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/data/refman/pasoursint/CMSSW_5_3_3/src/Alignment/CommonAlignmentMonitor/plugins/AlignmentMonitorTracksFromTrajectories.cc

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00001 // -*- C++ -*-
00002 //
00003 // Package:     CommonAlignmentProducer
00004 // Class  :     AlignmentMonitorTracksFromTrajectories
00005 // 
00006 // Implementation:
00007 //     <Notes on implementation>
00008 //
00009 // Original Author:  Jim Pivarski
00010 //         Created:  Thu Jun 28 01:38:33 CDT 2007
00011 //
00012 
00013 // system include files
00014 #include "Alignment/CommonAlignmentMonitor/interface/AlignmentMonitorPluginFactory.h"
00015 #include "FWCore/ParameterSet/interface/ParameterSet.h" 
00016 #include "FWCore/Utilities/interface/InputTag.h" 
00017 #include "TrackingTools/TrajectoryState/interface/FreeTrajectoryState.h" 
00018 #include "DataFormats/GeometrySurface/interface/Surface.h" 
00019 #include "TH1.h" 
00020 #include "TObject.h" 
00021 #include "Alignment/CommonAlignmentMonitor/interface/AlignmentMonitorBase.h"
00022 
00023 #include "RecoMuon/TrackingTools/interface/MuonServiceProxy.h"
00024 #include "RecoMuon/TrackingTools/interface/MuonUpdatorAtVertex.h"
00025 #include "DataFormats/BeamSpot/interface/BeamSpot.h"
00026 
00027 #include <fstream>
00028 
00029 // user include files
00030 
00031 // 
00032 // class definition
00033 // 
00034 
00035 class AlignmentMonitorTracksFromTrajectories: public AlignmentMonitorBase {
00036    public:
00037       AlignmentMonitorTracksFromTrajectories(const edm::ParameterSet& cfg);
00038       ~AlignmentMonitorTracksFromTrajectories() {};
00039 
00040       void book();
00041       void event(const edm::Event &iEvent, const edm::EventSetup &iSetup, const ConstTrajTrackPairCollection& iTrajTracks);
00042       void afterAlignment(const edm::EventSetup &iSetup);
00043 
00044    private:
00045       MuonServiceProxy *theMuonServiceProxy;
00046       MuonUpdatorAtVertex *theMuonUpdatorAtVertex;
00047       bool m_vertexConstraint;
00048       edm::InputTag m_beamSpot;
00049 
00050       TH1F *m_diMuon_Z;
00051       TH1F *m_diMuon_Zforward;
00052       TH1F *m_diMuon_Zbarrel;
00053       TH1F *m_diMuon_Zbackward;
00054       TH1F *m_diMuon_Ups;
00055       TH1F *m_diMuon_Jpsi;
00056       TH1F *m_diMuon_log;
00057       TH1F *m_chi2_100;
00058       TH1F *m_chi2_10000;
00059       TH1F *m_chi2_1000000;
00060       TH1F *m_chi2_log;
00061       TH1F *m_chi2DOF_5;
00062       TH1F *m_chi2DOF_100;
00063       TH1F *m_chi2DOF_1000;
00064       TH1F *m_chi2DOF_log;
00065       TH1F *m_chi2_improvement;
00066       TH1F *m_chi2DOF_improvement;
00067       TH1F *m_pt[36];
00068 };
00069 
00070 //
00071 // constants, enums and typedefs
00072 //
00073 
00074 //
00075 // static data member definitions
00076 //
00077 
00078 //
00079 // constructors and destructor
00080 //
00081 
00082 // AlignmentMonitorTracksFromTrajectories::AlignmentMonitorTracksFromTrajectories(const AlignmentMonitorTracksFromTrajectories& rhs)
00083 // {
00084 //    // do actual copying here;
00085 // }
00086 
00087 //
00088 // assignment operators
00089 //
00090 // const AlignmentMonitorTracksFromTrajectories& AlignmentMonitorTracksFromTrajectories::operator=(const AlignmentMonitorTracksFromTrajectories& rhs)
00091 // {
00092 //   //An exception safe implementation is
00093 //   AlignmentMonitorTracksFromTrajectories temp(rhs);
00094 //   swap(rhs);
00095 //
00096 //   return *this;
00097 // }
00098 
00099 AlignmentMonitorTracksFromTrajectories::AlignmentMonitorTracksFromTrajectories(const edm::ParameterSet& cfg)
00100    : AlignmentMonitorBase(cfg, "AlignmentMonitorTracksFromTrajectories")
00101    , m_vertexConstraint(cfg.getParameter<bool>("vertexConstraint"))
00102    , m_beamSpot(cfg.getParameter<edm::InputTag>("beamSpot"))
00103 {
00104    theMuonServiceProxy = new MuonServiceProxy(cfg.getParameter<edm::ParameterSet>("ServiceParameters"));
00105    theMuonUpdatorAtVertex = new MuonUpdatorAtVertex(cfg.getParameter<edm::ParameterSet>("MuonUpdatorAtVertexParameters"), theMuonServiceProxy);
00106 }
00107 
00108 //
