CategoriesEtaMin=cms.vdouble([cat.eta_min for cat in categories]), CategoriesEtaMax=cms.vdouble([cat.eta_max for cat in categories]), CategoriesPtMin=cms.vdouble([cat.pt_min for cat in categories]), CategoriesPtMax=cms.vdouble([cat.pt_max for cat in categories]), Weights=cms.vstring(bdt_weights_histomax['v8_352']), WorkingPoints=cms.vdouble([ wps[eff] for wps, eff in zip(working_points_histomax['v8_352'], tight_wp) ]), ) # Era Modification for HGCal v9: use correct training and WPs phase2_hgcalV9.toModify( egamma_identification_histomax, Inputs=cms.vstring(input_features_histomax['v9_394']), Weights=cms.vstring(bdt_weights_histomax['v9_394']), WorkingPoints=cms.vdouble([ wps[eff] for wps, eff in zip(working_points_histomax['v9_394'], tight_wp) ])) phase2_hgcalV10.toModify( egamma_identification_histomax, Inputs=cms.vstring(input_features_histomax['v10_3151']), Weights=cms.vstring(bdt_weights_histomax['v10_3151']), WorkingPoints=cms.vdouble([ wps[eff] for wps, eff in zip(working_points_histomax['v10_3151'], tight_wp) ])) phase2_hgcalV11.toModify( egamma_identification_histomax,
90.499812, 90.894274, 90.537470, 89.786205, 89.786205, 89.786205, 89.786205, 89.786205, 89.786205, 89.786205, 89.786205, 89.786205) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( dEdX, weights = dEdX_weights_v9 ) dEdX_weights_v10 = cms.vdouble(0.0, # there is no layer zero 8.894541, # Mev 10.937907, 10.937907, 10.937907, 10.937907, 10.937907, 10.937907, 10.937907, 10.937907, 10.932882, 10.932882, 10.937907, 10.937907,
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalHitCalibrationDefault_cfi import hgcalHitCalibrationDefault as _hgcalHitCalibrationDefault hgcalHitCalibration = _hgcalHitCalibrationDefault.clone() from Configuration.ProcessModifiers.premix_stage2_cff import premix_stage2 premix_stage2.toModify(hgcalHitCalibration, caloParticles = "mixData:MergedCaloTruth") from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalHitCalibration, depletionFine = 120)
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalDigiStudy_cfi import * from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalDigiStudy, detectorNames=cms.vstring( "HGCalEESensitive", "HGCalHESiliconSensitive", "HGCalHEScintillatorSensitive"))
HGCEE_keV2DIGI = hgceeDigitizer.digiCfg.keV2fC, HGCEE_isSiFE = HGCalUncalibRecHit.HGCEEConfig.isSiFE, HGCEE_fCPerMIP = HGCalUncalibRecHit.HGCEEConfig.fCPerMIP, HGCHEF_keV2DIGI = hgchefrontDigitizer.digiCfg.keV2fC, HGCHEF_isSiFE = HGCalUncalibRecHit.HGCHEFConfig.isSiFE, HGCHEF_fCPerMIP = HGCalUncalibRecHit.HGCHEFConfig.fCPerMIP, HGCHEB_keV2DIGI = hgchebackDigitizer.digiCfg.keV2MIP, HGCHEB_isSiFE = HGCalUncalibRecHit.HGCHEBConfig.isSiFE, # don't produce rechit if detid is a ghost one rangeMask = cms.uint32(4294442496), rangeMatch = cms.uint32(1161838592), # EM Scale calibrations layerWeights = dEdX.weights, thicknessCorrection = cms.vdouble(1.132,1.092,1.084), # 100, 200, 300 um HGCEE_noise_fC = hgceeDigitizer.digiCfg.noise_fC, HGCEE_cce = hgceeDigitizer.digiCfg.chargeCollectionEfficiencies, HGCHEF_noise_fC = hgchefrontDigitizer.digiCfg.noise_fC, HGCHEF_cce = hgchefrontDigitizer.digiCfg.chargeCollectionEfficiencies, HGCHEB_noise_MIP = hgchebackDigitizer.digiCfg.noise_MIP, # algo algo = cms.string("HGCalRecHitWorkerSimple") ) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( dEdX, weights = dEdX_weights_v9 ) phase2_hgcalV9.toModify( HGCalRecHit , thicknessCorrection = cms.vdouble(0.759,0.760,0.773) ) #120um, 200um, 300um
process.HGCAL_noise_fC = cms.PSet( values=cms.vdouble(0, 0, 0), #100,200,300 um ) process.HGCAL_noise_heback = cms.PSet( scaleByDose=cms.bool(False), doseMap=cms.string(""), noise_MIP=cms.double(0.) #zero noise ) process.HGCAL_noises = cms.PSet(values=cms.vdouble(0, 0, 0)) return process from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( hgceeDigitizer, geometryType=cms.uint32(1), ) phase2_hgcalV9.toModify( hgchefrontDigitizer, geometryType=cms.uint32(1), ) phase2_hgcalV9.toModify( hgchebackDigitizer, geometryType=cms.uint32(1), hitCollection=cms.string("HGCHitsHEback"), ) phase2_hgcalV9.toModify(HGCAL_noise_fC, values=[x * fC_per_ele for x in nonAgedNoises_v9]) phase2_hgcalV9.toModify(HGCAL_noises, values=[x for x in nonAgedNoises_v9])
