CMS 3D CMS Logo

/data/doxygen/doxygen-1.7.3/gen/CMSSW_4_2_8/src/RecoTauTag/RecoTau/plugins/RecoTauElectronRejectionPlugin.cc

Go to the documentation of this file.
00001 /*
00002  * ===========================================================================
00003  *
00004  *       Filename:  RecoTauElectronRejectionPlugin.cc
00005  *
00006  *    Description:  Add electron rejection information to PFTau
00007  *
00008  *         Authors:  Chi Nhan Nguyen, Simone Gennai, Evan Friis
00009  *
00010  * ===========================================================================
00011  */
00012 
00013 #include "RecoTauTag/RecoTau/interface/RecoTauBuilderPlugins.h"
00014 #include "DataFormats/TrackReco/interface/Track.h"
00015 #include "DataFormats/ParticleFlowCandidate/interface/PFCandidate.h"
00016 #include "DataFormats/ParticleFlowReco/interface/PFBlockElement.h"
00017 #include "DataFormats/ParticleFlowReco/interface/PFBlock.h"
00018 #include "DataFormats/ParticleFlowReco/interface/PFCluster.h"
00019 #include <Math/VectorUtil.h>
00020 #include <algorithm>
00021 
00022 namespace reco { namespace tau {
00023 
00024 class RecoTauElectronRejectionPlugin : public RecoTauModifierPlugin {
00025   public:
00026     explicit RecoTauElectronRejectionPlugin(const edm::ParameterSet& pset);
00027     virtual ~RecoTauElectronRejectionPlugin() {}
00028     void operator()(PFTau&) const;
00029   private:
00030     double ElecPreIDLeadTkMatch_maxDR_;
00031     double EcalStripSumE_minClusEnergy_;
00032     double EcalStripSumE_deltaEta_;
00033     double EcalStripSumE_deltaPhiOverQ_minValue_;
00034     double EcalStripSumE_deltaPhiOverQ_maxValue_;
00035     double maximumForElectrionPreIDOutput_;
00036     std::string DataType_;
00037 };
00038 
00039 RecoTauElectronRejectionPlugin::RecoTauElectronRejectionPlugin(
00040     const edm::ParameterSet& pset):RecoTauModifierPlugin(pset) {
00041   // Load parameters
00042   ElecPreIDLeadTkMatch_maxDR_ =
00043     pset.getParameter<double>("ElecPreIDLeadTkMatch_maxDR");
00044   EcalStripSumE_minClusEnergy_ =
00045     pset.getParameter<double>("EcalStripSumE_minClusEnergy");
00046   EcalStripSumE_deltaEta_ =
00047     pset.getParameter<double>("EcalStripSumE_deltaEta");
00048   EcalStripSumE_deltaPhiOverQ_minValue_ =
00049     pset.getParameter<double>("EcalStripSumE_deltaPhiOverQ_minValue");
00050   EcalStripSumE_deltaPhiOverQ_maxValue_ =
00051     pset.getParameter<double>("EcalStripSumE_deltaPhiOverQ_maxValue");
00052   maximumForElectrionPreIDOutput_ =
00053     pset.getParameter<double>("maximumForElectrionPreIDOutput");
00054   DataType_ = pset.getParameter<std::string>("DataType");
00055 }
00056 
00057 namespace {
00058 bool checkPos(std::vector<math::XYZPoint> CalPos,math::XYZPoint CandPos) {
00059   bool flag = false;
00060   for (unsigned int i=0;i<CalPos.size();i++) {
00061     if (CalPos[i] == CandPos) {
00062       flag = true;
00063       break;
00064     }
00065   }
00066   return flag;
00067 }
00068 }
00069 
00070 void RecoTauElectronRejectionPlugin::operator()(PFTau& tau) const {
00071   // copy pasted from PFRecoTauAlgorithm...
