#include <EGammaMvaEleEstimator.h>

Public Types
enum	MVAType { kTrig = 0, kTrigNoIP = 1, kNonTrig = 2, kIsoRings, kTrigIDIsoCombined, kTrigIDIsoCombinedPUCorrected }

Public Member Functions
void	bindVariables ()

	EGammaMvaEleEstimator ()

UInt_t	GetMVABin (double eta, double pt) const

Double_t	IDIsoCombinedMvaValue (const reco::GsfElectron &ele, const reco::Vertex &vertex, const TransientTrackBuilder &transientTrackBuilder, EcalClusterLazyTools const &myEcalCluster, const reco::PFCandidateCollection &PFCandidates, double Rho, ElectronEffectiveArea::ElectronEffectiveAreaTarget EATarget, bool printDebug=kFALSE)

Double_t	IDIsoCombinedMvaValue (Double_t fbrem, Double_t kfchi2, Int_t kfhits, Double_t gsfchi2, Double_t deta, Double_t dphi, Double_t detacalo, Double_t see, Double_t spp, Double_t etawidth, Double_t phiwidth, Double_t OneMinusE1x5E5x5, Double_t R9, Double_t HoE, Double_t EoP, Double_t IoEmIoP, Double_t eleEoPout, Double_t PreShowerOverRaw, Double_t d0, Double_t ip3d, Double_t ChargedIso_DR0p0To0p1, Double_t ChargedIso_DR0p1To0p2, Double_t ChargedIso_DR0p2To0p3, Double_t ChargedIso_DR0p3To0p4, Double_t ChargedIso_DR0p4To0p5, Double_t GammaIso_DR0p0To0p1, Double_t GammaIso_DR0p1To0p2, Double_t GammaIso_DR0p2To0p3, Double_t GammaIso_DR0p3To0p4, Double_t GammaIso_DR0p4To0p5, Double_t NeutralHadronIso_DR0p0To0p1, Double_t NeutralHadronIso_DR0p1To0p2, Double_t NeutralHadronIso_DR0p2To0p3, Double_t NeutralHadronIso_DR0p3To0p4, Double_t NeutralHadronIso_DR0p4To0p5, Double_t Rho, Double_t eta, Double_t pt, Bool_t printDebug=kFALSE)

void	initialize (std::string methodName, EGammaMvaEleEstimator::MVAType type, Bool_t useBinnedVersion, std::vector< std::string > weightsfiles)

void	initialize (std::string methodName, std::string weightsfile, EGammaMvaEleEstimator::MVAType type)

Bool_t	isInitialized () const

Double_t	isoMvaValue (const reco::GsfElectron &ele, const reco::Vertex &vertex, const reco::PFCandidateCollection &PFCandidates, double Rho, ElectronEffectiveArea::ElectronEffectiveAreaTarget EATarget, const reco::GsfElectronCollection &IdentifiedElectrons, const reco::MuonCollection &IdentifiedMuons, bool printDebug=kFALSE)

Double_t	isoMvaValue (Double_t Pt, Double_t Eta, Double_t Rho, ElectronEffectiveArea::ElectronEffectiveAreaTarget EATarget, Double_t ChargedIso_DR0p0To0p1, Double_t ChargedIso_DR0p1To0p2, Double_t ChargedIso_DR0p2To0p3, Double_t ChargedIso_DR0p3To0p4, Double_t ChargedIso_DR0p4To0p5, Double_t GammaIso_DR0p0To0p1, Double_t GammaIso_DR0p1To0p2, Double_t GammaIso_DR0p2To0p3, Double_t GammaIso_DR0p3To0p4, Double_t GammaIso_DR0p4To0p5, Double_t NeutralHadronIso_DR0p0To0p1, Double_t NeutralHadronIso_DR0p1To0p2, Double_t NeutralHadronIso_DR0p2To0p3, Double_t NeutralHadronIso_DR0p3To0p4, Double_t NeutralHadronIso_DR0p4To0p5, Bool_t printDebug=kFALSE)

Double_t	mvaValue (const pat::Electron &ele, const reco::Vertex &vertex, double rho, bool useFull5x5=kFALSE, bool printDebug=kFALSE)

Double_t	mvaValue (const pat::Electron &ele, double rho, bool printDebug=kFALSE)

Double_t	mvaValue (const reco::GsfElectron &ele, const reco::Vertex &vertex, const TransientTrackBuilder &transientTrackBuilder, EcalClusterLazyTools const &myEcalCluster, bool printDebug=kFALSE)

Double_t	mvaValue (const reco::GsfElectron &ele, const reco::Vertex &vertex, double rho, EcalClusterLazyTools const &myEcalCluster, bool printDebug=kFALSE)

Double_t	mvaValue (Double_t fbrem, Double_t kfchi2, Int_t kfhits, Double_t gsfchi2, Double_t deta, Double_t dphi, Double_t detacalo, Double_t see, Double_t spp, Double_t etawidth, Double_t phiwidth, Double_t e1x5e5x5, Double_t R9, Double_t HoE, Double_t EoP, Double_t IoEmIoP, Double_t eleEoPout, Double_t PreShowerOverRaw, Double_t d0, Double_t ip3d, Double_t eta, Double_t pt, Bool_t printDebug=kFALSE)

Double_t	mvaValue (Double_t fbrem, Double_t kfchi2, Int_t kfhits, Double_t gsfchi2, Double_t deta, Double_t dphi, Double_t detacalo, Double_t see, Double_t spp, Double_t etawidth, Double_t phiwidth, Double_t e1x5e5x5, Double_t R9, Double_t HoE, Double_t EoP, Double_t IoEmIoP, Double_t eleEoPout, Double_t PreShowerOverRaw, Double_t eta, Double_t pt, Bool_t printDebug=kFALSE)

Double_t	mvaValue (Double_t fbrem, Double_t kfchi2, Int_t kfhits, Double_t gsfchi2, Double_t deta, Double_t dphi, Double_t detacalo, Double_t see, Double_t spp, Double_t etawidth, Double_t phiwidth, Double_t e1x5e5x5, Double_t R9, Double_t HoE, Double_t EoP, Double_t IoEmIoP, Double_t eleEoPout, Double_t rho, Double_t PreShowerOverRaw, Double_t eta, Double_t pt, Bool_t printDebug=kFALSE)

	~EGammaMvaEleEstimator ()

Private Attributes
Bool_t	fisInitialized

std::string	fMethodname

MVAType	fMVAType

Float_t	fMVAVar_ChargedIso_DR0p0To0p1

Float_t	fMVAVar_ChargedIso_DR0p1To0p2

Float_t	fMVAVar_ChargedIso_DR0p2To0p3

Float_t	fMVAVar_ChargedIso_DR0p3To0p4

Float_t	fMVAVar_ChargedIso_DR0p4To0p5

Float_t	fMVAVar_d0

Float_t	fMVAVar_deta

Float_t	fMVAVar_detacalo

Float_t	fMVAVar_dphi

Float_t	fMVAVar_eleEoPout

Float_t	fMVAVar_EoP

Float_t	fMVAVar_EoPout

Float_t	fMVAVar_eta

Float_t	fMVAVar_etawidth

Float_t	fMVAVar_fbrem

Float_t	fMVAVar_GammaIso_DR0p0To0p1

Float_t	fMVAVar_GammaIso_DR0p1To0p2

Float_t	fMVAVar_GammaIso_DR0p2To0p3

Float_t	fMVAVar_GammaIso_DR0p3To0p4

Float_t	fMVAVar_GammaIso_DR0p4To0p5

Float_t	fMVAVar_gsfchi2

Float_t	fMVAVar_HoE

Float_t	fMVAVar_IoEmIoP

Float_t	fMVAVar_ip3d

Float_t	fMVAVar_ip3dSig

Float_t	fMVAVar_kfchi2

Float_t	fMVAVar_kfhits

Float_t	fMVAVar_kfhitsall

Float_t	fMVAVar_NeutralHadronIso_DR0p0To0p1

Float_t	fMVAVar_NeutralHadronIso_DR0p1To0p2

Float_t	fMVAVar_NeutralHadronIso_DR0p2To0p3

Float_t	fMVAVar_NeutralHadronIso_DR0p3To0p4

Float_t	fMVAVar_NeutralHadronIso_DR0p4To0p5

Float_t	fMVAVar_OneMinusE1x5E5x5

Float_t	fMVAVar_phiwidth

Float_t	fMVAVar_PreShowerOverRaw

Float_t	fMVAVar_pt

Float_t	fMVAVar_R9

Float_t	fMVAVar_rho

Float_t	fMVAVar_see

Float_t	fMVAVar_spp

UInt_t	fNMVABins

std::vector< TMVA::MethodBase * >	fTMVAMethod

std::vector< TMVA::Reader * >	fTMVAReader

Bool_t	fUseBinnedVersion

Detailed Description

--> NOTE if you want to use this class as standalone without the CMSSW part you need to uncomment the below line and compile normally with scramv1 b Then you need just to load it in your root macro the lib with the correct path, eg: gSystem->Load("/data/benedet/CMSSW_5_2_2/lib/slc5_amd64_gcc462/pluginEGammaEGammaAnalysisTools.so");

Definition at line 38 of file EGammaMvaEleEstimator.h.

Member Enumeration Documentation

◆ MVAType

enum EGammaMvaEleEstimator::MVAType

Enumerator
kTrig
kTrigNoIP
kNonTrig
kIsoRings
kTrigIDIsoCombined
kTrigIDIsoCombinedPUCorrected

Definition at line 43 of file EGammaMvaEleEstimator.h.

                {
     kTrig = 0,                     // MVA for triggering electrons
     kTrigNoIP = 1,                 // MVA for triggering electrons without IP info
     kNonTrig = 2,                  // MVA for non-triggering electrons
     kIsoRings,                     // Isolation MVA for non-trigger electrons
     kTrigIDIsoCombined,            // ID+Iso Combined MVA for triggering electrons
     kTrigIDIsoCombinedPUCorrected  // ID+Iso Combined MVA for triggering electrons
   };

Constructor & Destructor Documentation

◆ EGammaMvaEleEstimator()

EGammaMvaEleEstimator::EGammaMvaEleEstimator ( )

Definition at line 28 of file EGammaMvaEleEstimator.cc.

     : fMethodname("BDTG method"), fisInitialized(kFALSE), fMVAType(kTrig), fUseBinnedVersion(kTRUE), fNMVABins(0) {
   // Constructor.
 }

◆ ~EGammaMvaEleEstimator()

EGammaMvaEleEstimator::~EGammaMvaEleEstimator ( )

Definition at line 34 of file EGammaMvaEleEstimator.cc.

                                               {
   for (unsigned int i = 0; i < fTMVAReader.size(); ++i) {
     if (fTMVAReader[i])
       delete fTMVAReader[i];
   }
 }

References fTMVAReader, and mps_fire::i.

Member Function Documentation

◆ bindVariables()

void EGammaMvaEleEstimator::bindVariables ( )

Definition at line 1929 of file EGammaMvaEleEstimator.cc.

                                           {
   // this binding is needed for variables that sometime diverge.
  
   if (fMVAVar_fbrem < -1.)
     fMVAVar_fbrem = -1.;
  
   fMVAVar_deta = fabs(fMVAVar_deta);
   if (fMVAVar_deta > 0.06)
     fMVAVar_deta = 0.06;
  
   fMVAVar_dphi = fabs(fMVAVar_dphi);
   if (fMVAVar_dphi > 0.6)
     fMVAVar_dphi = 0.6;
  
   if (fMVAVar_EoP > 20.)
     fMVAVar_EoP = 20.;
  
   if (fMVAVar_eleEoPout > 20.)
     fMVAVar_eleEoPout = 20.;
  
   fMVAVar_detacalo = fabs(fMVAVar_detacalo);
   if (fMVAVar_detacalo > 0.2)
     fMVAVar_detacalo = 0.2;
  
   if (fMVAVar_OneMinusE1x5E5x5 < -1.)
     fMVAVar_OneMinusE1x5E5x5 = -1;
  
   if (fMVAVar_OneMinusE1x5E5x5 > 2.)
     fMVAVar_OneMinusE1x5E5x5 = 2.;
  
   if (fMVAVar_R9 > 5)
     fMVAVar_R9 = 5;
  
   if (fMVAVar_gsfchi2 > 200.)
     fMVAVar_gsfchi2 = 200;
  
   if (fMVAVar_kfchi2 > 10.)
     fMVAVar_kfchi2 = 10.;
  
     // Needed for a bug in CMSSW_420, fixed in more recent CMSSW versions
 #ifndef STANDALONE
   if (edm::isNotFinite(fMVAVar_spp))
 #else
   if (std::isnan(fMVAVar_spp))
 #endif
     fMVAVar_spp = 0.;
  
   return;
 }

References fMVAVar_deta, fMVAVar_detacalo, fMVAVar_dphi, fMVAVar_eleEoPout, fMVAVar_EoP, fMVAVar_fbrem, fMVAVar_gsfchi2, fMVAVar_kfchi2, fMVAVar_OneMinusE1x5E5x5, fMVAVar_R9, fMVAVar_spp, CommonMethods::isnan(), and edm::isNotFinite().

Referenced by isoMvaValue(), and mvaValue().

◆ GetMVABin()

UInt_t EGammaMvaEleEstimator::GetMVABin	(	double	eta,
		double	pt
	)		const

Definition at line 399 of file EGammaMvaEleEstimator.cc.

                                                                    {
   //Default is to return the first bin
   unsigned int bin = 0;
  
   if (fMVAType == EGammaMvaEleEstimator::kIsoRings) {
     if (pt < 10 && fabs(eta) < 1.479)
       bin = 0;
     if (pt < 10 && fabs(eta) >= 1.479)
       bin = 1;
     if (pt >= 10 && fabs(eta) < 1.479)
       bin = 2;
     if (pt >= 10 && fabs(eta) >= 1.479)
       bin = 3;
   }
  
   if (fMVAType == EGammaMvaEleEstimator::kNonTrig) {
     bin = 0;
     if (pt < 10 && fabs(eta) < 0.8)
       bin = 0;
     if (pt < 10 && fabs(eta) >= 0.8 && fabs(eta) < 1.479)
       bin = 1;
     if (pt < 10 && fabs(eta) >= 1.479)
       bin = 2;
     if (pt >= 10 && fabs(eta) < 0.8)
       bin = 3;
     if (pt >= 10 && fabs(eta) >= 0.8 && fabs(eta) < 1.479)
       bin = 4;
     if (pt >= 10 && fabs(eta) >= 1.479)
       bin = 5;
   }
  
   if (fMVAType == EGammaMvaEleEstimator::kTrig || fMVAType == EGammaMvaEleEstimator::kTrigIDIsoCombined ||
       fMVAType == EGammaMvaEleEstimator::kTrigIDIsoCombinedPUCorrected ||
       fMVAType == EGammaMvaEleEstimator::kTrigNoIP) {
     bin = 0;
     if (pt < 20 && fabs(eta) < 0.8)
       bin = 0;
     if (pt < 20 && fabs(eta) >= 0.8 && fabs(eta) < 1.479)
       bin = 1;
     if (pt < 20 && fabs(eta) >= 1.479)
       bin = 2;
     if (pt >= 20 && fabs(eta) < 0.8)
       bin = 3;
     if (pt >= 20 && fabs(eta) >= 0.8 && fabs(eta) < 1.479)
       bin = 4;
     if (pt >= 20 && fabs(eta) >= 1.479)
       bin = 5;
   }
  
   return bin;
 }

References newFWLiteAna::bin, PVValHelper::eta, fMVAType, kIsoRings, kNonTrig, kTrig, kTrigIDIsoCombined, kTrigIDIsoCombinedPUCorrected, kTrigNoIP, and DiDispStaMuonMonitor_cfi::pt.

Referenced by IDIsoCombinedMvaValue(), isoMvaValue(), and mvaValue().

◆ IDIsoCombinedMvaValue() [1/2]

Double_t EGammaMvaEleEstimator::IDIsoCombinedMvaValue	(	const reco::GsfElectron &	ele,
		const reco::Vertex &	vertex,
		const TransientTrackBuilder &	transientTrackBuilder,
		EcalClusterLazyTools const &	myEcalCluster,
		const reco::PFCandidateCollection &	PFCandidates,
		double	Rho,
		ElectronEffectiveArea::ElectronEffectiveAreaTarget	EATarget,
		bool	printDebug = `kFALSE`
	)

Definition at line 1619 of file EGammaMvaEleEstimator.cc.

