1 | /*
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2 | Example of using vertex fitter class to fit primary vertex
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3 | assumed to be generated in (0,0,0)
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4 | */
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5 |
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6 | #ifdef __CLING__
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7 | R__LOAD_LIBRARY(libDelphes)
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8 |
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9 | #include "classes/DelphesClasses.h"
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10 | #include "external/ExRootAnalysis/ExRootTreeReader.h"
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11 | #include "modules/TrackCovariance.h"
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12 | #include "external/TrackCovariance/TrkUtil.h"
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13 | #include "external/TrackCovariance/VertexFit.h"
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14 |
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15 | #endif
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16 |
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17 |
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18 |
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19 | //------------------------------------------------------------------------------
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20 |
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21 | void ExamplePVtxFitEC(const char* inputFile, Int_t Nevent = 5)
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22 | {
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23 | // Create chain of root trees
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24 | TChain chain("Delphes");
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25 | chain.Add(inputFile);
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26 |
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27 | // Create object of class ExRootTreeReader
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28 | ExRootTreeReader* treeReader = new ExRootTreeReader(&chain);
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29 | Long64_t numberOfEntries = treeReader->GetEntries();
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30 |
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31 | // Get pointers to branches used in this analysis
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32 | TClonesArray* branchGenPart = treeReader->UseBranch("Particle");
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33 | TClonesArray* branchTrack = treeReader->UseBranch("Track");
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34 |
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35 | // Book histograms
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36 | Int_t Nbin = 100;
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37 | TH1D* hXpull = new TH1D("hXpull", "Pull X vertex component", Nbin, -10., 10.);
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38 | TH1D* hYpull = new TH1D("hYpull", "Pull Y vertex component", Nbin, -10., 10.);
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39 | TH1D* hZpull = new TH1D("hZpull", "Pull Z vertex component", Nbin, -10., 10.);
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40 | TH1D* hChi2 = new TH1D("hChi2", "Vertex #chi^{2}/N_{dof}", Nbin, 0., 10.);
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41 | //
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42 | // Loop over all events
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43 | Int_t Nev = TMath::Min(Nevent, (Int_t)numberOfEntries);
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44 | for (Int_t entry = 0; entry < Nev; ++entry)
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45 | {
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46 | // Load selected branches with data from specified event
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47 | treeReader->ReadEntry(entry);
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48 | //
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49 | Int_t Ntr = 0; // # of tracks from primary vertex
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50 | Int_t NtrG = branchTrack->GetEntries();
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51 | TVectorD** pr = new TVectorD * [NtrG];
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52 | TMatrixDSym** cv = new TMatrixDSym * [NtrG];
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53 | //
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54 | // True vertex
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55 | Double_t xpv, ypv, zpv;
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56 | // If event contains at least 1 track
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57 | //
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58 | if (branchTrack->GetEntries() > 0)
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59 | {
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60 | // Loop on tracks
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61 | for (Int_t it = 0; it < branchTrack->GetEntries(); it++)
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62 | {
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63 | Track* trk = (Track*)branchTrack->At(it);
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64 | //
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65 | // Get associated generated particle
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66 | GenParticle* gp = (GenParticle*)trk->Particle.GetObject();
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67 | TVector3 xg(1.e-3*gp->X,1.e-3*gp->Y,1.e-3*gp->Z);
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68 | TVector3 pg(gp->Px,gp->Py,gp->Pz);
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69 | Double_t Q = (Double_t)gp->Charge;
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70 | Double_t Bz = 2.0;
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71 | TVectorD genParM =TrkUtil:: XPtoPar(xg, pg, Q, Bz);
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72 | TVectorD genPar = TrkUtil::ParToMm(genParM);
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73 | //
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74 | // Position of origin in mm
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75 | Double_t x = gp->X;
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76 | Double_t y = gp->Y;
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77 | Double_t z = gp->Z;
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78 | Bool_t prim = kTRUE; // Is primary?
