#include <TrackAnalyzer.h>

Classes
struct	Key

struct	KeyHasher

struct	TkParameterMEs

struct	TkRecHitsPerSubDetMEs

Public Member Functions
virtual void	analyze (const edm::Event &iEvent, const edm::EventSetup &iSetup, const reco::Track &track)

void	doReset ()

void	doSoftReset (DQMStore *dqmStore_)

virtual void	initHisto (DQMStore::IBooker &ibooker, const edm::EventSetup &)

void	setLumiFlag ()

void	setNumberOfGoodVertices (const edm::Event &)

	TrackAnalyzer (const edm::ParameterSet &)

	TrackAnalyzer (const edm::ParameterSet &, edm::ConsumesCollector &iC)

void	undoSoftReset (DQMStore *dqmStore_)

virtual	~TrackAnalyzer ()

Private Member Functions
void	bookHistosForBeamSpot (DQMStore::IBooker &ibooker)

void	bookHistosForEfficiencyFromHitPatter (DQMStore::IBooker &ibooker, const edm::EventSetup &iSetup)

void	bookHistosForHitProperties (DQMStore::IBooker &ibooker)

void	bookHistosForLScertification (DQMStore::IBooker &ibooker)

void	bookHistosForState (std::string sname, DQMStore::IBooker &ibooker)

void	bookHistosForTrackerSpecific (DQMStore::IBooker &ibooker)

void	fillHistosForHitProperties (const edm::EventSetup &iSetup, const reco::Track &track, std::string sname)

void	fillHistosForLScertification (const edm::EventSetup &iSetup, const reco::Track &track, std::string sname)

void	fillHistosForState (const edm::EventSetup &iSetup, const reco::Track &track, std::string sname)

void	fillHistosForTrackerSpecific (const reco::Track &track)

void	initHistos ()

Private Attributes
MonitorElement *	algorithm

edm::EDGetTokenT< reco::BeamSpot >	beamSpotToken_

MonitorElement *	Chi2

MonitorElement *	Chi2oNDF

MonitorElement *	Chi2oNDF_lumiFlag

MonitorElement *	Chi2oNDFVsEta

MonitorElement *	Chi2oNDFVsPhi

MonitorElement *	Chi2oNDFVsTheta

MonitorElement *	Chi2Prob

MonitorElement *	Chi2ProbVsEta

MonitorElement *	Chi2ProbVsPhi

MonitorElement *	Chi2ProbVsTheta

edm::ParameterSet	conf_

MonitorElement *	DistanceOfClosestApproach

MonitorElement *	DistanceOfClosestApproachToBS

MonitorElement *	DistanceOfClosestApproachToBSVsPhi

MonitorElement *	DistanceOfClosestApproachToPV

MonitorElement *	DistanceOfClosestApproachToPVVsPhi

MonitorElement *	DistanceOfClosestApproachVsEta

MonitorElement *	DistanceOfClosestApproachVsPhi

MonitorElement *	DistanceOfClosestApproachVsTheta

MonitorElement *	dNdEta_HighPurity

MonitorElement *	dNdPhi_HighPurity

MonitorElement *	dNdPt_HighPurity

MonitorElement *	dNhitdPt_HighPurity

bool	doAllPlots_

bool	doBSPlots_

bool	doDCAPlots_

bool	doDCAwrt000Plots_

bool	doDCAwrtPVPlots_

bool	doEffFromHitPattern_

bool	doGeneralPropertiesPlots_

bool	doHIPlots_

bool	doHitPropertiesPlots_

bool	doLayersVsPhiVsEtaPerTrack_

bool	doLumiAnalysis_

bool	doMeasurementStatePlots_

bool	doPVPlots_

bool	doRecHitsPerTrackProfile_

bool	doRecHitVsPhiVsEtaPerTrack_

bool	doSIPPlots_

bool	doTestPlots_

bool	doThetaPlots_

bool	doTrack2DChi2Plots_

bool	doTrackerSpecific_

bool	doTrackLayersVsPhiVsEtaPerTrack_

bool	doTrackPxPyPlots_

bool	doTrackRecHitVsPhiVsEtaPerTrack_

unsigned int	good_vertices_

std::string	histname

std::unordered_map< Key, MonitorElement *, KeyHasher >	hits_bad_

std::unordered_map< Key, MonitorElement *, KeyHasher >	hits_inactive_

std::unordered_map< Key, MonitorElement *, KeyHasher >	hits_missing_

std::unordered_map< Key, MonitorElement *, KeyHasher >	hits_total_

std::unordered_map< Key, MonitorElement *, KeyHasher >	hits_valid_

MonitorElement *	LongDCASig

MonitorElement *	NhitVsEta_HighPurity

MonitorElement *	NhitVsPhi_HighPurity

MonitorElement *	NumberOfLayersPerTrack [4] = { 0 , 0 , 0 , 0 }

MonitorElement *	NumberOfLayersPerTrackVsEta

MonitorElement *	NumberOfLayersPerTrackVsPhi

MonitorElement *	NumberOfLayersPerTrackVsTheta

MonitorElement *	NumberOfLayersVsPhiVsEtaPerTrack [4] = { 0 , 0 , 0 , 0 }

MonitorElement *	NumberOfLostRecHitsPerTrack

MonitorElement *	NumberOfLostRecHitsPerTrackVsEta = 0

MonitorElement *	NumberOfLostRecHitsPerTrackVsPhi = 0

MonitorElement *	NumberOfLostRecHitsPerTrackVsTheta = 0

MonitorElement *	NumberOfLostRecHitVsPhiVsEtaPerTrack = 0

MonitorElement *	NumberOfMIRecHitsPerTrack = 0

MonitorElement *	NumberOfMIRecHitsPerTrackVsEta = 0

MonitorElement *	NumberOfMIRecHitsPerTrackVsPhi = 0

MonitorElement *	NumberOfMIRecHitsPerTrackVsTheta = 0

MonitorElement *	NumberOfMIRecHitVsPhiVsEtaPerTrack = 0

MonitorElement *	NumberOfMORecHitsPerTrack = 0

MonitorElement *	NumberOfMORecHitsPerTrackVsEta = 0

MonitorElement *	NumberOfMORecHitsPerTrackVsPhi = 0

MonitorElement *	NumberOfMORecHitsPerTrackVsTheta = 0

MonitorElement *	NumberOfMORecHitVsPhiVsEtaPerTrack = 0

MonitorElement *	NumberOfRecHitsPerTrack

MonitorElement *	NumberOfRecHitsPerTrack_lumiFlag

MonitorElement *	NumberOfRecHitsPerTrackVsEta = 0

MonitorElement *	NumberOfRecHitsPerTrackVsPhi = 0

MonitorElement *	NumberOfRecHitsPerTrackVsTheta = 0

MonitorElement *	NumberOfRecHitVsPhiVsEtaPerTrack = 0

MonitorElement *	NumberOfValidRecHitsPerTrack

MonitorElement *	NumberOfValidRecHitsPerTrackVsEta = 0

MonitorElement *	NumberOfValidRecHitsPerTrackVsPhi = 0

MonitorElement *	NumberOfValidRecHitsPerTrackVsTheta = 0

MonitorElement *	NumberOfValidRecHitVsPhiVsEtaPerTrack = 0

MonitorElement *	oriAlgo

MonitorElement *	Ptdist_HighPurity

edm::EDGetTokenT < reco::VertexCollection >	pvToken_

std::string	qualityString_

MonitorElement *	sip2dToPV

MonitorElement *	sip3dToPV

MonitorElement *	sipDxyToBS

MonitorElement *	sipDxyToPV

MonitorElement *	sipDzToBS

MonitorElement *	sipDzToPV

MonitorElement *	TESTDistanceOfClosestApproachToBS

MonitorElement *	TESTDistanceOfClosestApproachToBSVsPhi

std::map< std::string, TkParameterMEs >	TkParameterMEMap

std::map< std::string, TkRecHitsPerSubDetMEs >	TkRecHitsPerSubDetMEMap

std::string	TopFolder_

MonitorElement *	TransDCASig

MonitorElement *	ValidFractionPerTrack = 0

MonitorElement *	ValidFractionVsPhiVsEtaPerTrack = 0

MonitorElement *	xPointOfClosestApproach

MonitorElement *	xPointOfClosestApproachToPV

MonitorElement *	xPointOfClosestApproachVsZ0wrt000

MonitorElement *	xPointOfClosestApproachVsZ0wrtBS

MonitorElement *	xPointOfClosestApproachVsZ0wrtPV

MonitorElement *	yPointOfClosestApproach

MonitorElement *	yPointOfClosestApproachToPV

MonitorElement *	yPointOfClosestApproachVsZ0wrt000

MonitorElement *	yPointOfClosestApproachVsZ0wrtBS

MonitorElement *	yPointOfClosestApproachVsZ0wrtPV

MonitorElement *	zPointOfClosestApproach

MonitorElement *	zPointOfClosestApproachToPV

MonitorElement *	zPointOfClosestApproachVsPhi

Detailed Description

Definition at line 32 of file TrackAnalyzer.h.

Constructor & Destructor Documentation

TrackAnalyzer::TrackAnalyzer ( const edm::ParameterSet & iConfig )

Definition at line 23 of file TrackAnalyzer.cc.

References conf_, edm::ParameterSet::getParameter(), initHistos(), AlCaHLTBitMon_QueryRunRegistry::string, and TopFolder_.

     : conf_( iConfig )
     , doTrackerSpecific_               ( conf_.getParameter<bool>("doTrackerSpecific") )
     , doAllPlots_                      ( conf_.getParameter<bool>("doAllPlots") )
     , doBSPlots_                       ( conf_.getParameter<bool>("doBeamSpotPlots") )
     , doPVPlots_                       ( conf_.getParameter<bool>("doPrimaryVertexPlots") )
     , doDCAPlots_                      ( conf_.getParameter<bool>("doDCAPlots") )
     , doGeneralPropertiesPlots_        ( conf_.getParameter<bool>("doGeneralPropertiesPlots") )
     , doMeasurementStatePlots_         ( conf_.getParameter<bool>("doMeasurementStatePlots") )
     , doHitPropertiesPlots_            ( conf_.getParameter<bool>("doHitPropertiesPlots") )
     , doRecHitVsPhiVsEtaPerTrack_      ( conf_.getParameter<bool>("doRecHitVsPhiVsEtaPerTrack") )
     , doLayersVsPhiVsEtaPerTrack_      ( conf_.getParameter<bool>("doLayersVsPhiVsEtaPerTrack") )
     , doRecHitsPerTrackProfile_        ( conf_.getParameter<bool>("doRecHitsPerTrackProfile") )
     , doThetaPlots_                    ( conf_.getParameter<bool>("doThetaPlots") )
     , doTrackPxPyPlots_                ( conf_.getParameter<bool>("doTrackPxPyPlots") )
     , doDCAwrtPVPlots_                 ( conf_.getParameter<bool>("doDCAwrtPVPlots") )
     , doDCAwrt000Plots_                ( conf_.getParameter<bool>("doDCAwrt000Plots") )
     , doLumiAnalysis_                  ( conf_.getParameter<bool>("doLumiAnalysis") )
     , doTestPlots_                     ( conf_.getParameter<bool>("doTestPlots") )
     , doHIPlots_                       ( conf_.getParameter<bool>("doHIPlots")  )
     , doSIPPlots_                      ( conf_.getParameter<bool>("doSIPPlots") )
     , doEffFromHitPattern_             ( conf_.getParameter<bool>("doEffFromHitPattern") )
     , qualityString_                   ( conf_.getParameter<std::string>("qualityString"))
     , good_vertices_(0)
 {
   initHistos();
   TopFolder_ = conf_.getParameter<std::string>("FolderName"); 
 }

TrackAnalyzer::TrackAnalyzer	(	const edm::ParameterSet &	iConfig,
		edm::ConsumesCollector &	iC
	)

Definition at line 52 of file TrackAnalyzer.cc.

References beamSpotToken_, conf_, edm::ConsumesCollector::consumes(), edm::ParameterSet::getParameter(), and pvToken_.

   : TrackAnalyzer(iConfig)
 {
   edm::InputTag bsSrc                 = conf_.getParameter<edm::InputTag>("beamSpot");
   edm::InputTag primaryVertexInputTag = conf_.getParameter<edm::InputTag>("primaryVertex");
   beamSpotToken_ = iC.consumes<reco::BeamSpot>(bsSrc);
   pvToken_       = iC.consumes<reco::VertexCollection>(primaryVertexInputTag);
 }

TrackAnalyzer::~TrackAnalyzer ( )

virtual

Definition at line 134 of file TrackAnalyzer.cc.

135 {

136 }

Member Function Documentation

void TrackAnalyzer::analyze	(	const edm::Event &	iEvent,
		const edm::EventSetup &	iSetup,
		const reco::Track &	track
	)

virtual

Definition at line 819 of file TrackAnalyzer.cc.

Referenced by TrackingMonitor::analyze().