                                                                        {
   if (!fisInitialized) {
     std::cout << "Error: EGammaMvaEleEstimator not properly initialized.\n";
     return -9999;
   }
  
   bool validKF = false;
   reco::TrackRef myTrackRef = ele.closestCtfTrackRef();
   validKF = (myTrackRef.isAvailable());
   validKF &= (myTrackRef.isNonnull());
  
   // Pure tracking variables
   fMVAVar_fbrem = (ele.fbrem() < -1.) ? -1. : ele.fbrem();
   fMVAVar_kfchi2 = (validKF) ? myTrackRef->normalizedChi2() : 0;
   if (fMVAVar_kfchi2 > 10)
     fMVAVar_kfchi2 = 10;
   fMVAVar_kfhits = (validKF) ? myTrackRef->hitPattern().trackerLayersWithMeasurement() : -1.;
   fMVAVar_kfhitsall =
       (validKF) ? myTrackRef->numberOfValidHits() : -1.;  //  save also this in your ntuple as possible alternative
   fMVAVar_gsfchi2 = ele.gsfTrack()->normalizedChi2();
   if (fMVAVar_gsfchi2 > 200)
     fMVAVar_gsfchi2 = 200;
  
   // Geometrical matchings
   fMVAVar_deta =
       (fabs(ele.deltaEtaSuperClusterTrackAtVtx()) > 0.06) ? 0.06 : fabs(ele.deltaEtaSuperClusterTrackAtVtx());
   fMVAVar_dphi = ele.deltaPhiSuperClusterTrackAtVtx();
   fMVAVar_detacalo = ele.deltaEtaSeedClusterTrackAtCalo();
  
   // Pure ECAL -> shower shapes
   fMVAVar_see = ele.sigmaIetaIeta();  //EleSigmaIEtaIEta
   const auto& vCov = myEcalCluster.localCovariances(*(ele.superCluster()->seed()));
   if (edm::isFinite(vCov[2]))
     fMVAVar_spp = sqrt(vCov[2]);  //EleSigmaIPhiIPhi
   else
     fMVAVar_spp = 0.;
  
   fMVAVar_etawidth = ele.superCluster()->etaWidth();
   fMVAVar_phiwidth = ele.superCluster()->phiWidth();
   fMVAVar_OneMinusE1x5E5x5 = (ele.e5x5()) != 0. ? 1. - (ele.e1x5() / ele.e5x5()) : -1.;
   fMVAVar_OneMinusE1x5E5x5 = std::max(std::min(double(fMVAVar_OneMinusE1x5E5x5), 2.0), -1.0);
   fMVAVar_R9 = myEcalCluster.e3x3(*(ele.superCluster()->seed())) / ele.superCluster()->rawEnergy();
   if (fMVAVar_R9 > 5)
     fMVAVar_R9 = 5;
  
   // Energy matching
   fMVAVar_HoE = ele.hadronicOverEm();
   fMVAVar_EoP = (ele.eSuperClusterOverP() > 20) ? 20 : ele.eSuperClusterOverP();
   fMVAVar_IoEmIoP =
       (1.0 / ele.superCluster()->energy()) - (1.0 / ele.trackMomentumAtVtx().R());  //this is the proper variable
   fMVAVar_eleEoPout = (ele.eEleClusterOverPout() > 20) ? 20 : ele.eEleClusterOverPout();
   fMVAVar_PreShowerOverRaw = ele.superCluster()->preshowerEnergy() / ele.superCluster()->rawEnergy();
  
   // Spectators
   fMVAVar_eta = ele.superCluster()->eta();
   fMVAVar_pt = ele.pt();
  
   // for triggering electrons get the impact parameteres
   if (fMVAType == kTrig) {
     //d0
     if (ele.gsfTrack().isNonnull()) {
       fMVAVar_d0 = (-1.0) * ele.gsfTrack()->dxy(vertex.position());
     } else if (ele.closestCtfTrackRef().isNonnull()) {
       fMVAVar_d0 = (-1.0) * ele.closestCtfTrackRef()->dxy(vertex.position());
     } else {
       fMVAVar_d0 = -9999.0;
     }
  
     //default values for IP3D
     fMVAVar_ip3d = -999.0;
     fMVAVar_ip3dSig = 0.0;
     if (ele.gsfTrack().isNonnull()) {
       const double gsfsign = ((-ele.gsfTrack()->dxy(vertex.position())) >= 0) ? 1. : -1.;
  
       const reco::TransientTrack& tt = transientTrackBuilder.build(ele.gsfTrack());
       const std::pair<bool, Measurement1D>& ip3dpv = IPTools::absoluteImpactParameter3D(tt, vertex);
       if (ip3dpv.first) {
         double ip3d = gsfsign * ip3dpv.second.value();
         double ip3derr = ip3dpv.second.error();
         fMVAVar_ip3d = ip3d;
         fMVAVar_ip3dSig = ip3d / ip3derr;
       }
     }
   }
  
   //**********************************************************
   //Isolation variables
   //**********************************************************
   Double_t tmpChargedIso_DR0p0To0p1 = 0;
   Double_t tmpChargedIso_DR0p1To0p2 = 0;
   Double_t tmpChargedIso_DR0p2To0p3 = 0;
   Double_t tmpChargedIso_DR0p3To0p4 = 0;
   Double_t tmpChargedIso_DR0p4To0p5 = 0;
   Double_t tmpGammaIso_DR0p0To0p1 = 0;
   Double_t tmpGammaIso_DR0p1To0p2 = 0;
   Double_t tmpGammaIso_DR0p2To0p3 = 0;
   Double_t tmpGammaIso_DR0p3To0p4 = 0;
   Double_t tmpGammaIso_DR0p4To0p5 = 0;
   Double_t tmpNeutralHadronIso_DR0p0To0p1 = 0;
   Double_t tmpNeutralHadronIso_DR0p1To0p2 = 0;
   Double_t tmpNeutralHadronIso_DR0p2To0p3 = 0;
   Double_t tmpNeutralHadronIso_DR0p3To0p4 = 0;
   Double_t tmpNeutralHadronIso_DR0p4To0p5 = 0;
  
   for (reco::PFCandidateCollection::const_iterator iP = PFCandidates.begin(); iP != PFCandidates.end(); ++iP) {
     double dr = sqrt(pow(iP->eta() - ele.eta(), 2) + pow(acos(cos(iP->phi() - ele.phi())), 2));
  
     Bool_t passVeto = kTRUE;
     //Charged
     if (iP->trackRef().isNonnull()) {
       //make sure charged pf candidates pass the PFNoPU condition (assumed)
  
       //************************************************************
       // Veto any PFmuon, or PFEle
       if (iP->particleId() == reco::PFCandidate::e || iP->particleId() == reco::PFCandidate::mu)
         passVeto = kFALSE;
       //************************************************************
       //************************************************************
       // Footprint Veto
       if (fabs(fMVAVar_eta) > 1.479 && dr < 0.015)
         passVeto = kFALSE;
       //************************************************************
       if (passVeto) {
         if (dr < 0.1)
           tmpChargedIso_DR0p0To0p1 += iP->pt();
         if (dr >= 0.1 && dr < 0.2)
           tmpChargedIso_DR0p1To0p2 += iP->pt();
         if (dr >= 0.2 && dr < 0.3)
           tmpChargedIso_DR0p2To0p3 += iP->pt();
         if (dr >= 0.3 && dr < 0.4)
           tmpChargedIso_DR0p3To0p4 += iP->pt();
         if (dr >= 0.4 && dr < 0.5)
           tmpChargedIso_DR0p4To0p5 += iP->pt();
       }  //pass veto
     }
     //Gamma
     else if (iP->particleId() == reco::PFCandidate::gamma) {
       //************************************************************
       // Footprint Veto
       if (fabs(fMVAVar_eta) > 1.479 && dr < 0.08)
         passVeto = kFALSE;
       //************************************************************
       if (passVeto) {
         if (dr < 0.1)
           tmpGammaIso_DR0p0To0p1 += iP->pt();
         if (dr >= 0.1 && dr < 0.2)
           tmpGammaIso_DR0p1To0p2 += iP->pt();
         if (dr >= 0.2 && dr < 0.3)
           tmpGammaIso_DR0p2To0p3 += iP->pt();
         if (dr >= 0.3 && dr < 0.4)
           tmpGammaIso_DR0p3To0p4 += iP->pt();
         if (dr >= 0.4 && dr < 0.5)
           tmpGammaIso_DR0p4To0p5 += iP->pt();
       }
     }
     //NeutralHadron
     else {
       if (dr < 0.1)
         tmpNeutralHadronIso_DR0p0To0p1 += iP->pt();
       if (dr >= 0.1 && dr < 0.2)
         tmpNeutralHadronIso_DR0p1To0p2 += iP->pt();
       if (dr >= 0.2 && dr < 0.3)
         tmpNeutralHadronIso_DR0p2To0p3 += iP->pt();
       if (dr >= 0.3 && dr < 0.4)
         tmpNeutralHadronIso_DR0p3To0p4 += iP->pt();
       if (dr >= 0.4 && dr < 0.5)
         tmpNeutralHadronIso_DR0p4To0p5 += iP->pt();
     }
   }  //loop over PF candidates
  
   if (fMVAType == kTrigIDIsoCombinedPUCorrected) {
     fMVAVar_ChargedIso_DR0p0To0p1 = TMath::Min((tmpChargedIso_DR0p0To0p1) / ele.pt(), 2.5);
     fMVAVar_ChargedIso_DR0p1To0p2 = TMath::Min((tmpChargedIso_DR0p1To0p2) / ele.pt(), 2.5);
     fMVAVar_ChargedIso_DR0p2To0p3 = TMath::Min((tmpChargedIso_DR0p2To0p3) / ele.pt(), 2.5);
     fMVAVar_ChargedIso_DR0p3To0p4 = TMath::Min((tmpChargedIso_DR0p3To0p4) / ele.pt(), 2.5);
     fMVAVar_ChargedIso_DR0p4To0p5 = TMath::Min((tmpChargedIso_DR0p4To0p5) / ele.pt(), 2.5);
     fMVAVar_GammaIso_DR0p0To0p1 = TMath::Max(
         TMath::Min(
             (tmpGammaIso_DR0p0To0p1 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                                 ElectronEffectiveArea::kEleGammaIsoDR0p0To0p1, fMVAVar_eta, EATarget)) /
                 ele.pt(),
             2.5),
         0.0);
     fMVAVar_GammaIso_DR0p1To0p2 = TMath::Max(
         TMath::Min(
             (tmpGammaIso_DR0p1To0p2 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                                 ElectronEffectiveArea::kEleGammaIsoDR0p1To0p2, fMVAVar_eta, EATarget)) /
                 ele.pt(),
             2.5),
         0.0);
     fMVAVar_GammaIso_DR0p2To0p3 = TMath::Max(
         TMath::Min(
             (tmpGammaIso_DR0p2To0p3 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                                 ElectronEffectiveArea::kEleGammaIsoDR0p2To0p3, fMVAVar_eta, EATarget)) /
                 ele.pt(),
             2.5),
         0.0);
     fMVAVar_GammaIso_DR0p3To0p4 = TMath::Max(
         TMath::Min(
             (tmpGammaIso_DR0p3To0p4 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                                 ElectronEffectiveArea::kEleGammaIsoDR0p3To0p4, fMVAVar_eta, EATarget)) /
                 ele.pt(),
             2.5),
         0.0);
     fMVAVar_GammaIso_DR0p4To0p5 = TMath::Max(
         TMath::Min(
             (tmpGammaIso_DR0p4To0p5 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                                 ElectronEffectiveArea::kEleGammaIsoDR0p4To0p5, fMVAVar_eta, EATarget)) /
                 ele.pt(),
             2.5),
         0.0);
     fMVAVar_NeutralHadronIso_DR0p0To0p1 = TMath::Max(
         TMath::Min((tmpNeutralHadronIso_DR0p0To0p1 -
                     Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                               ElectronEffectiveArea::kEleNeutralHadronIsoDR0p0To0p1, fMVAVar_eta, EATarget)) /
                        ele.pt(),
                    2.5),
         0.0);
     fMVAVar_NeutralHadronIso_DR0p1To0p2 = TMath::Max(
         TMath::Min((tmpNeutralHadronIso_DR0p1To0p2 -
                     Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                               ElectronEffectiveArea::kEleNeutralHadronIsoDR0p1To0p2, fMVAVar_eta, EATarget)) /
                        ele.pt(),
                    2.5),
         0.0);
     fMVAVar_NeutralHadronIso_DR0p2To0p3 = TMath::Max(
         TMath::Min((tmpNeutralHadronIso_DR0p2To0p3 -
                     Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                               ElectronEffectiveArea::kEleNeutralHadronIsoDR0p2To0p3, fMVAVar_eta, EATarget)) /
                        ele.pt(),
                    2.5),
         0.0);
     fMVAVar_NeutralHadronIso_DR0p3To0p4 = TMath::Max(
         TMath::Min((tmpNeutralHadronIso_DR0p3To0p4 -
                     Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                               ElectronEffectiveArea::kEleNeutralHadronIsoDR0p3To0p4, fMVAVar_eta, EATarget)) /
                        ele.pt(),
                    2.5),
         0.0);
     fMVAVar_NeutralHadronIso_DR0p4To0p5 = TMath::Max(
         TMath::Min((tmpNeutralHadronIso_DR0p4To0p5 -
                     Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                               ElectronEffectiveArea::kEleNeutralHadronIsoDR0p4To0p5, fMVAVar_eta, EATarget)) /
                        ele.pt(),
                    2.5),
         0.0);
   } else if (fMVAType == kTrigIDIsoCombined) {
     fMVAVar_ChargedIso_DR0p0To0p1 = TMath::Min((tmpChargedIso_DR0p0To0p1) / ele.pt(), 2.5);
     fMVAVar_ChargedIso_DR0p1To0p2 = TMath::Min((tmpChargedIso_DR0p1To0p2) / ele.pt(), 2.5);
     fMVAVar_ChargedIso_DR0p2To0p3 = TMath::Min((tmpChargedIso_DR0p2To0p3) / ele.pt(), 2.5);
     fMVAVar_ChargedIso_DR0p3To0p4 = TMath::Min((tmpChargedIso_DR0p3To0p4) / ele.pt(), 2.5);
     fMVAVar_ChargedIso_DR0p4To0p5 = TMath::Min((tmpChargedIso_DR0p4To0p5) / ele.pt(), 2.5);
     fMVAVar_GammaIso_DR0p0To0p1 = TMath::Max(TMath::Min((tmpGammaIso_DR0p0To0p1) / ele.pt(), 2.5), 0.0);
     fMVAVar_GammaIso_DR0p1To0p2 = TMath::Max(TMath::Min((tmpGammaIso_DR0p1To0p2) / ele.pt(), 2.5), 0.0);
     fMVAVar_GammaIso_DR0p2To0p3 = TMath::Max(TMath::Min((tmpGammaIso_DR0p2To0p3) / ele.pt(), 2.5), 0.0);
     fMVAVar_GammaIso_DR0p3To0p4 = TMath::Max(TMath::Min((tmpGammaIso_DR0p3To0p4) / ele.pt(), 2.5), 0.0);
     fMVAVar_GammaIso_DR0p4To0p5 = TMath::Max(TMath::Min((tmpGammaIso_DR0p4To0p5) / ele.pt(), 2.5), 0.0);
     fMVAVar_NeutralHadronIso_DR0p0To0p1 = TMath::Max(TMath::Min((tmpNeutralHadronIso_DR0p0To0p1) / ele.pt(), 2.5), 0.0);
     fMVAVar_NeutralHadronIso_DR0p1To0p2 = TMath::Max(TMath::Min((tmpNeutralHadronIso_DR0p1To0p2) / ele.pt(), 2.5), 0.0);
     fMVAVar_NeutralHadronIso_DR0p2To0p3 = TMath::Max(TMath::Min((tmpNeutralHadronIso_DR0p2To0p3) / ele.pt(), 2.5), 0.0);
     fMVAVar_NeutralHadronIso_DR0p3To0p4 = TMath::Max(TMath::Min((tmpNeutralHadronIso_DR0p3To0p4) / ele.pt(), 2.5), 0.0);
     fMVAVar_NeutralHadronIso_DR0p4To0p5 = TMath::Max(TMath::Min((tmpNeutralHadronIso_DR0p4To0p5) / ele.pt(), 2.5), 0.0);
     fMVAVar_rho = Rho;
   } else {
     std::cout << "Warning: Type " << fMVAType << " is not supported.\n";
   }
  
   // evaluate
   Double_t mva = -9999;
   if (fUseBinnedVersion) {
     int bin = GetMVABin(fMVAVar_eta, fMVAVar_pt);
     mva = fTMVAReader[bin]->EvaluateMVA(fTMVAMethod[bin]);
   } else {
     mva = fTMVAReader[0]->EvaluateMVA(fTMVAMethod[0]);
   }
  
   if (printDebug) {
     std::cout << " *** Inside the class fMethodname " << fMethodname << " fMVAType " << fMVAType << std::endl;
     std::cout << " fbrem " << fMVAVar_fbrem << " kfchi2 " << fMVAVar_kfchi2 << " mykfhits " << fMVAVar_kfhits
               << " gsfchi2 " << fMVAVar_gsfchi2 << " deta " << fMVAVar_deta << " dphi " << fMVAVar_dphi << " detacalo "
               << fMVAVar_detacalo << " see " << fMVAVar_see << " spp " << fMVAVar_spp << " etawidth "
               << fMVAVar_etawidth << " phiwidth " << fMVAVar_phiwidth << " OneMinusE1x5E5x5 "
               << fMVAVar_OneMinusE1x5E5x5 << " R9 " << fMVAVar_R9 << " HoE " << fMVAVar_HoE << " EoP " << fMVAVar_EoP
               << " IoEmIoP " << fMVAVar_IoEmIoP << " eleEoPout " << fMVAVar_eleEoPout << " d0 " << fMVAVar_d0
               << " ip3d " << fMVAVar_ip3d << " eta " << fMVAVar_eta << " pt " << fMVAVar_pt << std::endl;
     std::cout << "ChargedIso ( 0.0 | 0.1 | 0.2 | 0.3 | 0.4 | 0.5 ): " << fMVAVar_ChargedIso_DR0p0To0p1 << " "
               << fMVAVar_ChargedIso_DR0p1To0p2 << " " << fMVAVar_ChargedIso_DR0p2To0p3 << " "
               << fMVAVar_ChargedIso_DR0p3To0p4 << " " << fMVAVar_ChargedIso_DR0p4To0p5 << std::endl;
     std::cout << "PF Gamma Iso ( 0.0 | 0.1 | 0.2 | 0.3 | 0.4 | 0.5 ): " << fMVAVar_GammaIso_DR0p0To0p1 << " "
               << fMVAVar_GammaIso_DR0p1To0p2 << " " << fMVAVar_GammaIso_DR0p2To0p3 << " " << fMVAVar_GammaIso_DR0p3To0p4
               << " " << fMVAVar_GammaIso_DR0p4To0p5 << std::endl;
     std::cout << "PF Neutral Hadron Iso ( 0.0 | 0.1 | 0.2 | 0.3 | 0.4 | 0.5 ): " << fMVAVar_NeutralHadronIso_DR0p0To0p1
               << " " << fMVAVar_NeutralHadronIso_DR0p1To0p2 << " " << fMVAVar_NeutralHadronIso_DR0p2To0p3 << " "
               << fMVAVar_NeutralHadronIso_DR0p3To0p4 << " " << fMVAVar_NeutralHadronIso_DR0p4To0p5 << " " << std::endl;
     std::cout << "Rho : " << Rho << std::endl;
     std::cout << " ### MVA " << mva << std::endl;
   }
  
   return mva;
 }

◆ IDIsoCombinedMvaValue() [2/2]

Double_t EGammaMvaEleEstimator::IDIsoCombinedMvaValue	(	Double_t	fbrem,
		Double_t	kfchi2,
		Int_t	kfhits,
		Double_t	gsfchi2,
		Double_t	deta,
		Double_t	dphi,
		Double_t	detacalo,
		Double_t	see,
		Double_t	spp,
		Double_t	etawidth,
		Double_t	phiwidth,
		Double_t	OneMinusE1x5E5x5,
		Double_t	R9,
		Double_t	HoE,
		Double_t	EoP,
		Double_t	IoEmIoP,
		Double_t	eleEoPout,
		Double_t	PreShowerOverRaw,
		Double_t	d0,
		Double_t	ip3d,
		Double_t	ChargedIso_DR0p0To0p1,
		Double_t	ChargedIso_DR0p1To0p2,
		Double_t	ChargedIso_DR0p2To0p3,
		Double_t	ChargedIso_DR0p3To0p4,
		Double_t	ChargedIso_DR0p4To0p5,
		Double_t	GammaIso_DR0p0To0p1,
		Double_t	GammaIso_DR0p1To0p2,
		Double_t	GammaIso_DR0p2To0p3,
		Double_t	GammaIso_DR0p3To0p4,
		Double_t	GammaIso_DR0p4To0p5,
		Double_t	NeutralHadronIso_DR0p0To0p1,
		Double_t	NeutralHadronIso_DR0p1To0p2,
		Double_t	NeutralHadronIso_DR0p2To0p3,
		Double_t	NeutralHadronIso_DR0p3To0p4,
		Double_t	NeutralHadronIso_DR0p4To0p5,
		Double_t	Rho,
		Double_t	eta,
		Double_t	pt,
		Bool_t	printDebug = `kFALSE`
	)

Definition at line 711 of file EGammaMvaEleEstimator.cc.

