Public Types
typedef MonitorElement *	MEP

Public Member Functions
void	bookHistos (DQMStore::IBooker &ibooker, const string &dirName, const HistoDimensions &hDim)

void	fill (const TrackingParticle simRef, const Muon muonRef)

Public Attributes
bool	doAbsEta_

MEP	hChi2_

MEP	hChi2_vs_Eta_

MEP	hChi2Norm_

MEP	hChi2Norm_vs_Eta_

MEP	hChi2Prob_

MEP	hChi2Prob_vs_Eta_

MEP	hdPt_vs_Eta_

MEP	hdPt_vs_Pt_

MEP	hErrDxy_

MEP	hErrDz_

MEP	hErrEta_

MEP	hErrEta_vs_Eta_

MEP	hErrP_

MEP	hErrP_vs_Eta_

MEP	hErrP_vs_P_

MEP	hErrPBarrel_

MEP	hErrPEndcap_

MEP	hErrPhi_

MEP	hErrPOverlap_

MEP	hErrPt_

MEP	hErrPt_PF_

MEP	hErrPt_vs_Eta_

MEP	hErrPt_vs_Pt_

MEP	hErrPtBarrel_

MEP	hErrPtEndcap_

MEP	hErrPtOverlap_

MEP	hErrQPt_PF_

MEP	hErrQPt_vs_Eta_

MEP	hErrQPt_vs_Pt_

MEP	hEta_

MEP	hMisQEta_

MEP	hMisQPt_

MEP	hNDof_

MEP	hNDof_vs_Eta_

MEP	hNHits_

MEP	hNHits_vs_Eta_

MEP	hNHits_vs_Pt_

MEP	hNLostHits_

MEP	hNLostHits_vs_Eta_

MEP	hNLostHits_vs_Pt_

MEP	hNMuon_

MEP	hNMuonHits_

MEP	hNMuonHits_vs_Eta_

MEP	hNMuonHits_vs_Pt_

MEP	hNRecoToSim_

MEP	hNSim_

MEP	hNSimHits_

MEP	hNSimToReco_

MEP	hNTrackerHits_

MEP	hNTrackerHits_vs_Eta_

MEP	hNTrackerHits_vs_Pt_

MEP	hNTrks_

MEP	hNTrksEta_

MEP	hNTrksPt_

MEP	hP_

MEP	hPFMomAssCorrectness

MEP	hPhi_

MEP	hPt_

MEP	hPt_vs_PFMomAssCorrectness

MEP	hPullDxy_

MEP	hPullDz_

MEP	hPullEta_

MEP	hPullEta_vs_Eta_

MEP	hPullEta_vs_Pt_

MEP	hPullPhi_

MEP	hPullPhi_vs_Eta_

MEP	hPullPt_

MEP	hPullPt_vs_Eta_

MEP	hPullPt_vs_Pt_

MEP	hPullQPt_

MEP	hSimDxy_

MEP	hSimDz_

MEP	hSimEta_

MEP	hSimP_

MEP	hSimPhi_

MEP	hSimPt_

bool	usePFMuon_

Detailed Description

Definition at line 28 of file RecoMuonValidator.cc.

Member Typedef Documentation

◆ MEP

typedef MonitorElement* RecoMuonValidator::MuonME::MEP

Definition at line 29 of file RecoMuonValidator.cc.

Member Function Documentation

◆ bookHistos()

void RecoMuonValidator::MuonME::bookHistos	(	DQMStore::IBooker &	ibooker,
		const string &	dirName,
		const HistoDimensions &	hDim
	)

inline

Definition at line 82 of file RecoMuonValidator.cc.

   {
     ibooker.cd();
     ibooker.setCurrentFolder(dirName);
  
     doAbsEta_ = hDim.doAbsEta;
     usePFMuon_ = hDim.usePFMuon;
  
     //histograms for efficiency plots
     hP_ = ibooker.book1D("P", "p of recoTracks", hDim.nBinP, hDim.minP, hDim.maxP);
     hPt_ = ibooker.book1D("Pt", "p_{T} of recoTracks", hDim.nBinPt, hDim.minPt, hDim.maxPt);
     hEta_ = ibooker.book1D("Eta", "#eta of recoTracks", hDim.nBinEta, hDim.minEta, hDim.maxEta);
     hPhi_ = ibooker.book1D("Phi", "#phi of recoTracks", hDim.nBinPhi, hDim.minPhi, hDim.maxPhi);
  
     hSimP_ = ibooker.book1D("SimP", "p of simTracks", hDim.nBinP, hDim.minP, hDim.maxP);
     hSimPt_ = ibooker.book1D("SimPt", "p_{T} of simTracks", hDim.nBinPt, hDim.minPt, hDim.maxPt);
     hSimEta_ = ibooker.book1D("SimEta", "#eta of simTracks", hDim.nBinEta, hDim.minEta, hDim.maxEta);
     hSimPhi_ = ibooker.book1D("SimPhi", "#phi of simTracks", hDim.nBinPhi, hDim.minPhi, hDim.maxPhi);
     hSimDxy_ = ibooker.book1D("SimDxy", "Dxy of simTracks", hDim.nBinDxy, hDim.minDxy, hDim.maxDxy);
     hSimDz_ = ibooker.book1D("Dz", "Dz of simTracks", hDim.nBinDz, hDim.minDz, hDim.maxDz);
  
     //track multiplicities
     hNSim_ = ibooker.book1D("NSim", "Number of particles per event", hDim.nTrks, -0.5, hDim.nTrks + 0.5);
     hNMuon_ = ibooker.book1D("NMuon", "Number of muons per event", hDim.nTrks, -0.5, hDim.nTrks + 0.5);
  
