EIC code displayed by LXR master/​geant4/​examples/​extended/​biasing/​B02/​exampleB02.out	Source navigation Diff markup Identifier search General search
	Version: master test Revert   Change

Warning, /geant4/examples/extended/biasing/B02/exampleB02.out is written in an unsupported language. File is not indexed.

 Environment variable "G4FORCE_RUN_MANAGER_TYPE" enabled with value == Serial. Forcing G4RunManager type...
 
         ############################################
         !!! WARNING - FPE detection is activated !!!
         ############################################
 
 
           ################################
           !!! G4Backtrace is activated !!!
           ################################
 
 
 **************************************************************
  Geant4 version Name: geant4-11-02-ref-06    (28-June-2024)
                        Copyright : Geant4 Collaboration
                       References : NIM A 506 (2003), 250-303
                                  : IEEE-TNS 53 (2006), 270-278
                                  : NIM A 835 (2016), 186-225
                              WWW : http://geant4.org/
 **************************************************************
 
 <<< Geant4 Physics List simulation engine: FTFP_BERT
 
  constructing parallel world 
  B02ImportanceDetectorConstruction:: ghostWorldName = ParallelBiasingWorld
 --- G4CoupledTransportation is used 
 
  hInelastic FTFP_BERT : threshold between BERT and FTFP is over the interval 
  for pions :   3 to 6 GeV
  for kaons :   3 to 6 GeV
  for proton :  3 to 6 GeV
  for neutron : 3 to 6 GeV
 
 ### Adding tracking cuts for neutron  TimeCut(ns)= 10000  KinEnergyCut(MeV)= 0
  paraFlag: 1
  Preparing Importance Sampling 
 G4IStore:: Creating new Parallel IStore ParallelBiasingWorld
  G4IStore:: ParallelWorldName = ParallelBiasingWorld
  G4IStore:: fParallelWorldVolume = ParallelBiasingWorld
 G4GeometrySampler:: preparing importance sampling WorldName is 
  G4ImportanceConfigurator:: setting world name: 
 G4ImportanceConfigurator:: entering importance configure, paraflag 1
 ### G4ImportanceProcess:: Creating 
 G4ImportanceProcess:: importance process paraflag is: 1
 
 
 
