// // deplVphiN.C // Script to plot the result of the depletion voltage measurement as a function of the fluence // // Created by Christian Elsasser on 31.05.13. // University of Zurich, elsasser@cern.ch // Copyright only for commercial use // // 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/incDrawROOT.h" #include "../../include/incGraphROOT.h" #include "../../include/incHistROOT.h" #include "../../include/incIOROOT.h" #include "../../include/incRooFit.h" #include "../../include/basicROOTTools.h" #include "../../include/basicRooFitTools.h" #include "../../include/lhcbstyle.C" #include "deplTool.h" #include "hamburgTool.h" // -d detector (TT/IT) // -s set 0: all; // 1: TT [125-160] V / IT [ 75-150] V; // 1: TT [160-220] V / IT [150-220] V; // 1: TT [220-280] V / IT [220-250] V; // Voltage values are the initial depletion voltage values measured after production int deplVphiN(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 = deplVphiN(argc,argv); Printf("End"); if (!runBatch) { theApp->Run(!runBatch); } return exit; } // Executable method int deplVphiN(int argc, char* argv[]){ TVectorD v_res(5); gStyle->SetPadLeftMargin(0.20); gStyle->SetTitleOffset(1.5,"Y"); gStyle->SetTitleOffset(1.0,"X"); const char* diskVar = std::getenv ("DISK"); const char* homeVar = std::getenv ("CCEHOME"); TString det("TT"); TString lay("TTaU"); int set = 0; int val = 3; for (int i=1; i<argc; i++) { if (strcmp(argv[i],"-d")==0 && i+1<argc) { det = argv[++i]; }else if (strcmp(argv[i],"-s")==0 && i+1<argc) { set = std::atoi(argv[++i]); }else if (strcmp(argv[i],"-v")==0 && i+1<argc) { val = std::atoi(argv[++i]); } } if (det.EqualTo("IT")) { lay = "T3X2"; }else{ lay = "TTaU"; } // Directory and file names for the measured Vdepl values, the fluence values, // the Vdepl values after production and the luminosity (i.e. development of the flux over time) TString dn_data(Form("%s/data/ST/Aging",diskVar)); TString fn_data(Form("%s/CCEScan.root",dn_data.Data())); TString dn_deplV(Form("%s/data/db",homeVar)); TString fn_deplV(Form("%s/vdepl.root",dn_deplV.Data())); TString dn_fill(Form("%s/data/db",homeVar)); TString fn_fill(Form("%s/lumi.root",dn_fill.Data())); TString dn_sector(Form("%s/data/db",homeVar)); TString fn_sector(Form("%s/fluence.root",dn_sector.Data())); TFile* f_data = TFile::Open(fn_data.Data()); TFile* f_deplV = TFile::Open(fn_deplV.Data()); TFile* f_fill = TFile::Open(fn_fill.Data()); TFile* f_sector = TFile::Open(fn_sector.Data()); const Int_t nRTT = 4; // Define ranges of radii Double_t rTT[nRTT] = {-1.0,75.0,45.0,40.0}; // Get information about the luminosity and the TVectorD* vp_fill = (TVectorD*)f_fill->Get("v_fill"); TVectorD* vp_lumi7 = (TVectorD*)f_fill->Get("v_lumi7"); TVectorD* vp_lumi8 = (TVectorD*)f_fill->Get("v_lumi8"); if (!vp_fill || !vp_lumi7 || !vp_lumi8) { Error("deplVphiN","Luminosity vectors are not available"); return EXIT_FAILURE; } TVectorD v_fill = *vp_fill; TVectorD v_lumi7 = *vp_lumi7; TVectorD v_lumi8 = *vp_lumi8; // Get numbers of available read-out sectors and corresponding initial depletion voltage values TVectorD* vp_sector = (TVectorD*)f_deplV->Get(Form("v_sector_%s",lay.Data())); TVectorD* vp_vdepl = (TVectorD*)f_deplV->Get(Form("v_vdepl_%s",lay.Data())); if (!vp_sector || !vp_vdepl) { Error("deplVphiN","Depletion Voltage vectors are not available"); return EXIT_FAILURE; } TVectorD v_sector = *vp_sector; TVectorD v_vdepl = *vp_vdepl; Int_t effnR = nRTT; // No radius is taken into account in case of IT if (det.EqualTo("IT")) { effnR = 1; } // Define the starting depletion voltage for the predictions double startV = 200.0; if (set==1) { startV = 160.0; }else if(set==3){ startV = 240.0; } if (det.EqualTo("IT")) { startV = 100.0; if (set==1) { startV = 80.0; }else if(set==3){ startV = 120.0; } } // Prediction calculation based on the stable damage part in the Hamburg model int nTheoPoints = 1000; double minTheo = 1e+6; double maxTheo = 1e+20; double binTheo = TMath::Power(maxTheo/minTheo,1.0/nTheoPoints); std::vector<double> v_vdepl_v_theo; std::vector<double> v_vdepl_e_theo; std::vector<double> v_phiN_v_theo; std::vector<double> v_phiN_e_theo; Info("deplVphiN","Calculating theoretical prediction"); for (int i=0; i<nTheoPoints; i++) { double phiN_point = minTheo*TMath::Power(binTheo,i); std::vector<double> v_func = STHamburg::getVeff(phiN_point,det.EqualTo("IT")); Printf(" phi = %20.2f",phiN_point); Printf(" V = (%6.2f+/-%6.2f) V",TMath::Abs(startV-v_func[0]),v_func[1]); Printf("****"); v_vdepl_v_theo.push_back(TMath::Abs(startV-v_func[0])); v_vdepl_e_theo.push_back(v_func[1]); v_phiN_v_theo.push_back(phiN_point); v_phiN_e_theo.push_back(0.0); } // Convert vectors related to predictions into root vectors TVectorD vr_vdepl_v_theo = getROOTVector<double>(v_vdepl_v_theo); TVectorD vr_vdepl_e_theo = getROOTVector<double>(v_vdepl_e_theo); TVectorD vr_phiN_v_theo = getROOTVector<double>(v_phiN_v_theo); TVectorD vr_phiN_e_theo = getROOTVector<double>(v_phiN_e_theo); TGraphErrors* ge_theo = new TGraphErrors(vr_phiN_v_theo, vr_vdepl_v_theo, vr_phiN_e_theo, vr_vdepl_e_theo); TGraph* ge_theo_noerr = new TGraph(vr_phiN_v_theo, vr_vdepl_v_theo); ge_theo->SetFillColor(kGray+2); TMultiGraph* mg_frame = new TMultiGraph("mg_frame","Frame multigraph"); TCanvas* c_frame = new TCanvas("c_frame","Frame Canvas",800,600); c_frame->SetLogx(); mg_frame->Draw(""); // Vectors to store measurement points std::vector<double> v_vdepl_v_norm_low; std::vector<double> v_vdepl_v_norm_mid; std::vector<double> v_vdepl_v_norm_high; std::vector<double> v_vdepl_v_r_low; std::vector<double> v_vdepl_v_r_mid; std::vector<double> v_vdepl_v_r_high; std::vector<double> v_vdepl_e_norm_low; std::vector<double> v_vdepl_e_norm_mid; std::vector<double> v_vdepl_e_norm_high; std::vector<double> v_vdepl_e_r_low; std::vector<double> v_vdepl_e_r_mid; std::vector<double> v_vdepl_e_r_high; std::vector<double> v_phiN_v_norm_low; std::vector<double> v_phiN_v_norm_mid; std::vector<double> v_phiN_v_norm_high; std::vector<double> v_phiN_v_r_low; std::vector<double> v_phiN_v_r_mid; std::vector<double> v_phiN_v_r_high; std::vector<double> v_phiN_e_norm_low; std::vector<double> v_phiN_e_norm_mid; std::vector<double> v_phiN_e_norm_high; std::vector<double> v_phiN_e_r_low; std::vector<double> v_phiN_e_r_mid; std::vector<double> v_phiN_e_r_high; double