/** CbmMuchDigitizeGem.cxx *@author Vikas Singhal *@since 01.10.16 *@version 2.0 *@author Evgeny Kryshen *@since 01.05.11 *@version 2.0 *@author Mikhail Ryzhinskiy *@since 19.03.07 *@version 1.0 ** ** CBM task class for digitizing MUCH for both Event by event and Time based mode. ** Task level RECO ** Produces objects of type CbmMuchDigi out of CbmMuchPoint. **/ // Includes from MUCH #include "CbmMuchDigitizeGem.h" #include "CbmMuchPoint.h" #include "CbmMuchSector.h" #include "CbmMuchStation.h" #include "CbmMuchModuleGem.h" #include "CbmMuchModuleGemRadial.h" #include "CbmMuchModuleGemRectangular.h" #include "CbmMuchPad.h" #include "CbmMuchPadRadial.h" #include "CbmMuchPadRectangular.h" #include "CbmMuchSectorRadial.h" #include "CbmMuchSectorRectangular.h" #include "CbmMuchDigi.h" #include "CbmMuchReadoutBuffer.h" // Includes from base #include "FairRootManager.h" #include "FairEventHeader.h" #include "FairMCEventHeader.h" #include "FairMCPoint.h" #include "FairRunAna.h" #include "FairRunSim.h" #include "FairLogger.h" // Includes from Cbm #include "CbmMCTrack.h" #include "CbmMCEpoch.h" //#include "CbmMCBuffer.h" #include "TObjArray.h" #include "TDatabasePDG.h" #include "TFile.h" #include "TRandom.h" #include "TChain.h" #include "TH1D.h" #include #include #include #include #include #include #include "../../base/CbmDaqBuffer.h" using std::fixed; using std::right; using std::setprecision; using std::setw; using std::string; using std::map; using std::cout; using std::endl; // ----- Default constructor ------------------------------------------- CbmMuchDigitizeGem::CbmMuchDigitizeGem() : CbmDigitize("MuchDigitizeGem"), //fgDeltaResponse(), fAlgorithm(1), fGeoScheme(CbmMuchGeoScheme::Instance()), fDigiFile(), fFlag(0), fPoints(NULL), fMCTracks(NULL), fDigis(NULL), fDigiMatches(NULL), fNFailed(0), fNOutside(0), fNMulti(0), fNADCChannels(256), fQMax(500000), fQThreshold(10000), fMeanNoise(1500), fSpotRadius(0.05), fMeanGasGain(1e4), fDTime(3), fDeadPadsFrac(0), fTimer(), fMcChain(NULL), //fDeadTime(400), fDriftVelocity(100), //fPeakingTime(20), //fRemainderTime(40), fTimeBinWidth(1), fNTimeBins(200), fTOT(0), fTotalDriftTime(0.4/fDriftVelocity*10000), // 40 ns fSigma(), fMPV(), fIsLight(1), // fIsLight = 1 (default) Store Light CbmMuchDigiMatch in output branch, fIsLight = 0 Create Heavy CbmMuchDigiMatch with fSignalShape info. fTimePointLast(-1), fTimeDigiFirst(-1), fTimeDigiLast(-1), fNofPoints(0), fNofSignals(0), fNofDigis(0), fNofEvents(0), fNofPointsTot(0.), fNofSignalsTot(0.), fNofDigisTot(0.), fTimeTot(), fAddressCharge(), fGenerateElectronicsNoise(kFALSE), fPerPadNoiseRate(10e-9), fNoiseCharge(nullptr) { fSigma[0] = new TF1("sigma_e","pol6",-5,10); fSigma[0]->SetParameters(sigma_e); fSigma[1] = new TF1("sigma_mu","pol6",-5,10); fSigma[1]->SetParameters(sigma_mu); fSigma[2] = new TF1("sigma_p","pol6",-5,10); fSigma[2]->SetParameters(sigma_p); fMPV[0] = new TF1("mpv_e","pol6",-5,10); fMPV[0]->SetParameters(mpv_e); fMPV[1] = new TF1("mpv_mu","pol6",-5,10); fMPV[1]->SetParameters(mpv_mu); fMPV[2] = new TF1("mpv_p","pol6",-5,10); fMPV[2]->SetParameters(mpv_p); Reset(); fNoiseCharge = new TF1("Noise Charge", "TMath::Gaus(x, [0], [1])", fQThreshold, fQMax/10); //noise function to calculate charge for noise hit. mean=fQThreashold(10000),fQMax=500000 } // ------------------------------------------------------------------------- // ------------------------------------------------------------------------- CbmMuchDigitizeGem::CbmMuchDigitizeGem(const char* digiFileName, Int_t flag) : CbmDigitize("MuchDigitizeGem"), //fgDeltaResponse(), fAlgorithm(1), fGeoScheme(CbmMuchGeoScheme::Instance()), fDigiFile(digiFileName), fFlag(flag), fPoints(NULL), fMCTracks(NULL), fDigis(NULL), fDigiMatches(NULL), fNFailed(0), fNOutside(0), fNMulti(0), fNADCChannels(256), fQMax(500000), fQThreshold(10000), fMeanNoise(1500), fSpotRadius(0.05), fMeanGasGain(1e4), fDTime(3), fDeadPadsFrac(0), fTimer(), fMcChain(NULL), //fDeadTime(400), fDriftVelocity(100), //fPeakingTime(20), //fRemainderTime(40), fTimeBinWidth(1), fNTimeBins(200), fTOT(0), fTotalDriftTime(0.4/fDriftVelocity*10000), // 