#include <MuonCaloCompatibility.h>

Public Member Functions
void	configure (const edm::ParameterSet &)

double	evaluate (const reco::Muon &)

	MuonCaloCompatibility ()

Private Member Functions
bool	accessing_overflow (TH2D *histo, double x, double y)

Private Attributes
bool	isConfigured_

double	muon_compatibility

TH2D *	muon_em_etaB

TH2D *	muon_em_etaEmi

TH2D *	muon_em_etaEpl

TH2D *	muon_em_etaTmi

TH2D *	muon_em_etaTpl

TH2D *	muon_had_etaB

TH2D *	muon_had_etaEmi

TH2D *	muon_had_etaEpl

TH2D *	muon_had_etaTmi

TH2D *	muon_had_etaTpl

TH2D *	muon_ho_etaB

TH2D *	muon_template_em

TH2D *	muon_template_had

TH2D *	muon_template_ho

boost::shared_ptr< TFile >	muon_templates

std::string	MuonfileName_

double	pbx

double	pby

double	pbz

TH2D *	pion_em_etaB

TH2D *	pion_em_etaEmi

TH2D *	pion_em_etaEpl

TH2D *	pion_em_etaTmi

TH2D *	pion_em_etaTpl

TH2D *	pion_had_etaB

TH2D *	pion_had_etaEmi

TH2D *	pion_had_etaEpl

TH2D *	pion_had_etaTmi

TH2D *	pion_had_etaTpl

TH2D *	pion_ho_etaB

TH2D *	pion_template_em

TH2D *	pion_template_had

TH2D *	pion_template_ho

boost::shared_ptr< TFile >	pion_templates

std::string	PionfileName_

double	psx

double	psy

double	psz

bool	use_corrected_hcal

bool	use_em_special

Detailed Description

Definition at line 27 of file MuonCaloCompatibility.h.

Constructor & Destructor Documentation

MuonCaloCompatibility::MuonCaloCompatibility ( )

inline

Definition at line 29 of file MuonCaloCompatibility.h.

29 :isConfigured_(false){}

MuonCaloCompatibility::isConfigured_

bool isConfigured_

Definition: MuonCaloCompatibility.h:34

Member Function Documentation

bool MuonCaloCompatibility::accessing_overflow	(	TH2D *	histo,
		double	x,
		double	y
	)

private

Definition at line 74 of file MuonCaloCompatibility.cc.

Referenced by evaluate().

                                                                                 {
   bool access = false;
 
   if( histo->GetXaxis()->FindBin(x) == 0 || 
       histo->GetXaxis()->FindBin(x) > histo->GetXaxis()->GetNbins() ) {
     access = true;
   }
   if( histo->GetYaxis()->FindBin(y) == 0 || 
       histo->GetYaxis()->FindBin(y) > histo->GetYaxis()->GetNbins() ) {
     access = true;
   }
   return access;
 }

void MuonCaloCompatibility::configure ( const edm::ParameterSet & iConfig )

Definition at line 20 of file MuonCaloCompatibility.cc.

References edm::ParameterSet::getParameter(), isConfigured_, muon_compatibility, muon_em_etaB, muon_em_etaEmi, muon_em_etaEpl, muon_em_etaTmi, muon_em_etaTpl, muon_had_etaB, muon_had_etaEmi, muon_had_etaEpl, muon_had_etaTmi, muon_had_etaTpl, muon_ho_etaB, muon_templates, MuonfileName_, pbx, pby, pbz, pion_em_etaB, pion_em_etaEmi, pion_em_etaEpl, pion_em_etaTmi, pion_em_etaTpl, pion_had_etaB, pion_had_etaEmi, pion_had_etaEpl, pion_had_etaTmi, pion_had_etaTpl, pion_ho_etaB, pion_templates, PionfileName_, psx, psy, psz, use_corrected_hcal, and use_em_special.

Referenced by MuonIdProducer::MuonIdProducer().

