METTester.cc

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// author: Mike Schmitt, University of Florida
// first version 8/24/2006
// modification: Bobby Scurlock
// date:  03.11.2006
// note:  added RMS(METx) vs SumET capability
// modification: Rick Cavanaugh
// date:  05.11.2006
// note:  cleaned up constructor and beginJob, removed int conv. warning
//        added configuration params
// modification: Mike Schmitt
// date:  02.28.2007
// note:  code rewrite. Now uses STL map for monitoring element container. 
// modification: Bobby Scurlock
// date:  04.03.2007
// note:  Eliminated automated resolution fitting. This is now done in a ROOT script.

// date:  02.04.2009 
// note:  Added option to use fine binning or course binning for histos
//
// modification: Samantha Hewamanage, Florida International University
// date: 01.30.2012
// note: Added few hists for various nvtx ranges to study PU effects.
//       Cleaned up the code by making it readable and const'ing the
//       variables that should be changed.
//       Changed the number of bins from odd to even. Odd number of bins
//       makes it impossible to rebin a hist.
#include "METTester.h"
using namespace reco;
using namespace std;
using namespace edm;

METTester::METTester(const edm::ParameterSet& iConfig)
{

  inputMETLabel_           =iConfig.getParameter<edm::InputTag>("InputMETLabel");
  METType_                 =iConfig.getUntrackedParameter<std::string>("METType");

  std::string inputMETCollectionLabel(inputMETLabel_.label());

  isCaloMET = (std::string("calo")==METType_);
  isPFMET   = (std::string("pf")  ==METType_);
  isGenMET  = (std::string("gen") ==METType_);
  isMiniAODMET  = (std::string("miniaod") ==METType_);

  pvToken_ = consumes<std::vector<reco::Vertex> >(iConfig.getParameter<edm::InputTag>("PrimaryVertices"));
  if (isCaloMET)  caloMETsToken_ = consumes<reco::CaloMETCollection> (inputMETLabel_);
  if (isPFMET)    pfMETsToken_ = consumes<reco::PFMETCollection> (inputMETLabel_); 
  if(isMiniAODMET) patMETToken_ = consumes<pat::METCollection> (inputMETLabel_);
  if (isGenMET)   genMETsToken_ = consumes<reco::GenMETCollection> (inputMETLabel_); 
  if(!isMiniAODMET){
    genMETsTrueToken_ = consumes<reco::GenMETCollection> (edm::InputTag("genMetTrue"));
    genMETsCaloToken_ = consumes<reco::GenMETCollection> (edm::InputTag("genMetCalo"));
  }

  //Events variables
  mNvertex               = nullptr;

  //Common variables
  mMEx                         = nullptr;
  mMEy                         = nullptr;
  mMETSig                      = nullptr;
  mMET                         = nullptr;
  mMETFine                     = nullptr;
  mMET_Nvtx                    = nullptr;
  mMETPhi                      = nullptr;
  mSumET                       = nullptr;
  mMETDifference_GenMETTrue    = nullptr;
  mMETDeltaPhi_GenMETTrue      = nullptr;
  mMETDifference_GenMETCalo    = nullptr;
  mMETDeltaPhi_GenMETCalo      = nullptr;
  
  // MET Uncertainities: Only for MiniAOD
  mMETUnc_JetResUp  =  nullptr;
  mMETUnc_JetResDown  =  nullptr;
  mMETUnc_JetEnUp  =  nullptr;
  mMETUnc_JetEnDown  =  nullptr;
  mMETUnc_MuonEnUp  =  nullptr;
  mMETUnc_MuonEnDown  =  nullptr;
  mMETUnc_ElectronEnUp  =  nullptr;
  mMETUnc_ElectronEnDown  =  nullptr;
  mMETUnc_TauEnUp  =  nullptr;
  mMETUnc_TauEnDown  =  nullptr;
  mMETUnc_UnclusteredEnUp  =  nullptr;
  mMETUnc_UnclusteredEnDown  =  nullptr;
  mMETUnc_PhotonEnUp  =  nullptr;
  mMETUnc_PhotonEnDown  =  nullptr;
  