40 ns fSigma(), fMPV(), fIsLight(1), // fIsLight = 1 (default) Store Light CbmMuchDigiMatch in output branch, fIsLight = 0 Create Heavy CbmMuchDigiMatch with fSignalShape info. fTimePointLast(-1), fTimeDigiFirst(-1), fTimeDigiLast(-1), fNofPoints(0), fNofSignals(0), fNofDigis(0), fNofEvents(0), fNofPointsTot(0.), fNofSignalsTot(0.), fNofDigisTot(0.), fTimeTot(), fAddressCharge(), fGenerateElectronicsNoise(kFALSE), fPerPadNoiseRate(10e-9), fNoiseCharge(nullptr) { fSigma[0] = new TF1("sigma_e","pol6",-5,10); fSigma[0]->SetParameters(sigma_e); fSigma[1] = new TF1("sigma_mu","pol6",-5,10); fSigma[1]->SetParameters(sigma_mu); fSigma[2] = new TF1("sigma_p","pol6",-5,10); fSigma[2]->SetParameters(sigma_p); fMPV[0] = new TF1("mpv_e","pol6",-5,10); fMPV[0]->SetParameters(mpv_e); fMPV[1] = new TF1("mpv_mu","pol6",-5,10); fMPV[1]->SetParameters(mpv_mu); fMPV[2] = new TF1("mpv_p","pol6",-5,10); fMPV[2]->SetParameters(mpv_p); Reset(); fNoiseCharge = new TF1("Noise Charge", "TMath::Gaus(x, [0], [1])", fQThreshold, fQMax/10); //noise function to calculate charge for noise hit. mean=fQThreashold(10000),fQMax=500000 } // ------------------------------------------------------------------------- // ----- Destructor ---------------------------------------------------- CbmMuchDigitizeGem::~CbmMuchDigitizeGem() { if (fDigis) { fDigis->Delete(); delete fDigis; } if (fDigiMatches) { fDigiMatches->Delete(); delete fDigiMatches; } delete fSigma[0]; delete fSigma[1]; delete fSigma[2]; delete fMPV[0]; delete fMPV[1]; delete fMPV[2]; } // ------------------------------------------------------------------------- // ----- Private method Reset ------------------------------------------- void CbmMuchDigitizeGem::Reset() { fTimeDigiFirst = fTimeDigiLast = -1; fNofPoints = fNofSignals = fNofDigis = 0; } // ------------------------------------------------------------------------- // ----- Private method Init ------------------------------------------- InitStatus CbmMuchDigitizeGem::Init() { // Screen output std::cout << std::endl; LOG(INFO) << "==========================================================" << FairLogger::endl; LOG(INFO) << GetName() << ": Initialisation" << FairLogger::endl << FairLogger::endl; FairRootManager* ioman = FairRootManager::Instance(); if (!ioman) Fatal("Init", "No FairRootManager"); if ( fEventMode ) { LOG(INFO) << fName << ": Using event-by-event mode" << FairLogger::endl; } // Get geometry version tag gGeoManager->CdTop(); TGeoNode* cave = gGeoManager->GetCurrentNode(); // cave TString geoTag; for (Int_t iNode = 0; iNode < cave->GetNdaughters(); iNode++) { TString name = cave->GetDaughter(iNode)->GetVolume()->GetName(); if ( name.Contains("much", TString::kIgnoreCase) ) { geoTag = TString(name(5, name.Length() - 5)); LOG(INFO) << fName << ": MUCH geometry tag is " << geoTag << FairLogger::endl; break; } //? node is MUCH } //# top level nodes // Set the parameter file and the flag, if not done in constructor if ( fDigiFile.IsNull() ) { if ( geoTag.IsNull() ) LOG(FATAL) << fName << ": no parameter file specified and no MUCH node found in geometry!" << FairLogger::endl; fDigiFile = gSystem->Getenv("VMCWORKDIR"); // TODO: (VF) A better naming convention for the geometry tag and the // corresponding parameter file is surely desirable. fDigiFile += "/parameters/much/much_" + geoTag(0,4) + "_digi_sector.root"; LOG(INFO) << fName << ": Using parameter file " << fDigiFile << FairLogger::endl; fFlag = (geoTag.Contains("mcbm", TString::kIgnoreCase) ? 