 {
    MuonfileName_ = (iConfig.getParameter<edm::FileInPath>("MuonTemplateFileName")).fullPath();
    PionfileName_ = (iConfig.getParameter<edm::FileInPath>("PionTemplateFileName")).fullPath();
    muon_templates.reset( new TFile(MuonfileName_.c_str(),"READ") );
    pion_templates.reset( new TFile(PionfileName_.c_str(),"READ") );
 
    pion_em_etaEmi  = (TH2D*) pion_templates->Get("em_etaEmi");
    pion_had_etaEmi = (TH2D*) pion_templates->Get("had_etaEmi");
             
    pion_em_etaTmi  = (TH2D*) pion_templates->Get("em_etaTmi");
    pion_had_etaTmi = (TH2D*) pion_templates->Get("had_etaTmi");
         
    pion_em_etaB    = (TH2D*) pion_templates->Get("em_etaB");
    pion_had_etaB   = (TH2D*) pion_templates->Get("had_etaB");
    pion_ho_etaB    = (TH2D*) pion_templates->Get("ho_etaB");
    
    pion_em_etaTpl  = (TH2D*) pion_templates->Get("em_etaTpl");
    pion_had_etaTpl = (TH2D*) pion_templates->Get("had_etaTpl");
             
    pion_em_etaEpl  = (TH2D*) pion_templates->Get("em_etaEpl");
    pion_had_etaEpl = (TH2D*) pion_templates->Get("had_etaEpl");
         
    muon_em_etaEmi  = (TH2D*) muon_templates->Get("em_etaEmi");
    muon_had_etaEmi = (TH2D*) muon_templates->Get("had_etaEmi");
             
    muon_em_etaTmi  = (TH2D*) muon_templates->Get("em_etaTmi");
    muon_had_etaTmi = (TH2D*) muon_templates->Get("had_etaTmi");
             
    muon_em_etaB    = (TH2D*) muon_templates->Get("em_etaB");
    muon_had_etaB   = (TH2D*) muon_templates->Get("had_etaB");
    muon_ho_etaB    = (TH2D*) muon_templates->Get("ho_etaB");
             
    muon_em_etaTpl  = (TH2D*) muon_templates->Get("em_etaTpl");
    muon_had_etaTpl = (TH2D*) muon_templates->Get("had_etaTpl");
         
    muon_em_etaEpl  = (TH2D*) muon_templates->Get("em_etaEpl");
    muon_had_etaEpl = (TH2D*) muon_templates->Get("had_etaEpl");
 
    pbx = -1;
    pby = -1;
    pbz = -1;
 
    psx = -1;
    psy = -1;
    psz = -1;
 
    muon_compatibility = -1;
 
    use_corrected_hcal = true;
    use_em_special = true;
    isConfigured_ = true;
 }

double MuonCaloCompatibility::evaluate ( const reco::Muon & amuon )

Definition at line 88 of file MuonCaloCompatibility.cc.

References accessing_overflow(), reco::Muon::calEnergy(), reco::MuonEnergy::em, reco::TrackBase::eta(), eta(), edm::hlt::Exception, edm::Ref< C, T, F >::get(), reco::MuonEnergy::had, reco::MuonEnergy::ho, isConfigured_, edm::Ref< C, T, F >::isNull(), LogTrace, muon_compatibility, muon_em_etaB, muon_em_etaEmi, muon_em_etaEpl, muon_em_etaTmi, muon_em_etaTpl, muon_had_etaB, muon_had_etaEmi, muon_had_etaEpl, muon_had_etaTmi, muon_had_etaTpl, muon_ho_etaB, muon_template_em, muon_template_had, muon_template_ho, NULL, L1TEmulatorMonitor_cff::p, reco::TrackBase::p(), pbx, pby, pbz, pion_em_etaB, pion_em_etaEmi, pion_em_etaEpl, pion_em_etaTmi, pion_em_etaTpl, pion_had_etaB, pion_had_etaEmi, pion_had_etaEpl, pion_had_etaTmi, pion_had_etaTpl, pion_ho_etaB, pion_template_em, pion_template_had, pion_template_ho, psx, psy, psz, funct::sin(), reco::Muon::standAloneMuon(), reco::TrackBase::theta(), reco::Muon::track(), use_corrected_hcal, and use_em_special.

Referenced by MuonIdProducer::makeCaloMuon(), and MuonIdProducer::produce().

