analyzer::SiPixelLorentzAngle Class Reference

#include <SiPixelLorentzAngle.h>

Inheritance diagram for analyzer::SiPixelLorentzAngle:

Public Member Functions
virtual void	analyze (const edm::Event &e, const edm::EventSetup &c)
virtual void	beginJob ()
virtual void	endJob ()
	SiPixelLorentzAngle (const edm::ParameterSet &conf)
virtual	~SiPixelLorentzAngle ()
Public Member Functions inherited from edm::EDAnalyzer
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)
	EDAnalyzer ()
ModuleDescription const &	moduleDescription () const
std::string	workerType () const
virtual	~EDAnalyzer ()
Public Member Functions inherited from edm::EDConsumerBase
std::vector< ConsumesInfo >	consumesInfo () const
	EDConsumerBase ()
ProductHolderIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const
void	itemsMayGet (BranchType, std::vector< ProductHolderIndexAndSkipBit > &) const
void	itemsToGet (BranchType, std::vector< ProductHolderIndexAndSkipBit > &) const
std::vector < ProductHolderIndexAndSkipBit > const &	itemsToGetFromEvent () const
void	labelsForToken (EDGetToken iToken, Labels &oLabels) const
void	modulesDependentUpon (const std::string &iProcessName, std::vector< const char * > &oModuleLabels) const
void	modulesWhoseProductsAreConsumed (std::vector< ModuleDescription const * > &modules, ProductRegistry const &preg, std::map< std::string, ModuleDescription const * > const &labelsToDesc, std::string const &processName) const
bool	registeredToConsume (ProductHolderIndex, bool, BranchType) const
bool	registeredToConsumeMany (TypeID const &, BranchType) const
void	updateLookup (BranchType iBranchType, ProductHolderIndexHelper const &)
virtual	~EDConsumerBase ()

Private Member Functions
void	fillPix (const SiPixelCluster &LocPix, const PixelTopology *topol, Pixinfo &pixinfo)
void	findMean (int i, int i_ring)

Private Attributes
std::map< int, TH2F * >	_h_drift_depth_
std::map< int, TH2F * >	_h_drift_depth_adc2_
std::map< int, TH2F * >	_h_drift_depth_adc_
std::map< int, TH2F * >	_h_drift_depth_noadc_
std::map< int, TH1F * >	_h_mean_
int	bladeF_
double	chi2_
double	chi2F_
Clust	clust_
double	clustChargeMax_
Clust	clustF_
int	clustSizeYMin_
edm::ParameterSet	conf_
int	diskF_
float	eta_
float	etaF_
int	event_
int	event_counter_
int	eventF_
std::string	filename_
std::string	filenameFit_
TH2F *	h_cluster_shape_
TH2F *	h_cluster_shape_adc_
TH2F *	h_cluster_shape_adc_rot_
TH2F *	h_cluster_shape_noadc_
TH2F *	h_cluster_shape_noadc_rot_
TH2F *	h_cluster_shape_rot_
TH1F *	h_drift_depth_adc_slice_
TH1F *	h_tracks_
TFile *	hFile_
int	hist_depth_
int	hist_drift_
int	hist_x_
int	hist_y_
int	hitCounter_
int	isflipped_
int	ladder_
int	layer_
const MagneticField *	magfield
double	max_depth_
double	max_drift_
double	max_x_
double	max_y_
double	min_depth_
double	min_drift_
double	min_x_
double	min_y_
int	module_
int	moduleF_
double	ndof_
double	ndofF_
double	normChi2Max_
int	panelF_
float	phi_
float	phiF_
int	pixelTracksCounter_
Pixinfo	pixinfo_
Pixinfo	pixinfoF_
float	pt_
float	ptF_
double	ptmin_
Rechit	rechit_
Rechit	rechitF_
double	residualMax_
const TransientTrackingRecHitBuilder *	RHBuilder
int	run_
int	runF_
int	sideF_
bool	simData_
Hit	simhit_
Hit	simhitF_
TTree *	SiPixelLorentzAngleTree_
TTree *	SiPixelLorentzAngleTreeForward_
edm::EDGetTokenT < TrajTrackAssociationCollection >	t_trajTrack
Chi2MeasurementEstimator *	theEstimator
const KFTrajectoryFitter *	theFitter
PropagatorWithMaterial *	thePropagator
PropagatorWithMaterial *	thePropagatorOp
const KFTrajectorySmoother *	theSmoother
KFUpdator *	theUpdator
const TrackerGeometry *	tracker
int	trackEventsCounter_
Hit	trackhit_
Hit	trackhitF_
TrajectoryStateTransform	tsTransform
int	usedHitCounter_
double	width_

Additional Inherited Members
Public Types inherited from edm::EDAnalyzer
typedef EDAnalyzer	ModuleType
Static Public Member Functions inherited from edm::EDAnalyzer
static const std::string &	baseType ()
static void	fillDescriptions (ConfigurationDescriptions &descriptions)
static void	prevalidate (ConfigurationDescriptions &)
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

Definition at line 88 of file SiPixelLorentzAngle.h.

Constructor & Destructor Documentation

SiPixelLorentzAngle::SiPixelLorentzAngle ( const edm::ParameterSet &  conf )

explicit

Definition at line 40 of file SiPixelLorentzAngle.cc.

References edm::ParameterSet::getParameter(), hist_x_, hist_y_, max_depth_, max_drift_, max_x_, max_y_, min_depth_, min_drift_, min_x_, min_y_, t_trajTrack, and width_.

                                                                    : 
  conf_(conf), filename_(conf.getParameter<std::string>("fileName")), filenameFit_(conf.getParameter<std::string>("fileNameFit")), ptmin_(conf.getParameter<double>("ptMin")), simData_(conf.getParameter<bool>("simData")),    normChi2Max_(conf.getParameter<double>("normChi2Max")), clustSizeYMin_(conf.getParameter<int>("clustSizeYMin")), residualMax_(conf.getParameter<double>("residualMax")), clustChargeMax_(conf.getParameter<double>("clustChargeMax")),hist_depth_(conf.getParameter<int>("binsDepth")), hist_drift_(conf.getParameter<int>("binsDrift"))
{
  //    anglefinder_=new  TrackLocalAngle(conf);
  hist_x_ = 50;
  hist_y_ = 100;
  min_x_ = -500.;
  max_x_ = 500.;
  min_y_ = -1500.;
  max_y_ = 500.;
  width_ = 0.0285;
  min_depth_ = -100.;
  max_depth_ = 400.;
  min_drift_ = -1000.; //-200.;(conf.getParameter<double>("residualMax"))
  max_drift_ = 1000.; //400.;

  t_trajTrack = consumes<TrajTrackAssociationCollection> (conf.getParameter<edm::InputTag>("src"));

}

SiPixelLorentzAngle::~SiPixelLorentzAngle ( )

virtual

Definition at line 61 of file SiPixelLorentzAngle.cc.