     // - Misc. variables
     hNTrks_ = ibooker.book1D("NTrks", "Number of reco tracks per event", hDim.nTrks, -0.5, hDim.nTrks + 0.5);
     hNTrksEta_ = ibooker.book1D("NTrksEta", "Number of reco tracks vs #eta", hDim.nBinEta, hDim.minEta, hDim.maxEta);
     hNTrksPt_ = ibooker.book1D("NTrksPt", "Number of reco tracks vs p_{T}", hDim.nBinPt, hDim.minPt, hDim.maxPt);
  
     hMisQPt_ = ibooker.book1D("MisQPt", "Charge mis-id vs Pt", hDim.nBinPt, hDim.minPt, hDim.maxPt);
     hMisQEta_ = ibooker.book1D("MisQEta", "Charge mis-id vs Eta", hDim.nBinEta, hDim.minEta, hDim.maxEta);
  
     // - Resolutions
     hErrP_ = ibooker.book1D("ErrP", "#Delta(p)/p", hDim.nBinErr, hDim.minErrP, hDim.maxErrP);
     hErrPBarrel_ = ibooker.book1D("ErrP_barrel", "#Delta(p)/p", hDim.nBinErr, hDim.minErrP, hDim.maxErrP);
     hErrPOverlap_ = ibooker.book1D("ErrP_overlap", "#Delta(p)/p", hDim.nBinErr, hDim.minErrP, hDim.maxErrP);
     hErrPEndcap_ = ibooker.book1D("ErrP_endcap", "#Delta(p)/p", hDim.nBinErr, hDim.minErrP, hDim.maxErrP);
     hErrPt_ = ibooker.book1D("ErrPt", "#Delta(p_{T})/p_{T}", hDim.nBinErr, hDim.minErrPt, hDim.maxErrPt);
     hErrPtBarrel_ = ibooker.book1D("ErrPt_barrel", "#Delta(p_{T})/p_{T}", hDim.nBinErr, hDim.minErrPt, hDim.maxErrPt);
     hErrPtOverlap_ = ibooker.book1D("ErrPt_overlap", "#Delta(p_{T})/p_{T}", hDim.nBinErr, hDim.minErrPt, hDim.maxErrPt);
     hErrPtEndcap_ = ibooker.book1D("ErrPt_endcap", "#Delta(p_{T})/p_{T}", hDim.nBinErr, hDim.minErrPt, hDim.maxErrPt);
     hErrEta_ = ibooker.book1D("ErrEta", "#sigma(#eta))", hDim.nBinErr, hDim.minErrEta, hDim.maxErrEta);
     hErrPhi_ = ibooker.book1D("ErrPhi", "#sigma(#phi)", hDim.nBinErr, hDim.minErrPhi, hDim.maxErrPhi);
     hErrDxy_ = ibooker.book1D("ErrDxy", "#sigma(d_{xy})", hDim.nBinErr, hDim.minErrDxy, hDim.maxErrDxy);
     hErrDz_ = ibooker.book1D("ErrDz", "#sigma(d_{z})", hDim.nBinErr, hDim.minErrDz, hDim.maxErrDz);
  
     //PF-RECO comparisons
     if (usePFMuon_) {
       hErrPt_PF_ = ibooker.book1D("ErrPt_PF", "#Delta(p_{T})|_{PF}/p_{T}", hDim.nBinErr, hDim.minErrPt, hDim.maxErrPt);
       hErrQPt_PF_ =
           ibooker.book1D("ErrQPt_PF", "#Delta(q/p_{T})|_{PF}/(q/p_{T})", hDim.nBinErr, hDim.minErrQPt, hDim.maxErrQPt);
  
       hPFMomAssCorrectness =
           ibooker.book1D("hPFMomAssCorrectness", "Corrected momentum assignement PF/RECO", 2, 0.5, 2.5);
       hPt_vs_PFMomAssCorrectness = ibooker.book2D("hPt_vs_PFMomAssCorrectness",
                                                   "Corrected momentum assignement PF/RECO",
                                                   hDim.nBinPt,
                                                   hDim.minPt,
                                                   hDim.maxP,
                                                   2,
                                                   0.5,
                                                   2.5);
  
       hdPt_vs_Pt_ = ibooker.book2D("dPt_vs_Pt",
                                    "#Delta(p_{T}) vs p_{T}",
                                    hDim.nBinPt,
                                    hDim.minPt,
                                    hDim.maxPt,
                                    hDim.nBinErr,
                                    hDim.minErrPt,
                                    hDim.maxErrPt);
       hdPt_vs_Eta_ = ibooker.book2D("dPt_vs_Eta",
                                     "#Delta(p_{T}) vs #eta",
                                     hDim.nBinEta,
                                     hDim.minEta,
                                     hDim.maxEta,
                                     hDim.nBinErr,
                                     hDim.minErrPt,
                                     hDim.maxErrPt);
     }
  
