#include <SiPixelTrackResidualSource.h>

Inheritance diagram for SiPixelTrackResidualSource:

Public Member Functions
virtual void	analyze (const edm::Event &, const edm::EventSetup &)

virtual void	beginJob ()

virtual void	beginRun (const edm::Run &r, edm::EventSetup const &iSetup)

virtual void	endJob (void)

	SiPixelTrackResidualSource (const edm::ParameterSet &)

void	triplets (double x1, double y1, double z1, double x2, double y2, double z2, double x3, double y3, double z3, double ptsig, double &dc, double &dz, double kap)

	~SiPixelTrackResidualSource ()

Public Member Functions inherited from edm::EDAnalyzer
	EDAnalyzer ()

std::string	workerType () const

virtual	~EDAnalyzer ()

Public Member Functions inherited from edm::EDConsumerBase
	EDConsumerBase ()

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

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

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

void	labelsForToken (EDGetToken iToken, Labels &oLabels) const

void	updateLookup (BranchType iBranchType, ProductHolderIndexHelper const &)

virtual	~EDConsumerBase ()

Private Attributes
bool	bladeOn

edm::InputTag	clustersrc_

DQMStore *	dbe_

bool	debug_

bool	diskOn

bool	firstRun

bool	ladOn

bool	layOn

MonitorElement *	meClChargeNotOnTrack_all

MonitorElement *	meClChargeNotOnTrack_bpix

MonitorElement *	meClChargeNotOnTrack_diskm1

MonitorElement *	meClChargeNotOnTrack_diskm2

MonitorElement *	meClChargeNotOnTrack_diskp1

MonitorElement *	meClChargeNotOnTrack_diskp2

MonitorElement *	meClChargeNotOnTrack_fpix

MonitorElement *	meClChargeNotOnTrack_layer1

MonitorElement *	meClChargeNotOnTrack_layer2

MonitorElement *	meClChargeNotOnTrack_layer3

MonitorElement *	meClChargeOnTrack_all

MonitorElement *	meClChargeOnTrack_bpix

MonitorElement *	meClChargeOnTrack_diskm1

MonitorElement *	meClChargeOnTrack_diskm2

MonitorElement *	meClChargeOnTrack_diskp1

MonitorElement *	meClChargeOnTrack_diskp2

MonitorElement *	meClChargeOnTrack_fpix

MonitorElement *	meClChargeOnTrack_layer1

MonitorElement *	meClChargeOnTrack_layer2

MonitorElement *	meClChargeOnTrack_layer3

MonitorElement *	meClPosDisk1mzNotOnTrack

MonitorElement *	meClPosDisk1mzOnTrack

MonitorElement *	meClPosDisk1pzNotOnTrack

MonitorElement *	meClPosDisk1pzOnTrack

MonitorElement *	meClPosDisk2mzNotOnTrack

MonitorElement *	meClPosDisk2mzOnTrack

MonitorElement *	meClPosDisk2pzNotOnTrack

MonitorElement *	meClPosDisk2pzOnTrack

MonitorElement *	meClPosLayer1NotOnTrack

MonitorElement *	meClPosLayer1OnTrack

MonitorElement *	meClPosLayer2NotOnTrack

MonitorElement *	meClPosLayer2OnTrack

MonitorElement *	meClPosLayer3NotOnTrack

MonitorElement *	meClPosLayer3OnTrack

MonitorElement *	meClSizeNotOnTrack_all

MonitorElement *	meClSizeNotOnTrack_bpix

MonitorElement *	meClSizeNotOnTrack_diskm1

MonitorElement *	meClSizeNotOnTrack_diskm2

MonitorElement *	meClSizeNotOnTrack_diskp1

MonitorElement *	meClSizeNotOnTrack_diskp2

MonitorElement *	meClSizeNotOnTrack_fpix

MonitorElement *	meClSizeNotOnTrack_layer1

MonitorElement *	meClSizeNotOnTrack_layer2

MonitorElement *	meClSizeNotOnTrack_layer3

MonitorElement *	meClSizeOnTrack_all

MonitorElement *	meClSizeOnTrack_bpix

MonitorElement *	meClSizeOnTrack_diskm1

MonitorElement *	meClSizeOnTrack_diskm2

MonitorElement *	meClSizeOnTrack_diskp1

MonitorElement *	meClSizeOnTrack_diskp2

MonitorElement *	meClSizeOnTrack_fpix

MonitorElement *	meClSizeOnTrack_layer1

MonitorElement *	meClSizeOnTrack_layer2

MonitorElement *	meClSizeOnTrack_layer3

MonitorElement *	meClSizeXNotOnTrack_all

MonitorElement *	meClSizeXNotOnTrack_bpix

MonitorElement *	meClSizeXNotOnTrack_diskm1

MonitorElement *	meClSizeXNotOnTrack_diskm2

MonitorElement *	meClSizeXNotOnTrack_diskp1

MonitorElement *	meClSizeXNotOnTrack_diskp2

MonitorElement *	meClSizeXNotOnTrack_fpix

MonitorElement *	meClSizeXNotOnTrack_layer1

MonitorElement *	meClSizeXNotOnTrack_layer2

MonitorElement *	meClSizeXNotOnTrack_layer3

MonitorElement *	meClSizeXOnTrack_all

MonitorElement *	meClSizeXOnTrack_bpix

MonitorElement *	meClSizeXOnTrack_diskm1

MonitorElement *	meClSizeXOnTrack_diskm2

MonitorElement *	meClSizeXOnTrack_diskp1

MonitorElement *	meClSizeXOnTrack_diskp2

MonitorElement *	meClSizeXOnTrack_fpix

MonitorElement *	meClSizeXOnTrack_layer1

MonitorElement *	meClSizeXOnTrack_layer2

MonitorElement *	meClSizeXOnTrack_layer3

MonitorElement *	meClSizeYNotOnTrack_all

MonitorElement *	meClSizeYNotOnTrack_bpix

MonitorElement *	meClSizeYNotOnTrack_diskm1

MonitorElement *	meClSizeYNotOnTrack_diskm2

MonitorElement *	meClSizeYNotOnTrack_diskp1

MonitorElement *	meClSizeYNotOnTrack_diskp2

MonitorElement *	meClSizeYNotOnTrack_fpix

MonitorElement *	meClSizeYNotOnTrack_layer1

MonitorElement *	meClSizeYNotOnTrack_layer2

MonitorElement *	meClSizeYNotOnTrack_layer3

MonitorElement *	meClSizeYOnTrack_all

MonitorElement *	meClSizeYOnTrack_bpix

MonitorElement *	meClSizeYOnTrack_diskm1

MonitorElement *	meClSizeYOnTrack_diskm2

MonitorElement *	meClSizeYOnTrack_diskp1

MonitorElement *	meClSizeYOnTrack_diskp2

MonitorElement *	meClSizeYOnTrack_fpix

MonitorElement *	meClSizeYOnTrack_layer1

MonitorElement *	meClSizeYOnTrack_layer2

MonitorElement *	meClSizeYOnTrack_layer3

MonitorElement *	meHitProbability

MonitorElement *	meNClustersNotOnTrack_all

MonitorElement *	meNClustersNotOnTrack_bpix

MonitorElement *	meNClustersNotOnTrack_diskm1

MonitorElement *	meNClustersNotOnTrack_diskm2

MonitorElement *	meNClustersNotOnTrack_diskp1

MonitorElement *	meNClustersNotOnTrack_diskp2

MonitorElement *	meNClustersNotOnTrack_fpix

MonitorElement *	meNClustersNotOnTrack_layer1

MonitorElement *	meNClustersNotOnTrack_layer2

MonitorElement *	meNClustersNotOnTrack_layer3

MonitorElement *	meNClustersOnTrack_all

MonitorElement *	meNClustersOnTrack_bpix

MonitorElement *	meNClustersOnTrack_diskm1

MonitorElement *	meNClustersOnTrack_diskm2

MonitorElement *	meNClustersOnTrack_diskp1

MonitorElement *	meNClustersOnTrack_diskp2

MonitorElement *	meNClustersOnTrack_fpix

MonitorElement *	meNClustersOnTrack_layer1

MonitorElement *	meNClustersOnTrack_layer2

MonitorElement *	meNClustersOnTrack_layer3

MonitorElement *	meNofClustersNotOnTrack_

MonitorElement *	meNofClustersOnTrack_

MonitorElement *	meNofTracks_

MonitorElement *	meNofTracksInPixVol_

MonitorElement *	meSubdetResidualX [3]

MonitorElement *	meSubdetResidualY [3]

bool	modOn

int	NLowProb

int	NTotal

bool	phiOn

edm::ParameterSet	pSet_

double	ptminres_

bool	reducedSet

bool	ringOn

edm::InputTag	src_

std::map< uint32_t, SiPixelTrackResidualModule * >	theSiPixelStructure

edm::InputTag	tracksrc_

std::string	ttrhbuilder_

Additional Inherited Members
Public Types inherited from edm::EDAnalyzer
typedef EDAnalyzer	ModuleType

typedef WorkerT< EDAnalyzer >	WorkerType

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::EDAnalyzer
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)

CurrentProcessingContext const *	currentContext () const

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 41 of file SiPixelTrackResidualSource.h.

Constructor & Destructor Documentation

SiPixelTrackResidualSource::SiPixelTrackResidualSource ( const edm::ParameterSet & pSet )

explicit

Definition at line 64 of file SiPixelTrackResidualSource.cc.

References bladeOn, clustersrc_, dbe_, debug_, diskOn, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), ladOn, layOn, modOn, cppFunctionSkipper::operator, phiOn, pSet_, ptminres_, ringOn, src_, AlCaHLTBitMon_QueryRunRegistry::string, tracksrc_, and ttrhbuilder_.

                                                                                   :
   pSet_(pSet),
   modOn( pSet.getUntrackedParameter<bool>("modOn",true) ),
   reducedSet( pSet.getUntrackedParameter<bool>("reducedSet",true) ),
   ladOn( pSet.getUntrackedParameter<bool>("ladOn",false) ), 
   layOn( pSet.getUntrackedParameter<bool>("layOn",false) ), 
   phiOn( pSet.getUntrackedParameter<bool>("phiOn",false) ), 
   ringOn( pSet.getUntrackedParameter<bool>("ringOn",false) ), 
   bladeOn( pSet.getUntrackedParameter<bool>("bladeOn",false) ), 
   diskOn( pSet.getUntrackedParameter<bool>("diskOn",false) )
    
 { 
    pSet_ = pSet; 
    debug_ = pSet_.getUntrackedParameter<bool>("debug", false); 
    src_ = pSet_.getParameter<edm::InputTag>("src"); 
    clustersrc_ = pSet_.getParameter<edm::InputTag>("clustersrc");
    tracksrc_ = pSet_.getParameter<edm::InputTag>("trajectoryInput");
    dbe_ = edm::Service<DQMStore>().operator->();
    ttrhbuilder_ = pSet_.getParameter<std::string>("TTRHBuilder");
    ptminres_= pSet.getUntrackedParameter<double>("PtMinRes",4.0) ;
 
   LogInfo("PixelDQM") << "SiPixelTrackResidualSource constructor" << endl;
   LogInfo ("PixelDQM") << "Mod/Lad/Lay/Phi " << modOn << "/" << ladOn << "/" 
             << layOn << "/" << phiOn << std::endl;
   LogInfo ("PixelDQM") << "Blade/Disk/Ring" << bladeOn << "/" << diskOn << "/" 
             << ringOn << std::endl;
 }

SiPixelTrackResidualSource::~SiPixelTrackResidualSource ( )

Definition at line 93 of file SiPixelTrackResidualSource.cc.

