************************************************************* Geant4 version Name: geant4-08-01-patch-02 (10-November-2006) Copyright : Geant4 Collaboration Reference : NIM A 506 (2003), 250-303 WWW : http://cern.ch/geant4 ************************************************************* Visualization Manager instantiating... Visualization Manager initialising... Registering graphics systems... You have successfully registered the following graphics systems. Current available graphics systems are: ASCIITree (ATree) DAWNFILE (DAWNFILE) GAGTree (GAGTree) G4HepRep (HepRepXML) G4HepRepFile (HepRepFile) RayTracer (RayTracer) VRML1FILE (VRML1FILE) VRML2FILE (VRML2FILE) OpenGLImmediateX (OGLIX) OpenGLStoredX (OGLSX) RayTracerX (RayTracerX) Registering model factories... You have successfully registered the following model factories. Registered model factories: generic drawByCharge drawByParticleID drawByOriginVolume Registered models: None Registered filter factories: chargeFilter particleFilter originVolumeFilter Registered filters: None You are using the A01PhysicsList Full set of particles (barions bosons and mesons) will be created and Standard EM Physics and Low & High Energy parameterized models will be applied. A01PhysicsList is optimized for robustness and not for any particular usage. For the hadronic physics, educated guesses of physics list are prepared for various use cases. When you will start REAL calculations for your own interest, please consider the usage of hadronic_lists instead of A01PhysicsLists. More information can also be found from the Geant4 HyperNews. http://geant4-hn.slac.stanford.edu:5090/Geant4-HyperNews/index The materials defined are : ***** Table : Nb of materials = 5 ***** Material: ArgonGas density: 1.782 kg/m3 temperature: 273.15 K pressure: 1.00 atm RadLength: 109.708 m ---> Element: ArgonGas ( ) Z = 18.0 N = 40.0 A = 39.95 g/mole ElmMassFraction: 100.00 % ElmAbundance 100.00 % Material: Air density: 1.290 kg/m3 temperature: 273.15 K pressure: 1.00 atm RadLength: 285.161 m ---> Element: Nitrogen (N) Z = 7.0 N = 14.0 A = 14.01 g/mole ElmMassFraction: 70.00 % ElmAbundance 72.71 % ---> Element: Oxigen (O) Z = 8.0 N = 16.0 A = 16.00 g/mole ElmMassFraction: 30.00 % ElmAbundance 27.29 % Material: Scintillator density: 1.032 g/cm3 temperature: 273.15 K pressure: 1.00 atm RadLength: 42.549 cm ---> Element: Carbon (C) Z = 6.0 N = 12.0 A = 12.01 g/mole ElmMassFraction: 91.45 % ElmAbundance 47.37 % ---> Element: Hydrogen (H) Z = 1.0 N = 1.0 A = 1.01 g/mole ElmMassFraction: 8.55 % ElmAbundance 52.63 % Material: CsI density: 4.510 g/cm3 temperature: 273.15 K pressure: 1.00 atm RadLength: 1.861 cm ---> Element: Iodine (I) Z = 53.0 N = 126.9 A = 126.90 g/mole ElmMassFraction: 50.00 % ElmAbundance 51.15 % ---> Element: Cesium (Cs) Z = 55.0 N = 132.9 A = 132.90 g/mole ElmMassFraction: 50.00 % ElmAbundance 48.85 % Material: Lead density: 11.350 g/cm3 temperature: 273.15 K pressure: 1.00 atm RadLength: 5.612 mm ---> Element: Lead ( ) Z = 82.0 N = 207.2 A = 207.19 g/mole ElmMassFraction: 100.00 % ElmAbundance 100.00 % The geometrical tree defined are : worldPhysical[0] worldLogical 3 Air magneticPhysical[0] magneticLogical 0 Air firstArmPhysical[0] firstArmLogical 20 Air