     // -- Resolutions vs Eta
     hErrP_vs_Eta_ = ibooker.book2D("ErrP_vs_Eta",
                                    "#Delta(p)/p vs #eta",
                                    hDim.nBinEta,
                                    hDim.minEta,
                                    hDim.maxEta,
                                    hDim.nBinErr,
                                    hDim.minErrP,
                                    hDim.maxErrP);
     hErrPt_vs_Eta_ = ibooker.book2D("ErrPt_vs_Eta",
                                     "#Delta(p_{T})/p_{T} vs #eta",
                                     hDim.nBinEta,
                                     hDim.minEta,
                                     hDim.maxEta,
                                     hDim.nBinErr,
                                     hDim.minErrPt,
                                     hDim.maxErrPt);
     hErrQPt_vs_Eta_ = ibooker.book2D("ErrQPt_vs_Eta",
                                      "#Delta(q/p_{T})/(q/p_{T}) vs #eta",
                                      hDim.nBinEta,
                                      hDim.minEta,
                                      hDim.maxEta,
                                      hDim.nBinErr,
                                      hDim.minErrQPt,
                                      hDim.maxErrQPt);
     hErrEta_vs_Eta_ = ibooker.book2D("ErrEta_vs_Eta",
                                      "#sigma(#eta) vs #eta",
                                      hDim.nBinEta,
                                      hDim.minEta,
                                      hDim.maxEta,
                                      hDim.nBinErr,
                                      hDim.minErrEta,
                                      hDim.maxErrEta);
  
     // -- Resolutions vs momentum
     hErrP_vs_P_ = ibooker.book2D(
         "ErrP_vs_P", "#Delta(p)/p vs p", hDim.nBinP, hDim.minP, hDim.maxP, hDim.nBinErr, hDim.minErrP, hDim.maxErrP);
     hErrPt_vs_Pt_ = ibooker.book2D("ErrPt_vs_Pt",
                                    "#Delta(p_{T})/p_{T} vs p_{T}",
                                    hDim.nBinPt,
                                    hDim.minPt,
                                    hDim.maxPt,
                                    hDim.nBinErr,
                                    hDim.minErrPt,
                                    hDim.maxErrPt);
     hErrQPt_vs_Pt_ = ibooker.book2D("ErrQPt_vs_Pt",
                                     "#Delta(q/p_{T})/(q/p_{T}) vs p_{T}",
                                     hDim.nBinPt,
                                     hDim.minPt,
                                     hDim.maxPt,
                                     hDim.nBinErr,
                                     hDim.minErrQPt,
                                     hDim.maxErrQPt);
  
     // - Pulls
     hPullPt_ = ibooker.book1D("PullPt", "Pull(#p_{T})", hDim.nBinPull, -hDim.wPull, hDim.wPull);
     hPullEta_ = ibooker.book1D("PullEta", "Pull(#eta)", hDim.nBinPull, -hDim.wPull, hDim.wPull);
     hPullPhi_ = ibooker.book1D("PullPhi", "Pull(#phi)", hDim.nBinPull, -hDim.wPull, hDim.wPull);
     hPullQPt_ = ibooker.book1D("PullQPt", "Pull(q/p_{T})", hDim.nBinPull, -hDim.wPull, hDim.wPull);
     hPullDxy_ = ibooker.book1D("PullDxy", "Pull(D_{xy})", hDim.nBinPull, -hDim.wPull, hDim.wPull);
     hPullDz_ = ibooker.book1D("PullDz", "Pull(D_{z})", hDim.nBinPull, -hDim.wPull, hDim.wPull);
  
     // -- Pulls vs Eta
     hPullPt_vs_Eta_ = ibooker.book2D("PullPt_vs_Eta",
                                      "Pull(p_{T}) vs #eta",
                                      hDim.nBinEta,
                                      hDim.minEta,
                                      hDim.maxEta,
                                      hDim.nBinPull,
                                      -hDim.wPull,
                                      hDim.wPull);
     hPullEta_vs_Eta_ = ibooker.book2D("PullEta_vs_Eta",
                                       "Pull(#eta) vs #eta",
                                       hDim.nBinEta,
                                       hDim.minEta,
                                       hDim.maxEta,
                                       hDim.nBinPull,
                                       -hDim.wPull,
                                       hDim.wPull);
     hPullPhi_vs_Eta_ = ibooker.book2D("PullPhi_vs_Eta",
                                       "Pull(#phi) vs #eta",
                                       hDim.nBinEta,
                                       hDim.minEta,
                                       hDim.maxEta,
                                       hDim.nBinPull,
                                       -hDim.wPull,
                                       hDim.wPull);
  
     // -- Pulls vs Pt
     hPullPt_vs_Pt_ = ibooker.book2D("PullPt_vs_Pt",
                                     "Pull(p_{T}) vs p_{T}",
                                     hDim.nBinPt,
                                     hDim.minPt,
                                     hDim.maxPt,
                                     hDim.nBinPull,
                                     -hDim.wPull,
                                     hDim.wPull);
     hPullEta_vs_Pt_ = ibooker.book2D("PullEta_vs_Pt",
                                      "Pull(#eta) vs p_{T}",
                                      hDim.nBinPt,
                                      hDim.minPt,
                                      hDim.maxPt,
                                      hDim.nBinPull,
                                      -hDim.wPull,
                                      hDim.wPull);
  
