//
//Begin_Html
/*
-<img src="picts/ITS/AliITShit_Class_Diagram.gif">
-</pre>
-<br clear=left>
-<font size=+2 color=red>
-<p>This show the relasionships between the ITS hit class and the rest of Aliroot.
-</font>
-<pre>
-*/
-//End_Html
-//______________________________________________________________________
-Int_t power(Int_t b, Int_t e) {
- // compute b to the e power, where both b and e are Int_ts.
- Int_t power = 1,i;
-
- for(i=0; i<e; i++) power *= b;
- return power;
+ <img src="picts/ITS/AliITShit_Class_Diagram.gif">
+ </pre>
+ <br clear=left>
+ <font size=+2 color=red>
+ <p>This show the relasionships between the ITS hit class and the rest of Aliroot.
+ </font>
+ <pre>
+ */
+ //End_Html
+
+ //______________________________________________________________________
+ Int_t power(Int_t b, Int_t e) {
+ // compute b to the e power, where both b and e are Int_ts.
+ Int_t power = 1,i;
+
+ for(i=0; i<e; i++) power *= b;
+ return power;
}
//______________________________________________________________________
void FastFourierTransform(AliITSetfSDD *alisddetf,Double_t *real,
Double_t *imag,Int_t direction) {
- // Do a Fast Fourier Transform
-
- Int_t samples = alisddetf->GetSamples();
- Int_t l = (Int_t) ((log((Float_t) samples)/log(2.))+0.5);
- Int_t m1 = samples;
- Int_t m = samples/2;
- Int_t m2 = samples/m1;
- Int_t i,j,k;
- for(i=1; i<=l; i++) {
- for(j=0; j<samples; j += m1) {
- Int_t p = 0;
- for(k=j; k<= j+m-1; k++) {
- Double_t wsr = alisddetf->GetWeightReal(p);
- Double_t wsi = alisddetf->GetWeightImag(p);
- if(direction == -1) wsi = -wsi;
- Double_t xr = *(real+k+m);
- Double_t xi = *(imag+k+m);
- *(real+k+m) = wsr*(*(real+k)-xr) - wsi*(*(imag+k)-xi);
- *(imag+k+m) = wsr*(*(imag+k)-xi) + wsi*(*(real+k)-xr);
- *(real+k) += xr;
- *(imag+k) += xi;
- p += m2;
- } // end for k
- } // end for j
- m1 = m;
- m /= 2;
- m2 += m2;
- } // end for i
-
- for(j=0; j<samples; j++) {
- Int_t j1 = j;
- Int_t p = 0;
- Int_t i1;
- for(i1=1; i1<=l; i1++) {
- Int_t j2 = j1;
- j1 /= 2;
- p = p + p + j2 - j1 - j1;
- } // end for i1
- if(p >= j) {
- Double_t xr = *(real+j);
- Double_t xi = *(imag+j);
- *(real+j) = *(real+p);
- *(imag+j) = *(imag+p);
- *(real+p) = xr;
- *(imag+p) = xi;
- } // end if p>=j
+ // Do a Fast Fourier Transform
+
+ Int_t samples = alisddetf->GetSamples();
+ Int_t l = (Int_t) ((log((Float_t) samples)/log(2.))+0.5);
+ Int_t m1 = samples;
+ Int_t m = samples/2;
+ Int_t m2 = samples/m1;
+ Int_t i,j,k;
+ for(i=1; i<=l; i++) {
+ for(j=0; j<samples; j += m1) {
+ Int_t p = 0;
+ for(k=j; k<= j+m-1; k++) {
+ Double_t wsr = alisddetf->GetWeightReal(p);
+ Double_t wsi = alisddetf->GetWeightImag(p);
+ if(direction == -1) wsi = -wsi;
+ Double_t xr = *(real+k+m);
+ Double_t xi = *(imag+k+m);
+ *(real+k+m) = wsr*(*(real+k)-xr) - wsi*(*(imag+k)-xi);
+ *(imag+k+m) = wsr*(*(imag+k)-xi) + wsi*(*(real+k)-xr);
+ *(real+k) += xr;
+ *(imag+k) += xi;
+ p += m2;
+ } // end for k
} // end for j
- if(direction == -1) {
- for(i=0; i<samples; i++) {
- *(real+i) /= samples;
- *(imag+i) /= samples;
- } // end for i
- } // end if direction == -1
- return;
+ m1 = m;
+ m /= 2;
+ m2 += m2;
+ } // end for i
+
+ for(j=0; j<samples; j++) {
+ Int_t j1 = j;
+ Int_t p = 0;
+ Int_t i1;
+ for(i1=1; i1<=l; i1++) {
+ Int_t j2 = j1;
+ j1 /= 2;
+ p = p + p + j2 - j1 - j1;
+ } // end for i1
+ if(p >= j) {
+ Double_t xr = *(real+j);
+ Double_t xi = *(imag+j);
+ *(real+j) = *(real+p);
+ *(imag+j) = *(imag+p);
+ *(real+p) = xr;
+ *(imag+p) = xi;
+ } // end if p>=j
+ } // end for j
+ if(direction == -1) {
+ for(i=0; i<samples; i++) {
+ *(real+i) /= samples;
+ *(imag+i) /= samples;
+ } // end for i
+ } // end if direction == -1
+ return;
}
//______________________________________________________________________
AliITSsimulationSDD::AliITSsimulationSDD() {
- // Default constructor
-
- fResponse = 0;
- fSegmentation = 0;
- fHis = 0;
-// fpList = 0;
- fHitMap2 = 0;
- fHitSigMap2 = 0;
- fHitNoiMap2 = 0;
- fElectronics = 0;
- fStream = 0;
- fInZR = 0;
- fInZI = 0;
- fOutZR = 0;
- fOutZI = 0;
- fNofMaps = 0;
- fMaxNofSamples = 0;
- fITS = 0;
- fTreeB = 0;
- fAnodeFire = 0;
- SetScaleFourier();
- SetPerpendTracksFlag();
- SetCrosstalkFlag();
- SetDoFFT();
- SetCheckNoise();
+ // Default constructor
+
+ fResponse = 0;
+ fSegmentation = 0;
+ fHis = 0;
+ // fpList = 0;
+ fHitMap2 = 0;
+ fHitSigMap2 = 0;
+ fHitNoiMap2 = 0;
+ fElectronics = 0;
+ fStream = 0;
+ fInZR = 0;
+ fInZI = 0;
+ fOutZR = 0;
+ fOutZI = 0;
+ fNofMaps = 0;
+ fMaxNofSamples = 0;
+ fITS = 0;
+ fTreeB = 0;
+ fAnodeFire = 0;
+ SetScaleFourier();
+ SetPerpendTracksFlag();
+ SetCrosstalkFlag();
+ SetDoFFT();
+ SetCheckNoise();
}
//______________________________________________________________________
AliITSsimulationSDD::AliITSsimulationSDD(AliITSsimulationSDD &source) :
- AliITSsimulation(source){
- // Copy constructor to satify Coding roules only.
+ AliITSsimulation(source){
+ // Copy constructor to satify Coding roules only.
- if(this==&source) return;
- Error("AliITSsimulationSSD","Not allowed to make a copy of "
- "AliITSsimulationSDD Using default creater instead");
- AliITSsimulationSDD();
+ if(this==&source) return;
+ Error("AliITSsimulationSSD","Not allowed to make a copy of "
+ "AliITSsimulationSDD Using default creater instead");
+ AliITSsimulationSDD();
}
//______________________________________________________________________
AliITSsimulationSDD& AliITSsimulationSDD::operator=(AliITSsimulationSDD &src){
- // Assignment operator to satify Coding roules only.
+ // Assignment operator to satify Coding roules only.
- if(this==&src) return *this;
- Error("AliITSsimulationSSD","Not allowed to make a = with "
- "AliITSsimulationSDD Using default creater instead");
- return *this ;
+ if(this==&src) return *this;
+ Error("AliITSsimulationSSD","Not allowed to make a = with "
+ "AliITSsimulationSDD Using default creater instead");
+ return *this ;
}
//______________________________________________________________________
AliITSsimulationSDD::AliITSsimulationSDD(AliITSsegmentation *seg,
AliITSresponse *resp){
- // Standard Constructor
-
- fResponse = 0;
- fSegmentation = 0;
- fHis = 0;
-// fpList = 0;
- fHitMap2 = 0;
- fHitSigMap2 = 0;
- fHitNoiMap2 = 0;
- fElectronics = 0;
- fStream = 0;
- fInZR = 0;
- fInZI = 0;
- fOutZR = 0;
- fOutZI = 0;
- fNofMaps = 0;
- fMaxNofSamples = 0;
- fITS = 0;
- fTreeB = 0;
- SetDebug(kFALSE);
-
- Init((AliITSsegmentationSDD*)seg,(AliITSresponseSDD*)resp);
+ // Standard Constructor
+
+ fResponse = 0;
+ fSegmentation = 0;
+ fHis = 0;
+ // fpList = 0;
+ fHitMap2 = 0;
+ fHitSigMap2 = 0;
+ fHitNoiMap2 = 0;
+ fElectronics = 0;
+ fStream = 0;
+ fInZR = 0;
+ fInZI = 0;
+ fOutZR = 0;
+ fOutZI = 0;
+ fNofMaps = 0;
+ fMaxNofSamples = 0;
+ fITS = 0;
+ fTreeB = 0;
+ SetDebug(kFALSE);
+
+ Init((AliITSsegmentationSDD*)seg,(AliITSresponseSDD*)resp);
}
//______________________________________________________________________
void AliITSsimulationSDD::Init(AliITSsegmentationSDD *seg,
AliITSresponseSDD *resp){
- // Standard Constructor
-
- fResponse = resp;
- fSegmentation = seg;
- SetScaleFourier();
- SetPerpendTracksFlag();
- SetCrosstalkFlag();
- SetDoFFT();
- SetCheckNoise();
-
- fpList = new AliITSpList( fSegmentation->Npz(),
- fScaleSize*fSegmentation->Npx() );
- fHitSigMap2 = new AliITSMapA2(fSegmentation,fScaleSize,1);
- fHitNoiMap2 = new AliITSMapA2(fSegmentation,fScaleSize,1);
- fHitMap2 = fHitSigMap2;
-
- fNofMaps = fSegmentation->Npz();
- fMaxNofSamples = fSegmentation->Npx();
- fAnodeFire = new Bool_t [fNofMaps];
+ // Standard Constructor
+
+ fResponse = resp;
+ fSegmentation = seg;
+ SetScaleFourier();
+ SetPerpendTracksFlag();
+ SetCrosstalkFlag();
+ SetDoFFT();
+ SetCheckNoise();
+
+ fpList = new AliITSpList( fSegmentation->Npz(),
+ fScaleSize*fSegmentation->Npx() );
+ fHitSigMap2 = new AliITSMapA2(fSegmentation,fScaleSize,1);
+ fHitNoiMap2 = new AliITSMapA2(fSegmentation,fScaleSize,1);
+ fHitMap2 = fHitSigMap2;
+
+ fNofMaps = fSegmentation->Npz();
+ fMaxNofSamples = fSegmentation->Npx();
+ fAnodeFire = new Bool_t [fNofMaps];
- Float_t sddLength = fSegmentation->Dx();
- Float_t sddWidth = fSegmentation->Dz();
-
- Int_t dummy = 0;
- Float_t anodePitch = fSegmentation->Dpz(dummy);
- Double_t timeStep = (Double_t)fSegmentation->Dpx(dummy);
- Float_t driftSpeed = fResponse->DriftSpeed();
-
- if(anodePitch*(fNofMaps/2) > sddWidth) {
- Warning("AliITSsimulationSDD",
- "Too many anodes %d or too big pitch %f \n",
- fNofMaps/2,anodePitch);
- } // end if
-
- if(timeStep*fMaxNofSamples < sddLength/driftSpeed) {
- Error("AliITSsimulationSDD",
- "Time Interval > Allowed Time Interval: exit\n");
- return;
- } // end if
-
- fElectronics = new AliITSetfSDD(timeStep/fScaleSize,
- fResponse->Electronics());
-
- char opt1[20], opt2[20];
- fResponse->ParamOptions(opt1,opt2);
- fParam = opt2;
- char *same = strstr(opt1,"same");
- if (same) {
- fNoise.Set(0);
- fBaseline.Set(0);
- } else {
- fNoise.Set(fNofMaps);
- fBaseline.Set(fNofMaps);
- } // end if
-
- const char *kopt=fResponse->ZeroSuppOption();
- if (strstr(fParam.Data(),"file") ) {
- fD.Set(fNofMaps);
- fT1.Set(fNofMaps);
- if (strstr(kopt,"2D")) {
- fT2.Set(fNofMaps);
- fTol.Set(0);
- Init2D(); // desactivate if param change module by module
- } else if(strstr(kopt,"1D")) {
- fT2.Set(2);
- fTol.Set(2);
- Init1D(); // desactivate if param change module by module
- } // end if strstr
- } else {
- fD.Set(2);
- fTol.Set(2);
- fT1.Set(2);
- fT2.Set(2);
- SetCompressParam();
- } // end if else strstr
+ Float_t sddLength = fSegmentation->Dx();
+ Float_t sddWidth = fSegmentation->Dz();
+
+ Int_t dummy = 0;
+ Float_t anodePitch = fSegmentation->Dpz(dummy);
+ Double_t timeStep = (Double_t)fSegmentation->Dpx(dummy);
+ Float_t driftSpeed = fResponse->DriftSpeed();
+
+ if(anodePitch*(fNofMaps/2) > sddWidth) {
+ Warning("AliITSsimulationSDD",
+ "Too many anodes %d or too big pitch %f \n",
+ fNofMaps/2,anodePitch);
+ } // end if
+
+ if(timeStep*fMaxNofSamples < sddLength/driftSpeed) {
+ Error("AliITSsimulationSDD",
+ "Time Interval > Allowed Time Interval: exit\n");
+ return;
+ } // end if
+
+ fElectronics = new AliITSetfSDD(timeStep/fScaleSize,
+ fResponse->Electronics());
+
+ char opt1[20], opt2[20];
+ fResponse->ParamOptions(opt1,opt2);
+ fParam = opt2;
+ char *same = strstr(opt1,"same");
+ if (same) {
+ fNoise.Set(0);
+ fBaseline.Set(0);
+ } else {
+ fNoise.Set(fNofMaps);
+ fBaseline.Set(fNofMaps);
+ } // end if
+
+ const char *kopt=fResponse->ZeroSuppOption();
+ if (strstr(fParam.Data(),"file") ) {
+ fD.Set(fNofMaps);
+ fT1.Set(fNofMaps);
+ if (strstr(kopt,"2D")) {
+ fT2.Set(fNofMaps);
+ fTol.Set(0);
+ Init2D(); // desactivate if param change module by module
+ } else if(strstr(kopt,"1D")) {
+ fT2.Set(2);
+ fTol.Set(2);
+ Init1D(); // desactivate if param change module by module
+ } // end if strstr
+ } else {
+ fD.Set(2);
+ fTol.Set(2);
+ fT1.Set(2);
+ fT2.Set(2);
+ SetCompressParam();
+ } // end if else strstr
- Bool_t write = fResponse->OutputOption();
- if(write && strstr(kopt,"2D")) MakeTreeB();
+ Bool_t write = fResponse->OutputOption();
+ if(write && strstr(kopt,"2D")) MakeTreeB();
- // call here if baseline does not change by module
- // ReadBaseline();
+ // call here if baseline does not change by module
+ // ReadBaseline();
- fITS = (AliITS*)gAlice->GetModule("ITS");
- Int_t size = fNofMaps*fMaxNofSamples;
- fStream = new AliITSInStream(size);
+ fITS = (AliITS*)gAlice->GetModule("ITS");
+ Int_t size = fNofMaps*fMaxNofSamples;
+ fStream = new AliITSInStream(size);
- fInZR = new Double_t [fScaleSize*fMaxNofSamples];
- fInZI = new Double_t [fScaleSize*fMaxNofSamples];
- fOutZR = new Double_t [fScaleSize*fMaxNofSamples];
- fOutZI = new Double_t [fScaleSize*fMaxNofSamples];
+ fInZR = new Double_t [fScaleSize*fMaxNofSamples];
+ fInZI = new Double_t [fScaleSize*fMaxNofSamples];
+ fOutZR = new Double_t [fScaleSize*fMaxNofSamples];
+ fOutZI = new Double_t [fScaleSize*fMaxNofSamples];
}
//______________________________________________________________________
AliITSsimulationSDD::~AliITSsimulationSDD() {
- // destructor
-
-// delete fpList;
- delete fHitSigMap2;
- delete fHitNoiMap2;
- delete fStream;
- delete fElectronics;
-
- fITS = 0;
-
- if (fHis) {
- fHis->Delete();
- delete fHis;
- } // end if fHis
- if(fTreeB) delete fTreeB;
- if(fInZR) delete [] fInZR;
- if(fInZI) delete [] fInZI;
- if(fOutZR) delete [] fOutZR;
- if(fOutZI) delete [] fOutZI;
- if(fAnodeFire) delete [] fAnodeFire;
+ // destructor
+
+ // delete fpList;
+ delete fHitSigMap2;
+ delete fHitNoiMap2;
+ delete fStream;
+ delete fElectronics;
+
+ fITS = 0;
+
+ if (fHis) {
+ fHis->Delete();
+ delete fHis;
+ } // end if fHis
+ if(fTreeB) delete fTreeB;
+ if(fInZR) delete [] fInZR;
+ if(fInZI) delete [] fInZI;
+ if(fOutZR) delete [] fOutZR;
+ if(fOutZI) delete [] fOutZI;
+ if(fAnodeFire) delete [] fAnodeFire;
}
//______________________________________________________________________
void AliITSsimulationSDD::InitSimulationModule( Int_t module, Int_t event ) {
- // create maps to build the lists of tracks for each summable digit
- fModule = module;
- fEvent = event;
- ClearMaps();
- memset(fAnodeFire,0,sizeof(Bool_t)*fNofMaps);
+ // create maps to build the lists of tracks for each summable digit
+ fModule = module;
+ fEvent = event;
+ ClearMaps();
+ memset(fAnodeFire,0,sizeof(Bool_t)*fNofMaps);
}
//______________________________________________________________________
void AliITSsimulationSDD::ClearMaps() {
- // clear maps
- fpList->ClearMap();
- fHitSigMap2->ClearMap();
- fHitNoiMap2->ClearMap();
+ // clear maps
+ fpList->ClearMap();
+ fHitSigMap2->ClearMap();
+ fHitNoiMap2->ClearMap();
}
//______________________________________________________________________
void AliITSsimulationSDD::SDigitiseModule( AliITSmodule *mod, Int_t md, Int_t ev){
- // digitize module using the "slow" detector simulator creating
- // summable digits.
