) { fIsolateInModule = isol ; }
private:
- void FillTRU(const TClonesArray * digits, const AliPHOSGeometry * geom, TClonesArray * amptru, TClonesArray * timeRtru) const ;
+ AliPHOSTrigger & operator = (const AliPHOSTrigger & trig) ;//cpy assignment
+
+ void FillTRU(const TClonesArray * digits, const AliPHOSGeometry * geom) const ;
- void MakeSlidingCell(const TClonesArray * amptrus, const TClonesArray * timeRtrus, Int_t mod, TMatrixD *ampmax2, TMatrixD *ampmax4, const AliPHOSGeometry *geom) ;
+ Bool_t IsPatchIsolated(Int_t iPatchType, const Int_t imod, const Int_t mtru, const Float_t maxamp, const Int_t maxphi, const Int_t maxeta) ;
- void SetTriggers(Int_t iMod, const TMatrixD *ampmax2,const TMatrixD *ampmax4, const AliPHOSGeometry *geom) ;
+ void MakeSlidingCell(Int_t mod, TMatrixD &max2, TMatrixD &maxn) ;
+ void SetTriggers(Int_t iMod, const TMatrixD &max2,const TMatrixD &maxn) ;
+
+ void DoIt() ;
+
private:
Float_t f2x2MaxAmp ; //! Maximum 2x2 added amplitude (not overlapped)
Int_t f2x2CrystalPhi ; //! upper right cell, row(phi)
Int_t f2x2CrystalEta ; //! and column(eta)
Int_t f2x2SM ; //! Module where maximum is found
- Float_t f4x4MaxAmp ; //! Maximum 4x4 added amplitude (overlapped)
- Int_t f4x4CrystalPhi ; //! upper right cell, row(phi)
- Int_t f4x4CrystalEta ; //! and column(eta)
- Int_t f4x4SM ; //! Module where maximum is found
+ Float_t fnxnMaxAmp ; //! Maximum nxn added amplitude (overlapped)
+ Int_t fnxnCrystalPhi ; //! upper right cell, row(phi)
+ Int_t fnxnCrystalEta ; //! and column(eta)
+ Int_t fnxnSM ; //! Module where maximum is found
- Int_t* fADCValuesHigh4x4 ; //! Sampled ADC high gain values for the 4x4 crystals amplitude sum
- Int_t* fADCValuesLow4x4 ; //! " low gain "
+ Int_t* fADCValuesHighnxn ; //! Sampled ADC high gain values for the nxn crystals amplitude sum
+ Int_t* fADCValuesLownxn ; //! " low gain "
Int_t* fADCValuesHigh2x2 ; //! " high gain " 2x2 "
Int_t* fADCValuesLow2x2 ; //! " low gaing " "
- TClonesArray* fDigitsList ; //Array of digits
+ TClonesArray* fDigitsList ; // Array of digits
+ TClonesArray* fAmptrus ; //! Array of matrices with amplitudes per TRU
+ TClonesArray* fAmpmods ; //! Array of matrices with amplitudes per module
+ TClonesArray* fTimeRtrus ; //! Array of matrices with time
+
- Float_t fL0Threshold ; //! L0 trigger energy threshold
- Float_t fL1JetLowPtThreshold ; //! L1 Low pT trigger threshold
- Float_t fL1JetHighPtThreshold ; //! L1 High pT trigger threshold
-
- Int_t fNTRU ; //! Number of TRUs per module
- Int_t fNTRUZ ; //! Number of crystal rows per Z in one TRU
- Int_t fNTRUPhi ; //! Number of crystal rows per Phi in one TRU
-
+ Float_t fL0Threshold ; //! L0 trigger energy threshold
+ Float_t fL1JetLowPtThreshold ; //! L1 Low pT trigger threshold
+ Float_t fL1JetMediumPtThreshold ; //! L1 Medium pT trigger threshold
+ Float_t fL1JetHighPtThreshold ; //! L1 High pT trigger threshold
+
+ Int_t fNTRU ; //! Number of TRUs per module
+ Int_t fNTRUZ ; //! Number of crystal rows per Z in one TRU
+ Int_t fNTRUPhi ; //! Number of crystal rows per Phi in one TRU
+ Int_t fNCrystalsPhi; //! Number of rows in a TRU
+ Int_t fNCrystalsZ; //! Number of columns in a TRU
+
+ Int_t fPatchSize; //! Trigger patch factor, to be multiplied to 2x2 cells
+ // 0 means 2x2, 1 means 4x4, 2 means 6x6 ...
+ Int_t fIsolPatchSize ; // Isolation patch size, number of rows or columns to add to
+ // the 2x2 or nxn maximum amplitude patch.
+ // 1 means a patch around max amplitude of 2x2 of 4x4 and around
+ // max ampl patch of 4x4 of 8x8
+
+ Float_t f2x2AmpOutOfPatch; // Amplitude in isolation cone minus maximum amplitude of the reference patch
+ Float_t fnxnAmpOutOfPatch;
+ Float_t f2x2AmpOutOfPatchThres; // Threshold to select a trigger as isolated on f2x2AmpOutOfPatch value
+ Float_t fnxnAmpOutOfPatchThres;
+ Float_t fIs2x2Isol; //Patch is isolated if f2x2AmpOutOfPatchThres threshold is passed
+ Float_t fIsnxnIsol ;
+
Bool_t fSimulation ; //! Flag to do the trigger during simulation or reconstruction
- ClassDef(AliPHOSTrigger,4)
+ Bool_t fIsolateInModule; //! Flag to isolate trigger patch in Module or in TRU acceptance
+
+ ClassDef(AliPHOSTrigger,5)
} ;