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Public Member Functions | Private Member Functions | Private Attributes

QcdHighPtDQM Class Reference

#include <QcdHighPtDQM.h>

Inheritance diagram for QcdHighPtDQM:
edm::EDAnalyzer

List of all members.

Public Member Functions

void analyze (const edm::Event &, const edm::EventSetup &)
 Get the analysis.
void beginJob ()
 Inizialize parameters for histo binning.
void endJob (void)
 QcdHighPtDQM (const edm::ParameterSet &)
 Constructor.
virtual ~QcdHighPtDQM ()
 Destructor.

Private Member Functions

float moverl (const reco::CaloMETCollection &metcollection, float &ljpt)
float movers (const reco::CaloMETCollection &metcollection)

Private Attributes

edm::InputTag jetLabel_
std::map< std::string,
MonitorElement * > 
MEcontainer_
edm::InputTag metLabel1_
edm::InputTag metLabel2_
edm::InputTag metLabel3_
edm::InputTag metLabel4_
DQMStoretheDbe

Detailed Description

DQM Physics Module for High Pt QCD group

Based on DQM/SiPixel and DQM/Physics code Version 1.0, 7/7/09 By Keith Rose

Definition at line 26 of file QcdHighPtDQM.h.


Constructor & Destructor Documentation

QcdHighPtDQM::QcdHighPtDQM ( const edm::ParameterSet iConfig)

Constructor.

Definition at line 35 of file QcdHighPtDQM.cc.

References cppFunctionSkipper::operator, and theDbe.

QcdHighPtDQM::~QcdHighPtDQM ( ) [virtual]

Destructor.

Definition at line 47 of file QcdHighPtDQM.cc.

                            { 
  

}

Member Function Documentation

void QcdHighPtDQM::analyze ( const edm::Event iEvent,
const edm::EventSetup iSetup 
) [virtual]

Get the analysis.

Implements edm::EDAnalyzer.

Definition at line 138 of file QcdHighPtDQM.cc.

References reco::LeafCandidate::energy(), edm::Event::getByLabel(), jetLabel_, fwrapper::jets, M_PI, MEcontainer_, CaloMET_cfi::met, CaloMET_cfi::metHO, metLabel1_, metLabel2_, metLabel3_, metLabel4_, CaloMET_cfi::metNoHF, CaloMET_cfi::metNoHFHO, movers(), reco::LeafCandidate::p4(), and reco::LeafCandidate::pt().

                                                                        {
  
  //Get Jets
  edm::Handle<CaloJetCollection> jetHandle;
  iEvent.getByLabel(jetLabel_,jetHandle);
  const CaloJetCollection & jets = *jetHandle;
  CaloJetCollection::const_iterator jet_iter;

  //Get MET collections
  edm::Handle<CaloMETCollection> metHandle;
  iEvent.getByLabel(metLabel1_, metHandle);
  const CaloMETCollection &met = *metHandle;

  edm::Handle<CaloMETCollection> metHOHandle;
  iEvent.getByLabel(metLabel2_, metHOHandle);
  const CaloMETCollection &metHO = *metHOHandle;
  
  edm::Handle<CaloMETCollection> metNoHFHandle;
  iEvent.getByLabel(metLabel3_, metNoHFHandle);
  const CaloMETCollection &metNoHF = *metNoHFHandle;

  edm::Handle<CaloMETCollection> metNoHFHOHandle;
  iEvent.getByLabel(metLabel4_, metNoHFHOHandle);
  const CaloMETCollection &metNoHFHO = *metNoHFHOHandle;

  //initialize leading jet value and jet multiplicity counter
  int njets = 0;
  int njets30 = 0;
  float leading_jetpt = 0;
  float leading_jeteta = 0;

  //initialize variables for picking out leading 2 barrel jets
  reco::CaloJet leadingbarreljet; 
  reco::CaloJet secondbarreljet;
  int nbarreljets = 0;

  //get bins in eta.  
  //Bins correspond to calotower regions.

