A new approach to derive transparent boundary conditions (TBCs) for dispersive wave, Schrödinger, heat, and drift-diffusion equations is presented. It relies on the pole condition and distinguishes between physically reasonable and unreasonable solutions by the location of the singularities of the Laplace transform of the exterior solution. Here the Laplace transform is taken with respect to a generalized radial variable. To obtain a numerical algorithm, a Möbius transform is applied to map the Laplace transform onto the unit disc. In the transformed coordinate the solution is expanded into a power series. Finally, equations for the coefficients of the power series are derived. These are coupled to the equation in the interior and yield tra...
The numerical solution of the time dependent wave equation in an unbounded domain generally leads to...
AbstractThe paper presents a construction scheme of deriving transparent, i.e., reflection-free, bou...
International audienceIn this review article we discuss different techniques to solve numerically th...
A new approach to derive transparent boundary conditions (TBCs) for dispersive wave, Schrödinger, he...
Abstract. The pole condition approach for deriving transparent boundary conditions is ex-tended to t...
The pole condition approach for deriving transparent boundary conditions is extended to the time-dep...
A new approach to derive transparent boundary conditions (TBCs) for wave, Schr¨odinger and drift-di...
Abstract: Transparent Boundary Conditions (TBCs) for 2D mode of Maxwell’s equations in d...
Abstract: The preprint is devoted to constructing of Transparent Boundary Conditions (TBC)...
Abstract: Discrete transparent boundary conditions for 2D Maxwell equations with dispersio...
This work is concerned with transparent boundary conditions (TBCs) for systems of Schrödinger-type e...
This paper is concerned with transparent boundary conditions for the one dimensional time-dependent ...
We propose transparent boundary conditions (TBCs) for the time–dependent Schrödinger equation on a c...
International audienceIn this paper, we consider artificial boundary conditions for the linearized m...
Transparent boundary conditions (TBCs) for general Schrödinger-type equations on a bounded domain ca...
The numerical solution of the time dependent wave equation in an unbounded domain generally leads to...
AbstractThe paper presents a construction scheme of deriving transparent, i.e., reflection-free, bou...
International audienceIn this review article we discuss different techniques to solve numerically th...
A new approach to derive transparent boundary conditions (TBCs) for dispersive wave, Schrödinger, he...
Abstract. The pole condition approach for deriving transparent boundary conditions is ex-tended to t...
The pole condition approach for deriving transparent boundary conditions is extended to the time-dep...
A new approach to derive transparent boundary conditions (TBCs) for wave, Schr¨odinger and drift-di...
Abstract: Transparent Boundary Conditions (TBCs) for 2D mode of Maxwell’s equations in d...
Abstract: The preprint is devoted to constructing of Transparent Boundary Conditions (TBC)...
Abstract: Discrete transparent boundary conditions for 2D Maxwell equations with dispersio...
This work is concerned with transparent boundary conditions (TBCs) for systems of Schrödinger-type e...
This paper is concerned with transparent boundary conditions for the one dimensional time-dependent ...
We propose transparent boundary conditions (TBCs) for the time–dependent Schrödinger equation on a c...
International audienceIn this paper, we consider artificial boundary conditions for the linearized m...
Transparent boundary conditions (TBCs) for general Schrödinger-type equations on a bounded domain ca...
The numerical solution of the time dependent wave equation in an unbounded domain generally leads to...
AbstractThe paper presents a construction scheme of deriving transparent, i.e., reflection-free, bou...
International audienceIn this review article we discuss different techniques to solve numerically th...