                                                                          {
   if (!fisInitialized) {
     std::cout << "Error: EGammaMvaEleEstimator not properly initialized.\n";
     return -9999;
   }
  
   fMVAVar_fbrem = (fbrem < -1.0) ? -1.0 : fbrem;
   fMVAVar_kfchi2 = (kfchi2 > 10) ? 10 : kfchi2;
   fMVAVar_kfhits = float(kfhits);  // BTD does not support int variables
   fMVAVar_gsfchi2 = (gsfchi2 > 200) ? 200 : gsfchi2;
   fMVAVar_deta = (fabs(deta) > 0.06) ? 0.06 : fabs(deta);
   fMVAVar_dphi = dphi;
   fMVAVar_detacalo = detacalo;
  
   fMVAVar_see = see;
   fMVAVar_spp = spp;
   fMVAVar_etawidth = etawidth;
   fMVAVar_phiwidth = phiwidth;
   fMVAVar_OneMinusE1x5E5x5 = std::max(std::min(double(OneMinusE1x5E5x5), 2.0), -1.0);
   fMVAVar_R9 = (R9 > 5) ? 5 : R9;
  
   fMVAVar_HoE = HoE;
   fMVAVar_EoP = (EoP > 20) ? 20 : EoP;
   fMVAVar_IoEmIoP = IoEmIoP;
   fMVAVar_eleEoPout = (eleEoPout > 20) ? 20 : eleEoPout;
   fMVAVar_PreShowerOverRaw = PreShowerOverRaw;
  
   fMVAVar_d0 = d0;
   fMVAVar_ip3d = ip3d;
  
   fMVAVar_ChargedIso_DR0p0To0p1 = ChargedIso_DR0p0To0p1;
   fMVAVar_ChargedIso_DR0p1To0p2 = ChargedIso_DR0p1To0p2;
   fMVAVar_ChargedIso_DR0p2To0p3 = ChargedIso_DR0p2To0p3;
   fMVAVar_ChargedIso_DR0p3To0p4 = ChargedIso_DR0p3To0p4;
   fMVAVar_ChargedIso_DR0p4To0p5 = ChargedIso_DR0p4To0p5;
   fMVAVar_GammaIso_DR0p0To0p1 = GammaIso_DR0p0To0p1;
   fMVAVar_GammaIso_DR0p1To0p2 = GammaIso_DR0p1To0p2;
   fMVAVar_GammaIso_DR0p2To0p3 = GammaIso_DR0p2To0p3;
   fMVAVar_GammaIso_DR0p3To0p4 = GammaIso_DR0p3To0p4;
   fMVAVar_GammaIso_DR0p4To0p5 = GammaIso_DR0p4To0p5;
   fMVAVar_NeutralHadronIso_DR0p0To0p1 = NeutralHadronIso_DR0p0To0p1;
   fMVAVar_NeutralHadronIso_DR0p1To0p2 = NeutralHadronIso_DR0p1To0p2;
   fMVAVar_NeutralHadronIso_DR0p2To0p3 = NeutralHadronIso_DR0p2To0p3;
   fMVAVar_NeutralHadronIso_DR0p3To0p4 = NeutralHadronIso_DR0p3To0p4;
   fMVAVar_NeutralHadronIso_DR0p4To0p5 = NeutralHadronIso_DR0p4To0p5;
  
   fMVAVar_rho = Rho;
   fMVAVar_eta = eta;
   fMVAVar_pt = pt;
  
   Double_t mva = -9999;
   if (fUseBinnedVersion) {
     int bin = GetMVABin(fMVAVar_eta, fMVAVar_pt);
     mva = fTMVAReader[bin]->EvaluateMVA(fTMVAMethod[bin]);
   } else {
     mva = fTMVAReader[0]->EvaluateMVA(fTMVAMethod[0]);
   }
  
   if (printDebug) {
     std::cout << " *** Inside the class fMethodname " << fMethodname << std::endl;
     std::cout << " fbrem " << fMVAVar_fbrem << " kfchi2 " << fMVAVar_kfchi2 << " mykfhits " << fMVAVar_kfhits
               << " gsfchi2 " << fMVAVar_gsfchi2 << " deta " << fMVAVar_deta << " dphi " << fMVAVar_dphi << " detacalo "
               << fMVAVar_detacalo << " see " << fMVAVar_see << " spp " << fMVAVar_spp << " etawidth "
               << fMVAVar_etawidth << " phiwidth " << fMVAVar_phiwidth << " OneMinusE1x5E5x5 "
               << fMVAVar_OneMinusE1x5E5x5 << " R9 " << fMVAVar_R9 << " HoE " << fMVAVar_HoE << " EoP " << fMVAVar_EoP
               << " IoEmIoP " << fMVAVar_IoEmIoP << " eleEoPout " << fMVAVar_eleEoPout << " PreShowerOverRaw "
               << fMVAVar_PreShowerOverRaw << " d0 " << fMVAVar_d0 << " ip3d " << fMVAVar_ip3d
               << " ChargedIso_DR0p0To0p1 " << ChargedIso_DR0p0To0p1 << " ChargedIso_DR0p1To0p2 "
               << ChargedIso_DR0p1To0p2 << " ChargedIso_DR0p2To0p3 " << ChargedIso_DR0p2To0p3
               << " ChargedIso_DR0p3To0p4 " << ChargedIso_DR0p3To0p4 << " ChargedIso_DR0p4To0p5 "
               << ChargedIso_DR0p4To0p5 << " GammaIso_DR0p0To0p1 " << GammaIso_DR0p0To0p1 << " GammaIso_DR0p1To0p2 "
               << GammaIso_DR0p1To0p2 << " GammaIso_DR0p2To0p3 " << GammaIso_DR0p2To0p3 << " GammaIso_DR0p3To0p4 "
               << GammaIso_DR0p3To0p4 << " GammaIso_DR0p4To0p5 " << GammaIso_DR0p4To0p5
               << " NeutralHadronIso_DR0p0To0p1 " << NeutralHadronIso_DR0p0To0p1 << " NeutralHadronIso_DR0p1To0p2 "
               << NeutralHadronIso_DR0p1To0p2 << " NeutralHadronIso_DR0p2To0p3 " << NeutralHadronIso_DR0p2To0p3
               << " NeutralHadronIso_DR0p3To0p4 " << NeutralHadronIso_DR0p3To0p4 << " NeutralHadronIso_DR0p4To0p5 "
               << NeutralHadronIso_DR0p4To0p5 << " Rho " << Rho << " eta " << fMVAVar_eta << " pt " << fMVAVar_pt
               << std::endl;
     std::cout << " ### MVA " << mva << std::endl;
   }
  
   return mva;
 }

References newFWLiteAna::bin, gather_cfg::cout, d0, PVValHelper::eta, fisInitialized, dqmMemoryStats::float, fMethodname, fMVAVar_ChargedIso_DR0p0To0p1, fMVAVar_ChargedIso_DR0p1To0p2, fMVAVar_ChargedIso_DR0p2To0p3, fMVAVar_ChargedIso_DR0p3To0p4, fMVAVar_ChargedIso_DR0p4To0p5, fMVAVar_d0, fMVAVar_deta, fMVAVar_detacalo, fMVAVar_dphi, fMVAVar_eleEoPout, fMVAVar_EoP, fMVAVar_eta, fMVAVar_etawidth, fMVAVar_fbrem, fMVAVar_GammaIso_DR0p0To0p1, fMVAVar_GammaIso_DR0p1To0p2, fMVAVar_GammaIso_DR0p2To0p3, fMVAVar_GammaIso_DR0p3To0p4, fMVAVar_GammaIso_DR0p4To0p5, fMVAVar_gsfchi2, fMVAVar_HoE, fMVAVar_IoEmIoP, fMVAVar_ip3d, fMVAVar_kfchi2, fMVAVar_kfhits, fMVAVar_NeutralHadronIso_DR0p0To0p1, fMVAVar_NeutralHadronIso_DR0p1To0p2, fMVAVar_NeutralHadronIso_DR0p2To0p3, fMVAVar_NeutralHadronIso_DR0p3To0p4, fMVAVar_NeutralHadronIso_DR0p4To0p5, fMVAVar_OneMinusE1x5E5x5, fMVAVar_phiwidth, fMVAVar_PreShowerOverRaw, fMVAVar_pt, fMVAVar_R9, fMVAVar_rho, fMVAVar_see, fMVAVar_spp, fTMVAMethod, fTMVAReader, fUseBinnedVersion, GetMVABin(), electrons_cff::ip3d, SiStripPI::max, min(), beam_dqm_sourceclient-live_cfg::mva, HLT_FULL_cff::printDebug, and DiDispStaMuonMonitor_cfi::pt.

◆ initialize() [1/2]

void EGammaMvaEleEstimator::initialize	(	std::string	methodName,
		EGammaMvaEleEstimator::MVAType	type,
		Bool_t	useBinnedVersion,
		std::vector< std::string >	weightsfiles
	)

Definition at line 51 of file EGammaMvaEleEstimator.cc.

                                                                           {
   //clean up first
   for (unsigned int i = 0; i < fTMVAReader.size(); ++i) {
     if (fTMVAReader[i])
       delete fTMVAReader[i];
   }
   fTMVAReader.clear();
   fTMVAMethod.clear();
  
   //initialize
   fisInitialized = kTRUE;
   fMVAType = type;
   fMethodname = methodName;
   fUseBinnedVersion = useBinnedVersion;
  
   //Define expected number of bins
   UInt_t ExpectedNBins = 0;
   if (!fUseBinnedVersion) {
     ExpectedNBins = 1;
   } else if (type == kTrig) {
     ExpectedNBins = 6;
   } else if (type == kTrigNoIP) {
     ExpectedNBins = 6;
   } else if (type == kNonTrig) {
     ExpectedNBins = 6;
   } else if (type == kIsoRings) {
     ExpectedNBins = 4;
   } else if (type == kTrigIDIsoCombined) {
     ExpectedNBins = 6;
   } else if (type == kTrigIDIsoCombinedPUCorrected) {
     ExpectedNBins = 6;
   }
  
   fNMVABins = ExpectedNBins;
  
   //Check number of weight files given
   if (fNMVABins != weightsfiles.size()) {
     std::cout << "Error: Expected Number of bins = " << fNMVABins
               << " does not equal to weightsfiles.size() = " << weightsfiles.size() << std::endl;
  
 #ifndef STANDALONE
     assert(fNMVABins == weightsfiles.size());
 #endif
   }
  
   //Loop over all bins
   for (unsigned int i = 0; i < fNMVABins; ++i) {
     TMVA::Reader* tmpTMVAReader = new TMVA::Reader("!Color:!Silent:Error");
     tmpTMVAReader->SetVerbose(kTRUE);
  
     if (type == kTrig) {
       // Pure tracking variables
       tmpTMVAReader->AddVariable("fbrem", &fMVAVar_fbrem);
       tmpTMVAReader->AddVariable("kfchi2", &fMVAVar_kfchi2);
       tmpTMVAReader->AddVariable("kfhits", &fMVAVar_kfhits);
       tmpTMVAReader->AddVariable("gsfchi2", &fMVAVar_gsfchi2);
  
       // Geometrical matchings
       tmpTMVAReader->AddVariable("deta", &fMVAVar_deta);
       tmpTMVAReader->AddVariable("dphi", &fMVAVar_dphi);
       tmpTMVAReader->AddVariable("detacalo", &fMVAVar_detacalo);
  
       // Pure ECAL -> shower shapes
       tmpTMVAReader->AddVariable("see", &fMVAVar_see);
       tmpTMVAReader->AddVariable("spp", &fMVAVar_spp);
       tmpTMVAReader->AddVariable("etawidth", &fMVAVar_etawidth);
       tmpTMVAReader->AddVariable("phiwidth", &fMVAVar_phiwidth);
       tmpTMVAReader->AddVariable("e1x5e5x5", &fMVAVar_OneMinusE1x5E5x5);
       tmpTMVAReader->AddVariable("R9", &fMVAVar_R9);
  
       // Energy matching
       tmpTMVAReader->AddVariable("HoE", &fMVAVar_HoE);
       tmpTMVAReader->AddVariable("EoP", &fMVAVar_EoP);
       tmpTMVAReader->AddVariable("IoEmIoP", &fMVAVar_IoEmIoP);
       tmpTMVAReader->AddVariable("eleEoPout", &fMVAVar_eleEoPout);
       if (i == 2 || i == 5)
         tmpTMVAReader->AddVariable("PreShowerOverRaw", &fMVAVar_PreShowerOverRaw);
  
       if (!fUseBinnedVersion)
         tmpTMVAReader->AddVariable("PreShowerOverRaw", &fMVAVar_PreShowerOverRaw);
  
       // IP
       tmpTMVAReader->AddVariable("d0", &fMVAVar_d0);
       tmpTMVAReader->AddVariable("ip3d", &fMVAVar_ip3d);
  
       tmpTMVAReader->AddSpectator("eta", &fMVAVar_eta);
       tmpTMVAReader->AddSpectator("pt", &fMVAVar_pt);
     }
  
     if (type == kTrigNoIP) {
       // Pure tracking variables
       tmpTMVAReader->AddVariable("fbrem", &fMVAVar_fbrem);
       tmpTMVAReader->AddVariable("kfchi2", &fMVAVar_kfchi2);
       tmpTMVAReader->AddVariable("kfhits", &fMVAVar_kfhits);
       tmpTMVAReader->AddVariable("gsfchi2", &fMVAVar_gsfchi2);
  
       // Geometrical matchings
       tmpTMVAReader->AddVariable("deta", &fMVAVar_deta);
       tmpTMVAReader->AddVariable("dphi", &fMVAVar_dphi);
       tmpTMVAReader->AddVariable("detacalo", &fMVAVar_detacalo);
  
       // Pure ECAL -> shower shapes
       tmpTMVAReader->AddVariable("see", &fMVAVar_see);
       tmpTMVAReader->AddVariable("spp", &fMVAVar_spp);
       tmpTMVAReader->AddVariable("etawidth", &fMVAVar_etawidth);
       tmpTMVAReader->AddVariable("phiwidth", &fMVAVar_phiwidth);
       tmpTMVAReader->AddVariable("e1x5e5x5", &fMVAVar_OneMinusE1x5E5x5);
       tmpTMVAReader->AddVariable("R9", &fMVAVar_R9);
  
       // Energy matching
       tmpTMVAReader->AddVariable("HoE", &fMVAVar_HoE);
       tmpTMVAReader->AddVariable("EoP", &fMVAVar_EoP);
       tmpTMVAReader->AddVariable("IoEmIoP", &fMVAVar_IoEmIoP);
       tmpTMVAReader->AddVariable("eleEoPout", &fMVAVar_eleEoPout);
       tmpTMVAReader->AddVariable("rho", &fMVAVar_rho);
  
       if (i == 2 || i == 5)
         tmpTMVAReader->AddVariable("PreShowerOverRaw", &fMVAVar_PreShowerOverRaw);
  
       if (!fUseBinnedVersion)
         tmpTMVAReader->AddVariable("PreShowerOverRaw", &fMVAVar_PreShowerOverRaw);
  
       tmpTMVAReader->AddSpectator("eta", &fMVAVar_eta);
       tmpTMVAReader->AddSpectator("pt", &fMVAVar_pt);
     }
  
     if (type == kNonTrig) {
       // Pure tracking variables
       tmpTMVAReader->AddVariable("fbrem", &fMVAVar_fbrem);
       tmpTMVAReader->AddVariable("kfchi2", &fMVAVar_kfchi2);
       tmpTMVAReader->AddVariable("kfhits", &fMVAVar_kfhits);
       tmpTMVAReader->AddVariable("gsfchi2", &fMVAVar_gsfchi2);
  
       // Geometrical matchings
       tmpTMVAReader->AddVariable("deta", &fMVAVar_deta);
       tmpTMVAReader->AddVariable("dphi", &fMVAVar_dphi);
       tmpTMVAReader->AddVariable("detacalo", &fMVAVar_detacalo);
  