 G4ImportanceProcess:: SetParallelWorld name = ParallelBiasingWorld
 === G4ProcessPlacer::AddProcessAsSecondDoIt: for: neutron
   Modifying Process Order for ProcessName: ImportanceProcess
   The initial AlongStep Vectors: 
 GPIL Vector: 
    CoupledTransportation
 DoIt Vector: 
    CoupledTransportation
 The initial PostStep Vectors: 
 GPIL Vector: 
    nKiller
    nCapture
    neutronInelastic
    hadElastic
    Decay
    CoupledTransportation
 DoIt Vector: 
    CoupledTransportation
    Decay
    hadElastic
    neutronInelastic
    nCapture
    nKiller
   The final AlongStep Vectors: 
 GPIL Vector: 
    ImportanceProcess
    CoupledTransportation
 DoIt Vector: 
    CoupledTransportation
    ImportanceProcess
 The final PostStep Vectors: 
 GPIL Vector: 
    nKiller
    nCapture
    neutronInelastic
    hadElastic
    Decay
    ImportanceProcess
    CoupledTransportation
 DoIt Vector: 
    CoupledTransportation
    ImportanceProcess
    Decay
    hadElastic
    neutronInelastic
    nCapture
    nKiller
 ================================================
  B02ImportanceDetectorConstruction:: Creating Importance Store 
  adding cell: 1 replica: 0 name: cell_01
 Going to assign importance: 1, to volume: cell_01
  adding cell: 2 replica: 0 name: cell_02
 Going to assign importance: 2, to volume: cell_02
  adding cell: 3 replica: 0 name: cell_03
 Going to assign importance: 4, to volume: cell_03
  adding cell: 4 replica: 0 name: cell_04
 Going to assign importance: 8, to volume: cell_04
  adding cell: 5 replica: 0 name: cell_05
 Going to assign importance: 16, to volume: cell_05
  adding cell: 6 replica: 0 name: cell_06
 Going to assign importance: 32, to volume: cell_06
  adding cell: 7 replica: 0 name: cell_07
 Going to assign importance: 64, to volume: cell_07
  adding cell: 8 replica: 0 name: cell_08
 Going to assign importance: 128, to volume: cell_08
  adding cell: 9 replica: 0 name: cell_09
 Going to assign importance: 256, to volume: cell_09
  adding cell: 10 replica: 0 name: cell_10
 Going to assign importance: 512, to volume: cell_10
  adding cell: 11 replica: 0 name: cell_11
 Going to assign importance: 1024, to volume: cell_11
  adding cell: 12 replica: 0 name: cell_12
 Going to assign importance: 2048, to volume: cell_12
  adding cell: 13 replica: 0 name: cell_13
 Going to assign importance: 4096, to volume: cell_13
  adding cell: 14 replica: 0 name: cell_14
 Going to assign importance: 8192, to volume: cell_14
  adding cell: 15 replica: 0 name: cell_15
 Going to assign importance: 16384, to volume: cell_15
  adding cell: 16 replica: 0 name: cell_16
 Going to assign importance: 32768, to volume: cell_16
  adding cell: 17 replica: 0 name: cell_17
 Going to assign importance: 65536, to volume: cell_17
  adding cell: 18 replica: 0 name: cell_18
 Going to assign importance: 131072, to volume: cell_18
 =======================================================================
 ======                 Electromagnetic Physics Parameters      ========
 =======================================================================
 LPM effect enabled                                 1
 Enable creation and use of sampling tables         0
 Apply cuts on all EM processes                     0
 Use combined TransportationWithMsc                 Disabled
 Use general process                                1
 Enable linear polarisation for gamma               0
 Enable photoeffect sampling below K-shell          1
 Enable sampling of quantum entanglement            0
 X-section factor for integral approach             0.8
 Min kinetic energy for tables                      100 eV 
 Max kinetic energy for tables                      100 TeV
 Number of bins per decade of a table               7
 Verbose level                                      1
 Verbose level for worker thread                    0
 Bremsstrahlung energy threshold above which 
   primary e+- is added to the list of secondary    100 TeV
 Bremsstrahlung energy threshold above which primary
   muon/hadron is added to the list of secondary    100 TeV
 Lowest triplet kinetic energy                      1 MeV
 Enable sampling of gamma linear polarisation       0
 5D gamma conversion model type                     0
 5D gamma conversion model on isolated ion          0
 Livermore data directory                           epics_2017
 =======================================================================
 ======                 Ionisation Parameters                   ========
 =======================================================================
 Step function for e+-                              (0.2, 1 mm)
 Step function for muons/hadrons                    (0.2, 0.1 mm)
 Step function for light ions                       (0.2, 0.1 mm)
 Step function for general ions                     (0.2, 0.1 mm)
 Lowest e+e- kinetic energy                         1 keV
 Lowest muon/hadron kinetic energy                  1 keV
 Use ICRU90 data                                    0
 Fluctuations of dE/dx are enabled                  1
 Type of fluctuation model for leptons and hadrons  Urban
 Use built-in Birks satuaration                     0
 Build CSDA range enabled                           0
 Use cut as a final range enabled                   0
 Enable angular generator interface                 0
 Max kinetic energy for CSDA tables                 1 GeV
 Max kinetic energy for NIEL computation            0 eV 
 Linear loss limit                                  0.01
 Read data from file for e+e- pair production by mu 0
 =======================================================================
 ======                 Multiple Scattering Parameters          ========
 =======================================================================
 Type of msc step limit algorithm for e+-           1
 Type of msc step limit algorithm for muons/hadrons 0
 Msc lateral displacement for e+- enabled           1
 Msc lateral displacement for muons and hadrons     0
 Urban msc model lateral displacement alg96         1
 Range factor for msc step limit for e+-            0.04
 Range factor for msc step limit for muons/hadrons  0.2
 Geometry factor for msc step limitation of e+-     2.5
 Safety factor for msc step limit for e+-           0.6
 Skin parameter for msc step limitation of e+-      1
 Lambda limit for msc step limit for e+-            1 mm
 Use Mott correction for e- scattering              0
 Factor used for dynamic computation of angular 
   limit between single and multiple scattering     1
 Fixed angular limit between single 
   and multiple scattering                          3.1416 rad
 Upper energy limit for e+- multiple scattering     100 MeV
 Type of electron single scattering model           0
 Type of nuclear form-factor                        1
 Screening factor                                   1
 =======================================================================
 
