#include <stdio.h>
#include <stdlib.h>
-#include <iostream.h>
-#include <iomanip.h>
+#include <Riostream.h>
#include <TObjArray.h>
+#include <TParticle.h>
#include <TRandom.h>
#include <TMath.h>
+#include <TH1.h>
#include "AliITSmodule.h"
#include "AliITSMapA2.h"
#include "AliITSsegmentationSSD.h"
#include "AliITSdcsSSD.h"
#include "AliITS.h"
+#include "AliITShit.h"
+#include "AliITSdigit.h"
#include "AliRun.h"
#include "AliITSgeom.h"
#include "AliITSsimulationSSD.h"
+#include "AliITSTableSSD.h"
ClassImp(AliITSsimulationSSD);
////////////////////////////////////////////////////////////////////////
//----------------------------------------------------------------------
AliITSsimulationSSD::AliITSsimulationSSD(){
- //default Constructor
+ //default Constructor
- fDCS = 0;
- fDifConst[0] = fDifConst[1] = 0.0;
- fDriftVel[0] = fDriftVel[1] = 0.0;
- fMapA2 = 0;
+ fDCS = 0;
+ fDifConst[0] = fDifConst[1] = 0.0;
+ fDriftVel[0] = fDriftVel[1] = 0.0;
+ fMapA2 = 0;
+// fpList = 0;
}
//----------------------------------------------------------------------
AliITSsimulationSSD::AliITSsimulationSSD(AliITSsegmentation *seg,
AliITSresponse *resp){
- // Constructor
+ // Constructor
+ // Input:
+ // AliITSsegmentationSSD *seg Pointer to the SSD segmentation to be used
+ // AliITSresponseSSD *resp Pointer to the SSD responce class to be used
+ // Outputs:
+ // none.
+ // Return
+ // none.
fDCS = 0;
fDifConst[0] = fDifConst[1] = 0.0;
fDriftVel[0] = fDriftVel[1] = 0.0;
fMapA2 = 0;
+// fpList = 0;
Init((AliITSsegmentationSSD*)seg,(AliITSresponseSSD*)resp);
}
//----------------------------------------------------------------------
void AliITSsimulationSSD::Init(AliITSsegmentationSSD *seg,
- AliITSresponseSSD *resp){
- // Constructor
+ AliITSresponseSSD *resp){
+ // Inilizer, Inilizes all of the variable as needed in a standard place.
+ // Input:
+ // AliITSsegmentationSSD *seg Pointer to the SSD segmentation to be used
+ // AliITSresponseSSD *resp Pointer to the SSD responce class to be used
+ // Outputs:
+ // none.
+ // Return
+ // none.
fSegmentation = seg;
fResponse = resp;
SetDriftVelocity(); // use default values in .h file
SetIonizeE(); // use default values in .h file
SetDiffConst(); // use default values in .h file
+ fpList = new AliITSpList(2,GetNStrips());
fMapA2 = new AliITSMapA2(fSegmentation);
}
//______________________________________________________________________
AliITSsimulationSSD& AliITSsimulationSSD::operator=(
- const AliITSsimulationSSD &s){
- // Operator =
-
- if(this==&s) return *this;
-
- this->fDCS = new AliITSdcsSSD(*(s.fDCS));
- this->fMapA2 = s.fMapA2;
- this->fIonE = s.fIonE;
- this->fDifConst[0] = s.fDifConst[0];
- this->fDifConst[1] = s.fDifConst[1];
- this->fDriftVel[0] = s.fDriftVel[0];
- this->fDriftVel[1] = s.fDriftVel[1];
- return *this;
+ const AliITSsimulationSSD &s){
+ // Operator =
+
+ if(this==&s) return *this;
+
+ this->fDCS = new AliITSdcsSSD(*(s.fDCS));
+ this->fMapA2 = s.fMapA2;
+ this->fIonE = s.fIonE;
+ this->fDifConst[0] = s.fDifConst[0];
+ this->fDifConst[1] = s.fDifConst[1];
+ this->fDriftVel[0] = s.fDriftVel[0];
+ this->fDriftVel[1] = s.fDriftVel[1];
+ return *this;
}
//______________________________________________________________________
AliITSsimulationSSD::AliITSsimulationSSD(const AliITSsimulationSSD &source){
- // copy constructor
+ // copy constructor
- *this = source;
+ *this = source;
}
//______________________________________________________________________
AliITSsimulationSSD::~AliITSsimulationSSD() {
- // destructor
- delete fMapA2;
- delete fDCS;
+ // destructor
+ delete fMapA2;
+ delete fDCS;
+}
+//______________________________________________________________________
+void AliITSsimulationSSD::InitSimulationModule(Int_t module,Int_t event){
+ // Creates maps to build the list of tracks for each sumable digit
+ // Inputs:
+ // Int_t module // Module number to be simulated
+ // Int_t event // Event number to be simulated
+ // Outputs:
+ // none.