00072   double myECALenergy             =  0.;
00073   double myHCALenergy             =  0.;
00074   double myHCALenergy3x3          =  0.;
00075   double myMaximumHCALPFClusterE  =  0.;
00076   double myMaximumHCALPFClusterEt =  0.;
00077   double myStripClusterE          =  0.;
00078   double myEmfrac                 = -1.;
00079   double myElectronPreIDOutput    = -1111.;
00080   bool   myElecPreid              =  false;
00081   reco::TrackRef myElecTrk;
00082 
00083   typedef std::pair<reco::PFBlockRef, unsigned> ElementInBlock;
00084   typedef std::vector< ElementInBlock > ElementsInBlocks;
00085 
00086   PFCandidateRef myleadPFChargedCand = tau.leadPFChargedHadrCand();
00087   // Build list of PFCands in tau
00088   PFCandidateRefVector myPFCands;
00089   myPFCands.reserve(tau.isolationPFCands().size()+tau.signalPFCands().size());
00090 
00091   std::copy(tau.isolationPFCands().begin(), tau.isolationPFCands().end(),
00092       std::back_inserter(myPFCands));
00093   std::copy(tau.signalPFCands().begin(), tau.signalPFCands().end(),
00094       std::back_inserter(myPFCands));
00095 
00096   //Use the electron rejection only in case there is a charged leading pion
00097   if(myleadPFChargedCand.isNonnull()){
00098     myElectronPreIDOutput = myleadPFChargedCand->mva_e_pi();
00099 
00100     math::XYZPointF myElecTrkEcalPos = myleadPFChargedCand->positionAtECALEntrance();
00101     myElecTrk = myleadPFChargedCand->trackRef();//Electron candidate
00102 
00103     if(myElecTrk.isNonnull()) {
00104       //FROM AOD
00105       if(DataType_ == "AOD"){
00106         // Corrected Cluster energies
00107         for(int i=0;i<(int)myPFCands.size();i++){
00108           myHCALenergy += myPFCands[i]->hcalEnergy();
00109           myECALenergy += myPFCands[i]->ecalEnergy();
00110 
00111           math::XYZPointF candPos;
00112           if (myPFCands[i]->particleId()==1 || myPFCands[i]->particleId()==2)//if charged hadron or electron
00113             candPos = myPFCands[i]->positionAtECALEntrance();
00114           else
00115             candPos = math::XYZPointF(myPFCands[i]->px(),myPFCands[i]->py(),myPFCands[i]->pz());
00116 
00117           double deltaR   = ROOT::Math::VectorUtil::DeltaR(myElecTrkEcalPos,candPos);
00118           double deltaPhi = ROOT::Math::VectorUtil::DeltaPhi(myElecTrkEcalPos,candPos);
00119           double deltaEta = abs(myElecTrkEcalPos.eta()-candPos.eta());
00120           double deltaPhiOverQ = deltaPhi/(double)myElecTrk->charge();
00121 
00122           if (myPFCands[i]->ecalEnergy() >= EcalStripSumE_minClusEnergy_ && deltaEta < EcalStripSumE_deltaEta_ &&
00123               deltaPhiOverQ > EcalStripSumE_deltaPhiOverQ_minValue_  && deltaPhiOverQ < EcalStripSumE_deltaPhiOverQ_maxValue_) {
00124             myStripClusterE += myPFCands[i]->ecalEnergy();
00125           }
00126           if (deltaR<0.184) {
00127             myHCALenergy3x3 += myPFCands[i]->hcalEnergy();
00128           }
00129           if (myPFCands[i]->hcalEnergy()>myMaximumHCALPFClusterE) {
00130             myMaximumHCALPFClusterE = myPFCands[i]->hcalEnergy();
00131           }
00132           if ((myPFCands[i]->hcalEnergy()*fabs(sin(candPos.Theta())))>myMaximumHCALPFClusterEt) {
00133             myMaximumHCALPFClusterEt = (myPFCands[i]->hcalEnergy()*fabs(sin(candPos.Theta())));
00134           }
00135         }
00136 
00137       } else if(DataType_ == "RECO"){ //From RECO
00138         // Against double counting of clusters
00139         std::vector<math::XYZPoint> hcalPosV; hcalPosV.clear();
00140         std::vector<math::XYZPoint> ecalPosV; ecalPosV.clear();
00141         for(int i=0;i<(int)myPFCands.size();i++){
00142           const ElementsInBlocks& elts = myPFCands[i]->elementsInBlocks();
00143           for(ElementsInBlocks::const_iterator it=elts.begin(); it!=elts.end(); ++it) {
00144             const reco::PFBlock& block = *(it->first);
00145             unsigned indexOfElementInBlock = it->second;