 phot:  for gamma SubType=12 BuildTable=0
       LambdaPrime table from 200 keV to 100 TeV in 61 bins 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
  LivermorePhElectric : Emin=    0 eV  Emax=  100 TeV  SauterGavrila Fluo
 
 compt:  for gamma SubType=13 BuildTable=1
       Lambda table from 100 eV  to 1 MeV, 7 bins/decade, spline: 1
       LambdaPrime table from 1 MeV to 100 TeV in 56 bins 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
        Klein-Nishina : Emin=    0 eV  Emax=  100 TeV
 
 conv:  for gamma SubType=14 BuildTable=1
       Lambda table from 1.022 MeV to 100 TeV, 18 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
      BetheHeitlerLPM : Emin=    0 eV  Emax=  100 TeV  ModifiedTsai
 
 Rayl:  for gamma SubType=11 BuildTable=1
       Lambda table from 100 eV  to 150 keV, 7 bins/decade, spline: 0
       LambdaPrime table from 150 keV to 100 TeV in 62 bins 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
    LivermoreRayleigh : Emin=    0 eV  Emax=  100 TeV  CullenGenerator
 
 msc:  for e-  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             UrbanMsc : Emin=    0 eV  Emax=  100 MeV Nbins=42 100 eV  - 100 MeV
           StepLim=UseSafety Rfact=0.04 Gfact=2.5 Sfact=0.6 DispFlag:1 Skin=1 Llim=1 mm
         WentzelVIUni : Emin=  100 MeV Emax=  100 TeV Nbins=42 100 MeV - 100 TeV
           StepLim=UseSafety Rfact=0.04 Gfact=2.5 Sfact=0.6 DispFlag:1 Skin=1 Llim=1 mm
 
 eIoni:  for e-  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         MollerBhabha : Emin=    0 eV  Emax=  100 TeV
 
 eBrem:  for e-  XStype:4  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       LPM flag: 1 for E > 1 GeV,  VertexHighEnergyTh(GeV)= 100000
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
              eBremSB : Emin=    0 eV  Emax=    1 GeV  ModifiedTsai
             eBremLPM : Emin=    1 GeV Emax=  100 TeV  ModifiedTsai
 
 CoulombScat:  for e- XStype:1 SubType=1 BuildTable=1
       Lambda table from 100 MeV to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=  100 MeV Emax=  100 TeV
 
 msc:  for e+  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             UrbanMsc : Emin=    0 eV  Emax=  100 MeV Nbins=42 100 eV  - 100 MeV
           StepLim=UseSafety Rfact=0.04 Gfact=2.5 Sfact=0.6 DispFlag:1 Skin=1 Llim=1 mm
         WentzelVIUni : Emin=  100 MeV Emax=  100 TeV Nbins=42 100 MeV - 100 TeV
           StepLim=UseSafety Rfact=0.04 Gfact=2.5 Sfact=0.6 DispFlag:1 Skin=1 Llim=1 mm
 
 eIoni:  for e+  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         MollerBhabha : Emin=    0 eV  Emax=  100 TeV
 
 eBrem:  for e+  XStype:4  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       LPM flag: 1 for E > 1 GeV,  VertexHighEnergyTh(GeV)= 100000
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
              eBremSB : Emin=    0 eV  Emax=    1 GeV  ModifiedTsai
             eBremLPM : Emin=    1 GeV Emax=  100 TeV  ModifiedTsai
 
 annihil:  for e+ XStype:2 SubType=5 AtRestModel:Simple BuildTable=0
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             eplus2gg : Emin=    0 eV  Emax=  100 TeV
 