-
- TObjArray *fHits = mod->GetHits();
- Int_t nhits = fHits->GetEntriesFast();
- if( !nhits ) return;
-
- InitSimulationModule( md, ev );
- HitsToAnalogDigits( mod );
- ChargeToSignal( kFALSE ); // - Process signal without add noise
- fHitMap2 = fHitNoiMap2; // - Swap to noise map
- ChargeToSignal( kTRUE ); // - Process only noise
- fHitMap2 = fHitSigMap2; // - Return to signal map
- WriteSDigits();
- ClearMaps();
+ // digitize module using the "slow" detector simulator creating
+ // summable digits.
+
+ TObjArray *fHits = mod->GetHits();
+ Int_t nhits = fHits->GetEntriesFast();
+ if( !nhits ) return;
+
+ InitSimulationModule( md, ev );
+ HitsToAnalogDigits( mod );
+ ChargeToSignal( kFALSE ); // - Process signal without add noise
+ fHitMap2 = fHitNoiMap2; // - Swap to noise map
+ ChargeToSignal( kTRUE ); // - Process only noise
+ fHitMap2 = fHitSigMap2; // - Return to signal map
+ WriteSDigits();
+ ClearMaps();
}
//______________________________________________________________________
Bool_t AliITSsimulationSDD::AddSDigitsToModule( TClonesArray *pItemArray, Int_t mask ) {
- // Add Summable digits to module maps.
- Int_t nItems = pItemArray->GetEntries();
- Double_t maxadc = fResponse->MaxAdc();
- //Bool_t sig = kFALSE;
+ // Add Summable digits to module maps.
+ Int_t nItems = pItemArray->GetEntries();
+ Double_t maxadc = fResponse->MaxAdc();
+ //Bool_t sig = kFALSE;
- // cout << "Adding "<< nItems <<" SDigits to module " << fModule << endl;
- for( Int_t i=0; i<nItems; i++ ) {
- AliITSpListItem * pItem = (AliITSpListItem *)(pItemArray->At( i ));
- if( pItem->GetModule() != fModule ) {
- Error( "AliITSsimulationSDD",
- "Error reading, SDigits module %d != current module %d: exit\n",
- pItem->GetModule(), fModule );
- return kFALSE;
- } // end if
+ // cout << "Adding "<< nItems <<" SDigits to module " << fModule << endl;
+ for( Int_t i=0; i<nItems; i++ ) {
+ AliITSpListItem * pItem = (AliITSpListItem *)(pItemArray->At( i ));
+ if( pItem->GetModule() != fModule ) {
+ Error( "AliITSsimulationSDD",
+ "Error reading, SDigits module %d != current module %d: exit\n",
+ pItem->GetModule(), fModule );
+ return kFALSE;
+ } // end if
// if(pItem->GetSignal()>0.0 ) sig = kTRUE;
- fpList->AddItemTo( mask, pItem ); // Add SignalAfterElect + noise
- AliITSpListItem * pItem2 = fpList->GetpListItem( pItem->GetIndex() );
- Double_t sigAE = pItem2->GetSignalAfterElect();
- if( sigAE >= maxadc ) sigAE = maxadc-1; // avoid overflow signal
- Int_t ia;
- Int_t it;
- fpList->GetMapIndex( pItem->GetIndex(), ia, it );
- fHitMap2->SetHit( ia, it, sigAE );
- fAnodeFire[ia] = kTRUE;
- }
- return kTRUE;
+ fpList->AddItemTo( mask, pItem ); // Add SignalAfterElect + noise
+ AliITSpListItem * pItem2 = fpList->GetpListItem( pItem->GetIndex() );
+ Double_t sigAE = pItem2->GetSignalAfterElect();
+ if( sigAE >= maxadc ) sigAE = maxadc-1; // avoid overflow signal
+ Int_t ia;
+ Int_t it;
+ fpList->GetMapIndex( pItem->GetIndex(), ia, it );
+ fHitMap2->SetHit( ia, it, sigAE );
+ fAnodeFire[ia] = kTRUE;
+ }
+ return kTRUE;
}
//______________________________________________________________________
void AliITSsimulationSDD::FinishSDigitiseModule() {
- // digitize module using the "slow" detector simulator from
- // the sum of summable digits.
- FinishDigits() ;
- ClearMaps();
+ // digitize module using the "slow" detector simulator from
+ // the sum of summable digits.
+ FinishDigits() ;
+ ClearMaps();
}
//______________________________________________________________________
void AliITSsimulationSDD::DigitiseModule(AliITSmodule *mod,Int_t md,Int_t ev){
- // create maps to build the lists of tracks for each digit
+ // create maps to build the lists of tracks for each digit
- TObjArray *fHits = mod->GetHits();
- Int_t nhits = fHits->GetEntriesFast();
+ TObjArray *fHits = mod->GetHits();
+ Int_t nhits = fHits->GetEntriesFast();
- InitSimulationModule( md, ev );
+ InitSimulationModule( md, ev );
- if( !nhits && fCheckNoise ) {
- ChargeToSignal( kTRUE ); // process noise
- GetNoise();
- ClearMaps();
- return;
- } else
- if( !nhits ) return;
+ if( !nhits && fCheckNoise ) {
+ ChargeToSignal( kTRUE ); // process noise
+ GetNoise();
+ ClearMaps();
+ return;
+ } else
+ if( !nhits ) return;
- HitsToAnalogDigits( mod );
- ChargeToSignal( kTRUE ); // process signal + noise
-
- for( Int_t i=0; i<fNofMaps; i++ ) {
- for( Int_t j=0; j<fMaxNofSamples; j++ ) {
- Int_t jdx = j*fScaleSize;
- Int_t index = fpList->GetHitIndex( i, j );
- AliITSpListItem pItemTmp2( fModule, index, 0. );
- // put the fScaleSize analog digits in only one
- for( Int_t ik=0; ik<fScaleSize; ik++ ) {
- AliITSpListItem *pItemTmp = fpList->GetpListItem( i, jdx+ik );
- if( pItemTmp == 0 ) continue;
- pItemTmp2.Add( pItemTmp );
- }
- fpList->DeleteHit( i, j );
- fpList->AddItemTo( 0, &pItemTmp2 );
- }
+ HitsToAnalogDigits( mod );
+ ChargeToSignal( kTRUE ); // process signal + noise
+
+ for( Int_t i=0; i<fNofMaps; i++ ) {
+ for( Int_t j=0; j<fMaxNofSamples; j++ ) {
+ Int_t jdx = j*fScaleSize;
+ Int_t index = fpList->GetHitIndex( i, j );
+ AliITSpListItem pItemTmp2( fModule, index, 0. );
+ // put the fScaleSize analog digits in only one
+ for( Int_t ik=0; ik<fScaleSize; ik++ ) {
+ AliITSpListItem *pItemTmp = fpList->GetpListItem( i, jdx+ik );
+ if( pItemTmp == 0 ) continue;
+ pItemTmp2.Add( pItemTmp );
+ }
+ fpList->DeleteHit( i, j );
+ fpList->AddItemTo( 0, &pItemTmp2 );
}
+ }
- FinishDigits();
- ClearMaps();
+ FinishDigits();
+ ClearMaps();
}
//______________________________________________________________________
void AliITSsimulationSDD::FinishDigits() {
- // introduce the electronics effects and do zero-suppression if required
+ // introduce the electronics effects and do zero-suppression if required
- ApplyDeadChannels();
- if( fCrosstalkFlag ) ApplyCrosstalk();
+ ApplyDeadChannels();
+ if( fCrosstalkFlag ) ApplyCrosstalk();
- const char *kopt = fResponse->ZeroSuppOption();
- ZeroSuppression( kopt );
+ const char *kopt = fResponse->ZeroSuppOption();
+ ZeroSuppression( kopt );
}
//______________________________________________________________________
void AliITSsimulationSDD::HitsToAnalogDigits( AliITSmodule *mod ) {
- // create maps to build the lists of tracks for each digit
-
- TObjArray *fHits = mod->GetHits();
- Int_t nhits = fHits->GetEntriesFast();
-// Int_t arg[6] = {0,0,0,0,0,0};
- Int_t dummy = 0;
- Int_t nofAnodes = fNofMaps/2;
- Float_t sddLength = fSegmentation->Dx();
- Float_t sddWidth = fSegmentation->Dz();
- Float_t anodePitch = fSegmentation->Dpz(dummy);
- Float_t timeStep = fSegmentation->Dpx(dummy);
- Float_t driftSpeed = fResponse->DriftSpeed();
- Float_t maxadc = fResponse->MaxAdc();
- Float_t topValue = fResponse->DynamicRange();
- Float_t cHloss = fResponse->ChargeLoss();
- Float_t norm = maxadc/topValue;
- Float_t dfCoeff, s1; fResponse->DiffCoeff(dfCoeff,s1); // Signal 2d Shape
- Double_t eVpairs = 3.6; // electron pair energy eV.
- Float_t nsigma = fResponse->NSigmaIntegration(); //
- Int_t nlookups = fResponse->GausNLookUp(); //
- Float_t jitter = ((AliITSresponseSDD*)fResponse)->JitterError(); //
-
- // Piergiorgio's part (apart for few variables which I made float
- // when i thought that can be done
- // Fill detector maps with GEANT hits
- // loop over hits in the module
-
- const Float_t kconv = 1.0e+6; // GeV->KeV
- Int_t itrack = 0;
- Int_t hitDetector; // detector number (lay,lad,hitDetector)
- Int_t iWing; // which detector wing/side.
- Int_t detector; // 2*(detector-1)+iWing
- Int_t ii,kk,ka,kt; // loop indexs
- Int_t ia,it,index; // sub-pixel integration indexies
- Int_t iAnode; // anode number.
- Int_t timeSample; // time buckett.
- Int_t anodeWindow; // anode direction charge integration width
- Int_t timeWindow; // time direction charge integration width
- Int_t jamin,jamax; // anode charge integration window
- Int_t jtmin,jtmax; // time charge integration window
- Int_t ndiv; // Anode window division factor.
- Int_t nsplit; // the number of splits in anode and time windows==1.
- Int_t nOfSplits; // number of times track length is split into
- Float_t nOfSplitsF; // Floating point version of nOfSplits.
- Float_t kkF; // Floating point version of loop index kk.
- Float_t pathInSDD; // Track length in SDD.
- Float_t drPath; // average position of track in detector. in microns
- Float_t drTime; // Drift time
- Float_t nmul; // drift time window multiplication factor.
- Float_t avDrft; // x position of path length segment in cm.
- Float_t avAnode; // Anode for path length segment in Anode number (float)
- Float_t xAnode; // Floating point anode number.
- Float_t driftPath; // avDrft in microns.
- Float_t width; // width of signal at anodes.
- Double_t depEnergy; // Energy deposited in this GEANT step.
- Double_t xL[3],dxL[3]; // local hit coordinates and diff.
- Double_t sigA; // sigma of signal at anode.
- Double_t sigT; // sigma in time/drift direction for track segment
- Double_t aStep,aConst; // sub-pixel size and offset anode
- Double_t tStep,tConst; // sub-pixel size and offset time
- Double_t amplitude; // signal amplitude for track segment in nanoAmpere
- Double_t chargeloss; // charge loss for track segment.
- Double_t anodeAmplitude; // signal amplitude in anode direction
- Double_t aExpo; // exponent of Gaussian anode direction
- Double_t timeAmplitude; // signal amplitude in time direction
- Double_t tExpo; // exponent of Gaussian time direction
-// Double_t tof; // Time of flight in ns of this step.
-
- for(ii=0; ii<nhits; ii++) {
- if(!mod->LineSegmentL(ii,xL[0],dxL[0],xL[1],dxL[1],xL[2],dxL[2],
- depEnergy,itrack)) continue;
- xL[0] += 0.0001*gRandom->Gaus( 0, jitter ); //
- depEnergy *= kconv;
- hitDetector = mod->GetDet();
- //tof = 1.E+09*(mod->GetHit(ii)->GetTOF()); // tof in ns.
- //if(tof>sddLength/driftSpeed) continue; // hit happed too late.