HGCEE_keV2DIGI = hgceeDigitizer.digiCfg.keV2fC, HGCEE_isSiFE = HGCalUncalibRecHit.HGCEEConfig.isSiFE, HGCEE_fCPerMIP = HGCalUncalibRecHit.HGCEEConfig.fCPerMIP, HGCHEF_keV2DIGI = hgchefrontDigitizer.digiCfg.keV2fC, HGCHEF_isSiFE = HGCalUncalibRecHit.HGCHEFConfig.isSiFE, HGCHEF_fCPerMIP = HGCalUncalibRecHit.HGCHEFConfig.fCPerMIP, HGCHEB_keV2DIGI = hgchebackDigitizer.digiCfg.keV2MIP, HGCHEB_isSiFE = HGCalUncalibRecHit.HGCHEBConfig.isSiFE, # don't produce rechit if detid is a ghost one rangeMask = cms.uint32(4294442496), rangeMatch = cms.uint32(1161838592), # EM Scale calibrations layerWeights = dEdX_weights, thicknessCorrection = cms.vdouble(1.132,1.092,1.084), # 100, 200, 300 um HGCEE_noise_fC = hgceeDigitizer.digiCfg.noise_fC, HGCEE_cce = hgceeDigitizer.digiCfg.chargeCollectionEfficiencies, HGCHEF_noise_fC = hgchefrontDigitizer.digiCfg.noise_fC, HGCHEF_cce = hgchefrontDigitizer.digiCfg.chargeCollectionEfficiencies, HGCHEB_noise_MIP = hgchebackDigitizer.digiCfg.noise_MIP, # algo algo = cms.string("HGCalRecHitWorkerSimple") ) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( HGCalRecHit , layerWeights = dEdX_weights_v9 ) phase2_hgcalV9.toModify( HGCalRecHit , thicknessCorrection = cms.vdouble(0.759,0.760,0.773) ) #120um, 200um, 300um
71.265149, 90.499812, 90.894274, 90.537470, 89.786205, 89.786205, 89.786205, 89.786205, 89.786205, 89.786205, 89.786205, 89.786205, 89.786205) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(dEdX, weights=dEdX_weights_v9) dEdX_weights_v10 = cms.vdouble( 0.0, # there is no layer zero 8.894541, # Mev 10.937907, 10.937907, 10.937907, 10.937907, 10.937907, 10.937907, 10.937907, 10.937907, 10.932882, 10.932882, 10.937907,
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalBHAnalysis_cfi import * from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalBHAnalysis, GeometryType = cms.untracked.int32(1), HitCollection = cms.untracked.string("HGCHitsHEback"), )
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalSimHitValidationEE_cfi import * hgcalSimHitValidationHEF = hgcalSimHitValidationEE.clone( DetectorName=cms.string("HGCalHESiliconSensitive"), CaloHitSource=cms.string("HGCHitsHEfront")) hgcalSimHitValidationHEB = hgcalSimHitValidationEE.clone( DetectorName=cms.string("HCal"), CaloHitSource=cms.string("HcalHits")) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( hgcalSimHitValidationHEB, DetectorName=cms.string("HGCalHEScintillatorSensitive"), CaloHitSource=cms.string("HGCHitsHEback"), )
'HGCalHitValidation', geometrySource=cms.untracked.vstring("HGCalEESensitive", "HGCalHESiliconSensitive", "Hcal"), eeSimHitSource=cms.InputTag("g4SimHits", "HGCHitsEE"), fhSimHitSource=cms.InputTag("g4SimHits", "HGCHitsHEfront"), bhSimHitSource=cms.InputTag("g4SimHits", "HcalHits"), eeRecHitSource=cms.InputTag("HGCalRecHit", "HGCEERecHits"), fhRecHitSource=cms.InputTag("HGCalRecHit", "HGCHEFRecHits"), bhRecHitSource=cms.InputTag("HGCalRecHit", "HGCHEBRecHits"), ietaExcludeBH=cms.vint32([]), ifHCAL=cms.bool(False), ifHCALsim=cms.bool(True), ) from Validation.HGCalValidation.hgcalHitCalibration_cfi import hgcalHitCalibration from Validation.HGCalValidation.caloparticlevalidation_cfi import caloparticlevalidation hgcalHitValidationSequence = cms.Sequence(hgcalHitValidation + hgcalHitCalibration + caloparticlevalidation) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( hgcalHitValidation, bhSimHitSource=cms.InputTag("g4SimHits", "HGCHitsHEback"), geometrySource=cms.untracked.vstring("HGCalEESensitive", "HGCalHESiliconSensitive", "HGCalHEScintillatorSensitive"), ifHCALsim=cms.bool(False), )
dR_multicluster_byLayer_coefficientB=cms.vdouble(), minPt_multicluster=cms.double(0.5), # minimum pt of the multicluster (GeV) nBins_R_histo_multicluster=cms.uint32(36), nBins_Phi_histo_multicluster=cms.uint32(216), binSumsHisto=binSums, threshold_histo_multicluster=cms.double(10.), cluster_association=cms.string("NearestNeighbour"), EGIdentification=egamma_identification_histomax.clone(), neighbour_weights=neighbour_weights_1stOrder ) # V9 samples have a different defintiion of the dEdx calibrations. To account for it # we reascale the thresholds of the clustering seeds # (see https://indico.cern.ch/event/806845/contributions/3359859/attachments/1815187/2966402/19-03-20_EGPerf_HGCBE.pdf # for more details) phase2_hgcalV9.toModify(histoMax_C3d_params, threshold_histo_multicluster=7.5, # MipT ) histoMaxVariableDR_C3d_params = histoMax_C3d_params.clone( dR_multicluster = cms.double(0.), dR_multicluster_byLayer_coefficientA = cms.vdouble(dr_layerbylayer), dR_multicluster_byLayer_coefficientB = cms.vdouble([0]*(MAX_LAYERS+1)) ) histoSecondaryMax_C3d_params = histoMax_C3d_params.clone( type_multicluster = cms.string('HistoSecondaryMaxC3d') )
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalDigiStudyEE_cfi import * hgcalDigiStudyHEF = hgcalDigiStudyEE.clone( detectorName = cms.string("HGCalHESiliconSensitive"), digiSource = cms.InputTag("hgcalDigis","HEfront")) hgcalDigiStudyHEB = hgcalDigiStudyEE.clone( detectorName = cms.string("HCal"), digiSource = cms.InputTag("hgcalDigis","HEback")) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalDigiStudyHEB, detectorName = cms.string("HGCalHEScintillatorSensitive") )