References theSiPixelStructure.

                                                         {
   LogInfo("PixelDQM") << "SiPixelTrackResidualSource destructor" << endl;
 
   std::map<uint32_t,SiPixelTrackResidualModule*>::iterator struct_iter;
   for (struct_iter = theSiPixelStructure.begin() ; struct_iter != theSiPixelStructure.end() ; struct_iter++){
     delete struct_iter->second;
     struct_iter->second = 0;
   }
 }

Member Function Documentation

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

virtual

Implements edm::EDAnalyzer.

Definition at line 515 of file SiPixelTrackResidualSource.cc.

                                                                                             {
   //Retrieve tracker topology from geometry
   edm::ESHandle<TrackerTopology> tTopoHandle;
   iSetup.get<IdealGeometryRecord>().get(tTopoHandle);
   const TrackerTopology* const tTopo = tTopoHandle.product();
 
 
   
   // retrieve TrackerGeometry again and MagneticField for use in transforming 
   // a TrackCandidate's P(ersistent)TrajectoryStateoOnDet (PTSoD) to a TrajectoryStateOnSurface (TSoS)
   ESHandle<TrackerGeometry> TG;
   iSetup.get<TrackerDigiGeometryRecord>().get(TG);
   const TrackerGeometry* theTrackerGeometry = TG.product();
   
   //analytic triplet method to calculate the track residuals in the pixe barrel detector    
   
   //--------------------------------------------------------------------
   // beam spot:
   //
   edm::Handle<reco::BeamSpot> rbs;
   iEvent.getByLabel( "offlineBeamSpot", rbs );
   math::XYZPoint bsP = math::XYZPoint(0,0,0);
   if( !rbs.failedToGet() && rbs.isValid() )
     {
       bsP = math::XYZPoint( rbs->x0(), rbs->y0(), rbs->z0() );
     }
   
   //--------------------------------------------------------------------
   // primary vertices:
   //
   edm::Handle<reco::VertexCollection> vertices;
   iEvent.getByLabel("offlinePrimaryVertices", vertices );
   
   if( vertices.failedToGet() ) return;
   if( !vertices.isValid() ) return;
   
   math::XYZPoint vtxN = math::XYZPoint(0,0,0);
   math::XYZPoint vtxP = math::XYZPoint(0,0,0);
   
   double bestNdof = 0;
   double maxSumPt = 0;
   reco::Vertex bestPvx;
   for(reco::VertexCollection::const_iterator iVertex = vertices->begin();
       iVertex != vertices->end(); ++iVertex ) {
     if( iVertex->ndof() > bestNdof ) {
       bestNdof = iVertex->ndof();
       vtxN = math::XYZPoint( iVertex->x(), iVertex->y(), iVertex->z() );
     }//ndof
     if( iVertex->p4().pt() > maxSumPt ) {
       maxSumPt = iVertex->p4().pt();
       vtxP = math::XYZPoint( iVertex->x(), iVertex->y(), iVertex->z() );
       bestPvx = *iVertex;
     }//sumpt
     
   }//vertex
   
   if( maxSumPt < 1 ) return;
   
   if( maxSumPt < 1 ) vtxP = vtxN;
   
   //---------------------------------------------
   //get Tracks
   //
   edm:: Handle<reco::TrackCollection> TracksForRes;
   iEvent.getByLabel( "generalTracks", TracksForRes );
   //
   // transient track builder, needs B-field from data base (global tag in .py)
   //
   edm::ESHandle<TransientTrackBuilder> theB;
   iSetup.get<TransientTrackRecord>().get( "TransientTrackBuilder", theB );
 
   //get the TransienTrackingRecHitBuilder needed for extracting the global position of the hits in the pixel
   edm::ESHandle<TransientTrackingRecHitBuilder> theTrackerRecHitBuilder;
   iSetup.get<TransientRecHitRecord>().get(ttrhbuilder_,theTrackerRecHitBuilder);
 
   //check that tracks are valid
   if( TracksForRes.failedToGet() ) return;
   if( !TracksForRes.isValid() ) return;
 
   //get tracker geometry
   edm::ESHandle<TrackerGeometry> pDD;
   iSetup.get<TrackerDigiGeometryRecord>().get(pDD);
   
   if( !pDD.isValid() ) {
     cout << "Unable to find TrackerDigiGeometry. Return\n";
     return;
   }
  
   int kk = -1;
   //----------------------------------------------------------------------------
   // Residuals:
   //
   for( reco::TrackCollection::const_iterator iTrack = TracksForRes->begin();
        iTrack != TracksForRes->end(); ++iTrack ) {
     //count
     kk++;
     //Calculate minimal track pt before curling
     // cpt = cqRB = 0.3*R[m]*B[T] = 1.14*R[m] for B=3.8T
     // D = 2R = 2*pt/1.14
     // calo: D = 1.3 m => pt = 0.74 GeV/c
     double pt = iTrack->pt();
     if( pt < 0.75 ) continue;// curls up
     if( abs( iTrack->dxy(vtxP) ) > 5*iTrack->dxyError() ) continue; // not prompt
     
     double charge = iTrack->charge();
        
     reco::TransientTrack tTrack = theB->build(*iTrack);
     //get curvature of the track, needed for the residuals
     double kap = tTrack.initialFreeState().transverseCurvature();
     //needed for the TransienTrackingRecHitBuilder
     TrajectoryStateOnSurface initialTSOS = tTrack.innermostMeasurementState();
     if( iTrack->extra().isNonnull() &&iTrack->extra().isAvailable() ){
       
       double x1 = 0;
       double y1 = 0;
       double z1 = 0;
       double x2 = 0;
       double y2 = 0;
       double z2 = 0;
       double x3 = 0;
       double y3 = 0;
       double z3 = 0;
       int n1 = 0;
       int n2 = 0;
       int n3 = 0;
       
       //for saving the pixel barrel hits
       vector<TransientTrackingRecHit::RecHitPointer> GoodPixBarrelHits;
       //looping through the RecHits of the track
       for( trackingRecHit_iterator irecHit = iTrack->recHitsBegin();
        irecHit != iTrack->recHitsEnd(); ++irecHit){
     
     if( (*irecHit)->isValid() ){
       DetId detId = (*irecHit)->geographicalId();
       // enum Detector { Tracker=1, Muon=2, Ecal=3, Hcal=4, Calo=5 };
       if( detId.det() != 1 ){
         if(debug_){
           cout << "rec hit ID = " << detId.det() << " not in tracker!?!?\n";
         }
         continue;
       }
       uint32_t subDet = detId.subdetId();
       
       // enum SubDetector{ PixelBarrel=1, PixelEndcap=2 };
       // enum SubDetector{ TIB=3, TID=4, TOB=5, TEC=6 };
       
       TransientTrackingRecHit::RecHitPointer trecHit = theTrackerRecHitBuilder->build(  &*(*irecHit), initialTSOS);
       
       
       double gX = trecHit->globalPosition().x();
       double gY = trecHit->globalPosition().y();
       double gZ = trecHit->globalPosition().z();
           
           
           if( subDet == PixelSubdetector::PixelBarrel ) {
 
         int ilay = tTopo->pxbLayer(detId);
         
         if( ilay == 1 ){
           n1++;
           x1 = gX;
           y1 = gY;
           z1 = gZ;
           
           GoodPixBarrelHits.push_back((trecHit));
         }//PXB1
         if( ilay == 2 ){
           
           n2++;
           x2 = gX;
           y2 = gY;
           z2 = gZ;
           
           GoodPixBarrelHits.push_back((trecHit));
           
         }//PXB2
         if( ilay == 3 ){
           
           n3++;
           x3 = gX;
           y3 = gY;
           z3 = gZ;
           GoodPixBarrelHits.push_back((trecHit));
         }
           }//PXB
           
           
         }//valid
       }//loop rechits
       
       //CS extra plots    
       
           
       if( n1+n2+n3 == 3 && n1*n2*n3 > 0) {      
         for( unsigned int i = 0; i < GoodPixBarrelHits.size(); i++){
           
           if( GoodPixBarrelHits[i]->isValid() ){
         DetId detId = GoodPixBarrelHits[i]->geographicalId().rawId();
         int ilay = tTopo->pxbLayer(detId);
         if(pt > ptminres_){   
           
           double dca2 = 0.0, dz2=0.0;
           double ptsig = pt;
           if(charge<0.) ptsig = -pt;
           //Filling the histograms in modules
           
           MeasurementPoint Test;
           MeasurementPoint Test2;
           Test=MeasurementPoint(0,0);
           Test2=MeasurementPoint(0,0);
           Measurement2DVector residual;
          
           if( ilay == 1 ){
             
             triplets(x2,y2,z2,x1,y1,z1,x3,y3,z3,ptsig,dca2,dz2, kap);   
                     
             Test=MeasurementPoint(dca2*1E4,dz2*1E4);
             residual=Test-Test2;
           }
           
           if( ilay == 2 ){
             
             triplets(x1,y1,z1,x2,y2,z2,x3,y3,z3,ptsig,dca2,dz2, kap);
             
             Test=MeasurementPoint(dca2*1E4,dz2*1E4);
             residual=Test-Test2;
           
           }
           
           if( ilay == 3 ){
             
             triplets(x1,y1,z1,x3,y3,z3,x2,y2,z2,ptsig,dca2,dz2, kap);
             
             Test=MeasurementPoint(dca2*1E4,dz2*1E4);
             residual=Test-Test2;
         }
           // fill the residual histograms 
 
           std::map<uint32_t, SiPixelTrackResidualModule*>::iterator pxd = theSiPixelStructure.find(detId);
           if (pxd!=theSiPixelStructure.end()) (*pxd).second->fill(residual, reducedSet, modOn, ladOn, layOn, phiOn, bladeOn, diskOn, ringOn);       
         }//three hits
           }//is valid
         }//rechits loop
       }//pt 4
     }
     
     
  }//-----Tracks
   //get trajectories
   edm::Handle<std::vector<Trajectory> > trajCollectionHandle;
   iEvent.getByLabel(tracksrc_,trajCollectionHandle);
   const std::vector<Trajectory> trajColl = *(trajCollectionHandle.product());
    
   //get tracks
   edm::Handle<std::vector<reco::Track> > trackCollectionHandle;
   iEvent.getByLabel(tracksrc_,trackCollectionHandle);
   const std::vector<reco::Track> trackColl = *(trackCollectionHandle.product());
 