00109 // member functions
00110 //
00111 
00113 // book()
00115 
00116 void AlignmentMonitorTracksFromTrajectories::book() {
00117    m_diMuon_Z = book1D("/iterN/", "diMuon_Z", "Di-muon mass (GeV)", 200, 90. - 50., 90. + 50.);
00118    m_diMuon_Zforward = book1D("/iterN/", "diMuon_Zforward", "Di-muon mass (GeV) eta > 1.4", 200, 90. - 50., 90. + 50.);
00119    m_diMuon_Zbarrel = book1D("/iterN/", "diMuon_Zbarrel", "Di-muon mass (GeV) -1.4 < eta < 1.4", 200, 90. - 50., 90. + 50.);
00120    m_diMuon_Zbackward = book1D("/iterN/", "diMuon_Zbackward", "Di-muon mass (GeV) eta < -1.4", 200, 90. - 50., 90. + 50.);
00121    m_diMuon_Ups = book1D("/iterN/", "diMuon_Ups", "Di-muon mass (GeV)", 200, 9. - 3., 9. + 3.);
00122    m_diMuon_Jpsi = book1D("/iterN/", "diMuon_Jpsi", "Di-muon mass (GeV)", 200, 3. - 1., 3. + 1.);
00123    m_diMuon_log = book1D("/iterN/", "diMuon_log", "Di-muon mass (log GeV)", 300, 0, 3);
00124    m_chi2_100 = book1D("/iterN/", "m_chi2_100", "Track chi^2", 100, 0, 100);
00125    m_chi2_10000 = book1D("/iterN/", "m_chi2_10000", "Track chi^2", 100, 0, 10000);
00126    m_chi2_1000000 = book1D("/iterN/", "m_chi2_1000000", "Track chi^2", 100, 1, 1000000);
00127    m_chi2_log = book1D("/iterN/", "m_chi2_log", "Log track chi^2", 100, -3, 7);
00128    m_chi2DOF_5 = book1D("/iterN/", "m_chi2DOF_5", "Track chi^2/nDOF", 100, 0, 5);
00129    m_chi2DOF_100 = book1D("/iterN/", "m_chi2DOF_100", "Track chi^2/nDOF", 100, 0, 100);
00130    m_chi2DOF_1000 = book1D("/iterN/", "m_chi2DOF_1000", "Track chi^2/nDOF", 100, 0, 1000);
00131    m_chi2DOF_log = book1D("/iterN/", "m_chi2DOF_log", "Log track chi^2/nDOF", 100, -3, 7);
00132    m_chi2_improvement = book1D("/iterN/", "m_chi2_improvement", "Track-by-track chi^2/original chi^2", 100, 0., 10.);
00133    m_chi2DOF_improvement = book1D("/iterN/", "m_chi2DOF_improvement", "Track-by-track (chi^2/DOF)/(original chi^2/original DOF)", 100, 0., 10.);
00134    for (int i = 0;  i < 36;  i++) {
00135       char name[100], title[100];
00136       snprintf(name, sizeof(name), "m_pt_phi%d", i);
00137       snprintf(title, sizeof(title), "Track pt (GeV) in phi bin %d/36", i);
00138       m_pt[i] = book1D("/iterN/", name, title, 100, 0, 100);
00139    }
00140 }
00141 
00143 // event()
00145 
00146 void AlignmentMonitorTracksFromTrajectories::event(const edm::Event &iEvent, const edm::EventSetup &iSetup, const ConstTrajTrackPairCollection& tracks) {
00147    theMuonServiceProxy->update(iSetup);
00148 
00149    edm::Handle<reco::BeamSpot> beamSpot;
00150    iEvent.getByLabel(m_beamSpot, beamSpot);
00151 
00152    GlobalVector p1, p2;
00153    double e1 = 0.;
00154    double e2 = 0.;
00155 
00156    for (ConstTrajTrackPairCollection::const_iterator it = tracks.begin();  it != tracks.end();  ++it) {
00157       const Trajectory *traj = it->first;
00158       const reco::Track *track = it->second;
00159 
00160       int nDOF = 0;
00161       TrajectoryStateOnSurface closestTSOS;
00162       double closest = 10000.;
00163 
00164       std::vector<TrajectoryMeasurement> measurements = traj->measurements();
00165       for (std::vector<TrajectoryMeasurement>::const_iterator im = measurements.begin();  im != measurements.end();  ++im) {
00166          const TrajectoryMeasurement meas = *im;
00167          const TransientTrackingRecHit* hit = &(*meas.recHit());
00168 //       const DetId id = hit->geographicalId();
00169 
00170          nDOF += hit->dimension();
00171 
00172          TrajectoryStateOnSurface TSOS = meas.backwardPredictedState();
00173          GlobalPoint where = TSOS.surface().toGlobal(LocalPoint(0,0,0));
00174 
00175          if (where.mag() < closest) {
00176             closest = where.mag();
00177             closestTSOS = TSOS;
00178          }
00179 
00180       } // end loop over measurements
00181       nDOF -= 5;
00182 
00183       if (closest != 10000.) {
00184          std::pair<bool, FreeTrajectoryState> state;
00185 
00186          if (m_vertexConstraint) {
00187             state = theMuonUpdatorAtVertex->propagateWithUpdate(closestTSOS, *beamSpot);
00188             // add in chi^2 contribution from vertex contratint?
