In this paper we present three-dimensional numerical simulations of electromagnetic waves. The Maxwell equations are solved by the Discontinuous Galerkin (DG) method. For achieving high performance, we exploit two levels of parallelism. The coarse grain parallelism is managed through MPI and a classical domain decomposition. The fine grain parallelism is managed with OpenCL in order to optimize the local computations on multicore processors or GPU’s. We present several numerical experiments and performance comparisons
Abstract:- Our group has employed the use of modern graphics processor units (GPUs) for the accelera...
Large-scale simulations of wave-type equations have many industrial applications, such as in oil and...
The 3D Finite-Difference Time-Domain (FDTD) method simulates structures in the time-domain using a d...
Abstract. In this paper we present three-dimensional numerical simulations of electromagnetic waves....
In this dissertation, the hardware and API architectures of GPUs are investigated, and the correspon...
In the field of electromagnetic modeling, whether it is the complex designs for engineered materials...
Nous présentons dans cette thèse des solveurs de type Galerkin Discontinu (GD) permettant de résoudr...
In this thesis, we present Discontinuous Galerkin (DG) solvers made for solving multiple electromagn...
AbstractDiscontinuous Galerkin(DG) method has been successfully used in time dependent simulations. ...
Using parallel computation can enhance the performance of numerical simulation of electromagnetic ra...
International audience— We describe CLAC (Conservation Laws Approximation on many Cores), a generic ...
We present an implementation of a Vlasov-Maxwell solver for multicore processors. The Vlas...
Waves are all around us–be it in the form of sound, electromagnetic ra-diation, water waves, or eart...
Modeling electromagnetic (EM) fields and their interaction with a complex environment is important f...
Abstract. We present an implementation of a Vlasov-Maxwell solver for multicore processors. The Vlas...
Abstract:- Our group has employed the use of modern graphics processor units (GPUs) for the accelera...
Large-scale simulations of wave-type equations have many industrial applications, such as in oil and...
The 3D Finite-Difference Time-Domain (FDTD) method simulates structures in the time-domain using a d...
Abstract. In this paper we present three-dimensional numerical simulations of electromagnetic waves....
In this dissertation, the hardware and API architectures of GPUs are investigated, and the correspon...
In the field of electromagnetic modeling, whether it is the complex designs for engineered materials...
Nous présentons dans cette thèse des solveurs de type Galerkin Discontinu (GD) permettant de résoudr...
In this thesis, we present Discontinuous Galerkin (DG) solvers made for solving multiple electromagn...
AbstractDiscontinuous Galerkin(DG) method has been successfully used in time dependent simulations. ...
Using parallel computation can enhance the performance of numerical simulation of electromagnetic ra...
International audience— We describe CLAC (Conservation Laws Approximation on many Cores), a generic ...
We present an implementation of a Vlasov-Maxwell solver for multicore processors. The Vlas...
Waves are all around us–be it in the form of sound, electromagnetic ra-diation, water waves, or eart...
Modeling electromagnetic (EM) fields and their interaction with a complex environment is important f...
Abstract. We present an implementation of a Vlasov-Maxwell solver for multicore processors. The Vlas...
Abstract:- Our group has employed the use of modern graphics processor units (GPUs) for the accelera...
Large-scale simulations of wave-type equations have many industrial applications, such as in oil and...
The 3D Finite-Difference Time-Domain (FDTD) method simulates structures in the time-domain using a d...