AbstractTo solve the time-dependent wave equation in an infinite two (three) dimensional domain a circular (spherical) artificial boundary is introduced to restrict the computational domain. To determine the nonreflecting boundary we solve the exterior Dirichlet problem which involves the inverse Fourier transform. The truncation of the continued fraction representation of the ratio of Hankel function, that appear in the inverse Fourier transform, provides a stable and numerically accurate approximation. Consequently, there is a sequence of boundary conditions in both two and three dimensions that are new. Furthermore, only the first derivatives in space and time appear and the coefficients are updated in a simple way from the previous time...
We construct global artificial boundary conditions (ABCs) for the numerical sim-ulation of wave proc...
AbstractWe find low order approximations to the spherical nonreflecting boundary kernel for the wave...
Recently introduced non-reflecting boundary conditions are numerically exact: the solution on a give...
this paper, we couple fast nonreflecting boundary conditions, developed in [3] for spherical and cyl...
AbstractTo solve the Helmholtz equation in an infinite three-dimensional domain a spherical artifici...
Abstract. We present a systematic approach to the computation of exact nonreflecting bound-ary condi...
An exact nonreflecting boundary condition is derived for the time dependent elastic wave equation in...
Abstract: We propose artificial boundary conditions for the wave equation considered outsi...
Summary: When solving the wave equation in infinite regions using finite ele-ment methods, the domai...
Abstract. This paper is concerned with fast and accurate computation of exterior wave equations trun...
The numerical solution of the time dependent wave equation in an unbounded domain generally leads to...
ABSTRACTWhen modeling wave propagation, truncation of the computational domain to a manageable size ...
A modied version of an exact Non-re ecting Boundary Condition (NRBC) rst derived by Grote and Kelle...
Abstract. The numerical solution of the time dependent wave equation in an unbounded domain generall...
International audienceWe find low order approximations to the spherical nonreflecting boundary kerne...
We construct global artificial boundary conditions (ABCs) for the numerical sim-ulation of wave proc...
AbstractWe find low order approximations to the spherical nonreflecting boundary kernel for the wave...
Recently introduced non-reflecting boundary conditions are numerically exact: the solution on a give...
this paper, we couple fast nonreflecting boundary conditions, developed in [3] for spherical and cyl...
AbstractTo solve the Helmholtz equation in an infinite three-dimensional domain a spherical artifici...
Abstract. We present a systematic approach to the computation of exact nonreflecting bound-ary condi...
An exact nonreflecting boundary condition is derived for the time dependent elastic wave equation in...
Abstract: We propose artificial boundary conditions for the wave equation considered outsi...
Summary: When solving the wave equation in infinite regions using finite ele-ment methods, the domai...
Abstract. This paper is concerned with fast and accurate computation of exterior wave equations trun...
The numerical solution of the time dependent wave equation in an unbounded domain generally leads to...
ABSTRACTWhen modeling wave propagation, truncation of the computational domain to a manageable size ...
A modied version of an exact Non-re ecting Boundary Condition (NRBC) rst derived by Grote and Kelle...
Abstract. The numerical solution of the time dependent wave equation in an unbounded domain generall...
International audienceWe find low order approximations to the spherical nonreflecting boundary kerne...
We construct global artificial boundary conditions (ABCs) for the numerical sim-ulation of wave proc...
AbstractWe find low order approximations to the spherical nonreflecting boundary kernel for the wave...
Recently introduced non-reflecting boundary conditions are numerically exact: the solution on a give...