     // -- Number of Hits
     const int nHits = 100;
     hNHits_ = ibooker.book1D("NHits", "Number of hits", nHits + 1, -0.5, nHits + 0.5);
     hNHits_vs_Pt_ = ibooker.book2D("NHits_vs_Pt",
                                    "Number of hits vs p_{T}",
                                    hDim.nBinPt,
                                    hDim.minPt,
                                    hDim.maxPt,
                                    nHits / 4 + 1,
                                    -0.25,
                                    nHits + 0.25);
     hNHits_vs_Eta_ = ibooker.book2D("NHits_vs_Eta",
                                     "Number of hits vs #eta",
                                     hDim.nBinEta,
                                     hDim.minEta,
                                     hDim.maxEta,
                                     nHits / 4 + 1,
                                     -0.25,
                                     nHits + 0.25);
     hNSimHits_ = ibooker.book1D("NSimHits", "Number of simHits", nHits + 1, -0.5, nHits + 0.5);
  
     const int nLostHits = 5;
     hNLostHits_ = ibooker.book1D("NLostHits", "Number of Lost hits", nLostHits + 1, -0.5, nLostHits + 0.5);
     hNLostHits_vs_Pt_ = ibooker.book2D("NLostHits_vs_Pt",
                                        "Number of lost Hits vs p_{T}",
                                        hDim.nBinPt,
                                        hDim.minPt,
                                        hDim.maxPt,
                                        nLostHits + 1,
                                        -0.5,
                                        nLostHits + 0.5);
     hNLostHits_vs_Eta_ = ibooker.book2D("NLostHits_vs_Eta",
                                         "Number of lost Hits vs #eta",
                                         hDim.nBinEta,
                                         hDim.minEta,
                                         hDim.maxEta,
                                         nLostHits + 1,
                                         -0.5,
                                         nLostHits + 0.5);
  
     const int nTrackerHits = 40;
     hNTrackerHits_ =
         ibooker.book1D("NTrackerHits", "Number of valid tracker hits", nTrackerHits + 1, -0.5, nTrackerHits + 0.5);
     hNTrackerHits_vs_Pt_ = ibooker.book2D("NTrackerHits_vs_Pt",
                                           "Number of valid traker hits vs p_{T}",
                                           hDim.nBinPt,
                                           hDim.minPt,
                                           hDim.maxPt,
                                           nTrackerHits / 4 + 1,
                                           -0.25,
                                           nTrackerHits + 0.25);
     hNTrackerHits_vs_Eta_ = ibooker.book2D("NTrackerHits_vs_Eta",
                                            "Number of valid tracker hits vs #eta",
                                            hDim.nBinEta,
                                            hDim.minEta,
                                            hDim.maxEta,
                                            nTrackerHits / 4 + 1,
                                            -0.25,
                                            nTrackerHits + 0.25);
  
     const int nMuonHits = 60;
     hNMuonHits_ = ibooker.book1D("NMuonHits", "Number of valid muon hits", nMuonHits + 1, -0.5, nMuonHits + 0.5);
     hNMuonHits_vs_Pt_ = ibooker.book2D("NMuonHits_vs_Pt",
                                        "Number of valid muon hits vs p_{T}",
                                        hDim.nBinPt,
                                        hDim.minPt,
                                        hDim.maxPt,
                                        nMuonHits / 4 + 1,
                                        -0.25,
                                        nMuonHits + 0.25);
     hNMuonHits_vs_Eta_ = ibooker.book2D("NMuonHits_vs_Eta",
                                         "Number of valid muon hits vs #eta",
                                         hDim.nBinEta,
                                         hDim.minEta,
                                         hDim.maxEta,
                                         nMuonHits / 4 + 1,
                                         -0.25,
                                         nMuonHits + 0.25);
  
     hNDof_ = ibooker.book1D("NDof", "Number of DoF", hDim.nDof + 1, -0.5, hDim.nDof + 0.5);
     hChi2_ = ibooker.book1D("Chi2", "#Chi^{2}", hDim.nBinErr, 0, 200);
     hChi2Norm_ = ibooker.book1D("Chi2Norm", "Normalized #Chi^{2}", hDim.nBinErr, 0, 50);
     hChi2Prob_ = ibooker.book1D("Chi2Prob", "Prob(#Chi^{2})", hDim.nBinErr, 0, 1);
  
     hNDof_vs_Eta_ = ibooker.book2D("NDof_vs_Eta",
                                    "Number of DoF vs #eta",
                                    hDim.nBinEta,
                                    hDim.minEta,
                                    hDim.maxEta,
                                    hDim.nDof + 1,
                                    -0.5,
                                    hDim.nDof + 0.5);
     hChi2_vs_Eta_ = ibooker.book2D(
         "Chi2_vs_Eta", "#Chi^{2} vs #eta", hDim.nBinEta, hDim.minEta, hDim.maxEta, hDim.nBinErr, 0., 200.);
     hChi2Norm_vs_Eta_ = ibooker.book2D(
         "Chi2Norm_vs_Eta", "Normalized #Chi^{2} vs #eta", hDim.nBinEta, hDim.minEta, hDim.maxEta, hDim.nBinErr, 0., 50.);
     hChi2Prob_vs_Eta_ = ibooker.book2D(
         "Chi2Prob_vs_Eta", "Prob(#Chi^{2}) vs #eta", hDim.nBinEta, hDim.minEta, hDim.maxEta, hDim.nBinErr, 0., 1.);
  
     hNSimToReco_ =
         ibooker.book1D("NSimToReco", "Number of associated reco tracks", hDim.nAssoc + 1, -0.5, hDim.nAssoc + 0.5);
     hNRecoToSim_ =
         ibooker.book1D("NRecoToSim", "Number of associated sim TP's", hDim.nAssoc + 1, -0.5, hDim.nAssoc + 0.5);
   };

Referenced by RecoMuonValidator::bookHistograms().

◆ fill()

void RecoMuonValidator::MuonME::fill	(	const TrackingParticle *	simRef,
		const Muon *	muonRef
	)

inline

Definition at line 379 of file RecoMuonValidator.cc.

