Calorimetry_cff.py

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import FWCore.ParameterSet.Config as cms

# This is used to modify parameters for Run 2 (see bottom of file)

#Global fast calorimetry parameters
from FastSimulation.Calorimetry.HcalResponse_cfi import *
from FastSimulation.Calorimetry.HSParameters_cfi import *
#from FastSimulation.Configuration.CommonInputs_cff import *

from FastSimulation.Calorimetry.ECALResponse_cfi import *

FamosCalorimetryBlock = cms.PSet(
    Calorimetry = cms.PSet(
        #ECALScaleBlock, # comment out to disable scaling
        HSParameterBlock,
        HCALResponseBlock,
        ECAL = cms.PSet(
            # See FastSimulation/CaloRecHitsProducer/python/CaloRecHits_cff.py 
            Digitizer = cms.untracked.bool(False),
            # If set to true the simulation in ECAL would be done 1X0 by 1X0
            # this is slow but more adapted to detailed studies.
            # Otherwise roughty 5 steps are used.
            bFixedLength = cms.bool(False),
            
            # For the core 10% of the spots for
            CoreIntervals = cms.vdouble(100.0, 0.1),
            # change the radius of the tail of the shower
            RTFactor = cms.double(1.0),
            # change the radius of the core of the shower
            RCFactor = cms.double(1.0),
            # For the tail 10% of r<1RM. 100% otherwise
            TailIntervals = cms.vdouble(1.0, 0.1, 100.0, 1.0),
            FrontLeakageProbability = cms.double(1.0),
            GridSize = cms.int32(7),
            # change globally the Moliere radius 
            

            ### changed after tuning - Feb - July - Shilpi Jain
            #RadiusFactor = cms.double(1.096),
            RadiusFactorEB = cms.double(1.096),
            RadiusFactorEE = cms.double(1.25),
            ### changed after tuning - Feb - July - Shilpi Jain
            
            RadiusPreshowerCorrections = cms.vdouble(0.137, 10.3), # default value for maxshower depth dependence-->works fine
            MipsinGeV = cms.vdouble(0.0001421,0.0000812), # increase in mipsinGeV by 75% only in layer1
            #SpotFraction < 0 <=> deactivated. In the case, CoreIntervals and 
            #TailIntervals are used   
            SpotFraction = cms.double(-1.0),
            GapLossProbability = cms.double(0.9),
            SimulatePreshower = cms.bool(True)
            ),
        ForwardCalorimeterProperties = cms.PSet(
            HadronicCalorimeterProperties= cms.PSet(
                HCAL_Sampling = cms.double(0.0035),
                # Watch out ! The following two values are defined wrt the electron shower simulation
                # There are not directly related to the detector properties
                HCAL_PiOverE = cms.double(0.2),
                # HCAL_PiOverE = cms.double(0.4)
                HCALAeff= cms.double(55.845),
                HCALZeff= cms.double(26),
                HCALrho= cms.double(7.87),

                HCALradiationLengthIncm= cms.double(1.757),
                HCALradLenIngcm2= cms.double(13.84),
                HCALmoliereRadius= cms.double(1.719),
                HCALcriticalEnergy= cms.double(21E-3),
                HCALinteractionLength= cms.double(16.77),

