Inheritance diagram for StandaloneTrackMonitor:

Public Member Functions
	StandaloneTrackMonitor (const edm::ParameterSet &)

Public Member Functions inherited from DQMEDAnalyzer
void	accumulate (edm::Event const &event, edm::EventSetup const &setup) final

void	beginLuminosityBlock (edm::LuminosityBlock const &lumi, edm::EventSetup const &setup) final

void	beginRun (edm::Run const &run, edm::EventSetup const &setup) final

void	beginStream (edm::StreamID id) final

	DQMEDAnalyzer ()

void	endLuminosityBlock (edm::LuminosityBlock const &lumi, edm::EventSetup const &setup) final

void	endRun (edm::Run const &run, edm::EventSetup const &setup) final

virtual bool	getCanSaveByLumi ()

Public Member Functions inherited from edm::stream::EDProducer< edm::GlobalCache< DQMEDAnalyzerGlobalCache >, edm::EndRunProducer, edm::EndLuminosityBlockProducer, edm::Accumulator >
	EDProducer ()=default

	EDProducer (const EDProducer &)=delete

bool	hasAbilityToProduceInBeginLumis () const final

bool	hasAbilityToProduceInBeginProcessBlocks () const final

bool	hasAbilityToProduceInBeginRuns () const final

bool	hasAbilityToProduceInEndLumis () const final

bool	hasAbilityToProduceInEndProcessBlocks () const final

bool	hasAbilityToProduceInEndRuns () const final

const EDProducer &	operator= (const EDProducer &)=delete

Protected Member Functions
void	addClusterToMap (uint32_t detid, const SiStripCluster *cluster)

void	analyze (edm::Event const &iEvent, edm::EventSetup const &iSetup) override

void	bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override

void	dqmBeginRun (const edm::Run &iRun, const edm::EventSetup &iSetup) override

void	processClusters (edm::Event const &iEvent, edm::EventSetup const &iSetup, double wfac=1)

void	processHit (const TrackingRecHit &recHit, edm::EventSetup const &iSetup, double wfac=1)

Protected Member Functions inherited from DQMEDAnalyzer
uint64_t	meId () const

Private Attributes
MonitorElement *	beamSpotXYposerrH_

MonitorElement *	beamSpotXYposH_

MonitorElement *	beamSpotZposerrH_

MonitorElement *	beamSpotZposH_

const edm::InputTag	bsTag_

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

MonitorElement *	bunchCrossingH_

std::map< uint32_t, std::set< const SiStripCluster * > >	clusterMap_

const edm::InputTag	clusterTag_

const edm::EDGetTokenT< edmNew::DetSetVector< SiStripCluster > >	clusterToken_

const bool	doPUCorrection_

std::string	folderName_

const edm::ESGetToken< TrackerGeometry, TrackerDigiGeometryRecord >	geomToken_

const bool	haveAllHistograms_

MonitorElement *	hOffTrkClusChargeThickH_

MonitorElement *	hOffTrkClusChargeThinH_

MonitorElement *	hOffTrkClusWidthThickH_

MonitorElement *	hOffTrkClusWidthThinH_

MonitorElement *	hOnTrkClusChargeThickH_

MonitorElement *	hOnTrkClusChargeThinH_

MonitorElement *	hOnTrkClusWidthThickH_

MonitorElement *	hOnTrkClusWidthThinH_

const bool	isMC_

unsigned long long	m_cacheID_

std::string	moduleName_

MonitorElement *	nHitsVsCosThetaH_

MonitorElement *	nHitsVsEtaH_

MonitorElement *	nHitsVsnVtxH_

MonitorElement *	nHitsVsPhiH_

MonitorElement *	nHitsVspTH_

MonitorElement *	nlostHitsH_

MonitorElement *	nLostHitsVsCosThetaH_

MonitorElement *	nLostHitsVsEtaH_

MonitorElement *	nLostHitsVsPhiH_

MonitorElement *	nLostHitsVspTH_

MonitorElement *	nPixBarrelH_

MonitorElement *	nPixEndcapH_

MonitorElement *	nPUH_

MonitorElement *	nStripTECH_

MonitorElement *	nStripTIBH_

MonitorElement *	nStripTIDH_

MonitorElement *	nStripTOBH_

MonitorElement *	nTracksH_

MonitorElement *	nvalidPixelHitsH_

MonitorElement *	nvalidStripHitsH_

MonitorElement *	nvalidTrackerHitsH_

MonitorElement *	nVertexH_

edm::ParameterSet	parameters_

MonitorElement *	pixelLayerwithMeasurementH_

const std::string	puScaleFactorFile_

const edm::InputTag	puSummaryTag_

const edm::EDGetTokenT< std::vector< PileupSummaryInfo > >	puSummaryToken_

SiStripClusterInfo	siStripClusterInfo_

MonitorElement *	stripLayerwithMeasurementH_

const TrackerGeometry *	tkGeom_ = nullptr

MonitorElement *	trackChargeH_

MonitorElement *	trackChi2bynDOFH_

MonitorElement *	trackChi2H_

MonitorElement *	trackCosThetaH_

MonitorElement *	trackd0H_

MonitorElement *	trackEtaerrH_

MonitorElement *	trackEtaH_

MonitorElement *	tracknDOFH_

MonitorElement *	trackPH_

MonitorElement *	trackPhierrH_

MonitorElement *	trackPhiH_

MonitorElement *	trackPterrH_

MonitorElement *	trackPtH_

MonitorElement *	trackPtOver10GeVH_

MonitorElement *	trackPtUpto2GeVH_

MonitorElement *	trackqOverperrH_

MonitorElement *	trackqOverpH_

const std::string	trackQuality_

const edm::InputTag	trackTag_

MonitorElement *	trackThetaerrH_

const edm::EDGetTokenT< reco::TrackCollection >	trackToken_

MonitorElement *	trkLayerwithMeasurementH_

MonitorElement *	trueNIntH_

const bool	verbose_

const edm::InputTag	vertexTag_

const edm::EDGetTokenT< reco::VertexCollection >	vertexToken_

MonitorElement *	vertexXposH_

MonitorElement *	vertexYposH_

MonitorElement *	vertexZposH_

std::vector< float >	vpu_

Additional Inherited Members
Public Types inherited from DQMEDAnalyzer
typedef dqm::reco::DQMStore	DQMStore

