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Geant4/examples/extended/hadronic/Hadr05/README

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Diff markup

Differences between /examples/extended/hadronic/Hadr05/README (Version 11.3.0) and /examples/extended/hadronic/Hadr05/README (Version 10.0.p4)


  1 ---------------------------------------------- << 
  2                                                << 
  3      =========================================      1      =========================================================
  4      Geant4 - an Object-Oriented Toolkit for S      2      Geant4 - an Object-Oriented Toolkit for Simulation in HEP
  5      =========================================      3      =========================================================
  6                                                     4 
  7                             Hadr05             <<   5 
  8                             ------             <<   6                                  HADR05
  9                                                <<   7 
 10  How to collect energy deposition in a samplin <<   8                              W.Pokorski 
 11  How to survey energy flow.                    <<   9     (based on Hadr00 by V. Ivantchenko)
 12  Hadr05 is the hadronic equivalent of TestEm3. <<  10                        CERN, Geneva, Switzerland
 13                                                <<  11 
 14                                                <<  12 
 15  1- GEOMETRY DEFINITION                        <<  13 This example demonstrates the usage of G4GenericPhysicsList to build 
 16                                                <<  14 the concrete physics list at the run time. The code is a copy of
 17   The calorimeter is a box made of a given num <<  15 example Hadr00 with the only exception of the main file, where the
 18   A layer consists of a sequence of various ab <<  16 physics list is handled using the G4GenericPhysicsList
 19   The layer is replicated.                     <<  17 mechanism. Please refer to Hadr00 documentation for any other
 20                                                <<  18 functionality. 
 21   Parameters defining the calorimeter :        <<  19 
 22     - the number of layers,                    <<  20 The G4GenericPhysicsList class allows to build the physics list at the run
 23     - the number of absorbers within a layer,  <<  21 time in two possible ways, either by processing a macro file
 24     - the material of the absorbers,           <<  22 containing the 'physics list' or by passing a vector of 'physics
 25     - the thickness of the absorbers,          <<  23 constructors' names to the constructor of the class.
 26     - the transverse size of the calorimeter ( <<  24 
 27                                                <<  25 To run the example you can call
 28   In addition a transverse uniform magnetic fi <<  26 
 29                                                <<  27 Hadr05 hadr05.in FTFP_BERT.mac
 30   The default geometry is constructed in Detec <<  28 
 31   of the above parameters can be modified inte <<  29 where FTFP_BERT.mac is the macro file containing the 'physics list'. 
 32   defined in the DetectorMessenger class.      <<  30 
 33                                                <<  31 If you run this example by calling
 34                                                <<  32 
 35         |<----layer 0---------->|<----layer 1- <<  33 Hadr05 hadr05.in
 36         |           |           |              <<  34 
 37         ====================================== <<  35 the physics list will be constructed by using a vector of the names of
 38         ||          |           ||          |  <<  36 the different physics constructor defined in the Hard05.cc file.
 39         ||          |           ||          |  << 
 40         ||   abs 1  | abs 2     ||   abs 1  |  << 
 41         ||          |           ||          |  << 
 42         ||          |           ||          |  << 
 43  beam   ||          |           ||          |  << 
 44 ======> ||          |           ||          |  << 
 45         ||          |           ||          |  << 
 46         ||          |           ||          |  << 
 47         ||          |           ||          |  << 
 48         ||          |           ||          |  << 
 49         ||   cell 1 | cell 2    ||   cell 3 |  << 
 50         ====================================== << 
 51         ^           ^           ^           ^  << 
 52         pln1        pln2        pln3       pln << 
 53                                                << 
 54   NB. The number of absorbers and the number o << 
 55   In this case we have a unique homogeneous bl << 
 56   a bubble chamber rather than a calorimeter . << 
 57   (see the macro emtutor.mac)                  << 
 58                                                << 
 59   A function, and its associated UI command, a << 
 60   directly from a single isotope.              << 
 61                                                << 
 62   To be identified by the ThermalScattering mo << 
 63   material must have a specific name (see G4Pa << 
 64   Examples of such materials are build in Hadr << 
 65                                                << 
 66  2- PHYSICS LISTS                              << 
 67                                                << 
 68   "Full" set of physics processes are register << 
 69   objects rather than complete pre-defined G4  << 
 70   way gives more freedom to register physics.  << 
 71                                                << 
 72   Physics constructors are either constructors << 
 73   or 'local'. They include : HadronElastic, Ha << 
