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Public Member Functions | Private Member Functions | Private Attributes

SiStripElectronAnalyzer Class Reference

#include <RecoEgamma/Examples/interface/SiStripElectronAnalyzer.h>

Inheritance diagram for SiStripElectronAnalyzer:
edm::EDAnalyzer

List of all members.

Public Member Functions

virtual void analyze (const edm::Event &, const edm::EventSetup &)
virtual void beginJob ()
virtual void endJob (void)
virtual void initNtuple (void)
 SiStripElectronAnalyzer (const edm::ParameterSet &)
 ~SiStripElectronAnalyzer ()

Private Member Functions

double unwrapPhi (double phi) const

Private Attributes

std::string basicClusterCollection_
std::string basicClusterProducer_
std::string eBRecHitCollection_
std::string eBRecHitProducer_
std::string electronCollection_
std::string electronProducer_
TH1F * emaxSuperClusters_
TH1F * emaxSuperClustersEl_
TH1F * energySuperClusters_
TH1F * energySuperClustersEl_
TH1F * energySuperClustersFailed
TH1F * energySuperClustersPassed
TH1F * eOverPFailed
TH1F * eOverPPassed
float EShower_ [myMaxHits]
TFile * file_
std::string fileName_
int MatchedDetector_ [myMaxHits]
float MatchedHitCorr_ [myMaxHits]
float MatchedHitNoise_ [myMaxHits]
float MatchedHitPhi_ [myMaxHits]
float MatchedHitR_ [myMaxHits]
float MatchedHitSignal_ [myMaxHits]
float MatchedHitSigX_ [myMaxHits]
float MatchedHitSigY_ [myMaxHits]
float MatchedHitTheta_ [myMaxHits]
int MatchedHitWidth_ [myMaxHits]
float MatchedHitX_ [myMaxHits]
float MatchedHitY_ [myMaxHits]
float MatchedHitZ_ [myMaxHits]
int MatchedLayer_ [myMaxHits]
std::string mctruthCollection_
std::string mctruthProducer_
int MonoDetector_ [myMaxHits]
float MonoHitCorr_ [myMaxHits]
float MonoHitNoise_ [myMaxHits]
float MonoHitPhi_ [myMaxHits]
float MonoHitR_ [myMaxHits]
float MonoHitSignal_ [myMaxHits]
float MonoHitSigX_ [myMaxHits]
float MonoHitSigY_ [myMaxHits]
float MonoHitTheta_ [myMaxHits]
int MonoHitWidth_ [myMaxHits]
float MonoHitX_ [myMaxHits]
float MonoHitY_ [myMaxHits]
float MonoHitZ_ [myMaxHits]
int MonoLayer_ [myMaxHits]
TTree * myTree_
int NMatchedHits_
int NMonoHits_
int NShowers_
int NStereoHits_
TH1F * numCand_
TH1F * numElectrons_
TH1F * numSiMatchedHits_
TH1F * numSiMonoHits_
TH1F * numSiStereoHits_
TH1F * numSuperClusters_
TH1F * pDiff
TH1F * pElectronFailed
TH1F * pElectronPassed
TH1F * phiWidthSuperClusters_
TH1F * phiWidthSuperClustersEl_
TH1F * ptDiff
TH1F * ptElectronFailed
TH1F * ptElectronPassed
std::string siElectronCollection_
std::string siElectronProducer_
std::string siHitProducer_
std::string siMatchedHitCollection_
std::string siRphiHitCollection_
std::string siStereoHitCollection_
TH1F * sizeSuperClusters_
TH1F * sizeSuperClustersEl_
TH1F * sizeSuperClustersFailed
TH1F * sizeSuperClustersPassed
int StereoDetector_ [myMaxHits]
float StereoHitCorr_ [myMaxHits]
float StereoHitNoise_ [myMaxHits]
float StereoHitPhi_ [myMaxHits]
float StereoHitR_ [myMaxHits]
float StereoHitSignal_ [myMaxHits]
float StereoHitSigX_ [myMaxHits]
float StereoHitSigY_ [myMaxHits]
float StereoHitTheta_ [myMaxHits]
int StereoHitWidth_ [myMaxHits]
float StereoHitX_ [myMaxHits]
float StereoHitY_ [myMaxHits]
float StereoHitZ_ [myMaxHits]
int StereoLayer_ [myMaxHits]
std::string superClusterCollection_
std::string superClusterProducer_
float XShower_ [myMaxHits]
float YShower_ [myMaxHits]
float ZShower_ [myMaxHits]

Detailed Description

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

Usage: <usage>

Definition at line 47 of file SiStripElectronAnalyzer.h.


Constructor & Destructor Documentation

SiStripElectronAnalyzer::SiStripElectronAnalyzer ( const edm::ParameterSet iConfig) [explicit]

Definition at line 70 of file SiStripElectronAnalyzer.cc.

References eBRecHitCollection_, eBRecHitProducer_, electronCollection_, electronProducer_, emaxSuperClusters_, emaxSuperClustersEl_, energySuperClusters_, energySuperClustersEl_, energySuperClustersFailed, energySuperClustersPassed, eOverPFailed, eOverPPassed, file_, fileName_, edm::ParameterSet::getParameter(), mctruthCollection_, mctruthProducer_, numCand_, numElectrons_, numSiMatchedHits_, numSiMonoHits_, numSiStereoHits_, numSuperClusters_, pDiff, pElectronFailed, pElectronPassed, phiWidthSuperClusters_, phiWidthSuperClustersEl_, ptDiff, ptElectronFailed, ptElectronPassed, siElectronCollection_, siElectronProducer_, siHitProducer_, siMatchedHitCollection_, siRphiHitCollection_, siStereoHitCollection_, sizeSuperClusters_, sizeSuperClustersEl_, sizeSuperClustersFailed, sizeSuperClustersPassed, AlCaHLTBitMon_QueryRunRegistry::string, superClusterCollection_, and superClusterProducer_.

{
  //now do what ever initialization is needed
  fileName_ = iConfig.getParameter<std::string>("fileName");

  file_ = new TFile(fileName_.c_str(), "RECREATE");
  numCand_ = new TH1F("numCandidates", "Number of candidates found", 10, -0.5, 9.5);
  numElectrons_ = new TH1F("numElectrons", "Number of Electrons found", 10, -0.5, 9.5);
  numSuperClusters_ = new TH1F("numSuperClusters","Number of Ecal SuperClusters", 50, 0, 50);


  energySuperClusters_= new TH1F("energySuperClusters","Super Cluster Energy - all ", 200 , 0, 2000.);
  energySuperClustersEl_= new TH1F("energySuperClustersEl","Super Cluster Energy - Electron Cands ", 200, 0., 2000.);


  sizeSuperClusters_= new TH1F("sizeSuperClusters","Super Cluster Size - all ", 20, 0, 19);
  sizeSuperClustersEl_= new TH1F("sizeSuperClustersEl","Super Cluster Size - Electron Cands ", 20, 0, 19);

  emaxSuperClusters_= new TH1F("emaxSuperClusters","Super Cluster Emax - all ", 200, 0, 2000.);
  emaxSuperClustersEl_= new TH1F("emaxSuperClustersEl","Super Cluster Emax - Electron Cands ", 200, 0, 2000.);

  phiWidthSuperClusters_ = new TH1F("phiWidthSuperClusters", "Super Cluster Width - all ",20,  0., 0.05 );
  phiWidthSuperClustersEl_ = new TH1F("phiWidthSuperClustersEl", "Super Cluster Width - Electron Cands ", 20 , 0., 0.05 );





  ptDiff = new TH1F("ptDiff"," ptDiff ", 20, -10.,10.);
  pDiff = new TH1F("pDiff"," pDiff ", 100, -50.,50.);


  pElectronFailed  = new TH1F("pElectronFailed"," pElectronFailed ", 55, 0.,110.);
  ptElectronFailed  = new TH1F("ptElectronFailed"," ptElectronFailed ", 55, 0.,110.);


  pElectronPassed  = new TH1F("pElectronPassed"," pElectronPassed ", 55, 0.,110.);
  ptElectronPassed  = new TH1F("ptElectronPassed"," ptElectronPassed ", 55, 0.,110.);


  sizeSuperClustersFailed= new TH1F("sizeSuperClustersFailed","Super Cluster Size - Failed ", 20, 0, 19);
  sizeSuperClustersPassed= new TH1F("sizeSuperClustersPassed","Super Cluster Size - Passed ", 20, 0, 19);


  energySuperClustersPassed= new TH1F("energySuperClustersPassed","Super Cluster Energy - Passed ", 125, 0, 250.);
  energySuperClustersFailed= new TH1F("energySuperClustersFailed","Super Cluster Energy - Failed ", 125, 0, 250.);


  eOverPFailed = new TH1F("eOverPFailed"," E over P - Failed ", 50, 0, 10.) ;
  eOverPPassed = new TH1F("eOverPPassed"," E over P - Passed ", 50, 0, 10.) ;




  numSiStereoHits_ = new TH1F("numSiStereoHits","Number of Si StereoHits",100,0,1000);
  numSiMonoHits_ = new TH1F("numSiMonoHits","Number of Si MonoHits",100,0,1000);
  numSiMatchedHits_ = new TH1F("numSiMatchedHits","Number of Si MatchedHits",100,0,1000);






  mctruthProducer_ = iConfig.getParameter<std::string>("mctruthProducer");
  mctruthCollection_ = iConfig.getParameter<std::string>("mctruthCollection");

  superClusterProducer_ = iConfig.getParameter<std::string>("superClusterProducer");
  superClusterCollection_ = iConfig.getParameter<std::string>("superClusterCollection");

  eBRecHitProducer_ = iConfig.getParameter<std::string>("recHitProducer");
  eBRecHitCollection_ = iConfig.getParameter<std::string>("recHitCollection");

  siElectronProducer_ = iConfig.getParameter<std::string>("siElectronProducer");
  siElectronCollection_ = iConfig.getParameter<std::string>("siElectronCollection");

  electronProducer_ = iConfig.getParameter<std::string>("electronProducer");
  electronCollection_ = iConfig.getParameter<std::string>("electronCollection");

  siHitProducer_ = iConfig.getParameter<std::string>("siHitProducer");
  siRphiHitCollection_ = iConfig.getParameter<std::string>("siRphiHitCollection");
  siStereoHitCollection_ = iConfig.getParameter<std::string>("siStereoHitCollection");
  siMatchedHitCollection_ = iConfig.getParameter<std::string>("siMatchedHitCollection");

}
SiStripElectronAnalyzer::~SiStripElectronAnalyzer ( )

Definition at line 161 of file SiStripElectronAnalyzer.cc.