hodoscope1Physical[0] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[1] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[2] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[3] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[4] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[5] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[6] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[7] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[8] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[9] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[10] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[11] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[12] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[13] hodoscope1Logical 0 Scintillator /hodoscope1 hodoscope1Physical[14] hodoscope1Logical 0 Scintillator /hodoscope1 chamber1Physical[0] chamber1Logical 1 ArgonGas wirePlane1Physical[0] wirePlane1Logical 0 ArgonGas /chamber1 chamber1Physical[1] chamber1Logical 1 ArgonGas wirePlane1Physical[0] wirePlane1Logical 0 ArgonGas /chamber1 chamber1Physical[2] chamber1Logical 1 ArgonGas wirePlane1Physical[0] wirePlane1Logical 0 ArgonGas /chamber1 chamber1Physical[3] chamber1Logical 1 ArgonGas wirePlane1Physical[0] wirePlane1Logical 0 ArgonGas /chamber1 chamber1Physical[4] chamber1Logical 1 ArgonGas wirePlane1Physical[0] wirePlane1Logical 0 ArgonGas /chamber1 secondArmPhys[0] secondArmLogical 32 Air hodoscope2Physical[0] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[1] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[2] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[3] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[4] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[5] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[6] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[7] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[8] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[9] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[10] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[11] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[12] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[13] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[14] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[15] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[16] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[17] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[18] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[19] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[20] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[21] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[22] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[23] hodoscope2Logical 0 Scintillator /hodoscope2 hodoscope2Physical[24] hodoscope2Logical 0 Scintillator /hodoscope2 chamber2Physical[0] chamber2Logical 1 ArgonGas wirePlane2Physical[0] wirePlane2Logical 0 ArgonGas /chamber2 chamber2Physical[1] chamber2Logical 1 ArgonGas wirePlane2Physical[0] wirePlane2Logical 0 ArgonGas /chamber2 chamber2Physical[2] chamber2Logical 1 ArgonGas wirePlane2Physical[0] wirePlane2Logical 0 ArgonGas /chamber2 chamber2Physical[3] chamber2Logical 1 ArgonGas wirePlane2Physical[0] wirePlane2Logical 0 ArgonGas /chamber2 chamber2Physical[4] chamber2Logical 1 ArgonGas wirePlane2Physical[0] wirePlane2Logical 0 ArgonGas /chamber2 EMcalorimeterPhysical[0] EMcalorimeterLogical 1 CsI cellPhysical[-1] cellLogical 0 CsI /EMcalorimeter HadCalorimeterPhysical[0] HadCalorimeterLogical 1 Lead HadCalColumnPhysical[-1] HadCalColumnLogical 1 Lead HadCalCellPhysical[-1] HadCalCellLogical 1 Lead HadCalLayerPhysical[-1] HadCalLayerLogical 1 Lead HadCalScintiPhysical[0] HadCalScintiLogical 0 