This paper considers the application of the method of boundary penalty terms ("SAT") to the numerical solution of the wave equation on complex shapes with Dirichlet boundary conditions. A theory is developed, in a semi-discrete setting, that allows the use of a Cartesian grid on complex geometries, yet maintains the order of accuracy with only a linear temporal error-bound. A numerical example, involving the solution of Maxwell's equations inside a 2-D circular wave-guide demonstrates the efficacy of this method in comparison to others (e.g. the staggered Yee scheme) - we achieve a decrease of two orders of magnitude in the level of the L2-error
A convergent second-order Cartesian grid finite difference scheme for the solution of Maxwell’s equa...
This paper presents a review of high-order and optimized finite-difference methods for numerically s...
This paper provides a unified error analysis for non-conforming space discretizations of linear wave...
The accuracy of Cartesian embedded boundary methods for the second order wave equation in general tw...
A second order accurate embedded boundary method for the two-dimensional wave equation with disconti...
This thesis provides a unified framework for the error analysis of non-conforming space discretizati...
International audienceWe present a new class of explicit marching schemes for the wave equation in c...
An estimate is derived for the error committed by the introduction of artificial boundaries and corr...
Abstract: We propose artificial boundary conditions for the wave equation considered outsi...
Introduction The problem of accurate boundary treatments has long been an obstacle to the developme...
AbstractThis paper concerns error estimates for an approximation method for solving the Dirichlet bo...
Building upon recent results obtained in [7,8,9], we describe an efficient second order, A-stable sc...
In this thesis, we use finite difference operators with the Summation-By-Partsproperty (SBP) and a w...
This paper discusses several possibilities to improve the quality of the numerical WBM solution of H...
The Helmholtz equation (Delta + K(2)n(2))u = f with a variable index of refraction n, and a suitable...
A convergent second-order Cartesian grid finite difference scheme for the solution of Maxwell’s equa...
This paper presents a review of high-order and optimized finite-difference methods for numerically s...
This paper provides a unified error analysis for non-conforming space discretizations of linear wave...
The accuracy of Cartesian embedded boundary methods for the second order wave equation in general tw...
A second order accurate embedded boundary method for the two-dimensional wave equation with disconti...
This thesis provides a unified framework for the error analysis of non-conforming space discretizati...
International audienceWe present a new class of explicit marching schemes for the wave equation in c...
An estimate is derived for the error committed by the introduction of artificial boundaries and corr...
Abstract: We propose artificial boundary conditions for the wave equation considered outsi...
Introduction The problem of accurate boundary treatments has long been an obstacle to the developme...
AbstractThis paper concerns error estimates for an approximation method for solving the Dirichlet bo...
Building upon recent results obtained in [7,8,9], we describe an efficient second order, A-stable sc...
In this thesis, we use finite difference operators with the Summation-By-Partsproperty (SBP) and a w...
This paper discusses several possibilities to improve the quality of the numerical WBM solution of H...
The Helmholtz equation (Delta + K(2)n(2))u = f with a variable index of refraction n, and a suitable...
A convergent second-order Cartesian grid finite difference scheme for the solution of Maxwell’s equa...
This paper presents a review of high-order and optimized finite-difference methods for numerically s...
This paper provides a unified error analysis for non-conforming space discretizations of linear wave...