+ // Return
+ // none.
+
+ fModule = module;
+ fEvent = event;
+ fMapA2->ClearMap();
+ fpList->ClearMap();
+}
+//______________________________________________________________________
+void AliITSsimulationSSD::FinishSDigitiseModule(){
+ // Does the Sdigits to Digits work
+ // Inputs:
+ // none.
+ // Outputs:
+ // none.
+ // Return:
+ // none.
+
+ FillMapFrompList(fpList); // need to check if needed here or not????
+ SDigitToDigit(fModule,fpList);
+ fpList->ClearMap();
+ fMapA2->ClearMap();
}
//______________________________________________________________________
void AliITSsimulationSSD::DigitiseModule(AliITSmodule *mod,
- Int_t dummy0,Int_t dummy1) {
- // Digitizes hits for one SSD module
- Int_t module = mod->GetIndex();
- AliITSpList *pList = new AliITSpList(2,GetNStrips());
+ Int_t dummy0,Int_t dummy1) {
+ // Digitizes hits for one SSD module
+ Int_t module = mod->GetIndex();
- HitsToAnalogDigits(mod,pList);
- SDigitToDigit(module,pList);
+ HitsToAnalogDigits(mod,fpList);
+ SDigitToDigit(module,fpList);
- delete pList;
- fMapA2->ClearMap();
+ fpList->ClearMap();
+ fMapA2->ClearMap();
}
//______________________________________________________________________
void AliITSsimulationSSD::SDigitiseModule(AliITSmodule *mod,Int_t dummy0,
- Int_t dummy1) {
- // Produces Summable/Analog digits and writes them to the SDigit tree.
- AliITSpList *pList = new AliITSpList(2,GetNStrips());
+ Int_t dummy1) {
+ // Produces Summable/Analog digits and writes them to the SDigit tree.
- HitsToAnalogDigits(mod,pList);
+ HitsToAnalogDigits(mod,fpList);
- WriteSDigits(pList);
+ WriteSDigits(fpList);
- delete pList;
- fMapA2->ClearMap();
+ fpList->ClearMap();
+ fMapA2->ClearMap();
}
//______________________________________________________________________
void AliITSsimulationSSD::SDigitToDigit(Int_t module,AliITSpList *pList){
- // Takes the pList and finishes the digitization.
-
- //FillMapFrompList(pList); // commented out to avoid double counting of
- // the charge
+ // Takes the pList and finishes the digitization.
+
+ // FillMapFrompList(pList); //commented out to avoid double counting of the
+ //charge
- ApplyNoise(pList,module);
- ApplyCoupling(pList,module);
+ ApplyNoise(pList,module);
+ ApplyCoupling(pList,module);
- ChargeToSignal(pList);
+ ChargeToSignal(pList);
}
//______________________________________________________________________
void AliITSsimulationSSD::HitsToAnalogDigits(AliITSmodule *mod,
- AliITSpList *pList){
+ AliITSpList *pList){
// Loops over all hits to produce Analog/floating point digits. This
// is also the first task in producing standard digits.
