Inheritance diagram for AlignmentMonitorTracksFromTrajectories:

Public Member Functions
void	afterAlignment ()

	AlignmentMonitorTracksFromTrajectories (const edm::ParameterSet &cfg, edm::ConsumesCollector iC)

void	book ()
	Book or retrieve histograms; MUST be reimplemented. More...

void	event (const edm::Event &iEvent, const edm::EventSetup &iSetup, const ConstTrajTrackPairCollection &iTrajTracks)
	Called for each event (by "run()"): may be reimplemented. More...

	~AlignmentMonitorTracksFromTrajectories ()

Public Member Functions inherited from AlignmentMonitorBase
	AlignmentMonitorBase (const edm::ParameterSet &cfg, const edm::ConsumesCollector &iC, std::string name)
	Constructor. More...

	AlignmentMonitorBase (const AlignmentMonitorBase &)=delete

void	beginOfJob (AlignableTracker pTracker, AlignableMuon pMuon, AlignmentParameterStore *pStore)
	Called at beginning of job: don't reimplement. More...

void	duringLoop (const edm::Event &iEvent, const edm::EventSetup &iSetup, const ConstTrajTrackPairCollection &iTrajTracks)
	Called for each event: don't reimplement. More...

void	endOfJob ()
	Called at end of processing: don't implement. More...

void	endOfLoop ()
	Called at end of loop: don't reimplement. More...

const AlignmentMonitorBase &	operator= (const AlignmentMonitorBase &)=delete

void	startingNewLoop ()
	Called at beginning of loop: don't reimplement. More...

virtual	~AlignmentMonitorBase ()
	Destructor. More...

Private Attributes
const edm::EDGetTokenT< reco::BeamSpot >	bsToken_

const edm::InputTag	m_beamSpot

TH1F *	m_chi2_100

TH1F *	m_chi2_10000

TH1F *	m_chi2_1000000

TH1F *	m_chi2_improvement

TH1F *	m_chi2_log

TH1F *	m_chi2DOF_100

TH1F *	m_chi2DOF_1000

TH1F *	m_chi2DOF_5

TH1F *	m_chi2DOF_improvement

TH1F *	m_chi2DOF_log

TH1F *	m_diMuon_Jpsi

TH1F *	m_diMuon_log

TH1F *	m_diMuon_Ups

TH1F *	m_diMuon_Z

TH1F *	m_diMuon_Zbackward

TH1F *	m_diMuon_Zbarrel

TH1F *	m_diMuon_Zforward

TH1F *	m_pt [36]

const bool	m_vertexConstraint

MuonServiceProxy *	theMuonServiceProxy

MuonUpdatorAtVertex *	theMuonUpdatorAtVertex

Additional Inherited Members
Public Types inherited from AlignmentMonitorBase
typedef std::pair< const Trajectory , const reco::Track >	ConstTrajTrackPair

typedef std::vector< ConstTrajTrackPair >	ConstTrajTrackPairCollection

Protected Member Functions inherited from AlignmentMonitorBase
TH1F *	book1D (std::string dir, std::string name, std::string title, int nchX, double lowX, double highX)

TH2F *	book2D (std::string dir, std::string name, std::string title, int nchX, double lowX, double highX, int nchY, double lowY, double highY)

TProfile *	bookProfile (std::string dir, std::string name, std::string title, int nchX, double lowX, double highX, int nchY=1, double lowY=0., double highY=0., const char *option="s")

TFileDirectory *	directory (std::string dir)

int	iteration ()

AlignableMuon *	pMuon ()

AlignableNavigator *	pNavigator ()

AlignmentParameterStore *	pStore ()

AlignableTracker *	pTracker ()

Protected Attributes inherited from AlignmentMonitorBase
const edm::InputTag	m_beamSpotTag

Detailed Description

Definition at line 35 of file AlignmentMonitorTracksFromTrajectories.cc.

Constructor & Destructor Documentation

◆ AlignmentMonitorTracksFromTrajectories()

AlignmentMonitorTracksFromTrajectories::AlignmentMonitorTracksFromTrajectories	(	const edm::ParameterSet &	cfg,
		edm::ConsumesCollector	iC
	)

Definition at line 100 of file AlignmentMonitorTracksFromTrajectories.cc.