 CoulombScat:  for e+ XStype:1 SubType=1 BuildTable=1
       Lambda table from 100 MeV to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=  100 MeV Emax=  100 TeV
 
 msc:  for proton  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 hIoni:  for proton  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                Bragg : Emin=    0 eV  Emax=    2 MeV
           BetheBloch : Emin=    2 MeV Emax=  100 TeV
 
 hBrems:  for proton  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                hBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 hPairProd:  for proton  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 17x1001 from 7.50618 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
            hPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for proton XStype:1 SubType=1 BuildTable=1
       Lambda table from threshold  to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for GenericIon  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             UrbanMsc : Emin=    0 eV  Emax=  100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 ionIoni:  for GenericIon  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.02
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             BraggIon : Emin=    0 eV  Emax=    2 MeV
           BetheBloch : Emin=    2 MeV Emax=  100 TeV
 
 msc:  for alpha  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             UrbanMsc : Emin=    0 eV  Emax=  100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 ionIoni:  for alpha  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.02
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             BraggIon : Emin=    0 eV  Emax=7.9452 MeV
           BetheBloch : Emin=7.9452 MeV Emax=  100 TeV
 
 msc:  for anti_proton  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 hIoni:  for anti_proton  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             ICRU73QO : Emin=    0 eV  Emax=    2 MeV
           BetheBloch : Emin=    2 MeV Emax=  100 TeV
 
 hBrems:  for anti_proton  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                hBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 hPairProd:  for anti_proton  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 17x1001 from 7.50618 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
            hPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for anti_proton XStype:1 SubType=1 BuildTable=1
       Lambda table from threshold  to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for kaon+  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 hIoni:  for kaon+  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                Bragg : Emin=    0 eV  Emax=1.05231 MeV
           BetheBloch : Emin=1.05231 MeV Emax=  100 TeV
 
 hBrems:  for kaon+  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                hBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 hPairProd:  for kaon+  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 18x1001 from 3.94942 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
            hPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for kaon+ XStype:1 SubType=1 BuildTable=1
       Lambda table from threshold  to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for kaon-  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 hIoni:  for kaon-  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             ICRU73QO : Emin=    0 eV  Emax=1.05231 MeV
           BetheBloch : Emin=1.05231 MeV Emax=  100 TeV
 
 hBrems:  for kaon-  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                hBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 hPairProd:  for kaon-  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 18x1001 from 3.94942 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
            hPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for kaon- XStype:1 SubType=1 BuildTable=1
       Used Lambda table of kaon+
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for mu+  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 muIoni:  for mu+  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                Bragg : Emin=    0 eV  Emax=  200 keV
         MuBetheBloch : Emin=  200 keV Emax=  100 TeV
 
 muBrems:  for mu+  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
               MuBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 muPairProd:  for mu+  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 21x1001 from 0.85 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
           muPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for mu+ XStype:1 SubType=1 BuildTable=1
       Lambda table from threshold  to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for mu-  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 muIoni:  for mu-  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             ICRU73QO : Emin=    0 eV  Emax=  200 keV
         MuBetheBloch : Emin=  200 keV Emax=  100 TeV
 
 muBrems:  for mu-  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
               MuBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 muPairProd:  for mu-  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 21x1001 from 0.85 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
           muPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for mu- XStype:1 SubType=1 BuildTable=1
       Used Lambda table of mu+
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for pi+  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 hIoni:  for pi+  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                Bragg : Emin=    0 eV  Emax=297.505 keV
           BetheBloch : Emin=297.505 keV Emax=  100 TeV
 
 hBrems:  for pi+  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                hBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 hPairProd:  for pi+  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 20x1001 from 1.11656 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
            hPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for pi+ XStype:1 SubType=1 BuildTable=1
       Lambda table from threshold  to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for pi-  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 hIoni:  for pi-  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             ICRU73QO : Emin=    0 eV  Emax=297.505 keV
           BetheBloch : Emin=297.505 keV Emax=  100 TeV
 