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79 | Int_t mp = gp->M1; // Mother
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80 | while(mp>0){
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81 | GenParticle* gm =
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82 | (GenParticle*)branchGenPart->At(mp);
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83 | Double_t xm = gm->X;
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84 | Double_t ym = gm->Y;
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85 | Double_t zm = gm->Z;
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86 | if(x!=xm || y!=ym || z!=zm){
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87 | prim = kFALSE;
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88 | break;
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89 | }else mp = gm->M1;
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90 | }
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91 | //
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92 | // group tracks originating from the primary vertex
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93 | if (prim)
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94 | {
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95 | //std::cout<<"Event: "<<entry<<", track: "<<it;
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96 | //std::cout<<", x = "<<x<<", y = "<<y<<", z = "<<z<<std::endl;
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97 | xpv = x;
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98 | ypv = y;
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99 | zpv = z;
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100 | //
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101 | // Reconstructed track parameters
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102 | Double_t obsD0 = trk->D0;
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103 | Double_t obsPhi = trk->Phi;
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104 | Double_t obsC = trk->C;
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105 | Double_t obsZ0 = trk->DZ;
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106 | //std::cout<<"Z0 track = "<< obsZ0
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107 | //<<", gen Z0 = "<<genPar(3)
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108 | //<<", gen cot = "<<genPar(4)<<std::endl;
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109 | Double_t obsCtg = trk->CtgTheta;
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110 | Double_t oPar[5] = { obsD0, obsPhi, obsC, obsZ0, obsCtg };
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111 | TVectorD obsPar(5, oPar); // Fill observed parameters
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112 | //
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113 | pr[Ntr] = new TVectorD(obsPar);
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114 | //std::cout<<"Cov Matrix:"<<std::endl;
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115 | //trk->CovarianceMatrix().Print();
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116 | cv[Ntr] = new TMatrixDSym(trk->CovarianceMatrix());
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117 | Ntr++;
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118 | }
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119 | } // End loop on tracks
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120 | }
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121 | //
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122 | // Fit primary vertex with beam constraint
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123 | //
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124 | //Beam constraint
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125 | TVectorD xpvc(3);
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126 | xpvc(0) = 1.0;
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127 | xpvc(1) = -2.0;
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128 | xpvc(2) = 10.0;
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129 | TMatrixDSym covpvc(3); covpvc.Zero();
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130 | covpvc(0, 0) = 0.0097 * 0.0097;
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131 | covpvc(1, 1) = 2.55e-05 * 2.55e-05;
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132 | covpvc(2, 2) = 0.64 * 0.64;
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133 | Int_t MinTrk = 2; // Minumum # tracks for vertex fit
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134 | if (Ntr >= MinTrk) {
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135 | VertexFit* Vtx = new VertexFit(Ntr, pr, cv);
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136 | Vtx->AddVtxConstraint(xpvc, covpvc);
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137 | TVectorD xvtx = Vtx->GetVtx();
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138 | TMatrixDSym covX = Vtx->GetVtxCov();
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139 | Double_t Chi2 = Vtx->GetVtxChi2();
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140 | Double_t Ndof = 2 * (Double_t)Ntr;
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141 | Double_t PullX = (xvtx(0)-xpv) / TMath::Sqrt(covX(0, 0));
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142 | Double_t PullY = (xvtx(1)-ypv) / TMath::Sqrt(covX(1, 1));
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143 | Double_t PullZ = (xvtx(2)-zpv) / TMath::Sqrt(covX(2, 2));
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144 | //std::cout<<"**** True vertex (x, y, z) "<<xpv<<", "
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145 | //<<ypv<<", "<<zpv<<std::endl;
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146 | //std::cout<<"**** Found vertex (x, y, z) "<<xvtx(0)<<", "
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147 | //<<xvtx(1)<<", "<<xvtx(2)<<std::endl;
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148 | //
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149 | // Fill histograms
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150 | hXpull->Fill(PullX);
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151 | hYpull->Fill(PullY);
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152 | hZpull->Fill(PullZ);
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153 | hChi2->Fill(Chi2 / Ndof);
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154 | }
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155 |
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156 | //std::cout << "Vertex chi2/Ndof = " << Chi2 / Ndof << std::endl;
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157 | //
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158 | // Cleanup
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159 | for (Int_t i = 0; i < Ntr; i++) delete pr[i];
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160 | for (Int_t i = 0; i < Ntr; i++) delete cv[i];
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161 | delete[] pr;
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162 | delete[] cv;
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163 | }
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164 | //
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165 | // Show resulting histograms
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166 | //
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167 | TCanvas* Cnv = new TCanvas("Cnv", "Delphes primary vertex pulls", 50, 50, 900, 500);
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168 | Cnv->Divide(2, 2);
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169 | Cnv->cd(1); gPad->SetLogy(1); gStyle->SetOptFit(1111);
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170 | hXpull->Fit("gaus"); hXpull->Draw();
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171 | Cnv->cd(2); gPad->SetLogy(1); gStyle->SetOptFit(1111);
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172 | hYpull->Fit("gaus"); hYpull->Draw();
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173 | Cnv->cd(3); gPad->SetLogy(1); gStyle->SetOptFit(1111);
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174 | hZpull->Fit("gaus"); hZpull->Draw();
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175 | Cnv->cd(4); hChi2->Draw();
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176 | }
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