-
- // scale path to simulate a perpendicular track
- // continue if the particle did not lose energy
- // passing through detector
- if (!depEnergy) {
- if(GetDebug()){
- Warning("HitsToAnalogDigits",
- "fTrack = %d hit=%d module=%d This particle has"
- " passed without losing energy!",
- itrack,ii,mod->GetIndex());
- }
- continue;
- } // end if !depEnergy
-
- pathInSDD = TMath::Sqrt(dxL[0]*dxL[0]+dxL[1]*dxL[1]+dxL[2]*dxL[2]);
-
- if (fFlag && pathInSDD) { depEnergy *= (0.03/pathInSDD); }
- drPath = 10000.*(dxL[0]+2.*xL[0])*0.5;
- if(drPath < 0) drPath = -drPath;
- drPath = sddLength-drPath;
- if(drPath < 0) {
- if(GetDebug()){ // this should be fixed at geometry level
- Warning("HitsToAnalogDigits",
- "negative drift path drPath=%e sddLength=%e dxL[0]=%e "
- "xL[0]=%e",
- drPath,sddLength,dxL[0],xL[0]);
- }
- continue;
- } // end if drPath < 0
-
- // Compute number of segments to brake step path into
- drTime = drPath/driftSpeed; // Drift Time
- sigA = TMath::Sqrt(2.*dfCoeff*drTime+s1*s1);// Sigma along the anodes
- // calcuate the number of time the path length should be split into.
- nOfSplits = (Int_t) (1. + 10000.*pathInSDD/sigA);
- if(fFlag) nOfSplits = 1;
-
- // loop over path segments, init. some variables.
- depEnergy /= nOfSplits;
- nOfSplitsF = (Float_t) nOfSplits;
- for(kk=0;kk<nOfSplits;kk++) { // loop over path segments
- kkF = (Float_t) kk + 0.5;
- avDrft = xL[0]+dxL[0]*kkF/nOfSplitsF;
- avAnode = xL[2]+dxL[2]*kkF/nOfSplitsF;
- driftPath = 10000.*avDrft;
-
- iWing = 2; // Assume wing is 2
- if(driftPath < 0) { // if wing is not 2 it is 1.
- iWing = 1;
- driftPath = -driftPath;
- } // end if driftPath < 0
- driftPath = sddLength-driftPath;
- detector = 2*(hitDetector-1) + iWing;
- if(driftPath < 0) {
- if(GetDebug()){ // this should be fixed at geometry level
- Warning("HitsToAnalogDigits","negative drift path "
- "driftPath=%e sddLength=%e avDrft=%e dxL[0]=%e "
- "xL[0]=%e",driftPath,sddLength,avDrft,dxL[0],xL[0]);
- }
- continue;
- } // end if driftPath < 0
-
- // Drift Time
- drTime = driftPath/driftSpeed; // drift time for segment.
- timeSample = (Int_t) (fScaleSize*drTime/timeStep + 1);
- // compute time Sample including tof information. The tof only
- // effects the time of the signal is recoreded and not the
- // the defusion.
- // timeSample = (Int_t) (fScaleSize*(drTime+tof)/timeStep + 1);
- if(timeSample > fScaleSize*fMaxNofSamples) {
- Warning("HitsToAnalogDigits","Wrong Time Sample: %e",
- timeSample);
- continue;
- } // end if timeSample > fScaleSize*fMaxNoofSamples
-
- // Anode
- xAnode = 10000.*(avAnode)/anodePitch + nofAnodes/2; // +1?
- if(xAnode*anodePitch > sddWidth || xAnode*anodePitch < 0.)
- Warning("HitsToAnalogDigits",
- "Exceedubg sddWidth=%e Z = %e",
- sddWidth,xAnode*anodePitch);
- iAnode = (Int_t) (1.+xAnode); // xAnode?
- if(iAnode < 1 || iAnode > nofAnodes) {
- Warning("HitToAnalogDigits","Wrong iAnode: 1<%d>%d",
- iAnode,nofAnodes);
- continue;
- } // end if iAnode < 1 || iAnode > nofAnodes
-
- // store straight away the particle position in the array
- // of particles and take idhit=ii only when part is entering (this
- // requires FillModules() in the macro for analysis) :
+ // create maps to build the lists of tracks for each digit
+
+ TObjArray *fHits = mod->GetHits();
+ Int_t nhits = fHits->GetEntriesFast();
+ // Int_t arg[6] = {0,0,0,0,0,0};
+ Int_t dummy = 0;
+ Int_t nofAnodes = fNofMaps/2;
+ Float_t sddLength = fSegmentation->Dx();
+ Float_t sddWidth = fSegmentation->Dz();
+ Float_t anodePitch = fSegmentation->Dpz(dummy);
+ Float_t timeStep = fSegmentation->Dpx(dummy);
+ Float_t driftSpeed = fResponse->DriftSpeed();
+ Float_t maxadc = fResponse->MaxAdc();
+ Float_t topValue = fResponse->DynamicRange();
+ Float_t cHloss = fResponse->ChargeLoss();
+ Float_t norm = maxadc/topValue;
+ Float_t dfCoeff, s1; fResponse->DiffCoeff(dfCoeff,s1); // Signal 2d Shape
+ Double_t eVpairs = 3.6; // electron pair energy eV.
+ Float_t nsigma = fResponse->NSigmaIntegration(); //
+ Int_t nlookups = fResponse->GausNLookUp(); //
+ Float_t jitter = ((AliITSresponseSDD*)fResponse)->JitterError(); //
+
+ // Piergiorgio's part (apart for few variables which I made float
+ // when i thought that can be done
+ // Fill detector maps with GEANT hits
+ // loop over hits in the module
+
+ const Float_t kconv = 1.0e+6; // GeV->KeV
+ Int_t itrack = 0;
+ Int_t hitDetector; // detector number (lay,lad,hitDetector)
+ Int_t iWing; // which detector wing/side.
+ Int_t detector; // 2*(detector-1)+iWing
+ Int_t ii,kk,ka,kt; // loop indexs
+ Int_t ia,it,index; // sub-pixel integration indexies
+ Int_t iAnode; // anode number.
+ Int_t timeSample; // time buckett.
+ Int_t anodeWindow; // anode direction charge integration width
+ Int_t timeWindow; // time direction charge integration width
+ Int_t jamin,jamax; // anode charge integration window
+ Int_t jtmin,jtmax; // time charge integration window
+ Int_t ndiv; // Anode window division factor.
+ Int_t nsplit; // the number of splits in anode and time windows==1.
+ Int_t nOfSplits; // number of times track length is split into
+ Float_t nOfSplitsF; // Floating point version of nOfSplits.
+ Float_t kkF; // Floating point version of loop index kk.
+ Float_t pathInSDD; // Track length in SDD.
+ Float_t drPath; // average position of track in detector. in microns
+ Float_t drTime; // Drift time
+ Float_t nmul; // drift time window multiplication factor.
+ Float_t avDrft; // x position of path length segment in cm.
+ Float_t avAnode; // Anode for path length segment in Anode number (float)
+ Float_t xAnode; // Floating point anode number.
+ Float_t driftPath; // avDrft in microns.
+ Float_t width; // width of signal at anodes.
+ Double_t depEnergy; // Energy deposited in this GEANT step.
+ Double_t xL[3],dxL[3]; // local hit coordinates and diff.
+ Double_t sigA; // sigma of signal at anode.
+ Double_t sigT; // sigma in time/drift direction for track segment
+ Double_t aStep,aConst; // sub-pixel size and offset anode
+ Double_t tStep,tConst; // sub-pixel size and offset time
+ Double_t amplitude; // signal amplitude for track segment in nanoAmpere
+ Double_t chargeloss; // charge loss for track segment.
+ Double_t anodeAmplitude; // signal amplitude in anode direction
+ Double_t aExpo; // exponent of Gaussian anode direction
+ Double_t timeAmplitude; // signal amplitude in time direction
+ Double_t tExpo; // exponent of Gaussian time direction
+ // Double_t tof; // Time of flight in ns of this step.
+
+ for(ii=0; ii<nhits; ii++) {
+ if(!mod->LineSegmentL(ii,xL[0],dxL[0],xL[1],dxL[1],xL[2],dxL[2],
+ depEnergy,itrack)) continue;
+ xL[0] += 0.0001*gRandom->Gaus( 0, jitter ); //
+ depEnergy *= kconv;
+ hitDetector = mod->GetDet();
+ //tof = 1.E+09*(mod->GetHit(ii)->GetTOF()); // tof in ns.
+ //if(tof>sddLength/driftSpeed) continue; // hit happed too late.
+
+ // scale path to simulate a perpendicular track
+ // continue if the particle did not lose energy
+ // passing through detector
+ if (!depEnergy) {
+ if(GetDebug()){
+ Warning("HitsToAnalogDigits",
+ "fTrack = %d hit=%d module=%d This particle has"
+ " passed without losing energy!",
+ itrack,ii,mod->GetIndex());
+ }
+ continue;
+ } // end if !depEnergy
+
+ pathInSDD = TMath::Sqrt(dxL[0]*dxL[0]+dxL[1]*dxL[1]+dxL[2]*dxL[2]);
+
+ if (fFlag && pathInSDD) { depEnergy *= (0.03/pathInSDD); }
+ drPath = 10000.*(dxL[0]+2.*xL[0])*0.5;
+ if(drPath < 0) drPath = -drPath;
+ drPath = sddLength-drPath;
+ if(drPath < 0) {
+ if(GetDebug()){ // this should be fixed at geometry level
+ Warning("HitsToAnalogDigits",
+ "negative drift path drPath=%e sddLength=%e dxL[0]=%e "
+ "xL[0]=%e",
+ drPath,sddLength,dxL[0],xL[0]);
+ }
+ continue;
+ } // end if drPath < 0
+
+ // Compute number of segments to brake step path into
+ drTime = drPath/driftSpeed; // Drift Time
+ sigA = TMath::Sqrt(2.*dfCoeff*drTime+s1*s1);// Sigma along the anodes
+ // calcuate the number of time the path length should be split into.
+ nOfSplits = (Int_t) (1. + 10000.*pathInSDD/sigA);
+ if(fFlag) nOfSplits = 1;
+
+ // loop over path segments, init. some variables.
+ depEnergy /= nOfSplits;
+ nOfSplitsF = (Float_t) nOfSplits;
+ for(kk=0;kk<nOfSplits;kk++) { // loop over path segments
+ kkF = (Float_t) kk + 0.5;
+ avDrft = xL[0]+dxL[0]*kkF/nOfSplitsF;
+ avAnode = xL[2]+dxL[2]*kkF/nOfSplitsF;
+ driftPath = 10000.*avDrft;
+
+ iWing = 2; // Assume wing is 2
+ if(driftPath < 0) { // if wing is not 2 it is 1.
+ iWing = 1;
+ driftPath = -driftPath;
+ } // end if driftPath < 0
+ driftPath = sddLength-driftPath;
+ detector = 2*(hitDetector-1) + iWing;
+ if(driftPath < 0) {
+ if(GetDebug()){ // this should be fixed at geometry level
+ Warning("HitsToAnalogDigits","negative drift path "
+ "driftPath=%e sddLength=%e avDrft=%e dxL[0]=%e "
+ "xL[0]=%e",driftPath,sddLength,avDrft,dxL[0],xL[0]);
+ }
+ continue;
+ } // end if driftPath < 0
+
+ // Drift Time
+ drTime = driftPath/driftSpeed; // drift time for segment.
+ timeSample = (Int_t) (fScaleSize*drTime/timeStep + 1);
+ // compute time Sample including tof information. The tof only
+ // effects the time of the signal is recoreded and not the
+ // the defusion.
+ // timeSample = (Int_t) (fScaleSize*(drTime+tof)/timeStep + 1);
+ if(timeSample > fScaleSize*fMaxNofSamples) {
+ Warning("HitsToAnalogDigits","Wrong Time Sample: %e",
+ timeSample);
+ continue;
+ } // end if timeSample > fScaleSize*fMaxNoofSamples
+
+ // Anode
+ xAnode = 10000.*(avAnode)/anodePitch + nofAnodes/2; // +1?
+ if(xAnode*anodePitch > sddWidth || xAnode*anodePitch < 0.)
+ Warning("HitsToAnalogDigits",
+ "Exceedubg sddWidth=%e Z = %e",
+ sddWidth,xAnode*anodePitch);
+ iAnode = (Int_t) (1.+xAnode); // xAnode?
+ if(iAnode < 1 || iAnode > nofAnodes) {
+ Warning("HitToAnalogDigits","Wrong iAnode: 1<%d>%d",
+ iAnode,nofAnodes);
+ continue;
+ } // end if iAnode < 1 || iAnode > nofAnodes
+
+ // store straight away the particle position in the array
+ // of particles and take idhit=ii only when part is entering (this
+ // requires FillModules() in the macro for analysis) :
- // Sigma along the anodes for track segment.
- sigA = TMath::Sqrt(2.*dfCoeff*drTime+s1*s1);
- sigT = sigA/driftSpeed;
- // Peak amplitude in nanoAmpere
- amplitude = fScaleSize*160.*depEnergy/
- (timeStep*eVpairs*2.*acos(-1.)*sigT*sigA);
- amplitude *= timeStep/25.; // WARNING!!!!! Amplitude scaling to
- // account for clock variations
- // (reference value: 40 MHz)
- chargeloss = 1.-cHloss*driftPath/1000;
- amplitude *= chargeloss;
- width = 2.*nsigma/(nlookups-1);
- // Spread the charge
- // Pixel index
- ndiv = 2;
- nmul = 3.;
- if(drTime > 1200.) {
- ndiv = 4;
- nmul = 1.5;
- } // end if drTime > 1200.
- // Sub-pixel index
- nsplit = 4; // hard-wired //nsplit=4;nsplit = (nsplit+1)/2*2;
- // Sub-pixel size see computation of aExpo and tExpo.
- aStep = anodePitch/(nsplit*fScaleSize*sigA);
- aConst = xAnode*anodePitch/sigA;
- tStep = timeStep/(nsplit*fScaleSize*sigT);
- tConst = drTime/sigT;
- // Define SDD window corresponding to the hit
- anodeWindow = (Int_t)(fScaleSize*nsigma*sigA/anodePitch+1);
- timeWindow = (Int_t) (fScaleSize*nsigma*sigT/timeStep+1.);
- jamin = (iAnode - anodeWindow/ndiv - 1)*fScaleSize*nsplit +1;
- jamax = (iAnode + anodeWindow/ndiv)*fScaleSize*nsplit;
- if(jamin <= 0) jamin = 1;
- if(jamax > fScaleSize*nofAnodes*nsplit)
- jamax = fScaleSize*nofAnodes*nsplit;
- // jtmin and jtmax are Hard-wired
- jtmin = (Int_t)(timeSample-timeWindow*nmul-1)*nsplit+1;
- jtmax = (Int_t)(timeSample+timeWindow*nmul)*nsplit;
- if(jtmin <= 0) jtmin = 1;
- if(jtmax > fScaleSize*fMaxNofSamples*nsplit)
- jtmax = fScaleSize*fMaxNofSamples*nsplit;
- // Spread the charge in the anode-time window
- for(ka=jamin; ka <=jamax; ka++) {
- ia = (ka-1)/(fScaleSize*nsplit) + 1;
- if(ia <= 0) {
- Warning("HitsToAnalogDigits","ia < 1: ");
- continue;
- } // end if
- if(ia > nofAnodes) ia = nofAnodes;
- aExpo = (aStep*(ka-0.5)-aConst);
- if(TMath::Abs(aExpo) > nsigma) anodeAmplitude = 0.;
- else {
- dummy = (Int_t) ((aExpo+nsigma)/width);
- anodeAmplitude = amplitude*fResponse->GausLookUp(dummy);
- } // end if TMath::Abs(aEspo) > nsigma
- // index starts from 0
- index = ((detector+1)%2)*nofAnodes+ia-1;
- if(anodeAmplitude) for(kt=jtmin; kt<=jtmax; kt++) {
- it = (kt-1)/nsplit+1; // it starts from 1
- if(it<=0){
- Warning("HitsToAnalogDigits","it < 1:");
- continue;
- } // end if
- if(it>fScaleSize*fMaxNofSamples)
- it = fScaleSize*fMaxNofSamples;
- tExpo = (tStep*(kt-0.5)-tConst);
- if(TMath::Abs(tExpo) > nsigma) timeAmplitude = 0.;
- else {
- dummy = (Int_t) ((tExpo+nsigma)/width);
- timeAmplitude = anodeAmplitude*
- fResponse->GausLookUp(dummy);
- } // end if TMath::Abs(tExpo) > nsigma
- // build the list of Sdigits for this module
-// arg[0] = index;
-// arg[1] = it;
-// arg[2] = itrack; // track number
-// arg[3] = ii-1; // hit number.