1 : 0); LOG(INFO) << fName << ": Using flag " << fFlag << (fFlag ? " (mcbm) " : "(standard)") << FairLogger::endl; } // Initialize GeoScheme TFile* oldfile=gFile; TFile* file=new TFile(fDigiFile); if ( ! file->IsOpen() ) LOG(FATAL) << fName << ": parameter file " << fDigiFile << " does not exist!" << FairLogger::endl; TObjArray* stations = (TObjArray*) file->Get("stations"); file->Close(); file->Delete(); gFile=oldfile; fGeoScheme->Init(stations,fFlag); // Determine drift volume width Double_t driftVolumeWidth = 0.4; // cm - default for (Int_t i=0;iGetNStations();i++){ CbmMuchStation* station = fGeoScheme->GetStation(i); if (station->GetNLayers()<=0) continue; CbmMuchLayerSide* side = station->GetLayer(0)->GetSide(0); if (side->GetNModules()<=0) continue; CbmMuchModule* module = side->GetModule(0); if (module->GetDetectorType()!=1 && module->GetDetectorType()!=3) continue; driftVolumeWidth = module->GetSize().Z(); break; } fTotalDriftTime = driftVolumeWidth/fDriftVelocity*10000; // [ns]; //Reading MC point as Event by event for time based digi generation also. // Get input array of MuchPoints fPoints = (TClonesArray*) ioman->GetObject("MuchPoint"); assert( fPoints ); // Get input array of MC tracks fMCTracks = (TClonesArray*) ioman->GetObject("MCTrack"); assert( fMCTracks ); // Register output arrays fDigis = new TClonesArray("CbmMuchDigi", 1000); ioman->Register("MuchDigi", "Digital response in MUCH", fDigis, kTRUE); fDigiMatches = new TClonesArray("CbmMuchDigiMatch", 1000); ioman->Register("MuchDigiMatch", "Digi Match in MUCH", fDigiMatches, kTRUE); //fgDeltaResponse is used in the CbmMuchSignal for analysing the Signal Shape, //it is generated once in the digitizer and then be used by each CbmMuchSignal. //For reducing the time therefore generated once in the CbmMuchDigitize Gem and //not generated in the CbmMuchSignal // Set response on delta function // Not using fSignalShape as consuming memory. Commening all the field related. //Int_t nShapeTimeBins=Int_t(gkResponsePeriod/gkResponseBin); //fgDeltaResponse.Set(nShapeTimeBins); //for (Int_t i=0;iGetEntriesFast() << " MuchPoints " << FairLogger::endl; //ReadAndRegister(fCurrentEventTime); for (Int_t iPoint=0; iPointGetEntriesFast(); iPoint++) { const CbmMuchPoint* point = (const CbmMuchPoint*) fPoints->At(iPoint); LOG(DEBUG1) << GetName() << ": Processing MCPoint " << iPoint << FairLogger::endl; assert( point ); ExecPoint(point, iPoint); fNofPoints++; } // MuchPoint loop if( fEventMode ) ReadAndRegister(-1); else ReadAndRegister(fCurrentEventTime); // --- Event log LOG(INFO) << "+ " << setw(15) << GetName() << ": Event " << setw(6) << right << fCurrentEvent << " at " << fixed << setprecision(3) << fCurrentEventTime << " ns, points: " << fNofPoints << ", signals: " << fNofSignals << ", digis: " << fNofDigis << ". Exec time " << setprecision(6) << fTimer.RealTime() << " s." << FairLogger::endl; // --------------------NOISE---------------------- // if (fGenerateElectronicsNoise) { fPreviousEventTime = fNofEvents ? fPreviousEventTime : 0.; Int_t nNoise = GenerateNoise(fPreviousEventTime,fCurrentEventTime); fNofNoiseTot += nNoise; //noise->Fill(nNoise); LOG(INFO) << "+ " << setw(20) << GetName() << ": Generated " << nNoise << " noise signals from t = " << fPreviousEventTime << " ns to " << fCurrentEventTime << " ns" << FairLogger::endl; LOG(DEBUG3) << "+ " << setw(20) << GetName() << ": Generated " << fNofNoiseSignals << " noise signals for this time slice from t = " << fPreviousEventTime << " ns to " << fCurrentEventTime << "ns" << FairLogger::endl; } LOG(INFO) << "+ " << setw(20) << GetName() << " : " << fNofNoiseTot << " total noise generated till now." << FairLogger::endl; fPreviousEventTime = fCurrentEventTime ; fTimer.Stop(); fNofEvents++; fNofPointsTot += fNofPoints; fNofSignalsTot += fNofSignals; fNofDigisTot += fNofDigis; fTimeTot += fTimer.RealTime(); } Int_t CbmMuchDigitizeGem::GenerateNoise(Double_t t1, Double_t t2){ LOG(DEBUG) << "+ " << setw(20) << GetName()<< ": Previous Time " << fPreviousEventTime << " Current Time " << fCurrentEventTime << "ns" << FairLogger::endl; assert( t2 > t1 ); Int_t numberofstations=fGeoScheme->GetNStations(); auto StationNoise = 0; for (Int_t i=0;iGetStation(i); auto numberoflayers=station->GetNLayers(); if (numberoflayers<=0) continue; auto LayerNoise = 0; for (Int_t j=0;jGetLayer(j)->GetSide(0); auto numberofmodules=side->GetNModules(); if (numberofmodules<=0) continue; auto FrontModuleNoise = 0; for (auto k=0;kGetModule(k)); if (module->GetDetectorType()!