#include <QcdPhotonsDQM.h>
DQM offline for QCD-Photons
Definition at line 27 of file QcdPhotonsDQM.h.
QcdPhotonsDQM::QcdPhotonsDQM | ( | const edm::ParameterSet & | parameters | ) |
Constructor.
Definition at line 65 of file QcdPhotonsDQM.cc.
References edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), and cppFunctionSkipper::operator.
{ // Get parameters from configuration file theTriggerPathToPass_ = parameters.getParameter<string>("triggerPathToPass"); thePlotTheseTriggersToo_ = parameters.getParameter<vector<string> >("plotTheseTriggersToo"); trigTag_ = parameters.getUntrackedParameter<edm::InputTag>("trigTag"); thePhotonCollectionLabel_ = parameters.getParameter<InputTag>("photonCollection"); theJetCollectionLabel_ = parameters.getParameter<InputTag>("jetCollection"); theVertexCollectionLabel_ = parameters.getParameter<InputTag>("vertexCollection"); theMinJetPt_ = parameters.getParameter<double>("minJetPt"); theMinPhotonEt_ = parameters.getParameter<double>("minPhotonEt"); theRequirePhotonFound_ = parameters.getParameter<bool>("requirePhotonFound"); thePlotPhotonMaxEt_ = parameters.getParameter<double>("plotPhotonMaxEt"); thePlotPhotonMaxEta_ = parameters.getParameter<double>("plotPhotonMaxEta"); thePlotJetMaxEta_ = parameters.getParameter<double>("plotJetMaxEta"); theBarrelRecHitTag = parameters.getParameter<InputTag>("barrelRecHitTag"); theEndcapRecHitTag = parameters.getParameter<InputTag>("endcapRecHitTag"); // just to initialize isValidHltConfig_ = false; // coverity says... h_deltaEt_photon_jet = 0; h_deltaPhi_jet_jet2 = 0; h_deltaPhi_photon_jet = 0; h_deltaPhi_photon_jet2 = 0; h_deltaR_jet_jet2 = 0; h_deltaR_photon_jet2 = 0; h_jet2_eta = 0; h_jet2_pt = 0; h_jet2_ptOverPhotonEt = 0; h_jet_count = 0; h_jet_eta = 0; h_jet_pt = 0; h_photon_count_bar = 0; h_photon_count_end = 0; h_photon_et = 0; h_photon_et_beforeCuts = 0; h_photon_et_jetco = 0; h_photon_et_jetcs = 0; h_photon_et_jetfo = 0; h_photon_et_jetfs = 0; h_photon_et_ratio_co_cs = 0; h_photon_et_ratio_co_fo = 0; h_photon_et_ratio_co_fs = 0; h_photon_et_ratio_cs_fo = 0; h_photon_et_ratio_cs_fs = 0; h_photon_et_ratio_fo_fs = 0; h_photon_eta = 0; h_triggers_passed = 0; theDbe = Service<DQMStore>().operator->(); }
QcdPhotonsDQM::~QcdPhotonsDQM | ( | ) | [virtual] |
void QcdPhotonsDQM::analyze | ( | const edm::Event & | iEvent, |
const edm::EventSetup & | iSetup | ||
) | [virtual] |
Get the analysis.
Implements edm::EDAnalyzer.
Definition at line 204 of file QcdPhotonsDQM.cc.
References abs, SiPixelRawToDigiRegional_cfi::deltaPhi, deltaR(), reco::LeafCandidate::eta(), edm::Event::getByLabel(), i, edm::HandleBase::isValid(), metsig::jet, LogTrace, reco::LeafCandidate::phi(), pos, edm::Handle< T >::product(), reco::LeafCandidate::pt(), edm::TriggerNames::size(), edm::TriggerNames::triggerName(), edm::Event::triggerNames(), trigNames, and GoodVertex_cfg::vertexCollection.
