1 #ifndef ALIITSCALIBRATIONSSD_H
2 #define ALIITSCALIBRATIONSSD_H
3 /* Copyright(c) 2007-2009, ALICE Experiment at CERN, All rights reserved. *
4 * See cxx source for full Copyright notice */
5 #include "AliITSCalibration.h"
6 #include "AliITSNoiseSSD.h"
7 #include "AliITSPedestalSSD.h"
8 #include "AliITSGainSSD.h"
9 #include "AliITSBadChannelsSSD.h"
10 #include "AliITSresponseSSD.h"
15 //////////////////////////////////////////////
16 // Response class for SSD //
18 //////////////////////////////////////////////
19 class AliITSCalibrationSSD : public AliITSCalibration {
22 AliITSCalibrationSSD();
23 AliITSCalibrationSSD(const char *dataType);
24 virtual ~AliITSCalibrationSSD();
26 virtual void SetNoiseParam(Double_t np, Double_t nn) {
28 fNoiseP=np; fNoiseN=nn;
31 virtual void GetNoiseParam(Double_t &np, Double_t &nn) const {
33 np=fNoiseP; nn=fNoiseN;
36 void AddNoiseP(Int_t c, Float_t n) { fNoise->AddNoiseP(c,n);}
37 TArrayF GetNoiseP() {return fNoise->GetNoiseP(); }
38 Float_t GetNoiseP(Int_t n) {return fNoise->GetNoiseP(n); }
39 void AddNoiseN(Int_t c, Float_t n) { fNoise->AddNoiseN(c,n);}
40 TArrayF GetNoiseN() {return fNoise->GetNoiseN(); }
41 Float_t GetNoiseN(Int_t n) {return fNoise->GetNoiseN(n); }
42 void SetNoise( AliITSNoiseSSD* noise) {fNoise=noise;}
44 void AddPedestalP(Int_t c, Float_t n) { fPedestal->AddPedestalP(c,n);}
45 TArrayF GetPedestalP() {return fPedestal->GetPedestalP(); }
46 Float_t GetPedestalP(Int_t n) {return fPedestal->GetPedestalP(n); }
47 void AddPedestalN(Int_t c, Float_t n) { fPedestal->AddPedestalN(c,n);}
48 TArrayF GetPedestalN() {return fPedestal->GetPedestalN(); }
49 Float_t GetPedestalN(Int_t n) {return fPedestal->GetPedestalN(n); }
50 void SetPedestal( AliITSPedestalSSD* pedestal) {fPedestal=pedestal;}
52 void AddGainP(Int_t c, Float_t n) { fGain->AddGainP(c,n);}
53 TArrayF GetGainP() {return fGain->GetGainP(); }
54 Float_t GetGainP(Int_t n) {return fGain->GetGainP(n); }
55 void AddGainN(Int_t c, Float_t n) { fGain->AddGainN(c,n);}
56 TArrayF GetGainN() {return fGain->GetGainN(); }
57 Float_t GetGainN(Int_t n) {return fGain->GetGainN(n); }
58 void SetGain( AliITSGainSSD* gain) {fGain=gain;}
62 for(Int_t i=0;i<fgkChipsPerModule;i++) fIsChipBad[i]=kTRUE;
64 virtual Bool_t IsBad() const { return fIsBad; }
65 void SetChipBad(Int_t nChip) {
66 fIsChipBad[nChip] = kTRUE;
68 virtual Bool_t IsChipBad(Int_t nChip) const {
69 return fIsChipBad[nChip];
71 Int_t ChipsPerModule() const{return fgkChipsPerModule;} // Number of chips/module
72 Int_t ChannelsPerChip() const{ return fgkChannelsPerChip;}//Number of channels/chip
74 TArrayI GetBadPChannelsList() { return fBadChannels->GetBadPChannelsList(); } const
75 TArrayI GetBadNChannelsList() { return fBadChannels->GetBadNChannelsList(); } const
76 void SetBadChannels( AliITSBadChannelsSSD* badchannels) {fBadChannels=badchannels;}
78 void SetNoisePThreshold(Int_t threshold) { fNoisePThreshold = threshold;}
79 void AddNoisyPChannel(Int_t c, Int_t n) { fNoisyPChannelsList.AddAt(n,c);}
80 TArrayI GetNoisyPChannelsList() const {return fNoisyPChannelsList; }
81 void SetNoiseNThreshold(Int_t threshold) { fNoiseNThreshold = threshold;}
82 void AddNoisyNChannel(Int_t c, Int_t n) { fNoisyNChannelsList.AddAt(n,c);}
83 TArrayI GetNoisyNChannelsList() const {return fNoisyNChannelsList; }
85 void SetNDeadPChannelsList(Int_t n) { fDeadPChannelsList.Set(n); }
86 void AddDeadPChannel(Int_t c, Int_t n) { fDeadPChannelsList.AddAt(n,c);}
87 TArrayI GetDeadPChannelsList() const {return fDeadPChannelsList; }
88 void SetNDeadNChannelsList(Int_t n) { fDeadNChannelsList.Set(n); }
89 void AddDeadNChannel(Int_t c, Int_t n) { fDeadNChannelsList.AddAt(n,c);}
90 TArrayI GetDeadNChannelsList() const {return fDeadNChannelsList; }
94 virtual void SetNDetParam(Int_t npar) {
95 // set number of param
98 virtual void SetDetParam(Double_t *par);
100 // Parameters options
101 virtual Int_t NDetParam() const {
