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Public Member Functions | Private Attributes

PFClusterWidthAlgo Class Reference

#include <PFClusterWidthAlgo.h>

List of all members.

Public Member Functions

 PFClusterWidthAlgo (const std::vector< const reco::PFCluster * > &pfclust, const EBRecHitCollection *ebRecHits=0, const EERecHitCollection *eeRecHits=0)
double pflowEtaWidth () const
double pflowPhiWidth () const
double pflowSigmaEtaEta () const
 ~PFClusterWidthAlgo ()

Private Attributes

double etaWidth_
double phiWidth_
double sigmaEtaEta_

Detailed Description

Definition at line 6 of file PFClusterWidthAlgo.h.


Constructor & Destructor Documentation

PFClusterWidthAlgo::PFClusterWidthAlgo ( const std::vector< const reco::PFCluster * > &  pfclust,
const EBRecHitCollection ebRecHits = 0,
const EERecHitCollection eeRecHits = 0 
)

Definition at line 13 of file PFClusterWidthAlgo.cc.

References RecoTauValidation_cfi::denominator, dPhi(), DetId::Ecal, EcalBarrel, EcalEndcap, edm::SortedCollection< T, SORT >::end(), edm::SortedCollection< T, SORT >::find(), getHLTprescales::index, edm::Ref< C, T, F >::isAvailable(), Pi, mathSSE::sqrt(), and TwoPi.

                                                                            {


  double numeratorEtaWidth = 0.;
  double numeratorPhiWidth = 0.;
  double sclusterE = 0.;
  double posX = 0.;
  double posY = 0.;
  double posZ = 0.;
  sigmaEtaEta_ = 0.;

  unsigned int nclust= pfclust.size();
  if(nclust == 0 ) {
    etaWidth_ = 0.;
    phiWidth_ = 0.;
    sigmaEtaEta_ = 0.;
  }
  else {

    for(unsigned int icl=0;icl<nclust;++icl) {
      double e = pfclust[icl]->energy();
      sclusterE += e;
      posX += e * pfclust[icl]->position().X();
      posY += e * pfclust[icl]->position().Y();
      posZ += e * pfclust[icl]->position().Z();   
    }
    
    posX /=sclusterE;
    posY /=sclusterE;
    posZ /=sclusterE;
    
    double denominator = sclusterE;
    
    math::XYZPoint pflowSCPos(posX,posY,posZ);
    
    double scEta    = pflowSCPos.eta();
    double scPhi    = pflowSCPos.phi();
    
    double SeedClusEnergy = -1.;
    unsigned int SeedDetID = 0;
    double SeedEta = -1.;
    double SeedPhi = -1.;

    for(unsigned int icl=0; icl<nclust; ++icl) {
      const std::vector< reco::PFRecHitFraction >& PFRecHits =  pfclust[icl]->recHitFractions();
      
      
      for ( std::vector< reco::PFRecHitFraction >::const_iterator it = PFRecHits.begin(); 
            it != PFRecHits.end(); ++it) {
        const PFRecHitRef& RefPFRecHit = it->recHitRef(); 
        double energyHit=0;
        // if the PFRecHit is not available, try to get it from the collections
        //      if(!RefPFRecHit.isAvailable() && ebRecHits && eeRecHits )
        if(ebRecHits && eeRecHits )
          {
            //      std::cout << " Recomputing " << std::endl;
            unsigned index=it-PFRecHits.begin();
            DetId id=pfclust[icl]->hitsAndFractions()[index].first;
            // look for the hit; do not forget to multiply by the fraction
            if(id.det()==DetId::Ecal && id.subdetId()==EcalBarrel)
              {
                EBRecHitCollection::const_iterator itcheck=ebRecHits->find(id);
                if(itcheck!=ebRecHits->end())
                  energyHit= itcheck->energy();
                // The cluster shapes do not take into account the RecHit fraction !            
                // * pfclust[icl]->hitsAndFractions()[index].second;
              }
            if(id.det()==DetId::Ecal && id.subdetId()==EcalEndcap)
              {
                EERecHitCollection::const_iterator itcheck=eeRecHits->find(id);
                if(itcheck!=eeRecHits->end())
                  energyHit= itcheck->energy();
                // The cluster shapes do not take into account the RecHit fraction !            
                //               * pfclust[icl]->hitsAndFractions()[index].second;
              }
          }
        else
          energyHit = RefPFRecHit->energy();

        //only for the first cluster (from GSF) find the seed
        if(icl==0) {
          if (energyHit > SeedClusEnergy) {
            SeedClusEnergy = energyHit;
            SeedEta = RefPFRecHit->position().eta();
            SeedPhi =  RefPFRecHit->position().phi();
            SeedDetID = RefPFRecHit->detId();
          }
        }


        double dPhi = RefPFRecHit->position().phi() - scPhi;
        if (dPhi > + TMath::Pi()) { dPhi = TMath::TwoPi() - dPhi; }
        if (dPhi < - TMath::Pi()) { dPhi = TMath::TwoPi() + dPhi; }
        double dEta = RefPFRecHit->position().eta() - scEta;
        if ( energyHit > 0 ) {
          numeratorEtaWidth += energyHit * dEta * dEta;
          numeratorPhiWidth += energyHit * dPhi * dPhi;
        }
      }
    } // end for ncluster

    //for the first cluster (from GSF) computed sigmaEtaEta
    const std::vector< reco::PFRecHitFraction >& PFRecHits =  pfclust[0]->recHitFractions();
    for ( std::vector< reco::PFRecHitFraction >::const_iterator it = PFRecHits.begin(); 
          it != PFRecHits.end(); ++it) {
      const PFRecHitRef& RefPFRecHit = it->recHitRef(); 
      if(!RefPFRecHit.isAvailable()) 
        return;
      double energyHit = RefPFRecHit->energy();
      if (RefPFRecHit->detId() != SeedDetID) {
        float diffEta =  RefPFRecHit->position().eta() - SeedEta;
        sigmaEtaEta_ += (diffEta*diffEta) * (energyHit/SeedClusEnergy);
      }
    }
    if (sigmaEtaEta_ == 0.) sigmaEtaEta_ = 0.00000001;

    etaWidth_ = sqrt(numeratorEtaWidth / denominator);
    phiWidth_ = sqrt(numeratorPhiWidth / denominator);
    

  } // endif ncluster > 0
}
PFClusterWidthAlgo::~PFClusterWidthAlgo ( )

Definition at line 137 of file PFClusterWidthAlgo.cc.

{
}

Member Function Documentation

double PFClusterWidthAlgo::pflowEtaWidth ( ) const [inline]
double PFClusterWidthAlgo::pflowPhiWidth ( ) const [inline]
double PFClusterWidthAlgo::pflowSigmaEtaEta ( ) const [inline]

Definition at line 20 of file PFClusterWidthAlgo.h.

References sigmaEtaEta_.

Referenced by PFElectronAlgo::SetIDOutputs().

{return sigmaEtaEta_;}

Member Data Documentation

Definition at line 26 of file PFClusterWidthAlgo.h.

Referenced by pflowEtaWidth().

Definition at line 25 of file PFClusterWidthAlgo.h.

Referenced by pflowPhiWidth().

Definition at line 27 of file PFClusterWidthAlgo.h.

Referenced by pflowSigmaEtaEta().