=1 && module->GetDetectorType()!=3) continue; FrontModuleNoise += GenerateNoisePerModule(module,t1,t2); } side = station->GetLayer(j)->GetSide(1); numberofmodules=side->GetNModules(); if (numberofmodules<=0) continue; auto BackModuleNoise = 0; for (auto k=0;kGetModule(k); if (module->GetDetectorType()!=1 && module->GetDetectorType()!=3) continue; BackModuleNoise += GenerateNoisePerModule(module,t1,t2); } LayerNoise+=FrontModuleNoise+BackModuleNoise; } LOG(DEBUG1) << "+ " << setw(20) << GetName() << ": Generated " << LayerNoise << " noise signals in station " << i <<" from t = " << fPreviousEventTime << " ns to " << fCurrentEventTime << " ns" << FairLogger::endl; StationNoise+=LayerNoise; } return StationNoise; } //================================Generte Noise==============================================// Int_t CbmMuchDigitizeGem::GenerateNoisePerModule(CbmMuchModuleGem* module, Double_t t1,Double_t t2) { auto NumberOfPad = module->GetNPads(); Double_t nNoiseMean = fPerPadNoiseRate * NumberOfPad * ( t2 - t1 ); Int_t nNoise = gRandom->Poisson(nNoiseMean); LOG(DEBUG) << "+ " << setw(20) << GetName() << ": Number of noise signals : " << nNoise << " in one module. "<< FairLogger::endl; for (Int_t iNoise = 0; iNoise <= nNoise; iNoise++) { Int_t padnumber = Int_t(gRandom->Uniform(Double_t(NumberOfPad))); CbmMuchPad *pad = module->GetPad(padnumber); Double_t NoiseTime = gRandom->Uniform(t1, t2); Double_t charge = fNoiseCharge->GetRandom(); while(charge<0) charge = fNoiseCharge->GetRandom(); AddNoiseSignal(pad, NoiseTime, charge); } //noise->Fill(nNoise); return nNoise; } //=================Add a signal to the buffer=====================// void CbmMuchDigitizeGem::AddNoiseSignal(CbmMuchPad* pad, Double_t time,Double_t charge) { assert(pad); LOG(DEBUG3) << GetName() << ": Receiving signal " << charge << " in channel " << pad->GetAddress() << " at time " << time << "ns" << FairLogger::endl; // LOG(DEBUG) << GetName() << ": discarding signal in dead channel " // << channel << FairLogger::endl; // return; CbmMuchSignal* signal = new CbmMuchSignal(pad->GetAddress(),time); //signal->SetTimeStart(time); //signal->SetTimeStop(time+fDeadTime); signal->SetCharge((UInt_t)charge); UInt_t address = pad->GetAddress(); CbmMuchReadoutBuffer::Instance()->Fill(address, signal); fNofNoiseSignals++; LOG(DEBUG3)<< "+ " << setw(20) << GetName() <<": Registered a Noise CbmMuchSignal into the CbmMuchReadoutBuffer. Number of Noise Signal generated "<< fNofNoiseSignals < SignalList; //Event Time should be passed with the Call /*Double_t eventTime = -1.; if(fDaq){ eventTime = FairRun::Instance()->GetEventHeader()->GetEventTime(); }*/ Int_t ReadOutSignal = CbmMuchReadoutBuffer::Instance()->ReadOutData(eventTime,SignalList); LOG(DEBUG) << GetName() << ": Number of Signals read out from Buffer "<< ReadOutSignal << " and SignalList contain " << SignalList.size() << " entries."<::iterator LoopOver= SignalList.begin(); LoopOver != SignalList.end(); LoopOver++) { CbmMuchDigi* digi = ConvertSignalToDigi(*LoopOver); //assert(digi); if (!digi){ LOG(DEBUG2)<< GetName() << ": Digi not created as signal is below threshold."<GetCharge() < fQThreshold) return (NULL); Long64_t TimeStamp = signal->GetTimeStamp(); // Int_t TimeStamp = signal->GetTimeStamp(fQThreshold); // // if (TimeStamp < 0) return (NULL);//entire signal is below threshold, no digi generation. CbmMuchDigi *digi = new CbmMuchDigi(); digi->SetAddress(signal->GetAddress()); //Charge in number of electrons, need to be converted in ADC value digi->SetAdc((signal->GetCharge())*fNADCChannels/fQMax);//Charge should be computed as per Electronics Response. digi->SetTime(TimeStamp); // Create new match object. If one uses the pointer from the CbmMuchSignal // it is not possible to remove the CbmMuchSignal CbmMatch* digiMatch = new CbmMatch(*signal->GetMatch()); digi->SetMatch(digiMatch); // Update times of first and last