                                                               {
   if (! isConfigured_) {
      edm::LogWarning("MuonIdentification") << "MuonCaloCompatibility is not configured! Nothing is calculated.";
      return -9999;
   }
    
   double eta = 0.;
   double p   = 0.;
   double em  = 0.;
   double had = 0.;
   double ho  = 0.;
 
   // had forgotten this reset in previous versions 070409
   pbx = 1.;
   pby = 1.;
   pbz = 1.;
 
   psx = 1.;
   psy = 1.;
   psz = 1.;
 
   muon_compatibility = -1.;
   
   pion_template_em   = NULL;
   muon_template_em   = NULL;
   
   pion_template_had  = NULL;
   muon_template_had  = NULL;
   
   pion_template_ho   = NULL;
   muon_template_ho   = NULL;
   
   // 071002: Get either tracker track, or SAmuon track.
   // CaloCompatibility templates may have to be specialized for 
   // the use with SAmuons, currently just using the ones produced
   // using tracker tracks. 
   const reco::Track* track = 0;
   if ( ! amuon.track().isNull() ) {
     track = amuon.track().get();
   }
   else {
     if ( ! amuon.standAloneMuon().isNull() ) {
       track = amuon.standAloneMuon().get();
     }
     else {
       throw cms::Exception("FatalError") << "Failed to fill muon id calo_compatibility information for a muon with undefined references to tracks"; 
     }
   }
 
   if( !use_corrected_hcal ) { // old eta regions, uncorrected energy
     eta = track->eta();
     p   = track->p(); 
 
     // new 070904: Set lookup momentum to 1999.9 if larger than 2 TeV. 
     // Though the templates were produced with p<2TeV, we believe that
     // this approximation should be roughly valid. A special treatment
     // for >1 TeV muons is advisable anyway :)
     if( p>=2000. ) p = 1999.9;
 
     //    p   = 10./sin(track->theta()); // use this for templates < 1_5
     if( use_em_special ) {
       if( amuon.calEnergy().em == 0. )    em  = -5.;
       else em  = amuon.calEnergy().em;
     }
     else {
       em  = amuon.calEnergy().em;
     }
     had = amuon.calEnergy().had;
     ho  = amuon.calEnergy().ho;
   }
   else {
     eta = track->eta();
     p   = track->p();
     
     // new 070904: Set lookup momentum to 1999.9 if larger than 2 TeV. 
     // Though the templates were produced with p<2TeV, we believe that
     // this approximation should be roughly valid. A special treatment
     // for >1 TeV muons is advisable anyway :)
     if( p>=2000. ) p = 1999.9;
 
     //    p   = 10./sin(track->theta());  // use this for templates < 1_5
     // hcal energy is now done where we get the template histograms (to use corrected cal energy)!
     //     had = amuon.calEnergy().had;
     if( use_em_special ) {
       if( amuon.calEnergy().em == 0. )    em  = -5.;
       else em  = amuon.calEnergy().em;
     }
     else {
       em  = amuon.calEnergy().em;
     }
     ho  = amuon.calEnergy().ho;
   }
 
 
   // Skip everyting and return "I don't know" (i.e. 0.5) for uncovered regions:
   //  if( p < 0. || p > 500.) return 0.5; // removed 500 GeV cutoff 070817 after updating the tempates (v2_0) to have valid entried beyond 500 GeV
   if( p < 0. ) return 0.5; // return "unknown" for unphysical momentum input.
   if( fabs(eta) >  2.5 ) return 0.5; 
   // temporary fix for low association efficiency:
   // set caloCompatibility to 0.12345 for tracks
   // which have 0 energy in BOTH ecal and hcal
   if( amuon.calEnergy().had == 0.0 && amuon.calEnergy().em == 0.0 ) return 0.12345; 
 
   //  std::cout<<std::endl<<"Input values are: "<<eta <<" "<< p <<" "<< em <<" "<< had <<" "<< ho;
 