- timeAmplitude *= norm;
- timeAmplitude *= 10;
-// ListOfFiredCells(arg,timeAmplitude,alst,padr);
- Double_t charge = timeAmplitude;
- charge += fHitMap2->GetSignal(index,it-1);
- fHitMap2->SetHit(index, it-1, charge);
- fpList->AddSignal(index,it-1,itrack,ii-1,
- mod->GetIndex(),timeAmplitude);
- fAnodeFire[index] = kTRUE;
- } // end if anodeAmplitude and loop over time in window
- } // loop over anodes in window
- } // end loop over "sub-hits"
- } // end loop over hits
+ // Sigma along the anodes for track segment.
+ sigA = TMath::Sqrt(2.*dfCoeff*drTime+s1*s1);
+ sigT = sigA/driftSpeed;
+ // Peak amplitude in nanoAmpere
+ amplitude = fScaleSize*160.*depEnergy/
+ (timeStep*eVpairs*2.*acos(-1.)*sigT*sigA);
+ amplitude *= timeStep/25.; // WARNING!!!!! Amplitude scaling to
+ // account for clock variations
+ // (reference value: 40 MHz)
+ chargeloss = 1.-cHloss*driftPath/1000;
+ amplitude *= chargeloss;
+ width = 2.*nsigma/(nlookups-1);
+ // Spread the charge
+ // Pixel index
+ ndiv = 2;
+ nmul = 3.;
+ if(drTime > 1200.) {
+ ndiv = 4;
+ nmul = 1.5;
+ } // end if drTime > 1200.
+ // Sub-pixel index
+ nsplit = 4; // hard-wired //nsplit=4;nsplit = (nsplit+1)/2*2;
+ // Sub-pixel size see computation of aExpo and tExpo.
+ aStep = anodePitch/(nsplit*fScaleSize*sigA);
+ aConst = xAnode*anodePitch/sigA;
+ tStep = timeStep/(nsplit*fScaleSize*sigT);
+ tConst = drTime/sigT;
+ // Define SDD window corresponding to the hit
+ anodeWindow = (Int_t)(fScaleSize*nsigma*sigA/anodePitch+1);
+ timeWindow = (Int_t) (fScaleSize*nsigma*sigT/timeStep+1.);
+ jamin = (iAnode - anodeWindow/ndiv - 1)*fScaleSize*nsplit +1;
+ jamax = (iAnode + anodeWindow/ndiv)*fScaleSize*nsplit;
+ if(jamin <= 0) jamin = 1;
+ if(jamax > fScaleSize*nofAnodes*nsplit)
+ jamax = fScaleSize*nofAnodes*nsplit;
+ // jtmin and jtmax are Hard-wired
+ jtmin = (Int_t)(timeSample-timeWindow*nmul-1)*nsplit+1;
+ jtmax = (Int_t)(timeSample+timeWindow*nmul)*nsplit;
+ if(jtmin <= 0) jtmin = 1;
+ if(jtmax > fScaleSize*fMaxNofSamples*nsplit)
+ jtmax = fScaleSize*fMaxNofSamples*nsplit;
+ // Spread the charge in the anode-time window
+ for(ka=jamin; ka <=jamax; ka++) {
+ ia = (ka-1)/(fScaleSize*nsplit) + 1;
+ if(ia <= 0) {
+ Warning("HitsToAnalogDigits","ia < 1: ");
+ continue;
+ } // end if
+ if(ia > nofAnodes) ia = nofAnodes;
+ aExpo = (aStep*(ka-0.5)-aConst);
+ if(TMath::Abs(aExpo) > nsigma) anodeAmplitude = 0.;
+ else {
+ dummy = (Int_t) ((aExpo+nsigma)/width);
+ anodeAmplitude = amplitude*fResponse->GausLookUp(dummy);
+ } // end if TMath::Abs(aEspo) > nsigma
+ // index starts from 0
+ index = ((detector+1)%2)*nofAnodes+ia-1;
+ if(anodeAmplitude) for(kt=jtmin; kt<=jtmax; kt++) {
+ it = (kt-1)/nsplit+1; // it starts from 1
+ if(it<=0){
+ Warning("HitsToAnalogDigits","it < 1:");
+ continue;
+ } // end if
+ if(it>fScaleSize*fMaxNofSamples)
+ it = fScaleSize*fMaxNofSamples;
+ tExpo = (tStep*(kt-0.5)-tConst);
+ if(TMath::Abs(tExpo) > nsigma) timeAmplitude = 0.;
+ else {
+ dummy = (Int_t) ((tExpo+nsigma)/width);
+ timeAmplitude = anodeAmplitude*
+ fResponse->GausLookUp(dummy);
+ } // end if TMath::Abs(tExpo) > nsigma
+ // build the list of Sdigits for this module
+ // arg[0] = index;
+ // arg[1] = it;
+ // arg[2] = itrack; // track number
+ // arg[3] = ii-1; // hit number.
+ timeAmplitude *= norm;
+ timeAmplitude *= 10;
+ // ListOfFiredCells(arg,timeAmplitude,alst,padr);
+ Double_t charge = timeAmplitude;
+ charge += fHitMap2->GetSignal(index,it-1);
+ fHitMap2->SetHit(index, it-1, charge);
+ fpList->AddSignal(index,it-1,itrack,ii-1,
+ mod->GetIndex(),timeAmplitude);
+ fAnodeFire[index] = kTRUE;
+ } // end if anodeAmplitude and loop over time in window
+ } // loop over anodes in window
+ } // end loop over "sub-hits"
+ } // end loop over hits
}
/*
//______________________________________________________________________
void AliITSsimulationSDD::ListOfFiredCells(Int_t *arg,Double_t timeAmplitude,
- TObjArray *alist,TClonesArray *padr){
- // Returns the list of "fired" cells.
-
- Int_t index = arg[0];
- Int_t ik = arg[1];
- Int_t idtrack = arg[2];
- Int_t idhit = arg[3];
- Int_t counter = arg[4];
- Int_t countadr = arg[5];
- Double_t charge = timeAmplitude;
- charge += fHitMap2->GetSignal(index,ik-1);
- fHitMap2->SetHit(index, ik-1, charge);
-
- Int_t digits[3];
- Int_t it = (Int_t)((ik-1)/fScaleSize);
- digits[0] = index;
- digits[1] = it;
- digits[2] = (Int_t)timeAmplitude;
- Float_t phys;
- if (idtrack >= 0) phys = (Float_t)timeAmplitude;
- else phys = 0;
-
- Double_t cellcharge = 0.;
- AliITSTransientDigit* pdigit;
- // build the list of fired cells and update the info
- if (!fHitMap1->TestHit(index, it)) {
- new((*padr)[countadr++]) TVector(3);
- TVector &trinfo=*((TVector*) (*padr)[countadr-1]);
- trinfo(0) = (Float_t)idtrack;
- trinfo(1) = (Float_t)idhit;
- trinfo(2) = (Float_t)timeAmplitude;
-
- alist->AddAtAndExpand(new AliITSTransientDigit(phys,digits),counter);
- fHitMap1->SetHit(index, it, counter);
- counter++;
- pdigit=(AliITSTransientDigit*)alist->At(alist->GetLast());
- // list of tracks
- TObjArray *trlist=(TObjArray*)pdigit->TrackList();
- trlist->Add(&trinfo);
- } else {
- pdigit = (AliITSTransientDigit*) fHitMap1->GetHit(index, it);
- for(Int_t kk=0;kk<fScaleSize;kk++) {
- cellcharge += fHitMap2->GetSignal(index,fScaleSize*it+kk);
- } // end for kk
- // update charge
- (*pdigit).fSignal = (Int_t)cellcharge;
- (*pdigit).fPhysics += phys;
- // update list of tracks
- TObjArray* trlist = (TObjArray*)pdigit->TrackList();
- Int_t lastentry = trlist->GetLast();
- TVector *ptrkp = (TVector*)trlist->At(lastentry);
- TVector &trinfo = *ptrkp;
- Int_t lasttrack = Int_t(trinfo(0));
- Float_t lastcharge=(trinfo(2));
- if (lasttrack==idtrack ) {
- lastcharge += (Float_t)timeAmplitude;
- trlist->RemoveAt(lastentry);
- trinfo(0) = lasttrack;
- trinfo(1) = idhit;
- trinfo(2) = lastcharge;
- trlist->AddAt(&trinfo,lastentry);
- } else {
- new((*padr)[countadr++]) TVector(3);
- TVector &trinfo=*((TVector*) (*padr)[countadr-1]);
- trinfo(0) = (Float_t)idtrack;
- trinfo(1) = (Float_t)idhit;
- trinfo(2) = (Float_t)timeAmplitude;
- trlist->Add(&trinfo);
- } // end if lasttrack==idtrack
+ TObjArray *alist,TClonesArray *padr){
+ // Returns the list of "fired" cells.
+
+ Int_t index = arg[0];
+ Int_t ik = arg[1];
+ Int_t idtrack = arg[2];
+ Int_t idhit = arg[3];
+ Int_t counter = arg[4];
+ Int_t countadr = arg[5];
+ Double_t charge = timeAmplitude;
+ charge += fHitMap2->GetSignal(index,ik-1);
+ fHitMap2->SetHit(index, ik-1, charge);
+
+ Int_t digits[3];
+ Int_t it = (Int_t)((ik-1)/fScaleSize);
+ digits[0] = index;
+ digits[1] = it;
+ digits[2] = (Int_t)timeAmplitude;
+ Float_t phys;
+ if (idtrack >= 0) phys = (Float_t)timeAmplitude;
+ else phys = 0;
+
+ Double_t cellcharge = 0.;
+ AliITSTransientDigit* pdigit;
+ // build the list of fired cells and update the info
+ if (!fHitMap1->TestHit(index, it)) {
+ new((*padr)[countadr++]) TVector(3);
+ TVector &trinfo=*((TVector*) (*padr)[countadr-1]);
+ trinfo(0) = (Float_t)idtrack;
+ trinfo(1) = (Float_t)idhit;
+ trinfo(2) = (Float_t)timeAmplitude;
+
+ alist->AddAtAndExpand(new AliITSTransientDigit(phys,digits),counter);
+ fHitMap1->SetHit(index, it, counter);
+ counter++;
+ pdigit=(AliITSTransientDigit*)alist->At(alist->GetLast());
+ // list of tracks
+ TObjArray *trlist=(TObjArray*)pdigit->TrackList();
+ trlist->Add(&trinfo);
+ } else {
+ pdigit = (AliITSTransientDigit*) fHitMap1->GetHit(index, it);
+ for(Int_t kk=0;kk<fScaleSize;kk++) {
+ cellcharge += fHitMap2->GetSignal(index,fScaleSize*it+kk);
+ } // end for kk
+ // update charge
+ (*pdigit).fSignal = (Int_t)cellcharge;
+ (*pdigit).fPhysics += phys;
+ // update list of tracks
+ TObjArray* trlist = (TObjArray*)pdigit->TrackList();
+ Int_t lastentry = trlist->GetLast();
+ TVector *ptrkp = (TVector*)trlist->At(lastentry);
+ TVector &trinfo = *ptrkp;
+ Int_t lasttrack = Int_t(trinfo(0));
+ Float_t lastcharge=(trinfo(2));
+ if (lasttrack==idtrack ) {
+ lastcharge += (Float_t)timeAmplitude;
+ trlist->RemoveAt(lastentry);
+ trinfo(0) = lasttrack;
+ trinfo(1) = idhit;
+ trinfo(2) = lastcharge;
+ trlist->AddAt(&trinfo,lastentry);
+ } else {
+ new((*padr)[countadr++]) TVector(3);
+ TVector &trinfo=*((TVector*) (*padr)[countadr-1]);
+ trinfo(0) = (Float_t)idtrack;
+ trinfo(1) = (Float_t)idhit;
+ trinfo(2) = (Float_t)timeAmplitude;
+ trlist->Add(&trinfo);
+ } // end if lasttrack==idtrack
#ifdef print
- // check the track list - debugging
- Int_t trk[20], htrk[20];
- Float_t chtrk[20];
- Int_t nptracks = trlist->GetEntriesFast();
- if (nptracks > 2) {
- Int_t tr;
- for (tr=0;tr<nptracks;tr++) {
- TVector *pptrkp = (TVector*)trlist->At(tr);
- TVector &pptrk = *pptrkp;
- trk[tr] = Int_t(pptrk(0));
- htrk[tr] = Int_t(pptrk(1));
- chtrk[tr] = (pptrk(2));
- cout << "nptracks "<<nptracks << endl;
- } // end for tr
- } // end if nptracks
+ // check the track list - debugging
+ Int_t trk[20], htrk[20];
+ Float_t chtrk[20];
+ Int_t nptracks = trlist->GetEntriesFast();
+ if (nptracks > 2) {
+ Int_t tr;
+ for (tr=0;tr<nptracks;tr++) {
+ TVector *pptrkp = (TVector*)trlist->At(tr);
+ TVector &pptrk = *pptrkp;
+ trk[tr] = Int_t(pptrk(0));
+ htrk[tr] = Int_t(pptrk(1));
+ chtrk[tr] = (pptrk(2));
+ cout << "nptracks "<<nptracks << endl;
+ } // end for tr
+ } // end if nptracks
#endif
- } // end if pdigit
+ } // end if pdigit
- // update counter and countadr for next call.
- arg[4] = counter;
- arg[5] = countadr;
+ // update counter and countadr for next call.
+ arg[4] = counter;
+ arg[5] = countadr;
}
*/
//____________________________________________
void AliITSsimulationSDD::AddDigit( Int_t i, Int_t j, Int_t signal ) {
- // Adds a Digit.
