Commit 7287bf5e authored by Marcos Derós's avatar Marcos Derós

informações

parent 9ac62b98
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Simulação de um "Air Shower" utilizando Geant4.
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Geant4 - an Object-Oriented Toolkit for Simulation in HEP
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Foi utilizado como ponto de partida o Exemplo B1. A 'physics list' escolhida foi FTFP-BERT.
Example B1
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Geometricamente, trata-se de um cilindro de Ar(por enquanto com densidade e pressão constantes),
Ainda n]ao há nenhum detetor, todo o cilindro é o 'World'. Por fins de praticidade, ele possui 90m de altura.
This example demonstrates a very simple application where an energy
deposit is accounted in user actions and their associated objects
and a dose in a selected volume is calculated.
Verbose para physics list (no exampleB1.cc), event e tracking(ambos no init_vis.mac) foram adicionadas.
1- GEOMETRY DEFINITION
The geometry is constructed in the B1DetectorConstruction class.
The setup consists of a an envelope of box shape containing two
volumes: a spherical cone and a trapezoid.
Tracking de partículas utilzada foi "GetParticleByParentID" e printada ao iniciar o programa.
In this example we use some common materials materials for medical
applications. The envelope is made of water and the two inner volumes
are made from tissue and bone materials.
The materials are created with the help of the G4NistManager class,
which allows to build a material from the NIST database using their
names. All available materials can be found in the Geant4 User's Guide
for Application Developers, Appendix 10: Geant4 Materials Database.
2- PHYSICS LIST
The particle's type and the physic processes which will be available
in this example are set in the QBBC physics list. This physics list
requires data files for electromagnetic and hadronic processes.
See more on installation of the datasets in Geant4 Installation Guide,
Chapter 3.3: Note On Geant4 Datasets:
http://geant4.web.cern.ch/geant4/UserDocumentation/UsersGuides
/InstallationGuide/html/ch03s03.html
The following datasets: G4LEDATA, G4LEVELGAMMADATA, G4NEUTRONXSDATA,
G4SAIDXSDATA and G4ENSDFSTATEDATA are mandatory for this example.
In addition the build-in interactive command:
/process/(in)activate processName
allows to activate/inactivate the processes one by one.
3- ACTION INITALIZATION
A newly introduced class, B1ActionInitialization, instantiates and registers
to Geant4 kernel all user action classes.
While in sequential mode the action classes are instatiated just once,
via invoking the method:
B1ActionInitialization::Build()
in multi-threading mode the same method is invoked for each thread worker
and so all user action classes are defined thread-local.
A run action class is instantiated both thread-local
and global that's why its instance is created also in the method
B1ActionInitialization::BuildForMaster()
which is invoked only in multi-threading mode.
4- PRIMARY GENERATOR
The primary generator is defined in the B1PrimaryGeneratorAction class.
The default kinematics is a 6 MeV gamma, randomly distributed in front
of the envelope across 80% of the transverse (X,Y) envelope size.
This default setting can be changed via the Geant4 built-in commands
of the G4ParticleGun class.
5- DETECTOR RESPONSE
This example demonstrates a simple scoring implemented directly
in the user action classes. Alternative ways of scoring via Geant4 classes
can be found in the other examples.
The energy deposited is collected step by step for a selected volume
in B1SteppingAction and accumulated event by event in B1EventAction.
At end of event, the value acummulated in B1EventAction is added in B1RunAction
and summed over the whole run (see B1EventAction::EndOfevent()).
Total dose deposited is computed at B1RunAction::EndOfRunAction(),
and printed together with informations about the primary particle.
In multi-threading mode the energy accumulated in G4Accumulable objects per
workers is merged to the master in B1RunAction::EndOfRunAction() and the final
result is printed on the screen.
G4Parameter<G4double> type instead of G4double type is used for the B1RunAction
data members in order to facilitate merging of the values accumulated on workers
to the master. Currently the accumulables have to be registered to G4AccumulablesManager
and G4AccumulablesManager::Merge() has to be called from the users code. This is planned
to be further simplified with a closer integration of G4Accumulable classes in
the Geant4 kernel next year.
An example of creating and computing new units (e.g., dose) is also shown
in the class constructor.
The following paragraphs are common to all basic examples
A- VISUALISATION
The visualization manager is set via the G4VisExecutive class
in the main() function in exampleB1.cc.
The initialisation of the drawing is done via a set of /vis/ commands
in the macro vis.mac. This macro is automatically read from
the main function when the example is used in interactive running mode.
By default, vis.mac opens an OpenGL viewer (/vis/open OGL).
The user can change the initial viewer by commenting out this line
and instead uncommenting one of the other /vis/open statements, such as
HepRepFile or DAWNFILE (which produce files that can be viewed with the
HepRApp and DAWN viewers, respectively). Note that one can always
open new viewers at any time from the command line. For example, if
you already have a view in, say, an OpenGL window with a name
"viewer-0", then
/vis/open DAWNFILE
then to get the same view
/vis/viewer/copyView viewer-0
or to get the same view *plus* scene-modifications
/vis/viewer/set/all viewer-0
then to see the result
/vis/viewer/flush
The DAWNFILE, HepRepFile drivers are always available
(since they require no external libraries), but the OGL driver requires
that the Geant4 libraries have been built with the OpenGL option.
From Release 9.6 the vis.mac macro in example B1 has additional commands
that demonstrate additional functionality of the vis system, such as
displaying text, axes, scales, date, logo and shows how to change
viewpoint and style. Consider copying these to other examples or
your application. To see even more commands use help or
ls or browse the available UI commands in the Application
Developers Guide, Section 7.1.
For more information on visualization, including information on how to
install and run DAWN, OpenGL and HepRApp, see the visualization tutorials,
for example,
http://geant4.slac.stanford.edu/Presentations/vis/G4[VIS]Tutorial/G4[VIS]Tutorial.html
(where [VIS] can be replaced by DAWN, OpenGL and HepRApp)
The tracks are automatically drawn at the end of each event, accumulated
for all events and erased at the beginning of the next run.
B- USER INTERFACES
The user command interface is set via the G4UIExecutive class
in the main() function in exampleB1.cc
The selection of the user command interface is then done automatically
according to the Geant4 configuration or it can be done explicitly via
the third argument of the G4UIExecutive constructor (see exampleB4a.cc).
C- HOW TO RUN
- Execute exampleB1 in the 'interactive mode' with visualization:
% ./exampleB1
and type in the commands from run1.mac line by line:
Idle> /control/verbose 2
Idle> /tracking/verbose 1
Idle> /run/beamOn 10
Idle> ...
Idle> exit
or
Idle> /control/execute run1.mac
....
Idle> exit
- Execute exampleB1 in the 'batch' mode from macro files
(without visualization)
% ./exampleB1 run2.mac
% ./exampleB1 exampleB1.in > exampleB1.out
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