  const float etabins[83] = {-5.191, -4.889, -4.716, -4.538, -4.363, -4.191, -4.013, -3.839, -3.664, -3.489, -3.314, -3.139, -2.964, -2.853, -2.650, -2.500, -2.322, -2.172, -2.043, -1.930, -1.830, -1.740, -1.653, -1.566, -1.479, -1.392, -1.305, -1.218, -1.131, -1.044, -.957, -.879, -.783, -.696, -.609, -.522, -.435, -.348, -.261, -.174, -.087, 0, .087, .174, .261, .348, .435, .522, .609, .696, .783, .879, .957, 1.044, 1.131, 1.218, 1.305, 1.392, 1.479, 1.566, 1.653, 1.740, 1.830, 1.930, 2.043, 2.172, 2.322, 2.500, 2.650, 2.853, 2.964, 3.139, 3.314, 3.489, 3.664, 3.839, 4.013, 4.191, 4.363, 4.538, 4.889, 5.191};

  for(jet_iter = jets.begin(); jet_iter!= jets.end(); ++jet_iter){
    njets++;
  
    //get Jet stats
    float jet_pt = jet_iter->pt();
    float jet_eta = jet_iter->eta();
    float jet_phi = jet_iter->phi();

    //fill jet Pt and jet EMF
    MEcontainer_["inclusive_jet_pt"]->Fill(jet_pt);
    MEcontainer_["inclusive_jet_EMF"]->Fill(jet_iter->emEnergyFraction());

    // pick out up to the first 2 leading barrel jets
    // for use in calculating dijet mass in barrel region
    // also fill jet Pt histogram for barrel

    if(jet_eta <= 1.3){
      MEcontainer_["inclusive_jet_pt_barrel"]->Fill(jet_pt);
      if(nbarreljets == 0){
        leadingbarreljet = jets[(njets-1)];
        nbarreljets++;
      }
      else if(nbarreljets == 1){
        secondbarreljet = jets[(njets-1)];
        nbarreljets++;
      }

    }

    // fill jet Pt for endcap and forward regions
    else if(jet_eta <= 3.0 && jet_eta > 1.3){MEcontainer_["inclusive_jet_pt_endcap"]->Fill(jet_pt);}

    else if(jet_eta <= 5.0 && jet_eta > 3.0){MEcontainer_["inclusive_jet_pt_forward"]->Fill(jet_pt);}


    // count jet multiplicity for jets with Pt > 30
    if((jet_pt) > 30) njets30++;

    // check leading jet quantities
    if(jet_pt > leading_jetpt){
      leading_jetpt = jet_pt;
      leading_jeteta = jet_eta;
    }

    //fill eta-phi plot
    for (int eit = 0; eit < 81; eit++){
      for(int pit = 0; pit < 72; pit++){
        float low_eta = etabins[eit];
        float high_eta = etabins[eit+1];
        float low_phi = (-M_PI) + pit*(M_PI/36);
        float high_phi = low_phi + (M_PI/36);
        if(jet_eta > low_eta && jet_eta < high_eta && jet_phi > low_phi && jet_phi < high_phi){
          MEcontainer_["etaphi"]->Fill((eit - 41), jet_phi);}


      }
    }
  }
  
  // after iterating over all jets, fill leading jet quantity histograms 
  // and jet multiplicity histograms

  MEcontainer_["leading_jet_pt"]->Fill(leading_jetpt);
  
  if(leading_jeteta <= 1.3){MEcontainer_["leading_jet_pt_barrel"]->Fill(leading_jetpt);}

  else if(leading_jeteta <= 3.0 && leading_jeteta > 1.3){MEcontainer_["leading_jet_pt_endcap"]->Fill(leading_jetpt);}

  else if(leading_jeteta <= 5.0 && leading_jeteta > 3.0){MEcontainer_["leading_jet_pt_forward"]->Fill(leading_jetpt);}

  MEcontainer_["njets"]->Fill(njets);

  MEcontainer_["njets30"]->Fill(njets30);

  // fill MET over Sum ET and Leading jet PT for all MET flavors
  MEcontainer_["movers_met"]->Fill(movers(met));
  MEcontainer_["moverl_met"]->Fill(movers(met), leading_jetpt);
  MEcontainer_["movers_metho"]->Fill(movers(metHO));
  MEcontainer_["moverl_metho"]->Fill(movers(metHO), leading_jetpt);
  MEcontainer_["movers_metnohf"]->Fill(movers(metNoHF));
  MEcontainer_["moverl_metnohf"]->Fill(movers(metNoHF), leading_jetpt);
  MEcontainer_["movers_metnohfho"]->Fill(movers(metNoHFHO));
  MEcontainer_["moverl_metnohfho"]->Fill(movers(metNoHFHO), leading_jetpt);
  

