KVIonRangeTableMaterial* KVRangeYanez::MakeNaturallyOccuringElementMixture(Int_t z) { // create a material containing the naturally occuring isotopes of the given element, // weighted according to their abundance. if (!gNDTManager) { Error("MakeNaturallyOccuringElementMixture", "Nuclear data tables have not been initialised"); return NULL; } KVElementDensity* ed = (KVElementDensity*)gNDTManager->GetData(z, z, "ElementDensity"); if (!ed) { Error("AddElementalMaterial", "No element found in ElementDensity NDT-table with Z=%d", z); return 0x0; } TString state = "solid"; if (ed->IsGas()) state = "gas"; KVRangeYanezMaterial* mat = new KVRangeYanezMaterial(this, ed->GetElementName(), ed->GetElementSymbol(), state, ed->GetValue()); KVNucleus nuc(z); KVNumberList isotopes = nuc.GetKnownARange(); isotopes.Begin(); while (!isotopes.End()) { nuc.SetA(isotopes.Next()); Double_t abundance = nuc.GetAbundance() / 100.; if (abundance > 0.) mat->AddMixtureElement(z, nuc.GetA(), 1, abundance); } mat->Initialize(); return (KVIonRangeTableMaterial*)mat; }
//_____________________________________________________________________________________________________// KVIDGrid* KVIDTelescope::CalculateDeltaE_EGrid(TH2* haa_zz, Bool_t Zonly, Int_t npoints) { //Genere une grille dE-E (perte d'energie - energie residuelle) //Le calcul est fait pour chaque couple comptant de charge (Z) et masse (A) //au moins un coup dans l'histogramme haa_zz definit : // Axe X -> Z // Axe Y -> A // //- Si Zonly=kTRUE (kFALSE par defaut), pour un Z donne, le A choisi est la valeur entiere la //plus proche de la valeur moyenne <A> //- Si Zonly=kFALSE et que pour un Z donne il n'y a qu'un seul A associe, les lignes correspondants //a A-1 et A+1 sont ajoutes //- Si a un Z donne, il n'y a aucun A, pas de ligne tracee //un noyau de A et Z donne n'est considere que s'il retourne KVNucleus::IsKnown() = kTRUE // // Warning : the grid is not added to the list of the telescope and MUST BE DELETED by the user ! if (GetSize() <= 1) return 0; TClass* cl = new TClass(GetDefaultIDGridClass()); KVIDGrid* idgrid = (KVIDGrid*)cl->New(); delete cl; idgrid->AddIDTelescope(this); idgrid->SetOnlyZId(Zonly); KVDetector* det_de = GetDetector(1); if (!det_de) return 0; KVDetector* det_eres = GetDetector(2); if (!det_eres) return 0; KVNucleus part; Info("CalculateDeltaE_EGrid", "Calculating dE-E grid: dE detector = %s, E detector = %s", det_de->GetName(), det_eres->GetName()); KVIDCutLine* B_line = (KVIDCutLine*)idgrid->Add("OK", "KVIDCutLine"); Int_t npoi_bragg = 0; B_line->SetName("Bragg_line"); B_line->SetAcceptedDirection("right"); Double_t SeuilE = 0.1; for (Int_t nx = 1; nx <= haa_zz->GetNbinsX(); nx += 1) { Int_t zz = TMath::Nint(haa_zz->GetXaxis()->GetBinCenter(nx)); KVNumberList nlA; Double_t sumA = 0, sum = 0; for (Int_t ny = 1; ny <= haa_zz->GetNbinsY(); ny += 1) { Double_t stat = haa_zz->GetBinContent(nx, ny); if (stat > 0) { Double_t val = haa_zz->GetYaxis()->GetBinCenter(ny); nlA.Add(TMath::Nint(val)); sumA += val * stat; sum += stat; } } sumA /= sum; Int_t nA = nlA.GetNValues(); if (nA == 0) { Warning("CalculateDeltaE_EGrid", "no count for Z=%d", zz); } else { if (Zonly) { nlA.Clear(); nlA.Add(TMath::Nint(sumA)); } else { if (nA == 1) { Int_t aref = nlA.Last(); nlA.Add(aref - 1); nlA.Add(aref + 1); } } part.SetZ(zz); // printf("zz=%d\n",zz); nlA.Begin(); while (!nlA.End()) { Int_t aa = nlA.Next(); part.SetA(aa); // printf("+ aa=%d known=%d\n",aa,part.IsKnown()); if (part.IsKnown()) { //loop over energy //first find : // ****E1 = energy at which particle passes 1st detector and starts to enter in the 2nd one**** // E2 = energy at which particle passes the 2nd detector //then perform npoints calculations between these two energies and use these //to construct a KVIDZALine Double_t E1, E2; //find E1 //go from SeuilE MeV to det_de->GetEIncOfMaxDeltaE(part.GetZ(),part.GetA())) Double_t E1min = SeuilE, E1max = det_de->GetEIncOfMaxDeltaE(zz, aa); E1 = (E1min + E1max) / 2.; while ((E1max - E1min) > SeuilE) { part.SetEnergy(E1); det_de->Clear(); det_eres->Clear(); det_de->DetectParticle(&part); det_eres->DetectParticle(&part); if (det_eres->GetEnergy() > SeuilE) { //particle got through - decrease energy E1max = E1; E1 = (E1max + E1min) / 2.; } else { //particle stopped - increase energy E1min = E1; E1 = (E1max + E1min) / 2.; } } //add point to Bragg line Double_t dE_B = det_de->GetMaxDeltaE(zz, aa); Double_t E_B = det_de->GetEIncOfMaxDeltaE(zz, aa); Double_t Eres_B = det_de->GetERes(zz, aa, E_B); B_line->SetPoint(npoi_bragg++, Eres_B, dE_B); //find E2 //go from E1 MeV to maximum value where the energy loss formula is valid Double_t E2min = E1, E2max = det_eres->GetEmaxValid(part.GetZ(), part.GetA()); E2 = (E2min + E2max) / 2.; while ((E2max - E2min > SeuilE)) { part.SetEnergy(E2); det_de->Clear(); det_eres->Clear(); det_de->DetectParticle(&part); det_eres->DetectParticle(&part); if (part.GetEnergy() > SeuilE) { //particle got through - decrease energy E2max = E2; E2 = (E2max + E2min) / 2.; } else { //particle stopped - increase energy E2min = E2; E2 = (E2max + E2min) / 2.; } } // printf("z=%d a=%d E1=%lf E2=%lf\n",zz,aa,E1,E2); KVIDZALine* line = (KVIDZALine*)idgrid->Add("ID", "KVIDZALine"); if (TMath::Even(zz)) line->SetLineColor(4); line->SetAandZ(aa, zz); Double_t logE1 = TMath::Log(E1); Double_t logE2 = TMath::Log(E2); Double_t dLog = (logE2 - logE1) / (npoints - 1.); for (Int_t i = 0; i < npoints; i++) { Double_t E = TMath::Exp(logE1 + i * dLog); Double_t Eres = 0.; Int_t niter = 0; while (Eres < SeuilE && niter <= 20) { det_de->Clear(); det_eres->Clear(); part.SetEnergy(E); det_de->DetectParticle(&part); det_eres->DetectParticle(&part); Eres = det_eres->GetEnergy(); E += SeuilE; niter += 1; } if (!(niter > 20)) { Double_t dE = det_de->GetEnergy(); Double_t gEres, gdE; line->GetPoint(i - 1, gEres, gdE); line->SetPoint(i, Eres, dE); } } } } } } return idgrid; }
