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ElectronAnalyzer.cc
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2 
4 
11 
18 //#include "FWCore/Framework/interface/EDAnalyzer.h"
20 
21 #include "CLHEP/Units/GlobalPhysicalConstants.h"
22 #include "TMath.h"
23 
24 #include <iostream>
25 
26 using namespace reco ;
27 
30  {
31  // general, collections
32  Selection_ = conf.getParameter<int>("Selection");
33  electronCollection_ = consumes<GsfElectronCollection>(conf.getParameter<edm::InputTag>("ElectronCollection"));
34  matchingObjectCollection_ = consumes<SuperClusterCollection>(conf.getParameter<edm::InputTag>("MatchingObjectCollection"));
35  trackCollection_ = consumes<TrackCollection>(conf.getParameter<edm::InputTag>("TrackCollection"));
36  vertexCollection_ = consumes<VertexCollection>(conf.getParameter<edm::InputTag>("VertexCollection"));
37  gsftrackCollection_ = consumes<GsfTrackCollection>(conf.getParameter<edm::InputTag>("GsfTrackCollection"));
38  beamSpotTag_ = consumes<BeamSpot>(conf.getParameter<edm::InputTag>("BeamSpot"));
39  readAOD_ = conf.getParameter<bool>("ReadAOD");
40 
41  // matching
42  matchingCondition_ = conf.getParameter<std::string>("MatchingCondition");
43  assert (matchingCondition_=="Cone") ;
44  maxPtMatchingObject_ = conf.getParameter<double>("MaxPtMatchingObject");
45  maxAbsEtaMatchingObject_ = conf.getParameter<double>("MaxAbsEtaMatchingObject");
46  deltaR_ = conf.getParameter<double>("DeltaR");
47 
48  // electron selection
49  minEt_ = conf.getParameter<double>("MinEt");
50  minPt_ = conf.getParameter<double>("MinPt");
51  maxAbsEta_ = conf.getParameter<double>("MaxAbsEta");
52  isEB_ = conf.getParameter<bool>("SelectEb");
53  isEE_ = conf.getParameter<bool>("SelectEe");
54  isNotEBEEGap_ = conf.getParameter<bool>("SelectNotEbEeGap");
55  isEcalDriven_ = conf.getParameter<bool>("SelectEcalDriven");
56  isTrackerDriven_ = conf.getParameter<bool>("SelectTrackerDriven");
57  eOverPMinBarrel_ = conf.getParameter<double>("MinEopBarrel");
58  eOverPMaxBarrel_ = conf.getParameter<double>("MaxEopBarrel");
59  eOverPMinEndcaps_ = conf.getParameter<double>("MinEopEndcaps");
60  eOverPMaxEndcaps_ = conf.getParameter<double>("MaxEopEndcaps");
61  dEtaMinBarrel_ = conf.getParameter<double>("MinDetaBarrel");
62  dEtaMaxBarrel_ = conf.getParameter<double>("MaxDetaBarrel");
63  dEtaMinEndcaps_ = conf.getParameter<double>("MinDetaEndcaps");
64  dEtaMaxEndcaps_ = conf.getParameter<double>("MaxDetaEndcaps");
65  dPhiMinBarrel_ = conf.getParameter<double>("MinDphiBarrel");
66  dPhiMaxBarrel_ = conf.getParameter<double>("MaxDphiBarrel");
67  dPhiMinEndcaps_ = conf.getParameter<double>("MinDphiEndcaps");
68  dPhiMaxEndcaps_ = conf.getParameter<double>("MaxDphiEndcaps");
69  sigIetaIetaMinBarrel_ = conf.getParameter<double>("MinSigIetaIetaBarrel");
70  sigIetaIetaMaxBarrel_ = conf.getParameter<double>("MaxSigIetaIetaBarrel");
71  sigIetaIetaMinEndcaps_ = conf.getParameter<double>("MinSigIetaIetaEndcaps");
72  sigIetaIetaMaxEndcaps_ = conf.getParameter<double>("MaxSigIetaIetaEndcaps");
73  hadronicOverEmMaxBarrel_ = conf.getParameter<double>("MaxHoeBarrel");
74  hadronicOverEmMaxEndcaps_ = conf.getParameter<double>("MaxHoeEndcaps");
75  mvaMin_ = conf.getParameter<double>("MinMva");
76  tipMaxBarrel_ = conf.getParameter<double>("MaxTipBarrel");
77  tipMaxEndcaps_ = conf.getParameter<double>("MaxTipEndcaps");
78  tkIso03Max_ = conf.getParameter<double>("MaxTkIso03");
79  hcalIso03Depth1MaxBarrel_ = conf.getParameter<double>("MaxHcalIso03Depth1Barrel");
80  hcalIso03Depth1MaxEndcaps_ = conf.getParameter<double>("MaxHcalIso03Depth1Endcaps");
81  hcalIso03Depth2MaxEndcaps_ = conf.getParameter<double>("MaxHcalIso03Depth2Endcaps");
82  ecalIso03MaxBarrel_ = conf.getParameter<double>("MaxEcalIso03Barrel");
83  ecalIso03MaxEndcaps_ = conf.getParameter<double>("MaxEcalIso03Endcaps");
84 
85  // for trigger
86  triggerResults_ = conf.getParameter<edm::InputTag>("TriggerResults");
87 // HLTPathsByName_= conf.getParameter<std::vector<std::string > >("HltPaths");
88 // HLTPathsByIndex_.resize(HLTPathsByName_.size());
89 
90  // histos limits and binning
91  nbineta=conf.getParameter<int>("NbinEta");
92  nbineta2D=conf.getParameter<int>("NbinEta2D");
93  etamin=conf.getParameter<double>("EtaMin");
94  etamax=conf.getParameter<double>("EtaMax");
95  //
96  nbinphi=conf.getParameter<int>("NbinPhi");
97  nbinphi2D=conf.getParameter<int>("NbinPhi2D");
98  phimin=conf.getParameter<double>("PhiMin");
99  phimax=conf.getParameter<double>("PhiMax");
100  //
101  nbinpt=conf.getParameter<int>("NbinPt");
102  nbinpteff=conf.getParameter<int>("NbinPtEff");
103  nbinpt2D=conf.getParameter<int>("NbinPt2D");
104  ptmax=conf.getParameter<double>("PtMax");
105  //
106  nbinp=conf.getParameter<int>("NbinP");
107  nbinp2D=conf.getParameter<int>("NbinP2D");
108  pmax=conf.getParameter<double>("PMax");
109  //
110  nbineop=conf.getParameter<int>("NbinEop");
111  nbineop2D=conf.getParameter<int>("NbinEop2D");
112  eopmax=conf.getParameter<double>("EopMax");
113  eopmaxsht=conf.getParameter<double>("EopMaxSht");
114  //
115  nbindeta=conf.getParameter<int>("NbinDeta");
116  detamin=conf.getParameter<double>("DetaMin");
117  detamax=conf.getParameter<double>("DetaMax");
118  //
119  nbindphi=conf.getParameter<int>("NbinDphi");
120  dphimin=conf.getParameter<double>("DphiMin");
121  dphimax=conf.getParameter<double>("DphiMax");
122  //
123  nbindetamatch=conf.getParameter<int>("NbinDetaMatch");