                                                                  {
     const double simP = simRef->p();
     const double simPt = simRef->pt();
     const double simEta = doAbsEta_ ? fabs(simRef->eta()) : simRef->eta();
     const double simPhi = simRef->phi();
     const double simQ = simRef->charge();
     const double simQPt = simQ / simPt;
  
     GlobalPoint simVtx(simRef->vertex().x(), simRef->vertex().y(), simRef->vertex().z());
     GlobalVector simMom(simRef->momentum().x(), simRef->momentum().y(), simRef->momentum().z());
     const double simDxy = -simVtx.x() * sin(simPhi) + simVtx.y() * cos(simPhi);
     const double simDz = simVtx.z() - (simVtx.x() * simMom.x() + simVtx.y() * simMom.y()) * simMom.z() / simMom.perp2();
  
     const double recoQ = muonRef->charge();
     if (simQ * recoQ < 0) {
       hMisQPt_->Fill(simPt);
       hMisQEta_->Fill(simEta);
     }
  
     double recoP, recoPt, recoEta, recoPhi, recoQPt;
     if (usePFMuon_) {
       //      const double origRecoP   = muonRef->p();
       const double origRecoPt = muonRef->pt();
       //      const double origRecoEta = muonRef->eta();
       //      const double origRecoPhi = muonRef->phi();
       const double origRecoQPt = recoQ / origRecoPt;
       recoP = muonRef->pfP4().P();
       recoPt = muonRef->pfP4().Pt();
       recoEta = muonRef->pfP4().Eta();
       recoPhi = muonRef->pfP4().Phi();
       recoQPt = recoQ / recoPt;
       hErrPt_PF_->Fill((recoPt - origRecoPt) / origRecoPt);
       hErrQPt_PF_->Fill((recoQPt - origRecoQPt) / origRecoQPt);
  
       hdPt_vs_Eta_->Fill(recoEta, recoPt - origRecoPt);
       hdPt_vs_Pt_->Fill(recoPt, recoPt - origRecoPt);
  
       int theCorrectPFAss = (fabs(recoPt - simPt) < fabs(origRecoPt - simPt)) ? 1 : 2;
       hPFMomAssCorrectness->Fill(theCorrectPFAss);
       hPt_vs_PFMomAssCorrectness->Fill(simPt, theCorrectPFAss);
     }
  
     else {
       recoP = muonRef->p();
       recoPt = muonRef->pt();
       recoEta = muonRef->eta();
       recoPhi = muonRef->phi();
       recoQPt = recoQ / recoPt;
     }
  
     const double errP = (recoP - simP) / simP;
     const double errPt = (recoPt - simPt) / simPt;
     const double errEta = (recoEta - simEta) / simEta;
     const double errPhi = (recoPhi - simPhi) / simPhi;
     const double errQPt = (recoQPt - simQPt) / simQPt;
  
     hP_->Fill(simP);
     hPt_->Fill(simPt);
     hEta_->Fill(simEta);
     hPhi_->Fill(simPhi);
  
     hErrP_->Fill(errP);
     hErrPt_->Fill(errPt);
     hErrEta_->Fill(errEta);
     hErrPhi_->Fill(errPhi);
  
     if (fabs(simEta) > 0. && fabs(simEta) < 0.8) {
       hErrPBarrel_->Fill(errP);
       hErrPtBarrel_->Fill(errPt);
     } else if (fabs(simEta) > 0.8 && fabs(simEta) < 1.2) {
       hErrPOverlap_->Fill(errP);
       hErrPtOverlap_->Fill(errPt);
     } else if (fabs(simEta) > 1.2) {
       hErrPEndcap_->Fill(errP);
       hErrPtEndcap_->Fill(errPt);
     }
  
     hErrP_vs_Eta_->Fill(simEta, errP);
     hErrPt_vs_Eta_->Fill(simEta, errPt);
     hErrQPt_vs_Eta_->Fill(simEta, errQPt);
  
     hErrP_vs_P_->Fill(simP, errP);
     hErrPt_vs_Pt_->Fill(simPt, errPt);
     hErrQPt_vs_Pt_->Fill(simQPt, errQPt);
  
     hErrEta_vs_Eta_->Fill(simEta, errEta);
  
     //access from track
     reco::TrackRef recoRef = muonRef->track();
     if (recoRef.isNonnull()) {
       // Number of reco-hits
       const int nRecoHits = recoRef->numberOfValidHits();
       const int nLostHits = recoRef->numberOfLostHits();
  
       hNHits_->Fill(nRecoHits);
       hNHits_vs_Pt_->Fill(simPt, nRecoHits);
       hNHits_vs_Eta_->Fill(simEta, nRecoHits);
  
       hNLostHits_->Fill(nLostHits);
       hNLostHits_vs_Pt_->Fill(simPt, nLostHits);
       hNLostHits_vs_Eta_->Fill(simEta, nLostHits);
  
       const double recoNDof = recoRef->ndof();
       const double recoChi2 = recoRef->chi2();
       const double recoChi2Norm = recoRef->normalizedChi2();
       const double recoChi2Prob = TMath::Prob(recoRef->chi2(), static_cast<int>(recoRef->ndof()));
  
       hNDof_->Fill(recoNDof);
       hChi2_->Fill(recoChi2);
       hChi2Norm_->Fill(recoChi2Norm);
       hChi2Prob_->Fill(recoChi2Prob);
  
       hNDof_vs_Eta_->Fill(simEta, recoNDof);
       hChi2_vs_Eta_->Fill(simEta, recoChi2);
       hChi2Norm_vs_Eta_->Fill(simEta, recoChi2Norm);
       hChi2Prob_vs_Eta_->Fill(simEta, recoChi2Prob);
  
       const double recoDxy = recoRef->dxy();
       const double recoDz = recoRef->dz();
  