       // Pure ECAL -> shower shapes
       tmpTMVAReader->AddVariable("see", &fMVAVar_see);
       tmpTMVAReader->AddVariable("spp", &fMVAVar_spp);
       tmpTMVAReader->AddVariable("etawidth", &fMVAVar_etawidth);
       tmpTMVAReader->AddVariable("phiwidth", &fMVAVar_phiwidth);
       tmpTMVAReader->AddVariable("e1x5e5x5", &fMVAVar_OneMinusE1x5E5x5);
       tmpTMVAReader->AddVariable("R9", &fMVAVar_R9);
  
       // Energy matching
       tmpTMVAReader->AddVariable("HoE", &fMVAVar_HoE);
       tmpTMVAReader->AddVariable("EoP", &fMVAVar_EoP);
       tmpTMVAReader->AddVariable("IoEmIoP", &fMVAVar_IoEmIoP);
       tmpTMVAReader->AddVariable("eleEoPout", &fMVAVar_eleEoPout);
       if (i == 2 || i == 5)
         tmpTMVAReader->AddVariable("PreShowerOverRaw", &fMVAVar_PreShowerOverRaw);
  
       if (!fUseBinnedVersion)
         tmpTMVAReader->AddVariable("PreShowerOverRaw", &fMVAVar_PreShowerOverRaw);
  
       tmpTMVAReader->AddSpectator("eta", &fMVAVar_eta);
       tmpTMVAReader->AddSpectator("pt", &fMVAVar_pt);
     }
  
     if (type == kIsoRings) {
       tmpTMVAReader->AddVariable("ChargedIso_DR0p0To0p1", &fMVAVar_ChargedIso_DR0p0To0p1);
       tmpTMVAReader->AddVariable("ChargedIso_DR0p1To0p2", &fMVAVar_ChargedIso_DR0p1To0p2);
       tmpTMVAReader->AddVariable("ChargedIso_DR0p2To0p3", &fMVAVar_ChargedIso_DR0p2To0p3);
       tmpTMVAReader->AddVariable("ChargedIso_DR0p3To0p4", &fMVAVar_ChargedIso_DR0p3To0p4);
       tmpTMVAReader->AddVariable("ChargedIso_DR0p4To0p5", &fMVAVar_ChargedIso_DR0p4To0p5);
       tmpTMVAReader->AddVariable("GammaIso_DR0p0To0p1", &fMVAVar_GammaIso_DR0p0To0p1);
       tmpTMVAReader->AddVariable("GammaIso_DR0p1To0p2", &fMVAVar_GammaIso_DR0p1To0p2);
       tmpTMVAReader->AddVariable("GammaIso_DR0p2To0p3", &fMVAVar_GammaIso_DR0p2To0p3);
       tmpTMVAReader->AddVariable("GammaIso_DR0p3To0p4", &fMVAVar_GammaIso_DR0p3To0p4);
       tmpTMVAReader->AddVariable("GammaIso_DR0p4To0p5", &fMVAVar_GammaIso_DR0p4To0p5);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p0To0p1", &fMVAVar_NeutralHadronIso_DR0p0To0p1);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p1To0p2", &fMVAVar_NeutralHadronIso_DR0p1To0p2);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p2To0p3", &fMVAVar_NeutralHadronIso_DR0p2To0p3);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p3To0p4", &fMVAVar_NeutralHadronIso_DR0p3To0p4);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p4To0p5", &fMVAVar_NeutralHadronIso_DR0p4To0p5);
       tmpTMVAReader->AddSpectator("eta", &fMVAVar_eta);
       tmpTMVAReader->AddSpectator("pt", &fMVAVar_pt);
     }
  
     if (type == kTrigIDIsoCombinedPUCorrected) {
       // Pure tracking variables
       tmpTMVAReader->AddVariable("fbrem", &fMVAVar_fbrem);
       tmpTMVAReader->AddVariable("kfchi2", &fMVAVar_kfchi2);
       tmpTMVAReader->AddVariable("kflayers", &fMVAVar_kfhits);
       tmpTMVAReader->AddVariable("gsfchi2", &fMVAVar_gsfchi2);
  
       // Geometrical matchings
       tmpTMVAReader->AddVariable("deta", &fMVAVar_deta);
       tmpTMVAReader->AddVariable("dphi", &fMVAVar_dphi);
       tmpTMVAReader->AddVariable("detacalo", &fMVAVar_detacalo);
  
       // Pure ECAL -> shower shapes
       tmpTMVAReader->AddVariable("see", &fMVAVar_see);
       tmpTMVAReader->AddVariable("spp", &fMVAVar_spp);
       tmpTMVAReader->AddVariable("etawidth", &fMVAVar_etawidth);
       tmpTMVAReader->AddVariable("phiwidth", &fMVAVar_phiwidth);
       tmpTMVAReader->AddVariable("OneMinusSeedE1x5OverE5x5", &fMVAVar_OneMinusE1x5E5x5);
       tmpTMVAReader->AddVariable("R9", &fMVAVar_R9);
  
       // Energy matching
       tmpTMVAReader->AddVariable("HoE", &fMVAVar_HoE);
       tmpTMVAReader->AddVariable("EoP", &fMVAVar_EoP);
       tmpTMVAReader->AddVariable("IoEmIoP", &fMVAVar_IoEmIoP);
       tmpTMVAReader->AddVariable("EEleoPout", &fMVAVar_eleEoPout);
       if (i == 2 || i == 5) {
         tmpTMVAReader->AddVariable("PreShowerOverRaw", &fMVAVar_PreShowerOverRaw);
       }
       if (!fUseBinnedVersion) {
         tmpTMVAReader->AddVariable("PreShowerOverRaw", &fMVAVar_PreShowerOverRaw);
       }
  
       // IP
       tmpTMVAReader->AddVariable("d0", &fMVAVar_d0);
       tmpTMVAReader->AddVariable("ip3d", &fMVAVar_ip3d);
  
       //isolation variables
       tmpTMVAReader->AddVariable("ChargedIso_DR0p0To0p1", &fMVAVar_ChargedIso_DR0p0To0p1);
       tmpTMVAReader->AddVariable("ChargedIso_DR0p1To0p2", &fMVAVar_ChargedIso_DR0p1To0p2);
       tmpTMVAReader->AddVariable("ChargedIso_DR0p2To0p3", &fMVAVar_ChargedIso_DR0p2To0p3);
       tmpTMVAReader->AddVariable("ChargedIso_DR0p3To0p4", &fMVAVar_ChargedIso_DR0p3To0p4);
       tmpTMVAReader->AddVariable("ChargedIso_DR0p4To0p5", &fMVAVar_ChargedIso_DR0p4To0p5);
       tmpTMVAReader->AddVariable("GammaIso_DR0p0To0p1", &fMVAVar_GammaIso_DR0p0To0p1);
       tmpTMVAReader->AddVariable("GammaIso_DR0p1To0p2", &fMVAVar_GammaIso_DR0p1To0p2);
       tmpTMVAReader->AddVariable("GammaIso_DR0p2To0p3", &fMVAVar_GammaIso_DR0p2To0p3);
       tmpTMVAReader->AddVariable("GammaIso_DR0p3To0p4", &fMVAVar_GammaIso_DR0p3To0p4);
       tmpTMVAReader->AddVariable("GammaIso_DR0p4To0p5", &fMVAVar_GammaIso_DR0p4To0p5);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p0To0p1", &fMVAVar_NeutralHadronIso_DR0p0To0p1);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p1To0p2", &fMVAVar_NeutralHadronIso_DR0p1To0p2);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p2To0p3", &fMVAVar_NeutralHadronIso_DR0p2To0p3);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p3To0p4", &fMVAVar_NeutralHadronIso_DR0p3To0p4);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p4To0p5", &fMVAVar_NeutralHadronIso_DR0p4To0p5);
  
       //spectators
       tmpTMVAReader->AddSpectator("eta", &fMVAVar_eta);
       tmpTMVAReader->AddSpectator("pt", &fMVAVar_pt);
     }
  
     if (type == kTrigIDIsoCombined) {
       // Pure tracking variables
       tmpTMVAReader->AddVariable("fbrem", &fMVAVar_fbrem);
       tmpTMVAReader->AddVariable("kfchi2", &fMVAVar_kfchi2);
       tmpTMVAReader->AddVariable("kflayers", &fMVAVar_kfhits);
       tmpTMVAReader->AddVariable("gsfchi2", &fMVAVar_gsfchi2);
  
       // Geometrical matchings
       tmpTMVAReader->AddVariable("deta", &fMVAVar_deta);
       tmpTMVAReader->AddVariable("dphi", &fMVAVar_dphi);
       tmpTMVAReader->AddVariable("detacalo", &fMVAVar_detacalo);
  
       // Pure ECAL -> shower shapes
       tmpTMVAReader->AddVariable("see", &fMVAVar_see);
       tmpTMVAReader->AddVariable("spp", &fMVAVar_spp);
       tmpTMVAReader->AddVariable("etawidth", &fMVAVar_etawidth);
       tmpTMVAReader->AddVariable("phiwidth", &fMVAVar_phiwidth);
       tmpTMVAReader->AddVariable("OneMinusSeedE1x5OverE5x5", &fMVAVar_OneMinusE1x5E5x5);
       tmpTMVAReader->AddVariable("R9", &fMVAVar_R9);
  
       // Energy matching
       tmpTMVAReader->AddVariable("HoE", &fMVAVar_HoE);
       tmpTMVAReader->AddVariable("EoP", &fMVAVar_EoP);
       tmpTMVAReader->AddVariable("IoEmIoP", &fMVAVar_IoEmIoP);
       tmpTMVAReader->AddVariable("EEleoPout", &fMVAVar_eleEoPout);
       if (i == 2 || i == 5) {
         tmpTMVAReader->AddVariable("PreShowerOverRaw", &fMVAVar_PreShowerOverRaw);
       }
       if (!fUseBinnedVersion) {
         tmpTMVAReader->AddVariable("PreShowerOverRaw", &fMVAVar_PreShowerOverRaw);
       }
  
       // IP
       tmpTMVAReader->AddVariable("d0", &fMVAVar_d0);
       tmpTMVAReader->AddVariable("ip3d", &fMVAVar_ip3d);
  
       //isolation variables
       tmpTMVAReader->AddVariable("ChargedIso_DR0p0To0p1", &fMVAVar_ChargedIso_DR0p0To0p1);
       tmpTMVAReader->AddVariable("ChargedIso_DR0p1To0p2", &fMVAVar_ChargedIso_DR0p1To0p2);
       tmpTMVAReader->AddVariable("ChargedIso_DR0p2To0p3", &fMVAVar_ChargedIso_DR0p2To0p3);
       tmpTMVAReader->AddVariable("ChargedIso_DR0p3To0p4", &fMVAVar_ChargedIso_DR0p3To0p4);
       tmpTMVAReader->AddVariable("ChargedIso_DR0p4To0p5", &fMVAVar_ChargedIso_DR0p4To0p5);
       tmpTMVAReader->AddVariable("GammaIso_DR0p0To0p1", &fMVAVar_GammaIso_DR0p0To0p1);
       tmpTMVAReader->AddVariable("GammaIso_DR0p1To0p2", &fMVAVar_GammaIso_DR0p1To0p2);
       tmpTMVAReader->AddVariable("GammaIso_DR0p2To0p3", &fMVAVar_GammaIso_DR0p2To0p3);
       tmpTMVAReader->AddVariable("GammaIso_DR0p3To0p4", &fMVAVar_GammaIso_DR0p3To0p4);
       tmpTMVAReader->AddVariable("GammaIso_DR0p4To0p5", &fMVAVar_GammaIso_DR0p4To0p5);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p0To0p1", &fMVAVar_NeutralHadronIso_DR0p0To0p1);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p1To0p2", &fMVAVar_NeutralHadronIso_DR0p1To0p2);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p2To0p3", &fMVAVar_NeutralHadronIso_DR0p2To0p3);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p3To0p4", &fMVAVar_NeutralHadronIso_DR0p3To0p4);
       tmpTMVAReader->AddVariable("NeutralHadronIso_DR0p4To0p5", &fMVAVar_NeutralHadronIso_DR0p4To0p5);
       tmpTMVAReader->AddVariable("rho", &fMVAVar_rho);
  
       //spectators
       tmpTMVAReader->AddSpectator("eta", &fMVAVar_eta);
       tmpTMVAReader->AddSpectator("pt", &fMVAVar_pt);
     }
  
 #ifndef STANDALONE
     if ((fMethodname == "BDT") && (weightsfiles[i].rfind(".xml.gz") == weightsfiles[i].length() - strlen(".xml.gz"))) {
       gzFile file = gzopen(weightsfiles[i].c_str(), "rb");
       if (file == nullptr) {
         std::cout << "Error opening gzip file associated to " << weightsfiles[i] << std::endl;
         throw cms::Exception("Configuration", "Error reading zipped XML file");
       }
       std::vector<char> data;
       data.reserve(1024 * 1024 * 10);
       unsigned int bufflen = 32 * 1024;
       char* buff = reinterpret_cast<char*>(malloc(bufflen));
       if (buff == nullptr) {
         std::cout << "Error creating buffer for " << weightsfiles[i] << std::endl;
         gzclose(file);
         throw cms::Exception("Configuration", "Error reading zipped XML file");
       }
       int read;
       while ((read = gzread(file, buff, bufflen)) != 0) {
         if (read == -1) {
           std::cout << "Error reading gzip file associated to " << weightsfiles[i] << ": " << gzerror(file, &read)
                     << std::endl;
           gzclose(file);
           free(buff);
           throw cms::Exception("Configuration", "Error reading zipped XML file");
         }
         data.insert(data.end(), buff, buff + read);
       }
       if (gzclose(file) != Z_OK) {
         std::cout << "Error closing gzip file associated to " << weightsfiles[i] << std::endl;
       }
       free(buff);
       data.push_back('\0');  // IMPORTANT
       fTMVAMethod.push_back(dynamic_cast<TMVA::MethodBase*>(tmpTMVAReader->BookMVA(TMVA::Types::kBDT, &data[0])));
     } else {
       fTMVAMethod.push_back(dynamic_cast<TMVA::MethodBase*>(tmpTMVAReader->BookMVA(fMethodname, weightsfiles[i])));
     }
 #else
     fTMVAMethod.push_back(dynamic_cast<TMVA::MethodBase*>(tmpTMVAReader->BookMVA(fMethodname, weightsfiles[i])));
 #endif
     std::cout << "MVABin " << i << " : MethodName = " << fMethodname << " , type == " << type << " , "
               << "Load weights file : " << weightsfiles[i] << std::endl;
     fTMVAReader.push_back(tmpTMVAReader);
   }
   std::cout << "Electron ID MVA Completed\n";
 }

References cms::cuda::assert(), gather_cfg::cout, data, Exception, FrontierConditions_GlobalTag_cff::file, fisInitialized, fMethodname, fMVAType, fMVAVar_ChargedIso_DR0p0To0p1, fMVAVar_ChargedIso_DR0p1To0p2, fMVAVar_ChargedIso_DR0p2To0p3, fMVAVar_ChargedIso_DR0p3To0p4, fMVAVar_ChargedIso_DR0p4To0p5, fMVAVar_d0, fMVAVar_deta, fMVAVar_detacalo, fMVAVar_dphi, fMVAVar_eleEoPout, fMVAVar_EoP, fMVAVar_eta, fMVAVar_etawidth, fMVAVar_fbrem, fMVAVar_GammaIso_DR0p0To0p1, fMVAVar_GammaIso_DR0p1To0p2, fMVAVar_GammaIso_DR0p2To0p3, fMVAVar_GammaIso_DR0p3To0p4, fMVAVar_GammaIso_DR0p4To0p5, fMVAVar_gsfchi2, fMVAVar_HoE, fMVAVar_IoEmIoP, fMVAVar_ip3d, fMVAVar_kfchi2, fMVAVar_kfhits, fMVAVar_NeutralHadronIso_DR0p0To0p1, fMVAVar_NeutralHadronIso_DR0p1To0p2, fMVAVar_NeutralHadronIso_DR0p2To0p3, fMVAVar_NeutralHadronIso_DR0p3To0p4, fMVAVar_NeutralHadronIso_DR0p4To0p5, fMVAVar_OneMinusE1x5E5x5, fMVAVar_phiwidth, fMVAVar_PreShowerOverRaw, fMVAVar_pt, fMVAVar_R9, fMVAVar_rho, fMVAVar_see, fMVAVar_spp, fNMVABins, fTMVAMethod, fTMVAReader, fUseBinnedVersion, mps_fire::i, kIsoRings, kNonTrig, kTrig, kTrigIDIsoCombined, kTrigIDIsoCombinedPUCorrected, kTrigNoIP, and readEcalDQMStatus::read.

◆ initialize() [2/2]

void EGammaMvaEleEstimator::initialize	(	std::string	methodName,
		std::string	weightsfile,
		EGammaMvaEleEstimator::MVAType	type
	)

Definition at line 42 of file EGammaMvaEleEstimator.cc.

                                                                           {
   std::vector<std::string> tempWeightFileVector;
   tempWeightFileVector.push_back(weightsfile);
   initialize(methodName, type, kFALSE, tempWeightFileVector);
 }

Referenced by ElectronPATIdMVAProducer::ElectronPATIdMVAProducer(), and heppy::EGammaMvaEleEstimatorFWLite::initialize().

◆ isInitialized()

Bool_t EGammaMvaEleEstimator::isInitialized ( ) const

inline

Definition at line 58 of file EGammaMvaEleEstimator.h.

58 { return fisInitialized; }

References fisInitialized.

◆ isoMvaValue() [1/2]

Double_t EGammaMvaEleEstimator::isoMvaValue	(	const reco::GsfElectron &	ele,
		const reco::Vertex &	vertex,
		const reco::PFCandidateCollection &	PFCandidates,
		double	Rho,
		ElectronEffectiveArea::ElectronEffectiveAreaTarget	EATarget,
		const reco::GsfElectronCollection &	IdentifiedElectrons,
		const reco::MuonCollection &	IdentifiedMuons,
		bool	printDebug = `kFALSE`
	)

Definition at line 1348 of file EGammaMvaEleEstimator.cc.