 {
   double phi   = track.phi();
   // double eta   = track.eta();
   auto phiIn =  track.innerPosition().phi();
   auto etaIn =  track.innerPosition().eta();
   auto phiOut =  track.outerPosition().phi();
   auto etaOut =  track.outerPosition().eta();
 
   int nRecHits      = track.hitPattern().numberOfHits(reco::HitPattern::TRACK_HITS);
   int nValidRecHits = track.numberOfValidHits();
   int nLostRecHits  = track.numberOfLostHits();
   int nLostIn =      track.hitPattern().numberOfLostTrackerHits(reco::HitPattern::MISSING_INNER_HITS);
   int nLostOut =     track.hitPattern().numberOfLostTrackerHits(reco::HitPattern::MISSING_OUTER_HITS);
 
   double chi2     = track.chi2();
   double chi2prob = TMath::Prob(track.chi2(),(int)track.ndof());
   double chi2oNDF = track.normalizedChi2();
   
   if ( doHitPropertiesPlots_ || doAllPlots_ ){
     // rec hits
     NumberOfRecHitsPerTrack     -> Fill(nRecHits);
     NumberOfValidRecHitsPerTrack-> Fill(nValidRecHits);
     NumberOfLostRecHitsPerTrack -> Fill(nLostRecHits);
     NumberOfMIRecHitsPerTrack -> Fill(nLostIn);
     NumberOfMORecHitsPerTrack -> Fill(nLostOut);
     ValidFractionPerTrack -> Fill(track.validFraction());
 
 
     // 2D plots    
     if ( doRecHitVsPhiVsEtaPerTrack_ || doAllPlots_ ) {
       NumberOfValidRecHitVsPhiVsEtaPerTrack->Fill(etaIn,phiIn,nValidRecHits);
       NumberOfLostRecHitVsPhiVsEtaPerTrack->Fill(etaIn,phiIn,nLostRecHits);
       NumberOfMIRecHitVsPhiVsEtaPerTrack->Fill(etaIn,phiIn,nLostIn);
       NumberOfMORecHitVsPhiVsEtaPerTrack->Fill(etaOut,phiOut,nLostOut);
       ValidFractionVsPhiVsEtaPerTrack -> Fill(etaIn,phiIn,track.validFraction());
     }
 
     int nLayers[4]   = { track.hitPattern().trackerLayersWithMeasurement(),
                          track.hitPattern().trackerLayersTotallyOffOrBad(),
                          track.hitPattern().numberOfValidStripLayersWithMonoAndStereo() +  track.hitPattern().pixelLayersWithMeasurement(),
                          track.hitPattern().trackerLayersWithoutMeasurement(reco::HitPattern::TRACK_HITS)
                        };
 
     // layers
     for (int i=0;i<4;++i) NumberOfLayersPerTrack[i]->Fill(nLayers[i]);
 
     // 2D plots    
     if ( doLayersVsPhiVsEtaPerTrack_ || doAllPlots_ )
       for (int i=0;i<4;++i) NumberOfLayersVsPhiVsEtaPerTrack[i]->Fill(etaIn,phiIn,nLayers[i]);
 
   }
 
   if (doEffFromHitPattern_ || doAllPlots_) {
     if (track.pt() > 1.0 && track.dxy() < 0.1 and good_vertices_ > 0) {
       auto hp = track.hitPattern();
       // Here hit_category is meant to iterate over
       // reco::HitPattern::HitCategory, defined here:
       // http://cmslxr.fnal.gov/dxr/CMSSW/source/DataFormats/TrackReco/interface/HitPattern.h
       for (unsigned int category = 0; category < 3; ++category) {
         for (int hit = 0; hit < hp.numberOfHits((reco::HitPattern::HitCategory)(category)); ++hit) {
           auto pattern = hp.getHitPattern((reco::HitPattern::HitCategory)(category), hit);
           // Boolean bad is missing simply because it is inferred and the only missing case.
           bool valid = hp.validHitFilter(pattern);
           bool missing = hp.missingHitFilter(pattern);
           bool inactive = hp.inactiveHitFilter(pattern);
           int hit_type = -1;
           hit_type = valid ? 0 :
               ( missing ? 1 :
                 ( inactive ? 2 : 3));
           if (hits_valid_.find(Key(hp.getSubStructure(pattern), hp.getSubSubStructure(pattern))) == hits_valid_.end()) {
             LogDebug("TrackAnalyzer") << "Invalid combination of detector and subdetector: ("
                                       << hp.getSubStructure(pattern) << ", "
                                       << hp.getSubSubStructure(pattern)
                                       << "): ignoring it.\n";
             continue;
           }
           switch (hit_type) {
             case 0:
               hits_valid_[Key(hp.getSubStructure(pattern), hp.getSubSubStructure(pattern))]->Fill(good_vertices_);
               hits_total_[Key(hp.getSubStructure(pattern), hp.getSubSubStructure(pattern))]->Fill(good_vertices_);
               break;
             case 1:
               hits_missing_[Key(hp.getSubStructure(pattern), hp.getSubSubStructure(pattern))]->Fill(good_vertices_);
               hits_total_[Key(hp.getSubStructure(pattern), hp.getSubSubStructure(pattern))]->Fill(good_vertices_);
               break;
             case 2:
               hits_inactive_[Key(hp.getSubStructure(pattern), hp.getSubSubStructure(pattern))]->Fill(good_vertices_);
               break;
             case 3:
               hits_bad_[Key(hp.getSubStructure(pattern), hp.getSubSubStructure(pattern))]->Fill(good_vertices_);
               break;
             default:
               LogDebug("TrackAnalyzer") << "Invalid hit category used " << hit_type << " ignored\n";
           }
         }
       }
     }
   }
   
   if (doGeneralPropertiesPlots_ || doAllPlots_){
     // fitting
     Chi2     -> Fill(chi2);
     Chi2Prob -> Fill(chi2prob);
     Chi2oNDF -> Fill(chi2oNDF);
 
     // DCA
     // temporary patch in order to put back those MEs in Muon Workspace 
     if (doDCAPlots_) {
       if (doDCAwrt000Plots_) {
     DistanceOfClosestApproach->Fill(track.dxy());
     DistanceOfClosestApproachVsPhi->Fill(phi, track.dxy());
       }
 
       // PCA
       xPointOfClosestApproach->Fill(track.referencePoint().x());
       yPointOfClosestApproach->Fill(track.referencePoint().y());
       zPointOfClosestApproach->Fill(track.referencePoint().z());
     }
 
     // algorithm
     algorithm->Fill(static_cast<double>(track.algo()));
     oriAlgo->Fill(static_cast<double>(track.originalAlgo()));
   }
 
   if ( doLumiAnalysis_ ) {
     NumberOfRecHitsPerTrack_lumiFlag -> Fill(nRecHits);
     Chi2oNDF_lumiFlag                -> Fill(chi2oNDF);
   }
 
   if(doDCAPlots_ || doBSPlots_ || doSIPPlots_ || doAllPlots_) {
     
     edm::Handle<reco::BeamSpot> recoBeamSpotHandle;
     iEvent.getByToken(beamSpotToken_,recoBeamSpotHandle);
     const reco::BeamSpot& bs = *recoBeamSpotHandle;
 
     DistanceOfClosestApproachToBS      -> Fill(track.dxy(bs.position()));
     DistanceOfClosestApproachToBSVsPhi -> Fill(track.phi(), track.dxy(bs.position()));
     zPointOfClosestApproachVsPhi       -> Fill(track.phi(), track.vz());
     xPointOfClosestApproachVsZ0wrt000  -> Fill(track.dz(),  track.vx());
     yPointOfClosestApproachVsZ0wrt000  -> Fill(track.dz(),  track.vy());
     xPointOfClosestApproachVsZ0wrtBS   -> Fill(track.dz(bs.position()),(track.vx()-bs.position(track.vz()).x()));
     yPointOfClosestApproachVsZ0wrtBS   -> Fill(track.dz(bs.position()),(track.vy()-bs.position(track.vz()).y()));
     if (doTestPlots_) {
       TESTDistanceOfClosestApproachToBS      -> Fill(track.dxy(bs.position(track.vz())));
       TESTDistanceOfClosestApproachToBSVsPhi -> Fill(track.phi(), track.dxy(bs.position(track.vz())));
     }
 
     if(doSIPPlots_) {
       sipDxyToBS->Fill(track.dxy(bs.position())/track.dxyError());
       sipDzToBS->Fill(track.dz(bs.position())/track.dzError());
     }
   }
   
   if(doDCAPlots_ || doPVPlots_ || doSIPPlots_ || doAllPlots_) {
     edm::Handle<reco::VertexCollection> recoPrimaryVerticesHandle;
     iEvent.getByToken(pvToken_,recoPrimaryVerticesHandle);
     if (recoPrimaryVerticesHandle.isValid() && recoPrimaryVerticesHandle->size() > 0) {
       const reco::Vertex& pv = (*recoPrimaryVerticesHandle)[0];
     
 
       //HI PLOTS/////// 
 
       if(doHIPlots_)
     {
        double longDCAsig = 0, transDCAsig = 0;
        double zerr2 = track.dzError()*track.dzError()+pv.zError()*pv.zError();
        double xyerr2 = track.d0Error()*track.d0Error()+pv.xError()*pv.yError();
        if(zerr2 > 0) longDCAsig = track.dz(pv.position())/zerr2;
            if(xyerr2 > 0) transDCAsig = track.dxy(pv.position())/xyerr2;       
        LongDCASig->Fill(longDCAsig);
        TransDCASig->Fill(transDCAsig);
 
 
        
 
        if(track.quality(reco::TrackBase::qualityByName(qualityString_)) ==1)
          {
            dNdEta_HighPurity->Fill(track.eta());
            dNdPhi_HighPurity->Fill(track.phi());
            dNdPt_HighPurity->Fill(track.ptError()/track.pt());
            NhitVsEta_HighPurity->Fill(track.eta(),track.numberOfValidHits());
            NhitVsPhi_HighPurity->Fill(track.phi(),track.numberOfValidHits());
            dNhitdPt_HighPurity->Fill(track.pt(),track.numberOfValidHits());
            Ptdist_HighPurity->Fill(track.pt());
          }//end of high quality tracks requirement
         }
 
 
       xPointOfClosestApproachToPV->Fill(track.vx()-pv.position().x());
       yPointOfClosestApproachToPV->Fill(track.vy()-pv.position().y());
       zPointOfClosestApproachToPV->Fill(track.dz(pv.position()));
       DistanceOfClosestApproachToPV      -> Fill(track.dxy(pv.position()));
       DistanceOfClosestApproachToPVVsPhi -> Fill(track.phi(), track.dxy(pv.position()));
       xPointOfClosestApproachVsZ0wrtPV   -> Fill(track.dz(pv.position()),(track.vx()-pv.position().x()));
       yPointOfClosestApproachVsZ0wrtPV   -> Fill(track.dz(pv.position()),(track.vy()-pv.position().y()));
 
 
       if(doSIPPlots_) {
         edm::ESHandle<TransientTrackBuilder> theB;
         iSetup.get<TransientTrackRecord>().get("TransientTrackBuilder",theB);
         reco::TransientTrack transTrack = theB->build(track);
 
         GlobalVector dir(track.px(), track.py(), track.pz());
         std::pair<bool, Measurement1D> ip3d = IPTools::signedImpactParameter3D(transTrack, dir, pv);
         std::pair<bool, Measurement1D> ip2d = IPTools::signedTransverseImpactParameter(transTrack, dir, pv);
         if(ip3d.first) sip3dToPV->Fill(ip3d.second.value() / ip3d.second.error());
         if(ip2d.first) sip2dToPV->Fill(ip2d.second.value() / ip2d.second.error());
         sipDxyToPV->Fill(track.dxy(pv.position())/track.dxyError());
         sipDzToPV->Fill(track.dz(pv.position())/track.dzError());
       }
     }
   }
 
   if(doDCAPlots_ || doAllPlots_) {
     if (doDCAwrt000Plots_) {
       if (doThetaPlots_) {
     DistanceOfClosestApproachVsTheta->Fill(track.theta(), track.d0());
       }
       DistanceOfClosestApproachVsEta->Fill(track.eta(), track.d0());
     }  
     
   }
 
   //Tracker Specific Histograms
   if(doTrackerSpecific_ || doAllPlots_) {
     fillHistosForTrackerSpecific(track);
   }
 
   if (doMeasurementStatePlots_ || doAllPlots_){
     std::string StateName = conf_.getParameter<std::string>("MeasurementState");
 
     if (StateName == "All") {
       fillHistosForState(iSetup, track, std::string("OuterSurface"));
       fillHistosForState(iSetup, track, std::string("InnerSurface"));
       fillHistosForState(iSetup, track, std::string("ImpactPoint"));
     } else if ( 
            StateName != "OuterSurface" && 
            StateName != "InnerSurface" && 
            StateName != "ImpactPoint" &&
            StateName != "default" 
            ) {
       fillHistosForState(iSetup, track, std::string("default"));
     } else {
       fillHistosForState(iSetup, track, StateName);
     }
   }
   
   if ( doAllPlots_ ) {
   }
 
 }

void TrackAnalyzer::bookHistosForBeamSpot ( DQMStore::IBooker & ibooker )

private

Definition at line 562 of file TrackAnalyzer.cc.

Referenced by initHisto().

                                                                    {
 
     // parameters from the configuration
     std::string QualName       = conf_.getParameter<std::string>("Quality");
     std::string AlgoName       = conf_.getParameter<std::string>("AlgoName");
 
     // use the AlgoName and Quality Name 
     std::string CategoryName = QualName != "" ? AlgoName + "_" + QualName : AlgoName;
 
     // book the Beam Spot related histograms
     // ---------------------------------------------------------------------------------//
     
     if(doDCAPlots_ || doBSPlots_ || doAllPlots_) {
     
       int    DxyBin       = conf_.getParameter<int>(   "DxyBin");
       double DxyMin       = conf_.getParameter<double>("DxyMin");
       double DxyMax       = conf_.getParameter<double>("DxyMax");
       
       int    PhiBin     = conf_.getParameter<int>(   "PhiBin");
       double PhiMin     = conf_.getParameter<double>("PhiMin");
       double PhiMax     = conf_.getParameter<double>("PhiMax");
       
       int    X0Bin        = conf_.getParameter<int>(   "X0Bin");
       double X0Min        = conf_.getParameter<double>("X0Min");
       double X0Max        = conf_.getParameter<double>("X0Max");
       
       int    Y0Bin        = conf_.getParameter<int>(   "Y0Bin");
       double Y0Min        = conf_.getParameter<double>("Y0Min");
       double Y0Max        = conf_.getParameter<double>("Y0Max");
       
       int    Z0Bin        = conf_.getParameter<int>(   "Z0Bin");
       double Z0Min        = conf_.getParameter<double>("Z0Min");
       double Z0Max        = conf_.getParameter<double>("Z0Max");
       
       int    VZBinProf    = conf_.getParameter<int>(   "VZBinProf");
       double VZMinProf    = conf_.getParameter<double>("VZMinProf");
       double VZMaxProf    = conf_.getParameter<double>("VZMaxProf");
       
       
       ibooker.setCurrentFolder(TopFolder_+"/GeneralProperties");
       
       histname = "DistanceOfClosestApproachToBS_";
       DistanceOfClosestApproachToBS = ibooker.book1D(histname+CategoryName,histname+CategoryName,DxyBin,DxyMin,DxyMax);
       DistanceOfClosestApproachToBS->setAxisTitle("Track d_{xy} wrt beam spot (cm)",1);
       DistanceOfClosestApproachToBS->setAxisTitle("Number of Tracks",2);
       
       histname = "DistanceOfClosestApproachToBSVsPhi_";
       DistanceOfClosestApproachToBSVsPhi = ibooker.bookProfile(histname+CategoryName,histname+CategoryName, PhiBin, PhiMin, PhiMax, DxyBin, DxyMin, DxyMax,"");
       DistanceOfClosestApproachToBSVsPhi->getTH1()->SetCanExtend(TH1::kAllAxes);
       DistanceOfClosestApproachToBSVsPhi->setAxisTitle("Track #phi",1);
       DistanceOfClosestApproachToBSVsPhi->setAxisTitle("Track d_{xy} wrt beam spot (cm)",2);
       