124  nbindetamatch2D=conf.getParameter<int>("NbinDetaMatch2D");
125  detamatchmin=conf.getParameter<double>("DetaMatchMin");
126  detamatchmax=conf.getParameter<double>("DetaMatchMax");
127  //
128  nbindphimatch=conf.getParameter<int>("NbinDphiMatch");
129  nbindphimatch2D=conf.getParameter<int>("NbinDphiMatch2D");
130  dphimatchmin=conf.getParameter<double>("DphiMatchMin");
131  dphimatchmax=conf.getParameter<double>("DphiMatchMax");
132  //
133  nbinfhits=conf.getParameter<int>("NbinFhits");
134  fhitsmax=conf.getParameter<double>("FhitsMax");
135  //
136  nbinlhits=conf.getParameter<int>("NbinLhits");
137  lhitsmax=conf.getParameter<double>("LhitsMax");
138  //
139  nbinxyz=conf.getParameter<int>("NbinXyz");
140  nbinxyz2D=conf.getParameter<int>("NbinXyz2D");
141  //
142  nbinpoptrue= conf.getParameter<int>("NbinPopTrue");
143  poptruemin=conf.getParameter<double>("PopTrueMin");
144  poptruemax=conf.getParameter<double>("PopTrueMax");
145  //
146  nbinmee= conf.getParameter<int>("NbinMee");
147  meemin=conf.getParameter<double>("MeeMin");
148  meemax=conf.getParameter<double>("MeeMax");
149  //
150  nbinhoe= conf.getParameter<int>("NbinHoe");
151  hoemin=conf.getParameter<double>("HoeMin");
152  hoemax=conf.getParameter<double>("HoeMax");
153  }
154 
156  {}
157 
159  {
160  nEvents_ = 0 ;
161  //nAfterTrigger_ = 0 ;
162 
163 
164  // basic quantities
165 // h1_num_= bookH1("num","# rec electrons",20, 0.,20.,"N_{ele}");
166 // h1_vertexP = bookH1("vertexP", "ele p at vertex", nbinp,0.,pmax,"p_{vertex} (GeV/c)");
167 // h1_Et = bookH1("Et","ele SC transverse energy", nbinpt,0.,ptmax,"E_{T} (GeV)");
168 // h1_vertexTIP = bookH1("vertexTIP","ele transverse impact parameter (wrt bs)",90,0.,0.15,"TIP (cm)");
169 // h1_charge = bookH1("charge","ele charge",5,-2.,2.,"charge");
170  h1_vertexPt_barrel = bookH1("vertexPt_barrel","ele transverse momentum in barrel",nbinpt,0.,ptmax,"p_{T vertex} (GeV/c)");
171  h1_vertexPt_endcaps = bookH1("vertexPt_endcaps","ele transverse momentum in endcaps",nbinpt,0.,ptmax,"p_{T vertex} (GeV/c)");
172  h1_vertexEta = bookH1("vertexEta","ele momentum #eta",nbineta,etamin,etamax,"#eta");
173 // h1_vertexPhi = bookH1("vertexPhi","ele momentum #phi",nbinphi,phimin,phimax,"#phi (rad)");
174  h2_vertexEtaVsPhi = bookH2("vertexEtaVsPhi","ele momentum #eta vs #phi",nbineta2D,etamin,etamax,nbinphi2D,phimin,phimax,"#eta","#phi (rad)");
175 // h1_vertexX = bookH1("vertexX","ele vertex x",nbinxyz,-0.1,0.1,"x (cm)");
176 // h1_vertexY = bookH1("vertexY","ele vertex y",nbinxyz,-0.1,0.1,"y (cm)");
177  h2_vertexXvsY = bookH2("vertexXvsY","ele vertex x vs y",nbinxyz2D,-0.1,0.1,nbinxyz2D,-0.1,0.1,"x (cm)","y (cm)");
178  h1_vertexZ = bookH1("vertexZ","ele vertex z",nbinxyz,-25, 25,"z (cm)");
179 
180  // super-clusters
181 // h1_sclEn = bookH1("sclEnergy","ele supercluster energy",nbinp,0.,pmax,"E (GeV)");
182 // h1_sclEta = bookH1("sclEta","ele supercluster #eta",nbineta,etamin,etamax,"#eta");
183 // h1_sclPhi = bookH1("sclPhi","ele supercluster #phi",nbinphi,phimin,phimax,"#phi (rad)");
184  h1_sclEt = bookH1("sclEt","ele supercluster transverse energy",nbinpt,0.,ptmax,"E_{T} (GeV)");
185 
186  // electron track
187 // h1_ambiguousTracks = bookH1("ambiguousTracks","ele # ambiguous tracks", 5,0.,5.,"N_{amb. tk}");
188 // h2_ambiguousTracksVsEta = bookH2("ambiguousTracksVsEta","ele # ambiguous tracks vs #eta", nbineta2D,etamin,etamax,5,0.,5.,"#eta","N_{amb. tk}");
189 // h2_ambiguousTracksVsPhi = bookH2("ambiguousTracksVsPhi","ele # ambiguous tracks vs #phi", nbinphi2D,phimin,phimax,5,0.,5.,"#phi(rad)","N_{amb. tk}");
190 // h2_ambiguousTracksVsPt = bookH2("ambiguousTracksVsPt","ele # ambiguous tracks vs pt", nbinpt2D,0.,ptmax,5,0.,5.,"p_{T} (GeV/c),"N_{amb. tk}");
191  h1_chi2 = bookH1("chi2","ele track #chi^{2}",100,0.,15.,"#Chi^{2}");
192  py_chi2VsEta = bookP1("chi2VsEta","ele track #chi^{2} vs #eta",nbineta2D,etamin,etamax,0.,15.,"#eta","<#chi^{2}>");
193  py_chi2VsPhi = bookP1("chi2VsPhi","ele track #chi^{2} vs #phi",nbinphi2D,phimin,phimax,0.,15.,"#phi (rad)","<#chi^{2}>");
194  //h2_chi2VsPt = bookH2("chi2VsPt","ele track #chi^{2} vs pt",nbinpt2D,0.,ptmax,50,0.,15.,"p_{T} (GeV/c)","<#chi^{2}>");
195  h1_foundHits = bookH1("foundHits","ele track # found hits",nbinfhits,0.,fhitsmax,"N_{hits}");
196  py_foundHitsVsEta = bookP1("foundHitsVsEta","ele track # found hits vs #eta",nbineta2D,etamin,etamax,0.,fhitsmax,"#eta","<# hits>");
197  py_foundHitsVsPhi = bookP1("foundHitsVsPhi","ele track # found hits vs #phi",nbinphi2D,phimin,phimax,0.,fhitsmax,"#phi (rad)","<# hits>");
198 // h2_foundHitsVsPt = bookH2("foundHitsVsPt","ele track # found hits vs pt",nbinpt2D,0.,ptmax,nbinfhits,0.,fhitsmax,"p_{T} (GeV/c)","<# hits>");
199  h1_lostHits = bookH1("lostHits","ele track # lost hits",5,0.,5.,"N_{lost hits}");
200  py_lostHitsVsEta = bookP1("lostHitsVsEta","ele track # lost hits vs #eta",nbineta2D,etamin,etamax,0.,lhitsmax,"#eta","<# hits>");
201  py_lostHitsVsPhi = bookP1("lostHitsVsPhi","ele track # lost hits vs #eta",nbinphi2D,phimin,phimax,0.,lhitsmax,"#phi (rad)","<# hits>");
202 // h2_lostHitsVsPt = bookH2("lostHitsVsPt","ele track # lost hits vs #eta",nbinpt2D,0.,ptmax,nbinlhits,0.,lhitsmax,"p_{T} (GeV/c)","<# hits>");
203 
204  // electron matching and ID
205  //h1_EoPout = bookH1( "EoPout","ele E/P_{out}",nbineop,0.,eopmax,"E_{seed}/P_{out}");
206  //h1_dEtaCl_propOut = bookH1( "dEtaCl_propOut","ele #eta_{cl} - #eta_{tr}, prop from outermost",nbindetamatch,detamatchmin,detamatchmax,"#eta_{seedcl} - #eta_{tr}");