  // fetch first 3 jet EMF

  if(jets.size() >= 1){
    MEcontainer_["leading_jet_EMF"]->Fill(jets[0].emEnergyFraction());
    if(jets.size() >=2){
      MEcontainer_["second_jet_EMF"]->Fill(jets[1].emEnergyFraction());    
      if(jets.size() >= 3){
        MEcontainer_["third_jet_EMF"]->Fill(jets[2].emEnergyFraction());
      }
    }
  }

  // if 2 nontrivial barrel jets, reconstruct dijet mass

  if(nbarreljets == 2){
    if(leadingbarreljet.energy() > 0 && secondbarreljet.energy() > 0){
      math::XYZTLorentzVector DiJet = leadingbarreljet.p4() + secondbarreljet.p4();
      float dijet_mass = DiJet.mass();
        MEcontainer_["dijet_mass"]->Fill(dijet_mass);
    }
  }
      
    
}
void QcdHighPtDQM::beginJob ( void  ) [virtual]

Inizialize parameters for histo binning.

Reimplemented from edm::EDAnalyzer.

Definition at line 53 of file QcdHighPtDQM.cc.

References DQMStore::book1D(), DQMStore::book2D(), M_PI, MEcontainer_, DQMStore::setCurrentFolder(), and theDbe.

                            {
 

  //Book MEs
 
  theDbe->setCurrentFolder("Physics/QcdHighPt");  

  MEcontainer_["dijet_mass"] = theDbe->book1D("dijet_mass", "dijet resonance invariant mass, barrel region", 100, 0, 1000);
  MEcontainer_["njets"] = theDbe->book1D("njets", "jet multiplicity", 10, 0, 10);
  MEcontainer_["etaphi"] = theDbe->book2D("etaphi", "eta/phi distribution", 83, -42, 42, 72, -M_PI, M_PI);
  MEcontainer_["njets30"] = theDbe->book1D("njets30", "jet multiplicity, pt > 30 GeV", 10, 0, 10);

  //book histograms for inclusive jet quantities
  MEcontainer_["inclusive_jet_pt"] = theDbe->book1D("inclusive_jet_pt", "inclusive jet Pt spectrum", 100, 0, 1000);
  MEcontainer_["inclusive_jet_pt_barrel"] = theDbe->book1D("inclusive_jet_pt_barrel", "inclusive jet Pt, eta < 1.3", 100, 0, 1000);
  MEcontainer_["inclusive_jet_pt_forward"] = theDbe->book1D("inclusive_jet_pt_forward", "inclusive jet Pt, 3.0 < eta < 5.0", 100, 0, 1000);
  MEcontainer_["inclusive_jet_pt_endcap"] = theDbe->book1D("inclusive_jet_pt_endcap", "inclusive jet Pt, 1.3 < eta < 3.0", 100, 0, 1000);

  //book histograms for leading jet quantities
  MEcontainer_["leading_jet_pt"] = theDbe->book1D("leading_jet_pt", "leading jet Pt", 100, 0, 1000);
  MEcontainer_["leading_jet_pt_barrel"] = theDbe->book1D("leading_jet_pt_barrel", "leading jet Pt, eta < 1.3", 100, 0, 1000);
  MEcontainer_["leading_jet_pt_forward"] = theDbe->book1D("leading_jet_pt_forward", "leading jet Pt, 3.0 < eta < 5.0", 100, 0, 1000);
  MEcontainer_["leading_jet_pt_endcap"] = theDbe->book1D("leading_jet_pt_endcap", "leading jet Pt, 1.3 < eta < 3.0", 100, 0, 1000);

  //book histograms for met over sum et and met over leading jet pt for various
  //flavors of MET
  MEcontainer_["movers_met"] = theDbe->book1D("movers_met", "MET over Sum ET for basic MET collection", 50, 0, 1);
  MEcontainer_["moverl_met"] = theDbe->book1D("moverl_met", "MET over leading jet Pt for basic MET collection", 50, 0, 2);
  