  //CaloMET variables
  mCaloMaxEtInEmTowers             = nullptr;
  mCaloMaxEtInHadTowers            = nullptr;
  mCaloEtFractionHadronic          = nullptr;
  mCaloEmEtFraction                = nullptr;
  mCaloHadEtInHB                   = nullptr;
  mCaloHadEtInHO                   = nullptr;
  mCaloHadEtInHE                   = nullptr;
  mCaloHadEtInHF                   = nullptr;
  mCaloEmEtInHF                    = nullptr;
  mCaloSETInpHF                    = nullptr;
  mCaloSETInmHF                    = nullptr;
  mCaloEmEtInEE                    = nullptr;
  mCaloEmEtInEB                    = nullptr;


  //GenMET variables
  mNeutralEMEtFraction=nullptr;
  mNeutralHadEtFraction=nullptr;
  mChargedEMEtFraction=nullptr;
  mChargedHadEtFraction=nullptr;
  mMuonEtFraction=nullptr; 
  mInvisibleEtFraction=nullptr;
  
  //MET variables
  
  //PFMET variables
  mMETDifference_GenMETTrue_MET0to20=nullptr;
  mMETDifference_GenMETTrue_MET20to40=nullptr;
  mMETDifference_GenMETTrue_MET40to60=nullptr;
  mMETDifference_GenMETTrue_MET60to80=nullptr;
  mMETDifference_GenMETTrue_MET80to100=nullptr;
  mMETDifference_GenMETTrue_MET100to150=nullptr;
  mMETDifference_GenMETTrue_MET150to200=nullptr;
  mMETDifference_GenMETTrue_MET200to300=nullptr;
  mMETDifference_GenMETTrue_MET300to400=nullptr;
  mMETDifference_GenMETTrue_MET400to500=nullptr;
  mMETDifference_GenMETTrue_MET500=nullptr;
  
 
} 
void METTester::bookHistograms(DQMStore::IBooker & ibooker,
                   edm::Run const & iRun,
                   edm::EventSetup const & /* iSetup */)
{
    ibooker.setCurrentFolder("JetMET/METValidation/"+inputMETLabel_.label()) ;

    mNvertex                     = ibooker.book1D("Nvertex","Nvertex",80,0,80);
    mMEx                         = ibooker.book1D("MEx","MEx",160,-800,800); 
    mMEy                         = ibooker.book1D("MEy","MEy",160,-800,800);
    mMETSig                      = ibooker.book1D("METSig","METSig",25,0,24.5);
    mMET                         = ibooker.book1D("MET", "MET (20 GeV binning)"           , 100,0,2000);
    mMETFine                     = ibooker.book1D("METFine", "MET (2 GeV binning)"        , 1000,0,2000);
    mMET_Nvtx                    = ibooker.bookProfile("MET_Nvtx", "MET vs. nvtx",    60, 0., 60., 0., 2000., " ");
    mMETPhi                      = ibooker.book1D("METPhi","METPhi",80,-4,4);
    mSumET                       = ibooker.book1D("SumET"            , "SumET"            , 200,0,4000);   //10GeV
    mMETDifference_GenMETTrue    = ibooker.book1D("METDifference_GenMETTrue","METDifference_GenMETTrue", 500,-500,500); 
    mMETDeltaPhi_GenMETTrue      = ibooker.book1D("METDeltaPhi_GenMETTrue","METDeltaPhi_GenMETTrue", 80,0,4); 

