#include <PFJetAnalyzer.h>
DQM monitoring source for PFlow Jets
Definition at line 32 of file PFJetAnalyzer.h.
PFJetAnalyzer::PFJetAnalyzer | ( | const edm::ParameterSet & | pSet | ) |
Constructor.
Definition at line 20 of file PFJetAnalyzer.cc.
References Parameters::parameters.
{ parameters = pSet; _leadJetFlag = 0; _JetLoPass = 0; _JetHiPass = 0; _ptThreshold = 5.; _asymmetryThirdJetCut = 30.; _balanceThirdJetCut = 0.2; _LooseCHFMin = -999.; _LooseNHFMax = -999.; _LooseCEFMax = -999.; _LooseNEFMax = -999.; _TightCHFMin = -999.; _TightNHFMax = -999.; _TightCEFMax = -999.; _TightNEFMax = -999.; _ThisCHFMin = -999.; _ThisNHFMax = -999.; _ThisCEFMax = -999.; _ThisNEFMax = -999.; }
PFJetAnalyzer::~PFJetAnalyzer | ( | ) | [virtual] |
void PFJetAnalyzer::analyze | ( | const edm::Event & | iEvent, |
const edm::EventSetup & | iSetup, | ||
const reco::PFJetCollection & | pfJets, | ||
const int | numPV | ||
) |
Get the analysis.
Definition at line 423 of file PFJetAnalyzer.cc.
References corr, diffTreeTool::diff, dPhi(), eta, edm::EventID::event(), edm::EventBase::id(), metsig::jet, LogTrace, metname, and phi.
{ int numofjets=0; double fstPhi=0.; double sndPhi=0.; double diff = 0.; double corr = 0.; double dphi = -999. ; bool Thiscleaned=false; bool Loosecleaned=false; bool Tightcleaned=false; bool ThisCHFcleaned=false; bool LooseCHFcleaned=false; bool TightCHFcleaned=false; srand( iEvent.id().event() % 10000); if (makedijetselection == 1) { //Dijet selection - careful: the pT is uncorrected! //if(makedijetselection==1 && pfJets.size()>=2){ if(pfJets.size()>=2){ double dphiDJ = -999. ; bool LoosecleanedFirstJet =false; bool LoosecleanedSecondJet=false; bool TightcleanedFirstJet =false; bool TightcleanedSecondJet=false; bool LooseCHFcleanedFirstJet =false; bool LooseCHFcleanedSecondJet=false; bool TightCHFcleanedFirstJet =false; bool TightCHFcleanedSecondJet=false; //both jets pass pt threshold if ((pfJets.at(0)).pt() > _ptThreshold && (pfJets.at(1)).pt() > _ptThreshold ) { if(fabs((pfJets.at(0)).eta())<3. && fabs((pfJets.at(1)).eta())<3. ){ //calculate dphi dphiDJ = fabs((pfJets.at(0)).phi()-(pfJets.at(1)).phi()); if (dphiDJ > 3.14) dphiDJ=fabs(dphiDJ -6.28 ); //fill DPhi histo (before cutting) if (mDPhi) mDPhi->Fill (dphiDJ); //dphi cut if(fabs(dphiDJ)>2.1){ //first jet LooseCHFcleanedFirstJet=true; TightCHFcleanedFirstJet=true; if((pfJets.at(0).chargedHadronEnergy()/pfJets.at(0).energy())<=_LooseCHFMin && fabs(pfJets.at(0).eta())<2.4) LooseCHFcleanedFirstJet=false; //apply CHF>0 only if |eta|<2.4 if((pfJets.at(0).chargedHadronEnergy()/pfJets.at(0).energy())<=_TightCHFMin && fabs(pfJets.at(0).eta())<2.4) TightCHFcleanedFirstJet=false; //apply CHF>0 only if |eta|<2.4 if(LooseCHFcleanedFirstJet && (pfJets.at(0).neutralHadronEnergy()/pfJets.at(0).energy())<_LooseNHFMax && (pfJets.at(0).chargedEmEnergy()/pfJets.at(0).energy())<_LooseCEFMax && (pfJets.at(0).neutralEmEnergy()/pfJets.at(0).energy())<_LooseNEFMax) LoosecleanedFirstJet=true; if(TightCHFcleanedFirstJet && (pfJets.at(0).neutralHadronEnergy()/pfJets.at(0).energy())<_TightNHFMax && (pfJets.at(0).chargedEmEnergy()/pfJets.at(0).energy())<_TightCEFMax && (pfJets.at(0).neutralEmEnergy()/pfJets.at(0).energy())<_TightNEFMax) TightcleanedFirstJet=true; //second jet LooseCHFcleanedSecondJet=true; TightCHFcleanedSecondJet=true; if((pfJets.at(1).chargedHadronEnergy()/pfJets.at(1).energy())<=_LooseCHFMin && fabs(pfJets.at(1).eta())<2.4) LooseCHFcleanedSecondJet=false; //apply CHF>0 only if |eta|<2.4 if((pfJets.at(1).chargedHadronEnergy()/pfJets.at(1).energy())<=_TightCHFMin && fabs(pfJets.at(1).eta())<2.4) TightCHFcleanedSecondJet=false; //apply CHF>0 only if |eta|<2.4 if(LooseCHFcleanedSecondJet && (pfJets.at(1).neutralHadronEnergy()/pfJets.at(1).energy())<_LooseNHFMax && (pfJets.at(1).chargedEmEnergy()/pfJets.at(1).energy())<_LooseCEFMax && (pfJets.at(1).neutralEmEnergy()/pfJets.at(1).energy())<_LooseNEFMax) LoosecleanedSecondJet=true; if(TightCHFcleanedSecondJet && (pfJets.at(1).neutralHadronEnergy()/pfJets.at(1).energy())<_TightNHFMax && (pfJets.at(1).chargedEmEnergy()/pfJets.at(1).energy())<_TightCEFMax && (pfJets.at(1).neutralEmEnergy()/pfJets.at(1).energy())<_TightNEFMax) TightcleanedSecondJet=true; if(fillpfJIDPassFrac==1) { //fill the profile for jid efficiency if(LoosecleanedFirstJet) { mLooseJIDPassFractionVSeta->Fill(pfJets.at(0).eta(),1.); mLooseJIDPassFractionVSpt->Fill(pfJets.at(0).pt(),1.); } else { mLooseJIDPassFractionVSeta->Fill(pfJets.at(0).eta(),0.); mLooseJIDPassFractionVSpt->Fill(pfJets.at(0).pt(),0.); } if(TightcleanedFirstJet) { mTightJIDPassFractionVSeta->Fill(pfJets.at(0).eta(),1.); mTightJIDPassFractionVSpt->Fill(pfJets.at(0).pt(),1.); } else { mTightJIDPassFractionVSeta->Fill(pfJets.at(0).eta(),0.); mTightJIDPassFractionVSpt->Fill(pfJets.at(0).pt(),0.); } if(LoosecleanedSecondJet) { mLooseJIDPassFractionVSeta->Fill(pfJets.at(1).eta(),1.); mLooseJIDPassFractionVSpt->Fill(pfJets.at(1).pt(),1.); } else { mLooseJIDPassFractionVSeta->Fill(pfJets.at(1).eta(),0.); mLooseJIDPassFractionVSpt->Fill(pfJets.at(1).pt(),0.); } if(TightcleanedSecondJet) { mTightJIDPassFractionVSeta->Fill(pfJets.at(1).eta(),1.); mTightJIDPassFractionVSpt->Fill(pfJets.at(1).pt(),1.); } else { mTightJIDPassFractionVSeta->Fill(pfJets.at(1).eta(),0.); mTightJIDPassFractionVSpt->Fill(pfJets.at(1).pt(),0.); } } if(LoosecleanedFirstJet && LoosecleanedSecondJet) { //Filling variables for first jet if (mPt) mPt->Fill (pfJets.at(0).pt()); if (mEta) mEta->Fill (pfJets.at(0).eta()); if (mPhi) mPhi->Fill (pfJets.at(0).phi()); if (mPhiVSEta) mPhiVSEta->Fill(pfJets.at(0).eta(),pfJets.at(0).phi()); if (mConstituents) mConstituents->Fill (pfJets.at(0).nConstituents()); if (mHFrac) mHFrac->Fill (pfJets.at(0).chargedHadronEnergyFraction()+pfJets.at(0).neutralHadronEnergyFraction()); if (mEFrac) mEFrac->Fill (pfJets.at(0).chargedEmEnergyFraction() +pfJets.at(0).neutralEmEnergyFraction()); //if (mE) mE->Fill (pfJets.at(0).energy()); //if (mP) mP->Fill (pfJets.at(0).p()); //if (mMass) mMass->Fill (pfJets.at(0).mass()); if (mChargedHadronEnergy) mChargedHadronEnergy->Fill (pfJets.at(0).chargedHadronEnergy()); if (mNeutralHadronEnergy) mNeutralHadronEnergy->Fill (pfJets.at(0).neutralHadronEnergy()); if (mChargedEmEnergy) mChargedEmEnergy->Fill(pfJets.at(0).chargedEmEnergy()); if (mChargedMuEnergy) mChargedMuEnergy->Fill (pfJets.at(0).chargedMuEnergy ()); if (mNeutralEmEnergy) mNeutralEmEnergy->Fill(pfJets.at(0).neutralEmEnergy()); if (mChargedMultiplicity ) mChargedMultiplicity->Fill(pfJets.at(0).chargedMultiplicity()); if (mNeutralMultiplicity ) mNeutralMultiplicity->Fill(pfJets.at(0).neutralMultiplicity()); if (mMuonMultiplicity )mMuonMultiplicity->Fill (pfJets.at(0). muonMultiplicity()); //_______________________________________________________ if (mNeutralFraction) mNeutralFraction->Fill (pfJets.at(0).neutralMultiplicity()/pfJets.at(0).nConstituents()); //Filling variables for second jet if (mPt) mPt->Fill (pfJets.at(1).pt()); if (mEta) mEta->Fill (pfJets.at(1).eta()); if (mPhi) mPhi->Fill (pfJets.at(1).phi()); if (mPhiVSEta) mPhiVSEta->Fill(pfJets.at(1).eta(),pfJets.at(1).phi()); if (mConstituents) mConstituents->Fill (pfJets.at(1).nConstituents()); if (mHFrac) mHFrac->Fill (pfJets.at(1).chargedHadronEnergyFraction()+pfJets.at(1).neutralHadronEnergyFraction()); if (mEFrac) mEFrac->Fill (pfJets.at(1).chargedEmEnergyFraction() +pfJets.at(1).neutralEmEnergyFraction()); //if (mE) mE->Fill (pfJets.at(1).energy()); //if (mP) mP->Fill (pfJets.at(1).p()); //if (mMass) mMass->Fill (pfJets.at(1).mass()); if (mChargedHadronEnergy) mChargedHadronEnergy->Fill (pfJets.at(1).chargedHadronEnergy()); if (mNeutralHadronEnergy) mNeutralHadronEnergy->Fill (pfJets.at(1).neutralHadronEnergy()); if (mChargedEmEnergy) mChargedEmEnergy->Fill(pfJets.at(1).chargedEmEnergy()); if (mChargedMuEnergy) mChargedMuEnergy->Fill (pfJets.at(1).chargedMuEnergy ()); if (mNeutralEmEnergy) mNeutralEmEnergy->Fill(pfJets.at(1).neutralEmEnergy()); if (mChargedMultiplicity ) mChargedMultiplicity->Fill(pfJets.at(1).chargedMultiplicity()); if (mNeutralMultiplicity ) mNeutralMultiplicity->Fill(pfJets.at(1).neutralMultiplicity()); if (mMuonMultiplicity )mMuonMultiplicity->Fill (pfJets.at(1). muonMultiplicity()); //_______________________________________________________ if (mNeutralFraction) mNeutralFraction->Fill (pfJets.at(1).neutralMultiplicity()/pfJets.at(1).nConstituents()); // Fill NPV profiles //---------------------------------------------------------------- for (int iJet=0; iJet<2; iJet++) { if (mPt_profile) mPt_profile ->Fill(numPV, pfJets.at(iJet).pt()); if (mEta_profile) mEta_profile ->Fill(numPV, pfJets.at(iJet).eta()); if (mPhi_profile) mPhi_profile ->Fill(numPV, pfJets.at(iJet).phi()); if (mConstituents_profile) mConstituents_profile->Fill(numPV, pfJets.at(iJet).nConstituents()); if (mHFrac_profile) mHFrac_profile ->Fill(numPV, pfJets.at(iJet).chargedHadronEnergyFraction() + pfJets.at(iJet).neutralHadronEnergyFraction()); if (mEFrac_profile) mEFrac_profile ->Fill(numPV, pfJets.at(iJet).chargedEmEnergyFraction() + pfJets.at(iJet).neutralEmEnergyFraction()); if (mChargedHadronEnergy_profile) mChargedHadronEnergy_profile->Fill(numPV, pfJets.at(iJet).chargedHadronEnergy()); if (mNeutralHadronEnergy_profile) mNeutralHadronEnergy_profile->Fill(numPV, pfJets.at(iJet).neutralHadronEnergy()); if (mChargedEmEnergy_profile) mChargedEmEnergy_profile ->Fill(numPV, pfJets.at(iJet).chargedEmEnergy()); if (mChargedMuEnergy_profile) mChargedMuEnergy_profile ->Fill(numPV, pfJets.at(iJet).chargedMuEnergy()); if (mNeutralEmEnergy_profile) mNeutralEmEnergy_profile ->Fill(numPV, pfJets.at(iJet).neutralEmEnergy()); if (mChargedMultiplicity_profile) mChargedMultiplicity_profile->Fill(numPV, pfJets.at(iJet).chargedMultiplicity()); if (mNeutralMultiplicity_profile) mNeutralMultiplicity_profile->Fill(numPV, pfJets.at(iJet).neutralMultiplicity()); if (mMuonMultiplicity_profile) mMuonMultiplicity_profile ->Fill(numPV, pfJets.at(iJet).muonMultiplicity()); } }// loose cleaned jets 1 and 2 }// fabs dphi < 2.1 }// fabs eta < 3 }// pt jets > threshold //now do the dijet balance and asymmetry calculations if (fabs(pfJets.at(0).eta() < 1.4)) { double pt_dijet = (pfJets.at(0).pt() + pfJets.at(1).pt())/2; double dPhi = fabs((pfJets.at(0)).phi()-(pfJets.at(1)).phi()); if (dPhi > 3.14) dPhi=fabs(dPhi -6.28 ); if (dPhi > 2.7) { double pt_probe; double pt_barrel; int jet1, jet2; int randJet = rand() % 2; if (fabs(pfJets.at(1).eta() < 1.4)) { if (randJet) { jet1 = 0; jet2 = 1; } else { jet1 = 1; jet2 = 0; } /***Di-Jet Asymmetry**** * leading jets eta < 1.4 * leading jets dphi > 2.7 * pt_third jet < threshold * A = (pt_1 - pt_2)/(pt_1 + pt_2) * jets 1 and two are randomly ordered */ bool thirdJetCut = true; for (unsigned int third = 2; third < pfJets.size(); ++third) if (pfJets.at(third).pt() > _asymmetryThirdJetCut) thirdJetCut = false; if (thirdJetCut) { double dijetAsymmetry = (pfJets.at(jet1).pt() - pfJets.at(jet2).pt()) / (pfJets.at(jet1).pt() + pfJets.at(jet2).pt()); mDijetAsymmetry->Fill(dijetAsymmetry); }// end restriction on third jet pt in asymmetry calculation } else { jet1 = 0; jet2 = 1; } pt_barrel = pfJets.at(jet1).pt(); pt_probe = pfJets.at(jet2).pt(); //dijet balance cuts /***Di-Jet Balance**** * pt_dijet = (pt_probe+pt_barrel)/2 * leading jets dphi > 2.7 * reject evnets where pt_third/pt_dijet > 0.2 * pv selection * B = (pt_probe - pt_barrel)/pt_dijet * select probe randomly from 2 jets if both leading jets are in the barrel */ bool thirdJetCut = true; for (unsigned int third = 2; third < pfJets.size(); ++third) if (pfJets.at(third).pt()/pt_dijet > _balanceThirdJetCut) thirdJetCut = false; if (thirdJetCut) { double dijetBalance = (pt_probe - pt_barrel) / pt_dijet; mDijetBalance->Fill(dijetBalance); }// end restriction on third jet pt ratio in balance calculation }// dPhi > 2.7 }// leading jet eta cut for asymmetry and balance calculations }// jet size >= 2 } // do dijet selection else{ for (reco::PFJetCollection::const_iterator jet = pfJets.begin(); jet!=pfJets.end(); ++jet){ LogTrace(metname)<<"[JetAnalyzer] Analyze PFJet"; Thiscleaned=false; Loosecleaned=false; Tightcleaned=false; if (jet == pfJets.begin()) { fstPhi = jet->phi(); _leadJetFlag = 1; } else { _leadJetFlag = 0; } if (jet == (pfJets.begin()+1)) sndPhi = jet->phi(); // if (jet->pt() < _ptThreshold) return; if (jet->pt() > _ptThreshold) { numofjets++ ; jetME->Fill(2); //calculate the jetID ThisCHFcleaned=true; LooseCHFcleaned=true; TightCHFcleaned=true; if((jet->chargedHadronEnergy()/jet->energy())<=_ThisCHFMin && fabs(jet->eta())<2.4) ThisCHFcleaned=false; //apply CHF>0 only if |eta|<2.4 if((jet->chargedHadronEnergy()/jet->energy())<=_LooseCHFMin && fabs(jet->eta())<2.4) LooseCHFcleaned=false; //apply CHF>0 only if |eta|<2.4 if((jet->chargedHadronEnergy()/jet->energy())<=_TightCHFMin && fabs(jet->eta())<2.4) TightCHFcleaned=false; //apply CHF>0 only if |eta|<2.4 if(ThisCHFcleaned && (jet->neutralHadronEnergy()/jet->energy())<_ThisNHFMax && (jet->chargedEmEnergy()/jet->energy())<_ThisCEFMax && (jet->neutralEmEnergy()/jet->energy())<_ThisNEFMax) Thiscleaned=true; if(LooseCHFcleaned && (jet->neutralHadronEnergy()/jet->energy())<_LooseNHFMax && (jet->chargedEmEnergy()/jet->energy())<_LooseCEFMax && (jet->neutralEmEnergy()/jet->energy())<_LooseNEFMax) Loosecleaned=true; if(TightCHFcleaned && (jet->neutralHadronEnergy()/jet->energy())<_TightNHFMax && (jet->chargedEmEnergy()/jet->energy())<_TightCEFMax && (jet->neutralEmEnergy()/jet->energy())<_TightNEFMax) Tightcleaned=true; if(fillpfJIDPassFrac==1) { //fill the profile for jid efficiency if(Loosecleaned) { mLooseJIDPassFractionVSeta->Fill(jet->eta(),1.); mLooseJIDPassFractionVSpt->Fill(jet->pt(),1.); } else { mLooseJIDPassFractionVSeta->Fill(jet->eta(),0.); mLooseJIDPassFractionVSpt->Fill(jet->pt(),0.); } if(Tightcleaned) { mTightJIDPassFractionVSeta->Fill(jet->eta(),1.); mTightJIDPassFractionVSpt->Fill(jet->pt(),1.); } else { mTightJIDPassFractionVSeta->Fill(jet->eta(),0.); mTightJIDPassFractionVSpt->Fill(jet->pt(),0.); } } if(!Thiscleaned) continue; // Leading jet // Histograms are filled once per event if (_leadJetFlag == 1) { if (mEtaFirst) mEtaFirst->Fill (jet->eta()); if (mPhiFirst) mPhiFirst->Fill (jet->phi()); //if (mEFirst) mEFirst->Fill (jet->energy()); if (mPtFirst) mPtFirst->Fill (jet->pt()); } // --- Passed the low pt jet trigger (no longer used) if (_JetLoPass == 1) { /* if (fabs(jet->eta()) <= 1.3) { if (mPt_Barrel_Lo) mPt_Barrel_Lo->Fill(jet->pt()); if (mEta_Lo) mEta_Lo->Fill(jet->eta()); if (mPhi_Barrel_Lo) mPhi_Barrel_Lo->Fill(jet->phi()); } if ( (fabs(jet->eta()) > 1.3) && (fabs(jet->eta()) <= 3) ) { if (mPt_EndCap_Lo) mPt_EndCap_Lo->Fill(jet->pt()); if (mEta_Lo) mEta_Lo->Fill(jet->eta()); if (mPhi_EndCap_Lo) mPhi_EndCap_Lo->Fill(jet->phi()); } if (fabs(jet->eta()) > 3.0) { if (mPt_Forward_Lo) mPt_Forward_Lo->Fill(jet->pt()); if (mEta_Lo) mEta_Lo->Fill(jet->eta()); if (mPhi_Forward_Lo) mPhi_Forward_Lo->Fill(jet->phi()); }*/ //if (mEta_Lo) mEta_Lo->Fill (jet->eta()); if (mPhi_Lo) mPhi_Lo->Fill (jet->phi()); if (mPt_Lo) mPt_Lo->Fill (jet->pt()); } // --- Passed the high pt jet trigger if (_JetHiPass == 1) { if (fabs(jet->eta()) <= 1.3) { if (mPt_Barrel_Hi && jet->pt()>100.) mPt_Barrel_Hi->Fill(jet->pt()); if (mEta_Hi && jet->pt()>100.) mEta_Hi->Fill(jet->eta()); if (mPhi_Barrel_Hi) mPhi_Barrel_Hi->Fill(jet->phi()); //if (mConstituents_Barrel_Hi) mConstituents_Barrel_Hi->Fill(jet->nConstituents()); //if (mHFrac_Barrel_Hi) mHFrac_Barrel_Hi->Fill(jet->chargedHadronEnergyFraction()+jet->neutralHadronEnergyFraction()); } if ( (fabs(jet->eta()) > 1.3) && (fabs(jet->eta()) <= 3) ) { if (mPt_EndCap_Hi && jet->pt()>100.) mPt_EndCap_Hi->Fill(jet->pt()); if (mEta_Hi && jet->pt()>100.) mEta_Hi->Fill(jet->eta()); if (mPhi_EndCap_Hi) mPhi_EndCap_Hi->Fill(jet->phi()); //if (mConstituents_EndCap_Hi) mConstituents_EndCap_Hi->Fill(jet->nConstituents()); //if (mHFrac_EndCap_Hi) mHFrac_EndCap_Hi->Fill(jet->chargedHadronEnergyFraction()+jet->neutralHadronEnergyFraction()); } if (fabs(jet->eta()) > 3.0) { if (mPt_Forward_Hi && jet->pt()>100.) mPt_Forward_Hi->Fill(jet->pt()); if (mEta_Hi && jet->pt()>100.) mEta_Hi->Fill(jet->eta()); if (mPhi_Forward_Hi) mPhi_Forward_Hi->Fill(jet->phi()); //if (mConstituents_Forward_Hi) mConstituents_Forward_Hi->Fill(jet->nConstituents()); //if (mHFrac_Forward_Hi) mHFrac_Forward_Hi->Fill(jet->chargedHadronEnergyFraction()+jet->neutralHadronEnergyFraction()); } if (mEta_Hi && jet->pt()>100.) mEta_Hi->Fill (jet->eta()); if (mPhi_Hi) mPhi_Hi->Fill (jet->phi()); if (mPt_Hi) mPt_Hi->Fill (jet->pt()); } if (mPt) mPt->Fill (jet->pt()); if (mPt_1) mPt_1->Fill (jet->pt()); if (mPt_2) mPt_2->Fill (jet->pt()); if (mPt_3) mPt_3->Fill (jet->pt()); if (mEta) mEta->Fill (jet->eta()); if (mPhi) mPhi->Fill (jet->phi()); if (mPhiVSEta) mPhiVSEta->Fill(jet->eta(),jet->phi()); if (mConstituents) mConstituents->Fill (jet->nConstituents()); if (mHFrac) mHFrac->Fill (jet->chargedHadronEnergyFraction()+jet->neutralHadronEnergyFraction()); if (mEFrac) mEFrac->Fill (jet->chargedEmEnergyFraction() +jet->neutralEmEnergyFraction()); if (jet->pt()<= 50) { if (mCHFracVSeta_lowPt) mCHFracVSeta_lowPt->Fill(jet->eta(),jet->chargedHadronEnergyFraction()); if (mNHFracVSeta_lowPt) mNHFracVSeta_lowPt->Fill(jet->eta(),jet->neutralHadronEnergyFraction()); if (mPhFracVSeta_lowPt) mPhFracVSeta_lowPt->Fill(jet->eta(),jet->neutralEmEnergyFraction()); if (mElFracVSeta_lowPt) mElFracVSeta_lowPt->Fill(jet->eta(),jet->chargedEmEnergyFraction()); if (mMuFracVSeta_lowPt) mMuFracVSeta_lowPt->Fill(jet->eta(),jet->chargedMuEnergyFraction()); } if (jet->pt()>50. && jet->pt()<=140.) { if (mCHFracVSeta_mediumPt) mCHFracVSeta_mediumPt->Fill(jet->eta(),jet->chargedHadronEnergyFraction()); if (mNHFracVSeta_mediumPt) mNHFracVSeta_mediumPt->Fill(jet->eta(),jet->neutralHadronEnergyFraction()); if (mPhFracVSeta_mediumPt) mPhFracVSeta_mediumPt->Fill(jet->eta(),jet->neutralEmEnergyFraction()); if (mElFracVSeta_mediumPt) mElFracVSeta_mediumPt->Fill(jet->eta(),jet->chargedEmEnergyFraction()); if (mMuFracVSeta_mediumPt) mMuFracVSeta_mediumPt->Fill(jet->eta(),jet->chargedMuEnergyFraction()); } if (jet->pt()>140.) { if (mCHFracVSeta_highPt) mCHFracVSeta_highPt->Fill(jet->eta(),jet->chargedHadronEnergyFraction()); if (mNHFracVSeta_highPt) mNHFracVSeta_highPt->Fill(jet->eta(),jet->neutralHadronEnergyFraction()); if (mPhFracVSeta_highPt) mPhFracVSeta_highPt->Fill(jet->eta(),jet->neutralEmEnergyFraction()); if (mElFracVSeta_highPt) mElFracVSeta_highPt->Fill(jet->eta(),jet->chargedEmEnergyFraction()); if (mMuFracVSeta_highPt) mMuFracVSeta_highPt->Fill(jet->eta(),jet->chargedMuEnergyFraction()); } if (fabs(jet->eta()) <= 1.3) { if (mPt_Barrel) mPt_Barrel->Fill (jet->pt()); if (mPhi_Barrel) mPhi_Barrel->Fill (jet->phi()); //if (mE_Barrel) mE_Barrel->Fill (jet->energy()); if (mConstituents_Barrel) mConstituents_Barrel->Fill(jet->nConstituents()); if (mHFrac_Barrel) mHFrac_Barrel->Fill(jet->chargedHadronEnergyFraction() + jet->neutralHadronEnergyFraction() ); if (mEFrac_Barrel) mEFrac->Fill (jet->chargedEmEnergyFraction() + jet->neutralEmEnergyFraction()); //fractions if (jet->pt()<=50.) { if (mCHFrac_lowPt_Barrel) mCHFrac_lowPt_Barrel->Fill(jet->chargedHadronEnergyFraction()); if (mNHFrac_lowPt_Barrel) mNHFrac_lowPt_Barrel->Fill(jet->neutralHadronEnergyFraction()); if (mPhFrac_lowPt_Barrel) mPhFrac_lowPt_Barrel->Fill(jet->neutralEmEnergyFraction()); if (mElFrac_lowPt_Barrel) mElFrac_lowPt_Barrel->Fill(jet->chargedEmEnergyFraction()); if (mMuFrac_lowPt_Barrel) mMuFrac_lowPt_Barrel->Fill(jet->chargedMuEnergyFraction()); // if (mCHEn_lowPt_Barrel) mCHEn_lowPt_Barrel->Fill(jet->chargedHadronEnergy()); if (mNHEn_lowPt_Barrel) mNHEn_lowPt_Barrel->Fill(jet->neutralHadronEnergy()); if (mPhEn_lowPt_Barrel) mPhEn_lowPt_Barrel->Fill(jet->neutralEmEnergy()); if (mElEn_lowPt_Barrel) mElEn_lowPt_Barrel->Fill(jet->chargedEmEnergy()); if (mMuEn_lowPt_Barrel) mMuEn_lowPt_Barrel->Fill(jet->chargedMuEnergy()); } if (jet->pt()>50. && jet->pt()<=140.) { if (mCHFrac_mediumPt_Barrel) mCHFrac_mediumPt_Barrel->Fill(jet->chargedHadronEnergyFraction()); if (mNHFrac_mediumPt_Barrel) mNHFrac_mediumPt_Barrel->Fill(jet->neutralHadronEnergyFraction()); if (mPhFrac_mediumPt_Barrel) mPhFrac_mediumPt_Barrel->Fill(jet->neutralEmEnergyFraction()); if (mElFrac_mediumPt_Barrel) mElFrac_mediumPt_Barrel->Fill(jet->chargedEmEnergyFraction()); if (mMuFrac_mediumPt_Barrel) mMuFrac_mediumPt_Barrel->Fill(jet->chargedMuEnergyFraction()); // if (mCHEn_mediumPt_Barrel) mCHEn_mediumPt_Barrel->Fill(jet->chargedHadronEnergy()); if (mNHEn_mediumPt_Barrel) mNHEn_mediumPt_Barrel->Fill(jet->neutralHadronEnergy()); if (mPhEn_mediumPt_Barrel) mPhEn_mediumPt_Barrel->Fill(jet->neutralEmEnergy()); if (mElEn_mediumPt_Barrel) mElEn_mediumPt_Barrel->Fill(jet->chargedEmEnergy()); if (mMuEn_mediumPt_Barrel) mMuEn_mediumPt_Barrel->Fill(jet->chargedMuEnergy()); } if (jet->pt()>140.) { if (mCHFrac_highPt_Barrel) mCHFrac_highPt_Barrel->Fill(jet->chargedHadronEnergyFraction()); if (mNHFrac_highPt_Barrel) mNHFrac_highPt_Barrel->Fill(jet->neutralHadronEnergyFraction()); if (mPhFrac_highPt_Barrel) mPhFrac_highPt_Barrel->Fill(jet->neutralEmEnergyFraction()); if (mElFrac_highPt_Barrel) mElFrac_highPt_Barrel->Fill(jet->chargedEmEnergyFraction()); if (mMuFrac_highPt_Barrel) mMuFrac_highPt_Barrel->Fill(jet->chargedMuEnergyFraction()); // if (mCHEn_highPt_Barrel) mCHEn_highPt_Barrel->Fill(jet->chargedHadronEnergy()); if (mNHEn_highPt_Barrel) mNHEn_highPt_Barrel->Fill(jet->neutralHadronEnergy()); if (mPhEn_highPt_Barrel) mPhEn_highPt_Barrel->Fill(jet->neutralEmEnergy()); if (mElEn_highPt_Barrel) mElEn_highPt_Barrel->Fill(jet->chargedEmEnergy()); if (mMuEn_highPt_Barrel) mMuEn_highPt_Barrel->Fill(jet->chargedMuEnergy()); } if(mChMultiplicity_lowPt_Barrel) mChMultiplicity_lowPt_Barrel->Fill(jet->chargedMultiplicity()); if(mNeuMultiplicity_lowPt_Barrel) mNeuMultiplicity_lowPt_Barrel->Fill(jet->neutralMultiplicity()); if(mMuMultiplicity_lowPt_Barrel) mMuMultiplicity_lowPt_Barrel->Fill(jet->muonMultiplicity()); if(mChMultiplicity_mediumPt_Barrel) mChMultiplicity_mediumPt_Barrel->Fill(jet->chargedMultiplicity()); if(mNeuMultiplicity_mediumPt_Barrel) mNeuMultiplicity_mediumPt_Barrel->Fill(jet->neutralMultiplicity()); if(mMuMultiplicity_mediumPt_Barrel) mMuMultiplicity_mediumPt_Barrel->Fill(jet->muonMultiplicity()); if(mChMultiplicity_highPt_Barrel) mChMultiplicity_highPt_Barrel->Fill(jet->chargedMultiplicity()); if(mNeuMultiplicity_highPt_Barrel) mNeuMultiplicity_highPt_Barrel->Fill(jet->neutralMultiplicity()); if(mMuMultiplicity_highPt_Barrel) mMuMultiplicity_highPt_Barrel->Fill(jet->muonMultiplicity()); // if (mCHFracVSpT_Barrel) mCHFracVSpT_Barrel->Fill(jet->pt(),jet->chargedHadronEnergyFraction()); if (mNHFracVSpT_Barrel) mNHFracVSpT_Barrel->Fill(jet->pt(),jet->neutralHadronEnergyFraction()); if (mPhFracVSpT_Barrel) mPhFracVSpT_Barrel->Fill(jet->pt(),jet->neutralEmEnergyFraction()); if (mElFracVSpT_Barrel) mElFracVSpT_Barrel->Fill(jet->pt(),jet->chargedEmEnergyFraction()); if (mMuFracVSpT_Barrel) mMuFracVSpT_Barrel->Fill(jet->pt(),jet->chargedMuEnergyFraction()); } if ( (fabs(jet->eta()) > 1.3) && (fabs(jet->eta()) <= 3) ) { if (mPt_EndCap) mPt_EndCap->Fill (jet->pt()); if (mPhi_EndCap) mPhi_EndCap->Fill (jet->phi()); //if (mE_EndCap) mE_EndCap->Fill (jet->energy()); if (mConstituents_EndCap) mConstituents_EndCap->Fill(jet->nConstituents()); if (mHFrac_EndCap) mHFrac_EndCap->Fill(jet->chargedHadronEnergyFraction() + jet->neutralHadronEnergyFraction()); if (mEFrac_EndCap) mEFrac->Fill (jet->chargedEmEnergyFraction() + jet->neutralEmEnergyFraction()); //fractions if (jet->pt()<=50.) { if (mCHFrac_lowPt_EndCap) mCHFrac_lowPt_EndCap->Fill(jet->chargedHadronEnergyFraction()); if (mNHFrac_lowPt_EndCap) mNHFrac_lowPt_EndCap->Fill(jet->neutralHadronEnergyFraction()); if (mPhFrac_lowPt_EndCap) mPhFrac_lowPt_EndCap->Fill(jet->neutralEmEnergyFraction()); if (mElFrac_lowPt_EndCap) mElFrac_lowPt_EndCap->Fill(jet->chargedEmEnergyFraction()); if (mMuFrac_lowPt_EndCap) mMuFrac_lowPt_EndCap->Fill(jet->chargedMuEnergyFraction()); // if (mCHEn_lowPt_EndCap) mCHEn_lowPt_EndCap->Fill(jet->chargedHadronEnergy()); if (mNHEn_lowPt_EndCap) mNHEn_lowPt_EndCap->Fill(jet->neutralHadronEnergy()); if (mPhEn_lowPt_EndCap) mPhEn_lowPt_EndCap->Fill(jet->neutralEmEnergy()); if (mElEn_lowPt_EndCap) mElEn_lowPt_EndCap->Fill(jet->chargedEmEnergy()); if (mMuEn_lowPt_EndCap) mMuEn_lowPt_EndCap->Fill(jet->chargedMuEnergy()); } if (jet->pt()>50. && jet->pt()<=140.) { if (mCHFrac_mediumPt_EndCap) mCHFrac_mediumPt_EndCap->Fill(jet->chargedHadronEnergyFraction()); if (mNHFrac_mediumPt_EndCap) mNHFrac_mediumPt_EndCap->Fill(jet->neutralHadronEnergyFraction()); if (mPhFrac_mediumPt_EndCap) mPhFrac_mediumPt_EndCap->Fill(jet->neutralEmEnergyFraction()); if (mElFrac_mediumPt_EndCap) mElFrac_mediumPt_EndCap->Fill(jet->chargedEmEnergyFraction()); if (mMuFrac_mediumPt_EndCap) mMuFrac_mediumPt_EndCap->Fill(jet->chargedMuEnergyFraction()); // if (mCHEn_mediumPt_EndCap) mCHEn_mediumPt_EndCap->Fill(jet->chargedHadronEnergy()); if (mNHEn_mediumPt_EndCap) mNHEn_mediumPt_EndCap->Fill(jet->neutralHadronEnergy()); if (mPhEn_mediumPt_EndCap) mPhEn_mediumPt_EndCap->Fill(jet->neutralEmEnergy()); if (mElEn_mediumPt_EndCap) mElEn_mediumPt_EndCap->Fill(jet->chargedEmEnergy()); if (mMuEn_mediumPt_EndCap) mMuEn_mediumPt_EndCap->Fill(jet->chargedMuEnergy()); } if (jet->pt()>140.) { if (mCHFrac_highPt_EndCap) mCHFrac_highPt_EndCap->Fill(jet->chargedHadronEnergyFraction()); if (mNHFrac_highPt_EndCap) mNHFrac_highPt_EndCap->Fill(jet->neutralHadronEnergyFraction()); if (mPhFrac_highPt_EndCap) mPhFrac_highPt_EndCap->Fill(jet->neutralEmEnergyFraction()); if (mElFrac_highPt_EndCap) mElFrac_highPt_EndCap->Fill(jet->chargedEmEnergyFraction()); if (mMuFrac_highPt_EndCap) mMuFrac_highPt_EndCap->Fill(jet->chargedMuEnergyFraction()); // if (mCHEn_highPt_EndCap) mCHEn_highPt_EndCap->Fill(jet->chargedHadronEnergy()); if (mNHEn_highPt_EndCap) mNHEn_highPt_EndCap->Fill(jet->neutralHadronEnergy()); if (mPhEn_highPt_EndCap) mPhEn_highPt_EndCap->Fill(jet->neutralEmEnergy()); if (mElEn_highPt_EndCap) mElEn_highPt_EndCap->Fill(jet->chargedEmEnergy()); if (mMuEn_highPt_EndCap) mMuEn_highPt_EndCap->Fill(jet->chargedMuEnergy()); } if(mChMultiplicity_lowPt_EndCap) mChMultiplicity_lowPt_EndCap->Fill(jet->chargedMultiplicity()); if(mNeuMultiplicity_lowPt_EndCap) mNeuMultiplicity_lowPt_EndCap->Fill(jet->neutralMultiplicity()); if(mMuMultiplicity_lowPt_EndCap) mMuMultiplicity_lowPt_EndCap->Fill(jet->muonMultiplicity()); if(mChMultiplicity_mediumPt_EndCap) mChMultiplicity_mediumPt_EndCap->Fill(jet->chargedMultiplicity()); if(mNeuMultiplicity_mediumPt_EndCap) mNeuMultiplicity_mediumPt_EndCap->Fill(jet->neutralMultiplicity()); if(mMuMultiplicity_mediumPt_EndCap) mMuMultiplicity_mediumPt_EndCap->Fill(jet->muonMultiplicity()); if(mChMultiplicity_highPt_EndCap) mChMultiplicity_highPt_EndCap->Fill(jet->chargedMultiplicity()); if(mNeuMultiplicity_highPt_EndCap) mNeuMultiplicity_highPt_EndCap->Fill(jet->neutralMultiplicity()); if(mMuMultiplicity_highPt_EndCap) mMuMultiplicity_highPt_EndCap->Fill(jet->muonMultiplicity()); // if (mCHFracVSpT_EndCap) mCHFracVSpT_EndCap->Fill(jet->pt(),jet->chargedHadronEnergyFraction()); if (mNHFracVSpT_EndCap) mNHFracVSpT_EndCap->Fill(jet->pt(),jet->neutralHadronEnergyFraction()); if (mPhFracVSpT_EndCap) mPhFracVSpT_EndCap->Fill(jet->pt(),jet->neutralEmEnergyFraction()); if (mElFracVSpT_EndCap) mElFracVSpT_EndCap->Fill(jet->pt(),jet->chargedEmEnergyFraction()); if (mMuFracVSpT_EndCap) mMuFracVSpT_EndCap->Fill(jet->pt(),jet->chargedMuEnergyFraction()); } if (fabs(jet->eta()) > 3.0) { if (mPt_Forward) mPt_Forward->Fill (jet->pt()); if (mPhi_Forward) mPhi_Forward->Fill (jet->phi()); //if (mE_Forward) mE_Forward->Fill (jet->energy()); if (mConstituents_Forward) mConstituents_Forward->Fill(jet->nConstituents()); if (mHFrac_Forward) mHFrac_Forward->Fill(jet->chargedHadronEnergyFraction() + jet->neutralHadronEnergyFraction()); if (mEFrac_Forward) mEFrac->Fill (jet->chargedEmEnergyFraction() + jet->neutralEmEnergyFraction()); //fractions if (jet->pt()<=50.) { if(mHFEFrac_lowPt_Forward) mHFEFrac_lowPt_Forward->Fill(jet->HFEMEnergyFraction()); if(mHFHFrac_lowPt_Forward) mHFHFrac_lowPt_Forward->Fill(jet->HFHadronEnergyFraction()); // if(mHFEEn_lowPt_Forward) mHFEEn_lowPt_Forward->Fill(jet->HFEMEnergy()); if(mHFHEn_lowPt_Forward) mHFHEn_lowPt_Forward->Fill(jet->HFHadronEnergy()); } if (jet->pt()>50. && jet->pt()<=140.) { if(mHFEFrac_mediumPt_Forward) mHFEFrac_mediumPt_Forward->Fill(jet->HFEMEnergyFraction()); if(mHFHFrac_mediumPt_Forward) mHFHFrac_mediumPt_Forward->Fill(jet->HFHadronEnergyFraction()); // if(mHFEEn_mediumPt_Forward) mHFEEn_mediumPt_Forward->Fill(jet->HFEMEnergy()); if(mHFHEn_mediumPt_Forward) mHFHEn_mediumPt_Forward->Fill(jet->HFHadronEnergy()); } if (jet->pt()>140.) { if(mHFEFrac_highPt_Forward) mHFEFrac_highPt_Forward->Fill(jet->HFEMEnergyFraction()); if(mHFHFrac_highPt_Forward) mHFHFrac_highPt_Forward->Fill(jet->HFHadronEnergyFraction()); // if(mHFEEn_highPt_Forward) mHFEEn_highPt_Forward->Fill(jet->HFEMEnergy()); if(mHFHEn_highPt_Forward) mHFHEn_highPt_Forward->Fill(jet->HFHadronEnergy()); } if(mChMultiplicity_lowPt_Forward) mChMultiplicity_lowPt_Forward->Fill(jet->chargedMultiplicity()); if(mNeuMultiplicity_lowPt_Forward) mNeuMultiplicity_lowPt_Forward->Fill(jet->neutralMultiplicity()); if(mMuMultiplicity_lowPt_Forward) mMuMultiplicity_lowPt_Forward->Fill(jet->muonMultiplicity()); if(mChMultiplicity_mediumPt_Forward) mChMultiplicity_mediumPt_Forward->Fill(jet->chargedMultiplicity()); if(mNeuMultiplicity_mediumPt_Forward) mNeuMultiplicity_mediumPt_Forward->Fill(jet->neutralMultiplicity()); if(mMuMultiplicity_mediumPt_Forward) mMuMultiplicity_mediumPt_Forward->Fill(jet->muonMultiplicity()); if(mChMultiplicity_highPt_Forward) mChMultiplicity_highPt_Forward->Fill(jet->chargedMultiplicity()); if(mNeuMultiplicity_highPt_Forward) mNeuMultiplicity_highPt_Forward->Fill(jet->neutralMultiplicity()); if(mMuMultiplicity_highPt_Forward) mMuMultiplicity_highPt_Forward->Fill(jet->muonMultiplicity()); if(mHFHFracVSpT_Forward) mHFHFracVSpT_Forward->Fill(jet->pt(),jet->HFHadronEnergyFraction()); if(mHFEFracVSpT_Forward) mHFEFracVSpT_Forward->Fill(jet->pt(),jet->HFEMEnergyFraction()); } //if (mE) mE->Fill (jet->energy()); //if (mP) mP->Fill (jet->p()); //if (mMass) mMass->Fill (jet->mass()); if (mChargedHadronEnergy) mChargedHadronEnergy->Fill (jet->chargedHadronEnergy()); if (mNeutralHadronEnergy) mNeutralHadronEnergy->Fill (jet->neutralHadronEnergy()); if (mChargedEmEnergy) mChargedEmEnergy->Fill(jet->chargedEmEnergy()); if (mChargedMuEnergy) mChargedMuEnergy->Fill (jet->chargedMuEnergy ()); if (mNeutralEmEnergy) mNeutralEmEnergy->Fill(jet->neutralEmEnergy()); if (mChargedMultiplicity ) mChargedMultiplicity->Fill(jet->chargedMultiplicity()); if (mNeutralMultiplicity ) mNeutralMultiplicity->Fill(jet->neutralMultiplicity()); if (mMuonMultiplicity )mMuonMultiplicity->Fill (jet-> muonMultiplicity()); //_______________________________________________________ if (mNeutralFraction) mNeutralFraction->Fill (jet->neutralMultiplicity()/jet->nConstituents()); // Fill NPV profiles //---------------------------------------------------------------------- if (mPt_profile) mPt_profile ->Fill(numPV, jet->pt()); if (mEta_profile) mEta_profile ->Fill(numPV, jet->eta()); if (mPhi_profile) mPhi_profile ->Fill(numPV, jet->phi()); if (mConstituents_profile) mConstituents_profile->Fill(numPV, jet->nConstituents()); if (mHFrac_profile) mHFrac_profile ->Fill(numPV, jet->chargedHadronEnergyFraction() + jet->neutralHadronEnergyFraction()); if (mEFrac_profile) mEFrac_profile ->Fill(numPV, jet->chargedEmEnergyFraction() + jet->neutralEmEnergyFraction()); if (mChargedHadronEnergy_profile) mChargedHadronEnergy_profile->Fill(numPV, jet->chargedHadronEnergy()); if (mNeutralHadronEnergy_profile) mNeutralHadronEnergy_profile->Fill(numPV, jet->neutralHadronEnergy()); if (mChargedEmEnergy_profile) mChargedEmEnergy_profile ->Fill(numPV, jet->chargedEmEnergy()); if (mChargedMuEnergy_profile) mChargedMuEnergy_profile ->Fill(numPV, jet->chargedMuEnergy ()); if (mNeutralEmEnergy_profile) mNeutralEmEnergy_profile ->Fill(numPV, jet->neutralEmEnergy()); if (mChargedMultiplicity_profile) mChargedMultiplicity_profile->Fill(numPV, jet->chargedMultiplicity()); if (mNeutralMultiplicity_profile) mNeutralMultiplicity_profile->Fill(numPV, jet->neutralMultiplicity()); if (mMuonMultiplicity_profile) mMuonMultiplicity_profile ->Fill(numPV, jet->muonMultiplicity()); //calculate correctly the dphi if(numofjets>1) { diff = fabs(fstPhi - sndPhi); corr = 2*acos(-1.) - diff; if(diff < acos(-1.)) { dphi = diff; } else { dphi = corr; } } // numofjets>1 } // JetPt>_ptThreshold } // PF jet loop if (mNJets) mNJets->Fill (numofjets); if (mDPhi) mDPhi->Fill (dphi); if (mNJets_profile) mNJets_profile->Fill(numPV, numofjets); } // non dijet selection }
void PFJetAnalyzer::beginJob | ( | DQMStore * | dbe | ) | [virtual] |
Inizialize parameters for histo binning.
Implements PFJetAnalyzerBase.
Definition at line 48 of file PFJetAnalyzer.cc.
References DQMStore::book1D(), DQMStore::book2D(), DQMStore::bookProfile(), jptDQMConfig_cff::eMax, jptDQMConfig_cff::etaMax, jptDQMConfig_cff::etaMin, LogTrace, metname, nbinsPV, Parameters::parameters, jptDQMConfig_cff::phiMax, jptDQMConfig_cff::phiMin, jptDQMConfig_cff::pMax, jptDQMConfig_cff::ptMax, PtMinSelector_cfg::ptMin, PVlow, PVup, MonitorElement::setAxisTitle(), MonitorElement::setBinLabel(), and DQMStore::setCurrentFolder().
{ metname = "pFJetAnalyzer"; LogTrace(metname)<<"[PFJetAnalyzer] Parameters initialization"; //dbe->setCurrentFolder("JetMET/Jet/PFJets");//old version, now name set to source, which //can be set for each instance of PFJetAnalyzer called inside JetMETAnalyzer. Useful, e.g., to //name differently the dir for all jets and cleaned jets dbe->setCurrentFolder("JetMET/Jet/"+_source); // dbe->setCurrentFolder("JetMET/Jet/PFJets"); jetME = dbe->book1D("jetReco", "jetReco", 3, 1, 4); jetME->setBinLabel(2,"PFJets",1); // monitoring of eta parameter etaBin = parameters.getParameter<int>("etaBin"); etaMin = parameters.getParameter<double>("etaMin"); etaMax = parameters.getParameter<double>("etaMax"); // monitoring of phi paramater phiBin = parameters.getParameter<int>("phiBin"); phiMin = parameters.getParameter<double>("phiMin"); phiMax = parameters.getParameter<double>("phiMax"); // monitoring of the transverse momentum ptBin = parameters.getParameter<int>("ptBin"); ptMin = parameters.getParameter<double>("ptMin"); ptMax = parameters.getParameter<double>("ptMax"); // eBin = parameters.getParameter<int>("eBin"); eMin = parameters.getParameter<double>("eMin"); eMax = parameters.getParameter<double>("eMax"); // pBin = parameters.getParameter<int>("pBin"); pMin = parameters.getParameter<double>("pMin"); pMax = parameters.getParameter<double>("pMax"); _ptThreshold = parameters.getParameter<double>("ptThreshold"); _asymmetryThirdJetCut = parameters.getParameter<double>("asymmetryThirdJetCut"); _balanceThirdJetCut = parameters.getParameter<double>("balanceThirdJetCut"); _TightCHFMin = parameters.getParameter<double>("TightCHFMin"); _TightNHFMax = parameters.getParameter<double>("TightNHFMax"); _TightCEFMax = parameters.getParameter<double>("TightCEFMax"); _TightNEFMax = parameters.getParameter<double>("TightNEFMax"); _LooseCHFMin = parameters.getParameter<double>("LooseCHFMin"); _LooseNHFMax = parameters.getParameter<double>("LooseNHFMax"); _LooseCEFMax = parameters.getParameter<double>("LooseCEFMax"); _LooseNEFMax = parameters.getParameter<double>("LooseNEFMax"); fillpfJIDPassFrac = parameters.getParameter<int>("fillpfJIDPassFrac"); makedijetselection = parameters.getParameter<int>("makedijetselection"); _ThisCHFMin = parameters.getParameter<double>("ThisCHFMin"); _ThisNHFMax = parameters.getParameter<double>("ThisNHFMax"); _ThisCEFMax = parameters.getParameter<double>("ThisCEFMax"); _ThisNEFMax = parameters.getParameter<double>("ThisNEFMax"); // Generic Jet Parameters mPt = dbe->book1D("Pt", "Pt", ptBin, ptMin, ptMax); mEta = dbe->book1D("Eta", "Eta", etaBin, etaMin, etaMax); mPhi = dbe->book1D("Phi", "Phi", phiBin, phiMin, phiMax); mConstituents = dbe->book1D("Constituents", "# of constituents", 50, 0, 100); mHFrac = dbe->book1D("HFrac", "HFrac", 