{  }  

Member Function Documentation

void SiPixelLorentzAngle::analyze ( const edm::Event &  e, const edm::EventSetup &  c  )

virtual

Implements edm::EDAnalyzer.

Definition at line 156 of file SiPixelLorentzAngle.cc.

References _h_drift_depth_adc2_, _h_drift_depth_adc_, _h_drift_depth_noadc_, Pixinfo::adc, Hit::alpha, TrackerHitAssociator::associateHit(), Hit::beta, bladeF_, Clust::charge, chi2_, Trajectory::chiSquared(), clust_, clustChargeMax_, SiPixelRecHit::cluster(), clustF_, clustSizeYMin_, Pixinfo::col, edm::AssociationMap< edm::OneToOne< std::vector< Trajectory >, reco::TrackCollection, unsigned short > >::const_iterator, gather_cfg::cout, HLT_25ns14e33_v1_cff::depth, diskF_, shallow::drift(), reco::TrackBase::eta(), eta_, edm::EventID::event(), event_, event_counter_, HcalObjRepresent::Fill(), fillPix(), Hit::gamma, edm::EventSetup::get(), edm::Event::getByToken(), h_cluster_shape_adc_, h_cluster_shape_adc_rot_, h_cluster_shape_noadc_, h_cluster_shape_noadc_rot_, h_tracks_, hitCounter_, edm::EventBase::id(), TrackerGeometry::idToDet(), isflipped_, TrajectoryStateOnSurface::isValid(), j, ladder_, layer_, TrajectoryStateOnSurface::localDirection(), BaseTrackerRecHit::localPosition(), TrajectoryStateOnSurface::localPosition(), Clust::maxPixelCol, Clust::maxPixelRow, Trajectory::measurements(), Clust::minPixelCol, Clust::minPixelRow, module_, moduleF_, Trajectory::ndof(), ndof_, normChi2Max_, Pixinfo::npix, panelF_, PV3DBase< T, PVType, FrameType >::perp(), reco::TrackBase::phi(), phi_, PixelSubdetector::PixelBarrel, PixelSubdetector::PixelEndcap, pixelTracksCounter_, pixinfo_, pixinfoF_, edm::ESHandle< class >::product(), reco::TrackBase::pt(), pt_, ptmin_, TrackerTopology::pxbLadder(), TrackerTopology::pxbLayer(), TrackerTopology::pxbModule(), TrackerTopology::pxfBlade(), TrackerTopology::pxfDisk(), TrackerTopology::pxfModule(), TrackerTopology::pxfPanel(), TrackerTopology::pxfSide(), rechit_, rechitF_, residualMax_, Pixinfo::row, edm::EventID::run(), run_, sideF_, simData_, simhit_, simhitF_, SiPixelLorentzAngleTree_, SiPixelLorentzAngleTreeForward_, Clust::size_x, Clust::size_y, PixelGeomDetUnit::specificTopology(), GeomDet::surface(), t_trajTrack, funct::tan(), Surface::toGlobal(), DetId::Tracker, tracker, trackEventsCounter_, trackhit_, trackhitF_, usedHitCounter_, width_, x, Pixinfo::x, Hit::x, PV3DBase< T, PVType, FrameType >::x(), Clust::x, Rechit::x, detailsBasic3DVector::y, Pixinfo::y, Hit::y, PV3DBase< T, PVType, FrameType >::y(), Clust::y, Rechit::y, and PV3DBase< T, PVType, FrameType >::z().

{
  //Retrieve tracker topology from geometry
  edm::ESHandle<TrackerTopology> tTopoHandle;
  es.get<IdealGeometryRecord>().get(tTopoHandle);
  const TrackerTopology* const tTopo = tTopoHandle.product();
  
  event_counter_++;
  //    if(event_counter_ % 500 == 0) cout << "event number " << event_counter_ << endl;
  cout << "event number " << event_counter_ << endl;

  edm::ESHandle<TrackerGeometry> estracker;
  es.get<TrackerDigiGeometryRecord>().get(estracker);
  tracker=&(* estracker);

  TrackerHitAssociator* associate;
  if(simData_) associate = new TrackerHitAssociator(e); else associate = 0; 
  // restet values
  module_=-1;
  layer_=-1;
  ladder_ = -1;
  isflipped_ = -1;
  pt_ = -999;
  eta_ = 999;
  phi_ = 999;
  pixinfo_.npix = 0;

  run_       = e.id().run();
  event_     = e.id().event();
    
  // get the association map between tracks and trajectories
  edm::Handle<TrajTrackAssociationCollection> trajTrackCollectionHandle;
  e.getByToken(t_trajTrack,trajTrackCollectionHandle);
  if(trajTrackCollectionHandle->size() >0){
    trackEventsCounter_++;
    for(TrajTrackAssociationCollection::const_iterator it = trajTrackCollectionHandle->begin(); it!=trajTrackCollectionHandle->end();++it){
      const Track&      track = *it->val;
      const Trajectory& traj  = *it->key;
        
      // get the trajectory measurements
      std::vector<TrajectoryMeasurement> tmColl = traj.measurements(); 
      //            TrajectoryStateOnSurface tsos = tsoscomb( itTraj->forwardPredictedState(), itTraj->backwardPredictedState() );
      pt_ = track.pt();
      eta_ = track.eta();
      phi_ = track.phi();
      chi2_ = traj.chiSquared();
      ndof_ = traj.ndof();
      if(pt_ < ptmin_) continue;
      // iterate over trajectory measurements
      std::vector<PSimHit> matched;
      h_tracks_->Fill(0);
      bool pixeltrack = false;
      for(std::vector<TrajectoryMeasurement>::const_iterator itTraj = tmColl.begin(); itTraj != tmColl.end(); itTraj++) {
    if(! itTraj->updatedState().isValid()) continue;
    TransientTrackingRecHit::ConstRecHitPointer recHit = itTraj->recHit();
    if(! recHit->isValid() || recHit->geographicalId().det() != DetId::Tracker ) continue;
    unsigned int subDetID = (recHit->geographicalId().subdetId());
    if( subDetID == PixelSubdetector::PixelBarrel || subDetID == PixelSubdetector::PixelEndcap){
      if(!pixeltrack){
        h_tracks_->Fill(1);
        pixelTracksCounter_++;
      }
      pixeltrack = true;
    }
    if( subDetID == PixelSubdetector::PixelBarrel){
                
      hitCounter_++;
                