isSiFE=cms.bool(False), adcNbits=hgchebackDigitizer.digiCfg.feCfg.adcNbits, adcSaturation=hgchebackDigitizer.digiCfg.feCfg.adcSaturation_fC, fCPerMIP=cms.vdouble(1.0, 1.0, 1.0) #dummy values, it's scintillator ), HGCHFNoseConfig=cms.PSet( isSiFE=cms.bool(False), # adc information adcNbits=hfnoseDigitizer.digiCfg.feCfg.adcNbits, adcSaturation=hfnoseDigitizer.digiCfg.feCfg.adcSaturation_fC, #tdc information tdcNbits=hfnoseDigitizer.digiCfg.feCfg.tdcNbits, tdcSaturation=hfnoseDigitizer.digiCfg.feCfg.tdcSaturation_fC, tdcOnset=hfnoseDigitizer.digiCfg.feCfg.tdcOnset_fC, toaLSB_ns=hfnoseDigitizer.digiCfg.feCfg.toaLSB_ns, fCPerMIP=cms.vdouble(1.25, 2.57, 3.88) #100um, 200um, 300um ), algo=cms.string("HGCalUncalibRecHitWorkerWeights")) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(HGCalUncalibRecHit.HGCEEConfig, fCPerMIP=fCPerMIP_v9) phase2_hgcalV9.toModify(HGCalUncalibRecHit.HGCHEFConfig, fCPerMIP=fCPerMIP_v9) from Configuration.Eras.Modifier_phase2_hgcalV10_cff import phase2_hgcalV10 phase2_hgcalV10.toModify(HGCalUncalibRecHit.HGCEEConfig, fCPerMIP=fCPerMIP_v10) phase2_hgcalV10.toModify(HGCalUncalibRecHit.HGCHEFConfig, fCPerMIP=fCPerMIP_v10) from Configuration.Eras.Modifier_phase2_hfnose_cff import phase2_hfnose phase2_hfnose.toModify(HGCalUncalibRecHit.HGCHFNoseConfig, isSiFE=True)
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcHitAnalysis_cfi import * from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcHitAnalysis, geometrySource = cms.untracked.vstring("HGCalEESensitive", "HGCalHESiliconSensitive", "HGCalHEScintillatorSensitive"), bhSimHitSource = cms.InputTag("g4SimHits","HGCHitsHEback"), )
TCThreshold_fC = cms.double(0.), TCThresholdBH_MIP = cms.double(0.), triggercell_threshold_silicon = cms.double(0.), triggercell_threshold_scintillator = cms.double(0.), ) supertc_conc_proc = cms.PSet(ProcessorName = cms.string('HGCalConcentratorProcessorSelection'), Method = cms.string('superTriggerCellSelect'), stcSize = cms.vuint32(4,4,4) ) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 # V9 samples have a different defintiion of the dEdx calibrations. To account for it # we reascale the thresholds of the FE selection # (see https://indico.cern.ch/event/806845/contributions/3359859/attachments/1815187/2966402/19-03-20_EGPerf_HGCBE.pdf # for more details) phase2_hgcalV9.toModify(threshold_conc_proc, triggercell_threshold_silicon=1.5, # MipT triggercell_threshold_scintillator=1.5, # MipT ) hgcalConcentratorProducer = cms.EDProducer( "HGCalConcentratorProducer", InputTriggerCells = cms.InputTag('hgcalVFEProducer:HGCalVFEProcessorSums'), InputTriggerSums = cms.InputTag('hgcalVFEProducer:HGCalVFEProcessorSums'), ProcessorParameters = threshold_conc_proc.clone() )
adcNbits = hgchefrontDigitizer.digiCfg.feCfg.adcNbits, adcSaturation = hgchefrontDigitizer.digiCfg.feCfg.adcSaturation_fC, #tdc information tdcNbits = hgchefrontDigitizer.digiCfg.feCfg.tdcNbits, tdcSaturation = hgchefrontDigitizer.digiCfg.feCfg.tdcSaturation_fC, tdcOnset = hgchefrontDigitizer.digiCfg.feCfg.tdcOnset_fC, toaLSB_ns = hgchefrontDigitizer.digiCfg.feCfg.toaLSB_ns, fCPerMIP = cms.vdouble(1.25,2.57,3.88) #100um, 200um, 300um ), HGCHEBConfig = cms.PSet( isSiFE = cms.bool(False), adcNbits = hgchebackDigitizer.digiCfg.feCfg.adcNbits, adcSaturation = hgchebackDigitizer.digiCfg.feCfg.adcSaturation_fC, fCPerMIP = cms.vdouble(1.0,1.0,1.0) #dummy values, it's scintillator ), geometryType = cms.uint32(0), algo = cms.string("HGCalUncalibRecHitWorkerWeights") ) from Configuration.ProcessModifiers.premix_stage2_cff import premix_stage2 premix_stage2.toModify(HGCalUncalibRecHit, HGCEEdigiCollection = 'mixData:HGCDigisEE', HGCHEFdigiCollection = 'mixData:HGCDigisHEfront', HGCHEBdigiCollection = 'mixData:HGCDigisHEback', ) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(HGCalUncalibRecHit, geometryType = cms.uint32(1))
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcHitAnalysis_cfi import * from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( hgcHitAnalysis, geometrySource=cms.untracked.vstring("HGCalEESensitive", "HGCalHESiliconSensitive", "HGCalHEScintillatorSensitive"), bhSimHitSource=cms.InputTag("g4SimHits", "HGCHitsHEback"), )
endOfLifeNoises = [2400.0, 2250.0, 1750.0] def HGCal_setEndOfLifeNoise(digitizer, process): process.HGCAL_noise_fC = cms.PSet( values=cms.vdouble([x * fC_per_ele for x in endOfLifeNoises]), #100,200,300 um ) process.HGCAL_chargeCollectionEfficiencies = cms.PSet( values=cms.vdouble(endOfLifeCCEs)) process.HGCAL_noise_MIP = cms.PSet(value=cms.double(1.0 / 5.0)) process.HGCAL_noises = cms.PSet( values=cms.vdouble([x for x in endOfLifeNoises])) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( hgceeDigitizer, geometryType=cms.uint32(1), ) phase2_hgcalV9.toModify( hgchefrontDigitizer, geometryType=cms.uint32(1), ) phase2_hgcalV9.toModify( hgchebackDigitizer, geometryType=cms.uint32(1), hitCollection=cms.string("HGCHitsHEback"), )