digi fTimeDigiFirst = fNofDigis ? TMath::Min(fTimeDigiFirst, Double_t(TimeStamp)) : TimeStamp; fTimeDigiLast = TMath::Max(fTimeDigiLast, Double_t(TimeStamp)); // digi->SetPileUp(); // digi->SetDiffEvent(); return(digi); } // ------------------------------------------------------------------------- void CbmMuchDigitizeGem::Finish(){ // --- In event-by-event mode, the analogue buffer should be empty. if ( fEventMode ) { if ( CbmMuchReadoutBuffer::Instance()->GetNData() ) { LOG(INFO) << fName << ": " << CbmMuchReadoutBuffer::Instance()->GetNData() << " signals in readout buffer" << FairLogger::endl; LOG(FATAL) << fName << ": Readout buffer is not empty at end of run " << "in event-by-event mode!" << FairLogger::endl; } //? non-empty buffer } //? event-by-event mode else { // time-based mode fTimer.Start(); std::cout << std::endl; LOG(INFO) << GetName() << ": Finish run" << FairLogger::endl; Reset(); LOG(INFO) << fName << ": " << CbmMuchReadoutBuffer::Instance()->GetNData() << " signals in readout buffer" << FairLogger::endl; ReadAndRegister(-1.); // -1 means process all data LOG(INFO) << setw(15) << GetName() << ": Finish, points " << fNofPoints<< ", signals: " << fNofSignals << ", digis: " << fNofDigis << ". Exec time " << setprecision(6) << fTimer.RealTime() << " s." << FairLogger::endl; LOG(INFO) << fName << ": " << CbmMuchReadoutBuffer::Instance()->GetNData() << " signals in readout buffer" << FairLogger::endl; fTimer.Stop(); fNofPointsTot += fNofPoints; fNofSignalsTot += fNofSignals; fNofDigisTot += fNofDigis; fTimeTot += fTimer.RealTime(); } //? time-based mode //noise->Draw(); std::cout << std::endl; LOG(INFO) << "=====================================" << FairLogger::endl; LOG(INFO) << GetName() << ": Run summary" << FairLogger::endl; LOG(INFO) << "Events processed : " << fNofEvents << FairLogger::endl; LOG(INFO) << "MuchPoint / event : " << setprecision(1) << fNofPointsTot / Double_t(fNofEvents) << FairLogger::endl; LOG(INFO) << "MuchSignal / event : " << fNofSignalsTot / Double_t(fNofEvents) //<< " / " << fNofSignalsBTot / Double_t(fNofEvents) << FairLogger::endl; LOG(INFO) << "MuchDigi / event : " << fNofDigisTot / Double_t(fNofEvents) << FairLogger::endl; LOG(INFO) << "Digis per point : " << setprecision(6) << fNofDigisTot / fNofPointsTot << FairLogger::endl; LOG(INFO) << "Digis per signal : " << fNofDigisTot / fNofSignalsTot << FairLogger::endl; LOG(INFO) << "Noise digis / event : " << fNofNoiseTot / Double_t(fNofEvents) << FairLogger::endl; LOG(INFO) << "Noise fraction : " << fNofNoiseTot / fNofDigisTot << FairLogger::endl; LOG(INFO) << "Real time per event : " << fTimeTot / Double_t(fNofEvents) << " s" << FairLogger::endl; LOG(INFO) << "=====================================" << FairLogger::endl; //if (fDaq) ReadAndRegister(-1.); } // ------------------------------------------------------------------------- // ------- Private method ExecAdvanced ------------------------------------- Bool_t CbmMuchDigitizeGem::ExecPoint(const CbmMuchPoint* point, Int_t iPoint) { //std::cout<<" start execution "<PositionIn(v1); point->PositionOut(v2); dv = v2-v1; Bool_t Status; Int_t detectorId = point->GetDetectorID(); CbmMuchModule* module = fGeoScheme->GetModuleByDetId(detectorId); if (fAlgorithm==0){ // Simple digitization TVector3 v = 0.5*(v1+v2); CbmMuchPad* pad = 0; if (module->GetDetectorType()==1){ CbmMuchModuleGemRectangular* module1 = (CbmMuchModuleGemRectangular*) module; pad = module1->GetPad(v[0],v[1]); if (pad) printf("x0=%f,y0=%f\n",pad->GetX(),pad->GetY()); } else if (module->GetDetectorType()==3){ CbmMuchModuleGemRadial* module3 = (CbmMuchModuleGemRadial*) module; pad = module3->GetPad(v[0],v[1]); } if (!pad) return kFALSE; AddCharge(pad,fQMax,iPoint,point->GetTime(),0); return kTRUE; } // Start of advanced digitization Int_t nElectrons = Int_t(GetNPrimaryElectronsPerCm(point)*dv.Mag()); if (nElectrons<0) return kFALSE; Double_t time = point->GetTime(); if (module->GetDetectorType()==1) { CbmMuchModuleGemRectangular* module1 = (CbmMuchModuleGemRectangular*) module; map firedSectors; for (Int_t i=0;iRndm(); Double_t driftTime = (1-aL)*fTotalDriftTime; TVector3 ve = v1 + dv*aL; UInt_t ne = GasGain(); Double_t x = ve.X(); Double_t y = ve.Y(); Double_t x1 = x-fSpotRadius; Double_t x2 = x+fSpotRadius; Double_t y1 = y-fSpotRadius; Double_t y2 = y+fSpotRadius; Double_t s = 4*fSpotRadius*fSpotRadius; firedSectors[module1->GetSector(x1,y1)]=0; firedSectors[module1->GetSector(x1,y2)]=0; firedSectors[module1->GetSector(x2,y1)]=0; firedSectors[module1->GetSector(x2,y2)]=0; for (map::iterator it = firedSectors.begin(); it!