   //  depending on the eta, choose correct histogram: (now all for barrel):
   // bad! eta range has to be syncronised with choice for histogram... should be read out from the histo file somehow... 070322
   if(42 != 42) { // old eta ranges and uncorrected hcal energy
     if(eta <= -1.4) {
       //    std::cout<<"Emi"<<std::endl;
       pion_template_em  = pion_em_etaEmi;
       pion_template_had = pion_had_etaEmi;
       muon_template_em  = muon_em_etaEmi;
       muon_template_had = muon_had_etaEmi;
     }
     else if(eta > -1.4 && eta <= -1.31) {
       //    std::cout<<"Tmi"<<std::endl;
       pion_template_em  = pion_em_etaTmi;
       pion_template_had = pion_had_etaTmi;
       muon_template_em  = muon_em_etaTmi;
       muon_template_had = muon_had_etaTmi;
     }
     else if(eta > -1.31 && eta <= 1.31) {
       //    std::cout<<"B"<<std::endl;
       pion_template_em  = pion_em_etaB;
       pion_template_had = pion_had_etaB;
       pion_template_ho  = pion_ho_etaB;
       muon_template_em  = muon_em_etaB;
       muon_template_had = muon_had_etaB;
       muon_template_ho  = muon_ho_etaB;
     }
     else if(eta > 1.31 && eta <= 1.4) {
       //    std::cout<<"Tpl"<<std::endl;
       pion_template_em  = pion_em_etaTpl;
       pion_template_had = pion_had_etaTpl;
       muon_template_em  = muon_em_etaTpl;
       muon_template_had = muon_had_etaTpl;
     }
     else if(eta > 1.4) {
       //    std::cout<<"Epl"<<std::endl;
       pion_template_em  = pion_em_etaEpl;
       pion_template_had = pion_had_etaEpl;
       muon_template_em  = muon_em_etaEpl;
       muon_template_had = muon_had_etaEpl;
     }
     else {
       LogTrace("MuonIdentification")<<"Some very weird thing happened in MuonCaloCompatibility::evaluate - go figure ;) ";
       return -999;
     }
   }
   else if( 42 == 42 ) { // new eta bins, corrected hcal energy
     if(  track->eta() >  1.27  ) {
       //    had_etaEpl ->Fill(muon->track().get()->p(),1.8/2.2*muon->calEnergy().had );
       if(use_corrected_hcal)    had = 1.8/2.2*amuon.calEnergy().had;
       else  had = amuon.calEnergy().had;
       pion_template_had = pion_had_etaEpl;
       muon_template_had = muon_had_etaEpl;
     }
     if( track->eta() <=  1.27  && track->eta() >  1.1 ) {
       //    had_etaTpl ->Fill(muon->track().get()->p(),(1.8/(-2.2*muon->track().get()->eta()+5.5))*muon->calEnergy().had );
       if(use_corrected_hcal)    had = (1.8/(-2.2*track->eta()+5.5))*amuon.calEnergy().had;
       else  had = amuon.calEnergy().had;
       pion_template_had  = pion_had_etaTpl;
       muon_template_had  = muon_had_etaTpl;
     }
     if( track->eta() <=  1.1 && track->eta() > -1.1 ) {
       //    had_etaB   ->Fill(muon->track().get()->p(),sin(muon->track().get()->theta())*muon->calEnergy().had );
       if(use_corrected_hcal)    had = sin(track->theta())*amuon.calEnergy().had;
       else  had = amuon.calEnergy().had;
       pion_template_had  = pion_had_etaB;
       muon_template_had  = muon_had_etaB;
     }
     if( track->eta() <= -1.1 && track->eta() > -1.27 ) {
       //    had_etaTmi ->Fill(muon->track().get()->p(),(1.8/(-2.2*muon->track().get()->eta()+5.5))*muon->calEnergy().had );
       if(use_corrected_hcal)    had = (1.8/(2.2*track->eta()+5.5))*amuon.calEnergy().had;
       else  had = amuon.calEnergy().had;
       pion_template_had = pion_had_etaTmi;
       muon_template_had = muon_had_etaTmi;
     }
     if( track->eta() <= -1.27 ) {
       //    had_etaEmi ->Fill(muon->track().get()->p(),1.8/2.2*muon->calEnergy().had );
       if(use_corrected_hcal)    had = 1.8/2.2*amuon.calEnergy().had;
       else  had = amuon.calEnergy().had;
       pion_template_had = pion_had_etaEmi;
       muon_template_had = muon_had_etaEmi;
     }
     
     // just two eta regions for Ecal (+- 1.479 for barrel, else for rest), no correction:
 