207  //h1_dPhiCl_propOut = bookH1( "dPhiCl_propOut","ele #phi_{cl} - #phi_{tr}, prop from outermost",nbindphimatch,dphimatchmin,dphimatchmax,"#phi_{seedcl} - #phi_{tr} (rad)");
208  //h1_outerP = bookH1( "outerP","ele track outer p, mean",nbinp,0.,pmax,"P_{out} (GeV/c)");
209  //h1_outerP_mode = bookH1( "outerP_mode","ele track outer p, mode",nbinp,0.,pmax,"P_{out} (GeV/c)");
210  h1_Eop_barrel = bookH1( "Eop_barrel","ele E/P_{vertex} in barrel",nbineop,0.,eopmax,"E/P_{vertex}");
211  h1_Eop_endcaps = bookH1( "Eop_endcaps","ele E/P_{vertex} in endcaps",nbineop,0.,eopmax,"E/P_{vertex}");
212  py_EopVsPhi = bookP1("EopVsPhi","ele E/P_{vertex} vs #phi",nbinphi2D,phimin,phimax,0.,eopmax,"#phi (rad)","<E/P_{vertex}>");
213 // h2_EopVsPt = bookH2("EopVsPt","ele E/P_{vertex} vs pt",nbinpt2D,0.,ptmax,nbineop,0.,eopmax,"p_{T} (GeV/c)","E/P_{vertex}");
214  h1_EeleOPout_barrel = bookH1( "EeleOPout_barrel","ele E_{ele}/P_{out} in barrel",nbineop,0.,eopmax,"E_{ele}/P_{out}");
215  h1_EeleOPout_endcaps = bookH1( "EeleOPout_endcaps","ele E_{ele}/P_{out} in endcaps",nbineop,0.,eopmax,"E_{ele}/P_{out}");
216 // h2_EeleOPoutVsPhi = bookH2("EeleOPoutVsPhi","ele E_{ele}/P_{out} vs #phi",nbinphi2D,phimin,phimax,nbineop,0.,eopmax,"#phi","E_{ele}/P_{out}");
217 // h2_EeleOPoutVsPt = bookH2("EeleOPoutVsPt","ele E_{ele}/P_{out} vs pt",nbinpt2D,0.,ptmax,nbineop,0.,eopmax,"p_{T} (GeV/c)","E_{ele}/P_{out}");
218  h1_dEtaSc_propVtx_barrel = bookH1( "dEtaSc_propVtx_barrel","ele #eta_{sc} - #eta_{tr}, prop from vertex, in barrel",nbindetamatch,detamatchmin,detamatchmax,"#eta_{sc} - #eta_{tr}");
219  h1_dEtaSc_propVtx_endcaps = bookH1( "dEtaSc_propVtx_endcaps","ele #eta_{sc} - #eta_{tr}, prop from vertex, in endcaps",nbindetamatch,detamatchmin,detamatchmax,"#eta_{sc} - #eta_{tr}");
220  py_dEtaSc_propVtxVsPhi = bookP1("dEtaSc_propVtxVsPhi","ele #eta_{sc} - #eta_{tr}, prop from vertex vs #phi",nbinphi2D,phimin,phimax,detamatchmin,detamatchmax,"#phi (rad)","<#eta_{sc} - #eta_{tr}>");
221 // h2_dEtaSc_propVtxVsPt = bookH2("dEtaSc_propVtxVsPt","ele #eta_{sc} - #eta_{tr}, prop from vertex vs pt",nbinpt2D,0.,ptmax,nbindetamatch,detamatchmin,detamatchmax,"#eta_{sc} - #eta_{tr}");
222  h1_dEtaEleCl_propOut_barrel = bookH1( "dEtaEleCl_propOut_barrel","ele #eta_{EleCl} - #eta_{tr}, prop from outermost, in barrel",nbindetamatch,detamatchmin,detamatchmax,"#eta_{elecl} - #eta_{tr}");
223  h1_dEtaEleCl_propOut_endcaps = bookH1( "dEtaEleCl_propOut_endcaps","ele #eta_{EleCl} - #eta_{tr}, prop from outermost, in endcaps",nbindetamatch,detamatchmin,detamatchmax,"#eta_{elecl} - #eta_{tr}");
224 // h2_dEtaEleCl_propOutVsPhi = bookH2("dEtaEleCl_propOutVsPhi","ele #eta_{EleCl} - #eta_{tr}, prop from outermost vs #phi",nbinphi2D,phimin,phimax,nbindetamatch,detamatchmin,detamatchmax,"#phi (rad)","#eta_{elecl} - #eta_{tr}");
225 // h2_dEtaEleCl_propOutVsPt = bookH2("dEtaEleCl_propOutVsPt","ele #eta_{EleCl} - #eta_{tr}, prop from outermost vs pt",nbinpt2D,0.,ptmax,nbindetamatch,detamatchmin,detamatchmax,"p_{T} (GeV/c)","#eta_{elecl} - #eta_{tr}");
226  h1_dPhiSc_propVtx_barrel = bookH1( "dPhiSc_propVtx_barrel","ele #phi_{sc} - #phi_{tr}, prop from vertex, in barrel",nbindphimatch,dphimatchmin,dphimatchmax,"#phi_{sc} - #phi_{tr} (rad)");
227  h1_dPhiSc_propVtx_endcaps = bookH1( "dPhiSc_propVtx_endcaps","ele #phi_{sc} - #phi_{tr}, prop from vertex, in endcaps",nbindphimatch,dphimatchmin,dphimatchmax,"#phi_{sc} - #phi_{tr} (rad)");
228  py_dPhiSc_propVtxVsPhi = bookP1("dPhiSc_propVtxVsPhi","ele #phi_{sc} - #phi_{tr}, prop from vertex vs #phi",nbinphi2D,phimin,phimax,dphimatchmin,dphimatchmax,"#phi (rad)","<#phi_{sc} - #phi_{tr}> (rad)");
229 // h2_dPhiSc_propVtxVsPt = bookH2("dPhiSc_propVtxVsPt","ele #phi_{sc} - #phi_{tr}, prop from vertex vs pt",nbinpt2D,0.,ptmax,nbindphimatch,dphimatchmin,dphimatchmax,"p_{T} (GeV/c)","#phi_{sc} - #phi_{tr} (rad)");
230  h1_dPhiEleCl_propOut_barrel = bookH1( "dPhiEleCl_propOut_barrel","ele #phi_{EleCl} - #phi_{tr}, prop from outermost, in barrel",nbindphimatch,dphimatchmin,dphimatchmax,"#phi_{elecl} - #phi_{tr} (rad)");
231  h1_dPhiEleCl_propOut_endcaps = bookH1( "dPhiEleCl_propOut_endcaps","ele #phi_{EleCl} - #phi_{tr}, prop from outermost, in endcaps",nbindphimatch,dphimatchmin,dphimatchmax,"#phi_{elecl} - #phi_{tr} (rad)");
232 // h2_dPhiEleCl_propOutVsPhi = bookH2("dPhiEleCl_propOutVsPhi","ele #phi_{EleCl} - #phi_{tr}, prop from outermost vs #phi",nbinphi2D,phimin,phimax,nbindphimatch,dphimatchmin,dphimatchmax,"#phi_{elecl} - #phi_{tr} (rad)");
233 // h2_dPhiEleCl_propOutVsPt = bookH2("dPhiEleCl_propOutVsPt","ele #phi_{EleCl} - #phi_{tr}, prop from outermost vs pt",nbinpt2D,0.,ptmax,nbindphimatch,dphimatchmin,dphimatchmax,"p_{T} (GeV/c)","#phi_{elecl} - #phi_{tr} (rad)");
234  h1_Hoe_barrel = bookH1("Hoe_barrel","ele hadronic energy / em energy, in barrel", nbinhoe, hoemin, hoemax,"H/E","Events","ELE_LOGY E1 P") ;
235  h1_Hoe_endcaps = bookH1("Hoe_endcaps","ele hadronic energy / em energy, in endcaps", nbinhoe, hoemin, hoemax,"H/E","Events","ELE_LOGY E1 P") ;
236  py_HoeVsPhi = bookP1("HoeVsPhi","ele hadronic energy / em energy vs #phi",nbinphi2D,phimin,phimax,hoemin,hoemax,"#phi (rad)","<H/E>","E1 P") ;
237 // h2_HoeVsPt = bookH2("HoeVsPt","ele hadronic energy / em energy vs pt",nbinpt2D,0.,ptmax,nbinhoe,hoemin,hoemax,"p_{T} (GeV/c)","<H/E>","ELE_LOGY COLZ") ;
238  h1_sclSigEtaEta_barrel = bookH1("sclSigEtaEta_barrel","ele supercluster sigma ieta ieta in barrel",100,0.,0.05,"sietaieta");
