The aim of the present paper is to report on our recent results for GPU accelerated simulations of compressible flows. For numerical simulation the adaptive discontinuous Galerkin method with the multidimensional bicharacteristic based evolution Galerkin operator has been used. For time discretization we have applied the explicit third order Runge-Kutta method. Evaluation of the genuinely multidimensional evolution operator has been accelerated using the GPU implementation. We have obtained a speedup up to 30 (in comparison to a single CPU core) for the calculation of the evolution Galerkin operator on a typical discretization mesh consisting of 16384 mesh cells
International audienceThis paper illustrates how GPU computing can be used to accelerate computation...
The space-time discontinuous Galerkin method allows the simulation of compressible flow in complex a...
We present a GPU accelerated nodal discontinuous Galerkin method for the solution of the three dimen...
The aim of the present paper is to report on our recent results for GPU accelerated simulations of c...
A GPU-accelerated discontinuous Galerkin (DG) method is presented for the solution of compressible f...
Abstract: In this paper the approach to simulation of unsteady fluid dynamic problems in t...
In the present work we implemented parallel version of a computational fluid dynamics code. This cod...
We explore the possibilities to accelerate simulations in computational fluid dynamics by additional...
summary:We deal with a numerical simulation of the inviscid compressible flow with the aid of the co...
DoctorComputational methods for GPU-accelerated solutions of incompressible and compressible Navier-...
Kinetic equations are used to mathematically model gas flows that are far from equilibrium due to th...
Computational Fluid Dynamics (CFD) is a useful tool that enables highly cost-effective numerical sol...
Graphical processing units (GPUs), characterized by significant computing performance, are nowadays ...
This paper presents a Graphics Processing Unit (GPU) acceleration of an iteration-based discrete vel...
In this paper, the performance of the Cyclic Reduction (CR) algorithm for solving tridiagonal system...
International audienceThis paper illustrates how GPU computing can be used to accelerate computation...
The space-time discontinuous Galerkin method allows the simulation of compressible flow in complex a...
We present a GPU accelerated nodal discontinuous Galerkin method for the solution of the three dimen...
The aim of the present paper is to report on our recent results for GPU accelerated simulations of c...
A GPU-accelerated discontinuous Galerkin (DG) method is presented for the solution of compressible f...
Abstract: In this paper the approach to simulation of unsteady fluid dynamic problems in t...
In the present work we implemented parallel version of a computational fluid dynamics code. This cod...
We explore the possibilities to accelerate simulations in computational fluid dynamics by additional...
summary:We deal with a numerical simulation of the inviscid compressible flow with the aid of the co...
DoctorComputational methods for GPU-accelerated solutions of incompressible and compressible Navier-...
Kinetic equations are used to mathematically model gas flows that are far from equilibrium due to th...
Computational Fluid Dynamics (CFD) is a useful tool that enables highly cost-effective numerical sol...
Graphical processing units (GPUs), characterized by significant computing performance, are nowadays ...
This paper presents a Graphics Processing Unit (GPU) acceleration of an iteration-based discrete vel...
In this paper, the performance of the Cyclic Reduction (CR) algorithm for solving tridiagonal system...
International audienceThis paper illustrates how GPU computing can be used to accelerate computation...
The space-time discontinuous Galerkin method allows the simulation of compressible flow in complex a...
We present a GPU accelerated nodal discontinuous Galerkin method for the solution of the three dimen...