     //    std::cout<<"We have a muon with an eta of: "<<track->eta()<<std::endl;
 
     if(  track->eta() >  1.479  ) {
       //    em_etaEpl  ->Fill(muon->track().get()->p(),muon->calEnergy().em   );
       //    //  em_etaTpl  ->Fill(muon->track().get()->p(),muon->calEnergy().em   );
       pion_template_em  = pion_em_etaEpl;
       muon_template_em  = muon_em_etaEpl;
     }
     if( track->eta() <=  1.479 && track->eta() > -1.479 ) {
       //    em_etaB    ->Fill(muon->track().get()->p(),muon->calEnergy().em   );
       pion_template_em  = pion_em_etaB;
       muon_template_em  = muon_em_etaB;
     }
     if( track->eta() <= -1.479 ) {
       //    //  em_etaTmi  ->Fill(muon->track().get()->p(),muon->calEnergy().em   );
       //    em_etaEmi  ->Fill(muon->track().get()->p(),muon->calEnergy().em   );
       pion_template_em  = pion_em_etaEmi;
       muon_template_em  = muon_em_etaEmi;
     }
     
     // just one barrel eta region for the HO, no correction
     //    if( track->eta() < 1.4 && track->eta() > -1.4 ) { // experimenting now...
     if( track->eta() < 1.28 && track->eta() > -1.28 ) {
       //    ho_etaB    ->Fill(muon->track().get()->p(),muon->calEnergy().ho   );
       pion_template_ho  = pion_ho_etaB;
       muon_template_ho  = muon_ho_etaB;
     }
 
     
   }
 
 
   if( 42 != 42 ) { // check validity of input template histos and input variables"
     pion_template_em ->ls();
     pion_template_had->ls();
     if(pion_template_ho)   pion_template_ho ->ls();
     muon_template_em ->ls();
     muon_template_had->ls();
     if(muon_template_ho)   muon_template_ho ->ls();
 
     LogTrace("MuonIdentification")<<"Input variables: eta    p     em     had    ho "<<"\n"
          <<eta<<" "<<p<<" "<<em<<" "<<had<<" "<<ho<<" "<<"\n"
          <<"cal uncorr:    em     had    ho "<<"\n"
          <<eta<<" "<<p<<" "<<amuon.calEnergy().em<<" "<<amuon.calEnergy().had<<" "<<amuon.calEnergy().ho;
   }
   
 
   //  Look up Compatibility by, where x is p and y the energy. 
   //  We have a set of different histograms for different regions of eta.
 
   // need error meassage in case the template histos are missing / the template file is not present!!! 070412
 
   if( pion_template_em )  { // access ecal background template
     if( accessing_overflow( pion_template_em, p, em ) ) {
       pbx = 1.;
       psx = 1.;
       LogTrace("MuonIdentification")<<"            // Message: trying to access overflow bin in MuonCompatibility template for ecal - defaulting signal and background  ";
       LogTrace("MuonIdentification")<<"            // template value to 1. "<<pion_template_em->GetName()<<" e: "<<em<<" p: "<<p;
     }
     else pbx =  pion_template_em->GetBinContent(  pion_template_em->GetXaxis()->FindBin(p), pion_template_em->GetYaxis()->FindBin(em) );
   }
   if( pion_template_had ) { // access hcal background template
     if( accessing_overflow( pion_template_had, p, had ) ) {
       pby = 1.;
       psy = 1.;
       LogTrace("MuonIdentification")<<"            // Message: trying to access overflow bin in MuonCompatibility template for hcal - defaulting signal and background  ";
       LogTrace("MuonIdentification")<<"            // template value to 1. "<<pion_template_had->GetName()<<" e: "<<had<<" p: "<<p;
     }
     else pby =  pion_template_had->GetBinContent(  pion_template_had->GetXaxis()->FindBin(p), pion_template_had->GetYaxis()->FindBin(had) );
   }
   if(pion_template_ho) { // access ho background template
     if( accessing_overflow( pion_template_ho, p, ho ) ) {
       pbz = 1.;
       psz = 1.;
       LogTrace("MuonIdentification")<<"            // Message: trying to access overflow bin in MuonCompatibility template for ho   - defaulting signal and background  ";
       LogTrace("MuonIdentification")<<"            // template value to 1. "<<pion_template_ho->GetName()<<" e: "<<em<<" p: "<<p; 
     }
     else pbz =  pion_template_ho->GetBinContent(  pion_template_ho->GetXaxis()->FindBin(p), pion_template_ho->GetYaxis()->FindBin(ho) );
   }
 
