The Rivet MC analysis system: ATLAS_2010_S8914702.cc Source File

The Rivet MC analysis system 2.1.0
00001 // -*- C++ -*-
00002 #include <iostream>
00003 #include <sstream>
00004 #include <string>
00005 
00006 #include "Rivet/Analysis.hh"
00007 #include "Rivet/Projections/FinalState.hh"
00008 
00009 #include "Rivet/Projections/LeadingParticlesFinalState.hh"
00010 #include "Rivet/Jet.hh"
00011 #include "Rivet/Projections/FastJets.hh"
00012 
00013 #include "fastjet/internal/base.hh"
00014 #include "fastjet/JetDefinition.hh"
00015 #include "fastjet/AreaDefinition.hh"
00016 #include "fastjet/ClusterSequence.hh"
00017 #include "fastjet/ClusterSequenceArea.hh"
00018 #include "fastjet/PseudoJet.hh"
00019 
00020 namespace Rivet {
00021 
00022 
00023   class ATLAS_2010_S8914702 : public Analysis {
00024   public:
00025 
00026     /// Constructor
00027     ATLAS_2010_S8914702()
00028       : Analysis("ATLAS_2010_S8914702")
00029     {
00030       _eta_bins.push_back( 0.00);
00031       _eta_bins.push_back( 0.60);
00032       _eta_bins.push_back( 1.37);
00033       _eta_bins.push_back( 1.52);
00034       _eta_bins.push_back( 1.81);
00035 
00036       _eta_bins_areaoffset.push_back(0.0);
00037       _eta_bins_areaoffset.push_back(1.5);
00038       _eta_bins_areaoffset.push_back(3.0);
00039     }
00040 
00041 
00042     /// Book histograms and initialise projections before the run
00043     void init() {
00044       FinalState fs;
00045       addProjection(fs, "FS");
00046 
00047       FastJets fj(fs, FastJets::KT, 0.5);
00048       _area_def = new fastjet::AreaDefinition(fastjet::VoronoiAreaSpec());
00049       fj.useJetArea(_area_def);
00050       addProjection(fj, "KtJetsD05");
00051 
00052       LeadingParticlesFinalState photonfs(FinalState(-1.81, 1.81, 15.0*GeV));
00053       photonfs.addParticleId(PID::PHOTON);
00054       addProjection(photonfs, "LeadingPhoton");
00055 
00056       int hist_bin = 0;
00057       for (int i = 0; i < (int)_eta_bins.size()-1; ++i) {
00058         if (fabs(_eta_bins[i] - 1.37) < .0001) continue;
00059         _h_Et_photon[i] = bookHisto1D(1, 1, hist_bin+1);
00060         hist_bin += 1;
00061       }
00062     }
00063 
00064 
00065     int getEtaBin(double eta_w, bool area_eta) const {
00066       double eta = fabs(eta_w);
00067       int v_iter = 0;
00068       if (!area_eta) {
00069         for (v_iter=0; v_iter < (int)_eta_bins.size()-1; ++v_iter) {
00070           if (eta >= _eta_bins.at(v_iter) && eta < _eta_bins.at(v_iter+1)) break;
00071         }
00072       } else {
00073         for (v_iter=0; v_iter < (int)_eta_bins_areaoffset.size()-1; ++v_iter) {
00074           if (eta >= _eta_bins_areaoffset.at(v_iter) && eta < _eta_bins_areaoffset.at(v_iter+1)) break;
00075         }
00076       }
00077       return v_iter;
00078     }
00079 
00080 
00081     /// Perform the per-event analysis
00082     void analyze(const Event& event) {
00083       const double weight = event.weight();
00084 
00085       Particles photons = applyProjection<LeadingParticlesFinalState>(event, "LeadingPhoton").particles();
00086       if (photons.size() != 1) {
00087         vetoEvent;
00088       }
00089 
00090       FourMomentum leadingPhoton = photons[0].momentum();
00091       double eta_P = leadingPhoton.eta();
00092       double phi_P = leadingPhoton.phi();
00093 
00094       if(fabs(eta_P)>=1.37 && fabs(eta_P)<1.52){
00095         vetoEvent;
00096       }
00097 
00098       int eta_bin = getEtaBin(eta_P,false);
00099 
00100       Particles fs = applyProjection<FinalState>(event, "FS").particles();
00101       FourMomentum mom_in_EtCone;
00102       foreach (const Particle& p, fs) {
00103         // check if it's in the cone of .4