= firedSectors.end(); it++) { CbmMuchSector* sector = (*it).first; if (!sector) continue; for (Int_t iPad=0;iPadGetNChannels();iPad++){ CbmMuchPad* pad = sector->GetPadByChannelIndex(iPad); Double_t xp0 = pad->GetX(); Double_t xpd = pad->GetDx()/2.; Double_t xp1 = xp0-xpd; Double_t xp2 = xp0+xpd; if (x1>xp2 || x2GetY(); Double_t ypd = pad->GetDy()/2.; Double_t yp1 = yp0-ypd; Double_t yp2 = yp0+ypd; if (y1>yp2 || y2xp1 ? (x2yp1 ? (y2GetDetectorType()==3) { fAddressCharge.clear(); CbmMuchModuleGemRadial* module3 = (CbmMuchModuleGemRadial*) module; if(!module3){ LOG(DEBUG) << GetName() << ": Not Processing MCPoint " << iPoint <<" because it is not on any GEM module."<< FairLogger::endl; return 1; } CbmMuchSectorRadial* sFirst = (CbmMuchSectorRadial*) module3->GetSectorByIndex(0); //First sector if(!sFirst){ LOG(DEBUG) << GetName() << ": Not Processing MCPoint " << iPoint <<" because it is on the module " << module3 <<" but not the first sector. "<< sFirst << FairLogger::endl; return 1; } CbmMuchSectorRadial* sLast = (CbmMuchSectorRadial*) module3->GetSectorByIndex(module3->GetNSectors()-1); //Last sector if(!sLast){ LOG(DEBUG) << GetName() << ": Not Processing MCPoint " << iPoint <<" because it is not the last sector of module."<< module3 << FairLogger::endl; return 1; } Double_t rMin =sFirst->GetR1(); //Mimimum radius of the Sector//5 Double_t rMax =sLast->GetR2(); //Maximum radius of the Sector//35 //cout<Gaus(0.5,0.133); //Generting random number for calculating Drift Time. driftTime = (1-aL)*fTotalDriftTime; } for (Int_t i=0;iRndm(); TVector3 ve = v1 + dv*RandomNumberForPrimaryElectronPosition; //------------------------Added by O. Singh 11.12.2017 for mCbm------------------------- Double_t r=0.0, phi=0.0; if(fFlag==1){//mCbm TVector3 nVe; Double_t XX = ve.X(); Double_t YY = ve.Y(); Double_t ZZ = ve.Z(); Double_t tX=11.8; Double_t tY=72.0; Double_t rAng = 168.5; Double_t nXX = (XX-tX)*cos(rAng*TMath::DegToRad())+(YY-tY)*sin(rAng*TMath::DegToRad());//Transfotamation of MuChpoints to pads position Double_t nYY = -(XX-tX)*sin(rAng*TMath::DegToRad())+(YY-tY)*cos(rAng*TMath::DegToRad()); Double_t nZZ = ZZ; nVe.SetX(nXX); nVe.SetY(nYY); nVe.SetZ(nZZ); r = nVe.Perp(); phi = nVe.Phi(); }else {//Cbm r = ve.Perp(); phi = ve.Phi(); } //-------------------------------------------------------------------------- UInt_t ne = GasGain(); //Number of secondary electrons Double_t r1 = r-fSpotRadius; Double_t r2 = r+fSpotRadius; Double_t phi1 = phi-fSpotRadius/r; Double_t phi2 = phi+fSpotRadius/r; if (r1rMin) {//Adding charge to the pad which is on Lower Boundary Status = AddCharge(sFirst,UInt_t(ne*(r2-rMin)/(r2-r1)),iPoint,time,driftTime,phi1,phi2); if(!Status)LOG(DEBUG) << GetName() << ": Processing MCPoint " << iPoint <<" in which Primary Electron : "<rMax) {//Adding charge to the pad which is on Upper Boundary Status = AddCharge(sLast,UInt_t(ne*(rMax-r1)/(r2-r1)),iPoint,time,driftTime,phi1,phi2); if(!Status)LOG(DEBUG) << GetName() << ": Processing MCPoint " << iPoint <<" in which Primary Electron : "<rMax && r2 >rMax) continue; CbmMuchSectorRadial* s1 = module3->GetSectorByRadius(r1); CbmMuchSectorRadial* s2 = module3->GetSectorByRadius(r2); if (s1==s2) {Status = AddCharge(s1,ne,iPoint,time,driftTime,phi1,phi2); if (!Status) LOG(DEBUG3) << GetName() << ": Processing MCPoint " << iPoint <<" in which Primary Electron : "<GetR2()-r1)/(r2-r1)),iPoint,time,driftTime,phi1,phi2); if(!Status)LOG(DEBUG3) << GetName() << ": Processing