                HCALetatow=cms.vdouble( 0.000, 0.087, 0.174, 0.261, 0.348, 0.435, 0.522, 0.609, 0.696, 0.783, 0.870,    0.957, 1.044, 1.131, 1.218, 1.305, 1.392, 1.479, 1.566, 1.653, 1.740, 1.830,    1.930, 2.043, 2.172, 2.322, 2.500, 2.650, 2.853, 3.000, 3.139, 3.314, 3.489,    3.664, 3.839, 4.013, 4.191, 4.363, 4.538, 4.716, 4.889, 5.191),
                #                  HCALDepthLam=cms.vdouble( 8.930, 9.001, 9.132, 8.912, 8.104, 8.571, 8.852, 9.230, 9.732, 10.29,          10.95, 11.68, 12.49, 12.57, 12.63,  6.449, 5.806, 8.973, 8.934,  8.823,          8.727, 8.641, 8.565, 8.496, 8.436, 8.383, 8.346, 8.307, 8.298,  8.281,          9.442, 9.437, 9.432, 9.429, 9.432, 9.433, 9.430, 9.437, 9.442, 9.446, 9.435)
                HCALDepthLam=cms.vdouble(8.014, 8.078, 8.195, 7.998, 7.273, 7.692, 7.944, 8.283, 8.734, 9.235, 9.827, 10.482, 11.209, 11.281, 11.335, 5.788, 5.211, 8.053, 8.018, 7.918, 7.832, 7.755, 7.687, 7.625, 7.571, 7.523, 7.490, 7.455, 7.447, 7.432, 8.474, 8.469, 8.465, 8.462, 8.465, 8.466, 8.463, 8.469, 8.474, 8.477, 8.467)
                ),
            ),
        CalorimeterProperties = cms.PSet(
            # triplet for each p value:  p, k_e(p), k_h(p) ...
            RespCorrP = cms.vdouble(1.0, 1.0, 1.0, 1000.0, 1.0, 1.0),  
            PreshowerLayer2_thickness = cms.double(0.38), # layer2 thickness back to original 
            ECALEndcap_LightCollection = cms.double(0.023),
            PreshowerLayer1_thickness = cms.double(1.65), # increase in thickness of layer 1 by 3%
            PreshowerLayer1_mipsPerGeV = cms.double(17.85),  # 50% decrease in mipsperGeV 
            PreshowerLayer2_mipsPerGeV = cms.double(59.5),
            ECALBarrel_LightCollection = cms.double(0.03),
            HadronicCalorimeterProperties= cms.PSet(
                HCAL_Sampling = cms.double(0.0035),
                # Watch out ! The following two values are defined wrt the electron shower simulation
                # There are not directly related to the detector properties
                HCAL_PiOverE = cms.double(0.2),
                # HCAL_PiOverE = cms.double(0.4)
                HCALAeff= cms.double(63.546),
                HCALZeff= cms.double(29.),
                HCALrho= cms.double(8.960),
                
                HCALradiationLengthIncm= cms.double(1.43),
                HCALradLenIngcm2= cms.double(12.86),
                HCALmoliereRadius= cms.double(1.712),
                HCALcriticalEnergy= cms.double(18.63E-3),
                HCALinteractionLength= cms.double(15.05),
                
                HCALetatow=cms.vdouble( 0.000, 0.087, 0.174, 0.261, 0.348, 0.435, 0.522, 0.609, 0.696, 0.783, 0.870,    0.957, 1.044, 1.131, 1.218, 1.305, 1.392, 1.479, 1.566, 1.653, 1.740, 1.830,    1.930, 2.043, 2.172, 2.322, 2.500, 2.650, 2.853, 3.000, 3.139, 3.314, 3.489,    3.664, 3.839, 4.013, 4.191, 4.363, 4.538, 4.716, 4.889, 5.191),
                HCALDepthLam=cms.vdouble( 8.930, 9.001, 9.132, 8.912, 8.104, 8.571, 8.852, 9.230, 9.732, 10.29,          10.95, 11.68, 12.49, 12.57, 12.63,  6.449, 5.806, 8.973, 8.934,  8.823,          8.727, 8.641, 8.565, 8.496, 8.436, 8.383, 8.346, 8.307, 8.298,  8.281,          9.442, 9.437, 9.432, 9.429, 9.432, 9.433, 9.430, 9.437, 9.442, 9.446, 9.435)
                ),
            
            BarrelCalorimeterProperties = cms.PSet(

                #======  Geometrical material properties ========
                
                # Light Collection efficiency 
                lightColl = cms.double(0.03),
                # Light Collection uniformity
                lightCollUnif = cms.double(0.003),
                # Photostatistics (photons/GeV) in the homegeneous material
                photoStatistics = cms.double(50.E3),
                # Thickness of the detector in cm
                thickness = cms.double(23.0),

                #====== Global parameters of the material ========

                # Interaction length in cm
                interactionLength  = cms.double(18.5),
                Aeff = cms.double(170.87),
                Zeff = cms.double(68.36),
                rho = cms.double(8.280),
                # Radiation length in g/cm^2
                radLenIngcm2 = cms.double(7.37),