References looper::cfg, MuonServiceProxy_cff::MuonServiceProxy, MuonUpdatorAtVertex_cff::MuonUpdatorAtVertex, theMuonServiceProxy, and theMuonUpdatorAtVertex.

     : AlignmentMonitorBase(cfg, iC, "AlignmentMonitorTracksFromTrajectories"),
       m_vertexConstraint(cfg.getParameter<bool>("vertexConstraint")),
       m_beamSpot(cfg.getParameter<edm::InputTag>("beamSpot")),
       bsToken_(iC.consumes<reco::BeamSpot>(m_beamSpot)) {
   theMuonServiceProxy = new MuonServiceProxy(cfg.getParameter<edm::ParameterSet>("ServiceParameters"));
   theMuonUpdatorAtVertex = new MuonUpdatorAtVertex(cfg.getParameter<edm::ParameterSet>("MuonUpdatorAtVertexParameters"),
                                                    theMuonServiceProxy);
 }

◆ ~AlignmentMonitorTracksFromTrajectories()

AlignmentMonitorTracksFromTrajectories::~AlignmentMonitorTracksFromTrajectories ( )

inline

Definition at line 38 of file AlignmentMonitorTracksFromTrajectories.cc.

38 {};

Member Function Documentation

◆ afterAlignment()

void AlignmentMonitorTracksFromTrajectories::afterAlignment ( )

virtual

Called after updating AlignableTracker and AlignableMuon (by "endOfLoop()"): may be reimplemented

Reimplemented from AlignmentMonitorBase.

Definition at line 273 of file AlignmentMonitorTracksFromTrajectories.cc.

273 {}

◆ book()

void AlignmentMonitorTracksFromTrajectories::book ( )

virtual

Book or retrieve histograms; MUST be reimplemented.

Implements AlignmentMonitorBase.

Definition at line 119 of file AlignmentMonitorTracksFromTrajectories.cc.

References AlignmentMonitorBase::book1D(), mps_fire::i, m_chi2_100, m_chi2_10000, m_chi2_1000000, m_chi2_improvement, m_chi2_log, m_chi2DOF_100, m_chi2DOF_1000, m_chi2DOF_5, m_chi2DOF_improvement, m_chi2DOF_log, m_diMuon_Jpsi, m_diMuon_log, m_diMuon_Ups, m_diMuon_Z, m_diMuon_Zbackward, m_diMuon_Zbarrel, m_diMuon_Zforward, m_pt, Skims_PA_cff::name, and runGCPTkAlMap::title.