                                                              {
   if (!fisInitialized) {
     std::cout << "Error: EGammaMvaEleEstimator not properly initialized.\n";
     return -9999;
   }
  
   // Spectators
   fMVAVar_eta = ele.superCluster()->eta();
   fMVAVar_pt = ele.pt();
  
   //**********************************************************
   //Isolation variables
   //**********************************************************
   Double_t tmpChargedIso_DR0p0To0p1 = 0;
   Double_t tmpChargedIso_DR0p1To0p2 = 0;
   Double_t tmpChargedIso_DR0p2To0p3 = 0;
   Double_t tmpChargedIso_DR0p3To0p4 = 0;
   Double_t tmpChargedIso_DR0p4To0p5 = 0;
   Double_t tmpGammaIso_DR0p0To0p1 = 0;
   Double_t tmpGammaIso_DR0p1To0p2 = 0;
   Double_t tmpGammaIso_DR0p2To0p3 = 0;
   Double_t tmpGammaIso_DR0p3To0p4 = 0;
   Double_t tmpGammaIso_DR0p4To0p5 = 0;
   Double_t tmpNeutralHadronIso_DR0p0To0p1 = 0;
   Double_t tmpNeutralHadronIso_DR0p1To0p2 = 0;
   Double_t tmpNeutralHadronIso_DR0p2To0p3 = 0;
   Double_t tmpNeutralHadronIso_DR0p3To0p4 = 0;
   Double_t tmpNeutralHadronIso_DR0p4To0p5 = 0;
  
   double electronTrackZ = 0;
   if (ele.gsfTrack().isNonnull()) {
     electronTrackZ = ele.gsfTrack()->dz(vertex.position());
   } else if (ele.closestCtfTrackRef().isNonnull()) {
     electronTrackZ = ele.closestCtfTrackRef()->dz(vertex.position());
   }
  
   for (reco::PFCandidateCollection::const_iterator iP = PFCandidates.begin(); iP != PFCandidates.end(); ++iP) {
     //exclude the electron itself
     if (iP->gsfTrackRef().isNonnull() && ele.gsfTrack().isNonnull() &&
         refToPtr(iP->gsfTrackRef()) == refToPtr(ele.gsfTrack()))
       continue;
     if (iP->trackRef().isNonnull() && ele.closestCtfTrackRef().isNonnull() &&
         refToPtr(iP->trackRef()) == refToPtr(ele.closestCtfTrackRef()))
       continue;
  
     //************************************************************
     // New Isolation Calculations
     //************************************************************
     double dr = sqrt(pow(iP->eta() - ele.eta(), 2) + pow(acos(cos(iP->phi() - ele.phi())), 2));
     //Double_t deta = (iP->eta() - ele.eta());
  
     if (dr < 1.0) {
       Bool_t IsLeptonFootprint = kFALSE;
       //************************************************************
       // Lepton Footprint Removal
       //************************************************************
       for (reco::GsfElectronCollection::const_iterator iE = IdentifiedElectrons.begin();
            iE != IdentifiedElectrons.end();
            ++iE) {
         //if pf candidate matches an electron passing ID cuts, then veto it
         if (iP->gsfTrackRef().isNonnull() && iE->gsfTrack().isNonnull() &&
             refToPtr(iP->gsfTrackRef()) == refToPtr(iE->gsfTrack()))
           IsLeptonFootprint = kTRUE;
         if (iP->trackRef().isNonnull() && iE->closestCtfTrackRef().isNonnull() &&
             refToPtr(iP->trackRef()) == refToPtr(iE->closestCtfTrackRef()))
           IsLeptonFootprint = kTRUE;
  
         //if pf candidate lies in veto regions of electron passing ID cuts, then veto it
         double tmpDR = sqrt(pow(iP->eta() - iE->eta(), 2) + pow(acos(cos(iP->phi() - iE->phi())), 2));
         if (iP->trackRef().isNonnull() && fabs(iE->superCluster()->eta()) >= 1.479 && tmpDR < 0.015)
           IsLeptonFootprint = kTRUE;
         if (iP->particleId() == reco::PFCandidate::gamma && fabs(iE->superCluster()->eta()) >= 1.479 && tmpDR < 0.08)
           IsLeptonFootprint = kTRUE;
       }
       for (reco::MuonCollection::const_iterator iM = IdentifiedMuons.begin(); iM != IdentifiedMuons.end(); ++iM) {
         //if pf candidate matches an muon passing ID cuts, then veto it
         if (iP->trackRef().isNonnull() && iM->innerTrack().isNonnull() &&
             refToPtr(iP->trackRef()) == refToPtr(iM->innerTrack()))
           IsLeptonFootprint = kTRUE;
  
         //if pf candidate lies in veto regions of muon passing ID cuts, then veto it
         double tmpDR = sqrt(pow(iP->eta() - iM->eta(), 2) + pow(acos(cos(iP->phi() - iM->phi())), 2));
         if (iP->trackRef().isNonnull() && tmpDR < 0.01)
           IsLeptonFootprint = kTRUE;
       }
  
       if (!IsLeptonFootprint) {
         Bool_t passVeto = kTRUE;
         //Charged
         if (iP->trackRef().isNonnull()) {
           if (!(fabs(iP->trackRef()->dz(vertex.position()) - electronTrackZ) < 0.2))
             passVeto = kFALSE;
           //************************************************************
           // Veto any PFmuon, or PFEle
           if (iP->particleId() == reco::PFCandidate::e || iP->particleId() == reco::PFCandidate::mu)
             passVeto = kFALSE;
           //************************************************************
           //************************************************************
           // Footprint Veto
           if (fabs(fMVAVar_eta) > 1.479 && dr < 0.015)
             passVeto = kFALSE;
           //************************************************************
           if (passVeto) {
             if (dr < 0.1)
               tmpChargedIso_DR0p0To0p1 += iP->pt();
             if (dr >= 0.1 && dr < 0.2)
               tmpChargedIso_DR0p1To0p2 += iP->pt();
             if (dr >= 0.2 && dr < 0.3)
               tmpChargedIso_DR0p2To0p3 += iP->pt();
             if (dr >= 0.3 && dr < 0.4)
               tmpChargedIso_DR0p3To0p4 += iP->pt();
             if (dr >= 0.4 && dr < 0.5)
               tmpChargedIso_DR0p4To0p5 += iP->pt();
           }  //pass veto
         }
         //Gamma
         else if (iP->particleId() == reco::PFCandidate::gamma) {
           //************************************************************
           // Footprint Veto
           if (fabs(fMVAVar_eta) > 1.479 && dr < 0.08)
             passVeto = kFALSE;
           //************************************************************
           if (passVeto) {
             if (dr < 0.1)
               tmpGammaIso_DR0p0To0p1 += iP->pt();
             if (dr >= 0.1 && dr < 0.2)
               tmpGammaIso_DR0p1To0p2 += iP->pt();
             if (dr >= 0.2 && dr < 0.3)
               tmpGammaIso_DR0p2To0p3 += iP->pt();
             if (dr >= 0.3 && dr < 0.4)
               tmpGammaIso_DR0p3To0p4 += iP->pt();
             if (dr >= 0.4 && dr < 0.5)
               tmpGammaIso_DR0p4To0p5 += iP->pt();
           }
         }
         //NeutralHadron
         else {
           if (dr < 0.1)
             tmpNeutralHadronIso_DR0p0To0p1 += iP->pt();
           if (dr >= 0.1 && dr < 0.2)
             tmpNeutralHadronIso_DR0p1To0p2 += iP->pt();
           if (dr >= 0.2 && dr < 0.3)
             tmpNeutralHadronIso_DR0p2To0p3 += iP->pt();
           if (dr >= 0.3 && dr < 0.4)
             tmpNeutralHadronIso_DR0p3To0p4 += iP->pt();
           if (dr >= 0.4 && dr < 0.5)
             tmpNeutralHadronIso_DR0p4To0p5 += iP->pt();
         }
       }  //not lepton footprint
     }    //in 1.0 dr cone
   }      //loop over PF candidates
  
   fMVAVar_ChargedIso_DR0p0To0p1 = TMath::Min((tmpChargedIso_DR0p0To0p1) / ele.pt(), 2.5);
   fMVAVar_ChargedIso_DR0p1To0p2 = TMath::Min((tmpChargedIso_DR0p1To0p2) / ele.pt(), 2.5);
   fMVAVar_ChargedIso_DR0p2To0p3 = TMath::Min((tmpChargedIso_DR0p2To0p3) / ele.pt(), 2.5);
   fMVAVar_ChargedIso_DR0p3To0p4 = TMath::Min((tmpChargedIso_DR0p3To0p4) / ele.pt(), 2.5);
   fMVAVar_ChargedIso_DR0p4To0p5 = TMath::Min((tmpChargedIso_DR0p4To0p5) / ele.pt(), 2.5);
   fMVAVar_GammaIso_DR0p0To0p1 = TMath::Max(
       TMath::Min(
           (tmpGammaIso_DR0p0To0p1 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                               ElectronEffectiveArea::kEleGammaIsoDR0p0To0p1, fMVAVar_eta, EATarget)) /
               ele.pt(),
           2.5),
       0.0);
   fMVAVar_GammaIso_DR0p1To0p2 = TMath::Max(
       TMath::Min(
           (tmpGammaIso_DR0p1To0p2 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                               ElectronEffectiveArea::kEleGammaIsoDR0p1To0p2, fMVAVar_eta, EATarget)) /
               ele.pt(),
           2.5),
       0.0);
   fMVAVar_GammaIso_DR0p2To0p3 = TMath::Max(
       TMath::Min(
           (tmpGammaIso_DR0p2To0p3 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                               ElectronEffectiveArea::kEleGammaIsoDR0p2To0p3, fMVAVar_eta, EATarget)) /
               ele.pt(),
           2.5),
       0.0);
   fMVAVar_GammaIso_DR0p3To0p4 = TMath::Max(
       TMath::Min(
           (tmpGammaIso_DR0p3To0p4 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                               ElectronEffectiveArea::kEleGammaIsoDR0p3To0p4, fMVAVar_eta, EATarget)) /
               ele.pt(),
           2.5),
       0.0);
   fMVAVar_GammaIso_DR0p4To0p5 = TMath::Max(
       TMath::Min(
           (tmpGammaIso_DR0p4To0p5 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                               ElectronEffectiveArea::kEleGammaIsoDR0p4To0p5, fMVAVar_eta, EATarget)) /
               ele.pt(),
           2.5),
       0.0);
   fMVAVar_NeutralHadronIso_DR0p0To0p1 =
       TMath::Max(TMath::Min((tmpNeutralHadronIso_DR0p0To0p1 -
                              Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                        ElectronEffectiveArea::kEleNeutralHadronIsoDR0p0To0p1, fMVAVar_eta, EATarget)) /
                                 ele.pt(),
                             2.5),
                  0.0);
   fMVAVar_NeutralHadronIso_DR0p1To0p2 =
       TMath::Max(TMath::Min((tmpNeutralHadronIso_DR0p1To0p2 -
                              Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                        ElectronEffectiveArea::kEleNeutralHadronIsoDR0p1To0p2, fMVAVar_eta, EATarget)) /
                                 ele.pt(),
                             2.5),
                  0.0);
   fMVAVar_NeutralHadronIso_DR0p2To0p3 =
       TMath::Max(TMath::Min((tmpNeutralHadronIso_DR0p2To0p3 -
                              Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                        ElectronEffectiveArea::kEleNeutralHadronIsoDR0p2To0p3, fMVAVar_eta, EATarget)) /
                                 ele.pt(),
                             2.5),
                  0.0);
   fMVAVar_NeutralHadronIso_DR0p3To0p4 =
       TMath::Max(TMath::Min((tmpNeutralHadronIso_DR0p3To0p4 -
                              Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                        ElectronEffectiveArea::kEleNeutralHadronIsoDR0p3To0p4, fMVAVar_eta, EATarget)) /
                                 ele.pt(),
                             2.5),
                  0.0);
   fMVAVar_NeutralHadronIso_DR0p4To0p5 =
       TMath::Max(TMath::Min((tmpNeutralHadronIso_DR0p4To0p5 -
                              Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                        ElectronEffectiveArea::kEleNeutralHadronIsoDR0p4To0p5, fMVAVar_eta, EATarget)) /
                                 ele.pt(),
                             2.5),
                  0.0);
  
   if (printDebug) {
     std::cout << "UseBinnedVersion=" << fUseBinnedVersion << " -> BIN: " << fMVAVar_eta << " " << fMVAVar_pt << " : "
               << GetMVABin(fMVAVar_eta, fMVAVar_pt) << std::endl;
   }
  
   // evaluate
   bindVariables();
   Double_t mva = -9999;
  
   //   mva = fTMVAReader[0]->EvaluateMVA(fMethodname);
   if (fUseBinnedVersion) {
     int bin = GetMVABin(fMVAVar_eta, fMVAVar_pt);
     mva = fTMVAReader[bin]->EvaluateMVA(fTMVAMethod[bin]);
   } else {
     mva = fTMVAReader[0]->EvaluateMVA(fTMVAMethod[0]);
   }
  
   if (printDebug) {
     std::cout << " *** Inside the class fMethodname " << fMethodname << " fMVAType " << fMVAType << std::endl;
     std::cout << "ChargedIso ( 0.0 | 0.1 | 0.2 | 0.3 | 0.4 | 0.5 ): " << fMVAVar_ChargedIso_DR0p0To0p1 << " "
               << fMVAVar_ChargedIso_DR0p1To0p2 << " " << fMVAVar_ChargedIso_DR0p2To0p3 << " "
               << fMVAVar_ChargedIso_DR0p3To0p4 << " " << fMVAVar_ChargedIso_DR0p4To0p5 << std::endl;
     std::cout << "PF Gamma Iso ( 0.0 | 0.1 | 0.2 | 0.3 | 0.4 | 0.5 ): " << fMVAVar_GammaIso_DR0p0To0p1 << " "
               << fMVAVar_GammaIso_DR0p1To0p2 << " " << fMVAVar_GammaIso_DR0p2To0p3 << " " << fMVAVar_GammaIso_DR0p3To0p4
               << " " << fMVAVar_GammaIso_DR0p4To0p5 << std::endl;
     std::cout << "PF Neutral Hadron Iso ( 0.0 | 0.1 | 0.2 | 0.3 | 0.4 | 0.5 ): " << fMVAVar_NeutralHadronIso_DR0p0To0p1
               << " " << fMVAVar_NeutralHadronIso_DR0p1To0p2 << " " << fMVAVar_NeutralHadronIso_DR0p2To0p3 << " "
               << fMVAVar_NeutralHadronIso_DR0p3To0p4 << " " << fMVAVar_NeutralHadronIso_DR0p4To0p5 << " " << std::endl;
     std::cout << " ### MVA " << mva << std::endl;
   }
  
   return mva;
 }

◆ isoMvaValue() [2/2]

Double_t EGammaMvaEleEstimator::isoMvaValue	(	Double_t	Pt,
		Double_t	Eta,
		Double_t	Rho,
		ElectronEffectiveArea::ElectronEffectiveAreaTarget	EATarget,
		Double_t	ChargedIso_DR0p0To0p1,
		Double_t	ChargedIso_DR0p1To0p2,
		Double_t	ChargedIso_DR0p2To0p3,
		Double_t	ChargedIso_DR0p3To0p4,
		Double_t	ChargedIso_DR0p4To0p5,
		Double_t	GammaIso_DR0p0To0p1,
		Double_t	GammaIso_DR0p1To0p2,
		Double_t	GammaIso_DR0p2To0p3,
		Double_t	GammaIso_DR0p3To0p4,
		Double_t	GammaIso_DR0p4To0p5,
		Double_t	NeutralHadronIso_DR0p0To0p1,
		Double_t	NeutralHadronIso_DR0p1To0p2,
		Double_t	NeutralHadronIso_DR0p2To0p3,
		Double_t	NeutralHadronIso_DR0p3To0p4,
		Double_t	NeutralHadronIso_DR0p4To0p5,
		Bool_t	printDebug = `kFALSE`
	)

Definition at line 834 of file EGammaMvaEleEstimator.cc.

