For the propagation of elastic waves in unbounded domains, absorbing boundary conditions (ABCs) at the fictitious numerical boundaries have been proposed. In this paper we focus on both first-and second-order ABCs in the framework of variational (weak) approximations, like those stemming from Galerkin method (or its variants) for finite element or spectral approximations [1]. In particular, we recover first order conditions as natural (or Neumann) conditions, whereas we propose a penalty residual method for the treatment of second order ABCs. The time discretization is based on implicit backward finite differences, whereas we use spectral Legendre collocation methods set in a variational form for the spatial discretization (treatment of fin...
This paper introduces an effective way to equip the standard finite element method (FEM) for the sol...
The presence of wave motion is the defining feature in many fields of application,such as electro-ma...
International audienceWe present a discontinuous Galerkin finite-element method (DG-FEM) formulation...
We study wave transmission through infinite media. From the computational point of view, an infinite...
For the propagation of elastic waves in unbounded domains, absorbing boundary conditions at the fic...
International audienceThis monograph presents numerical methods for solving transient wave equations...
In recent years there has been an increased attention to the accurate simulation of wave propagation...
Numerical computation of wave propagation in a large domain usually requires significant computation...
The subject of the paper is the study of some nonreflecting and reflecting boundary conditions for t...
High-order absorbing boundary conditions (ABC) and perfectly matched layers (PML) are two powerful m...
In this work we develop a numerical simulator for the propagation of elastic waves by solving the on...
Wave propagation problems can be modeled by partial differential equations. In this thesis, we study...
We explore a novel avenue for generating absorbing boundary conditions for wave problems. The key pa...
During my PhD, I have worked on the construction of absorbing boundary conditions (ABCs) designed fo...
This paper introduces an effective way to equip the standard finite element method (FEM) for the sol...
The presence of wave motion is the defining feature in many fields of application,such as electro-ma...
International audienceWe present a discontinuous Galerkin finite-element method (DG-FEM) formulation...
We study wave transmission through infinite media. From the computational point of view, an infinite...
For the propagation of elastic waves in unbounded domains, absorbing boundary conditions at the fic...
International audienceThis monograph presents numerical methods for solving transient wave equations...
In recent years there has been an increased attention to the accurate simulation of wave propagation...
Numerical computation of wave propagation in a large domain usually requires significant computation...
The subject of the paper is the study of some nonreflecting and reflecting boundary conditions for t...
High-order absorbing boundary conditions (ABC) and perfectly matched layers (PML) are two powerful m...
In this work we develop a numerical simulator for the propagation of elastic waves by solving the on...
Wave propagation problems can be modeled by partial differential equations. In this thesis, we study...
We explore a novel avenue for generating absorbing boundary conditions for wave problems. The key pa...
During my PhD, I have worked on the construction of absorbing boundary conditions (ABCs) designed fo...
This paper introduces an effective way to equip the standard finite element method (FEM) for the sol...
The presence of wave motion is the defining feature in many fields of application,such as electro-ma...
International audienceWe present a discontinuous Galerkin finite-element method (DG-FEM) formulation...