{ num_events_in_run++; //if( ! isValidHltConfig_ ) return; LogTrace(logTraceName)<<"Analysis of event # "; // Did event pass HLT paths? Handle<TriggerResults> HLTresults; iEvent.getByLabel(trigTag_, HLTresults); if (!HLTresults.isValid()) { //LogWarning("") << ">>> TRIGGER collection does not exist !!!"; return; } const edm::TriggerNames & trigNames = iEvent.triggerNames(*HLTresults); bool passed_HLT=false; // See if event passed trigger paths // increment that bin in the trigger plot for (unsigned int i=0; i<thePlotTheseTriggersToo_.size(); i++) { passed_HLT = false; for (unsigned int ti=0; (ti<trigNames.size()) && !passed_HLT; ++ti) { size_t pos = trigNames.triggerName(ti).find(thePlotTheseTriggersToo_[i]); if (pos==0) passed_HLT = HLTresults->accept(ti); } if (passed_HLT) h_triggers_passed->Fill(i); } // grab photons Handle<PhotonCollection> photonCollection; iEvent.getByLabel(thePhotonCollectionLabel_, photonCollection); // If photon collection is empty, exit if (!photonCollection.isValid()) return; // Quit if the event did not pass the HLT path we care about passed_HLT = false; { //bool found=false; for (unsigned int ti=0; ti<trigNames.size(); ++ti) { size_t pos = trigNames.triggerName(ti).find(theTriggerPathToPass_); if (pos==0) { passed_HLT = HLTresults->accept(ti); //found=true; break; } } // Assumption: reco photons are ordered by Et for (PhotonCollection::const_iterator recoPhoton = photonCollection->begin(); recoPhoton!=photonCollection->end(); recoPhoton++){ // stop looping over photons once we get to too low Et if ( recoPhoton->et() < theMinPhotonEt_ ) break; h_photon_et_beforeCuts->Fill(recoPhoton->et()); break; // leading photon only } if (!passed_HLT) { return; } } //std::cout << "\tpassed main trigger (" << theTriggerPathToPass_ << ")" << std::endl; // Does event have valid vertex? // Get the primary event vertex Handle<VertexCollection> vertexHandle; iEvent.getByLabel(theVertexCollectionLabel_, vertexHandle); VertexCollection vertexCollection = *(vertexHandle.product()); //double vtx_ndof = -1.0; //double vtx_z = 0.0; //bool vtx_isFake = true; //if (vertexCollection.size()>0) { // vtx_ndof = vertexCollection.begin()->ndof(); // vtx_z = vertexCollection.begin()->z(); // vtx_isFake = false; //} //if (vtx_isFake || fabs(vtx_z)>15 || vtx_ndof<4) return; int nvvertex = 0; for (unsigned int i=0; i<vertexCollection.size(); ++i) { if (vertexCollection[i].isValid()) nvvertex++; } if (nvvertex==0) return; //std::cout << "\tpassed vertex selection" << std::endl; // Did the event pass certain L1 Technical Trigger bits? // It's probably beam halo // TODO: ADD code // For finding spikes Handle<EcalRecHitCollection> EBReducedRecHits; iEvent.getByLabel(theBarrelRecHitTag, EBReducedRecHits); Handle<EcalRecHitCollection> EEReducedRecHits; iEvent.getByLabel(theEndcapRecHitTag, EEReducedRecHits); EcalClusterLazyTools lazyTool(iEvent, iSetup, theBarrelRecHitTag, theEndcapRecHitTag); // Find the highest et "decent" photon float photon_et = -9.0; float photon_eta = -9.0; float photon_phi = -9.0; bool photon_passPhotonID = false; bool found_lead_pho = false; int photon_count_bar = 0; int photon_count_end = 0; // Assumption: reco photons are ordered by Et for (PhotonCollection::const_iterator recoPhoton = photonCollection->begin(); recoPhoton!