53 minPhotonAbsEta_ = ps.
getParameter<
double>(
"minPhotonAbsEta");
54 maxPhotonAbsEta_ = ps.
getParameter<
double>(
"maxPhotonAbsEta");
56 maxPhotonHoverE_ = ps.
getParameter<
double>(
"maxPhotonHoverE");
60 createPhotonTTree_ = ps.
getParameter<
bool>(
"createPhotonTTree");
63 rootFile_ = TFile::Open(outputFile_.c_str(),
"RECREATE");
91 h_isoEcalRecHit_ =
new TH1F(
"photonEcalIso",
"Ecal Rec Hit Isolation", 100, 0, 100);
92 h_isoHcalRecHit_ =
new TH1F(
"photonHcalIso",
"Hcal Rec Hit Isolation", 100, 0, 100);
93 h_trk_pt_solid_ =
new TH1F(
"photonTrackSolidIso",
"Sum of track pT in a cone of #DeltaR" , 100, 0, 100);
94 h_trk_pt_hollow_ =
new TH1F(
"photonTrackHollowIso",
"Sum of track pT in a hollow cone" , 100, 0, 100);
95 h_ntrk_solid_ =
new TH1F(
"photonTrackCountSolid",
"Number of tracks in a cone of #DeltaR", 100, 0, 100);
96 h_ntrk_hollow_ =
new TH1F(
"photonTrackCountHollow",
"Number of tracks in a hollow cone", 100, 0, 100);
97 h_ebgap_ =
new TH1F(
"photonInEBgap",
"Ecal Barrel gap flag", 2, -0.5, 1.5);
98 h_eeGap_ =
new TH1F(
"photonInEEgap",
"Ecal Endcap gap flag", 2, -0.5, 1.5);
99 h_ebeeGap_ =
new TH1F(
"photonInEEgap",
"Ecal Barrel/Endcap gap flag", 2, -0.5, 1.5);
100 h_r9_ =
new TH1F(
"photonR9",
"R9 = E(3x3) / E(SuperCluster)", 300, 0, 3);
103 h_photonEt_ =
new TH1F(
"photonEt",
"Photon E_{T}", 200, 0, 200);
104 h_photonEta_ =
new TH1F(
"photonEta",
"Photon #eta", 200, -4, 4);
105 h_photonPhi_ =
new TH1F(
"photonPhi",
"Photon #phi", 200, -1.*
TMath::Pi(),
TMath::Pi());
106 h_hadoverem_ =
new TH1F(
"photonHoverE",
"Hadronic over EM", 200, 0, 1);
109 h_photonScEt_ =
new TH1F(
"photonScEt",
"Photon SuperCluster E_{T}", 200, 0, 200);
110 h_photonScEta_ =
new TH1F(
"photonScEta",
"Photon #eta", 200, -4, 4);
111 h_photonScPhi_ =
new TH1F(
"photonScPhi",
"Photon #phi", 200, -1.*
TMath::Pi(),
TMath::Pi());
112 h_photonScEtaWidth_ =
new TH1F(
"photonScEtaWidth",
"#eta-width", 100, 0, .1);
115 h_photonInAnyGap_ =
new TH1F(
"photonInAnyGap",
"Photon in any gap flag", 2, -0.5, 1.5);
116 h_nPassingPho_ =
new TH1F(
"photonPassingCount",
"Total number photons (0=NotPassing, 1=Passing)", 2, -0.5, 1.5);
117 h_nPho_ =
new TH1F(
"photonCount",
"Number of photons passing cuts in event", 10, 0, 10);
120 if ( createPhotonTTree_ ) {
121 tree_PhotonAll_ =
new TTree(
"TreePhotonAll",
"Reconstructed Photon");
122 tree_PhotonAll_->Branch(
"recPhoton", &recPhoton.isolationEcalRecHit,
"isolationEcalRecHit/F:isolationHcalRecHit:isolationSolidTrkCone:isolationHollowTrkCone:nTrkSolidCone:nTrkHollowCone:isEBGap:isEEGap:isEBEEGap:r9:et:eta:phi:hadronicOverEm:ecalIso:hcalIso:trackIso");
138 evt.