 hBrems:  for pi-  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                hBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 hPairProd:  for pi-  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 20x1001 from 1.11656 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
            hPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for pi- XStype:1 SubType=1 BuildTable=1
       Used Lambda table of pi+
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 ====================================================================
                   HADRONIC PROCESSES SUMMARY (verbose level 1)
 -----------------------------------------------------------------------
                            Hadronic Processes for neutron
   Process: hadElastic
         Model:             hElasticCHIPS: 0 eV  ---> 100 TeV
      Cr_sctns:        G4NeutronElasticXS: 0 eV  ---> 100 TeV
   Process: neutronInelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:      G4NeutronInelasticXS: 0 eV  ---> 100 TeV
   Process: nCapture
         Model:               nRadCapture: 0 eV  ---> 100 TeV
      Cr_sctns:        G4NeutronCaptureXS: 0 eV  ---> 100 TeV
   Process: nKiller
 -----------------------------------------------------------------------
                            Hadronic Processes for B-
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: B-Inelastic
         Model:                      FTFP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for D-
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: D-Inelastic
         Model:                      FTFP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for GenericIon
   Process: ionInelastic
         Model:  Binary Light Ion Cascade: 0 eV /n ---> 6 GeV/n
         Model:                      FTFP: 3 GeV/n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
 -----------------------------------------------------------------------
                            Hadronic Processes for He3
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
   Process: He3Inelastic
         Model:  Binary Light Ion Cascade: 0 eV /n ---> 6 GeV/n
         Model:                      FTFP: 3 GeV/n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
 -----------------------------------------------------------------------
                            Hadronic Processes for alpha
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
   Process: alphaInelastic
         Model:  Binary Light Ion Cascade: 0 eV /n ---> 6 GeV/n
         Model:                      FTFP: 3 GeV/n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_He3
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100.1 MeV/n
         Model:              AntiAElastic: 100 MeV/n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: anti_He3Inelastic
         Model:                      FTFP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_alpha
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100.1 MeV/n
         Model:              AntiAElastic: 100 MeV/n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: anti_alphaInelastic
         Model:                      FTFP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_deuteron
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100.1 MeV/n
         Model:              AntiAElastic: 100 MeV/n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: anti_deuteronInelastic
         Model:                      FTFP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: hFritiofCaptureAtRest
 -------------------------------------------------------------------------
                            Hadronic Processes for anti_hypertriton
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_lambda
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: anti_lambdaInelastic
         Model:                      FTFP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_neutron
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100.1 MeV
         Model:              AntiAElastic: 100 MeV ---> 100 TeV
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: anti_neutronInelastic
         Model:                      FTFP: 0 eV  ---> 100 TeV
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_proton
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100.1 MeV
         Model:              AntiAElastic: 100 MeV ---> 100 TeV
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: anti_protonInelastic
         Model:                      FTFP: 0 eV  ---> 100 TeV
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_triton
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100.1 MeV/n
         Model:              AntiAElastic: 100 MeV/n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: anti_tritonInelastic
         Model:                      FTFP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for deuteron
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
   Process: dInelastic
         Model:  Binary Light Ion Cascade: 0 eV /n ---> 6 GeV/n
         Model:                      FTFP: 3 GeV/n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
 -----------------------------------------------------------------------
                            Hadronic Processes for e+