105 virtual void GetDetParam(Double_t *dpar) const;
107 virtual void SetSigmaSpread(Double_t p1, Double_t p2) {
108 // Set sigmas of the charge spread function: Pside-Nside
109 // square of (microns)
110 fSigmaP=p1; fSigmaN=p2;
113 virtual void SigmaSpread(Double_t &sP, Double_t &sN) const {
114 // Get sigmas for the charge spread
115 sP=fSigmaP; sN=fSigmaN;
118 virtual void SetThresholds(Double_t /* a */, Double_t /* b */)
119 {NotImplemented("SetThresholds");}
120 virtual void Thresholds(Double_t & /* a */, Double_t & /* b */) const
121 {NotImplemented("Thresholds");}
123 virtual void SetParamOptions(const char *opt1, const char *opt2) {((AliITSresponseSSD*)fResponse)->SetParamOptions(opt1,opt2);}
124 virtual void GetParamOptions(char *opt1,char *opt2) const {((AliITSresponseSSD*)fResponse)->ParamOptions(opt1,opt2);}
125 virtual void SetADCpereV(Double_t a=120./24888.9) {((AliITSresponseSSD*)fResponse)->SetADCpereV(a);}
126 virtual Double_t GetDEvToADC(Double_t eV) const {return ((AliITSresponseSSD*)fResponse)->DEvToADC(eV);}
127 virtual Int_t IEvToADC(Double_t eV) const {return ((AliITSresponseSSD*)fResponse)->IEvToADC(eV);}
129 virtual void SetKeVperADC(Double_t a=86.4/120.0) {((AliITSresponseSSD*)fResponse)->SetKeVperADC(a);}
130 virtual Double_t ADCToKeV(Double_t adc) const {return ((AliITSresponseSSD*)fResponse)->ADCToKeV(adc);}
132 virtual Double_t GetCouplingPR() const {return ((AliITSresponseSSD*)fResponse)->GetCouplingPR();}
133 virtual Double_t GetCouplingPL() const {return ((AliITSresponseSSD*)fResponse)->GetCouplingPL();}
134 virtual Double_t GetCouplingNR() const {return ((AliITSresponseSSD*)fResponse)->GetCouplingNR();}
135 virtual Double_t GetCouplingNL() const {return ((AliITSresponseSSD*)fResponse)->GetCouplingNL();}
136 virtual void SetCouplings(Double_t pr, Double_t pl, Double_t nr, Double_t nl)
137 { ((AliITSresponseSSD*)fResponse)->SetCouplings(pr,pl,nr,nl);}
139 virtual Int_t GetZSThreshold() const {return ((AliITSresponseSSD*)fResponse)->GetZSThreshold();}
140 virtual void SetZSThreshold(Int_t zsth)
141 { ((AliITSresponseSSD*)fResponse)->SetZSThreshold(zsth);}
145 static const Int_t fgkChipsPerModule = 12; // Number of chips/module
146 static const Int_t fgkChannelsPerChip = 128; // Number of channels/chip
148 static const Double_t fgkNoiseNDefault; // default for fNoiseN
149 static const Double_t fgkNoisePDefault; // default for fNoiseP
150 static const Int_t fgkNParDefault; // default for fNPar
151 static const Double_t fgkSigmaPDefault; //default for fSigmaP
152 static const Double_t fgkSigmaNDefault; //default for fSigmaP
154 Int_t fNPar; // Number of detector param
155 Double_t *fDetPar; //[fNPar] Array of parameters
157 Double_t fNoiseP; // Noise on Pside
158 Double_t fNoiseN; // Noise on Nside
159 Double_t fSigmaP; // Sigma charge spread on Pside
160 Double_t fSigmaN; // Sigma charge spread on Nside
162 AliITSNoiseSSD *fNoise;
163 AliITSPedestalSSD *fPedestal;
164 AliITSGainSSD *fGain;
165 AliITSBadChannelsSSD *fBadChannels;
167 Bool_t fIsBad; // module is dead or alive ?
168 Bool_t fIsChipBad[fgkChipsPerModule]; // chip is dead or alive ?
170 TArrayF fGainP; // Gain for P side channels
171 TArrayF fGainN; // Gain for N side channels
173 TArrayF fNoisP; // Noise for P side channels
174 TArrayF fNoisN; // Noise for N side channels
179 Float_t fNoisePThreshold; // need to decide if channel is noisy
180 TArrayI fNoisyPChannelsList; // list of P side noisy channels
181 Float_t fNoiseNThreshold; // need to decide if channel is noisy
182 TArrayI fNoisyNChannelsList; // list of N side noisy channels
184 TArrayI fDeadNChannelsList; // list of P side dead channels
185 TArrayI fDeadPChannelsList; // list of N side dead channels
188 AliITSCalibrationSSD(const AliITSCalibrationSSD &source); // copy constructor
189 AliITSCalibrationSSD& operator=(const AliITSCalibrationSSD &source); // ass. op.
191 ClassDef(AliITSCalibrationSSD,3) //Response class for SSD