   //get the map
   edm::Handle<TrajTrackAssociationCollection> match;
   iEvent.getByLabel(tracksrc_,match);
   const TrajTrackAssociationCollection ttac = *(match.product());
 
   // get clusters
   edm::Handle< edmNew::DetSetVector<SiPixelCluster> >  clusterColl;
   iEvent.getByLabel( clustersrc_, clusterColl );
   const edmNew::DetSetVector<SiPixelCluster> clustColl = *(clusterColl.product());
 
   if(debug_){
     std::cout << "Trajectories\t : " << trajColl.size() << std::endl;
     std::cout << "recoTracks  \t : " << trackColl.size() << std::endl;
     std::cout << "Map entries \t : " << ttac.size() << std::endl;
   }
 
   std::set<SiPixelCluster> clusterSet;
   TrajectoryStateCombiner tsoscomb;
   int tracks=0, pixeltracks=0, bpixtracks=0, fpixtracks=0; 
   int trackclusters=0, barreltrackclusters=0, endcaptrackclusters=0;
   int otherclusters=0, barrelotherclusters=0, endcapotherclusters=0;
 
   //Loop over map entries
   for(TrajTrackAssociationCollection::const_iterator it =  ttac.begin();it !=  ttac.end(); ++it){
     const edm::Ref<std::vector<Trajectory> > traj_iterator = it->key;  
     // Trajectory Map, extract Trajectory for this track
     reco::TrackRef trackref = it->val;
     tracks++;
 
     bool isBpixtrack = false, isFpixtrack = false, crossesPixVol=false;
     
     //find out whether track crosses pixel fiducial volume (for cosmic tracks)
     
     double d0 = (*trackref).d0(), dz = (*trackref).dz(); 
     
     if(abs(d0)<15 && abs(dz)<50) crossesPixVol = true;
 
     std::vector<TrajectoryMeasurement> tmeasColl =traj_iterator->measurements();
     std::vector<TrajectoryMeasurement>::const_iterator tmeasIt;
     //loop on measurements to find out whether there are bpix and/or fpix hits
     for(tmeasIt = tmeasColl.begin();tmeasIt!=tmeasColl.end();tmeasIt++){
       if(! tmeasIt->updatedState().isValid()) continue; 
       TransientTrackingRecHit::ConstRecHitPointer testhit = tmeasIt->recHit();
       if(! testhit->isValid() || testhit->geographicalId().det() != DetId::Tracker) continue; 
       uint testSubDetID = (testhit->geographicalId().subdetId()); 
       if(testSubDetID==PixelSubdetector::PixelBarrel) isBpixtrack = true;
       if(testSubDetID==PixelSubdetector::PixelEndcap) isFpixtrack = true;
     }//end loop on measurements
     if(isBpixtrack) {
       bpixtracks++; 
       if(debug_) std::cout << "bpixtrack\n";
     }
     if(isFpixtrack) {
       fpixtracks++; 
       if(debug_) std::cout << "fpixtrack\n";
     }
     if(isBpixtrack || isFpixtrack){
       pixeltracks++;
       
       if(crossesPixVol) meNofTracksInPixVol_->Fill(0,1);
 
       std::vector<TrajectoryMeasurement> tmeasColl = traj_iterator->measurements();
       for(std::vector<TrajectoryMeasurement>::const_iterator tmeasIt = tmeasColl.begin(); tmeasIt!=tmeasColl.end(); tmeasIt++){   
     if(! tmeasIt->updatedState().isValid()) continue; 
     
     TrajectoryStateOnSurface tsos = tsoscomb( tmeasIt->forwardPredictedState(), tmeasIt->backwardPredictedState() );
     TransientTrackingRecHit::ConstRecHitPointer hit = tmeasIt->recHit();
     if(! hit->isValid() || hit->geographicalId().det() != DetId::Tracker ) {
       continue; 
     } else {
       
 //    //residual
           const DetId & hit_detId = hit->geographicalId();
       //uint IntRawDetID = (hit_detId.rawId());
       uint IntSubDetID = (hit_detId.subdetId());
       
       if(IntSubDetID == 0 ) continue; // don't look at SiStrip hits!        
 
       // get the enclosed persistent hit
       const TrackingRecHit *persistentHit = hit->hit();
       // check if it's not null, and if it's a valid pixel hit
       if ((persistentHit != 0) && (typeid(*persistentHit) == typeid(SiPixelRecHit))) {
         // tell the C++ compiler that the hit is a pixel hit
         const SiPixelRecHit* pixhit = static_cast<const SiPixelRecHit*>( hit->hit() );
         //Hit probability:
         float hit_prob = -1.;
         if(pixhit->hasFilledProb()){
           hit_prob = pixhit->clusterProbability(0);
           //std::cout<<"HITPROB= "<<hit_prob<<std::endl;
           if(hit_prob<pow(10.,-15.)) NLowProb++;
           NTotal++;
           if(NTotal>0) meHitProbability->Fill(float(NLowProb/NTotal));
         }
         
         // get the edm::Ref to the cluster
         edm::Ref<edmNew::DetSetVector<SiPixelCluster>, SiPixelCluster> const& clust = (*pixhit).cluster();
         //  check if the ref is not null
         if (clust.isNonnull()) {
 
           //define tracker and pixel geometry and topology
           const TrackerGeometry& theTracker(*theTrackerGeometry);
           const PixelGeomDetUnit* theGeomDet = static_cast<const PixelGeomDetUnit*> (theTracker.idToDet(hit_detId) );
           //test if PixelGeomDetUnit exists
           if(theGeomDet == 0) {
         if(debug_) std::cout << "NO THEGEOMDET\n";
         continue;
           }
 
           const PixelTopology * topol = &(theGeomDet->specificTopology());
           //fill histograms for clusters on tracks
           //correct SiPixelTrackResidualModule
           std::map<uint32_t, SiPixelTrackResidualModule*>::iterator pxd = theSiPixelStructure.find((*hit).geographicalId().rawId());
 
           //CHARGE CORRECTION (for track impact angle)
           // calculate alpha and beta from cluster position
           LocalTrajectoryParameters ltp = tsos.localParameters();
           LocalVector localDir = ltp.momentum()/ltp.momentum().mag();
           
           float clust_alpha = atan2(localDir.z(), localDir.x());
           float clust_beta = atan2(localDir.z(), localDir.y());
           double corrCharge = clust->charge() * sqrt( 1.0 / ( 1.0/pow( tan(clust_alpha), 2 ) + 
                                   1.0/pow( tan(clust_beta ), 2 ) + 
                                   1.0 )
                               )/1000.;
 
           if (pxd!=theSiPixelStructure.end()) (*pxd).second->fill((*clust), true, corrCharge, reducedSet, modOn, ladOn, layOn, phiOn, bladeOn, diskOn, ringOn);     
 
 
           trackclusters++;
           //CORR CHARGE
           meClChargeOnTrack_all->Fill(corrCharge);
           meClSizeOnTrack_all->Fill((*clust).size());
           meClSizeXOnTrack_all->Fill((*clust).sizeX());
           meClSizeYOnTrack_all->Fill((*clust).sizeY());
           clusterSet.insert(*clust);
 
           //find cluster global position (rphi, z)
           // get cluster center of gravity (of charge)
           float xcenter = clust->x();
           float ycenter = clust->y();
           // get the cluster position in local coordinates (cm) 
           LocalPoint clustlp = topol->localPosition( MeasurementPoint(xcenter, ycenter) );
           // get the cluster position in global coordinates (cm)
           GlobalPoint clustgp = theGeomDet->surface().toGlobal( clustlp );
 
           //find location of hit (barrel or endcap, same for cluster)
           bool barrel = DetId((*hit).geographicalId()).subdetId() == static_cast<int>(PixelSubdetector::PixelBarrel);
           bool endcap = DetId((*hit).geographicalId()).subdetId() == static_cast<int>(PixelSubdetector::PixelEndcap);
           if(barrel) {
         barreltrackclusters++;
         //CORR CHARGE
         meClChargeOnTrack_bpix->Fill(corrCharge);
         meClSizeOnTrack_bpix->Fill((*clust).size());
         meClSizeXOnTrack_bpix->Fill((*clust).sizeX());
         meClSizeYOnTrack_bpix->Fill((*clust).sizeY());
         uint32_t DBlayer = PixelBarrelName(DetId((*hit).geographicalId())).layerName();
         float phi = clustgp.phi(); 
         float z = clustgp.z();
         switch(DBlayer){
         case 1: {
           meClPosLayer1OnTrack->Fill(z,phi); 
           meClChargeOnTrack_layer1->Fill(corrCharge);
           meClSizeOnTrack_layer1->Fill((*clust).size());
           meClSizeXOnTrack_layer1->Fill((*clust).sizeX());
           meClSizeYOnTrack_layer1->Fill((*clust).sizeY());
           break;
         }
         case 2: {
           meClPosLayer2OnTrack->Fill(z,phi); 
           meClChargeOnTrack_layer2->Fill(corrCharge);
           meClSizeOnTrack_layer2->Fill((*clust).size());
           meClSizeXOnTrack_layer2->Fill((*clust).sizeX());
           meClSizeYOnTrack_layer2->Fill((*clust).sizeY());
           break;
         }
         case 3: {
           meClPosLayer3OnTrack->Fill(z,phi); 
           meClChargeOnTrack_layer3->Fill(corrCharge);
           meClSizeOnTrack_layer3->Fill((*clust).size());
           meClSizeXOnTrack_layer3->Fill((*clust).sizeX());
           meClSizeYOnTrack_layer3->Fill((*clust).sizeY());
           break;
         }
         
         }
         
           }
           if(endcap) {
         endcaptrackclusters++;
         //CORR CHARGE
         meClChargeOnTrack_fpix->Fill(corrCharge);
         meClSizeOnTrack_fpix->Fill((*clust).size());
         meClSizeXOnTrack_fpix->Fill((*clust).sizeX());
         meClSizeYOnTrack_fpix->Fill((*clust).sizeY());
         uint32_t DBdisk = PixelEndcapName(DetId((*hit).geographicalId())).diskName();
         float x = clustgp.x(); 
         float y = clustgp.y(); 
         float z = clustgp.z();
         if(z>0){
           if(DBdisk==1) {
             meClPosDisk1pzOnTrack->Fill(x,y);
             meClChargeOnTrack_diskp1->Fill(corrCharge);
             meClSizeOnTrack_diskp1->Fill((*clust).size());
             meClSizeXOnTrack_diskp1->Fill((*clust).sizeX());
             meClSizeYOnTrack_diskp1->Fill((*clust).sizeY());
           }
           if(DBdisk==2) {
             meClPosDisk2pzOnTrack->Fill(x,y); 
             meClChargeOnTrack_diskp2->Fill(corrCharge);
             meClSizeOnTrack_diskp2->Fill((*clust).size());
             meClSizeXOnTrack_diskp2->Fill((*clust).sizeX());
             meClSizeYOnTrack_diskp2->Fill((*clust).sizeY());
           }
         }
         else{
           if(DBdisk==1) {
             meClPosDisk1mzOnTrack->Fill(x,y);
             meClChargeOnTrack_diskm1->Fill(corrCharge);
             meClSizeOnTrack_diskm1->Fill((*clust).size());
             meClSizeXOnTrack_diskm1->Fill((*clust).sizeX());
             meClSizeYOnTrack_diskm1->Fill((*clust).sizeY());
           }
           if(DBdisk==2) {
             meClPosDisk2mzOnTrack->Fill(x,y); 
             meClChargeOnTrack_diskm2->Fill(corrCharge);
             meClSizeOnTrack_diskm2->Fill((*clust).size());
             meClSizeXOnTrack_diskm2->Fill((*clust).sizeX());
             meClSizeYOnTrack_diskm2->Fill((*clust).sizeY());
           }
         } 
           }
           