- Int_t size = AliITSdigitSPD::GetNTracks();
- Int_t digits[3];
- Int_t * tracks = new Int_t[size];
- Int_t * hits = new Int_t[size];
- Float_t phys;
- Float_t * charges = new Float_t[size];
-
- digits[0] = i;
- digits[1] = j;
- digits[2] = signal;
-
- AliITSpListItem *pItem = fpList->GetpListItem( i, j );
- if( pItem == 0 ) {
- phys = 0.0;
- for( Int_t l=0; l<size; l++ ) {
- tracks[l] = 0;
- hits[l] = 0;
- charges[l] = 0.0;
- }
- } else {
- Int_t idtrack = pItem->GetTrack( 0 );
- if( idtrack >= 0 ) phys = pItem->GetSignal();
- else phys = 0.0;
-
- for( Int_t l=0; l<size; l++ ) if(l<pItem->GetMaxKept()) {
- tracks[l] = pItem->GetTrack( l );
- hits[l] = pItem->GetHit( l );
- charges[l] = pItem->GetSignal( l );
- }else{
- tracks[l] = -3;
- hits[l] = -1;
- charges[l] = 0.0;
- }// end for if
+ // Adds a Digit.
+ Int_t size = AliITSdigitSPD::GetNTracks();
+ Int_t digits[3];
+ Int_t * tracks = new Int_t[size];
+ Int_t * hits = new Int_t[size];
+ Float_t phys;
+ Float_t * charges = new Float_t[size];
+
+ digits[0] = i;
+ digits[1] = j;
+ digits[2] = signal;
+
+ AliITSpListItem *pItem = fpList->GetpListItem( i, j );
+ if( pItem == 0 ) {
+ phys = 0.0;
+ for( Int_t l=0; l<size; l++ ) {
+ tracks[l] = 0;
+ hits[l] = 0;
+ charges[l] = 0.0;
}
-
- fITS->AddSimDigit( 1, phys, digits, tracks, hits, charges );
- delete [] tracks;
- delete [] hits;
- delete [] charges;
+ } else {
+ Int_t idtrack = pItem->GetTrack( 0 );
+ if( idtrack >= 0 ) phys = pItem->GetSignal();
+ else phys = 0.0;
+
+ for( Int_t l=0; l<size; l++ ) if(l<pItem->GetMaxKept()) {
+ tracks[l] = pItem->GetTrack( l );
+ hits[l] = pItem->GetHit( l );
+ charges[l] = pItem->GetSignal( l );
+ }else{
+ tracks[l] = -3;
+ hits[l] = -1;
+ charges[l] = 0.0;
+ }// end for if
+ }
+
+ fITS->AddSimDigit( 1, phys, digits, tracks, hits, charges );
+ delete [] tracks;
+ delete [] hits;
+ delete [] charges;
}
//______________________________________________________________________
void AliITSsimulationSDD::ChargeToSignal(Bool_t bAddNoise) {
- // add baseline, noise, electronics and ADC saturation effects
-
- char opt1[20], opt2[20];
- fResponse->ParamOptions(opt1,opt2);
- char *read = strstr(opt1,"file");
- Float_t baseline, noise;
-
- if (read) {
- static Bool_t readfile=kTRUE;
- //read baseline and noise from file
- if (readfile) ReadBaseline();
- readfile=kFALSE;
- } else fResponse->GetNoiseParam(noise,baseline);
-
- Float_t contrib=0;
- Int_t i,k,kk;
- Float_t maxadc = fResponse->MaxAdc();
- if(!fDoFFT) {
- for (i=0;i<fNofMaps;i++) {
- if( !fAnodeFire[i] ) continue;
- if (read && i<fNofMaps) GetAnodeBaseline(i,baseline,noise);
- for(k=0; k<fScaleSize*fMaxNofSamples; k++) {
- fInZR[k] = fHitMap2->GetSignal(i,k);
- if( bAddNoise ) {
- contrib = (baseline + noise*gRandom->Gaus());
- fInZR[k] += contrib;
- }
- } // end for k
- for(k=0; k<fMaxNofSamples; k++) {
- Double_t newcont = 0.;
- Double_t maxcont = 0.;
- for(kk=0;kk<fScaleSize;kk++) {
- newcont = fInZR[fScaleSize*k+kk];
- if(newcont > maxcont) maxcont = newcont;
- } // end for kk
- newcont = maxcont;
- if (newcont >= maxadc) newcont = maxadc -1;
- if(newcont >= baseline){
- Warning("","newcont=%d>=baseline=%d",newcont,baseline);
- } // end if
- // back to analog: ?
- fHitMap2->SetHit(i,k,newcont);
- } // end for k
- } // end for i loop over anodes
- return;
- } // end if DoFFT
-
+ // add baseline, noise, electronics and ADC saturation effects
+
+ char opt1[20], opt2[20];
+ fResponse->ParamOptions(opt1,opt2);
+ char *read = strstr(opt1,"file");
+ Float_t baseline, noise;
+
+ if (read) {
+ static Bool_t readfile=kTRUE;
+ //read baseline and noise from file
+ if (readfile) ReadBaseline();
+ readfile=kFALSE;
+ } else fResponse->GetNoiseParam(noise,baseline);
+
+ Float_t contrib=0;
+ Int_t i,k,kk;
+ Float_t maxadc = fResponse->MaxAdc();
+ if(!fDoFFT) {
for (i=0;i<fNofMaps;i++) {
- if( !fAnodeFire[i] ) continue;
- if (read && i<fNofMaps) GetAnodeBaseline(i,baseline,noise);
- for(k=0; k<fScaleSize*fMaxNofSamples; k++) {
- fInZR[k] = fHitMap2->GetSignal(i,k);
- if( bAddNoise ) {
- contrib = (baseline + noise*gRandom->Gaus());
- fInZR[k] += contrib;
- }
- fInZI[k] = 0.;
- } // end for k
- FastFourierTransform(fElectronics,&fInZR[0],&fInZI[0],1);
- for(k=0; k<fScaleSize*fMaxNofSamples; k++) {
- Double_t rw = fElectronics->GetTraFunReal(k);
- Double_t iw = fElectronics->GetTraFunImag(k);
- fOutZR[k] = fInZR[k]*rw - fInZI[k]*iw;
- fOutZI[k] = fInZR[k]*iw + fInZI[k]*rw;
- } // end for k
- FastFourierTransform(fElectronics,&fOutZR[0],&fOutZI[0],-1);
- for(k=0; k<fMaxNofSamples; k++) {
- Double_t newcont1 = 0.;
- Double_t maxcont1 = 0.;
- for(kk=0;kk<fScaleSize;kk++) {
- newcont1 = fOutZR[fScaleSize*k+kk];
- if(newcont1 > maxcont1) maxcont1 = newcont1;
- } // end for kk
- newcont1 = maxcont1;
- if (newcont1 >= maxadc) newcont1 = maxadc -1;
- fHitMap2->SetHit(i,k,newcont1);
- } // end for k
+ if( !fAnodeFire[i] ) continue;
+ if (read && i<fNofMaps) GetAnodeBaseline(i,baseline,noise);
+ for(k=0; k<fScaleSize*fMaxNofSamples; k++) {
+ fInZR[k] = fHitMap2->GetSignal(i,k);
+ if( bAddNoise ) {
+ contrib = (baseline + noise*gRandom->Gaus());
+ fInZR[k] += contrib;
+ }
+ } // end for k
+ for(k=0; k<fMaxNofSamples; k++) {
+ Double_t newcont = 0.;
+ Double_t maxcont = 0.;
+ for(kk=0;kk<fScaleSize;kk++) {
+ newcont = fInZR[fScaleSize*k+kk];
+ if(newcont > maxcont) maxcont = newcont;
+ } // end for kk
+ newcont = maxcont;
+ if (newcont >= maxadc) newcont = maxadc -1;
+ if(newcont >= baseline){
+ Warning("","newcont=%d>=baseline=%d",newcont,baseline);
+ } // end if
+ // back to analog: ?
+ fHitMap2->SetHit(i,k,newcont);
+ } // end for k
} // end for i loop over anodes
+ return;
+ } // end if DoFFT
+
+ for (i=0;i<fNofMaps;i++) {
+ if( !fAnodeFire[i] ) continue;
+ if (read && i<fNofMaps) GetAnodeBaseline(i,baseline,noise);
+ for(k=0; k<fScaleSize*fMaxNofSamples; k++) {
+ fInZR[k] = fHitMap2->GetSignal(i,k);
+ if( bAddNoise ) {
+ contrib = (baseline + noise*gRandom->Gaus());
+ fInZR[k] += contrib;
+ }
+ fInZI[k] = 0.;
+ } // end for k
+ FastFourierTransform(fElectronics,&fInZR[0],&fInZI[0],1);
+ for(k=0; k<fScaleSize*fMaxNofSamples; k++) {
+ Double_t rw = fElectronics->GetTraFunReal(k);
+ Double_t iw = fElectronics->GetTraFunImag(k);
+ fOutZR[k] = fInZR[k]*rw - fInZI[k]*iw;
+ fOutZI[k] = fInZR[k]*iw + fInZI[k]*rw;
+ } // end for k
+ FastFourierTransform(fElectronics,&fOutZR[0],&fOutZI[0],-1);
+ for(k=0; k<fMaxNofSamples; k++) {
+ Double_t newcont1 = 0.;
+ Double_t maxcont1 = 0.;
+ for(kk=0;kk<fScaleSize;kk++) {
+ newcont1 = fOutZR[fScaleSize*k+kk];
+ if(newcont1 > maxcont1) maxcont1 = newcont1;
+ } // end for kk
+ newcont1 = maxcont1;
+ if (newcont1 >= maxadc) newcont1 = maxadc -1;
+ fHitMap2->SetHit(i,k,newcont1);
+ } // end for k
+ } // end for i loop over anodes
return;
}
//____________________________________________________________________
void AliITSsimulationSDD::ApplyDeadChannels() {
- // Set dead channel signal to zero
- AliITSresponseSDD * response = (AliITSresponseSDD *)fResponse;
+ // Set dead channel signal to zero
+ AliITSresponseSDD * response = (AliITSresponseSDD *)fResponse;
- // nothing to do
- if( response->GetDeadModules() == 0 &&
- response->GetDeadChips() == 0 &&
- response->GetDeadChannels() == 0 )
- return;
+ // nothing to do
+ if( response->GetDeadModules() == 0 &&
+ response->GetDeadChips() == 0 &&
+ response->GetDeadChannels() == 0 )
+ return;
- static AliITS *iTS = (AliITS*)gAlice->GetModule( "ITS" );
-
- Int_t fMaxNofSamples = fSegmentation->Npx();
- AliITSgeom *geom = iTS->GetITSgeom();
- Int_t firstSDDMod = geom->GetStartDet( 1 );
- // loop over wings
- for( Int_t j=0; j<2; j++ ) {
- Int_t mod = (fModule-firstSDDMod)*2 + j;
- for( Int_t u=0; u<response->Chips(); u++ )
- for( Int_t v=0; v<response->Channels(); v++ ) {
- Float_t Gain = response->Gain( mod, u, v );
- for( Int_t k=0; k<fMaxNofSamples; k++ ) {
- Int_t i = j*response->Chips()*response->Channels() +
- u*response->Channels() +
- v;
- Double_t signal = Gain * fHitMap2->GetSignal( i, k );
- fHitMap2->SetHit( i, k, signal ); ///
- }
- }
- }
+ static AliITS *iTS = (AliITS*)gAlice->GetModule( "ITS" );
+
+ Int_t fMaxNofSamples = fSegmentation->Npx();
+ AliITSgeom *geom = iTS->GetITSgeom();
+ Int_t firstSDDMod = geom->GetStartDet( 1 );
+ // loop over wings
+ for( Int_t j=0; j<2; j++ ) {
+ Int_t mod = (fModule-firstSDDMod)*2 + j;
+ for( Int_t u=0; u<response->Chips(); u++ )
+ for( Int_t v=0; v<response->Channels(); v++ ) {
+ Float_t Gain = response->Gain( mod, u, v );
+ for( Int_t k=0; k<fMaxNofSamples; k++ ) {
+ Int_t i = j*response->Chips()*response->Channels() +
+ u*response->Channels() +
+ v;
+ Double_t signal = Gain * fHitMap2->GetSignal( i, k );
+ fHitMap2->SetHit( i, k, signal ); ///
+ }
+ }
+ }
}
//______________________________________________________________________
void AliITSsimulationSDD::ApplyCrosstalk() {
- // function add the crosstalk effect to signal
- // temporal function, should be checked...!!!
+ // function add the crosstalk effect to signal
+ // temporal function, should be checked...!!!