      DetId detIdObj = recHit->geographicalId();
      const PixelGeomDetUnit * theGeomDet = dynamic_cast<const PixelGeomDetUnit*> ( tracker->idToDet(detIdObj) );
      if(!theGeomDet) continue;

      const PixelTopology * topol = &(theGeomDet->specificTopology());

      if(!topol) continue;
      
      layer_ = tTopo->pxbLayer(detIdObj);
      ladder_ = tTopo->pxbLadder(detIdObj);
      module_ = tTopo->pxbModule(detIdObj);
      float tmp1 = theGeomDet->surface().toGlobal(Local3DPoint(0.,0.,0.)).perp();
      float tmp2 = theGeomDet->surface().toGlobal(Local3DPoint(0.,0.,1.)).perp();
      if ( tmp2<tmp1 ) isflipped_ = 1;
      else isflipped_ = 0;
      const SiPixelRecHit * recHitPix = dynamic_cast<const SiPixelRecHit *>((*recHit).hit());
      if(!recHitPix) continue;
      rechit_.x  = recHitPix->localPosition().x();
      rechit_.y  = recHitPix->localPosition().y();
      SiPixelRecHit::ClusterRef const& cluster = recHitPix->cluster();  
    
      // fill entries in clust_
      clust_.x = (cluster)->x();
      clust_.y = (cluster)->y();
      clust_.charge = (cluster->charge())/1000.;
      clust_.size_x = cluster->sizeX();
      clust_.size_y = cluster->sizeY();
      clust_.maxPixelCol = cluster->maxPixelCol();
      clust_.maxPixelRow = cluster->maxPixelRow();
      clust_.minPixelCol = cluster->minPixelCol();
      clust_.minPixelRow = cluster->minPixelRow();
      // fill entries in pixinfo_:
      fillPix(*cluster ,topol, pixinfo_);
      // fill the trackhit info
      TrajectoryStateOnSurface tsos=itTraj->updatedState();
      if(!tsos.isValid()){
        cout << "tsos not valid" << endl;
        continue;   
      } 
      LocalVector trackdirection=tsos.localDirection();
      LocalPoint trackposition=tsos.localPosition();
    
      if(trackdirection.z()==0) continue;               
      // the local position and direction
      trackhit_.alpha = atan2(trackdirection.z(),trackdirection.x());
      trackhit_.beta = atan2(trackdirection.z(),trackdirection.y());
      trackhit_.gamma = atan2(trackdirection.x(),trackdirection.y());
      trackhit_.x = trackposition.x();
      trackhit_.y = trackposition.y();
                    
    
      // fill entries in simhit_:   
      if(simData_){
        matched.clear();        
        matched = associate->associateHit((*recHitPix));    
        float dr_start=9999.;
        for (std::vector<PSimHit>::iterator isim = matched.begin(); isim != matched.end(); ++isim){
          DetId simdetIdObj((*isim).detUnitId());
          if (simdetIdObj == detIdObj) {
        float sim_x1 = (*isim).entryPoint().x(); // width (row index, in col direction)
        float sim_y1 = (*isim).entryPoint().y(); // length (col index, in row direction)
        float sim_x2 = (*isim).exitPoint().x();
        float sim_y2 = (*isim).exitPoint().y();
        float sim_xpos = 0.5*(sim_x1+sim_x2);
        float sim_ypos = 0.5*(sim_y1+sim_y2);
        float sim_px = (*isim).momentumAtEntry().x();
        float sim_py = (*isim).momentumAtEntry().y();
        float sim_pz = (*isim).momentumAtEntry().z();
                        
        float dr = (sim_xpos-(recHitPix->localPosition().x()))*(sim_xpos-recHitPix->localPosition().x()) +
          (sim_ypos-recHitPix->localPosition().y())*(sim_ypos-recHitPix->localPosition().y());
        if(dr<dr_start) {
          simhit_.x     = sim_xpos;
          simhit_.y     = sim_ypos;
          simhit_.alpha = atan2(sim_pz, sim_px);
          simhit_.beta  = atan2(sim_pz, sim_py);
          simhit_.gamma = atan2(sim_px, sim_py);
          dr_start = dr;
        }
          }
        } // end of filling simhit_
      }
      // is one pixel in cluster a large pixel ? (hit will be excluded)
      bool large_pix = false;
      for (int j = 0; j <  pixinfo_.npix; j++){
        int colpos = static_cast<int>(pixinfo_.col[j]);
        if (pixinfo_.row[j] == 0 || pixinfo_.row[j] == 79 || pixinfo_.row[j] == 80 || pixinfo_.row[j] == 159 || colpos % 52 == 0 || colpos % 52 == 51 ){
          large_pix = true; 
        }
      }
                    
      double residual = TMath::Sqrt( (trackhit_.x - rechit_.x) * (trackhit_.x - rechit_.x) + (trackhit_.y - rechit_.y) * (trackhit_.y - rechit_.y) );
    
      SiPixelLorentzAngleTree_->Fill();
      if( !large_pix && (chi2_/ndof_) < normChi2Max_ && cluster->sizeY() >= clustSizeYMin_ && residual < residualMax_ && (cluster->charge() < clustChargeMax_)){
        usedHitCounter_++;
        // iterate over pixels in hit
        for (int j = 0; j <  pixinfo_.npix; j++){
          // use trackhits
          float dx = (pixinfo_.x[j]  - (trackhit_.x - width_/2. / TMath::Tan(trackhit_.alpha))) * 10000.;
          float dy = (pixinfo_.y[j]  - (trackhit_.y - width_/2. / TMath::Tan(trackhit_.beta))) * 10000.;
          float depth = dy * tan(trackhit_.beta);
          float drift = dx - dy * tan(trackhit_.gamma);
          _h_drift_depth_adc_[module_ + (layer_ -1) * 8]->Fill(drift, depth, pixinfo_.adc[j]);
          _h_drift_depth_adc2_[module_ + (layer_ -1) * 8]->Fill(drift, depth, pixinfo_.adc[j]*pixinfo_.adc[j]);
          _h_drift_depth_noadc_[module_ + (layer_ -1) * 8]->Fill(drift, depth);     
          if( layer_ == 3 && module_==1 && isflipped_){
        float dx_rot = dx * TMath::Cos(trackhit_.gamma) + dy * TMath::Sin(trackhit_.gamma);
        float dy_rot = dy * TMath::Cos(trackhit_.gamma) - dx * TMath::Sin(trackhit_.gamma) ;
        h_cluster_shape_adc_->Fill(dx, dy, pixinfo_.adc[j]);
        h_cluster_shape_noadc_->Fill(dx, dy);
        h_cluster_shape_adc_rot_->Fill(dx_rot, dy_rot, pixinfo_.adc[j]);
        h_cluster_shape_noadc_rot_->Fill(dx_rot, dy_rot);
          }
        }
      }
    } else if (subDetID == PixelSubdetector::PixelEndcap) {
      DetId detIdObj = recHit->geographicalId();
      const PixelGeomDetUnit * theGeomDet = dynamic_cast<const PixelGeomDetUnit*> ( tracker->idToDet(detIdObj) );
      if(!theGeomDet) continue;
      