=photonCollection->end(); recoPhoton++){ // stop looping over photons once we get to too low Et if ( recoPhoton->et() < theMinPhotonEt_ ) break; /* // Ignore ECAL Spikes const reco::CaloClusterPtr seed = recoPhoton->superCluster()->seed(); DetId id = lazyTool.getMaximum(*seed).first; // Cluster shape variables // float time = -999., outOfTimeChi2 = -999., chi2 = -999.; // UNUSED int flags=-1, severity = -1; const EcalRecHitCollection & rechits = ( recoPhoton->isEB() ? *EBReducedRecHits : *EEReducedRecHits); EcalRecHitCollection::const_iterator it = rechits.find( id ); if( it != rechits.end() ) { // time = it->time(); // UNUSED // outOfTimeChi2 = it->outOfTimeChi2(); // UNUSED // chi2 = it->chi2(); // UNUSED flags = it->recoFlag(); edm::ESHandle<EcalSeverityLevelAlgo> sevlv; iSetup.get<EcalSeverityLevelAlgoRcd>().get(sevlv); severity = sevlv->severityLevel( id, rechits); } bool isNotSpike = ((recoPhoton->isEB() && (severity!=3 && severity!=4 ) && (flags != 2) ) || recoPhoton->isEE()); if (!isNotSpike) continue; // move on to next photon // END of determining ECAL Spikes */ bool pho_current_passPhotonID = false; bool pho_current_isEB = recoPhoton->isEB(); bool pho_current_isEE = recoPhoton->isEE(); if ( pho_current_isEB && (recoPhoton->sigmaIetaIeta() < 0.01 || recoPhoton->hadronicOverEm() < 0.05) ) { // Photon object in barrel passes photon ID pho_current_passPhotonID = true; photon_count_bar++; } else if ( pho_current_isEE && (recoPhoton->hadronicOverEm() < 0.05) ) { // Photon object in endcap passes photon ID pho_current_passPhotonID = true; photon_count_end++; } if (!found_lead_pho) { found_lead_pho = true; photon_passPhotonID = pho_current_passPhotonID; photon_et = recoPhoton->et(); photon_eta = recoPhoton->eta(); photon_phi = recoPhoton->phi(); } } // If user requires a photon to be found, but none is, return. // theRequirePhotonFound should pretty much always be set to 'True' // except when running on qcd monte carlo just to see the jets. if ( theRequirePhotonFound_ && (!photon_passPhotonID || photon_et<theMinPhotonEt_) ) return; // Find the highest et jet Handle<View<Jet> > jetCollection; iEvent.getByLabel (theJetCollectionLabel_,jetCollection); if (!jetCollection.isValid()) return; float jet_pt = -8.0; float jet_eta = -8.0; float jet_phi = -8.0; int jet_count = 0; float jet2_pt = -9.0; float jet2_eta = -9.0; float jet2_phi = -9.0; // Assumption: jets are ordered by Et for (unsigned int i_jet = 0; i_jet < jetCollection->size(); i_jet++) { const Jet* jet = & jetCollection->at(i_jet); float jet_current_pt = jet->pt(); // don't care about jets that overlap with the lead photon if ( deltaR(jet->eta(), jet->phi(), photon_eta, photon_phi) < 0.5 ) continue; // stop looping over jets once we get to too low Et if (jet_current_pt < theMinJetPt_) break; jet_count++; if (jet_current_pt > jet_pt) { jet2_pt = jet_pt; // 2nd highest jet get's et from current highest jet2_eta = jet_eta; jet2_phi = jet_phi; jet_pt = jet_current_pt; // current highest jet gets et from the new highest jet_eta = jet->eta(); jet_phi = jet->phi(); } else