Scintillator /HadCalorimeter Idle> /vis/open OGLIX Got standard cmap Window name: viewer-0 (OpenGLImmediateX) WARNING: objects with visibility flag set to "false" will not be drawn! "/vis/viewer/set/culling global false" to Draw such objects. Also see other "/vis/viewer/set" commands. WARNING: SceneHandler "scene-handler-0", to which viewer "viewer-0" is attached, has no scene - "/vis/scene/create" and"/vis/sceneHandler/attach" (or use compound command "/vis/drawVolume"). Idle> /vis/drawVolume WARNING: For systems which are not "auto-refresh" you will need to issue "/vis/viewer/refresh" or "/vis/viewer/flush". Idle> /vis/scene/add/trajectories WARNING: "/tracking/storeTrajectory 1" has been executed. Idle> /vis/scene/add/hits Idle> /run/beamOn 1 conv: Total cross sections has a good parametrisation from 1.5 MeV to 100 GeV for all Z; sampling secondary e+e- according to the Bethe-Heitler model tables are built for gamma Lambda tables from 1.022 MeV to 100 GeV in 100 bins. compt: Total cross sections has a good parametrisation from 10 KeV to (100/Z) GeV Sampling according Klein-Nishina model tables are built for gamma Lambda tables from 100 eV to 100 GeV in 90 bins. phot: Total cross sections from Sandia parametrisation. msc: Model variant of multiple scattering for e- Lambda tables from 100 eV to 100 TeV in 120 bins. Boundary/stepping algorithm is active with facrange= 0.02 Step limitation 1 eIoni: tables are built for e- dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Delta cross sections from Moller+Bhabha, good description from 1 KeV to 100 GeV. Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1 eBrem: tables are built for e- dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Total cross sections from a parametrisation based on the EEDL data library. Good description from 1 KeV to 100 GeV, log scale extrapolation above 100 GeV. eIoni: tables are built for e+ dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Delta cross sections from Moller+Bhabha, good description from 1 KeV to 100 GeV. Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1 eBrem: tables are built for e+ dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Total cross sections from a parametrisation based on the EEDL data library. Good description from 1 KeV to 100 GeV, log scale extrapolation above 100 GeV. annihil: Heilter model of formula of annihilation into 2 photons tables are built for e+ Lambda tables from 100 eV to 100 TeV in 120 bins. hIoni: tables are built for proton dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Scaling relation is used to proton dE/dx and range Bether-Bloch model for Escaled > 2 MeV, ICRU49 parametrisation for protons below. Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1 msc: Model variant of multiple scattering for proton Lambda tables from 100 eV to 100 TeV in 120 bins. Boundary/stepping algorithm is active with facrange= 0.02 Step limitation 1 ionIoni: tables are built for GenericIon dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Scaling relation is used to proton dE/dx and range Bether-Bloch model for Escaled > 2 MeV, ICRU49 parametrisation for alpha particles below. Stopping Power data for 8 ion/material pairs are used. Step function: finalRange(mm)= 0.1, dRoverRange= 0.1, integral: 1 msc: Model variant of multiple scattering for GenericIon Boundary/stepping algorithm is active with facrange= 0.02 Step limitation 1 hIoni: tables are built for anti_proton dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Scaling relation is used to proton dE/dx and range Bether-Bloch model for Escaled > 2 MeV, ICRU49 parametrisation for protons below. Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1 muIoni: tables are built for mu+ dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Bether-Bloch model for E > 0.2 MeV, parametrisation of Bragg peak below, radiative corrections for E > 1 GeV Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1 msc: Model variant of multiple scattering for mu+ Lambda tables from 100 eV to 100 TeV in 120 bins. Boundary/stepping algorithm is active with facrange= 0.02 Step limitation 1 muBrems: tables are built for mu+ dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Parametrised model muPairProd: tables are built for mu+ dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Parametrised model muIoni: tables are built for mu- dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Bether-Bloch model for E > 0.2 MeV, parametrisation of Bragg peak below, radiative corrections for E > 1 GeV Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1 muBrems: tables are built for mu- dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Parametrised model muPairProd: tables are built for mu- dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Parametrised model hIoni: tables are built for pi+ dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Scaling relation is used to proton dE/dx and range Bether-Bloch model for Escaled > 0.297504 MeV, ICRU49 parametrisation for protons below. Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1 hIoni: tables are built for pi- dE/dx and range tables from 100 eV to 100 TeV in 120 bins. Lambda tables from threshold to 100 TeV in 120 bins. Scaling relation is used to proton dE/dx and range Bether-Bloch model for Escaled > 0.297504 MeV, ICRU49 parametrisation for protons below. Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1 msc: Model variant of multiple scattering for pi- Lambda tables from 100 eV to 100 TeV in 120 bins. Boundary/stepping algorithm is active with facrange= 0.02 Step limitation 1 >>> Event 0 >>> Simulation truth : e+ (15.359274,0,993.19785) Hodoscope 1 has 1 hits. Hodoscope[7] 4.9873918 (nsec) Hodoscope 2 has 1 hits. Hodoscope[10] 43.383883 (nsec) Drift Chamber 1 has 84 hits. Layer[0] : time 6.6717581 (nsec) --- local (x,y) 31.098272, 1.1442509 Layer[0] : time 6.6719487 (nsec) --- local (x,y) 31.099137, 1.1443031 Layer[0] : time 6.6721393 (nsec) --- local (x,y) 31.100001, 1.1443556 Layer[0] : time 6.67233 (nsec) --- local (x,y) 31.100865, 1.1444082 Layer[0] : time 6.7051084 (nsec) --- local (x,y) 35.471796, 8.6306033 Layer[0] : time 6.7055409 (nsec) --- local (x,y) 35.518043, 8.6729669 Layer[0] : time 6.7059734 (nsec) --- local (x,y) 35.564452, 8.7152199 Layer[0] : time 6.7064058 (nsec) --- local (x,y) 35.607625, 8.7603672 Layer[0] : time 6.8436056 (nsec) --- local (x,y) 54.52506, 24.874707 Layer[0] : time 6.8455981 (nsec) --- local (x,y) 54.892583, 24.956695 Layer[0] : time 6.8475908 (nsec) --- local (x,y) 55.252123, 25.064509 Layer[0] : time 6.8447052 (nsec) --- local (x,y) 54.496283, 24.91133 Layer[0] : time 6.8449406 (nsec) --- local (x,y) 54.500695, 24.917408 Layer[0] : time 6.8452021 (nsec) --- local (x,y) 54.508932, 24.919108 Layer[0] : time 6.8454729 (nsec) --- local (x,y) 54.516375, 24.922746 Layer[0] : time 6.8457417 (nsec) --- local (x,y) 54.52432, 24.9255 Layer[0] : time 6.846005 (nsec) --- local (x,y) 54.532122, 24.928242 Layer[0] : time 6.8462657 (nsec) --- local (x,y) 54.539709, 24.928818 Layer[0] : time 6.8465327 (nsec) --- local (x,y) 54.547201, 24.931998 Layer[0] : time 6.8468034 (nsec) --- local (x,y) 54.555489, 24.93171 Layer[0] : time 6.8470617 (nsec) --- local (x,y) 54.563296, 24.932083 Layer[0] : time 6.8473305 (nsec) --- local (x,y) 54.570985, 24.933461 Layer[0] : time 6.8476939 (nsec) --- local (x,y) 54.576094, 24.925591 Layer[0] : time 6.8478196 (nsec) --- local (x,y) 54.578458, 24.92356 Layer[0] : time 6.8479356 (nsec) --- local (x,y) 54.580158, 24.922026 Layer[0] : time 6.8480591 (nsec) --- local (x,y) 54.582409, 24.920718 Layer[0] : time 6.8481846 (nsec) --- local (x,y) 54.584651, 24.919214 Layer[0] : time 6.8483092 (nsec) --- local (x,y) 54.585934, 24.916666 Layer[0] : time 6.8484346 (nsec) --- local (x,y) 54.586557, 24.913983 Layer[0] : time 6.8485621 (nsec) --- local (x,y) 54.588111, 24.912294 Layer[0] : time 6.8486878 (nsec) --- local (x,y) 54.590182, 24.909883 Layer[0] : time 6.8488107 (nsec) --- local (x,y) 54.591275, 24.907233 Layer[0] : time 6.8489387 (nsec) --- local (x,y) 54.591459, 24.905787 Layer[0] : time 6.8490656 (nsec) --- local (x,y) 54.592238, 24.902916 Layer[0] : time 6.8491848 (nsec) --- local (x,y) 54.592217, 24.899898 Layer[0] : time 6.8493139 (nsec) --- local (x,y) 54.59316, 24.897012 Layer[0] : time 6.8494378 (nsec) --- local (x,y) 54.595079, 24.894412 Layer[0] : time 6.8495704 (nsec) --- local (x,y) 54.597199, 24.891807 Layer[0] : time 6.8496963 (nsec) --- local (x,y) 54.59963, 24.889724 Layer[0] : time 6.8498286 (nsec) --- local (x,y) 54.601883, 24.887458 Layer[0] : time 6.849949 (nsec) --- local (x,y) 54.604578, 24.886069 Layer[0] : time 6.8500812 (nsec) --- local (x,y) 54.607217, 24.884727 Layer[0] : time 6.8502058 (nsec) --- local (x,y) 54.610007, 24.883763 Layer[0] : time 6.8503346 (nsec) --- local (x,y) 54.612004, 24.88196 Layer[0] : time 6.8504678 (nsec) --- local (x,y) 54.614553, 24.880963 Layer[0] : time 6.8506009 (nsec) --- local (x,y) 54.616659, 24.8795 Layer[0] : time 6.8507311 (nsec) --- local (x,y) 54.616372, 24.878151 Layer[0] : time 6.8508612 (nsec) --- local (x,y) 54.615247, 24.876698 Layer[0] : time 6.8509939 (nsec) --- local (x,y) 54.613639, 24.874877 Layer[0] : time 6.8511361 (nsec) --- local (x,y) 54.611243, 24.875094 Layer[0] : time 6.851292 (nsec) --- local (x,y) 54.610212, 24.873563 Layer[0] : time 6.8514193 (nsec) --- local (x,y) 54.608719, 24.873518 Layer[0] : time 6.8515802 (nsec) --- local (x,y) 54.610538, 24.875021 Layer[0] : time 6.8517379 (nsec) --- local (x,y) 54.612357, 24.875728 Layer[0] : time 6.8518978 (nsec) --- local (x,y) 54.611997, 24.876294 Layer[0] : time 6.8520544 (nsec) --- local (x,y) 54.611431, 24.878942 Layer[0] : time 6.8522098 (nsec) --- local (x,y) 54.611585, 24.881527 Layer[0] : time 6.8523831 (nsec) --- local (x,y) 54.611003, 24.884845 Layer[0] : time 6.8525611 (nsec) --- local (x,y) 54.610202, 24.887477 Layer[0] : time 6.8527041 (nsec) --- local (x,y) 54.611194, 24.888053 Layer[0] : time 6.8528718 (nsec) --- local (x,y) 54.614267, 24.888096 Layer[0] : time 6.8530383 (nsec) --- local (x,y) 54.616141, 24.89042 Layer[0] : time 6.8532233 (nsec) --- local (x,y) 54.615715, 24.893681 Layer[0] : time 6.8533777 (nsec) --- local (x,y) 54.615014, 24.895766 Layer[0] : time 6.8535644 (nsec) --- local (x,y) 54.616716, 24.895571 Layer[0] : time 6.8537576 (nsec) --- local (x,y) 54.61499, 24.893443 Layer[0] : time 6.8539321 (nsec) --- local (x,y) 54.614375, 24.891178 Layer[0] : time 6.8541293 (nsec) --- local (x,y) 