       histname = "xPointOfClosestApproachVsZ0wrt000_";
       xPointOfClosestApproachVsZ0wrt000 = ibooker.bookProfile(histname+CategoryName, histname+CategoryName, Z0Bin, Z0Min, Z0Max, X0Bin, X0Min, X0Max,"");
       xPointOfClosestApproachVsZ0wrt000->setAxisTitle("d_{z} (cm)",1);
       xPointOfClosestApproachVsZ0wrt000->setAxisTitle("x component of Track PCA to beam line (cm)",2);
       
       histname = "yPointOfClosestApproachVsZ0wrt000_";
       yPointOfClosestApproachVsZ0wrt000 = ibooker.bookProfile(histname+CategoryName, histname+CategoryName, Z0Bin, Z0Min, Z0Max, Y0Bin, Y0Min, Y0Max,"");
       yPointOfClosestApproachVsZ0wrt000->setAxisTitle("d_{z} (cm)",1);
       yPointOfClosestApproachVsZ0wrt000->setAxisTitle("y component of Track PCA to beam line (cm)",2);
       
       histname = "xPointOfClosestApproachVsZ0wrtBS_";
       xPointOfClosestApproachVsZ0wrtBS = ibooker.bookProfile(histname+CategoryName, histname+CategoryName, Z0Bin, Z0Min, Z0Max, X0Bin, X0Min, X0Max,"");
       xPointOfClosestApproachVsZ0wrtBS->setAxisTitle("d_{z} w.r.t. Beam Spot  (cm)",1);
       xPointOfClosestApproachVsZ0wrtBS->setAxisTitle("x component of Track PCA to BS (cm)",2);
       
       histname = "yPointOfClosestApproachVsZ0wrtBS_";
       yPointOfClosestApproachVsZ0wrtBS = ibooker.bookProfile(histname+CategoryName, histname+CategoryName, Z0Bin, Z0Min, Z0Max, Y0Bin, Y0Min, Y0Max,"");
       yPointOfClosestApproachVsZ0wrtBS->setAxisTitle("d_{z} w.r.t. Beam Spot (cm)",1);
       yPointOfClosestApproachVsZ0wrtBS->setAxisTitle("y component of Track PCA to BS (cm)",2);
       
       histname = "zPointOfClosestApproachVsPhi_";
       zPointOfClosestApproachVsPhi = ibooker.bookProfile(histname+CategoryName, histname+CategoryName, PhiBin, PhiMin, PhiMax, VZBinProf, VZMinProf, VZMaxProf, "");
       zPointOfClosestApproachVsPhi->setAxisTitle("Track #phi",1);
       zPointOfClosestApproachVsPhi->setAxisTitle("y component of Track PCA to beam line (cm)",2);
     }
     
     if(doDCAPlots_ || doPVPlots_ || doAllPlots_) {
       
       int    DxyBin       = conf_.getParameter<int>(   "DxyBin");
       double DxyMin       = conf_.getParameter<double>("DxyMin");
       double DxyMax       = conf_.getParameter<double>("DxyMax");
       
       int    PhiBin     = conf_.getParameter<int>(   "PhiBin");
       double PhiMin     = conf_.getParameter<double>("PhiMin");
       double PhiMax     = conf_.getParameter<double>("PhiMax");
       
       int    X0Bin        = conf_.getParameter<int>(   "X0Bin");
       double X0Min        = conf_.getParameter<double>("X0Min");
       double X0Max        = conf_.getParameter<double>("X0Max");
       
       int    Y0Bin        = conf_.getParameter<int>(   "Y0Bin");
       double Y0Min        = conf_.getParameter<double>("Y0Min");
       double Y0Max        = conf_.getParameter<double>("Y0Max");
       
       int    Z0Bin        = conf_.getParameter<int>(   "Z0Bin");
       double Z0Min        = conf_.getParameter<double>("Z0Min");
       double Z0Max        = conf_.getParameter<double>("Z0Max");
       
       ibooker.setCurrentFolder(TopFolder_+"/GeneralProperties");
       
       histname = "DistanceOfClosestApproachToPV_";
       DistanceOfClosestApproachToPV = ibooker.book1D(histname+CategoryName,histname+CategoryName,DxyBin,DxyMin,DxyMax);
       DistanceOfClosestApproachToPV->setAxisTitle("Track d_{xy} wrt beam spot (cm)",1);
       DistanceOfClosestApproachToPV->setAxisTitle("Number of Tracks",2);
       
       histname = "DistanceOfClosestApproachToPVVsPhi_";
       DistanceOfClosestApproachToPVVsPhi = ibooker.bookProfile(histname+CategoryName,histname+CategoryName, PhiBin, PhiMin, PhiMax, DxyBin, DxyMin, DxyMax,"");
       DistanceOfClosestApproachToPVVsPhi->getTH1()->SetCanExtend(TH1::kAllAxes);
       DistanceOfClosestApproachToPVVsPhi->setAxisTitle("Track #phi",1);
       DistanceOfClosestApproachToPVVsPhi->setAxisTitle("Track d_{xy} wrt beam spot (cm)",2);
       
       histname = "xPointOfClosestApproachVsZ0wrtPV_";
       xPointOfClosestApproachVsZ0wrtPV = ibooker.bookProfile(histname+CategoryName, histname+CategoryName, Z0Bin, Z0Min, Z0Max, X0Bin, X0Min, X0Max,"");
       xPointOfClosestApproachVsZ0wrtPV->setAxisTitle("d_{z} w.r.t. Beam Spot  (cm)",1);
       xPointOfClosestApproachVsZ0wrtPV->setAxisTitle("x component of Track PCA to PV (cm)",2);
       
       histname = "yPointOfClosestApproachVsZ0wrtPV_";
       yPointOfClosestApproachVsZ0wrtPV = ibooker.bookProfile(histname+CategoryName, histname+CategoryName, Z0Bin, Z0Min, Z0Max, Y0Bin, Y0Min, Y0Max,"");
       yPointOfClosestApproachVsZ0wrtPV->setAxisTitle("d_{z} w.r.t. Beam Spot (cm)",1);
       yPointOfClosestApproachVsZ0wrtPV->setAxisTitle("y component of Track PCA to PV (cm)",2);
       
     }
 
     if (doBSPlots_ || doAllPlots_) {
       if (doTestPlots_) {
     
     int    DxyBin       = conf_.getParameter<int>(   "DxyBin");
     double DxyMin       = conf_.getParameter<double>("DxyMin");
     double DxyMax       = conf_.getParameter<double>("DxyMax");
       
     int    PhiBin     = conf_.getParameter<int>(   "PhiBin");
     double PhiMin     = conf_.getParameter<double>("PhiMin");
     double PhiMax     = conf_.getParameter<double>("PhiMax");
 
     histname = "TESTDistanceOfClosestApproachToBS_";
     TESTDistanceOfClosestApproachToBS = ibooker.book1D(histname+CategoryName,histname+CategoryName,DxyBin,DxyMin,DxyMax);
     TESTDistanceOfClosestApproachToBS->setAxisTitle("Track d_{xy} wrt beam spot (cm)",1);
     TESTDistanceOfClosestApproachToBS->setAxisTitle("Number of Tracks",2);
     
     histname = "TESTDistanceOfClosestApproachToBSVsPhi_";
     TESTDistanceOfClosestApproachToBSVsPhi = ibooker.bookProfile(histname+CategoryName,histname+CategoryName, PhiBin, PhiMin, PhiMax, DxyBin, DxyMin, DxyMax,"");
     TESTDistanceOfClosestApproachToBSVsPhi->getTH1()->SetCanExtend(TH1::kAllAxes);
     TESTDistanceOfClosestApproachToBSVsPhi->setAxisTitle("Track #phi",1);
     TESTDistanceOfClosestApproachToBSVsPhi->setAxisTitle("Track d_{xy} wrt beam spot (cm)",2);
     
       }
       
     }
     
     // book the Profile plots for DCA related histograms
     // ---------------------------------------------------------------------------------//
     if(doDCAPlots_ || doAllPlots_) {
 
       if (doDCAwrt000Plots_) {
 
     int    EtaBin     = conf_.getParameter<int>(   "EtaBin");
     double EtaMin     = conf_.getParameter<double>("EtaMin");
     double EtaMax     = conf_.getParameter<double>("EtaMax");
     
     int    PhiBin     = conf_.getParameter<int>(   "PhiBin");
     double PhiMin     = conf_.getParameter<double>("PhiMin");
     double PhiMax     = conf_.getParameter<double>("PhiMax");
 
     int    DxyBin       = conf_.getParameter<int>(   "DxyBin");
     double DxyMin       = conf_.getParameter<double>("DxyMin");
     double DxyMax       = conf_.getParameter<double>("DxyMax");
       
     if (doThetaPlots_) {
       int    ThetaBin   = conf_.getParameter<int>(   "ThetaBin");
       double ThetaMin   = conf_.getParameter<double>("ThetaMin");
       double ThetaMax   = conf_.getParameter<double>("ThetaMax");
       
       ibooker.setCurrentFolder(TopFolder_+"/GeneralProperties");
       histname = "DistanceOfClosestApproachVsTheta_";
       DistanceOfClosestApproachVsTheta = ibooker.bookProfile(histname+CategoryName,histname+CategoryName, ThetaBin, ThetaMin, ThetaMax, DxyMin,DxyMax,"");
       DistanceOfClosestApproachVsTheta->setAxisTitle("Track #theta",1);
       DistanceOfClosestApproachVsTheta->setAxisTitle("Track d_{xy} wrt (0,0,0) (cm)",2);
     }
     
     histname = "DistanceOfClosestApproachVsEta_";
     DistanceOfClosestApproachVsEta = ibooker.bookProfile(histname+CategoryName,histname+CategoryName, EtaBin, EtaMin, EtaMax, DxyMin, DxyMax,"");
     DistanceOfClosestApproachVsEta->setAxisTitle("Track #eta",1);
     DistanceOfClosestApproachVsEta->setAxisTitle("Track d_{xy} wrt (0,0,0) (cm)",2);
     // temporary patch in order to put back those MEs in Muon Workspace
     
     histname = "DistanceOfClosestApproach_";
     DistanceOfClosestApproach = ibooker.book1D(histname+CategoryName,histname+CategoryName,DxyBin,DxyMin,DxyMax);
     DistanceOfClosestApproach->setAxisTitle("Track d_{xy} wrt (0,0,0) (cm)",1);
     DistanceOfClosestApproach->setAxisTitle("Number of Tracks",2);
     
     histname = "DistanceOfClosestApproachVsPhi_";
     DistanceOfClosestApproachVsPhi = ibooker.bookProfile(histname+CategoryName,histname+CategoryName, PhiBin, PhiMin, PhiMax, DxyMin,DxyMax,"");
     DistanceOfClosestApproachVsPhi->getTH1()->SetCanExtend(TH1::kAllAxes);
     DistanceOfClosestApproachVsPhi->setAxisTitle("Track #phi",1);
     DistanceOfClosestApproachVsPhi->setAxisTitle("Track d_{xy} wrt (0,0,0) (cm)",2);
       }
     }
 
 
     if (doSIPPlots_ || doAllPlots_) {
       const double sipBins = 200;
       const double sipMin = -20;
       const double sipMax = 20;
 
       ibooker.setCurrentFolder(TopFolder_+"/GeneralProperties");
 
       // SIP wrt. beamspot
       histname = "SIPDxyToBS_";
       sipDxyToBS = ibooker.book1D(histname+CategoryName, histname+CategoryName, sipBins, sipMin, sipMax);
       sipDxyToBS->setAxisTitle("Track dxy significance wrt beam spot",1);
       sipDxyToBS->setAxisTitle("Number of Tracks",2);
 
       histname = "SIPDzToBS_";
       sipDzToBS = ibooker.book1D(histname+CategoryName, histname+CategoryName, sipBins, sipMin, sipMax);
       sipDzToBS->setAxisTitle("Track dz significance wrt beam spot",1);
       sipDzToBS->setAxisTitle("Number of Tracks",2);
 
       // SIP wrt. vertex
       histname = "SIP3DToPV_";
       sip3dToPV = ibooker.book1D(histname+CategoryName, histname+CategoryName, sipBins, sipMin, sipMax);
       sip3dToPV->setAxisTitle("3D IP significance wrt primary vertex",1);
       sip3dToPV->setAxisTitle("Number of Tracks",2);
 
       histname = "SIP2DToPV_";
       sip2dToPV = ibooker.book1D(histname+CategoryName, histname+CategoryName, sipBins, sipMin, sipMax);
       sip2dToPV->setAxisTitle("2D IP significance wrt primary vertex",1);
       sip2dToPV->setAxisTitle("Number of Tracks",2);
 
       histname = "SIPDxyToPV_";
       sipDxyToPV = ibooker.book1D(histname+CategoryName, histname+CategoryName, sipBins, sipMin, sipMax);
       sipDxyToPV->setAxisTitle("Track dxy significance wrt primary vertex",1);
       sipDxyToPV->setAxisTitle("Number of Tracks",2);
 
       histname = "SIPDzToPV_";
       sipDzToPV = ibooker.book1D(histname+CategoryName, histname+CategoryName, sipBins, sipMin, sipMax);
       sipDzToPV->setAxisTitle("Track dz significance wrt primary vertex",1);
       sipDzToPV->setAxisTitle("Number of Tracks",2);
     }
 }

void TrackAnalyzer::bookHistosForEfficiencyFromHitPatter	(	DQMStore::IBooker &	ibooker,
		const edm::EventSetup &	iSetup
	)

private

Definition at line 175 of file TrackAnalyzer.cc.

References DQMStore::IBooker::book1D(), doAllPlots_, doEffFromHitPattern_, edm::EventSetup::get(), hits_bad_, hits_inactive_, hits_missing_, hits_total_, hits_valid_, LogDebug, DQMStore::IBooker::setCurrentFolder(), indexGen::title, and TopFolder_.

Referenced by initHisto().