      const PixelTopology * topol = &(theGeomDet->specificTopology());

      if(!topol) continue;
      
      sideF_ = tTopo->pxfSide(detIdObj);
      diskF_ = tTopo->pxfDisk(detIdObj);
      bladeF_ = tTopo->pxfBlade(detIdObj);
      panelF_ = tTopo->pxfPanel(detIdObj);
      moduleF_ = tTopo->pxfModule(detIdObj);
      //                    float tmp1 = theGeomDet->surface().toGlobal(Local3DPoint(0.,0.,0.)).perp();
      //                    float tmp2 = theGeomDet->surface().toGlobal(Local3DPoint(0.,0.,1.)).perp();
      //                    if ( tmp2<tmp1 ) isflipped_ = 1;
      //                    else isflipped_ = 0;
      const SiPixelRecHit * recHitPix = dynamic_cast<const SiPixelRecHit *>((*recHit).hit());
      if(!recHitPix) continue;
      rechitF_.x  = recHitPix->localPosition().x();
      rechitF_.y  = recHitPix->localPosition().y();
      SiPixelRecHit::ClusterRef const& cluster = recHitPix->cluster();  
    
      // fill entries in clust_
      clustF_.x = (cluster)->x();
      clustF_.y = (cluster)->y();
      clustF_.charge = (cluster->charge())/1000.;
      clustF_.size_x = cluster->sizeX();
      clustF_.size_y = cluster->sizeY();
      clustF_.maxPixelCol = cluster->maxPixelCol();
      clustF_.maxPixelRow = cluster->maxPixelRow();
      clustF_.minPixelCol = cluster->minPixelCol();
      clustF_.minPixelRow = cluster->minPixelRow();
      // fill entries in pixinfo_:
      fillPix(*cluster ,topol, pixinfoF_);
      // fill the trackhit info
      TrajectoryStateOnSurface tsos=itTraj->updatedState();
      if(!tsos.isValid()){
        cout << "tsos not valid" << endl;
        continue;   
      } 
      LocalVector trackdirection=tsos.localDirection();
      LocalPoint trackposition=tsos.localPosition();
    
      if(trackdirection.z()==0) continue;               
      // the local position and direction
      trackhitF_.alpha = atan2(trackdirection.z(),trackdirection.x());
      trackhitF_.beta = atan2(trackdirection.z(),trackdirection.y());
      trackhitF_.gamma = atan2(trackdirection.x(),trackdirection.y());
      trackhitF_.x = trackposition.x();
      trackhitF_.y = trackposition.y();
                    
    
      // fill entries in simhit_:   
      if(simData_){
        matched.clear();        
        matched = associate->associateHit((*recHitPix));    
        float dr_start=9999.;
        for (std::vector<PSimHit>::iterator isim = matched.begin(); isim != matched.end(); ++isim){
          DetId simdetIdObj((*isim).detUnitId());
          if (simdetIdObj == detIdObj) {
        float sim_x1 = (*isim).entryPoint().x(); // width (row index, in col direction)
        float sim_y1 = (*isim).entryPoint().y(); // length (col index, in row direction)
        float sim_x2 = (*isim).exitPoint().x();
        float sim_y2 = (*isim).exitPoint().y();
        float sim_xpos = 0.5*(sim_x1+sim_x2);
        float sim_ypos = 0.5*(sim_y1+sim_y2);
        float sim_px = (*isim).momentumAtEntry().x();
        float sim_py = (*isim).momentumAtEntry().y();
        float sim_pz = (*isim).momentumAtEntry().z();
                        
        float dr = (sim_xpos-(recHitPix->localPosition().x()))*(sim_xpos-recHitPix->localPosition().x()) +
          (sim_ypos-recHitPix->localPosition().y())*(sim_ypos-recHitPix->localPosition().y());
        if(dr<dr_start) {
          simhitF_.x     = sim_xpos;
          simhitF_.y     = sim_ypos;
          simhitF_.alpha = atan2(sim_pz, sim_px);
          simhitF_.beta  = atan2(sim_pz, sim_py);
          simhitF_.gamma = atan2(sim_px, sim_py);
          dr_start = dr;
        }
          }
        } // end of filling simhit_
      }
      SiPixelLorentzAngleTreeForward_->Fill();
    }
      } //end iteration over trajectory measurements
    } //end iteration over trajectories
  }

    
    
    
    
}

void SiPixelLorentzAngle::beginJob ( void  )

virtual

Reimplemented from edm::EDAnalyzer.

Definition at line 63 of file SiPixelLorentzAngle.cc.

References _h_drift_depth_, _h_drift_depth_adc2_, _h_drift_depth_adc_, _h_drift_depth_noadc_, _h_mean_, Pixinfo::adc, bladeF_, chi2_, clust_, clustF_, Pixinfo::col, diskF_, eta_, event_, event_counter_, filename_, h_cluster_shape_, h_cluster_shape_adc_, h_cluster_shape_adc_rot_, h_cluster_shape_noadc_, h_cluster_shape_noadc_rot_, h_cluster_shape_rot_, h_tracks_, hFile_, hist_depth_, hist_drift_, hist_x_, hist_y_, hitCounter_, isflipped_, ladder_, layer_, max_depth_, max_drift_, max_x_, max_y_, min_depth_, min_drift_, min_x_, min_y_, module_, moduleF_, mergeVDriftHistosByStation::name, ndof_, Pixinfo::npix, panelF_, phi_, pixelTracksCounter_, pixinfo_, pixinfoF_, pt_, rechit_, rechitF_, Pixinfo::row, run_, sideF_, simhit_, simhitF_, SiPixelLorentzAngleTree_, SiPixelLorentzAngleTreeForward_, trackEventsCounter_, trackhit_, trackhitF_, usedHitCounter_, Pixinfo::x, and Pixinfo::y.