getByLabel(
"selectedLayer1Photons", photonHandle);
141 int photonCounter = 0;
148 float photonEt = currentPhoton.
et();
149 float superClusterEt = (currentPhoton.
superCluster()->energy())/(cosh(currentPhoton.
superCluster()->position().eta()));
152 bool passCuts = ( photonEt > minPhotonEt_ ) &&
153 ( fabs(currentPhoton.
eta()) > minPhotonAbsEta_ ) &&
154 ( fabs(currentPhoton.
eta()) < maxPhotonAbsEta_ ) &&
155 ( currentPhoton.
r9() > minPhotonR9_ ) &&
173 h_r9_->
Fill(currentPhoton.
r9());
176 h_photonEt_->
Fill(photonEt);
177 h_photonEta_->
Fill(currentPhoton.
eta());
178 h_photonPhi_->
Fill(currentPhoton.
phi());
184 h_photonScEt_->
Fill(superClusterEt);
187 h_photonScEtaWidth_->Fill(currentPhoton.
superCluster()->etaWidth());
190 h_nPassingPho_->Fill(1.0);
195 if ( createPhotonTTree_ ) {
202 recPhoton.isEBGap = currentPhoton.
isEBGap();
203 recPhoton.isEEGap = currentPhoton.
isEEGap();
204 recPhoton.isEBEEGap = currentPhoton.
isEBEEGap();
205 recPhoton.r9 = currentPhoton.
r9();
206 recPhoton.et = currentPhoton.
et();
207 recPhoton.eta = currentPhoton.
eta();
208 recPhoton.phi = currentPhoton.
phi();
210 recPhoton.ecalIso = currentPhoton.
ecalIso();
211 recPhoton.hcalIso = currentPhoton.
hcalIso();
212 recPhoton.trackIso = currentPhoton.
trackIso();
216 tree_PhotonAll_->Fill();
223 h_photonInAnyGap_->Fill(1.0);
225 h_photonInAnyGap_->Fill(0.0);
233 h_nPassingPho_->Fill(0.0);
237 h_nPho_->Fill(photonCounter);
252 h_isoEcalRecHit_->Write();
253 h_isoHcalRecHit_->Write();
254 h_trk_pt_solid_-> Write();
255 h_trk_pt_hollow_->Write();
256 h_ntrk_solid_-> Write();
257 h_ntrk_hollow_-> Write();
260 h_ebeeGap_-> Write();
264 h_photonEt_-> Write();
265 h_photonEta_-> Write();
266 h_photonPhi_-> Write();
267 h_hadoverem_-> Write();
270 h_photonScEt_-> Write();
271 h_photonScEta_-> Write();
272 h_photonScPhi_-> Write();
273 h_photonScEtaWidth_->Write();
276 h_photonInAnyGap_->Write();
277 h_nPassingPho_-> Write();
T getParameter(std::string const &) const
float hcalTowerSumEtConeDR04() const
Hcal isolation sum.
Analysis-level Photon class.
virtual void analyze(const edm::Event &, const edm::EventSetup &)
virtual double et() const
transverse energy
bool isEBGap() const
true if photon is in EB, and inside the boundaries in super crystals/modules
virtual float phi() const
momentum azimuthal angle
PatPhotonSimpleAnalyzer(const edm::ParameterSet &)
float trkSumPtSolidConeDR04() const
bool isEBEEGap() const
true if photon is in boundary between EB and EE
float ecalRecHitSumEtConeDR04() const
void Fill(HcalDetId &id, double val, std::vector< TH2F > &depth)
virtual float eta() const
momentum pseudorapidity
int nTrkHollowConeDR04() const
float hadronicOverEm() const
the total hadronic over electromagnetic fraction
bool getByLabel(InputTag const &tag, Handle< PROD > &result) const
bool isEEGap() const
true if photon is in EE, and inside the boundaries in supercrystal/D
~PatPhotonSimpleAnalyzer()
reco::SuperClusterRef superCluster() const
override the superCluster method from CaloJet, to access the internal storage of the supercluster ...
int nTrkSolidConeDR04() const
float trkSumPtHollowConeDR04() const