         }//end if (cluster exists)
 
       }//end if (persistent hit exists and is pixel hit)
       
     }//end of else 
     
     
       }//end for (all traj measurements of pixeltrack)
     }//end if (is pixeltrack)
     else {
       if(debug_) std::cout << "no pixeltrack:\n";
       if(crossesPixVol) meNofTracksInPixVol_->Fill(1,1);
     }
     
   }//end loop on map entries
 
   //find clusters that are NOT on track
   //edmNew::DetSet<SiPixelCluster>::const_iterator  di;
   if(debug_) std::cout << "clusters not on track: (size " << clustColl.size() << ") ";
 
   for(TrackerGeometry::DetContainer::const_iterator it = TG->dets().begin(); it != TG->dets().end(); it++){
     //if(dynamic_cast<PixelGeomDetUnit*>((*it))!=0){
     DetId detId = (*it)->geographicalId();
     if(detId>=302055684 && detId<=352477708){ // make sure it's a Pixel module WITHOUT using dynamic_cast!  
       int nofclOnTrack = 0, nofclOffTrack=0; 
       uint32_t DBlayer=10, DBdisk=10; 
       float z=0.; 
       //set layer/disk
       if(DetId(detId).subdetId() == 1) { // Barrel module
     DBlayer = PixelBarrelName(DetId(detId)).layerName();
       }
       if(DetId(detId).subdetId() == 2){ // Endcap module
     DBdisk = PixelEndcapName(DetId(detId )).diskName();
       }
       edmNew::DetSetVector<SiPixelCluster>::const_iterator isearch = clustColl.find(detId);
       if( isearch != clustColl.end() ) {  // Not an empty iterator
     edmNew::DetSet<SiPixelCluster>::const_iterator  di;
     for(di=isearch->begin(); di!=isearch->end(); di++){
       unsigned int temp = clusterSet.size();
       clusterSet.insert(*di);
       //check if cluster is off track
       if(clusterSet.size()>temp) {
         otherclusters++;
         nofclOffTrack++; 
         //fill histograms for clusters off tracks
         //correct SiPixelTrackResidualModule
         std::map<uint32_t, SiPixelTrackResidualModule*>::iterator pxd = theSiPixelStructure.find((*it)->geographicalId().rawId());
 
         if (pxd!=theSiPixelStructure.end()) (*pxd).second->fill((*di), false, -1., reducedSet, modOn, ladOn, layOn, phiOn, bladeOn, diskOn, ringOn); 
         
 
 
         meClSizeNotOnTrack_all->Fill((*di).size());
         meClSizeXNotOnTrack_all->Fill((*di).sizeX());
         meClSizeYNotOnTrack_all->Fill((*di).sizeY());
         meClChargeNotOnTrack_all->Fill((*di).charge()/1000);
 
         //find cluster global position (rphi, z) get cluster
         //define tracker and pixel geometry and topology
         const TrackerGeometry& theTracker(*theTrackerGeometry);
         const PixelGeomDetUnit* theGeomDet = static_cast<const PixelGeomDetUnit*> (theTracker.idToDet(detId) );
         //test if PixelGeomDetUnit exists
         if(theGeomDet == 0) {
           if(debug_) std::cout << "NO THEGEOMDET\n";
           continue;
         }
         const PixelTopology * topol = &(theGeomDet->specificTopology());
        
         //center of gravity (of charge)
         float xcenter = di->x();
         float ycenter = di->y();
         // get the cluster position in local coordinates (cm) 
         LocalPoint clustlp = topol->localPosition( MeasurementPoint(xcenter, ycenter) );
         // get the cluster position in global coordinates (cm)
         GlobalPoint clustgp = theGeomDet->surface().toGlobal( clustlp );
 
 
         //barrel
         if(DetId(detId).subdetId() == 1) {
           meClSizeNotOnTrack_bpix->Fill((*di).size());
           meClSizeXNotOnTrack_bpix->Fill((*di).sizeX());
           meClSizeYNotOnTrack_bpix->Fill((*di).sizeY());
           meClChargeNotOnTrack_bpix->Fill((*di).charge()/1000);
           barrelotherclusters++;
           //DBlayer = PixelBarrelName(DetId(detId)).layerName();
           float phi = clustgp.phi(); 
           //float r = clustgp.perp();
           z = clustgp.z();
           switch(DBlayer){
           case 1: {
         meClPosLayer1NotOnTrack->Fill(z,phi); 
         meClSizeNotOnTrack_layer1->Fill((*di).size());
         meClSizeXNotOnTrack_layer1->Fill((*di).sizeX());
         meClSizeYNotOnTrack_layer1->Fill((*di).sizeY());
         meClChargeNotOnTrack_layer1->Fill((*di).charge()/1000);
         break;
           }
           case 2: {
         meClPosLayer2NotOnTrack->Fill(z,phi);
         meClSizeNotOnTrack_layer2->Fill((*di).size());
         meClSizeXNotOnTrack_layer2->Fill((*di).sizeX());
         meClSizeYNotOnTrack_layer2->Fill((*di).sizeY());
         meClChargeNotOnTrack_layer2->Fill((*di).charge()/1000);
         break;
           }
           case 3: {
         meClPosLayer3NotOnTrack->Fill(z,phi); 
         meClSizeNotOnTrack_layer3->Fill((*di).size());
         meClSizeXNotOnTrack_layer3->Fill((*di).sizeX());
         meClSizeYNotOnTrack_layer3->Fill((*di).sizeY());
         meClChargeNotOnTrack_layer3->Fill((*di).charge()/1000);
         break;
           }
         
           }
         }
         //endcap
         if(DetId(detId).subdetId() == 2) {
           meClSizeNotOnTrack_fpix->Fill((*di).size());
           meClSizeXNotOnTrack_fpix->Fill((*di).sizeX());
           meClSizeYNotOnTrack_fpix->Fill((*di).sizeY());
           meClChargeNotOnTrack_fpix->Fill((*di).charge()/1000);
           endcapotherclusters++;
           //DBdisk = PixelEndcapName(DetId(detId )).diskName();
           float x = clustgp.x(); 
           float y = clustgp.y(); 
           z = clustgp.z();
           if(z>0){
         if(DBdisk==1) {
           meClPosDisk1pzNotOnTrack->Fill(x,y);
           meClSizeNotOnTrack_diskp1->Fill((*di).size());
           meClSizeXNotOnTrack_diskp1->Fill((*di).sizeX());
           meClSizeYNotOnTrack_diskp1->Fill((*di).sizeY());
           meClChargeNotOnTrack_diskp1->Fill((*di).charge()/1000);
         }
         if(DBdisk==2) {
           meClPosDisk2pzNotOnTrack->Fill(x,y); 
           meClSizeNotOnTrack_diskp2->Fill((*di).size());
           meClSizeXNotOnTrack_diskp2->Fill((*di).sizeX());
           meClSizeYNotOnTrack_diskp2->Fill((*di).sizeY());
           meClChargeNotOnTrack_diskp2->Fill((*di).charge()/1000);
         }
           }
           else{
         if(DBdisk==1) {
           meClPosDisk1mzNotOnTrack->Fill(x,y);
           meClSizeNotOnTrack_diskm1->Fill((*di).size());
           meClSizeXNotOnTrack_diskm1->Fill((*di).sizeX());
           meClSizeYNotOnTrack_diskm1->Fill((*di).sizeY());
           meClChargeNotOnTrack_diskm1->Fill((*di).charge()/1000);
         }
         if(DBdisk==2) {
           meClPosDisk2mzNotOnTrack->Fill(x,y); 
           meClSizeNotOnTrack_diskm2->Fill((*di).size());
           meClSizeXNotOnTrack_diskm2->Fill((*di).sizeX());
           meClSizeYNotOnTrack_diskm2->Fill((*di).sizeY());
           meClChargeNotOnTrack_diskm2->Fill((*di).charge()/1000);
         }
           } 
 
         }
       }// end "if cluster off track"
       else {
         nofclOnTrack++; 
         if(z == 0 && DBdisk != 10){
           //find cluster global position (rphi, z) get cluster
           //define tracker and pixel geometry and topology
           const TrackerGeometry& theTracker(*theTrackerGeometry);
           const PixelGeomDetUnit* theGeomDet = static_cast<const PixelGeomDetUnit*> (theTracker.idToDet(detId) );
           //test if PixelGeomDetUnit exists
           if(theGeomDet == 0) {
         if(debug_) std::cout << "NO THEGEOMDET\n";
         continue;
           }
           const PixelTopology * topol = &(theGeomDet->specificTopology());
           //center of gravity (of charge)
           float xcenter = di->x();
           float ycenter = di->y();
           // get the cluster position in local coordinates (cm) 
           LocalPoint clustlp = topol->localPosition( MeasurementPoint(xcenter, ycenter) );
           // get the cluster position in global coordinates (cm)
           GlobalPoint clustgp = theGeomDet->surface().toGlobal( clustlp );  
           z = clustgp.z();
         }
       }
     }
       }
       //++ fill the number of clusters on a module
       std::map<uint32_t, SiPixelTrackResidualModule*>::iterator pxd = theSiPixelStructure.find((*it)->geographicalId().rawId());
       if (pxd!=theSiPixelStructure.end()) (*pxd).second->nfill(nofclOnTrack, nofclOffTrack, reducedSet, modOn, ladOn, layOn, phiOn, bladeOn, diskOn, ringOn); 
       if(nofclOnTrack!=0) meNClustersOnTrack_all->Fill(nofclOnTrack); 
       if(nofclOffTrack!=0) meNClustersNotOnTrack_all->Fill(nofclOffTrack); 
       //barrel
       if(DetId(detId).subdetId() == 1){
     if(nofclOnTrack!=0) meNClustersOnTrack_bpix->Fill(nofclOnTrack); 
     if(nofclOffTrack!=0) meNClustersNotOnTrack_bpix->Fill(nofclOffTrack); 
     //DBlayer = PixelBarrelName(DetId(detId)).layerName();
     switch(DBlayer){
     case 1: { 
       if(nofclOnTrack!=0) meNClustersOnTrack_layer1->Fill(nofclOnTrack);
       if(nofclOffTrack!=0) meNClustersNotOnTrack_layer1->Fill(nofclOffTrack); break;
     }
     case 2: {
       if(nofclOnTrack!=0) meNClustersOnTrack_layer2->Fill(nofclOnTrack);
       if(nofclOffTrack!=0) meNClustersNotOnTrack_layer2->Fill(nofclOffTrack); break; 
     }
     case 3: {
       if(nofclOnTrack!=0) meNClustersOnTrack_layer3->Fill(nofclOnTrack); 
       if(nofclOffTrack!=0) meNClustersNotOnTrack_layer3->Fill(nofclOffTrack); break; 
     }
     }
       }//end barrel
       //endcap
       if(DetId(detId).subdetId() == 2) {
     //DBdisk = PixelEndcapName(DetId(detId )).diskName();
     //z = clustgp.z();
     if(nofclOnTrack!=0) meNClustersOnTrack_fpix->Fill(nofclOnTrack); 
     if(nofclOffTrack!=0) meNClustersNotOnTrack_fpix->Fill(nofclOffTrack);
     if(z>0){
       if(DBdisk==1) {
         if(nofclOnTrack!=0) meNClustersOnTrack_diskp1->Fill(nofclOnTrack); 
         if(nofclOffTrack!=0) meNClustersNotOnTrack_diskp1->Fill(nofclOffTrack);
       }
       if(DBdisk==2) {
         if(nofclOnTrack!=0) meNClustersOnTrack_diskp2->Fill(nofclOnTrack); 
         if(nofclOffTrack!=0) meNClustersNotOnTrack_diskp2->Fill(nofclOffTrack);
       }
     }
     if(z<0){
       if(DBdisk==1) {
         if(nofclOnTrack!=0) meNClustersOnTrack_diskm1->Fill(nofclOnTrack); 
         if(nofclOffTrack!=0) meNClustersNotOnTrack_diskm1->Fill(nofclOffTrack);
       }
       if(DBdisk==2) {
         if(nofclOnTrack!=0) meNClustersOnTrack_diskm2->Fill(nofclOnTrack); 
         if(nofclOffTrack!=0) meNClustersNotOnTrack_diskm2->Fill(nofclOffTrack);
       }
     }
       }
 