- Int_t fNofMaps = fSegmentation->Npz();
- Int_t fMaxNofSamples = fSegmentation->Npx();
-
- // create and inizialice crosstalk map
- Float_t* ctk = new Float_t[fNofMaps*fMaxNofSamples+1];
- if( ctk == NULL ) {
- Error( "ApplyCrosstalk", "no memory for temporal map: exit \n" );
- return;
- }
- memset( ctk, 0, sizeof(Float_t)*(fNofMaps*fMaxNofSamples+1) );
+ Int_t fNofMaps = fSegmentation->Npz();
+ Int_t fMaxNofSamples = fSegmentation->Npx();
+
+ // create and inizialice crosstalk map
+ Float_t* ctk = new Float_t[fNofMaps*fMaxNofSamples+1];
+ if( ctk == NULL ) {
+ Error( "ApplyCrosstalk", "no memory for temporal map: exit \n" );
+ return;
+ }
+ memset( ctk, 0, sizeof(Float_t)*(fNofMaps*fMaxNofSamples+1) );
- Float_t noise, baseline;
- fResponse->GetNoiseParam( noise, baseline );
+ Float_t noise, baseline;
+ fResponse->GetNoiseParam( noise, baseline );
- for( Int_t z=0; z<fNofMaps; z++ ) {
- Bool_t on = kFALSE;
- Int_t tstart = 0;
- Int_t tstop = 0;
- Int_t nTsteps = 0;
+ for( Int_t z=0; z<fNofMaps; z++ ) {
+ Bool_t on = kFALSE;
+ Int_t tstart = 0;
+ Int_t tstop = 0;
+ Int_t nTsteps = 0;
- for( Int_t l=0; l<fMaxNofSamples; l++ ) {
- Float_t fadc = (Float_t)fHitMap2->GetSignal( z, l );
- if( fadc > baseline ) {
- if( on == kFALSE && l<fMaxNofSamples-4 ) {
- Float_t fadc1 = (Float_t)fHitMap2->GetSignal( z, l+1 );
- if( fadc1 < fadc ) continue;
- on = kTRUE;
- nTsteps = 0;
- tstart = l;
- }
- nTsteps++;
- }
- else { // end fadc > baseline
- if( on == kTRUE ) {
- if( nTsteps > 2 ) {
- tstop = l;
- // make smooth derivative
- Float_t* dev = new Float_t[fMaxNofSamples+1];
- memset( dev, 0, sizeof(Float_t)*(fMaxNofSamples+1) );
- if( ctk == NULL ) {
- Error( "ApplyCrosstalk",
- "no memory for temporal array: exit \n" );
- return;
- }
- for( Int_t i=tstart; i<tstop; i++ ) {
- if( i > 2 && i < fMaxNofSamples-2 )
- dev[i] = -0.2*fHitMap2->GetSignal( z,i-2 )
- -0.1*fHitMap2->GetSignal( z,i-1 )
- +0.1*fHitMap2->GetSignal( z,i+1 )
- +0.2*fHitMap2->GetSignal( z,i+2 );
- }
+ for( Int_t l=0; l<fMaxNofSamples; l++ ) {
+ Float_t fadc = (Float_t)fHitMap2->GetSignal( z, l );
+ if( fadc > baseline ) {
+ if( on == kFALSE && l<fMaxNofSamples-4 ) {
+ Float_t fadc1 = (Float_t)fHitMap2->GetSignal( z, l+1 );
+ if( fadc1 < fadc ) continue;
+ on = kTRUE;
+ nTsteps = 0;
+ tstart = l;
+ }
+ nTsteps++;
+ }
+ else { // end fadc > baseline
+ if( on == kTRUE ) {
+ if( nTsteps > 2 ) {
+ tstop = l;
+ // make smooth derivative
+ Float_t* dev = new Float_t[fMaxNofSamples+1];
+ memset( dev, 0, sizeof(Float_t)*(fMaxNofSamples+1) );
+ if( ctk == NULL ) {
+ Error( "ApplyCrosstalk",
+ "no memory for temporal array: exit \n" );
+ return;
+ }
+ for( Int_t i=tstart; i<tstop; i++ ) {
+ if( i > 2 && i < fMaxNofSamples-2 )
+ dev[i] = -0.2*fHitMap2->GetSignal( z,i-2 )
+ -0.1*fHitMap2->GetSignal( z,i-1 )
+ +0.1*fHitMap2->GetSignal( z,i+1 )
+ +0.2*fHitMap2->GetSignal( z,i+2 );
+ }
- // add crosstalk contribution to neibourg anodes
- for( Int_t i=tstart; i<tstop; i++ ) {
- Int_t anode = z - 1;
- Int_t i1 = (Int_t)((i-tstart)*.61+tstart+0.5); //
- Float_t ctktmp = -dev[i1] * 0.25;
- if( anode > 0 ) {
- ctk[anode*fMaxNofSamples+i] += ctktmp;
- }
- anode = z + 1;
- if( anode < fNofMaps ) {
- ctk[anode*fMaxNofSamples+i] += ctktmp;
- }
- }
- delete [] dev;
+ // add crosstalk contribution to neibourg anodes
+ for( Int_t i=tstart; i<tstop; i++ ) {
+ Int_t anode = z - 1;
+ Int_t i1 = (Int_t)((i-tstart)*.61+tstart+0.5); //
+ Float_t ctktmp = -dev[i1] * 0.25;
+ if( anode > 0 ) {
+ ctk[anode*fMaxNofSamples+i] += ctktmp;
+ }
+ anode = z + 1;
+ if( anode < fNofMaps ) {
+ ctk[anode*fMaxNofSamples+i] += ctktmp;
+ }
+ }
+ delete [] dev;
- } // if( nTsteps > 2 )
- on = kFALSE;
- } // if( on == kTRUE )
- } // else
- }
+ } // if( nTsteps > 2 )
+ on = kFALSE;
+ } // if( on == kTRUE )
+ } // else
}
+ }
- for( Int_t a=0; a<fNofMaps; a++ )
- for( Int_t t=0; t<fMaxNofSamples; t++ ) {
- Float_t signal = fHitMap2->GetSignal( a, t ) + ctk[a*fMaxNofSamples+t];
- fHitMap2->SetHit( a, t, signal );
- }
+ for( Int_t a=0; a<fNofMaps; a++ )
+ for( Int_t t=0; t<fMaxNofSamples; t++ ) {
+ Float_t signal = fHitMap2->GetSignal( a, t ) + ctk[a*fMaxNofSamples+t];
+ fHitMap2->SetHit( a, t, signal );
+ }
- delete [] ctk;
+ delete [] ctk;
}
//______________________________________________________________________
void AliITSsimulationSDD::GetAnodeBaseline(Int_t i,Float_t &baseline,
Float_t &noise){
- // Returns the Baseline for a particular anode.
- baseline = fBaseline[i];
- noise = fNoise[i];
+ // Returns the Baseline for a particular anode.
+ baseline = fBaseline[i];
+ noise = fNoise[i];
}
//______________________________________________________________________
void AliITSsimulationSDD::CompressionParam(Int_t i,Int_t &db,Int_t &tl,
Int_t &th){
- // Returns the compression alogirthm parameters
- Int_t size = fD.GetSize();
- if (size > 2 ) {
- db=fD[i]; tl=fT1[i]; th=fT2[i];
+ // Returns the compression alogirthm parameters
+ Int_t size = fD.GetSize();
+ if (size > 2 ) {
+ db=fD[i]; tl=fT1[i]; th=fT2[i];
+ } else {
+ if (size <= 2 && i>=fNofMaps/2) {
+ db=fD[1]; tl=fT1[1]; th=fT2[1];
} else {
- if (size <= 2 && i>=fNofMaps/2) {
- db=fD[1]; tl=fT1[1]; th=fT2[1];
- } else {
- db=fD[0]; tl=fT1[0]; th=fT2[0];
- } // end if size <=2 && i>=fNofMaps/2
- } // end if size >2
+ db=fD[0]; tl=fT1[0]; th=fT2[0];
+ } // end if size <=2 && i>=fNofMaps/2
+ } // end if size >2
}
//______________________________________________________________________
void AliITSsimulationSDD::CompressionParam(Int_t i,Int_t &db,Int_t &tl){
- // returns the compression alogirthm parameters
- Int_t size = fD.GetSize();
-
- if (size > 2 ) {
- db=fD[i]; tl=fT1[i];
+ // returns the compression alogirthm parameters
+ Int_t size = fD.GetSize();
+
+ if (size > 2 ) {
+ db=fD[i]; tl=fT1[i];
+ } else {
+ if (size <= 2 && i>=fNofMaps/2) {
+ db=fD[1]; tl=fT1[1];
} else {
- if (size <= 2 && i>=fNofMaps/2) {
- db=fD[1]; tl=fT1[1];
- } else {
- db=fD[0]; tl=fT1[0];
- } // end if size <=2 && i>=fNofMaps/2
- // Warning("CompressionParam","\n Size= %d . Values i=%d ; db= %d ; tl= %d",size,i,db,tl);
- } // end if size > 2
+ db=fD[0]; tl=fT1[0];
+ } // end if size <=2 && i>=fNofMaps/2
+ // Warning("CompressionParam","\n Size= %d . Values i=%d ; db= %d ; tl= %d",size,i,db,tl);
+ } // end if size > 2
}
//______________________________________________________________________
void AliITSsimulationSDD::SetCompressParam(){
- // Sets the compression alogirthm parameters
- Int_t cp[8],i;
-
- fResponse->GiveCompressParam(cp);
- for (i=0; i<2; i++) {
- fD[i] = cp[i];
- fT1[i] = cp[i+2];
- fT2[i] = cp[i+4];
- fTol[i] = cp[i+6];
- } // end for i
+ // Sets the compression alogirthm parameters
+ Int_t cp[8],i;
+
+ fResponse->GiveCompressParam(cp);
+ for (i=0; i<2; i++) {
+ fD[i] = cp[i];
+ fT1[i] = cp[i+2];
+ fT2[i] = cp[i+4];
+ fTol[i] = cp[i+6];
+ } // end for i
}
//______________________________________________________________________
void AliITSsimulationSDD::ReadBaseline(){
- // read baseline and noise from file - either a .root file and in this
- // case data should be organised in a tree with one entry for each
- // module => reading should be done accordingly
- // or a classic file and do smth. like this:
- // Read baselines and noise for SDD
-
- Int_t na,pos;
- Float_t bl,n;
- char input[100], base[100], param[100];
- char *filtmp;
-
- fResponse->Filenames(input,base,param);
- fFileName=base;
-//
- filtmp = gSystem->ExpandPathName(fFileName.Data());
- FILE *bline = fopen(filtmp,"r");
- na = 0;
-
- if(bline) {
- while(fscanf(bline,"%d %f %f",&pos, &bl, &n) != EOF) {
- if (pos != na+1) {
- Error("ReadBaseline","Anode number not in increasing order!",
- filtmp);
- exit(1);
- } // end if pos != na+1
- fBaseline[na]=bl;
- fNoise[na]=n;
- na++;
- } // end while
- } else {
- Error("ReadBaseline"," THE BASELINE FILE %s DOES NOT EXIST !",filtmp);
- exit(1);
- } // end if(bline)
-
- fclose(bline);
- delete [] filtmp;
+ // read baseline and noise from file - either a .root file and in this
+ // case data should be organised in a tree with one entry for each
+ // module => reading should be done accordingly
+ // or a classic file and do smth. like this:
+ // Read baselines and noise for SDD
+
+ Int_t na,pos;
+ Float_t bl,n;
+ char input[100], base[100], param[100];
+ char *filtmp;
+
+ fResponse->Filenames(input,base,param);
+ fFileName=base;
+ //
+ filtmp = gSystem->ExpandPathName(fFileName.Data());
+ FILE *bline = fopen(filtmp,"r");
+ na = 0;
+
+ if(bline) {
+ while(fscanf(bline,"%d %f %f",&pos, &bl, &n) != EOF) {
+ if (pos != na+1) {
+ Error("ReadBaseline","Anode number not in increasing order!",
+ filtmp);
+ exit(1);
+ } // end if pos != na+1
+ fBaseline[na]=bl;
+ fNoise[na]=n;
+ na++;
+ } // end while
+ } else {
+ Error("ReadBaseline"," THE BASELINE FILE %s DOES NOT EXIST !",filtmp);
+ exit(1);
+ } // end if(bline)
+
+ fclose(bline);
+ delete [] filtmp;
}
//______________________________________________________________________
Int_t AliITSsimulationSDD::Convert10to8(Int_t signal) const {
- // To the 10 to 8 bit lossive compression.
- // code from Davide C. and Albert W.
-
- if (signal < 128) return signal;
- if (signal < 256) return (128+((signal-128)>>1));
- if (signal < 512) return (192+((signal-256)>>3));
- if (signal < 1024) return (224+((signal-512)>>4));
- return 0;
+ // To the 10 to 8 bit lossive compression.
+ // code from Davide C. and Albert W.
+
+ if (signal < 128) return signal;
+ if (signal < 256) return (128+((signal-128)>>1));
+ if (signal < 512) return (192+((signal-256)>>3));
+ if (signal < 1024) return (224+((signal-512)>>4));
+ return 0;
}
/*
//______________________________________________________________________
AliITSMap* AliITSsimulationSDD::HitMap(Int_t i){
- //Return the correct map.
+ //Return the correct map.
- return ((i==0)? fHitMap1 : fHitMap2);
-}*/
+ return ((i==0)? fHitMap1 : fHitMap2);
+}
+*/
//______________________________________________________________________
void AliITSsimulationSDD::ZeroSuppression(const char *option) {
- // perform the zero suppresion
-
- if (strstr(option,"2D")) {
- //Init2D(); // activate if param change module by module
- Compress2D();
- } else if (strstr(option,"1D")) {
- //Init1D(); // activate if param change module by module
- Compress1D();
- } else StoreAllDigits();
+ // perform the zero suppresion
+
+ if (strstr(option,"2D")) {
+ //Init2D(); // activate if param change module by module
+ Compress2D();
+ } else if (strstr(option,"1D")) {
+ //Init1D(); // activate if param change module by module
+ Compress1D();
+ } else StoreAllDigits();
}
//______________________________________________________________________
void AliITSsimulationSDD::Init2D(){
- // read in and prepare arrays: fD, fT1, fT2
- // savemu[nanodes], savesigma[nanodes]
- // read baseline and noise from file - either a .root file and in this
- // case data should be organised in a tree with one entry for each
- // module => reading should be done accordingly
- // or a classic file and do smth. like this ( code from Davide C. and
- // Albert W.) :
- // Read 2D zero-suppression parameters for SDD
-
- if (!strstr(fParam.Data(),"file")) return;
-
- Int_t na,pos,tempTh;
- Float_t mu,sigma;
- Float_t *savemu = new Float_t [fNofMaps];
- Float_t *savesigma = new Float_t [fNofMaps];
- char input[100],basel[100],par[100];
- char *filtmp;
- Float_t tmp1,tmp2;
- fResponse->Thresholds(tmp1,tmp2);
- Int_t minval = static_cast<Int_t>(tmp1);
-
- fResponse->Filenames(input,basel,par);
- fFileName = par;
-//
- filtmp = gSystem->ExpandPathName(fFileName.Data());
- FILE *param = fopen(filtmp,"r");
- na = 0;
-
- if(param) {
- while(fscanf(param,"%d %f %f",&pos, &mu, &sigma) != EOF) {
- if (pos != na+1) {
- Error("Init2D","Anode number not in increasing order!",filtmp);
- exit(1);
- } // end if pos != na+1
- savemu[na] = mu;
- savesigma[na] = sigma;
- if ((2.*sigma) < mu) {
- fD[na] = (Int_t)floor(mu - 2.0*sigma + 0.5);
- mu = 2.0 * sigma;
- } else fD[na] = 0;
- tempTh = (Int_t)floor(mu+2.25*sigma+0.5) - minval;
- if (tempTh < 0) tempTh=0;
- fT1[na] = tempTh;
- tempTh = (Int_t)floor(mu+3.0*sigma+0.5) - minval;
- if (tempTh < 0) tempTh=0;
- fT2[na] = tempTh;
- na++;
- } // end while
- } else {
- Error("Init2D","THE FILE %s DOES NOT EXIST !",filtmp);
- exit(1);
- } // end if(param)
-
- fclose(param);
- delete [] filtmp;