 {
   if (doEffFromHitPattern_ || doAllPlots_) {
     ibooker.setCurrentFolder(TopFolder_ + "/HitEffFromHitPattern");
   
     edm::ESHandle<TrackerGeometry> trackerGeometry;
     iSetup.get<TrackerDigiGeometryRecord>().get(trackerGeometry);
 
     // Values are not ordered randomly, but the order is taken from
     // http://cmslxr.fnal.gov/dxr/CMSSW/source/Geometry/CommonDetUnit/interface/GeomDetEnumerators.h#15
     const char * dets[] = { "None", "PXB", "PXF", "TIB", "TID", "TOB", "TEC"};
 
     // Also in this case, ordering is not random but extracted from
     // http://cmslxr.fnal.gov/dxr/CMSSW/source/DataFormats/TrackReco/interface/HitPattern.h
     // The category "total" is an addition to ease the computation of
     // the efficiencies and is not part of the original HitPattern.
     const char * hit_category[] = { "valid", "missing", "inactive", "bad", "total"};
 
     // We set sub_det to be a 1-based index since to it is the sub-sub-structure in the HitPattern
     char title[50];
     for (unsigned int det = 1; det < sizeof(dets)/sizeof(char*); ++det ) {
       for (unsigned int sub_det = 1;
            sub_det <= trackerGeometry->numberOfLayers(det); ++sub_det) {
         for (unsigned int cat = 0;
              cat < sizeof(hit_category)/sizeof(char *); ++cat) {
           memset(title, 0, sizeof(title));
           snprintf(title, sizeof(title), "Hits_%s_%s_Subdet%d", hit_category[cat], dets[det], sub_det);
           switch(cat) {
             case 0:
               hits_valid_.insert(std::make_pair(
                   Key(det, sub_det),
                   ibooker.book1D(title, title, 50, 0.5, 50.5)));
               break;
             case 1:
               hits_missing_.insert(std::make_pair(
                   Key(det, sub_det),
                   ibooker.book1D(title, title, 50, 0.5, 50.5)));
               break;
             case 2:
               hits_inactive_.insert(std::make_pair(
                   Key(det, sub_det),
                   ibooker.book1D(title, title, 50, 0.5, 50.5)));
               break;
             case 3:
               hits_bad_.insert(std::make_pair(
                   Key(det, sub_det),
                   ibooker.book1D(title, title, 50, 0.5, 50.5)));
               break;
             case 4:
               hits_total_.insert(std::make_pair(
                   Key(det, sub_det),
                   ibooker.book1D(title, title, 50, 0.5, 50.5)));
               break;
             default:
               LogDebug("TrackAnalyzer") << "Invalid hit category used " << cat << " ignored\n";
           }
         }
       }
     }
   }
 }

void TrackAnalyzer::bookHistosForHitProperties ( DQMStore::IBooker & ibooker )

private

Definition at line 238 of file TrackAnalyzer.cc.

References HLT_25ns14e33_v1_cff::AlgoName, reco::TrackBase::algoNames, algorithm, reco::TrackBase::algoSize, DQMStore::IBooker::book1D(), DQMStore::IBooker::bookProfile(), DQMStore::IBooker::bookProfile2D(), Chi2oNDF, Chi2Prob, conf_, dNdEta_HighPurity, dNdPhi_HighPurity, dNdPt_HighPurity, dNhitdPt_HighPurity, doAllPlots_, doDCAPlots_, doGeneralPropertiesPlots_, doHIPlots_, doHitPropertiesPlots_, doLayersVsPhiVsEtaPerTrack_, doPVPlots_, doRecHitVsPhiVsEtaPerTrack_, doSIPPlots_, HLT_25ns14e33_v3_cff::EtaMax, Gflash::EtaMin, edm::ParameterSet::getParameter(), histname, i, LongDCASig, NhitVsEta_HighPurity, NhitVsPhi_HighPurity, NumberOfLayersPerTrack, NumberOfLayersVsPhiVsEtaPerTrack, NumberOfLostRecHitsPerTrack, NumberOfLostRecHitVsPhiVsEtaPerTrack, NumberOfMIRecHitsPerTrack, NumberOfMIRecHitVsPhiVsEtaPerTrack, NumberOfMORecHitsPerTrack, NumberOfMORecHitVsPhiVsEtaPerTrack, NumberOfRecHitsPerTrack, NumberOfValidRecHitsPerTrack, NumberOfValidRecHitVsPhiVsEtaPerTrack, oriAlgo, Ptdist_HighPurity, MonitorElement::setAxisTitle(), MonitorElement::setBinLabel(), DQMStore::IBooker::setCurrentFolder(), AlCaHLTBitMon_QueryRunRegistry::string, TopFolder_, TransDCASig, ValidFractionPerTrack, ValidFractionVsPhiVsEtaPerTrack, xPointOfClosestApproach, xPointOfClosestApproachToPV, yPointOfClosestApproach, yPointOfClosestApproachToPV, zPointOfClosestApproach, and zPointOfClosestApproachToPV.

Referenced by initHisto().

                                                                         {
   
     // parameters from the configuration
     std::string QualName       = conf_.getParameter<std::string>("Quality");
     std::string AlgoName       = conf_.getParameter<std::string>("AlgoName");
     std::string MEBSFolderName = conf_.getParameter<std::string>("BSFolderName"); 
 
     // use the AlgoName and Quality Name 
     std::string CategoryName = QualName != "" ? AlgoName + "_" + QualName : AlgoName;
 
     // get binning from the configuration
     int    TKHitBin     = conf_.getParameter<int>(   "RecHitBin");
     double TKHitMin     = conf_.getParameter<double>("RecHitMin");
     double TKHitMax     = conf_.getParameter<double>("RecHitMax");
 
     int    TKLostBin    = conf_.getParameter<int>(   "RecLostBin");
     double TKLostMin    = conf_.getParameter<double>("RecLostMin");
     double TKLostMax    = conf_.getParameter<double>("RecLostMax");
 
     int    TKLayBin     = conf_.getParameter<int>(   "RecLayBin");
     double TKLayMin     = conf_.getParameter<double>("RecLayMin");
     double TKLayMax     = conf_.getParameter<double>("RecLayMax");
 
     int    PhiBin       = conf_.getParameter<int>(   "PhiBin");
     double PhiMin       = conf_.getParameter<double>("PhiMin");
     double PhiMax       = conf_.getParameter<double>("PhiMax");
 
     int    EtaBin       = conf_.getParameter<int>(   "EtaBin");
     double EtaMin       = conf_.getParameter<double>("EtaMin");
     double EtaMax       = conf_.getParameter<double>("EtaMax");
 
     int    VXBin        = conf_.getParameter<int>(   "VXBin");
     double VXMin        = conf_.getParameter<double>("VXMin");
     double VXMax        = conf_.getParameter<double>("VXMax");
 
     int    VYBin        = conf_.getParameter<int>(   "VYBin");
     double VYMin        = conf_.getParameter<double>("VYMin");
     double VYMax        = conf_.getParameter<double>("VYMax");
 
     int    VZBin        = conf_.getParameter<int>(   "VZBin");
     double VZMin        = conf_.getParameter<double>("VZMin");
     double VZMax        = conf_.getParameter<double>("VZMax");
 
     ibooker.setCurrentFolder(TopFolder_);
 
     // book the Hit Property histograms
     // ---------------------------------------------------------------------------------//
 
     TkParameterMEs tkmes;
     if ( doHitPropertiesPlots_ || doAllPlots_ ){
 
       ibooker.setCurrentFolder(TopFolder_+"/HitProperties");
       
       histname = "NumberOfRecHitsPerTrack_";
       NumberOfRecHitsPerTrack = ibooker.book1D(histname+CategoryName, histname+CategoryName, TKHitBin, TKHitMin, TKHitMax);
       NumberOfRecHitsPerTrack->setAxisTitle("Number of all RecHits of each Track");
       NumberOfRecHitsPerTrack->setAxisTitle("Number of Tracks", 2);
 
       histname = "NumberOfValidRecHitsPerTrack_";
       NumberOfValidRecHitsPerTrack = ibooker.book1D(histname+CategoryName, histname+CategoryName, TKHitBin, TKHitMin, TKHitMax);
       NumberOfValidRecHitsPerTrack->setAxisTitle("Number of valid RecHits for each Track");
       NumberOfValidRecHitsPerTrack->setAxisTitle("Number of Tracks", 2);
 
       histname = "NumberOfLostRecHitsPerTrack_";
       NumberOfLostRecHitsPerTrack = ibooker.book1D(histname+CategoryName, histname+CategoryName, TKLostBin, TKLostMin, TKLostMax);
       NumberOfLostRecHitsPerTrack->setAxisTitle("Number of lost RecHits for each Track");
       NumberOfLostRecHitsPerTrack->setAxisTitle("Number of Tracks", 2);
 
       histname = "NumberOfMissingInnerRecHitsPerTrack_";
       NumberOfMIRecHitsPerTrack = ibooker.book1D(histname+CategoryName, histname+CategoryName, 10, -0.5, 9.5);
       NumberOfMIRecHitsPerTrack->setAxisTitle("Number of missing-inner RecHits for each Track");
       NumberOfMIRecHitsPerTrack->setAxisTitle("Number of Tracks", 2);
 
       histname = "NumberOfMissingOuterRecHitsPerTrack_";
       NumberOfMORecHitsPerTrack = ibooker.book1D(histname+CategoryName, histname+CategoryName, 10, -0.5, 9.5);
       NumberOfMORecHitsPerTrack->setAxisTitle("Number of missing-outer RecHits for each Track");
       NumberOfMORecHitsPerTrack->setAxisTitle("Number of Tracks", 2);
 
       histname = "ValidFractionPerTrack_";
       ValidFractionPerTrack = ibooker.book1D(histname+CategoryName, histname+CategoryName, 101, 0., 1.01);
       ValidFractionPerTrack->setAxisTitle("ValidFraction of RecHits for each Track");
       ValidFractionPerTrack->setAxisTitle("Number of Tracks", 2);
 
 
 
       if ( doRecHitVsPhiVsEtaPerTrack_ || doAllPlots_ ){
     
     histname = "NumberOfValidRecHitVsPhiVsEtaPerTrack_";
     NumberOfValidRecHitVsPhiVsEtaPerTrack = ibooker.bookProfile2D(histname+CategoryName, histname+CategoryName, 
                                     EtaBin, EtaMin, EtaMax, PhiBin, PhiMin, PhiMax, 0, 40., "");
     NumberOfValidRecHitVsPhiVsEtaPerTrack->setAxisTitle("Track #eta ", 1);
     NumberOfValidRecHitVsPhiVsEtaPerTrack->setAxisTitle("Track #phi ", 2);
 
         histname = "NumberOfLostRecHitVsPhiVsEtaPerTrack_";
         NumberOfLostRecHitVsPhiVsEtaPerTrack = ibooker.bookProfile2D(histname+CategoryName, histname+CategoryName,
                                                                     EtaBin, EtaMin, EtaMax, PhiBin, PhiMin, PhiMax, 0, 5., "");
         NumberOfLostRecHitVsPhiVsEtaPerTrack->setAxisTitle("Track #eta ", 1);
         NumberOfLostRecHitVsPhiVsEtaPerTrack->setAxisTitle("Track #phi ", 2);
 
 
         histname = "NumberMIRecHitVsPhiVsEtaPerTrack_";
         NumberOfMIRecHitVsPhiVsEtaPerTrack = ibooker.bookProfile2D(histname+CategoryName, histname+CategoryName,
                                                                     EtaBin, EtaMin, EtaMax, PhiBin, PhiMin, PhiMax, 0, 15., "");
         NumberOfMIRecHitVsPhiVsEtaPerTrack->setAxisTitle("Track #eta ", 1);
         NumberOfMIRecHitVsPhiVsEtaPerTrack->setAxisTitle("Track #phi ", 2);
 
         histname = "NumberMORecHitVsPhiVsEtaPerTrack_";
         NumberOfMORecHitVsPhiVsEtaPerTrack = ibooker.bookProfile2D(histname+CategoryName, histname+CategoryName,
                                                                     EtaBin, EtaMin, EtaMax, PhiBin, PhiMin, PhiMax, 0, 15., "");
         NumberOfMORecHitVsPhiVsEtaPerTrack->setAxisTitle("Track #eta ", 1);
         NumberOfMORecHitVsPhiVsEtaPerTrack->setAxisTitle("Track #phi ", 2);
 
         histname = "ValidFractionVsPhiVsEtaPerTrack_";
         ValidFractionVsPhiVsEtaPerTrack = ibooker.bookProfile2D(histname+CategoryName, histname+CategoryName,
                                                                     EtaBin, EtaMin, EtaMax, PhiBin, PhiMin, PhiMax, 0, 2., "");
         ValidFractionVsPhiVsEtaPerTrack->setAxisTitle("Track #eta ", 1);
         ValidFractionVsPhiVsEtaPerTrack->setAxisTitle("Track #phi ", 2);
 
 
       }
 
       std::string layerTypeName[4] = {"","Off","3D","Missing"};
       for (int i=0; i<4; ++i) {
         histname = "NumberOf"+ layerTypeName[i] + "LayersPerTrack_";
         NumberOfLayersPerTrack[i] = ibooker.book1D(histname+CategoryName, histname+CategoryName, TKLayBin, TKLayMin, TKLayMax);
         NumberOfLayersPerTrack[i]->setAxisTitle("Number of " + layerTypeName[i] + " Layers of each Track", 1);
         NumberOfLayersPerTrack[i]->setAxisTitle("Number of Tracks", 2);
       }
       if ( doLayersVsPhiVsEtaPerTrack_ || doAllPlots_ )
     for (int i=0; i<4; ++i) {
           histname = "NumberOf"+ layerTypeName[i] + "LayersVsPhiVsEtaPerTrack_";
       NumberOfLayersVsPhiVsEtaPerTrack[i] = ibooker.bookProfile2D(histname+CategoryName, histname+CategoryName, 
                                     EtaBin, EtaMin, EtaMax, PhiBin, PhiMin, PhiMax, 0, 40., "");
       NumberOfLayersVsPhiVsEtaPerTrack[i]->setAxisTitle("Track #eta ", 1);
       NumberOfLayersVsPhiVsEtaPerTrack[i]->setAxisTitle("Track #phi ", 2);
       }
     }
 
     // book the General Property histograms
     // ---------------------------------------------------------------------------------//
     
     if (doGeneralPropertiesPlots_ || doAllPlots_){
       
       int    Chi2Bin      = conf_.getParameter<int>(   "Chi2Bin");
       double Chi2Min      = conf_.getParameter<double>("Chi2Min");
       double Chi2Max      = conf_.getParameter<double>("Chi2Max");
       
       int    Chi2NDFBin   = conf_.getParameter<int>(   "Chi2NDFBin");
       double Chi2NDFMin   = conf_.getParameter<double>("Chi2NDFMin");
       double Chi2NDFMax   = conf_.getParameter<double>("Chi2NDFMax");
       
       int    Chi2ProbBin  = conf_.getParameter<int>(   "Chi2ProbBin");
       double Chi2ProbMin  = conf_.getParameter<double>("Chi2ProbMin");
       double Chi2ProbMax  = conf_.getParameter<double>("Chi2ProbMax");
     