typedef dqm::reco::MonitorElement	MonitorElement

Public Types inherited from edm::stream::EDProducer< edm::GlobalCache< DQMEDAnalyzerGlobalCache >, edm::EndRunProducer, edm::EndLuminosityBlockProducer, edm::Accumulator >
using	CacheTypes = CacheContexts< T... >

using	GlobalCache = typename CacheTypes::GlobalCache

using	HasAbility = AbilityChecker< T... >

using	InputProcessBlockCache = typename CacheTypes::InputProcessBlockCache

using	LuminosityBlockCache = typename CacheTypes::LuminosityBlockCache

using	LuminosityBlockContext = LuminosityBlockContextT< LuminosityBlockCache, RunCache, GlobalCache >

using	LuminosityBlockSummaryCache = typename CacheTypes::LuminosityBlockSummaryCache

using	RunCache = typename CacheTypes::RunCache

using	RunContext = RunContextT< RunCache, GlobalCache >

using	RunSummaryCache = typename CacheTypes::RunSummaryCache

Static Public Member Functions inherited from DQMEDAnalyzer
static void	globalEndJob (DQMEDAnalyzerGlobalCache const *)

static void	globalEndLuminosityBlockProduce (edm::LuminosityBlock &lumi, edm::EventSetup const &setup, LuminosityBlockContext const *context)

static void	globalEndRunProduce (edm::Run &run, edm::EventSetup const &setup, RunContext const *context)

static std::unique_ptr< DQMEDAnalyzerGlobalCache >	initializeGlobalCache (edm::ParameterSet const &)

Protected Attributes inherited from DQMEDAnalyzer
edm::EDPutTokenT< DQMToken >	lumiToken_

edm::EDPutTokenT< DQMToken >	runToken_

unsigned int	streamId_

Detailed Description

Definition at line 44 of file StandaloneTrackMonitor.cc.

Constructor & Destructor Documentation

◆ StandaloneTrackMonitor()

StandaloneTrackMonitor::StandaloneTrackMonitor ( const edm::ParameterSet & ps )

Definition at line 162 of file StandaloneTrackMonitor.cc.

     : parameters_(ps),
       moduleName_(parameters_.getUntrackedParameter<std::string>("moduleName", "StandaloneTrackMonitor")),
       folderName_(parameters_.getUntrackedParameter<std::string>("folderName", "highPurityTracks")),
       trackTag_(parameters_.getUntrackedParameter<edm::InputTag>("trackInputTag", edm::InputTag("generalTracks"))),
       bsTag_(parameters_.getUntrackedParameter<edm::InputTag>("offlineBeamSpot", edm::InputTag("offlineBeamSpot"))),
       vertexTag_(
           parameters_.getUntrackedParameter<edm::InputTag>("vertexTag", edm::InputTag("offlinePrimaryVertices"))),
       puSummaryTag_(parameters_.getUntrackedParameter<edm::InputTag>("puTag", edm::InputTag("addPileupInfo"))),
       clusterTag_(parameters_.getUntrackedParameter<edm::InputTag>("clusterTag", edm::InputTag("siStripClusters"))),
       trackToken_(consumes<reco::TrackCollection>(trackTag_)),
       bsToken_(consumes<reco::BeamSpot>(bsTag_)),
       vertexToken_(consumes<reco::VertexCollection>(vertexTag_)),
       puSummaryToken_(consumes<std::vector<PileupSummaryInfo> >(puSummaryTag_)),
       clusterToken_(consumes<edmNew::DetSetVector<SiStripCluster> >(clusterTag_)),
       trackQuality_(parameters_.getUntrackedParameter<std::string>("trackQuality", "highPurity")),
       siStripClusterInfo_(consumesCollector()),
       doPUCorrection_(parameters_.getUntrackedParameter<bool>("doPUCorrection", false)),
       isMC_(parameters_.getUntrackedParameter<bool>("isMC", false)),
       haveAllHistograms_(parameters_.getUntrackedParameter<bool>("haveAllHistograms", false)),
       puScaleFactorFile_(
           parameters_.getUntrackedParameter<std::string>("puScaleFactorFile", "PileupScaleFactor_run203002.root")),
       verbose_(parameters_.getUntrackedParameter<bool>("verbose", false)),
       geomToken_(esConsumes<TrackerGeometry, TrackerDigiGeometryRecord, edm::Transition::BeginRun>()) {
   trackEtaH_ = nullptr;
   trackEtaerrH_ = nullptr;
   trackCosThetaH_ = nullptr;
   trackThetaerrH_ = nullptr;
   trackPhiH_ = nullptr;
   trackPhierrH_ = nullptr;
   trackPH_ = nullptr;
   trackPtH_ = nullptr;
   trackPtUpto2GeVH_ = nullptr;
   trackPtOver10GeVH_ = nullptr;
   trackPterrH_ = nullptr;
   trackqOverpH_ = nullptr;
   trackqOverperrH_ = nullptr;
   trackChargeH_ = nullptr;
   nlostHitsH_ = nullptr;
   nvalidTrackerHitsH_ = nullptr;
   nvalidPixelHitsH_ = nullptr;
   nvalidStripHitsH_ = nullptr;
   trkLayerwithMeasurementH_ = nullptr;
   pixelLayerwithMeasurementH_ = nullptr;
   stripLayerwithMeasurementH_ = nullptr;
   beamSpotXYposH_ = nullptr;
   beamSpotXYposerrH_ = nullptr;
   beamSpotZposH_ = nullptr;
   beamSpotZposerrH_ = nullptr;
   trackChi2H_ = nullptr;
   tracknDOFH_ = nullptr;
   trackd0H_ = nullptr;
   trackChi2bynDOFH_ = nullptr;
   vertexXposH_ = nullptr;
   vertexYposH_ = nullptr;
   vertexZposH_ = nullptr;
  
   nPixBarrelH_ = nullptr;
   nPixEndcapH_ = nullptr;
   nStripTIBH_ = nullptr;
   nStripTOBH_ = nullptr;
   nStripTECH_ = nullptr;
   nStripTIDH_ = nullptr;
   nTracksH_ = nullptr;
  