{

  //    cout << "started SiPixelLorentzAngle" << endl;
  hFile_ = new TFile (filename_.c_str(), "RECREATE" );
  int bufsize = 64000;
  // create tree structure
  SiPixelLorentzAngleTree_ = new TTree("SiPixelLorentzAngleTree_","SiPixel LorentzAngle tree", bufsize);
  SiPixelLorentzAngleTree_->Branch("run", &run_, "run/I", bufsize);
  SiPixelLorentzAngleTree_->Branch("event", &event_, "event/I", bufsize);
  SiPixelLorentzAngleTree_->Branch("module", &module_, "module/I", bufsize);
  SiPixelLorentzAngleTree_->Branch("ladder", &ladder_, "ladder/I", bufsize);
  SiPixelLorentzAngleTree_->Branch("layer", &layer_, "layer/I", bufsize);
  SiPixelLorentzAngleTree_->Branch("isflipped", &isflipped_, "isflipped/I", bufsize);
  SiPixelLorentzAngleTree_->Branch("pt", &pt_, "pt/F", bufsize);
  SiPixelLorentzAngleTree_->Branch("eta", &eta_, "eta/F", bufsize);
  SiPixelLorentzAngleTree_->Branch("phi", &phi_, "phi/F", bufsize);
  SiPixelLorentzAngleTree_->Branch("chi2", &chi2_, "chi2/D", bufsize);
  SiPixelLorentzAngleTree_->Branch("ndof", &ndof_, "ndof/D", bufsize);
  SiPixelLorentzAngleTree_->Branch("trackhit", &trackhit_, "x/F:y/F:alpha/D:beta/D:gamma_/D", bufsize);
  SiPixelLorentzAngleTree_->Branch("simhit", &simhit_, "x/F:y/F:alpha/D:beta/D:gamma_/D", bufsize);
  SiPixelLorentzAngleTree_->Branch("npix", &pixinfo_.npix, "npix/I", bufsize);
  SiPixelLorentzAngleTree_->Branch("rowpix", pixinfo_.row, "row[npix]/F", bufsize);
  SiPixelLorentzAngleTree_->Branch("colpix", pixinfo_.col, "col[npix]/F", bufsize);
  SiPixelLorentzAngleTree_->Branch("adc", pixinfo_.adc, "adc[npix]/F", bufsize);
  SiPixelLorentzAngleTree_->Branch("xpix", pixinfo_.x, "x[npix]/F", bufsize);
  SiPixelLorentzAngleTree_->Branch("ypix", pixinfo_.y, "y[npix]/F", bufsize);
  SiPixelLorentzAngleTree_->Branch("clust", &clust_, "x/F:y/F:charge/F:size_x/I:size_y/I:maxPixelCol/I:maxPixelRow:minPixelCol/I:minPixelRow/I", bufsize);
  SiPixelLorentzAngleTree_->Branch("rechit", &rechit_, "x/F:y/F", bufsize);
    
  SiPixelLorentzAngleTreeForward_ = new TTree("SiPixelLorentzAngleTreeForward_","SiPixel LorentzAngle tree forward", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("run", &run_, "run/I", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("event", &event_, "event/I", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("side", &sideF_, "side/I", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("disk", &diskF_, "disk/I", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("blade", &bladeF_, "blade/I", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("panel", &panelF_, "panel/I", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("module", &moduleF_, "module/I", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("pt", &pt_, "pt/F", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("eta", &eta_, "eta/F", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("phi", &phi_, "phi/F", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("chi2", &chi2_, "chi2/D", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("ndof", &ndof_, "ndof/D", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("trackhit", &trackhitF_, "x/F:y/F:alpha/D:beta/D:gamma_/D", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("simhit", &simhitF_, "x/F:y/F:alpha/D:beta/D:gamma_/D", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("npix", &pixinfoF_.npix, "npix/I", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("rowpix", pixinfoF_.row, "row[npix]/F", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("colpix", pixinfoF_.col, "col[npix]/F", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("adc", pixinfoF_.adc, "adc[npix]/F", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("xpix", pixinfoF_.x, "x[npix]/F", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("ypix", pixinfoF_.y, "y[npix]/F", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("clust", &clustF_, "x/F:y/F:charge/F:size_x/I:size_y/I:maxPixelCol/I:maxPixelRow:minPixelCol/I:minPixelRow/I", bufsize);
  SiPixelLorentzAngleTreeForward_->Branch("rechit", &rechitF_, "x/F:y/F", bufsize);
    
    
  //book histograms
  char name[128];
  for(int i_module = 1; i_module<=8; i_module++){
    for(int i_layer = 1; i_layer<=3; i_layer++){
      sprintf(name, "h_drift_depth_adc_layer%i_module%i", i_layer, i_module); 
      _h_drift_depth_adc_[i_module + (i_layer -1) * 8] = new TH2F(name,name,hist_drift_ , min_drift_, max_drift_, hist_depth_, min_depth_, max_depth_);
      sprintf(name, "h_drift_depth_adc2_layer%i_module%i", i_layer, i_module); 
      _h_drift_depth_adc2_[i_module + (i_layer -1) * 8] = new TH2F(name,name,hist_drift_ , min_drift_, max_drift_, hist_depth_, min_depth_, max_depth_);
      sprintf(name, "h_drift_depth_noadc_layer%i_module%i", i_layer, i_module); 
      _h_drift_depth_noadc_[i_module + (i_layer -1) * 8] = new TH2F(name,name,hist_drift_ , min_drift_, max_drift_, hist_depth_, min_depth_, max_depth_);
      sprintf(name, "h_drift_depth_layer%i_module%i", i_layer, i_module); 
      _h_drift_depth_[i_module + (i_layer -1) * 8] = new TH2F(name,name,hist_drift_ , min_drift_, max_drift_, hist_depth_, min_depth_, max_depth_);
      sprintf(name, "h_mean_layer%i_module%i", i_layer, i_module); 
      _h_mean_[i_module + (i_layer -1) * 8] = new TH1F(name,name,hist_depth_, min_depth_, max_depth_);
    }
  }
    
  // just for some expaining plots
  h_cluster_shape_adc_  = new TH2F("h_cluster_shape_adc","cluster shape with adc weight", hist_x_, min_x_, max_x_, hist_y_, min_y_, max_y_);
  h_cluster_shape_noadc_  = new TH2F("h_cluster_shape_noadc","cluster shape without adc weight", hist_x_, min_x_, max_x_, hist_y_, min_y_, max_y_);
  h_cluster_shape_  = new TH2F("h_cluster_shape","cluster shape", hist_x_, min_x_, max_x_, hist_y_, min_y_, max_y_);
  h_cluster_shape_adc_rot_  = new TH2F("h_cluster_shape_adc_rot","cluster shape with adc weight", hist_x_, min_x_, max_x_, hist_y_, -max_y_, -min_y_);
  h_cluster_shape_noadc_rot_  = new TH2F("h_cluster_shape_noadc_rot","cluster shape without adc weight", hist_x_, min_x_, max_x_, hist_y_, -max_y_, -min_y_);
  h_cluster_shape_rot_  = new TH2F("h_cluster_shape_rot","cluster shape", hist_x_, min_x_, max_x_, hist_y_, -max_y_, -min_y_);
  h_tracks_ = new TH1F("h_tracks","h_tracks",2,0.,2.);
  event_counter_ = 0;
  trackEventsCounter_ = 0;
  //    trackcounter_ = 0;
  hitCounter_ = 0;
  usedHitCounter_ = 0;
  pixelTracksCounter_ = 0;
//   edm::ESHandle<TrackerGeometry> estracker; //this block should not be in beginJob()
//   c.get<TrackerDigiGeometryRecord>().get(estracker);
//   tracker=&(* estracker);
}

void SiPixelLorentzAngle::endJob ( void  )

virtual

Reimplemented from edm::EDAnalyzer.