References file_.

{

  // do anything here that needs to be done at desctruction time
  // (e.g. close files, deallocate resources etc.)

  file_->Write();
  file_->Close();
}

Member Function Documentation

void SiStripElectronAnalyzer::analyze ( const edm::Event iEvent,
const edm::EventSetup iSetup 
) [virtual]

For events w/ more than 1 electron candidate, try to plot m(e,e)

//////////////////////////////////////////////////////////////////////////////// ////////////////// Now for tracker hits: ///////////////////////////////////////

loop again to get all info into myTree

Implements edm::EDAnalyzer.

Definition at line 328 of file SiStripElectronAnalyzer.cc.

References abs, alignCSCRings::e, eBRecHitCollection_, eBRecHitProducer_, electronCollection_, electronProducer_, HI_PhotonSkim_cff::electrons, emaxSuperClusters_, emaxSuperClustersEl_, relval_parameters_module::energy, energySuperClusters_, energySuperClustersEl_, EShower_, funct::false, edm::EventSetup::get(), edm::Event::getByLabel(), i, initNtuple(), TIBDetId::layer(), TOBDetId::layer(), LogDebug, mag(), MatchedDetector_, MatchedHitCorr_, MatchedHitNoise_, MatchedHitPhi_, MatchedHitR_, MatchedHitSignal_, MatchedHitSigX_, MatchedHitSigY_, MatchedHitTheta_, MatchedHitWidth_, MatchedHitX_, MatchedHitY_, MatchedHitZ_, MatchedLayer_, MonoDetector_, MonoHitCorr_, MonoHitNoise_, MonoHitPhi_, MonoHitR_, MonoHitSignal_, MonoHitSigX_, MonoHitSigY_, MonoHitTheta_, MonoHitWidth_, MonoHitX_, MonoHitY_, MonoHitZ_, MonoLayer_, myMaxHits, myTree_, NMatchedHits_, NMonoHits_, NShowers_, NStereoHits_, numCand_, numElectrons_, numSiMatchedHits_, numSiMonoHits_, numSiStereoHits_, numSuperClusters_, pDiff, pElectronFailed, pElectronPassed, PV3DBase< T, PVType, FrameType >::perp(), PV3DBase< T, PVType, FrameType >::phi(), phiWidthSuperClusters_, phiWidthSuperClustersEl_, pos, position, funct::pow(), ptDiff, ptElectronFailed, ptElectronPassed, siElectronCollection_, siElectronProducer_, Signal, siHitProducer_, siMatchedHitCollection_, siRphiHitCollection_, siStereoHitCollection_, sizeSuperClusters_, sizeSuperClustersEl_, sizeSuperClustersFailed, sizeSuperClustersPassed, mathSSE::sqrt(), StereoDetector_, StereoHitCorr_, StereoHitNoise_, StereoHitPhi_, StereoHitR_, StereoHitSignal_, StereoHitSigX_, StereoHitSigY_, StereoHitTheta_, StereoHitWidth_, StereoHitX_, StereoHitY_, StereoHitZ_, StereoLayer_, superClusterCollection_, superClusterProducer_, PV3DBase< T, PVType, FrameType >::theta(), sistripsummary::TIB, StripSubdetector::TIB, sistripsummary::TOB, funct::true, PV3DBase< T, PVType, FrameType >::x(), XShower_, LocalError::xx(), LocalError::xy(), PV3DBase< T, PVType, FrameType >::y(), YShower_, LocalError::yy(), PV3DBase< T, PVType, FrameType >::z(), and ZShower_.

{
  using namespace std;  // so you can say "cout" and "endl"

  initNtuple();


  // https://cmsdoc.cern.ch/swdev/lxr/CMSSW/source/clhep/CLHEP/HepMC/GenParticle.h
  // https://cmsdoc.cern.ch/swdev/lxr/CMSSW/source/clhep/CLHEP/HepMC/GenVertex.h
  // removed by JED - causes trouble in release post 0_9_0
  //   edm::Handle<edm::HepMCProduct> mctruthHandle;
  //   iEvent.getByLabel(mctruthProducer_, mctruthCollection_, mctruthHandle);
  //   HepMC::GenEvent mctruth = mctruthHandle->getHepMCData();

  //   for (HepMC::GenEvent::particle_const_iterator partIter = mctruth.particles_begin();
  //    partIter != mctruth.particles_end();
  //    ++partIter) {
  // //    for (HepMC::GenEvent::vertex_const_iterator vertIter = mctruth.vertices_begin();
  // //         vertIter != mctruth.vertices_end();
  // //         ++vertIter) {
  //    CLHEP::HepLorentzVector creation = (*partIter)->CreationVertex();
  //    CLHEP::HepLorentzVector momentum = (*partIter)->Momentum();
  //   HepPDT::ParticleID id = (*partIter)->particleID();  // electrons and positrons are 11 and -11
  //     edm::LogInfo("") << "MC particle id " << id.pid() << ", creationVertex " << creation << " cm, initialMomentum " << momentum << " GeV/c" << endl;
  //  }

  // load the rechits for the Ecal
  edm::Handle<EcalRecHitCollection> pRecHits;
  iEvent.getByLabel(eBRecHitProducer_, eBRecHitCollection_, pRecHits);
  // Create a pointer to the RecHits  - unused for now
  //  const EcalRecHitCollection *hitCollection = pRecHits.product();


  // https://cmsdoc.cern.ch/swdev/lxr/CMSSW/source/self/DataFormats/EgammaReco/interface/SuperCluster.h
  edm::Handle<reco::SuperClusterCollection> clusterHandle;
  iEvent.getByLabel(superClusterProducer_, superClusterCollection_, clusterHandle);



  LogDebug("") << " Start loop over "
               << clusterHandle->end()-clusterHandle->begin()
               << "  superClusters " ;

  for (reco::SuperClusterCollection::const_iterator clusterIter = clusterHandle->begin();
       clusterIter != clusterHandle->end();
       ++clusterIter) {
    double energy = clusterIter->energy();
    math::XYZPoint position = clusterIter->position();
    std::ostringstream str;

    str  << " SuperCluster " << energy << " GeV, position "
         << position << " cm" << "\n" ;

    energySuperClusters_->Fill(energy);
    sizeSuperClusters_->Fill(clusterIter->clustersSize());
    // this only makes sense for hybrid superclusters

    // try to point to the constituent clusters for this SuperCluster

    str << "About to loop over basicClusters" << "\n" ;

    double emaxSuperCluster = 0. ;
    double phibar = 0. ;
    double phi2bar = 0. ;
    double eTotSuperCluster = 0. ;



    for (reco::CaloCluster_iterator basicClusterIter = clusterIter->clustersBegin() ;
         basicClusterIter != clusterIter->clustersEnd() ;
         ++basicClusterIter ){

      //std::vector<DetId> theIds= (*basicClusterIter)->getHitsByDetId();

      str << " basicCluster Energy " << (*basicClusterIter)->energy()
          << " Position " << (*basicClusterIter)->position()
          << " \n"
          << "        Position phi " << (*basicClusterIter)->position().phi()
          << " recHits " << (*basicClusterIter)->size()
          << " \n" ;

      double eCluster =  (*basicClusterIter)->energy();
      if(eCluster > emaxSuperCluster  ){
        emaxSuperCluster = eCluster ;
      }
      eTotSuperCluster += eCluster ;
      double phiCluster = (*basicClusterIter)->position().phi() ;
      phibar += eCluster * phiCluster ;
      phi2bar += eCluster * phiCluster * phiCluster ;


    } // end of basicClusterIter loop



    phibar= phibar /eTotSuperCluster ;
    phi2bar= phi2bar /eTotSuperCluster ;
    double phiWidth = phi2bar - phibar*phibar ;
    if(phiWidth>0.) {
      phiWidth = std::pow(phiWidth,0.5);
    }else{
      phiWidth =0.;
    }
    str << " SuperCluster stats " << "\n" ;
    str << "phibar " << phibar
        << " phi2bar " << phi2bar
        << " eTotSuperCluster " << eTotSuperCluster
        << " phiWidth " << phiWidth
        << std::endl  ;

    phiWidthSuperClusters_->Fill(phiWidth);

    emaxSuperClusters_->Fill(emaxSuperCluster);

    str << " Done with this SuperCluster " << std::endl;