- delete [] savemu;
- delete [] savesigma;
+ // read in and prepare arrays: fD, fT1, fT2
+ // savemu[nanodes], savesigma[nanodes]
+ // read baseline and noise from file - either a .root file and in this
+ // case data should be organised in a tree with one entry for each
+ // module => reading should be done accordingly
+ // or a classic file and do smth. like this ( code from Davide C. and
+ // Albert W.) :
+ // Read 2D zero-suppression parameters for SDD
+
+ if (!strstr(fParam.Data(),"file")) return;
+
+ Int_t na,pos,tempTh;
+ Float_t mu,sigma;
+ Float_t *savemu = new Float_t [fNofMaps];
+ Float_t *savesigma = new Float_t [fNofMaps];
+ char input[100],basel[100],par[100];
+ char *filtmp;
+ Float_t tmp1,tmp2;
+ fResponse->Thresholds(tmp1,tmp2);
+ Int_t minval = static_cast<Int_t>(tmp1);
+
+ fResponse->Filenames(input,basel,par);
+ fFileName = par;
+ //
+ filtmp = gSystem->ExpandPathName(fFileName.Data());
+ FILE *param = fopen(filtmp,"r");
+ na = 0;
+
+ if(param) {
+ while(fscanf(param,"%d %f %f",&pos, &mu, &sigma) != EOF) {
+ if (pos != na+1) {
+ Error("Init2D","Anode number not in increasing order!",filtmp);
+ exit(1);
+ } // end if pos != na+1
+ savemu[na] = mu;
+ savesigma[na] = sigma;
+ if ((2.*sigma) < mu) {
+ fD[na] = (Int_t)floor(mu - 2.0*sigma + 0.5);
+ mu = 2.0 * sigma;
+ } else fD[na] = 0;
+ tempTh = (Int_t)floor(mu+2.25*sigma+0.5) - minval;
+ if (tempTh < 0) tempTh=0;
+ fT1[na] = tempTh;
+ tempTh = (Int_t)floor(mu+3.0*sigma+0.5) - minval;
+ if (tempTh < 0) tempTh=0;
+ fT2[na] = tempTh;
+ na++;
+ } // end while
+ } else {
+ Error("Init2D","THE FILE %s DOES NOT EXIST !",filtmp);
+ exit(1);
+ } // end if(param)
+
+ fclose(param);
+ delete [] filtmp;
+ delete [] savemu;
+ delete [] savesigma;
}
//______________________________________________________________________
void AliITSsimulationSDD::Compress2D(){
- // simple ITS cluster finder -- online zero-suppression conditions
-
- Int_t db,tl,th;
- Float_t tmp1,tmp2;
- fResponse->Thresholds(tmp1,tmp2);
- Int_t minval = static_cast<Int_t>(tmp1);
- Bool_t write = fResponse->OutputOption();
- Bool_t do10to8 = fResponse->Do10to8();
- Int_t nz, nl, nh, low, i, j;
-
- for (i=0; i<fNofMaps; i++) {
- CompressionParam(i,db,tl,th);
- nz = 0;
- nl = 0;
- nh = 0;
- low = 0;
- for (j=0; j<fMaxNofSamples; j++) {
- Int_t signal=(Int_t)(fHitMap2->GetSignal(i,j));
- signal -= db; // if baseline eq. is done here
- if (signal <= 0) {nz++; continue;}
- if ((signal - tl) < minval) low++;
- if ((signal - th) >= minval) {
- nh++;
- Bool_t cond=kTRUE;
- FindCluster(i,j,signal,minval,cond);
- if(cond && j &&
- ((TMath::Abs(fHitMap2->GetSignal(i,j-1))-th)>=minval)){
- if(do10to8) signal = Convert10to8(signal);
- AddDigit(i,j,signal);
- } // end if cond&&j&&()
- } else if ((signal - tl) >= minval) nl++;
- } // end for j loop time samples
- if (write) TreeB()->Fill(nz,nl,nh,low,i+1);
- } //end for i loop anodes
-
- char hname[30];
- if (write) {
- sprintf(hname,"TNtuple%d_%d",fModule,fEvent);
- TreeB()->Write(hname);
- // reset tree
- TreeB()->Reset();
- } // end if write
+ // simple ITS cluster finder -- online zero-suppression conditions
+
+ Int_t db,tl,th;
+ Float_t tmp1,tmp2;
+ fResponse->Thresholds(tmp1,tmp2);
+ Int_t minval = static_cast<Int_t>(tmp1);
+ Bool_t write = fResponse->OutputOption();
+ Bool_t do10to8 = fResponse->Do10to8();
+ Int_t nz, nl, nh, low, i, j;
+
+ for (i=0; i<fNofMaps; i++) {
+ CompressionParam(i,db,tl,th);
+ nz = 0;
+ nl = 0;
+ nh = 0;
+ low = 0;
+ for (j=0; j<fMaxNofSamples; j++) {
+ Int_t signal=(Int_t)(fHitMap2->GetSignal(i,j));
+ signal -= db; // if baseline eq. is done here
+ if (signal <= 0) {nz++; continue;}
+ if ((signal - tl) < minval) low++;
+ if ((signal - th) >= minval) {
+ nh++;
+ Bool_t cond=kTRUE;
+ FindCluster(i,j,signal,minval,cond);
+ if(cond && j &&
+ ((TMath::Abs(fHitMap2->GetSignal(i,j-1))-th)>=minval)){
+ if(do10to8) signal = Convert10to8(signal);
+ AddDigit(i,j,signal);
+ } // end if cond&&j&&()
+ } else if ((signal - tl) >= minval) nl++;
+ } // end for j loop time samples
+ if (write) TreeB()->Fill(nz,nl,nh,low,i+1);
+ } //end for i loop anodes
+
+ char hname[30];
+ if (write) {
+ sprintf(hname,"TNtuple%d_%d",fModule,fEvent);
+ TreeB()->Write(hname);
+ // reset tree
+ TreeB()->Reset();
+ } // end if write
}
//______________________________________________________________________
void AliITSsimulationSDD::FindCluster(Int_t i,Int_t j,Int_t signal,
Int_t minval,Bool_t &cond){
- // Find clusters according to the online 2D zero-suppression algorithm
- Bool_t do10to8 = fResponse->Do10to8();
- Bool_t high = kFALSE;
+ // Find clusters according to the online 2D zero-suppression algorithm
+ Bool_t do10to8 = fResponse->Do10to8();
+ Bool_t high = kFALSE;
- fHitMap2->FlagHit(i,j);
-//
-// check the online zero-suppression conditions
-//
- const Int_t kMaxNeighbours = 4;
- Int_t nn;
- Int_t dbx,tlx,thx;
- Int_t xList[kMaxNeighbours], yList[kMaxNeighbours];
- fSegmentation->Neighbours(i,j,&nn,xList,yList);
- Int_t in,ix,iy,qns;
- for (in=0; in<nn; in++) {
- ix=xList[in];
- iy=yList[in];
- if (fHitMap2->TestHit(ix,iy)==kUnused) {
- CompressionParam(ix,dbx,tlx,thx);
- Int_t qn = (Int_t)(fHitMap2->GetSignal(ix,iy));
- qn -= dbx; // if baseline eq. is done here
- if ((qn-tlx) < minval) {
- fHitMap2->FlagHit(ix,iy);
- continue;
- } else {
- if ((qn - thx) >= minval) high=kTRUE;
- if (cond) {
- if(do10to8) signal = Convert10to8(signal);
- AddDigit(i,j,signal);
- } // end if cond
- if(do10to8) qns = Convert10to8(qn);
- else qns=qn;
- if (!high) AddDigit(ix,iy,qns);
- cond=kFALSE;
- if(!high) fHitMap2->FlagHit(ix,iy);
- } // end if qn-tlx < minval
- } // end if TestHit
- } // end for in loop over neighbours
+ fHitMap2->FlagHit(i,j);
+ //
+ // check the online zero-suppression conditions
+ //
+ const Int_t kMaxNeighbours = 4;
+ Int_t nn;
+ Int_t dbx,tlx,thx;
+ Int_t xList[kMaxNeighbours], yList[kMaxNeighbours];
+ fSegmentation->Neighbours(i,j,&nn,xList,yList);
+ Int_t in,ix,iy,qns;
+ for (in=0; in<nn; in++) {
+ ix=xList[in];
+ iy=yList[in];
+ if (fHitMap2->TestHit(ix,iy)==kUnused) {
+ CompressionParam(ix,dbx,tlx,thx);
+ Int_t qn = (Int_t)(fHitMap2->GetSignal(ix,iy));
+ qn -= dbx; // if baseline eq. is done here
+ if ((qn-tlx) < minval) {
+ fHitMap2->FlagHit(ix,iy);
+ continue;
+ } else {
+ if ((qn - thx) >= minval) high=kTRUE;
+ if (cond) {
+ if(do10to8) signal = Convert10to8(signal);
+ AddDigit(i,j,signal);
+ } // end if cond
+ if(do10to8) qns = Convert10to8(qn);
+ else qns=qn;
+ if (!high) AddDigit(ix,iy,qns);
+ cond=kFALSE;
+ if(!high) fHitMap2->FlagHit(ix,iy);
+ } // end if qn-tlx < minval
+ } // end if TestHit
+ } // end for in loop over neighbours
}
//______________________________________________________________________
void AliITSsimulationSDD::Init1D(){
- // this is just a copy-paste of input taken from 2D algo
- // Torino people should give input
- // Read 1D zero-suppression parameters for SDD
-
- if (!strstr(fParam.Data(),"file")) return;
-
- Int_t na,pos,tempTh;
- Float_t mu,sigma;
- Float_t *savemu = new Float_t [fNofMaps];
- Float_t *savesigma = new Float_t [fNofMaps];
- char input[100],basel[100],par[100];
- char *filtmp;
- Float_t tmp1,tmp2;
- fResponse->Thresholds(tmp1,tmp2);
- Int_t minval = static_cast<Int_t>(tmp1);
-
- fResponse->Filenames(input,basel,par);
- fFileName=par;
-
-// set first the disable and tol param
- SetCompressParam();
-//
- filtmp = gSystem->ExpandPathName(fFileName.Data());
- FILE *param = fopen(filtmp,"r");
- na = 0;
-
- if (param) {
- fscanf(param,"%d %d %d %d ", &fT2[0], &fT2[1], &fTol[0], &fTol[1]);
- while(fscanf(param,"%d %f %f",&pos, &mu, &sigma) != EOF) {
- if (pos != na+1) {
- Error("Init1D","Anode number not in increasing order!",filtmp);
- exit(1);
- } // end if pos != na+1
- savemu[na]=mu;
- savesigma[na]=sigma;
- if ((2.*sigma) < mu) {
- fD[na] = (Int_t)floor(mu - 2.0*sigma + 0.5);
- mu = 2.0 * sigma;
- } else fD[na] = 0;
- tempTh = (Int_t)floor(mu+2.25*sigma+0.5) - minval;
- if (tempTh < 0) tempTh=0;
- fT1[na] = tempTh;
- na++;
- } // end while
- } else {
- Error("Init1D","THE FILE %s DOES NOT EXIST !",filtmp);
- exit(1);
- } // end if(param)
-
- fclose(param);
- delete [] filtmp;
- delete [] savemu;
- delete [] savesigma;
+ // this is just a copy-paste of input taken from 2D algo
+ // Torino people should give input
+ // Read 1D zero-suppression parameters for SDD
+
+ if (!strstr(fParam.Data(),"file")) return;
+
+ Int_t na,pos,tempTh;
+ Float_t mu,sigma;
+ Float_t *savemu = new Float_t [fNofMaps];
+ Float_t *savesigma = new Float_t [fNofMaps];
+ char input[100],basel[100],par[100];
+ char *filtmp;
+ Float_t tmp1,tmp2;
+ fResponse->Thresholds(tmp1,tmp2);
+ Int_t minval = static_cast<Int_t>(tmp1);
+
+ fResponse->Filenames(input,basel,par);
+ fFileName=par;
+
+ // set first the disable and tol param
+ SetCompressParam();
+ //
+ filtmp = gSystem->ExpandPathName(fFileName.Data());
+ FILE *param = fopen(filtmp,"r");
+ na = 0;
+
+ if (param) {
+ fscanf(param,"%d %d %d %d ", &fT2[0], &fT2[1], &fTol[0], &fTol[1]);
+ while(fscanf(param,"%d %f %f",&pos, &mu, &sigma) != EOF) {
+ if (pos != na+1) {
+ Error("Init1D","Anode number not in increasing order!",filtmp);
+ exit(1);
+ } // end if pos != na+1
+ savemu[na]=mu;
+ savesigma[na]=sigma;
+ if ((2.*sigma) < mu) {
+ fD[na] = (Int_t)floor(mu - 2.0*sigma + 0.5);
+ mu = 2.0 * sigma;
+ } else fD[na] = 0;
+ tempTh = (Int_t)floor(mu+2.25*sigma+0.5) - minval;
+ if (tempTh < 0) tempTh=0;
+ fT1[na] = tempTh;
+ na++;
+ } // end while
+ } else {
+ Error("Init1D","THE FILE %s DOES NOT EXIST !",filtmp);
+ exit(1);
+ } // end if(param)
+
+ fclose(param);
+ delete [] filtmp;
+ delete [] savemu;
+ delete [] savesigma;
}
//______________________________________________________________________
void AliITSsimulationSDD::Compress1D(){
- // 1D zero-suppression algorithm (from Gianluca A.)
- Int_t dis,tol,thres,decr,diff;
- UChar_t *str=fStream->Stream();
- Int_t counter=0;
- Bool_t do10to8=fResponse->Do10to8();
- Int_t last=0;
- Int_t k,i,j;
-
- for (k=0; k<2; k++) {
- tol = Tolerance(k);
- dis = Disable(k);
- for (i=0; i<fNofMaps/2; i++) {
- Bool_t firstSignal=kTRUE;
- Int_t idx=i+k*fNofMaps/2;
- if( !fAnodeFire[idx] ) continue;
- CompressionParam(idx,decr,thres);
-
- decr=20; thres=3; //I.Belikov's temporary fix (needed for the PID)
-
- for (j=0; j<fMaxNofSamples; j++) {
- Int_t signal=(Int_t)(fHitMap2->GetSignal(idx,j));
- signal -= decr; // if baseline eq.
- if(do10to8) signal = Convert10to8(signal);
- if (signal <= thres) {
- signal=0;
- diff=128;
- last=0;
- // write diff in the buffer for HuffT
- str[counter]=(UChar_t)diff;
- counter++;
- continue;
- } // end if signal <= thres
- diff=signal-last;
- if (diff > 127) diff=127;
- if (diff < -128) diff=-128;
- if (signal < dis) {
- // tol has changed to 8 possible cases ? - one can write
- // this if(TMath::Abs(diff)<tol) ... else ...
- if(TMath::Abs(diff)<tol) diff=0;
- // or keep it as it was before
- AddDigit(idx,j,last+diff);
- } else {
- AddDigit(idx,j,signal);
- } // end if singal < dis
- diff += 128;
- // write diff in the buffer used to compute Huffman tables
- if (firstSignal) str[counter]=(UChar_t)signal;
- else str[counter]=(UChar_t)diff;
- counter++;
- last=signal;
- firstSignal=kFALSE;
- } // end for j loop time samples
- } // end for i loop anodes one half of detector
- } // end for k
+ // 1D zero-suppression algorithm (from Gianluca A.)
+ Int_t dis,tol,thres,decr,diff;
+ UChar_t *str=fStream->Stream();
+ Int_t counter=0;
+ Bool_t do10to8=fResponse->Do10to8();
+ Int_t last=0;
+ Int_t k,i,j;
+
+ for (k=0; k<2; k++) {
+ tol = Tolerance(k);
+ dis = Disable(k);
+ for (i=0; i<fNofMaps/2; i++) {
+ Bool_t firstSignal=kTRUE;
+ Int_t idx=i+k*fNofMaps/2;
+ if( !fAnodeFire[idx] ) continue;
+ CompressionParam(idx,decr,thres);
+
+ for (j=0; j<fMaxNofSamples; j++) {
+ Int_t signal=(Int_t)(fHitMap2->GetSignal(idx,j));
+ signal -= decr; // if baseline eq.
+ if(do10to8) signal = Convert10to8(signal);
+ if (signal <= thres) {
+ signal=0;
+ diff=128;
+ last=0;
+ // write diff in the buffer for HuffT
+ str[counter]=(UChar_t)diff;
+ counter++;
+ continue;
+ } // end if signal <= thres
+ diff=signal-last;
+ if (diff > 127) diff=127;
+ if (diff < -128) diff=-128;
+ if (signal < dis) {
+ // tol has changed to 8 possible cases ? - one can write
+ // this if(TMath::Abs(diff)<tol) ... else ...