 
   if( muon_template_em )  { // access ecal background template
     if( accessing_overflow( muon_template_em, p, em ) ) {
       psx = 1.;
       pbx = 1.;
       LogTrace("MuonIdentification")<<"            // Message: trying to access overflow bin in MuonCompatibility template for ecal - defaulting signal and background  ";
       LogTrace("MuonIdentification")<<"            // template value to 1. "<<muon_template_em->GetName()<<" e: "<<em<<" p: "<<p;
     }
     else psx =  muon_template_em->GetBinContent(  muon_template_em->GetXaxis()->FindBin(p), muon_template_em->GetYaxis()->FindBin(em) );
   }
   if( muon_template_had ) { // access hcal background template
     if( accessing_overflow( muon_template_had, p, had ) ) {
       psy = 1.;
       pby = 1.;
       LogTrace("MuonIdentification")<<"            // Message: trying to access overflow bin in MuonCompatibility template for hcal - defaulting signal and background  ";
       LogTrace("MuonIdentification")<<"            // template value to 1. "<<muon_template_had->GetName()<<" e: "<<had<<" p: "<<p;
     }
     else psy =  muon_template_had->GetBinContent(  muon_template_had->GetXaxis()->FindBin(p), muon_template_had->GetYaxis()->FindBin(had) );
   }
   if(muon_template_ho) { // access ho background template
     if( accessing_overflow( muon_template_ho, p, ho ) ) {
       psz = 1.;
       pbz = 1.;
        LogTrace("MuonIdentification")<<"            // Message: trying to access overflow bin in MuonCompatibility template for ho   - defaulting signal and background  ";
        LogTrace("MuonIdentification")<<"            // template value to 1. "<<muon_template_ho->GetName()<<" e: "<<ho<<" p: "<<p;
     }
     else psz =  muon_template_ho->GetBinContent(  muon_template_ho->GetXaxis()->FindBin(p), muon_template_ho->GetYaxis()->FindBin(ho) );
   }
 
   // erm - what is this?!?! How could the HO probability be less than 0????? Do we want this line!?!?
   if(psz <= 0.) psz = 1.;
   if(pbz <= 0.) pbz = 1.;
 
   // Protection agains empty bins - set cal part to neutral if the bin of the template is empty 
   // (temporary fix, a proper extrapolation would be better)
   if (psx == 0. || pbx == 0.) {
     psx = 1.;
     pbx = 1.;
   } 
   if (psy == 0. || pby == 0.) {
     psy = 1.;
     pby = 1.;
   } 
   if (psz == 0. || pbz == 0.) {
     psz = 1.;
     pbz = 1.;
   }
 
   // There are two classes of events that deliver 0 for the hcal or ho energy:
   // 1) the track momentum is so low that the extrapolation tells us it should not have reached the cal
   // 2) the crossed cell had an reading below the readout cuts.
   // The 2nd case discriminates between muons and hadrons, the 1st not. Thus for the time being, 
   // we set the returned ps and pb to 0 for these cases.
   // We need to have a return value different from 0 for the 1st case in the long run.
   if ( had == 0.0 ) {
     psy = 1.;
     pby = 1.;
   } 
   if ( ho == 0.0 ) {
     psz = 1.;
     pbz = 1.;
   }
   
 
   // Set em to neutral if no energy in em or negative energy measured. 
   // (These cases might indicate problems in the ecal association or readout?! The only 
   // hint so far: for critical eta region (eta in [1.52, 1.64]) have negative em values.)
   if( em <= 0. && !use_em_special ) {
     pbx = 1.;
     psx = 1.;
   }
 
   if( (psx*psy*psz+pbx*pby*pbz) > 0. ) muon_compatibility = psx*psy*psz / (psx*psy*psz+pbx*pby*pbz);
   else {
     LogTrace("MuonIdentification")<<"Divide by 0 - defaulting consistency to 0.5 (neutral)!!";
     muon_compatibility = 0.5;
     LogTrace("MuonIdentification")<<"Input variables: eta    p     em     had    ho "<<"\n"
          <<eta<<" "<<p<<" "<<em<<" "<<had<<" "<<ho<<" "<<"\n"
          <<"cal uncorr:    em     had    ho "<<"\n"
          <<eta<<" "<<p<<" "<<amuon.calEnergy().em<<" "<<amuon.calEnergy().had<<" "<<amuon.calEnergy().ho;
   }
   return muon_compatibility;
 }