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalRecHitValidationEE_cfi import * hgcalRecHitValidationHEF = hgcalRecHitValidationEE.clone( DetectorName = cms.string("HGCalHESiliconSensitive"), RecHitSource = cms.InputTag("HGCalRecHit", "HGCHEFRecHits")) hgcalRecHitValidationHEB = hgcalRecHitValidationEE.clone( DetectorName = cms.string("HCal"), RecHitSource = cms.InputTag("HGCalRecHit", "HGCHEBRecHits")) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalRecHitValidationHEB, DetectorName = cms.string("HGCalHEScintillatorSensitive"));
dR_multicluster_byLayer_coefficientA=cms.vdouble(), dR_multicluster_byLayer_coefficientB=cms.vdouble(), shape_threshold=cms.double(1.), shape_distance=cms.double(0.015), minPt_multicluster=cms.double(0.5), # minimum pt of the multicluster (GeV) cluster_association=cms.string("NearestNeighbour"), EGIdentification=egamma_identification_histomax.clone(), ) # V9 samples have a different defintion of the dEdx calibrations. To account for it # we reascale the thresholds of the clustering seeds # (see https://indico.cern.ch/event/806845/contributions/3359859/attachments/1815187/2966402/19-03-20_EGPerf_HGCBE.pdf # for more details) phase2_hgcalV9.toModify(histoMax_C3d_seeding_params, threshold_histo_multicluster=7.5, # MipT ) histoMaxVariableDR_C3d_params = histoMax_C3d_clustering_params.clone( dR_multicluster = cms.double(0.), dR_multicluster_byLayer_coefficientA = cms.vdouble(dr_layerbylayer), dR_multicluster_byLayer_coefficientB = cms.vdouble([0]*(MAX_LAYERS+1)) ) histoSecondaryMax_C3d_params = histoMax_C3d_seeding_params.clone( type_histoalgo = cms.string('HistoSecondaryMaxC3d') ) histoMaxXYVariableDR_C3d_params = histoMax_C3d_seeding_params.clone(
disconnectedTriggerLayers = [ 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 22, 24, 26, 28 ] geometry = cms.PSet( TriggerGeometryName=cms.string('HGCalTriggerGeometryHexLayerBasedImp1'), L1TCellsMapping=cms.FileInPath( "L1Trigger/L1THGCal/data/triggercell_mapping_8inch_aligned_192_432_V8_0.txt" ), L1TModulesMapping=cms.FileInPath( "L1Trigger/L1THGCal/data/panel_mapping_tdr_0.txt"), L1TCellNeighborsMapping=cms.FileInPath( "L1Trigger/L1THGCal/data/triggercell_neighbor_mapping_8inch_aligned_192_432_0.txt" ), L1TCellsBHMapping=cms.FileInPath( "L1Trigger/L1THGCal/data/triggercell_mapping_BH_3x3_30deg_0.txt"), L1TCellNeighborsBHMapping=cms.FileInPath( "L1Trigger/L1THGCal/data/triggercell_neighbor_mapping_BH_3x3_30deg_0.txt" ), DisconnectedModules=cms.vuint32(0), DisconnectedLayers=cms.vuint32(disconnectedTriggerLayers)) hgcalTriggerGeometryESProducer = cms.ESProducer( 'HGCalTriggerGeometryESProducer', TriggerGeometry=geometry, isV9Geometry=cms.bool(False)) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalTriggerGeometryESProducer, isV9Geometry=True)
import FWCore.ParameterSet.Config as cms minEtaCorrection = cms.double(1.4) maxEtaCorrection = cms.double(3.0) hadronCorrections = cms.PSet( value=cms.vdouble(1.24, 1.24, 1.24, 1.23, 1.24, 1.25, 1.29, 1.29)) egammaCorrections = cms.PSet( value=cms.vdouble(1.00, 1.00, 1.01, 1.01, 1.02, 1.03, 1.04, 1.04)) hadronCorrections_hgcalV9 = cms.vdouble(1.28, 1.28, 1.24, 1.19, 1.17, 1.17, 1.17, 1.17) egammaCorrections_hgcalV9 = cms.vdouble(1.00, 1.00, 1.01, 1.01, 1.02, 1.01, 1.01, 1.01) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hadronCorrections, value=hadronCorrections_hgcalV9) phase2_hgcalV9.toModify(egammaCorrections, value=egammaCorrections_hgcalV9)
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalSimHitValidationEE_cfi import * hgcalSimHitValidationHEF = hgcalSimHitValidationEE.clone( DetectorName = cms.string("HGCalHESiliconSensitive"), CaloHitSource = cms.string("HGCHitsHEfront")) hgcalSimHitValidationHEB = hgcalSimHitValidationEE.clone( DetectorName = cms.string("HCal"), CaloHitSource = cms.string("HcalHits")) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalSimHitValidationHEB, DetectorName = cms.string("HGCalHEScintillatorSensitive"), CaloHitSource = cms.string("HGCHitsHEback"), )
premix_stage1.toModify(_m, premixStage1 = True) #function to set noise to aged HGCal endOfLifeCCEs = [0.5, 0.5, 0.7] endOfLifeNoises = [2400.0,2250.0,1750.0] def HGCal_setEndOfLifeNoise(digitizer,process): process.HGCAL_noise_fC = cms.PSet( values = cms.vdouble( [x*fC_per_ele for x in endOfLifeNoises] ), #100,200,300 um ) process.HGCAL_chargeCollectionEfficiencies = cms.PSet( values = cms.vdouble(endOfLifeCCEs) ) process.HGCAL_noise_MIP = cms.PSet( value = cms.double( 1.0/5.0 ) ) process.HGCAL_noises = cms.PSet( values = cms.vdouble([x for x in endOfLifeNoises]) ) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( hgceeDigitizer, geometryType = cms.uint32(1), ) phase2_hgcalV9.toModify( hgchefrontDigitizer, geometryType = cms.uint32(1), ) phase2_hgcalV9.toModify( hgchebackDigitizer, geometryType = cms.uint32(1), )