    LogDebug("") << str.str() ;

  } // end of loop over superClusters

  LogDebug("") << " End loop over superClusters ";



  //
  // loop over all EcalRecHits and print out their x,y,z,E
  //  edm::LogInfo("") << " Dumping all recHits in this event " << endl ;
  // for(EcalRecHitCollection::const_iterator _blah = hitCollection->begin();
  //     _blah != hitCollection->end() ; ++_blah ) {
  //   edm::LogInfo("") << "Ecal RecHit Energy: " << _blah->energy() << endl ;
  //   //      " Position " << _blah.position() << endl ;
  //  }
  //
  //  edm::LogInfo("") << "Dump finished " << endl ;
  //




  // DataFormats/EgammaCandidates/src/SiStripElectron.cc
  edm::Handle<reco::SiStripElectronCollection> siStripElectronHandle;
  iEvent.getByLabel(siElectronProducer_, siElectronCollection_, siStripElectronHandle);





  LogDebug("") << " Dumping Algo's guess of SiStripElectron Candidate Info " ;
  int numberOfElectrons = 0;
  // need to check if fit succeeded
  LogDebug("") << " Number of SiStripElectrons  " << siStripElectronHandle->size() ;


  for (reco::SiStripElectronCollection::const_iterator electronIter = siStripElectronHandle->begin();
       electronIter != siStripElectronHandle->end();  ++electronIter) {


    LogDebug("")  << "about to get stuff from electroncandidate "
                  << numberOfElectrons << "\n"
                  << "supercluster energy = "
                  << electronIter->superCluster()->energy() << "\n"
                  << "fit results are phi(r) = "
                  << electronIter->phiAtOrigin() << " + "
                  << electronIter->phiVsRSlope() << "*r" << "\n"
                  << " chi2 " << electronIter->chi2()
                  << " ndof " << electronIter->ndof() << "\n"
                  << " Pt " << electronIter->pt() << "\n"
                  << "P, Px, Py, Pz  "
                  << electronIter->p() << " "
                  << electronIter->px() << " "
                  << electronIter->py() << " "
                  << electronIter->pz() << "\n"
                  << "you get the idea..." ;

    // make plots for supercluster that an electron has been associ w/. here
    energySuperClustersEl_->Fill(electronIter->superCluster()->energy());
    sizeSuperClustersEl_->Fill(electronIter->superCluster()->clustersSize());

    // loop over basicClusters to get energy
    double emaxSuperCluster = 0. ;
    double phibar = 0. ;
    double phi2bar = 0. ;
    double eTotSuperCluster = 0. ;

    for (reco::CaloCluster_iterator basicClusterIter = electronIter->superCluster()->clustersBegin() ;
         basicClusterIter != electronIter->superCluster()->clustersEnd() ;
         ++basicClusterIter ){

      //std::vector<DetId> theIds= (*basicClusterIter)->getHitsByDetId();

      double eCluster =  (*basicClusterIter)->energy();
      if(eCluster > emaxSuperCluster  ){
        emaxSuperCluster = eCluster ;
      }
      eTotSuperCluster += eCluster ;
      double phiCluster = (*basicClusterIter)->position().phi() ;
      phibar += eCluster * phiCluster ;
      phi2bar += eCluster * phiCluster * phiCluster ;

    }

    phibar=phibar/eTotSuperCluster ;
    phi2bar=phi2bar/eTotSuperCluster ;
    double phiWidth = phi2bar - phibar*phibar ;
    if(phiWidth>0.) {
      phiWidth = std::pow(phiWidth,0.5);
    }else{
      phiWidth =0.;
    }

    phiWidthSuperClustersEl_->Fill(phiWidth);

    emaxSuperClustersEl_->Fill(emaxSuperCluster);

    numberOfElectrons++;
  }

  numCand_->Fill(siStripElectronHandle->size());




  // Now loop over the electrons (ie the fitted things.)

  LogDebug("")<< " About to check Electrons" ;

  edm::Handle<reco::ElectronCollection> electrons ;
  iEvent.getByLabel(electronProducer_, electronCollection_, electrons);

  numElectrons_->Fill(electrons->end()- electrons->begin());

  // set up vector of bool for SiStrips having or not having Electrons
  // this causes a warning because of variable array size at compilation time ;
  // BAD  bool hasElectron_[siStripElectronHandle->end()- siStripElectronHandle->begin()] ;
  bool* hasElectron_ = new bool[siStripElectronHandle->end()- siStripElectronHandle->begin()] ;
  for (int icount = 0 ;
       icount < siStripElectronHandle->end()- siStripElectronHandle->begin() ;
       ++icount)
    { hasElectron_[icount] = false ;}

  // also set up a counter to associate the ith electron to the jth strippy
  // Electron_to_strippy[i] = j: i-th Electron is j-th strippy
  // BAD  unsigned int Electron_to_strippy[electrons->end()- electrons->begin()];
  unsigned int* Electron_to_strippy = new unsigned int[electrons->end()- electrons->begin()];
  for (int icount = 0 ;
       icount <electrons->end()- electrons->begin();  ++icount)
    { Electron_to_strippy[icount] = 0 ;}

  unsigned int ecount=0 ;
  for (reco::ElectronCollection::const_iterator electronIter = electrons->begin();
       electronIter != electrons->end(); ++electronIter ){


    LogDebug("")<< " Associating Electrons to Strippies " ;
    LogDebug("")<< " PT is " << electronIter->track()->pt() ;

    reco::TrackRef tr =(*electronIter).track();
    uint32_t id = (*electronIter->track()->recHitsBegin())->geographicalId().rawId();
    LocalPoint pos = (*electronIter->track()->recHitsBegin())->localPosition();

    unsigned int icount = 0 ;
    LogDebug("") << " About to loop over Strippies " << " \n "
                 << " icount " << icount
                 << " max " << siStripElectronHandle->end()- siStripElectronHandle->begin() ;

    for (reco::SiStripElectronCollection::const_iterator strippyiter = siStripElectronHandle->begin();
         strippyiter != siStripElectronHandle->end(); ++strippyiter) {

      bool hitInCommon = false;
      // loop over rphi hits
      for (std::vector<SiStripRecHit2D>::const_iterator
             hiter = strippyiter->rphiRecHits().begin();
           hiter != strippyiter->rphiRecHits().end();
           ++hiter) {
        if (hiter->geographicalId().rawId() == id  &&
            (hiter->localPosition() - pos).mag() < 1e-10) {
          hitInCommon = true;
          break;
        }
      }

      for (std::vector<SiStripRecHit2D>::const_iterator
             hiter = strippyiter->stereoRecHits().begin();
           hiter != strippyiter->stereoRecHits().end();
           ++hiter) {
        if (hiter->geographicalId().rawId() == id  &&
            (hiter->localPosition() - pos).mag() < 1e-10) {
          hitInCommon = true;
          break;
        }
      }
      if (hitInCommon) {  //this Electron belongs to this SiStripElectron.
        hasElectron_[icount] = true ;
        Electron_to_strippy[ecount]= icount ;
        ptDiff->Fill( std::abs(electronIter->track()->pt()) - std::abs(strippyiter->pt()) );
        pDiff->Fill( std::abs(electronIter->track()->p()) - std::abs(strippyiter->p()) );

      }
      icount++ ;
    } // Sistrip loop
    ecount++;
  } // Electrons

  LogDebug("") << " Done looping over Electrons " ;


  unsigned int counter = 0 ;
  for (reco::SiStripElectronCollection::const_iterator strippyIter = siStripElectronHandle->begin();  strippyIter != siStripElectronHandle->end();  ++strippyIter) {


    bool skipThis = !hasElectron_[counter] ;
    if( skipThis ) {
      // plot stuff for SIStripElectrons that don't have fits associated

      LogDebug("") << " SiStrip Failed Electron " << " \n " <<
        " p " << strippyIter->p() << " \n " <<
        " pt " << strippyIter->pt() << " \n " <<
        " SuperClust size " << strippyIter->superCluster()->clustersSize() ;

      pElectronFailed->Fill( std::abs(strippyIter->p()) );
      ptElectronFailed->Fill( std::abs(strippyIter->pt()) );
      sizeSuperClustersFailed->Fill(strippyIter->superCluster()->clustersSize());
      LogDebug("") << " done filling Failed histos " ;
      //      energySuperClustersFailed->Fill(strippyIter->superCluster()->energy());
      //       if(strippyIter->p()>0.) {
      //        eOverPFailed->Fill(strippyIter->superCluster()->energy()/strippyIter->p());
      //       }else {
      //        eOverPFailed->Fill(-1.0);
      //       }