   // for MC only
   nVertexH_ = nullptr;
   bunchCrossingH_ = nullptr;
   nPUH_ = nullptr;
   trueNIntH_ = nullptr;
  
   nHitsVspTH_ = nullptr;
   nHitsVsEtaH_ = nullptr;
   nHitsVsCosThetaH_ = nullptr;
   nHitsVsPhiH_ = nullptr;
   nHitsVsnVtxH_ = nullptr;
   nLostHitsVspTH_ = nullptr;
   nLostHitsVsEtaH_ = nullptr;
   nLostHitsVsCosThetaH_ = nullptr;
   nLostHitsVsPhiH_ = nullptr;
  
   hOnTrkClusChargeThinH_ = nullptr;
   hOnTrkClusWidthThinH_ = nullptr;
   hOnTrkClusChargeThickH_ = nullptr;
   hOnTrkClusWidthThickH_ = nullptr;
  
   hOffTrkClusChargeThinH_ = nullptr;
   hOffTrkClusWidthThinH_ = nullptr;
   hOffTrkClusChargeThickH_ = nullptr;
   hOffTrkClusWidthThickH_ = nullptr;
  
   // Read pileup weight factors
   if (isMC_ && doPUCorrection_) {
     vpu_.clear();
     TFile* f1 = TFile::Open(puScaleFactorFile_.c_str());
     TH1F* h1 = dynamic_cast<TH1F*>(f1->Get("pileupweight"));
     for (int i = 1; i <= h1->GetNbinsX(); ++i)
       vpu_.push_back(h1->GetBinContent(i));
     f1->Close();
   }
 }

References beamSpotXYposerrH_, beamSpotXYposH_, beamSpotZposerrH_, beamSpotZposH_, bunchCrossingH_, doPUCorrection_, DeadROC_duringRun::f1, hOffTrkClusChargeThickH_, hOffTrkClusChargeThinH_, hOffTrkClusWidthThickH_, hOffTrkClusWidthThinH_, hOnTrkClusChargeThickH_, hOnTrkClusChargeThinH_, hOnTrkClusWidthThickH_, hOnTrkClusWidthThinH_, mps_fire::i, isMC_, nHitsVsCosThetaH_, nHitsVsEtaH_, nHitsVsnVtxH_, nHitsVsPhiH_, nHitsVspTH_, nlostHitsH_, nLostHitsVsCosThetaH_, nLostHitsVsEtaH_, nLostHitsVsPhiH_, nLostHitsVspTH_, nPixBarrelH_, nPixEndcapH_, nPUH_, nStripTECH_, nStripTIBH_, nStripTIDH_, nStripTOBH_, nTracksH_, nvalidPixelHitsH_, nvalidStripHitsH_, nvalidTrackerHitsH_, nVertexH_, pixelLayerwithMeasurementH_, puScaleFactorFile_, stripLayerwithMeasurementH_, trackChargeH_, trackChi2bynDOFH_, trackChi2H_, trackCosThetaH_, trackd0H_, trackEtaerrH_, trackEtaH_, tracknDOFH_, trackPH_, trackPhierrH_, trackPhiH_, trackPterrH_, trackPtH_, trackPtOver10GeVH_, trackPtUpto2GeVH_, trackqOverperrH_, trackqOverpH_, trackThetaerrH_, trkLayerwithMeasurementH_, trueNIntH_, vertexXposH_, vertexYposH_, vertexZposH_, and vpu_.

Member Function Documentation

◆ addClusterToMap()

void StandaloneTrackMonitor::addClusterToMap	(	uint32_t	detid,
		const SiStripCluster *	cluster
	)

protected

Definition at line 752 of file StandaloneTrackMonitor.cc.

                                                                                           {
   std::map<uint32_t, std::set<const SiStripCluster*> >::iterator it = clusterMap_.find(detid);
   if (it == clusterMap_.end()) {
     std::set<const SiStripCluster*> s;
     s.insert(cluster);
     clusterMap_.insert(std::pair<uint32_t, std::set<const SiStripCluster*> >(detid, s));
   } else {
     std::set<const SiStripCluster*>& s = it->second;
     s.insert(cluster);
   }
 }

References clusterMap_, and alignCSCRings::s.

Referenced by processHit().

◆ analyze()

void StandaloneTrackMonitor::analyze	(	edm::Event const &	iEvent,
		edm::EventSetup const &	iSetup
	)

overrideprotectedvirtual

Reimplemented from DQMEDAnalyzer.

Definition at line 462 of file StandaloneTrackMonitor.cc.

                                                                                         {
   // Get event setup (to get global transformation)
  
   siStripClusterInfo_.initEvent(iSetup);
  
   // Primary vertex collection
   edm::Handle<reco::VertexCollection> vertexColl;
   iEvent.getByToken(vertexToken_, vertexColl);
  
   // Beam spot
   edm::Handle<reco::BeamSpot> beamSpot;
   iEvent.getByToken(bsToken_, beamSpot);
  
   // Track collection
   edm::Handle<reco::TrackCollection> tracks;
   iEvent.getByToken(trackToken_, tracks);
  
   // Access PU information
   double wfac = 1.0;  // for data
   if (!iEvent.isRealData()) {
     edm::Handle<std::vector<PileupSummaryInfo> > PupInfo;
     iEvent.getByToken(puSummaryToken_, PupInfo);
  
     if (verbose_)
       edm::LogInfo("StandaloneTrackMonitor") << "nPUColl = " << PupInfo->size();
     for (auto const& v : *PupInfo) {
       int bx = v.getBunchCrossing();
       if (bunchCrossingH_)
         bunchCrossingH_->Fill(bx);
       if (bx == 0) {
         if (nPUH_)
           nPUH_->Fill(v.getPU_NumInteractions());
         int ntrueInt = v.getTrueNumInteractions();
         if (trueNIntH_)
           trueNIntH_->Fill(ntrueInt);
         if (doPUCorrection_)
           if (ntrueInt > -1 && ntrueInt < int(vpu_.size()))
             wfac = vpu_.at(ntrueInt);
       }
     }
   }
   if (verbose_)
     edm::LogInfo("StandaloneTrackMonitor") << "PU reweight factor = " << wfac;
  
   if (!vertexColl.isValid())
     edm::LogError("DqmTrackStudy") << "Error! Failed to get reco::Vertex Collection, " << vertexTag_;
   if (haveAllHistograms_) {
     int nvtx = (vertexColl.isValid() ? vertexColl->size() : 0);
     nVertexH_->Fill(nvtx);
   }
  
   int ntracks = 0;
   if (tracks.isValid()) {
     edm::LogInfo("StandaloneTrackMonitor") << "Total # of Tracks: " << tracks->size();
     if (verbose_)
       edm::LogInfo("StandaloneTrackMonitor") << "Total # of Tracks: " << tracks->size();
     reco::Track::TrackQuality quality = reco::Track::qualityByName(trackQuality_);
     for (auto const& track : *tracks) {
       if (!track.quality(quality))
         continue;
  