00146             const edm::OwnVector< reco::PFBlockElement >& elements = block.elements();
00147             assert(indexOfElementInBlock<elements.size());
00148 
00149             const reco::PFBlockElement& element = elements[indexOfElementInBlock];
00150 
00151             if(element.type()==reco::PFBlockElement::HCAL) {
00152               math::XYZPoint clusPos = element.clusterRef()->position();
00153               double en = (double)element.clusterRef()->energy();
00154               double et = (double)element.clusterRef()->energy()*fabs(sin(clusPos.Theta()));
00155               if (en>myMaximumHCALPFClusterE) {
00156                 myMaximumHCALPFClusterE = en;
00157               }
00158               if (et>myMaximumHCALPFClusterEt) {
00159                 myMaximumHCALPFClusterEt = et;
00160               }
00161               if (!checkPos(hcalPosV,clusPos)) {
00162                 hcalPosV.push_back(clusPos);
00163                 myHCALenergy += en;
00164                 double deltaR = ROOT::Math::VectorUtil::DeltaR(myElecTrkEcalPos,clusPos);
00165                 if (deltaR<0.184) {
00166                   myHCALenergy3x3 += en;
00167                 }
00168               }
00169             } else if(element.type()==reco::PFBlockElement::ECAL) {
00170               double en = (double)element.clusterRef()->energy();
00171               math::XYZPoint clusPos = element.clusterRef()->position();
00172               if (!checkPos(ecalPosV,clusPos)) {
00173                 ecalPosV.push_back(clusPos);
00174                 myECALenergy += en;
00175                 double deltaPhi = ROOT::Math::VectorUtil::DeltaPhi(myElecTrkEcalPos,clusPos);
00176                 double deltaEta = abs(myElecTrkEcalPos.eta()-clusPos.eta());
00177                 double deltaPhiOverQ = deltaPhi/(double)myElecTrk->charge();
00178                 if (en >= EcalStripSumE_minClusEnergy_ && deltaEta<EcalStripSumE_deltaEta_ && deltaPhiOverQ > EcalStripSumE_deltaPhiOverQ_minValue_ && deltaPhiOverQ < EcalStripSumE_deltaPhiOverQ_maxValue_) {
00179                   myStripClusterE += en;
00180                 }
00181               }
00182             }
00183           } //end elements in blocks
00184         } //end loop over PFcands
00185       } //end RECO case
00186     } // end check for null electrk
00187   } // end check for null pfChargedHadrCand
00188 
00189   if ((myHCALenergy+myECALenergy)>0.)
00190     myEmfrac = myECALenergy/(myHCALenergy+myECALenergy);
00191   tau.setemFraction((float)myEmfrac);
00192 
00193   // scale the appropriate quantities by the momentum of the electron if it exists
00194   if (myElecTrk.isNonnull())
00195   {
00196     float myElectronMomentum = (float)myElecTrk->p();
00197     if (myElectronMomentum > 0.)
00198     {
00199       myHCALenergy            /= myElectronMomentum;
00200       myMaximumHCALPFClusterE /= myElectronMomentum;
00201       myHCALenergy3x3         /= myElectronMomentum;
00202       myStripClusterE         /= myElectronMomentum;
00203     }
00204   }
00205   tau.sethcalTotOverPLead((float)myHCALenergy);
00206   tau.sethcalMaxOverPLead((float)myMaximumHCALPFClusterE);
00207   tau.sethcal3x3OverPLead((float)myHCALenergy3x3);
00208   tau.setecalStripSumEOverPLead((float)myStripClusterE);
00209   tau.setmaximumHCALPFClusterEt(myMaximumHCALPFClusterEt);
00210   tau.setelectronPreIDOutput(myElectronPreIDOutput);
00211   if (myElecTrk.isNonnull())
00212     tau.setelectronPreIDTrack(myElecTrk);
00213   if (myElectronPreIDOutput > maximumForElectrionPreIDOutput_)
00214     myElecPreid = true;
00215   tau.setelectronPreIDDecision(myElecPreid);
00216 
00217   // These need to be filled!
00218   //tau.setbremsRecoveryEOverPLead(my...);
00219 
00220   /* End elecron rejection */
00221 }
00222 }} // end namespace reco::tau
00223 #include "FWCore/Framework/interface/MakerMacros.h"
00224 DEFINE_EDM_PLUGIN(RecoTauModifierPluginFactory,
00225     reco::tau::RecoTauElectronRejectionPlugin,
00226     "RecoTauElectronRejectionPlugin");