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| // -*- C++ -*-
#include "Rivet/Analyses/MC_JetAnalysis.hh"
#include "Rivet/Projections/LeadingParticlesFinalState.hh"
#include "Rivet/Projections/VetoedFinalState.hh"
#include "Rivet/Projections/FastJets.hh"
namespace Rivet {
/// @brief MC validation analysis for photon + jets events
class MC_PHOTONJETS : public MC_JetAnalysis {
public:
/// Default constructor
MC_PHOTONJETS()
: MC_JetAnalysis("MC_PHOTONJETS", 4, "Jets")
{ }
/// @name Analysis methods
//@{
/// Book histograms
void init() {
// General FS
FinalState fs((Cuts::etaIn(-5.0, 5.0)));
declare(fs, "FS");
// Get leading photon
LeadingParticlesFinalState photonfs(FinalState(Cuts::abseta < 2.5 && Cuts::pT >= 30*GeV));
photonfs.addParticleId(PID::PHOTON);
declare(photonfs, "LeadingPhoton");
// FS for jets excludes the leading photon
VetoedFinalState vfs(fs);
vfs.addVetoOnThisFinalState(photonfs);
declare(vfs, "JetFS");
FastJets jetpro(vfs, FastJets::ANTIKT, 0.4);
declare(jetpro, "Jets");
book(_h_photon_jet1_deta ,"photon_jet1_deta", 50, -5.0, 5.0);
book(_h_photon_jet1_dphi ,"photon_jet1_dphi", 20, 0.0, M_PI);
book(_h_photon_jet1_dR ,"photon_jet1_dR", 25, 0.5, 7.0);
MC_JetAnalysis::init();
}
/// Do the analysis
void analyze(const Event& e) {
// Get the photon
/// @todo share IsolatedPhoton projection between all MC_*PHOTON* analyses
const Particles photons = apply<FinalState>(e, "LeadingPhoton").particles();
if (photons.size() != 1) {
vetoEvent;
}
const FourMomentum photon = photons.front().momentum();
// Get all charged particles
const FinalState& fs = apply<FinalState>(e, "JetFS");
if (fs.empty()) {
vetoEvent;
}
// Passed cuts, so get the weight
const double weight = 1.0;
// Isolate photon by ensuring that a 0.4 cone around it contains less than 7% of the photon's energy
const double egamma = photon.E();
double econe = 0.0;
for (const Particle& p : fs.particles()) {
if (deltaR(photon, p.momentum()) < 0.4) {
econe += p.E();
// Veto as soon as E_cone gets larger
if (econe/egamma > 0.07) {
vetoEvent;
}
}
}
const Jets& jets = apply<FastJets>(e, "Jets").jetsByPt(_jetptcut);
if (jets.size()>0) {
_h_photon_jet1_deta->fill(photon.eta()-jets[0].eta(), weight);
_h_photon_jet1_dphi->fill(mapAngle0ToPi(photon.phi()-jets[0].phi()), weight);
_h_photon_jet1_dR->fill(deltaR(photon, jets[0].momentum()), weight);
}
MC_JetAnalysis::analyze(e);
}
// Finalize
void finalize() {
scale(_h_photon_jet1_deta, crossSectionPerEvent());
scale(_h_photon_jet1_dphi, crossSectionPerEvent());
scale(_h_photon_jet1_dR, crossSectionPerEvent());
MC_JetAnalysis::finalize();
}
//@}
private:
/// @name Histograms
//@{
Histo1DPtr _h_photon_jet1_deta;
Histo1DPtr _h_photon_jet1_dphi;
Histo1DPtr _h_photon_jet1_dR;
//@}
};
// The hook for the plugin system
RIVET_DECLARE_PLUGIN(MC_PHOTONJETS);
}
|