                                                                {
   if (!fisInitialized) {
     std::cout << "Error: EGammaMvaEleEstimator not properly initialized.\n";
     return -9999;
   }
  
   fMVAVar_ChargedIso_DR0p0To0p1 = TMath::Min((ChargedIso_DR0p0To0p1) / Pt, 2.5);
   fMVAVar_ChargedIso_DR0p1To0p2 = TMath::Min((ChargedIso_DR0p1To0p2) / Pt, 2.5);
   fMVAVar_ChargedIso_DR0p2To0p3 = TMath::Min((ChargedIso_DR0p2To0p3) / Pt, 2.5);
   fMVAVar_ChargedIso_DR0p3To0p4 = TMath::Min((ChargedIso_DR0p3To0p4) / Pt, 2.5);
   fMVAVar_ChargedIso_DR0p4To0p5 = TMath::Min((ChargedIso_DR0p4To0p5) / Pt, 2.5);
   fMVAVar_GammaIso_DR0p0To0p1 = TMath::Max(
       TMath::Min((GammaIso_DR0p0To0p1 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                                   ElectronEffectiveArea::kEleGammaIsoDR0p0To0p1, Eta, EATarget)) /
                      Pt,
                  2.5),
       0.0);
   fMVAVar_GammaIso_DR0p1To0p2 = TMath::Max(
       TMath::Min((GammaIso_DR0p1To0p2 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                                   ElectronEffectiveArea::kEleGammaIsoDR0p1To0p2, Eta, EATarget)) /
                      Pt,
                  2.5),
       0.0);
   fMVAVar_GammaIso_DR0p2To0p3 = TMath::Max(
       TMath::Min((GammaIso_DR0p2To0p3 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                                   ElectronEffectiveArea::kEleGammaIsoDR0p2To0p3, Eta, EATarget)) /
                      Pt,
                  2.5),
       0.0);
   fMVAVar_GammaIso_DR0p3To0p4 = TMath::Max(
       TMath::Min((GammaIso_DR0p3To0p4 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                                   ElectronEffectiveArea::kEleGammaIsoDR0p3To0p4, Eta, EATarget)) /
                      Pt,
                  2.5),
       0.0);
   fMVAVar_GammaIso_DR0p4To0p5 = TMath::Max(
       TMath::Min((GammaIso_DR0p4To0p5 - Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                                   ElectronEffectiveArea::kEleGammaIsoDR0p4To0p5, Eta, EATarget)) /
                      Pt,
                  2.5),
       0.0);
   fMVAVar_NeutralHadronIso_DR0p0To0p1 =
       TMath::Max(TMath::Min((NeutralHadronIso_DR0p0To0p1 -
                              Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                        ElectronEffectiveArea::kEleNeutralHadronIsoDR0p0To0p1, Eta, EATarget)) /
                                 Pt,
                             2.5),
                  0.0);
   fMVAVar_NeutralHadronIso_DR0p1To0p2 =
       TMath::Max(TMath::Min((NeutralHadronIso_DR0p1To0p2 -
                              Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                        ElectronEffectiveArea::kEleNeutralHadronIsoDR0p1To0p2, Eta, EATarget)) /
                                 Pt,
                             2.5),
                  0.0);
   fMVAVar_NeutralHadronIso_DR0p2To0p3 =
       TMath::Max(TMath::Min((NeutralHadronIso_DR0p2To0p3 -
                              Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                        ElectronEffectiveArea::kEleNeutralHadronIsoDR0p2To0p3, Eta, EATarget)) /
                                 Pt,
                             2.5),
                  0.0);
   fMVAVar_NeutralHadronIso_DR0p3To0p4 =
       TMath::Max(TMath::Min((NeutralHadronIso_DR0p3To0p4 -
                              Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                        ElectronEffectiveArea::kEleNeutralHadronIsoDR0p3To0p4, Eta, EATarget)) /
                                 Pt,
                             2.5),
                  0.0);
   fMVAVar_NeutralHadronIso_DR0p4To0p5 =
       TMath::Max(TMath::Min((NeutralHadronIso_DR0p4To0p5 -
                              Rho * ElectronEffectiveArea::GetElectronEffectiveArea(
                                        ElectronEffectiveArea::kEleNeutralHadronIsoDR0p4To0p5, Eta, EATarget)) /
                                 Pt,
                             2.5),
                  0.0);
  
   // evaluate
   int bin = GetMVABin(Eta, Pt);
   Double_t mva = fTMVAReader[bin]->EvaluateMVA(fTMVAMethod[bin]);
  
   if (printDebug) {
     std::cout << " *** Inside the class fMethodname " << fMethodname << " fMVAType " << fMVAType << std::endl;
     std::cout << "ChargedIso ( 0.0 | 0.1 | 0.2 | 0.3 | 0.4 | 0.5 ): " << fMVAVar_ChargedIso_DR0p0To0p1 << " "
               << fMVAVar_ChargedIso_DR0p1To0p2 << " " << fMVAVar_ChargedIso_DR0p2To0p3 << " "
               << fMVAVar_ChargedIso_DR0p3To0p4 << " " << fMVAVar_ChargedIso_DR0p4To0p5 << std::endl;
     std::cout << "PF Gamma Iso ( 0.0 | 0.1 | 0.2 | 0.3 | 0.4 | 0.5 ): " << fMVAVar_GammaIso_DR0p0To0p1 << " "
               << fMVAVar_GammaIso_DR0p1To0p2 << " " << fMVAVar_GammaIso_DR0p2To0p3 << " " << fMVAVar_GammaIso_DR0p3To0p4
               << " " << fMVAVar_GammaIso_DR0p4To0p5 << std::endl;
     std::cout << "PF Neutral Hadron Iso ( 0.0 | 0.1 | 0.2 | 0.3 | 0.4 | 0.5 ): " << fMVAVar_NeutralHadronIso_DR0p0To0p1
               << " " << fMVAVar_NeutralHadronIso_DR0p1To0p2 << " " << fMVAVar_NeutralHadronIso_DR0p2To0p3 << " "
               << fMVAVar_NeutralHadronIso_DR0p3To0p4 << " " << fMVAVar_NeutralHadronIso_DR0p4To0p5 << " " << std::endl;
     std::cout << " ### MVA " << mva << std::endl;
   }
  
   return mva;
 }

◆ mvaValue() [1/7]

Double_t EGammaMvaEleEstimator::mvaValue	(	const pat::Electron &	ele,
		const reco::Vertex &	vertex,
		double	rho,
		bool	useFull5x5 = `kFALSE`,
		bool	printDebug = `kFALSE`
	)

Definition at line 1155 of file EGammaMvaEleEstimator.cc.

                                                                                                     {
   if (!fisInitialized) {
     std::cout << "Error: EGammaMvaEleEstimator not properly initialized.\n";
     return -9999;
   }
  
   bool validKF = false;
   reco::TrackRef myTrackRef = ele.closestCtfTrackRef();
   validKF = (myTrackRef.isAvailable());
   validKF &= (myTrackRef.isNonnull());
  
   // Pure tracking variables
   fMVAVar_fbrem = ele.fbrem();
   fMVAVar_kfchi2 = (validKF) ? myTrackRef->normalizedChi2() : 0;
   fMVAVar_kfhits = (validKF) ? myTrackRef->hitPattern().trackerLayersWithMeasurement() : -1.;
   fMVAVar_gsfchi2 = ele.gsfTrack()->normalizedChi2();
  
   // Geometrical matchings
   fMVAVar_deta = ele.deltaEtaSuperClusterTrackAtVtx();
   fMVAVar_dphi = ele.deltaPhiSuperClusterTrackAtVtx();
   fMVAVar_detacalo = ele.deltaEtaSeedClusterTrackAtCalo();
  
   // Pure ECAL -> shower shapes
   fMVAVar_see = useFull5x5 ? ele.full5x5_sigmaIetaIeta() : ele.sigmaIetaIeta();  //EleSigmaIEtaIEta
   fMVAVar_spp = useFull5x5 ? ele.full5x5_sigmaIphiIphi() : ele.sigmaIphiIphi();  //EleSigmaIEtaIEta
  
   fMVAVar_etawidth = ele.superCluster()->etaWidth();
   fMVAVar_phiwidth = ele.superCluster()->phiWidth();
   fMVAVar_OneMinusE1x5E5x5 = useFull5x5
                                  ? ((ele.full5x5_e5x5()) != 0. ? 1. - (ele.full5x5_e1x5() / ele.full5x5_e5x5()) : -1.)
                                  : ((ele.e5x5()) != 0. ? 1. - (ele.e1x5() / ele.e5x5()) : -1.);
   fMVAVar_R9 = useFull5x5 ? ele.full5x5_r9() : ele.r9();
  
   // Energy matching
   fMVAVar_HoE = ele.hadronicOverEm();  // this is identical for both
   fMVAVar_EoP = ele.eSuperClusterOverP();
  
   // unify this in the future?
   if (fMVAType == kTrig || fMVAType == kNonTrig) {
     fMVAVar_IoEmIoP =
         (1.0 / ele.ecalEnergy()) - (1.0 / ele.p());  // in the future to be changed with ele.gsfTrack()->p()
   } else {
     fMVAVar_IoEmIoP = (1.0 / ele.superCluster()->energy()) -
                       (1.0 / ele.gsfTrack()->p());  // in the future to be changed with ele.gsfTrack()->p()
   }
   fMVAVar_eleEoPout = ele.eEleClusterOverPout();
   fMVAVar_rho = rho;
   fMVAVar_PreShowerOverRaw = ele.superCluster()->preshowerEnergy() / ele.superCluster()->rawEnergy();
  
   // for triggering electrons get the impact parameteres
   if (fMVAType == kTrig) {
     //d0
     if (ele.gsfTrack().isNonnull()) {
       fMVAVar_d0 = (-1.0) * ele.gsfTrack()->dxy(vertex.position());
     } else if (ele.closestCtfTrackRef().isNonnull()) {
       fMVAVar_d0 = (-1.0) * ele.closestCtfTrackRef()->dxy(vertex.position());
     } else {
       fMVAVar_d0 = -9999.0;
     }
  
     //default values for IP3D
     fMVAVar_ip3d = -999.0;
     fMVAVar_ip3dSig = 0.0;
     if (ele.gsfTrack().isNonnull()) {
       const double gsfsign = ((-ele.gsfTrack()->dxy(vertex.position())) >= 0) ? 1. : -1.;
  
       //std::cout << "Warning : if usePV = false when pat-electrons were produced, dB() was calculated with respect to beamspot while original mva uses primary vertex" << std::endl;
       double ip3d = gsfsign * ele.dB();
       double ip3derr = ele.edB();
       fMVAVar_ip3d = ip3d;
       fMVAVar_ip3dSig = ip3d / ip3derr;
     }
   }
  
   // Spectators
   fMVAVar_eta = ele.superCluster()->eta();
   fMVAVar_pt = ele.pt();
  
   // evaluate
   bindVariables();
   Double_t mva = -9999;
   if (fUseBinnedVersion) {
     int bin = GetMVABin(fMVAVar_eta, fMVAVar_pt);
     mva = fTMVAReader[bin]->EvaluateMVA(fTMVAMethod[bin]);
   } else {
     mva = fTMVAReader[0]->EvaluateMVA(fTMVAMethod[0]);
   }
  
   if (printDebug) {
     std::cout << " *** Inside the class fMethodname " << fMethodname << " fMVAType " << fMVAType << std::endl;
     std::cout << " fbrem " << fMVAVar_fbrem << " kfchi2 " << fMVAVar_kfchi2 << " mykfhits " << fMVAVar_kfhits
               << " gsfchi2 " << fMVAVar_gsfchi2 << " deta " << fMVAVar_deta << " dphi " << fMVAVar_dphi << " detacalo "
               << fMVAVar_detacalo
               // << " dphicalo " << fMVAVar_dphicalo
               << " see " << fMVAVar_see << " spp " << fMVAVar_spp << " etawidth " << fMVAVar_etawidth << " phiwidth "
               << fMVAVar_phiwidth << " e1x5e5x5 " << fMVAVar_OneMinusE1x5E5x5 << " R9 "
               << fMVAVar_R9
               // << " mynbrems " << fMVAVar_nbrems
               << " HoE " << fMVAVar_HoE << " EoP " << fMVAVar_EoP << " IoEmIoP " << fMVAVar_IoEmIoP << " eleEoPout "
               << fMVAVar_eleEoPout << " rho "
               << fMVAVar_rho
               // << " EoPout " << fMVAVar_EoPout
               << " d0 " << fMVAVar_d0 << " ip3d " << fMVAVar_ip3d << " eta " << fMVAVar_eta << " pt " << fMVAVar_pt
               << std::endl;
     std::cout << " ### MVA " << mva << std::endl;
   }
  
   return mva;
 }

◆ mvaValue() [2/7]

Double_t EGammaMvaEleEstimator::mvaValue	(	const pat::Electron &	ele,
		double	rho,
		bool	printDebug = `kFALSE`
	)

Definition at line 1267 of file EGammaMvaEleEstimator.cc.

                                                                                             {
   if (!fisInitialized) {
     std::cout << "Error: EGammaMvaEleEstimator not properly initialized.\n";
     return -9999;
   }
  
   if ((fMVAType != EGammaMvaEleEstimator::kTrigNoIP)) {
     std::cout << "Error: This method should be called for kTrigNoIP mva only" << std::endl;
     return -9999;
   }
  
   bool validKF = false;
   reco::TrackRef myTrackRef = ele.closestCtfTrackRef();
   validKF = (myTrackRef.isAvailable());
   validKF &= (myTrackRef.isNonnull());
  
   // Pure tracking variables
   fMVAVar_fbrem = ele.fbrem();
   fMVAVar_kfchi2 = (validKF) ? myTrackRef->normalizedChi2() : 0;
   fMVAVar_kfhits = (validKF) ? myTrackRef->hitPattern().trackerLayersWithMeasurement() : -1.;
   fMVAVar_gsfchi2 = ele.gsfTrack()->normalizedChi2();
  
   // Geometrical matchings
   fMVAVar_deta = ele.deltaEtaSuperClusterTrackAtVtx();
   fMVAVar_dphi = ele.deltaPhiSuperClusterTrackAtVtx();
   fMVAVar_detacalo = ele.deltaEtaSeedClusterTrackAtCalo();
  
   // Pure ECAL -> shower shapes
   fMVAVar_see = ele.sigmaIetaIeta();  //EleSigmaIEtaIEta
  
   fMVAVar_spp = ele.sigmaIphiIphi();
  
   fMVAVar_etawidth = ele.superCluster()->etaWidth();
   fMVAVar_phiwidth = ele.superCluster()->phiWidth();
   fMVAVar_OneMinusE1x5E5x5 = (ele.e5x5()) != 0. ? 1. - (ele.e1x5() / ele.e5x5()) : -1.;
   fMVAVar_R9 = ele.r9();
  
   // Energy matching
   fMVAVar_HoE = ele.hadronicOverEm();
   fMVAVar_EoP = ele.eSuperClusterOverP();
   fMVAVar_IoEmIoP = (1.0 / ele.superCluster()->energy()) -
                     (1.0 / ele.gsfTrack()->p());  // in the future to be changed with ele.gsfTrack()->p()
   fMVAVar_eleEoPout = ele.eEleClusterOverPout();
   fMVAVar_rho = rho;
   fMVAVar_PreShowerOverRaw = ele.superCluster()->preshowerEnergy() / ele.superCluster()->rawEnergy();
  
   // Spectators
   fMVAVar_eta = ele.superCluster()->eta();
   fMVAVar_pt = ele.pt();
  
   // evaluate
   bindVariables();
   Double_t mva = -9999;
   if (fUseBinnedVersion) {
     int bin = GetMVABin(fMVAVar_eta, fMVAVar_pt);
     mva = fTMVAReader[bin]->EvaluateMVA(fTMVAMethod[bin]);
   } else {
     mva = fTMVAReader[0]->EvaluateMVA(fTMVAMethod[0]);
   }
  
   if (printDebug) {
     std::cout << " *** Inside the class fMethodname " << fMethodname << " fMVAType " << fMVAType << std::endl;
     std::cout << " fbrem " << fMVAVar_fbrem << " kfchi2 " << fMVAVar_kfchi2 << " mykfhits " << fMVAVar_kfhits
               << " gsfchi2 " << fMVAVar_gsfchi2 << " deta " << fMVAVar_deta << " dphi " << fMVAVar_dphi << " detacalo "
               << fMVAVar_detacalo
               // << " dphicalo " << fMVAVar_dphicalo
               << " see " << fMVAVar_see << " spp " << fMVAVar_spp << " etawidth " << fMVAVar_etawidth << " phiwidth "
               << fMVAVar_phiwidth << " e1x5e5x5 " << fMVAVar_OneMinusE1x5E5x5 << " R9 "
               << fMVAVar_R9
               // << " mynbrems " << fMVAVar_nbrems
               << " HoE " << fMVAVar_HoE << " EoP " << fMVAVar_EoP << " IoEmIoP " << fMVAVar_IoEmIoP << " eleEoPout "
               << fMVAVar_eleEoPout << " rho "
               << fMVAVar_rho
               // << " EoPout " << fMVAVar_EoPout
               << " eta " << fMVAVar_eta << " pt " << fMVAVar_pt << std::endl;
     std::cout << " ### MVA " << mva << std::endl;
   }
  
   return mva;
 }

◆ mvaValue() [3/7]

Double_t EGammaMvaEleEstimator::mvaValue	(	const reco::GsfElectron &	ele,
		const reco::Vertex &	vertex,
		const TransientTrackBuilder &	transientTrackBuilder,
		EcalClusterLazyTools const &	myEcalCluster,
		bool	printDebug = `kFALSE`
	)

Definition at line 954 of file EGammaMvaEleEstimator.cc.