vTop = 280.0; double vBottom = 125.0; double v1Bound = 160.0; double v2Bound = 220.0; if (det.EqualTo("IT")) { vTop = 250.0; vBottom = 75.0; v1Bound = 150.0; v2Bound = 220.0; } double vMax = vTop; double vMin = vBottom; if (set==1) { vMax = v1Bound; }else if(set==2){ vMax = v2Bound; vMin = v1Bound; }else if(set==3){ vMin = v2Bound; } double mean_sys = 0.0; int nMeas = 0; // Loop over all fills, sectors and radii for (int i=0; i<v_fill.GetNoElements(); i++) { for (int j=0; j<v_sector.GetNoElements(); j++) { for (int k=0; k<effnR; k++) { // Obtain corresponding vector names int sector = (int) v_sector(j); int fill = (int) v_fill(i); TString s_rad(""); TString vn_sector_flux(Form("v_sector_%s",lay.Data())); TString vn_flux7_val(Form("v_flux7_v_%s",lay.Data())); TString vn_flux8_val(Form("v_flux8_v_%s",lay.Data())); TString vn_flux7_err(Form("v_flux7_e_%s",lay.Data())); TString vn_flux8_err(Form("v_flux8_e_%s",lay.Data())); TString vn_data(Form("%s/%s/%d/%d/v_volt_val%d", det.Data(),lay.Data(),sector,fill,val)); // Add radius postfix if (rTT[k]>0.0) { s_rad = Form("%d",(int)rTT[k]); vn_sector_flux += "_r"+s_rad; vn_flux7_val += "_r"+s_rad; vn_flux8_val += "_r"+s_rad; vn_flux7_err += "_r"+s_rad; vn_flux8_err += "_r"+s_rad; vn_data += "_r"+s_rad; } // Extract them from the file TVectorD* vp_sector_flux = (TVectorD*)f_sector->Get(vn_sector_flux.Data()); TVectorD* vp_flux7_val = (TVectorD*)f_sector->Get(vn_flux7_val.Data()); TVectorD* vp_flux8_val = (TVectorD*)f_sector->Get(vn_flux8_val.Data()); TVectorD* vp_flux7_err = (TVectorD*)f_sector->Get(vn_flux7_err.Data()); TVectorD* vp_flux8_err = (TVectorD*)f_sector->Get(vn_flux8_err.Data()); if (!vp_sector_flux || !vp_flux7_val || !vp_flux7_err || !vp_flux8_val || !vp_flux8_err) { Error("deplVphiN","Flux information for radius = %6.2f mm",rTT[k]>0.0?rTT[k]:2000.0); continue; } TVectorD* vp_data = (TVectorD*)f_data->Get(vn_data.Data()); if (!vp_data){ Warning("deplVphiN","No vector found for %s",vn_data.Data()); continue; } TVectorD v_sector_flux = *vp_sector_flux; TVectorD v_flux7_val = *vp_flux7_val; TVectorD v_flux7_err = *vp_flux7_err; TVectorD v_flux8_val = *vp_flux8_val; TVectorD v_flux8_err = *vp_flux8_err; TVectorD v_data = *vp_data; int i_flux = getClosestIndex(v_sector_flux,(double)sector); double flux7_val = v_flux7_val(i_flux); double flux7_err = v_flux7_err(i_flux); double flux8_val = v_flux8_val(i_flux); double flux8_err = v_flux8_err(i_flux); double lumi7 = v_lumi7(i); double lumi8 = v_lumi8(i); double vdepl_prod = v_vdepl(j); double vdepl_val = v_data(0); double vdepl_err = v_data(1); double vdepl_sys = v_data(2); double vdepl_tot = vdepl_err; double phiN_val = STTool::FLUKAConvFac; double phiN_err = STTool::FLUKAConvFac; phiN_val *= (flux7_val*lumi7+flux8_val*lumi8); phiN_err *= (flux7_err*lumi7+flux8_err*lumi8); // Define maximal and minimal Vdepl values to be drawn double plotMin = 40.0; double plotMax = 290.0; if (det.EqualTo("TT")) { plotMin = 80.0; } // Remove points with