Tag: physics
Performance of FORTRAN and C GPU Extensions for a Benchmark Suite of Fourier Pseudospectral Algorithms
A comparison of PGI OpenACC, FORTRAN CUDA, and Nvidia CUDA pseudospectral methods on a single GPU and GCC FORTRAN on single and multiple CPU cores is reported
Solving the Ghost-Gluon System of Yang-Mills Theory on GPUs
We solve the ghost-gluon system of Yang-Mills theory using Graphics Processing Units (GPUs). Working in Landau gauge, we use the Dyson-Schwinger formalism for the mathematical description as this approach is well-suited to directly benefit from the computing power of the GPUs.
Relativistic Hydrodynamics on Graphic Cards
We show how to accelerate relativistic hydrodynamics simulations using graphic cards (graphic processing units, GPUs).
Opening the gate to robust quantum computing
Scientists have overcome a major hurdle facing quantum computing: how to protect quantum information from degradation by the environment while simultaneously performing computation in a solid-state quantum system.
Optimizing the multipole-to-local operator in the fast multipole method for GPU
This paper presents a number of algorithms to run the fast multipole method (FMM) on NVIDIA CUDA-capable graphical processing units. The FMM is a class of methods to compute pairwise interactions between N particles for a given error tolerance and with computational cost.
Improved tracking technique for visual measurements of ionic polymer–metal composites (IPMC) actuators using CUDA
The implementation of a real-time measurement system based on visual measurements of displacement of an actuator–cantilever is presented in this paper.
DirectCompute Lecture Series: GPU Accelerated Physics
This lecture explains how DirectCompute can be employed to create solutions simulating physical systems such as fluid and cloth systems. It also covers how to employ some of the libraries powered by DirectCompute and how to integrate these libraries into your application.
