Convolution quadrature (CQ) methods have enjoyed tremendous interest in recent years as an efficient tool for solving time-domain wave problems in unbounded domains via boundary integral equation techniques. In this paper we consider CQ type formulations for the parallel space-time evaluation of multistep or stiffly accurate Runge--Kutta rules for the wave equation. In particular, we decouple the number of Laplace domain solves from the number of time steps. This allows us to overresolve in the Laplace domain by computing more Laplace domain solutions than there are time steps. We use techniques from complex approximation theory to analyze the error of the CQ approximation of the underlying time-stepping rule when overresolving in the Lapla...
International audienceThanks to the use of the Cagniard–De Hoop method, we derive an analytic soluti...
We consider the Laplace transform filtering integration scheme applied to the shallow water equation...
The Helmholtz equation is notoriously difficult to solve with standard numerical methods, increasing...
We investigate high-order Convolution Quadratures methods for the solution of the wave equation in u...
This work addresses the question of the efficient numerical solution of time-domain boundary integra...
We introduce a new "convolution spline'' temporal approximation of time domain boundary integral equ...
An investigation of high order Convolution Quadratures (CQ) methods for the solution of the wave equ...
A coercivity property of temporal convolution operators is an essential tool in the analysis of time...
Abstract. In this talk we will discuss the efficient numerical solution of time dependent acoustic s...
In this dissertation we describe a coordinate scaling technique for the numerical approximation of ...
AbstractLinear hyperbolic partial differential equations in a homogeneous medium, e.g., the wave equ...
Many important physical applications are governed by the wave equation. The formulation as time doma...
This paper is concerned with the numerical solution of the wave equation in an unbounded domain. Pro...
Efficient time stepping algorithms are crucial for accurate long time simulations of nonlinear waves...
International audiencePopular finite difference numerical schemes for the resolution of the one-dime...
International audienceThanks to the use of the Cagniard–De Hoop method, we derive an analytic soluti...
We consider the Laplace transform filtering integration scheme applied to the shallow water equation...
The Helmholtz equation is notoriously difficult to solve with standard numerical methods, increasing...
We investigate high-order Convolution Quadratures methods for the solution of the wave equation in u...
This work addresses the question of the efficient numerical solution of time-domain boundary integra...
We introduce a new "convolution spline'' temporal approximation of time domain boundary integral equ...
An investigation of high order Convolution Quadratures (CQ) methods for the solution of the wave equ...
A coercivity property of temporal convolution operators is an essential tool in the analysis of time...
Abstract. In this talk we will discuss the efficient numerical solution of time dependent acoustic s...
In this dissertation we describe a coordinate scaling technique for the numerical approximation of ...
AbstractLinear hyperbolic partial differential equations in a homogeneous medium, e.g., the wave equ...
Many important physical applications are governed by the wave equation. The formulation as time doma...
This paper is concerned with the numerical solution of the wave equation in an unbounded domain. Pro...
Efficient time stepping algorithms are crucial for accurate long time simulations of nonlinear waves...
International audiencePopular finite difference numerical schemes for the resolution of the one-dime...
International audienceThanks to the use of the Cagniard–De Hoop method, we derive an analytic soluti...
We consider the Laplace transform filtering integration scheme applied to the shallow water equation...
The Helmholtz equation is notoriously difficult to solve with standard numerical methods, increasing...