- Int_t indexRange[4] = {0,0,0,0};
- static Bool_t first = kTRUE;
Int_t lasttrack = -2;
Int_t idtrack = -2;
Double_t x0=0.0, y0=0.0, z0=0.0;
TObjArray *hits = mod->GetHits();
Int_t nhits = hits->GetEntriesFast();
if (nhits<=0) return;
-
+ AliITSTableSSD * tav = new AliITSTableSSD(GetNStrips());
module = mod->GetIndex();
if ( mod->GetLayer() == 6 ) GetSegmentation()->SetLayer(6);
if ( mod->GetLayer() == 5 ) GetSegmentation()->SetLayer(5);
-
for(Int_t i=0; i<nhits; i++) {
// LineSegmentL returns 0 if the hit is entering
// If hits is exiting returns positions of entering and exiting hits
// Returns also energy loss
-
+// cout << i << " ";
+// cout << mod->GetHit(i)->GetXL() << " "<<mod->GetHit(i)->GetYL();
+// cout << " " << mod->GetHit(i)->GetZL();
+// cout << endl;
if (mod->LineSegmentL(i, x0, x1, y0, y1, z0, z1, de, idtrack)) {
- HitToDigit(module, x0, y0, z0, x1, y1, z1, de, indexRange, first);
-
+ HitToDigit(module, x0, y0, z0, x1, y1, z1, de,tav);
if (lasttrack != idtrack || i==(nhits-1)) {
- GetList(idtrack,i,module,pList,indexRange);
- first=kTRUE;
+ GetList(idtrack,i,module,pList,tav);
} // end if
lasttrack=idtrack;
} // end if
} // end loop over hits
+ delete tav; tav=0;
return;
}
//----------------------------------------------------------------------
void AliITSsimulationSSD::HitToDigit(Int_t module, Double_t x0, Double_t y0,
- Double_t z0, Double_t x1, Double_t y1,
- Double_t z1, Double_t de,
- Int_t *indexRange, Bool_t first) {
+ Double_t z0, Double_t x1, Double_t y1,
+ Double_t z1, Double_t de,
+ AliITSTableSSD *tav) {
// Turns hits in SSD module into one or more digits.
-
Float_t tang[2] = {0.0,0.0};
GetSegmentation()->Angles(tang[0], tang[1]);//stereo<<->tan(stereo)~=stereo
Double_t x, y, z;
- Double_t dex=0.0, dey=0.0, dez=0.0;
+ Double_t dex=0.0, dey=0.0, dez=0.0;
Double_t pairs; // pair generation energy per step.
Double_t sigma[2] = {0.,0.};// standard deviation of the diffusion gaussian
Double_t tdrift[2] = {0.,0.}; // time of drift
// Steps in the module are determined "manually" (i.e. No Geant)
// NumOfSteps divide path between entering and exiting hits in steps
Int_t numOfSteps = NumOfSteps(x1, y1, z1, dex, dey, dez);
-
// Enery loss is equally distributed among steps
de = de/numOfSteps;
pairs = de/GetIonizeE(); // e-h pairs generated
-
for(Int_t j=0; j<numOfSteps; j++) { // stepping
x = x0 + (j+0.5)*dex;
y = y0 + (j+0.5)*dey;
return;
} // end if
z = z0 + (j+0.5)*dez;
-
+// cout <<"HitToDigit "<<x<<" "<<y<<" "<<z<< " "<<dex<<" "<<dey<<" "<<dez<<endl;
// calculate drift time
// y is the minimum path
tdrift[0] = (y+(GetSegmentation()->Dy()*1.0E-4)/2)/GetDriftVelocity(0);
tang[k]=TMath::Tan(tang[k]);
// w is the coord. perpendicular to the strips
+ /*
if(k==0) {
w = (x+(GetSegmentation()->Dx()*1.0E-4)/2) -
(z+(GetSegmentation()->Dz()*1.0E-4)/2)*tang[k];
(z-(GetSegmentation()->Dz()*1.0E-4)/2)*tang[k];
} // end if
w /= (GetStripPitch()*1.0E-4); // w is converted in units of pitch
+ */
+ { // replacement block for the above.
+ Float_t xp=x*1.e+4,zp=z*1.e+4; // microns
+ GetSegmentation()->GetPadTxz(xp,zp);
+ if(k==0) w = xp; // P side strip number
+ else w = zp; // N side strip number
+ } // end test block
if((w<(-0.5)) || (w>(GetNStrips()-0.5))) {
// this check rejects hits in regions not covered by strips
// 0.5 takes into account boundaries
+ //cout << "x,z="<<x<<","<<z<<" w="<<w<<" Nstrips="<<GetNStrips()<<endl;
return; // There are dead region on the SSD sensitive volume.
- /*
- if(k==0) Warning("HitToDigit",
- "no strip in this region of P side");
- else Warning"HitToDigit","no strip in this region of N side");
- return;
- */
} // end if
// sigma is the standard deviation of the diffusion gaussian
// we integrate the diffusion gaussian from -3sigma to 3sigma
inf[k] = w - 3*sigma[k]; // 3 sigma from the gaussian average
sup[k] = w + 3*sigma[k]; // 3 sigma from the gaussian average
- // IntegrateGaussian does the actual
- // integration of diffusion gaussian
- IntegrateGaussian(k, par0[k], w, sigma[k], inf[k], sup[k],
- indexRange, first);
+ // IntegrateGaussian does the actual
+ // integration of diffusion gaussian
+ IntegrateGaussian(k, par0[k], w, sigma[k], inf[k], sup[k],tav);
} // end for loop over side (0=Pside, 1=Nside)
} // end stepping
- //delete seg;
}
//______________________________________________________________________
void AliITSsimulationSSD::ApplyNoise(AliITSpList *pList,Int_t module){
- // Apply Noise.