    } else {
      LogDebug("") << " SiStrip Passed Electron " << " \n " <<
        " p " << strippyIter->p() << " \n " <<
        " pt " << strippyIter->pt() << " \n " <<
        " SuperClust size " << strippyIter->superCluster()->clustersSize() ;
      pElectronPassed->Fill( std::abs(strippyIter->p()) );
      ptElectronPassed->Fill( std::abs(strippyIter->pt()) );
      sizeSuperClustersPassed->Fill(strippyIter->superCluster()->clustersSize());
      LogDebug("") << " done filling passed histos " ;
      //      energySuperClustersPassed->Fill(strippyIter->superCluster()->energy());
      //       if(strippyIter->p()>0.) {
      //        eOverPPassed->Fill(strippyIter->superCluster()->energy()/strippyIter->p());
      //       }else {
      //        eOverPPassed->Fill(-1.0);
      //       }

    } // skipThis
    counter++;
  }

  LogDebug("")<< "Dump info for all electrons ";

  for (reco::ElectronCollection::const_iterator electronIter1 = electrons->begin();
       electronIter1 != electrons->end(); ++electronIter1 ){
    reco::TrackRef tr1 =(*electronIter1).track();
    // let's find its associated SiStripElectron and SuperCluster
    unsigned int ecount1= electronIter1-electrons->begin() ;
    unsigned int stripCount1 = 0 ;
    reco::SiStripElectronCollection::const_iterator strippyIter1 ;
    for (reco::SiStripElectronCollection::const_iterator strippyIter = siStripElectronHandle->begin();
         strippyIter != siStripElectronHandle->end();  ++strippyIter) {
      if(Electron_to_strippy[ecount1]==stripCount1 ) {
        strippyIter1 = strippyIter ;
        break ; }
      stripCount1++ ;
    } // strippy loop
    ecount1++;

    std::ostringstream str;


    str << " SiStripElect p , px, py, pz " << strippyIter1->p()
        << "  " << strippyIter1->px()
        << "  " << strippyIter1->py()
        << "  " << strippyIter1->pz()
        << "\n " << std::endl ;


    str  << " Electron p px, py, pz,  = " << tr1->p()
         << "  " << tr1->px()
         << "  " << tr1->py()
         << "  " << tr1->pz()
         << "\n" <<  std::endl ;


    double EClust1 = strippyIter1->superCluster()->energy() ;
    double XClust1 = strippyIter1->superCluster()->x();
    double YClust1 = strippyIter1->superCluster()->y();
    double ZClust1 = strippyIter1->superCluster()->z();

    double rho1 = sqrt(XClust1*XClust1+YClust1*YClust1+ZClust1*ZClust1) ;
    double costheta1 = ZClust1/rho1 ;
    double sintheta1 = sqrt(1-costheta1*costheta1);
    if(ZClust1<0 ) { sintheta1 = - sintheta1 ; }
    double cosphi1 = XClust1/sqrt(XClust1*XClust1+YClust1*YClust1);
    double sinphi1 = YClust1/sqrt(XClust1*XClust1+YClust1*YClust1);

    str << " Ecal for electron E, px, py, pz "
        << EClust1 << " "
        << EClust1*sintheta1*cosphi1 << " "
        << EClust1*sintheta1*sinphi1  << " "
        << EClust1*costheta1
        << "\n" << std::endl ;

    LogDebug("") << str.str() ;

  } // loop over electrons
 LogDebug("")<< "Done Dumping info for all electrons ";

  // LogDebug("")<< " Checking Electrons" ;
  //  LogDebug("")<< " PT is " << electronIter->track()->pt() ;
  //    reco::TrackRef tr =(*electronIter).track();
  if(electrons->end()-electrons->begin()> 1) {
    edm::LogInfo("") << " Two electrons in this event " << std::endl;
    for (reco::ElectronCollection::const_iterator electronIter1 = electrons->begin();
         electronIter1 != electrons->end()-1; ++electronIter1 ){
      reco::TrackRef tr1 =(*electronIter1).track();

      // let's find its associated SiStripElectron and SuperCluster
      // use the Electron_to_strippy[] array
      unsigned int ecount1= electronIter1-electrons->begin() ;
      // loop over strippies to find the corresponding one
      unsigned int stripCount1 = 0 ;
      reco::SiStripElectronCollection::const_iterator strippyIter1 ;
      for (reco::SiStripElectronCollection::const_iterator strippyIter = siStripElectronHandle->begin();  strippyIter != siStripElectronHandle->end();  ++strippyIter) {
        if(Electron_to_strippy[ecount1]==stripCount1 ) {
          strippyIter1 = strippyIter ;
          break ; }
        stripCount1++ ;
      } // strippy loop

      double EClust1 = strippyIter1->superCluster()->energy() ;
      double XClust1 = strippyIter1->superCluster()->x();
      double YClust1 = strippyIter1->superCluster()->y();
      double ZClust1 = strippyIter1->superCluster()->z();

      for (reco::ElectronCollection::const_iterator electronIter2 = electronIter1+1;
           electronIter2 != electrons->end(); ++electronIter2 ){

        reco::TrackRef tr2 =(*electronIter2).track();

        unsigned int ecount2= electronIter2-electrons->begin() ;
        unsigned int stripCount2 = 0 ;
        reco::SiStripElectronCollection::const_iterator strippyIter2 ;
        for (reco::SiStripElectronCollection::const_iterator strippyIter = siStripElectronHandle->begin();  strippyIter != siStripElectronHandle->end();  ++strippyIter) {
          if(Electron_to_strippy[ecount2]==stripCount2 ) {
            strippyIter2 = strippyIter ;
            break ; }
          stripCount2++ ;
        } // strippy loop



        double EClust2 = strippyIter2->superCluster()->energy() ;
        double XClust2 = strippyIter2->superCluster()->x();
        double YClust2 = strippyIter2->superCluster()->y();
        double ZClust2 = strippyIter2->superCluster()->z();


        // now get supercluster from this:


        edm::LogInfo("")  << " Electron p1 = " << tr1->p()
                          << " p1x " << tr1->px()
                          << " p1y " << tr1->py()
                          << " p1z " << tr1->pz()
                          << std::endl ;


        edm::LogInfo("")  << " Electron p2 = " << tr2->p()
                          << " p2x " << tr2->px()
                          << " p2y " << tr2->py()
                          << " p2z " << tr2->pz()
                          << std::endl ;


        // combine the two in an (e,e) pair
        double Zpx = tr1->px()+tr2->px() ;
        double Zpy = tr1->py()+tr2->py() ;
        double Zpz = tr1->pz()+tr2->pz() ;
        double Ze = std::abs(tr1->p())+std::abs(tr2->p()) ;
        edm::LogInfo("") << " Z mass " <<
          sqrt(Ze*Ze-Zpx*Zpx-Zpy*Zpy-Zpz*Zpz) << std::endl ;

        // combine the SuperClusts into a Z
        double rho1 = sqrt(XClust1*XClust1+YClust1*YClust1+ZClust1*ZClust1) ;
        double costheta1 = ZClust1/rho1 ;
        double sintheta1 = sqrt(1-costheta1*costheta1);
        if(ZClust1<0 ) { sintheta1 = - sintheta1 ; }
        double cosphi1 = XClust1/sqrt(XClust1*XClust1+YClust1*YClust1);
        double sinphi1 = YClust1/sqrt(XClust1*XClust1+YClust1*YClust1);

        double rho2 = sqrt(XClust2*XClust2+YClust2*YClust2+ZClust2*ZClust2) ;
        double costheta2 = ZClust2/rho2 ;
        double sintheta2 = sqrt(1-costheta2*costheta2);
        if(ZClust2<0 ) { sintheta2 = - sintheta2 ; }
        double cosphi2 = XClust2/sqrt(XClust2*XClust2+YClust2*YClust2);
        double sinphi2 = YClust2/sqrt(XClust2*XClust2+YClust2*YClust2);

        edm::LogInfo("") << "Energy of supercluster for 1st electron "
                         << EClust1 << " "
                         << EClust1*sintheta1*cosphi1 << " "
                         << EClust1*sintheta1*sinphi1  << " "
                         << EClust1*costheta1  << " "
                         << std::endl ;

        edm::LogInfo("") << "Energy of supercluster for 2nd electron "
                         << EClust2 << " "
                         << EClust2*sintheta2*cosphi2 << " "
                         << EClust2*sintheta2*sinphi2  << " "
                         << EClust2*costheta2  << " "
                         << std::endl ;


        // get the supercluster pair
        double Zgpx = EClust1*sintheta1*cosphi1+EClust2*sintheta2*cosphi2 ;
        double Zgpy = EClust1*sintheta1*sinphi1+EClust2*sintheta2*sinphi2 ;
        double Zgpz = EClust1*costheta1+EClust2*costheta2 ;
        double ZgE = EClust1+EClust2 ;

        edm::LogInfo("") << " Z mass from ECAL " <<
          sqrt(ZgE*ZgE-Zgpx*Zgpx-Zgpy*Zgpy-Zgpz*Zgpz) << std::endl ;


      } //inner loop
    } // outer loop
  }// m(ee) loop

  delete[] hasElectron_;
  delete[] Electron_to_strippy;

  LogDebug("") << " About to dump tracker info " ;

  edm::ESHandle<TrackerGeometry> trackerHandle;
  iSetup.get<TrackerDigiGeometryRecord>().get(trackerHandle);

  edm::Handle<SiStripRecHit2DCollection> rphiHitsHandle;
  iEvent.getByLabel(siHitProducer_, siRphiHitCollection_, rphiHitsHandle);

  edm::Handle<SiStripRecHit2DCollection> stereoHitsHandle;
  iEvent.getByLabel(siHitProducer_, siStereoHitCollection_, stereoHitsHandle);

  edm::Handle<SiStripMatchedRecHit2DCollection> matchedHitsHandle;
  iEvent.getByLabel(siHitProducer_, siMatchedHitCollection_, matchedHitsHandle);


