// // pulseFit.C // Obtaining the integral of the pulse shape (between the roots) // representing the amount of collected charge // // Created by Christian Elsasser on 31.05.13. // University of Zurich, elsasser@cern.ch // Copyright only for commercial use // // Compile with: // g++ -o pulseFit pulseFit.C `root-config --glibs --cflags` -lRooFit -lRooFitCore -lEG // // General include #include <iostream> #include <fstream> #include <vector> #include <map> #include <stdlib.h> #include <limits> #include <string> #include <time.h> // ROOT include #include "../../include/incBasicROOT.h" #include "../../include/incFuncROOT.h" #include "../../include/incDrawROOT.h" #include "../../include/incGraphROOT.h" #include "../../include/incIOROOT.h" #include "../../include/basicROOTTools.h" #include "../../include/lhcbstyle.C" #include "deplTool.h" // -d detector (TT/IT) // -l layer (TTaX,TTaU,TTbV,TTbX, T[1-3]{X1,U,V,X2}) // -s read-out sector number // -f fill number // -c Voltage step [0-10] // -r consider only hit in a distance closer than r mm from the beam axis // -v number of summed up strips // -ns Do not save the value in the root file // -ss Perform a temporary save int pulseFit(int argc, char* argv[]); int main(int argc, char* argv[]){ TStyle* style = lhcbStyle(); int argc_copy = argc; TApplication* theApp = new TApplication("Analysis", &argc, argv); argc = theApp->Argc(); argv = theApp->Argv(); bool runBatch = false; for (int i = 1; i<argc; i++) { if (strcmp(argv[i],"-b")==0) { runBatch = true; gROOT->SetBatch(); } } int exit = pulseFit(argc,argv); Printf("End"); if (!runBatch) { theApp->Run(!runBatch); } return exit; } // Executable method int pulseFit(int argc, char* argv[]){ TVectorD v_res(11); gStyle->SetPadLeftMargin(0.20); gStyle->SetTitleOffset(1.5,"Y"); gStyle->SetTitleOffset(1.0,"X"); const char* diskVar = std::getenv ("DISK"); int fill = 2083; TString det("TT"); TString lay("TTaU"); int sector = 2634; int caliStep = 0; int val = 3; bool notSave = false; bool temSave = false; double radius = -10.0; for (int i=1; i<argc; i++) { if (strcmp(argv[i],"-d")==0 && i+1<argc) { det = argv[++i]; }else if (strcmp(argv[i],"-l")==0 && i+1<argc) { lay = argv[++i]; }else if (strcmp(argv[i],"-s")==0 && i+1<argc) { sector = std::atoi(argv[++i]); }else if (strcmp(argv[i],"-f")==0 && i+1<argc) { fill = std::atoi(argv[++i]); }else if (strcmp(argv[i],"-v")==0 && i+1<argc) { val = std::atoi(argv[++i]); }else if (strcmp(argv[i],"-c")==0 && i+1<argc) { caliStep = std::atoi(argv[++i]); }else if (strcmp(argv[i],"-r")==0 && i+1<argc) { radius = std::atof(argv[++i]); }else if (strcmp(argv[i],"-ns")==0) { notSave = true; }else if (strcmp(argv[i],"-ss")==0) { temSave = true; } } int voltStep = caliStep; double volt = 0.0; // Vectors to store the ADC and time values obtained in the landau fit std::vector<double> v_time_val; std::vector<double> v_time_err; std::vector<double> v_adc_val; std::vector<double> v_adc_err; double time = STTool::GetTime(caliStep, fill); // Get the correct voltage value if (det.EqualTo("TT")) { volt = STTool::GetTTVoltage(caliStep*6); }else{ volt = STTool::GetITVoltage(caliStep*6); } // Name of the vector where the result is stored TString vn_result(Form("v_pulse%d_val%d",caliStep,val)); // Directory and file name for the plots TString