- Int_t k,ix;
- Double_t signal,noise;
- Double_t noiseP[2] = {0.,0.};
- Float_t a,b;
-
- fResponse->GetNoiseParam(a,b); // retrieves noise parameters
- noiseP[0] = (Double_t) a; noiseP[1] = (Double_t) b;
- for(k=0;k<2;k++){ // both sides (0=Pside, 1=Nside)
+ // Apply Noise.
+ Int_t k,ix;
+ Double_t signal,noise;
+ Double_t noiseP[2] = {0.,0.};
+ Float_t a,b;
+
+ fResponse->GetNoiseParam(a,b); // retrieves noise parameters
+ noiseP[0] = (Double_t) a; noiseP[1] = (Double_t) b;
+ for(k=0;k<2;k++){ // both sides (0=Pside, 1=Nside)
for(ix=0;ix<GetNStrips();ix++){ // loop over strips
noise = gRandom->Gaus(0,noiseP[k]);// get noise to signal
signal = noise + fMapA2->GetSignal(k,ix);//get signal from map
fMapA2->SetHit(k,ix,signal); // give back signal to map
if(signal>0.0) pList->AddNoise(k,ix,module,noise);
} // loop over strip
- } // loop over k (P or N side)
+ } // loop over k (P or N side)
}
//______________________________________________________________________
void AliITSsimulationSSD::ApplyCoupling(AliITSpList *pList,Int_t module) {
- // Apply the effect of electronic coupling between channels
- Int_t ix;
- Double_t signalLeft=0, signalRight=0,signal=0;
+ // Apply the effect of electronic coupling between channels
+ Int_t ix;
+ Double_t signalLeft=0, signalRight=0,signal=0;
- for(ix=0;ix<GetNStrips();ix++){
+ for(ix=0;ix<GetNStrips();ix++){
// P side coupling
if(ix>0.)signalLeft = fMapA2->GetSignal(0,ix-1)*fDCS->GetCouplingPL();
else signalLeft = 0.0;
if(ix<(GetNStrips()-1)) signalRight = fMapA2->GetSignal(0,ix+1)*
- fDCS->GetCouplingPR();
+ fDCS->GetCouplingPR();
else signalRight = 0.0;
signal = signalLeft + signalRight;
fMapA2->AddSignal(0,ix,signal);
if(ix>0.) signalLeft = fMapA2->GetSignal(1,ix-1)*fDCS->GetCouplingNL();
else signalLeft = 0.0;
if(ix<(GetNStrips()-1)) signalRight = fMapA2->GetSignal(1,ix+1)*
- fDCS->GetCouplingNR();
+ fDCS->GetCouplingNR();
else signalRight = 0.0;
signal = signalLeft + signalRight;
fMapA2->AddSignal(1,ix,signal);
if(signal>0.0) pList->AddNoise(1,ix,module,signal);
- } // loop over strips
+ } // loop over strips
}
//______________________________________________________________________
Float_t AliITSsimulationSSD::F(Float_t av, Float_t x, Float_t s) {
- // Computes the integral of a gaussian using Error Function
- Float_t sqrt2 = TMath::Sqrt(2.0);
- Float_t sigm2 = sqrt2*s;
- Float_t integral;
+ // Computes the integral of a gaussian using Error Function
+ Float_t sqrt2 = TMath::Sqrt(2.0);
+ Float_t sigm2 = sqrt2*s;
+ Float_t integral;
- integral = 0.5 * TMath::Erf( (x - av) / sigm2);
- return integral;
+ integral = 0.5 * TMath::Erf( (x - av) / sigm2);
+ return integral;
}
//______________________________________________________________________
void AliITSsimulationSSD::IntegrateGaussian(Int_t k,Double_t par, Double_t w,
- Double_t sigma,
- Double_t inf, Double_t sup,
- Int_t *indexRange, Bool_t first) {
- // integrate the diffusion gaussian
- // remind: inf and sup are w-3sigma and w+3sigma
- // we could define them here instead of passing them
- // this way we are free to introduce asimmetry
-
- Double_t a=0.0, b=0.0;
- Double_t dXCharge1 = 0.0, dXCharge2 = 0.0;
- // dXCharge1 and 2 are the charge to two neighbouring strips
- // Watch that we only involve at least two strips
- // Numbers greater than 2 of strips in a cluster depend on
- // geometry of the track and delta rays, not charge diffusion!