Definition at line 437 of file SiPixelLorentzAngle.cc.

References _h_drift_depth_, _h_drift_depth_adc2_, _h_drift_depth_adc_, _h_drift_depth_noadc_, _h_mean_, gather_cfg::cout, event_counter_, python.connectstrParser::f1, filenameFit_, findMean(), h_cluster_shape_adc_, h_cluster_shape_adc_rot_, h_cluster_shape_noadc_, h_cluster_shape_noadc_rot_, h_drift_depth_adc_slice_, h_tracks_, hFile_, hist_depth_, hist_drift_, hitCounter_, i, max_drift_, min_drift_, p1, pixelTracksCounter_, trackEventsCounter_, estimatePileup_makeJSON::trunc, and usedHitCounter_.

{
  // produce histograms with the average adc counts
  for(int i_ring = 1; i_ring<=24; i_ring++){
    _h_drift_depth_[i_ring]->Divide(_h_drift_depth_adc_[i_ring], _h_drift_depth_noadc_[i_ring]);
  }
    
  h_drift_depth_adc_slice_ = new TH1F("h_drift_depth_adc_slice", "slice of adc histogram", hist_drift_ , min_drift_, max_drift_);

  TF1 *f1 = new TF1("f1","[0] + [1]*x",50., 235.); 
  f1->SetParName(0,"p0");
  f1->SetParName(1,"p1");
  f1->SetParameter(0,0);
  f1->SetParameter(1,0.4);
  ofstream fLorentzFit( filenameFit_.c_str(), ios::trunc );
  cout.precision( 4 );
  fLorentzFit << "module" << "\t" << "layer" << "\t" << "offset" << "\t" << "error" << "\t" << "slope" << "\t" << "error" << "\t" "rel.err" << "\t" "pull" << "\t" << "chi2" << "\t" << "prob" << endl;
  //loop over modlues and layers to fit the lorentz angle
  for( int i_layer = 1; i_layer<=3; i_layer++){
    for(int i_module = 1; i_module<=8; i_module++){
      //loop over bins in depth (z-local-coordinate) (in order to fit slices)
      for( int i = 1; i <= hist_depth_; i++){
    findMean(i, (i_module + (i_layer - 1) * 8));    
      }// end loop over bins in depth 
      _h_mean_[i_module + (i_layer - 1) * 8]->Fit(f1,"ERQ");
      double p0 = f1->GetParameter(0);
      double e0 = f1->GetParError(0);
      double p1 = f1->GetParameter(1);
      double e1 = f1->GetParError(1);
      double chi2 = f1->GetChisquare();
      double prob = f1->GetProb();
      fLorentzFit << setprecision( 4 ) << i_module << "\t" << i_layer << "\t" << p0 << "\t" << e0 << "\t" << p1 << setprecision( 3 ) << "\t" << e1 << "\t" << e1 / p1 *100. << "\t"<< (p1 - 0.424) / e1 << "\t"<< chi2 << "\t" << prob << endl;
    }
  } // end loop over modules and layers
  fLorentzFit.close(); 
  hFile_->cd();
  for(int i_module = 1; i_module<=8; i_module++){
    for(int i_layer = 1; i_layer<=3; i_layer++){
      _h_drift_depth_adc_[i_module + (i_layer -1) * 8]->Write();
      _h_drift_depth_adc2_[i_module + (i_layer -1) * 8]->Write();
      _h_drift_depth_noadc_[i_module + (i_layer -1) * 8]->Write();
      _h_drift_depth_[i_module + (i_layer -1) * 8]->Write();
      _h_mean_[i_module + (i_layer -1) * 8]->Write();
    }
  }
  h_cluster_shape_adc_->Write();
  h_cluster_shape_noadc_->Write();
  h_cluster_shape_adc_rot_->Write();
  h_cluster_shape_noadc_rot_->Write();
  h_tracks_->Write();
    
  hFile_->Write();
  hFile_->Close();
  cout << "events: " << event_counter_ << endl;
  cout << "events with tracks: " << trackEventsCounter_ << endl;    
  cout << "events with pixeltracks: " << pixelTracksCounter_ << endl;   
  cout << "hits in the pixel: " << hitCounter_ << endl;
  cout << "number of used Hits: " << usedHitCounter_ << endl;
}

void SiPixelLorentzAngle::fillPix ( const SiPixelCluster &  LocPix, const PixelTopology *  topol, Pixinfo &  pixinfo  )

inlineprivate

Definition at line 497 of file SiPixelLorentzAngle.cc.

References Pixinfo::adc, Pixinfo::col, Topology::localPosition(), Pixinfo::npix, SiPixelCluster::pixels(), Pixinfo::row, Pixinfo::x, PV3DBase< T, PVType, FrameType >::x(), Pixinfo::y, and PV3DBase< T, PVType, FrameType >::y().

Referenced by analyze().

{
  const std::vector<SiPixelCluster::Pixel>& pixvector = LocPix.pixels();
  pixinfo.npix = 0;
  for(std::vector<SiPixelCluster::Pixel>::const_iterator itPix = pixvector.begin(); itPix != pixvector.end(); itPix++){
    //  for(pixinfo.npix = 0; pixinfo.npix < static_cast<int>(pixvector.size()); ++pixinfo.npix) {
    pixinfo.row[pixinfo.npix] = itPix->x;
    pixinfo.col[pixinfo.npix] = itPix->y;
    pixinfo.adc[pixinfo.npix] = itPix->adc;
    LocalPoint lp = topol->localPosition(MeasurementPoint(itPix->x + 0.5, itPix->y+0.5));
    pixinfo.x[pixinfo.npix] = lp.x();
    pixinfo.y[pixinfo.npix]= lp.y();
    pixinfo.npix++;
  }
}

void SiPixelLorentzAngle::findMean ( int  i, int  i_ring  )

private

Definition at line 514 of file SiPixelLorentzAngle.cc.

References _h_drift_depth_, _h_drift_depth_adc2_, _h_drift_depth_adc_, _h_drift_depth_noadc_, _h_mean_, relativeConstraints::error, h_drift_depth_adc_slice_, hist_drift_, j, timingPdfMaker::mean, and mathSSE::sqrt().

Referenced by endJob().

