#include <Alignment/APEEstimation/src/ApeEstimator.cc>

Inheritance diagram for ApeEstimator:

Classes
struct	PositionAndError2

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

	~ApeEstimator () override

Public Member Functions inherited from edm::one::EDAnalyzer<>
	EDAnalyzer ()=default

SerialTaskQueue *	globalLuminosityBlocksQueue () final

SerialTaskQueue *	globalRunsQueue () final

bool	wantsGlobalLuminosityBlocks () const final

bool	wantsGlobalRuns () const final

Public Member Functions inherited from edm::one::EDAnalyzerBase
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)

	EDAnalyzerBase ()

ModuleDescription const &	moduleDescription () const

bool	wantsStreamLuminosityBlocks () const

bool	wantsStreamRuns () const

	~EDAnalyzerBase () override

Public Member Functions inherited from edm::EDConsumerBase
std::vector< ConsumesInfo >	consumesInfo () const

void	convertCurrentProcessAlias (std::string const &processName)
	Convert "@currentProcess" in InputTag process names to the actual current process name. More...

	EDConsumerBase ()

	EDConsumerBase (EDConsumerBase const &)=delete

	EDConsumerBase (EDConsumerBase &&)=default

ProductResolverIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const

void	itemsMayGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const

void	itemsToGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const

std::vector< ProductResolverIndexAndSkipBit > const &	itemsToGetFrom (BranchType iType) const

void	labelsForToken (EDGetToken iToken, Labels &oLabels) const

void	modulesWhoseProductsAreConsumed (std::vector< ModuleDescription const * > &modules, ProductRegistry const &preg, std::map< std::string, ModuleDescription const * > const &labelsToDesc, std::string const &processName) const

EDConsumerBase const &	operator= (EDConsumerBase const &)=delete

EDConsumerBase &	operator= (EDConsumerBase &&)=default

bool	registeredToConsume (ProductResolverIndex, bool, BranchType) const

bool	registeredToConsumeMany (TypeID const &, BranchType) const

ProductResolverIndexAndSkipBit	uncheckedIndexFrom (EDGetToken) const

void	updateLookup (BranchType iBranchType, ProductResolverIndexHelper const &, bool iPrefetchMayGet)

virtual	~EDConsumerBase () noexcept(false)

Private Types
typedef std::pair< TrackStruct::HitState, PositionAndError2 >	StatePositionAndError2

Private Member Functions
void	analyze (const edm::Event &, const edm::EventSetup &) override

void	beginJob () override

void	bookSectorHistsForAnalyzerMode ()

void	bookSectorHistsForApeCalculation ()

void	bookTrackHists ()

void	calculateAPE ()

bool	checkIntervalsForSectors (const unsigned int sectorCounter, const std::vector< double > &) const

bool	checkModuleBools (const bool, const std::vector< unsigned int > &) const

bool	checkModuleDirections (const int, const std::vector< int > &) const

bool	checkModuleIds (const unsigned int, const std::vector< unsigned int > &) const

bool	checkModulePositions (const float, const std::vector< double > &) const

void	endJob () override

void	fillHistsForAnalyzerMode (const TrackStruct &)

void	fillHistsForApeCalculation (const TrackStruct &)

void	fillHitHistsXForAnalyzerMode (const TrackStruct::HitParameterStruct &, TrackerSectorStruct &)

void	fillHitHistsYForAnalyzerMode (const TrackStruct::HitParameterStruct &, TrackerSectorStruct &)

TrackStruct::HitParameterStruct	fillHitVariables (const TrajectoryMeasurement &, const edm::EventSetup &)

TrackStruct::TrackParameterStruct	fillTrackVariables (const reco::Track &, const Trajectory &, const reco::BeamSpot &)

bool	hitSelected (TrackStruct::HitParameterStruct &) const

void	hitSelection ()

bool	inDoubleInterval (const std::vector< double > &, const float) const

bool	inUintInterval (const std::vector< unsigned int > &, const unsigned int, const unsigned int=999) const

bool	isHit2D (const TrackingRecHit &) const

StatePositionAndError2	positionAndError2 (const LocalPoint &, const LocalError &, const TransientTrackingRecHit &)

PositionAndError2	radialPositionAndError2 (const LocalPoint &, const LocalError &, const RadialStripTopology &)

PositionAndError2	rectangularPositionAndError2 (const LocalPoint &, const LocalError &)

void	residualErrorBinning ()

void	sectorBuilder ()

void	setHitSelectionMap (const std::string &)

void	setHitSelectionMapUInt (const std::string &)

void	statistics (const TrackerSectorStruct &, const int) const

Private Attributes
const bool	analyzerMode_

const bool	calculateApe_

unsigned int	counter1

unsigned int	counter2

unsigned int	counter3

unsigned int	counter4

unsigned int	counter5

unsigned int	counter6

std::map< std::string, std::vector< double > >	m_hitSelection_

std::map< std::string, std::vector< unsigned int > >	m_hitSelectionUInt_

std::map< unsigned int, std::pair< double, double > >	m_resErrBins_

std::map< unsigned int, TrackerSectorStruct >	m_tkSector_

std::map< unsigned int, ReducedTrackerTreeVariables >	m_tkTreeVar_

const unsigned int	maxTracksPerEvent_

const unsigned int	minGoodHitsPerTrack_

edm::EDGetTokenT< reco::BeamSpot >	offlinebeamSpot_

const edm::ParameterSet	parameterSet_

edm::EDGetTokenT< TrajTrackAssociationCollection >	tjTagToken_

TrackerDetectorStruct	tkDetector_

bool	trackCut_

Additional Inherited Members
Public Types inherited from edm::one::EDAnalyzerBase
typedef EDAnalyzerBase	ModuleType

Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels

Static Public Member Functions inherited from edm::one::EDAnalyzerBase
static const std::string &	baseType ()

static void	fillDescriptions (ConfigurationDescriptions &descriptions)

static void	prevalidate (ConfigurationDescriptions &descriptions)

Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)

EDGetToken	consumes (const TypeToGet &id, edm::InputTag const &tag)

template<BranchType B>
EDGetToken	consumes (TypeToGet const &id, edm::InputTag const &tag)

ConsumesCollector	consumesCollector ()
	Use a ConsumesCollector to gather consumes information from helper functions. More...

template<typename ProductType , BranchType B = InEvent>
void	consumesMany ()

void	consumesMany (const TypeToGet &id)

template<BranchType B>
void	consumesMany (const TypeToGet &id)

template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	mayConsume (edm::InputTag const &tag)

EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

template<BranchType B>
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

Detailed Description

Description: <one line="" class="" summary>="">

Implementation: <Notes on="" implementation>="">

Definition at line 129 of file ApeEstimator.cc.

Member Typedef Documentation

typedef std::pair<TrackStruct::HitState,PositionAndError2> ApeEstimator::StatePositionAndError2

private

Definition at line 144 of file ApeEstimator.cc.

Constructor & Destructor Documentation

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

explicit

Definition at line 226 of file ApeEstimator.cc.

References counter1, counter2, counter3, counter4, counter5, and counter6.

                                                         :
   parameterSet_(iConfig),
   tjTagToken_(consumes<TrajTrackAssociationCollection>(parameterSet_.getParameter<edm::InputTag>("tjTkAssociationMapTag"))),
   offlinebeamSpot_(consumes<reco::BeamSpot>(edm::InputTag("offlineBeamSpot"))),
   trackCut_(false), maxTracksPerEvent_(parameterSet_.getParameter<unsigned int>("maxTracksPerEvent")),
   minGoodHitsPerTrack_(parameterSet_.getParameter<unsigned int>("minGoodHitsPerTrack")),
   analyzerMode_(parameterSet_.getParameter<bool>("analyzerMode")),
   calculateApe_(parameterSet_.getParameter<bool>("calculateApe"))
 {
    counter1 = counter2 = counter3 = counter4 = counter5 = counter6 = 0;
 }

ApeEstimator::~ApeEstimator ( )

override

Definition at line 239 of file ApeEstimator.cc.

240 {

241 }

Member Function Documentation

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

overrideprivate

Definition at line 2171 of file ApeEstimator.cc.

References analyzerMode_, ecalDrivenElectronSeedsParameters_cff::beamSpot, edm::AssociationMap< Tag >::begin(), calculateApe_, edm::AssociationMap< edm::OneToOne< std::vector< Trajectory >, reco::TrackCollection, unsigned short > >::const_iterator, edm::AssociationMap< Tag >::end(), fillHistsForAnalyzerMode(), fillHistsForApeCalculation(), fillHitVariables(), fillTrackVariables(), edm::Event::getByToken(), hitSelected(), edm::HandleBase::isValid(), maxTracksPerEvent_, offlinebeamSpot_, edm::AssociationMap< Tag >::size(), tjTagToken_, tkDetector_, HiIsolationCommonParameters_cff::track, trackCut_, TrackStruct::trkParams, TrackerDetectorStruct::TrkSize, TrackerDetectorStruct::TrkSizeGood, and TrackStruct::v_hitParams.

 {
    reco::BeamSpot beamSpot;
    edm::Handle<reco::BeamSpot> beamSpotHandle;
    iEvent.getByToken(offlinebeamSpot_, beamSpotHandle);
    
    if (beamSpotHandle.isValid()){
      beamSpot = *beamSpotHandle;
    }else{
      edm::LogError("ApeEstimator")<<"No beam spot available from EventSetup"
                                   <<"\n...skip event";
      return;
    }
       
    edm::Handle<TrajTrackAssociationCollection> m_TrajTracksMap;
    iEvent.getByToken(tjTagToken_, m_TrajTracksMap);
    
    if(analyzerMode_)tkDetector_.TrkSize->Fill(m_TrajTracksMap->size());
    
    if(maxTracksPerEvent_!=0 && m_TrajTracksMap->size()>maxTracksPerEvent_)return;
    
    //Creation of (traj,track)
    typedef std::pair<const Trajectory*, const reco::Track*> ConstTrajTrackPair;
    typedef std::vector<ConstTrajTrackPair> ConstTrajTrackPairCollection;
    ConstTrajTrackPairCollection trajTracks;
    
    TrajTrackAssociationCollection::const_iterator i_trajTrack;
    for(i_trajTrack = m_TrajTracksMap->begin();i_trajTrack != m_TrajTracksMap->end();++i_trajTrack){
      trajTracks.push_back(ConstTrajTrackPair(&(*(*i_trajTrack).key), &(*(*i_trajTrack).val)));
    }
    
    
    //Loop over Tracks & Hits
    unsigned int trackSizeGood(0);
    ConstTrajTrackPairCollection::const_iterator iTrack;
    for(iTrack = trajTracks.begin(); iTrack != trajTracks.end();++iTrack){
      
      const Trajectory *traj = (*iTrack).first;
      const reco::Track *track = (*iTrack).second;
      
      TrackStruct trackStruct;
      trackStruct.trkParams = this->fillTrackVariables(*track, *traj, beamSpot);
      
      if(trackCut_)continue;
      
      const std::vector<TrajectoryMeasurement> v_meas = (*traj).measurements();
      
      //Loop over Hits
      for(std::vector<TrajectoryMeasurement>::const_iterator i_meas = v_meas.begin(); i_meas != v_meas.end(); ++i_meas){
        TrackStruct::HitParameterStruct hitParams = this->fillHitVariables(*i_meas, iSetup);
        if(this->hitSelected(hitParams))trackStruct.v_hitParams.push_back(hitParams);
      }
      
      if(analyzerMode_)this->fillHistsForAnalyzerMode(trackStruct);
      if(calculateApe_)this->fillHistsForApeCalculation(trackStruct);
      
      if(!trackStruct.v_hitParams.empty())++trackSizeGood;
    }
    if(analyzerMode_ && trackSizeGood>0)tkDetector_.TrkSizeGood->Fill(trackSizeGood);
 }

void ApeEstimator::beginJob ( )

overrideprivatevirtual

Reimplemented from edm::one::EDAnalyzerBase.

Definition at line 2235 of file ApeEstimator.cc.

References analyzerMode_, bookSectorHistsForAnalyzerMode(), bookSectorHistsForApeCalculation(), bookTrackHists(), calculateApe_, hitSelection(), residualErrorBinning(), and sectorBuilder().

                       {
    this->hitSelection();
    
    this->sectorBuilder();
    
    this->residualErrorBinning();
    
    if(analyzerMode_)this->bookSectorHistsForAnalyzerMode();
    
    if(calculateApe_)this->bookSectorHistsForApeCalculation();
    
    if(analyzerMode_)this->bookTrackHists();
    
 }

void ApeEstimator::bookSectorHistsForAnalyzerMode ( )

private

Definition at line 576 of file ApeEstimator.cc.

References edm::errors::Configuration, AlignmentTrackSelector_cfi::d0Max, AlignmentTrackSelector_cfi::dzMax, Exception, fileService, edm::ParameterSet::getParameter(), m_tkSector_, TFileDirectory::make(), TFileService::mkdir(), parameterSet_, AlignmentTrackSelector_cfi::pMax, fftjetvertexadder_cfi::sigmaX, beamspotanalyzer_cfi::sigmaXMax, beamspotanalyzer_cfi::sigmaXMin, fftjetvertexadder_cfi::sigmaY, anotherprimaryvertexanalyzer_cfi::xMax, and anotherprimaryvertexanalyzer_cfi::xMin.

Referenced by beginJob().

                                             {
   std::vector<unsigned int> v_errHists(parameterSet_.getParameter<std::vector<unsigned int> >("vErrHists"));
   for(std::vector<unsigned int>::iterator i_errHists = v_errHists.begin(); i_errHists != v_errHists.end(); ++i_errHists){
     for(std::vector<unsigned int>::iterator i_errHists2 = i_errHists; i_errHists2 != v_errHists.end();){
       ++i_errHists2;
       if(*i_errHists==*i_errHists2){
         edm::LogError("BookSectorHists")<<"Value of vErrHists in config exists twice: "<<*i_errHists<<"\n... delete one of both";
         v_errHists.erase(i_errHists2);
       }
     }
   }
   
   
   for(auto & i_sector : m_tkSector_){
     bool zoomHists(parameterSet_.getParameter<bool>("zoomHists"));
     
     double widthMax = zoomHists ? 20. : 200.;
     double chargePixelMax = zoomHists ? 200000. : 2000000.;
     double chargeStripMax = zoomHists ? 1000. : 10000.;
     double sOverNMax = zoomHists ? 200. : 2000.;
     double logClusterProbMin = zoomHists ? -5. : -15.;
     
     double resXAbsMax = zoomHists ? 0.5 : 5.;
     double norResXAbsMax = zoomHists ? 10. : 50.;
     double probXMin = zoomHists ? -0.01 :  -0.1;
     double probXMax = zoomHists ? 0.11 :  1.1;
     double sigmaXMin = zoomHists ? 0. : -0.05;
     double sigmaXMax = zoomHists ? 0.02 : 1.;
     double sigmaX2Max = sigmaXMax*sigmaXMax;
     double sigmaXHitMax = zoomHists ? 0.02 : 1.;
     double phiSensXMax = zoomHists ? 31. : 93.;
     
     double norChi2Max = zoomHists ? 5. : 1000.;
     double d0Max = zoomHists ? 0.02 : 40.;  // cosmics: 100.|100.
     double dzMax = zoomHists ? 15. : 100.;  // cosmics: 200.|600.
     double pMax = zoomHists ? 200. : 2000.;
     double invPMax = zoomHists ? 0.05 : 10.;   //begins at 20GeV, 0.1GeV
     
     
     edm::Service<TFileService> fileService;
     if(!fileService){
       throw edm::Exception( edm::errors::Configuration,
                             "TFileService is not registered in cfg file" );
     }
     
     std::stringstream sector; sector << "Sector_" << i_sector.first;
     TFileDirectory secDir = fileService->mkdir(sector.str());
     
     // Dummy histo containing the sector name as title
     i_sector.second.Name = secDir.make<TH1F>("z_name",i_sector.second.name.c_str(),1,0,1);
     
     // Do not book histos for empty sectors
     if(i_sector.second.v_rawId.empty()){
       continue;
     }
     // Set parameters for correlationHists
     i_sector.second.setCorrHistParams(&secDir,norResXAbsMax,sigmaXHitMax,sigmaXMax);
     
     
     // Book pixel or strip specific hists
     const bool pixelSector(i_sector.second.isPixel);
     