  NShowers_=0 ;
  for (reco::SuperClusterCollection::const_iterator clusterIter = clusterHandle->begin();
       clusterIter != clusterHandle->end();
       ++clusterIter) {
    double energy = clusterIter->energy();
    math::XYZPoint position = clusterIter->position();
    if(NShowers_ < myMaxHits ) {
      EShower_[NShowers_] = energy ;
      XShower_[NShowers_] = position.x() ;
      YShower_[NShowers_] = position.y() ;
      ZShower_[NShowers_] = position.z() ;
      ++NShowers_ ;
    }
    // Loop over all crystals in this supercluster - see
    // RecoEcal/EgamaClusterProducers/src/EgammaSimpleAnalyzer.cc
    // Look also at DataFormats/EgammaReco/interface/SuperCluster.h

  }
  numSuperClusters_->Fill(NShowers_);


  LogDebug("") << " Looping over stereo hits " ;


  int myHits = 0 ;
  for (SiStripRecHit2DCollection::DataContainer::const_iterator hit = stereoHitsHandle->data().begin(), hitend = stereoHitsHandle->data().end();
          hit != hitend;  ++hit) {
      DetId id(hit->geographicalId());
      if( (hit->geographicalId()).subdetId() == StripSubdetector::TIB  ||
          (hit->geographicalId()).subdetId() == StripSubdetector::TOB    ) {
        GlobalPoint position = trackerHandle->idToDet(hit->geographicalId())->surface().toGlobal(hit->localPosition());
        //from RecoLocalTracker/SiStripClusterizer/test/TestCluster.cc
        // cf also TrackHitAssociator.cc SiStripRecHitMatcher.cc SiStrip1DMeasurementTransformator.cc (KalmanUpdators)
        SiStripRecHit2D const rechit = *hit ;
        //      LocalPoint myposition = rechit.localPosition() ;
        LocalError myerror = rechit.localPositionError();

        // Get layer and subdetector ID here for this hit
        // see SiStripRecHitConverter/test/ValHit.cc
        Int_t siLayerNum = 0 ;
        Int_t siDetNum = 0 ;
        string siDetName = "" ;
        if( (hit->geographicalId()).subdetId() == StripSubdetector::TIB ){
          //       siLayerNum = TIBDetId(rechit->geographicalID()).layer();
          siLayerNum = TIBDetId(id).layer();
          siDetNum = 1 ;
          siDetName = "TIB" ;
        } else if ( (hit->geographicalId()).subdetId() == StripSubdetector::TOB ){
          siLayerNum = TOBDetId(id).layer();
          siDetNum = 2 ;
          siDetName = "TOB" ;
          //            } else if ( (hit->geographicalId()).subdetId() == StripSubdetector::TID ){
          //      // should we use side/wheel/ring/module/stereo() ?
          //      siLayerNum = TIDDetId(id).wheel();
          //      siDetNum = 3 ;
          //      siDetName = "TID" ;
          //    }else if ( (hit->geographicalId()).subdetId() == StripSubdetector::TEC ){
          //      //choices are side/petal/wheel/ring/module/glued/stereo
          //      siLayerNum = TECDetId(id).wheel();
          //      siDetNum = 4 ;
          //      siDetName = "TEC" ;
        }else {
          siLayerNum = -999 ;
          siDetNum = -999 ;
          siDetName = "NULL" ;
        }
        //      LogDebug("") << siDetName << " " << siLayerNum ;

        const SiStripRecHit2D::ClusterRef & clust=rechit.cluster();
        double Signal = 0 ;
        double Noise2 = 0 ;
        int StripCount = 0 ;
        if(clust.isNonnull()) {
          //      LogDebug("") << " barycenter " << clust->barycenter() ;
          //      const std::vector<uint16_t> amplitudes=clust->amplitudes();
          const std::vector<uint8_t> amplitudes=clust->amplitudes();
          for(size_t i = 0 ; i<amplitudes.size(); i++ ){
            Signal +=amplitudes[i] ;
            //ignore for now         Noise2 +=SiStripNoiseService_.getNoise(detid,clust->firstStrip()+i)*SiStripNoiseService_.getNoise(detid,clust->firstStrip()+i);
            StripCount++;
          }
        } else {
          LogDebug("") << " null cluster " ;
        }
        //      LogDebug("") << "Signal " << Signal << " Noise2 " << Noise2 << " StripCount " << StripCount ;
        // Dump position
        //      LogDebug("") << " Stereo "
        //                       << "local position: "<<myposition.x()<<" "
        //                       << myposition.y()<<" "<<myposition.z()<<"\n"
        //                       << "local error: "<<myerror.xx()<<" "
        //                       << myerror.xy()<<" "<<myerror.yy() << "\n"
        //                       << "global position: " << position.x() << " "
        //                       <<  position.y()<<" "<< position.z()<<"\n"
        //                       << " siDetNum " << siDetNum
        //                       << " siLayerNum " << siLayerNum ;


        if( myHits < myMaxHits ) {
          StereoHitX_[myHits] = position.x();
          StereoHitY_[myHits] = position.y();
          StereoHitZ_[myHits] = position.z();

          StereoHitR_[myHits]=position.perp();
          StereoHitPhi_[myHits]=position.phi();
          StereoHitTheta_[myHits]=position.theta();

          StereoHitSigX_[myHits]=sqrt(myerror.xx());
          StereoHitSigY_[myHits]=sqrt(myerror.yy());
          StereoHitCorr_[myHits]=myerror.xy()/sqrt(myerror.xx()*myerror.yy());

          StereoHitSignal_[myHits] = Signal ;
          StereoHitNoise_[myHits] = Noise2 ;
          StereoHitWidth_[myHits] = StripCount ;

          StereoDetector_[myHits] = siDetNum ;
          StereoLayer_[myHits] = siLayerNum ;

          ++myHits ;
        }
      } // end if this is the right subdetector
  } // end loop over hits
  NStereoHits_ = myHits ;

  numSiStereoHits_->Fill(NStereoHits_);


  LogDebug("") << " Looping over Mono Hits " ;
  myHits = 0 ;
  for (SiStripRecHit2DCollection::DataContainer::const_iterator hit = rphiHitsHandle->data().begin(), hitend = rphiHitsHandle->data().end();
          hit != hitend;  ++hit) {
      DetId id(hit->geographicalId());

      if ((hit->geographicalId()).subdetId() == StripSubdetector::TIB ||
          (hit->geographicalId()).subdetId() == StripSubdetector::TOB) {

        GlobalPoint position = trackerHandle->idToDet(hit->geographicalId())->surface().toGlobal(hit->localPosition());
        //from RecoLocalTracker/SiStripClusterizer/test/TestCluster.cc
        // cf also TrackHitAssociator.cc SiStripRecHitMatcher.cc SiStrip1DMeasurementTransformator.cc (KalmanUpdators)
        SiStripRecHit2D const rechit = *hit ;
        //      LocalPoint myposition = rechit.localPosition() ;
        LocalError myerror = rechit.localPositionError();

        // Get layer and subdetector ID here for this hit
        // see SiStripRecHitConverter/test/ValHit.cc
        Int_t siLayerNum = 0 ;
        Int_t siDetNum = 0 ;
        string siDetName = "" ;
        if( (hit->geographicalId()).subdetId() == StripSubdetector::TIB ){
          //       siLayerNum = TIBDetId(rechit->geographicalID()).layer();
          siLayerNum = TIBDetId(id).layer();
          siDetNum = 1 ;
          siDetName = "TIB" ;
        } else if ( (hit->geographicalId()).subdetId() == StripSubdetector::TOB ){
          siLayerNum = TOBDetId(id).layer();
          siDetNum = 2 ;
          siDetName = "TOB" ;
          //    } else if ( (hit->geographicalId()).subdetId() == StripSubdetector::TID ){
          //      // should we use side/wheel/ring/module/stereo() ?
          //      siLayerNum = TIDDetId(id).wheel();
          //      siDetNum = 3 ;
          //      siDetName = "TID" ;
          //    }else if ( (hit->geographicalId()).subdetId() == StripSubdetector::TEC ){
          //      //choices are side/petal/wheel/ring/module/glued/stereo
          //      siLayerNum = TECDetId(id).wheel();
          //      siDetNum = 4 ;
          //      siDetName = "TEC"
          ;
        }else {
          siLayerNum = -999 ;
          siDetNum = -999 ;
          siDetName = "NULL" ;
        }
        //      LogDebug("") << siDetName << " " << siLayerNum ;
        const SiStripRecHit2D::ClusterRef & clust=rechit.cluster();
        double Signal = 0 ;
        double Noise2 = 0 ;
        int StripCount = 0 ;
        if(clust.isNonnull()) {
          //      LogDebug("") << " barycenter " << clust->barycenter() ;
          //      const std::vector<uint16_t> amplitudes=clust->amplitudes();
          const std::vector<uint8_t> amplitudes=clust->amplitudes();
          for(size_t i = 0 ; i<amplitudes.size(); i++ ){
            Signal +=amplitudes[i] ;
            //ignore for now         Noise2 +=SiStripNoiseService_.getNoise(detid,clust->firstStrip()+i)*SiStripNoiseService_.getNoise(detid,clust->firstStrip()+i);
            StripCount++;
          }
        } else {
          LogDebug("") << " null cluster " ;
        }
        //      LogDebug("") << "Signal " << Signal << " Noise2 " << Noise2 << " StripCount " << StripCount ;