                                                   {
   m_diMuon_Z = book1D("/iterN/", "diMuon_Z", "Di-muon mass (GeV)", 200, 90. - 50., 90. + 50.);
   m_diMuon_Zforward = book1D("/iterN/", "diMuon_Zforward", "Di-muon mass (GeV) eta > 1.4", 200, 90. - 50., 90. + 50.);
   m_diMuon_Zbarrel =
       book1D("/iterN/", "diMuon_Zbarrel", "Di-muon mass (GeV) -1.4 < eta < 1.4", 200, 90. - 50., 90. + 50.);
   m_diMuon_Zbackward =
       book1D("/iterN/", "diMuon_Zbackward", "Di-muon mass (GeV) eta < -1.4", 200, 90. - 50., 90. + 50.);
   m_diMuon_Ups = book1D("/iterN/", "diMuon_Ups", "Di-muon mass (GeV)", 200, 9. - 3., 9. + 3.);
   m_diMuon_Jpsi = book1D("/iterN/", "diMuon_Jpsi", "Di-muon mass (GeV)", 200, 3. - 1., 3. + 1.);
   m_diMuon_log = book1D("/iterN/", "diMuon_log", "Di-muon mass (log GeV)", 300, 0, 3);
   m_chi2_100 = book1D("/iterN/", "m_chi2_100", "Track chi^2", 100, 0, 100);
   m_chi2_10000 = book1D("/iterN/", "m_chi2_10000", "Track chi^2", 100, 0, 10000);
   m_chi2_1000000 = book1D("/iterN/", "m_chi2_1000000", "Track chi^2", 100, 1, 1000000);
   m_chi2_log = book1D("/iterN/", "m_chi2_log", "Log track chi^2", 100, -3, 7);
   m_chi2DOF_5 = book1D("/iterN/", "m_chi2DOF_5", "Track chi^2/nDOF", 100, 0, 5);
   m_chi2DOF_100 = book1D("/iterN/", "m_chi2DOF_100", "Track chi^2/nDOF", 100, 0, 100);
   m_chi2DOF_1000 = book1D("/iterN/", "m_chi2DOF_1000", "Track chi^2/nDOF", 100, 0, 1000);
   m_chi2DOF_log = book1D("/iterN/", "m_chi2DOF_log", "Log track chi^2/nDOF", 100, -3, 7);
   m_chi2_improvement = book1D("/iterN/", "m_chi2_improvement", "Track-by-track chi^2/original chi^2", 100, 0., 10.);
   m_chi2DOF_improvement = book1D(
       "/iterN/", "m_chi2DOF_improvement", "Track-by-track (chi^2/DOF)/(original chi^2/original DOF)", 100, 0., 10.);
   for (int i = 0; i < 36; i++) {
     char name[100], title[100];
     snprintf(name, sizeof(name), "m_pt_phi%d", i);
     snprintf(title, sizeof(title), "Track pt (GeV) in phi bin %d/36", i);
     m_pt[i] = book1D("/iterN/", name, title, 100, 0, 100);
   }
 }

◆ event()

void AlignmentMonitorTracksFromTrajectories::event	(	const edm::Event &	iEvent,
		const edm::EventSetup &	iSetup,
		const ConstTrajTrackPairCollection &	iTrajTracks
	)

virtual

Called for each event (by "run()"): may be reimplemented.

Reimplemented from AlignmentMonitorBase.

Definition at line 152 of file AlignmentMonitorTracksFromTrajectories.cc.

References TrajectoryMeasurement::backwardPredictedState(), pwdgSkimBPark_cfi::beamSpot, bsToken_, nano_mu_local_reco_cff::chi2, Trajectory::chiSquared(), pv::closest(), StorageManager_cfg::e1, hcalRecHitTable_cff::energy, PVValHelper::eta, PV3DBase< T, PVType, FrameType >::eta(), mps_fire::i, iEvent, ALPAKA_ACCELERATOR_NAMESPACE::vertexFinder::it, m_chi2_100, m_chi2_10000, m_chi2_1000000, m_chi2_improvement, m_chi2_log, m_chi2DOF_100, m_chi2DOF_1000, m_chi2DOF_5, m_chi2DOF_improvement, m_chi2DOF_log, m_diMuon_Jpsi, m_diMuon_log, m_diMuon_Ups, m_diMuon_Z, m_diMuon_Zbackward, m_diMuon_Zbarrel, m_diMuon_Zforward, M_PI, m_pt, m_vertexConstraint, PV3DBase< T, PVType, FrameType >::mag(), PV3DBase< T, PVType, FrameType >::mag2(), EgHLTOffHistBins_cfi::mass, Trajectory::measurements(), LaserDQM_cfg::p1, SiStripOfflineCRack_cfg::p2, PV3DBase< T, PVType, FrameType >::perp(), phi, PV3DBase< T, PVType, FrameType >::phi(), MuonUpdatorAtVertex::propagate(), MuonUpdatorAtVertex::propagateWithUpdate(), DiDispStaMuonMonitor_cfi::pt, TrajectoryMeasurement::recHit(), mathSSE::sqrt(), TrajectoryStateOnSurface::surface(), theMuonServiceProxy, theMuonUpdatorAtVertex, Surface::toGlobal(), HLT_2024v12_cff::track, DiMuonV_cfg::tracks, and MuonServiceProxy::update().

Referenced by Types.EventID::cppID().