       ++ntracks;
  
       double eta = track.eta();
       double theta = track.theta();
       double phi = track.phi();
       double pt = track.pt();
  
       const reco::HitPattern& hitp = track.hitPattern();
       double nValidTrackerHits = hitp.numberOfValidTrackerHits();
       nHitsVsEtaH_->Fill(eta, nValidTrackerHits);
       nHitsVsCosThetaH_->Fill(std::cos(theta), nValidTrackerHits);
       nHitsVsPhiH_->Fill(phi, nValidTrackerHits);
       nHitsVspTH_->Fill(pt, nValidTrackerHits);
       nHitsVsnVtxH_->Fill(vertexColl->size(), nValidTrackerHits);
  
       int nLostHits = track.numberOfLostHits();
       nLostHitsVspTH_->Fill(pt, nLostHits);
       nLostHitsVsEtaH_->Fill(eta, nLostHits);
       nLostHitsVsCosThetaH_->Fill(std::cos(theta), nLostHits);
       nLostHitsVsPhiH_->Fill(phi, nLostHits);
  
       double nValidPixelHits = hitp.numberOfValidPixelHits();
       double nValidStripHits = hitp.numberOfValidStripHits();
       double pixelLayersWithMeasurement = hitp.pixelLayersWithMeasurement();
       double stripLayersWithMeasurement = hitp.stripLayersWithMeasurement();
  
       if (haveAllHistograms_) {
         double etaError = track.etaError();
         double thetaError = track.thetaError();
         double phiError = track.phiError();
         double p = track.p();
         double ptError = track.ptError();
         double qoverp = track.qoverp();
         double qoverpError = track.qoverpError();
         double charge = track.charge();
  
         double trackerLayersWithMeasurement = hitp.trackerLayersWithMeasurement();
  
         double dxy = track.dxy(beamSpot->position());
         double dxyError = track.dxyError();
         double dz = track.dz(beamSpot->position());
         double dzError = track.dzError();
  
         double trkd0 = track.d0();
         double chi2 = track.chi2();
         double ndof = track.ndof();
         double vx = track.vx();
         double vy = track.vy();
         double vz = track.vz();
  
         // Fill the histograms
         trackEtaH_->Fill(eta, wfac);
         trackEtaerrH_->Fill(etaError, wfac);
         trackCosThetaH_->Fill(std::cos(theta), wfac);
         trackThetaerrH_->Fill(thetaError, wfac);
         trackPhiH_->Fill(phi, wfac);
         trackPhierrH_->Fill(phiError, wfac);
         trackPH_->Fill(p, wfac);
         trackPtH_->Fill(pt, wfac);
         if (pt <= 2)
           trackPtUpto2GeVH_->Fill(pt, wfac);
         if (pt >= 10)
           trackPtOver10GeVH_->Fill(pt, wfac);
         trackPterrH_->Fill(ptError, wfac);
         trackqOverpH_->Fill(qoverp, wfac);
         trackqOverperrH_->Fill(qoverpError, wfac);
         trackChargeH_->Fill(charge, wfac);
         trackChi2H_->Fill(chi2, wfac);
         trackd0H_->Fill(trkd0, wfac);
         tracknDOFH_->Fill(ndof, wfac);
         trackChi2bynDOFH_->Fill(chi2 / ndof, wfac);
  
         nlostHitsH_->Fill(nLostHits, wfac);
         nvalidTrackerHitsH_->Fill(nValidTrackerHits, wfac);
         nvalidPixelHitsH_->Fill(nValidPixelHits, wfac);
         nvalidStripHitsH_->Fill(nValidStripHits, wfac);
  
         trkLayerwithMeasurementH_->Fill(trackerLayersWithMeasurement, wfac);
         pixelLayerwithMeasurementH_->Fill(pixelLayersWithMeasurement, wfac);
         stripLayerwithMeasurementH_->Fill(stripLayersWithMeasurement, wfac);
  
         beamSpotXYposH_->Fill(dxy, wfac);
         beamSpotXYposerrH_->Fill(dxyError, wfac);
         beamSpotZposH_->Fill(dz, wfac);
         beamSpotZposerrH_->Fill(dzError, wfac);
  
         vertexXposH_->Fill(vx, wfac);
         vertexYposH_->Fill(vy, wfac);
         vertexZposH_->Fill(vz, wfac);
       }
       int nPixBarrel = 0, nPixEndcap = 0, nStripTIB = 0, nStripTOB = 0, nStripTEC = 0, nStripTID = 0;
       for (auto it = track.recHitsBegin(); it != track.recHitsEnd(); ++it) {
         const TrackingRecHit& hit = (**it);
         if (hit.isValid()) {
           if (hit.geographicalId().det() == DetId::Tracker) {
             int subdetId = hit.geographicalId().subdetId();
             if (subdetId == PixelSubdetector::PixelBarrel)
               ++nPixBarrel;
             else if (subdetId == PixelSubdetector::PixelEndcap)
               ++nPixEndcap;
             else if (subdetId == StripSubdetector::TIB)
               ++nStripTIB;
             else if (subdetId == StripSubdetector::TOB)
               ++nStripTOB;
             else if (subdetId == StripSubdetector::TEC)
               ++nStripTEC;
             else if (subdetId == StripSubdetector::TID)
               ++nStripTID;
  
             // Find on-track clusters
             processHit(hit, iSetup, wfac);
           }
         }
       }
       if (verbose_)
         edm::LogInfo("StandaloneTrackMonitor")
             << " >>> HITs: nPixBarrel: " << nPixBarrel << " nPixEndcap: " << nPixEndcap << " nStripTIB: " << nStripTIB
             << " nStripTOB: " << nStripTOB << " nStripTEC: " << nStripTEC << " nStripTID: " << nStripTID;
       if (haveAllHistograms_) {
         nPixBarrelH_->Fill(nPixBarrel, wfac);
         nPixEndcapH_->Fill(nPixEndcap, wfac);
         nStripTIBH_->Fill(nStripTIB, wfac);
         nStripTOBH_->Fill(nStripTOB, wfac);
         nStripTECH_->Fill(nStripTEC, wfac);
         nStripTIDH_->Fill(nStripTID, wfac);
       }
     }
   } else {
     edm::LogError("DqmTrackStudy") << "Error! Failed to get reco::Track collection, " << trackTag_;
   }
   if (haveAllHistograms_)
     nTracksH_->Fill(ntracks);
  