import FWCore.ParameterSet.Config as cms from Geometry.HGCalGeometry.hgcalEETestNeighbor_cfi import * hgcalHEFTestNeighbor = hgcalEETestNeighbor.clone( detector = cms.string("HGCalHESiliconSensitive")) hgcalHEBTestNeighbor = hgcalEETestNeighbor.clone( detector = cms.string("HCal")) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalHEBTestNeighbor, detector = cms.string("HGCalHEScintillatorSensitive") )
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalDigiStudyEE_cfi import * hgcalDigiStudyHEF = hgcalDigiStudyEE.clone( detectorName = cms.string("HGCalHESiliconSensitive"), digiSource = cms.InputTag("hgcalDigis","HEfront"), layers = cms.untracked.int32(24)) hgcalDigiStudyHEB = hgcalDigiStudyEE.clone( detectorName = cms.string("HCal"), digiSource = cms.InputTag("hgcalDigis","HEback"), layers = cms.untracked.int32(24)) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalDigiStudyHEB, detectorName = cms.string("HGCalHEScintillatorSensitive") )
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalDigiStudy_cfi import * from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalDigiStudy, detectorNames = cms.vstring("HGCalEESensitive", "HGCalHESiliconSensitive", "HGCalHEScintillatorSensitive") )
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalRecHitStudyEE_cfi import * hgcalRecHitStudyFH = hgcalRecHitStudyEE.clone( DetectorName = cms.string("HGCalHESiliconSensitive"), RecHitSource = cms.InputTag("HGCalRecHit", "HGCHEFRecHits")) hgcalRecHitStudyBH = hgcalRecHitStudyEE.clone( DetectorName = cms.string("HCal"), RecHitSource = cms.InputTag("HGCalRecHit", "HGCHEBRecHits")) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalRecHitStudyBH, DetectorName = cms.string("HGCalHEScintillatorSensitive"), )
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.HGCalRecHitsClient_cfi import * hgcalRecHitClientHEF = hgcalRecHitClientEE.clone( DetectorName=cms.string("HGCalHESiliconSensitive")) hgcalRecHitClientHEB = hgcalRecHitClientEE.clone( DetectorName=cms.string("HCal")) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( hgcalRecHitClientHEB, DetectorName=cms.string("HGCalHEScintillatorSensitive"), )
pcrossingFrames = theMixObjects.mixSH.pcrossingFrames + [ 'MuonME0Hits' ] ) ) from Configuration.Eras.Modifier_phase2_hgcal_cff import phase2_hgcal phase2_hgcal.toModify( theMixObjects, mixCH = dict( input = theMixObjects.mixCH.input + [ cms.InputTag("g4SimHits",hgceeDigitizer.hitCollection.value()), cms.InputTag("g4SimHits",hgchefrontDigitizer.hitCollection.value()) ], subdets = theMixObjects.mixCH.subdets + [ hgceeDigitizer.hitCollection.value(), hgchefrontDigitizer.hitCollection.value() ], ) ) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( theMixObjects, mixCH = dict( input = theMixObjects.mixCH.input + [ cms.InputTag("g4SimHits",hgchebackDigitizer.hitCollection.value()) ], subdets = theMixObjects.mixCH.subdets + [ hgchebackDigitizer.hitCollection.value() ], ) ) from Configuration.Eras.Modifier_phase2_hfnose_cff import phase2_hfnose phase2_hfnose.toModify( theMixObjects, mixCH = dict( input = theMixObjects.mixCH.input + [ cms.InputTag("g4SimHits",hfnoseDigitizer.hitCollection.value()) ], subdets = theMixObjects.mixCH.subdets + [ hfnoseDigitizer.hitCollection.value() ], ) ) from Configuration.Eras.Modifier_phase2_timing_layer_cff import phase2_timing_layer phase2_timing_layer.toModify( theMixObjects, mixSH = dict( input = theMixObjects.mixSH.input + [ cms.InputTag("g4SimHits","FastTimerHitsBarrel"), cms.InputTag("g4SimHits","FastTimerHitsEndcap") ], subdets = theMixObjects.mixSH.subdets + [ 'FastTimerHitsBarrel','FastTimerHitsEndcap' ],
adcNbits = hgchefrontDigitizer.digiCfg.feCfg.adcNbits, adcSaturation = hgchefrontDigitizer.digiCfg.feCfg.adcSaturation_fC, #tdc information tdcNbits = hgchefrontDigitizer.digiCfg.feCfg.tdcNbits, tdcSaturation = hgchefrontDigitizer.digiCfg.feCfg.tdcSaturation_fC, tdcOnset = hgchefrontDigitizer.digiCfg.feCfg.tdcOnset_fC, toaLSB_ns = hgchefrontDigitizer.digiCfg.feCfg.toaLSB_ns, fCPerMIP = cms.vdouble(1.25,2.57,3.88) #100um, 200um, 300um ), HGCHEBConfig = cms.PSet( isSiFE = cms.bool(False), adcNbits = hgchebackDigitizer.digiCfg.feCfg.adcNbits, adcSaturation = hgchebackDigitizer.digiCfg.feCfg.adcSaturation_fC, fCPerMIP = cms.vdouble(1.0,1.0,1.0) #dummy values, it's scintillator ), algo = cms.string("HGCalUncalibRecHitWorkerWeights") ) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( HGCalUncalibRecHit.HGCEEConfig , fCPerMIP = fCPerMIP_v9 ) phase2_hgcalV9.toModify( HGCalUncalibRecHit.HGCHEFConfig , fCPerMIP = fCPerMIP_v9 ) from Configuration.Eras.Modifier_phase2_hgcalV10_cff import phase2_hgcalV10 phase2_hgcalV10.toModify( HGCalUncalibRecHit.HGCEEConfig , fCPerMIP = fCPerMIP_v10 ) phase2_hgcalV10.toModify( HGCalUncalibRecHit.HGCHEFConfig , fCPerMIP = fCPerMIP_v10 )