    if(isMiniAODMET){
      mMETUnc_JetResUp               = ibooker.book1D("METUnc_JetResUp",               "METUnc_JetResUp",                200,    -10, 10);
      mMETUnc_JetResDown             = ibooker.book1D("METUnc_JetResDown",             "METUnc_JetResDown",              200,    -10, 10);
      mMETUnc_JetEnUp                = ibooker.book1D("METUnc_JetEnUp",                "METUnc_JetEnUp",                 200,    -10, 10);
      mMETUnc_JetEnDown              = ibooker.book1D("METUnc_JetEnDown",              "METUnc_JetEnDown",               200,    -10, 10);
      mMETUnc_MuonEnUp               = ibooker.book1D("METUnc_MuonEnUp",               "METUnc_MuonEnUp",                200,    -10, 10);
      mMETUnc_MuonEnDown             = ibooker.book1D("METUnc_MuonEnDown",             "METUnc_MuonEnDown",              200,    -10, 10);
      mMETUnc_ElectronEnUp           = ibooker.book1D("METUnc_ElectronEnUp",           "METUnc_ElectronEnUp",            200,    -10, 10);
      mMETUnc_ElectronEnDown         = ibooker.book1D("METUnc_ElectronEnDown",         "METUnc_ElectronEnDown",          200,    -10, 10);
      mMETUnc_TauEnUp                = ibooker.book1D("METUnc_TauEnUp",                "METUnc_TauEnUp",                 200,    -10, 10);
      mMETUnc_TauEnDown              = ibooker.book1D("METUnc_TauEnDown",              "METUnc_TauEnDown",               200,    -10, 10);
      mMETUnc_UnclusteredEnUp        = ibooker.book1D("METUnc_UnclusteredEnUp",        "METUnc_UnclusteredEnUp",         200,    -10, 10);
      mMETUnc_UnclusteredEnDown      = ibooker.book1D("METUnc_UnclusteredEnDown",      "METUnc_UnclusteredEnDown",       200,    -10, 10);
      mMETUnc_PhotonEnUp             = ibooker.book1D("METUnc_UnclusteredEnDown",      "METUnc_UnclusteredEnDown",       200,    -10, 10);
      mMETUnc_PhotonEnDown           = ibooker.book1D("METUnc_PhotonEnDown",           "METUnc_PhotonEnDown",            200,    -10, 10);
      
    }
    if(!isMiniAODMET){
      mMETDifference_GenMETCalo    = ibooker.book1D("METDifference_GenMETCalo","METDifference_GenMETCalo", 500,-500,500); 
      mMETDeltaPhi_GenMETCalo      = ibooker.book1D("METDeltaPhi_GenMETCalo","METDeltaPhi_GenMETCalo", 80,0,4); 
    }
    if(!isGenMET){
      mMETDifference_GenMETTrue_MET0to20    = ibooker.book1D("METResolution_GenMETTrue_MET0to20"   , "METResolution_GenMETTrue_MET0to20"   , 500,-500,500); 
      mMETDifference_GenMETTrue_MET20to40   = ibooker.book1D("METResolution_GenMETTrue_MET20to40"  , "METResolution_GenMETTrue_MET20to40"  , 500,-500,500); 
      mMETDifference_GenMETTrue_MET40to60   = ibooker.book1D("METResolution_GenMETTrue_MET40to60"  , "METResolution_GenMETTrue_MET40to60"  , 500,-500,500); 
      mMETDifference_GenMETTrue_MET60to80   = ibooker.book1D("METResolution_GenMETTrue_MET60to80"  , "METResolution_GenMETTrue_MET60to80"  , 500,-500,500); 
      mMETDifference_GenMETTrue_MET80to100  = ibooker.book1D("METResolution_GenMETTrue_MET80to100" , "METResolution_GenMETTrue_MET80to100" , 500,-500,500); 
      mMETDifference_GenMETTrue_MET100to150 = ibooker.book1D("METResolution_GenMETTrue_MET100to150", "METResolution_GenMETTrue_MET100to150", 500,-500,500); 
      mMETDifference_GenMETTrue_MET150to200 = ibooker.book1D("METResolution_GenMETTrue_MET150to200", "METResolution_GenMETTrue_MET150to200", 500,-500,500); 
      mMETDifference_GenMETTrue_MET200to300 = ibooker.book1D("METResolution_GenMETTrue_MET200to300", "METResolution_GenMETTrue_MET200to300", 500,-500,500); 
      mMETDifference_GenMETTrue_MET300to400 = ibooker.book1D("METResolution_GenMETTrue_MET300to400", "METResolution_GenMETTrue_MET300to400", 500,-500,500); 
      mMETDifference_GenMETTrue_MET400to500 = ibooker.book1D("METResolution_GenMETTrue_MET400to500", "METResolution_GenMETTrue_MET400to500", 500,-500,500); 
      mMETDifference_GenMETTrue_MET500      = ibooker.book1D("METResolution_GenMETTrue_MET500", "METResolution_GenMETTrue_MET500", 500,-500,500);  
    }
    if ( isCaloMET) { 
      mCaloMaxEtInEmTowers             = ibooker.book1D("CaloMaxEtInEmTowers","CaloMaxEtInEmTowers",300,0,1500);   //5GeV
      mCaloMaxEtInHadTowers            = ibooker.book1D("CaloMaxEtInHadTowers","CaloMaxEtInHadTowers",300,0,1500);  //5GeV
      mCaloEtFractionHadronic          = ibooker.book1D("CaloEtFractionHadronic","CaloEtFractionHadronic",100,0,1);
      mCaloEmEtFraction                = ibooker.book1D("CaloEmEtFraction","CaloEmEtFraction",100,0,1);
      mCaloHadEtInHB                   = ibooker.book1D("CaloHadEtInHB","CaloHadEtInHB", 200, 0, 2000);  //5GeV  
      mCaloHadEtInHE                   = ibooker.book1D("CaloHadEtInHE","CaloHadEtInHE", 100, 0, 500);  //5GeV
      mCaloHadEtInHO                   = ibooker.book1D("CaloHadEtInHO","CaloHadEtInHO", 100, 0, 200);  //5GeV
      mCaloHadEtInHF                   = ibooker.book1D("CaloHadEtInHF","CaloHadEtInHF", 100, 0, 200);  //5GeV
      mCaloSETInpHF                    = ibooker.book1D("CaloSETInpHF","CaloSETInpHF",100, 0, 500);
      mCaloSETInmHF                    = ibooker.book1D("CaloSETInmHF","CaloSETInmHF",100, 0, 500);
      mCaloEmEtInEE                    = ibooker.book1D("CaloEmEtInEE","CaloEmEtInEE",100, 0, 500);    //5GeV
      mCaloEmEtInEB                    = ibooker.book1D("CaloEmEtInEB","CaloEmEtInEB",100, 0, 500);   //5GeV
      mCaloEmEtInHF                    = ibooker.book1D("CaloEmEtInHF","CaloEmEtInHF",100, 0, 500);   //5GeV
    } 