void KV_CCIN2P3_GE::Run() { //Processes the job requests for the batch system. //In normal mode, this submits one job for the data analyser fAnalyser //In multijobs mode, this submits one job for each run in the runlist associated to fAnalyser if (!CheckJobParameters()) return; if (MultiJobsMode()) { if (fAnalyser->InheritsFrom("KVDataSetAnalyser")) { //submit jobs for every GetRunsPerJob() runs in runlist KVDataSetAnalyser* ana = dynamic_cast<KVDataSetAnalyser*>(fAnalyser); KVNumberList runs = ana->GetRunList(); runs.Begin(); Int_t remaining_runs = runs.GetNValues(); fCurrJobRunList.Clear(); while (remaining_runs && !runs.End()) { Int_t run = runs.Next(); remaining_runs--; fCurrJobRunList.Add(run); if ((fCurrJobRunList.GetNValues() == GetRunsPerJob()) || runs.End()) { // submit job for GetRunsPerJob() runs (or less if we have reached end of runlist 'runs') ana->SetRuns(fCurrJobRunList, kFALSE); ana->SetFullRunList(runs); SubmitJob(); fCurrJobRunList.Clear(); } } ana->SetRuns(runs, kFALSE); } else if (fAnalyser->InheritsFrom("KVSimDirAnalyser")) { // here we understand "run" to mean "file" KVSimDirAnalyser* ana = dynamic_cast<KVSimDirAnalyser*>(fAnalyser); TList* file_list = ana->GetFileList(); Int_t remaining_runs = ana->GetNumberOfFilesToAnalyse(); fCurrJobRunList.Clear(); TList cur_file_list; TObject* of; TIter it(file_list); Int_t file_no = 1; while ((of = it())) { cur_file_list.Add(of); fCurrJobRunList.Add(file_no); remaining_runs--; file_no++; if ((fCurrJobRunList.GetNValues() == GetRunsPerJob()) || (remaining_runs == 0)) { // submit job for GetRunsPerJob() files (or less if we have reached end of list) ana->SetFileList(&cur_file_list); SubmitJob(); fCurrJobRunList.Clear(); cur_file_list.Clear(); } } ana->SetFileList(file_list); } } else { SubmitJob(); } }
void CsICalib::InitTelescopeChioSi(Int_t ci_num, Int_t si_num) { Char_t si_name [128] = "null"; Char_t ci_name [128] = "null"; sprintf(si_name, "SIE_%02i", si_num+1); sprintf(ci_name, "CI_%02i", ci_num); Char_t tel_name [128] = "null"; //sprintf(tel_name, "CI_%02i_SIE_%02i", ci_num, si_num+1); sprintf(tel_name, "CI_01_SIE_18"); //Similar grids (using energies) for all Chio-Si combinaisons //cout<<"tel_name 1: "<<tel_name<<endl; list_chiosi = 0; // KVList *grid_list = 0; kvid_chiosi = 0; KVNumberList runList = 0; list_chiosi = (KVList*) gIDGridManager->GetGrids(); if(list_chiosi != 0){ //cout<<"list_chiosi!=0"<<endl; Int_t entries = (Int_t) list_chiosi->GetEntries(); // Int_t kHasGrids = 0; KVIDGrid *tmpGrid = 0; // Int_t nGridsForRun = 0; for(Int_t i=0; i<entries; i++){ tmpGrid = (KVIDGrid*) list_chiosi->At(i); if(tmpGrid != 0){ //cout<<"tmpGrid!=0"<<endl; runList = (KVNumberList) tmpGrid->GetRuns(); runList.Begin(); while( !runList.End() ){ UInt_t next_val = (UInt_t) runList.Next(); if(next_val == gIndra->GetCurrentRunNumber()){ //cout<<"next_val : "<<next_val<<endl; //L->Log<<"name : "<<tmpGrid->GetName()<<endl; if(strcmp(tmpGrid->GetName(),tel_name)==0){ //L->Log<<"tel_name 2 : "<<tmpGrid->GetName()<<endl; //cout<<"tel_name 2: "<<tel_name<<endl; kvid_chiosi = tmpGrid; } } } } } if(kvid_chiosi != 0){ }else{ printf("Error: 'kvid_chiosi' assignment failed\n"); cout<<"ci_num : "<<ci_num<<" si_num : "<<si_num+1<<endl; cout<<"name : "<<tel_name<<endl; } }else{ //printf("Error: 'list' assignment failed\n"); } return; }