120, -0.1, 1.1); mEFrac = dbe->book1D("EFrac", "EFrac", 120, -0.1, 1.1); // Book NPV profiles //---------------------------------------------------------------------------- mPt_profile = dbe->bookProfile("Pt_profile", "pt", nbinsPV, PVlow, PVup, ptBin, ptMin, ptMax); mEta_profile = dbe->bookProfile("Eta_profile", "eta", nbinsPV, PVlow, PVup, etaBin, etaMin, etaMax); mPhi_profile = dbe->bookProfile("Phi_profile", "phi", nbinsPV, PVlow, PVup, phiBin, phiMin, phiMax); mConstituents_profile = dbe->bookProfile("Constituents_profile", "# of constituents", nbinsPV, PVlow, PVup, 50, 0, 100); mHFrac_profile = dbe->bookProfile("HFrac_profile", "Hfrac", nbinsPV, PVlow, PVup, 120, -0.1, 1.1); mEFrac_profile = dbe->bookProfile("EFrac_profile", "Efrac", nbinsPV, PVlow, PVup, 120, -0.1, 1.1); // Set NPV profiles x-axis title //---------------------------------------------------------------------------- mPt_profile ->setAxisTitle("nvtx",1); mEta_profile ->setAxisTitle("nvtx",1); mPhi_profile ->setAxisTitle("nvtx",1); mConstituents_profile->setAxisTitle("nvtx",1); mHFrac_profile ->setAxisTitle("nvtx",1); mEFrac_profile ->setAxisTitle("nvtx",1); //mE = dbe->book1D("E", "E", eBin, eMin, eMax); //mP = dbe->book1D("P", "P", pBin, pMin, pMax); //mMass = dbe->book1D("Mass", "Mass", 100, 0, 25); // mPhiVSEta = dbe->book2D("PhiVSEta", "PhiVSEta", 50, etaMin, etaMax, 24, phiMin, phiMax); if(makedijetselection!=1) { mPt_1 = dbe->book1D("Pt1", "Pt1", 50, 0, 100); mPt_2 = dbe->book1D("Pt2", "Pt2", 60, 0, 300); mPt_3 = dbe->book1D("Pt3", "Pt3", 100, 0, 5000); // Low and high pt trigger paths mPt_Lo = dbe->book1D("Pt_Lo", "Pt (Pass Low Pt Jet Trigger)", 20, 0, 100); //mEta_Lo = dbe->book1D("Eta_Lo", "Eta (Pass Low Pt Jet Trigger)", etaBin, etaMin, etaMax); mPhi_Lo = dbe->book1D("Phi_Lo", "Phi (Pass Low Pt Jet Trigger)", phiBin, phiMin, phiMax); mPt_Hi = dbe->book1D("Pt_Hi", "Pt (Pass Hi Pt Jet Trigger)", 100, 0, 300); mEta_Hi = dbe->book1D("Eta_Hi", "Eta (Pass Hi Pt Jet Trigger)", etaBin, etaMin, etaMax); mPhi_Hi = dbe->book1D("Phi_Hi", "Phi (Pass Hi Pt Jet Trigger)", phiBin, phiMin, phiMax); mNJets = dbe->book1D("NJets", "number of jets", 100, 0, 100); mCHFracVSeta_lowPt= dbe->bookProfile("CHFracVSeta_lowPt","CHFracVSeta_lowPt",etaBin, etaMin, etaMax,0.,1.2); mNHFracVSeta_lowPt= dbe->bookProfile("NHFracVSeta_lowPt","NHFracVSeta_lowPt",etaBin, etaMin, etaMax,0.,1.2); mPhFracVSeta_lowPt= dbe->bookProfile("PhFracVSeta_lowPt","PhFracVSeta_lowPt",etaBin, etaMin, etaMax,0.,1.2); mElFracVSeta_lowPt= dbe->bookProfile("ElFracVSeta_lowPt","ElFracVSeta_lowPt",etaBin, etaMin, etaMax,0.,1.2); mMuFracVSeta_lowPt= dbe->bookProfile("MuFracVSeta_lowPt","MuFracVSeta_lowPt",etaBin, etaMin, etaMax,0.,1.2); mCHFracVSeta_mediumPt= dbe->bookProfile("CHFracVSeta_mediumPt","CHFracVSeta_mediumPt",etaBin, etaMin, etaMax,0.,1.2); mNHFracVSeta_mediumPt= dbe->bookProfile("NHFracVSeta_mediumPt","NHFracVSeta_mediumPt",etaBin, etaMin, etaMax,0.,1.2); mPhFracVSeta_mediumPt= dbe->bookProfile("PhFracVSeta_mediumPt","PhFracVSeta_mediumPt",etaBin, etaMin, etaMax,0.,1.2); mElFracVSeta_mediumPt= dbe->bookProfile("ElFracVSeta_mediumPt","ElFracVSeta_mediumPt",etaBin, etaMin, etaMax,0.,1.2); mMuFracVSeta_mediumPt= dbe->bookProfile("MuFracVSeta_mediumPt","MuFracVSeta_mediumPt",etaBin, etaMin, etaMax,0.,1.2); mCHFracVSeta_highPt= dbe->bookProfile("CHFracVSeta_highPt","CHFracVSeta_highPt",etaBin, etaMin, etaMax,0.,1.2); mNHFracVSeta_highPt= dbe->bookProfile("NHFracVSeta_highPt","NHFracVSeta_highPt",etaBin, etaMin, etaMax,0.,1.2); mPhFracVSeta_highPt= dbe->bookProfile("PhFracVSeta_highPt","PhFracVSeta_highPt",etaBin, etaMin, etaMax,0.,1.2); mElFracVSeta_highPt= dbe->bookProfile("ElFracVSeta_highPt","ElFracVSeta_highPt",etaBin, etaMin, etaMax,0.,1.2); mMuFracVSeta_highPt= dbe->bookProfile("MuFracVSeta_highPt","MuFracVSeta_highPt",etaBin, etaMin, etaMax,0.,1.2); //mPt_Barrel_Lo = dbe->book1D("Pt_Barrel_Lo", "Pt Barrel (Pass Low Pt Jet Trigger)", 20, 0, 100); //mPhi_Barrel_Lo = dbe->book1D("Phi_Barrel_Lo", "Phi Barrel (Pass Low Pt Jet Trigger)", phiBin, phiMin, phiMax); mConstituents_Barrel = dbe->book1D("Constituents_Barrel", "Constituents Barrel", 50, 0, 100); mHFrac_Barrel = dbe->book1D("HFrac_Barrel", "HFrac Barrel", 100, 0, 1); mEFrac_Barrel = dbe->book1D("EFrac_Barrel", "EFrac Barrel", 110, -0.05, 1.05); //mPt_EndCap_Lo = dbe->book1D("Pt_EndCap_Lo", "Pt EndCap (Pass Low Pt Jet Trigger)", 20, 0, 100); //mPhi_EndCap_Lo = dbe->book1D("Phi_EndCap_Lo", "Phi EndCap (Pass Low Pt Jet Trigger)", phiBin, phiMin, phiMax); mConstituents_EndCap = dbe->book1D("Constituents_EndCap", "Constituents EndCap", 50, 0, 100); mHFrac_EndCap = dbe->book1D("HFrac_Endcap", "HFrac EndCap", 100, 0, 1); mEFrac_EndCap = dbe->book1D("EFrac_Endcap", "EFrac EndCap", 110, -0.05, 1.05); //mPt_Forward_Lo = dbe->book1D("Pt_Forward_Lo", "Pt Forward (Pass Low Pt Jet Trigger)", 20, 0, 100); //mPhi_Forward_Lo = dbe->book1D("Phi_Forward_Lo", "Phi Forward (Pass Low Pt Jet Trigger)", phiBin, phiMin, phiMax); mConstituents_Forward = dbe->book1D("Constituents_Forward", "Constituents Forward", 50, 0, 100); mHFrac_Forward = dbe->book1D("HFrac_Forward", "HFrac Forward", 100, 0, 1); mEFrac_Forward = dbe->book1D("EFrac_Forward", "EFrac Forward", 110, -0.05, 1.05); mPt_Barrel_Hi = dbe->book1D("Pt_Barrel_Hi", "Pt Barrel (Pass Hi Pt Jet Trigger)", 60, 0, 300); mPhi_Barrel_Hi = dbe->book1D("Phi_Barrel_Hi", "Phi Barrel (Pass Hi Pt Jet Trigger)", phiBin, phiMin, phiMax); //mConstituents_Barrel_Hi = dbe->book1D("Constituents_Barrel_Hi", "Constituents Barrel (Pass Hi Pt Jet Trigger)", 50, 0, 100); //mHFrac_Barrel_Hi = dbe->book1D("HFrac_Barrel_Hi", "HFrac Barrel (Pass Hi Pt Jet Trigger)", 100, 0, 1); mPt_EndCap_Hi = dbe->book1D("Pt_EndCap_Hi", "Pt EndCap (Pass Hi Pt Jet Trigger)", 60, 0, 300); mPhi_EndCap_Hi = dbe->book1D("Phi_EndCap_Hi", "Phi EndCap (Pass Hi Pt Jet Trigger)", phiBin, phiMin, phiMax); //mConstituents_EndCap_Hi = dbe->book1D("Constituents_EndCap_Hi", "Constituents EndCap (Pass Hi Pt Jet Trigger)", 50, 0, 100); //mHFrac_EndCap_Hi = dbe->book1D("HFrac_EndCap_Hi", "HFrac EndCap (Pass Hi Pt Jet Trigger)", 100, 0, 1); mPt_Forward_Hi = dbe->book1D("Pt_Forward_Hi", "Pt Forward (Pass Hi Pt Jet Trigger)", 60, 0, 300); mPhi_Forward_Hi = dbe->book1D("Phi_Forward_Hi", "Phi Forward (Pass Hi Pt Jet Trigger)", phiBin, phiMin, phiMax); //mConstituents_Forward_Hi = dbe->book1D("Constituents_Forward_Hi", "Constituents Forward (Pass Hi Pt Jet Trigger)", 50, 0, 100); //mHFrac_Forward_Hi = dbe->book1D("HFrac_Forward_Hi", "HFrac Forward (Pass Hi Pt Jet Trigger)", 100, 0, 1); mPhi_Barrel = dbe->book1D("Phi_Barrel", "Phi_Barrel", phiBin, phiMin, phiMax); //mE_Barrel = dbe->book1D("E_Barrel", "E_Barrel", eBin, eMin, eMax); mPt_Barrel = dbe->book1D("Pt_Barrel", "Pt_Barrel", ptBin, ptMin, ptMax); // energy fractions mCHFrac_lowPt_Barrel = dbe->book1D("CHFrac_lowPt_Barrel", "CHFrac_lowPt_Barrel", 120, -0.1, 1.1); mNHFrac_lowPt_Barrel = dbe->book1D("NHFrac_lowPt_Barrel", "NHFrac_lowPt_Barrel", 120, -0.1, 1.1); mPhFrac_lowPt_Barrel = dbe->book1D("PhFrac_lowPt_Barrel", "PhFrac_lowPt_Barrel", 120, -0.1, 1.1); mElFrac_lowPt_Barrel = dbe->book1D("ElFrac_lowPt_Barrel", "ElFrac_lowPt_Barrel", 120, -0.1, 1.1); mMuFrac_lowPt_Barrel = dbe->book1D("MuFrac_lowPt_Barrel", "MuFrac_lowPt_Barrel", 120, -0.1, 1.1); mCHFrac_mediumPt_Barrel = dbe->book1D("CHFrac_mediumPt_Barrel", "CHFrac_mediumPt_Barrel", 120, -0.1, 1.1); mNHFrac_mediumPt_Barrel = dbe->book1D("NHFrac_mediumPt_Barrel", "NHFrac_mediumPt_Barrel", 120, -0.1, 1.1); mPhFrac_mediumPt_Barrel = dbe->book1D("PhFrac_mediumPt_Barrel", "PhFrac_mediumPt_Barrel", 120, -0.1, 1.1); mElFrac_mediumPt_Barrel = dbe->book1D("ElFrac_mediumPt_Barrel", "ElFrac_mediumPt_Barrel", 120, -0.1, 1.1); mMuFrac_mediumPt_Barrel = dbe->book1D("MuFrac_mediumPt_Barrel", "MuFrac_mediumPt_Barrel", 120, -0.1, 1.1); mCHFrac_highPt_Barrel = dbe->book1D("CHFrac_highPt_Barrel", "CHFrac_highPt_Barrel", 120, -0.1, 1.1); mNHFrac_highPt_Barrel = dbe->book1D("NHFrac_highPt_Barrel", "NHFrac_highPt_Barrel", 120, -0.1, 1.1); mPhFrac_highPt_Barrel = dbe->book1D("PhFrac_highPt_Barrel", "PhFrac_highPt_Barrel", 120, -0.1, 1.1); mElFrac_highPt_Barrel = dbe->book1D("ElFrac_highPt_Barrel", "ElFrac_highPt_Barrel", 120, -0.1, 1.1); mMuFrac_highPt_Barrel = dbe->book1D("MuFrac_highPt_Barrel", "MuFrac_highPt_Barrel", 120, -0.1, 1.1); //energies mCHEn_lowPt_Barrel = dbe->book1D("CHEn_lowPt_Barrel", "CHEn_lowPt_Barrel", ptBin, ptMin, ptMax); mNHEn_lowPt_Barrel = dbe->book1D("NHEn_lowPt_Barrel", "NHEn_lowPt_Barrel", ptBin, ptMin, ptMax); mPhEn_lowPt_Barrel = dbe->book1D("PhEn_lowPt_Barrel", "PhEn_lowPt_Barrel", ptBin, ptMin, ptMax); mElEn_lowPt_Barrel = dbe->book1D("ElEn_lowPt_Barrel", "ElEn_lowPt_Barrel", ptBin, ptMin, ptMax); mMuEn_lowPt_Barrel = dbe->book1D("MuEn_lowPt_Barrel", "MuEn_lowPt_Barrel", ptBin, ptMin, ptMax); mCHEn_mediumPt_Barrel = dbe->book1D("CHEn_mediumPt_Barrel", "CHEn_mediumPt_Barrel", ptBin, ptMin, ptMax); mNHEn_mediumPt_Barrel = dbe->book1D("NHEn_mediumPt_Barrel", "NHEn_mediumPt_Barrel", ptBin, ptMin, ptMax); mPhEn_mediumPt_Barrel = dbe->book1D("PhEn_mediumPt_Barrel", "PhEn_mediumPt_Barrel", ptBin, ptMin, ptMax); mElEn_mediumPt_Barrel = dbe->book1D("ElEn_mediumPt_Barrel", "ElEn_mediumPt_Barrel", ptBin, ptMin, ptMax); mMuEn_mediumPt_Barrel = dbe->book1D("MuEn_mediumPt_Barrel", "MuEn_mediumPt_Barrel", ptBin, ptMin, ptMax); mCHEn_highPt_Barrel = dbe->book1D("CHEn_highPt_Barrel", "CHEn_highPt_Barrel", ptBin, ptMin, ptMax); mNHEn_highPt_Barrel = dbe->book1D("NHEn_highPt_Barrel", "NHEn_highPt_Barrel", ptBin, ptMin, ptMax); mPhEn_highPt_Barrel = dbe->book1D("PhEn_highPt_Barrel", "PhEn_highPt_Barrel", ptBin, ptMin, ptMax); mElEn_highPt_Barrel = dbe->book1D("ElEn_highPt_Barrel", "ElEn_highPt_Barrel", ptBin, ptMin, ptMax); mMuEn_highPt_Barrel = dbe->book1D("MuEn_highPt_Barrel", "MuEn_highPt_Barrel", ptBin, ptMin, ptMax); //multiplicities mChMultiplicity_lowPt_Barrel = dbe->book1D("ChMultiplicity_lowPt_Barrel", "ChMultiplicity_lowPt_Barrel", 30,0,30); mNeuMultiplicity_lowPt_Barrel = dbe->book1D("NeuMultiplicity_lowPt_Barrel", "NeuMultiplicity_lowPt_Barrel", 30,0,30); mMuMultiplicity_lowPt_Barrel = dbe->book1D("MuMultiplicity_lowPt_Barrel", "MuMultiplicity_lowPt_Barrel", 30,0,30); mChMultiplicity_mediumPt_Barrel = dbe->book1D("ChMultiplicity_mediumPt_Barrel", "ChMultiplicity_mediumPt_Barrel", 30,0,30); mNeuMultiplicity_mediumPt_Barrel = dbe->book1D("NeuMultiplicity_mediumPt_Barrel", "NeuMultiplicity_mediumPt_Barrel", 30,0,30); mMuMultiplicity_mediumPt_Barrel = dbe->book1D("MuMultiplicity_mediumPt_Barrel", "MuMultiplicity_mediumPt_Barrel", 30,0,30); mChMultiplicity_highPt_Barrel = dbe->book1D("ChMultiplicity_highPt_Barrel", "ChMultiplicity_highPt_Barrel", 30,0,30); mNeuMultiplicity_highPt_Barrel = dbe->book1D("NeuMultiplicity_highPt_Barrel", "NeuMultiplicity_highPt_Barrel", 30,0,30); mMuMultiplicity_highPt_Barrel = dbe->book1D("MuMultiplicity_highPt_Barrel", "MuMultiplicity_highPt_Barrel", 30,0,30); // mCHFracVSpT_Barrel= dbe->bookProfile("CHFracVSpT_Barrel","CHFracVSpT_Barrel",ptBin, ptMin, ptMax,0.,1.2); mNHFracVSpT_Barrel= dbe->bookProfile("NHFracVSpT_Barrel","NHFracVSpT_Barrel",ptBin, ptMin, ptMax,0.,1.2); mPhFracVSpT_Barrel= dbe->bookProfile("PhFracVSpT_Barrel","PhFracVSpT_Barrel",ptBin, ptMin, ptMax,0.,1.2); mElFracVSpT_Barrel= dbe->bookProfile("ElFracVSpT_Barrel","ElFracVSpT_Barrel",ptBin, ptMin, ptMax,0.,1.2); mMuFracVSpT_Barrel= dbe->bookProfile("MuFracVSpT_Barrel","MuFracVSpT_Barrel",ptBin, ptMin, ptMax,0.,1.2); mCHFracVSpT_EndCap= dbe->bookProfile("CHFracVSpT_EndCap","CHFracVSpT_EndCap",ptBin, ptMin, ptMax,0.,1.2); mNHFracVSpT_EndCap= dbe->bookProfile("NHFracVSpT_EndCap","NHFracVSpT_EndCap",ptBin, ptMin, ptMax,0.,1.2); mPhFracVSpT_EndCap= dbe->bookProfile("PhFracVSpT_EndCap","PhFracVSpT_EndCap",ptBin, ptMin, ptMax,0.,1.2); mElFracVSpT_EndCap= dbe->bookProfile("ElFracVSpT_EndCap","ElFracVSpT_EndCap",ptBin, ptMin, ptMax,0.,1.2); mMuFracVSpT_EndCap= dbe->bookProfile("MuFracVSpT_EndCap","MuFracVSpT_EndCap",ptBin, ptMin, ptMax,0.,1.2); mHFHFracVSpT_Forward= dbe->bookProfile("HFHFracVSpT_Forward","HFHFracVSpT_Forward",ptBin, ptMin, ptMax,0.,1.2); mHFEFracVSpT_Forward= dbe->bookProfile("HFEFracVSpT_Forward","HFEFracVSpT_Forward",ptBin, ptMin, ptMax,0.,1.2); mPhi_EndCap = dbe->book1D("Phi_EndCap", "Phi_EndCap", phiBin, phiMin, phiMax); //mE_EndCap = dbe->book1D("E_EndCap", "E_EndCap", eBin, eMin, eMax); mPt_EndCap = dbe->book1D("Pt_EndCap", "Pt_EndCap", ptBin, ptMin, ptMax); //energy fractions mCHFrac_lowPt_EndCap = dbe->book1D("CHFrac_lowPt_EndCap", "CHFrac_lowPt_EndCap", 120, -0.1, 1.1); mNHFrac_lowPt_EndCap = dbe->book1D("NHFrac_lowPt_EndCap", "NHFrac_lowPt_EndCap", 120, -0.1, 1.1); mPhFrac_lowPt_EndCap = dbe->book1D("PhFrac_lowPt_EndCap", "PhFrac_lowPt_EndCap", 120, -0.1, 1.1); mElFrac_lowPt_EndCap = dbe->book1D("ElFrac_lowPt_EndCap", "ElFrac_lowPt_EndCap", 120, -0.1, 1.1); mMuFrac_lowPt_EndCap = dbe->book1D("MuFrac_lowPt_EndCap", "MuFrac_lowPt_EndCap", 120, -0.1, 1.1); mCHFrac_mediumPt_EndCap = dbe->book1D("CHFrac_mediumPt_EndCap", "CHFrac_mediumPt_EndCap", 120, -0.1, 1.1); mNHFrac_mediumPt_EndCap = dbe->book1D("NHFrac_mediumPt_EndCap", "NHFrac_mediumPt_EndCap", 120, -0.1, 1.1); mPhFrac_mediumPt_EndCap = dbe->book1D("PhFrac_mediumPt_EndCap", "PhFrac_mediumPt_EndCap", 120, -0.1, 1.1); mElFrac_mediumPt_EndCap = dbe->book1D("ElFrac_mediumPt_EndCap", "ElFrac_mediumPt_EndCap", 120, -0.1, 1.1); mMuFrac_mediumPt_EndCap = dbe->book1D("MuFrac_mediumPt_EndCap", "MuFrac_mediumPt_EndCap", 120, -0.1, 1.1); mCHFrac_highPt_EndCap = dbe->book1D("CHFrac_highPt_EndCap", "CHFrac_highPt_EndCap", 120, -0.1, 1.1); mNHFrac_highPt_EndCap = dbe->book1D("NHFrac_highPt_EndCap", "NHFrac_highPt_EndCap", 120, -0.1, 1.1); mPhFrac_highPt_EndCap = dbe->book1D("PhFrac_highPt_EndCap", "PhFrac_highPt_EndCap", 120, -0.1, 1.1); mElFrac_highPt_EndCap = dbe->book1D("ElFrac_highPt_EndCap", "ElFrac_highPt_EndCap", 120, -0.1, 1.1); mMuFrac_highPt_EndCap = dbe->book1D("MuFrac_highPt_EndCap", "MuFrac_highPt_EndCap", 120, -0.1, 1.1); //energies mCHEn_lowPt_EndCap = dbe->book1D("CHEn_lowPt_EndCap", "CHEn_lowPt_EndCap", ptBin, ptMin, ptMax); mNHEn_lowPt_EndCap = dbe->book1D("NHEn_lowPt_EndCap", "NHEn_lowPt_EndCap", ptBin, ptMin, ptMax); mPhEn_lowPt_EndCap = dbe->book1D("PhEn_lowPt_EndCap", "PhEn_lowPt_EndCap", ptBin, ptMin, ptMax); mElEn_lowPt_EndCap = dbe->book1D("ElEn_lowPt_EndCap", "ElEn_lowPt_EndCap", ptBin, ptMin, ptMax); mMuEn_lowPt_EndCap = dbe->book1D("MuEn_lowPt_EndCap", "MuEn_lowPt_EndCap", ptBin, ptMin, ptMax); mCHEn_mediumPt_EndCap = dbe->book1D("CHEn_mediumPt_EndCap", "CHEn_mediumPt_EndCap", ptBin, ptMin, ptMax); mNHEn_mediumPt_EndCap = dbe->book1D("NHEn_mediumPt_EndCap", "NHEn_mediumPt_EndCap", ptBin, ptMin, ptMax); mPhEn_mediumPt_EndCap = dbe->book1D("PhEn_mediumPt_EndCap", "PhEn_mediumPt_EndCap", ptBin, ptMin, ptMax); mElEn_mediumPt_EndCap = dbe->book1D("ElEn_mediumPt_EndCap", "ElEn_mediumPt_EndCap", ptBin, ptMin, ptMax); mMuEn_mediumPt_EndCap = dbe->book1D("MuEn_mediumPt_EndCap", "MuEn_mediumPt_EndCap", ptBin, ptMin, ptMax); mCHEn_highPt_EndCap = dbe->book1D("CHEn_highPt_EndCap", "CHEn_highPt_EndCap", ptBin, ptMin, ptMax); mNHEn_highPt_EndCap = dbe->book1D("NHEn_highPt_EndCap", "NHEn_highPt_EndCap", ptBin, ptMin, ptMax); mPhEn_highPt_EndCap = dbe->book1D("PhEn_highPt_EndCap", "PhEn_highPt_EndCap", ptBin, ptMin, ptMax); mElEn_highPt_EndCap = dbe->book1D("ElEn_highPt_EndCap", "ElEn_highPt_EndCap", ptBin, ptMin, ptMax); mMuEn_highPt_EndCap = dbe->book1D("MuEn_highPt_EndCap", "MuEn_highPt_EndCap", ptBin, ptMin, ptMax); //multiplicities mChMultiplicity_lowPt_EndCap = dbe->book1D("ChMultiplicity_lowPt_EndCap", "ChMultiplicity_lowPt_EndCap", 30,0,30); mNeuMultiplicity_lowPt_EndCap = dbe->book1D("NeuMultiplicity_lowPt_EndCap", "NeuMultiplicity_lowPt_EndCap", 30,0,30); mMuMultiplicity_lowPt_EndCap = dbe->book1D("MuMultiplicity_lowPt_EndCap", "MuMultiplicity_lowPt_EndCap", 30,0,30); mChMultiplicity_mediumPt_EndCap = dbe->book1D("ChMultiplicity_mediumPt_EndCap", "ChMultiplicity_mediumPt_EndCap", 30,0,30); mNeuMultiplicity_mediumPt_EndCap = dbe->book1D("NeuMultiplicity_mediumPt_EndCap", "NeuMultiplicity_mediumPt_EndCap", 30,0,30); mMuMultiplicity_mediumPt_EndCap = dbe->book1D("MuMultiplicity_mediumPt_EndCap", "MuMultiplicity_mediumPt_EndCap", 30,0,30); mChMultiplicity_highPt_EndCap = dbe->book1D("ChMultiplicity_highPt_EndCap", "ChMultiplicity_highPt_EndCap", 30,0,30); mNeuMultiplicity_highPt_EndCap = dbe->book1D("NeuMultiplicity_highPt_EndCap", "NeuMultiplicity_highPt_EndCap", 30,0,30); mMuMultiplicity_highPt_EndCap = dbe->book1D("MuMultiplicity_highPt_EndCap", "MuMultiplicity_highPt_EndCap", 30,0,30); mPhi_Forward = dbe->book1D("Phi_Forward", "Phi_Forward", phiBin, phiMin, phiMax); //mE_Forward = dbe->book1D("E_Forward", "E_Forward", eBin, eMin, eMax); mPt_Forward = dbe->book1D("Pt_Forward", "Pt_Forward", ptBin, ptMin, ptMax); //energy fraction mHFEFrac_lowPt_Forward = dbe->book1D("HFEFrac_lowPt_Forward", "HFEFrac_lowPt_Forward", 120, -0.1, 1.1); mHFHFrac_lowPt_Forward = dbe->book1D("HFHFrac_lowPt_Forward", "HFHFrac_lowPt_Forward", 120, -0.1, 1.1); mHFEFrac_mediumPt_Forward = dbe->book1D("HFEFrac_mediumPt_Forward", "HFEFrac_mediumPt_Forward", 120, -0.1, 1.1); mHFHFrac_mediumPt_Forward = dbe->book1D("HFHFrac_mediumPt_Forward", "HFHFrac_mediumPt_Forward", 120, -0.1, 1.1); mHFEFrac_highPt_Forward = dbe->book1D("HFEFrac_highPt_Forward", "HFEFrac_highPt_Forward", 120, -0.1, 1.1); mHFHFrac_highPt_Forward = dbe->book1D("HFHFrac_highPt_Forward", "HFHFrac_highPt_Forward", 120, -0.1, 1.1); //energies mHFEEn_lowPt_Forward = dbe->book1D("HFEEn_lowPt_Forward", "HFEEn_lowPt_Forward", ptBin, ptMin, ptMax); mHFHEn_lowPt_Forward = dbe->book1D("HFHEn_lowPt_Forward", "HFHEn_lowPt_Forward", ptBin, ptMin, ptMax); mHFEEn_mediumPt_Forward = dbe->book1D("HFEEn_mediumPt_Forward", "HFEEn_mediumPt_Forward", ptBin, ptMin, ptMax); mHFHEn_mediumPt_Forward = dbe->book1D("HFHEn_mediumPt_Forward", "HFHEn_mediumPt_Forward", ptBin, ptMin, ptMax); mHFEEn_highPt_Forward = dbe->book1D("HFEEn_highPt_Forward", "HFEEn_highPt_Forward", ptBin, ptMin, ptMax); mHFHEn_highPt_Forward = dbe->book1D("HFHEn_highPt_Forward", "HFHEn_highPt_Forward", ptBin, ptMin, ptMax); //multiplicities