This paper presents the development and implementation of a Meshless two-phase incompressible fluid flow solver and its acceleration using the graphics processing unit (GPU). The solver is formulated as a Localized Radial-Basis Function Collocation Meshless Method and the interface of the two-phase flow is captured using an implementation of the Level-Set method. The Compute Unified Device Architecture (CUDA) language for general-purpose computing on the CPU is used to accelerate the solver. Through the combined use of the LRC Meshless method and GPU acceleration this paper seeks to address the issue of robustness and speed in computational fluid dynamics. Traditional mesh-based methods require extensive and time-consuming user input for th...
A graphics processing unit (GPU) is utilized to apply the direct-forcing immersed boundary method. T...
This paper presents GPU parallelization for a computational fluid dynamics solver which works on a m...
The study was undertaken as part of a larger effort to establish a common computational fluid dynami...
This paper presents the development and implementation of a Meshless two-phase incompressible fluid ...
This paper presents the development and implementation of a Meshless twophase incompressible fluid f...
This project presents the development and implementation of a GPU-accelerated meshless two-phase inc...
A graphics processing unit (GPU) -accelerated meshless method is presented for solving two-dimension...
Computational fluid dynamics has seen a surge of popularity as a tool for visual effects animators o...
The use of graphics hardware for general purpose computations allows scientists to enormously speed ...
Real-time fluid engineering simulations require significant computational power and high-resolution ...
We present parallelization of single and two phase flow CFD solvers on a graphics processing unit (G...
A graphic processing unit (GPU) implementation of a meshless method for solving compressible flow pr...
We present a fully multi-GPU-based double-precision solver for the three-dimensional two-phase incom...
DoctorComputational methods for GPU-accelerated solutions of incompressible and compressible Navier-...
Key words: graphics processing units, unstructured finite volume method, computational fluid dynam...
A graphics processing unit (GPU) is utilized to apply the direct-forcing immersed boundary method. T...
This paper presents GPU parallelization for a computational fluid dynamics solver which works on a m...
The study was undertaken as part of a larger effort to establish a common computational fluid dynami...
This paper presents the development and implementation of a Meshless two-phase incompressible fluid ...
This paper presents the development and implementation of a Meshless twophase incompressible fluid f...
This project presents the development and implementation of a GPU-accelerated meshless two-phase inc...
A graphics processing unit (GPU) -accelerated meshless method is presented for solving two-dimension...
Computational fluid dynamics has seen a surge of popularity as a tool for visual effects animators o...
The use of graphics hardware for general purpose computations allows scientists to enormously speed ...
Real-time fluid engineering simulations require significant computational power and high-resolution ...
We present parallelization of single and two phase flow CFD solvers on a graphics processing unit (G...
A graphic processing unit (GPU) implementation of a meshless method for solving compressible flow pr...
We present a fully multi-GPU-based double-precision solver for the three-dimensional two-phase incom...
DoctorComputational methods for GPU-accelerated solutions of incompressible and compressible Navier-...
Key words: graphics processing units, unstructured finite volume method, computational fluid dynam...
A graphics processing unit (GPU) is utilized to apply the direct-forcing immersed boundary method. T...
This paper presents GPU parallelization for a computational fluid dynamics solver which works on a m...
The study was undertaken as part of a larger effort to establish a common computational fluid dynami...