{
  double nentries = 0;
    
  h_drift_depth_adc_slice_->Reset("ICE");
    
  // determine sigma and sigma^2 of the adc counts and average adc counts
  //loop over bins in drift width
  for( int j = 1; j<= hist_drift_; j++){
    if(_h_drift_depth_noadc_[i_ring]->GetBinContent(j, i) >= 1){
      double adc_error2 = (_h_drift_depth_adc2_[i_ring]->GetBinContent(j,i) - _h_drift_depth_adc_[i_ring]->GetBinContent(j,i)*_h_drift_depth_adc_[i_ring]->GetBinContent(j, i) / _h_drift_depth_noadc_[i_ring]->GetBinContent(j, i)) /  _h_drift_depth_noadc_[i_ring]->GetBinContent(j, i);
      _h_drift_depth_adc_[i_ring]->SetBinError(j, i, sqrt(adc_error2));
      double error2 = adc_error2 / (_h_drift_depth_noadc_[i_ring]->GetBinContent(j,i) - 1.);
      _h_drift_depth_[i_ring]->SetBinError(j,i,sqrt(error2));
    } 
    else{
      _h_drift_depth_[i_ring]->SetBinError(j,i,0);
      _h_drift_depth_adc_[i_ring]->SetBinError(j, i, 0);
    }
    h_drift_depth_adc_slice_->SetBinContent(j, _h_drift_depth_adc_[i_ring]->GetBinContent(j,i));
    h_drift_depth_adc_slice_->SetBinError(j, _h_drift_depth_adc_[i_ring]->GetBinError(j,i));
    nentries += _h_drift_depth_noadc_[i_ring]->GetBinContent(j,i);  
  } // end loop over bins in drift width
        
  double mean = h_drift_depth_adc_slice_->GetMean(1); 
  double error = 0;
  if(nentries != 0){
    error = h_drift_depth_adc_slice_->GetRMS(1) / sqrt(nentries);
  }
        
  _h_mean_[i_ring]->SetBinContent(i, mean);
  _h_mean_[i_ring]->SetBinError(i, error);

}

Member Data Documentation

std::map<int, TH2F*> analyzer::SiPixelLorentzAngle::_h_drift_depth_

private

Definition at line 175 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), endJob(), and findMean().

std::map<int, TH2F*> analyzer::SiPixelLorentzAngle::_h_drift_depth_adc2_

private

Definition at line 173 of file SiPixelLorentzAngle.h.

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

std::map<int, TH2F*> analyzer::SiPixelLorentzAngle::_h_drift_depth_adc_

private

Definition at line 172 of file SiPixelLorentzAngle.h.

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

std::map<int, TH2F*> analyzer::SiPixelLorentzAngle::_h_drift_depth_noadc_

private

Definition at line 174 of file SiPixelLorentzAngle.h.

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

std::map<int, TH1F*> analyzer::SiPixelLorentzAngle::_h_mean_

private

Definition at line 177 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), endJob(), and findMean().

int analyzer::SiPixelLorentzAngle::bladeF_

private

Definition at line 133 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

double analyzer::SiPixelLorentzAngle::chi2_

private

Definition at line 121 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

double analyzer::SiPixelLorentzAngle::chi2F_

private

Definition at line 139 of file SiPixelLorentzAngle.h.

Clust analyzer::SiPixelLorentzAngle::clust_

private

Definition at line 125 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

double analyzer::SiPixelLorentzAngle::clustChargeMax_

private

Definition at line 155 of file SiPixelLorentzAngle.h.

Referenced by analyze().

Clust analyzer::SiPixelLorentzAngle::clustF_

private

Definition at line 143 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

int analyzer::SiPixelLorentzAngle::clustSizeYMin_

private

Definition at line 153 of file SiPixelLorentzAngle.h.

Referenced by analyze().

edm::ParameterSet analyzer::SiPixelLorentzAngle::conf_

private

Definition at line 147 of file SiPixelLorentzAngle.h.

int analyzer::SiPixelLorentzAngle::diskF_

private

Definition at line 132 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

float analyzer::SiPixelLorentzAngle::eta_

private

Definition at line 119 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

float analyzer::SiPixelLorentzAngle::etaF_

private

Definition at line 137 of file SiPixelLorentzAngle.h.

int analyzer::SiPixelLorentzAngle::event_

private

Definition at line 113 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

int analyzer::SiPixelLorentzAngle::event_counter_

private

Definition at line 187 of file SiPixelLorentzAngle.h.

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

int analyzer::SiPixelLorentzAngle::eventF_

private

Definition at line 130 of file SiPixelLorentzAngle.h.

std::string analyzer::SiPixelLorentzAngle::filename_

private

Definition at line 148 of file SiPixelLorentzAngle.h.

Referenced by beginJob().

std::string analyzer::SiPixelLorentzAngle::filenameFit_

private

Definition at line 149 of file SiPixelLorentzAngle.h.

Referenced by endJob().

TH2F* analyzer::SiPixelLorentzAngle::h_cluster_shape_

private

Definition at line 180 of file SiPixelLorentzAngle.h.

Referenced by beginJob().

TH2F* analyzer::SiPixelLorentzAngle::h_cluster_shape_adc_

private

Definition at line 178 of file SiPixelLorentzAngle.h.

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

TH2F* analyzer::SiPixelLorentzAngle::h_cluster_shape_adc_rot_

private

Definition at line 181 of file SiPixelLorentzAngle.h.

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

TH2F* analyzer::SiPixelLorentzAngle::h_cluster_shape_noadc_

private

Definition at line 179 of file SiPixelLorentzAngle.h.

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

TH2F* analyzer::SiPixelLorentzAngle::h_cluster_shape_noadc_rot_

private

Definition at line 182 of file SiPixelLorentzAngle.h.

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

TH2F* analyzer::SiPixelLorentzAngle::h_cluster_shape_rot_

private

Definition at line 183 of file SiPixelLorentzAngle.h.

Referenced by beginJob().

TH1F* analyzer::SiPixelLorentzAngle::h_drift_depth_adc_slice_

private

Definition at line 176 of file SiPixelLorentzAngle.h.

Referenced by endJob(), and findMean().

TH1F* analyzer::SiPixelLorentzAngle::h_tracks_

private

Definition at line 184 of file SiPixelLorentzAngle.h.

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

TFile* analyzer::SiPixelLorentzAngle::hFile_

private

Definition at line 107 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), and endJob().

int analyzer::SiPixelLorentzAngle::hist_depth_

private

Definition at line 156 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), and endJob().

int analyzer::SiPixelLorentzAngle::hist_drift_

private

Definition at line 157 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), endJob(), and findMean().

int analyzer::SiPixelLorentzAngle::hist_x_

private

Definition at line 160 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), and SiPixelLorentzAngle().

int analyzer::SiPixelLorentzAngle::hist_y_

private

Definition at line 161 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), and SiPixelLorentzAngle().

int analyzer::SiPixelLorentzAngle::hitCounter_

private

Definition at line 187 of file SiPixelLorentzAngle.h.