        // Dump position info
        //      LogDebug("") << " Mono "
        //                       << "local position: "<<myposition.x()<<" "
        //                       << myposition.y()<<" "<<myposition.z()<<"\n"
        //                       <<"local error: "<<myerror.xx()<<" "
        //                       << myerror.xy()<<" "<<myerror.yy() << "\n"
        //                       << "global position: " << position.x() << " "
        //                       <<  position.y()<<" "<< position.z()<<"\n"
        //                       << " siDetNum " << siDetNum
        //                       << " siLayerNum " << siLayerNum ;

        if( myHits < myMaxHits ) {
          MonoHitX_[myHits] = position.x();
          MonoHitY_[myHits] = position.y();
          MonoHitZ_[myHits] = position.z();

          MonoHitR_[myHits]=position.perp();
          MonoHitPhi_[myHits]=position.phi();
          MonoHitTheta_[myHits]=position.theta();

          MonoHitSigX_[myHits]=sqrt(myerror.xx());
          MonoHitSigY_[myHits]=sqrt(myerror.yy());
          MonoHitCorr_[myHits]=myerror.xy()/sqrt(myerror.xx()*myerror.yy());


          MonoHitSignal_[myHits] = Signal ;
          MonoHitNoise_[myHits] = Noise2 ;
          MonoHitWidth_[myHits] = StripCount ;

          MonoDetector_[myHits] = siDetNum ;
          MonoLayer_[myHits] = siLayerNum ;

          ++myHits ;
        }  // of  if(myHits < myMaxHits)
        //      LogDebug("")<< "end of myHits < myMaxHits " ;
      } // end if this is the right subdetector
      //      LogDebug("")<< "end of TIB/TOB check " ;
  } // end loop over hits
  //    LogDebug("")<< " end of loop over hits  " ;
  NMonoHits_ = myHits ;

  numSiMonoHits_->Fill(NMonoHits_);



  LogDebug("") << "  Loop over Matched Hits " ;

  myHits = 0 ;
  for (SiStripMatchedRecHit2DCollection::DataContainer::const_iterator hit = matchedHitsHandle->data().begin(), hitend = matchedHitsHandle->data().end();
          hit != hitend;  ++hit) {
        DetId id(hit->geographicalId());
        if ((hit->geographicalId()).subdetId() == StripSubdetector::TIB  ||
          (hit->geographicalId()).subdetId() == StripSubdetector::TOB    ) {
        GlobalPoint position = trackerHandle->idToDet(hit->geographicalId())->surface().toGlobal(hit->localPosition());
        SiStripMatchedRecHit2D const rechit = *hit ;
        //      LocalPoint myposition = rechit.localPosition() ;
        LocalError myerror = rechit.localPositionError();

        // Get layer and subdetector ID here for this hit
        // see SiStripRecHitConverter/test/ValHit.cc
        Int_t siLayerNum = 0 ;
        Int_t siDetNum = 0 ;
        string siDetName = "" ;
        if( (hit->geographicalId()).subdetId() == StripSubdetector::TIB ){
          siLayerNum = TIBDetId(id).layer();
          siDetNum = 1 ;
          siDetName = "TIB" ;
        } else if ( (hit->geographicalId()).subdetId() == StripSubdetector::TOB ){
          siLayerNum = TOBDetId(id).layer();
          siDetNum = 2 ;
          siDetName = "TOB" ;
          //            } else if ( (hit->geographicalId()).subdetId() == StripSubdetector::TID ){
          //              // should we use side/wheel/ring/module/stereo() ?
          //              siLayerNum = TIDDetId(id).wheel();
          //              siDetNum = 3 ;
          //              siDetName = "TID" ;
          //            }else if ( (hit->geographicalId()).subdetId() == StripSubdetector::TEC ){
          //              //choices are side/petal/wheel/ring/module/glued/stereo
          //              siLayerNum = TECDetId(id).wheel();
          //              siDetNum = 4 ;
          //              siDetName = "TEC" ;
        }else {
          siLayerNum = -999 ;
          siDetNum = -999 ;
          siDetName = "NULL" ;
        }
        //      const edm::Ref<edm::DetSetVector<SiStripCluster>, SiStripCluster, edm::refhelper::FindForDetSetVector<SiStripCluster> > clust=rechit.cluster();
        double Signal = 0 ;
        double Noise2 = 0 ;
        int StripCount = 0 ;
        //      if(clust.isNonnull()) {
        //        LogDebug("") << " barycenter " << clust->barycenter() ;
        //        const std::vector<uint16_t> amplitudes=clust->amplitudes();
        //        for(size_t i = 0 ; i<amplitudes.size(); i++ ){
        //          Signal +=amplitudes[i] ;
        //          //ignore for now         Noise2 +=SiStripNoiseService_.getNoise(detid,clust->firstStrip()+i)*SiStripNoiseService_.getNoise(detid,clust->firstStrip()+i);
        //          StripCount++;
        //        }
        //      } else {
        //        LogDebug("") << " null cluster " ;
        //      }
        //      LogDebug("") << "Signal " << Signal << " Noise2 " << Noise2 << " StripCount " << StripCount ;

        // Dump position info
        //      LogDebug("") << " Matched "
        //                       << "local position: "<<myposition.x()<<" "
        //                       << myposition.y()<<" "<<myposition.z()<<"\n"
        //                       << "local error: "<<myerror.xx()<<" "
        //                       << myerror.xy()<<" "<<myerror.yy() << "\n"
        //                       << "global position: " << position.x() << " "
        //                       <<  position.y()<<" "<< position.z()<<"\n"
        //                       << " siDetNum " << siDetNum
        //                       << " siLayerNum " << siLayerNum ;

        if( myHits < myMaxHits ) {
          MatchedHitX_[myHits] = position.x();
          MatchedHitY_[myHits] = position.y();
          MatchedHitZ_[myHits] = position.z();


          MatchedHitR_[myHits]=position.perp();
          MatchedHitPhi_[myHits]=position.phi();
          MatchedHitTheta_[myHits]=position.theta();

          MatchedHitSigX_[myHits]=sqrt(myerror.xx());
          MatchedHitSigY_[myHits]=sqrt(myerror.yy());
          MatchedHitCorr_[myHits]=myerror.xy()/sqrt(myerror.xx()*myerror.yy());



          MatchedHitSignal_[myHits] = Signal ;
          MatchedHitNoise_[myHits] = Noise2 ;
          MatchedHitWidth_[myHits] = StripCount ;

          MatchedDetector_[myHits] = siDetNum ;
          MatchedLayer_[myHits] = siLayerNum ;

          ++myHits ;
        }
      } // end if this is the right subdetector (TIB/TOB)
  } // end loop over hits
  NMatchedHits_ = myHits ;

  numSiMatchedHits_->Fill(NMatchedHits_);




  LogDebug("") << "Writing to myTree with " << NShowers_ << " Showers "
               << NStereoHits_ << " Si StereoHits "
               << NMonoHits_ << " Si MonoHits "
               << NMatchedHits_ << " Si MatchedHits " ;

  myTree_->Fill();





} // end of Analyzer
void SiStripElectronAnalyzer::beginJob ( void  ) [virtual]

Reimplemented from edm::EDAnalyzer.

Definition at line 187 of file SiStripElectronAnalyzer.cc.

References EShower_, MatchedDetector_, MatchedHitCorr_, MatchedHitNoise_, MatchedHitPhi_, MatchedHitR_, MatchedHitSignal_, MatchedHitSigX_, MatchedHitSigY_, MatchedHitTheta_, MatchedHitWidth_, MatchedHitX_, MatchedHitY_, MatchedHitZ_, MatchedLayer_, MonoDetector_, MonoHitCorr_, MonoHitNoise_, MonoHitPhi_, MonoHitR_, MonoHitSignal_, MonoHitSigX_, MonoHitSigY_, MonoHitTheta_, MonoHitWidth_, MonoHitX_, MonoHitY_, MonoHitZ_, MonoLayer_, myTree_, NMatchedHits_, NMonoHits_, NShowers_, NStereoHits_, StereoDetector_, StereoHitCorr_, StereoHitNoise_, StereoHitPhi_, StereoHitR_, StereoHitSignal_, StereoHitSigX_, StereoHitSigY_, StereoHitTheta_, StereoHitWidth_, StereoHitX_, StereoHitY_, StereoHitZ_, StereoLayer_, XShower_, YShower_, and ZShower_.

