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The Virtual MonteCarlo

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Title: The Virtual MonteCarlo


1
The Virtual MonteCarlo
  • D.Adamova2, V.Berejnoi1, R.Brun1, F.Carminati1,
    A.Fassó1, E.Futo1, I.Gonzalez3, I.Hrivnacova4,
    A.Morsch1
  • 1CERN, Geneva 2NPI, Rez 3IFCA, Cantabria 4IPN,
    Orsay
  • For the ALICE Collaboration
  • Presented by I. Hrivnacova
  • Conference forComputing in High Energy and
    Nuclear Physics
  • La Jolla, 27 March 2003

2
Outline
  • Interfaces
  • Available MCs
  • Examples
  • Distribution
  • Future

3
The VMC Concept
  • The Virtual MonteCarlo (VMC) has been developed
    in order to
  • Run the same user application with all supported
    transport Monte Carlos
  • Run different transport Monte Carlo programs
    without changing the user code and therefore the
    geometry definition, the detector response
    simulation, or input and output formats
  • VMC decouples the dependence of a user code from
    a concrete MC

4
VMC Concept
User Code
VMC
Geant3
Input
Geant4
Particles Hits
Geant3 VMC
Fluka
Geant4 VMC
Output
Fluka VMC
5
Virtual Monte Carlo
6
Interfaces (1)
Virtual MC
  • TVirtualMC
  • Interface to the Monte Carlo program
  • Generalization of Geant3 functions for definition
    of simulation task
  • Provides methods for definition of geometry and
    physics setup for access to tracked particle
    properties during stepping for run control
  • Implementations
  • TGeant3, TGeant4, TFluka (coming
    soon)
  • Are provided for the user

Methods For Building Accessing Geometry
Methods For Building Accessing Materials
Methods For Setting Physics
Methods For Accessing Tracked Particle During
Stepping
Methods For Run Control
7
Interfaces (2)
Virtual MC Application
  • TVirtualMCApplication
  • Interface to a user application
  • Defines user actions at each stage of a
    simulation run
  • Mandatory
  • Implementation has to be done by a user

ConstructGeometry InitGeometry GeneratePrimaries
BeginEvent BeginPrimary PreTrack Stepping PostTrac
k FinishPrimary FinishEvent
8
Interfaces (3)
  • TVirtualMCStack
  • Interface to a user defined particles stack
  • Mandatory
  • User can use the concrete stack classes provided
    in the examples or implement their own stack
    class
  • TVirtualMCDecayer
  • Interface to an external decayer
  • Eg. Pythia6
  • Optional

9
Use of VMCGeometry Construction
void MyMCApplicationConstruct Geometry()
Double_t trackerTube3 trackerTube0 0.
trackerTube1 60. trackerTube2 50.
gMC-gtGsvolu("TRTU", "TUBE", fImedAl,
trackerTube, 3) Double_t posX -100.
Double_t posY 0. Double_t posZ 0.
gMC-gtGspos("TRTU", 1 , "EXPH", posX, posY, posZ,
0, "ONLY")
User MC Application
ConstructGeometry InitGeometry GeneratePrimaries
BeginEvent BeginPrimary PreTrack Stepping PostTrac
k FinishPrimary FinishEvent
  • Geometry is defined by calls to TVirtualMC
    interface

10
Use of VMCPrimary Particles
void MyMCApplicationGeneratePrimaries()
// Define particle properties // PDG
encoding // position vx, vy, vz, vt //
momentum px py, pz, e // // Add particle
to MC stack gMC-gtGetStack()
-gtSetTrack(toBeDone, -1, pdg, px, py, pz, e,
vx, vy, vz, t, )
User MC Application
ConstructGeometry InitGeometry GeneratePrimaries
BeginEvent BeginPrimary PreTrack Stepping PostTrac
k FinishPrimary FinishEvent
  • Primary particles are defined by calls to the
    TVirtualMCStack interface

11
Use of VMCHits Production
void MyMCApplication Stepping() // Get
track position Double_t x, y, z
gMC-gtTrackPosition(x, y, z) // Get energy
deposit Double_t edep gMC-gtEdep() //
Create user hit mySD-gtAddHit(x, y, z, edep)
User MC Application
ConstructGeometry InitGeometry GeneratePrimaries
BeginEvent BeginPrimary PreTrack Stepping PostTrac
k FinishPrimary FinishEvent
  • The user stepping function is called by MC at
    each step
  • User gets the properties of the tracked particle
    by calls to TVirtualMC and saves them in their
    own hits objects

12
Available MCs
  • Geant3, Geant4
  • Geant3 VMC and Geant4 VMC in production
  • Fluka
  • Fluka VMC in development

13
Available MCsGeant3 VMC
  • Provided within a single package together with
    Geant321 (FORTRAN)
  • Straightforward implementation
  • VirtualMC was largely inspired by Geant3
  • Geant3 Geometry Browser
  • Provided within TGeant3
  • http//alisoft.cern.ch/ people/morsch/Geant3GUI.ht
    ml

