Variables
tuple	DenominatorMEname = cms.untracked.string("massVsEtaJpsi_denom")
tuple	EfficiencyMEname = cms.untracked.string("massVsEtaJpsi_efficiency")
tuple	hltMuonEfficiencies
tuple	hltMuonPostVal
tuple	jpsiClient = zClient.clone()
tuple	JpsiPars
tuple	NumeratorMEname = cms.untracked.string("massVsEtaJpsi_numer")
tuple	zClient
tuple	ZPars

Variable Documentation

tuple MuonPostProcessor_cff::DenominatorMEname = cms.untracked.string("massVsEtaJpsi_denom")

Definition at line 71 of file MuonPostProcessor_cff.py.

tuple MuonPostProcessor_cff::EfficiencyMEname = cms.untracked.string("massVsEtaJpsi_efficiency")

Definition at line 72 of file MuonPostProcessor_cff.py.

tuple MuonPostProcessor_cff::hltMuonEfficiencies

Initial value:

00001 cms.EDAnalyzer("DQMGenericClient",
00002 
00003     subDirs        = cms.untracked.vstring("HLT/Muon/Distributions.*"),
00004     verbose        = cms.untracked.uint32(0), # Set to 2 for all messages
00005     outputFileName = cms.untracked.string(''),
00006     commands       = cms.vstring(),
00007     resolution     = cms.vstring(),
00008     efficiency     = cms.vstring(
00009         "efficiencyPhiVsEta 'Efficiency to Match Reco Muons to Trigger Objects; #eta^{reco}; #phi^{reco}' efficiencyPhiVsEta_numer efficiencyPhiVsEta_denom",
00010     ),
00011 
00012     efficiencyProfile = cms.untracked.vstring(
00013         "efficiencyEta 'Efficiency to Match Reco Muons to Trigger Objects; #eta^{reco}; N(#mu matched to trigger object) / N(#mu)' efficiencyEta_numer efficiencyEta_denom",
00014         "efficiencyPhi 'Efficiency to Match Reco Muons to Trigger Objects; #phi^{reco}; N(#mu matched to trigger object) / N(#mu)' efficiencyPhi_numer efficiencyPhi_denom",
00015         "efficiencyTurnOn 'Efficiency to Match Reco Muons to Trigger Objects; p_{T}^{reco}; N(#mu matched to trigger object) / N(#mu)' efficiencyTurnOn_numer efficiencyTurnOn_denom",
00016         "efficiencyD0 'Efficiency to Match Reco Muons to Trigger Objects; d0^{reco}; N(#mu matched to trigger object) / N(#mu)' efficiencyD0_numer efficiencyD0_denom",
00017         "efficiencyZ0 'Efficiency to Match Reco Muons to Trigger Objects; z0^{reco}; N(#mu matched to trigger object) / N(#mu)' efficiencyZ0_numer efficiencyZ0_denom",
00018         "efficiencyCharge 'Efficiency to Match Reco Muons to Trigger Objects; q^{reco}; N(#mu matched to trigger object) / N(#mu)' efficiencyCharge_numer efficiencyCharge_denom",
00019         "fakerateEta 'Trigger Fake Rate; #eta^{trigger}; N(unmatched trigger objects) / N(trigger objects)' fakerateEta_numer fakerateEta_denom",
00020         "fakeratePhi 'Trigger Fake Rate; #phi^{trigger}; N(unmatched trigger objects) / N(trigger objects)' fakeratePhi_numer fakeratePhi_denom",
00021         "fakerateTurnOn 'Trigger Fake Rate; p_{T}^{trigger}; N(unmatched trigger objects) / N(trigger objects)' fakerateTurnOn_numer fakerateTurnOn_denom",
00022     ),
00023 
00024 )

Definition at line 3 of file MuonPostProcessor_cff.py.

tuple MuonPostProcessor_cff::hltMuonPostVal

Initial value:

00001 cms.Sequence(
00002     hltMuonEfficiencies *
00003     zClient *
00004     jpsiClient
00005 )

Definition at line 77 of file MuonPostProcessor_cff.py.

tuple MuonPostProcessor_cff::jpsiClient = zClient.clone()

Definition at line 67 of file MuonPostProcessor_cff.py.

tuple MuonPostProcessor_cff::JpsiPars

Initial value:

00001 cms.untracked.PSet(
00002     MassDimension = cms.untracked.int32(2),
00003     FitFunction = cms.untracked.string("VoigtianPlusExponential"),
00004     ExpectedMean = cms.untracked.double(3.1),
00005     ExpectedSigma = cms.untracked.double(1.),
00006     FixedWidth = cms.untracked.double(0.1),
00007     FitRangeLow = cms.untracked.double(0.),
00008     FitRangeHigh = cms.untracked.double(6.),
00009     SignalRangeLow = cms.untracked.double(2.9),
00010     SignalRangeHigh = cms.untracked.double(3.3),
00011 )

Definition at line 40 of file MuonPostProcessor_cff.py.

tuple MuonPostProcessor_cff::NumeratorMEname = cms.untracked.string("massVsEtaJpsi_numer")

Definition at line 70 of file MuonPostProcessor_cff.py.

tuple MuonPostProcessor_cff::zClient

Initial value:

00001 cms.EDAnalyzer("DQMGenericTnPClient",
00002   subDirs = cms.untracked.vstring("HLT/Muon/Distributions*"),
00003   #MyDQMrootFolder = cms.untracked.string("HLT/Muon/DistributionsVbtf/HLT_Mu5"),
00004   # Set this if you want to save info about each fit
00005   # SavePlotsInRootFileName = cms.untracked.string("fittingPlots.root"),
00006   Verbose = cms.untracked.bool(False),
00007   Efficiencies = cms.untracked.VPSet(
00008     ZPars.clone(
00009       NumeratorMEname = cms.untracked.string("massVsEtaZ_numer"),
00010       DenominatorMEname = cms.untracked.string("massVsEtaZ_denom"),
00011       EfficiencyMEname = cms.untracked.string("massVsEtaZ_efficiency"),
00012     ),
00013   )
00014 )

Definition at line 52 of file MuonPostProcessor_cff.py.

tuple MuonPostProcessor_cff::ZPars

Initial value:

00001 cms.untracked.PSet(
00002     MassDimension = cms.untracked.int32(2),
00003     FitFunction = cms.untracked.string("VoigtianPlusExponential"),
00004     ExpectedMean = cms.untracked.double(91.),
00005     ExpectedSigma = cms.untracked.double(1.),
00006     FixedWidth = cms.untracked.double(2.5),
00007     FitRangeLow = cms.untracked.double(65.),
00008     FitRangeHigh = cms.untracked.double(115.),
00009     SignalRangeLow = cms.untracked.double(83.),
00010     SignalRangeHigh = cms.untracked.double(99.),
00011 )

Definition at line 28 of file MuonPostProcessor_cff.py.

MuonPostProcessor_cff Namespace Reference

Variables

Variable Documentation