 
       //HI PLOTS////                                                       
       int TransDCABins = conf_.getParameter<int>("TransDCABins");
       double TransDCAMin = conf_.getParameter<double>("TransDCAMin");
       double TransDCAMax = conf_.getParameter<double>("TransDCAMax");
 
       int LongDCABins = conf_.getParameter<int>("LongDCABins");
       double LongDCAMin = conf_.getParameter<double>("LongDCAMin");
       double LongDCAMax = conf_.getParameter<double>("LongDCAMax");
 
 
       ibooker.setCurrentFolder(TopFolder_+"/GeneralProperties");
 
       histname = "Chi2_";
       Chi2 = ibooker.book1D(histname+CategoryName, histname+CategoryName, Chi2Bin, Chi2Min, Chi2Max);
       Chi2->setAxisTitle("Track #chi^{2}"  ,1);
       Chi2->setAxisTitle("Number of Tracks",2);
 
       histname = "Chi2Prob_";
       Chi2Prob = ibooker.book1D(histname+CategoryName, histname+CategoryName, Chi2ProbBin, Chi2ProbMin, Chi2ProbMax);
       Chi2Prob->setAxisTitle("Track #chi^{2} probability",1);
       Chi2Prob->setAxisTitle("Number of Tracks"        ,2);
       
       histname = "Chi2oNDF_";
       Chi2oNDF = ibooker.book1D(histname+CategoryName, histname+CategoryName, Chi2NDFBin, Chi2NDFMin, Chi2NDFMax);
       Chi2oNDF->setAxisTitle("Track #chi^{2}/ndf",1);
       Chi2oNDF->setAxisTitle("Number of Tracks"  ,2);
 
 
       //HI PLOTS///                                                                                                                                                                                       
       if (doHIPlots_)
         {
           histname = "LongDCASig_";
           LongDCASig = ibooker.book1D(histname+CategoryName, histname+CategoryName,LongDCABins,LongDCAMin,LongDCAMax);
           LongDCASig->setAxisTitle("dz/#sigma_{dz}",1);
 
           histname = "TransDCASig_";
           TransDCASig = ibooker.book1D(histname+CategoryName,histname+CategoryName,TransDCABins,TransDCAMin,TransDCAMax);
           TransDCASig->setAxisTitle("dxy/#sigma_{dxy}",1);
 
       histname = "dNdPhi_HighPurity_";
       dNdPhi_HighPurity = ibooker.book1D(histname+CategoryName,histname+CategoryName,PhiBin,PhiMin,PhiMax);
       dNdPhi_HighPurity->setAxisTitle("#phi",1);
 
       histname = "dNdEta_HighPurity_";
           dNdEta_HighPurity = ibooker.book1D(histname+CategoryName,histname+CategoryName,EtaBin,EtaMin,EtaMax);
           dNdEta_HighPurity->setAxisTitle("#eta",1);
 
           histname = "dNdPt_HighPurity_";
           dNdPt_HighPurity = ibooker.book1D(histname+CategoryName,histname+CategoryName,150,0,0.3);
           dNdPt_HighPurity->setAxisTitle("#sigma_{p_{T}}/p_{T}",1);
 
       histname = "NhitVsEta_HighPurity_";
       NhitVsEta_HighPurity = ibooker.bookProfile(histname+CategoryName,histname+CategoryName,EtaBin,EtaMin,EtaMax,-0.5,39.5,"");
       NhitVsEta_HighPurity->setAxisTitle("Track #eta",1);
       NhitVsEta_HighPurity->setAxisTitle("Number of Valid RecHits in each Track",2);
 
           histname = "NhitVsPhi_HighPurity_";
           NhitVsPhi_HighPurity = ibooker.bookProfile(histname+CategoryName,histname+CategoryName,PhiBin,PhiMin,PhiMax,-0.5,39.5,"");
           NhitVsPhi_HighPurity->setAxisTitle("Track #phi",1);
           NhitVsPhi_HighPurity->setAxisTitle("Number of Valid RecHits in each Track",2);
 
       histname = "Ptdist_HighPurity_";
           Ptdist_HighPurity = ibooker.book1D(histname+CategoryName,histname+CategoryName,150,0,50.);
           Ptdist_HighPurity->setAxisTitle("p_{T} (GeV/c)",1);
           Ptdist_HighPurity->setAxisTitle("Number of Tracks",2);
 
           histname = "dNhitdPt_HighPurity_";
           dNhitdPt_HighPurity = ibooker.bookProfile(histname+CategoryName,histname+CategoryName,150,0,25.,-0.5,39.5,"");
           dNhitdPt_HighPurity->setAxisTitle("p_{T} (GeV/c)",1);
           dNhitdPt_HighPurity->setAxisTitle("N_{hit}",2);
       
         }
 
 
       
       if(doDCAPlots_ || doPVPlots_ || doSIPPlots_ || doAllPlots_)  {
     histname = "xPointOfClosestApproach_";
     xPointOfClosestApproach = ibooker.book1D(histname+CategoryName, histname+CategoryName, VXBin, VXMin, VXMax);
     xPointOfClosestApproach->setAxisTitle("x component of Track PCA to beam line (cm)",1);
     xPointOfClosestApproach->setAxisTitle("Number of Tracks",2);
     
     histname = "yPointOfClosestApproach_";
     yPointOfClosestApproach = ibooker.book1D(histname+CategoryName, histname+CategoryName, VYBin, VYMin, VYMax);
     yPointOfClosestApproach->setAxisTitle("y component of Track PCA to beam line (cm)",1);
     yPointOfClosestApproach->setAxisTitle("Number of Tracks",2);
     
     histname = "zPointOfClosestApproach_";
     zPointOfClosestApproach = ibooker.book1D(histname+CategoryName, histname+CategoryName, VZBin, VZMin, VZMax);
     zPointOfClosestApproach->setAxisTitle("z component of Track PCA to beam line (cm)",1);
     zPointOfClosestApproach->setAxisTitle("Number of Tracks",2);
     
     histname = "xPointOfClosestApproachToPV_";
         xPointOfClosestApproachToPV = ibooker.book1D(histname+CategoryName, histname+CategoryName, VXBin, VXMin, VXMax);
     xPointOfClosestApproachToPV->setAxisTitle("x component of Track PCA to pv (cm)",1);
     xPointOfClosestApproachToPV->setAxisTitle("Number of Tracks",2);
     
     histname = "yPointOfClosestApproachToPV_";
     yPointOfClosestApproachToPV = ibooker.book1D(histname+CategoryName, histname+CategoryName, VYBin, VYMin, VYMax);
     yPointOfClosestApproachToPV->setAxisTitle("y component of Track PCA to pv line (cm)",1);
     yPointOfClosestApproachToPV->setAxisTitle("Number of Tracks",2);
     
     histname = "zPointOfClosestApproachToPV_";
     zPointOfClosestApproachToPV = ibooker.book1D(histname+CategoryName, histname+CategoryName, VZBin, VZMin, VZMax);
     zPointOfClosestApproachToPV->setAxisTitle("z component of Track PCA to pv line (cm)",1);
     zPointOfClosestApproachToPV->setAxisTitle("Number of Tracks",2);
       }
 
       // See DataFormats/TrackReco/interface/TrackBase.h for track algorithm enum definition
       // http://cmssw.cvs.cern.ch/cgi-bin/cmssw.cgi/CMSSW/DataFormats/TrackReco/interface/TrackBase.h?view=log
       histname = "algorithm_";
       algorithm = ibooker.book1D(histname+CategoryName, histname+CategoryName, reco::TrackBase::algoSize, 0., double(reco::TrackBase::algoSize));
       algorithm->setAxisTitle("Tracking algorithm",1);
       algorithm->setAxisTitle("Number of Tracks",2);
       histname = "originalAlgorithm_";
       oriAlgo = ibooker.book1D(histname+CategoryName, histname+CategoryName, reco::TrackBase::algoSize, 0., double(reco::TrackBase::algoSize));
       oriAlgo->setAxisTitle("Tracking algorithm",1);
       oriAlgo->setAxisTitle("Number of Tracks",2);
 
       for (size_t ibin=0; ibin<reco::TrackBase::algoSize-1; ibin++) {
     algorithm->setBinLabel(ibin+1,reco::TrackBase::algoNames[ibin]);
         oriAlgo->setBinLabel(ibin+1,reco::TrackBase::algoNames[ibin]);
       }
     }
 
 }

void TrackAnalyzer::bookHistosForLScertification ( DQMStore::IBooker & ibooker )

private

Definition at line 523 of file TrackAnalyzer.cc.

References HLT_25ns14e33_v1_cff::AlgoName, DQMStore::IBooker::book1D(), Chi2oNDF_lumiFlag, conf_, doLumiAnalysis_, edm::ParameterSet::getParameter(), histname, NumberOfRecHitsPerTrack_lumiFlag, MonitorElement::setAxisTitle(), DQMStore::IBooker::setCurrentFolder(), AlCaHLTBitMon_QueryRunRegistry::string, and TopFolder_.

Referenced by initHisto().

                                                                           {
 
     // parameters from the configuration
     std::string QualName       = conf_.getParameter<std::string>("Quality");
     std::string AlgoName       = conf_.getParameter<std::string>("AlgoName");
 
     // use the AlgoName and Quality Name 
     std::string CategoryName = QualName != "" ? AlgoName + "_" + QualName : AlgoName;
 
 
     // book LS analysis related histograms
     // -----------------------------------
     if ( doLumiAnalysis_ ) {
 
       // get binning from the configuration
       int    TKHitBin     = conf_.getParameter<int>(   "RecHitBin");
       double TKHitMin     = conf_.getParameter<double>("RecHitMin");
       double TKHitMax     = conf_.getParameter<double>("RecHitMax");
 
       int    Chi2NDFBin   = conf_.getParameter<int>(   "Chi2NDFBin");
       double Chi2NDFMin   = conf_.getParameter<double>("Chi2NDFMin");
       double Chi2NDFMax   = conf_.getParameter<double>("Chi2NDFMax");
 
       // add by Mia in order to deal w/ LS transitions  
       ibooker.setCurrentFolder(TopFolder_+"/LSanalysis");
 
       histname = "NumberOfRecHitsPerTrack_lumiFlag_";
       NumberOfRecHitsPerTrack_lumiFlag = ibooker.book1D(histname+CategoryName, histname+CategoryName, TKHitBin, TKHitMin, TKHitMax);
       NumberOfRecHitsPerTrack_lumiFlag->setAxisTitle("Number of all RecHits of each Track");
       NumberOfRecHitsPerTrack_lumiFlag->setAxisTitle("Number of Tracks", 2);
 
       histname = "Chi2oNDF_lumiFlag_";
       Chi2oNDF_lumiFlag = ibooker.book1D(histname+CategoryName, histname+CategoryName, Chi2NDFBin, Chi2NDFMin, Chi2NDFMax);
       Chi2oNDF_lumiFlag->setAxisTitle("Track #chi^{2}/ndf",1);
       Chi2oNDF_lumiFlag->setAxisTitle("Number of Tracks"  ,2);
 
     }
 }

void TrackAnalyzer::bookHistosForState	(	std::string	sname,
		DQMStore::IBooker &	ibooker
	)

private

Definition at line 1076 of file TrackAnalyzer.cc.

Referenced by initHisto().

 {
 
     // parameters from the configuration
     std::string QualName       = conf_.getParameter<std::string>("Quality");
     std::string AlgoName       = conf_.getParameter<std::string>("AlgoName");
 
     // use the AlgoName and Quality Name 
     std::string CategoryName = QualName != "" ? AlgoName + "_" + QualName : AlgoName;
 
     // get binning from the configuration
     double Chi2NDFMin = conf_.getParameter<double>("Chi2NDFMin");
     double Chi2NDFMax = conf_.getParameter<double>("Chi2NDFMax");
 
     int    RecHitBin   = conf_.getParameter<int>(   "RecHitBin");
     double RecHitMin   = conf_.getParameter<double>("RecHitMin");
     double RecHitMax   = conf_.getParameter<double>("RecHitMax");
 
     int    RecLayBin   = conf_.getParameter<int>(   "RecHitBin");
     double RecLayMin   = conf_.getParameter<double>("RecHitMin");
     double RecLayMax   = conf_.getParameter<double>("RecHitMax");
 
 
     int    PhiBin     = conf_.getParameter<int>(   "PhiBin");
     double PhiMin     = conf_.getParameter<double>("PhiMin");
     double PhiMax     = conf_.getParameter<double>("PhiMax");
 
     int    EtaBin     = conf_.getParameter<int>(   "EtaBin");
     double EtaMin     = conf_.getParameter<double>("EtaMin");
     double EtaMax     = conf_.getParameter<double>("EtaMax");
 
     int    ThetaBin   = conf_.getParameter<int>(   "ThetaBin");
     double ThetaMin   = conf_.getParameter<double>("ThetaMin");
     double ThetaMax   = conf_.getParameter<double>("ThetaMax");
 
     int    TrackQBin  = conf_.getParameter<int>(   "TrackQBin");
     double TrackQMin  = conf_.getParameter<double>("TrackQMin");
     double TrackQMax  = conf_.getParameter<double>("TrackQMax");
 
     int    TrackPtBin = conf_.getParameter<int>(   "TrackPtBin");
     double TrackPtMin = conf_.getParameter<double>("TrackPtMin");
     double TrackPtMax = conf_.getParameter<double>("TrackPtMax");
 
     int    TrackPBin  = conf_.getParameter<int>(   "TrackPBin");
     double TrackPMin  = conf_.getParameter<double>("TrackPMin");
     double TrackPMax  = conf_.getParameter<double>("TrackPMax");
 
     int    TrackPxBin = conf_.getParameter<int>(   "TrackPxBin");
     double TrackPxMin = conf_.getParameter<double>("TrackPxMin");
     double TrackPxMax = conf_.getParameter<double>("TrackPxMax");
 
     int    TrackPyBin = conf_.getParameter<int>(   "TrackPyBin");
     double TrackPyMin = conf_.getParameter<double>("TrackPyMin");
     double TrackPyMax = conf_.getParameter<double>("TrackPyMax");
 
     int    TrackPzBin = conf_.getParameter<int>(   "TrackPzBin");
     double TrackPzMin = conf_.getParameter<double>("TrackPzMin");
     double TrackPzMax = conf_.getParameter<double>("TrackPzMax");
 
     int    ptErrBin   = conf_.getParameter<int>(   "ptErrBin");
     double ptErrMin   = conf_.getParameter<double>("ptErrMin");
     double ptErrMax   = conf_.getParameter<double>("ptErrMax");
 
     int    pxErrBin   = conf_.getParameter<int>(   "pxErrBin");
     double pxErrMin   = conf_.getParameter<double>("pxErrMin");
     double pxErrMax   = conf_.getParameter<double>("pxErrMax");
 
     int    pyErrBin   = conf_.getParameter<int>(   "pyErrBin");
     double pyErrMin   = conf_.getParameter<double>("pyErrMin");
     double pyErrMax   = conf_.getParameter<double>("pyErrMax");
 
     int    pzErrBin   = conf_.getParameter<int>(   "pzErrBin");
     double pzErrMin   = conf_.getParameter<double>("pzErrMin");
     double pzErrMax   = conf_.getParameter<double>("pzErrMax");
 
     int    pErrBin    = conf_.getParameter<int>(   "pErrBin");
     double pErrMin    = conf_.getParameter<double>("pErrMin");
     double pErrMax    = conf_.getParameter<double>("pErrMax");
 
     int    phiErrBin  = conf_.getParameter<int>(   "phiErrBin");
     double phiErrMin  = conf_.getParameter<double>("phiErrMin");
     double phiErrMax  = conf_.getParameter<double>("phiErrMax");
 
     int    etaErrBin  = conf_.getParameter<int>(   "etaErrBin");
     double etaErrMin  = conf_.getParameter<double>("etaErrMin");
     double etaErrMax  = conf_.getParameter<double>("etaErrMax");
 
 
     double Chi2ProbMin  = conf_.getParameter<double>("Chi2ProbMin");
     double Chi2ProbMax  = conf_.getParameter<double>("Chi2ProbMax");
 
     ibooker.setCurrentFolder(TopFolder_);
 