    if(isGenMET){        
      mNeutralEMEtFraction    = ibooker.book1D("GenNeutralEMEtFraction", "GenNeutralEMEtFraction", 120, 0.0, 1.2 );
      mNeutralHadEtFraction   = ibooker.book1D("GenNeutralHadEtFraction", "GenNeutralHadEtFraction", 120, 0.0, 1.2 );
      mChargedEMEtFraction    = ibooker.book1D("GenChargedEMEtFraction", "GenChargedEMEtFraction", 120, 0.0, 1.2);
      mChargedHadEtFraction   = ibooker.book1D("GenChargedHadEtFraction", "GenChargedHadEtFraction", 120, 0.0,1.2);
      mMuonEtFraction         = ibooker.book1D("GenMuonEtFraction", "GenMuonEtFraction", 120, 0.0, 1.2 );
      mInvisibleEtFraction    = ibooker.book1D("GenInvisibleEtFraction", "GenInvisibleEtFraction", 120, 0.0, 1.2 );
    }

    if (isPFMET ||  isMiniAODMET){
      mPFphotonEtFraction = ibooker.book1D("photonEtFraction", "photonEtFraction", 100, 0, 1);
      mPFneutralHadronEtFraction = ibooker.book1D("neutralHadronEtFraction", "neutralHadronEtFraction", 100, 0, 1);
      mPFelectronEtFraction = ibooker.book1D("electronEtFraction", "electronEtFraction", 100, 0, 1);
      mPFchargedHadronEtFraction = ibooker.book1D("chargedHadronEtFraction", "chargedHadronEtFraction", 100, 0, 1);
      mPFHFHadronEtFraction = ibooker.book1D("HFHadronEtFraction", "HFHadronEtFraction", 100, 0, 1);
      mPFmuonEtFraction = ibooker.book1D("muonEtFraction", "muonEtFraction", 100, 0, 1);
      mPFHFEMEtFraction = ibooker.book1D("HFEMEtFraction", "HFEMEtFraction", 100, 0, 1);

      if(!isMiniAODMET){
    mPFphotonEt = ibooker.book1D("photonEt", "photonEt", 100, 0, 1000);
    mPFneutralHadronEt = ibooker.book1D("neutralHadronEt", "neutralHadronEt", 100, 0, 1000);
    mPFelectronEt = ibooker.book1D("electronEt", "electronEt", 100, 0, 1000);
    mPFchargedHadronEt = ibooker.book1D("chargedHadronEt", "chargedHadronEt", 100, 0, 1000);
    mPFmuonEt = ibooker.book1D("muonEt", "muonEt", 100, 0, 1000);
    mPFHFHadronEt = ibooker.book1D("HFHadronEt", "HFHadronEt", 100, 0, 500);
    mPFHFEMEt = ibooker.book1D("HFEMEt", "HFEMEt", 100, 0, 300);
      }

