Go to the documentation of this file.00001 #include <memory>
00002
00003 #include "FWCore/Framework/interface/Frameworkfwd.h"
00004 #include "FWCore/Framework/interface/EDProducer.h"
00005
00006 #include "FWCore/Framework/interface/Event.h"
00007 #include "FWCore/Framework/interface/MakerMacros.h"
00008
00009 #include "FWCore/ParameterSet/interface/ParameterSet.h"
00010
00011 #include "DataFormats/HepMCCandidate/interface/GenParticle.h"
00012 #include "DataFormats/Candidate/interface/CompositeCandidate.h"
00013 #include "CommonTools/CandUtils/interface/AddFourMomenta.h"
00014 #include "CommonTools/CandUtils/interface/Booster.h"
00015 #include <Math/VectorUtil.h>
00016
00017
00018
00019
00020 class FSRWeightProducer : public edm::EDProducer {
00021 public:
00022 explicit FSRWeightProducer(const edm::ParameterSet&);
00023 ~FSRWeightProducer();
00024
00025 private:
00026 virtual void beginJob() ;
00027 virtual void produce(edm::Event&, const edm::EventSetup&);
00028 virtual void endJob() ;
00029 double alphaRatio(double) ;
00030
00031 edm::InputTag genTag_;
00032 };
00033
00034
00035 #include "DataFormats/HepMCCandidate/interface/GenParticle.h"
00037 FSRWeightProducer::FSRWeightProducer(const edm::ParameterSet& pset) {
00038 genTag_ = pset.getUntrackedParameter<edm::InputTag> ("GenTag", edm::InputTag("genParticles"));
00039
00040 produces<double>();
00041 }
00042
00044 FSRWeightProducer::~FSRWeightProducer(){}
00045
00047 void FSRWeightProducer::beginJob() {}
00048
00050 void FSRWeightProducer::endJob(){}
00051
00053 void FSRWeightProducer::produce(edm::Event& iEvent, const edm::EventSetup&) {
00054
00055 if (iEvent.isRealData()) return;
00056
00057 edm::Handle<reco::GenParticleCollection> genParticles;
00058 iEvent.getByLabel(genTag_, genParticles);
00059
00060 std::auto_ptr<double> weight (new double);
00061
00062
00063 (*weight) = 1.;
00064
00065 unsigned int gensize = genParticles->size();
00066 for (unsigned int i = 0; i<gensize; ++i) {
00067 const reco::GenParticle& lepton = (*genParticles)[i];
00068 if (lepton.status()!=3) continue;
00069 int leptonId = lepton.pdgId();
00070 if (abs(leptonId)!=11 && abs(leptonId)!=13 && abs(leptonId)!=15) continue;
00071 if (lepton.numberOfMothers()!=1) continue;
00072 const reco::Candidate * boson = lepton.mother();
00073 int bosonId = abs(boson->pdgId());
00074 if (bosonId!=23 && bosonId!=24) continue;
00075 double bosonMass = boson->mass();
00076 double leptonMass = lepton.mass();
00077 double leptonEnergy = lepton.energy();
00078 double cosLeptonTheta = cos(lepton.theta());
00079 double sinLeptonTheta = sin(lepton.theta());
00080 double leptonPhi = lepton.phi();
00081
00082 int trueKey = i;
00083 if (lepton.numberOfDaughters()==0) {
00084 continue;
00085 } else if (lepton.numberOfDaughters()==1) {
00086 int otherleptonKey = lepton.daughterRef(0).key();
00087 const reco::GenParticle& otherlepton = (*genParticles)[otherleptonKey];
00088 if (otherlepton.pdgId()!=leptonId) continue;
00089 if (otherlepton.numberOfDaughters()<=1) continue;
00090 trueKey = otherleptonKey;
00091 }
00092
00093 const reco::GenParticle& trueLepton = (*genParticles)[trueKey];
00094 unsigned int nDaughters = trueLepton.numberOfDaughters();
00095
00096 for (unsigned int j = 0; j<nDaughters; ++j) {
00097 const reco::Candidate * photon = trueLepton.daughter(j);
00098 if (photon->pdgId()!=22) continue;
00099 double photonEnergy = photon->energy();
00100 double cosPhotonTheta = cos(photon->theta());
00101 double sinPhotonTheta = sin(photon->theta());
00102 double photonPhi = photon->phi();
00103 double costheta = sinLeptonTheta*sinPhotonTheta*cos(leptonPhi-photonPhi)
00104 + cosLeptonTheta*cosPhotonTheta;
00105
00106
00107 if (bosonId==24) {
00108 double betaLepton = sqrt(1-pow(leptonMass/leptonEnergy,2));
00109 double delta = - 8*photonEnergy *(1-betaLepton*costheta)
00110 / pow(bosonMass,3)
00111 / (1-pow(leptonMass/bosonMass,2))
00112 / (4-pow(leptonMass/bosonMass,2))
00113 * leptonEnergy * (pow(leptonMass,2)/bosonMass+2*photonEnergy);
00114 (*weight) *= (1 + delta);
00115 }
00116
00117
00118 (*weight) *= alphaRatio(photonEnergy*sqrt(1-pow(costheta,2)));
00119 }
00120 }
00121
00122
00123 iEvent.put(weight);
00124 }
00125
00126 double FSRWeightProducer::alphaRatio(double pt) {
00127
00128 double pigaga = 0.;
00129
00130
00131 const double alphapi = 1/137.036/M_PI;
00132 const double mass_e = 0.0005;
00133 const double mass_mu = 0.106;
00134 const double mass_tau = 1.777;
00135 const double mass_Z = 91.2;
00136 if (pt>mass_e) pigaga += alphapi * (2*log(pt/mass_e)/3.-5./9.);
00137 if (pt>mass_mu) pigaga += alphapi * (2*log(pt/mass_mu)/3.-5./9.);
00138 if (pt>mass_tau) pigaga += alphapi * (2*log(pt/mass_tau)/3.-5./9.);
00139
00140
00141
00142
00143 double A = 0.;
00144 double B = 0.;
00145 double C = 0.;
00146 if (pt<0.7) {
00147 A = 0.0; B = 0.0023092; C = 3.9925370;
00148 } else if (pt<2.0) {
00149 A = 0.0; B = 0.0022333; C = 4.2191779;
00150 } else if (pt<4.0) {
00151 A = 0.0; B = 0.0024402; C = 3.2496684;
00152 } else if (pt<10.0) {
00153 A = 0.0; B = 0.0027340; C = 2.0995092;
00154 } else if (pt<mass_Z) {
00155 A = 0.0010485; B = 0.0029431; C = 1.0;
00156 } else if (pt<10000.) {
00157 A = 0.0012234; B = 0.0029237; C = 1.0;
00158 } else {
00159 A = 0.0016894; B = 0.0028984; C = 1.0;
00160 }
00161 pigaga += A + B*log(1.+C*pt*pt);
00162
00163
00164 return 1./(1.-pigaga);
00165 }
00166
00167 DEFINE_FWK_MODULE(FSRWeightProducer);