     TkParameterMEs tkmes;
 
     std::string histTag = (sname == "default") ? CategoryName : sname + "_" + CategoryName;
 
     if(doAllPlots_) {
 
       // general properties
       ibooker.setCurrentFolder(TopFolder_+"/GeneralProperties");
       
       if (doThetaPlots_) {
     histname = "Chi2oNDFVsTheta_" + histTag;
     tkmes.Chi2oNDFVsTheta = ibooker.bookProfile(histname, histname, ThetaBin, ThetaMin, ThetaMax, Chi2NDFMin, Chi2NDFMax,"");
     tkmes.Chi2oNDFVsTheta->setAxisTitle("Track #theta",1);
     tkmes.Chi2oNDFVsTheta->setAxisTitle("Track #chi^{2}/ndf",2);
       }
       histname = "Chi2oNDFVsPhi_" + histTag;
       tkmes.Chi2oNDFVsPhi   = ibooker.bookProfile(histname, histname, PhiBin, PhiMin, PhiMax, Chi2NDFMin, Chi2NDFMax,"");
       tkmes.Chi2oNDFVsPhi->setAxisTitle("Track #phi",1);
       tkmes.Chi2oNDFVsPhi->setAxisTitle("Track #chi^{2}/ndf",2);
       
       histname = "Chi2oNDFVsEta_" + histTag;
       tkmes.Chi2oNDFVsEta   = ibooker.bookProfile(histname, histname, EtaBin, EtaMin, EtaMax, Chi2NDFMin, Chi2NDFMax,"");
       tkmes.Chi2oNDFVsEta->setAxisTitle("Track #eta",1);
       tkmes.Chi2oNDFVsEta->setAxisTitle("Track #chi^{2}/ndf",2);
       
       histname = "Chi2ProbVsPhi_" + histTag;
       tkmes.Chi2ProbVsPhi = ibooker.bookProfile(histname+CategoryName, histname+CategoryName, PhiBin, PhiMin, PhiMax, Chi2ProbMin, Chi2ProbMax);
       tkmes.Chi2ProbVsPhi->setAxisTitle("Tracks #phi"  ,1);
       tkmes.Chi2ProbVsPhi->setAxisTitle("Track #chi^{2} probability",2);
       
       histname = "Chi2ProbVsEta_" + histTag;
       tkmes.Chi2ProbVsEta = ibooker.bookProfile(histname+CategoryName, histname+CategoryName, EtaBin, EtaMin, EtaMax, Chi2ProbMin, Chi2ProbMax);
       tkmes.Chi2ProbVsEta->setAxisTitle("Tracks #eta"  ,1);
       tkmes.Chi2ProbVsEta->setAxisTitle("Track #chi^{2} probability",2);
 
     }
     
     // general properties
     ibooker.setCurrentFolder(TopFolder_+"/GeneralProperties");
 
     histname = "TrackP_" + histTag;
     tkmes.TrackP = ibooker.book1D(histname, histname, TrackPBin, TrackPMin, TrackPMax);
     tkmes.TrackP->setAxisTitle("Track |p| (GeV/c)", 1);
     tkmes.TrackP->setAxisTitle("Number of Tracks",2);
 
     histname = "TrackPt_" + histTag;
     tkmes.TrackPt = ibooker.book1D(histname, histname, TrackPtBin, TrackPtMin, TrackPtMax);
     tkmes.TrackPt->setAxisTitle("Track p_{T} (GeV/c)", 1);
     tkmes.TrackPt->setAxisTitle("Number of Tracks",2);
 
     if (doTrackPxPyPlots_) {
       histname = "TrackPx_" + histTag;
       tkmes.TrackPx = ibooker.book1D(histname, histname, TrackPxBin, TrackPxMin, TrackPxMax);
       tkmes.TrackPx->setAxisTitle("Track p_{x} (GeV/c)", 1);
       tkmes.TrackPx->setAxisTitle("Number of Tracks",2);
 
       histname = "TrackPy_" + histTag;
       tkmes.TrackPy = ibooker.book1D(histname, histname, TrackPyBin, TrackPyMin, TrackPyMax);
       tkmes.TrackPy->setAxisTitle("Track p_{y} (GeV/c)", 1);
       tkmes.TrackPy->setAxisTitle("Number of Tracks",2);
     }
     histname = "TrackPz_" + histTag;
     tkmes.TrackPz = ibooker.book1D(histname, histname, TrackPzBin, TrackPzMin, TrackPzMax);
     tkmes.TrackPz->setAxisTitle("Track p_{z} (GeV/c)", 1);
     tkmes.TrackPz->setAxisTitle("Number of Tracks",2);
 
     histname = "TrackPhi_" + histTag;
     tkmes.TrackPhi = ibooker.book1D(histname, histname, PhiBin, PhiMin, PhiMax);
     tkmes.TrackPhi->setAxisTitle("Track #phi", 1);
     tkmes.TrackPhi->setAxisTitle("Number of Tracks",2);
 
     histname = "TrackEta_" + histTag;
     tkmes.TrackEta = ibooker.book1D(histname, histname, EtaBin, EtaMin, EtaMax);
     tkmes.TrackEta->setAxisTitle("Track #eta", 1);
     tkmes.TrackEta->setAxisTitle("Number of Tracks",2);
 
     histname = "TrackEtaPhi_" + histTag;
     tkmes.TrackEtaPhi = ibooker.book2D(histname, histname, EtaBin, EtaMin, EtaMax, PhiBin, PhiMin, PhiMax);
     tkmes.TrackEtaPhi->setAxisTitle("Track #eta", 1);
     tkmes.TrackEtaPhi->setAxisTitle("Track #phi", 2);
 
     histname = "TrackEtaPhiInner_" + histTag;
     tkmes.TrackEtaPhiInner = ibooker.book2D(histname, histname, EtaBin, EtaMin, EtaMax, PhiBin, PhiMin, PhiMax);
     tkmes.TrackEtaPhiInner->setAxisTitle("Track #eta", 1);
     tkmes.TrackEtaPhiInner->setAxisTitle("Track #phi", 2);
 
     histname = "TrackEtaPhiOuter_" + histTag;
     tkmes.TrackEtaPhiOuter = ibooker.book2D(histname, histname, EtaBin, EtaMin, EtaMax, PhiBin, PhiMin, PhiMax);
     tkmes.TrackEtaPhiOuter->setAxisTitle("Track #eta", 1);
     tkmes.TrackEtaPhiOuter->setAxisTitle("Track #phi", 2);
 
 
 
     if (doThetaPlots_) {  
       histname = "TrackTheta_" + histTag;
       tkmes.TrackTheta = ibooker.book1D(histname, histname, ThetaBin, ThetaMin, ThetaMax);
       tkmes.TrackTheta->setAxisTitle("Track #theta", 1);
       tkmes.TrackTheta->setAxisTitle("Number of Tracks",2);
     }
     histname = "TrackQ_" + histTag;
     tkmes.TrackQ = ibooker.book1D(histname, histname, TrackQBin, TrackQMin, TrackQMax);
     tkmes.TrackQ->setAxisTitle("Track Charge", 1);
     tkmes.TrackQ->setAxisTitle("Number of Tracks",2);
 
     histname = "TrackPErrOverP_" + histTag;
     tkmes.TrackPErr = ibooker.book1D(histname, histname, pErrBin, pErrMin, pErrMax);
     tkmes.TrackPErr->setAxisTitle("track error(p)/p", 1);
     tkmes.TrackPErr->setAxisTitle("Number of Tracks",2);
 
     histname = "TrackPtErrOverPt_" + histTag;
     tkmes.TrackPtErr = ibooker.book1D(histname, histname, ptErrBin, ptErrMin, ptErrMax);
     tkmes.TrackPtErr->setAxisTitle("track error(p_{T})/p_{T}", 1);
     tkmes.TrackPtErr->setAxisTitle("Number of Tracks",2);
 
     histname = "TrackPtErrOverPtVsEta_" + histTag;
     tkmes.TrackPtErrVsEta = ibooker.bookProfile(histname, histname, EtaBin, EtaMin, EtaMax, ptErrMin, ptErrMax);
     tkmes.TrackPtErrVsEta->setAxisTitle("Track #eta",1);
     tkmes.TrackPtErrVsEta->setAxisTitle("track error(p_{T})/p_{T}", 2);
 
     if (doTrackPxPyPlots_) {
       histname = "TrackPxErrOverPx_" + histTag;
       tkmes.TrackPxErr = ibooker.book1D(histname, histname, pxErrBin, pxErrMin, pxErrMax);
       tkmes.TrackPxErr->setAxisTitle("track error(p_{x})/p_{x}", 1);
       tkmes.TrackPxErr->setAxisTitle("Number of Tracks",2);
       
       histname = "TrackPyErrOverPy_" + histTag;
       tkmes.TrackPyErr = ibooker.book1D(histname, histname, pyErrBin, pyErrMin, pyErrMax);
       tkmes.TrackPyErr->setAxisTitle("track error(p_{y})/p_{y}", 1);
       tkmes.TrackPyErr->setAxisTitle("Number of Tracks",2);
     }
     histname = "TrackPzErrOverPz_" + histTag;
     tkmes.TrackPzErr = ibooker.book1D(histname, histname, pzErrBin, pzErrMin, pzErrMax);
     tkmes.TrackPzErr->setAxisTitle("track error(p_{z})/p_{z}", 1);
     tkmes.TrackPzErr->setAxisTitle("Number of Tracks",2);
 
     histname = "TrackPhiErr_" + histTag;
     tkmes.TrackPhiErr = ibooker.book1D(histname, histname, phiErrBin, phiErrMin, phiErrMax);
     tkmes.TrackPhiErr->setAxisTitle("track error(#phi)");
     tkmes.TrackPhiErr->setAxisTitle("Number of Tracks",2);
 
     histname = "TrackEtaErr_" + histTag;
     tkmes.TrackEtaErr = ibooker.book1D(histname, histname, etaErrBin, etaErrMin, etaErrMax);
     tkmes.TrackEtaErr->setAxisTitle("track error(#eta)");
     tkmes.TrackEtaErr->setAxisTitle("Number of Tracks",2);
 
     // rec hit profiles
     ibooker.setCurrentFolder(TopFolder_+"/GeneralProperties");
     histname = "NumberOfRecHitsPerTrackVsPhi_" + histTag;
     tkmes.NumberOfRecHitsPerTrackVsPhi = ibooker.bookProfile(histname, histname, PhiBin, PhiMin, PhiMax, RecHitBin, RecHitMin, RecHitMax,"");
     tkmes.NumberOfRecHitsPerTrackVsPhi->setAxisTitle("Track #phi",1);
     tkmes.NumberOfRecHitsPerTrackVsPhi->setAxisTitle("Number of RecHits in each Track",2);
 
     if (doThetaPlots_) {
       histname = "NumberOfRecHitsPerTrackVsTheta_" + histTag;
       tkmes.NumberOfRecHitsPerTrackVsTheta = ibooker.bookProfile(histname, histname, ThetaBin, ThetaMin, ThetaMax, RecHitBin, RecHitMin, RecHitMax,"");
       tkmes.NumberOfRecHitsPerTrackVsTheta->setAxisTitle("Track #phi",1);
       tkmes.NumberOfRecHitsPerTrackVsTheta->setAxisTitle("Number of RecHits in each Track",2);
     }
     histname = "NumberOfRecHitsPerTrackVsEta_" + histTag;
     tkmes.NumberOfRecHitsPerTrackVsEta = ibooker.bookProfile(histname, histname, EtaBin, EtaMin, EtaMax, RecHitBin, RecHitMin, RecHitMax,"");
     tkmes.NumberOfRecHitsPerTrackVsEta->setAxisTitle("Track #eta",1);
     tkmes.NumberOfRecHitsPerTrackVsEta->setAxisTitle("Number of RecHits in each Track",2);
 
     histname = "NumberOfValidRecHitsPerTrackVsPhi_" + histTag;
     tkmes.NumberOfValidRecHitsPerTrackVsPhi = ibooker.bookProfile(histname, histname, PhiBin, PhiMin, PhiMax, RecHitMin, RecHitMax,"");
     tkmes.NumberOfValidRecHitsPerTrackVsPhi->setAxisTitle("Track #phi",1);
     tkmes.NumberOfValidRecHitsPerTrackVsPhi->setAxisTitle("Number of valid RecHits in each Track",2);
     