     
     // Cluster Parameters
     i_sector.second.m_correlationHistsX["WidthX"] = i_sector.second.bookCorrHistsX("WidthX","cluster width","w_{cl,x}","[# channels]",static_cast<int>(widthMax),static_cast<int>(widthMax),0.,widthMax,"nph");
     i_sector.second.m_correlationHistsX["BaryStripX"] = i_sector.second.bookCorrHistsX("BaryStripX","barycenter of cluster charge","b_{cl,x}","[# channels]",800,100,-10.,790.,"nph");
     
     if(pixelSector){
       i_sector.second.m_correlationHistsY["WidthY"] = i_sector.second.bookCorrHistsY("WidthY","cluster width","w_{cl,y}","[# channels]",static_cast<int>(widthMax),static_cast<int>(widthMax),0.,widthMax,"nph");
       i_sector.second.m_correlationHistsY["BaryStripY"] = i_sector.second.bookCorrHistsY("BaryStripY","barycenter of cluster charge","b_{cl,y}","[# channels]",800,100,-10.,790.,"nph");
       
       i_sector.second.m_correlationHistsX["ChargePixel"] = i_sector.second.bookCorrHistsX("ChargePixel","cluster charge","c_{cl}","[e]",100,50,0.,chargePixelMax,"nph");
       i_sector.second.m_correlationHistsX["ClusterProbXY"] = i_sector.second.bookCorrHistsX("ClusterProbXY","cluster probability xy","prob_{cl,xy}","",100,50,0.,1.,"nph");
       i_sector.second.m_correlationHistsX["ClusterProbQ"] = i_sector.second.bookCorrHistsX("ClusterProbQ","cluster probability q","prob_{cl,q}","",100,50,0.,1.,"nph");
       i_sector.second.m_correlationHistsX["ClusterProbXYQ"] = i_sector.second.bookCorrHistsX("ClusterProbXYQ","cluster probability xyq","prob_{cl,xyq}","",100,50,0.,1.,"nph");
       i_sector.second.m_correlationHistsX["LogClusterProb"] = i_sector.second.bookCorrHistsX("LogClusterProb","cluster probability xy","log(prob_{cl,xy})","",60,30,logClusterProbMin,0.,"nph");
       i_sector.second.m_correlationHistsX["IsOnEdge"] = i_sector.second.bookCorrHistsX("IsOnEdge","IsOnEdge","isOnEdge","",2,2,0,2,"nph");
       i_sector.second.m_correlationHistsX["HasBadPixels"] = i_sector.second.bookCorrHistsX("HasBadPixels","HasBadPixels","hasBadPixels","",2,2,0,2,"nph");
       i_sector.second.m_correlationHistsX["SpansTwoRoc"] = i_sector.second.bookCorrHistsX("SpansTwoRoc","SpansTwoRoc","spansTwoRoc","",2,2,0,2,"nph");
       i_sector.second.m_correlationHistsX["QBin"] = i_sector.second.bookCorrHistsX("QBin","q bin","q bin","",8,8,0,8,"nph");
       
       i_sector.second.m_correlationHistsY["ChargePixel"] = i_sector.second.bookCorrHistsY("ChargePixel","cluster charge","c_{cl}","[e]",100,50,0.,chargePixelMax,"nph");
       i_sector.second.m_correlationHistsY["ClusterProbXY"] = i_sector.second.bookCorrHistsY("ClusterProbXY","cluster probability xy","prob_{cl,xy}","",100,50,0.,1.,"nph");
       i_sector.second.m_correlationHistsY["ClusterProbQ"] = i_sector.second.bookCorrHistsY("ClusterProbQ","cluster probability q","prob_{cl,q}","",100,50,0.,1.,"nph");
       i_sector.second.m_correlationHistsY["ClusterProbXYQ"] = i_sector.second.bookCorrHistsY("ClusterProbXYQ","cluster probability xyq","prob_{cl,xyq}","",100,50,0.,1.,"nph");
       i_sector.second.m_correlationHistsY["LogClusterProb"] = i_sector.second.bookCorrHistsY("LogClusterProb","cluster probability xy","log(prob_{cl,xy})","",60,30,logClusterProbMin,0.,"nph");
       i_sector.second.m_correlationHistsY["IsOnEdge"] = i_sector.second.bookCorrHistsY("IsOnEdge","IsOnEdge","isOnEdge","",2,2,0,2,"nph");
       i_sector.second.m_correlationHistsY["HasBadPixels"] = i_sector.second.bookCorrHistsY("HasBadPixels","HasBadPixels","hasBadPixels","",2,2,0,2,"nph");
       i_sector.second.m_correlationHistsY["SpansTwoRoc"] = i_sector.second.bookCorrHistsY("SpansTwoRoc","SpansTwoRoc","spansTwoRoc","",2,2,0,2,"nph");
       i_sector.second.m_correlationHistsY["QBin"] = i_sector.second.bookCorrHistsY("QBin","q bin","q bin","",8,8,0,8,"nph");
     }
     
     else{
       i_sector.second.m_correlationHistsX["ChargeStrip"] = i_sector.second.bookCorrHistsX("ChargeStrip","cluster charge","c_{cl}","[APV counts]",100,50,0.,chargeStripMax,"nph");
       i_sector.second.m_correlationHistsX["MaxStrip"] = i_sector.second.bookCorrHistsX("MaxStrip","strip with max. charge","n_{cl,max}","[# strips]",800,800,-10.,790.,"npht");
       i_sector.second.m_correlationHistsX["MaxCharge"] = i_sector.second.bookCorrHistsX("MaxCharge","charge of strip with max. charge","c_{cl,max}","[APV counts]",300,75,-10.,290.,"nph");
       i_sector.second.m_correlationHistsX["MaxIndex"] = i_sector.second.bookCorrHistsX("MaxIndex","cluster-index of strip with max. charge","i_{cl,max}","[# strips]",10,10,0.,10.,"nph");
       i_sector.second.m_correlationHistsX["ChargeOnEdges"] = i_sector.second.bookCorrHistsX("ChargeOnEdges","fraction of charge on edge strips","(c_{st,L}+c_{st,R})/c_{cl}","",60,60,-0.1,1.1,"nph");
       i_sector.second.m_correlationHistsX["ChargeAsymmetry"] = i_sector.second.bookCorrHistsX("ChargeAsymmetry","asymmetry of charge on edge strips","(c_{st,L}-c_{st,R})/c_{cl}","",110,55,-1.1,1.1,"nph");
       i_sector.second.m_correlationHistsX["ChargeLRplus"] = i_sector.second.bookCorrHistsX("ChargeLRplus","fraction of charge not on maxStrip","(c_{cl,L}+c_{cl,R})/c_{cl}","",60,60,-0.1,1.1,"nph");
       i_sector.second.m_correlationHistsX["ChargeLRminus"] = i_sector.second.bookCorrHistsX("ChargeLRminus","asymmetry of charge L and R of maxStrip","(c_{cl,L}-c_{cl,R})/c_{cl}","",110,55,-1.1,1.1,"nph");
       i_sector.second.m_correlationHistsX["SOverN"] = i_sector.second.bookCorrHistsX("SOverN","signal over noise","s/N","",100,50,0,sOverNMax,"nph");
       i_sector.second.m_correlationHistsX["WidthProj"] = i_sector.second.bookCorrHistsX("WidthProj","projected width","w_{p}","[# strips]",200,20,0.,widthMax,"nph");
       i_sector.second.m_correlationHistsX["WidthDiff"] = i_sector.second.bookCorrHistsX("WidthDiff","width difference","w_{p} - w_{cl}","[# strips]",200,20,-widthMax/2.,widthMax/2.,"nph");
       
       i_sector.second.WidthVsWidthProjected = secDir.make<TH2F>("h2_widthVsWidthProj","w_{cl} vs. w_{p};w_{p}  [# strips];w_{cl}  [# strips]",static_cast<int>(widthMax),0,widthMax,static_cast<int>(widthMax),0,widthMax);
       i_sector.second.PWidthVsWidthProjected = secDir.make<TProfile>("p_widthVsWidthProj","w_{cl} vs. w_{p};w_{p}  [# strips];w_{cl}  [# strips]",static_cast<int>(widthMax),0,widthMax);
       
       i_sector.second.WidthDiffVsMaxStrip = secDir.make<TH2F>("h2_widthDiffVsMaxStrip","(w_{p} - w_{cl}) vs. n_{cl,max};n_{cl,max};w_{p} - w_{cl}  [# strips]",800,-10.,790.,static_cast<int>(widthMax),-widthMax/2.,widthMax/2.);
       i_sector.second.PWidthDiffVsMaxStrip = secDir.make<TProfile>("p_widthDiffVsMaxStrip","(w_{p} - w_{cl}) vs. n_{cl,max};n_{cl,max};w_{p} - w_{cl}  [# strips]",800,-10.,790.);
       
       i_sector.second.WidthDiffVsSigmaXHit = secDir.make<TH2F>("h2_widthDiffVsSigmaXHit","(w_{p} - w_{cl}) vs. #sigma_{hit,x};#sigma_{hit,x}  [cm];w_{p} - w_{cl}  [# strips]",100,0.,sigmaXMax,100,-10.,10.);
       i_sector.second.PWidthDiffVsSigmaXHit = secDir.make<TProfile>("p_widthDiffVsSigmaXHit","(w_{p} - w_{cl}) vs. #sigma_{hit,x};#sigma_{hit,x}  [cm];w_{p} - w_{cl}  [# strips]",100,0.,sigmaXMax);
       
       i_sector.second.WidthVsPhiSensX = secDir.make<TH2F>("h2_widthVsPhiSensX","w_{cl} vs. #phi_{module,x};#phi_{module,x}  [ ^{o}];w_{cl}  [# strips]",93,-93,93,static_cast<int>(widthMax),0,widthMax);
       i_sector.second.PWidthVsPhiSensX = secDir.make<TProfile>("p_widthVsPhiSensX","w_{cl} vs. #phi_{module,x};#phi_{module,x}  [ ^{o}];w_{cl}  [# strips]",93,-93,93);
     }
     
     
     // Hit Parameters (transform errors and residuals from [cm] in [mum])
     i_sector.second.m_correlationHistsX["SigmaXHit"] = i_sector.second.bookCorrHistsX("SigmaXHit","hit error","#sigma_{hit,x}","[#mum]",105,20,sigmaXMin*10000.,sigmaXMax*10000.,"np");
     i_sector.second.m_correlationHistsX["SigmaXTrk"] = i_sector.second.bookCorrHistsX("SigmaXTrk","track error","#sigma_{trk,x}","[#mum]",105,20,sigmaXMin*10000.,sigmaXMax*10000.,"np");
     i_sector.second.m_correlationHistsX["SigmaX"]    = i_sector.second.bookCorrHistsX("SigmaX","residual error","#sigma_{r,x}","[#mum]",105,20,sigmaXMin*10000.,sigmaXMax*10000.,"np");
     i_sector.second.m_correlationHistsX["PhiSens"]   = i_sector.second.bookCorrHistsX("PhiSens","track angle on sensor","#phi_{module}","[ ^{o}]",96,48,-3,93,"nphtr");
     i_sector.second.m_correlationHistsX["PhiSensX"]  = i_sector.second.bookCorrHistsX("PhiSensX","track angle on sensor","#phi_{module,x}","[ ^{o}]",186,93,-phiSensXMax,phiSensXMax,"nphtr");
     i_sector.second.m_correlationHistsX["PhiSensY"]  = i_sector.second.bookCorrHistsX("PhiSensY","track angle on sensor","#phi_{module,y}","[ ^{o}]",186,93,-93,93,"nphtr");
     
     i_sector.second.XHit    = secDir.make<TH1F>("h_XHit"," hit measurement x_{hit};x_{hit}  [cm];# hits",100,-20,20);
     i_sector.second.XTrk    = secDir.make<TH1F>("h_XTrk","track prediction x_{trk};x_{trk}  [cm];# hits",100,-20,20);
     i_sector.second.SigmaX2 = secDir.make<TH1F>("h_SigmaX2","squared residual error #sigma_{r,x}^{2};#sigma_{r,x}^{2}  [#mum^{2}];# hits",105,sigmaXMin*10000.,sigmaX2Max*10000.*10000.); //no mistake !
     i_sector.second.ResX    = secDir.make<TH1F>("h_ResX","residual r_{x};x_{trk}-x_{hit}  [#mum];# hits",100,-resXAbsMax*10000.,resXAbsMax*10000.);
     i_sector.second.NorResX = secDir.make<TH1F>("h_NorResX","normalized residual r_{x}/#sigma_{r,x};(x_{trk}-x_{hit})/#sigma_{r,x};# hits",100,-norResXAbsMax,norResXAbsMax);
     i_sector.second.ProbX   = secDir.make<TH1F>("h_ProbX","residual probability;prob(r_{x}^{2}/#sigma_{r,x}^{2},1);# hits",60,probXMin,probXMax);
     
     i_sector.second.PhiSensXVsBarycentreX = secDir.make<TH2F>("h2_phiSensXVsBarycentreX","#phi_{module,x} vs. b_{cl,x};b_{cl,x}  [# channels];#phi_{module,x}  [ ^{o}]",200,-10.,790.,93,-93,93);
     i_sector.second.PPhiSensXVsBarycentreX = secDir.make<TProfile>("p_phiSensXVsBarycentreX","#phi_{module,x} vs. b_{cl,x};b_{cl,x}  [# channels];#phi_{module,x}  [ ^{o}]",200,-10.,790.);
     
     if(pixelSector){
       i_sector.second.m_correlationHistsY["SigmaYHit"] = i_sector.second.bookCorrHistsY("SigmaYHit","hit error","#sigma_{hit,y}","[#mum]",105,20,sigmaXMin*10000.,sigmaXMax*10000.,"np");
       i_sector.second.m_correlationHistsY["SigmaYTrk"] = i_sector.second.bookCorrHistsY("SigmaYTrk","track error","#sigma_{trk,y}","[#mum]",105,20,sigmaXMin*10000.,sigmaXMax*10000.,"np");
       i_sector.second.m_correlationHistsY["SigmaY"]    = i_sector.second.bookCorrHistsY("SigmaY","residual error","#sigma_{r,y}","[#mum]",105,20,sigmaXMin*10000.,sigmaXMax*10000.,"np");
       i_sector.second.m_correlationHistsY["PhiSens"]   = i_sector.second.bookCorrHistsY("PhiSens","track angle on sensor","#phi_{module}","[ ^{o}]",96,48,-3,93,"nphtr");
       i_sector.second.m_correlationHistsY["PhiSensX"]  = i_sector.second.bookCorrHistsY("PhiSensX","track angle on sensor","#phi_{module,x}","[ ^{o}]",186,93,-phiSensXMax,phiSensXMax,"nphtr");
       i_sector.second.m_correlationHistsY["PhiSensY"]  = i_sector.second.bookCorrHistsY("PhiSensY","track angle on sensor","#phi_{module,y}","[ ^{o}]",186,93,-93,93,"nphtr");
       
       i_sector.second.YHit    = secDir.make<TH1F>("h_YHit"," hit measurement y_{hit};y_{hit}  [cm];# hits",100,-20,20);
       i_sector.second.YTrk    = secDir.make<TH1F>("h_YTrk","track prediction y_{trk};y_{trk}  [cm];# hits",100,-20,20);
       i_sector.second.SigmaY2 = secDir.make<TH1F>("h_SigmaY2","squared residual error #sigma_{r,y}^{2};#sigma_{r,y}^{2}  [#mum^{2}];# hits",105,sigmaXMin*10000.,sigmaX2Max*10000.*10000.); //no mistake !
       i_sector.second.ResY    = secDir.make<TH1F>("h_ResY","residual r_{y};y_{trk}-y_{hit}  [#mum];# hits",100,-resXAbsMax*10000.,resXAbsMax*10000.);
       i_sector.second.NorResY = secDir.make<TH1F>("h_NorResY","normalized residual r_{y}/#sigma_{r,y};(y_{trk}-y_{hit})/#sigma_{r,y};# hits",100,-norResXAbsMax,norResXAbsMax);
       i_sector.second.ProbY   = secDir.make<TH1F>("h_ProbY","residual probability;prob(r_{y}^{2}/#sigma_{r,y}^{2},1);# hits",60,probXMin,probXMax);
       
       i_sector.second.PhiSensYVsBarycentreY = secDir.make<TH2F>("h2_phiSensYVsBarycentreY","#phi_{module,y} vs. b_{cl,y};b_{cl,y}  [# channels];#phi_{module,y}  [ ^{o}]",200,-10.,790.,93,-93,93);
       i_sector.second.PPhiSensYVsBarycentreY = secDir.make<TProfile>("p_phiSensYVsBarycentreY","#phi_{module,y} vs. b_{cl,y};b_{cl,y}  [# channels];#phi_{module,y}  [ ^{o}]",200,-10.,790.);
     }
     
     
     // Track Parameters
     i_sector.second.m_correlationHistsX["HitsValid"] = i_sector.second.bookCorrHistsX("HitsValid","# hits","[valid]",50,0,50,"npt");
     i_sector.second.m_correlationHistsX["HitsInvalid"] = i_sector.second.bookCorrHistsX("HitsInvalid","# hits","[invalid]",20,0,20,"npt");
     i_sector.second.m_correlationHistsX["Hits2D"] = i_sector.second.bookCorrHistsX("Hits2D","# hits","[2D]",20,0,20,"npt");
     i_sector.second.m_correlationHistsX["LayersMissed"] = i_sector.second.bookCorrHistsX("LayersMissed","# layers","[missed]",10,0,10,"npt");
     i_sector.second.m_correlationHistsX["HitsPixel"] = i_sector.second.bookCorrHistsX("HitsPixel","# hits","[pixel]",10,0,10,"npt");
     i_sector.second.m_correlationHistsX["HitsStrip"] = i_sector.second.bookCorrHistsX("HitsStrip","# hits","[strip]",40,0,40,"npt");
     i_sector.second.m_correlationHistsX["HitsGood"] = i_sector.second.bookCorrHistsX("HitsGood","# hits","[good]",50,0,50,"npt");
     i_sector.second.m_correlationHistsX["NorChi2"] = i_sector.second.bookCorrHistsX("NorChi2","#chi^{2}/f","",50,0,norChi2Max,"npr");
     i_sector.second.m_correlationHistsX["Theta"] = i_sector.second.bookCorrHistsX("Theta","#theta","[ ^{o}]",40,-10,190,"npt");
     i_sector.second.m_correlationHistsX["Phi"] = i_sector.second.bookCorrHistsX("Phi","#phi","[ ^{o}]",76,-190,190,"npt");
     i_sector.second.m_correlationHistsX["D0Beamspot"] = i_sector.second.bookCorrHistsX("D0Beamspot","d_{0, BS}","[cm]",40,-d0Max,d0Max,"npt");
     i_sector.second.m_correlationHistsX["Dz"] = i_sector.second.bookCorrHistsX("Dz","d_{z}","[cm]",40,-dzMax,dzMax,"npt");
     i_sector.second.m_correlationHistsX["Pt"] = i_sector.second.bookCorrHistsX("Pt","p_{t}","[GeV]",50,0,pMax,"npt");
     i_sector.second.m_correlationHistsX["P"] = i_sector.second.bookCorrHistsX("P","|p|","[GeV]",50,0,pMax,"npt");
     i_sector.second.m_correlationHistsX["InvP"] = i_sector.second.bookCorrHistsX("InvP","1/|p|","[GeV^{-1}]",25,0,invPMax,"t");
     i_sector.second.m_correlationHistsX["MeanAngle"] = i_sector.second.bookCorrHistsX("MeanAngle","<#phi_{module}>","[ ^{o}]",25,-5,95,"npt");
     //i_sector.second.m_correlationHistsX[""] = i_sector.second.bookCorrHistsX("","","",,,,"nphtr");
     
     if(pixelSector){
       i_sector.second.m_correlationHistsY["HitsValid"] = i_sector.second.bookCorrHistsY("HitsValid","# hits","[valid]",50,0,50,"npt");
       i_sector.second.m_correlationHistsY["HitsInvalid"] = i_sector.second.bookCorrHistsY("HitsInvalid","# hits","[invalid]",20,0,20,"npt");
       i_sector.second.m_correlationHistsY["Hits2D"] = i_sector.second.bookCorrHistsY("Hits2D","# hits","[2D]",20,0,20,"npt");
       i_sector.second.m_correlationHistsY["LayersMissed"] = i_sector.second.bookCorrHistsY("LayersMissed","# layers","[missed]",10,0,10,"npt");
       i_sector.second.m_correlationHistsY["HitsPixel"] = i_sector.second.bookCorrHistsY("HitsPixel","# hits","[pixel]",10,0,10,"npt");
       i_sector.second.m_correlationHistsY["HitsStrip"] = i_sector.second.bookCorrHistsY("HitsStrip","# hits","[strip]",40,0,40,"npt");
       i_sector.second.m_correlationHistsY["HitsGood"] = i_sector.second.bookCorrHistsY("HitsGood","# hits","[good]",50,0,50,"npt");
       i_sector.second.m_correlationHistsY["NorChi2"] = i_sector.second.bookCorrHistsY("NorChi2","#chi^{2}/f","",50,0,norChi2Max,"npr");
       i_sector.second.m_correlationHistsY["Theta"] = i_sector.second.bookCorrHistsY("Theta","#theta","[ ^{o}]",40,-10,190,"npt");
       i_sector.second.m_correlationHistsY["Phi"] = i_sector.second.bookCorrHistsY("Phi","#phi","[ ^{o}]",76,-190,190,"npt");
       i_sector.second.m_correlationHistsY["D0Beamspot"] = i_sector.second.bookCorrHistsY("D0Beamspot","d_{0, BS}","[cm]",40,-d0Max,d0Max,"npt");
       i_sector.second.m_correlationHistsY["Dz"] = i_sector.second.bookCorrHistsY("Dz","d_{z}","[cm]",40,-dzMax,dzMax,"npt");
       i_sector.second.m_correlationHistsY["Pt"] = i_sector.second.bookCorrHistsY("Pt","p_{t}","[GeV]",50,0,pMax,"npt");
       i_sector.second.m_correlationHistsY["P"] = i_sector.second.bookCorrHistsY("P","|p|","[GeV]",50,0,pMax,"npt");
       i_sector.second.m_correlationHistsY["InvP"] = i_sector.second.bookCorrHistsY("InvP","1/|p|","[GeV^{-1}]",25,0,invPMax,"t");
       i_sector.second.m_correlationHistsY["MeanAngle"] = i_sector.second.bookCorrHistsY("MeanAngle","<#phi_{module}>","[ ^{o}]",25,-5,95,"npt");
     }
     