dn_graph(Form("%s/data/ST/graphics/%s/%s/%d/%d", diskVar,det.Data(),lay.Data(),sector,fill)); TString fn_graph_p(Form("%s/pulse_%d_val%d", dn_graph.Data(),caliStep,val)); // Dealing with the radius if (radius<0.0) { }else{ vn_result +=Form("_r%d",(int)radius); fn_graph_p +=Form("_r%d",(int)radius); } fn_graph_p += ".pdf"; Printf("========================================="); Info("pulseFit","Analyze: "); Printf(" Sector: %d",sector); if (radius>0.0) { Printf(" Radius: %4.2f mm",radius); } Printf(" Fill: %d",fill); Printf(" Detector: %s",det.Data()); Printf(" Layer: %s",lay.Data()); Printf(" Voltage: %4.2f V",volt); // Directory and file name for the input data TString dn_data(Form("%s/data/ST/Aging" ,diskVar)); TString fn_data(Form("%s/CCEScan.root", dn_data.Data())); TString fn_dummy(Form("%s/check",dn_data.Data())); if (temSave) { fn_data= TString(Form("%s/temp_%s_%s_%d_%d_r%d.root", dn_data.Data(),det.Data(),lay.Data(), sector,fill,(int)radius)); } TFile* f_data = TFile::Open(fn_data.Data()); if (!f_data) { Error("pulseFit","Data file does not exist!"); Printf("=========================================\n"); return EXIT_FAILURE; } // Loading the values from the Landau distribution fits and the corresponding time Info("pulseFit","Loading data:"); TString dn_input(Form("%s/%s/%d/%d", det.Data(), lay.Data(), sector, fill)); for (int i=6*caliStep; i<6*caliStep+6; i++) { TString vn_input(Form("%s/v_%d_val%d",dn_input.Data(),i,val)); if (radius>0.0) { vn_input +=Form("_r%d",(int)radius); } TVectorD* v_input = (TVectorD*)f_data->Get(vn_input.Data()); if (!v_input) { Warning("pulseFit","Vector %s not available",vn_input.Data()); continue; } Printf(" %8.2f ns: %8.4f+/-%8.4f",STTool::GetTime(i,fill),(*v_input)(0),(*v_input)(1)); if (i==6*caliStep) { v_res(6) = (*v_input)(0); v_res(7) = (*v_input)(1); } // Excluding steps bad data quality if (i==0 && (fill==2797 || fill==3108)) { Info("pulseFit","Bad calibration step! Skip it!"); continue; } v_adc_val.push_back((*v_input)(0)); v_adc_err.push_back((*v_input)(1)); v_time_val.push_back(STTool::GetTime(i,fill)); v_time_err.push_back(0.0); } if (v_adc_val.size()<3) { Error("pulseFit","Too few (%d) data points",v_adc_val.size()); Printf("=========================================\n"); return EXIT_FAILURE; } // Transform STL vectors into ROOT vectors TVectorD vr_adc_val = getROOTVector(v_adc_val); TVectorD vr_adc_err = getROOTVector(v_adc_err); TVectorD vr_time_val = getROOTVector(v_time_val); TVectorD vr_time_err = getROOTVector(v_time_err); TGraphErrors* ge_pulse = new TGraphErrors(vr_time_val,vr_adc_val,vr_time_err,vr_adc_err); // Fit the pulse shape TF1* fu_pulse = STTool::halfGauss; ge_pulse->Fit(fu_pulse,"M0Q","0"); double chi2ndf = fu_pulse->GetChisquare()/fu_pulse->GetNDF(); Info("pulseFit","#chi^{2}/ndf: %6.2f/%d",fu_pulse->GetChisquare(),fu_pulse->GetNDF()); // Make PDG-like correction of the uncertainties /*Michele if (chi2ndf>1.0) { Info("pulseFit","scaling"); vr_adc_err*=TMath::Sqrt(chi2ndf); } //Michele*/ TMultiGraph* mg_pulse = new TMultiGraph("mg_pulse","Pulse multigraph"); ge_pulse = new TGraphErrors(vr_time_val,vr_adc_val,vr_time_err,vr_adc_err); ge_pulse->Fit(fu_pulse,"M0Q","0"); TVirtualFitter *fit_volt = TVirtualFitter::GetFitter(); Double_t* cov_volt = fit_volt->GetCovarianceMatrix(); double maxPos = 3-TMath::Sqrt(3); double maxFac = TMath::Exp(-maxPos)*(maxPos*maxPos/2.0-maxPos*maxPos*maxPos/6.0); double max_val = maxFac*fu_pulse->GetParameter(0); double max_err = maxFac*fu_pulse->GetParError(0); double tau_val = fu_pulse->GetParameter(2); double tau_err = fu_pulse->GetParError(2); double t0_val = fu_pulse->GetParameter(1); double t0_err = fu_pulse->GetParError(1); // Calculate integrale; factor 1/20 is included such that the maximal value of the pulse and the integral have // a similar numerical value double int_val = 9.0/2.0*TMath::Exp(-3.0)*fu_pulse->GetParameter(0)*tau_val/20.0; double int_err = int_val*TMath::Sqrt(TMath::Power(fu_pulse->GetParError(0)/fu_pulse->GetParameter(0),2)+ TMath::Power(tau_err/tau_val,2)+ 2.0*cov_volt[2]/(tau_val*fu_pulse->GetParameter(0)) ); mg_pulse->Add(ge_pulse,"pe"); Info("pulseFit","pulse Height: %8.4f+/-%8.4f",max_val,max_err); Info("pulseFit"," tau: %8.4f+/-%8.4f ns",tau_val,tau_err); Info("pulseFit"," charge eq: %8.4f+/-%8.4f",int_val,int_err); // Plot pulse TCanvas* c_pul = new TCanvas("c_pul","Pulse Canvas",800,600); mg_pulse->Draw("A"); fu_pulse->Draw("Same"); mg_pulse->Draw(""); mg_pulse->GetXaxis()->SetLimits(-30.0,30.0); mg_pulse->GetXaxis()->SetTitle("#delta#it{t} [ns]"); mg_pulse->SetMaximum( 1.2*max_val); mg_pulse->SetMinimum(0.0); mg_pulse->GetYaxis()->SetTitle("MPV [ADC value]"); TLine* line = new TLine(-30.0,0.0,30.0,0.0); //line->Draw(); mg_pulse->GetHistogram()->Draw("axissame"); // 0,1: Maximal signal height v_res(0) = max_val; v_res(1) = max_err; // 2,3: tau (width of pulse) v_res(2) = tau_val; v_res(3) = tau_err; // 4,5: t0 (first root)b v_res(4) = t0_val; v_res(5) = t0_err; // 6,7: covariance (tau,A0) (t0,A0) (t0,tau) v_res(8) = cov_volt[1]; v_res(9) = cov_volt[2]; v_res(10)= cov_volt[5]; // Write the data and the plots while (!gSystem->Exec(Form("ls %s &> /dev/null",fn_dummy.Data()))) { Info("landauFit","Waiting until file is closed"); gSystem->Sleep(1000); } gSystem->Exec(Form("touch %s &> /dev/null",fn_dummy.Data())); f_data = new TFile(fn_data.Data(),"UPDATE"); TString dn_result = TString::Format("%s/%s/%d/%d", det.Data(), lay.Data(), sector, fill); // Get right directory bool isThere = f_data->GetListOfKeys()->Contains(det.Data()); if (!isThere) { f_data->mkdir(det.Data()); } isThere = f_data->GetListOfKeys()->Contains(Form("%s/%s", det.Data(), lay.Data())); if (!isThere) { f_data->mkdir(Form("%s/%s", det.Data(), lay.Data())); } isThere = f_data->GetListOfKeys()->Contains(Form("%s/%s/%d", det.Data(), lay.Data(), sector)); if (!isThere) { f_data->mkdir(Form("%s/%s/%d", det.Data(), lay.Data(), sector)); } isThere = f_data->GetListOfKeys()->Contains(Form("%s/%s/%d/%d", det.Data(), lay.Data(), sector, fill)); if (!isThere) { f_data->mkdir(Form("%s/%s/%d/%d", det.Data(), lay.Data(), sector, fill)); } f_data->cd(Form("%s/%s/%d/%d", det.Data(), lay.Data(), sector, fill)); if (!notSave) { gDirectory->Delete(Form("%s;*", vn_result.Data())); v_res.Write(Form("%s", vn_result.Data())); Info("pulseFit","Result written to %s",fn_data.Data()); } f_data->Close(); gSystem->Exec(Form("rm -f %s &> /dev/null",fn_dummy.Data())); if (!notSave) { // Save picture gSystem->Exec(Form("mkdir -p %s",dn_graph.Data())); gSystem->Exec(Form("rm %s &> /dev/null",fn_graph_p.Data())); c_pul->SaveAs(fn_graph_p.Data()); } Printf("=========================================\n"); return EXIT_SUCCESS; }