                                      {

  myTree_ = new TTree("myTree","my first Tree example");

  myTree_->Branch("NShowers",&NShowers_,"NShowers/I");


  // first specify the ECAL clusters
  // need to explicitly include array length.
  myTree_->Branch("EShower",&EShower_,"EShower[1000]/F");
  myTree_->Branch("XShower",&XShower_,"XShower[1000]/F");
  myTree_->Branch("YShower",&YShower_,"YShower[1000]/F");
  myTree_->Branch("ZShower",&ZShower_,"ZShower[1000]/F");

  // second specify the Si Stereo Hits
  myTree_->Branch("NStereoHits",&NStereoHits_,"NStereoHits/I");
  myTree_->Branch("StereoHitX",&StereoHitX_,"StereoHitX[1000]/F");
  myTree_->Branch("StereoHitY",&StereoHitY_,"StereoHitY[1000]/F");
  myTree_->Branch("StereoHitZ",&StereoHitZ_,"StereoHitZ[1000]/F");

  myTree_->Branch("StereoHitR",&StereoHitR_,"StereoHitR[1000]/F");
  myTree_->Branch("StereoHitPhi",&StereoHitPhi_,"StereoHitPhi[1000]/F");
  myTree_->Branch("StereoHitTheta",&StereoHitTheta_,"StereoHitTheta[1000]/F");

  myTree_->Branch("StereoHitSigX",&StereoHitSigX_,"StereoHitSigX[1000]/F");
  myTree_->Branch("StereoHitSigY",&StereoHitSigY_,"StereoHitSigY[1000]/F");
  myTree_->Branch("StereoHitCorr",&StereoHitCorr_,"StereoHitCorr[1000]/F");

  myTree_->Branch("StereoHitSignal",&StereoHitSignal_,"StereoHitSignal[1000]/F");
  myTree_->Branch("StereoHitNoise",&StereoHitNoise_,"StereoHitNoise[1000]/F");
  myTree_->Branch("StereoHitWidth",&StereoHitWidth_,"StereoHitWidth[1000]/I");

  myTree_->Branch("StereoDetector",&StereoDetector_,"StereoDetector[1000]/I");
  myTree_->Branch("StereoLayer",&StereoLayer_,"StereoLayer[1000]/I");


  // specify the Si mono (rphi) hits
  myTree_->Branch("NMonoHits",&NMonoHits_,"NMonoHits/I");
  myTree_->Branch("MonoHitX",&MonoHitX_,"MonoHitX[1000]/F");
  myTree_->Branch("MonoHitY",&MonoHitY_,"MonoHitY[1000]/F");
  myTree_->Branch("MonoHitZ",&MonoHitZ_,"MonoHitZ[1000]/F");


  myTree_->Branch("MonoHitR",&MonoHitR_,"MonoHitR[1000]/F");
  myTree_->Branch("MonoHitPhi",&MonoHitPhi_,"MonoHitPhi[1000]/F");
  myTree_->Branch("MonoHitTheta",&MonoHitTheta_,"MonoHitTheta[1000]/F");

  myTree_->Branch("MonoHitSigX",&MonoHitSigX_,"MonoHitSigX[1000]/F");
  myTree_->Branch("MonoHitSigY",&MonoHitSigY_,"MonoHitSigY[1000]/F");
  myTree_->Branch("MonoHitCorr",&MonoHitCorr_,"MonoHitCorr[1000]/F");

  myTree_->Branch("MonoHitSignal",&MonoHitSignal_,"MonoHitSignal[1000]/F");
  myTree_->Branch("MonoHitNoise",&MonoHitNoise_,"MonoHitNoise[1000]/F");
  myTree_->Branch("MonoHitWidth",&MonoHitWidth_,"MonoHitWidth[1000]/I");

  myTree_->Branch("MonoDetector",&MonoDetector_,"MonoDetector[1000]/I");
  myTree_->Branch("MonoLayer",&MonoLayer_,"MonoLayer[1000]/I");

  // specify the Si matched (rphi) hits
  myTree_->Branch("NMatchedHits",&NMatchedHits_,"NMatchedHits/I");
  myTree_->Branch("MatchedHitX",&MatchedHitX_,"MatchedHitX[1000]/F");
  myTree_->Branch("MatchedHitY",&MatchedHitY_,"MatchedHitY[1000]/F");
  myTree_->Branch("MatchedHitZ",&MatchedHitZ_,"MatchedHitZ[1000]/F");

  myTree_->Branch("MatchedHitR",&MatchedHitR_,"MatchedHitR[1000]/F");
  myTree_->Branch("MatchedHitPhi",&MatchedHitPhi_,"MatchedHitPhi[1000]/F");
  myTree_->Branch("MatchedHitTheta",&MatchedHitTheta_,"MatchedHitTheta[1000]/F");

  myTree_->Branch("MatchedHitSigX",&MatchedHitSigX_,"MatchedHitSigX[1000]/F");
  myTree_->Branch("MatchedHitSigY",&MatchedHitSigY_,"MatchedHitSigY[1000]/F");
  myTree_->Branch("MatchedHitCorr",&MatchedHitCorr_,"MatchedHitCorr[1000]/F");

  myTree_->Branch("MatchedHitSignal",&MatchedHitSignal_,"MatchedHitSignal[1000]/F");
  myTree_->Branch("MatchedHitNoise",&MatchedHitNoise_,"MatchedHitNoise[1000]/F");
  myTree_->Branch("MatchedHitWidth",&MatchedHitWidth_,"MatchedHitWidth[1000]/I");

  myTree_->Branch("MatchedDetector",&MatchedDetector_,"MatchedDetector[1000]/I");
  myTree_->Branch("MatchedLayer",&MatchedLayer_,"MatchedLayer[1000]/I");

}
void SiStripElectronAnalyzer::endJob ( void  ) [virtual]

Reimplemented from edm::EDAnalyzer.

Definition at line 1253 of file SiStripElectronAnalyzer.cc.

References emaxSuperClusters_, emaxSuperClustersEl_, energySuperClusters_, energySuperClustersEl_, file_, LogDebug, myTree_, numCand_, numElectrons_, numSiMatchedHits_, numSiMonoHits_, numSiStereoHits_, numSuperClusters_, pDiff, pElectronFailed, pElectronPassed, phiWidthSuperClusters_, phiWidthSuperClustersEl_, ptDiff, ptElectronFailed, ptElectronPassed, sizeSuperClusters_, sizeSuperClustersEl_, sizeSuperClustersFailed, and sizeSuperClustersPassed.

                                    {
  LogDebug("") << "Entering endJob " ;
  file_->cd() ;
  numCand_->Write();
  numElectrons_->Write();
  numSuperClusters_->Write();

  energySuperClusters_->Write();
  sizeSuperClusters_->Write();
  emaxSuperClusters_->Write();
  phiWidthSuperClusters_->Write();

  energySuperClustersEl_->Write();
  sizeSuperClustersEl_->Write();
  emaxSuperClustersEl_->Write();
  phiWidthSuperClustersEl_->Write();

  ptDiff->Write();
  pDiff->Write();
  pElectronFailed->Write();
  ptElectronFailed->Write();
  pElectronPassed->Write();
  ptElectronPassed->Write();
  sizeSuperClustersPassed->Write();
  sizeSuperClustersFailed->Write();
  //   energySuperClustersPassed->Write();
  //   energySuperClustersFailed->Write();
  //   eOverPPassed->Write();
  //   eOverPFailed->Write();


  numSiStereoHits_->Write();
  numSiMonoHits_->Write();
  numSiMatchedHits_->Write();

  // disable for large dataset
  LogDebug("") << " Writing out ntuple is disabled for now " ;
   myTree_->Write();


  file_->Close();
}
void SiStripElectronAnalyzer::initNtuple ( void  ) [virtual]

Definition at line 268 of file SiStripElectronAnalyzer.cc.

References EShower_, init, LogDebug, MatchedHitNoise_, MatchedHitPhi_, MatchedHitR_, MatchedHitSignal_, MatchedHitTheta_, MatchedHitWidth_, MatchedHitX_, MatchedHitY_, MatchedHitZ_, MonoHitNoise_, MonoHitPhi_, MonoHitR_, MonoHitSignal_, MonoHitTheta_, MonoHitWidth_, MonoHitX_, MonoHitY_, MonoHitZ_, myMaxHits, NMatchedHits_, NMonoHits_, NShowers_, NStereoHits_, StereoHitNoise_, StereoHitPhi_, StereoHitR_, StereoHitSignal_, StereoHitTheta_, StereoHitWidth_, StereoHitX_, StereoHitY_, StereoHitZ_, XShower_, YShower_, and ZShower_.

Referenced by analyze().

                                        {

  LogDebug("") << " In initNtuple " ;

  NShowers_ = -999 ;
  for (int init = 0 ; init < myMaxHits ; ++init){
    EShower_[init] = -999.;
    XShower_[init] = -999.;
    YShower_[init] = -999.;
    ZShower_[init] = -999.;
  }
  NStereoHits_ = -999 ;

  for (int init = 0 ; init < myMaxHits ; ++init){
    StereoHitX_[init] = -999.;
    StereoHitY_[init] = -999.;
    StereoHitZ_[init] = -999.;
    StereoHitR_[init] = -999.;
    StereoHitPhi_[init] = -999.;
    StereoHitTheta_[init] = -999.;

    StereoHitSignal_[init] = -999.;
    StereoHitNoise_[init] = -999.;
    StereoHitWidth_[init] = -999 ;;
  }

  NMonoHits_ = -999 ;
  for (int init = 0 ; init < myMaxHits ; ++init){
    MonoHitX_[init] = -999.;
    MonoHitY_[init] = -999.;
    MonoHitZ_[init] = -999.;
    MonoHitR_[init] = -999.;
    MonoHitPhi_[init] = -999.;
    MonoHitTheta_[init] = -999.;

    MonoHitSignal_[init] = -999.;
    MonoHitNoise_[init] = -999.;
    MonoHitWidth_[init] = -999 ;;
  }

  NMatchedHits_ = -999 ;
  for (int init = 0 ; init < myMaxHits ; ++init){
    MatchedHitX_[init] = -999.;
    MatchedHitY_[init] = -999.;
    MatchedHitZ_[init] = -999.;
    MatchedHitR_[init] = -999.;
    MatchedHitPhi_[init] = -999.;
    MatchedHitTheta_[init] = -999.;

    MatchedHitSignal_[init] = -999.;
    MatchedHitNoise_[init] = -999.;
    MatchedHitWidth_[init] = -999 ;;
  }



}
double SiStripElectronAnalyzer::unwrapPhi ( double  phi) const [inline, private]

Definition at line 59 of file SiStripElectronAnalyzer.h.