       const double errDxy = (recoDxy - simDxy) / simDxy;
       const double errDz = (recoDz - simDz) / simDz;
       hErrDxy_->Fill(errDxy);
       hErrDz_->Fill(errDz);
  
       const double pullPt = (recoPt - simPt) / recoRef->ptError();
       const double pullQPt = (recoQPt - simQPt) / recoRef->qoverpError();
       const double pullEta = (recoEta - simEta) / recoRef->etaError();
       const double pullPhi = (recoPhi - simPhi) / recoRef->phiError();
       const double pullDxy = (recoDxy - simDxy) / recoRef->dxyError();
       const double pullDz = (recoDz - simDz) / recoRef->dzError();
  
       hPullPt_->Fill(pullPt);
       hPullEta_->Fill(pullEta);
       hPullPhi_->Fill(pullPhi);
       hPullQPt_->Fill(pullQPt);
       hPullDxy_->Fill(pullDxy);
       hPullDz_->Fill(pullDz);
  
       hPullPt_vs_Eta_->Fill(simEta, pullPt);
       hPullPt_vs_Pt_->Fill(simPt, pullPt);
  
       hPullEta_vs_Eta_->Fill(simEta, pullEta);
       hPullPhi_vs_Eta_->Fill(simEta, pullPhi);
  
       hPullEta_vs_Pt_->Fill(simPt, pullEta);
     }
   };

References TrackingParticle::charge(), reco::LeafCandidate::charge(), funct::cos(), reco::LeafCandidate::eta(), TrackingParticle::eta(), dqm::impl::MonitorElement::Fill(), edm::Ref< C, T, F >::isNonnull(), TrackingParticle::momentum(), TrackingParticle::p(), reco::LeafCandidate::p(), reco::Muon::pfP4(), reco::LeafCandidate::phi(), TrackingParticle::phi(), TrackingParticle::pt(), reco::LeafCandidate::pt(), funct::sin(), reco::Muon::track(), TrackingParticle::vertex(), and PV3DBase< T, PVType, FrameType >::x().

Referenced by RecoMuonValidator::analyze().

Member Data Documentation

◆ doAbsEta_

bool RecoMuonValidator::MuonME::doAbsEta_

Definition at line 76 of file RecoMuonValidator.cc.

◆ hChi2_

MEP RecoMuonValidator::MuonME::hChi2_

Definition at line 73 of file RecoMuonValidator.cc.

◆ hChi2_vs_Eta_

MEP RecoMuonValidator::MuonME::hChi2_vs_Eta_

Definition at line 74 of file RecoMuonValidator.cc.

◆ hChi2Norm_

MEP RecoMuonValidator::MuonME::hChi2Norm_

Definition at line 73 of file RecoMuonValidator.cc.

◆ hChi2Norm_vs_Eta_

MEP RecoMuonValidator::MuonME::hChi2Norm_vs_Eta_

Definition at line 74 of file RecoMuonValidator.cc.

◆ hChi2Prob_

MEP RecoMuonValidator::MuonME::hChi2Prob_

Definition at line 73 of file RecoMuonValidator.cc.

◆ hChi2Prob_vs_Eta_

MEP RecoMuonValidator::MuonME::hChi2Prob_vs_Eta_

Definition at line 74 of file RecoMuonValidator.cc.

◆ hdPt_vs_Eta_

MEP RecoMuonValidator::MuonME::hdPt_vs_Eta_

Definition at line 53 of file RecoMuonValidator.cc.

◆ hdPt_vs_Pt_

MEP RecoMuonValidator::MuonME::hdPt_vs_Pt_

Definition at line 54 of file RecoMuonValidator.cc.

◆ hErrDxy_

MEP RecoMuonValidator::MuonME::hErrDxy_

Definition at line 45 of file RecoMuonValidator.cc.

◆ hErrDz_

MEP RecoMuonValidator::MuonME::hErrDz_

Definition at line 45 of file RecoMuonValidator.cc.

◆ hErrEta_

MEP RecoMuonValidator::MuonME::hErrEta_

Definition at line 42 of file RecoMuonValidator.cc.

◆ hErrEta_vs_Eta_

MEP RecoMuonValidator::MuonME::hErrEta_vs_Eta_

Definition at line 48 of file RecoMuonValidator.cc.

◆ hErrP_

MEP RecoMuonValidator::MuonME::hErrP_

Definition at line 42 of file RecoMuonValidator.cc.

◆ hErrP_vs_Eta_

MEP RecoMuonValidator::MuonME::hErrP_vs_Eta_

Definition at line 47 of file RecoMuonValidator.cc.

◆ hErrP_vs_P_

MEP RecoMuonValidator::MuonME::hErrP_vs_P_

Definition at line 48 of file RecoMuonValidator.cc.

◆ hErrPBarrel_

MEP RecoMuonValidator::MuonME::hErrPBarrel_

Definition at line 43 of file RecoMuonValidator.cc.

◆ hErrPEndcap_

MEP RecoMuonValidator::MuonME::hErrPEndcap_

Definition at line 43 of file RecoMuonValidator.cc.

◆ hErrPhi_

MEP RecoMuonValidator::MuonME::hErrPhi_

Definition at line 42 of file RecoMuonValidator.cc.

◆ hErrPOverlap_

MEP RecoMuonValidator::MuonME::hErrPOverlap_

Definition at line 43 of file RecoMuonValidator.cc.

◆ hErrPt_

MEP RecoMuonValidator::MuonME::hErrPt_

Definition at line 42 of file RecoMuonValidator.cc.