     }//end if it's a Pixel module
   }//end for loop over tracker detector geometry modules
 
 
   if(trackclusters>0) (meNofClustersOnTrack_)->Fill(0,trackclusters);
   if(barreltrackclusters>0)(meNofClustersOnTrack_)->Fill(1,barreltrackclusters);
   if(endcaptrackclusters>0)(meNofClustersOnTrack_)->Fill(2,endcaptrackclusters);
   if(otherclusters>0)(meNofClustersNotOnTrack_)->Fill(0,otherclusters);
   if(barrelotherclusters>0)(meNofClustersNotOnTrack_)->Fill(1,barrelotherclusters);
   if(endcapotherclusters>0)(meNofClustersNotOnTrack_)->Fill(2,endcapotherclusters);
   if(tracks>0)(meNofTracks_)->Fill(0,tracks);
   if(pixeltracks>0)(meNofTracks_)->Fill(1,pixeltracks);
   if(bpixtracks>0)(meNofTracks_)->Fill(2,bpixtracks);
   if(fpixtracks>0)(meNofTracks_)->Fill(3,fpixtracks);
 }

void SiPixelTrackResidualSource::beginJob ( void )

virtual

Reimplemented from edm::EDAnalyzer.

Definition at line 103 of file SiPixelTrackResidualSource.cc.

References firstRun, NLowProb, and NTotal.

                                           {
   LogInfo("PixelDQM") << "SiPixelTrackResidualSource beginJob()" << endl;
   firstRun = true;
   NTotal=0;
   NLowProb=0;
 }

void SiPixelTrackResidualSource::beginRun	(	const edm::Run &	r,
		edm::EventSetup const &	iSetup
	)

virtual

Reimplemented from edm::EDAnalyzer.

Definition at line 111 of file SiPixelTrackResidualSource.cc.

                                                                                       {
   LogInfo("PixelDQM") << "SiPixelTrackResidualSource beginRun()" << endl;
 
   if(firstRun){
   // retrieve TrackerGeometry for pixel dets
   edm::ESHandle<TrackerGeometry> TG;
   iSetup.get<TrackerDigiGeometryRecord>().get(TG);
   if (debug_) LogVerbatim("PixelDQM") << "TrackerGeometry "<< &(*TG) <<" size is "<< TG->dets().size() << endl;
  
   // build theSiPixelStructure with the pixel barrel and endcap dets from TrackerGeometry
   for (TrackerGeometry::DetContainer::const_iterator pxb = TG->detsPXB().begin();  
        pxb!=TG->detsPXB().end(); pxb++) {
     if (dynamic_cast<PixelGeomDetUnit*>((*pxb))!=0) {
       SiPixelTrackResidualModule* module = new SiPixelTrackResidualModule((*pxb)->geographicalId().rawId());
       theSiPixelStructure.insert(pair<uint32_t, SiPixelTrackResidualModule*>((*pxb)->geographicalId().rawId(), module));
     }
   }
   for (TrackerGeometry::DetContainer::const_iterator pxf = TG->detsPXF().begin(); 
        pxf!=TG->detsPXF().end(); pxf++) {
     if (dynamic_cast<PixelGeomDetUnit*>((*pxf))!=0) {
       SiPixelTrackResidualModule* module = new SiPixelTrackResidualModule((*pxf)->geographicalId().rawId());
       theSiPixelStructure.insert(pair<uint32_t, SiPixelTrackResidualModule*>((*pxf)->geographicalId().rawId(), module));
     }
   }
   LogInfo("PixelDQM") << "SiPixelStructure size is " << theSiPixelStructure.size() << endl;
 
   // book residual histograms in theSiPixelFolder - one (x,y) pair of histograms per det
   SiPixelFolderOrganizer theSiPixelFolder;
   for (std::map<uint32_t, SiPixelTrackResidualModule*>::iterator pxd = theSiPixelStructure.begin(); 
        pxd!=theSiPixelStructure.end(); pxd++) {
 
     if(modOn){
       if (theSiPixelFolder.setModuleFolder((*pxd).first)) (*pxd).second->book(pSet_,reducedSet);
       else throw cms::Exception("LogicError") << "SiPixelTrackResidualSource Folder Creation Failed! "; 
     }
     if(ladOn){
       if (theSiPixelFolder.setModuleFolder((*pxd).first,1)) {
     
     (*pxd).second->book(pSet_,reducedSet,1);
       }
       else throw cms::Exception("LogicError") << "SiPixelTrackResidualSource ladder Folder Creation Failed! "; 
     }
     if(layOn){
       if (theSiPixelFolder.setModuleFolder((*pxd).first,2)) (*pxd).second->book(pSet_,reducedSet,2);
       else throw cms::Exception("LogicError") << "SiPixelTrackResidualSource layer Folder Creation Failed! "; 
     }
     if(phiOn){
       if (theSiPixelFolder.setModuleFolder((*pxd).first,3)) (*pxd).second->book(pSet_,reducedSet,3);
       else throw cms::Exception("LogicError") << "SiPixelTrackResidualSource phi Folder Creation Failed! "; 
     }
     if(bladeOn){
       if (theSiPixelFolder.setModuleFolder((*pxd).first,4)) (*pxd).second->book(pSet_,reducedSet,4);
       else throw cms::Exception("LogicError") << "SiPixelTrackResidualSource Blade Folder Creation Failed! "; 
     }
     if(diskOn){
       if (theSiPixelFolder.setModuleFolder((*pxd).first,5)) (*pxd).second->book(pSet_,reducedSet,5);
       else throw cms::Exception("LogicError") << "SiPixelTrackResidualSource Disk Folder Creation Failed! "; 
     }
     if(ringOn){
       if (theSiPixelFolder.setModuleFolder((*pxd).first,6)) (*pxd).second->book(pSet_,reducedSet,6);
       else throw cms::Exception("LogicError") << "SiPixelTrackResidualSource Ring Folder Creation Failed! "; 
     }
   }
 
 
 //   edm::InputTag tracksrc = pSet_.getParameter<edm::InputTag>("trajectoryInput");
 //   edm::InputTag clustersrc = pSet_.getParameter<edm::InputTag>("clustersrc");
 
   //number of tracks
   dbe_->setCurrentFolder("Pixel/Tracks");
   meNofTracks_ = dbe_->book1D("ntracks_" + tracksrc_.label(),"Number of Tracks",4,0,4);
   meNofTracks_->setAxisTitle("Number of Tracks",1);
   meNofTracks_->setBinLabel(1,"All");
   meNofTracks_->setBinLabel(2,"Pixel");
   meNofTracks_->setBinLabel(3,"BPix");
   meNofTracks_->setBinLabel(4,"FPix");
 
   //number of tracks in pixel fiducial volume
   dbe_->setCurrentFolder("Pixel/Tracks");
   meNofTracksInPixVol_ = dbe_->book1D("ntracksInPixVol_" + tracksrc_.label(),"Number of Tracks crossing Pixel fiducial Volume",2,0,2);
   meNofTracksInPixVol_->setAxisTitle("Number of Tracks",1);
   meNofTracksInPixVol_->setBinLabel(1,"With Hits");
   meNofTracksInPixVol_->setBinLabel(2,"Without Hits");
 
   //number of clusters (associated to track / not associated)
   dbe_->setCurrentFolder("Pixel/Clusters/OnTrack");
   meNofClustersOnTrack_ = dbe_->book1D("nclusters_" + clustersrc_.label() + "_tot","Number of Clusters (on track)",3,0,3);
   meNofClustersOnTrack_->setAxisTitle("Number of Clusters on Track",1);
   meNofClustersOnTrack_->setBinLabel(1,"All");
   meNofClustersOnTrack_->setBinLabel(2,"BPix");
   meNofClustersOnTrack_->setBinLabel(3,"FPix");
   dbe_->setCurrentFolder("Pixel/Clusters/OffTrack");
   meNofClustersNotOnTrack_ = dbe_->book1D("nclusters_" + clustersrc_.label() + "_tot","Number of Clusters (off track)",3,0,3);
   meNofClustersNotOnTrack_->setAxisTitle("Number of Clusters off Track",1);
   meNofClustersNotOnTrack_->setBinLabel(1,"All");
   meNofClustersNotOnTrack_->setBinLabel(2,"BPix");
   meNofClustersNotOnTrack_->setBinLabel(3,"FPix");
 