14
Available MCsGeant4 VMC (1)
  • Provided within a package - geant4_vmc
  • Requires Geant4 installation
  • Access to Geant4
  • Switching between Root UI and Geant4 UI
  • Geant4 classes are not processed by CINT G4
    objects are not accessible from the Root UI
  • Use of G3toG4
  • TVirtualMC has been inspired by Geant3
  • An effort has been made to minimize the
    limitations of the G3toG4 tool in Geant4 4.0
  • Support for reflections
  • Limited support for MANY volume positions

15
Available MCsGeant4 VMC (2)
  • Geant4 VMC extensions
  • Geant4 VMC Geometry Browser
  • Analogy to Geant3 Geometry browser
  • Geometry XML Convertor
  • Enables to export Geant4 geometry to XML (AGDD)
    and then to browse and visualize using GraXML
  • More on GraXML in the presentation
  • GraXML Modular Geometric Modeller (J.
    Hrivnac)

16
Available MCsFluka VMC
  • In development by the ALICE collaboration and
    FLUKA team
  • TFluka in AliRoot
  • Implemented
  • Functions for building/accessing geometry
  • Use of Geant4 VMC Flugg
  • Functions for accessing tracked particle during
    stepping
  • Recording particles in VMC stack
  • Functions for run management
  • To be done
  • Functions for setting physics
  • External decayer

17
Examples
  • 3 examples provided in geant4_vmc
  • In spite of being provided within Geant4 VMC,
    they are built independently and do not require
    Geant4 installation in case a user wants to run
    them with Geant3 only
  • Geant4 novice examples N01, N02 and N03 rewritten
    with use of Virtual Monte Carlo
  • Implement MC Application and MC Stack
  • All examples are executed in the same way
  • cd geant4_vmc/examples/E0n
  • root
  • root0 .x run_g3.C or run_g4.C

18
  • // Load basic libraries
  • gROOT-gtLoadMacro(basiclibs.C)
  • basiclibs()
  • // Load this example library
  • gSystem-gtLoad("libexample01")
  • // MC application
  • Ex01MCApplication appl
  • new Ex01MCApplication("Example01", "The
    example01 MC application")

E01 run_g3.C run_g4.C
// Load Geant3 libraries gROOT-gtLoadMacro(g3libs
.C) g3libs()
// Load Geant4 libraries gROOT-gtLoadMacro(g4libs
.C) g4libs()
appl-gtInitMC("g3Config.C")
appl-gtInitMC("g4Config.C")
19
E01 g3Config.C g4Config.C
void Config() new TGeant3("C Interface
to Geant3")
void Config()

// RunConfiguration for Geant4
TG4RunConfiguration runConfiguration new
TG4RunConfiguration() // Geant4 VMC
new TGeant4("TGeant4", "The Geant4 Monte Carlo",
runConfiguration)
20
ExamplesAliRoot
  • AliRoot Framework
  • Integrates simulation, reconstruction and
    analysis software for the ALICE experiment
  • Simulation based on Virtual Monte Carlo
  • A complex example of VMC usage
  • No MC specific code in user code
  • PPR production with Geant3
  • More on AliRoot in the presentations
  • The AliRoot Framework, status and perspectives
    (F.Carminati)
  • Simulation in ALICE (A. Morsch)
  • ALICE experience with Geant4 (I. Gonzalez)

21
AliRoot Geometry
Dimuon Arm
22
AliRoot Hits Production
Geant3
Geant4
23
VMC Future (1)
  • Integration of the new Root geometrical modeller
    (TGeo) in VMC in progress
  • Will then be able to define MC geometry directly
    via TGeo
  • Geant3, Fluka
  • Replacement of the native geometry with TGeo
    inside the program itself
  • Geant3
  • Already operational, close to completion
  • Production release in coming weeks
  • Fluka
  • Work is ongoing

24
VMC Future (2)
  • Geant4
  • Discussions about using the Root geometry
    modeller through an abstract interface to Geant4
    geometry have been started
  • RootToG4 converter
  • Converter from Root geometry to Geant4 native
    geometry
  • Already operational, close to completion
  • Production release will follow the release of the
    new Geant3 version
  • More on TGeo in the presentation
  • A Geometrical Modeller for HEP (A. Gheata)

25
Distribution
  • ROOT CVS server
  • mc core package (interfaces), in Root
  • geant3, geant4_vmc
  • 2 independent modules (parallel to root)
  • cvs -d pservercvs_at_root.cern.ch/user/cvs co P
    geant3
  • cvs -d pservercvs_at_root.cern.ch/user/cvs co P
    geant4_vmc
  • ROOT Web
  • http//root.cern.ch/root/vmc/VirtualMC.html
  • Distribution of sources
  • geant321_vmc.version.tar.gz
  • geant4_vmc.version.tar.gz

26
Summary
  • VMC allows the user to run different transport
    MonteCarlos from the same user code
  • On the menu today Geant3, Geant4
  • Coming soon Fluka
  • VMC available from
  • http//root.cern.ch/root/vmc/VirtualMC.html
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