CMS 3D CMS Logo

isotracks_cff.py
Go to the documentation of this file.
1 import FWCore.ParameterSet.Config as cms
3 
4 finalIsolatedTracks = cms.EDProducer("IsolatedTrackCleaner",
5  tracks = cms.InputTag("isolatedTracks"),
6  cut = cms.string("((pt>5 && (abs(pdgId) == 11 || abs(pdgId) == 13)) || pt > 10) && (abs(pdgId) < 15 || abs(eta) < 2.5) && abs(dxy) < 0.2 && abs(dz) < 0.1 && ((pfIsolationDR03().chargedHadronIso < 5 && pt < 25) || pfIsolationDR03().chargedHadronIso/pt < 0.2)"),
7  finalLeptons = cms.VInputTag(
8  cms.InputTag("finalElectrons"),
9  cms.InputTag("finalLooseMuons"),
10  ),
11 )
12 
13 isoForIsoTk = cms.EDProducer("IsoTrackIsoValueMapProducer",
14  src = cms.InputTag("finalIsolatedTracks"),
15  relative = cms.bool(True),
16  rho_MiniIso = cms.InputTag("fixedGridRhoFastjetAll"),
17  EAFile_MiniIso = cms.FileInPath("PhysicsTools/NanoAOD/data/effAreaMuons_cone03_pfNeuHadronsAndPhotons_80X.txt"),
18 )
19 
20 isFromLostTrackForIsoTk = cms.EDProducer("IsFromLostTrackMapProducer",
21  srcIsoTracks = cms.InputTag("finalIsolatedTracks"),
22  packedPFCandidates = cms.InputTag("packedPFCandidates"),
23  lostTracks = cms.InputTag("lostTracks"),
24 )
25 
26 isoTrackTable = cms.EDProducer("SimpleCandidateFlatTableProducer",
27  src = cms.InputTag("finalIsolatedTracks"),
28  cut = cms.string(""), # filtered already above
29  name = cms.string("IsoTrack"),
30  doc = cms.string("isolated tracks after basic selection (" + finalIsolatedTracks.cut.value() + ") and lepton veto"),
31  singleton = cms.bool(False), # the number of entries is variable
32  extension = cms.bool(False), # this is the main table for the muons
33  variables = cms.PSet(P3Vars,
34  dz = Var("dz",float,doc="dz (with sign) wrt first PV, in cm",precision=10),
35  dxy = Var("dxy",float,doc="dxy (with sign) wrt first PV, in cm",precision=10),
36  pfRelIso03_chg = Var("pfIsolationDR03().chargedHadronIso/pt",float,doc="PF relative isolation dR=0.3, charged component",precision=10),
37  pfRelIso03_all = Var("(pfIsolationDR03().chargedHadronIso + max(pfIsolationDR03().neutralHadronIso + pfIsolationDR03().photonIso - pfIsolationDR03().puChargedHadronIso/2,0.0))/pt",float,doc="PF relative isolation dR=0.3, total (deltaBeta corrections)",precision=10),
38  isPFcand = Var("packedCandRef().isNonnull()",bool,doc="if isolated track is a PF candidate"),
39  fromPV = Var("fromPV", int, doc="isolated track comes from PV"),
40  pdgId = Var("pdgId",int,doc="PDG id of PF cand"),
41  isHighPurityTrack = Var("isHighPurityTrack",bool,doc="track is high purity"),
42  ),
43  externalVariables = cms.PSet(
44  miniPFRelIso_chg = ExtVar("isoForIsoTk:miniIsoChg",float,doc="mini PF relative isolation, charged component",precision=10),
45  miniPFRelIso_all = ExtVar("isoForIsoTk:miniIsoAll",float,doc="mini PF relative isolation, total (with scaled rho*EA PU corrections)",precision=10),
46  isFromLostTrack = ExtVar("isFromLostTrackForIsoTk:isFromLostTrack",bool,doc="if isolated track comes from a lost track"),
47  ),
48 )
49 
50 isoTrackSequence = cms.Sequence(finalIsolatedTracks + isoForIsoTk + isFromLostTrackForIsoTk)
51 isoTrackTables = cms.Sequence(isoTrackTable)
52 
common_cff
common_cff.Var
def Var(expr, valtype, compression=None, doc=None, mcOnly=False, precision=-1)
Definition: common_cff.py:20
common_cff.ExtVar
def ExtVar(tag, valtype, compression=None, doc=None, mcOnly=False, precision=-1)
Definition: common_cff.py:31