   // off track cluster properties
   processClusters(iEvent, iSetup, wfac);
 }

References pwdgSkimBPark_cfi::beamSpot, beamSpotXYposerrH_, beamSpotXYposH_, beamSpotZposerrH_, beamSpotZposH_, bsToken_, bunchCrossingH_, l1GtPatternGenerator_cfi::bx, ALCARECOTkAlJpsiMuMu_cff::charge, hltPixelTracks_cff::chi2, funct::cos(), doPUCorrection_, PVValHelper::dxy, PVValHelper::dz, PVValHelper::eta, muonME0PseudoDigis_cfi::etaError, dqm::impl::MonitorElement::Fill(), haveAllHistograms_, iEvent, SiStripClusterInfo::initEvent(), edm::HandleBase::isValid(), ndof, nHitsVsCosThetaH_, nHitsVsEtaH_, nHitsVsnVtxH_, nHitsVsPhiH_, nHitsVspTH_, nlostHitsH_, nLostHitsVsCosThetaH_, nLostHitsVsEtaH_, nLostHitsVsPhiH_, nLostHitsVspTH_, nPixBarrelH_, nPixEndcapH_, nPUH_, nStripTECH_, nStripTIBH_, nStripTIDH_, nStripTOBH_, vertices_cff::ntracks, nTracksH_, reco::HitPattern::numberOfValidPixelHits(), reco::HitPattern::numberOfValidStripHits(), reco::HitPattern::numberOfValidTrackerHits(), nvalidPixelHitsH_, nvalidStripHitsH_, nvalidTrackerHitsH_, nVertexH_, AlCaHLTBitMon_ParallelJobs::p, phi, muonME0PseudoDigis_cfi::phiError, PixelSubdetector::PixelBarrel, PixelSubdetector::PixelEndcap, reco::HitPattern::pixelLayersWithMeasurement(), pixelLayerwithMeasurementH_, processClusters(), processHit(), DiDispStaMuonMonitor_cfi::pt, puSummaryToken_, quality, reco::TrackBase::qualityByName(), siStripClusterInfo_, reco::HitPattern::stripLayersWithMeasurement(), stripLayerwithMeasurementH_, StripSubdetector::TEC, theta(), StripSubdetector::TIB, StripSubdetector::TID, StripSubdetector::TOB, HLT_FULL_cff::track, trackChargeH_, trackChi2bynDOFH_, trackChi2H_, trackCosThetaH_, trackd0H_, DetId::Tracker, reco::HitPattern::trackerLayersWithMeasurement(), trackEtaerrH_, trackEtaH_, tracknDOFH_, trackPH_, trackPhierrH_, trackPhiH_, trackPterrH_, trackPtH_, trackPtOver10GeVH_, trackPtUpto2GeVH_, trackqOverperrH_, trackqOverpH_, trackQuality_, tracks, trackTag_, trackThetaerrH_, trackToken_, trkLayerwithMeasurementH_, trueNIntH_, findQualityFiles::v, verbose_, vertexTag_, vertexToken_, vertexXposH_, vertexYposH_, vertexZposH_, and vpu_.

◆ bookHistograms()

void StandaloneTrackMonitor::bookHistograms	(	DQMStore::IBooker &	iBook,
		edm::Run const &	iRun,
		edm::EventSetup const &	iSetup
	)

overrideprotectedvirtual

Implements DQMEDAnalyzer.

Definition at line 268 of file StandaloneTrackMonitor.cc.

                                                                          {
   edm::ParameterSet TrackEtaHistoPar = parameters_.getParameter<edm::ParameterSet>("trackEtaH");
   edm::ParameterSet TrackPtHistoPar = parameters_.getParameter<edm::ParameterSet>("trackPtH");
  
   std::string currentFolder = moduleName_ + "/" + folderName_;
   iBook.setCurrentFolder(currentFolder);
  
   // The following are common with the official tool
   if (haveAllHistograms_) {
     if (!trackEtaH_)
       trackEtaH_ = iBook.book1D("trackEta",
                                 "Track Eta",
                                 TrackEtaHistoPar.getParameter<int32_t>("Xbins"),
                                 TrackEtaHistoPar.getParameter<double>("Xmin"),
                                 TrackEtaHistoPar.getParameter<double>("Xmax"));
     if (!trackEtaerrH_)
       trackEtaerrH_ = iBook.book1D("trackEtaerr", "Track Eta Error", 50, 0.0, 1.0);
     if (!trackCosThetaH_)
       trackCosThetaH_ = iBook.book1D("trackCosTheta", "Track Cos(Theta)", 50, -1.0, 1.0);
     if (!trackThetaerrH_)
       trackThetaerrH_ = iBook.book1D("trackThetaerr", "Track Theta Error", 50, 0.0, 1.0);
     if (!trackPhiH_)
       trackPhiH_ = iBook.book1D("trackPhi", "Track Phi", 70, -3.5, 3.5);
     if (!trackPhierrH_)
       trackPhierrH_ = iBook.book1D("trackPhierr", "Track Phi Error", 50, 0.0, 1.0);
  