+ Double_t sigma,
+ Double_t inf, Double_t sup,
+ AliITSTableSSD *tav) {
+ // integrate the diffusion gaussian
+ // remind: inf and sup are w-3sigma and w+3sigma
+ // we could define them here instead of passing them
+ // this way we are free to introduce asimmetry
+
+ Double_t a=0.0, b=0.0;
+ Double_t dXCharge1 = 0.0, dXCharge2 = 0.0;
+ // dXCharge1 and 2 are the charge to two neighbouring strips
+ // Watch that we only involve at least two strips
+ // Numbers greater than 2 of strips in a cluster depend on
+ // geometry of the track and delta rays, not charge diffusion!
- Double_t strip = TMath::Floor(w); // clostest strip on the left
-
- if ( TMath::Abs((strip - w)) < 0.5) {
- // gaussian mean is closer to strip on the left
- a = inf; // integration starting point
- if((strip+0.5)<=sup) {
- // this means that the tail of the gaussian goes beyond
- // the middle point between strips ---> part of the signal
- // is given to the strip on the right
- b = strip + 0.5; // integration stopping point
- dXCharge1 = F( w, b, sigma) - F(w, a, sigma);
- dXCharge2 = F( w, sup, sigma) - F(w ,b, sigma);
- }else {
- // this means that all the charge is given to the strip on the left
- b = sup;
- dXCharge1 = 0.9973; // gaussian integral at 3 sigmas
- dXCharge2 = 0.0;
- } // end if
-
- dXCharge1 = par * dXCharge1;// normalize by mean of number of carriers
- dXCharge2 = par * dXCharge2;
-
- // for the time being, signal is the charge
- // in ChargeToSignal signal is converted in ADC channel
- fMapA2->AddSignal(k,(Int_t)strip,dXCharge1);
- if(((Int_t) strip) < (GetNStrips()-1)) {
- // strip doesn't have to be the last (remind: last=GetNStrips()-1)
- // otherwise part of the charge is lost
- fMapA2->AddSignal(k,((Int_t)strip+1),dXCharge2);
- } // end if
-
- if(dXCharge1 > 1.) {
- if (first) {
- indexRange[k*2+0] = indexRange[k*2+1]=(Int_t) strip;
- first=kFALSE;
- } // end if first
-
- indexRange[k*2+0]=TMath::Min(indexRange[k*2+0],(Int_t) strip);
- indexRange[k*2+1]=TMath::Max(indexRange[k*2+1],(Int_t) strip);
- } // dXCharge > 1 e-
-
- }else{
- // gaussian mean is closer to strip on the right
- strip++; // move to strip on the rigth
- b = sup; // now you know where to stop integrating
- if((strip-0.5)>=inf) {
- // tail of diffusion gaussian on the left goes left of
- // middle point between strips
- a = strip - 0.5; // integration starting point
- dXCharge1 = F(w, b, sigma) - F(w, a, sigma);
- dXCharge2 = F(w, a, sigma) - F(w, inf, sigma);
- }else {
- a = inf;
- dXCharge1 = 0.9973; // gaussian integral at 3 sigmas
- dXCharge2 = 0.0;
- } // end if
-
- dXCharge1 = par * dXCharge1; // normalize by means of carriers
- dXCharge2 = par * dXCharge2;
-
- // for the time being, signal is the charge
- // in ChargeToSignal signal is converted in ADC channel
- fMapA2->AddSignal(k,(Int_t)strip,dXCharge1);
- if(((Int_t) strip) > 0) {
- // strip doesn't have to be the first
- // otherwise part of the charge is lost
- fMapA2->AddSignal(k,((Int_t)strip-1),dXCharge2);
- } // end if
-
- if(dXCharge1 > 1.) {
- if (first) {
- indexRange[k*2+0]=indexRange[k*2+1]=(Int_t) strip;
- first=kFALSE;
- } // end if first
-
- indexRange[k*2+0]=TMath::Min(indexRange[k*2+0],(Int_t) strip);
- indexRange[k*2+1]=TMath::Max(indexRange[k*2+1],(Int_t) strip);
- } // dXCharge > 1 e-