     
     // (transform errors and residuals from [cm] in [mum])
     for(auto const & i_errHists : v_errHists){
       double xMin(0.01*(i_errHists-1)), xMax(0.01*(i_errHists));
       std::stringstream sigmaXHit, sigmaXTrk, sigmaX;
       sigmaXHit << "h_sigmaXHit_" << i_errHists;
       sigmaXTrk << "h_sigmaXTrk_" << i_errHists;
       sigmaX    << "h_sigmaX_"    << i_errHists;
       i_sector.second.m_sigmaX["sigmaXHit"].push_back(secDir.make<TH1F>(sigmaXHit.str().c_str(),"hit error #sigma_{hit,x};#sigma_{hit,x}  [#mum];# hits",100,xMin*10000.,xMax*10000.));
       i_sector.second.m_sigmaX["sigmaXTrk"].push_back(secDir.make<TH1F>(sigmaXTrk.str().c_str(),"track error #sigma_{trk,x};#sigma_{trk,x}  [#mum];# hits",100,xMin*10000.,xMax*10000.));
       i_sector.second.m_sigmaX["sigmaX"   ].push_back(secDir.make<TH1F>(sigmaX.str().c_str(),"residual error #sigma_{r,x};#sigma_{r,x}  [#mum];# hits",100,xMin*10000.,xMax*10000.));
       if(pixelSector){
         std::stringstream sigmaYHit, sigmaYTrk, sigmaY;
         sigmaYHit << "h_sigmaYHit_" << i_errHists;
         sigmaYTrk << "h_sigmaYTrk_" << i_errHists;
         sigmaY    << "h_sigmaY_"    << i_errHists;
         i_sector.second.m_sigmaY["sigmaYHit"].push_back(secDir.make<TH1F>(sigmaYHit.str().c_str(),"hit error #sigma_{hit,y};#sigma_{hit,y}  [#mum];# hits",100,xMin*10000.,xMax*10000.));
         i_sector.second.m_sigmaY["sigmaYTrk"].push_back(secDir.make<TH1F>(sigmaYTrk.str().c_str(),"track error #sigma_{trk,y};#sigma_{trk,y}  [#mum];# hits",100,xMin*10000.,xMax*10000.));
         i_sector.second.m_sigmaY["sigmaY"   ].push_back(secDir.make<TH1F>(sigmaY.str().c_str(),"residual error #sigma_{r,y};#sigma_{r,y}  [#mum];# hits",100,xMin*10000.,xMax*10000.));
       }
     }
     
   }
 }

void ApeEstimator::bookSectorHistsForApeCalculation ( )

private

Definition at line 799 of file ApeEstimator.cc.

References edm::errors::Configuration, Exception, fileService, edm::ParameterSet::getParameter(), m_resErrBins_, m_tkSector_, TFileDirectory::make(), TFileService::mkdir(), TFileDirectory::mkdir(), and parameterSet_.

Referenced by beginJob().

                                               {
   std::vector<unsigned int> v_errHists(parameterSet_.getParameter<std::vector<unsigned int> >("vErrHists"));
   for(std::vector<unsigned int>::iterator i_errHists = v_errHists.begin(); i_errHists != v_errHists.end(); ++i_errHists){
     for(std::vector<unsigned int>::iterator i_errHists2 = i_errHists; i_errHists2 != v_errHists.end();){
       ++i_errHists2;
       if(*i_errHists==*i_errHists2){
         edm::LogError("BookSectorHists")<<"Value of vErrHists in config exists twice: "<<*i_errHists<<"\n... delete one of both";
         v_errHists.erase(i_errHists2);
       }
     }
   }
   
   for(auto &i_sector : m_tkSector_){
     edm::Service<TFileService> fileService;
     if(!fileService){
       throw edm::Exception( edm::errors::Configuration,
                             "TFileService is not registered in cfg file" );
     }
     
     std::stringstream sector; sector << "Sector_" << i_sector.first;
     TFileDirectory secDir = fileService->mkdir(sector.str());
     
     // Dummy histo containing the sector name as title
     i_sector.second.Name = secDir.make<TH1F>("z_name",i_sector.second.name.c_str(),1,0,1);
     
     // Do not book histos for empty sectors
     if(i_sector.second.v_rawId.empty()){
       continue;
     }
     
     
     // Distributions in each interval (stay in [cm], to have all calculations in [cm])
     if(m_resErrBins_.empty()){ // default if no selection taken into account: calculate APE with one bin with residual error 0-100um
       m_resErrBins_[1].first = 0.;
       m_resErrBins_[1].second = 0.01;
     } 
     for(auto const & i_errBins : m_resErrBins_){
       std::stringstream interval; interval << "Interval_" << i_errBins.first;
       TFileDirectory intDir = secDir.mkdir(interval.str());
       i_sector.second.m_binnedHists[i_errBins.first]["sigmaX"]  = intDir.make<TH1F>("h_sigmaX","residual resolution #sigma_{x};#sigma_{x}  [cm];# hits",100,0.,0.01);
       i_sector.second.m_binnedHists[i_errBins.first]["norResX"] = intDir.make<TH1F>("h_norResX","normalized residual r_{x}/#sigma_{r,x};(x_{trk}-x_{hit})/#sigma_{r,x};# hits",100,-10,10);
       if(i_sector.second.isPixel){
         i_sector.second.m_binnedHists[i_errBins.first]["sigmaY"]  = intDir.make<TH1F>("h_sigmaY","residual resolution #sigma_{y};#sigma_{y}  [cm];# hits",100,0.,0.01);
         i_sector.second.m_binnedHists[i_errBins.first]["norResY"] = intDir.make<TH1F>("h_norResY","normalized residual r_{y}/#sigma_{r,y};(y_{trk}-y_{hit})/#sigma_{r,y};# hits",100,-10,10);
       }
     }
     
     
     TFileDirectory resDir = secDir.mkdir("Results");
     
     // TTree containing rawIds of all modules in sector
     unsigned int rawId(0);
     i_sector.second.RawId = resDir.make<TTree>("rawIdTree","Tree containing rawIds of all modules in sector");
     i_sector.second.RawId->Branch("RawId", &rawId, "RawId/i");
     for(auto const & i_rawId : i_sector.second.v_rawId){
       rawId = i_rawId;
       i_sector.second.RawId->Fill();
     }
     
     // Result plots (one hist per sector containing one bin per interval)
     // (transform errors and residuals from [cm] in [mum])
     std::vector<double> v_binX(parameterSet_.getParameter<std::vector<double> >("residualErrorBinning"));
     for(auto & i_binX : v_binX){
       i_binX *= 10000.;
     }
     i_sector.second.EntriesX = resDir.make<TH1F>("h_entriesX","# hits used;#sigma_{x}  [#mum];# hits",v_binX.size()-1,&(v_binX[0]));
     if(i_sector.second.isPixel){
       i_sector.second.EntriesY = resDir.make<TH1F>("h_entriesY","# hits used;#sigma_{y}  [#mum];# hits",v_binX.size()-1,&(v_binX[0]));
     }
     
     // In fact these are un-needed Analyzer plots, but I want to have them always for every sector visible
     // (transform errors and residuals from [cm] in [mum])
     i_sector.second.ResX    = resDir.make<TH1F>("h_ResX","residual r_{x};x_{trk}-x_{hit}  [#mum];# hits",100,-0.03*10000.,0.03*10000.);
     i_sector.second.NorResX = resDir.make<TH1F>("h_NorResX","normalized residual r_{x}/#sigma_{r,x};(x_{trk}-x_{hit})/#sigma_{r,x};# hits",100,-5.,5.);
     if(i_sector.second.isPixel){
       i_sector.second.ResY    = resDir.make<TH1F>("h_ResY","residual r_{y};y_{trk}-y_{hit}  [#mum];# hits",100,-0.03*10000.,0.03*10000.);
       i_sector.second.NorResY = resDir.make<TH1F>("h_NorResY","normalized residual r_{y}/#sigma_{r,y};(y_{trk}-y_{hit})/#sigma_{r,y};# hits",100,-5.,5.);
     }
   }
 }

void ApeEstimator::bookTrackHists ( )

private

Definition at line 884 of file ApeEstimator.cc.

Referenced by beginJob().

                             {
   bool zoomHists(parameterSet_.getParameter<bool>("zoomHists"));
   
   int trackSizeBins = zoomHists ? 6 : 201;
   double trackSizeMax = trackSizeBins -1;
   
   double chi2Max = zoomHists ? 100. : 2000.;
   double norChi2Max = zoomHists ? 5. : 1000.;
   double d0max = zoomHists ? 0.02 : 40.;  // cosmics: 100.|100.
   double dzmax = zoomHists ? 15. : 100.;  // cosmics: 200.|600.
   double pMax = zoomHists ? 200. : 2000.;
   
   edm::Service<TFileService> fileService;
   TFileDirectory evtDir = fileService->mkdir("EventVariables");
   tkDetector_.TrkSize     = evtDir.make<TH1F>("h_trackSize","# tracks  [all];# tracks;# events",trackSizeBins,-1,trackSizeMax);
   tkDetector_.TrkSizeGood = evtDir.make<TH1F>("h_trackSizeGood","# tracks  [good];# tracks;# events",trackSizeBins,-1,trackSizeMax);
   TFileDirectory trkDir = fileService->mkdir("TrackVariables");
   tkDetector_.HitsSize      = trkDir.make<TH1F>("h_hitsSize","# hits;# hits;# tracks",51,-1,50);
   tkDetector_.HitsValid     = trkDir.make<TH1F>("h_hitsValid","# hits  [valid];# hits  [valid];# tracks",51,-1,50);
   tkDetector_.HitsInvalid   = trkDir.make<TH1F>("h_hitsInvalid","# hits  [invalid];# hits  [invalid];# tracks",21,-1,20);
   tkDetector_.Hits2D        = trkDir.make<TH1F>("h_hits2D","# hits  [2D];# hits  [2D];# tracks",21,-1,20);
   tkDetector_.LayersMissed  = trkDir.make<TH1F>("h_layersMissed","# layers  [missed];# layers  [missed];# tracks",11,-1,10);
   tkDetector_.HitsPixel     = trkDir.make<TH1F>("h_hitsPixel","# hits  [pixel];# hits  [pixel];# tracks",11,-1,10);
   tkDetector_.HitsStrip     = trkDir.make<TH1F>("h_hitsStrip","# hits  [strip];# hits  [strip];# tracks",41,-1,40);
   tkDetector_.Charge        = trkDir.make<TH1F>("h_charge","charge q;q  [e];# tracks",5,-2,3);
   tkDetector_.Chi2          = trkDir.make<TH1F>("h_chi2"," #chi^{2};#chi^{2};# tracks",100,0,chi2Max);
   tkDetector_.Ndof          = trkDir.make<TH1F>("h_ndof","# degrees of freedom f;f;# tracks",101,-1,100);
   tkDetector_.NorChi2       = trkDir.make<TH1F>("h_norChi2","normalized #chi^{2};#chi^{2}/f;# tracks",200,0,norChi2Max);
   tkDetector_.Prob          = trkDir.make<TH1F>("h_prob"," #chi^{2} probability;prob(#chi^{2},f);# tracks",50,0,1);
   tkDetector_.Eta           = trkDir.make<TH1F>("h_eta","pseudorapidity #eta;#eta;# tracks",100,-5,5);
   tkDetector_.EtaErr        = trkDir.make<TH1F>("h_etaErr","Error of #eta;#sigma(#eta);# tracks",100,0,0.001);
   tkDetector_.EtaSig        = trkDir.make<TH1F>("h_etaSig","Significance of #eta;#eta/#sigma(#eta);# tracks",100,-20000,20000);
   tkDetector_.Theta         = trkDir.make<TH1F>("h_theta","polar angle #theta;#theta  [ ^{o}];# tracks",100,-10,190);
   tkDetector_.Phi           = trkDir.make<TH1F>("h_phi","azimuth angle #phi;#phi  [ ^{o}];# tracks",190,-190,190);
   tkDetector_.PhiErr        = trkDir.make<TH1F>("h_phiErr","Error of #phi;#sigma(#phi)  [ ^{o}];# tracks",100,0,0.04);
   tkDetector_.PhiSig        = trkDir.make<TH1F>("h_phiSig","Significance of #phi;#phi/#sigma(#phi)  [ ^{o}];# tracks",100,-50000,50000);
   tkDetector_.D0Beamspot    = trkDir.make<TH1F>("h_d0Beamspot","Closest approach d_{0} wrt. beamspot;d_{0, BS}  [cm];# tracks",200,-d0max,d0max);
   tkDetector_.D0BeamspotErr = trkDir.make<TH1F>("h_d0BeamspotErr","Error of d_{0, BS};#sigma(d_{0, BS})  [cm];# tracks",200,0,0.01);
   tkDetector_.D0BeamspotSig = trkDir.make<TH1F>("h_d0BeamspotSig","Significance of d_{0, BS};d_{0, BS}/#sigma(d_{0, BS});# tracks",100,-5,5);
   tkDetector_.Dz            = trkDir.make<TH1F>("h_dz","Closest approach d_{z};d_{z}  [cm];# tracks",200,-dzmax,dzmax);
   tkDetector_.DzErr         = trkDir.make<TH1F>("h_dzErr","Error of d_{z};#sigma(d_{z})  [cm];# tracks",200,0,0.01);
   tkDetector_.DzSig         = trkDir.make<TH1F>("h_dzSig","Significance of d_{z};d_{z}/#sigma(d_{z});# tracks",100,-10000,10000);
   tkDetector_.Pt      = trkDir.make<TH1F>("h_pt","transverse momentum p_{t};p_{t}  [GeV];# tracks",100,0,pMax);
   tkDetector_.PtErr         = trkDir.make<TH1F>("h_ptErr","Error of p_{t};#sigma(p_{t})  [GeV];# tracks",100,0,1.6);
   tkDetector_.PtSig         = trkDir.make<TH1F>("h_ptSig","Significance of p_{t};p_{t}/#sigma(p_{t});# tracks",100,0,200);
   tkDetector_.P             = trkDir.make<TH1F>("h_p","momentum magnitude |p|;|p|  [GeV];# tracks",100,0,pMax);
   tkDetector_.MeanAngle     = trkDir.make<TH1F>("h_meanAngle","mean angle on module <#phi_{module}>;<#phi_{module}>  [ ^{o}];# tracks",100,-5,95);
   tkDetector_.HitsGood      = trkDir.make<TH1F>("h_hitsGood","# hits  [good];# hits  [good];# tracks",51,-1,50);
   
   tkDetector_.MeanAngleVsHits     = trkDir.make<TH2F>("h2_meanAngleVsHits","<#phi_{module}> vs. # hits;# hits;<#phi_{module}>  [ ^{o}]",51,-1,50,50,-5,95);
   tkDetector_.HitsGoodVsHitsValid = trkDir.make<TH2F>("h2_hitsGoodVsHitsValid","# hits  [good] vs. # hits  [valid];# hits  [valid];# hits  [good]",51,-1,50,51,-1,50);
   tkDetector_.HitsPixelVsEta      = trkDir.make<TH2F>("h2_hitsPixelVsEta","# hits  [pixel] vs. #eta;#eta;# hits  [pixel]",60,-3,3,11,-1,10);
   tkDetector_.HitsPixelVsTheta    = trkDir.make<TH2F>("h2_hitsPixelVsTheta","# hits  [pixel] vs. #theta;#theta;# hits  [pixel]",100,-10,190,11,-1,10);
   tkDetector_.HitsStripVsEta      = trkDir.make<TH2F>("h2_hitsStripVsEta","# hits  [strip] vs. #eta;#eta;# hits  [strip]",60,-3,3,31,-1,40);
   tkDetector_.HitsStripVsTheta    = trkDir.make<TH2F>("h2_hitsStripVsTheta","# hits  [strip] vs. #theta;#theta;# hits  [strip]",100,-10,190,31,-1,40);
   tkDetector_.PtVsEta             = trkDir.make<TH2F>("h2_ptVsEta","p_{t} vs. #eta;#eta;p_{t}  [GeV]",60,-3,3,100,0,pMax);
   tkDetector_.PtVsTheta           = trkDir.make<TH2F>("h2_ptVsTheta","p_{t} vs. #theta;#theta;p_{t}  [GeV]",100,-10,190,100,0,pMax);
   
   tkDetector_.PMeanAngleVsHits     = trkDir.make<TProfile>("p_meanAngleVsHits","<#phi_{module}> vs. # hits;# hits;<#phi_{module}>  [ ^{o}]",51,-1,50);
   tkDetector_.PHitsGoodVsHitsValid = trkDir.make<TProfile>("p_hitsGoodVsHitsValid","# hits  [good] vs. # hits  [valid];# hits  [valid];# hits  [good]",51,-1,50);
   tkDetector_.PHitsPixelVsEta      = trkDir.make<TProfile>("p_hitsPixelVsEta","# hits  [pixel] vs. #eta;#eta;# hits  [pixel]",60,-3,3);
   tkDetector_.PHitsPixelVsTheta    = trkDir.make<TProfile>("p_hitsPixelVsTheta","# hits  [pixel] vs. #theta;#theta;# hits  [pixel]",100,-10,190);
   tkDetector_.PHitsStripVsEta      = trkDir.make<TProfile>("p_hitsStripVsEta","# hits  [strip] vs. #eta;#eta;# hits  [strip]",60,-3,3);
   tkDetector_.PHitsStripVsTheta    = trkDir.make<TProfile>("p_hitsStripVsTheta","# hits  [strip] vs. #theta;#theta;# hits  [strip]",100,-10,190);
   tkDetector_.PPtVsEta             = trkDir.make<TProfile>("p_ptVsEta","p_{t} vs. #eta;#eta;p_{t}  [GeV]",60,-3,3);
   tkDetector_.PPtVsTheta           = trkDir.make<TProfile>("p_ptVsTheta","p_{t} vs. #theta;#theta;p_{t}  [GeV]",100,-10,190);
 }

void ApeEstimator::calculateAPE ( )

private

Definition at line 2101 of file ApeEstimator.cc.

References m_tkSector_.

Referenced by endJob().