References M_PI, and phi.

                                         {
        while (phi > M_PI) { phi -= 2.*M_PI; }
        while (phi < -M_PI) { phi += 2.*M_PI; }
        return phi;
      }

Member Data Documentation

Definition at line 181 of file SiStripElectronAnalyzer.h.

Definition at line 180 of file SiStripElectronAnalyzer.h.

Definition at line 183 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and SiStripElectronAnalyzer().

Definition at line 182 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and SiStripElectronAnalyzer().

Definition at line 187 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and SiStripElectronAnalyzer().

Definition at line 186 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and SiStripElectronAnalyzer().

Definition at line 76 of file SiStripElectronAnalyzer.h.

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

Definition at line 81 of file SiStripElectronAnalyzer.h.

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

Definition at line 74 of file SiStripElectronAnalyzer.h.

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

Definition at line 79 of file SiStripElectronAnalyzer.h.

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

Definition at line 93 of file SiStripElectronAnalyzer.h.

Referenced by SiStripElectronAnalyzer().

Definition at line 92 of file SiStripElectronAnalyzer.h.

Referenced by SiStripElectronAnalyzer().

Definition at line 94 of file SiStripElectronAnalyzer.h.

Referenced by SiStripElectronAnalyzer().

Definition at line 95 of file SiStripElectronAnalyzer.h.

Referenced by SiStripElectronAnalyzer().

float SiStripElectronAnalyzer::EShower_[myMaxHits] [private]

Definition at line 105 of file SiStripElectronAnalyzer.h.

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

std::string SiStripElectronAnalyzer::fileName_ [private]

Definition at line 67 of file SiStripElectronAnalyzer.h.

Referenced by SiStripElectronAnalyzer().

Definition at line 172 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

float SiStripElectronAnalyzer::MatchedHitCorr_[myMaxHits] [private]

Definition at line 166 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

float SiStripElectronAnalyzer::MatchedHitNoise_[myMaxHits] [private]

Definition at line 169 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MatchedHitPhi_[myMaxHits] [private]

Definition at line 160 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MatchedHitR_[myMaxHits] [private]

Definition at line 159 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MatchedHitSignal_[myMaxHits] [private]

Definition at line 168 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MatchedHitSigX_[myMaxHits] [private]

Definition at line 164 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

float SiStripElectronAnalyzer::MatchedHitSigY_[myMaxHits] [private]

Definition at line 165 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

float SiStripElectronAnalyzer::MatchedHitTheta_[myMaxHits] [private]

Definition at line 161 of file SiStripElectronAnalyzer.h.

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

Definition at line 170 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MatchedHitX_[myMaxHits] [private]

Definition at line 155 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MatchedHitY_[myMaxHits] [private]

Definition at line 156 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MatchedHitZ_[myMaxHits] [private]

Definition at line 157 of file SiStripElectronAnalyzer.h.

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

int SiStripElectronAnalyzer::MatchedLayer_[myMaxHits] [private]

Definition at line 173 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

Definition at line 177 of file SiStripElectronAnalyzer.h.

Referenced by SiStripElectronAnalyzer().

Definition at line 176 of file SiStripElectronAnalyzer.h.

Referenced by SiStripElectronAnalyzer().

int SiStripElectronAnalyzer::MonoDetector_[myMaxHits] [private]

Definition at line 150 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

float SiStripElectronAnalyzer::MonoHitCorr_[myMaxHits] [private]

Definition at line 144 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

float SiStripElectronAnalyzer::MonoHitNoise_[myMaxHits] [private]

Definition at line 147 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MonoHitPhi_[myMaxHits] [private]

Definition at line 138 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MonoHitR_[myMaxHits] [private]

Definition at line 137 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MonoHitSignal_[myMaxHits] [private]

Definition at line 146 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MonoHitSigX_[myMaxHits] [private]

Definition at line 142 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

float SiStripElectronAnalyzer::MonoHitSigY_[myMaxHits] [private]

Definition at line 143 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

float SiStripElectronAnalyzer::MonoHitTheta_[myMaxHits] [private]

Definition at line 139 of file SiStripElectronAnalyzer.h.

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

int SiStripElectronAnalyzer::MonoHitWidth_[myMaxHits] [private]

Definition at line 148 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MonoHitX_[myMaxHits] [private]

Definition at line 133 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MonoHitY_[myMaxHits] [private]

Definition at line 134 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::MonoHitZ_[myMaxHits] [private]

Definition at line 135 of file SiStripElectronAnalyzer.h.

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

int SiStripElectronAnalyzer::MonoLayer_[myMaxHits] [private]

Definition at line 151 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

Definition at line 102 of file SiStripElectronAnalyzer.h.

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

Definition at line 154 of file SiStripElectronAnalyzer.h.

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

Definition at line 132 of file SiStripElectronAnalyzer.h.

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

Definition at line 104 of file SiStripElectronAnalyzer.h.

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

Definition at line 110 of file SiStripElectronAnalyzer.h.

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

Definition at line 71 of file SiStripElectronAnalyzer.h.

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

Definition at line 72 of file SiStripElectronAnalyzer.h.

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

Definition at line 100 of file SiStripElectronAnalyzer.h.

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

Definition at line 99 of file SiStripElectronAnalyzer.h.

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

Definition at line 98 of file SiStripElectronAnalyzer.h.

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

Definition at line 73 of file SiStripElectronAnalyzer.h.

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

Definition at line 85 of file SiStripElectronAnalyzer.h.

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

Definition at line 86 of file SiStripElectronAnalyzer.h.

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

Definition at line 88 of file SiStripElectronAnalyzer.h.

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

Definition at line 77 of file SiStripElectronAnalyzer.h.

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

Definition at line 82 of file SiStripElectronAnalyzer.h.

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

Definition at line 84 of file SiStripElectronAnalyzer.h.

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

Definition at line 87 of file SiStripElectronAnalyzer.h.

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

Definition at line 89 of file SiStripElectronAnalyzer.h.

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

Definition at line 185 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and SiStripElectronAnalyzer().

Definition at line 184 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and SiStripElectronAnalyzer().

Definition at line 188 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and SiStripElectronAnalyzer().

Definition at line 191 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and SiStripElectronAnalyzer().

Definition at line 189 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and SiStripElectronAnalyzer().

Definition at line 190 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and SiStripElectronAnalyzer().

Definition at line 75 of file SiStripElectronAnalyzer.h.

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

Definition at line 80 of file SiStripElectronAnalyzer.h.

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

Definition at line 91 of file SiStripElectronAnalyzer.h.

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

Definition at line 90 of file SiStripElectronAnalyzer.h.

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

int SiStripElectronAnalyzer::StereoDetector_[myMaxHits] [private]

Definition at line 128 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

float SiStripElectronAnalyzer::StereoHitCorr_[myMaxHits] [private]

Definition at line 122 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

float SiStripElectronAnalyzer::StereoHitNoise_[myMaxHits] [private]

Definition at line 125 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::StereoHitPhi_[myMaxHits] [private]

Definition at line 116 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::StereoHitR_[myMaxHits] [private]

Definition at line 115 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::StereoHitSignal_[myMaxHits] [private]

Definition at line 124 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::StereoHitSigX_[myMaxHits] [private]

Definition at line 120 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

float SiStripElectronAnalyzer::StereoHitSigY_[myMaxHits] [private]

Definition at line 121 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

float SiStripElectronAnalyzer::StereoHitTheta_[myMaxHits] [private]

Definition at line 117 of file SiStripElectronAnalyzer.h.

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

int SiStripElectronAnalyzer::StereoHitWidth_[myMaxHits] [private]

Definition at line 126 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::StereoHitX_[myMaxHits] [private]

Definition at line 111 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::StereoHitY_[myMaxHits] [private]

Definition at line 112 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::StereoHitZ_[myMaxHits] [private]

Definition at line 113 of file SiStripElectronAnalyzer.h.

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

int SiStripElectronAnalyzer::StereoLayer_[myMaxHits] [private]

Definition at line 129 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and beginJob().

Definition at line 179 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and SiStripElectronAnalyzer().

Definition at line 178 of file SiStripElectronAnalyzer.h.

Referenced by analyze(), and SiStripElectronAnalyzer().

float SiStripElectronAnalyzer::XShower_[myMaxHits] [private]

Definition at line 106 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::YShower_[myMaxHits] [private]

Definition at line 107 of file SiStripElectronAnalyzer.h.

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

float SiStripElectronAnalyzer::ZShower_[myMaxHits] [private]

Definition at line 108 of file SiStripElectronAnalyzer.h.

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