- } // end if
+ Double_t strip = TMath::Floor(w); // closest strip on the left
+
+ if ( TMath::Abs((strip - w)) < 0.5) {
+ // gaussian mean is closer to strip on the left
+ a = inf; // integration starting point
+ if((strip+0.5)<=sup) {
+ // this means that the tail of the gaussian goes beyond
+ // the middle point between strips ---> part of the signal
+ // is given to the strip on the right
+ b = strip + 0.5; // integration stopping point
+ dXCharge1 = F( w, b, sigma) - F(w, a, sigma);
+ dXCharge2 = F( w, sup, sigma) - F(w ,b, sigma);
+ }else {
+ // this means that all the charge is given to the strip on the left
+ b = sup;
+ dXCharge1 = 0.9973; // gaussian integral at 3 sigmas
+ dXCharge2 = 0.0;
+ } // end if
+ dXCharge1 = par * dXCharge1;// normalize by mean of number of carriers
+ dXCharge2 = par * dXCharge2;
+
+ // for the time being, signal is the charge
+ // in ChargeToSignal signal is converted in ADC channel
+ fMapA2->AddSignal(k,(Int_t)strip,dXCharge1);
+ tav->Add(k,(Int_t)strip);
+ if(((Int_t) strip) < (GetNStrips()-1)) {
+ // strip doesn't have to be the last (remind: last=GetNStrips()-1)
+ // otherwise part of the charge is lost
+ fMapA2->AddSignal(k,((Int_t)strip+1),dXCharge2);
+ tav->Add(k,((Int_t)(strip+1)));
+ } // end if
+ }else{
+ // gaussian mean is closer to strip on the right
+ strip++; // move to strip on the rigth
+ b = sup; // now you know where to stop integrating
+ if((strip-0.5)>=inf) {
+ // tail of diffusion gaussian on the left goes left of
+ // middle point between strips
+ a = strip - 0.5; // integration starting point
+ dXCharge1 = F(w, b, sigma) - F(w, a, sigma);
+ dXCharge2 = F(w, a, sigma) - F(w, inf, sigma);
+ }else {
+ a = inf;
+ dXCharge1 = 0.9973; // gaussian integral at 3 sigmas
+ dXCharge2 = 0.0;
+ } // end if
+ dXCharge1 = par * dXCharge1; // normalize by means of carriers
+ dXCharge2 = par * dXCharge2;
+ // for the time being, signal is the charge
+ // in ChargeToSignal signal is converted in ADC channel
+ fMapA2->AddSignal(k,(Int_t)strip,dXCharge1);
+ tav->Add(k,(Int_t)strip);
+ if(((Int_t) strip) > 0) {
+ // strip doesn't have to be the first
+ // otherwise part of the charge is lost
+ fMapA2->AddSignal(k,((Int_t)strip-1),dXCharge2);
+ tav->Add(k,((Int_t)(strip-1)));
+ } // end if
+ } // end if
}
//______________________________________________________________________
Int_t AliITSsimulationSSD::NumOfSteps(Double_t x, Double_t y, Double_t z,
- Double_t & dex,Double_t & dey,Double_t & dez){
- // number of steps
- // it also returns steps for each coord
- //AliITSsegmentationSSD *seg = new AliITSsegmentationSSD();
+ Double_t & dex,Double_t & dey,Double_t & dez){
+ // number of steps
+ // it also returns steps for each coord
+ //AliITSsegmentationSSD *seg = new AliITSsegmentationSSD();
- Double_t step = 25E-4;
- //step = (Double_t) seg->GetStepSize(); // step size (cm)
- Int_t numOfSteps = (Int_t) (TMath::Sqrt(x*x+y*y+z*z)/step);
+ Double_t step = 25E-4;
+ //step = (Double_t) seg->GetStepSize(); // step size (cm)
+ Int_t numOfSteps = (Int_t) (TMath::Sqrt(x*x+y*y+z*z)/step);
- if (numOfSteps < 1) numOfSteps = 1; // one step, at least
+ if (numOfSteps < 1) numOfSteps = 1; // one step, at least
- // we could condition the stepping depending on the incident angle
- // of the track
- dex = x/numOfSteps;