Member Data Documentation

bool MuonCaloCompatibility::isConfigured_

private

Definition at line 34 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

double MuonCaloCompatibility::muon_compatibility

private

Definition at line 83 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::muon_em_etaB

private

Definition at line 69 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::muon_em_etaEmi

private

Definition at line 73 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::muon_em_etaEpl

private

Definition at line 64 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::muon_em_etaTmi

private

Definition at line 71 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::muon_em_etaTpl

private

Definition at line 66 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::muon_had_etaB

private

Definition at line 68 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::muon_had_etaEmi

private

Definition at line 72 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::muon_had_etaEpl

private

Definition at line 63 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::muon_had_etaTmi

private

Definition at line 70 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::muon_had_etaTpl

private

Definition at line 65 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::muon_ho_etaB

private

Definition at line 67 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::muon_template_em

private

Definition at line 47 of file MuonCaloCompatibility.h.

Referenced by evaluate().

TH2D* MuonCaloCompatibility::muon_template_had

private

Definition at line 48 of file MuonCaloCompatibility.h.

Referenced by evaluate().

TH2D* MuonCaloCompatibility::muon_template_ho

private

Definition at line 49 of file MuonCaloCompatibility.h.

Referenced by evaluate().

boost::shared_ptr<TFile> MuonCaloCompatibility::muon_templates

private

Definition at line 42 of file MuonCaloCompatibility.h.

Referenced by configure().

std::string MuonCaloCompatibility::MuonfileName_

private

Definition at line 38 of file MuonCaloCompatibility.h.

Referenced by configure().

double MuonCaloCompatibility::pbx

private

Definition at line 75 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

double MuonCaloCompatibility::pby

private

Definition at line 76 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

double MuonCaloCompatibility::pbz

private

Definition at line 77 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::pion_em_etaB

private

Definition at line 57 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::pion_em_etaEmi

private

Definition at line 61 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::pion_em_etaEpl

private

Definition at line 52 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::pion_em_etaTmi

private

Definition at line 59 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::pion_em_etaTpl

private

Definition at line 54 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::pion_had_etaB

private

Definition at line 56 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::pion_had_etaEmi

private

Definition at line 60 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::pion_had_etaEpl

private

Definition at line 51 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::pion_had_etaTmi

private

Definition at line 58 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::pion_had_etaTpl

private

Definition at line 53 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::pion_ho_etaB

private

Definition at line 55 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

TH2D* MuonCaloCompatibility::pion_template_em

private

Definition at line 44 of file MuonCaloCompatibility.h.

Referenced by evaluate().

TH2D* MuonCaloCompatibility::pion_template_had

private

Definition at line 45 of file MuonCaloCompatibility.h.

Referenced by evaluate().

TH2D* MuonCaloCompatibility::pion_template_ho

private

Definition at line 46 of file MuonCaloCompatibility.h.

Referenced by evaluate().

boost::shared_ptr<TFile> MuonCaloCompatibility::pion_templates

private

Definition at line 41 of file MuonCaloCompatibility.h.

Referenced by configure().

std::string MuonCaloCompatibility::PionfileName_

private

Definition at line 39 of file MuonCaloCompatibility.h.

Referenced by configure().

double MuonCaloCompatibility::psx

private

Definition at line 79 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

double MuonCaloCompatibility::psy

private

Definition at line 80 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

double MuonCaloCompatibility::psz

private

Definition at line 81 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

bool MuonCaloCompatibility::use_corrected_hcal

private

Definition at line 85 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

bool MuonCaloCompatibility::use_em_special

private

Definition at line 86 of file MuonCaloCompatibility.h.

Referenced by configure(), and evaluate().

Public Member Functions

Private Member Functions

Private Attributes

Detailed Description

Constructor & Destructor Documentation

Member Function Documentation

Member Data Documentation