   Process: positronNuclear
         Model:   G4ElectroVDNuclearModel: 0 eV  ---> 1 PeV
      Cr_sctns:          ElectroNuclearXS: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for e-
   Process: electronNuclear
         Model:   G4ElectroVDNuclearModel: 0 eV  ---> 1 PeV
      Cr_sctns:          ElectroNuclearXS: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for gamma
   Process: photonNuclear
         Model:               GammaNPreco: 0 eV  ---> 200 MeV
         Model:            BertiniCascade: 199 MeV ---> 6 GeV
         Model:           TheoFSGenerator: 3 GeV ---> 100 TeV
      Cr_sctns:            GammaNuclearXS: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for kaon+
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: kaon+Inelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for kaon-
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: kaon-Inelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: hBertiniCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for lambda
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: lambdaInelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for mu+
   Process: muonNuclear
         Model:      G4MuonVDNuclearModel: 0 eV  ---> 1 PeV
      Cr_sctns:     KokoulinMuonNuclearXS: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for mu-
   Process: muonNuclear
         Model:      G4MuonVDNuclearModel: 0 eV  ---> 1 PeV
      Cr_sctns:     KokoulinMuonNuclearXS: 0 eV  ---> 100 TeV
   Process: muMinusCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for pi+
   Process: hadElastic
         Model:           hElasticGlauber: 0 eV  ---> 100 TeV
      Cr_sctns:  BarashenkovGlauberGribov: 0 eV  ---> 100 TeV
   Process: pi+Inelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:  BarashenkovGlauberGribov: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for pi-
   Process: hadElastic
         Model:           hElasticGlauber: 0 eV  ---> 100 TeV
      Cr_sctns:  BarashenkovGlauberGribov: 0 eV  ---> 100 TeV
   Process: pi-Inelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:  BarashenkovGlauberGribov: 0 eV  ---> 100 TeV
   Process: hBertiniCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for proton
   Process: hadElastic
         Model:             hElasticCHIPS: 0 eV  ---> 100 TeV
      Cr_sctns:  BarashenkovGlauberGribov: 0 eV  ---> 100 TeV
   Process: protonInelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:  BarashenkovGlauberGribov: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for sigma-
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: sigma-Inelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: hBertiniCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for triton
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
   Process: tInelastic
         Model:  Binary Light Ion Cascade: 0 eV /n ---> 6 GeV/n
         Model:                      FTFP: 3 GeV/n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
 =======================================================================
 ======       Geant4 Native Pre-compound Model Parameters       ========
 =======================================================================
 Type of pre-compound inverse x-section              3
 Pre-compound model active                           1
 Pre-compound excitation low energy                  100 keV
 Pre-compound excitation high energy                 30 MeV
 Angular generator for pre-compound model            1
 Use NeverGoBack option for pre-compound model       0
 Use SoftCutOff option for pre-compound model        0
 Use CEM transitions for pre-compound model          1
 Use GNASH transitions for pre-compound model        0
 Use HETC submodel for pre-compound model            0
 =======================================================================
 ======       Nuclear De-excitation Module Parameters           ========
 =======================================================================
 Type of de-excitation inverse x-section             3
 Type of de-excitation factory                       Evaporation+GEM
 Number of de-excitation channels                    68
 Min excitation energy                               10 eV 
 Min energy per nucleon for multifragmentation       200 GeV
 Limit excitation energy for Fermi BreakUp           20 MeV
 Level density (1/MeV)                               0.075
 Use simple level density model                      1
 Use discrete excitation energy of the residual      0
 Time limit for long lived isomeres                  1 ns 
 Isomer production flag                              1
 Internal e- conversion flag                         1
 Store e- internal conversion data                   0
 Correlated gamma emission flag                      0
 Max 2J for sampling of angular correlations         10
 =======================================================================
 ++ ConcreteSD/Collisions id 0
 ++ ConcreteSD/CollWeight id 1
 ++ ConcreteSD/Population id 2
 ++ ConcreteSD/TrackEnter id 3
 ++ ConcreteSD/SL id 4
 ++ ConcreteSD/SLW id 5
 ++ ConcreteSD/SLWE id 6
 ++ ConcreteSD/SLW_V id 7
 ++ ConcreteSD/SLWE_V id 8
 ### Run 0 start.
  ###### EndOfRunAction  
 