MCPoint " << iPoint <<" in which Primary Electron : "<GetR1())/(r2-r1)),iPoint,time,driftTime,phi1,phi2); if(!Status)LOG(DEBUG3) << GetName() << ": Processing MCPoint " << iPoint <<" in which Primary Electron : "<Rndm()); if (gasGain < 0.) gasGain = 1e6; return (Int_t) gasGain; } // ------------------------------------------------------------------------- // ------------------------------------------------------------------------- Double_t CbmMuchDigitizeGem::Sigma_n_e(Double_t Tkin, Double_t mass) { Double_t logT; if (mass < 0.1) { logT = log(Tkin * 0.511 / mass); if (logT > 9.21034) logT = 9.21034; if (logT < min_logT_e) logT = min_logT_e; return fSigma[0]->Eval(logT); } else if (mass >= 0.1 && mass < 0.2) { logT = log(Tkin * 105.658 / mass); if (logT > 9.21034) logT = 9.21034; if (logT < min_logT_mu) logT = min_logT_mu; return fSigma[1]->Eval(logT); } else { logT = log(Tkin * 938.272 / mass); if (logT > 9.21034) logT = 9.21034; if (logT < min_logT_p) logT = min_logT_p; return fSigma[2]->Eval(logT); } } // ------------------------------------------------------------------------- // ------------------------------------------------------------------------- Double_t CbmMuchDigitizeGem::MPV_n_e(Double_t Tkin, Double_t mass) { Double_t logT; if (mass < 0.1) { logT = log(Tkin * 0.511 / mass); if (logT > 9.21034) logT = 9.21034; if (logT < min_logT_e) logT = min_logT_e; return fMPV[0]->Eval(logT); } else if (mass >= 0.1 && mass < 0.2) { logT = log(Tkin * 105.658 / mass); if (logT > 9.21034) logT = 9.21034; if (logT < min_logT_mu) logT = min_logT_mu; return fMPV[1]->Eval(logT); } else { logT = log(Tkin * 938.272 / mass); if (logT > 9.21034) logT = 9.21034; if (logT < min_logT_p) logT = min_logT_p; return fMPV[2]->Eval(logT); } } // ------------------------------------------------------------------------- // ------------------------------------------------------------------------- Double_t CbmMuchDigitizeGem::GetNPrimaryElectronsPerCm(const CbmMuchPoint* point){ Int_t trackId = point->GetTrackID(); // Int_t eventId = point->GetEventID(); if (trackId < 0) return -1; /* Commented out on request of A. Senger from 22.01.2014 if (fDaq && eventId!=FairRootManager::Instance()->GetInTree()->GetBranch("MCTrack")->GetReadEntry()) FairRootManager::Instance()->GetInTree()->GetBranch("MCTrack")->GetEntry(eventId); */ CbmMCTrack* mcTrack = (CbmMCTrack*) fMCTracks->At(trackId); if (!mcTrack) return -1; Int_t pdgCode = mcTrack->GetPdgCode(); TParticlePDG *particle = TDatabasePDG::Instance()->GetParticle(pdgCode); // Assign proton hypothesis for unknown particles if (!particle) particle = TDatabasePDG::Instance()->GetParticle(2212); if (TMath::Abs(particle->Charge()) < 0.1) return -1; Double_t m = particle->Mass(); TLorentzVector p; p.SetXYZM(point->GetPx(),point->GetPy(),point->GetPz(),m); Double_t Tkin = p.E()-m; // kinetic energy of the particle Double_t sigma = CbmMuchDigitizeGem::Sigma_n_e(Tkin,m); // sigma for Landau distribution Double_t mpv = CbmMuchDigitizeGem::MPV_n_e(Tkin,m); // most probable value for Landau distr. Double_t n = gRandom->Landau(mpv, sigma); while (n > 5e4) n = gRandom->Landau(mpv, sigma); // restrict Landau tail to increase performance return m<0.1 ? n/l_e : n/l_not_e; } // ------------------------------------------------------------------------- // ------------------------------------------------------------------------- Bool_t CbmMuchDigitizeGem::AddCharge(CbmMuchSectorRadial* s,UInt_t ne, Int_t /*iPoint*/, Double_t /*time*/, Double_t /*driftTime*/, Double_t phi1, Double_t phi2){ CbmMuchPadRadial* pad1 = s->GetPadByPhi(phi1); if(!pad1) return kFALSE; //assert(pad1); has to check if any pad address is NULL CbmMuchPadRadial* pad2 = s->GetPadByPhi(phi2); if(!pad2) return kFALSE; //assert(pad2); has to check if any pad address is NULL if (pad1==pad2){ UInt_t address = pad1->GetAddress(); //Finding that if for the same address if already charge stored then add the charge. std::map::iterator it=fAddressCharge.find(address); if(it!