- dey = y/numOfSteps;
- dez = z/numOfSteps;
+ // we could condition the stepping depending on the incident angle
+ // of the track
+ dex = x/numOfSteps;
+ dey = y/numOfSteps;
+ dez = z/numOfSteps;
- return numOfSteps;
+ return numOfSteps;
}
//----------------------------------------------------------------------
void AliITSsimulationSSD::GetList(Int_t label,Int_t hit,Int_t mod,
- AliITSpList *pList,Int_t *indexRange) {
- // loop over nonzero digits
- Int_t ix,i;
- Double_t signal=0.;
-
- for(Int_t k=0; k<2; k++) {
- for(ix=indexRange[k*2+0];ix<indexRange[k*2+1]+1;ix++){
-// if(indexRange[k*2+0]<indexRange[k*2+1])
- signal = fMapA2->GetSignal(k,ix);
- if(signal==0.0) continue;
- // check the signal magnitude
- for(i=0;i<pList->GetNSignals(k,ix);i++)
- signal -= pList->GetTSignal(k,ix,i);
- // compare the new signal with already existing list
- pList->AddSignal(k,ix,label,hit,mod,signal);
- } // end of loop pixels in x
- } // end of loop over pixels in z
+ AliITSpList *pList,AliITSTableSSD *tav) {
+ // loop over nonzero digits
+ Int_t ix,i;
+ Double_t signal=0.;
+
+ for(Int_t k=0; k<2; k++) {
+ ix=tav->Use(k);
+ while(ix>-1){
+ signal = fMapA2->GetSignal(k,ix);
+ if(signal==0.0) {
+ ix=tav->Use(k);
+ continue;
+ } // end if signal==0.0
+ // check the signal magnitude
+ for(i=0;i<pList->GetNSignals(k,ix);i++){
+ signal -= pList->GetTSignal(k,ix,i);
+ } // end for i
+ // compare the new signal with already existing list
+ if(signal>0)pList->AddSignal(k,ix,label,hit,mod,signal);
+ ix=tav->Use(k);
+ } // end of loop on strips
+ } // end of loop on P/N side
+ tav->Clear();
}
//----------------------------------------------------------------------
void AliITSsimulationSSD::ChargeToSignal(AliITSpList *pList) {
- // charge to signal
- static AliITS *aliITS = (AliITS*)gAlice->GetModule("ITS");
- Float_t threshold = 0.;
- Int_t digits[3], tracks[3],hits[3],j1;
- Float_t charges[3] = {0.0,0.0,0.0};
- Float_t signal;
- Float_t noise[2] = {0.,0.};
-
- ((AliITSresponseSSD*)fResponse)->GetNoiseParam(noise[0],noise[1]);
-
- for(Int_t k=0;k<2;k++){ // both sides (0=Pside, 1=Nside)
+ // charge to signal
+ static AliITS *aliITS = (AliITS*)gAlice->GetModule("ITS");
+ Float_t threshold = 0.;
+ Int_t size = AliITSdigitSSD::GetNTracks();
+ Int_t * digits = new Int_t[size];
+ Int_t * tracks = new Int_t[size];
+ Int_t * hits = new Int_t[size];
+ Int_t j1;
+ Float_t charges[3] = {0.0,0.0,0.0};
+ Float_t signal;
+ Float_t noise[2] = {0.,0.};
+
+ ((AliITSresponseSSD*)fResponse)->GetNoiseParam(noise[0],noise[1]);
+
+ for(Int_t k=0;k<2;k++){ // both sides (0=Pside, 1=Nside)
// Threshold for zero-suppression
// It can be defined in AliITSresponseSSD
// threshold = (Float_t)fResponse->MinVal(k);
// at the scope, and considering noise standard deviation
threshold = 4.0*noise[k]; // 4 times noise is a choice
for(Int_t ix=0;ix<GetNStrips();ix++){ // loop over strips
- if(fMapA2->GetSignal(k,ix) <= threshold) continue;
+ if(fMapA2->GetSignal(k,ix) <= threshold)continue;
// convert to ADC signal
signal = ((AliITSresponseSSD*)fResponse)->DEvToADC(
- fMapA2->GetSignal(k,ix));
+ fMapA2->GetSignal(k,ix));
if(signal>1024.) signal = 1024.;//if exceeding, accumulate last one
digits[0] = k;
digits[1] = ix;
digits[2] = (Int_t) signal;
- for(j1=0;j1<3;j1++){ // only three in digit.