   //cluster charge and size
   //charge
   //on track
   dbe_->setCurrentFolder("Pixel/Clusters/OnTrack");
   meClChargeOnTrack_all = dbe_->book1D("charge_" + clustersrc_.label(),"Charge (on track)",500,0.,500.);
   meClChargeOnTrack_all->setAxisTitle("Charge size (in ke)",1);
   meClChargeOnTrack_bpix = dbe_->book1D("charge_" + clustersrc_.label() + "_Barrel","Charge (on track, barrel)",500,0.,500.);
   meClChargeOnTrack_bpix->setAxisTitle("Charge size (in ke)",1);
   meClChargeOnTrack_fpix = dbe_->book1D("charge_" + clustersrc_.label() + "_Endcap","Charge (on track, endcap)",500,0.,500.);
   meClChargeOnTrack_fpix->setAxisTitle("Charge size (in ke)",1);
   meClChargeOnTrack_layer1 = dbe_->book1D("charge_" + clustersrc_.label() + "_Layer_1","Charge (on track, layer1)",500,0.,500.);
   meClChargeOnTrack_layer1->setAxisTitle("Charge size (in ke)",1);
   meClChargeOnTrack_layer2 = dbe_->book1D("charge_" + clustersrc_.label() + "_Layer_2","Charge (on track, layer2)",500,0.,500.);
   meClChargeOnTrack_layer2->setAxisTitle("Charge size (in ke)",1);
   meClChargeOnTrack_layer3 = dbe_->book1D("charge_" + clustersrc_.label() + "_Layer_3","Charge (on track, layer3)",500,0.,500.);
   meClChargeOnTrack_layer3->setAxisTitle("Charge size (in ke)",1);
   meClChargeOnTrack_diskp1 = dbe_->book1D("charge_" + clustersrc_.label() + "_Disk_p1","Charge (on track, diskp1)",500,0.,500.);
   meClChargeOnTrack_diskp1->setAxisTitle("Charge size (in ke)",1);
   meClChargeOnTrack_diskp2 = dbe_->book1D("charge_" + clustersrc_.label() + "_Disk_p2","Charge (on track, diskp2)",500,0.,500.);
   meClChargeOnTrack_diskp2->setAxisTitle("Charge size (in ke)",1);
   meClChargeOnTrack_diskm1 = dbe_->book1D("charge_" + clustersrc_.label() + "_Disk_m1","Charge (on track, diskm1)",500,0.,500.);
   meClChargeOnTrack_diskm1->setAxisTitle("Charge size (in ke)",1);
   meClChargeOnTrack_diskm2 = dbe_->book1D("charge_" + clustersrc_.label() + "_Disk_m2","Charge (on track, diskm2)",500,0.,500.);
   meClChargeOnTrack_diskm2->setAxisTitle("Charge size (in ke)",1);
   //off track
   dbe_->setCurrentFolder("Pixel/Clusters/OffTrack");
   meClChargeNotOnTrack_all = dbe_->book1D("charge_" + clustersrc_.label(),"Charge (off track)",500,0.,500.);
   meClChargeNotOnTrack_all->setAxisTitle("Charge size (in ke)",1);
   meClChargeNotOnTrack_bpix = dbe_->book1D("charge_" + clustersrc_.label() + "_Barrel","Charge (off track, barrel)",500,0.,500.);
   meClChargeNotOnTrack_bpix->setAxisTitle("Charge size (in ke)",1);
   meClChargeNotOnTrack_fpix = dbe_->book1D("charge_" + clustersrc_.label() + "_Endcap","Charge (off track, endcap)",500,0.,500.);
   meClChargeNotOnTrack_fpix->setAxisTitle("Charge size (in ke)",1);
   meClChargeNotOnTrack_layer1 = dbe_->book1D("charge_" + clustersrc_.label() + "_Layer_1","Charge (off track, layer1)",500,0.,500.);
   meClChargeNotOnTrack_layer1->setAxisTitle("Charge size (in ke)",1);
   meClChargeNotOnTrack_layer2 = dbe_->book1D("charge_" + clustersrc_.label() + "_Layer_2","Charge (off track, layer2)",500,0.,500.);
   meClChargeNotOnTrack_layer2->setAxisTitle("Charge size (in ke)",1);
   meClChargeNotOnTrack_layer3 = dbe_->book1D("charge_" + clustersrc_.label() + "_Layer_3","Charge (off track, layer3)",500,0.,500.);
   meClChargeNotOnTrack_layer3->setAxisTitle("Charge size (in ke)",1);
   meClChargeNotOnTrack_diskp1 = dbe_->book1D("charge_" + clustersrc_.label() + "_Disk_p1","Charge (off track, diskp1)",500,0.,500.);
   meClChargeNotOnTrack_diskp1->setAxisTitle("Charge size (in ke)",1);
   meClChargeNotOnTrack_diskp2 = dbe_->book1D("charge_" + clustersrc_.label() + "_Disk_p2","Charge (off track, diskp2)",500,0.,500.);
   meClChargeNotOnTrack_diskp2->setAxisTitle("Charge size (in ke)",1);
   meClChargeNotOnTrack_diskm1 = dbe_->book1D("charge_" + clustersrc_.label() + "_Disk_m1","Charge (off track, diskm1)",500,0.,500.);
   meClChargeNotOnTrack_diskm1->setAxisTitle("Charge size (in ke)",1);
   meClChargeNotOnTrack_diskm2 = dbe_->book1D("charge_" + clustersrc_.label() + "_Disk_m2","Charge (off track, diskm2)",500,0.,500.);
   meClChargeNotOnTrack_diskm2->setAxisTitle("Charge size (in ke)",1);
 
   //size
   //on track
   dbe_->setCurrentFolder("Pixel/Clusters/OnTrack");
   meClSizeOnTrack_all = dbe_->book1D("size_" + clustersrc_.label(),"Size (on track)",100,0.,100.);
   meClSizeOnTrack_all->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeOnTrack_bpix = dbe_->book1D("size_" + clustersrc_.label() + "_Barrel","Size (on track, barrel)",100,0.,100.);
   meClSizeOnTrack_bpix->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeOnTrack_fpix = dbe_->book1D("size_" + clustersrc_.label() + "_Endcap","Size (on track, endcap)",100,0.,100.);
   meClSizeOnTrack_fpix->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeOnTrack_layer1 = dbe_->book1D("size_" + clustersrc_.label() + "_Layer_1","Size (on track, layer1)",100,0.,100.);
   meClSizeOnTrack_layer1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeOnTrack_layer2 = dbe_->book1D("size_" + clustersrc_.label() + "_Layer_2","Size (on track, layer2)",100,0.,100.);
   meClSizeOnTrack_layer2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeOnTrack_layer3 = dbe_->book1D("size_" + clustersrc_.label() + "_Layer_3","Size (on track, layer3)",100,0.,100.);
   meClSizeOnTrack_layer3->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeOnTrack_diskp1 = dbe_->book1D("size_" + clustersrc_.label() + "_Disk_p1","Size (on track, diskp1)",100,0.,100.);
   meClSizeOnTrack_diskp1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeOnTrack_diskp2 = dbe_->book1D("size_" + clustersrc_.label() + "_Disk_p2","Size (on track, diskp2)",100,0.,100.);
   meClSizeOnTrack_diskp2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeOnTrack_diskm1 = dbe_->book1D("size_" + clustersrc_.label() + "_Disk_m1","Size (on track, diskm1)",100,0.,100.);
   meClSizeOnTrack_diskm1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeOnTrack_diskm2 = dbe_->book1D("size_" + clustersrc_.label() + "_Disk_m2","Size (on track, diskm2)",100,0.,100.);
   meClSizeOnTrack_diskm2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXOnTrack_all = dbe_->book1D("sizeX_" + clustersrc_.label(),"SizeX (on track)",100,0.,100.);
   meClSizeXOnTrack_all->setAxisTitle("Cluster sizeX (in pixels)",1);
   meClSizeXOnTrack_bpix = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Barrel","SizeX (on track, barrel)",100,0.,100.);
   meClSizeXOnTrack_bpix->setAxisTitle("Cluster sizeX (in pixels)",1);
   meClSizeXOnTrack_fpix = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Endcap","SizeX (on track, endcap)",100,0.,100.);
   meClSizeXOnTrack_fpix->setAxisTitle("Cluster sizeX (in pixels)",1);
   meClSizeXOnTrack_layer1 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Layer_1","SizeX (on track, layer1)",100,0.,100.);
   meClSizeXOnTrack_layer1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXOnTrack_layer2 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Layer_2","SizeX (on track, layer2)",100,0.,100.);
   meClSizeXOnTrack_layer2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXOnTrack_layer3 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Layer_3","SizeX (on track, layer3)",100,0.,100.);
   meClSizeXOnTrack_layer3->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXOnTrack_diskp1 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Disk_p1","SizeX (on track, diskp1)",100,0.,100.);
   meClSizeXOnTrack_diskp1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXOnTrack_diskp2 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Disk_p2","SizeX (on track, diskp2)",100,0.,100.);
   meClSizeXOnTrack_diskp2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXOnTrack_diskm1 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Disk_m1","SizeX (on track, diskm1)",100,0.,100.);
   meClSizeXOnTrack_diskm1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXOnTrack_diskm2 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Disk_m2","SizeX (on track, diskm2)",100,0.,100.);
   meClSizeXOnTrack_diskm2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYOnTrack_all = dbe_->book1D("sizeY_" + clustersrc_.label(),"SizeY (on track)",100,0.,100.);
   meClSizeYOnTrack_all->setAxisTitle("Cluster sizeY (in pixels)",1);
   meClSizeYOnTrack_bpix = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Barrel","SizeY (on track, barrel)",100,0.,100.);
   meClSizeYOnTrack_bpix->setAxisTitle("Cluster sizeY (in pixels)",1);
   meClSizeYOnTrack_fpix = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Endcap","SizeY (on track, endcap)",100,0.,100.);
   meClSizeYOnTrack_fpix->setAxisTitle("Cluster sizeY (in pixels)",1);
   meClSizeYOnTrack_layer1 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Layer_1","SizeY (on track, layer1)",100,0.,100.);
   meClSizeYOnTrack_layer1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYOnTrack_layer2 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Layer_2","SizeY (on track, layer2)",100,0.,100.);
   meClSizeYOnTrack_layer2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYOnTrack_layer3 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Layer_3","SizeY (on track, layer3)",100,0.,100.);
   meClSizeYOnTrack_layer3->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYOnTrack_diskp1 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Disk_p1","SizeY (on track, diskp1)",100,0.,100.);
   meClSizeYOnTrack_diskp1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYOnTrack_diskp2 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Disk_p2","SizeY (on track, diskp2)",100,0.,100.);
   meClSizeYOnTrack_diskp2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYOnTrack_diskm1 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Disk_m1","SizeY (on track, diskm1)",100,0.,100.);
   meClSizeYOnTrack_diskm1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYOnTrack_diskm2 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Disk_m2","SizeY (on track, diskm2)",100,0.,100.);
   meClSizeYOnTrack_diskm2->setAxisTitle("Cluster size (in pixels)",1);
   //off track
   dbe_->setCurrentFolder("Pixel/Clusters/OffTrack");
   meClSizeNotOnTrack_all = dbe_->book1D("size_" + clustersrc_.label(),"Size (off track)",100,0.,100.);
   meClSizeNotOnTrack_all->setAxisTitle("Cluster size (in pixels)",1); 
   meClSizeNotOnTrack_bpix = dbe_->book1D("size_" + clustersrc_.label() + "_Barrel","Size (off track, barrel)",100,0.,100.);
   meClSizeNotOnTrack_bpix->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeNotOnTrack_fpix = dbe_->book1D("size_" + clustersrc_.label() + "_Endcap","Size (off track, endcap)",100,0.,100.);
   meClSizeNotOnTrack_fpix->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeNotOnTrack_layer1 = dbe_->book1D("size_" + clustersrc_.label() + "_Layer_1","Size (off track, layer1)",100,0.,100.);
   meClSizeNotOnTrack_layer1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeNotOnTrack_layer2 = dbe_->book1D("size_" + clustersrc_.label() + "_Layer_2","Size (off track, layer2)",100,0.,100.);
   meClSizeNotOnTrack_layer2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeNotOnTrack_layer3 = dbe_->book1D("size_" + clustersrc_.label() + "_Layer_3","Size (off track, layer3)",100,0.,100.);
   meClSizeNotOnTrack_layer3->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeNotOnTrack_diskp1 = dbe_->book1D("size_" + clustersrc_.label() + "_Disk_p1","Size (off track, diskp1)",100,0.,100.);
   meClSizeNotOnTrack_diskp1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeNotOnTrack_diskp2 = dbe_->book1D("size_" + clustersrc_.label() + "_Disk_p2","Size (off track, diskp2)",100,0.,100.);
   meClSizeNotOnTrack_diskp2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeNotOnTrack_diskm1 = dbe_->book1D("size_" + clustersrc_.label() + "_Disk_m1","Size (off track, diskm1)",100,0.,100.);
   meClSizeNotOnTrack_diskm1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeNotOnTrack_diskm2 = dbe_->book1D("size_" + clustersrc_.label() + "_Disk_m2","Size (off track, diskm2)",100,0.,100.);
   meClSizeNotOnTrack_diskm2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXNotOnTrack_all = dbe_->book1D("sizeX_" + clustersrc_.label(),"SizeX (off track)",100,0.,100.);
   meClSizeXNotOnTrack_all->setAxisTitle("Cluster sizeX (in pixels)",1);
   meClSizeXNotOnTrack_bpix = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Barrel","SizeX (off track, barrel)",100,0.,100.);
   meClSizeXNotOnTrack_bpix->setAxisTitle("Cluster sizeX (in pixels)",1);
   meClSizeXNotOnTrack_fpix = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Endcap","SizeX (off track, endcap)",100,0.,100.);
   meClSizeXNotOnTrack_fpix->setAxisTitle("Cluster sizeX (in pixels)",1);
   meClSizeXNotOnTrack_layer1 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Layer_1","SizeX (off track, layer1)",100,0.,100.);
   meClSizeXNotOnTrack_layer1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXNotOnTrack_layer2 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Layer_2","SizeX (off track, layer2)",100,0.,100.);
   meClSizeXNotOnTrack_layer2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXNotOnTrack_layer3 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Layer_3","SizeX (off track, layer3)",100,0.,100.);
   meClSizeXNotOnTrack_layer3->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXNotOnTrack_diskp1 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Disk_p1","SizeX (off track, diskp1)",100,0.,100.);
   meClSizeXNotOnTrack_diskp1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXNotOnTrack_diskp2 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Disk_p2","SizeX (off track, diskp2)",100,0.,100.);
   meClSizeXNotOnTrack_diskp2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXNotOnTrack_diskm1 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Disk_m1","SizeX (off track, diskm1)",100,0.,100.);
   meClSizeXNotOnTrack_diskm1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeXNotOnTrack_diskm2 = dbe_->book1D("sizeX_" + clustersrc_.label() + "_Disk_m2","SizeX (off track, diskm2)",100,0.,100.);
   meClSizeXNotOnTrack_diskm2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYNotOnTrack_all = dbe_->book1D("sizeY_" + clustersrc_.label(),"SizeY (off track)",100,0.,100.);
   meClSizeYNotOnTrack_all->setAxisTitle("Cluster sizeY (in pixels)",1);
   meClSizeYNotOnTrack_bpix = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Barrel","SizeY (off track, barrel)",100,0.,100.);
   meClSizeYNotOnTrack_bpix->setAxisTitle("Cluster sizeY (in pixels)",1);
   meClSizeYNotOnTrack_fpix = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Endcap","SizeY (off track, endcap)",100,0.,100.);
   meClSizeYNotOnTrack_fpix->setAxisTitle("Cluster sizeY (in pixels)",1);
   meClSizeYNotOnTrack_layer1 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Layer_1","SizeY (off track, layer1)",100,0.,100.);
   meClSizeYNotOnTrack_layer1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYNotOnTrack_layer2 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Layer_2","SizeY (off track, layer2)",100,0.,100.);
   meClSizeYNotOnTrack_layer2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYNotOnTrack_layer3 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Layer_3","SizeY (off track, layer3)",100,0.,100.);
   meClSizeYNotOnTrack_layer3->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYNotOnTrack_diskp1 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Disk_p1","SizeY (off track, diskp1)",100,0.,100.);
   meClSizeYNotOnTrack_diskp1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYNotOnTrack_diskp2 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Disk_p2","SizeY (off track, diskp2)",100,0.,100.);
   meClSizeYNotOnTrack_diskp2->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYNotOnTrack_diskm1 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Disk_m1","SizeY (off track, diskm1)",100,0.,100.);
   meClSizeYNotOnTrack_diskm1->setAxisTitle("Cluster size (in pixels)",1);
   meClSizeYNotOnTrack_diskm2 = dbe_->book1D("sizeY_" + clustersrc_.label() + "_Disk_m2","SizeY (off track, diskm2)",100,0.,100.);
   meClSizeYNotOnTrack_diskm2->setAxisTitle("Cluster size (in pixels)",1);
   