239  h1_sclSigEtaEta_endcaps = bookH1("sclSigEtaEta_endcaps","ele supercluster sigma ieta ieta in endcaps",100,0.,0.05,"sietaieta");
240 
241  // fbrem
242 // h1_innerPt_mean = bookH1( "innerPt_mean","ele track inner p_{T}, mean",nbinpt,0.,ptmax,"P_{T in} (GeV/c)");
243 // h1_outerPt_mean = bookH1( "outerPt_mean","ele track outer p_{T}, mean",nbinpt,0.,ptmax,"P_{T out} (GeV/c)");
244 // h1_outerPt_mode = bookH1( "outerPt_mode","ele track outer p_{T}, mode",nbinpt,0.,ptmax,"P_{T out} (GeV/c)");
245 // //h_PinMnPout_mode = bookH1( "PinMnPout_mode","ele track inner p - outer p, mode" ,nbinp,0.,100.,"P_{in} - P_{out} (GeV/c)");
246 // h1_PinMnPout = bookH1( "PinMnPout","ele track inner p - outer p, mean" ,nbinp,0.,200.,"P_{in} - P_{out} (GeV/c)");
247 // h1_PinMnPout_mode = bookH1( "PinMnPout_mode","ele track inner p - outer p, mode",nbinp,0.,100.,"P_{in} - P_{out}, mode (GeV/c)");
248  h1_fbrem = bookH1("fbrem","ele brem fraction",100,0.,1.,"P_{in} - P_{out} / P_{in}") ;
249  py_fbremVsEta = bookP1("fbremVsEta","ele brem fraction vs #eta",nbineta2D,etamin,etamax,0.,1.,"#eta","<P_{in} - P_{out} / P_{in}>") ;
250  py_fbremVsPhi = bookP1("fbremVsPhi","ele brem fraction vs #phi",nbinphi2D,phimin,phimax,0.,1.,"#phi (rad)","<P_{in} - P_{out} / P_{in}>") ;
251 // h2_fbremVsPt = bookH2("fbremVsPt","ele brem fraction vs pt",nbinpt2D,0.,ptmax,100,0.,1.,"p_{T} (GeV/c)","<P_{in} - P_{out} / P_{in}>") ;
252  h1_classes = bookH1("classes","ele electron classes",10,0.0,10.);
253 
254  // pflow
255  h1_mva = bookH1( "mva","ele identification mva",100,-1.,1.,"mva");
256  h1_provenance = bookH1( "provenance","ele provenance",5,-2.,3.,"provenance");
257 
258  // isolation
259  h1_tkSumPt_dr03 = bookH1("tkSumPt_dr03","tk isolation sum, dR=0.3",100,0.0,20.,"TkIsoSum (GeV/c)","Events","ELE_LOGY E1 P");
260  h1_ecalRecHitSumEt_dr03 = bookH1("ecalRecHitSumEt_dr03","ecal isolation sum, dR=0.3",100,0.0,20.,"EcalIsoSum (GeV)","Events","ELE_LOGY E1 P");
261  h1_hcalTowerSumEt_dr03 = bookH1("hcalTowerSumEt_dr03","hcal isolation sum, dR=0.3",100,0.0,20.,"HcalIsoSum (GeV)","Events","ELE_LOGY E1 P");
262 // h1_hcalDepth1TowerSumEt_dr03 = bookH1("hcalDepth1TowerSumEt_dr03","hcal depth1 isolation sum, dR=0.3",100,0.0,20.,"Hcal1IsoSum (GeV)","Events","ELE_LOGY E1 P");
263 // h1_hcalDepth2TowerSumEt_dr03 = bookH1("hcalDepth2TowerSumEt_dr03","hcal depth2 isolation sum, dR=0.3",100,0.0,20.,"Hcal2IsoSum (GeV)","Events","ELE_LOGY E1 P");
264 // h1_tkSumPt_dr04 = bookH1("tkSumPt_dr04","hcal isolation sum",100,0.0,20.,"TkIsoSum (GeV/c)","Events","ELE_LOGY E1 P");
265 // h1_ecalRecHitSumEt_dr04 = bookH1("ecalRecHitSumEt_dr04","ecal isolation sum, dR=0.4",100,0.0,20.,"EcalIsoSum (GeV)","Events","ELE_LOGY E1 P");
266 // h1_hcalTowerSumEt_dr04 = bookH1("hcalTowerSumEt_dr04","hcal isolation sum, dR=0.4",100,0.0,20.,"HcalIsoSum (GeV)","Events","ELE_LOGY E1 P");
269 
270  // di-electron mass
271  setBookIndex(200) ;
272  h1_mee = bookH1("mee","ele pairs invariant mass", nbinmee, meemin, meemax,"m_{ee} (GeV/c^{2})");
273  h1_mee_os = bookH1("mee_os","ele pairs invariant mass, opposite sign", nbinmee, meemin, meemax,"m_{e^{+}e^{-}} (GeV/c^{2})");
274 
275 
276 
277  //===========================
278  // histos for matching and matched matched objects
279  //===========================
280 
281  // matching object
282  std::string matchingObjectType ;
283  Labels l;
285  if (std::string::npos != std::string(l.module).find("SuperCluster",0))
286  { matchingObjectType = "SC" ; }
287  if (matchingObjectType=="")
288  { edm::LogError("ElectronMcFakeValidator::beginJob")<<"Unknown matching object type !" ; }
289  else
290  { edm::LogInfo("ElectronMcFakeValidator::beginJob")<<"Matching object type: "<<matchingObjectType ; }
291 // std::string htitle = "# "+matchingObjectType+"s", xtitle = "N_{"+matchingObjectType+"}" ;
292 // h1_matchingObject_Num = bookH1withSumw2("matchingObject_Num",htitle,nbinfhits,0.,fhitsmax,xtitle) ;
293 
294  // matching object distributions
295  h1_matchingObject_Eta = bookH1withSumw2("matchingObject_Eta",matchingObjectType+" #eta",nbineta,etamin,etamax,"#eta_{SC}");
296 // h1_matchingObject_AbsEta = bookH1withSumw2("matchingObject_AbsEta",matchingObjectType+" |#eta|",nbineta/2,0.,etamax,"|#eta|_{SC}");
297 // h1_matchingObject_P = bookH1withSumw2("matchingObject_P",matchingObjectType+" p",nbinp,0.,pmax,"E_{SC} (GeV)");
298  h1_matchingObject_Pt = bookH1withSumw2("matchingObject_Pt",matchingObjectType+" pt",nbinpteff,5.,ptmax,"pt_{SC} (GeV/c)");
299  h1_matchingObject_Phi = bookH1withSumw2("matchingObject_Phi",matchingObjectType+" #phi",nbinphi,phimin,phimax,"#phi (rad)");
300 // h1_matchingObject_Z = bookH1withSumw2("matchingObject_Z",matchingObjectType+" z",nbinxyz,-25,25,"z (cm)");
301 
302  h1_matchedObject_Eta = bookH1withSumw2("matchedObject_Eta","Efficiency vs matching SC #eta",nbineta,etamin,etamax,"#eta_{SC}");
303 // h1_matchedObject_AbsEta = bookH1withSumw2("matchedObject_AbsEta","Efficiency vs matching SC |#eta|",nbineta/2,0.,2.5,"|#eta|_{SC}");
304  h1_matchedObject_Pt = bookH1withSumw2("matchedObject_Pt","Efficiency vs matching SC E_{T}",nbinpteff,5.,ptmax,"pt_{SC} (GeV/c)");
305  h1_matchedObject_Phi = bookH1withSumw2("matchedObject_Phi","Efficiency vs matching SC #phi",nbinphi,phimin,phimax,"#phi (rad)");
306 // h1_matchedObject_Z = bookH1withSumw2("matchedObject_Z","Efficiency vs matching SC z",nbinxyz,-25,25,"z (cm)");
307 
308 // // classes
309 // h1_matchedEle_eta = bookH1( "matchedEle_eta", "ele electron #eta", nbineta/2,0.0,etamax,"#eta");