00104         if (deltaR(eta_P, phi_P, p.eta(), p.momentum().phi()) >= 0.4) continue;
00105 
00106         // check if it's in the 5x7 central core
00107         if (fabs(eta_P-p.eta()) < .025*7.0*0.5 &&
00108             fabs(phi_P-p.momentum().phi()) < (PI/128.)*5.0*0.5) continue;
00109         mom_in_EtCone += p.momentum();
00110       }
00111       MSG_DEBUG("Done with initial EtCone.");
00112 
00113       // Now compute the median energy density
00114       _ptDensity.clear();
00115       _sigma.clear();
00116       _Njets.clear();
00117 
00118       std::vector< std::vector<double> > ptDensities;
00119       std::vector<double> emptyVec;
00120       ptDensities.assign(_eta_bins_areaoffset.size()-1,emptyVec);
00121 
00122       const fastjet::ClusterSequenceArea* clust_seq_area = applyProjection<FastJets>(event, "KtJetsD05").clusterSeqArea();
00123       foreach (const fastjet::PseudoJet& jet, applyProjection<FastJets>(event, "KtJetsD05").pseudoJets(0.0*GeV)) {
00124         //const double y = fabs(jet.rapidity());
00125         const double eta = fabs(jet.eta());
00126         const double pt = fabs(jet.perp());
00127 
00128         // Get the cluster sequence
00129         double area = clust_seq_area->area(jet);
00130 
00131         if (area > 10e-4 && fabs(eta)<_eta_bins_areaoffset[_eta_bins_areaoffset.size()-1]) {
00132           ptDensities.at(getEtaBin(fabs(eta),true)).push_back(pt/area);
00133         }
00134       }
00135 
00136       for (int b = 0; b < (int)_eta_bins_areaoffset.size()-1; ++b) {
00137         double median = 0.0;
00138         double sigma = 0.0;
00139         int Njets = 0;
00140         if (ptDensities[b].size() > 0) {
00141           std::sort(ptDensities[b].begin(), ptDensities[b].end());
00142           int nDens = ptDensities[b].size();
00143           if (nDens % 2 == 0) {
00144             median = (ptDensities[b][nDens/2]+ptDensities[b][(nDens-2)/2])/2;
00145           } else {
00146             median = ptDensities[b][(nDens-1)/2];
00147           }
00148           sigma = ptDensities[b][(int)(.15865*nDens)];
00149           Njets = nDens;
00150         }
00151         _ptDensity.push_back(median);
00152         _sigma.push_back(sigma);
00153         _Njets.push_back(Njets);
00154       }
00155 
00156       // Now figure out the correction
00157       float EtCone_area = PI*.4*.4 - (7.0*.025)*(5.0*PI/128.);
00158       float correction = _ptDensity[getEtaBin(eta_P,true)]*EtCone_area;
00159       MSG_DEBUG("Jet area correction done.");
00160 
00161       // Shouldn't need to subtract photon
00162       // NB. Using expected cut at hadron/particle level, not cut at reco level
00163       if (mom_in_EtCone.Et() - correction/*-leadingPhoton.Et()*/ > 4.0*GeV) {
00164         vetoEvent;
00165       }
00166       MSG_DEBUG("Passed isolation cut.");
00167 
00168       _h_Et_photon[eta_bin]->fill(leadingPhoton.Et(), weight);
00169     }
00170 
00171 
00172     /// Normalise histograms etc., after the run
00173     void finalize() {
00174       for (int i = 0; i < (int)_eta_bins.size()-1; ++i) {
00175         if (fabs(_eta_bins[i] - 1.37) < .0001) continue;
00176         scale(_h_Et_photon[i], crossSection()/sumOfWeights());
00177       }
00178     }
00179 
00180 
00181   private:
00182 
00183     Histo1DPtr _h_Et_photon[6];
00184 
00185     fastjet::AreaDefinition* _area_def;
00186 
00187     std::vector<float> _eta_bins;
00188     std::vector<float> _eta_bins_areaoffset;
00189 
00190     std::vector<float> _ptDensity;
00191     std::vector<float> _sigma;
00192     std::vector<float> _Njets;
00193   };
00194 
00195 
00196 
00197   // The hook for the plugin system
00198   DECLARE_RIVET_PLUGIN(ATLAS_2010_S8914702);
00199 
00200 }