=fAddressCharge.end()) it->second=it->second+ne; else fAddressCharge.insert(std::pair(address,ne)); // AddChargePerMC(pad1,ne,iPoint,time,driftTime); } else { Double_t phi = pad1 ? pad1->GetPhi2() : pad2 ? pad2->GetPhi1() : 0; UInt_t pad1_ne = UInt_t(ne*(phi-phi1)/(phi2-phi1)); UInt_t address = pad1->GetAddress(); //Finding that if for the same address if already charge stored then add the charge. std::map::iterator it=fAddressCharge.find(address); if(it!=fAddressCharge.end()) it->second=it->second+pad1_ne; else fAddressCharge.insert (std::pair(address,pad1_ne)); // AddChargePerMC(pad1,pad1_ne ,iPoint,time,driftTime); // Getting some segmentation fault a address = pad2->GetAddress(); //Finding that if for the same address if already charge stored then add the charge. it=fAddressCharge.find(address); if(it!=fAddressCharge.end()) it->second=it->second+ne-pad1_ne; else fAddressCharge.insert (std::pair(address,ne-pad1_ne)); // AddChargePerMC(pad2,ne-pad1_ne,iPoint,time,driftTime); } return kTRUE; } // ------------------------------------------------------------------------- // ------------------------------------------------------------------------- //Will remove this AddCharge, only used for simple and Rectangular Geometry. void CbmMuchDigitizeGem::AddCharge(CbmMuchPad* pad, UInt_t charge, Int_t iPoint, Double_t time, Double_t driftTime){ if (!pad) return; Long_t AbsTime = fCurrentEventTime + time + driftTime; //Creating a new Signal, it will be deleted by CbmReadoutBuffer() CbmMuchSignal* signal = new CbmMuchSignal(pad->GetAddress(),AbsTime); //signal->SetTimeStart(AbsTime); //signal->SetTimeStop(AbsTime+fDeadTime); signal->SetCharge(charge); //signal->MakeSignalShape(charge,fgDeltaResponse); signal->AddNoise(fMeanNoise); UInt_t address = pad->GetAddress(); //match->AddCharge(iPoint,charge,time+driftTime,fgDeltaResponse,time,eventNr,inputNr); CbmLink link(charge, iPoint, fCurrentEvent, fCurrentInput); //std::cout<<"Before AddLink"<< endl; (signal->GetMatch())->AddLink(link); //std::cout<<"After AddLink"<< endl; //Adding all these temporary signal into the CbmMuchReadoutBuffer CbmMuchReadoutBuffer::Instance()->Fill(address, signal); //Increasing number of signal by one. fNofSignals++; LOG(DEBUG4)<<" Registered the CbmMuchSignal into the CbmMuchReadoutBuffer "<GetEntriesFast() << " MuchPoints " << " and Number of pad hit is "<< fAddressCharge.size()<<"." << FairLogger::endl; //Loop on the fAddressCharge to store all the Signals into the CbmReadoutBuffer() //Generate one by one CbmMuchSignal from the fAddressCharge and store them into the CbmMuchReadoutBuffer. for(auto it=fAddressCharge.begin();it!=fAddressCharge.end();++it){ UInt_t address = it->first; //Creating a new Signal, it will be deleted by CbmReadoutBuffer() CbmMuchSignal* signal = new CbmMuchSignal(address,AbsTime); //signal->SetTimeStart(AbsTime); //signal->SetTimeStop(AbsTime+fDeadTime); //signal->MakeSignalShape(it->second,fgDeltaResponse); signal->SetCharge(it->second); signal->AddNoise(fMeanNoise); CbmLink link(signal->GetCharge(), iPoint, fCurrentEvent, fCurrentInput); (signal->GetMatch())->AddLink(link); //Adding all these temporary signal into the CbmMuchReadoutBuffer CbmMuchReadoutBuffer::Instance()->Fill(address, signal); //Increasing number of signal by one. fNofSignals++; LOG(DEBUG3)<<" Registered the CbmMuchSignal into the CbmMuchReadoutBuffer "<Delete(); if ( fDigiMatches ) fDigiMatches->Delete(); } // ------------------------------------------------------------------------- // ----- Write to output ----------------------------------------------- void CbmMuchDigitizeGem::WriteDigi(CbmDigi* digi) { CbmMuchDigi* muchDigi = dynamic_cast(digi); assert(digi); new ((*fDigis)[fDigis->GetEntriesFast()]) CbmMuchDigi(muchDigi); new ((*fDigiMatches)[fDigiMatches->GetEntriesFast()]) CbmMuchDigiMatch((CbmMuchDigiMatch*)digi->GetMatch()); } // ------------------------------------------------------------------------- ClassImp(CbmMuchDigitizeGem)