310 // h1_matchedEle_eta_golden = bookH1( "matchedEle_eta_golden", "ele electron #eta golden", nbineta/2,0.0,etamax,"#eta");
311 // h1_matchedEle_eta_shower = bookH1( "matchedEle_eta_shower", "ele electron #eta showering", nbineta/2,0.0,etamax,"#eta");
312 // //h1_matchedEle_eta_bbrem = bookH1( "matchedEle_eta_bbrem", "ele electron #eta bbrem", nbineta/2,0.0,etamax,"#eta");
313 // //h1_matchedEle_eta_narrow = bookH1( "matchedEle_eta_narrow", "ele electron #eta narrow", nbineta/2,0.0,etamax,"#eta");
314 //
315  }
316 
318 {
319  nEvents_++ ;
320 
322  iEvent.getByToken(electronCollection_,gsfElectrons) ;
324  iEvent.getByToken(matchingObjectCollection_,recoClusters) ;
326  iEvent.getByToken(trackCollection_,tracks);
328  iEvent.getByToken(gsftrackCollection_,gsfTracks);
330  iEvent.getByToken(vertexCollection_,vertices);
331  edm::Handle<reco::BeamSpot> recoBeamSpotHandle ;
332  iEvent.getByToken(beamSpotTag_,recoBeamSpotHandle) ;
333  const BeamSpot bs = *recoBeamSpotHandle ;
334 
335  int ievt = iEvent.id().event();
336  int irun = iEvent.id().run();
337  int ils = iEvent.luminosityBlock();
338 
339  edm::LogInfo("ElectronAnalyzer::analyze")
340  <<"Treating "<<gsfElectrons.product()->size()<<" electrons"
341  <<" from event "<<ievt<<" in run "<<irun<<" and lumiblock "<<ils ;
342  //h1_num_->Fill((*gsfElectrons).size()) ;
343 
344  // selected rec electrons
345  reco::GsfElectronCollection::const_iterator gsfIter ;
346  for
347  ( gsfIter=gsfElectrons->begin() ;
348  gsfIter!=gsfElectrons->end();
349  gsfIter++ )
350  {
351  // vertex TIP
352  double vertexTIP =
353  (gsfIter->vertex().x()-bs.position().x()) * (gsfIter->vertex().x()-bs.position().x()) +
354  (gsfIter->vertex().y()-bs.position().y()) * (gsfIter->vertex().y()-bs.position().y()) ;
355  vertexTIP = sqrt(vertexTIP) ;
356 
357  // select electrons
358  if (!selected(gsfIter,vertexTIP)) continue ;
359 
360  // basic quantities
361  if (gsfIter->isEB()) h1_vertexPt_barrel->Fill( gsfIter->pt() );
362  if (gsfIter->isEE()) h1_vertexPt_endcaps->Fill( gsfIter->pt() );
363  h1_vertexEta->Fill( gsfIter->eta() );
364 // h1_vertexPhi->Fill( gsfIter->phi() );
365  h2_vertexEtaVsPhi->Fill( gsfIter->eta(), gsfIter->phi() );
366 // h1_vertexX->Fill( gsfIter->vertex().x() );
367 // h1_vertexY->Fill( gsfIter->vertex().y() );
368  h2_vertexXvsY->Fill( gsfIter->vertex().x(), gsfIter->vertex().y() );
369  h1_vertexZ->Fill( gsfIter->vertex().z() );
370 // h1_vertexP->Fill( gsfIter->p() );
371 // h1_Et->Fill( gsfIter->superCluster()->energy()/cosh( gsfIter->superCluster()->eta()) );
372 // h1_vertexTIP->Fill( vertexTIP );
373 // h1_charge->Fill( gsfIter->charge() );
374 
375  // supercluster related distributions
376  reco::SuperClusterRef sclRef = gsfIter->superCluster() ;
377  // ALREADY DONE IN GSF ELECTRON CORE
378  // if (!gsfIter->ecalDrivenSeed()&&gsfIter->trackerDrivenSeed())
379  // sclRef = gsfIter->parentSuperCluster() ;
380 // h1_sclEn->Fill(sclRef->energy());
381 // h1_sclEta->Fill(sclRef->eta());
382 // h1_sclPhi->Fill(sclRef->phi());
383  double R=TMath::Sqrt(sclRef->x()*sclRef->x() + sclRef->y()*sclRef->y() +sclRef->z()*sclRef->z());
384  double Rt=TMath::Sqrt(sclRef->x()*sclRef->x() + sclRef->y()*sclRef->y());
385  h1_sclEt->Fill(sclRef->energy()*(Rt/R));
386 
387  // track related distributions
388 // h1_ambiguousTracks->Fill( gsfIter->ambiguousGsfTracksSize() );
389 // h2_ambiguousTracksVsEta->Fill( gsfIter->eta(), gsfIter->ambiguousGsfTracksSize() );
390 // h2_ambiguousTracksVsPhi->Fill( gsfIter->phi(), gsfIter->ambiguousGsfTracksSize() );
391 // h2_ambiguousTracksVsPt->Fill( gsfIter->pt(), gsfIter->ambiguousGsfTracksSize() );
392  if (!readAOD_)
393  { // track extra does not exist in AOD
394  h1_foundHits->Fill( gsfIter->gsfTrack()->numberOfValidHits() );
395  py_foundHitsVsEta->Fill( gsfIter->eta(), gsfIter->gsfTrack()->numberOfValidHits() );
396  py_foundHitsVsPhi->Fill( gsfIter->phi(), gsfIter->gsfTrack()->numberOfValidHits() );
397  //h2_foundHitsVsPt->Fill( gsfIter->pt(), gsfIter->gsfTrack()->numberOfValidHits() );
398  h1_lostHits->Fill( gsfIter->gsfTrack()->numberOfLostHits() );
399  py_lostHitsVsEta->Fill( gsfIter->eta(), gsfIter->gsfTrack()->numberOfLostHits() );
400  py_lostHitsVsPhi->Fill( gsfIter->phi(), gsfIter->gsfTrack()->numberOfLostHits() );
401  //h2_lostHitsVsPt->Fill( gsfIter->pt(), gsfIter->gsfTrack()->numberOfLostHits() );
402  h1_chi2->Fill( gsfIter->gsfTrack()->normalizedChi2() );
403  py_chi2VsEta->Fill( gsfIter->eta(), gsfIter->gsfTrack()->normalizedChi2() );
404  py_chi2VsPhi->Fill( gsfIter->phi(), gsfIter->gsfTrack()->normalizedChi2() );
405  //h2_chi2VsPt->Fill( gsfIter->pt(), gsfIter->gsfTrack()->normalizedChi2() );
406  }
407 
408  // match distributions
409  if (gsfIter->isEB())
410  {
411  h1_Eop_barrel->Fill( gsfIter->eSuperClusterOverP() );
412  h1_EeleOPout_barrel->Fill( gsfIter->eEleClusterOverPout() );
413  h1_dEtaSc_propVtx_barrel->Fill(gsfIter->deltaEtaSuperClusterTrackAtVtx());
414  h1_dEtaEleCl_propOut_barrel->Fill(gsfIter->deltaEtaEleClusterTrackAtCalo());
415  h1_dPhiSc_propVtx_barrel->Fill(gsfIter->deltaPhiSuperClusterTrackAtVtx());
416  h1_dPhiEleCl_propOut_barrel->Fill(gsfIter->deltaPhiEleClusterTrackAtCalo());
417  h1_Hoe_barrel->Fill(gsfIter->hadronicOverEm());
418  h1_sclSigEtaEta_barrel->Fill( gsfIter->scSigmaEtaEta() );
419  }
420  if (gsfIter->isEE())
421  {
422  h1_Eop_endcaps->Fill( gsfIter->eSuperClusterOverP() );
423  h1_EeleOPout_endcaps->Fill( gsfIter->eEleClusterOverPout() );