                           {
   // Loop over sectors for calculating APE
   for(auto & i_sector : m_tkSector_){    
      
      // Loop over residual error bins to calculate APE for every bin
     for(auto const & i_errBins : i_sector.second.m_binnedHists){
       std::map<std::string,TH1*> m_Hists = i_errBins.second;
        
        // Fitting Parameters
       double integralX = m_Hists["norResX"]->Integral();
       i_sector.second.EntriesX->SetBinContent(i_errBins.first, integralX);
       
       if(i_sector.second.isPixel){
         double integralY = m_Hists["norResY"]->Integral();
         i_sector.second.EntriesY->SetBinContent(i_errBins.first, integralY);
       }
     }
   }
 }

bool ApeEstimator::checkIntervalsForSectors	(	const unsigned int	sectorCounter,
		const std::vector< double > &	v_id
	)		const

private

Definition at line 431 of file ApeEstimator.cc.

References mps_splice::entry.

Referenced by sectorBuilder().

 {
     
   if(v_id.empty())return true;
   if(v_id.size()%2==1){
     edm::LogError("SectorBuilder")<<"Incorrect Sector Definition: Position Vectors need even number of arguments (Intervals)"
                                      <<"\n... sector selection is not applied, sector "<<sectorCounter<<" is not built";
     return false;
   }
   int entry(0); double intervalBegin(999.);
   for(auto const & i_id : v_id){
     ++entry;
     if(entry%2==1) intervalBegin = i_id;
     if(entry%2==0 && intervalBegin > i_id){
       edm::LogError("SectorBuilder")<<"Incorrect Sector Definition (Position Vector Intervals): \t"
                                     <<intervalBegin<<" is bigger than "<<i_id<<" but is expected to be smaller"
                                     <<"\n... sector selection is not applied, sector "<<sectorCounter<<" is not built";
       return false;
     }
   }
   return true;
 }

bool ApeEstimator::checkModuleBools	(	const bool	id,
		const std::vector< unsigned int > &	v_id
	)		const

private

Definition at line 466 of file ApeEstimator.cc.

Referenced by sectorBuilder().

 {
     
   if(v_id.empty())return true;
   for(auto const & i_id : v_id){
     if(1==i_id && id)return true;
     if(2==i_id && !id)return true;
   }
   return false;
 }

bool ApeEstimator::checkModuleDirections	(	const int	id,
		const std::vector< int > &	v_id
	)		const

private

Definition at line 478 of file ApeEstimator.cc.

Referenced by sectorBuilder().

 {
     
   if(v_id.empty())return true;
   for(auto const & i_id : v_id){
     if(id==i_id)return true;
   }
   return false;
 }

bool ApeEstimator::checkModuleIds	(	const unsigned int	id,
		const std::vector< unsigned int > &	v_id
	)		const

private

Definition at line 455 of file ApeEstimator.cc.

Referenced by sectorBuilder().

 {
     
   if(v_id.empty())return true;
   for(auto const & i_id : v_id){
     if(id==i_id)return true;
   }
   return false;
 }

bool ApeEstimator::checkModulePositions	(	const float	id,
		const std::vector< double > &	v_id
	)		const

private

Definition at line 489 of file ApeEstimator.cc.

References mps_splice::entry.

Referenced by sectorBuilder().

 {
     
   if(v_id.empty())return true;
   int entry(0); double intervalBegin(999.);
   for(auto const & i_id : v_id){
     ++entry;
     if(entry%2==1)intervalBegin = i_id;
     if(entry%2==0 && id>=intervalBegin && id<i_id)return true;
   }
   return false;
 }

void ApeEstimator::endJob ( )

overrideprivatevirtual

Reimplemented from edm::one::EDAnalyzerBase.

Definition at line 2253 of file ApeEstimator.cc.

References calculateAPE(), calculateApe_, counter1, and DEFINE_FWK_MODULE.

Referenced by o2olib.O2ORunMgr::executeJob().

                      {
    if(calculateApe_)this->calculateAPE();
    
    edm::LogInfo("HitSelector")<<"\nThere are "<<counter1<< " negative Errors calculated\n";
 }

void ApeEstimator::fillHistsForAnalyzerMode ( const TrackStruct & trackStruct )

private

Definition at line 1773 of file ApeEstimator.cc.

Referenced by analyze().

                                                                     { 
   unsigned int goodHitsPerTrack(trackStruct.v_hitParams.size());
   tkDetector_.HitsGood->Fill(goodHitsPerTrack);
   tkDetector_.HitsGoodVsHitsValid->Fill(trackStruct.trkParams.hitsValid,goodHitsPerTrack);
   tkDetector_.PHitsGoodVsHitsValid->Fill(trackStruct.trkParams.hitsValid,goodHitsPerTrack);
   
   if(parameterSet_.getParameter<bool>("applyTrackCuts")){
     // which tracks to take? need min. nr. of selected hits?
     if(goodHitsPerTrack < minGoodHitsPerTrack_)return;
   }
   
   tkDetector_.HitsSize     ->Fill(trackStruct.trkParams.hitsSize);
   tkDetector_.HitsValid    ->Fill(trackStruct.trkParams.hitsValid);
   tkDetector_.HitsInvalid  ->Fill(trackStruct.trkParams.hitsInvalid);
   tkDetector_.Hits2D       ->Fill(trackStruct.trkParams.hits2D);
   tkDetector_.LayersMissed ->Fill(trackStruct.trkParams.layersMissed);
   tkDetector_.HitsPixel    ->Fill(trackStruct.trkParams.hitsPixel);
   tkDetector_.HitsStrip    ->Fill(trackStruct.trkParams.hitsStrip);
   tkDetector_.Charge       ->Fill(trackStruct.trkParams.charge);
   tkDetector_.Chi2         ->Fill(trackStruct.trkParams.chi2);
   tkDetector_.Ndof         ->Fill(trackStruct.trkParams.ndof);
   tkDetector_.NorChi2      ->Fill(trackStruct.trkParams.norChi2);
   tkDetector_.Prob         ->Fill(trackStruct.trkParams.prob);
   tkDetector_.Eta          ->Fill(trackStruct.trkParams.eta);
   tkDetector_.EtaErr       ->Fill(trackStruct.trkParams.etaErr);
   tkDetector_.EtaSig       ->Fill(trackStruct.trkParams.eta/trackStruct.trkParams.etaErr);
   tkDetector_.Theta        ->Fill(trackStruct.trkParams.theta*180./M_PI);
   tkDetector_.Phi          ->Fill(trackStruct.trkParams.phi*180./M_PI);
   tkDetector_.PhiErr       ->Fill(trackStruct.trkParams.phiErr*180./M_PI);
   tkDetector_.PhiSig       ->Fill(trackStruct.trkParams.phi/trackStruct.trkParams.phiErr);
   tkDetector_.D0Beamspot   ->Fill(trackStruct.trkParams.d0Beamspot);
   tkDetector_.D0BeamspotErr->Fill(trackStruct.trkParams.d0BeamspotErr);
   tkDetector_.D0BeamspotSig->Fill(trackStruct.trkParams.d0Beamspot/trackStruct.trkParams.d0BeamspotErr);
   tkDetector_.Dz           ->Fill(trackStruct.trkParams.dz);
   tkDetector_.DzErr        ->Fill(trackStruct.trkParams.dzErr);
   tkDetector_.DzSig        ->Fill(trackStruct.trkParams.dz/trackStruct.trkParams.dzErr);
   tkDetector_.P            ->Fill(trackStruct.trkParams.p);
   tkDetector_.Pt           ->Fill(trackStruct.trkParams.pt);
   tkDetector_.PtErr        ->Fill(trackStruct.trkParams.ptErr);
   tkDetector_.PtSig        ->Fill(trackStruct.trkParams.pt/trackStruct.trkParams.ptErr);
   tkDetector_.MeanAngle    ->Fill(trackStruct.trkParams.meanPhiSensToNorm*180./M_PI);
   
   tkDetector_.MeanAngleVsHits ->Fill(trackStruct.trkParams.hitsSize,trackStruct.trkParams.meanPhiSensToNorm*180./M_PI);
   tkDetector_.HitsPixelVsEta  ->Fill(trackStruct.trkParams.eta,trackStruct.trkParams.hitsPixel);
   tkDetector_.HitsPixelVsTheta->Fill(trackStruct.trkParams.theta*180./M_PI,trackStruct.trkParams.hitsPixel);
   tkDetector_.HitsStripVsEta  ->Fill(trackStruct.trkParams.eta,trackStruct.trkParams.hitsStrip);
   tkDetector_.HitsStripVsTheta->Fill(trackStruct.trkParams.theta*180./M_PI,trackStruct.trkParams.hitsStrip);
   tkDetector_.PtVsEta       ->Fill(trackStruct.trkParams.eta,trackStruct.trkParams.pt);
   tkDetector_.PtVsTheta       ->Fill(trackStruct.trkParams.theta*180./M_PI,trackStruct.trkParams.pt);
   
   tkDetector_.PMeanAngleVsHits ->Fill(trackStruct.trkParams.hitsSize,trackStruct.trkParams.meanPhiSensToNorm*180./M_PI);
   tkDetector_.PHitsPixelVsEta  ->Fill(trackStruct.trkParams.eta,trackStruct.trkParams.hitsPixel);
   tkDetector_.PHitsPixelVsTheta->Fill(trackStruct.trkParams.theta*180./M_PI,trackStruct.trkParams.hitsPixel);
   tkDetector_.PHitsStripVsEta  ->Fill(trackStruct.trkParams.eta,trackStruct.trkParams.hitsStrip);
   tkDetector_.PHitsStripVsTheta->Fill(trackStruct.trkParams.theta*180./M_PI,trackStruct.trkParams.hitsStrip);
   tkDetector_.PPtVsEta         ->Fill(trackStruct.trkParams.eta,trackStruct.trkParams.pt);
   tkDetector_.PPtVsTheta       ->Fill(trackStruct.trkParams.theta*180./M_PI,trackStruct.trkParams.pt);
   
   
   for(auto & i_hit : trackStruct.v_hitParams){
     const TrackStruct::HitParameterStruct& hit(i_hit);
     //Put here from earlier method
     if(hit.hitState == TrackStruct::notAssignedToSectors)continue;
     
     for(auto & i_sector : m_tkSector_){
       bool moduleInSector(false);
       for(auto const & i_hitSector : hit.v_sector){
         if(i_sector.first == i_hitSector){
           moduleInSector = true; 
           break;
         }
       }
       if(!moduleInSector)continue;
       TrackerSectorStruct& sector(i_sector.second);
       
       if(hit.goodXMeasurement){
         std::map<std::string,TrackerSectorStruct::CorrelationHists>& m_corrHists(sector.m_correlationHistsX);
   
         // Cluster and Hit Parameters
         this->fillHitHistsXForAnalyzerMode(hit, sector);
         
         // Track Parameters
         m_corrHists["HitsValid"].fillCorrHistsX(hit,trackStruct.trkParams.hitsValid);
         m_corrHists["HitsGood"].fillCorrHistsX(hit,goodHitsPerTrack);
         m_corrHists["HitsInvalid"].fillCorrHistsX(hit,trackStruct.trkParams.hitsInvalid);
         m_corrHists["Hits2D"].fillCorrHistsX(hit,trackStruct.trkParams.hits2D);
         m_corrHists["LayersMissed"].fillCorrHistsX(hit,trackStruct.trkParams.layersMissed);
         m_corrHists["HitsPixel"].fillCorrHistsX(hit,trackStruct.trkParams.hitsPixel);
         m_corrHists["HitsStrip"].fillCorrHistsX(hit,trackStruct.trkParams.hitsStrip);
         m_corrHists["NorChi2"].fillCorrHistsX(hit,trackStruct.trkParams.norChi2);
         m_corrHists["Theta"].fillCorrHistsX(hit,trackStruct.trkParams.theta*180./M_PI);
         m_corrHists["Phi"].fillCorrHistsX(hit,trackStruct.trkParams.phi*180./M_PI);
         m_corrHists["D0Beamspot"].fillCorrHistsX(hit,trackStruct.trkParams.d0Beamspot);
         m_corrHists["Dz"].fillCorrHistsX(hit,trackStruct.trkParams.dz);
         m_corrHists["Pt"].fillCorrHistsX(hit,trackStruct.trkParams.pt);
         m_corrHists["P"].fillCorrHistsX(hit,trackStruct.trkParams.p);
         m_corrHists["InvP"].fillCorrHistsX(hit,1./trackStruct.trkParams.p);
         m_corrHists["MeanAngle"].fillCorrHistsX(hit,trackStruct.trkParams.meanPhiSensToNorm*180./M_PI);
       }
             
       if(hit.goodYMeasurement){
         std::map<std::string,TrackerSectorStruct::CorrelationHists>& m_corrHists(sector.m_correlationHistsY);
   
         // Cluster and Hit Parameters
         this->fillHitHistsYForAnalyzerMode(hit, sector);
   
         // Track Parameters
         m_corrHists["HitsValid"].fillCorrHistsY(hit,trackStruct.trkParams.hitsValid);
         m_corrHists["HitsGood"].fillCorrHistsY(hit,goodHitsPerTrack);
         m_corrHists["HitsInvalid"].fillCorrHistsY(hit,trackStruct.trkParams.hitsInvalid);
         m_corrHists["Hits2D"].fillCorrHistsY(hit,trackStruct.trkParams.hits2D);
         m_corrHists["LayersMissed"].fillCorrHistsY(hit,trackStruct.trkParams.layersMissed);
         m_corrHists["HitsPixel"].fillCorrHistsY(hit,trackStruct.trkParams.hitsPixel);
         m_corrHists["HitsStrip"].fillCorrHistsY(hit,trackStruct.trkParams.hitsStrip);
         m_corrHists["NorChi2"].fillCorrHistsY(hit,trackStruct.trkParams.norChi2);
         m_corrHists["Theta"].fillCorrHistsY(hit,trackStruct.trkParams.theta*180./M_PI);
         m_corrHists["Phi"].fillCorrHistsY(hit,trackStruct.trkParams.phi*180./M_PI);
         m_corrHists["D0Beamspot"].fillCorrHistsY(hit,trackStruct.trkParams.d0Beamspot);
         m_corrHists["Dz"].fillCorrHistsY(hit,trackStruct.trkParams.dz);
         m_corrHists["Pt"].fillCorrHistsY(hit,trackStruct.trkParams.pt);
         m_corrHists["P"].fillCorrHistsY(hit,trackStruct.trkParams.p);
         m_corrHists["InvP"].fillCorrHistsY(hit,1./trackStruct.trkParams.p);
         m_corrHists["MeanAngle"].fillCorrHistsY(hit,trackStruct.trkParams.meanPhiSensToNorm*180./M_PI);
       }
       
       // Special Histograms 
       for(auto & i_sigmaX : sector.m_sigmaX){
         for(auto & iHist : i_sigmaX.second){
           if     (i_sigmaX.first=="sigmaXHit") iHist->Fill(hit.errXHit*10000.);
           else if(i_sigmaX.first=="sigmaXTrk") iHist->Fill(hit.errXTrk*10000.);
           else if(i_sigmaX.first=="sigmaX")    iHist->Fill(hit.errX*10000.);
         }
       }
       for(auto & i_sigmaY : sector.m_sigmaY){
         for(auto & iHist : i_sigmaY.second){
           if     (i_sigmaY.first=="sigmaYHit") iHist->Fill(hit.errYHit*10000.);
           else if(i_sigmaY.first=="sigmaYTrk") iHist->Fill(hit.errYTrk*10000.);
           else if(i_sigmaY.first=="sigmaY")    iHist->Fill(hit.errY*10000.);
         }
       }
     }
   }
 }

void ApeEstimator::fillHistsForApeCalculation ( const TrackStruct & trackStruct )

private

Definition at line 2033 of file ApeEstimator.cc.

References calculateApe_, edm::ParameterSet::getParameter(), m_resErrBins_, m_tkSector_, minGoodHitsPerTrack_, TrackStruct::notAssignedToSectors, parameterSet_, and TrackStruct::v_hitParams.

Referenced by analyze().

                                                                       {
   unsigned int goodHitsPerTrack(trackStruct.v_hitParams.size());
   
   if(parameterSet_.getParameter<bool>("applyTrackCuts")){
     // which tracks to take? need min. nr. of selected hits?
     if(goodHitsPerTrack < minGoodHitsPerTrack_)return;
   }
   
   for(auto const & i_hit : trackStruct.v_hitParams){
     // Put here from earlier method
     if(i_hit.hitState == TrackStruct::notAssignedToSectors)continue;
     
     for(auto & i_sector : m_tkSector_){
       
       bool moduleInSector(false);
       for(auto const & i_hitSector : i_hit.v_sector){
         if(i_sector.first == i_hitSector){
           moduleInSector = true; 
           break;
         }
       }
       if(!moduleInSector)continue;      
       
       if(!calculateApe_)continue;
       
       if(i_hit.goodXMeasurement){
         for(auto const & i_errBins : m_resErrBins_){
           // Separate the bins for residual resolution w/o APE, to be consistent within iterations where APE will change (have same hit always in same bin)
           // So also fill this value in the histogram sigmaX
           // But of course use the normalized residual regarding the APE to have its influence in its width
           if(i_hit.errXWoApe < i_errBins.second.first || i_hit.errXWoApe >= i_errBins.second.second){
             continue;
           }
           i_sector.second.m_binnedHists[i_errBins.first]["sigmaX"] ->Fill(i_hit.errXWoApe);
           i_sector.second.m_binnedHists[i_errBins.first]["norResX"]->Fill(i_hit.norResX);
           break;
         }
         i_sector.second.ResX->Fill(i_hit.resX*10000.);
         i_sector.second.NorResX->Fill(i_hit.norResX);
       }
       
       if(i_hit.goodYMeasurement){
         for(auto const & i_errBins : m_resErrBins_){
             // Separate the bins for residual resolution w/o APE, to be consistent within iterations where APE will change (have same hit always in same bin)
             // So also fill this value in the histogram sigmaY
             // But of course use the normalized residual regarding the APE to have its influence in its width
             if(i_hit.errYWoApe < i_errBins.second.first || i_hit.errYWoApe >= i_errBins.second.second){
               continue;
             }
             i_sector.second.m_binnedHists[i_errBins.first]["sigmaY"] ->Fill(i_hit.errYWoApe);
             i_sector.second.m_binnedHists[i_errBins.first]["norResY"]->Fill(i_hit.norResY);
             break;
         }
         i_sector.second.ResY->Fill(i_hit.resY*10000.);
         i_sector.second.NorResY->Fill(i_hit.norResY);
       }
     }
   }
 }

void ApeEstimator::fillHitHistsXForAnalyzerMode	(	const TrackStruct::HitParameterStruct &	hit,
		TrackerSectorStruct &	sector
	)

private

Definition at line 1920 of file ApeEstimator.cc.

Referenced by fillHistsForAnalyzerMode().