too high uncertainty if (vdepl_err>20.0 ){ Warning("deplVphiN","Too high or low uncertainty on V_depl"); continue; } if (vdepl_val>plotMax || vdepl_val<plotMin) { Warning("deplVphiN","Too high or low values for V_depl"); continue; } if (vdepl_prod>vMax || vdepl_prod<=vMin) { continue; } // Add systematic uncertainty to get mean value mean_sys += vdepl_sys; nMeas++; // Remove excluded sectors if (STTool::IsExcluded(sector)) { Warning("deplVphiN","Sector excluded"); continue; } Info("deplVphiN","Result for %s/%s sector %d, fill %d, radius %7.2f mm:", det.Data(),lay.Data(),sector,fill,rTT[k]>0.0?rTT[k]:2000.0); Printf(" phi_N = (%10.2f+/-%7.2f)*10^12 cm^{-2}", phiN_val/1e12,phiN_err/1e12); Printf(" V_depl = (%6.2f+/-%6.2f(stat)+/-%6.2f(syst)) V", vdepl_val,vdepl_err,vdepl_sys); Printf(" V_depl,prod = %6.2f V", vdepl_prod); // Define data point in plot TMarker* m_res = new TMarker(phiN_val,vdepl_val,20); TLine* l_hor = new TLine(phiN_val-phiN_err,vdepl_val, phiN_val+phiN_err,vdepl_val); TLine* l_ver = new TLine(phiN_val,vdepl_val-vdepl_err, phiN_val,vdepl_val+vdepl_err); // Add them to the proper vector if (det.EqualTo("TT")) { if (vdepl_prod>v2Bound) { if (rTT[k]>0.0) { v_vdepl_v_r_high.push_back(vdepl_val); v_vdepl_e_r_high.push_back(vdepl_tot); v_phiN_v_r_high.push_back(phiN_val); v_phiN_e_r_high.push_back(phiN_err); }else{ v_vdepl_v_norm_high.push_back(vdepl_val); v_vdepl_e_norm_high.push_back(vdepl_tot); v_phiN_v_norm_high.push_back(phiN_val); v_phiN_e_norm_high.push_back(phiN_err); } }else if(vdepl_prod>v1Bound) { if (rTT[k]>0.0) { v_vdepl_v_r_mid.push_back(vdepl_val); v_vdepl_e_r_mid.push_back(vdepl_tot); v_phiN_v_r_mid.push_back(phiN_val); v_phiN_e_r_mid.push_back(phiN_err); }else{ v_vdepl_v_norm_mid.push_back(vdepl_val); v_vdepl_e_norm_mid.push_back(vdepl_tot); v_phiN_v_norm_mid.push_back(phiN_val); v_phiN_e_norm_mid.push_back(phiN_err); } }else{ if (rTT[k]>0.0) { v_vdepl_v_r_low.push_back(vdepl_val); v_vdepl_e_r_low.push_back(vdepl_tot); v_phiN_v_r_low.push_back(phiN_val); v_phiN_e_r_low.push_back(phiN_err); }else{ v_vdepl_v_norm_low.push_back(vdepl_val); v_vdepl_e_norm_low.push_back(vdepl_tot); v_phiN_v_norm_low.push_back(phiN_val); v_phiN_e_norm_low.push_back(phiN_err); } } }else{ if (vdepl_prod>v2Bound) { v_vdepl_v_norm_high.push_back(vdepl_val); v_vdepl_e_norm_high.push_back(vdepl_tot); v_phiN_v_norm_high.push_back(phiN_val); v_phiN_e_norm_high.push_back(phiN_err); }else if(vdepl_prod>v1Bound) { v_vdepl_v_norm_mid.push_back(vdepl_val); v_vdepl_e_norm_mid.push_back(vdepl_tot); v_phiN_v_norm_mid.push_back(phiN_val); v_phiN_e_norm_mid.push_back(phiN_err); }else{ v_vdepl_v_norm_low.push_back(vdepl_val); v_vdepl_e_norm_low.push_back(vdepl_tot); v_phiN_v_norm_low.push_back(phiN_val); v_phiN_e_norm_low.push_back(phiN_err); } } } } } // Calculate mean systematic uncertainty if (nMeas>0) { mean_sys /= nMeas; } // Add systmatic uncertainty from the extraction procedure of the depletion voltage if (det.EqualTo("IT")) { mean_sys = TMath::Sqrt(mean_sys*mean_sys+STTool::voltSyst_IT*STTool::voltSyst_IT); } if (det.EqualTo("TT")) { mean_sys = TMath::Sqrt(mean_sys*mean_sys+STTool::voltSyst_TT*STTool::voltSyst_TT); } vr_vdepl_v_theo+=mean_sys; TGraph* ge_theo_high = new TGraph(vr_phiN_v_theo, vr_vdepl_v_theo); ge_theo_high->SetLineStyle(9); vr_vdepl_v_theo-=2*mean_sys; TGraph* ge_theo_low = new TGraph(vr_phiN_v_theo, vr_vdepl_v_theo); ge_theo_low->SetLineStyle(9); // Transfrom STL vectors to ROOT vectors TVectorD vr_vdepl_v_norm_low = getROOTVector<double>(v_vdepl_v_norm_low); TVectorD vr_vdepl_v_norm_mid = getROOTVector<double>(v_vdepl_v_norm_mid); TVectorD vr_vdepl_v_norm_high = getROOTVector<double>(v_vdepl_v_norm_high); TVectorD vr_vdepl_v_r_low = getROOTVector<double>(v_vdepl_v_r_low); TVectorD vr_vdepl_v_r_mid = getROOTVector<double>(v_vdepl_v_r_mid); TVectorD vr_vdepl_v_r_high = getROOTVector<double>(v_vdepl_v_r_high); TVectorD vr_vdepl_e_norm_low = getROOTVector<double>(v_vdepl_e_norm_low); TVectorD vr_vdepl_e_norm_mid = getROOTVector<double>(v_vdepl_e_norm_mid); TVectorD vr_vdepl_e_norm_high = getROOTVector<double>(v_vdepl_e_norm_high); TVectorD vr_vdepl_e_r_low = getROOTVector<double>(v_vdepl_e_r_low); TVectorD vr_vdepl_e_r_mid = getROOTVector<double>(v_vdepl_e_r_mid); TVectorD vr_vdepl_e_r_high = getROOTVector<double>(v_vdepl_e_r_high); TVectorD vr_phiN_v_norm_low = getROOTVector<double>(v_phiN_v_norm_low); TVectorD vr_phiN_v_norm_mid = getROOTVector<double>(v_phiN_v_norm_mid); TVectorD vr_phiN_v_norm_high = getROOTVector<double>(v_phiN_v_norm_high); TVectorD vr_phiN_v_r_low = getROOTVector<double>(v_phiN_v_r_low); TVectorD vr_phiN_v_r_mid = getROOTVector<double>(v_phiN_v_r_mid); TVectorD vr_phiN_v_r_high = getROOTVector<double>(v_phiN_v_r_high); TVectorD vr_phiN_e_norm_low = getROOTVector<double>(v_phiN_e_norm_low); TVectorD vr_phiN_e_norm_mid = getROOTVector<double>(v_phiN_e_norm_mid); TVectorD vr_phiN_e_norm_high = getROOTVector<double>(v_phiN_e_norm_high); TVectorD vr_phiN_e_r_low = getROOTVector<double>(v_phiN_e_r_low); TVectorD vr_phiN_e_r_mid = getROOTVector<double>(v_phiN_e_r_mid); TVectorD vr_phiN_e_r_high = getROOTVector<double>(v_phiN_e_r_high); // Generate graphs double markerSize = 1.0; TGraphErrors* ge_norm_low = new TGraphErrors(vr_phiN_v_norm_low, vr_vdepl_v_norm_low, vr_phiN_e_norm_low, vr_vdepl_e_norm_low); ge_norm_low->SetMarkerSize(markerSize); ge_norm_low->SetMarkerStyle(23); ge_norm_low->SetMarkerColor(kGreen+3); ge_norm_low->SetLineColor(kGreen+3); TGraphErrors* ge_norm_mid = new TGraphErrors(vr_phiN_v_norm_mid, vr_vdepl_v_norm_mid, vr_phiN_e_norm_mid, vr_vdepl_e_norm_mid); ge_norm_mid->SetMarkerSize(markerSize); ge_norm_mid->SetMarkerStyle(22); ge_norm_mid->SetMarkerColor(kBlue); ge_norm_mid->SetLineColor(kBlue); TGraphErrors* ge_norm_high = new TGraphErrors(vr_phiN_v_norm_high, vr_vdepl_v_norm_high, vr_phiN_e_norm_high, vr_vdepl_e_norm_high); ge_norm_high->SetMarkerSize(markerSize); ge_norm_high->SetMarkerStyle(20); ge_norm_high->SetMarkerColor(kRed); ge_norm_high->SetLineColor(kRed); TGraphErrors* ge_r_low = new TGraphErrors(vr_phiN_v_r_low, vr_vdepl_v_r_low, vr_phiN_e_r_low, vr_vdepl_e_r_low); ge_r_low->SetMarkerSize(markerSize); ge_r_low->SetMarkerStyle(32); ge_r_low->SetMarkerColor(kGreen+3); ge_r_low->SetLineColor(kGreen+3); TGraphErrors* ge_r_mid = new TGraphErrors(vr_phiN_v_r_mid, vr_vdepl_v_r_mid, vr_phiN_e_r_mid, vr_vdepl_e_r_mid); ge_r_mid->SetMarkerSize(markerSize); ge_r_mid->SetMarkerStyle(26); ge_r_mid->SetMarkerColor(kBlue); ge_r_mid->SetLineColor(kBlue); TGraphErrors* ge_r_high = new TGraphErrors(vr_phiN_v_r_high, vr_vdepl_v_r_high, vr_phiN_e_r_high, vr_vdepl_e_r_high); ge_r_high->SetMarkerSize(markerSize); ge_r_high->SetMarkerStyle(24); ge_r_high->SetMarkerColor(kRed); ge_r_high->SetLineColor(kRed); mg_frame->Add(ge_theo,"E3"); mg_frame->Add(ge_theo_noerr,"L"); mg_frame->Add(ge_theo_high,"L"); mg_frame->Add(ge_theo_low,"L"); mg_frame->Add(ge_norm_low,"pe"); mg_frame->Add(ge_norm_mid,"pe"); mg_frame->Add(ge_norm_high,"pe"); mg_frame->Add(ge_r_low,"p"); mg_frame->Add(ge_r_mid,"p"); mg_frame->Add(ge_r_high,"p"); mg_frame->Draw("a"); // Plot graphs mg_frame->GetXaxis()->SetTitle("#phi_{1 MeV-n,eq} [cm^{-2}]"); mg_frame->GetYaxis()->SetTitle("#it{V}_{depl} [V]"); mg_frame->GetXaxis()->SetLimits(1e+8,1e+14); mg_frame->GetXaxis()->SetLabelOffset(-0.005); mg_frame->GetXaxis()->SetTitleOffset(1.2); mg_frame->SetMaximum(300.0); mg_frame->SetMinimum(0.0); // Draw legend double baseY = 0.30; if (det.EqualTo("IT")) { baseY = 0.90; } TMarker* m_leg = new TMarker(0.25,baseY,20); TLatex* t_leg = new TLatex(0.27,baseY,"#it{V}_{depl} > 225 V"); t_leg->SetTextSize(0.04); t_leg->SetTextAlign(12); t_leg->SetNDC(); m_leg->SetNDC(); if (det.EqualTo("TT") && (set==3 || set==0)) { m_leg->SetX(0.25); m_leg->SetY(baseY); m_leg->SetMarkerColor(kRed); m_leg->SetMarkerStyle(20); m_leg->DrawClone(); m_leg->SetMarkerStyle(24); m_leg->SetX(0.55); if (det.EqualTo("TT")) { m_leg->DrawClone(); } t_leg->DrawLatex(0.30,baseY,Form("#it{V}_{depl} #in [%3.0f,%3.0f] V",v2Bound,vTop)); if (det.EqualTo("TT")) { t_leg->DrawLatex(0.60,baseY,"Innermost region"); } baseY -= 0.05; } if (det.EqualTo("TT") && (set==2 || set==0)) { m_leg->SetX(0.25); m_leg->SetY(baseY); m_leg->SetMarkerColor(kBlue); m_leg->SetMarkerStyle(22); m_leg->DrawClone(); m_leg->SetMarkerStyle(26); m_leg->SetX(0.55); if (det.EqualTo("TT")) { m_leg->DrawClone(); } t_leg->DrawLatex(0.30,baseY,Form("#it{V}_{depl} #in [%3.0f,%3.0f] V",v1Bound,v2Bound)); if (det.EqualTo("TT")) { t_leg->DrawLatex(0.60,baseY,"Innermost region"); } baseY -= 0.05; } if (det.EqualTo("IT") && (set==1 || set==0)) { m_leg->SetX(0.25); m_leg->SetY(baseY); m_leg->SetMarkerColor(kGreen+3); m_leg->SetMarkerStyle(23); m_leg->DrawClone(); m_leg->SetMarkerStyle(32); m_leg->SetX(0.55); if (det.EqualTo("TT")) { m_leg->DrawClone(); } t_leg->DrawLatex(0.30,baseY,Form("#it{V}_{depl} #in [%3.0f,%3.0f] V",vBottom,v1Bound)); if (det.EqualTo("TT")) { t_leg->DrawLatex(0.60,baseY,"Innermost region"); } baseY -= 0.05; } TLine* l_line = new TLine(0.20,baseY,0.25,baseY); l_line->DrawLineNDC(0.23,baseY,0.27,baseY); t_leg->DrawLatex(0.30,baseY,Form("Hamburg Model (#it{V}_{depl} = %3.0f V)",startV)); mg_frame->GetHistogram()->Draw("axissame"); Printf("=========================================\n"); return EXIT_SUCCESS; }