c2d_calib_pset = cms.PSet(calibSF_cluster=cms.double(1.), layerWeights=layercalibparam.TrgLayer_weights, applyLayerCalibration=cms.bool(True)) c2d_thresholds_pset = cms.PSet(seeding_threshold_silicon=cms.double(5.), seeding_threshold_scintillator=cms.double(5.), clustering_threshold_silicon=cms.double(2.), clustering_threshold_scintillator=cms.double(2.)) # V9 samples have a different defintiion of the dEdx calibrations. To account for it # we reascale the thresholds for the clustering # (see https://indico.cern.ch/event/806845/contributions/3359859/attachments/1815187/2966402/19-03-20_EGPerf_HGCBE.pdf # for more details) phase2_hgcalV9.toModify(c2d_thresholds_pset, seeding_threshold_silicon=3.75, seeding_threshold_scintillator=3.75, clustering_threshold_silicon=1.5, clustering_threshold_scintillator=1.5, ) # we still don't have layer calibrations for V9 geometry. Switching this off we # use the dEdx calibrated energy of the TCs phase2_hgcalV9.toModify(c2d_calib_pset, applyLayerCalibration=False ) dummy_C2d_params = cms.PSet(c2d_calib_pset, clusterType=cms.string('dummyC2d') )
simVertexCollection=cms.InputTag('g4SimHits'), genParticleCollection=cms.InputTag('genParticles'), allowDifferentSimHitProcesses=cms.bool( False), # should be True for FastSim, False for FullSim HepMCProductLabel=cms.InputTag('generatorSmeared'), ) from Configuration.ProcessModifiers.premix_stage1_cff import premix_stage1 premix_stage1.toModify(caloParticles, premixStage1=True) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( caloParticles, simHitCollections=dict( hgc={2: cms.InputTag('g4SimHits', 'HGCHitsHEback')}), ) # Uncommented the following block before part 2 as per Maria's instruction from Configuration.Eras.Modifier_phase2_hfnose_cff import phase2_hfnose phase2_hfnose.toModify( caloParticles, simHitCollections=dict(hgc=caloParticles.simHitCollections.hgc + [cms.InputTag('g4SimHits', 'HFNoseHits')], hcal=cms.VInputTag( cms.InputTag('g4SimHits', 'HcalHits')))) from Configuration.ProcessModifiers.run3_ecalclustering_cff import run3_ecalclustering
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalSimHitStudy_cfi import * from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( hgcalSimHitStudy, detectorNames=cms.vstring("HGCalEESensitive", "HGCalHESiliconSensitive", "HGCalHEScintillatorSensitive"), caloHitSources=cms.vstring('HGCHitsEE', 'HGCHitsHEfront', 'HGCHitsHEback'))
import FWCore.ParameterSet.Config as cms minEtaCorrection = cms.double(1.4) maxEtaCorrection = cms.double(3.0) hadronCorrections = cms.PSet(value = cms.vdouble(1.24, 1.24, 1.24, 1.23, 1.24, 1.25, 1.29, 1.29)) egammaCorrections = cms.PSet(value = cms.vdouble(1.00, 1.00, 1.01, 1.01, 1.02, 1.03, 1.04, 1.04)) hadronCorrections_hgcalV9 = cms.vdouble(1.28, 1.28, 1.24, 1.19, 1.17, 1.17, 1.17, 1.17) egammaCorrections_hgcalV9 = cms.vdouble(1.00, 1.00, 1.01, 1.01, 1.02, 1.01, 1.01, 1.01) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hadronCorrections, value = hadronCorrections_hgcalV9) phase2_hgcalV9.toModify(egammaCorrections, value = egammaCorrections_hgcalV9)
applyLayerCalibration=cms.bool(True)) c2d_thresholds_pset = cms.PSet( seeding_threshold_silicon=cms.double(5.), seeding_threshold_scintillator=cms.double(5.), clustering_threshold_silicon=cms.double(2.), clustering_threshold_scintillator=cms.double(2.)) # V9 samples have a different defintiion of the dEdx calibrations. To account for it # we reascale the thresholds for the clustering # (see https://indico.cern.ch/event/806845/contributions/3359859/attachments/1815187/2966402/19-03-20_EGPerf_HGCBE.pdf # for more details) phase2_hgcalV9.toModify( c2d_thresholds_pset, seeding_threshold_silicon=3.75, seeding_threshold_scintillator=3.75, clustering_threshold_silicon=1.5, clustering_threshold_scintillator=1.5, ) # we still don't have layer calibrations for V9 geometry. Switching this off we # use the dEdx calibrated energy of the TCs phase2_hgcalV9.toModify(c2d_calib_pset, applyLayerCalibration=False) dummy_C2d_params = cms.PSet(c2d_calib_pset, clusterType=cms.string('dummyC2d')) distance_C2d_params = cms.PSet( c2d_calib_pset, c2d_thresholds_pset, clusterType=cms.string('dRC2d'), dR_cluster=cms.double(6.),
