#include <RecoEgamma/Examples/interface/SiStripElectronAnalyzer.h>
Description: <one line="" class="" summary>="">
Usage: <usage>
Definition at line 47 of file SiStripElectronAnalyzer.h.
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_.
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] |
std::string SiStripElectronAnalyzer::basicClusterCollection_ [private] |
Definition at line 181 of file SiStripElectronAnalyzer.h.
std::string SiStripElectronAnalyzer::basicClusterProducer_ [private] |
Definition at line 180 of file SiStripElectronAnalyzer.h.
std::string SiStripElectronAnalyzer::eBRecHitCollection_ [private] |
Definition at line 183 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), and SiStripElectronAnalyzer().
std::string SiStripElectronAnalyzer::eBRecHitProducer_ [private] |
Definition at line 182 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), and SiStripElectronAnalyzer().
std::string SiStripElectronAnalyzer::electronCollection_ [private] |
Definition at line 187 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), and SiStripElectronAnalyzer().
std::string SiStripElectronAnalyzer::electronProducer_ [private] |
Definition at line 186 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::emaxSuperClusters_ [private] |
Definition at line 76 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::emaxSuperClustersEl_ [private] |
Definition at line 81 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::energySuperClusters_ [private] |
Definition at line 74 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::energySuperClustersEl_ [private] |
Definition at line 79 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::energySuperClustersFailed [private] |
Definition at line 93 of file SiStripElectronAnalyzer.h.
Referenced by SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::energySuperClustersPassed [private] |
Definition at line 92 of file SiStripElectronAnalyzer.h.
Referenced by SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::eOverPFailed [private] |
Definition at line 94 of file SiStripElectronAnalyzer.h.
Referenced by SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::eOverPPassed [private] |
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().
TFile* SiStripElectronAnalyzer::file_ [private] |
Definition at line 70 of file SiStripElectronAnalyzer.h.
Referenced by endJob(), SiStripElectronAnalyzer(), and ~SiStripElectronAnalyzer().
std::string SiStripElectronAnalyzer::fileName_ [private] |
Definition at line 67 of file SiStripElectronAnalyzer.h.
Referenced by SiStripElectronAnalyzer().
int SiStripElectronAnalyzer::MatchedDetector_[myMaxHits] [private] |
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().
int SiStripElectronAnalyzer::MatchedHitWidth_[myMaxHits] [private] |
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().
std::string SiStripElectronAnalyzer::mctruthCollection_ [private] |
Definition at line 177 of file SiStripElectronAnalyzer.h.
Referenced by SiStripElectronAnalyzer().
std::string SiStripElectronAnalyzer::mctruthProducer_ [private] |
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().
TTree* SiStripElectronAnalyzer::myTree_ [private] |
Definition at line 102 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), beginJob(), and endJob().
int SiStripElectronAnalyzer::NMatchedHits_ [private] |
Definition at line 154 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), beginJob(), and initNtuple().
int SiStripElectronAnalyzer::NMonoHits_ [private] |
Definition at line 132 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), beginJob(), and initNtuple().
int SiStripElectronAnalyzer::NShowers_ [private] |
Definition at line 104 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), beginJob(), and initNtuple().
int SiStripElectronAnalyzer::NStereoHits_ [private] |
Definition at line 110 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), beginJob(), and initNtuple().
TH1F* SiStripElectronAnalyzer::numCand_ [private] |
Definition at line 71 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::numElectrons_ [private] |
Definition at line 72 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::numSiMatchedHits_ [private] |
Definition at line 100 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::numSiMonoHits_ [private] |
Definition at line 99 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::numSiStereoHits_ [private] |
Definition at line 98 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::numSuperClusters_ [private] |
Definition at line 73 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::pDiff [private] |
Definition at line 85 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::pElectronFailed [private] |
Definition at line 86 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::pElectronPassed [private] |
Definition at line 88 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::phiWidthSuperClusters_ [private] |
Definition at line 77 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::phiWidthSuperClustersEl_ [private] |
Definition at line 82 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::ptDiff [private] |
Definition at line 84 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::ptElectronFailed [private] |
Definition at line 87 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::ptElectronPassed [private] |
Definition at line 89 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
std::string SiStripElectronAnalyzer::siElectronCollection_ [private] |
Definition at line 185 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), and SiStripElectronAnalyzer().
std::string SiStripElectronAnalyzer::siElectronProducer_ [private] |
Definition at line 184 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), and SiStripElectronAnalyzer().
std::string SiStripElectronAnalyzer::siHitProducer_ [private] |
Definition at line 188 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), and SiStripElectronAnalyzer().
std::string SiStripElectronAnalyzer::siMatchedHitCollection_ [private] |
Definition at line 191 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), and SiStripElectronAnalyzer().
std::string SiStripElectronAnalyzer::siRphiHitCollection_ [private] |
Definition at line 189 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), and SiStripElectronAnalyzer().
std::string SiStripElectronAnalyzer::siStereoHitCollection_ [private] |
Definition at line 190 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::sizeSuperClusters_ [private] |
Definition at line 75 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::sizeSuperClustersEl_ [private] |
Definition at line 80 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::sizeSuperClustersFailed [private] |
Definition at line 91 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), endJob(), and SiStripElectronAnalyzer().
TH1F* SiStripElectronAnalyzer::sizeSuperClustersPassed [private] |
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().
std::string SiStripElectronAnalyzer::superClusterCollection_ [private] |
Definition at line 179 of file SiStripElectronAnalyzer.h.
Referenced by analyze(), and SiStripElectronAnalyzer().
std::string SiStripElectronAnalyzer::superClusterProducer_ [private] |
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().