     //    std::cout << "[TrackAnalyzer::bookHistosForState] histTag: " << histTag << std::endl;
     histname = "NumberOfValidRecHitsPerTrackVsEta_" + histTag;
     tkmes.NumberOfValidRecHitsPerTrackVsEta = ibooker.bookProfile(histname, histname, EtaBin, EtaMin, EtaMax, RecHitMin, RecHitMax,"");
     tkmes.NumberOfValidRecHitsPerTrackVsEta->setAxisTitle("Track #eta",1);
     tkmes.NumberOfValidRecHitsPerTrackVsEta->setAxisTitle("Number of valid RecHits in each Track",2);
     
     histname = "NumberOfLayersPerTrackVsPhi_" + histTag;
     tkmes.NumberOfLayersPerTrackVsPhi = ibooker.bookProfile(histname, histname, PhiBin, PhiMin, PhiMax, RecLayBin, RecLayMin, RecLayMax,"");
     tkmes.NumberOfLayersPerTrackVsPhi->setAxisTitle("Track #phi",1);
     tkmes.NumberOfLayersPerTrackVsPhi->setAxisTitle("Number of Layers in each Track",2);
 
     if (doThetaPlots_) {
       histname = "NumberOfLayersPerTrackVsTheta_" + histTag;
       tkmes.NumberOfLayersPerTrackVsTheta = ibooker.bookProfile(histname, histname, ThetaBin, ThetaMin, ThetaMax, RecLayBin, RecLayMin, RecLayMax,"");
       tkmes.NumberOfLayersPerTrackVsTheta->setAxisTitle("Track #phi",1);
       tkmes.NumberOfLayersPerTrackVsTheta->setAxisTitle("Number of Layers in each Track",2);
     }
     histname = "NumberOfLayersPerTrackVsEta_" + histTag;
     tkmes.NumberOfLayersPerTrackVsEta = ibooker.bookProfile(histname, histname, EtaBin, EtaMin, EtaMax, RecLayBin, RecLayMin, RecLayMax,"");
     tkmes.NumberOfLayersPerTrackVsEta->setAxisTitle("Track #eta",1);
     tkmes.NumberOfLayersPerTrackVsEta->setAxisTitle("Number of Layers in each Track",2);
 
     if (doThetaPlots_) {
       histname = "Chi2oNDFVsTheta_" + histTag;
       tkmes.Chi2oNDFVsTheta = ibooker.bookProfile(histname, histname, ThetaBin, ThetaMin, ThetaMax, Chi2NDFMin, Chi2NDFMax,"");
       tkmes.Chi2oNDFVsTheta->setAxisTitle("Track #theta",1);
       tkmes.Chi2oNDFVsTheta->setAxisTitle("Track #chi^{2}/ndf",2);
     }
     if (doAllPlots_) {
       histname = "Chi2oNDFVsPhi_" + histTag;
       tkmes.Chi2oNDFVsPhi   = ibooker.bookProfile(histname, histname, PhiBin, PhiMin, PhiMax, Chi2NDFMin, Chi2NDFMax,"");
       tkmes.Chi2oNDFVsPhi->setAxisTitle("Track #phi",1);
       tkmes.Chi2oNDFVsPhi->setAxisTitle("Track #chi^{2}/ndf",2);
       
       histname = "Chi2oNDFVsEta_" + histTag;
       tkmes.Chi2oNDFVsEta   = ibooker.bookProfile(histname, histname, EtaBin, EtaMin, EtaMax, Chi2NDFMin, Chi2NDFMax,"");
       tkmes.Chi2oNDFVsEta->setAxisTitle("Track #eta",1);
       tkmes.Chi2oNDFVsEta->setAxisTitle("Track #chi^{2}/ndf",2);
       
       histname = "Chi2ProbVsPhi_" + histTag;
       tkmes.Chi2ProbVsPhi = ibooker.bookProfile(histname+CategoryName, histname+CategoryName, PhiBin, PhiMin, PhiMax, Chi2ProbMin, Chi2ProbMax);
       tkmes.Chi2ProbVsPhi->setAxisTitle("Tracks #phi"  ,1);
       tkmes.Chi2ProbVsPhi->setAxisTitle("Track #chi^{2} probability",2);
       
       histname = "Chi2ProbVsEta_" + histTag;
       tkmes.Chi2ProbVsEta = ibooker.bookProfile(histname+CategoryName, histname+CategoryName, EtaBin, EtaMin, EtaMax, Chi2ProbMin, Chi2ProbMax);
       tkmes.Chi2ProbVsEta->setAxisTitle("Tracks #eta"  ,1);
       tkmes.Chi2ProbVsEta->setAxisTitle("Track #chi^{2} probability",2);
     }
 
     // now put the MEs in the map
     TkParameterMEMap.insert( std::make_pair(sname, tkmes) );
 
 }

void TrackAnalyzer::bookHistosForTrackerSpecific ( DQMStore::IBooker & ibooker )

private

Definition at line 1541 of file TrackAnalyzer.cc.

Referenced by initHisto().

 {
 
     // parameters from the configuration
     std::string QualName     = conf_.getParameter<std::string>("Quality");
     std::string AlgoName     = conf_.getParameter<std::string>("AlgoName");
 
     // use the AlgoName and Quality Name 
     std::string CategoryName = QualName != "" ? AlgoName + "_" + QualName : AlgoName;
 
     int    PhiBin     = conf_.getParameter<int>(   "PhiBin");
     double PhiMin     = conf_.getParameter<double>("PhiMin");
     double PhiMax     = conf_.getParameter<double>("PhiMax");
 
     int    EtaBin     = conf_.getParameter<int>(   "EtaBin");
     double EtaMin     = conf_.getParameter<double>("EtaMin");
     double EtaMax     = conf_.getParameter<double>("EtaMax");
 
     // book hit property histograms
     // ---------------------------------------------------------------------------------//
     ibooker.setCurrentFolder(TopFolder_+"/HitProperties");
 
 
 
     std::vector<std::string> subdetectors = conf_.getParameter<std::vector<std::string> >("subdetectors");
     int detBin = conf_.getParameter<int>("subdetectorBin");
 
     for ( auto det : subdetectors ) {
       
       // hits properties
       ibooker.setCurrentFolder(TopFolder_+"/HitProperties/"+det);
       
       TkRecHitsPerSubDetMEs recHitsPerSubDet_mes;
 
       recHitsPerSubDet_mes.detectorTag = det;
       int detID = -1;
       if ( det == "TIB" ) detID = StripSubdetector::TIB;
       if ( det == "TOB" ) detID = StripSubdetector::TOB;
       if ( det == "TID" ) detID = StripSubdetector::TID;
       if ( det == "TEC" ) detID = StripSubdetector::TEC;
       if ( det == "PixBarrel" ) detID = PixelSubdetector::PixelBarrel;
       if ( det == "PixEndcap" ) detID = PixelSubdetector::PixelEndcap;
       recHitsPerSubDet_mes.detectorId  = detID;
 
       histname = "NumberOfRecHitsPerTrack_" + det + "_" + CategoryName;
       recHitsPerSubDet_mes.NumberOfRecHitsPerTrack = ibooker.book1D(histname, histname, detBin, -0.5, double(detBin)-0.5);
       recHitsPerSubDet_mes.NumberOfRecHitsPerTrack->setAxisTitle("Number of " + det + " valid RecHits in each Track",1);
       recHitsPerSubDet_mes.NumberOfRecHitsPerTrack->setAxisTitle("Number of Tracks", 2);
 
       histname = "NumberOfRecHitsPerTrackVsPhi_" + det + "_" + CategoryName;
       recHitsPerSubDet_mes.NumberOfRecHitsPerTrackVsPhi = ibooker.bookProfile(histname, histname, PhiBin, PhiMin, PhiMax, detBin, -0.5, double(detBin)-0.5,"");
       recHitsPerSubDet_mes.NumberOfRecHitsPerTrackVsPhi->setAxisTitle("Track #phi",1);
       recHitsPerSubDet_mes.NumberOfRecHitsPerTrackVsPhi->setAxisTitle("Number of " + det + " valid RecHits in each Track",2);
 
       histname = "NumberOfRecHitsPerTrackVsEta_" + det + "_" + CategoryName;
       recHitsPerSubDet_mes.NumberOfRecHitsPerTrackVsEta = ibooker.bookProfile(histname, histname, EtaBin, EtaMin, EtaMax, detBin, -0.5, double(detBin)-0.5,"");
       recHitsPerSubDet_mes.NumberOfRecHitsPerTrackVsEta->setAxisTitle("Track #eta",1);
       recHitsPerSubDet_mes.NumberOfRecHitsPerTrackVsEta->setAxisTitle("Number of " + det + " valid RecHits in each Track",2);
 
       histname = "NumberOfLayersPerTrack_" + det + "_" + CategoryName;
       recHitsPerSubDet_mes.NumberOfLayersPerTrack = ibooker.book1D(histname, histname, detBin, -0.5, double(detBin)-0.5);
       recHitsPerSubDet_mes.NumberOfLayersPerTrack->setAxisTitle("Number of " + det + " valid Layers in each Track",1);
       recHitsPerSubDet_mes.NumberOfLayersPerTrack->setAxisTitle("Number of Tracks", 2);
 
       histname = "NumberOfLayersPerTrackVsPhi_" + det + "_" + CategoryName;
       recHitsPerSubDet_mes.NumberOfLayersPerTrackVsPhi = ibooker.bookProfile(histname, histname, PhiBin, PhiMin, PhiMax, detBin, -0.5, double(detBin)-0.5,"");
       recHitsPerSubDet_mes.NumberOfLayersPerTrackVsPhi->setAxisTitle("Track #phi",1);
       recHitsPerSubDet_mes.NumberOfLayersPerTrackVsPhi->setAxisTitle("Number of " + det + " valid Layers in each Track",2);
 
       histname = "NumberOfLayersPerTrackVsEta_" + det + "_" + CategoryName;
       recHitsPerSubDet_mes.NumberOfLayersPerTrackVsEta = ibooker.bookProfile(histname, histname, EtaBin, EtaMin, EtaMax, detBin, -0.5, double(detBin)-0.5,"");
       recHitsPerSubDet_mes.NumberOfLayersPerTrackVsEta->setAxisTitle("Track #eta",1);
       recHitsPerSubDet_mes.NumberOfLayersPerTrackVsEta->setAxisTitle("Number of " + det + " valid Layers in each Track",2);
 
       TkRecHitsPerSubDetMEMap.insert(std::pair<std::string,TkRecHitsPerSubDetMEs>(det,recHitsPerSubDet_mes));
 
       
     }
 
 
 }

void TrackAnalyzer::doReset ( )

Definition at line 1696 of file TrackAnalyzer.cc.

References Chi2oNDF_lumiFlag, NumberOfRecHitsPerTrack_lumiFlag, and HcalObjRepresent::Reset().

Referenced by TrackingMonitor::beginLuminosityBlock().

                             {
   TkParameterMEs tkmes;
   if ( Chi2oNDF_lumiFlag                ) Chi2oNDF_lumiFlag                -> Reset();
   if ( NumberOfRecHitsPerTrack_lumiFlag ) NumberOfRecHitsPerTrack_lumiFlag -> Reset();
 }

void TrackAnalyzer::doSoftReset ( DQMStore * dqmStore_ )

Definition at line 1688 of file TrackAnalyzer.cc.

References Chi2oNDF, NumberOfRecHitsPerTrack, and DQMStore::softReset().

                                                     {
   TkParameterMEs tkmes;
   dqmStore_->softReset(Chi2oNDF);
   dqmStore_->softReset(NumberOfRecHitsPerTrack);
 }

void TrackAnalyzer::fillHistosForHitProperties	(	const edm::EventSetup &	iSetup,
		const reco::Track &	track,
		std::string	sname
	)

private

void TrackAnalyzer::fillHistosForLScertification	(	const edm::EventSetup &	iSetup,
		const reco::Track &	track,
		std::string	sname
	)

private

void TrackAnalyzer::fillHistosForState	(	const edm::EventSetup &	iSetup,
		const reco::Track &	track,
		std::string	sname
	)

private

Definition at line 1396 of file TrackAnalyzer.cc.

Referenced by analyze().

 {
     //get the kinematic parameters
     double p, px, py, pz, pt, theta, phi, eta, q;
     double pxerror, pyerror, pzerror, pterror, perror, phierror, etaerror;
 
     auto phiIn =  track.innerPosition().phi();
     auto etaIn =  track.innerPosition().eta();
     auto phiOut =  track.outerPosition().phi();
     auto etaOut =  track.outerPosition().eta();
 
 
     if (sname == "default") {
 
       p     = track.p();
       px    = track.px();
       py    = track.py();
       pz    = track.pz();
       pt    = track.pt();
       phi   = track.phi();
       theta = track.theta();
       eta   = track.eta();
       q     = track.charge();
       
       pterror  = (pt) ? track.ptError()/(pt*pt) : 0.0;
       pxerror  = -1.0;
       pyerror  = -1.0;
       pzerror  = -1.0;
       perror   = -1.0;
       phierror = track.phiError();
       etaerror = track.etaError();
       
     } else {
       
       edm::ESHandle<TransientTrackBuilder> theB;
       iSetup.get<TransientTrackRecord>().get("TransientTrackBuilder",theB);
       reco::TransientTrack TransTrack = theB->build(track);
       
       TrajectoryStateOnSurface TSOS;
 
       if      (sname == "OuterSurface")  TSOS = TransTrack.outermostMeasurementState();
       else if (sname == "InnerSurface")  TSOS = TransTrack.innermostMeasurementState();
       else if (sname == "ImpactPoint")   TSOS = TransTrack.impactPointState();
 
       p     = TSOS.globalMomentum().mag();
       px    = TSOS.globalMomentum().x();
       py    = TSOS.globalMomentum().y();
       pz    = TSOS.globalMomentum().z();
       pt    = TSOS.globalMomentum().perp();
       phi   = TSOS.globalMomentum().phi();
       theta = TSOS.globalMomentum().theta();
       eta   = TSOS.globalMomentum().eta();
       q     = TSOS.charge();
 
       //get the error of the kinimatic parameters
       AlgebraicSymMatrix66 errors = TSOS.cartesianError().matrix();
       double partialPterror = errors(3,3)*pow(TSOS.globalMomentum().x(),2) + errors(4,4)*pow(TSOS.globalMomentum().y(),2);
       pterror  = sqrt(partialPterror)/TSOS.globalMomentum().perp();
       pxerror  = sqrt(errors(3,3))/TSOS.globalMomentum().x();
       pyerror  = sqrt(errors(4,4))/TSOS.globalMomentum().y();
       pzerror  = sqrt(errors(5,5))/TSOS.globalMomentum().z();
       perror   = sqrt(partialPterror+errors(5,5)*pow(TSOS.globalMomentum().z(),2))/TSOS.globalMomentum().mag();
       phierror = sqrt(TSOS.curvilinearError().matrix()(2,2));
       etaerror = sqrt(TSOS.curvilinearError().matrix()(1,1))*fabs(sin(TSOS.globalMomentum().theta()));
 
     }
 
     std::map<std::string, TkParameterMEs>::iterator iPos = TkParameterMEMap.find(sname); 
     if (iPos != TkParameterMEMap.end()) {
 
       TkParameterMEs tkmes = iPos->second;
       
       // momentum
       tkmes.TrackP->Fill(p);
       if (doTrackPxPyPlots_) {
     tkmes.TrackPx->Fill(px);
     tkmes.TrackPy->Fill(py);
       }
       tkmes.TrackPz->Fill(pz);
       tkmes.TrackPt->Fill(pt);
       
