2007 APS April Meeting
Volume 52, Number 3
Saturday–Tuesday, April 14–17, 2007;
Jacksonville, Florida
Session M9: Computational Methods in Beam Physics
3:15 PM–5:03 PM,
Sunday, April 15, 2007
Hyatt Regency Jacksonville Riverfront
Room: City Terrace 5
Sponsoring
Unit:
DPB
Chair: Joseph Bisognano, University of Wisconsin-Madison
Abstract ID: BAPS.2007.APR.M9.3
Abstract: M9.00003 : A New Approach to Adaptive Control of Multiple Scales in Plasma Simulations
4:27 PM–5:03 PM
Preview Abstract
Abstract
Author:
Yuri Omelchenko
(SciberQuest, Inc/UCSD)
A new approach to temporal refinement of kinetic
(Particle-in-Cell, Vlasov)
and fluid (MHD, two-fluid) simulations of plasmas is presented:
Discrete-Event Simulation (DES). DES adaptively distributes CPU
resources in
accordance with local time scales and enables asynchronous
integration of
inhomogeneous nonlinear systems with multiple time scales on
meshes of
arbitrary topologies. This removes computational penalties
usually incurred
in explicit codes due to the global Courant-Friedrich-Levy (CFL)
restriction
on a time-step size. DES stands apart from multiple time-stepping
algorithms
in that it requires neither selecting a global synchronization
time step nor
pre-determining a sequence of time-integration operations for
individual
parts of the system (local time increments need not bear any integer
multiple relations). Instead, elements of a mesh-distributed
solution
self-adaptively predict and synchronize their temporal
trajectories by
directly enforcing local causality (accuracy) constraints, which are
formulated in terms of incremental changes to the evolving solution.
Together with flux-conservative propagation of information, this new
paradigm ensures stable and fast asynchronous runs, where idle
computation
is automatically eliminated. DES is parallelized via a novel
Preemptive
Event Processing (PEP) technique, which automatically
synchronizes elements
with similar update rates. In this mode, events with close
execution times
are projected onto time levels, which are adaptively determined
by the
program. PEP allows reuse of standard message-passing algorithms on
distributed architectures. For optimum accuracy, DES can be
combined with
adaptive mesh refinement (AMR) techniques for structured and
unstructured
meshes. Current examples of event-driven models range from
electrostatic,
hybrid particle-in-cell plasma systems to reactive fluid dynamics
simulations. They demonstrate the superior performance of DES in
terms of
accuracy, speed and robustness.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2007.APR.M9.3