                                                                                                                {
   std::map<std::string, TrackerSectorStruct::CorrelationHists>& m_corrHists(sector.m_correlationHistsX);
   
   // Cluster Parameters
   m_corrHists["WidthX"].fillCorrHistsX(hit, hit.widthX);
   m_corrHists["BaryStripX"].fillCorrHistsX(hit, hit.baryStripX);
   
   if(hit.isPixelHit){
     m_corrHists["ChargePixel"].fillCorrHistsX(hit, hit.chargePixel);
     m_corrHists["ClusterProbXY"].fillCorrHistsX(hit, hit.clusterProbabilityXY);
     m_corrHists["ClusterProbQ"].fillCorrHistsX(hit, hit.clusterProbabilityQ);
     m_corrHists["ClusterProbXYQ"].fillCorrHistsX(hit, hit.clusterProbabilityXYQ);
     m_corrHists["LogClusterProb"].fillCorrHistsX(hit, hit.logClusterProbability);
     m_corrHists["IsOnEdge"].fillCorrHistsX(hit, hit.isOnEdge);
     m_corrHists["HasBadPixels"].fillCorrHistsX(hit, hit.hasBadPixels);
     m_corrHists["SpansTwoRoc"].fillCorrHistsX(hit, hit.spansTwoRoc);
     m_corrHists["QBin"].fillCorrHistsX(hit, hit.qBin);
     
   }else{
     m_corrHists["ChargeStrip"].fillCorrHistsX(hit, hit.chargeStrip);
     m_corrHists["MaxStrip"].fillCorrHistsX(hit, hit.maxStrip);
     m_corrHists["MaxCharge"].fillCorrHistsX(hit, hit.maxCharge);
     m_corrHists["MaxIndex"].fillCorrHistsX(hit, hit.maxIndex);
     m_corrHists["ChargeOnEdges"].fillCorrHistsX(hit, hit.chargeOnEdges);
     m_corrHists["ChargeAsymmetry"].fillCorrHistsX(hit, hit.chargeAsymmetry);
     m_corrHists["ChargeLRplus"].fillCorrHistsX(hit, hit.chargeLRplus);
     m_corrHists["ChargeLRminus"].fillCorrHistsX(hit, hit.chargeLRminus);
     m_corrHists["SOverN"].fillCorrHistsX(hit, hit.sOverN);
     m_corrHists["WidthProj"].fillCorrHistsX(hit, hit.projWidth);
     m_corrHists["WidthDiff"].fillCorrHistsX(hit, hit.projWidth-static_cast<float>( hit.widthX));
     
     sector.WidthVsWidthProjected->Fill( hit.projWidth, hit.widthX);
     sector.PWidthVsWidthProjected->Fill( hit.projWidth, hit.widthX);
     
     sector.WidthDiffVsMaxStrip->Fill( hit.maxStrip, hit.projWidth-static_cast<float>( hit.widthX));
     sector.PWidthDiffVsMaxStrip->Fill( hit.maxStrip, hit.projWidth-static_cast<float>( hit.widthX));
     
     sector.WidthDiffVsSigmaXHit->Fill( hit.errXHit, hit.projWidth-static_cast<float>( hit.widthX));
     sector.PWidthDiffVsSigmaXHit->Fill( hit.errXHit, hit.projWidth-static_cast<float>( hit.widthX));
     
     sector.WidthVsPhiSensX->Fill( hit.phiSensX*180./M_PI, hit.widthX);
     sector.PWidthVsPhiSensX->Fill( hit.phiSensX*180./M_PI, hit.widthX);
   }
   
   // Hit Parameters
   m_corrHists["SigmaXHit"].fillCorrHistsX(hit, hit.errXHit*10000.);
   m_corrHists["SigmaXTrk"].fillCorrHistsX(hit, hit.errXTrk*10000.);
   m_corrHists["SigmaX"].fillCorrHistsX(hit, hit.errX*10000.);
   
   m_corrHists["PhiSens"].fillCorrHistsX(hit, hit.phiSens*180./M_PI);
   m_corrHists["PhiSensX"].fillCorrHistsX(hit, hit.phiSensX*180./M_PI);
   m_corrHists["PhiSensY"].fillCorrHistsX(hit, hit.phiSensY*180./M_PI);
   
   sector.XHit ->Fill(hit.xHit);
   sector.XTrk ->Fill(hit.xTrk);
   sector.SigmaX2->Fill(hit.errX2*10000.*10000.);
   
   sector.ResX ->Fill(hit.resX*10000.);
   sector.NorResX->Fill(hit.norResX);
   
   sector.ProbX->Fill(hit.probX);
   
   sector.PhiSensXVsBarycentreX->Fill(hit.baryStripX, hit.phiSensX*180./M_PI);
   sector.PPhiSensXVsBarycentreX->Fill(hit.baryStripX, hit.phiSensX*180./M_PI);
 }

void ApeEstimator::fillHitHistsYForAnalyzerMode	(	const TrackStruct::HitParameterStruct &	hit,
		TrackerSectorStruct &	sector
	)

private

Definition at line 1989 of file ApeEstimator.cc.

Referenced by fillHistsForAnalyzerMode().

                                                                                                                {
   std::map<std::string, TrackerSectorStruct::CorrelationHists>& m_corrHists(sector.m_correlationHistsY);
   // Do not fill anything for strip
   if(!hit.isPixelHit)return;
   
   // Cluster Parameters
   m_corrHists["WidthY"].fillCorrHistsY(hit,hit.widthY);
   m_corrHists["BaryStripY"].fillCorrHistsY(hit,hit.baryStripY);
   
   m_corrHists["ChargePixel"].fillCorrHistsY(hit, hit.chargePixel);
   m_corrHists["ClusterProbXY"].fillCorrHistsY(hit, hit.clusterProbabilityXY);
   m_corrHists["ClusterProbQ"].fillCorrHistsY(hit, hit.clusterProbabilityQ);
   m_corrHists["ClusterProbXYQ"].fillCorrHistsY(hit, hit.clusterProbabilityXYQ);
   m_corrHists["LogClusterProb"].fillCorrHistsY(hit, hit.logClusterProbability);
   m_corrHists["IsOnEdge"].fillCorrHistsY(hit, hit.isOnEdge);
   m_corrHists["HasBadPixels"].fillCorrHistsY(hit, hit.hasBadPixels);
   m_corrHists["SpansTwoRoc"].fillCorrHistsY(hit, hit.spansTwoRoc);
   m_corrHists["QBin"].fillCorrHistsY(hit, hit.qBin);
   
   // Hit Parameters
   m_corrHists["SigmaYHit"].fillCorrHistsY(hit, hit.errYHit*10000.);
   m_corrHists["SigmaYTrk"].fillCorrHistsY(hit, hit.errYTrk*10000.);
   m_corrHists["SigmaY"].fillCorrHistsY(hit, hit.errY*10000.);
   
   m_corrHists["PhiSens"].fillCorrHistsY(hit, hit.phiSens*180./M_PI);
   m_corrHists["PhiSensX"].fillCorrHistsY(hit, hit.phiSensX*180./M_PI);
   m_corrHists["PhiSensY"].fillCorrHistsY(hit, hit.phiSensY*180./M_PI);
   
   sector.YHit ->Fill(hit.yHit);
   sector.YTrk ->Fill(hit.yTrk);
   sector.SigmaY2->Fill(hit.errY2*10000.*10000.);
   
   sector.ResY ->Fill(hit.resY*10000.);
   sector.NorResY->Fill(hit.norResY);
   
   sector.ProbY->Fill(hit.probY);
   
   sector.PhiSensYVsBarycentreY->Fill(hit.baryStripY, hit.phiSensY*180./M_PI);
   sector.PPhiSensYVsBarycentreY->Fill(hit.baryStripY, hit.phiSensY*180./M_PI);
 }

TrackStruct::HitParameterStruct ApeEstimator::fillHitVariables	(	const TrajectoryMeasurement &	i_meas,
		const edm::EventSetup &	iSetup
	)

private

Definition at line 1031 of file ApeEstimator.cc.

Referenced by analyze().

                                                                                               {
   TrackStruct::HitParameterStruct hitParams;
   
   const static TrajectoryStateCombiner tsoscomb;
   
   const TrajectoryMeasurement& meas = i_meas;
   const TransientTrackingRecHit& hit = *meas.recHit();
   const TrackingRecHit& recHit = *hit.hit();
   const TrajectoryStateOnSurface& tsos = tsoscomb(meas.forwardPredictedState(),meas.backwardPredictedState());
   
   const DetId& detId(hit.geographicalId());
   const DetId::Detector& detector = detId.det(); if(detector != DetId::Tracker){hitParams.hitState = TrackStruct::notInTracker; return hitParams;}
   const uint32_t rawId(detId.rawId());
   
   for(auto & i_sector : m_tkSector_){
     for(auto const & i_rawId : i_sector.second.v_rawId){
       if(rawId==i_rawId){hitParams.v_sector.push_back(i_sector.first); break;}
     }
   }
  
   const align::LocalVector& mom(tsos.localDirection());
   int xMomentum(0), yMomentum(0), zMomentum(0);
   xMomentum = mom.x()>0. ? 1 : -1;
   yMomentum = mom.y()>0. ? 1 : -1;
   zMomentum = mom.z()>0. ? 1 : -1;
   float phiSensX = std::atan(std::fabs(mom.x()/mom.z()))*static_cast<float>(m_tkTreeVar_[rawId].vDirection);  // check for orientation of E- and B- Field (thoughts for barrel)
   float phiSensY = std::atan(std::fabs(mom.y()/mom.z()))*static_cast<float>(m_tkTreeVar_[rawId].vDirection);
   hitParams.phiSens  = std::atan(std::fabs(std::sqrt(mom.x()*mom.x()+mom.y()*mom.y())/mom.z()));
   hitParams.phiSensX = (xMomentum==zMomentum ? phiSensX : -phiSensX );
   hitParams.phiSensY = (yMomentum==zMomentum ? phiSensY : -phiSensY );
   
   if(!hit.isValid()){
     hitParams.hitState = TrackStruct::invalid; 
     return hitParams;
   }
   
   // Get local positions and errors of hit and track
   const LocalPoint& lPHit = hit.localPosition();
   const LocalPoint& lPTrk = tsos.localPosition();
   
   // use APE also for the hit error, while APE is automatically included in tsos error
   //
   //  no need to add  APE to hitError anymore by Ajay 27 Oct 2014
   const LocalError& errHitApe = hit.localPositionError();  // now sum of CPE+APE as said by MARCO?
   LocalError errorWithoutAPE;
   
   bool Pixel(false);
   bool Strip(false);
 
   if(       m_tkTreeVar_[rawId].subdetId==PixelSubdetector::PixelBarrel || m_tkTreeVar_[rawId].subdetId==PixelSubdetector::PixelEndcap){
     Pixel = true;
   }else if( m_tkTreeVar_[rawId].subdetId==StripSubdetector::TIB || m_tkTreeVar_[rawId].subdetId==StripSubdetector::TOB ||
             m_tkTreeVar_[rawId].subdetId==StripSubdetector::TID || m_tkTreeVar_[rawId].subdetId==StripSubdetector::TEC){
     Strip = true;
   }else{ 
     edm::LogWarning("FillHitVariables")<<"cant identify wether hit is from pixel or strip";
     hitParams.hitState = TrackStruct::invalid; return hitParams;
   }
 
   if(!hit.detUnit()){
     hitParams.hitState = TrackStruct::invalid; 
     return hitParams;
   } // is it a single physical module?
   const GeomDetUnit& detUnit = *hit.detUnit();
 
   if(Pixel){
     if(!dynamic_cast<const PixelTopology*>(&detUnit.type().topology())){
       hitParams.hitState = TrackStruct::invalid; 
       return hitParams;
     }
     const PixelGeomDetUnit * pixelDet = (const PixelGeomDetUnit*)(&detUnit);
     const LocalError& lape = pixelDet->localAlignmentError();
     if (lape.valid()){ 
       errorWithoutAPE = LocalError(errHitApe.xx() -lape.xx(), errHitApe.xy()- lape.xy(), errHitApe.yy()-lape.yy());
     }
   }
   if(Strip){
     if(!dynamic_cast<const StripTopology*>(&detUnit.type().topology())){
       hitParams.hitState = TrackStruct::invalid; 
       return hitParams;
     }
     const StripGeomDetUnit * stripDet = (const StripGeomDetUnit*)(&detUnit);
     const LocalError& lape = stripDet->localAlignmentError();
     if (lape.valid())
               { errorWithoutAPE = LocalError(errHitApe.xx() -lape.xx(), errHitApe.xy()- lape.xy(), errHitApe.yy()-lape.yy());
     }
   }
 
 
   const LocalError& errHitWoApe = errorWithoutAPE;
   const LocalError& errTrk = tsos.localError().positionError();
   
   const StatePositionAndError2 positionAndError2Hit = this->positionAndError2(lPHit, errHitApe, hit);
   const StatePositionAndError2 positionAndError2HitWoApe = this->positionAndError2(lPHit, errHitWoApe, hit);
   edm::LogInfo("CalculateAPE")<<"errHitWoApe  "<<errHitWoApe<<"errHitApe  "<<errHitApe;
 
   const StatePositionAndError2 positionAndError2Trk = this->positionAndError2(lPTrk, errTrk, hit);
   
   const TrackStruct::HitState& stateHit(positionAndError2Hit.first);
   const TrackStruct::HitState& stateHitWoApe(positionAndError2HitWoApe.first);
   const TrackStruct::HitState& stateTrk(positionAndError2Trk.first);
   
   if(stateHit==TrackStruct::invalid || stateHitWoApe==TrackStruct::invalid || stateTrk==TrackStruct::invalid){
     hitParams.hitState = TrackStruct::invalid;
     return hitParams;
   }else if(stateHit==TrackStruct::negativeError || stateHitWoApe==TrackStruct::negativeError || stateTrk==TrackStruct::negativeError){
     ++counter1;
     // Do not print error message by default
     //std::stringstream ss_error;
     //ss_error<<"Upper values belong to: ";
     //if(stateHit==TrackStruct::negativeError)ss_error<<"Hit without APE, ";
     //if(stateHitWoApe==TrackStruct::negativeError)ss_error<<"Hit with APE, ";
     //if(stateTrk==TrackStruct::negativeError)ss_error<<"Track,";
     //edm::LogError("Negative error Value")<<"@SUB=ApeEstimator::fillHitVariables"<<ss_error.str();
     hitParams.hitState = TrackStruct::negativeError;
     return hitParams;
   }
   
   
   // Calculate residuals
   
   const float xHit = positionAndError2Hit.second.posX;
   const float xTrk = positionAndError2Trk.second.posX;
   const float yHit = positionAndError2Hit.second.posY;
   const float yTrk = positionAndError2Trk.second.posY;
   
   const float errXHit2(positionAndError2Hit.second.errX2);
   const float errXHitWoApe2(positionAndError2HitWoApe.second.errX2);
   const float errXTrk2(positionAndError2Trk.second.errX2);
   const float errYHit2(positionAndError2Hit.second.errY2);
   const float errYHitWoApe2(positionAndError2HitWoApe.second.errY2);
   const float errYTrk2(positionAndError2Trk.second.errY2);
   
   const float errXHit = std::sqrt(positionAndError2Hit.second.errX2);
   const float errXHitWoApe = std::sqrt(positionAndError2HitWoApe.second.errX2);
   const float errXTrk = std::sqrt(positionAndError2Trk.second.errX2);
   const float errYHit = std::sqrt(positionAndError2Hit.second.errY2);
   const float errYHitWoApe = std::sqrt(positionAndError2HitWoApe.second.errY2);
   const float errYTrk = std::sqrt(positionAndError2Trk.second.errY2);
   
   const float resX = xTrk - xHit;
   const float resY = yTrk - yHit;
   
   const float errX = std::sqrt(errXHit2 + errXTrk2);
   const float errXWoApe2 = errXHitWoApe2 + errXTrk2;
   const float errXWoApe = std::sqrt(errXWoApe2);
   const float errY = std::sqrt(errYHit2 + errYTrk2);
   const float errYWoApe2 = errYHitWoApe2 + errYTrk2;
   const float errYWoApe = std::sqrt(errYWoApe2);
   
   const float norResX = resX/errX;
   const float norResY = resY/errY;
   
     
   // Take global orientation into account for residuals (sign is not important for errors)
   
   float resXprime(999.F), resYprime(999.F), norResXprime(999.F), norResYprime(999.F);
   if(m_tkTreeVar_[rawId].uDirection == 1){
     resXprime = resX; 
     norResXprime = norResX;
   }else if(m_tkTreeVar_[rawId].uDirection == -1){
     resXprime = -resX; 
     norResXprime = -norResX;
   }else{
     edm::LogError("FillHitVariables")<<"Incorrect value of uDirection, which gives global module orientation"; 
     hitParams.hitState = TrackStruct::invalid; 
     return hitParams;
   }
   if(m_tkTreeVar_[rawId].vDirection == 1){
     resYprime = resY; 
     norResYprime = norResY;
   }else if(m_tkTreeVar_[rawId].vDirection == -1){
     resYprime = -resY; 
     norResYprime = -norResY;
   }else{
     edm::LogError("FillHitVariables")<<"Incorrect value of vDirection, which gives global module orientation"; 
     hitParams.hitState = TrackStruct::invalid; 
     return hitParams;
   }
   
   hitParams.xHit = xHit;
   hitParams.xTrk = xTrk;
   
   hitParams.errXHit = errXHit;
   hitParams.errXHitWoApe = errXHitWoApe;
   hitParams.errXTrk = errXTrk;
   
   hitParams.errX2 = errX*errX;
   hitParams.errX = errX;
   hitParams.errXWoApe = errXWoApe;
 
   hitParams.resX = resXprime;
   hitParams.norResX = norResXprime;
   
   const float norResX2(norResXprime*norResXprime);
   hitParams.probX = TMath::Prob(norResX2,1);
   
   
   hitParams.yHit = yHit;
   hitParams.yTrk = yTrk;
   
   hitParams.errYHit = errYHit;
   hitParams.errYHitWoApe = errYHitWoApe;
   hitParams.errYTrk = errYTrk;
   
   hitParams.errY2 = errY*errY;
   hitParams.errY = errY;
   hitParams.errYWoApe = errYWoApe;
 
   hitParams.resY = resYprime;
   hitParams.norResY = norResYprime;
   
   const float norResY2(norResYprime*norResYprime);
   hitParams.probY = TMath::Prob(norResY2,1);
   
