/* Example of using vertex fitter class to fit primary vertex assumed to be generated in (0,0,0) */ #ifdef __CLING__ R__LOAD_LIBRARY(libDelphes) #include "classes/DelphesClasses.h" #include "external/ExRootAnalysis/ExRootTreeReader.h" #include "modules/TrackCovariance.h" #include "external/TrackCovariance/TrkUtil.h" #include "external/TrackCovariance/VertexFit.h" #endif //------------------------------------------------------------------------------ void ExamplePVtxFit(const char* inputFile, Int_t Nevent = 5) { // Create chain of root trees TChain chain("Delphes"); chain.Add(inputFile); // Create object of class ExRootTreeReader ExRootTreeReader* treeReader = new ExRootTreeReader(&chain); Long64_t numberOfEntries = treeReader->GetEntries(); // Get pointers to branches used in this analysis TClonesArray* branchGenPart = treeReader->UseBranch("Particle"); TClonesArray* branchTrack = treeReader->UseBranch("Track"); // Book histograms Int_t Nbin = 100; TH1D* hXpull = new TH1D("hXpull", "Pull X vertex component", Nbin, -10., 10.); TH1D* hYpull = new TH1D("hYpull", "Pull Y vertex component", Nbin, -10., 10.); TH1D* hZpull = new TH1D("hZpull", "Pull Z vertex component", Nbin, -10., 10.); TH1D* hChi2 = new TH1D("hChi2", "Vertex #chi^{2}/N_{dof}", Nbin, 0., 10.); // // Loop over all events Int_t Nev = TMath::Min(Nevent, (Int_t) numberOfEntries); for (Int_t entry = 0; entry < Nev; ++entry) { // Load selected branches with data from specified event treeReader->ReadEntry(entry); Int_t Ntr = 0; // # of tracks from primary vertex Int_t NtrG = branchTrack->GetEntries(); TVectorD** pr = new TVectorD * [NtrG]; TMatrixDSym** cv = new TMatrixDSym * [NtrG]; // If event contains at least 1 track // if (branchTrack->GetEntries() > 0) { // Loop on tracks for (Int_t it = 0; it < branchTrack->GetEntries(); it++) { Track* trk = (Track*)branchTrack->At(it); // // Get associated generated particle GenParticle* gp = (GenParticle*)trk->Particle.GetObject(); // // Position of origin in meters Double_t x = 1.0e-3 * gp->X; Double_t y = 1.0e-3 * gp->Y; Double_t z = 1.0e-3 * gp->Z; // // group tracks originating from the primary vertex if (x == 0.0 && y == 0.0) { // // Reconstructed track parameters Double_t obsD0 = trk->D0; Double_t obsPhi = trk->Phi; Double_t obsC = trk->C; Double_t obsZ0 = trk->DZ; Double_t obsCtg = trk->CtgTheta; Double_t oPar[5] = { obsD0, obsPhi, obsC, obsZ0, obsCtg }; TVectorD obsPar(5, oPar); // Fill observed parameters TVector3 xv(x, y, z); // pr[Ntr] = new TVectorD(obsPar); cv[Ntr] = new TMatrixDSym(TrkUtil::CovToMm(trk->CovarianceMatrix())); Ntr++; } } // End loop on tracks //std::cout << "Total of " << Ntr << " primary tracks out of " << NtrG << " tracks" << std::endl; } // // Fit primary vertex Int_t MinTrk = 2; // Minumum # tracks for vertex fit if (Ntr >= MinTrk) { VertexFit* Vtx = new VertexFit(Ntr, pr, cv); TVectorD xvtx = Vtx->GetVtx(); TMatrixDSym covX = Vtx->GetVtxCov(); Double_t Chi2 = Vtx->GetVtxChi2(); Double_t Ndof = 2 * (Double_t)Ntr - 3; Double_t PullX = xvtx(0) / TMath::Sqrt(covX(0, 0)); Double_t PullY = xvtx(1) / TMath::Sqrt(covX(1, 1)); Double_t PullZ = xvtx(2) / TMath::Sqrt(covX(2, 2)); // // Fill histograms hXpull->Fill(PullX); hYpull->Fill(PullY); hZpull->Fill(PullZ); hChi2->Fill(Chi2 / Ndof); } //std::cout << "Vertex chi2/Ndof = " << Chi2 / Ndof << std::endl; // // Cleanup for (Int_t i = 0; i < Ntr; i++) delete pr[i]; for (Int_t i = 0; i < Ntr; i++) delete cv[i]; delete[] pr; delete[] cv; } // // Show resulting histograms // TCanvas* Cnv = new TCanvas("Cnv", "Delphes generated track plots", 50, 50, 900, 500); Cnv->Divide(2, 2); Cnv->cd(1); gPad->SetLogy(1); gStyle->SetOptFit(1111); hXpull->Fit("gaus"); hXpull->Draw(); Cnv->cd(2); gPad->SetLogy(1); gStyle->SetOptFit(1111); hYpull->Fit("gaus"); hYpull->Draw(); Cnv->cd(3); gPad->SetLogy(1); gStyle->SetOptFit(1111); hZpull->Fit("gaus"); hZpull->Draw(); Cnv->cd(4); hChi2->Draw(); }