+ if(TMath::Abs(diff)<tol) diff=0;
+ // or keep it as it was before
+ AddDigit(idx,j,last+diff);
+ } else {
+ AddDigit(idx,j,signal);
+ } // end if singal < dis
+ diff += 128;
+ // write diff in the buffer used to compute Huffman tables
+ if (firstSignal) str[counter]=(UChar_t)signal;
+ else str[counter]=(UChar_t)diff;
+ counter++;
+ last=signal;
+ firstSignal=kFALSE;
+ } // end for j loop time samples
+ } // end for i loop anodes one half of detector
+ } // end for k
// check
- fStream->CheckCount(counter);
+ fStream->CheckCount(counter);
- // open file and write out the stream of diff's
- static Bool_t open=kTRUE;
- static TFile *outFile;
- Bool_t write = fResponse->OutputOption();
- TDirectory *savedir = gDirectory;
+ // open file and write out the stream of diff's
+ static Bool_t open=kTRUE;
+ static TFile *outFile;
+ Bool_t write = fResponse->OutputOption();
+ TDirectory *savedir = gDirectory;
- if (write ) {
- if(open) {
- SetFileName("stream.root");
- cout<<"filename "<<fFileName<<endl;
- outFile=new TFile(fFileName,"recreate");
- cout<<"I have opened "<<fFileName<<" file "<<endl;
- } // end if open
- open = kFALSE;
- outFile->cd();
- fStream->Write();
- } // endif write
-
- fStream->ClearStream();
-
- // back to galice.root file
- if(savedir) savedir->cd();
+ if (write ) {
+ if(open) {
+ SetFileName("stream.root");
+ cout<<"filename "<<fFileName<<endl;
+ outFile=new TFile(fFileName,"recreate");
+ cout<<"I have opened "<<fFileName<<" file "<<endl;
+ } // end if open
+ open = kFALSE;
+ outFile->cd();
+ fStream->Write();
+ } // endif write
+
+ fStream->ClearStream();
+
+ // back to galice.root file
+ if(savedir) savedir->cd();
}
//______________________________________________________________________
void AliITSsimulationSDD::StoreAllDigits(){
- // if non-zero-suppressed data
- Bool_t do10to8 = fResponse->Do10to8();
- Int_t i, j, digits[3];
-
- for (i=0; i<fNofMaps; i++) {
- for (j=0; j<fMaxNofSamples; j++) {
- Int_t signal=(Int_t)(fHitMap2->GetSignal(i,j));
- if(do10to8) signal = Convert10to8(signal);
- digits[0] = i;
- digits[1] = j;
- digits[2] = signal;
- fITS->AddRealDigit(1,digits);
- } // end for j
- } // end for i
+ // if non-zero-suppressed data
+ Bool_t do10to8 = fResponse->Do10to8();
+ Int_t i, j, digits[3];
+
+ for (i=0; i<fNofMaps; i++) {
+ for (j=0; j<fMaxNofSamples; j++) {
+ Int_t signal=(Int_t)(fHitMap2->GetSignal(i,j));
+ if(do10to8) signal = Convert10to8(signal);
+ digits[0] = i;
+ digits[1] = j;
+ digits[2] = signal;
+ fITS->AddRealDigit(1,digits);
+ } // end for j
+ } // end for i
}
//______________________________________________________________________
void AliITSsimulationSDD::CreateHistograms(Int_t scale){
- // Creates histograms of maps for debugging
- Int_t i;
-
- fHis=new TObjArray(fNofMaps);
- for (i=0;i<fNofMaps;i++) {
- TString sddName("sdd_");
- Char_t candNum[4];
- sprintf(candNum,"%d",i+1);
- sddName.Append(candNum);
- fHis->AddAt(new TH1F(sddName.Data(),"SDD maps",scale*fMaxNofSamples,
- 0.,(Float_t) scale*fMaxNofSamples), i);
- } // end for i
+ // Creates histograms of maps for debugging
+ Int_t i;
+
+ fHis=new TObjArray(fNofMaps);
+ for (i=0;i<fNofMaps;i++) {
+ TString sddName("sdd_");
+ Char_t candNum[4];
+ sprintf(candNum,"%d",i+1);
+ sddName.Append(candNum);
+ fHis->AddAt(new TH1F(sddName.Data(),"SDD maps",scale*fMaxNofSamples,
+ 0.,(Float_t) scale*fMaxNofSamples), i);
+ } // end for i
}
//______________________________________________________________________
void AliITSsimulationSDD::FillHistograms(){
- // fill 1D histograms from map
+ // fill 1D histograms from map
- if (!fHis) return;
+ if (!fHis) return;
- for( Int_t i=0; i<fNofMaps; i++) {
- TH1F *hist =(TH1F *)fHis->UncheckedAt(i);
- Int_t nsamples = hist->GetNbinsX();
- for( Int_t j=0; j<nsamples; j++) {
- Double_t signal=fHitMap2->GetSignal(i,j);
- hist->Fill((Float_t)j,signal);
- } // end for j
- } // end for i
+ for( Int_t i=0; i<fNofMaps; i++) {
+ TH1F *hist =(TH1F *)fHis->UncheckedAt(i);
+ Int_t nsamples = hist->GetNbinsX();
+ for( Int_t j=0; j<nsamples; j++) {
+ Double_t signal=fHitMap2->GetSignal(i,j);
+ hist->Fill((Float_t)j,signal);
+ } // end for j
+ } // end for i
}
//______________________________________________________________________
void AliITSsimulationSDD::ResetHistograms(){
- // Reset histograms for this detector
- Int_t i;
+ // Reset histograms for this detector
+ Int_t i;
- for (i=0;i<fNofMaps;i++ ) {
- if (fHis->At(i)) ((TH1F*)fHis->At(i))->Reset();
- } // end for i
+ for (i=0;i<fNofMaps;i++ ) {
+ if (fHis->At(i)) ((TH1F*)fHis->At(i))->Reset();
+ } // end for i
}
//______________________________________________________________________
TH1F *AliITSsimulationSDD::GetAnode(Int_t wing, Int_t anode) {
- // Fills a histogram from a give anode.
+ // Fills a histogram from a give anode.
- if (!fHis) return 0;
+ if (!fHis) return 0;
- if(wing <=0 || wing > 2) {
- Warning("GetAnode","Wrong wing number: %d",wing);
- return NULL;
- } // end if wing <=0 || wing >2
- if(anode <=0 || anode > fNofMaps/2) {
- Warning("GetAnode","Wrong anode number: %d",anode);
- return NULL;
- } // end if ampde <=0 || andoe > fNofMaps/2
+ if(wing <=0 || wing > 2) {
+ Warning("GetAnode","Wrong wing number: %d",wing);
+ return NULL;
+ } // end if wing <=0 || wing >2
+ if(anode <=0 || anode > fNofMaps/2) {
+ Warning("GetAnode","Wrong anode number: %d",anode);
+ return NULL;
+ } // end if ampde <=0 || andoe > fNofMaps/2
- Int_t index = (wing-1)*fNofMaps/2 + anode-1;
- return (TH1F*)(fHis->At(index));
+ Int_t index = (wing-1)*fNofMaps/2 + anode-1;
+ return (TH1F*)(fHis->At(index));
}
//______________________________________________________________________
void AliITSsimulationSDD::WriteToFile(TFile *hfile) {
- // Writes the histograms to a file
+ // Writes the histograms to a file
- if (!fHis) return;
+ if (!fHis) return;
- hfile->cd();
- Int_t i;
- for(i=0; i<fNofMaps; i++) fHis->At(i)->Write(); //fAdcs[i]->Write();
- return;
+ hfile->cd();
+ Int_t i;
+ for(i=0; i<fNofMaps; i++) fHis->At(i)->Write(); //fAdcs[i]->Write();
+ return;
}
//______________________________________________________________________
Float_t AliITSsimulationSDD::GetNoise() {
- // Returns the noise value
- //Bool_t do10to8=fResponse->Do10to8();
- //noise will always be in the liniar part of the signal
- Int_t decr;
- Int_t threshold = fT1[0];
- char opt1[20], opt2[20];
-
- fResponse->ParamOptions(opt1,opt2);
- fParam=opt2;
- char *same = strstr(opt1,"same");
- Float_t noise,baseline;
- if (same) {
- fResponse->GetNoiseParam(noise,baseline);
- } else {
- static Bool_t readfile=kTRUE;
- //read baseline and noise from file
- if (readfile) ReadBaseline();
- readfile=kFALSE;
- } // end if same
-
- TCanvas *c2 = (TCanvas*)gROOT->GetListOfCanvases()->FindObject("c2");
- if(c2) delete c2->GetPrimitive("noisehist");
- if(c2) delete c2->GetPrimitive("anode");
- else c2=new TCanvas("c2");
- c2->cd();
- c2->SetFillColor(0);
-
- TH1F *noisehist = new TH1F("noisehist","noise",100,0.,(float)2*threshold);
- TH1F *anode = new TH1F("anode","Anode Projection",fMaxNofSamples,0.,
- (float)fMaxNofSamples);
- Int_t i,k;
- for (i=0;i<fNofMaps;i++) {
- CompressionParam(i,decr,threshold);
- if (!same) GetAnodeBaseline(i,baseline,noise);
- anode->Reset();
- for (k=0;k<fMaxNofSamples;k++) {
- Float_t signal=(Float_t)fHitMap2->GetSignal(i,k);
- //if (signal <= (float)threshold) noisehist->Fill(signal-baseline);
- if (signal <= (float)threshold) noisehist->Fill(signal);
- anode->Fill((float)k,signal);
- } // end for k
- anode->Draw();
- c2->Update();
- } // end for i
- TF1 *gnoise = new TF1("gnoise","gaus",0.,threshold);
- noisehist->Fit("gnoise","RQ");
- noisehist->Draw();
+ // Returns the noise value
+ //Bool_t do10to8=fResponse->Do10to8();
+ //noise will always be in the liniar part of the signal
+ Int_t decr;
+ Int_t threshold = fT1[0];
+ char opt1[20], opt2[20];
+
+ fResponse->ParamOptions(opt1,opt2);
+ fParam=opt2;
+ char *same = strstr(opt1,"same");
+ Float_t noise,baseline;
+ if (same) {
+ fResponse->GetNoiseParam(noise,baseline);
+ } else {
+ static Bool_t readfile=kTRUE;
+ //read baseline and noise from file
+ if (readfile) ReadBaseline();
+ readfile=kFALSE;
+ } // end if same
+
+ TCanvas *c2 = (TCanvas*)gROOT->GetListOfCanvases()->FindObject("c2");
+ if(c2) delete c2->GetPrimitive("noisehist");
+ if(c2) delete c2->GetPrimitive("anode");
+ else c2=new TCanvas("c2");
+ c2->cd();
+ c2->SetFillColor(0);
+
+ TH1F *noisehist = new TH1F("noisehist","noise",100,0.,(float)2*threshold);
+ TH1F *anode = new TH1F("anode","Anode Projection",fMaxNofSamples,0.,
+ (float)fMaxNofSamples);
+ Int_t i,k;
+ for (i=0;i<fNofMaps;i++) {
+ CompressionParam(i,decr,threshold);
+ if (!same) GetAnodeBaseline(i,baseline,noise);
+ anode->Reset();
+ for (k=0;k<fMaxNofSamples;k++) {
+ Float_t signal=(Float_t)fHitMap2->GetSignal(i,k);
+ //if (signal <= (float)threshold) noisehist->Fill(signal-baseline);
+ if (signal <= (float)(threshold+decr)) noisehist->Fill(signal);
+ anode->Fill((float)k,signal);
+ } // end for k
+ anode->Draw();
c2->Update();
- Float_t mnoise = gnoise->GetParameter(1);
- cout << "mnoise : " << mnoise << endl;
- Float_t rnoise = gnoise->GetParameter(2);
- cout << "rnoise : " << rnoise << endl;
- delete noisehist;
- return rnoise;
+ } // end for i
+ TF1 *gnoise = new TF1("gnoise","gaus",0.,threshold);
+ noisehist->Fit("gnoise","RQ");
+ noisehist->Draw();
+ c2->Update();
+ Float_t mnoise = gnoise->GetParameter(1);
+ cout << "mnoise : " << mnoise << endl;
+ Float_t rnoise = gnoise->GetParameter(2);
+ cout << "rnoise : " << rnoise << endl;
+ delete noisehist;
+ return rnoise;
}
//______________________________________________________________________
void AliITSsimulationSDD::WriteSDigits(){
- // Fills the Summable digits Tree
- static AliITS *aliITS = (AliITS*)gAlice->GetModule("ITS");
-
- for( Int_t i=0; i<fNofMaps; i++ ) {
- if( !fAnodeFire[i] ) continue;
- for( Int_t j=0; j<fMaxNofSamples; j++ ) {
- Double_t sig = fHitMap2->GetSignal( i, j );
- if( sig > 0.2 ) {
- Int_t jdx = j*fScaleSize;
- Int_t index = fpList->GetHitIndex( i, j );
- AliITSpListItem pItemTmp2( fModule, index, 0. );
- // put the fScaleSize analog digits in only one
- for( Int_t ik=0; ik<fScaleSize; ik++ ) {
- AliITSpListItem *pItemTmp = fpList->GetpListItem( i, jdx+ik );
- if( pItemTmp == 0 ) continue;
- pItemTmp2.Add( pItemTmp );
- }
- pItemTmp2.AddSignalAfterElect( fModule, index, sig );
- pItemTmp2.AddNoise( fModule, index, fHitNoiMap2->GetSignal( i, j ) );
- aliITS->AddSumDigit( pItemTmp2 );
- } // end if (sig > 0.2)
- }
+ // Fills the Summable digits Tree
+ static AliITS *aliITS = (AliITS*)gAlice->GetModule("ITS");
+
+ for( Int_t i=0; i<fNofMaps; i++ ) {
+ if( !fAnodeFire[i] ) continue;
+ for( Int_t j=0; j<fMaxNofSamples; j++ ) {
+ Double_t sig = fHitMap2->GetSignal( i, j );
+ if( sig > 0.2 ) {
+ Int_t jdx = j*fScaleSize;
+ Int_t index = fpList->GetHitIndex( i, j );
+ AliITSpListItem pItemTmp2( fModule, index, 0. );
+ // put the fScaleSize analog digits in only one
+ for( Int_t ik=0; ik<fScaleSize; ik++ ) {
+ AliITSpListItem *pItemTmp = fpList->GetpListItem( i, jdx+ik );
+ if( pItemTmp == 0 ) continue;
+ pItemTmp2.Add( pItemTmp );
+ }
+ pItemTmp2.AddSignalAfterElect( fModule, index, sig );
+ pItemTmp2.AddNoise( fModule, index, fHitNoiMap2->GetSignal( i, j ) );
+ aliITS->AddSumDigit( pItemTmp2 );
+ } // end if (sig > 0.2)
}
- return;
+ }
+ return;
}
//______________________________________________________________________
void AliITSsimulationSDD::Print() {
- // Print SDD simulation Parameters
-
- cout << "**************************************************" << endl;
- cout << " Silicon Drift Detector Simulation Parameters " << endl;
- cout << "**************************************************" << endl;
- cout << "Flag for Perpendicular tracks: " << (Int_t) fFlag << endl;
- cout << "Flag for noise checking: " << (Int_t) fCheckNoise << endl;
- cout << "Flag to switch off electronics: " << (Int_t) fDoFFT << endl;
- cout << "Number pf Anodes used: " << fNofMaps << endl;
- cout << "Number of Time Samples: " << fMaxNofSamples << endl;
- cout << "Scale size factor: " << fScaleSize << endl;
- cout << "**************************************************" << endl;
+ // Print SDD simulation Parameters
+
+ cout << "**************************************************" << endl;
+ cout << " Silicon Drift Detector Simulation Parameters " << endl;
+ cout << "**************************************************" << endl;
+ cout << "Flag for Perpendicular tracks: " << (Int_t) fFlag << endl;
+ cout << "Flag for noise checking: " << (Int_t) fCheckNoise << endl;
+ cout << "Flag to switch off electronics: " << (Int_t) fDoFFT << endl;
+ cout << "Number pf Anodes used: " << fNofMaps << endl;
+ cout << "Number of Time Samples: " << fMaxNofSamples << endl;
+ cout << "Scale size factor: " << fScaleSize << endl;
+ cout << "**************************************************" << endl;
}
git://git.uio.no / u / mrichter / AliRoot.git / commitdiff