    }
}


void METTester::analyze(const edm::Event& iEvent, const edm::EventSetup& iSetup)
{ //int counter(0);

  edm::Handle<reco::VertexCollection> pvHandle;
  iEvent.getByToken(pvToken_, pvHandle);
   if (! pvHandle.isValid())
  {
    std::cout << __FUNCTION__ << ":" << __LINE__ << ":pvHandle handle not found!" << std::endl;
    assert(false);
  }
  const int nvtx = pvHandle->size();
  mNvertex->Fill(nvtx);
  //Collections for all MET collections

  edm::Handle<CaloMETCollection> caloMETs;
  edm::Handle<PFMETCollection> pfMETs;
  edm::Handle<GenMETCollection> genMETs;
  edm::Handle<pat::METCollection> patMET;

  if (isCaloMET) iEvent.getByToken(caloMETsToken_, caloMETs);
  if (isPFMET)   iEvent.getByToken(pfMETsToken_,   pfMETs);
  if (isGenMET)  iEvent.getByToken(genMETsToken_,  genMETs);
  if (isMiniAODMET)  iEvent.getByToken(patMETToken_,  patMET);
  if ((isCaloMET) and !caloMETs.isValid()) return; 
  if ((isPFMET)   and !pfMETs.isValid())   return;
  if ((isGenMET)  and !genMETs.isValid())  return;
  if ((isMiniAODMET)  and !patMET.isValid())  return;

  reco::MET met;
  if (isCaloMET) { met = caloMETs->front();}
  if (isPFMET)   { met = pfMETs->front()  ;}
  if (isGenMET)  { met = genMETs->front() ;}
  if (isMiniAODMET)  { met = patMET->front() ;}

  const double SumET = met.sumEt();
  const double METSig = met.mEtSig();
  const double MET = met.pt();
  const double MEx = met.px();
  const double MEy = met.py();
  const double METPhi = met.phi();
  mMEx->Fill(MEx);
  mMEy->Fill(MEy);
  mMET->Fill(MET);
  mMETFine->Fill(MET);
  mMET_Nvtx->Fill((double)nvtx, MET);
  mMETPhi->Fill(METPhi);
  mSumET->Fill(SumET);
  mMETSig->Fill(METSig);
  
    
  // Get Generated MET for Resolution plots
  const reco::GenMET *genMetTrue=nullptr;
  bool isvalidgenmet=false;

  if(!isMiniAODMET){
    edm::Handle<GenMETCollection> genTrue;
    iEvent.getByToken(genMETsTrueToken_, genTrue);
    if (genTrue.isValid()) {
      isvalidgenmet=true;
      const GenMETCollection *genmetcol = genTrue.product();
      genMetTrue = &(genmetcol->front());
    }
  }else{
    genMetTrue=patMET->front().genMET();
    isvalidgenmet=true;
  }

  if(isvalidgenmet){
    double genMET = genMetTrue->pt();
    double genMETPhi = genMetTrue->phi();

    mMETDifference_GenMETTrue->Fill( MET - genMET );
    mMETDeltaPhi_GenMETTrue->Fill( TMath::ACos( TMath::Cos( METPhi - genMETPhi ) ) );

    if(!isGenMET){
      //pfMET resolution in pfMET bins : Sam, Feb, 2012
      if (MET > 0 && MET < 20) mMETDifference_GenMETTrue_MET0to20->Fill( MET - genMET );
      else if (MET > 20 && MET < 40) mMETDifference_GenMETTrue_MET20to40->Fill( MET - genMET );
      else if (MET > 40 && MET < 60) mMETDifference_GenMETTrue_MET40to60->Fill( MET - genMET );
      else if (MET > 60 && MET < 80) mMETDifference_GenMETTrue_MET60to80->Fill( MET - genMET );
      else if (MET > 80 && MET <100) mMETDifference_GenMETTrue_MET80to100->Fill( MET - genMET );
      else if (MET >100 && MET <150) mMETDifference_GenMETTrue_MET100to150->Fill( MET - genMET );
      else if (MET >150 && MET <200) mMETDifference_GenMETTrue_MET150to200->Fill( MET - genMET );
      else if (MET >200 && MET <300) mMETDifference_GenMETTrue_MET200to300->Fill( MET - genMET );
      else if (MET >300 && MET <400) mMETDifference_GenMETTrue_MET300to400->Fill( MET - genMET );
      else if (MET >400 && MET <500) mMETDifference_GenMETTrue_MET400to500->Fill( MET - genMET );
      else if (MET >500) mMETDifference_GenMETTrue_MET500->Fill( MET - genMET );
      