00189          }
00190          else {
00191             state = theMuonUpdatorAtVertex->propagate(closestTSOS, *beamSpot);
00192          }
00193 
00194          if (state.first) {
00195             double chi2 = traj->chiSquared();
00196             double chi2DOF = chi2 / double(nDOF);
00197 
00198             m_chi2_100->Fill(chi2);
00199             m_chi2_10000->Fill(chi2);
00200             m_chi2_1000000->Fill(chi2);
00201             m_chi2_log->Fill(log10(chi2));
00202 
00203             m_chi2DOF_5->Fill(chi2DOF);
00204             m_chi2DOF_100->Fill(chi2DOF);
00205             m_chi2DOF_1000->Fill(chi2DOF);
00206             m_chi2DOF_log->Fill(log10(chi2DOF));
00207             m_chi2_improvement->Fill(chi2 / track->chi2());
00208             m_chi2DOF_improvement->Fill(chi2DOF / track->normalizedChi2());
00209 
00210             GlobalVector momentum = state.second.momentum();
00211             double energy = momentum.mag();
00212 
00213             if (energy > e1) {
00214                e2 = e1;
00215                e1 = energy;
00216                p2 = p1;
00217                p1 = momentum;
00218             }
00219             else if (energy > e2) {
00220                e2 = energy;
00221                p2 = momentum;
00222             }
00223 
00224             double pt = momentum.perp();
00225             double phi = momentum.phi();
00226             while (phi < -M_PI) phi += 2.* M_PI;
00227             while (phi > M_PI) phi -= 2.* M_PI;
00228             
00229             double phibin = (phi + M_PI) / (2. * M_PI) * 36.;
00230 
00231             for (int i = 0;  i < 36;  i++) {
00232                if (phibin < i+1) {
00233                   m_pt[i]->Fill(pt);
00234                   break;
00235                }
00236             }
00237 
00238          } // end if propagate was successful
00239       } // end if we have a closest TSOS
00240    } // end loop over tracks
00241 
00242    if (e1 > 0.  &&  e2 > 0.) {
00243       double energy_tot = e1 + e2;
00244       GlobalVector momentum_tot = p1 + p2;
00245       double mass = sqrt(energy_tot*energy_tot - momentum_tot.mag2());
00246       double eta = momentum_tot.eta();
00247 
00248       m_diMuon_Z->Fill(mass);
00249       if (eta > 1.4) m_diMuon_Zforward->Fill(mass);
00250       else if (eta > -1.4) m_diMuon_Zbarrel->Fill(mass);
00251       else m_diMuon_Zbackward->Fill(mass);
00252 
00253       m_diMuon_Ups->Fill(mass);
00254       m_diMuon_Jpsi->Fill(mass);
00255       m_diMuon_log->Fill(log10(mass));
00256    } // end if we have two tracks
00257 }
00258 
00260 // afterAlignment()
00262 
00263 void AlignmentMonitorTracksFromTrajectories::afterAlignment(const edm::EventSetup &iSetup) {
00264 }
00265 
00266 //
00267 // const member functions
00268 //
00269 
00270 //
00271 // static member functions
00272 //
00273 
00274 //
00275 // SEAL definitions
00276 //
00277 
00278 DEFINE_EDM_PLUGIN(AlignmentMonitorPluginFactory, AlignmentMonitorTracksFromTrajectories, "AlignmentMonitorTracksFromTrajectories");