if (jet_current_pt > jet2_pt) { jet2_pt = jet_current_pt; jet2_eta = jet->eta(); jet2_phi = jet->phi(); } } // Fill histograms if a jet found // NOTE: if a photon was required to be found, but wasn't // we wouldn't have made it to this point in the code if ( jet_pt > 0.0 ) { // Photon Plots h_photon_et ->Fill( photon_et ); h_photon_eta ->Fill( photon_eta ); h_photon_count_bar->Fill( photon_count_bar ); h_photon_count_end->Fill( photon_count_end ); // Photon Et hists for different orientations to the jet if ( fabs(photon_eta)<1.45 && photon_passPhotonID ) { // Lead photon is in barrel if (fabs(jet_eta)<1.45){ // jet is in barrel if (photon_eta*jet_eta>0) { h_photon_et_jetcs->Fill(photon_et); } else { h_photon_et_jetco->Fill(photon_et); } } else if (jet_eta>1.55 && jet_eta<2.5) { // jet is in endcap if (photon_eta*jet_eta>0) { h_photon_et_jetfs->Fill(photon_et); } else { h_photon_et_jetfo->Fill(photon_et); } } } // END of Lead Photon is in Barrel // Jet Plots h_jet_pt ->Fill( jet_pt ); h_jet_eta ->Fill( jet_eta ); h_jet_count ->Fill( jet_count ); h_deltaPhi_photon_jet ->Fill( abs(deltaPhi(photon_phi, jet_phi)) ); if ( abs(deltaPhi(photon_phi,jet_phi))>2.8 ) h_deltaEt_photon_jet->Fill( (photon_et-jet_pt)/photon_et ); // 2nd Highest Jet Plots if ( jet2_pt > 0.0 ) { h_jet2_pt ->Fill( jet2_pt ); h_jet2_eta ->Fill( jet2_eta ); h_jet2_ptOverPhotonEt ->Fill( jet2_pt/photon_et ); h_deltaPhi_photon_jet2->Fill( abs(deltaPhi(photon_phi, jet2_phi)) ); h_deltaPhi_jet_jet2 ->Fill( abs(deltaPhi( jet_phi, jet2_phi)) ); h_deltaR_jet_jet2 ->Fill( deltaR( jet_eta, jet_phi, jet2_eta, jet2_phi) ); h_deltaR_photon_jet2 ->Fill( deltaR(photon_eta, photon_phi, jet2_eta, jet2_phi) ); } } // End of Filling histograms }
void QcdPhotonsDQM::beginJob | ( | void | ) | [virtual] |
Inizialize parameters for histo binning.
Reimplemented from edm::EDAnalyzer.
Definition at line 122 of file QcdPhotonsDQM.cc.
{ logTraceName = "QcdPhotonAnalyzer"; LogTrace(logTraceName)<<"Parameters initialization"; theDbe->setCurrentFolder("Physics/QcdPhotons"); // Use folder with name of PAG std::stringstream aStringStream; std::string aString; aStringStream << theMinJetPt_; aString = aStringStream.str(); // Monitor of triggers passed int numOfTriggersToMonitor = thePlotTheseTriggersToo_.size(); h_triggers_passed = theDbe->book1D("triggers_passed", "Events passing these trigger paths", numOfTriggersToMonitor, 0, numOfTriggersToMonitor); for (int i=0; i<numOfTriggersToMonitor; i++) { h_triggers_passed->setBinLabel(i+1,thePlotTheseTriggersToo_[i]); } // Keep the number of plots and number of bins to a minimum! h_photon_et_beforeCuts = theDbe->book1D("photon_et_beforeCuts", "#gamma with highest E_{T};E_{T}(#gamma) (GeV)", 20, 0., thePlotPhotonMaxEt_); h_photon_et = theDbe->book1D("photon_et", "#gamma with highest E_{T};E_{T}(#gamma) (GeV)", 20, 0., thePlotPhotonMaxEt_); h_photon_eta = theDbe->book1D("photon_eta", "#gamma with highest E_{T};#eta(#gamma)", 40, -thePlotPhotonMaxEta_, thePlotPhotonMaxEta_); h_photon_count_bar = theDbe->book1D("photon_count_bar","Number of #gamma's passing selection (Barrel);Number of #gamma's", 8, -0.5, 7.5); h_photon_count_end = theDbe->book1D("photon_count_end","Number