◆ hErrPt_PF_

MEP RecoMuonValidator::MuonME::hErrPt_PF_

Definition at line 51 of file RecoMuonValidator.cc.

◆ hErrPt_vs_Eta_

MEP RecoMuonValidator::MuonME::hErrPt_vs_Eta_

Definition at line 47 of file RecoMuonValidator.cc.

◆ hErrPt_vs_Pt_

MEP RecoMuonValidator::MuonME::hErrPt_vs_Pt_

Definition at line 48 of file RecoMuonValidator.cc.

◆ hErrPtBarrel_

MEP RecoMuonValidator::MuonME::hErrPtBarrel_

Definition at line 44 of file RecoMuonValidator.cc.

◆ hErrPtEndcap_

MEP RecoMuonValidator::MuonME::hErrPtEndcap_

Definition at line 44 of file RecoMuonValidator.cc.

◆ hErrPtOverlap_

MEP RecoMuonValidator::MuonME::hErrPtOverlap_

Definition at line 44 of file RecoMuonValidator.cc.

◆ hErrQPt_PF_

MEP RecoMuonValidator::MuonME::hErrQPt_PF_

Definition at line 52 of file RecoMuonValidator.cc.

◆ hErrQPt_vs_Eta_

MEP RecoMuonValidator::MuonME::hErrQPt_vs_Eta_

Definition at line 47 of file RecoMuonValidator.cc.

◆ hErrQPt_vs_Pt_

MEP RecoMuonValidator::MuonME::hErrQPt_vs_Pt_

Definition at line 48 of file RecoMuonValidator.cc.

◆ hEta_

MEP RecoMuonValidator::MuonME::hEta_

Definition at line 34 of file RecoMuonValidator.cc.

◆ hMisQEta_

MEP RecoMuonValidator::MuonME::hMisQEta_

Definition at line 39 of file RecoMuonValidator.cc.

◆ hMisQPt_

MEP RecoMuonValidator::MuonME::hMisQPt_

Definition at line 39 of file RecoMuonValidator.cc.

◆ hNDof_

MEP RecoMuonValidator::MuonME::hNDof_

Definition at line 73 of file RecoMuonValidator.cc.

◆ hNDof_vs_Eta_

MEP RecoMuonValidator::MuonME::hNDof_vs_Eta_

Definition at line 74 of file RecoMuonValidator.cc.

◆ hNHits_

MEP RecoMuonValidator::MuonME::hNHits_

Definition at line 62 of file RecoMuonValidator.cc.

◆ hNHits_vs_Eta_

MEP RecoMuonValidator::MuonME::hNHits_vs_Eta_

Definition at line 63 of file RecoMuonValidator.cc.

◆ hNHits_vs_Pt_

MEP RecoMuonValidator::MuonME::hNHits_vs_Pt_

Definition at line 63 of file RecoMuonValidator.cc.

◆ hNLostHits_

MEP RecoMuonValidator::MuonME::hNLostHits_

Definition at line 62 of file RecoMuonValidator.cc.

◆ hNLostHits_vs_Eta_

MEP RecoMuonValidator::MuonME::hNLostHits_vs_Eta_

Definition at line 64 of file RecoMuonValidator.cc.

◆ hNLostHits_vs_Pt_

MEP RecoMuonValidator::MuonME::hNLostHits_vs_Pt_

Definition at line 64 of file RecoMuonValidator.cc.

◆ hNMuon_

MEP RecoMuonValidator::MuonME::hNMuon_

Definition at line 35 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hNMuonHits_

MEP RecoMuonValidator::MuonME::hNMuonHits_

Definition at line 62 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hNMuonHits_vs_Eta_

MEP RecoMuonValidator::MuonME::hNMuonHits_vs_Eta_

Definition at line 66 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hNMuonHits_vs_Pt_

MEP RecoMuonValidator::MuonME::hNMuonHits_vs_Pt_

Definition at line 66 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hNRecoToSim_

MEP RecoMuonValidator::MuonME::hNRecoToSim_

Definition at line 60 of file RecoMuonValidator.cc.

◆ hNSim_

MEP RecoMuonValidator::MuonME::hNSim_

Definition at line 35 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hNSimHits_

MEP RecoMuonValidator::MuonME::hNSimHits_

Definition at line 59 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hNSimToReco_

MEP RecoMuonValidator::MuonME::hNSimToReco_

Definition at line 60 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hNTrackerHits_

MEP RecoMuonValidator::MuonME::hNTrackerHits_

Definition at line 62 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hNTrackerHits_vs_Eta_

MEP RecoMuonValidator::MuonME::hNTrackerHits_vs_Eta_

Definition at line 65 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hNTrackerHits_vs_Pt_

MEP RecoMuonValidator::MuonME::hNTrackerHits_vs_Pt_

Definition at line 65 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hNTrks_

MEP RecoMuonValidator::MuonME::hNTrks_

Definition at line 38 of file RecoMuonValidator.cc.

◆ hNTrksEta_

MEP RecoMuonValidator::MuonME::hNTrksEta_

Definition at line 38 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hNTrksPt_

MEP RecoMuonValidator::MuonME::hNTrksPt_

Definition at line 38 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hP_

MEP RecoMuonValidator::MuonME::hP_

Definition at line 34 of file RecoMuonValidator.cc.

◆ hPFMomAssCorrectness

MEP RecoMuonValidator::MuonME::hPFMomAssCorrectness

Definition at line 55 of file RecoMuonValidator.cc.

◆ hPhi_

MEP RecoMuonValidator::MuonME::hPhi_

Definition at line 34 of file RecoMuonValidator.cc.