                # ===== Those parameters might be entered by hand
                # or calculated out of the previous ones 

                # Radiation length in cm. If value set to -1, FastSim uses internally the
                # formula radLenIngcm2/rho
                radLenIncm = cms.double(0.89), 
                # Critical energy in GeV. If value set to -1, FastSim uses internally the
                # formula (2.66E-3*(x0*Z/A)^1.1): 8.74E-3 for ECAL EndCap
                criticalEnergy = cms.double(8.74E-3),
                # Moliere Radius in cm.If value set to -1, FastSim uses internally the
                # formula : Es/criticalEnergy*X0 with Es=sqrt(4*Pi/alphaEM)*me*c^2=0.0212 GeV
                # This value is known to be 2.190 cm for ECAL Endcap, but the formula gives 2.159 cm
                moliereRadius = cms.double(2.190),

                #====== Parameters for sampling ECAL ========

                # Sampling Fraction: Fs = X0eff/(da+dp) where X0eff is the average X0
                # of the active and passive media and da/dp their thicknesses
                Fs = cms.double(0.0),

                # e/mip for the calorimeter. May be estimated by 1./(1+0.007*(Zp-Za))
                ehat = cms.double(0.0),

                # a rough estimate of ECAL resolution sigma/E = resE/sqrt(E)
                # it is used to generate Nspots in radial profiles.
                resE = cms.double(1.),

                # the width in cm of the active layer
                da = cms.double(0.2),

                # the width in cm of the passive layer
                dp = cms.double(0.8),

                # Is a homogenious detector?
                bHom = cms.bool(True),

                # Activate the LogDebug
                debug = cms.bool(False)

                ),
            
            EndcapCalorimeterProperties = cms.PSet(

                #======  Geometrical material properties ========
                
                # Light Collection efficiency 
                lightColl = cms.double(0.023),
                # Light Collection uniformity
                lightCollUnif = cms.double(0.003),
                # Photostatistics (photons/GeV) in the homegeneous material
                photoStatistics = cms.double(50.E3),
                # Thickness of the detector in cm
                thickness = cms.double(22.0),

                #====== Global parameters of the material ========

                # Interaction length in cm
                interactionLength  = cms.double(18.5),
                Aeff = cms.double(170.87),
                Zeff = cms.double(68.36),
                rho = cms.double(8.280),
                # Radiation length in g/cm^2
                radLenIngcm2 = cms.double(7.37),

                # ===== Those parameters might be entered by hand
                # or calculated out of the previous ones 

                # Radiation length in cm. If value set to -1, FastSim uses internally the
                # formula radLenIngcm2/rho
                radLenIncm = cms.double(0.89), 
                # Critical energy in GeV. If value set to -1, FastSim uses internally the
                # formula (2.66E-3*(x0*Z/A)^1.1): 8.74E-3 for ECAL EndCap
                criticalEnergy = cms.double(8.74E-3),
                # Moliere Radius in cm.If value set to -1, FastSim uses internally the
                # formula : Es/criticalEnergy*X0 with Es=sqrt(4*Pi/alphaEM)*me*c^2=0.0212 GeV
                # This value is known to be 2.190 cm for ECAL Endcap, but the formula gives 2.159 cm
                moliereRadius = cms.double(2.190),


                #====== Parameters for sampling ECAL ========

                # Sampling Fraction: Fs = X0eff/(da+dp) where X0eff is the average X0
                # of the active and passive media and da/dp their thicknesses
                Fs = cms.double(0.0),

                # e/mip for the calorimeter. May be estimated by 1./(1+0.007*(Zp-Za))
                ehat = cms.double(0.0),

                # a rough estimate of ECAL resolution sigma/E = resE/sqrt(E)
                # it is used to generate Nspots in radial profiles.
                resE = cms.double(1.),

                # the width in cm of the active layer
                da = cms.double(0.2),

                # the width in cm of the passive layer
                dp = cms.double(0.8),

                # Is a homogenious detector?
                bHom = cms.bool(True),

                # Activate the LogDebug
                debug = cms.bool(False)

                )