cms.PSet( name = cms.string("PFRecHitQTestHGCalThresholdSNR"), thresholdSNR = cms.double(5.0), ), ) ), cms.PSet( name = cms.string("PFHGCHEBRecHitCreator"), src = cms.InputTag("HGCalRecHit:HGCHEBRecHits"), geometryInstance = cms.string(""), qualityTests = cms.VPSet( # Enabling PFRecHitQTestHGCalThresholdSNR will filter out of the PFRecHits, all the HGCRecHits with energy not exceeding # 5 sigma noise cms.PSet( name = cms.string("PFRecHitQTestHGCalThresholdSNR"), thresholdSNR = cms.double(5.0), ), ) ) ) ) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(particleFlowRecHitHGC, producers = { 0 : dict(name = "PFHGCalEERecHitCreator"), 1 : dict(name = "PFHGCalHSiRecHitCreator"), 2 : dict(name = "PFHGCalHScRecHitCreator"), } )
values = cms.vdouble([x for x in endOfLifeNoises]) ) return process def HGCal_disableNoise(process): process.HGCAL_noise_fC = cms.PSet( values = cms.vdouble(0,0,0), #100,200,300 um ) process.HGCAL_noise_MIP = cms.PSet( value = cms.double(0) ) process.HGCAL_noises = cms.PSet( values = cms.vdouble(0,0,0) ) return process from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( hgceeDigitizer, geometryType = cms.uint32(1), ) phase2_hgcalV9.toModify( hgchefrontDigitizer, geometryType = cms.uint32(1), ) phase2_hgcalV9.toModify( hgchebackDigitizer, geometryType = cms.uint32(1), hitCollection = cms.string("HGCHitsHEback"), ) phase2_hgcalV9.toModify(HGCAL_noise_fC, values = [x*fC_per_ele for x in nonAgedNoises_v9]) phase2_hgcalV9.toModify(HGCAL_noises, values = [x for x in nonAgedNoises_v9])
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcGeomCheck_cfi import * from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcGeomCheck, geometrySource = cms.untracked.vstring( 'HGCalEESensitive', 'HGCalHESiliconSensitive', 'HGCalHEScintillatorSensitive'), )
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalDigiValidationEE_cfi import * hgcalDigiValidationHEF = hgcalDigiValidationEE.clone( DetectorName = cms.string("HGCalHESiliconSensitive"), DigiSource = cms.InputTag("hgcalDigis","HEfront")) hgcalDigiValidationHEB = hgcalDigiValidationEE.clone( DetectorName = cms.string("HCal"), DigiSource = cms.InputTag("hgcalDigis","HEback")) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalDigiValidationHEB, DetectorName = cms.string("HGCalHEScintillatorSensitive"))
import FWCore.ParameterSet.Config as cms from Geometry.HGCalGeometry.hgcalEETestNeighbor_cfi import * hgcalHEFTestNeighbor = hgcalEETestNeighbor.clone( detector=cms.string("HGCalHESiliconSensitive")) hgcalHEBTestNeighbor = hgcalEETestNeighbor.clone(detector=cms.string("HCal")) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalHEBTestNeighbor, detector=cms.string("HGCalHEScintillatorSensitive"))
linLSB=cms.double(100. / 1024.), adcsaturationBH=adcSaturationBH_MIP, adcnBitsBH=adcNbitsBH, TCThreshold_fC=cms.double(0.), TCThresholdBH_MIP=cms.double(0.), triggercell_threshold_silicon=cms.double(0.), triggercell_threshold_scintillator=cms.double(0.), ) supertc_conc_proc = cms.PSet( ProcessorName=cms.string('HGCalConcentratorProcessorSelection'), Method=cms.string('superTriggerCellSelect'), stcSize=cms.vuint32(4, 4, 4)) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 # V9 samples have a different defintiion of the dEdx calibrations. To account for it # we reascale the thresholds of the FE selection # (see https://indico.cern.ch/event/806845/contributions/3359859/attachments/1815187/2966402/19-03-20_EGPerf_HGCBE.pdf # for more details) phase2_hgcalV9.toModify( threshold_conc_proc, triggercell_threshold_silicon=1.5, # MipT triggercell_threshold_scintillator=1.5, # MipT ) hgcalConcentratorProducer = cms.EDProducer( "HGCalConcentratorProducer", InputTriggerCells=cms.InputTag('hgcalVFEProducer:HGCalVFEProcessorSums'), InputTriggerSums=cms.InputTag('hgcalVFEProducer:HGCalVFEProcessorSums'), ProcessorParameters=threshold_conc_proc.clone())
cms.InputTag('g4SimHits','HGCHitsEE'), cms.InputTag('g4SimHits','HGCHitsHEfront'), cms.InputTag('g4SimHits','HcalHits') ), # hcal = cms.VInputTag(cms.InputTag('g4SimHits','HcalHits')), # ecal = cms.VInputTag( # cms.InputTag('g4SimHits','EcalHitsEE'), # cms.InputTag('g4SimHits','EcalHitsEB'), # cms.InputTag('g4SimHits','EcalHitsES') # ) ), simTrackCollection = cms.InputTag('g4SimHits'), simVertexCollection = cms.InputTag('g4SimHits'), genParticleCollection = cms.InputTag('genParticles'), allowDifferentSimHitProcesses = cms.bool(False), # should be True for FastSim, False for FullSim HepMCProductLabel = cms.InputTag('generatorSmeared'), ) from Configuration.ProcessModifiers.premix_stage1_cff import premix_stage1 premix_stage1.toModify(caloParticles, premixStage1 = True) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( caloParticles, simHitCollections = dict(hgc = {2 : cms.InputTag('g4SimHits','HGCHitsHEback')} ), ) from Configuration.Eras.Modifier_fastSim_cff import fastSim fastSim.toReplaceWith(caloParticles, cms.PSet()) # don't allow this to run in fastsim
