Research Report: Manuscript CMCU-95-01, May 1995
A Space-Time Finite Element
Method for the Exterior
Acoustics Problem
Lonny L. Thompson
Computational Mechanics at Clemson University
Department of Mechanical Engineering
Clemson, South Carolina 29634-0921
Abstract
In this paper, the development of a
space-time finite element method for solution of the
transient acoustics problem in exterior domains
is discussed.
The space-time formulation for the exterior acoustics problem is
obtained from a time-discontinuous Galerkin
variational equation for coupled structural acoustics,
specialized to the case of zero normal velocities on the wet surface,
i.e., a rigid scatterer.
The formulation employs a finite computational acoustic domain
surrounding the scatterer and incorporates high-order time-dependent
non-reflecting (radiation) boundary conditions on the fluid
truncation boundary as `natural' boundary conditions in the
space-time variational equation, i.e. they are enforced weakly in
both space and time.
The result is an
algorithm for direct transient analysis of acoustic
radiation and scattering
with the desired combination of good stability and high accuracy.
The method is
especially useful for the application
of adaptive solution strategies for transient acoustics in which
unstructured space-time meshes are used to track wave fronts
propagating along space-time characteristics.
Optimal stability estimates and convergence rates are
reported together with two
representative numerical examples involving transient radiation
and scattering which illustrate the high-order accuracy
achieved by the method for the exterior acoustics problem.
Postscript file of Manuscript CMCU-95-01