1 #ifndef ALIITSUSIMULATION_H
2 #define ALIITSUSIMULATION_H
3 /**************************************************************************
4 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
6 * Author: The ALICE Off-line Project. *
7 * Contributors are mentioned in the code where appropriate. *
9 * Permission to use, copy, modify and distribute this software and its *
10 * documentation strictly for non-commercial purposes is hereby granted *
11 * without fee, provided that the above copyright notice appears in all *
12 * copies and that both the copyright notice and this permission notice *
13 * appear in the supporting documentation. The authors make no claims *
14 * about the suitability of this software for any purpose. It is *
15 * provided "as is" without express or implied warranty. *
16 **************************************************************************/
19 #include "AliITSUSensMap.h"
20 #include "AliITSsegmentation.h"
21 #include "AliMathBase.h"
24 class AliITSCalibration;
25 class AliITSUSimuParam;
29 class AliITSUParamList;
31 // This is the base class for ITS detector signal simulations. Data members
32 // include are a pointer to the detectors specific response and segmentation
33 // classes. See the detector specific implementations for the propper code.
34 // The detector-specific implementations are responsible for processing detector type,
35 // which still may have different segmentations!
36 // Note: the detector specific objects (segmentation, calib, etc.) are not owned
37 // by the object but set externaly
39 class AliITSUSimulation : public TObject
42 enum {kMaxROCycleAccept=126}; // flag for read-out cycle to discard
45 AliITSUSimulation(AliITSUSimuParam* sim, AliITSUSensMap* map);
46 virtual ~AliITSUSimulation() {}
47 AliITSUSimulation(const AliITSUSimulation &source);
48 AliITSUSimulation& operator=(const AliITSUSimulation &source);
49 virtual void Init() = 0;
51 void UpdateMapSignal(UInt_t col,UInt_t row, Int_t trk,Int_t ht,Double_t signal, Int_t roCycle=0);
52 void UpdateMapNoise(UInt_t col,UInt_t row, Double_t noise, Int_t roCycle=0);
53 virtual void InitSimulationModule(AliITSUModule* mod, Int_t ev, AliITSsegmentation* seg, AliITSUParamList* resp);
56 virtual void SDigitiseModule() = 0;
57 virtual void FinishSDigitiseModule() = 0;
58 virtual Bool_t AddSDigitsToModule( TSeqCollection *pItemArray, Int_t mask );
61 virtual void DigitiseModule() = 0;
62 virtual void CreateFastRecPoints(AliITSUModule *,Int_t,TRandom *,TClonesArray* /*recp*/) {}
64 // readout phase (strobe, timing etc) generation
65 virtual void GenerateReadOutCycleOffset() {}
67 AliITSCalibration* GetCalibDead() const {return fCalibDead;}
68 AliITSCalibration* GetCalibNoisy() const {return fCalibNoisy;}
69 AliITSsegmentation* GetSegmentation() const {return fSeg;}
70 AliITSUSimuParam* GetSimuParam() const {return fSimuParam;}
71 AliITSUSensMap* GetMap() const {return fSensMap;}
72 AliITSUModule* GetModule() const {return fModule;}
73 AliITSUParamList* GetResponseParam() const {return fResponseParam;}
74 Int_t GetEvent() const {return fEvent;}
75 Bool_t GetDebug(Int_t level=1) const {return fDebug>=level;}
78 void SetCalibDead(AliITSCalibration *calib) {fCalibDead = calib;}
79 void SetCalibNoisy(AliITSCalibration *calib) {fCalibNoisy = calib;}
80 void SetSegmentation(AliITSsegmentation *seg) {fSeg = seg; if (seg&&fSensMap) fSensMap->SetDimensions(seg->Npz(),seg->Npx(),2*kMaxROCycleAccept);}
81 void SetSimuParam(AliITSUSimuParam *sp) {fSimuParam = sp;}
82 virtual void SetResponseParam(AliITSUParamList* resp) {fResponseParam = resp;}
83 void SetMap(AliITSUSensMap *p) {fSensMap = p;}
84 void SetModule(AliITSUModule* mod) {fModule=mod;}
85 void SetEvent(Int_t evnt) {fEvent=evnt;}
86 void SetDebug(Int_t level=5) {fDebug=level;}
87 void SetNoDebug() {fDebug=0;}
88 void ClearMap() {fSensMap->Clear();}
90 static Int_t GenOrderedSample(UInt_t nmax,UInt_t ngen,TArrayI &vals,TArrayI &ind);
92 static Double_t GausInt1D(Double_t sig,Double_t a,Double_t b);
93 static Double_t GausInt2D(Double_t sig0,Double_t a0,Double_t b0,
94 Double_t sig1,Double_t a1,Double_t b1);
97 AliITSsegmentation *fSeg; //! segmentation
98 AliITSCalibration *fCalibDead; //! dead channels
99 AliITSCalibration *fCalibNoisy; //! noisy channels
100 AliITSUSensMap *fSensMap; //! sensor map for hits manipulations
101 AliITSUSimuParam *fSimuParam; //! simulation parameters
102 AliITSUParamList *fResponseParam; //! response parameterization data
103 AliITSUModule *fModule; //! module being processed
104 Int_t fEvent; //! event number being processed
105 Int_t fDebug; //! debug flag
106 Bool_t fCyclesID[2*kMaxROCycleAccept]; //! status of RO cycles
108 ClassDef(AliITSUSimulation,1) // Simulation base class
112 //_____________________________________________________________________________
113 inline Double_t AliITSUSimulation::GausInt1D(Double_t sig,Double_t a,Double_t b)
115 // calculate gaussian integral from a to b (with respecto to mean)
116 const Double_t kRoot2 = 1.414213562; // Sqrt(2).
117 double sp = 1.0/(sig*kRoot2);
118 return 0.5*TMath::Abs( AliMathBase::ErfcFast(sp*a) - AliMathBase::ErfcFast(sp*b) );
121 //_____________________________________________________________________________
122 inline Double_t AliITSUSimulation::GausInt2D(Double_t sig0,Double_t a0,Double_t b0,
123 Double_t sig1,Double_t a1,Double_t b1)
125 // calculate gaussian 2D integral from x0 to x1 (with respect to mean)
126 const Double_t kRoot2 = 1.414213562; // Sqrt(2).
127 double sp0 = 1.0/(sig0*kRoot2);
128 double sp1 = 1.0/(sig1*kRoot2);
129 return 0.25*TMath::Abs( (AliMathBase::ErfcFast(sp0*a0) - AliMathBase::ErfcFast(sp0*b0)) *
130 (AliMathBase::ErfcFast(sp1*a1) - AliMathBase::ErfcFast(sp1*b1)));