   
   // Cluster parameters
   
   if(m_tkTreeVar_[rawId].subdetId==PixelSubdetector::PixelBarrel || m_tkTreeVar_[rawId].subdetId==PixelSubdetector::PixelEndcap){
     const SiPixelRecHit& pixelHit = dynamic_cast<const SiPixelRecHit&>(recHit);
     const SiPixelCluster& pixelCluster = *pixelHit.cluster();
     
     hitParams.chargePixel = pixelCluster.charge();
     hitParams.widthX = pixelCluster.sizeX();
     hitParams.baryStripX = pixelCluster.x();
     hitParams.widthY = pixelCluster.sizeY();
     hitParams.baryStripY = pixelCluster.y();
     
     hitParams.clusterProbabilityXY = pixelHit.clusterProbability(0);
     hitParams.clusterProbabilityQ = pixelHit.clusterProbability(2);
     hitParams.clusterProbabilityXYQ = pixelHit.clusterProbability(1);
     hitParams.logClusterProbability = std::log10(hitParams.clusterProbabilityXY);
     
     hitParams.isOnEdge = pixelHit.isOnEdge();
     hitParams.hasBadPixels = pixelHit.hasBadPixels();
     hitParams.spansTwoRoc = pixelHit.spansTwoROCs();
     hitParams.qBin = pixelHit.qBin();
     
     hitParams.isPixelHit = true;
   }else if( m_tkTreeVar_[rawId].subdetId==StripSubdetector::TIB || m_tkTreeVar_[rawId].subdetId==StripSubdetector::TOB ||
             m_tkTreeVar_[rawId].subdetId==StripSubdetector::TID || m_tkTreeVar_[rawId].subdetId==StripSubdetector::TEC){
     if(!(dynamic_cast<const SiStripRecHit2D*>(&recHit) || dynamic_cast<const SiStripRecHit1D*>(&recHit))){
       edm::LogError("FillHitVariables")<<"RecHit in Strip is 'Matched' or 'Projected', but here all should be monohits per module";
       hitParams.hitState = TrackStruct::invalid; return hitParams;
     }
     const SiStripCluster* clusterPtr(nullptr);
     if( m_tkTreeVar_[rawId].subdetId==StripSubdetector::TIB || m_tkTreeVar_[rawId].subdetId==StripSubdetector::TOB){
       if(dynamic_cast<const SiStripRecHit1D*>(&recHit)){
         const SiStripRecHit1D& stripHit = dynamic_cast<const SiStripRecHit1D&>(recHit);
         clusterPtr = &(*stripHit.cluster());
       }else if(dynamic_cast<const SiStripRecHit2D*>(&recHit)){
         edm::LogWarning("FillHitVariables")<<"Data has TIB/TOB hits as SiStripRecHit2D and not 1D. Probably data is processed with CMSSW<34X. Nevertheless everything should work fine";
         const SiStripRecHit2D& stripHit = dynamic_cast<const SiStripRecHit2D&>(recHit);
         clusterPtr = &(*stripHit.cluster());
       }
     }else if( m_tkTreeVar_[rawId].subdetId==StripSubdetector::TID || m_tkTreeVar_[rawId].subdetId==StripSubdetector::TEC){
        const SiStripRecHit2D& stripHit = dynamic_cast<const SiStripRecHit2D&>(recHit);
        clusterPtr = &(*stripHit.cluster());
     }
     if(!clusterPtr){
       edm::LogError("FillHitVariables")<<"Pointer to cluster not valid!!! This should never happen...";
       hitParams.hitState = TrackStruct::invalid; return hitParams;
     }
     const SiStripCluster& stripCluster(*clusterPtr);
     
     const SiStripClusterInfo clusterInfo =SiStripClusterInfo(stripCluster,iSetup,rawId,std::string(""));
 
     const std::vector<uint8_t>::const_iterator stripChargeL(clusterInfo.stripCharges().begin());
     const std::vector<uint8_t>::const_iterator stripChargeR(--(clusterInfo.stripCharges().end()));
     const std::pair<uint16_t, uint16_t> stripChargeLR = std::make_pair(*stripChargeL,*stripChargeR);
     
     hitParams.chargeStrip      = clusterInfo.charge();
     hitParams.widthX           = clusterInfo.width();
     hitParams.baryStripX       = clusterInfo.baryStrip() +1.;
     hitParams.isModuleUsable   = clusterInfo.IsModuleUsable();
     hitParams.maxStrip         = clusterInfo.maxStrip() +1;
     hitParams.maxStripInv      = m_tkTreeVar_[rawId].nStrips - hitParams.maxStrip +1;
     hitParams.maxCharge        = clusterInfo.maxCharge();
     hitParams.maxIndex         = clusterInfo.maxIndex();
     hitParams.chargeOnEdges    = static_cast<float>(stripChargeLR.first + stripChargeLR.second)/static_cast<float>(hitParams.chargeStrip);
     hitParams.chargeAsymmetry  = static_cast<float>(stripChargeLR.first - stripChargeLR.second)/static_cast<float>(stripChargeLR.first + stripChargeLR.second);
     hitParams.chargeLRplus     = static_cast<float>(clusterInfo.chargeLR().first + clusterInfo.chargeLR().second)/static_cast<float>(hitParams.chargeStrip);
     hitParams.chargeLRminus    = static_cast<float>(clusterInfo.chargeLR().first - clusterInfo.chargeLR().second)/static_cast<float>(hitParams.chargeStrip);
     hitParams.sOverN          = clusterInfo.signalOverNoise();
 
 
     // Calculate projection length corrected by drift
     if(!hit.detUnit()){
       hitParams.hitState = TrackStruct::invalid; 
       return hitParams;
     } // is it a single physical module?
     const GeomDetUnit& detUnit = *hit.detUnit();
     if(!dynamic_cast<const StripTopology*>(&detUnit.type().topology())){
       hitParams.hitState = TrackStruct::invalid; 
       return hitParams;
     }
     
     
     edm::ESHandle<MagneticField> magFieldHandle;
     iSetup.get<IdealMagneticFieldRecord>().get(magFieldHandle);
    
     edm::ESHandle<SiStripLorentzAngle> lorentzAngleHandle;
     iSetup.get<SiStripLorentzAngleDepRcd>().get(lorentzAngleHandle);  //MODIFIED BY LOIC QUERTENMONT
 
 
     const StripGeomDetUnit * stripDet = (const StripGeomDetUnit*)(&detUnit);
     const MagneticField * magField(magFieldHandle.product());
     LocalVector bField = (stripDet->surface()).toLocal(magField->inTesla(stripDet->surface().position()));
     const SiStripLorentzAngle * lorentzAngle(lorentzAngleHandle.product());
     float tanLorentzAnglePerTesla = lorentzAngle->getLorentzAngle(stripDet->geographicalId().rawId());
 
     float dirX = -tanLorentzAnglePerTesla * bField.y();
     float dirY = tanLorentzAnglePerTesla * bField.x();
     float dirZ = 1.; // E field always in z direction
     LocalVector driftDirection(dirX,dirY,dirZ);
     
     
     const Bounds& bounds = stripDet->specificSurface().bounds();
     float maxLength = std::sqrt(std::pow(bounds.length(),2)+std::pow(bounds.width(),2));
     float thickness = bounds.thickness();
     
     
     
     const StripTopology& topol = dynamic_cast<const StripTopology&>(detUnit.type().topology());
     LocalVector momentumDir(tsos.localDirection());
     LocalPoint momentumPos(tsos.localPosition());
     LocalVector scaledMomentumDir(momentumDir);
     if(momentumDir.z() > 0.)scaledMomentumDir *= std::fabs(thickness/momentumDir.z());
     else if(momentumDir.z() < 0.)scaledMomentumDir *= -std::fabs(thickness/momentumDir.z());
     else scaledMomentumDir *= maxLength/momentumDir.mag();
     
     float projEdge1 = topol.measurementPosition(momentumPos - 0.5*scaledMomentumDir).x();
     if(projEdge1 < 0.)projEdge1 = 0.;
     else if(projEdge1 > m_tkTreeVar_[rawId].nStrips)projEdge1 = m_tkTreeVar_[rawId].nStrips;
     float projEdge2 = topol.measurementPosition(momentumPos + 0.5*scaledMomentumDir).x();
     if(projEdge2 < 0.)projEdge1 = 0.;
     else if(projEdge2 > m_tkTreeVar_[rawId].nStrips)projEdge1 = m_tkTreeVar_[rawId].nStrips;
     
     
     float coveredStrips = std::fabs(projEdge2 - projEdge1);
     
     hitParams.projWidth = coveredStrips;
       
     
   }
   else{
     edm::LogError("FillHitVariables")<<"Incorrect subdetector ID, hit not associated to tracker";
     hitParams.hitState = TrackStruct::notInTracker; return hitParams;
   }
   
   
   if(!hitParams.isModuleUsable){
     hitParams.hitState = TrackStruct::invalid; 
     return hitParams;
   }
   
   if(hitParams.v_sector.empty()){
     hitParams.hitState = TrackStruct::notAssignedToSectors; 
     return hitParams;
   }
   
   return hitParams;
 //}  
 }

TrackStruct::TrackParameterStruct ApeEstimator::fillTrackVariables	(	const reco::Track &	track,
		const Trajectory &	traj,
		const reco::BeamSpot &	beamSpot
	)

private

Definition at line 958 of file ApeEstimator.cc.

Referenced by analyze().

                                                                                                             {
   const math::XYZPoint beamPoint(beamSpot.x0(),beamSpot.y0(), beamSpot.z0());
   double d0BeamspotErr = std::sqrt( track.d0Error()*track.d0Error() + 0.5*beamSpot.BeamWidthX()*beamSpot.BeamWidthX() + 0.5*beamSpot.BeamWidthY()*beamSpot.BeamWidthY() );
   
   const static TrajectoryStateCombiner tsoscomb;
   
   const reco::HitPattern& hitPattern(track.hitPattern());
   
   TrackStruct::TrackParameterStruct trkParams;
   
   trkParams.hitsSize      = track.recHitsSize();
   trkParams.hitsValid     = track.found(); // invalid is every hit from every single module that expects a hit
   trkParams.hitsInvalid   = trkParams.hitsSize-trkParams.hitsValid;
   trkParams.layersMissed  = track.lost();  // lost hit means, that a crossed layer doesn't contain a hit (can be more than one invalid hit)
   trkParams.hitsPixel     = hitPattern.numberOfValidPixelHits();
   trkParams.hitsStrip     = hitPattern.numberOfValidStripHits();
   trkParams.charge        = track.charge();
   trkParams.chi2          = track.chi2();
   trkParams.ndof          = track.ndof();
   trkParams.norChi2       = trkParams.chi2/trkParams.ndof;
   trkParams.prob          = TMath::Prob(trkParams.chi2,trkParams.ndof);
   trkParams.eta           = track.eta();
   trkParams.etaErr        = track.etaError();
   trkParams.theta         = track.theta();
   trkParams.phi           = track.phi();
   trkParams.phiErr        = track.phiError();
   trkParams.d0            = track.d0();
   trkParams.d0Beamspot    = -1.*track.dxy(beamPoint);
   trkParams.d0BeamspotErr = d0BeamspotErr;
   trkParams.dz            = track.dz();
   trkParams.dzErr         = track.dzError();
   trkParams.dzBeamspot    = track.dz(beamPoint);
   trkParams.p             = track.p();
   trkParams.pt            = track.pt();
   trkParams.ptErr         = track.ptError();
   
   const std::vector<TrajectoryMeasurement>& v_meas = traj.measurements();
      
   int count2D(0); float meanPhiSensToNorm(0.F);
   std::vector<TrajectoryMeasurement>::const_iterator i_meas;
   for(auto const & i_meas : v_meas){     
     const TrajectoryMeasurement& meas = i_meas;
     const TransientTrackingRecHit& hit = *meas.recHit();
     const TrackingRecHit& recHit = *hit.hit();
     if(this->isHit2D(recHit)) ++count2D;
     
     TrajectoryStateOnSurface tsos = tsoscomb(meas.forwardPredictedState(),meas.backwardPredictedState());
     const align::LocalVector mom(tsos.localDirection());
     meanPhiSensToNorm += atan(fabs(sqrt(mom.x()*mom.x()+mom.y()*mom.y())/mom.z()));
   }
   meanPhiSensToNorm *= (1./static_cast<float>(trkParams.hitsSize));
   
   trkParams.hits2D            = count2D;
   trkParams.meanPhiSensToNorm = meanPhiSensToNorm;
   
   if(parameterSet_.getParameter<bool>("applyTrackCuts")){
     trackCut_ = false;
     if(trkParams.hitsStrip<11 || trkParams.hits2D<2 || trkParams.hitsPixel<2 || //trkParams.hitsInvalid>2 ||
        trkParams.hitsStrip>35 || trkParams.hitsPixel>7 ||
        trkParams.norChi2>5. ||
        trkParams.pt<25. || trkParams.pt>150. || 
        std::abs(trkParams.d0Beamspot)>0.02 || std::abs(trkParams.dz)>15.)trackCut_ = true;
   }
   else{
     trackCut_ = false;
   }
   
   return trkParams;
 }

bool ApeEstimator::hitSelected ( TrackStruct::HitParameterStruct & hitParams ) const

private

Definition at line 1645 of file ApeEstimator.cc.

Referenced by analyze().

                                                                       {
   if(hitParams.hitState == TrackStruct::notInTracker)return false;
   if(hitParams.hitState == TrackStruct::invalid || hitParams.hitState == TrackStruct::negativeError)return false;
   
   bool isGoodHit(true);
   bool isGoodHitX(true);
   bool isGoodHitY(true);
   
   for(auto & i_hitSelection : m_hitSelection_){
     const std::string& hitSelection(i_hitSelection.first);
     const std::vector<double>& v_hitSelection(i_hitSelection.second);
     if(v_hitSelection.empty())continue;
     
     // For pixel and strip sectors in common
     if     (hitSelection == "phiSens")        {if(!this->inDoubleInterval(v_hitSelection, hitParams.phiSens))isGoodHit = false;}
     else if(hitSelection == "phiSensX")       {if(!this->inDoubleInterval(v_hitSelection, hitParams.phiSensX))isGoodHit = false;}
     else if(hitSelection == "phiSensY")       {if(!this->inDoubleInterval(v_hitSelection, hitParams.phiSensY))isGoodHit = false;}
     
     else if(hitSelection == "resX")           {if(!this->inDoubleInterval(v_hitSelection, hitParams.resX))isGoodHitX = false;}
     else if(hitSelection == "norResX")        {if(!this->inDoubleInterval(v_hitSelection, hitParams.norResX))isGoodHitX = false;}
     else if(hitSelection == "probX")          {if(!this->inDoubleInterval(v_hitSelection, hitParams.probX))isGoodHitX = false;}
     else if(hitSelection == "errXHit")        {if(!this->inDoubleInterval(v_hitSelection, hitParams.errXHit))isGoodHitX = false;}
     else if(hitSelection == "errXTrk")        {if(!this->inDoubleInterval(v_hitSelection, hitParams.errXTrk))isGoodHitX = false;}
     else if(hitSelection == "errX")           {if(!this->inDoubleInterval(v_hitSelection, hitParams.errX))isGoodHitX = false;}
     else if(hitSelection == "errX2")          {if(!this->inDoubleInterval(v_hitSelection, hitParams.errX2))isGoodHitX = false;}
     
     // For pixel only
     if(hitParams.isPixelHit){
       if     (hitSelection == "chargePixel")          {if(!this->inDoubleInterval(v_hitSelection, hitParams.chargePixel))isGoodHit = false;}
       else if(hitSelection == "clusterProbabilityXY") {if(!this->inDoubleInterval(v_hitSelection, hitParams.clusterProbabilityXY))isGoodHit = false;}
       else if(hitSelection == "clusterProbabilityQ")  {if(!this->inDoubleInterval(v_hitSelection, hitParams.clusterProbabilityQ))isGoodHit = false;}
       else if(hitSelection == "clusterProbabilityXYQ"){if(!this->inDoubleInterval(v_hitSelection, hitParams.clusterProbabilityXYQ))isGoodHit = false;}
       else if(hitSelection == "logClusterProbability"){if(!this->inDoubleInterval(v_hitSelection, hitParams.logClusterProbability))isGoodHit = false;}
       
       else if(hitSelection == "baryStripX")           {if(!this->inDoubleInterval(v_hitSelection, hitParams.baryStripX))isGoodHitX = false;}
       else if(hitSelection == "baryStripY")           {if(!this->inDoubleInterval(v_hitSelection, hitParams.baryStripY))isGoodHitY = false;}
       
       
       
       else if(hitSelection == "resY")           {if(!this->inDoubleInterval(v_hitSelection, hitParams.resY))isGoodHitY = false;}
       else if(hitSelection == "norResY")        {if(!this->inDoubleInterval(v_hitSelection, hitParams.norResY))isGoodHitY = false;}
       else if(hitSelection == "probY")          {if(!this->inDoubleInterval(v_hitSelection, hitParams.probY))isGoodHitY = false;}
       else if(hitSelection == "errYHit")        {if(!this->inDoubleInterval(v_hitSelection, hitParams.errYHit))isGoodHitY = false;}
       else if(hitSelection == "errYTrk")        {if(!this->inDoubleInterval(v_hitSelection, hitParams.errYTrk))isGoodHitY = false;}
       else if(hitSelection == "errY")           {if(!this->inDoubleInterval(v_hitSelection, hitParams.errY))isGoodHitY = false;}
       else if(hitSelection == "errY2")          {if(!this->inDoubleInterval(v_hitSelection, hitParams.errY2))isGoodHitY = false;}
     }else{ // For strip only
       if     (hitSelection == "widthProj")      {if(!this->inDoubleInterval(v_hitSelection, hitParams.projWidth))isGoodHit = false;}
       else if(hitSelection == "widthDiff")      {if(!this->inDoubleInterval(v_hitSelection, hitParams.projWidth-static_cast<float>(hitParams.widthX)))isGoodHit = false;}
       else if(hitSelection == "charge")         {if(!this->inDoubleInterval(v_hitSelection, hitParams.chargeStrip))isGoodHit = false;}
       else if(hitSelection == "maxCharge")      {if(!this->inDoubleInterval(v_hitSelection, hitParams.maxCharge))isGoodHit = false;}
       else if(hitSelection == "chargeOnEdges")  {if(!this->inDoubleInterval(v_hitSelection, hitParams.chargeOnEdges))isGoodHit = false;}
       else if(hitSelection == "chargeAsymmetry"){if(!this->inDoubleInterval(v_hitSelection, hitParams.chargeAsymmetry))isGoodHit = false;}
       else if(hitSelection == "chargeLRplus")   {if(!this->inDoubleInterval(v_hitSelection, hitParams.chargeLRplus))isGoodHit = false;}
       else if(hitSelection == "chargeLRminus")  {if(!this->inDoubleInterval(v_hitSelection, hitParams.chargeLRminus))isGoodHit = false;}
       else if(hitSelection == "sOverN")         {if(!this->inDoubleInterval(v_hitSelection, hitParams.sOverN))isGoodHit = false;}
     }
   }
   
   for(auto & i_hitSelection : m_hitSelectionUInt_){
     const std::string& hitSelection(i_hitSelection.first);
     const std::vector<unsigned int>& v_hitSelection(i_hitSelection.second);
     if(v_hitSelection.empty())continue;
     
     // For pixel and strip sectors in common
     
     // For pixel only
     if(hitParams.isPixelHit){
       if(hitSelection == "isOnEdge")          {if(!this->inUintInterval(v_hitSelection, hitParams.isOnEdge))isGoodHit = false;}
       else if(hitSelection == "hasBadPixels") {if(!this->inUintInterval(v_hitSelection, hitParams.hasBadPixels))isGoodHit = false;}
       else if(hitSelection == "spansTwoRoc")  {if(!this->inUintInterval(v_hitSelection, hitParams.spansTwoRoc))isGoodHit = false;}
       else if(hitSelection == "qBin")         {if(!this->inUintInterval(v_hitSelection, hitParams.qBin))isGoodHit = false;}
       
       else if(hitSelection == "widthX")       {if(!this->inUintInterval(v_hitSelection, hitParams.widthX))isGoodHitX = false;}
       else if(hitSelection == "widthY")       {if(!this->inUintInterval(v_hitSelection, hitParams.widthY))isGoodHitY = false;}
     }else{ // For strip only
       if     (hitSelection == "width")     {if(!this->inUintInterval(v_hitSelection, hitParams.widthX))isGoodHit = false;}
       else if(hitSelection == "edgeStrips"){if(!this->inUintInterval(v_hitSelection, hitParams.maxStrip, hitParams.maxStripInv))isGoodHit = false;}
       else if(hitSelection == "maxIndex")  {if(!this->inUintInterval(v_hitSelection, hitParams.maxIndex))isGoodHit = false;}
     }
   }
   
   if(hitParams.isPixelHit){
     hitParams.goodXMeasurement = isGoodHit && isGoodHitX;
     hitParams.goodYMeasurement = isGoodHit && isGoodHitY;
   }else{
     hitParams.goodXMeasurement = isGoodHit && isGoodHitX;
     hitParams.goodYMeasurement = false;
   }
   
   if(!hitParams.goodXMeasurement && !hitParams.goodYMeasurement)return false;
   else return true;
 }

void ApeEstimator::hitSelection ( )

private

Definition at line 1504 of file ApeEstimator.cc.