◆ hPt_

MEP RecoMuonValidator::MuonME::hPt_

Definition at line 34 of file RecoMuonValidator.cc.

◆ hPt_vs_PFMomAssCorrectness

MEP RecoMuonValidator::MuonME::hPt_vs_PFMomAssCorrectness

Definition at line 56 of file RecoMuonValidator.cc.

◆ hPullDxy_

MEP RecoMuonValidator::MuonME::hPullDxy_

Definition at line 69 of file RecoMuonValidator.cc.

◆ hPullDz_

MEP RecoMuonValidator::MuonME::hPullDz_

Definition at line 69 of file RecoMuonValidator.cc.

◆ hPullEta_

MEP RecoMuonValidator::MuonME::hPullEta_

Definition at line 69 of file RecoMuonValidator.cc.

◆ hPullEta_vs_Eta_

MEP RecoMuonValidator::MuonME::hPullEta_vs_Eta_

Definition at line 70 of file RecoMuonValidator.cc.

◆ hPullEta_vs_Pt_

MEP RecoMuonValidator::MuonME::hPullEta_vs_Pt_

Definition at line 70 of file RecoMuonValidator.cc.

◆ hPullPhi_

MEP RecoMuonValidator::MuonME::hPullPhi_

Definition at line 69 of file RecoMuonValidator.cc.

◆ hPullPhi_vs_Eta_

MEP RecoMuonValidator::MuonME::hPullPhi_vs_Eta_

Definition at line 70 of file RecoMuonValidator.cc.

◆ hPullPt_

MEP RecoMuonValidator::MuonME::hPullPt_

Definition at line 69 of file RecoMuonValidator.cc.

◆ hPullPt_vs_Eta_

MEP RecoMuonValidator::MuonME::hPullPt_vs_Eta_

Definition at line 70 of file RecoMuonValidator.cc.

◆ hPullPt_vs_Pt_

MEP RecoMuonValidator::MuonME::hPullPt_vs_Pt_

Definition at line 70 of file RecoMuonValidator.cc.

◆ hPullQPt_

MEP RecoMuonValidator::MuonME::hPullQPt_

Definition at line 69 of file RecoMuonValidator.cc.

◆ hSimDxy_

MEP RecoMuonValidator::MuonME::hSimDxy_

Definition at line 32 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hSimDz_

MEP RecoMuonValidator::MuonME::hSimDz_

Definition at line 32 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hSimEta_

MEP RecoMuonValidator::MuonME::hSimEta_

Definition at line 32 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hSimP_

MEP RecoMuonValidator::MuonME::hSimP_

Definition at line 32 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hSimPhi_

MEP RecoMuonValidator::MuonME::hSimPhi_

Definition at line 32 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ hSimPt_

MEP RecoMuonValidator::MuonME::hSimPt_

Definition at line 32 of file RecoMuonValidator.cc.

Referenced by RecoMuonValidator::analyze().

◆ usePFMuon_

bool RecoMuonValidator::MuonME::usePFMuon_

Definition at line 77 of file RecoMuonValidator.cc.

Public Types

Public Member Functions

Public Attributes

Detailed Description

Member Typedef Documentation

◆ MEP

Member Function Documentation

◆ bookHistos()

◆ fill()

Member Data Documentation

◆ doAbsEta_

◆ hChi2_

◆ hChi2_vs_Eta_

◆ hChi2Norm_

◆ hChi2Norm_vs_Eta_

◆ hChi2Prob_

◆ hChi2Prob_vs_Eta_

◆ hdPt_vs_Eta_

◆ hdPt_vs_Pt_

◆ hErrDxy_

◆ hErrDz_

◆ hErrEta_

◆ hErrEta_vs_Eta_

◆ hErrP_

◆ hErrP_vs_Eta_

◆ hErrP_vs_P_

◆ hErrPBarrel_

◆ hErrPEndcap_

◆ hErrPhi_

◆ hErrPOverlap_

◆ hErrPt_

◆ hErrPt_PF_

◆ hErrPt_vs_Eta_

◆ hErrPt_vs_Pt_

◆ hErrPtBarrel_

◆ hErrPtEndcap_

◆ hErrPtOverlap_

◆ hErrQPt_PF_

◆ hErrQPt_vs_Eta_

◆ hErrQPt_vs_Pt_

◆ hEta_

◆ hMisQEta_

◆ hMisQPt_

◆ hNDof_

◆ hNDof_vs_Eta_

◆ hNHits_

◆ hNHits_vs_Eta_

◆ hNHits_vs_Pt_

◆ hNLostHits_

◆ hNLostHits_vs_Eta_

◆ hNLostHits_vs_Pt_

◆ hNMuon_

◆ hNMuonHits_

◆ hNMuonHits_vs_Eta_

◆ hNMuonHits_vs_Pt_

◆ hNRecoToSim_

◆ hNSim_

◆ hNSimHits_

◆ hNSimToReco_

◆ hNTrackerHits_

◆ hNTrackerHits_vs_Eta_

◆ hNTrackerHits_vs_Pt_

◆ hNTrks_

◆ hNTrksEta_

◆ hNTrksPt_

◆ hP_

◆ hPFMomAssCorrectness

◆ hPhi_

◆ hPt_

◆ hPt_vs_PFMomAssCorrectness

◆ hPullDxy_

◆ hPullDz_

◆ hPullEta_

◆ hPullEta_vs_Eta_

◆ hPullEta_vs_Pt_

◆ hPullPhi_

◆ hPullPhi_vs_Eta_

◆ hPullPt_

◆ hPullPt_vs_Eta_

◆ hPullPt_vs_Pt_