 74   GammaNuclear, RadioactiveDecay and Electomag << 
 75   (see geant4/source/physics_lists/constructor << 
 76                                                << 
 77   HadronElasticPhysicsHP include a model for t << 
 78   under the control of the command /testhadr/p << 
 79                                                << 
 80   GammmaNuclearPhysics is a subset of G4Bertin << 
 81                                                << 
 82   ElectromagneticPhysics is a readable version << 
 83                                                << 
 84   Several hadronic physics options are control << 
 85   To select them, see Hadr07.cc                << 
 86                                                << 
 87  3- AN EVENT : THE PRIMARY GENERATOR           << 
 88                                                << 
 89   The primary kinematic consists of a single p << 
 90   perpendicular to the input face. The type of << 
 91   set in the PrimaryGeneratorAction class, and << 
 92   G4 build-in commands of G4ParticleGun class  << 
 93   example).                                    << 
 94                                                << 
 95   In addition one can choose randomly the impa << 
 96   The corresponding interactive command is bui << 
 97                                                << 
 98   A RUN is a set of events.                    << 
 99                                                << 
100   Hadr05 computes the energy deposited per abs << 
101   the calorimeter.                             << 
102                                                << 
103  4- VISUALIZATION                              << 
104                                                << 
105   The Visualization Manager is set in the main << 
106   The initialisation of the drawing is done vi << 
107   /vis/... in the macro vis.mac. In interactiv << 
108   PreInit or Idle > /control/execute vis.mac   << 
109                                                << 
110   The default view is a longitudinal view of t << 
111                                                << 
112  5- PHYSICS DEMO                               << 
113                                                << 
114   The particle's type and the physics processe << 
115   in this example are set in PhysicsList class << 
116                                                << 
117   In addition a built-in interactive command ( << 
118   allows to activate/inactivate the processes  << 
119   Then one can well visualize the processes on << 
120   in the bubble chamber setup with a transvers << 
121                                                << 
122  6- HOW TO START ?                             << 
123                                                << 
124   - Execute Hadr05 in 'batch' mode from macro  << 
125       % Hadr05  Cu-lAr.mac                     << 
126                                                << 
127   - Execute Hadr05 in 'interactive mode' with  << 
128     % Hadr05                                   << 
129     ....                                       << 
130     Idle> type your commands. For instance:    << 
131     Idle> /control/execute vis.mac             << 
132     ....                                       << 
133     Idle> exit                                 << 
134                                                << 
135   Macros provided in this example:             << 
136   - hadr05.in: macro used in Geant4 testing    << 
137   - Fe-Sci.mac, Cu-lAr.mac, Pb-lAr.mac, W-lAr. << 
138   - Pb-lAr-em.mac : electromagnetic calorimete << 
139   - emtest.mac, emtutor.mac : to be run intera << 
140   - vis.mac: to activate visualization         << 
141                                                << 
142  7- HISTOGRAMS                                 << 
143                                                << 
144  Hadr05 can produce histograms :               << 
145   histo 1 : energy deposit in absorber 1       << 
146   histo 2 : energy deposit in absorber 2       << 
147   ...etc...........                            << 
148                                                << 
149   histo 11 : longitudinal profile of energy de << 
150   histo 12 : longitudinal profile of energy de << 
151   ...etc...........                            << 
152                                                << 
153   histo 21 : energy flow (MeV/event)           << 
154                                                << 
155   histo 22 : total energy deposited            << 
156   histo 23 : total energy leakage              << 
157   histo 24 : total energy released : Edep + El << 
158                                                << 
159   NB. Numbering scheme for histograms:         << 
160   layer     : from 1 to NbOfLayers (included)  << 
161   absorbers : from 1 to NbOfAbsor (included)   << 
162   planes    : from 1 to NbOfLayers*NbOfAbsor + << 
163                                                << 
164  One can control the binning of the histo with << 
165   /analysis/h1/set   idAbsor  nbin  Emin  Emax << 
166   where unit is the desired energy unit for th << 
167                                                << 
168   One can control the name of the histograms f << 
169   /analysis/setFileName  name  (default hadr05 << 
170                                                << 
171   It is possible to choose the format of the h << 
172   xml, csv, by using namespace in HistoManager << 
173                                                << 
174  It is also possible to print selected histogr << 
175  /analysis/h1/setAscii id                      << 
176  All selected histos will be written on a file << 
177                                                <<