 --------------------End of Global Run-----------------------
  Number of event processed : 100
 =============================================================
 =============================================================
         Volume |   Tr.Entering |    Population |    Collisions |      Coll*WGT |     NumWGTedE |    FluxWGTedE |     Av.Tr.WGT |            SL |           SLW |         SLW_v |          SLWE |        SLWE_v |
        cell_00 |            42 |           131 |             0 |             0 |      0.184971 |       3.37607 |             1 |       8498.22 |       8498.22 |       4902.45 |       28690.6 |        906.81 |
        cell_01 |           156 |           177 |           591 |           591 |     0.0253005 |       4.59154 |             1 |       26095.4 |       26095.4 |        128533 |        119818 |       3251.96 |
        cell_02 |           151 |           270 |          1364 |           682 |    0.00824517 |       2.88448 |           0.5 |       46809.7 |       23404.8 |        248723 |       67510.8 |       2050.76 |
        cell_03 |           213 |           339 |          1847 |        461.75 |    0.00784637 |       2.49261 |          0.25 |       60023.3 |       15005.8 |        152868 |       37403.7 |       1199.46 |
        cell_04 |           292 |           439 |          2704 |           338 |    0.00395717 |       1.82087 |         0.125 |       85481.2 |       10685.1 |        170951 |       19456.3 |       676.482 |
        cell_05 |           354 |           521 |          2902 |       181.375 |    0.00381489 |       1.74643 |        0.0625 |       90527.3 |       5657.96 |       92037.5 |       9881.21 |       351.113 |
        cell_06 |           357 |           536 |          3259 |       101.844 |     0.0036991 |       1.51354 |       0.03125 |        101450 |       3170.31 |       49567.1 |       4798.39 |       183.354 |
        cell_07 |           365 |           520 |          3235 |       50.5469 |    0.00397513 |       1.30445 |      0.015625 |       98869.1 |       1544.83 |       20778.6 |       2015.16 |       82.5977 |
        cell_08 |           353 |           506 |          3520 |          27.5 |    0.00341526 |       1.16311 |     0.0078125 |        104366 |       815.361 |       11933.1 |       948.352 |       40.7546 |
        cell_09 |           329 |           479 |          3030 |       11.8359 |    0.00321627 |       1.21251 |    0.00390625 |       89437.1 |       349.364 |       5523.33 |       423.608 |       17.7645 |
        cell_10 |           342 |           473 |          3183 |        6.2168 |     0.0026826 |        1.0116 |    0.00195312 |         96625 |       188.721 |       3212.72 |        190.91 |       8.61842 |
        cell_11 |           332 |           478 |          3205 |       3.12988 |    0.00238013 |      0.885205 |   0.000976562 |         90989 |       88.8565 |       1471.85 |       78.6562 |       3.50321 |
        cell_12 |           277 |           397 |          2565 |       1.25244 |    0.00235102 |      0.832991 |   0.000488281 |       71004.1 |         34.67 |       564.603 |       28.8798 |       1.32739 |
        cell_13 |           240 |           326 |          2169 |      0.529541 |     0.0021402 |      0.936454 |   0.000244141 |       62727.9 |       15.3144 |       290.008 |       14.3413 |      0.620674 |
        cell_14 |           191 |           291 |          1962 |      0.239502 |    0.00265347 |       1.12766 |    0.00012207 |       55184.8 |       6.73643 |       119.225 |       7.59638 |      0.316361 |
        cell_15 |           153 |           230 |          1472 |     0.0898438 |    0.00326666 |       1.15395 |   6.10352e-05 |       43572.5 |       2.65945 |       39.9852 |       3.06887 |      0.130618 |
        cell_16 |           152 |           221 |          1581 |     0.0482483 |    0.00272235 |       1.00827 |   3.05176e-05 |       45287.1 |       1.38205 |        22.507 |       1.39349 |     0.0612721 |
        cell_17 |           132 |           197 |          1326 |     0.0202332 |    0.00255942 |       1.01292 |   1.52588e-05 |       38901.4 |      0.593589 |       10.9514 |      0.601259 |     0.0280292 |
        cell_18 |            76 |           142 |           931 |    0.00710297 |       0.00258 |      0.814225 |   7.62939e-06 |       24945.4 |      0.190318 |       2.97786 |      0.154962 |    0.00768286 |
        cell_19 |            46 |            46 |             0 |             0 |     0.0218231 |       1.52808 |   7.62939e-06 |       6737.27 |     0.0514013 |       0.15395 |     0.0785454 |    0.00335965 |
 =============================================

This page was automatically generated by the 2.3.7 LXR engine. The LXR team