            ),
        Debug = cms.untracked.bool(False),
        useDQM = cms.untracked.bool(False),
        #        EvtsToDebug = cms.untracked.vuint32(487),
        HCAL = cms.PSet(
            SimMethod = cms.int32(0), ## 0 - use HDShower, 1 - use HDRShower, 2 - GFLASH
            GridSize = cms.int32(7),
            #-- 0 - simple response, 1 - parametrized response + showering, 2 - tabulated response + showering
            SimOption = cms.int32(2),
            Digitizer = cms.untracked.bool(False),
            
            samplingHBHE = cms.vdouble(125.44, 125.54, 125.32, 125.13, 124.46,
                                       125.01, 125.22, 125.48, 124.45, 125.90,
                                       125.83, 127.01, 126.82, 129.73, 131.83,
                                       143.52, # HB
                                       210.55, 197.93, 186.12, 189.64, 189.63,
                                       190.28, 189.61, 189.60, 190.12, 191.22,
                                       190.90, 193.06, 188.42, 188.42), #HE
            samplingHF   = cms.vdouble(0.383, 0.368),
            samplingHO   = cms.vdouble(231.0, 231.0, 231.0, 231.0, 360.0, 
                                       360.0, 360.0, 360.0, 360.0, 360.0,
                                       360.0, 360.0, 360.0, 360.0, 360.0),

            ietaShiftHB = cms.int32(1),
            timeShiftHB = cms.vdouble(6.9, 6.9, 7.1, 7.1, 7.3, 7.5, 7.9, 8.3, 8.7, 9.1, 9.5, 10.3, 10.9, 11.5, 12.3, 14.1),
            ietaShiftHE = cms.int32(16),
            timeShiftHE = cms.vdouble(16.9, 15.7, 15.3, 15.3, 15.1, 14.9, 14.7, 14.7, 14.5, 14.5, 14.3, 14.3, 14.5, 13.9),
            ietaShiftHO = cms.int32(1),
            timeShiftHO = cms.vdouble(13.7, 13.7, 13.9, 14.1, 15.1, 15.7, 16.5, 17.3, 18.1, 19.1, 20.3, 21.9, 23.3, 25.5, 26.1),
            ietaShiftHF = cms.int32(29),
            timeShiftHF = cms.vdouble(50.7, 52.5, 52.9, 53.9, 54.5, 55.1, 55.1, 55.7, 55.9, 56.1, 56.1, 56.1, 56.5),
            ),
        HFShower           = cms.PSet(
            ProbMax          = cms.double(1.0),
            CFibre           = cms.double(0.5),
            OnlyLong          = cms.bool(True)
            ),
        HFShowerLibrary    = cms.PSet(
            useShowerLibrary = cms.untracked.bool(True),
            useCorrectionSL  = cms.untracked.bool(True),
            FileName = cms.FileInPath('SimG4CMS/Calo/data/HFShowerLibrary_oldpmt_noatt_eta4_16en_v3.root'),
            BackProbability  = cms.double(0.2),
            TreeEMID         = cms.string('emParticles'),
            TreeHadID        = cms.string('hadParticles'),
            Verbosity        = cms.untracked.bool(False),
            ApplyFiducialCut = cms.bool(True),
            BranchEvt        = cms.untracked.string(''),
            BranchPre        = cms.untracked.string(''),
            BranchPost       = cms.untracked.string('')
            )
        ),
    GFlash = cms.PSet(
        GflashExportToFastSim = cms.bool(True),
        GflashHadronPhysics = cms.string('QGSP_BERT'),
        GflashEMShowerModel = cms.bool(False),
        GflashHadronShowerModel = cms.bool(True),
        GflashHcalOuter = cms.bool(False),
        GflashHistogram = cms.bool(False),
        GflashHistogramName = cms.string('gflash_histogram.root'),
        Verbosity = cms.untracked.int32(0),
        bField = cms.double(3.8),
        watcherOn = cms.bool(False),
        tuning_pList = cms.vdouble()
        )
    )

FamosCalorimetryBlock.Calorimetry.ECAL.Digitizer = True
FamosCalorimetryBlock.Calorimetry.HCAL.Digitizer = True

from Configuration.Eras.Modifier_run2_common_cff import run2_common
run2_common.toModify(FamosCalorimetryBlock.Calorimetry.HFShowerLibrary, FileName = 'SimG4CMS/Calo/data/HFShowerLibrary_npmt_noatt_eta4_16en_v4.root' )