                                                           {
   if (!fisInitialized) {
     std::cout << "Error: EGammaMvaEleEstimator not properly initialized.\n";
     return -9999;
   }
  
   if ((fMVAType != EGammaMvaEleEstimator::kTrig) && (fMVAType != EGammaMvaEleEstimator::kNonTrig)) {
     std::cout << "Error: This method should be called for kTrig or kNonTrig MVA only" << std::endl;
     return -9999;
   }
  
   bool validKF = false;
   reco::TrackRef myTrackRef = ele.closestCtfTrackRef();
   validKF = (myTrackRef.isAvailable());
   validKF &= (myTrackRef.isNonnull());
  
   // Pure tracking variables
   fMVAVar_fbrem = ele.fbrem();
   fMVAVar_kfchi2 = (validKF) ? myTrackRef->normalizedChi2() : 0;
   fMVAVar_kfhits = (validKF) ? myTrackRef->hitPattern().trackerLayersWithMeasurement() : -1.;
   fMVAVar_kfhitsall =
       (validKF) ? myTrackRef->numberOfValidHits() : -1.;  //  save also this in your ntuple as possible alternative
   fMVAVar_gsfchi2 = ele.gsfTrack()->normalizedChi2();
  
   // Geometrical matchings
   fMVAVar_deta = ele.deltaEtaSuperClusterTrackAtVtx();
   fMVAVar_dphi = ele.deltaPhiSuperClusterTrackAtVtx();
   fMVAVar_detacalo = ele.deltaEtaSeedClusterTrackAtCalo();
  
   // Pure ECAL -> shower shapes
   fMVAVar_see = ele.sigmaIetaIeta();  //EleSigmaIEtaIEta
   const auto& vCov = myEcalCluster.localCovariances(*(ele.superCluster()->seed()));
   if (edm::isFinite(vCov[2]))
     fMVAVar_spp = sqrt(vCov[2]);  //EleSigmaIPhiIPhi
   else
     fMVAVar_spp = 0.;
  
   fMVAVar_etawidth = ele.superCluster()->etaWidth();
   fMVAVar_phiwidth = ele.superCluster()->phiWidth();
   fMVAVar_OneMinusE1x5E5x5 = (ele.e5x5()) != 0. ? 1. - (ele.e1x5() / ele.e5x5()) : -1.;
   fMVAVar_R9 = myEcalCluster.e3x3(*(ele.superCluster()->seed())) / ele.superCluster()->rawEnergy();
  
   // Energy matching
   fMVAVar_HoE = ele.hadronicOverEm();
   fMVAVar_EoP = ele.eSuperClusterOverP();
   fMVAVar_IoEmIoP = (1.0 / ele.ecalEnergy()) - (1.0 / ele.p());  // in the future to be changed with ele.gsfTrack()->p()
   fMVAVar_eleEoPout = ele.eEleClusterOverPout();
   fMVAVar_PreShowerOverRaw = ele.superCluster()->preshowerEnergy() / ele.superCluster()->rawEnergy();
  
   // Spectators
   fMVAVar_eta = ele.superCluster()->eta();
   fMVAVar_pt = ele.pt();
  
   // for triggering electrons get the impact parameteres
   if (fMVAType == kTrig) {
     //d0
     if (ele.gsfTrack().isNonnull()) {
       fMVAVar_d0 = (-1.0) * ele.gsfTrack()->dxy(vertex.position());
     } else if (ele.closestCtfTrackRef().isNonnull()) {
       fMVAVar_d0 = (-1.0) * ele.closestCtfTrackRef()->dxy(vertex.position());
     } else {
       fMVAVar_d0 = -9999.0;
     }
  
     //default values for IP3D
     fMVAVar_ip3d = -999.0;
     fMVAVar_ip3dSig = 0.0;
     if (ele.gsfTrack().isNonnull()) {
       const double gsfsign = ((-ele.gsfTrack()->dxy(vertex.position())) >= 0) ? 1. : -1.;
  
       const reco::TransientTrack& tt = transientTrackBuilder.build(ele.gsfTrack());
       const std::pair<bool, Measurement1D>& ip3dpv = IPTools::absoluteImpactParameter3D(tt, vertex);
       if (ip3dpv.first) {
         double ip3d = gsfsign * ip3dpv.second.value();
         double ip3derr = ip3dpv.second.error();
         fMVAVar_ip3d = ip3d;
         fMVAVar_ip3dSig = ip3d / ip3derr;
       }
     }
   }
  
   // evaluate
   bindVariables();
   Double_t mva = -9999;
   if (fUseBinnedVersion) {
     int bin = GetMVABin(fMVAVar_eta, fMVAVar_pt);
     mva = fTMVAReader[bin]->EvaluateMVA(fTMVAMethod[bin]);
   } else {
     mva = fTMVAReader[0]->EvaluateMVA(fTMVAMethod[0]);
   }
  
   if (printDebug) {
     std::cout << " *** Inside the class fMethodname " << fMethodname << " fMVAType " << fMVAType << std::endl;
     std::cout << " fbrem " << fMVAVar_fbrem << " kfchi2 " << fMVAVar_kfchi2 << " mykfhits " << fMVAVar_kfhits
               << " gsfchi2 " << fMVAVar_gsfchi2 << " deta " << fMVAVar_deta << " dphi " << fMVAVar_dphi << " detacalo "
               << fMVAVar_detacalo << " see " << fMVAVar_see << " spp " << fMVAVar_spp << " etawidth "
               << fMVAVar_etawidth << " phiwidth " << fMVAVar_phiwidth << " OneMinusE1x5E5x5 "
               << fMVAVar_OneMinusE1x5E5x5 << " R9 " << fMVAVar_R9 << " HoE " << fMVAVar_HoE << " EoP " << fMVAVar_EoP
               << " IoEmIoP " << fMVAVar_IoEmIoP << " eleEoPout " << fMVAVar_eleEoPout << " d0 " << fMVAVar_d0
               << " ip3d " << fMVAVar_ip3d << " eta " << fMVAVar_eta << " pt " << fMVAVar_pt << std::endl;
     std::cout << " ### MVA " << mva << std::endl;
   }
  
   return mva;
 }

Referenced by ElectronIdMVAProducer::filter(), heppy::EGammaMvaEleEstimatorFWLite::mvaValue(), and ElectronPATIdMVAProducer::produce().

◆ mvaValue() [4/7]

Double_t EGammaMvaEleEstimator::mvaValue	(	const reco::GsfElectron &	ele,
		const reco::Vertex &	vertex,
		double	rho,
		EcalClusterLazyTools const &	myEcalCluster,
		bool	printDebug = `kFALSE`
	)

Definition at line 1065 of file EGammaMvaEleEstimator.cc.

                                                           {
   if (!fisInitialized) {
     std::cout << "Error: EGammaMvaEleEstimator not properly initialized.\n";
     return -9999;
   }
  
   if (fMVAType != EGammaMvaEleEstimator::kTrigNoIP) {
     std::cout << "Error: This method should be called for kTrigNoIP MVA only" << std::endl;
     return -9999;
   }
  
   bool validKF = false;
   reco::TrackRef myTrackRef = ele.closestCtfTrackRef();
   validKF = (myTrackRef.isAvailable());
   validKF &= (myTrackRef.isNonnull());
  
   // Pure tracking variables
   fMVAVar_fbrem = ele.fbrem();
   fMVAVar_kfchi2 = (validKF) ? myTrackRef->normalizedChi2() : 0;
   fMVAVar_kfhits = (validKF) ? myTrackRef->hitPattern().trackerLayersWithMeasurement() : -1.;
   fMVAVar_gsfchi2 = ele.gsfTrack()->normalizedChi2();
  
   // Geometrical matchings
   fMVAVar_deta = ele.deltaEtaSuperClusterTrackAtVtx();
   fMVAVar_dphi = ele.deltaPhiSuperClusterTrackAtVtx();
   fMVAVar_detacalo = ele.deltaEtaSeedClusterTrackAtCalo();
  
   // Pure ECAL -> shower shapes
   fMVAVar_see = ele.sigmaIetaIeta();  //EleSigmaIEtaIEta
   const auto& vCov = myEcalCluster.localCovariances(*(ele.superCluster()->seed()));
   if (edm::isFinite(vCov[2]))
     fMVAVar_spp = sqrt(vCov[2]);  //EleSigmaIPhiIPhi
   else
     fMVAVar_spp = 0.;
  
   fMVAVar_etawidth = ele.superCluster()->etaWidth();
   fMVAVar_phiwidth = ele.superCluster()->phiWidth();
   fMVAVar_OneMinusE1x5E5x5 = (ele.e5x5()) != 0. ? 1. - (ele.e1x5() / ele.e5x5()) : -1.;
   fMVAVar_R9 = myEcalCluster.e3x3(*(ele.superCluster()->seed())) / ele.superCluster()->rawEnergy();
  
   // Energy matching
   fMVAVar_HoE = ele.hadronicOverEm();
   fMVAVar_EoP = ele.eSuperClusterOverP();
   fMVAVar_IoEmIoP = (1.0 / ele.superCluster()->energy()) -
                     (1.0 / ele.gsfTrack()->p());  // in the future to be changed with ele.gsfTrack()->p()
   fMVAVar_eleEoPout = ele.eEleClusterOverPout();
   fMVAVar_rho = rho;
   fMVAVar_PreShowerOverRaw = ele.superCluster()->preshowerEnergy() / ele.superCluster()->rawEnergy();
  
   // Spectators
   fMVAVar_eta = ele.superCluster()->eta();
   fMVAVar_pt = ele.pt();
  
   // evaluate
   bindVariables();
   Double_t mva = -9999;
   if (fUseBinnedVersion) {
     int bin = GetMVABin(fMVAVar_eta, fMVAVar_pt);
     mva = fTMVAReader[bin]->EvaluateMVA(fTMVAMethod[bin]);
   } else {
     mva = fTMVAReader[0]->EvaluateMVA(fTMVAMethod[0]);
   }
  
   if (printDebug) {
     std::cout << " *** Inside the class fMethodname " << fMethodname << " fMVAType " << fMVAType << std::endl;
     std::cout << " fbrem " << fMVAVar_fbrem << " kfchi2 " << fMVAVar_kfchi2 << " mykfhits " << fMVAVar_kfhits
               << " gsfchi2 " << fMVAVar_gsfchi2 << " deta " << fMVAVar_deta << " dphi " << fMVAVar_dphi << " detacalo "
               << fMVAVar_detacalo
               // << " dphicalo " << fMVAVar_dphicalo
               << " see " << fMVAVar_see << " spp " << fMVAVar_spp << " etawidth " << fMVAVar_etawidth << " phiwidth "
               << fMVAVar_phiwidth << " e1x5e5x5 " << fMVAVar_OneMinusE1x5E5x5 << " R9 "
               << fMVAVar_R9
               // << " mynbrems " << fMVAVar_nbrems
               << " HoE " << fMVAVar_HoE << " EoP " << fMVAVar_EoP << " IoEmIoP " << fMVAVar_IoEmIoP << " eleEoPout "
               << fMVAVar_eleEoPout << " rho "
               << fMVAVar_rho
               // << " EoPout " << fMVAVar_EoPout
               << " eta " << fMVAVar_eta << " pt " << fMVAVar_pt << std::endl;
     std::cout << " ### MVA " << mva << std::endl;
   }
  
   return mva;
 }

◆ mvaValue() [5/7]

Double_t EGammaMvaEleEstimator::mvaValue	(	Double_t	fbrem,
		Double_t	kfchi2,
		Int_t	kfhits,
		Double_t	gsfchi2,
		Double_t	deta,
		Double_t	dphi,
		Double_t	detacalo,
		Double_t	see,
		Double_t	spp,
		Double_t	etawidth,
		Double_t	phiwidth,
		Double_t	e1x5e5x5,
		Double_t	R9,
		Double_t	HoE,
		Double_t	EoP,
		Double_t	IoEmIoP,
		Double_t	eleEoPout,
		Double_t	PreShowerOverRaw,
		Double_t	d0,
		Double_t	ip3d,
		Double_t	eta,
		Double_t	pt,
		Bool_t	printDebug = `kFALSE`
	)

Definition at line 453 of file EGammaMvaEleEstimator.cc.

                                                             {
   if (!fisInitialized) {
     std::cout << "Error: EGammaMvaEleEstimator not properly initialized.\n";
     return -9999;
   }
  
   if (fMVAType != EGammaMvaEleEstimator::kTrig) {
     std::cout << "Error: This method should be called for kTrig MVA only" << std::endl;
     return -9999;
   }
  
   fMVAVar_fbrem = fbrem;
   fMVAVar_kfchi2 = kfchi2;
   fMVAVar_kfhits = float(kfhits);  // BTD does not support int variables
   fMVAVar_gsfchi2 = gsfchi2;
  
   fMVAVar_deta = deta;
   fMVAVar_dphi = dphi;
   fMVAVar_detacalo = detacalo;
  
   fMVAVar_see = see;
   fMVAVar_spp = spp;
   fMVAVar_etawidth = etawidth;
   fMVAVar_phiwidth = phiwidth;
   fMVAVar_OneMinusE1x5E5x5 = OneMinusE1x5E5x5;
   fMVAVar_R9 = R9;
  
   fMVAVar_HoE = HoE;
   fMVAVar_EoP = EoP;
   fMVAVar_IoEmIoP = IoEmIoP;
   fMVAVar_eleEoPout = eleEoPout;
   fMVAVar_PreShowerOverRaw = PreShowerOverRaw;
  
   fMVAVar_d0 = d0;
   fMVAVar_ip3d = ip3d;
   fMVAVar_eta = eta;
   fMVAVar_pt = pt;
  
   bindVariables();
   Double_t mva = -9999;
   if (fUseBinnedVersion) {
     int bin = GetMVABin(fMVAVar_eta, fMVAVar_pt);
     mva = fTMVAReader[bin]->EvaluateMVA(fTMVAMethod[bin]);
   } else {
     mva = fTMVAReader[0]->EvaluateMVA(fTMVAMethod[0]);
   }
  
   if (printDebug) {
     std::cout << " *** Inside the class fMethodname " << fMethodname << std::endl;
     std::cout << " fbrem " << fMVAVar_fbrem << " kfchi2 " << fMVAVar_kfchi2 << " mykfhits " << fMVAVar_kfhits
               << " gsfchi2 " << fMVAVar_gsfchi2 << " deta " << fMVAVar_deta << " dphi " << fMVAVar_dphi << " detacalo "
               << fMVAVar_detacalo << " see " << fMVAVar_see << " spp " << fMVAVar_spp << " etawidth "
               << fMVAVar_etawidth << " phiwidth " << fMVAVar_phiwidth << " OneMinusE1x5E5x5 "
               << fMVAVar_OneMinusE1x5E5x5 << " R9 " << fMVAVar_R9 << " HoE " << fMVAVar_HoE << " EoP " << fMVAVar_EoP
               << " IoEmIoP " << fMVAVar_IoEmIoP << " eleEoPout " << fMVAVar_eleEoPout << " PreShowerOverRaw "
               << fMVAVar_PreShowerOverRaw << " d0 " << fMVAVar_d0 << " ip3d " << fMVAVar_ip3d << " eta " << fMVAVar_eta
               << " pt " << fMVAVar_pt << std::endl;
     std::cout << " ### MVA " << mva << std::endl;
   }
  
   return mva;
 }

References newFWLiteAna::bin, bindVariables(), gather_cfg::cout, d0, PVValHelper::eta, fisInitialized, dqmMemoryStats::float, fMethodname, fMVAType, fMVAVar_d0, fMVAVar_deta, fMVAVar_detacalo, fMVAVar_dphi, fMVAVar_eleEoPout, fMVAVar_EoP, fMVAVar_eta, fMVAVar_etawidth, fMVAVar_fbrem, fMVAVar_gsfchi2, fMVAVar_HoE, fMVAVar_IoEmIoP, fMVAVar_ip3d, fMVAVar_kfchi2, fMVAVar_kfhits, fMVAVar_OneMinusE1x5E5x5, fMVAVar_phiwidth, fMVAVar_PreShowerOverRaw, fMVAVar_pt, fMVAVar_R9, fMVAVar_see, fMVAVar_spp, fTMVAMethod, fTMVAReader, fUseBinnedVersion, GetMVABin(), electrons_cff::ip3d, kTrig, beam_dqm_sourceclient-live_cfg::mva, HLT_FULL_cff::printDebug, and DiDispStaMuonMonitor_cfi::pt.

◆ mvaValue() [6/7]

Double_t EGammaMvaEleEstimator::mvaValue	(	Double_t	fbrem,
		Double_t	kfchi2,
		Int_t	kfhits,
		Double_t	gsfchi2,
		Double_t	deta,
		Double_t	dphi,
		Double_t	detacalo,
		Double_t	see,
		Double_t	spp,
		Double_t	etawidth,
		Double_t	phiwidth,
		Double_t	e1x5e5x5,
		Double_t	R9,
		Double_t	HoE,
		Double_t	EoP,
		Double_t	IoEmIoP,
		Double_t	eleEoPout,
		Double_t	PreShowerOverRaw,
		Double_t	eta,
		Double_t	pt,
		Bool_t	printDebug = `kFALSE`
	)

Definition at line 627 of file EGammaMvaEleEstimator.cc.

                                                             {
   if (!fisInitialized) {
     std::cout << "Error: EGammaMvaEleEstimator not properly initialized.\n";
     return -9999;
   }
  
   if (fMVAType != EGammaMvaEleEstimator::kNonTrig) {
     std::cout << "Error: This method should be called for kNonTrig MVA only" << std::endl;
     return -9999;
   }
  
   fMVAVar_fbrem = fbrem;
   fMVAVar_kfchi2 = kfchi2;
   fMVAVar_kfhits = float(kfhits);  // BTD does not support int variables
   fMVAVar_gsfchi2 = gsfchi2;
  
   fMVAVar_deta = deta;
   fMVAVar_dphi = dphi;
   fMVAVar_detacalo = detacalo;
  
   fMVAVar_see = see;
   fMVAVar_spp = spp;
   fMVAVar_etawidth = etawidth;
   fMVAVar_phiwidth = phiwidth;
   fMVAVar_OneMinusE1x5E5x5 = OneMinusE1x5E5x5;
   fMVAVar_R9 = R9;
  
   fMVAVar_HoE = HoE;
   fMVAVar_EoP = EoP;
   fMVAVar_IoEmIoP = IoEmIoP;
   fMVAVar_eleEoPout = eleEoPout;
   fMVAVar_PreShowerOverRaw = PreShowerOverRaw;
  
   fMVAVar_eta = eta;
   fMVAVar_pt = pt;
  
   bindVariables();
   Double_t mva = -9999;
   if (fUseBinnedVersion) {
     int bin = GetMVABin(fMVAVar_eta, fMVAVar_pt);
     mva = fTMVAReader[bin]->EvaluateMVA(fTMVAMethod[bin]);
   } else {
     mva = fTMVAReader[0]->EvaluateMVA(fTMVAMethod[0]);
   }
  
   if (printDebug) {
     std::cout << " *** Inside the class fMethodname " << fMethodname << std::endl;
     std::cout << " fbrem " << fMVAVar_fbrem << " kfchi2 " << fMVAVar_kfchi2 << " mykfhits " << fMVAVar_kfhits
               << " gsfchi2 " << fMVAVar_gsfchi2 << " deta " << fMVAVar_deta << " dphi " << fMVAVar_dphi << " detacalo "
               << fMVAVar_detacalo << " see " << fMVAVar_see << " spp " << fMVAVar_spp << " etawidth "
               << fMVAVar_etawidth << " phiwidth " << fMVAVar_phiwidth << " OneMinusE1x5E5x5 "
               << fMVAVar_OneMinusE1x5E5x5 << " R9 " << fMVAVar_R9 << " HoE " << fMVAVar_HoE << " EoP " << fMVAVar_EoP
               << " IoEmIoP " << fMVAVar_IoEmIoP << " eleEoPout " << fMVAVar_eleEoPout << " PreShowerOverRaw "
               << fMVAVar_PreShowerOverRaw << " eta " << fMVAVar_eta << " pt " << fMVAVar_pt << std::endl;
     std::cout << " ### MVA " << mva << std::endl;
   }
  
   return mva;
 }

References newFWLiteAna::bin, bindVariables(), gather_cfg::cout, PVValHelper::eta, fisInitialized, dqmMemoryStats::float, fMethodname, fMVAType, fMVAVar_deta, fMVAVar_detacalo, fMVAVar_dphi, fMVAVar_eleEoPout, fMVAVar_EoP, fMVAVar_eta, fMVAVar_etawidth, fMVAVar_fbrem, fMVAVar_gsfchi2, fMVAVar_HoE, fMVAVar_IoEmIoP, fMVAVar_kfchi2, fMVAVar_kfhits, fMVAVar_OneMinusE1x5E5x5, fMVAVar_phiwidth, fMVAVar_PreShowerOverRaw, fMVAVar_pt, fMVAVar_R9, fMVAVar_see, fMVAVar_spp, fTMVAMethod, fTMVAReader, fUseBinnedVersion, GetMVABin(), kNonTrig, beam_dqm_sourceclient-live_cfg::mva, HLT_FULL_cff::printDebug, and DiDispStaMuonMonitor_cfi::pt.