of #gamma's passing selection (Endcap);Number of #gamma's", 8, -0.5, 7.5); h_jet_pt = theDbe->book1D("jet_pt", "Jet with highest p_{T} (from "+theJetCollectionLabel_.label()+");p_{T}(1^{st} jet) (GeV)", 20, 0., thePlotPhotonMaxEt_); h_jet_eta = theDbe->book1D("jet_eta", "Jet with highest p_{T} (from "+theJetCollectionLabel_.label()+");#eta(1^{st} jet)", 20, -thePlotJetMaxEta_, thePlotJetMaxEta_); h_deltaPhi_photon_jet = theDbe->book1D("deltaPhi_photon_jet", "#Delta#phi between Highest E_{T} #gamma and jet;#Delta#phi(#gamma,1^{st} jet)", 20, 0, 3.1415926); h_deltaPhi_jet_jet2 = theDbe->book1D("deltaPhi_jet_jet2", "#Delta#phi between Highest E_{T} jet and 2^{nd} jet;#Delta#phi(1^{st} jet,2^{nd} jet)", 20, 0, 3.1415926); h_deltaEt_photon_jet = theDbe->book1D("deltaEt_photon_jet", "(E_{T}(#gamma)-p_{T}(jet))/E_{T}(#gamma) when #Delta#phi(#gamma,1^{st} jet) > 2.8;#DeltaE_{T}(#gamma,1^{st} jet)/E_{T}(#gamma)", 20, -1.0, 1.0); h_jet_count = theDbe->book1D("jet_count", "Number of "+theJetCollectionLabel_.label()+" (p_{T} > "+aString+" GeV);Number of Jets", 8, -0.5, 7.5); h_jet2_pt = theDbe->book1D("jet2_pt", "Jet with 2^{nd} highest p_{T} (from "+theJetCollectionLabel_.label()+");p_{T}(2^{nd} jet) (GeV)", 20, 0., thePlotPhotonMaxEt_); h_jet2_eta = theDbe->book1D("jet2_eta", "Jet with 2^{nd} highest p_{T} (from "+theJetCollectionLabel_.label()+");#eta(2^{nd} jet)", 20, -thePlotJetMaxEta_, thePlotJetMaxEta_); h_jet2_ptOverPhotonEt = theDbe->book1D("jet2_ptOverPhotonEt", "p_{T}(2^{nd} highest jet) / E_{T}(#gamma);p_{T}(2^{nd} Jet)/E_{T}(#gamma)", 20, 0.0, 4.0); h_deltaPhi_photon_jet2 = theDbe->book1D("deltaPhi_photon_jet2","#Delta#phi between Highest E_{T} #gamma and 2^{nd} highest jet;#Delta#phi(#gamma,2^{nd} jet)", 20, 0, 3.1415926); h_deltaR_jet_jet2 = theDbe->book1D("deltaR_jet_jet2", "#DeltaR between Highest Jet and 2^{nd} Highest;#DeltaR(1^{st} jet,2^{nd} jet)", 30, 0, 6.0); h_deltaR_photon_jet2 = theDbe->book1D("deltaR_photon_jet2", "#DeltaR between Highest E_{T} #gamma and 2^{nd} jet;#DeltaR(#gamma, 2^{nd} jet)", 30, 0, 6.0); // Photon Et for different jet configurations Float_t bins_et[] = {15,20,30,50,80}; int num_bins_et = 4; h_photon_et_jetcs = theDbe->book1D("photon_et_jetcs", "#gamma with highest E_{T} (#eta(jet)<1.45, #eta(#gamma)#eta(jet)>0);E_{T}(#gamma) (GeV)", num_bins_et, bins_et); h_photon_et_jetco = theDbe->book1D("photon_et_jetco", "#gamma with highest E_{T} (#eta(jet)<1.45, #eta(#gamma)#eta(jet)<0);E_{T}(#gamma) (GeV)", num_bins_et, bins_et); h_photon_et_jetfs = theDbe->book1D("photon_et_jetfs", "#gamma with highest E_{T} (1.55<#eta(jet)<2.5, #eta(#gamma)#eta(jet)>0);E_{T}(#gamma) (GeV)", num_bins_et, bins_et); h_photon_et_jetfo = theDbe->book1D("photon_et_jetfo", "#gamma with highest E_{T} (1.55<#eta(jet)<2.5, #eta(#gamma)#eta(jet)<0);E_{T}(#gamma) (GeV)", num_bins_et, bins_et); h_photon_et_jetcs->getTH1F()->Sumw2(); h_photon_et_jetco->getTH1F()->Sumw2(); h_photon_et_jetfs->getTH1F()->Sumw2(); h_photon_et_jetfo->getTH1F()->Sumw2(); // Ratio of the above Photon Et distributions h_photon_et_ratio_co_cs = theDbe->book1D("photon_et_ratio_00_co_cs", "D(|#eta(jet)|<1.45, #eta(jet)*#eta(#gamma)<0) / D(|#eta(jet)|<1.45, #eta(jet)*#eta(#gamma)>0);E_{T}(#gamma) (GeV); ratio", num_bins_et, bins_et); h_photon_et_ratio_fo_fs = theDbe->book1D("photon_et_ratio_01_fo_fs", "D(1.55<|#eta(jet)|<2.6, #eta(jet)*#eta(#gamma)<0) / D(1.55<|#eta(jet)|<2.6, #eta(jet)*#eta(#gamma)>0);E_{T}(#gamma) (GeV); ratio", num_bins_et, bins_et); h_photon_et_ratio_cs_fs = theDbe->book1D("photon_et_ratio_02_cs_fs", "D(|#eta(jet)|<1.45, #eta(jet)*#eta(#gamma)>0) / D(1.55<|#eta(jet)|<2.6, #eta(jet)*#eta(#gamma)>0);E_{T}(#gamma) (GeV); ratio", num_bins_et, bins_et); h_photon_et_ratio_co_fs = theDbe->book1D("photon_et_ratio_03_co_fs", "D(|#eta(jet)|<1.45, #eta(jet)*#eta(#gamma)<0) / D(1.55<|#eta(jet)|<2.6, #eta(jet)*#eta(#gamma)>0);E_{T}(#gamma) (GeV); ratio", num_bins_et, bins_et); h_photon_et_ratio_cs_fo = theDbe->book1D("photon_et_ratio_04_cs_fo", "D(|#eta(jet)|<1.45, #eta(jet)*#eta(#gamma)>0) / D(1.55<|#eta(jet)|<2.6, #eta(jet)*#eta(#gamma)<0);E_{T}(#gamma) (GeV); ratio", num_bins_et, bins_et); h_photon_et_ratio_co_fo = theDbe->book1D("photon_et_ratio_05_co_fo", "D(|#eta(jet)|<1.45, #eta(jet)*#eta(#gamma)<0) / D(1.55<|#eta(jet)|<2.6, #eta(jet)*#eta(#gamma)<0);E_{T}(#gamma) (GeV); ratio", num_bins_et, bins_et); h_photon_et_ratio_co_cs->getTH1F()->Sumw2(); h_photon_et_ratio_fo_fs->getTH1F()->Sumw2(); h_photon_et_ratio_cs_fs->getTH1F()->Sumw2(); h_photon_et_ratio_co_fs->getTH1F()->Sumw2(); h_photon_et_ratio_cs_fo->getTH1F()->Sumw2(); h_photon_et_ratio_co_fo->getTH1F()->Sumw2(); }
void QcdPhotonsDQM::beginRun | ( | const edm::Run & | iRun, |
const edm::EventSetup & | iSet | ||
) | [virtual] |
Reimplemented from edm::EDAnalyzer.
Definition at line 192 of file QcdPhotonsDQM.cc.
{ // passed as parameter to HLTConfigProvider::init(), not yet used bool isConfigChanged = false; // isValidHltConfig_ could be used to short-circuit analyze() in case of problems isValidHltConfig_ = hltConfigProvider_.init( iRun, iSet, "HLT", isConfigChanged ); num_events_in_run = 0; }
void QcdPhotonsDQM::endJob | ( | void | ) | [virtual] |
Save the histos.
Reimplemented from edm::EDAnalyzer.
Definition at line 476 of file QcdPhotonsDQM.cc.
{}
void QcdPhotonsDQM::endRun | ( | const edm::Run & | run, |
const edm::EventSetup & | es | ||
) | [virtual] |
Reimplemented from edm::EDAnalyzer.
Definition at line 478 of file QcdPhotonsDQM.cc.
{ if (num_events_in_run>0) { h_triggers_passed->getTH1F()->Scale(1.0/num_events_in_run); } h_photon_et_ratio_co_cs->getTH1F()->Divide( h_photon_et_jetco->getTH1F(), h_photon_et_jetcs->getTH1F() ); h_photon_et_ratio_fo_fs->getTH1F()->Divide( h_photon_et_jetfo->getTH1F(), h_photon_et_jetfs->getTH1F() ); h_photon_et_ratio_cs_fs->getTH1F()->Divide( h_photon_et_jetcs->getTH1F(), h_photon_et_jetfs->getTH1F() ); h_photon_et_ratio_co_fs->getTH1F()->Divide( h_photon_et_jetco->getTH1F(), h_photon_et_jetfs->getTH1F() ); h_photon_et_ratio_cs_fo->getTH1F()->Divide( h_photon_et_jetcs->getTH1F(), h_photon_et_jetfo->getTH1F() ); h_photon_et_ratio_co_fo->getTH1F()->Divide( h_photon_et_jetco->getTH1F(), h_photon_et_jetfo->getTH1F() ); }
Definition at line 94 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_deltaPhi_jet_jet2 [private] |
Definition at line 93 of file QcdPhotonsDQM.h.