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

int analyzer::SiPixelLorentzAngle::isflipped_

private

Definition at line 117 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

int analyzer::SiPixelLorentzAngle::ladder_

private

Definition at line 115 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

int analyzer::SiPixelLorentzAngle::layer_

private

Definition at line 116 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

const MagneticField* analyzer::SiPixelLorentzAngle::magfield

private

Definition at line 198 of file SiPixelLorentzAngle.h.

double analyzer::SiPixelLorentzAngle::max_depth_

private

Definition at line 168 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), and SiPixelLorentzAngle().

double analyzer::SiPixelLorentzAngle::max_drift_

private

Definition at line 170 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), endJob(), and SiPixelLorentzAngle().

double analyzer::SiPixelLorentzAngle::max_x_

private

Definition at line 163 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), and SiPixelLorentzAngle().

double analyzer::SiPixelLorentzAngle::max_y_

private

Definition at line 165 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), and SiPixelLorentzAngle().

double analyzer::SiPixelLorentzAngle::min_depth_

private

Definition at line 167 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), and SiPixelLorentzAngle().

double analyzer::SiPixelLorentzAngle::min_drift_

private

Definition at line 169 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), endJob(), and SiPixelLorentzAngle().

double analyzer::SiPixelLorentzAngle::min_x_

private

Definition at line 162 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), and SiPixelLorentzAngle().

double analyzer::SiPixelLorentzAngle::min_y_

private

Definition at line 164 of file SiPixelLorentzAngle.h.

Referenced by beginJob(), and SiPixelLorentzAngle().

int analyzer::SiPixelLorentzAngle::module_

private

Definition at line 114 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

int analyzer::SiPixelLorentzAngle::moduleF_

private

Definition at line 135 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

double analyzer::SiPixelLorentzAngle::ndof_

private

Definition at line 122 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

double analyzer::SiPixelLorentzAngle::ndofF_

private

Definition at line 140 of file SiPixelLorentzAngle.h.

double analyzer::SiPixelLorentzAngle::normChi2Max_

private

Definition at line 152 of file SiPixelLorentzAngle.h.

Referenced by analyze().

int analyzer::SiPixelLorentzAngle::panelF_

private

Definition at line 134 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

float analyzer::SiPixelLorentzAngle::phi_

private

Definition at line 120 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

float analyzer::SiPixelLorentzAngle::phiF_

private

Definition at line 138 of file SiPixelLorentzAngle.h.

int analyzer::SiPixelLorentzAngle::pixelTracksCounter_

private

Definition at line 187 of file SiPixelLorentzAngle.h.

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

Pixinfo analyzer::SiPixelLorentzAngle::pixinfo_

private

Definition at line 123 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

Pixinfo analyzer::SiPixelLorentzAngle::pixinfoF_

private

Definition at line 141 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

float analyzer::SiPixelLorentzAngle::pt_

private

Definition at line 118 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

float analyzer::SiPixelLorentzAngle::ptF_

private

Definition at line 136 of file SiPixelLorentzAngle.h.

double analyzer::SiPixelLorentzAngle::ptmin_

private

Definition at line 150 of file SiPixelLorentzAngle.h.

Referenced by analyze().

Rechit analyzer::SiPixelLorentzAngle::rechit_

private

Definition at line 126 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

Rechit analyzer::SiPixelLorentzAngle::rechitF_

private

Definition at line 144 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

double analyzer::SiPixelLorentzAngle::residualMax_

private

Definition at line 154 of file SiPixelLorentzAngle.h.

Referenced by analyze().

const TransientTrackingRecHitBuilder* analyzer::SiPixelLorentzAngle::RHBuilder

private

Definition at line 194 of file SiPixelLorentzAngle.h.

int analyzer::SiPixelLorentzAngle::run_

private

Definition at line 112 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

int analyzer::SiPixelLorentzAngle::runF_

private

Definition at line 129 of file SiPixelLorentzAngle.h.

int analyzer::SiPixelLorentzAngle::sideF_

private

Definition at line 131 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

bool analyzer::SiPixelLorentzAngle::simData_

private

Definition at line 151 of file SiPixelLorentzAngle.h.

Referenced by analyze().

Hit analyzer::SiPixelLorentzAngle::simhit_

private

Definition at line 124 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

Hit analyzer::SiPixelLorentzAngle::simhitF_

private

Definition at line 142 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

TTree* analyzer::SiPixelLorentzAngle::SiPixelLorentzAngleTree_

private

Definition at line 108 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

TTree* analyzer::SiPixelLorentzAngle::SiPixelLorentzAngleTreeForward_

private

Definition at line 109 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

edm::EDGetTokenT<TrajTrackAssociationCollection> analyzer::SiPixelLorentzAngle::t_trajTrack

private

Definition at line 200 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and SiPixelLorentzAngle().

Chi2MeasurementEstimator* analyzer::SiPixelLorentzAngle::theEstimator

private

Definition at line 193 of file SiPixelLorentzAngle.h.

const KFTrajectoryFitter* analyzer::SiPixelLorentzAngle::theFitter

private

Definition at line 196 of file SiPixelLorentzAngle.h.

PropagatorWithMaterial* analyzer::SiPixelLorentzAngle::thePropagator

private

Definition at line 190 of file SiPixelLorentzAngle.h.

PropagatorWithMaterial* analyzer::SiPixelLorentzAngle::thePropagatorOp

private

Definition at line 191 of file SiPixelLorentzAngle.h.

const KFTrajectorySmoother* analyzer::SiPixelLorentzAngle::theSmoother

private

Definition at line 195 of file SiPixelLorentzAngle.h.

KFUpdator* analyzer::SiPixelLorentzAngle::theUpdator

private

Definition at line 192 of file SiPixelLorentzAngle.h.

const TrackerGeometry* analyzer::SiPixelLorentzAngle::tracker

private

Definition at line 197 of file SiPixelLorentzAngle.h.

Referenced by analyze().

int analyzer::SiPixelLorentzAngle::trackEventsCounter_

private

Definition at line 187 of file SiPixelLorentzAngle.h.

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

Hit analyzer::SiPixelLorentzAngle::trackhit_

private

Definition at line 124 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

Hit analyzer::SiPixelLorentzAngle::trackhitF_

private

Definition at line 142 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and beginJob().

TrajectoryStateTransform analyzer::SiPixelLorentzAngle::tsTransform

private

Definition at line 199 of file SiPixelLorentzAngle.h.

int analyzer::SiPixelLorentzAngle::usedHitCounter_

private

Definition at line 187 of file SiPixelLorentzAngle.h.

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

double analyzer::SiPixelLorentzAngle::width_

private

Definition at line 166 of file SiPixelLorentzAngle.h.

Referenced by analyze(), and SiPixelLorentzAngle().