    } else {
      edm::LogInfo("OutputInfo") << " failed to retrieve data required by MET Task:  genMetTrue";
    }    
  }
  if(!isMiniAODMET){
    edm::Handle<GenMETCollection> genCalo;
    iEvent.getByToken(genMETsCaloToken_, genCalo);
    if (genCalo.isValid()) {
      const GenMETCollection *genmetcol = genCalo.product();
      const GenMET  *genMetCalo = &(genmetcol->front());
      const double genMET = genMetCalo->pt();
      const double genMETPhi = genMetCalo->phi();
      
      mMETDifference_GenMETCalo->Fill( MET - genMET );
      mMETDeltaPhi_GenMETCalo->Fill( TMath::ACos( TMath::Cos( METPhi - genMETPhi ) ) );
    } else {
      edm::LogInfo("OutputInfo") << " failed to retrieve data required by MET Task:  genMetCalo";
    }    
  }
  if ( isCaloMET) { 
    const reco::CaloMET * calomet = &(caloMETs->front());
    // ==========================================================
    // Reconstructed MET Information
    const double caloMaxEtInEMTowers = calomet->maxEtInEmTowers();
    const double caloMaxEtInHadTowers = calomet->maxEtInHadTowers();
    const double caloEtFractionHadronic = calomet->etFractionHadronic();
    const double caloEmEtFraction = calomet->emEtFraction();
    const double caloHadEtInHB = calomet->hadEtInHB();
    const double caloHadEtInHO = calomet->hadEtInHO();
    const double caloHadEtInHE = calomet->hadEtInHE();
    const double caloHadEtInHF = calomet->hadEtInHF();
    const double caloEmEtInEB = calomet->emEtInEB();
    const double caloEmEtInEE = calomet->emEtInEE();
    const double caloEmEtInHF = calomet->emEtInHF();
    const double caloSETInpHF = calomet->CaloSETInpHF();
    const double caloSETInmHF = calomet->CaloSETInmHF();

    mCaloMaxEtInEmTowers->Fill(caloMaxEtInEMTowers);
    mCaloMaxEtInHadTowers->Fill(caloMaxEtInHadTowers);
    mCaloEtFractionHadronic->Fill(caloEtFractionHadronic);
    mCaloEmEtFraction->Fill(caloEmEtFraction);
    mCaloHadEtInHB->Fill(caloHadEtInHB);
    mCaloHadEtInHO->Fill(caloHadEtInHO);
    mCaloHadEtInHE->Fill(caloHadEtInHE);
    mCaloHadEtInHF->Fill(caloHadEtInHF);
    mCaloEmEtInEB->Fill(caloEmEtInEB);
    mCaloEmEtInEE->Fill(caloEmEtInEE);
    mCaloEmEtInHF->Fill(caloEmEtInHF);
    mCaloSETInpHF->Fill(caloSETInpHF);
    mCaloSETInmHF->Fill(caloSETInmHF);
  }  
  if (isGenMET)
  {
    const GenMET *genmet;
    // Get Generated MET
    genmet = &(genMETs->front());

    const double NeutralEMEtFraction = genmet->NeutralEMEtFraction() ;
    const double NeutralHadEtFraction = genmet->NeutralHadEtFraction() ;
    const double ChargedEMEtFraction = genmet->ChargedEMEtFraction () ;
    const double ChargedHadEtFraction = genmet->ChargedHadEtFraction();
    const double MuonEtFraction = genmet->MuonEtFraction() ;
    const double InvisibleEtFraction = genmet->InvisibleEtFraction() ;