mChMultiplicity_lowPt_Forward = dbe->book1D("ChMultiplicity_lowPt_Forward", "ChMultiplicity_lowPt_Forward", 30,0,30); mNeuMultiplicity_lowPt_Forward = dbe->book1D("NeuMultiplicity_lowPt_Forward", "NeuMultiplicity_lowPt_Forward", 30,0,30); mMuMultiplicity_lowPt_Forward = dbe->book1D("MuMultiplicity_lowPt_Forward", "MuMultiplicity_lowPt_Forward", 30,0,30); mChMultiplicity_mediumPt_Forward = dbe->book1D("ChMultiplicity_mediumPt_Forward", "ChMultiplicity_mediumPt_Forward", 30,0,30); mNeuMultiplicity_mediumPt_Forward = dbe->book1D("NeuMultiplicity_mediumPt_Forward", "NeuMultiplicity_mediumPt_Forward", 30,0,30); mMuMultiplicity_mediumPt_Forward = dbe->book1D("MuMultiplicity_mediumPt_Forward", "MuMultiplicity_mediumPt_Forward", 30,0,30); mChMultiplicity_highPt_Forward = dbe->book1D("ChMultiplicity_highPt_Forward", "ChMultiplicity_highPt_Forward", 30,0,30); mNeuMultiplicity_highPt_Forward = dbe->book1D("NeuMultiplicity_highPt_Forward", "NeuMultiplicity_highPt_Forward", 30,0,30); mMuMultiplicity_highPt_Forward = dbe->book1D("MuMultiplicity_highPt_Forward", "MuMultiplicity_highPt_Forward", 30,0,30); // Leading Jet Parameters mEtaFirst = dbe->book1D("EtaFirst", "EtaFirst", 100, -5, 5); mPhiFirst = dbe->book1D("PhiFirst", "PhiFirst", 70, -3.5, 3.5); //mEFirst = dbe->book1D("EFirst", "EFirst", 100, 0, 1000); mPtFirst = dbe->book1D("PtFirst", "PtFirst", 100, 0, 500); if(fillpfJIDPassFrac==1) { mLooseJIDPassFractionVSeta= dbe->bookProfile("LooseJIDPassFractionVSeta","LooseJIDPassFractionVSeta",etaBin, etaMin, etaMax,0.,1.2); mLooseJIDPassFractionVSpt= dbe->bookProfile("LooseJIDPassFractionVSpt","LooseJIDPassFractionVSpt",ptBin, ptMin, ptMax,0.,1.2); mTightJIDPassFractionVSeta= dbe->bookProfile("TightJIDPassFractionVSeta","TightJIDPassFractionVSeta",etaBin, etaMin, etaMax,0.,1.2); mTightJIDPassFractionVSpt= dbe->bookProfile("TightJIDPassFractionVSpt","TightJIDPassFractionVSpt",ptBin, ptMin, ptMax,0.,1.2); } } mChargedHadronEnergy = dbe->book1D("mChargedHadronEnergy", "charged HAD energy", 100, 0, 100); mNeutralHadronEnergy = dbe->book1D("mNeutralHadronEnergy", "neutral HAD energy", 100, 0, 100); mChargedEmEnergy = dbe->book1D("mChargedEmEnergy ", "charged EM energy ", 100, 0, 100); mChargedMuEnergy = dbe->book1D("mChargedMuEnergy", "charged Mu energy", 100, 0, 100); mNeutralEmEnergy = dbe->book1D("mNeutralEmEnergy", "neutral EM energy", 100, 0, 100); mChargedMultiplicity = dbe->book1D("mChargedMultiplicity", "charged multiplicity ", 100, 0, 100); mNeutralMultiplicity = dbe->book1D("mNeutralMultiplicity", "neutral multiplicity", 100, 0, 100); mMuonMultiplicity = dbe->book1D("mMuonMultiplicity", "muon multiplicity", 100, 0, 100); // Book NPV profiles //---------------------------------------------------------------------------- mChargedHadronEnergy_profile = dbe->bookProfile("mChargedHadronEnergy_profile", "charged HAD energy", nbinsPV, PVlow, PVup, 100, 0, 100); mNeutralHadronEnergy_profile = dbe->bookProfile("mNeutralHadronEnergy_profile", "neutral HAD energy", nbinsPV, PVlow, PVup, 100, 0, 100); mChargedEmEnergy_profile = dbe->bookProfile("mChargedEmEnergy_profile", "charged EM energy", nbinsPV, PVlow, PVup, 100, 0, 100); mChargedMuEnergy_profile = dbe->bookProfile("mChargedMuEnergy_profile", "charged Mu energy", nbinsPV, PVlow, PVup, 100, 0, 100); mNeutralEmEnergy_profile = dbe->bookProfile("mNeutralEmEnergy_profile", "neutral EM energy", nbinsPV, PVlow, PVup, 100, 0, 100); mChargedMultiplicity_profile = dbe->bookProfile("mChargedMultiplicity_profile", "charged multiplicity", nbinsPV, PVlow, PVup, 100, 0, 100); mNeutralMultiplicity_profile = dbe->bookProfile("mNeutralMultiplicity_profile", "neutral multiplicity", nbinsPV, PVlow, PVup, 100, 0, 100); mMuonMultiplicity_profile = dbe->bookProfile("mMuonMultiplicity_profile", "muon multiplicity", nbinsPV, PVlow, PVup, 100, 0, 100); if (makedijetselection != 1) { mNJets_profile = dbe->bookProfile("NJets_profile", "number of jets", nbinsPV, PVlow, PVup, 100, 0, 100); } // Set NPV profiles x-axis title //---------------------------------------------------------------------------- mChargedHadronEnergy_profile->setAxisTitle("nvtx",1); mNeutralHadronEnergy_profile->setAxisTitle("nvtx",1); mChargedEmEnergy_profile ->setAxisTitle("nvtx",1); mChargedMuEnergy_profile ->setAxisTitle("nvtx",1); mNeutralEmEnergy_profile ->setAxisTitle("nvtx",1); mChargedMultiplicity_profile->setAxisTitle("nvtx",1); mNeutralMultiplicity_profile->setAxisTitle("nvtx",1); mMuonMultiplicity_profile ->setAxisTitle("nvtx",1); if (makedijetselection != 1) { mNJets_profile->setAxisTitle("nvtx",1); } //__________________________________________________ mNeutralFraction = dbe->book1D("NeutralFraction","Neutral Fraction",100,0,1); //} mDPhi = dbe->book1D("DPhi", "dPhi btw the two leading jets", 100, 0., acos(-1.)); if(makedijetselection==1) { mDijetAsymmetry = dbe->book1D("DijetAsymmetry", "DijetAsymmetry", 100, -1., 1.); mDijetBalance = dbe->book1D("DijetBalance", "DijetBalance", 100, -2., 2.); if (fillpfJIDPassFrac==1) { mLooseJIDPassFractionVSeta = dbe->bookProfile("LooseJIDPassFractionVSeta","LooseJIDPassFractionVSeta",50, -3., 3.,0.,1.2); mLooseJIDPassFractionVSpt = dbe->bookProfile("LooseJIDPassFractionVSpt","LooseJIDPassFractionVSpt",ptBin, ptMin, ptMax,0.,1.2); mTightJIDPassFractionVSeta = dbe->bookProfile("TightJIDPassFractionVSeta","TightJIDPassFractionVSeta",50, -3., 3.,0.,1.2); mTightJIDPassFractionVSpt = dbe->bookProfile("TightJIDPassFractionVSpt","TightJIDPassFractionVSpt",ptBin, ptMin, ptMax,0.,1.2); } } }
void PFJetAnalyzer::endJob | ( | void | ) |
int PFJetAnalyzer::getLeadJetFlag | ( | ) | [inline] |
void PFJetAnalyzer::setJetHiPass | ( | int | pass | ) | [inline] |
void PFJetAnalyzer::setJetLoPass | ( | int | pass | ) | [inline] |
void PFJetAnalyzer::setLeadJetFlag | ( | int | flag | ) | [inline] |
void PFJetAnalyzer::setSource | ( | std::string | source | ) | [inline] |
Definition at line 50 of file PFJetAnalyzer.h.
References _source, and LaserTracksInput_cfi::source.
double PFJetAnalyzer::_asymmetryThirdJetCut [private] |
Definition at line 76 of file PFJetAnalyzer.h.
double PFJetAnalyzer::_balanceThirdJetCut [private] |
Definition at line 77 of file PFJetAnalyzer.h.
int PFJetAnalyzer::_JetHiPass [private] |
Definition at line 72 of file PFJetAnalyzer.h.
Referenced by setJetHiPass().
int PFJetAnalyzer::_JetLoPass [private] |
Definition at line 71 of file PFJetAnalyzer.h.
Referenced by setJetLoPass().
int PFJetAnalyzer::_leadJetFlag [private] |
Definition at line 73 of file PFJetAnalyzer.h.
Referenced by getLeadJetFlag(), and setLeadJetFlag().
double PFJetAnalyzer::_LooseCEFMax [private] |
Definition at line 110 of file PFJetAnalyzer.h.
double PFJetAnalyzer::_LooseCHFMin [private] |
Definition at line 108 of file PFJetAnalyzer.h.
double PFJetAnalyzer::_LooseNEFMax [private] |
Definition at line 111 of file PFJetAnalyzer.h.
double PFJetAnalyzer::_LooseNHFMax [private] |
Definition at line 109 of file PFJetAnalyzer.h.
double PFJetAnalyzer::_ptThreshold [private] |
Definition at line 74 of file PFJetAnalyzer.h.
std::string PFJetAnalyzer::_source [private] |
Definition at line 125 of file PFJetAnalyzer.h.
Referenced by setSource().
double PFJetAnalyzer::_ThisCEFMax [private] |
Definition at line 106 of file PFJetAnalyzer.h.
double PFJetAnalyzer::_ThisCHFMin [private] |
Definition at line 104 of file PFJetAnalyzer.h.
double PFJetAnalyzer::_ThisNEFMax [private] |
Definition at line 107 of file PFJetAnalyzer.h.
double PFJetAnalyzer::_ThisNHFMax [private] |
Definition at line 105 of file PFJetAnalyzer.h.
double PFJetAnalyzer::_TightCEFMax [private] |
Definition at line 114 of file PFJetAnalyzer.h.
double PFJetAnalyzer::_TightCHFMin [private] |
Definition at line 112 of file PFJetAnalyzer.h.
double PFJetAnalyzer::_TightNEFMax [private] |
Definition at line 115 of file PFJetAnalyzer.h.
double PFJetAnalyzer::_TightNHFMax [private] |
Definition at line 113 of file PFJetAnalyzer.h.
int PFJetAnalyzer::eBin [private] |
Definition at line 94 of file PFJetAnalyzer.h.
double PFJetAnalyzer::eMax [private] |
Definition at line 96 of file PFJetAnalyzer.h.
double PFJetAnalyzer::eMin [private] |
Definition at line 95 of file PFJetAnalyzer.h.
int PFJetAnalyzer::etaBin [private] |
Definition at line 82 of file PFJetAnalyzer.h.
double PFJetAnalyzer::etaMax [private] |
Definition at line 84 of file PFJetAnalyzer.h.
double PFJetAnalyzer::etaMin [private] |
Definition at line 83 of file PFJetAnalyzer.h.
int PFJetAnalyzer::fillpfJIDPassFrac [private] |
Definition at line 102 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::jetME [private] |
Definition at line 118 of file PFJetAnalyzer.h.
int PFJetAnalyzer::makedijetselection [private] |
Definition at line 79 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mChargedEmEnergy [private] |
Definition at line 354 of file PFJetAnalyzer.h.
Definition at line 394 of file PFJetAnalyzer.h.
Definition at line 352 of file PFJetAnalyzer.h.
Definition at line 392 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mChargedMuEnergy [private] |
Definition at line 355 of file PFJetAnalyzer.h.