     if (!trackPH_)
       trackPH_ = iBook.book1D("trackP", "Track 4-momentum", 50, 0.0, 10.0);
     if (!trackPtH_)
       trackPtH_ = iBook.book1D("trackPt",
                                "Track Pt",
                                TrackPtHistoPar.getParameter<int32_t>("Xbins"),
                                TrackPtHistoPar.getParameter<double>("Xmin"),
                                TrackPtHistoPar.getParameter<double>("Xmax"));
     if (!trackPtUpto2GeVH_)
       trackPtUpto2GeVH_ = iBook.book1D("trackPtUpto2GeV", "Track Pt upto 2GeV", 100, 0, 2.0);
     if (!trackPtOver10GeVH_)
       trackPtOver10GeVH_ = iBook.book1D("trackPtOver10GeV", "Track Pt greater than 10 GeV", 100, 0, 100.0);
     if (!trackPterrH_)
       trackPterrH_ = iBook.book1D("trackPterr", "Track Pt Error", 100, 0.0, 100.0);
     if (!trackqOverpH_)
       trackqOverpH_ = iBook.book1D("trackqOverp", "q Over p", 40, -10.0, 10.0);
     if (!trackqOverperrH_)
       trackqOverperrH_ = iBook.book1D("trackqOverperr", "q Over p Error", 50, 0.0, 25.0);
     if (!trackChargeH_)
       trackChargeH_ = iBook.book1D("trackCharge", "Track Charge", 50, -5, 5);
     if (!trackChi2H_)
       trackChi2H_ = iBook.book1D("trackChi2", "Chi2", 100, 0.0, 100.0);
     if (!tracknDOFH_)
       tracknDOFH_ = iBook.book1D("tracknDOF", "nDOF", 100, 0.0, 100.0);
     if (!trackd0H_)
       trackd0H_ = iBook.book1D("trackd0", "Track d0", 100, -1, 1);
     if (!trackChi2bynDOFH_)
       trackChi2bynDOFH_ = iBook.book1D("trackChi2bynDOF", "Chi2 Over nDOF", 100, 0.0, 10.0);
  
     if (!nlostHitsH_)
       nlostHitsH_ = iBook.book1D("nlostHits", "No. of Lost Hits", 10, 0.0, 10.0);
     if (!nvalidTrackerHitsH_)
       nvalidTrackerHitsH_ = iBook.book1D("nvalidTrackerhits", "No. of Valid Tracker Hits", 35, 0.0, 35.0);
     if (!nvalidPixelHitsH_)
       nvalidPixelHitsH_ = iBook.book1D("nvalidPixelHits", "No. of Valid Hits in Pixel", 10, 0.0, 10.0);
     if (!nvalidStripHitsH_)
       nvalidStripHitsH_ = iBook.book1D("nvalidStripHits", "No.of Valid Hits in Strip", 25, 0.0, 25.0);
  
     if (!trkLayerwithMeasurementH_)
       trkLayerwithMeasurementH_ = iBook.book1D("trkLayerwithMeasurement", "No. of Layers per Track", 25, 0.0, 25.0);
     if (!pixelLayerwithMeasurementH_)
       pixelLayerwithMeasurementH_ =
           iBook.book1D("pixelLayerwithMeasurement", "No. of Pixel Layers per Track", 10, 0.0, 10.0);
     if (!stripLayerwithMeasurementH_)
       stripLayerwithMeasurementH_ =
           iBook.book1D("stripLayerwithMeasurement", "No. of Strip Layers per Track", 20, 0.0, 20.0);
  
     if (!beamSpotXYposH_)
       beamSpotXYposH_ = iBook.book1D("beamSpotXYpos", "XY position of beam spot", 40, -4.0, 4.0);
     if (!beamSpotXYposerrH_)
       beamSpotXYposerrH_ = iBook.book1D("beamSpotXYposerr", "Error in XY position of beam spot", 20, 0.0, 4.0);
     if (!beamSpotZposH_)
       beamSpotZposH_ = iBook.book1D("beamSpotZpos", "Z position of beam spot", 100, -20.0, 20.0);
     if (!beamSpotZposerrH_)
       beamSpotZposerrH_ = iBook.book1D("beamSpotZposerr", "Error in Z position of beam spot", 50, 0.0, 5.0);
  
     if (!vertexXposH_)
       vertexXposH_ = iBook.book1D("vertexXpos", "Vertex X position", 50, -1.0, 1.0);
     if (!vertexYposH_)
       vertexYposH_ = iBook.book1D("vertexYpos", "Vertex Y position", 50, -1.0, 1.0);
     if (!vertexZposH_)
       vertexZposH_ = iBook.book1D("vertexZpos", "Vertex Z position", 100, -20.0, 20.0);
     if (!nVertexH_)
       nVertexH_ = iBook.book1D("nVertex", "# of vertices", 60, -0.5, 59.5);
  
     if (!nPixBarrelH_)
       nPixBarrelH_ = iBook.book1D("nHitPixelBarrel", "No. of hits in Pixel Barrel per Track", 20, 0, 20.0);
     if (!nPixEndcapH_)
       nPixEndcapH_ = iBook.book1D("nHitPixelEndcap", "No. of hits in Pixel Endcap per Track", 20, 0, 20.0);
     if (!nStripTIBH_)
       nStripTIBH_ = iBook.book1D("nHitStripTIB", "No. of hits in Strip TIB per Track", 30, 0, 30.0);
     if (!nStripTOBH_)
       nStripTOBH_ = iBook.book1D("nHitStripTOB", "No. of hits in Strip TOB per Track", 30, 0, 30.0);
     if (!nStripTECH_)
       nStripTECH_ = iBook.book1D("nHitStripTEC", "No. of hits in Strip TEC per Track", 30, 0, 30.0);
     if (!nStripTIDH_)
       nStripTIDH_ = iBook.book1D("nHitStripTID", "No. of hits in Strip TID per Tracks", 30, 0, 30.0);
  
     if (!nTracksH_)
       nTracksH_ = iBook.book1D("nTracks", "No. of Tracks", 100, -0.5, 999.5);
   }
   if (isMC_) {
     if (!bunchCrossingH_)
       bunchCrossingH_ = iBook.book1D("bunchCrossing", "Bunch Crosssing", 60, 0, 60.0);
     if (!nPUH_)
       nPUH_ = iBook.book1D("nPU", "No of Pileup", 60, 0, 60.0);
     if (!trueNIntH_)
       trueNIntH_ = iBook.book1D("trueNInt", "True no of Interactions", 60, 0, 60.0);
   }
   // Exclusive histograms
   if (!nHitsVspTH_)
     nHitsVspTH_ = iBook.bookProfile("nHitsVspT",
                                     "Number of Hits Vs pT",
                                     TrackPtHistoPar.getParameter<int32_t>("Xbins"),
                                     TrackPtHistoPar.getParameter<double>("Xmin"),
                                     TrackPtHistoPar.getParameter<double>("Xmax"),
                                     0.0,
                                     0.0,
                                     "g");
   if (!nHitsVsnVtxH_)
     nHitsVsnVtxH_ = iBook.bookProfile("nHitsVsnVtx", "Number of Hits Vs Number of Vertex", 100, 0.0, 50, 0.0, 0.0, "g");
   if (!nHitsVsEtaH_)
     nHitsVsEtaH_ = iBook.bookProfile("nHitsVsEta",
                                      "Number of Hits Vs Eta",
                                      TrackEtaHistoPar.getParameter<int32_t>("Xbins"),
                                      TrackEtaHistoPar.getParameter<double>("Xmin"),
                                      TrackEtaHistoPar.getParameter<double>("Xmax"),
                                      0.0,
                                      0.0,
                                      "g");
   if (!nHitsVsCosThetaH_)
     nHitsVsCosThetaH_ =
         iBook.bookProfile("nHitsVsCosTheta", "Number of Hits Vs Cos(Theta)", 50, -1.0, 1.0, 0.0, 0.0, "g");
   if (!nHitsVsPhiH_)
     nHitsVsPhiH_ = iBook.bookProfile("nHitsVsPhi", "Number of Hits Vs Phi", 100, -3.5, 3.5, 0.0, 0.0, "g");
  