    mNeutralEMEtFraction->Fill( NeutralEMEtFraction );
    mNeutralHadEtFraction->Fill( NeutralHadEtFraction );
    mChargedEMEtFraction->Fill( ChargedEMEtFraction );
    mChargedHadEtFraction->Fill( ChargedHadEtFraction );
    mMuonEtFraction->Fill( MuonEtFraction );
    mInvisibleEtFraction->Fill( InvisibleEtFraction );
  } 
  if(isPFMET)
  {
    const reco::PFMET  * pfmet = &(pfMETs->front());
    mPFphotonEtFraction->Fill(pfmet->photonEtFraction());
    mPFphotonEt->Fill(pfmet->photonEt());
    mPFneutralHadronEtFraction->Fill(pfmet->neutralHadronEtFraction());
    mPFneutralHadronEt->Fill(pfmet->neutralHadronEt());
    mPFelectronEtFraction->Fill(pfmet->electronEtFraction());
    mPFelectronEt->Fill(pfmet->electronEt());
    mPFchargedHadronEtFraction->Fill(pfmet->chargedHadronEtFraction());
    mPFchargedHadronEt->Fill(pfmet->chargedHadronEt());
    mPFmuonEtFraction->Fill(pfmet->muonEtFraction());
    mPFmuonEt->Fill(pfmet->muonEt());
    mPFHFHadronEtFraction->Fill(pfmet->HFHadronEtFraction());
    mPFHFHadronEt->Fill(pfmet->HFHadronEt());
    mPFHFEMEtFraction->Fill(pfmet->HFEMEtFraction());
    mPFHFEMEt->Fill(pfmet->HFEMEt());
    // Reconstructed MET Information                                                                                                     

  } 
   if(isMiniAODMET){
    const pat::MET *patmet = &(patMET->front());
    mMETUnc_JetResUp               ->Fill(MET- patmet->shiftedPt(pat::MET::JetResUp)) ;
    mMETUnc_JetResDown             ->Fill(MET- patmet->shiftedPt(pat::MET::JetResDown));
    mMETUnc_JetEnUp                ->Fill(MET- patmet->shiftedPt(pat::MET::JetEnUp));
    mMETUnc_JetEnDown              ->Fill(MET- patmet->shiftedPt(pat::MET::JetEnDown));
    mMETUnc_MuonEnUp               ->Fill(MET- patmet->shiftedPt(pat::MET::MuonEnUp));
    mMETUnc_MuonEnDown             ->Fill(MET- patmet->shiftedPt(pat::MET::MuonEnDown));
    mMETUnc_ElectronEnUp           ->Fill(MET- patmet->shiftedPt(pat::MET::ElectronEnUp));
    mMETUnc_ElectronEnDown         ->Fill(MET- patmet->shiftedPt(pat::MET::ElectronEnDown));
    mMETUnc_TauEnUp                ->Fill(MET- patmet->shiftedPt(pat::MET::TauEnUp));
    mMETUnc_TauEnDown              ->Fill(MET- patmet->shiftedPt(pat::MET::TauEnDown));
    mMETUnc_UnclusteredEnUp        ->Fill(MET- patmet->shiftedPt(pat::MET::UnclusteredEnUp));
    mMETUnc_UnclusteredEnDown      ->Fill(MET- patmet->shiftedPt(pat::MET::UnclusteredEnDown));
    mMETUnc_PhotonEnUp             ->Fill(MET- patmet->shiftedPt(pat::MET::PhotonEnUp));
    mMETUnc_PhotonEnDown           ->Fill(MET- patmet->shiftedPt(pat::MET::PhotonEnDown));
    
    
    if(patmet->isPFMET()){
      mPFphotonEtFraction->Fill(patmet->NeutralEMFraction());
      mPFneutralHadronEtFraction->Fill(patmet->NeutralHadEtFraction());
      mPFelectronEtFraction->Fill(patmet->ChargedEMEtFraction());
      mPFchargedHadronEtFraction->Fill(patmet->ChargedHadEtFraction());
      mPFmuonEtFraction->Fill(patmet->MuonEtFraction());
      mPFHFHadronEtFraction->Fill(patmet->Type6EtFraction());//HFHadrons
      mPFHFEMEtFraction->Fill(patmet->Type7EtFraction());//HFEMEt  
    }
  }  
}