Definition at line 395 of file PFJetAnalyzer.h.
Definition at line 357 of file PFJetAnalyzer.h.
Definition at line 397 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mCHEn_highPt_Barrel [private] |
Definition at line 180 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mCHEn_highPt_EndCap [private] |
Definition at line 250 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mCHEn_lowPt_Barrel [private] |
Definition at line 170 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mCHEn_lowPt_EndCap [private] |
Definition at line 240 of file PFJetAnalyzer.h.
Definition at line 175 of file PFJetAnalyzer.h.
Definition at line 245 of file PFJetAnalyzer.h.
Definition at line 165 of file PFJetAnalyzer.h.
Definition at line 234 of file PFJetAnalyzer.h.
Definition at line 155 of file PFJetAnalyzer.h.
Definition at line 224 of file PFJetAnalyzer.h.
Definition at line 160 of file PFJetAnalyzer.h.
Definition at line 229 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mCHFracVSeta_highPt [private] |
Definition at line 218 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mCHFracVSeta_lowPt [private] |
Definition at line 208 of file PFJetAnalyzer.h.
Definition at line 213 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mCHFracVSpT_Barrel [private] |
Definition at line 195 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mCHFracVSpT_EndCap [private] |
Definition at line 200 of file PFJetAnalyzer.h.
Definition at line 191 of file PFJetAnalyzer.h.
Definition at line 262 of file PFJetAnalyzer.h.
Definition at line 291 of file PFJetAnalyzer.h.
Definition at line 185 of file PFJetAnalyzer.h.
Definition at line 256 of file PFJetAnalyzer.h.
Definition at line 285 of file PFJetAnalyzer.h.
Definition at line 188 of file PFJetAnalyzer.h.
Definition at line 259 of file PFJetAnalyzer.h.
Definition at line 288 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mConstituents [private] |
Definition at line 147 of file PFJetAnalyzer.h.
Definition at line 297 of file PFJetAnalyzer.h.
Definition at line 313 of file PFJetAnalyzer.h.
Definition at line 302 of file PFJetAnalyzer.h.
Definition at line 317 of file PFJetAnalyzer.h.
Definition at line 307 of file PFJetAnalyzer.h.
Definition at line 321 of file PFJetAnalyzer.h.
Definition at line 388 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mDijetAsymmetry [private] |
Definition at line 379 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mDijetBalance [private] |
Definition at line 378 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mDPhi [private] |
Definition at line 334 of file PFJetAnalyzer.h.
Definition at line 367 of file PFJetAnalyzer.h.
Definition at line 366 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mEFrac [private] |
Definition at line 149 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mEFrac_Barrel [private] |
Definition at line 299 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mEFrac_EndCap [private] |
Definition at line 304 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mEFrac_Forward [private] |
Definition at line 309 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mEFrac_profile [private] |
Definition at line 390 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mElEn_highPt_Barrel [private] |
Definition at line 183 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mElEn_highPt_EndCap [private] |
Definition at line 253 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mElEn_lowPt_Barrel [private] |
Definition at line 173 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mElEn_lowPt_EndCap [private] |
Definition at line 243 of file PFJetAnalyzer.h.
Definition at line 178 of file PFJetAnalyzer.h.
Definition at line 248 of file PFJetAnalyzer.h.
Definition at line 168 of file PFJetAnalyzer.h.
Definition at line 237 of file PFJetAnalyzer.h.
Definition at line 158 of file PFJetAnalyzer.h.
Definition at line 227 of file PFJetAnalyzer.h.
Definition at line 163 of file PFJetAnalyzer.h.
Definition at line 232 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mElFracVSeta_highPt [private] |
Definition at line 221 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mElFracVSeta_lowPt [private] |
Definition at line 211 of file PFJetAnalyzer.h.
Definition at line 216 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mElFracVSpT_Barrel [private] |
Definition at line 198 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mElFracVSpT_EndCap [private] |
Definition at line 203 of file PFJetAnalyzer.h.
Definition at line 369 of file PFJetAnalyzer.h.
Definition at line 368 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mEta [private] |
Definition at line 145 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mEta_Hi [private] |
Definition at line 347 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mEta_profile [private] |
Definition at line 386 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mEtaFirst [private] |
Definition at line 337 of file PFJetAnalyzer.h.
std::string PFJetAnalyzer::metname [private] |
Definition at line 122 of file PFJetAnalyzer.h.
Definition at line 283 of file PFJetAnalyzer.h.
Definition at line 279 of file PFJetAnalyzer.h.
Definition at line 281 of file PFJetAnalyzer.h.
Definition at line 277 of file PFJetAnalyzer.h.
Definition at line 273 of file PFJetAnalyzer.h.
Definition at line 275 of file PFJetAnalyzer.h.
Definition at line 206 of file PFJetAnalyzer.h.
Definition at line 284 of file PFJetAnalyzer.h.
Definition at line 280 of file PFJetAnalyzer.h.
Definition at line 282 of file PFJetAnalyzer.h.
Definition at line 278 of file PFJetAnalyzer.h.
Definition at line 274 of file PFJetAnalyzer.h.
Definition at line 276 of file PFJetAnalyzer.h.
Definition at line 205 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mHFrac [private] |
Definition at line 148 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mHFrac_Barrel [private] |
Definition at line 298 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mHFrac_Barrel_Hi [private] |
Definition at line 314 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mHFrac_EndCap [private] |
Definition at line 303 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mHFrac_EndCap_Hi [private] |
Definition at line 318 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mHFrac_Forward [private] |
Definition at line 308 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mHFrac_Forward_Hi [private] |
Definition at line 322 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mHFrac_profile [private] |
Definition at line 389 of file PFJetAnalyzer.h.
Definition at line 372 of file PFJetAnalyzer.h.
Definition at line 373 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mMuEn_highPt_Barrel [private] |
Definition at line 184 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mMuEn_highPt_EndCap [private] |
Definition at line 254 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mMuEn_lowPt_Barrel [private] |
Definition at line 174 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mMuEn_lowPt_EndCap [private] |
Definition at line 244 of file PFJetAnalyzer.h.
Definition at line 179 of file PFJetAnalyzer.h.
Definition at line 249 of file PFJetAnalyzer.h.
Definition at line 169 of file PFJetAnalyzer.h.
Definition at line 238 of file PFJetAnalyzer.h.
Definition at line 159 of file PFJetAnalyzer.h.
Definition at line 228 of file PFJetAnalyzer.h.
Definition at line 164 of file PFJetAnalyzer.h.
Definition at line 233 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mMuFracVSeta_highPt [private] |
Definition at line 222 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mMuFracVSeta_lowPt [private] |
Definition at line 212 of file PFJetAnalyzer.h.
Definition at line 217 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mMuFracVSpT_Barrel [private] |
Definition at line 199 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mMuFracVSpT_EndCap [private] |
Definition at line 204 of file PFJetAnalyzer.h.
Definition at line 193 of file PFJetAnalyzer.h.
Definition at line 264 of file PFJetAnalyzer.h.
Definition at line 293 of file PFJetAnalyzer.h.
Definition at line 187 of file PFJetAnalyzer.h.
Definition at line 258 of file PFJetAnalyzer.h.
Definition at line 287 of file PFJetAnalyzer.h.
Definition at line 190 of file PFJetAnalyzer.h.
Definition at line 261 of file PFJetAnalyzer.h.
Definition at line 290 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mMuonMultiplicity [private] |
Definition at line 359 of file PFJetAnalyzer.h.
Definition at line 399 of file PFJetAnalyzer.h.
Definition at line 192 of file PFJetAnalyzer.h.
Definition at line 263 of file PFJetAnalyzer.h.
Definition at line 292 of file PFJetAnalyzer.h.
Definition at line 186 of file PFJetAnalyzer.h.
Definition at line 257 of file PFJetAnalyzer.h.
Definition at line 286 of file PFJetAnalyzer.h.
Definition at line 189 of file PFJetAnalyzer.h.
Definition at line 260 of file PFJetAnalyzer.h.
Definition at line 289 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNeutralEmEnergy [private] |
Definition at line 356 of file PFJetAnalyzer.h.
Definition at line 396 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNeutralFraction [private] |
Definition at line 363 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNeutralFraction2 [private] |
Definition at line 364 of file PFJetAnalyzer.h.
Definition at line 353 of file PFJetAnalyzer.h.
Definition at line 393 of file PFJetAnalyzer.h.
Definition at line 358 of file PFJetAnalyzer.h.
Definition at line 398 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNHEn_highPt_Barrel [private] |
Definition at line 181 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNHEn_highPt_EndCap [private] |
Definition at line 251 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNHEn_lowPt_Barrel [private] |
Definition at line 171 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNHEn_lowPt_EndCap [private] |
Definition at line 241 of file PFJetAnalyzer.h.
Definition at line 176 of file PFJetAnalyzer.h.
Definition at line 246 of file PFJetAnalyzer.h.
Definition at line 166 of file PFJetAnalyzer.h.
Definition at line 235 of file PFJetAnalyzer.h.
Definition at line 156 of file PFJetAnalyzer.h.
Definition at line 225 of file PFJetAnalyzer.h.
Definition at line 161 of file PFJetAnalyzer.h.
Definition at line 230 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNHFracVSeta_highPt [private] |
Definition at line 219 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNHFracVSeta_lowPt [private] |
Definition at line 209 of file PFJetAnalyzer.h.
Definition at line 214 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNHFracVSpT_Barrel [private] |
Definition at line 196 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNHFracVSpT_EndCap [private] |
Definition at line 201 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNJets [private] |
Definition at line 333 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mNJets_profile [private] |
Definition at line 384 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhEn_highPt_Barrel [private] |
Definition at line 182 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhEn_highPt_EndCap [private] |
Definition at line 252 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhEn_lowPt_Barrel [private] |
Definition at line 172 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhEn_lowPt_EndCap [private] |
Definition at line 242 of file PFJetAnalyzer.h.
Definition at line 177 of file PFJetAnalyzer.h.
Definition at line 247 of file PFJetAnalyzer.h.
Definition at line 167 of file PFJetAnalyzer.h.
Definition at line 236 of file PFJetAnalyzer.h.
Definition at line 157 of file PFJetAnalyzer.h.
Definition at line 226 of file PFJetAnalyzer.h.
Definition at line 162 of file PFJetAnalyzer.h.
Definition at line 231 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhFracVSeta_highPt [private] |
Definition at line 220 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhFracVSeta_lowPt [private] |
Definition at line 210 of file PFJetAnalyzer.h.
Definition at line 215 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhFracVSpT_Barrel [private] |
Definition at line 197 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhFracVSpT_EndCap [private] |
Definition at line 202 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhi [private] |
Definition at line 146 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhi_Barrel [private] |
Definition at line 153 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhi_Barrel_Hi [private] |
Definition at line 312 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhi_EndCap [private] |
Definition at line 268 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhi_EndCap_Hi [private] |
Definition at line 316 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhi_Forward [private] |
Definition at line 271 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhi_Forward_Hi [private] |
Definition at line 320 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhi_Hi [private] |
Definition at line 348 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhi_Lo [private] |
Definition at line 344 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhi_profile [private] |
Definition at line 387 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhiFirst [private] |
Definition at line 338 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPhiVSEta [private] |
Definition at line 150 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt [private] |
Definition at line 141 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt_1 [private] |
Definition at line 142 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt_2 [private] |
Definition at line 143 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt_3 [private] |
Definition at line 144 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt_Barrel [private] |
Definition at line 152 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt_Barrel_Hi [private] |
Definition at line 311 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt_EndCap [private] |
Definition at line 267 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt_EndCap_Hi [private] |
Definition at line 315 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt_Forward [private] |
Definition at line 270 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt_Forward_Hi [private] |
Definition at line 319 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt_Hi [private] |
Definition at line 349 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt_Lo [private] |
Definition at line 345 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPt_profile [private] |
Definition at line 385 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::mPtFirst [private] |
Definition at line 340 of file PFJetAnalyzer.h.
Definition at line 374 of file PFJetAnalyzer.h.
Definition at line 375 of file PFJetAnalyzer.h.
MonitorElement* PFJetAnalyzer::nEEff [private] |
Definition at line 370 of file PFJetAnalyzer.h.
edm::ParameterSet PFJetAnalyzer::parameters [private] |
Definition at line 120 of file PFJetAnalyzer.h.
int PFJetAnalyzer::pBin [private] |
Definition at line 98 of file PFJetAnalyzer.h.
int PFJetAnalyzer::phiBin [private] |
Definition at line 86 of file PFJetAnalyzer.h.
double PFJetAnalyzer::phiMax [private] |
Definition at line 88 of file PFJetAnalyzer.h.
double PFJetAnalyzer::phiMin [private] |
Definition at line 87 of file PFJetAnalyzer.h.
double PFJetAnalyzer::pMax [private] |
Definition at line 100 of file PFJetAnalyzer.h.
double PFJetAnalyzer::pMin [private] |
Definition at line 99 of file PFJetAnalyzer.h.
int PFJetAnalyzer::ptBin [private] |
Definition at line 90 of file PFJetAnalyzer.h.
double PFJetAnalyzer::ptMax [private] |
Definition at line 92 of file PFJetAnalyzer.h.
double PFJetAnalyzer::ptMin [private] |
Definition at line 91 of file PFJetAnalyzer.h.
Definition at line 124 of file PFJetAnalyzer.h.