  MEcontainer_["movers_metho"] = theDbe->book1D("movers_metho", "MET over Sum ET for MET HO collection", 50, 0, 1);
  MEcontainer_["moverl_metho"] = theDbe->book1D("moverl_metho", "MET over leading jet Pt for MET HO collection", 50, 0, 2);
  
  MEcontainer_["movers_metnohf"] = theDbe->book1D("movers_metnohf", "MET over Sum ET for MET no HF collection", 50, 0, 1);
  MEcontainer_["moverl_metnohf"] = theDbe->book1D("moverl_metnohf", "MET over leading jet Pt for MET no HF collection", 50, 0, 2);

  MEcontainer_["movers_metnohfho"] = theDbe->book1D("movers_metnohfho", "MET over Sum ET for MET no HF HO collection", 50, 0, 1);
  MEcontainer_["moverl_metnohfho"] = theDbe->book1D("moverl_metnohfho", "MET over leading jet Pt for MET no HF HO collection", 50, 0, 2);

  //book histograms for EMF fraction for all jets and first 3 jets
  MEcontainer_["inclusive_jet_EMF"] = theDbe->book1D("inclusive_jet_EMF", "inclusive jet EMF", 50, -1, 1);
  MEcontainer_["leading_jet_EMF"] = theDbe->book1D("leading_jet_EMF", "leading jet EMF", 50, -1, 1);
  MEcontainer_["second_jet_EMF"] = theDbe->book1D("second_jet_EMF", "second jet EMF", 50, -1, 1);
  MEcontainer_["third_jet_EMF"] = theDbe->book1D("third_jet_EMF", "third jet EMF", 50, -1, 1);
  



}
void QcdHighPtDQM::endJob ( void  ) [virtual]

Reimplemented from edm::EDAnalyzer.

Definition at line 102 of file QcdHighPtDQM.cc.

                              {

}
float QcdHighPtDQM::moverl ( const reco::CaloMETCollection metcollection,
float &  ljpt 
) [private]

Definition at line 124 of file QcdHighPtDQM.cc.

References CaloMET_cfi::met, and mathSSE::sqrt().

                                                                              {
 float metoverl = 0;
 CaloMETCollection::const_iterator met_iter;
 for(met_iter = metcollection.begin(); met_iter!= metcollection.end(); ++met_iter)
   {
     float mex = met_iter->momentum().x();
     float mey = met_iter->momentum().y();
     float met = sqrt(mex*mex+mey*mey);
     metoverl = (met / ljpt);
   }
 return metoverl;
}
float QcdHighPtDQM::movers ( const reco::CaloMETCollection metcollection) [private]

Definition at line 107 of file QcdHighPtDQM.cc.

References CaloMET_cfi::met, and mathSSE::sqrt().

Referenced by analyze().

                                                                 {

  float metovers = 0;
  CaloMETCollection::const_iterator met_iter;
  for(met_iter = metcollection.begin(); met_iter!= metcollection.end(); ++met_iter)
    {
      float mex = met_iter->momentum().x();
      float mey = met_iter->momentum().y();
      float met = sqrt(mex*mex+mey*mey);
      float sumet = met_iter->sumEt();
      metovers = (met / sumet);
    }
  return metovers;
}

Member Data Documentation

Definition at line 53 of file QcdHighPtDQM.h.

Referenced by analyze().

std::map<std::string, MonitorElement*> QcdHighPtDQM::MEcontainer_ [private]

Definition at line 60 of file QcdHighPtDQM.h.

Referenced by analyze(), and beginJob().

Definition at line 54 of file QcdHighPtDQM.h.

Referenced by analyze().

Definition at line 55 of file QcdHighPtDQM.h.

Referenced by analyze().

Definition at line 56 of file QcdHighPtDQM.h.

Referenced by analyze().

Definition at line 57 of file QcdHighPtDQM.h.

Referenced by analyze().

Definition at line 50 of file QcdHighPtDQM.h.

Referenced by beginJob(), and QcdHighPtDQM().