424  h1_dEtaSc_propVtx_endcaps->Fill(gsfIter->deltaEtaSuperClusterTrackAtVtx());
425  h1_dEtaEleCl_propOut_endcaps->Fill(gsfIter->deltaEtaEleClusterTrackAtCalo());
426  h1_dPhiSc_propVtx_endcaps->Fill(gsfIter->deltaPhiSuperClusterTrackAtVtx());
427  h1_dPhiEleCl_propOut_endcaps->Fill(gsfIter->deltaPhiEleClusterTrackAtCalo());
428  h1_Hoe_endcaps->Fill(gsfIter->hadronicOverEm());
429  h1_sclSigEtaEta_endcaps->Fill( gsfIter->scSigmaEtaEta() );
430  }
431  py_EopVsPhi->Fill( gsfIter->phi(), gsfIter->eSuperClusterOverP() );
432 // h2_EopVsPt->Fill( gsfIter->pt(), gsfIter->eSuperClusterOverP() );
433 // h2_EeleOPoutVsPhi->Fill( gsfIter->phi(), gsfIter->eEleClusterOverPout() );
434 // h2_EeleOPoutVsPt->Fill( gsfIter->pt(), gsfIter->eEleClusterOverPout() );
435  py_dEtaSc_propVtxVsPhi->Fill(gsfIter->phi(), gsfIter->deltaEtaSuperClusterTrackAtVtx());
436 // h2_dEtaSc_propVtxVsPt->Fill(gsfIter->pt(), gsfIter->deltaEtaSuperClusterTrackAtVtx());
437 // h2_dEtaEleCl_propOutVsPhi->Fill(gsfIter->phi(), gsfIter->deltaEtaEleClusterTrackAtCalo());
438 // h2_dEtaEleCl_propOutVsPt->Fill(gsfIter->pt(), gsfIter->deltaEtaEleClusterTrackAtCalo());
439  py_dPhiSc_propVtxVsPhi->Fill(gsfIter->phi(), gsfIter->deltaPhiSuperClusterTrackAtVtx());
440 // h2_dPhiSc_propVtxVsPt->Fill(gsfIter->pt(), gsfIter->deltaPhiSuperClusterTrackAtVtx());
441 // h2_dPhiEleCl_propOutVsPhi->Fill(gsfIter->phi(), gsfIter->deltaPhiEleClusterTrackAtCalo());
442 // h2_dPhiEleCl_propOutVsPt->Fill(gsfIter->pt(), gsfIter->deltaPhiEleClusterTrackAtCalo());
443  py_HoeVsPhi->Fill(gsfIter->phi(), gsfIter->hadronicOverEm());
444 // h2_HoeVsPt->Fill(gsfIter->pt(), gsfIter->hadronicOverEm());
445 
446 // // from gsf track interface, hence using mean
447 // if (!readAOD_)
448 // { // track extra does not exist in AOD
449 // h_PinMnPout->Fill( gsfIter->gsfTrack()->innerMomentum().R() - gsfIter->gsfTrack()->outerMomentum().R() );
450 // //h_outerP->Fill( gsfIter->gsfTrack()->outerMomentum().R() );
451 // h_innerPt_mean->Fill( gsfIter->gsfTrack()->innerMomentum().Rho() );
452 // h_outerPt_mean->Fill( gsfIter->gsfTrack()->outerMomentum().Rho() );
453 // }
454 //
455 // // from electron interface, hence using mode
456 // h_PinMnPout_mode->Fill( gsfIter->trackMomentumAtVtx().R() - gsfIter->trackMomentumOut().R() );
457 // //h_outerP_mode->Fill( gsfIter->trackMomentumOut().R() );
458 // h_outerPt_mode->Fill( gsfIter->trackMomentumOut().Rho() );
459 //
460 
461  // fbrem, classes
462  h1_fbrem->Fill(gsfIter->fbrem()) ;
463  py_fbremVsEta->Fill(gsfIter->eta(),gsfIter->fbrem()) ;
464  py_fbremVsPhi->Fill(gsfIter->phi(),gsfIter->fbrem()) ;
465 // h2_fbremVsPt->Fill(gsfIter->pt(),gsfIter->fbrem()) ;
466  int eleClass = gsfIter->classification() ;
467  if (gsfIter->isEE()) eleClass+=5;
468  h1_classes->Fill(eleClass) ;
469 
470 
471  // pflow
472  h1_mva->Fill(gsfIter->mva()) ;
473  if (gsfIter->ecalDrivenSeed()) h1_provenance->Fill(1.) ;
474  if (gsfIter->trackerDrivenSeed()) h1_provenance->Fill(-1.) ;
475  if (gsfIter->trackerDrivenSeed()||gsfIter->ecalDrivenSeed()) h1_provenance->Fill(0.);
476  if (gsfIter->trackerDrivenSeed()&&!gsfIter->ecalDrivenSeed()) h1_provenance->Fill(-2.);
477  if (!gsfIter->trackerDrivenSeed()&&gsfIter->ecalDrivenSeed()) h1_provenance->Fill(2.);
478 
479  // isolation
480  h1_tkSumPt_dr03->Fill(gsfIter->dr03TkSumPt());
481  h1_ecalRecHitSumEt_dr03->Fill(gsfIter->dr03EcalRecHitSumEt());
482  h1_hcalTowerSumEt_dr03->Fill(gsfIter->dr03HcalTowerSumEt());
483 // h1_hcalDepth1TowerSumEt_dr03->Fill(gsfIter->dr03HcalDepth1TowerSumEt());
484 // h1_hcalDepth2TowerSumEt_dr03->Fill(gsfIter->dr03HcalDepth2TowerSumEt());
485 // h1_tkSumPt_dr04->Fill(gsfIter->dr04TkSumPt());
486 // h1_ecalRecHitSumEt_dr04->Fill(gsfIter->dr04EcalRecHitSumEt());
487 // h1_hcalTowerSumEt_dr04->Fill(gsfIter->dr04HcalTowerSumEt());
490 
491  }
492 
493  // association matching object-reco electrons
494  int matchingObjectNum=0;
495  reco::SuperClusterCollection::const_iterator moIter ;
496  for
497  ( moIter=recoClusters->begin() ;
498  moIter!=recoClusters->end() ;
499  moIter++ )
500  {
501 // // number of matching objects
502  matchingObjectNum++;
503 
504  if
505  ( moIter->energy()/cosh(moIter->eta())>maxPtMatchingObject_ ||
506  std::abs(moIter->eta())> maxAbsEtaMatchingObject_ )
507  { continue ; }
508 
509 // // suppress the endcaps
510 // //if (std::abs(moIter->eta()) > 1.5) continue;
511 // // select central z
512 // //if ( std::abs((*mcIter)->production_vertex()->position().z())>50.) continue;
513 
514  h1_matchingObject_Eta->Fill( moIter->eta() );
515 // h1_matchingObject_AbsEta->Fill( std::abs(moIter->eta()) );
516 // h1_matchingObject_P->Fill( moIter->energy() );
517  h1_matchingObject_Pt->Fill( moIter->energy()/cosh(moIter->eta()) );
518  h1_matchingObject_Phi->Fill( moIter->phi() );
519 // h1_matchingObject_Z->Fill( moIter->z() );
520 
521  bool okGsfFound = false ;
522  double gsfOkRatio = 999999999. ;
523  reco::GsfElectron bestGsfElectron ;
524  reco::GsfElectronCollection::const_iterator gsfIter ;
525  for
526  ( gsfIter=gsfElectrons->begin() ;
527  gsfIter!=gsfElectrons->end() ;
528  gsfIter++ )
529  {
530  reco::GsfElectronCollection::const_iterator gsfIter2 ;
531  for
532  ( gsfIter2=gsfIter+1;
533  gsfIter2!=gsfElectrons->end() ;
534  gsfIter2++ )
535  {
536  float invMass = computeInvMass(*gsfIter,*gsfIter2) ;
537  if(matchingObjectNum == 1){h1_mee->Fill(invMass) ;}
538  if ((matchingObjectNum == 1) && (((gsfIter->charge())*(gsfIter2->charge()))<0.))