◆ mvaValue() [7/7]

Double_t EGammaMvaEleEstimator::mvaValue	(	Double_t	fbrem,
		Double_t	kfchi2,
		Int_t	kfhits,
		Double_t	gsfchi2,
		Double_t	deta,
		Double_t	dphi,
		Double_t	detacalo,
		Double_t	see,
		Double_t	spp,
		Double_t	etawidth,
		Double_t	phiwidth,
		Double_t	e1x5e5x5,
		Double_t	R9,
		Double_t	HoE,
		Double_t	EoP,
		Double_t	IoEmIoP,
		Double_t	eleEoPout,
		Double_t	rho,
		Double_t	PreShowerOverRaw,
		Double_t	eta,
		Double_t	pt,
		Bool_t	printDebug = `kFALSE`
	)

Definition at line 543 of file EGammaMvaEleEstimator.cc.

                                                             {
   if (!fisInitialized) {
     std::cout << "Error: EGammaMvaEleEstimator not properly initialized.\n";
     return -9999;
   }
  
   if (fMVAType != EGammaMvaEleEstimator::kTrigNoIP) {
     std::cout << "Error: This method should be called for kTrigNoIP MVA only" << std::endl;
     return -9999;
   }
  
   fMVAVar_fbrem = fbrem;
   fMVAVar_kfchi2 = kfchi2;
   fMVAVar_kfhits = float(kfhits);  // BTD does not support int variables
   fMVAVar_gsfchi2 = gsfchi2;
  
   fMVAVar_deta = deta;
   fMVAVar_dphi = dphi;
   fMVAVar_detacalo = detacalo;
  
   fMVAVar_see = see;
   fMVAVar_spp = spp;
   fMVAVar_etawidth = etawidth;
   fMVAVar_phiwidth = phiwidth;
   fMVAVar_OneMinusE1x5E5x5 = e1x5e5x5;
   fMVAVar_R9 = R9;
  
   fMVAVar_HoE = HoE;
   fMVAVar_EoP = EoP;
   fMVAVar_IoEmIoP = IoEmIoP;
   fMVAVar_eleEoPout = eleEoPout;
   fMVAVar_rho = rho;
   fMVAVar_PreShowerOverRaw = PreShowerOverRaw;
  
   fMVAVar_eta = eta;
   fMVAVar_pt = pt;
  
   bindVariables();
   Double_t mva = -9999;
   if (fUseBinnedVersion) {
     int bin = GetMVABin(fMVAVar_eta, fMVAVar_pt);
     mva = fTMVAReader[bin]->EvaluateMVA(fTMVAMethod[bin]);
   } else {
     mva = fTMVAReader[0]->EvaluateMVA(fTMVAMethod[0]);
   }
  
   if (printDebug) {
     std::cout << " *** Inside the class fMethodname " << fMethodname << std::endl;
     std::cout << " fbrem " << fMVAVar_fbrem << " kfchi2 " << fMVAVar_kfchi2 << " mykfhits " << fMVAVar_kfhits
               << " gsfchi2 " << fMVAVar_gsfchi2 << " deta " << fMVAVar_deta << " dphi " << fMVAVar_dphi << " detacalo "
               << fMVAVar_detacalo << " see " << fMVAVar_see << " spp " << fMVAVar_spp << " etawidth "
               << fMVAVar_etawidth << " phiwidth " << fMVAVar_phiwidth << " e1x5e5x5 " << fMVAVar_OneMinusE1x5E5x5
               << " R9 " << fMVAVar_R9 << " HoE " << fMVAVar_HoE << " EoP " << fMVAVar_EoP << " IoEmIoP "
               << fMVAVar_IoEmIoP << " eleEoPout " << fMVAVar_eleEoPout << " rho " << fMVAVar_rho << " PreShowerOverRaw "
               << fMVAVar_PreShowerOverRaw << " eta " << fMVAVar_eta << " pt " << fMVAVar_pt << std::endl;
     std::cout << " ### MVA " << mva << std::endl;
   }
  
   return mva;
 }

References newFWLiteAna::bin, bindVariables(), gather_cfg::cout, PVValHelper::eta, fisInitialized, dqmMemoryStats::float, fMethodname, fMVAType, fMVAVar_deta, fMVAVar_detacalo, fMVAVar_dphi, fMVAVar_eleEoPout, fMVAVar_EoP, fMVAVar_eta, fMVAVar_etawidth, fMVAVar_fbrem, fMVAVar_gsfchi2, fMVAVar_HoE, fMVAVar_IoEmIoP, fMVAVar_kfchi2, fMVAVar_kfhits, fMVAVar_OneMinusE1x5E5x5, fMVAVar_phiwidth, fMVAVar_PreShowerOverRaw, fMVAVar_pt, fMVAVar_R9, fMVAVar_rho, fMVAVar_see, fMVAVar_spp, fTMVAMethod, fTMVAReader, fUseBinnedVersion, GetMVABin(), kTrigNoIP, beam_dqm_sourceclient-live_cfg::mva, HLT_FULL_cff::printDebug, DiDispStaMuonMonitor_cfi::pt, and rho.

Member Data Documentation

◆ fisInitialized

Bool_t EGammaMvaEleEstimator::fisInitialized

private

Definition at line 244 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), isInitialized(), isoMvaValue(), and mvaValue().

◆ fMethodname

std::string EGammaMvaEleEstimator::fMethodname

private

Definition at line 243 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), isoMvaValue(), and mvaValue().

◆ fMVAType

MVAType EGammaMvaEleEstimator::fMVAType

private

Definition at line 245 of file EGammaMvaEleEstimator.h.

Referenced by GetMVABin(), IDIsoCombinedMvaValue(), initialize(), isoMvaValue(), and mvaValue().

◆ fMVAVar_ChargedIso_DR0p0To0p1

Float_t EGammaMvaEleEstimator::fMVAVar_ChargedIso_DR0p0To0p1

private

Definition at line 281 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_ChargedIso_DR0p1To0p2

Float_t EGammaMvaEleEstimator::fMVAVar_ChargedIso_DR0p1To0p2

private

Definition at line 282 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_ChargedIso_DR0p2To0p3

Float_t EGammaMvaEleEstimator::fMVAVar_ChargedIso_DR0p2To0p3

private

Definition at line 283 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_ChargedIso_DR0p3To0p4

Float_t EGammaMvaEleEstimator::fMVAVar_ChargedIso_DR0p3To0p4

private

Definition at line 284 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_ChargedIso_DR0p4To0p5

Float_t EGammaMvaEleEstimator::fMVAVar_ChargedIso_DR0p4To0p5

private

Definition at line 285 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_d0

Float_t EGammaMvaEleEstimator::fMVAVar_d0

private

Definition at line 273 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_deta

Float_t EGammaMvaEleEstimator::fMVAVar_deta

private

Definition at line 255 of file EGammaMvaEleEstimator.h.

Referenced by bindVariables(), IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_detacalo

Float_t EGammaMvaEleEstimator::fMVAVar_detacalo

private

Definition at line 257 of file EGammaMvaEleEstimator.h.

Referenced by bindVariables(), IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_dphi

Float_t EGammaMvaEleEstimator::fMVAVar_dphi

private

Definition at line 256 of file EGammaMvaEleEstimator.h.

Referenced by bindVariables(), IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_eleEoPout

Float_t EGammaMvaEleEstimator::fMVAVar_eleEoPout

private

Definition at line 269 of file EGammaMvaEleEstimator.h.

Referenced by bindVariables(), IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_EoP

Float_t EGammaMvaEleEstimator::fMVAVar_EoP

private

Definition at line 267 of file EGammaMvaEleEstimator.h.

Referenced by bindVariables(), IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_EoPout

Float_t EGammaMvaEleEstimator::fMVAVar_EoPout

private

Definition at line 270 of file EGammaMvaEleEstimator.h.

◆ fMVAVar_eta

Float_t EGammaMvaEleEstimator::fMVAVar_eta

private

Definition at line 277 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), isoMvaValue(), and mvaValue().

◆ fMVAVar_etawidth

Float_t EGammaMvaEleEstimator::fMVAVar_etawidth

private

Definition at line 261 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_fbrem

Float_t EGammaMvaEleEstimator::fMVAVar_fbrem

private

Definition at line 249 of file EGammaMvaEleEstimator.h.

Referenced by bindVariables(), IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_GammaIso_DR0p0To0p1

Float_t EGammaMvaEleEstimator::fMVAVar_GammaIso_DR0p0To0p1

private

Definition at line 286 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_GammaIso_DR0p1To0p2

Float_t EGammaMvaEleEstimator::fMVAVar_GammaIso_DR0p1To0p2

private

Definition at line 287 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_GammaIso_DR0p2To0p3

Float_t EGammaMvaEleEstimator::fMVAVar_GammaIso_DR0p2To0p3

private

Definition at line 288 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_GammaIso_DR0p3To0p4

Float_t EGammaMvaEleEstimator::fMVAVar_GammaIso_DR0p3To0p4

private

Definition at line 289 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_GammaIso_DR0p4To0p5

Float_t EGammaMvaEleEstimator::fMVAVar_GammaIso_DR0p4To0p5

private

Definition at line 290 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_gsfchi2

Float_t EGammaMvaEleEstimator::fMVAVar_gsfchi2

private

Definition at line 253 of file EGammaMvaEleEstimator.h.

Referenced by bindVariables(), IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_HoE

Float_t EGammaMvaEleEstimator::fMVAVar_HoE

private

Definition at line 266 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_IoEmIoP

Float_t EGammaMvaEleEstimator::fMVAVar_IoEmIoP

private

Definition at line 268 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_ip3d

Float_t EGammaMvaEleEstimator::fMVAVar_ip3d

private

Definition at line 274 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_ip3dSig

Float_t EGammaMvaEleEstimator::fMVAVar_ip3dSig

private

Definition at line 275 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), and mvaValue().

◆ fMVAVar_kfchi2

Float_t EGammaMvaEleEstimator::fMVAVar_kfchi2

private

Definition at line 250 of file EGammaMvaEleEstimator.h.

Referenced by bindVariables(), IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_kfhits

Float_t EGammaMvaEleEstimator::fMVAVar_kfhits

private

Definition at line 251 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_kfhitsall

Float_t EGammaMvaEleEstimator::fMVAVar_kfhitsall

private

Definition at line 252 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), and mvaValue().

◆ fMVAVar_NeutralHadronIso_DR0p0To0p1

Float_t EGammaMvaEleEstimator::fMVAVar_NeutralHadronIso_DR0p0To0p1

private

Definition at line 291 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_NeutralHadronIso_DR0p1To0p2

Float_t EGammaMvaEleEstimator::fMVAVar_NeutralHadronIso_DR0p1To0p2

private

Definition at line 292 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_NeutralHadronIso_DR0p2To0p3

Float_t EGammaMvaEleEstimator::fMVAVar_NeutralHadronIso_DR0p2To0p3

private

Definition at line 293 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_NeutralHadronIso_DR0p3To0p4

Float_t EGammaMvaEleEstimator::fMVAVar_NeutralHadronIso_DR0p3To0p4

private

Definition at line 294 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_NeutralHadronIso_DR0p4To0p5

Float_t EGammaMvaEleEstimator::fMVAVar_NeutralHadronIso_DR0p4To0p5

private

Definition at line 295 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and isoMvaValue().

◆ fMVAVar_OneMinusE1x5E5x5

Float_t EGammaMvaEleEstimator::fMVAVar_OneMinusE1x5E5x5

private

Definition at line 263 of file EGammaMvaEleEstimator.h.

Referenced by bindVariables(), IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_phiwidth

Float_t EGammaMvaEleEstimator::fMVAVar_phiwidth

private

Definition at line 262 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_PreShowerOverRaw

Float_t EGammaMvaEleEstimator::fMVAVar_PreShowerOverRaw

private

Definition at line 271 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_pt

Float_t EGammaMvaEleEstimator::fMVAVar_pt

private

Definition at line 278 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), isoMvaValue(), and mvaValue().

◆ fMVAVar_R9

Float_t EGammaMvaEleEstimator::fMVAVar_R9

private

Definition at line 264 of file EGammaMvaEleEstimator.h.

Referenced by bindVariables(), IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_rho

Float_t EGammaMvaEleEstimator::fMVAVar_rho

private

Definition at line 279 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_see

Float_t EGammaMvaEleEstimator::fMVAVar_see

private

Definition at line 259 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fMVAVar_spp

Float_t EGammaMvaEleEstimator::fMVAVar_spp

private

Definition at line 260 of file EGammaMvaEleEstimator.h.

Referenced by bindVariables(), IDIsoCombinedMvaValue(), initialize(), and mvaValue().

◆ fNMVABins

UInt_t EGammaMvaEleEstimator::fNMVABins

private

Definition at line 247 of file EGammaMvaEleEstimator.h.

Referenced by initialize().

◆ fTMVAMethod

std::vector<TMVA::MethodBase*> EGammaMvaEleEstimator::fTMVAMethod

private

Definition at line 242 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), isoMvaValue(), and mvaValue().

◆ fTMVAReader

std::vector<TMVA::Reader*> EGammaMvaEleEstimator::fTMVAReader

private

Definition at line 241 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), isoMvaValue(), mvaValue(), and ~EGammaMvaEleEstimator().

◆ fUseBinnedVersion

Bool_t EGammaMvaEleEstimator::fUseBinnedVersion

private

Definition at line 246 of file EGammaMvaEleEstimator.h.

Referenced by IDIsoCombinedMvaValue(), initialize(), isoMvaValue(), and mvaValue().

Public Types

Public Member Functions

Private Attributes

Detailed Description

Member Enumeration Documentation

◆ MVAType

Constructor & Destructor Documentation

◆ EGammaMvaEleEstimator()

◆ ~EGammaMvaEleEstimator()

Member Function Documentation

◆ bindVariables()

◆ GetMVABin()

◆ IDIsoCombinedMvaValue() [1/2]

◆ IDIsoCombinedMvaValue() [2/2]

◆ initialize() [1/2]

◆ initialize() [2/2]

◆ isInitialized()

◆ isoMvaValue() [1/2]

◆ isoMvaValue() [2/2]

◆ mvaValue() [1/7]

◆ mvaValue() [2/7]

◆ mvaValue() [3/7]

◆ mvaValue() [4/7]

◆ mvaValue() [5/7]

◆ mvaValue() [6/7]

◆ mvaValue() [7/7]

Member Data Documentation

◆ fisInitialized

◆ fMethodname

◆ fMVAType

◆ fMVAVar_ChargedIso_DR0p0To0p1

◆ fMVAVar_ChargedIso_DR0p1To0p2

◆ fMVAVar_ChargedIso_DR0p2To0p3

◆ fMVAVar_ChargedIso_DR0p3To0p4

◆ fMVAVar_ChargedIso_DR0p4To0p5

◆ fMVAVar_d0

◆ fMVAVar_deta

◆ fMVAVar_detacalo

◆ fMVAVar_dphi

◆ fMVAVar_eleEoPout

◆ fMVAVar_EoP

◆ fMVAVar_EoPout

◆ fMVAVar_eta

◆ fMVAVar_etawidth

◆ fMVAVar_fbrem

◆ fMVAVar_GammaIso_DR0p0To0p1

◆ fMVAVar_GammaIso_DR0p1To0p2

◆ fMVAVar_GammaIso_DR0p2To0p3

◆ fMVAVar_GammaIso_DR0p3To0p4

◆ fMVAVar_GammaIso_DR0p4To0p5

◆ fMVAVar_gsfchi2

◆ fMVAVar_HoE

◆ fMVAVar_IoEmIoP

◆ fMVAVar_ip3d

◆ fMVAVar_ip3dSig

◆ fMVAVar_kfchi2

◆ fMVAVar_kfhits

◆ fMVAVar_kfhitsall

◆ fMVAVar_NeutralHadronIso_DR0p0To0p1

◆ fMVAVar_NeutralHadronIso_DR0p1To0p2

◆ fMVAVar_NeutralHadronIso_DR0p2To0p3

◆ fMVAVar_NeutralHadronIso_DR0p3To0p4

◆ fMVAVar_NeutralHadronIso_DR0p4To0p5

◆ fMVAVar_OneMinusE1x5E5x5

◆ fMVAVar_phiwidth

◆ fMVAVar_PreShowerOverRaw

◆ fMVAVar_pt

◆ fMVAVar_R9

◆ fMVAVar_rho

◆ fMVAVar_see

◆ fMVAVar_spp

◆ fNMVABins

◆ fTMVAMethod

◆ fTMVAReader

◆ fUseBinnedVersion