+ for(j1=0;j1<size;j1++)if(j1<pList->GetNEnteries()){
+ // only three in digit.
tracks[j1] = pList->GetTrack(k,ix,j1);
hits[j1] = pList->GetHit(k,ix,j1);
+ }else{
+ tracks[j1] = -3;
+ hits[j1] = -1;
} // end for j1
// finally add digit
aliITS->AddSimDigit(2,0,digits,tracks,hits,charges);
} // end for ix
- } // end for k
+ } // end for k
+ delete [] digits;
+ delete [] tracks;
+ delete [] hits;
}
//______________________________________________________________________
void AliITSsimulationSSD::WriteSDigits(AliITSpList *pList){
- // Fills the Summable digits Tree
- Int_t i,ni,j,nj;
- static AliITS *aliITS = (AliITS*)gAlice->GetModule("ITS");
-
- pList->GetMaxMapIndex(ni,nj);
- for(i=0;i<ni;i++)for(j=0;j<nj;j++){
- if(pList->GetSignalOnly(i,j)>0.0){
- aliITS->AddSumDigit(*(pList->GetpListItem(i,j)));
+ // Fills the Summable digits Tree
+ Int_t i,ni,j,nj;
+ static AliITS *aliITS = (AliITS*)gAlice->GetModule("ITS");
+
+ pList->GetMaxMapIndex(ni,nj);
+ for(i=0;i<ni;i++)for(j=0;j<nj;j++){
+ if(pList->GetSignalOnly(i,j)>0.0){
+ aliITS->AddSumDigit(*(pList->GetpListItem(i,j)));
// cout << "pListSSD: " << *(pList->GetpListItem(i,j)) << endl;
- } // end if
- } // end for i,j
- return;
+ } // end if
+ } // end for i,j
+ return;
}
//______________________________________________________________________
void AliITSsimulationSSD::FillMapFrompList(AliITSpList *pList){
- // Fills fMap2A from the pList of Summable digits
- Int_t k,ix;
+ // Fills fMap2A from the pList of Summable digits
+ Int_t k,ix;
- for(k=0;k<2;k++)for(ix=0;ix<GetNStrips();ix++)
+ for(k=0;k<2;k++)for(ix=0;ix<GetNStrips();ix++)
fMapA2->AddSignal(k,ix,pList->GetSignal(k,ix));
- return;
+ return;
}
//______________________________________________________________________
void AliITSsimulationSSD::Print(ostream *os){
- //Standard output format for this class
-
- //AliITSsimulation::Print(os);
- *os << fIonE <<",";
- *os << fDifConst[0] <<","<< fDifConst[1] <<",";
- *os << fDriftVel[0] <<","<< fDriftVel[1];
- //*os <<","; fDCS->Print(os);
- //*os <<","; fMapA2->Print(os);
+ //Standard output format for this class
+
+ //AliITSsimulation::Print(os);
+ *os << fIonE <<",";
+ *os << fDifConst[0] <<","<< fDifConst[1] <<",";
+ *os << fDriftVel[0] <<","<< fDriftVel[1];
+ //*os <<","; fDCS->Print(os);
+ //*os <<","; fMapA2->Print(os);
}
//______________________________________________________________________
void AliITSsimulationSSD::Read(istream *is){
- // Standard output streaming function.
-
- //AliITSsimulation::Read(is);
- *is >> fIonE;
- *is >> fDifConst[0] >> fDifConst[1];
- *is >> fDriftVel[0] >> fDriftVel[1];
- //fDCS->Read(is);
- //fMapA2->Read(is);
+ // Standard output streaming function.
+
+ //AliITSsimulation::Read(is);
+ *is >> fIonE;
+ *is >> fDifConst[0] >> fDifConst[1];
+ *is >> fDriftVel[0] >> fDriftVel[1];
+ //fDCS->Read(is);
+ //fMapA2->Read(is);
}
//______________________________________________________________________
ostream &operator<<(ostream &os,AliITSsimulationSSD &source){
- // Standard output streaming function.
+ // Standard output streaming function.
- source.Print(&os);
- return os;
+ source.Print(&os);
+ return os;
}
//______________________________________________________________________
istream &operator>>(istream &os,AliITSsimulationSSD &source){
- // Standard output streaming function.
+ // Standard output streaming function.
- source.Read(&os);
- return os;
+ source.Read(&os);
+ return os;
}
//______________________________________________________________________
+
+
+
+
+