   if (!nLostHitsVspTH_)
     nLostHitsVspTH_ = iBook.bookProfile("nLostHitsVspT",
                                         "Number of Lost Hits Vs pT",
                                         TrackPtHistoPar.getParameter<int32_t>("Xbins"),
                                         TrackPtHistoPar.getParameter<double>("Xmin"),
                                         TrackPtHistoPar.getParameter<double>("Xmax"),
                                         0.0,
                                         0.0,
                                         "g");
   if (!nLostHitsVsEtaH_)
     nLostHitsVsEtaH_ = iBook.bookProfile("nLostHitsVsEta",
                                          "Number of Lost Hits Vs Eta",
                                          TrackEtaHistoPar.getParameter<int32_t>("Xbins"),
                                          TrackEtaHistoPar.getParameter<double>("Xmin"),
                                          TrackEtaHistoPar.getParameter<double>("Xmax"),
                                          0.0,
                                          0.0,
                                          "g");
   if (!nLostHitsVsCosThetaH_)
     nLostHitsVsCosThetaH_ =
         iBook.bookProfile("nLostHitsVsCosTheta", "Number of Lost Hits Vs Cos(Theta)", 50, -1.0, 1.0, 0.0, 0.0, "g");
   if (!nLostHitsVsPhiH_)
     nLostHitsVsPhiH_ = iBook.bookProfile("nLostHitsVsPhi", "Number of Lost Hits Vs Phi", 100, -3.5, 3.5, 0.0, 0.0, "g");
  
   // On and off-track cluster properties
   if (!hOnTrkClusChargeThinH_)
     hOnTrkClusChargeThinH_ =
         iBook.book1D("hOnTrkClusChargeThin", "On-track Cluster Charge (Thin Sensor)", 100, 0, 1000);
   if (!hOnTrkClusWidthThinH_)
     hOnTrkClusWidthThinH_ = iBook.book1D("hOnTrkClusWidthThin", "On-track Cluster Width (Thin Sensor)", 20, -0.5, 19.5);
   if (!hOnTrkClusChargeThickH_)
     hOnTrkClusChargeThickH_ =
         iBook.book1D("hOnTrkClusChargeThick", "On-track Cluster Charge (Thick Sensor)", 100, 0, 1000);
   if (!hOnTrkClusWidthThickH_)
     hOnTrkClusWidthThickH_ =
         iBook.book1D("hOnTrkClusWidthThick", "On-track Cluster Width (Thick Sensor)", 20, -0.5, 19.5);
  
   if (!hOffTrkClusChargeThinH_)
     hOffTrkClusChargeThinH_ =
         iBook.book1D("hOffTrkClusChargeThin", "Off-track Cluster Charge (Thin Sensor)", 100, 0, 1000);
   if (!hOffTrkClusWidthThinH_)
     hOffTrkClusWidthThinH_ =
         iBook.book1D("hOffTrkClusWidthThin", "Off-track Cluster Width (Thin Sensor)", 20, -0.5, 19.5);
   if (!hOffTrkClusChargeThickH_)
     hOffTrkClusChargeThickH_ =
         iBook.book1D("hOffTrkClusChargeThick", "Off-track Cluster Charge (Thick Sensor)", 100, 0, 1000);
   if (!hOffTrkClusWidthThickH_)
     hOffTrkClusWidthThickH_ =
         iBook.book1D("hOffTrkClusWidthThick", "Off-track Cluster Width (Thick Sensor)", 20, -0.5, 19.5);
 }

References beamSpotXYposerrH_, beamSpotXYposH_, beamSpotZposerrH_, beamSpotZposH_, dqm::implementation::IBooker::book1D(), dqm::implementation::IBooker::bookProfile(), bunchCrossingH_, folderName_, edm::ParameterSet::getParameter(), haveAllHistograms_, hOffTrkClusChargeThickH_, hOffTrkClusChargeThinH_, hOffTrkClusWidthThickH_, hOffTrkClusWidthThinH_, hOnTrkClusChargeThickH_, hOnTrkClusChargeThinH_, hOnTrkClusWidthThickH_, hOnTrkClusWidthThinH_, isMC_, moduleName_, nHitsVsCosThetaH_, nHitsVsEtaH_, nHitsVsnVtxH_, nHitsVsPhiH_, nHitsVspTH_, nlostHitsH_, nLostHitsVsCosThetaH_, nLostHitsVsEtaH_, nLostHitsVsPhiH_, nLostHitsVspTH_, nPixBarrelH_, nPixEndcapH_, nPUH_, nStripTECH_, nStripTIBH_, nStripTIDH_, nStripTOBH_, nTracksH_, nvalidPixelHitsH_, nvalidStripHitsH_, nvalidTrackerHitsH_, nVertexH_, parameters_, pixelLayerwithMeasurementH_, dqm::implementation::NavigatorBase::setCurrentFolder(), AlCaHLTBitMon_QueryRunRegistry::string, stripLayerwithMeasurementH_, trackChargeH_, trackChi2bynDOFH_, trackChi2H_, trackCosThetaH_, trackd0H_, trackEtaerrH_, trackEtaH_, tracknDOFH_, trackPH_, trackPhierrH_, trackPhiH_, trackPterrH_, trackPtH_, trackPtOver10GeVH_, trackPtUpto2GeVH_, trackqOverperrH_, trackqOverpH_, trackThetaerrH_, trkLayerwithMeasurementH_, trueNIntH_, vertexXposH_, vertexYposH_, and vertexZposH_.