539  { h1_mee_os->Fill(invMass) ; }
540  }
541 
542  double vertexTIP =
543  (gsfIter->vertex().x()-bs.position().x()) * (gsfIter->vertex().x()-bs.position().x()) +
544  (gsfIter->vertex().y()-bs.position().y()) * (gsfIter->vertex().y()-bs.position().y()) ;
545  vertexTIP = sqrt(vertexTIP) ;
546 
547  // select electrons
548  if (!selected(gsfIter,vertexTIP)) continue ;
549 
550  // matching with a cone in eta phi
551  if ( matchingCondition_ == "Cone" )
552  {
553  double dphi = gsfIter->phi()-moIter->phi() ;
554  if (std::abs(dphi)>CLHEP::pi)
555  { dphi = dphi < 0? (CLHEP::twopi) + dphi : dphi - CLHEP::twopi ; }
556  double deltaR = sqrt(pow((moIter->eta()-gsfIter->eta()),2) + pow(dphi,2)) ;
557  if ( deltaR < deltaR_ )
558  {
559  //if ( (genPc->pdg_id() == 11) && (gsfIter->charge() < 0.) || (genPc->pdg_id() == -11) &&
560  //(gsfIter->charge() > 0.) ){
561  double tmpGsfRatio = gsfIter->p()/moIter->energy() ;
562  if ( std::abs(tmpGsfRatio-1) < std::abs(gsfOkRatio-1) )
563  {
564  gsfOkRatio = tmpGsfRatio;
565  bestGsfElectron=*gsfIter;
566  okGsfFound = true;
567  }
568  //}
569  }
570  }
571  } // loop over rec ele to look for the best one
572  if (okGsfFound)
573  {
574  // generated distributions for matched electrons
575  h1_matchedObject_Eta->Fill( moIter->eta() );
576  // h1_matchedObject_AbsEta->Fill( std::abs(moIter->eta()) );
577  h1_matchedObject_Pt->Fill( moIter->energy()/cosh(moIter->eta()) );
578  h1_matchedObject_Phi->Fill( moIter->phi() );
579  // h1_matchedObject_Z->Fill( moIter->z() );
580 
581  //classes
582  // int eleClass = bestGsfElectron.classification() ;
583  // h_classes->Fill(eleClass) ;
584  // h_matchedEle_eta->Fill(std::abs(bestGsfElectron.eta()));
585  // if (bestGsfElectron.classification() == GsfElectron::GOLDEN) h_matchedEle_eta_golden->Fill(std::abs(bestGsfElectron.eta()));
586  // if (bestGsfElectron.classification() == GsfElectron::SHOWERING) h_matchedEle_eta_shower->Fill(std::abs(bestGsfElectron.eta()));
587  // //if (bestGsfElectron.classification() == GsfElectron::BIGBREM) h_matchedEle_eta_bbrem->Fill(std::abs(bestGsfElectron.eta()));
588  // //if (bestGsfElectron.classification() == GsfElectron::OLDNARROW) h_matchedEle_eta_narrow->Fill(std::abs(bestGsfElectron.eta()));
589  }
590 
591  } // loop overmatching object
592 
593 // h_matchingObject_Num->Fill(matchingObjectNum) ;
594 
595  }
596 
598  ( const reco::GsfElectron & e1,
599  const reco::GsfElectron & e2 )
600  {
601  math::XYZTLorentzVector p12 = e1.p4()+e2.p4() ;
602  float mee2 = p12.Dot(p12) ;
603  float invMass = sqrt(mee2) ;
604  return invMass ;
605  }
606 
607 bool ElectronAnalyzer::selected( const reco::GsfElectronCollection::const_iterator & gsfIter , double vertexTIP )
608  {
609  if ((Selection_>0)&&generalCut(gsfIter)) return false ;
610  if ((Selection_>=1)&&etCut(gsfIter)) return false ;
611  if ((Selection_>=2)&&isolationCut(gsfIter,vertexTIP)) return false ;
612  if ((Selection_>=3)&&idCut(gsfIter)) return false ;
613  return true ;
614  }
615 
616 bool ElectronAnalyzer::generalCut( const reco::GsfElectronCollection::const_iterator & gsfIter)
617  {
618  if (std::abs(gsfIter->eta())>maxAbsEta_) return true ;
619  if (gsfIter->pt()<minPt_) return true ;
620 
621  if (gsfIter->isEB() && isEE_) return true ;
622  if (gsfIter->isEE() && isEB_) return true ;
623  if (gsfIter->isEBEEGap() && isNotEBEEGap_) return true ;
624 
625  if (gsfIter->ecalDrivenSeed() && isTrackerDriven_) return true ;
626  if (gsfIter->trackerDrivenSeed() && isEcalDriven_) return true ;
627 
628  return false ;
629  }
630 
631 bool ElectronAnalyzer::etCut( const reco::GsfElectronCollection::const_iterator & gsfIter )
632  {
633  if (gsfIter->superCluster()->energy()/cosh(gsfIter->superCluster()->eta())<minEt_) return true ;
634 
635  return false ;
636  }
637 
638 bool ElectronAnalyzer::isolationCut( const reco::GsfElectronCollection::const_iterator & gsfIter, double vertexTIP )
639  {
640  if (gsfIter->isEB() && vertexTIP > tipMaxBarrel_) return true ;
641  if (gsfIter->isEE() && vertexTIP > tipMaxEndcaps_) return true ;
642 
643  if (gsfIter->dr03TkSumPt() > tkIso03Max_) return true ;
644  if (gsfIter->isEB() && gsfIter->dr03HcalDepth1TowerSumEt() > hcalIso03Depth1MaxBarrel_) return true ;
645  if (gsfIter->isEE() && gsfIter->dr03HcalDepth1TowerSumEt() > hcalIso03Depth1MaxEndcaps_) return true ;
646  if (gsfIter->isEE() && gsfIter->dr03HcalDepth2TowerSumEt() > hcalIso03Depth2MaxEndcaps_) return true ;
647  if (gsfIter->isEB() && gsfIter->dr03EcalRecHitSumEt() > ecalIso03MaxBarrel_) return true ;
648  if (gsfIter->isEE() && gsfIter->dr03EcalRecHitSumEt() > ecalIso03MaxEndcaps_) return true ;
649 
650  return false ;
651  }
652 
653 bool ElectronAnalyzer::idCut( const reco::GsfElectronCollection::const_iterator & gsfIter )
654  {
655  if (gsfIter->isEB() && gsfIter->eSuperClusterOverP() < eOverPMinBarrel_) return true ;
656  if (gsfIter->isEB() && gsfIter->eSuperClusterOverP() > eOverPMaxBarrel_) return true ;
657  if (gsfIter->isEE() && gsfIter->eSuperClusterOverP() < eOverPMinEndcaps_) return true ;
658  if (gsfIter->isEE() && gsfIter->eSuperClusterOverP() > eOverPMaxEndcaps_) return true ;
659  if (gsfIter->isEB() && std::abs(gsfIter->deltaEtaSuperClusterTrackAtVtx()) < dEtaMinBarrel_) return true ;
660  if (gsfIter->isEB() && std::abs(gsfIter->deltaEtaSuperClusterTrackAtVtx()) > dEtaMaxBarrel_) return true ;
661  if (gsfIter->isEE() && std::abs(gsfIter->deltaEtaSuperClusterTrackAtVtx()) < dEtaMinEndcaps_) return true ;
662  if (gsfIter->isEE() && std::abs(gsfIter->deltaEtaSuperClusterTrackAtVtx()) > dEtaMaxEndcaps_) return true ;
663  if (gsfIter->isEB() && std::abs(gsfIter->deltaPhiSuperClusterTrackAtVtx()) < dPhiMinBarrel_) return true ;
664  if (gsfIter->isEB() && std::abs(gsfIter->deltaPhiSuperClusterTrackAtVtx()) > dPhiMaxBarrel_) return true ;
665  if (gsfIter->isEE() && std::abs(gsfIter->deltaPhiSuperClusterTrackAtVtx()) < dPhiMinEndcaps_) return true ;