References mps_splice::entry, m_hitSelection_, m_hitSelectionUInt_, setHitSelectionMap(), and setHitSelectionMapUInt().

Referenced by beginJob(), and hitSelected().

                           {
   this->setHitSelectionMapUInt("width");
   this->setHitSelectionMap("widthProj");
   this->setHitSelectionMap("widthDiff");
   this->setHitSelectionMap("charge");
   this->setHitSelectionMapUInt("edgeStrips");
   this->setHitSelectionMap("maxCharge");
   this->setHitSelectionMapUInt("maxIndex");
   this->setHitSelectionMap("chargeOnEdges");
   this->setHitSelectionMap("chargeAsymmetry");
   this->setHitSelectionMap("chargeLRplus");
   this->setHitSelectionMap("chargeLRminus");
   this->setHitSelectionMap("sOverN");
   
   this->setHitSelectionMap("chargePixel");
   this->setHitSelectionMapUInt("widthX");
   this->setHitSelectionMapUInt("widthY");
   
   this->setHitSelectionMap("baryStripX");
   this->setHitSelectionMap("baryStripY");
   this->setHitSelectionMap("clusterProbabilityXY");
   this->setHitSelectionMap("clusterProbabilityQ");
   this->setHitSelectionMap("clusterProbabilityXYQ");
   this->setHitSelectionMap("logClusterProbability");
   this->setHitSelectionMapUInt("isOnEdge");
   this->setHitSelectionMapUInt("hasBadPixels");
   this->setHitSelectionMapUInt("spansTwoRoc");
   this->setHitSelectionMapUInt("qBin");
   
   this->setHitSelectionMap("phiSens");
   this->setHitSelectionMap("phiSensX");
   this->setHitSelectionMap("phiSensY");
   this->setHitSelectionMap("resX");
   this->setHitSelectionMap("norResX");
   this->setHitSelectionMap("probX");
   this->setHitSelectionMap("errXHit");
   this->setHitSelectionMap("errXTrk");
   this->setHitSelectionMap("errX");
   this->setHitSelectionMap("errX2");
   
   this->setHitSelectionMap("resY");
   this->setHitSelectionMap("norResY");
   this->setHitSelectionMap("probY");
   this->setHitSelectionMap("errYHit");
   this->setHitSelectionMap("errYTrk");
   this->setHitSelectionMap("errY");
   this->setHitSelectionMap("errY2");
   
   edm::LogInfo("HitSelector")<<"applying hit cuts ...";
   bool emptyMap(true);
   for(auto & i_hitSelection : m_hitSelection_){
     if(!i_hitSelection.second.empty()){
       int entry(1); double intervalBegin(999.);
       for(std::vector<double>::iterator i_hitInterval = i_hitSelection.second.begin(); i_hitInterval != i_hitSelection.second.end(); ++entry){
         if(entry%2==1){
           intervalBegin = *i_hitInterval; ++i_hitInterval;
         }else{
           if(intervalBegin > *i_hitInterval){
             edm::LogError("HitSelector")<<"INVALID Interval selected for  "<<i_hitSelection.first<<":\t"<<intervalBegin<<" > "<<(*i_hitInterval)
                                   <<"\n ... delete Selection for "<<i_hitSelection.first;
             i_hitSelection.second.clear(); i_hitInterval = i_hitSelection.second.begin(); //emptyMap = true; i_hitSelection = m_hitSelection_.begin();
           }else{
             edm::LogInfo("HitSelector")<<"Interval selected for  "<<i_hitSelection.first<<":\t"<<intervalBegin<<", "<<(*i_hitInterval);
             ++i_hitInterval;
           }
         }
       }
       if(!i_hitSelection.second.empty())emptyMap = false;
     }
   }
   
   
   bool emptyMapUInt(true);
   for(auto & i_hitSelection : m_hitSelectionUInt_){
     if(!i_hitSelection.second.empty()){
       int entry(1); unsigned int intervalBegin(999);
       for(std::vector<unsigned int>::iterator i_hitInterval = i_hitSelection.second.begin(); i_hitInterval != i_hitSelection.second.end(); ++entry){
         if(entry%2==1){
           intervalBegin = *i_hitInterval; 
           ++i_hitInterval;
         }else{
           if(intervalBegin > *i_hitInterval){
             edm::LogError("HitSelector")<<"INVALID Interval selected for  "<<i_hitSelection.first<<":\t"<<intervalBegin<<" > "<<(*i_hitInterval)
                                   <<"\n ... delete Selection for "<<i_hitSelection.first;
             i_hitSelection.second.clear(); i_hitInterval = i_hitSelection.second.begin(); //emptyMap = true; i_hitSelection = m_hitSelection_.begin();
           }else{
             edm::LogInfo("HitSelector")<<"Interval selected for  "<<i_hitSelection.first<<":\t"<<intervalBegin<<", "<<(*i_hitInterval);
             ++i_hitInterval;
           }
         }
       }
       if(!i_hitSelection.second.empty())emptyMapUInt = false;
     }
   }
   
   if(emptyMap && emptyMapUInt){
     m_hitSelection_.clear();
     m_hitSelectionUInt_.clear();
     edm::LogInfo("HitSelector")<<"NO hit cuts applied";
   }
   return;
 }

bool ApeEstimator::inDoubleInterval	(	const std::vector< double > &	v_hitSelection,
		const float	variable
	)		const

private

Definition at line 1741 of file ApeEstimator.cc.

References mps_splice::entry.

Referenced by hitSelected().

                                                                                                 {
   int entry(0); double intervalBegin(999.);
   bool isSelected(false);
   for(auto const & i_hitInterval : v_hitSelection){
     ++entry;
     if(entry%2==1)intervalBegin = i_hitInterval;
     else if(variable>=intervalBegin && variable<i_hitInterval)isSelected = true;
   }
   return isSelected;
 }

bool ApeEstimator::inUintInterval	(	const std::vector< unsigned int > &	v_hitSelection,
		const unsigned int	variable,
		const unsigned int	variable2 = `999`
	)		const

private

Definition at line 1754 of file ApeEstimator.cc.

References mps_splice::entry.

Referenced by hitSelected().

                                                                                                                                          {
   int entry(0); unsigned int intervalBegin(999);
   bool isSelected(false);
   for(auto i_hitInterval : v_hitSelection ){
     ++entry;
     if(entry%2==1)intervalBegin = i_hitInterval;
     else if(variable>=intervalBegin && variable<=i_hitInterval){
       if(variable2==999 || (variable2>=intervalBegin && variable2<=i_hitInterval))isSelected = true;
     }
   }
   return isSelected;
 }

bool ApeEstimator::isHit2D ( const TrackingRecHit & hit ) const

private

Definition at line 2128 of file ApeEstimator.cc.

References TrackingRecHit::dimension(), TrackingRecHit::geographicalId(), TrackingRecHit::isValid(), ProjectedSiStripRecHit2D::originalHit(), PixelSubdetector::PixelBarrel, PixelSubdetector::PixelEndcap, SiStripDetId::stereo(), and DetId::Tracker.

Referenced by fillTrackVariables().

 {
   // we count SiStrip stereo modules as 2D if selected via countStereoHitAs2D_
   // (since they provide theta information)
   // --- NO, here it is always set to true ---
   if(!hit.isValid() || (hit.dimension() < 2 && !dynamic_cast<const SiStripRecHit1D*>(&hit))){
     return false; // real RecHit1D - but SiStripRecHit1D depends on countStereoHitAs2D_
   }else{
     const DetId detId(hit.geographicalId());
     if(detId.det() == DetId::Tracker) {
       if(detId.subdetId() == PixelSubdetector::PixelBarrel || detId.subdetId() == PixelSubdetector::PixelEndcap) {
         return true; // pixel is always 2D
       }else{ // should be SiStrip now
         const SiStripDetId stripId(detId);
         if (stripId.stereo()) return true; // stereo modules
         else if (dynamic_cast<const SiStripRecHit1D*>(&hit) || dynamic_cast<const SiStripRecHit2D*>(&hit)) return false; // rphi modules hit
         //the following two are not used any more since ages... 
         else if (dynamic_cast<const SiStripMatchedRecHit2D*>(&hit)) return true; // matched is 2D
         else if (dynamic_cast<const ProjectedSiStripRecHit2D*>(&hit)) {
           const ProjectedSiStripRecHit2D* pH = static_cast<const ProjectedSiStripRecHit2D*>(&hit);
           return (this->isHit2D(pH->originalHit())); // depends on original...
         }else{
           edm::LogError("UnkownType") << "@SUB=AlignmentTrackSelector::isHit2D"
                                       << "Tracker hit not in pixel, neither SiStripRecHit[12]D nor "
                                       << "SiStripMatchedRecHit2D nor ProjectedSiStripRecHit2D.";
           return false;
         }
       }
     }else{ // not tracker??
       edm::LogWarning("DetectorMismatch") << "@SUB=AlignmentTrackSelector::isHit2D"
                                           << "Hit not in tracker with 'official' dimension >=2.";
       return true; // dimension() >= 2 so accept that...
     }
   }
   // never reached...
 }

ApeEstimator::StatePositionAndError2 ApeEstimator::positionAndError2	(	const LocalPoint &	localPoint,
		const LocalError &	localError,
		const TransientTrackingRecHit &	hit
	)

private

Definition at line 1399 of file ApeEstimator.cc.

References TrackingRecHit::detUnit(), TrackingRecHit::geographicalId(), TrackStruct::invalid, m_tkTreeVar_, RadialStripTopology::measurementError(), TrackStruct::negativeError, TrackStruct::ok, PixelSubdetector::PixelBarrel, PixelSubdetector::PixelEndcap, radialPositionAndError2(), rectangularPositionAndError2(), StripSubdetector::TEC, StripSubdetector::TIB, StripSubdetector::TID, StripSubdetector::TOB, GeomDetType::topology(), GeomDet::type(), MeasurementError::uu(), MeasurementError::vv(), LocalError::xx(), and LocalError::yy().

Referenced by fillHitVariables().

                                                                                                                              {
   StatePositionAndError2 vPE2 = std::make_pair(TrackStruct::invalid,PositionAndError2());
   
   const DetId& detId(hit.geographicalId());
   const uint32_t& rawId(detId.rawId());
   const unsigned int& subdetId(m_tkTreeVar_[rawId].subdetId);
   
   if(localError.xx()<0. || localError.yy()<0.){
     // Do not print error message by default
     //edm::LogError("Negative error Value")<<"@SUB=ApeEstimator::fillHitVariables"
     //                                     <<"One of the squared error methods gives negative result\n"
     //                                     <<"\tSubdetector\tlocalError.xx()\tlocalError.yy()\n"
     //                                     <<"\t"<<subdetId<<"\t\t"<<localError.xx()<<"\t"<<localError.yy();
     vPE2.first = TrackStruct::negativeError;
     return vPE2;
   }
   
   if(subdetId==PixelSubdetector::PixelBarrel || subdetId==PixelSubdetector::PixelEndcap ||
      subdetId==StripSubdetector::TIB || subdetId==StripSubdetector::TOB){
     // Cartesian coordinates
     vPE2 = std::make_pair(TrackStruct::ok, this->rectangularPositionAndError2(localPoint, localError));
   }
   else if(subdetId==StripSubdetector::TID || subdetId==StripSubdetector::TEC){
     // Local x in radial coordinates
     if(!hit.detUnit())return vPE2; // is it a single physical module?
     const GeomDetUnit& detUnit = *hit.detUnit();
     
     if(!dynamic_cast<const RadialStripTopology*>(&detUnit.type().topology()))return vPE2;
     const RadialStripTopology& topol = dynamic_cast<const RadialStripTopology&>(detUnit.type().topology());
     
     MeasurementError measError = topol.measurementError(localPoint,localError);
     if(measError.uu()<0. || measError.vv()<0.){
       // Do not print error message by default
       //edm::LogError("Negative error Value")<<"@SUB=ApeEstimator::fillHitVariables"
       //                                     <<"One of the squared error methods gives negative result\n"
       //                                     <<"\tmeasError.uu()\tmeasError.vv()\n"
       //                                     <<"\t"<<measError.uu()<<"\t"<<measError.vv()
       //                                     <<"\n\nOriginalValues:\n"
       //                                     <<localPoint.x()<<" "<<localPoint.y()<<"\n"
       //                                     <<localError.xx()<<" "<<localError.yy()<<"\n"
       //                                     <<"Subdet: "<<subdetId;
       vPE2.first = TrackStruct::negativeError;
       return vPE2;
     }
     vPE2 = std::make_pair(TrackStruct::ok, this->radialPositionAndError2(localPoint, localError, topol));
   }else{
     edm::LogError("FillHitVariables")<<"Incorrect subdetector ID, hit not associated to tracker";
   }
   
   return vPE2;
 }

ApeEstimator::PositionAndError2 ApeEstimator::radialPositionAndError2	(	const LocalPoint &	lP,
		const LocalError &	lE,
		const RadialStripTopology &	topol
	)

private

Definition at line 1466 of file ApeEstimator.cc.

References RadialStripTopology::angularWidth(), funct::cos(), RadialStripTopology::detHeight(), F(), RadialStripTopology::localStripLength(), RadialStripTopology::measurementError(), RadialStripTopology::measurementPosition(), RadialStripTopology::originToIntersection(), phi, funct::pow(), funct::sin(), RadialStripTopology::stripAngle(), MeasurementError::uu(), MeasurementError::vv(), x, PV2DBase< T, PVType, FrameType >::x(), y, and PV2DBase< T, PVType, FrameType >::y().

Referenced by positionAndError2().

                                                                                                                  {
   MeasurementPoint measPos = topol.measurementPosition(lP);
   MeasurementError measErr = topol.measurementError(lP,lE);
   
   const float r_0 = topol.originToIntersection();
   const float stripLength = topol.localStripLength(lP);
   const float phi = topol.stripAngle(measPos.x());
   
   float x(-999.F);
   float y(-999.F);
   float errX2(-999.F);
   float errY2(-999.F);
   
   x = phi*r_0;
   // Radial y (not symmetric around 0; radial distance with minimum at middle strip at lower edge [0, yMax])
   const float l_0 = r_0 - topol.detHeight()/2;
   const float cosPhi(std::cos(phi));
   y = measPos.y()*stripLength - 0.5*stripLength + l_0*(1./cosPhi - 1.);
   
   const float angularWidth2(topol.angularWidth()*topol.angularWidth());
   const float errPhi2(measErr.uu()*angularWidth2);
   
   errX2 = errPhi2*r_0*r_0;
   // Radial y (not symmetric around 0, real radial distance from intersection point)
   const float cosPhi4(std::pow(cosPhi,4)), sinPhi2(std::sin(phi)*std::sin(phi));
   const float helpSummand = l_0*l_0*(sinPhi2/cosPhi4*errPhi2);
   errY2 = measErr.vv()*stripLength*stripLength + helpSummand;
 
   return PositionAndError2(x, y, errX2, errY2);
 }

ApeEstimator::PositionAndError2 ApeEstimator::rectangularPositionAndError2	(	const LocalPoint &	lP,
		const LocalError &	lE
	)

private

Definition at line 1454 of file ApeEstimator.cc.

References x, PV3DBase< T, PVType, FrameType >::x(), LocalError::xx(), y, PV3DBase< T, PVType, FrameType >::y(), and LocalError::yy().

Referenced by positionAndError2().

                                                                                     {
   const float x(lP.x());
   const float y(lP.y());
   const float errX2(lE.xx());
   const float errY2(lE.yy());
   
   return PositionAndError2(x, y, errX2, errY2);
 }

void ApeEstimator::residualErrorBinning ( )

private

Definition at line 538 of file ApeEstimator.cc.

References edm::ParameterSet::getParameter(), m_resErrBins_, parameterSet_, anotherprimaryvertexanalyzer_cfi::xMax, and anotherprimaryvertexanalyzer_cfi::xMin.

Referenced by beginJob().

                                   {
   std::vector<double> v_residualErrorBinning(parameterSet_.getParameter<std::vector<double> >("residualErrorBinning"));
   if(v_residualErrorBinning.size()==1){
     edm::LogError("ResidualErrorBinning")<<"Incorrect selection of Residual Error Bins (used for APE calculation): \t"
                                         <<"Only one argument passed, so no interval is specified"
           <<"\n... delete whole bin selection";    //m_resErrBins_ remains empty
     return;
   }
   double xMin(0.), xMax(0.);
   unsigned int binCounter(-1);
   for(auto const & i_binning : v_residualErrorBinning){
     ++binCounter;
     if(binCounter == 0){
         xMin = i_binning;
         continue;
     }
     xMax = i_binning;
     if(xMax<=xMin){
       edm::LogError("ResidualErrorBinning")<<"Incorrect selection of Residual Error Bins (used for APE calculation): \t"
                                             <<xMin<<" is bigger than "<<xMax<<" but is expected to be smaller"
               <<"\n... delete whole bin selection";
       m_resErrBins_.clear();
       return;
     }
     m_resErrBins_[binCounter].first = xMin;
     m_resErrBins_[binCounter].second = xMax;
     xMin = xMax;
   }
   edm::LogInfo("ResidualErrorBinning")<<m_resErrBins_.size()<<" Intervals of residual errors used for separate APE calculation sucessfully set";
 }

void ApeEstimator::sectorBuilder ( )

private

Definition at line 251 of file ApeEstimator.cc.