                                                                                                {
   theMuonServiceProxy->update(iSetup);
 
   const edm::Handle<reco::BeamSpot> &beamSpot = iEvent.getHandle(bsToken_);
 
   GlobalVector p1, p2;
   double e1 = 0.;
   double e2 = 0.;
 
   for (ConstTrajTrackPairCollection::const_iterator it = tracks.begin(); it != tracks.end(); ++it) {
     const Trajectory *traj = it->first;
     const reco::Track *track = it->second;
 
     int nDOF = 0;
     TrajectoryStateOnSurface closestTSOS;
     double closest = 10000.;
 
     std::vector<TrajectoryMeasurement> measurements = traj->measurements();
     for (std::vector<TrajectoryMeasurement>::const_iterator im = measurements.begin(); im != measurements.end(); ++im) {
       const TrajectoryMeasurement meas = *im;
       const TransientTrackingRecHit *hit = &(*meas.recHit());
       //     const DetId id = hit->geographicalId();
 
       nDOF += hit->dimension();
 
       TrajectoryStateOnSurface TSOS = meas.backwardPredictedState();
       GlobalPoint where = TSOS.surface().toGlobal(LocalPoint(0, 0, 0));
 
       if (where.mag() < closest) {
         closest = where.mag();
         closestTSOS = TSOS;
       }
 
     }  // end loop over measurements
     nDOF -= 5;
 
     if (closest != 10000.) {
       std::pair<bool, FreeTrajectoryState> state;
 
       if (m_vertexConstraint) {
         state = theMuonUpdatorAtVertex->propagateWithUpdate(closestTSOS, *beamSpot);
         // add in chi^2 contribution from vertex contratint?
       } else {
         state = theMuonUpdatorAtVertex->propagate(closestTSOS, *beamSpot);
       }
 
       if (state.first) {
         double chi2 = traj->chiSquared();
         double chi2DOF = chi2 / double(nDOF);
 
         m_chi2_100->Fill(chi2);
         m_chi2_10000->Fill(chi2);
         m_chi2_1000000->Fill(chi2);
         m_chi2_log->Fill(log10(chi2));
 
         m_chi2DOF_5->Fill(chi2DOF);
         m_chi2DOF_100->Fill(chi2DOF);
         m_chi2DOF_1000->Fill(chi2DOF);
         m_chi2DOF_log->Fill(log10(chi2DOF));
         m_chi2_improvement->Fill(chi2 / track->chi2());
         m_chi2DOF_improvement->Fill(chi2DOF / track->normalizedChi2());
 
         GlobalVector momentum = state.second.momentum();
         double energy = momentum.mag();
 
         if (energy > e1) {
           e2 = e1;
           e1 = energy;
           p2 = p1;
           p1 = momentum;
         } else if (energy > e2) {
           e2 = energy;
           p2 = momentum;
         }
 
         double pt = momentum.perp();
         double phi = momentum.phi();
         while (phi < -M_PI)
           phi += 2. * M_PI;
         while (phi > M_PI)
           phi -= 2. * M_PI;
 
         double phibin = (phi + M_PI) / (2. * M_PI) * 36.;
 
         for (int i = 0; i < 36; i++) {
           if (phibin < i + 1) {
             m_pt[i]->Fill(pt);
             break;
           }
         }
 
       }  // end if propagate was successful
     }    // end if we have a closest TSOS
   }      // end loop over tracks
 
   if (e1 > 0. && e2 > 0.) {
     double energy_tot = e1 + e2;
     GlobalVector momentum_tot = p1 + p2;
     double mass = sqrt(energy_tot * energy_tot - momentum_tot.mag2());
     double eta = momentum_tot.eta();
 
     m_diMuon_Z->Fill(mass);
     if (eta > 1.4)
       m_diMuon_Zforward->Fill(mass);
     else if (eta > -1.4)
       m_diMuon_Zbarrel->Fill(mass);
     else
       m_diMuon_Zbackward->Fill(mass);
 
     m_diMuon_Ups->Fill(mass);
     m_diMuon_Jpsi->Fill(mass);
     m_diMuon_log->Fill(log10(mass));
   }  // end if we have two tracks
 }