 
   //cluster global position
   //on track
   dbe_->setCurrentFolder("Pixel/Clusters/OnTrack");
   //bpix
   meClPosLayer1OnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_Layer_1","Clusters Layer1 (on track)",200,-30.,30.,128,-3.2,3.2);
   meClPosLayer1OnTrack->setAxisTitle("Global Z (cm)",1);
   meClPosLayer1OnTrack->setAxisTitle("Global #phi",2);
   meClPosLayer2OnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_Layer_2","Clusters Layer2 (on track)",200,-30.,30.,128,-3.2,3.2);
   meClPosLayer2OnTrack->setAxisTitle("Global Z (cm)",1);
   meClPosLayer2OnTrack->setAxisTitle("Global #phi",2);
   meClPosLayer3OnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_Layer_3","Clusters Layer3 (on track)",200,-30.,30.,128,-3.2,3.2);
   meClPosLayer3OnTrack->setAxisTitle("Global Z (cm)",1);
   meClPosLayer3OnTrack->setAxisTitle("Global #phi",2);
   //fpix
   meClPosDisk1pzOnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_pz_Disk_1","Clusters +Z Disk1 (on track)",80,-20.,20.,80,-20.,20.);
   meClPosDisk1pzOnTrack->setAxisTitle("Global X (cm)",1);
   meClPosDisk1pzOnTrack->setAxisTitle("Global Y (cm)",2);
   meClPosDisk2pzOnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_pz_Disk_2","Clusters +Z Disk2 (on track)",80,-20.,20.,80,-20.,20.);
   meClPosDisk2pzOnTrack->setAxisTitle("Global X (cm)",1);
   meClPosDisk2pzOnTrack->setAxisTitle("Global Y (cm)",2);
   meClPosDisk1mzOnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_mz_Disk_1","Clusters -Z Disk1 (on track)",80,-20.,20.,80,-20.,20.);
   meClPosDisk1mzOnTrack->setAxisTitle("Global X (cm)",1);
   meClPosDisk1mzOnTrack->setAxisTitle("Global Y (cm)",2);
   meClPosDisk2mzOnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_mz_Disk_2","Clusters -Z Disk2 (on track)",80,-20.,20.,80,-20.,20.);
   meClPosDisk2mzOnTrack->setAxisTitle("Global X (cm)",1);
   meClPosDisk2mzOnTrack->setAxisTitle("Global Y (cm)",2);
 
   meNClustersOnTrack_all = dbe_->book1D("nclusters_" + clustersrc_.label(),"Number of Clusters (on Track)",50,0.,50.);
   meNClustersOnTrack_all->setAxisTitle("Number of Clusters",1);
   meNClustersOnTrack_bpix = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Barrel","Number of Clusters (on track, barrel)",50,0.,50.);
   meNClustersOnTrack_bpix->setAxisTitle("Number of Clusters",1);
   meNClustersOnTrack_fpix = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Endcap","Number of Clusters (on track, endcap)",50,0.,50.);
   meNClustersOnTrack_fpix->setAxisTitle("Number of Clusters",1);
   meNClustersOnTrack_layer1 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Layer_1","Number of Clusters (on track, layer1)",50,0.,50.);
   meNClustersOnTrack_layer1->setAxisTitle("Number of Clusters",1);
   meNClustersOnTrack_layer2 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Layer_2","Number of Clusters (on track, layer2)",50,0.,50.);
   meNClustersOnTrack_layer2->setAxisTitle("Number of Clusters",1);
   meNClustersOnTrack_layer3 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Layer_3","Number of Clusters (on track, layer3)",50,0.,50.);
   meNClustersOnTrack_layer3->setAxisTitle("Number of Clusters",1);
   meNClustersOnTrack_diskp1 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Disk_p1","Number of Clusters (on track, diskp1)",50,0.,50.);
   meNClustersOnTrack_diskp1->setAxisTitle("Number of Clusters",1);
   meNClustersOnTrack_diskp2 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Disk_p2","Number of Clusters (on track, diskp2)",50,0.,50.);
   meNClustersOnTrack_diskp2->setAxisTitle("Number of Clusters",1);
   meNClustersOnTrack_diskm1 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Disk_m1","Number of Clusters (on track, diskm1)",50,0.,50.);
   meNClustersOnTrack_diskm1->setAxisTitle("Number of Clusters",1);
   meNClustersOnTrack_diskm2 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Disk_m2","Number of Clusters (on track, diskm2)",50,0.,50.);
   meNClustersOnTrack_diskm2->setAxisTitle("Number of Clusters",1);
 