References checkIntervalsForSectors(), checkModuleBools(), checkModuleDirections(), checkModuleIds(), checkModulePositions(), F(), edm::ParameterSet::getParameter(), fastTrackerRecHitType::isPixel(), TrackerSectorStruct::isPixel, m_tkSector_, m_tkTreeVar_, python.rootplot.argparse::module, TrackerSectorStruct::name, ReducedTrackerTreeVariables::nStrips, parameterSet_, PixelSubdetector::PixelBarrel, PixelSubdetector::PixelEndcap, RecoTauValidation_cfi::posX, RecoTauValidation_cfi::posY, relativeConstraints::ring, statistics(), AlCaHLTBitMon_QueryRunRegistry::string, ReducedTrackerTreeVariables::subdetId, StripSubdetector::TEC, StripSubdetector::TIB, StripSubdetector::TID, StripSubdetector::TOB, ReducedTrackerTreeVariables::uDirection, TrackerSectorStruct::v_rawId, ReducedTrackerTreeVariables::vDirection, and ReducedTrackerTreeVariables::wDirection.

Referenced by beginJob().

                            {
   
   TFile* tkTreeFile(TFile::Open((parameterSet_.getParameter<std::string>("TrackerTreeFile")).c_str()));
   if(tkTreeFile){
       edm::LogInfo("SectorBuilder")<<"TrackerTreeFile OK";
   }else{
       edm::LogError("SectorBuilder")<<"TrackerTreeFile not found";
       return;
   }
   TTree* tkTree(nullptr);
   tkTreeFile->GetObject("TrackerTreeGenerator/TrackerTree/TrackerTree",tkTree);
   if(tkTree){
       edm::LogInfo("SectorBuilder")<<"TrackerTree OK";
   }else{
       edm::LogError("SectorBuilder")<<"TrackerTree not found in file";
       return;
   }
   unsigned int rawId(999), subdetId(999), layer(999), side(999), half(999), rod(999), ring(999), petal(999),
          blade(999), panel(999), outerInner(999), module(999), nStrips(999);
   bool isDoubleSide(false), isRPhi(false), isStereo(false);
   int uDirection(999), vDirection(999), wDirection(999);
   float posR(999.F), posPhi(999.F), posEta(999.F), posX(999.F), posY(999.F), posZ(999.F); 
   
   tkTree->SetBranchAddress("RawId", &rawId);
   tkTree->SetBranchAddress("SubdetId", &subdetId);
   tkTree->SetBranchAddress("Layer", &layer);
   tkTree->SetBranchAddress("Side", &side);
   tkTree->SetBranchAddress("Half", &half);
   tkTree->SetBranchAddress("Rod", &rod);
   tkTree->SetBranchAddress("Ring", &ring);
   tkTree->SetBranchAddress("Petal", &petal);
   tkTree->SetBranchAddress("Blade", &blade);
   tkTree->SetBranchAddress("Panel", &panel);
   tkTree->SetBranchAddress("OuterInner", &outerInner);
   tkTree->SetBranchAddress("Module", &module);
   tkTree->SetBranchAddress("NStrips", &nStrips);
   tkTree->SetBranchAddress("IsDoubleSide", &isDoubleSide);
   tkTree->SetBranchAddress("IsRPhi", &isRPhi);
   tkTree->SetBranchAddress("IsStereo", &isStereo);
   tkTree->SetBranchAddress("UDirection", &uDirection);
   tkTree->SetBranchAddress("VDirection", &vDirection);
   tkTree->SetBranchAddress("WDirection", &wDirection);
   tkTree->SetBranchAddress("PosR", &posR);
   tkTree->SetBranchAddress("PosPhi", &posPhi);
   tkTree->SetBranchAddress("PosEta", &posEta);
   tkTree->SetBranchAddress("PosX", &posX);
   tkTree->SetBranchAddress("PosY", &posY);
   tkTree->SetBranchAddress("PosZ", &posZ);
   
   int nModules(tkTree->GetEntries());
   TrackerSectorStruct allSectors;
   
   //Loop over all Sectors
   unsigned int sectorCounter(0);
   std::vector<edm::ParameterSet> v_sectorDef(parameterSet_.getParameter<std::vector<edm::ParameterSet> >("Sectors"));
   edm::LogInfo("SectorBuilder")<<"There are "<<v_sectorDef.size()<<" Sectors definded";
   std::vector<edm::ParameterSet>::const_iterator i_parSet;
   for(auto const & parSet : v_sectorDef){
       ++sectorCounter;
       const std::string& sectorName(parSet.getParameter<std::string>("name"));
       std::vector<unsigned int> v_rawId(parSet.getParameter<std::vector<unsigned int> >("rawId")),
                                 v_subdetId(parSet.getParameter<std::vector<unsigned int> >("subdetId")),
                                 v_layer(parSet.getParameter<std::vector<unsigned int> >("layer")),
                                 v_side(parSet.getParameter<std::vector<unsigned int> >("side")),
                                 v_half(parSet.getParameter<std::vector<unsigned int> >("half")),
                                 v_rod(parSet.getParameter<std::vector<unsigned int> >("rod")),
                                 v_ring(parSet.getParameter<std::vector<unsigned int> >("ring")),
                                 v_petal(parSet.getParameter<std::vector<unsigned int> >("petal")),
                                 v_blade(parSet.getParameter<std::vector<unsigned int> >("blade")),
                                 v_panel(parSet.getParameter<std::vector<unsigned int> >("panel")),
                                 v_outerInner(parSet.getParameter<std::vector<unsigned int> >("outerInner")),
                                 v_module(parSet.getParameter<std::vector<unsigned int> >("module")),
                                 v_nStrips(parSet.getParameter<std::vector<unsigned int> >("nStrips")),
                                 v_isDoubleSide(parSet.getParameter<std::vector<unsigned int> >("isDoubleSide")),
                                 v_isRPhi(parSet.getParameter<std::vector<unsigned int> >("isRPhi")),
                                 v_isStereo(parSet.getParameter<std::vector<unsigned int> >("isStereo"));
       std::vector<int>  v_uDirection(parSet.getParameter<std::vector<int> >("uDirection")),
                         v_vDirection(parSet.getParameter<std::vector<int> >("vDirection")),
                         v_wDirection(parSet.getParameter<std::vector<int> >("wDirection"));
       std::vector<double> v_posR(parSet.getParameter<std::vector<double> >("posR")),
                           v_posPhi(parSet.getParameter<std::vector<double> >("posPhi")),
                           v_posEta(parSet.getParameter<std::vector<double> >("posEta")),
                           v_posX(parSet.getParameter<std::vector<double> >("posX")),
                           v_posY(parSet.getParameter<std::vector<double> >("posY")),
                           v_posZ(parSet.getParameter<std::vector<double> >("posZ"));
     
       if(!this->checkIntervalsForSectors(sectorCounter,v_posR) || !this->checkIntervalsForSectors(sectorCounter,v_posPhi) ||
         !this->checkIntervalsForSectors(sectorCounter,v_posEta) || !this->checkIntervalsForSectors(sectorCounter,v_posX) ||
         !this->checkIntervalsForSectors(sectorCounter,v_posY)   || !this->checkIntervalsForSectors(sectorCounter,v_posZ))continue;
     
     
       TrackerSectorStruct tkSector;
       tkSector.name = sectorName;
       
       ReducedTrackerTreeVariables tkTreeVar;
     
       //Loop over all Modules
       for(int module = 0; module < nModules; ++module){
           tkTree->GetEntry(module);
           
           if(sectorCounter==1){
             tkTreeVar.subdetId = subdetId;
             tkTreeVar.nStrips = nStrips;
             tkTreeVar.uDirection = uDirection;
             tkTreeVar.vDirection = vDirection;
             tkTreeVar.wDirection = wDirection;
             m_tkTreeVar_[rawId] = tkTreeVar;
           }
       
           if(!this->checkModuleIds(rawId,v_rawId))continue;
           if(!this->checkModuleIds(subdetId,v_subdetId))continue;
           if(!this->checkModuleIds(layer,v_layer))continue;
           if(!this->checkModuleIds(side,v_side))continue;
           if(!this->checkModuleIds(half,v_half))continue;
           if(!this->checkModuleIds(rod,v_rod))continue;
           if(!this->checkModuleIds(ring,v_ring))continue;
           if(!this->checkModuleIds(petal,v_petal))continue;
           if(!this->checkModuleIds(blade,v_blade))continue;
           if(!this->checkModuleIds(panel,v_panel))continue;
           if(!this->checkModuleIds(outerInner,v_outerInner))continue;
           if(!this->checkModuleIds(module,v_module))continue;
           if(!this->checkModuleIds(nStrips,v_nStrips))continue;
           if(!this->checkModuleBools(isDoubleSide,v_isDoubleSide))continue;
           if(!this->checkModuleBools(isRPhi,v_isRPhi))continue;
           if(!this->checkModuleBools(isStereo,v_isStereo))continue;
           if(!this->checkModuleDirections(uDirection,v_uDirection))continue;
           if(!this->checkModuleDirections(vDirection,v_vDirection))continue;
           if(!this->checkModuleDirections(wDirection,v_wDirection))continue;
           if(!this->checkModulePositions(posR,v_posR))continue;
           if(!this->checkModulePositions(posPhi,v_posPhi))continue;
           if(!this->checkModulePositions(posEta,v_posEta))continue;
           if(!this->checkModulePositions(posX,v_posX))continue;
           if(!this->checkModulePositions(posY,v_posY))continue;
           if(!this->checkModulePositions(posZ,v_posZ))continue;
           
           tkSector.v_rawId.push_back(rawId);
           bool moduleSelected(false);
           for(auto const & i_rawId : allSectors.v_rawId){
             if(rawId == i_rawId)moduleSelected = true;
           }
           if(!moduleSelected)allSectors.v_rawId.push_back(rawId);
       }
     
       bool isPixel(false);
       bool isStrip(false);
       for(auto const & i_rawId : tkSector.v_rawId){
         switch (m_tkTreeVar_[i_rawId].subdetId) {
           case PixelSubdetector::PixelBarrel:
           case PixelSubdetector::PixelEndcap:
             isPixel = true;
             break;
           case StripSubdetector::TIB:
           case StripSubdetector::TOB:
           case StripSubdetector::TID:
           case StripSubdetector::TEC:
             isStrip = true;
             break;
         }
       }
 
       if(isPixel && isStrip){
         edm::LogError("SectorBuilder")<<"Incorrect Sector Definition: there are pixel and strip modules within one sector"
                                      <<"\n... sector selection is not applied, sector "<<sectorCounter<<" is not built";
         continue;
       }
       tkSector.isPixel = isPixel;
     
       m_tkSector_[sectorCounter] = tkSector;
       edm::LogInfo("SectorBuilder")<<"There are "<<tkSector.v_rawId.size()<<" Modules in Sector "<<sectorCounter;
   }
   this->statistics(allSectors, nModules);
   return;
 }

void ApeEstimator::setHitSelectionMap ( const std::string & cutVariable )

private

Definition at line 1610 of file ApeEstimator.cc.

References edm::ParameterSet::getParameter(), m_hitSelection_, and parameterSet_.

Referenced by hitSelection().

                                                             {
   edm::ParameterSet parSet(parameterSet_.getParameter<edm::ParameterSet>("HitSelector"));
   std::vector<double> v_cutVariable(parSet.getParameter<std::vector<double> >(cutVariable));
   if(v_cutVariable.size()%2==1){
     edm::LogError("HitSelector")<<"Invalid Hit Selection for "<<cutVariable<<": need even number of arguments (intervals)"
                                 <<"\n ... delete Selection for "<<cutVariable;
     v_cutVariable.clear();
     m_hitSelection_[cutVariable] = v_cutVariable;
     return;
   }
   m_hitSelection_[cutVariable] = v_cutVariable;
   return;
 }

void ApeEstimator::setHitSelectionMapUInt ( const std::string & cutVariable )

private

Definition at line 1626 of file ApeEstimator.cc.

References edm::ParameterSet::getParameter(), m_hitSelectionUInt_, and parameterSet_.

Referenced by hitSelection().

                                                                 {
   edm::ParameterSet parSet(parameterSet_.getParameter<edm::ParameterSet>("HitSelector"));
   std::vector<unsigned int> v_cutVariable(parSet.getParameter<std::vector<unsigned int> >(cutVariable));
   if(v_cutVariable.size()%2==1){
     edm::LogError("HitSelector")<<"Invalid Hit Selection for "<<cutVariable<<": need even number of arguments (intervals)"
                                 <<"\n ... delete Selection for "<<cutVariable;
     v_cutVariable.clear();
     m_hitSelectionUInt_[cutVariable] = v_cutVariable;
     return;
   }
   m_hitSelectionUInt_[cutVariable] = v_cutVariable;
   return;
 }

void ApeEstimator::statistics	(	const TrackerSectorStruct &	allSectors,
		const int	nModules
	)		const

private

Definition at line 503 of file ApeEstimator.cc.

References m_tkSector_, and TrackerSectorStruct::v_rawId.

Referenced by sectorBuilder().

                                                                                       {
   bool commonModules(false);
   for(std::map<unsigned int,TrackerSectorStruct>::const_iterator i_sector = m_tkSector_.begin(); i_sector != m_tkSector_.end(); ++i_sector){
     std::map<unsigned int,TrackerSectorStruct>::const_iterator i_sector2(i_sector);
     for(++i_sector2; i_sector2 != m_tkSector_.end(); ++i_sector2){
       unsigned int nCommonModules(0);
       for(auto const & i_module : (*i_sector).second.v_rawId){
         for(auto const & i_module2 : (*i_sector2).second.v_rawId){
           if(i_module2 == i_module) ++nCommonModules;
         }
       }
       if(nCommonModules==0)
         ;//edm::LogInfo("SectorBuilder")<<"Sector "<<(*i_sector).first<<" and Sector "<<(*i_sector2).first<< " have ZERO Modules in common";
       else{
         edm::LogError("SectorBuilder")<<"Sector "<<(*i_sector).first<<" and Sector "<<(*i_sector2).first<< " have "<<nCommonModules<<" Modules in common";
         commonModules = true;
       }
     }
   }
   if(static_cast<int>(allSectors.v_rawId.size())==nModules)
     edm::LogInfo("SectorBuilder")<<"ALL Tracker Modules are contained in the Sectors";
   else
     edm::LogWarning("SectorBuilder")<<"There are "<<allSectors.v_rawId.size()<<" Modules in all Sectors"
                                <<" out of "<<nModules<<" Tracker Modules";
   if(!commonModules)
     edm::LogInfo("SectorBuilder")<<"There are ZERO modules associated to different sectors, no ambiguities exist";
   else
   edm::LogError("SectorBuilder")<<"There are modules associated to different sectors, APE value cannot be assigned reasonably";
 }

Member Data Documentation

const bool ApeEstimator::analyzerMode_

private

Definition at line 207 of file ApeEstimator.cc.

Referenced by analyze(), and beginJob().

const bool ApeEstimator::calculateApe_

private

Definition at line 209 of file ApeEstimator.cc.

Referenced by analyze(), beginJob(), endJob(), and fillHistsForApeCalculation().

unsigned int ApeEstimator::counter1

private

Definition at line 211 of file ApeEstimator.cc.

Referenced by ApeEstimator(), endJob(), and fillHitVariables().

unsigned int ApeEstimator::counter2

private

Definition at line 211 of file ApeEstimator.cc.

Referenced by ApeEstimator().

unsigned int ApeEstimator::counter3

private

Definition at line 211 of file ApeEstimator.cc.

Referenced by ApeEstimator().

unsigned int ApeEstimator::counter4

private

Definition at line 211 of file ApeEstimator.cc.

Referenced by ApeEstimator().

unsigned int ApeEstimator::counter5

private

Definition at line 211 of file ApeEstimator.cc.

Referenced by ApeEstimator().

unsigned int ApeEstimator::counter6

private

Definition at line 211 of file ApeEstimator.cc.

Referenced by ApeEstimator().

std::map<std::string,std::vector<double> > ApeEstimator::m_hitSelection_

private

Definition at line 199 of file ApeEstimator.cc.

Referenced by hitSelected(), hitSelection(), and setHitSelectionMap().

std::map<std::string,std::vector<unsigned int> > ApeEstimator::m_hitSelectionUInt_

private

Definition at line 200 of file ApeEstimator.cc.

Referenced by hitSelected(), hitSelection(), and setHitSelectionMapUInt().

std::map<unsigned int, std::pair<double,double> > ApeEstimator::m_resErrBins_

private

Definition at line 196 of file ApeEstimator.cc.

Referenced by bookSectorHistsForApeCalculation(), fillHistsForApeCalculation(), and residualErrorBinning().

std::map<unsigned int, TrackerSectorStruct> ApeEstimator::m_tkSector_

private

Definition at line 189 of file ApeEstimator.cc.

Referenced by bookSectorHistsForAnalyzerMode(), bookSectorHistsForApeCalculation(), calculateAPE(), fillHistsForAnalyzerMode(), fillHistsForApeCalculation(), fillHitVariables(), sectorBuilder(), and statistics().

std::map<unsigned int, ReducedTrackerTreeVariables> ApeEstimator::m_tkTreeVar_

private

Definition at line 197 of file ApeEstimator.cc.

Referenced by fillHitVariables(), positionAndError2(), and sectorBuilder().

const unsigned int ApeEstimator::maxTracksPerEvent_

private

Definition at line 204 of file ApeEstimator.cc.

Referenced by analyze().

const unsigned int ApeEstimator::minGoodHitsPerTrack_

private

Definition at line 205 of file ApeEstimator.cc.

Referenced by fillHistsForAnalyzerMode(), and fillHistsForApeCalculation().

edm::EDGetTokenT<reco::BeamSpot> ApeEstimator::offlinebeamSpot_

private

Definition at line 193 of file ApeEstimator.cc.

Referenced by analyze().

const edm::ParameterSet ApeEstimator::parameterSet_

private

Definition at line 188 of file ApeEstimator.cc.

Referenced by bookSectorHistsForAnalyzerMode(), bookSectorHistsForApeCalculation(), bookTrackHists(), fillHistsForAnalyzerMode(), fillHistsForApeCalculation(), fillTrackVariables(), residualErrorBinning(), sectorBuilder(), setHitSelectionMap(), and setHitSelectionMapUInt().

edm::EDGetTokenT<TrajTrackAssociationCollection> ApeEstimator::tjTagToken_

private

Definition at line 192 of file ApeEstimator.cc.

Referenced by analyze().

TrackerDetectorStruct ApeEstimator::tkDetector_

private

Definition at line 190 of file ApeEstimator.cc.

Referenced by analyze(), bookTrackHists(), and fillHistsForAnalyzerMode().

bool ApeEstimator::trackCut_

private

Definition at line 202 of file ApeEstimator.cc.

Referenced by analyze(), and fillTrackVariables().

Classes

Public Member Functions

Private Types

Private Member Functions

Private Attributes

Additional Inherited Members

Detailed Description

Member Typedef Documentation

Constructor & Destructor Documentation

Member Function Documentation

Member Data Documentation