54.614297, 24.888126 Layer[1] : time 8.3397683 (nsec) --- local (x,y) 38.627511, 1.4919031 Layer[1] : time 8.3399589 (nsec) --- local (x,y) 38.628369, 1.4919205 Layer[1] : time 8.3401495 (nsec) --- local (x,y) 38.629227, 1.4919378 Layer[1] : time 8.3403402 (nsec) --- local (x,y) 38.630086, 1.4919545 Layer[2] : time 10.007785 (nsec) --- local (x,y) 46.259198, 0.82475697 Layer[2] : time 10.007976 (nsec) --- local (x,y) 46.260071, 0.82467883 Layer[2] : time 10.008166 (nsec) --- local (x,y) 46.260943, 0.82460173 Layer[2] : time 10.008357 (nsec) --- local (x,y) 46.261816, 0.82452432 Layer[3] : time 11.675802 (nsec) --- local (x,y) 53.885026, -0.029880638 Layer[3] : time 11.675993 (nsec) --- local (x,y) 53.885889, -0.030023434 Layer[3] : time 11.676183 (nsec) --- local (x,y) 53.886752, -0.030165877 Layer[3] : time 11.676374 (nsec) --- local (x,y) 53.887615, -0.030307756 Layer[4] : time 13.343805 (nsec) --- local (x,y) 61.126751, -1.4344922 Layer[4] : time 13.343995 (nsec) --- local (x,y) 61.12755, -1.434655 Layer[4] : time 13.344186 (nsec) --- local (x,y) 61.12835, -1.4348186 Layer[4] : time 13.344376 (nsec) --- local (x,y) 61.129149, -1.434982 Drift Chamber 2 has 28 hits. Layer[0] : time 35.041609 (nsec) --- local (x,y) -54.363271, -25.882207 Layer[0] : time 35.0418 (nsec) --- local (x,y) -54.367073, -25.882547 Layer[0] : time 35.041991 (nsec) --- local (x,y) -54.370874, -25.882888 Layer[0] : time 35.042182 (nsec) --- local (x,y) -54.374676, -25.883229 Layer[0] : time 35.546702 (nsec) --- local (x,y) -63.923122, 261.14185 Layer[0] : time 35.546996 (nsec) --- local (x,y) -63.96867, 261.17482 Layer[0] : time 35.547291 (nsec) --- local (x,y) -64.014772, 261.20742 Layer[0] : time 35.547585 (nsec) --- local (x,y) -64.060683, 261.24122 Layer[1] : time 36.713219 (nsec) --- local (x,y) -87.966926, -28.738865 Layer[1] : time 36.71341 (nsec) --- local (x,y) -87.970801, -28.739172 Layer[1] : time 36.713601 (nsec) --- local (x,y) -87.974674, -28.739478 Layer[1] : time 36.713792 (nsec) --- local (x,y) -87.978548, -28.739781 Layer[2] : time 38.384921 (nsec) --- local (x,y) -121.98474, -31.492843 Layer[2] : time 38.385112 (nsec) --- local (x,y) -121.98865, -31.493161 Layer[2] : time 38.385303 (nsec) --- local (x,y) -121.99256, -31.493479 Layer[2] : time 38.385494 (nsec) --- local (x,y) -121.99647, -31.493797 Layer[3] : time 40.056663 (nsec) --- local (x,y) -156.19136, -34.077018 Layer[3] : time 40.056854 (nsec) --- local (x,y) -156.19535, -34.077202 Layer[3] : time 40.057045 (nsec) --- local (x,y) -156.19934, -34.077386 Layer[3] : time 40.057236 (nsec) --- local (x,y) -156.20333, -34.077572 Layer[4] : time 41.728515 (nsec) --- local (x,y) -190.93352, -35.759692 Layer[4] : time 41.728706 (nsec) --- local (x,y) -190.93748, -35.759919 Layer[4] : time 41.728897 (nsec) --- local (x,y) -190.94144, -35.760147 Layer[4] : time 41.729088 (nsec) --- local (x,y) -190.94541, -35.760375 Layer[4] : time 41.995686 (nsec) --- local (x,y) -91.763031, -150.39544 Layer[4] : time 41.995917 (nsec) --- local (x,y) -91.765818, -150.41983 Layer[4] : time 41.996148 (nsec) --- local (x,y) -91.769065, -150.44367 Layer[4] : time 41.996379 (nsec) --- local (x,y) -91.773198, -150.46739 EM Calorimeter has 7 hits. Total Edep is 970.19374 (MeV) Hadron Calorimeter has 0 hits. Total Edep is 0 (MeV) G4VisManager: Using G4TrajectoryDrawByCharge as default trajectory model. See commands in /vis/modeling/trajectories/ for other options. Idle> exit Graphics systems deleted. Visualization Manager deleting...