Definition at line 92 of file QcdPhotonsDQM.h.
Definition at line 98 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_deltaR_jet_jet2 [private] |
Definition at line 99 of file QcdPhotonsDQM.h.
Definition at line 100 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_jet2_eta [private] |
Definition at line 97 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_jet2_pt [private] |
Definition at line 96 of file QcdPhotonsDQM.h.
Definition at line 95 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_jet_count [private] |
Definition at line 91 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_jet_eta [private] |
Definition at line 90 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_jet_pt [private] |
Definition at line 89 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_photon_count_bar [private] |
Definition at line 87 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_photon_count_end [private] |
Definition at line 88 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_photon_et [private] |
Definition at line 85 of file QcdPhotonsDQM.h.
Definition at line 84 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_photon_et_jetco [private] |
Definition at line 103 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_photon_et_jetcs [private] |
Definition at line 102 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_photon_et_jetfo [private] |
Definition at line 105 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_photon_et_jetfs [private] |
Definition at line 104 of file QcdPhotonsDQM.h.
Definition at line 107 of file QcdPhotonsDQM.h.
Definition at line 112 of file QcdPhotonsDQM.h.
Definition at line 110 of file QcdPhotonsDQM.h.
Definition at line 111 of file QcdPhotonsDQM.h.
Definition at line 109 of file QcdPhotonsDQM.h.
Definition at line 108 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_photon_eta [private] |
Definition at line 86 of file QcdPhotonsDQM.h.
MonitorElement* QcdPhotonsDQM::h_triggers_passed [private] |
Definition at line 83 of file QcdPhotonsDQM.h.
Definition at line 57 of file QcdPhotonsDQM.h.
bool QcdPhotonsDQM::isValidHltConfig_ [private] |
Definition at line 58 of file QcdPhotonsDQM.h.
std::string QcdPhotonsDQM::logTraceName [private] |
Definition at line 61 of file QcdPhotonsDQM.h.
int QcdPhotonsDQM::num_events_in_run [private] |
Definition at line 80 of file QcdPhotonsDQM.h.
Definition at line 77 of file QcdPhotonsDQM.h.
DQMStore* QcdPhotonsDQM::theDbe [private] |
Definition at line 55 of file QcdPhotonsDQM.h.
Definition at line 78 of file QcdPhotonsDQM.h.
Definition at line 68 of file QcdPhotonsDQM.h.
double QcdPhotonsDQM::theMinJetPt_ [private] |
Definition at line 70 of file QcdPhotonsDQM.h.
double QcdPhotonsDQM::theMinPhotonEt_ [private] |
Definition at line 71 of file QcdPhotonsDQM.h.
Definition at line 67 of file QcdPhotonsDQM.h.
double QcdPhotonsDQM::thePlotJetMaxEta_ [private] |
Definition at line 75 of file QcdPhotonsDQM.h.
double QcdPhotonsDQM::thePlotPhotonMaxEt_ [private] |
Definition at line 73 of file QcdPhotonsDQM.h.
double QcdPhotonsDQM::thePlotPhotonMaxEta_ [private] |
Definition at line 74 of file QcdPhotonsDQM.h.
std::vector<std::string> QcdPhotonsDQM::thePlotTheseTriggersToo_ [private] |
Definition at line 65 of file QcdPhotonsDQM.h.
bool QcdPhotonsDQM::theRequirePhotonFound_ [private] |
Definition at line 72 of file QcdPhotonsDQM.h.
std::string QcdPhotonsDQM::theTriggerPathToPass_ [private] |
Definition at line 64 of file QcdPhotonsDQM.h.
Definition at line 69 of file QcdPhotonsDQM.h.
edm::InputTag QcdPhotonsDQM::trigTag_ [private] |
Definition at line 66 of file QcdPhotonsDQM.h.