666  if (gsfIter->isEE() && std::abs(gsfIter->deltaPhiSuperClusterTrackAtVtx()) > dPhiMaxEndcaps_) return true ;
667  if (gsfIter->isEB() && gsfIter->scSigmaIEtaIEta() < sigIetaIetaMinBarrel_) return true ;
668  if (gsfIter->isEB() && gsfIter->scSigmaIEtaIEta() > sigIetaIetaMaxBarrel_) return true ;
669  if (gsfIter->isEE() && gsfIter->scSigmaIEtaIEta() < sigIetaIetaMinEndcaps_) return true ;
670  if (gsfIter->isEE() && gsfIter->scSigmaIEtaIEta() > sigIetaIetaMaxEndcaps_) return true ;
671  if (gsfIter->isEB() && gsfIter->hadronicOverEm() > hadronicOverEmMaxBarrel_) return true ;
672  if (gsfIter->isEE() && gsfIter->hadronicOverEm() > hadronicOverEmMaxEndcaps_) return true ;
673 
674  return false ;
675  }
RunNumber_t run() const
Definition: EventID.h:42
MonitorElement * h1_foundHits
virtual void book()
T getParameter(std::string const &) const
EventNumber_t event() const
Definition: EventID.h:44
MonitorElement * bookP1(const std::string &name, const std::string &title, int nchX, double lowX, double highX, double lowY, double highY, const std::string &titleX="", const std::string &titleY="", Option_t *option="E1 P")
MonitorElement * bookH1(const std::string &name, const std::string &title, int nchX, double lowX, double highX, const std::string &titleX="", const std::string &titleY="Events", Option_t *option="E1 P")
double hadronicOverEmMaxEndcaps_
MonitorElement * h1_mee_os
const LorentzVector & p4(P4Kind kind) const
Definition: GsfElectron.cc:229
bool selected(const reco::GsfElectronCollection::const_iterator &gsfIter, double vertexTIP)
MonitorElement * h1_dPhiSc_propVtx_barrel
unsigned int nEvents_
bool getByToken(EDGetToken token, Handle< PROD > &result) const
Definition: Event.h:434
MonitorElement * h1_vertexPt_barrel
MonitorElement * py_lostHitsVsEta
MonitorElement * h1_sclSigEtaEta_barrel
MonitorElement * py_chi2VsEta
edm::EDGetTokenT< reco::SuperClusterCollection > matchingObjectCollection_
MonitorElement * h1_vertexEta
MonitorElement * py_chi2VsPhi
MonitorElement * h1_Eop_endcaps
MonitorElement * h1_ecalRecHitSumEt_dr03
edm::LuminosityBlockNumber_t luminosityBlock() const
Definition: EventBase.h:59
MonitorElement * h1_hcalTowerSumEt_dr03
MonitorElement * h1_matchingObject_Eta
MonitorElement * h1_Hoe_barrel
edm::InputTag triggerResults_
MonitorElement * py_HoeVsPhi
MonitorElement * h1_matchedObject_Pt
double sigIetaIetaMinBarrel_
MonitorElement * bookH1withSumw2(const std::string &name, const std::string &title, int nchX, double lowX, double highX, const std::string &titleX="", const std::string &titleY="Events", Option_t *option="E1 P")
MonitorElement * h1_matchedObject_Phi
void Fill(long long x)
const Double_t pi
MonitorElement * h1_tkSumPt_dr03
XYZTLorentzVectorD XYZTLorentzVector
Lorentz vector with cylindrical internal representation using pseudorapidity.
Definition: LorentzVector.h:29
double sigIetaIetaMaxBarrel_
int iEvent
Definition: GenABIO.cc:230
MonitorElement * h2_vertexXvsY
MonitorElement * py_fbremVsEta
MonitorElement * h1_provenance
MonitorElement * h1_dEtaEleCl_propOut_barrel
MonitorElement * py_EopVsPhi
MonitorElement * h1_Eop_barrel
T sqrt(T t)
Definition: SSEVec.h:48
double sigIetaIetaMinEndcaps_
MonitorElement * py_dEtaSc_propVtxVsPhi
double sigIetaIetaMaxEndcaps_
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
std::string matchingCondition_
double hcalIso03Depth1MaxBarrel_
MonitorElement * h1_dEtaEleCl_propOut_endcaps
MonitorElement * h1_Hoe_endcaps
tuple conf
Definition: dbtoconf.py:185
ElectronAnalyzer(const edm::ParameterSet &conf)
edm::EDGetTokenT< reco::GsfTrackCollection > gsftrackCollection_
MonitorElement * h1_vertexPt_endcaps
MonitorElement * py_lostHitsVsPhi
double deltaR(double eta1, double eta2, double phi1, double phi2)
Definition: TreeUtility.cc:17
MonitorElement * h1_vertexZ
MonitorElement * py_dPhiSc_propVtxVsPhi
double hcalIso03Depth1MaxEndcaps_
MonitorElement * h1_dPhiEleCl_propOut_endcaps
virtual void analyze(const edm::Event &e, const edm::EventSetup &c)
MonitorElement * py_fbremVsPhi
MonitorElement * py_foundHitsVsPhi
bool etCut(const reco::GsfElectronCollection::const_iterator &gsfIter)
tuple tracks
Definition: testEve_cfg.py:39
MonitorElement * h1_fbrem
edm::EDGetTokenT< reco::TrackCollection > trackCollection_
MonitorElement * h1_chi2
double maxAbsEtaMatchingObject_
MonitorElement * h1_lostHits
MonitorElement * h2_vertexEtaVsPhi
MonitorElement * h1_EeleOPout_endcaps
MonitorElement * h1_mee
T const * product() const
Definition: Handle.h:81
MonitorElement * bookH2(const std::string &name, const std::string &title, int nchX, double lowX, double highX, int nchY, double lowY, double highY, const std::string &titleX="", const std::string &titleY="", Option_t *option="COLZ")
edm::EDGetTokenT< reco::GsfElectronCollection > electronCollection_
MonitorElement * h1_classes
MonitorElement * h1_sclEt
void labelsForToken(EDGetToken iToken, Labels &oLabels) const
MonitorElement * h1_EeleOPout_barrel
edm::EventID id() const
Definition: EventBase.h:56
bool generalCut(const reco::GsfElectronCollection::const_iterator &gsfIter)
MonitorElement * h1_dEtaSc_propVtx_barrel
float computeInvMass(const reco::GsfElectron &e1, const reco::GsfElectron &e2)
MonitorElement * h1_matchingObject_Phi
MonitorElement * h1_dPhiSc_propVtx_endcaps
edm::EDGetTokenT< reco::BeamSpot > beamSpotTag_
virtual ~ElectronAnalyzer()
MonitorElement * h1_sclSigEtaEta_endcaps
const Point & position() const
position
Definition: BeamSpot.h:62
volatile std::atomic< bool > shutdown_flag false
MonitorElement * py_foundHitsVsEta
edm::EDGetTokenT< reco::VertexCollection > vertexCollection_
bool idCut(const reco::GsfElectronCollection::const_iterator &gsfIter)
double hcalIso03Depth2MaxEndcaps_
double hadronicOverEmMaxBarrel_
MonitorElement * h1_matchedObject_Eta
MonitorElement * h1_matchingObject_Pt
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:40
MonitorElement * h1_dPhiEleCl_propOut_barrel
MonitorElement * h1_dEtaSc_propVtx_endcaps
MonitorElement * h1_mva
bool isolationCut(const reco::GsfElectronCollection::const_iterator &gsfIter, double vertexTIP)