endOfLifeCCEs = [0.5, 0.5, 0.7] endOfLifeNoises = [2400.0, 2250.0, 1750.0] def HGCal_setEndOfLifeNoise(digitizer, process): process.HGCAL_noise_fC = cms.PSet( values=cms.vdouble([x * fC_per_ele for x in endOfLifeNoises]), #100,200,300 um ) process.HGCAL_chargeCollectionEfficiencies = cms.PSet( values=cms.vdouble(endOfLifeCCEs)) process.HGCAL_noise_MIP = cms.PSet(value=cms.double(1.0 / 5.0)) process.HGCAL_noises = cms.PSet( values=cms.vdouble([x for x in endOfLifeNoises])) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( hgceeDigitizer, geometryType=cms.uint32(1), ) phase2_hgcalV9.toModify( hgchefrontDigitizer, geometryType=cms.uint32(1), ) phase2_hgcalV9.toModify( hgchebackDigitizer, geometryType=cms.uint32(1), )
superTCCompression = superTCCompression_proc.clone(), coarseTCCompression = coarseTCCompression_proc.clone(), superTCCalibration = vfe_proc.clone(), ) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 # V9 samples have a different defintiion of the dEdx calibrations. To account for it # we reascale the thresholds of the FE selection # (see https://indico.cern.ch/event/806845/contributions/3359859/attachments/1815187/2966402/19-03-20_EGPerf_HGCBE.pdf # for more details) phase2_hgcalV9.toModify(threshold_conc_proc, threshold_silicon=1.35, # MipT threshold_scintillator=1.35, # MipT ) hgcalConcentratorProducer = cms.EDProducer( "HGCalConcentratorProducer", InputTriggerCells = cms.InputTag('hgcalVFEProducer:HGCalVFEProcessorSums'), InputTriggerSums = cms.InputTag('hgcalVFEProducer:HGCalVFEProcessorSums'), ProcessorParameters = threshold_conc_proc.clone() ) hgcalConcentratorProducerHFNose = hgcalConcentratorProducer.clone( InputTriggerCells = cms.InputTag('hfnoseVFEProducer:HGCalVFEProcessorSums'), InputTriggerSums = cms.InputTag('hfnoseVFEProducer:HGCalVFEProcessorSums') )
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.HGCalSimHitsClient_cfi import * hgcalSimHitClientHEF = hgcalSimHitClientEE.clone( DetectorName = cms.string("HGCalHESiliconSensitive")) hgcalSimHitClientHEB = hgcalSimHitClientEE.clone( DetectorName = cms.string("HCal")) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalSimHitClientHEB, DetectorName = cms.string("HGCalHEScintillatorSensitive"), )
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalHitCalibrationDefault_cfi import hgcalHitCalibrationDefault as _hgcalHitCalibrationDefault hgcalHitCalibration = _hgcalHitCalibrationDefault.clone() from Configuration.ProcessModifiers.premix_stage2_cff import premix_stage2 premix_stage2.toModify(hgcalHitCalibration, caloParticles="mixData:MergedCaloTruth") from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify(hgcalHitCalibration, depletionFine=120)
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcGeomCheck_cfi import * from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( hgcGeomCheck, geometrySource=cms.untracked.vstring('HGCalEESensitive', 'HGCalHESiliconSensitive', 'HGCalHEScintillatorSensitive'), )
import FWCore.ParameterSet.Config as cms from Validation.HGCalValidation.hgcalRecHitStudyEE_cfi import * hgcalRecHitStudyFH = hgcalRecHitStudyEE.clone( detectorName=cms.string("HGCalHESiliconSensitive"), source=cms.InputTag("HGCalRecHit", "HGCHEFRecHits")) hgcalRecHitStudyBH = hgcalRecHitStudyEE.clone(detectorName=cms.string("HCal"), source=cms.InputTag( "HGCalRecHit", "HGCHEBRecHits")) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( hgcalRecHitStudyBH, detectorName=cms.string("HGCalHEScintillatorSensitive"), )
mixCH=dict( input=theMixObjects.mixCH.input + [ cms.InputTag("g4SimHits", hgceeDigitizer.hitCollection.value()), cms.InputTag("g4SimHits", hgchefrontDigitizer.hitCollection.value()) ], subdets=theMixObjects.mixCH.subdets + [ hgceeDigitizer.hitCollection.value(), hgchefrontDigitizer.hitCollection.value() ], )) from Configuration.Eras.Modifier_phase2_hgcalV9_cff import phase2_hgcalV9 phase2_hgcalV9.toModify( theMixObjects, mixCH=dict( input=theMixObjects.mixCH.input + [cms.InputTag("g4SimHits", hgchebackDigitizer.hitCollection.value())], subdets=theMixObjects.mixCH.subdets + [hgchebackDigitizer.hitCollection.value()], )) from Configuration.Eras.Modifier_phase2_hfnose_cff import phase2_hfnose phase2_hfnose.toModify( theMixObjects, mixCH=dict( input=theMixObjects.mixCH.input + [cms.InputTag("g4SimHits", hfnoseDigitizer.hitCollection.value())], subdets=theMixObjects.mixCH.subdets + [hfnoseDigitizer.hitCollection.value()], )) from Configuration.Eras.Modifier_phase2_timing_layer_cff import phase2_timing_layer phase2_timing_layer.toModify(