   //not on track
   dbe_->setCurrentFolder("Pixel/Clusters/OffTrack");
   //bpix
   meClPosLayer1NotOnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_Layer_1","Clusters Layer1 (off track)",200,-30.,30.,128,-3.2,3.2);
   meClPosLayer1NotOnTrack->setAxisTitle("Global Z (cm)",1);
   meClPosLayer1NotOnTrack->setAxisTitle("Global #phi",2);
   meClPosLayer2NotOnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_Layer_2","Clusters Layer2 (off track)",200,-30.,30.,128,-3.2,3.2);
   meClPosLayer2NotOnTrack->setAxisTitle("Global Z (cm)",1);
   meClPosLayer2NotOnTrack->setAxisTitle("Global #phi",2);
   meClPosLayer3NotOnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_Layer_3","Clusters Layer3 (off track)",200,-30.,30.,128,-3.2,3.2);
   meClPosLayer3NotOnTrack->setAxisTitle("Global Z (cm)",1);
   meClPosLayer3NotOnTrack->setAxisTitle("Global #phi",2);
   //fpix
   meClPosDisk1pzNotOnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_pz_Disk_1","Clusters +Z Disk1 (off track)",80,-20.,20.,80,-20.,20.);
   meClPosDisk1pzNotOnTrack->setAxisTitle("Global X (cm)",1);
   meClPosDisk1pzNotOnTrack->setAxisTitle("Global Y (cm)",2);
   meClPosDisk2pzNotOnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_pz_Disk_2","Clusters +Z Disk2 (off track)",80,-20.,20.,80,-20.,20.);
   meClPosDisk2pzNotOnTrack->setAxisTitle("Global X (cm)",1);
   meClPosDisk2pzNotOnTrack->setAxisTitle("Global Y (cm)",2);
   meClPosDisk1mzNotOnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_mz_Disk_1","Clusters -Z Disk1 (off track)",80,-20.,20.,80,-20.,20.);
   meClPosDisk1mzNotOnTrack->setAxisTitle("Global X (cm)",1);
   meClPosDisk1mzNotOnTrack->setAxisTitle("Global Y (cm)",2);
   meClPosDisk2mzNotOnTrack = dbe_->book2D("position_" + clustersrc_.label() + "_mz_Disk_2","Clusters -Z Disk2 (off track)",80,-20.,20.,80,-20.,20.);
   meClPosDisk2mzNotOnTrack->setAxisTitle("Global X (cm)",1);
   meClPosDisk2mzNotOnTrack->setAxisTitle("Global Y (cm)",2);
 
   meNClustersNotOnTrack_all = dbe_->book1D("nclusters_" + clustersrc_.label(),"Number of Clusters (off Track)",50,0.,50.);
   meNClustersNotOnTrack_all->setAxisTitle("Number of Clusters",1);
   meNClustersNotOnTrack_bpix = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Barrel","Number of Clusters (off track, barrel)",50,0.,50.);
   meNClustersNotOnTrack_bpix->setAxisTitle("Number of Clusters",1);
   meNClustersNotOnTrack_fpix = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Endcap","Number of Clusters (off track, endcap)",50,0.,50.);
   meNClustersNotOnTrack_fpix->setAxisTitle("Number of Clusters",1);
   meNClustersNotOnTrack_layer1 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Layer_1","Number of Clusters (off track, layer1)",50,0.,50.);
   meNClustersNotOnTrack_layer1->setAxisTitle("Number of Clusters",1);
   meNClustersNotOnTrack_layer2 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Layer_2","Number of Clusters (off track, layer2)",50,0.,50.);
   meNClustersNotOnTrack_layer2->setAxisTitle("Number of Clusters",1);
   meNClustersNotOnTrack_layer3 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Layer_3","Number of Clusters (off track, layer3)",50,0.,50.);
   meNClustersNotOnTrack_layer3->setAxisTitle("Number of Clusters",1);
   meNClustersNotOnTrack_diskp1 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Disk_p1","Number of Clusters (off track, diskp1)",50,0.,50.);
   meNClustersNotOnTrack_diskp1->setAxisTitle("Number of Clusters",1);
   meNClustersNotOnTrack_diskp2 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Disk_p2","Number of Clusters (off track, diskp2)",50,0.,50.);
   meNClustersNotOnTrack_diskp2->setAxisTitle("Number of Clusters",1);
   meNClustersNotOnTrack_diskm1 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Disk_m1","Number of Clusters (off track, diskm1)",50,0.,50.);
   meNClustersNotOnTrack_diskm1->setAxisTitle("Number of Clusters",1);
   meNClustersNotOnTrack_diskm2 = dbe_->book1D("nclusters_" + clustersrc_.label() + "_Disk_m2","Number of Clusters (off track, diskm2)",50,0.,50.);
   meNClustersNotOnTrack_diskm2->setAxisTitle("Number of Clusters",1);
 
   //HitProbability
   //on track
   dbe_->setCurrentFolder("Pixel/Clusters/OnTrack");
   meHitProbability = dbe_->book1D("FractionLowProb","Fraction of hits with low probability;FractionLowProb;#HitsOnTrack",100,0.,1.);
 
   if (debug_) {
     // book summary residual histograms in a debugging folder - one (x,y) pair of histograms per subdetector 
     dbe_->setCurrentFolder("debugging"); 
     char hisID[80]; 
     for (int s=0; s<3; s++) {
       sprintf(hisID,"residual_x_subdet_%i",s); 
       meSubdetResidualX[s] = dbe_->book1D(hisID,"Pixel Hit-to-Track Residual in X",500,-5.,5.);
       
       sprintf(hisID,"residual_y_subdet_%i",s);
       meSubdetResidualY[s] = dbe_->book1D(hisID,"Pixel Hit-to-Track Residual in Y",500,-5.,5.);  
     }
   }
   
   firstRun = false;
   }
 }

void SiPixelTrackResidualSource::endJob ( void )

virtual

Reimplemented from edm::EDAnalyzer.

Definition at line 501 of file SiPixelTrackResidualSource.cc.

References dbe_, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), download_sqlite_cfg::outputFile, pSet_, DQMStore::save(), and AlCaHLTBitMon_QueryRunRegistry::string.

                                             {
   LogInfo("PixelDQM") << "SiPixelTrackResidualSource endJob()";
 
   // save the residual histograms to an output root file
   bool saveFile = pSet_.getUntrackedParameter<bool>("saveFile", true);
   if (saveFile) { 
     std::string outputFile = pSet_.getParameter<std::string>("outputFile");
     LogInfo("PixelDQM") << " - saving histograms to "<< outputFile.data();
     dbe_->save(outputFile);
   } 
   LogInfo("PixelDQM") << endl; // dbe_->showDirStructure();
 }

void SiPixelTrackResidualSource::triplets	(	double	x1,
		double	y1,
		double	z1,
		double	x2,
		double	y2,
		double	z2,
		double	x3,
		double	y3,
		double	z3,
		double	ptsig,
		double &	dc,
		double &	dz,
		double	kap
	)

Definition at line 1263 of file SiPixelTrackResidualSource.cc.

References gather_cfg::cout, kap, dttmaxenums::L, lam, diffTwoXMLs::r1, rho, and mathSSE::sqrt().

Referenced by analyze().

                                                                             {
   
   //Define some constants
   using namespace std;
 
   //Curvature kap from global Track
 
  //inverse of the curvature is the radius in the transverse plane
   double rho = 1/kap;
   //Check that the hits are in the correct layers
   double r1 = sqrt( x1*x1 + y1*y1 );
   double r3 = sqrt( x3*x3 + y3*y3 );
 
   if( r3-r1 < 2.0 ) cout << "warn r1 = " << r1 << ", r3 = " << r3 << endl;
   
   // Calculate the centre of the helix in xy-projection with radius rho from the track.
   //start with a line (sekante) connecting the two points (x1,y1) and (x3,y3) vec_L = vec_x3-vec_x1
   //with L being the length of that vector.
   double L=sqrt((x3-x1)*(x3-x1)+(y3-y1)*(y3-y1));
   //lam is the line from the middel point of vec_q towards the center of the circle X0,Y0
   // we already have kap and rho = 1/kap
   double lam = sqrt(rho*rho - L*L/4);
   
   // There are two solutions, the sign of kap gives the information
   // which of them is correct.
   //
   if( kap > 0 ) lam = -lam;
 
   //
   // ( X0, Y0 ) is the centre of the circle that describes the helix in xy-projection.
   //
   double x0 =  0.5*( x1 + x3 ) + lam/L * ( -y1 + y3 );
   double y0 =  0.5*( y1 + y3 ) + lam/L * (  x1 - x3 );
 
   // Calculate the dipangle in z direction (needed later for z residual) :
   //Starting from the heliz equation whihc has to hold for both points z1,z3
   double num = ( y3 - y0 ) * ( x1 - x0 ) - ( x3 - x0 ) * ( y1 - y0 );
   double den = ( x1 - x0 ) * ( x3 - x0 ) + ( y1 - y0 ) * ( y3 - y0 );
   double tandip = kap * ( z3 - z1 ) / atan( num / den );
 
  
   // angle from first hit to dca point:
   //
   double dphi = atan( ( ( x1 - x0 ) * y0 - ( y1 - y0 ) * x0 )
                       / ( ( x1 - x0 ) * x0 + ( y1 - y0 ) * y0 ) );
   //z position of the track based on the middle of the circle
   //track equation for the z component
   double uz0 = z1 + tandip * dphi * rho;
 
   //RESIDUAL IN R-PHI
   //Calculate distance dca2 from point (x2,y2) to the circle which is given by
   //the distance of the point to the middlepoint dcM = sqrt((x0-x2)^2+(y0-y2)) and rho
   //dca = rho +- dcM
   if(kap>0) dca2=rho-sqrt((x0-x2)*(x0-x2)+(y0-y2)*(y0-y2));
   else dca2=rho+sqrt((-x0+x2)*(-x0+x2)+(-y0+y2)*(-y0+y2));
 
   //RESIDUAL IN Z
   double xx =0 ;
   double yy =0 ;
   //sign of kappa determines the calculation
   //xx and yy are the new coordinates starting from x2, y2 that are on the track itself
   //vec_X2+-dca2*vec(X0-X2)/|(X0-X2)|
   if(kap<0){
     xx =   x2+(dca2*((x0-x2))/sqrt((x0-x2)*(x0-x2)+(y0-y2)*(y0-y2)));
     yy = y2+(dca2*((y0-y2))/sqrt((x0-x2)*(x0-x2)+(y0-y2)*(y0-y2)));
   }
   else if(kap>=0){
     xx =   x2-(dca2*((x0-x2))/sqrt((x0-x2)*(x0-x2)+(y0-y2)*(y0-y2)));
     yy = y2-(dca2*((y0-y2))/sqrt((x0-x2)*(x0-x2)+(y0-y2)*(y0-y2)));
   }
 
   //to get residual in z start with calculating the new uz2 position if one has moved to xx, yy
   //on the track. First calculate the change in phi2 with respect to the center X0, Y0
   double dphi2 = atan( ( ( xx - x0 ) * y0 - ( yy - y0 ) * x0 )
                / ( ( xx - x0 ) * x0 + ( yy - y0 ) * y0 ) );
   //Solve track equation for this new z depending on the dip angle of the track (see above
   //calculated based on X1, X3 and X0, use uz0 as reference point again.
   double  uz2= uz0 - dphi2*tandip*rho;
   
   //subtract new z position from the old one
   dz2=z2-uz2;
   
   //if we are interested in the arclength this is unsigned though
   //  double cosphi2 = (x2*xx+y2*yy)/(sqrt(x2*x2+y2*y2)*sqrt(xx*xx+yy*yy));
   //double arcdca2=sqrt(x2*x2+y2*y2)*acos(cosphi2);
   
 }