◆ dqmBeginRun()

void StandaloneTrackMonitor::dqmBeginRun	(	const edm::Run &	iRun,
		const edm::EventSetup &	iSetup
	)

overrideprotectedvirtual

Reimplemented from DQMEDAnalyzer.

Definition at line 264 of file StandaloneTrackMonitor.cc.

                                                                                         {
   tkGeom_ = &(iSetup.getData(geomToken_));
 }

References geomToken_, edm::EventSetup::getData(), and tkGeom_.

◆ processClusters()

void StandaloneTrackMonitor::processClusters	(	edm::Event const &	iEvent,
		edm::EventSetup const &	iSetup,
		double	wfac = `1`
	)

protected

Definition at line 659 of file StandaloneTrackMonitor.cc.

                                                                                                              {
   // SiStripClusters
   edm::Handle<edmNew::DetSetVector<SiStripCluster> > clusterHandle;
   iEvent.getByToken(clusterToken_, clusterHandle);
  
   if (clusterHandle.isValid()) {
     // Loop on Dets
     for (edmNew::DetSetVector<SiStripCluster>::const_iterator dsvit = clusterHandle->begin();
          dsvit != clusterHandle->end();
          ++dsvit) {
       uint32_t detId = dsvit->id();
       std::map<uint32_t, std::set<const SiStripCluster*> >::iterator jt = clusterMap_.find(detId);
       bool detid_found = (jt != clusterMap_.end()) ? true : false;
  
       // Loop on Clusters
       for (edmNew::DetSet<SiStripCluster>::const_iterator clusit = dsvit->begin(); clusit != dsvit->end(); ++clusit) {
         if (detid_found) {
           std::set<const SiStripCluster*>& s = jt->second;
           if (s.find(&*clusit) != s.end())
             continue;
         }
  
         siStripClusterInfo_.setCluster(*clusit, detId);
         float charge = siStripClusterInfo_.charge();
         float width = siStripClusterInfo_.width();
  
         const GeomDetUnit* detUnit = tkGeom_->idToDetUnit(detId);
         float thickness = detUnit->surface().bounds().thickness();  // unit cm
         if (thickness > 0.035) {
           hOffTrkClusChargeThickH_->Fill(charge, wfac);
           hOffTrkClusWidthThickH_->Fill(width, wfac);
         } else {
           hOffTrkClusChargeThinH_->Fill(charge, wfac);
           hOffTrkClusWidthThinH_->Fill(width, wfac);
         }
       }
     }
   } else {
     edm::LogError("StandaloneTrackMonitor") << "ClusterCollection " << clusterTag_ << " not valid!!" << std::endl;
   }
 }

References Surface::bounds(), SiStripClusterInfo::charge(), ALCARECOTkAlJpsiMuMu_cff::charge, clusterMap_, clusterTag_, clusterToken_, dqm::impl::MonitorElement::Fill(), hOffTrkClusChargeThickH_, hOffTrkClusChargeThinH_, hOffTrkClusWidthThickH_, hOffTrkClusWidthThinH_, TrackerGeometry::idToDetUnit(), iEvent, edm::HandleBase::isValid(), alignCSCRings::s, SiStripClusterInfo::setCluster(), siStripClusterInfo_, GeomDet::surface(), Bounds::thickness(), Calorimetry_cff::thickness, tkGeom_, ApeEstimator_cff::width, and SiStripClusterInfo::width().

Referenced by analyze().

◆ processHit()

void StandaloneTrackMonitor::processHit	(	const TrackingRecHit &	recHit,
		edm::EventSetup const &	iSetup,
		double	wfac = `1`
	)

protected

Definition at line 700 of file StandaloneTrackMonitor.cc.

                                                                                                               {
   uint32_t detid = recHit.geographicalId();
   const GeomDetUnit* detUnit = tkGeom_->idToDetUnit(detid);
   float thickness = detUnit->surface().bounds().thickness();  // unit cm
  
   auto const& thit = static_cast<BaseTrackerRecHit const&>(recHit);
   if (!thit.isValid())
     return;
  
   auto const& clus = thit.firstClusterRef();
   if (!clus.isValid())
     return;
   if (!clus.isStrip())
     return;
  
   if (thit.isMatched()) {
     const SiStripMatchedRecHit2D& matchedHit = dynamic_cast<const SiStripMatchedRecHit2D&>(recHit);
  
     auto& clusterM = matchedHit.monoCluster();
     siStripClusterInfo_.setCluster(clusterM, detid);
     if (thickness > 0.035) {
       hOnTrkClusChargeThickH_->Fill(siStripClusterInfo_.charge(), wfac);
       hOnTrkClusWidthThickH_->Fill(siStripClusterInfo_.width(), wfac);
     } else {
       hOnTrkClusChargeThinH_->Fill(siStripClusterInfo_.charge(), wfac);
       hOnTrkClusWidthThinH_->Fill(siStripClusterInfo_.width(), wfac);
     }
     addClusterToMap(detid, &clusterM);
  
     auto& clusterS = matchedHit.stereoCluster();
     siStripClusterInfo_.setCluster(clusterS, detid);
     if (thickness > 0.035) {
       hOnTrkClusChargeThickH_->Fill(siStripClusterInfo_.charge(), wfac);
       hOnTrkClusWidthThickH_->Fill(siStripClusterInfo_.width(), wfac);
     } else {
       hOnTrkClusChargeThinH_->Fill(siStripClusterInfo_.charge(), wfac);
       hOnTrkClusWidthThinH_->Fill(siStripClusterInfo_.width(), wfac);
     }
     addClusterToMap(detid, &clusterS);
   } else {
     auto& cluster = clus.stripCluster();
     siStripClusterInfo_.setCluster(cluster, detid);
     if (thickness > 0.035) {
       hOnTrkClusChargeThickH_->Fill(siStripClusterInfo_.charge(), wfac);
       hOnTrkClusWidthThickH_->Fill(siStripClusterInfo_.width(), wfac);
     } else {
       hOnTrkClusChargeThinH_->Fill(siStripClusterInfo_.charge(), wfac);
       hOnTrkClusWidthThinH_->Fill(siStripClusterInfo_.width(), wfac);
     }
     addClusterToMap(detid, &cluster);
   }
 }