       // angles
       tkmes.TrackPhi->Fill(phi);
       tkmes.TrackEta->Fill(eta);
       tkmes.TrackEtaPhi->Fill(eta,phi);
       tkmes.TrackEtaPhiInner->Fill(etaIn,phiIn);
       tkmes.TrackEtaPhiOuter->Fill(etaOut,phiOut);
 
       if (doThetaPlots_) {
     tkmes.TrackTheta->Fill(theta);
       }
       tkmes.TrackQ->Fill(q);
       
       // errors
       tkmes.TrackPtErr->Fill(pterror);
       tkmes.TrackPtErrVsEta->Fill(eta,pterror);
       if (doTrackPxPyPlots_) {
     tkmes.TrackPxErr->Fill(pxerror);
     tkmes.TrackPyErr->Fill(pyerror);
       }
       tkmes.TrackPzErr->Fill(pzerror);
       tkmes.TrackPErr->Fill(perror);
       tkmes.TrackPhiErr->Fill(phierror);
       tkmes.TrackEtaErr->Fill(etaerror);
       
       int nRecHits      = track.hitPattern().numberOfHits(reco::HitPattern::TRACK_HITS);
       int nValidRecHits = track.numberOfValidHits();
       // rec hits 
       tkmes.NumberOfRecHitsPerTrackVsPhi->Fill(phi,    nRecHits);
       if (doThetaPlots_) {
     tkmes.NumberOfRecHitsPerTrackVsTheta->Fill(theta,nRecHits);
       }
       tkmes.NumberOfRecHitsPerTrackVsEta->Fill(eta,    nRecHits);
       
       tkmes.NumberOfValidRecHitsPerTrackVsPhi->Fill(phi,    nValidRecHits);
       tkmes.NumberOfValidRecHitsPerTrackVsEta->Fill(eta,    nValidRecHits);
 
       int nLayers = track.hitPattern().trackerLayersWithMeasurement();
       // rec layers 
       tkmes.NumberOfLayersPerTrackVsPhi->Fill(phi,     nLayers);
       if (doThetaPlots_) {
     tkmes.NumberOfLayersPerTrackVsTheta->Fill(theta, nLayers);
       }
       tkmes.NumberOfLayersPerTrackVsEta->Fill(eta,     nLayers);
       
       double chi2prob = TMath::Prob(track.chi2(),(int)track.ndof());
       double chi2oNDF = track.normalizedChi2();
 
       if(doAllPlots_) {
     
     // general properties
     if (doThetaPlots_) {
       tkmes.Chi2oNDFVsTheta->Fill(theta, chi2oNDF);
     }
     tkmes.Chi2oNDFVsPhi->Fill(phi, chi2oNDF);
     tkmes.Chi2oNDFVsEta->Fill(eta, chi2oNDF);
     tkmes.Chi2ProbVsPhi->Fill(phi, chi2prob);
     tkmes.Chi2ProbVsEta->Fill(eta, chi2prob);
       }
       
     }
 
 }

void TrackAnalyzer::fillHistosForTrackerSpecific ( const reco::Track & track )

private

Definition at line 1624 of file TrackAnalyzer.cc.

Referenced by analyze().

 {
     
   double phi   = track.phi();
   double eta   = track.eta();
 
   for ( std::map<std::string,TkRecHitsPerSubDetMEs>::iterator it = TkRecHitsPerSubDetMEMap.begin();
        it != TkRecHitsPerSubDetMEMap.end(); it++ ) {
 
     int nValidLayers  = 0;
     int nValidRecHits = 0;
     int substr = it->second.detectorId;
     switch(substr) {
     case StripSubdetector::TIB :
       nValidLayers  = track.hitPattern().stripTIBLayersWithMeasurement();       // case 0: strip TIB
       nValidRecHits = track.hitPattern().numberOfValidStripTIBHits();           // case 0: strip TIB
       break;
     case StripSubdetector::TID :
       nValidLayers  = track.hitPattern().stripTIDLayersWithMeasurement();       // case 0: strip TID
       nValidRecHits = track.hitPattern().numberOfValidStripTIDHits();           // case 0: strip TID
       break;
     case StripSubdetector::TOB :
       nValidLayers  = track.hitPattern().stripTOBLayersWithMeasurement();       // case 0: strip TOB
       nValidRecHits = track.hitPattern().numberOfValidStripTOBHits();           // case 0: strip TOB
       break;
     case StripSubdetector::TEC :
       nValidLayers  = track.hitPattern().stripTECLayersWithMeasurement();       // case 0: strip TEC
       nValidRecHits = track.hitPattern().numberOfValidStripTECHits();           // case 0: strip TEC
       break;
     case PixelSubdetector::PixelBarrel :
       nValidLayers  = track.hitPattern().pixelBarrelLayersWithMeasurement();    // case 0: pixel PXB
       nValidRecHits = track.hitPattern().numberOfValidPixelBarrelHits();        // case 0: pixel PXB
       break;
     case PixelSubdetector::PixelEndcap :
       nValidLayers  = track.hitPattern().pixelEndcapLayersWithMeasurement();    // case 0: pixel PXF
       nValidRecHits = track.hitPattern().numberOfValidPixelEndcapHits();        // case 0: pixel PXF
       break;
     default :
       break;
     }
 
     //Fill Layers and RecHits
     it->second.NumberOfRecHitsPerTrack      -> Fill(nValidRecHits); 
     it->second.NumberOfRecHitsPerTrackVsPhi -> Fill(phi,    nValidRecHits);
     it->second.NumberOfRecHitsPerTrackVsEta -> Fill(eta,    nValidRecHits);
     
     it->second.NumberOfLayersPerTrack      -> Fill(nValidLayers);
     it->second.NumberOfLayersPerTrackVsPhi -> Fill(phi,     nValidLayers);
     it->second.NumberOfLayersPerTrackVsEta -> Fill(eta,     nValidLayers);
   }
 
 }

void TrackAnalyzer::initHisto	(	DQMStore::IBooker &	ibooker,
		const edm::EventSetup &	iSetup
	)

virtual

Definition at line 138 of file TrackAnalyzer.cc.

References bookHistosForBeamSpot(), bookHistosForEfficiencyFromHitPatter(), bookHistosForHitProperties(), bookHistosForLScertification(), bookHistosForState(), bookHistosForTrackerSpecific(), conf_, doAllPlots_, doMeasurementStatePlots_, doTrackerSpecific_, edm::ParameterSet::getParameter(), and AlCaHLTBitMon_QueryRunRegistry::string.

Referenced by TrackingMonitor::bookHistograms().

 {
 
   bookHistosForHitProperties(ibooker);
   bookHistosForBeamSpot(ibooker);
   bookHistosForLScertification( ibooker);
   bookHistosForEfficiencyFromHitPatter(ibooker, iSetup);
 
   // book tracker specific related histograms
   // ---------------------------------------------------------------------------------//
   if(doTrackerSpecific_ || doAllPlots_) bookHistosForTrackerSpecific(ibooker);
     
   // book state related histograms
   // ---------------------------------------------------------------------------------//
   if (doMeasurementStatePlots_ || doAllPlots_) {
 
     std::string StateName = conf_.getParameter<std::string>("MeasurementState");
     
     if (StateName == "All") {
       bookHistosForState("OuterSurface", ibooker);
       bookHistosForState("InnerSurface", ibooker);
       bookHistosForState("ImpactPoint" , ibooker);
     } else if (
            StateName != "OuterSurface" && 
            StateName != "InnerSurface" && 
            StateName != "ImpactPoint" &&
            StateName != "default" 
            ) {
       bookHistosForState("default", ibooker);
 
     } else {
       bookHistosForState(StateName, ibooker);
     }
     
   }
 }

void TrackAnalyzer::initHistos ( )

private

Definition at line 61 of file TrackAnalyzer.cc.

References algorithm, Chi2oNDF, Chi2oNDF_lumiFlag, Chi2oNDFVsEta, Chi2oNDFVsPhi, Chi2oNDFVsTheta, Chi2Prob, Chi2ProbVsEta, Chi2ProbVsPhi, DistanceOfClosestApproach, DistanceOfClosestApproachToBS, DistanceOfClosestApproachToBSVsPhi, DistanceOfClosestApproachVsEta, DistanceOfClosestApproachVsPhi, DistanceOfClosestApproachVsTheta, dNdEta_HighPurity, dNdPhi_HighPurity, dNdPt_HighPurity, LongDCASig, NhitVsEta_HighPurity, NhitVsPhi_HighPurity, NumberOfLostRecHitsPerTrack, NumberOfRecHitsPerTrack, NumberOfRecHitsPerTrack_lumiFlag, NumberOfRecHitsPerTrackVsEta, NumberOfRecHitsPerTrackVsPhi, NumberOfRecHitsPerTrackVsTheta, NumberOfRecHitVsPhiVsEtaPerTrack, NumberOfValidRecHitsPerTrack, NumberOfValidRecHitsPerTrackVsEta, NumberOfValidRecHitsPerTrackVsPhi, oriAlgo, sip2dToPV, sip3dToPV, sipDxyToBS, sipDxyToPV, sipDzToBS, sipDzToPV, TESTDistanceOfClosestApproachToBS, TESTDistanceOfClosestApproachToBSVsPhi, TransDCASig, xPointOfClosestApproach, xPointOfClosestApproachVsZ0wrt000, xPointOfClosestApproachVsZ0wrtBS, yPointOfClosestApproach, yPointOfClosestApproachVsZ0wrt000, yPointOfClosestApproachVsZ0wrtBS, zPointOfClosestApproach, and zPointOfClosestApproachVsPhi.

Referenced by TrackAnalyzer().

 {
   Chi2 = nullptr;
   Chi2Prob = nullptr;
   Chi2ProbVsPhi = nullptr;
   Chi2ProbVsEta = nullptr;
   Chi2oNDF = nullptr;
   Chi2oNDFVsEta = nullptr;
   Chi2oNDFVsPhi = nullptr;
   Chi2oNDFVsTheta = nullptr;
   Chi2oNDFVsTheta = nullptr;
   Chi2oNDFVsPhi = nullptr;
   Chi2oNDFVsEta = nullptr;
         
   NumberOfRecHitsPerTrack = nullptr;
   NumberOfValidRecHitsPerTrack = nullptr;
   NumberOfLostRecHitsPerTrack = nullptr;
 
   NumberOfRecHitsPerTrackVsPhi = nullptr;
   NumberOfRecHitsPerTrackVsTheta = nullptr;
   NumberOfRecHitsPerTrackVsEta = nullptr;
 
   NumberOfRecHitVsPhiVsEtaPerTrack = nullptr;
 
   NumberOfValidRecHitsPerTrackVsPhi = nullptr;
   NumberOfValidRecHitsPerTrackVsEta = nullptr;
 
 
   DistanceOfClosestApproach = nullptr;
   DistanceOfClosestApproachToBS = nullptr;
   DistanceOfClosestApproachVsTheta = nullptr;
   DistanceOfClosestApproachVsPhi = nullptr;
   DistanceOfClosestApproachToBSVsPhi = nullptr;
   DistanceOfClosestApproachVsEta = nullptr;
   xPointOfClosestApproach = nullptr;
   xPointOfClosestApproachVsZ0wrt000 = nullptr;
   xPointOfClosestApproachVsZ0wrtBS = nullptr;
   yPointOfClosestApproach = nullptr;
   yPointOfClosestApproachVsZ0wrt000 = nullptr;
   yPointOfClosestApproachVsZ0wrtBS = nullptr;
   zPointOfClosestApproach = nullptr;
   zPointOfClosestApproachVsPhi = nullptr;
   algorithm = nullptr;
   oriAlgo = nullptr;
     // TESTING
   TESTDistanceOfClosestApproachToBS = nullptr;
   TESTDistanceOfClosestApproachToBSVsPhi = nullptr;
 
 // by Mia in order to deal w/ LS transitions
   Chi2oNDF_lumiFlag = nullptr;
   NumberOfRecHitsPerTrack_lumiFlag = nullptr;
 
   //special Plots for HI DQM  //SHOULD I ADD THE BOOL HERE??                                                                                                                                               
   LongDCASig = nullptr;
   TransDCASig = nullptr;
   dNdPhi_HighPurity = nullptr;
   dNdEta_HighPurity = nullptr;
   dNdPt_HighPurity = nullptr;
   NhitVsEta_HighPurity = nullptr;
   NhitVsPhi_HighPurity = nullptr;
 
   // IP significance
   sipDxyToBS = nullptr;
   sipDzToBS = nullptr;
   sip3dToPV = nullptr;
   sip2dToPV = nullptr;
   sipDxyToPV = nullptr;
   sipDzToPV = nullptr;
 
 }

void TrackAnalyzer::setLumiFlag ( )

Definition at line 1679 of file TrackAnalyzer.cc.

References Chi2oNDF_lumiFlag, and NumberOfRecHitsPerTrack_lumiFlag.

Referenced by TrackingMonitor::bookHistograms().

                                 { 
 
   TkParameterMEs tkmes;
   if ( Chi2oNDF_lumiFlag                ) Chi2oNDF_lumiFlag                -> setLumiFlag();
   if ( NumberOfRecHitsPerTrack_lumiFlag ) NumberOfRecHitsPerTrack_lumiFlag -> setLumiFlag();
 }

void TrackAnalyzer::setNumberOfGoodVertices ( const edm::Event & iEvent )

Definition at line 806 of file TrackAnalyzer.cc.

References edm::Event::getByToken(), good_vertices_, edm::HandleBase::isValid(), pvToken_, and findQualityFiles::v.

Referenced by TrackingMonitor::analyze().

                                                                    {
 
   good_vertices_ = 0;
   
   edm::Handle<reco::VertexCollection> recoPrimaryVerticesHandle;
   iEvent.getByToken(pvToken_, recoPrimaryVerticesHandle);
   if (recoPrimaryVerticesHandle.isValid())
     if (recoPrimaryVerticesHandle->size() > 0)
       for (auto v : *recoPrimaryVerticesHandle)
         if (v.ndof() >=4 && !v.isFake())
           ++good_vertices_;
 }

void TrackAnalyzer::undoSoftReset ( DQMStore * dqmStore_ )

Definition at line 1704 of file TrackAnalyzer.cc.

References Chi2oNDF, DQMStore::disableSoftReset(), and NumberOfRecHitsPerTrack.

                                                       {
   TkParameterMEs tkmes;
   dqmStore_->disableSoftReset(Chi2oNDF);
   dqmStore_->disableSoftReset(NumberOfRecHitsPerTrack);
 }