Here we present the cuLGT 1 code for gauge fixing in lattice gauge field theories with graphic processing units (GPUs). Implementations for SU(3) Coulomb, Landau and maximally Abelian gauge fixing are available and the overrelaxation, stochastic relaxation and simulated annealing algorithms are supported. Performance results for single and multi-GPUs are given. PACS numbers: 11.15.Ha, 12.38.Gc 1
This paper reviews the unusual computational requirements associated to numerical simulations of La...
We present the first GPU-based conjugate gradient (CG) solver for lattice QCD with domain-wall fermi...
This paper briefly describes the physics motivations and strategies of Lattice Gauge Theory (LGT), t...
We adopt CUDA-capable Graphic Processing Units (GPUs) for Landau, Coulomb and maximally Abelian gaug...
We discuss how the steepest descent method with Fourier acceleration for Laudau gauge fixing in latt...
The starting point of any lattice QCD computation is the generation of a Markov chain of gauge field...
In this work, we consider the GPU implementation of the steepest descent method with Fourier acceler...
We discuss the CUDA approach to the simulation of pure gauge Lattice SU(2). CUDA is a hardware and s...
In this work we explore the performance of CUDA in quenched lattice SU(2) simulations. CUDA, NVIDIA ...
We explore the performance of CUDA in performing Landau gauge fixing in Lattice QCD, using the steep...
This report is devoted to Lattice QCD simulations carried out at the “Govorun” supercomputer. The ba...
Graphics Processing Units (GPUs) are being used in many areas of physics, since the performance vers...
Lattice QCD is widely considered the correct theory of the strong force and is able to make quantita...
Abstract—Computing platforms equipped with accelerators like GPUs have proven to provide great compu...
We solve the ghost-gluon system of Yang-Mills theory using Graphics Processing Units (GPUs). Working...
This paper reviews the unusual computational requirements associated to numerical simulations of La...
We present the first GPU-based conjugate gradient (CG) solver for lattice QCD with domain-wall fermi...
This paper briefly describes the physics motivations and strategies of Lattice Gauge Theory (LGT), t...
We adopt CUDA-capable Graphic Processing Units (GPUs) for Landau, Coulomb and maximally Abelian gaug...
We discuss how the steepest descent method with Fourier acceleration for Laudau gauge fixing in latt...
The starting point of any lattice QCD computation is the generation of a Markov chain of gauge field...
In this work, we consider the GPU implementation of the steepest descent method with Fourier acceler...
We discuss the CUDA approach to the simulation of pure gauge Lattice SU(2). CUDA is a hardware and s...
In this work we explore the performance of CUDA in quenched lattice SU(2) simulations. CUDA, NVIDIA ...
We explore the performance of CUDA in performing Landau gauge fixing in Lattice QCD, using the steep...
This report is devoted to Lattice QCD simulations carried out at the “Govorun” supercomputer. The ba...
Graphics Processing Units (GPUs) are being used in many areas of physics, since the performance vers...
Lattice QCD is widely considered the correct theory of the strong force and is able to make quantita...
Abstract—Computing platforms equipped with accelerators like GPUs have proven to provide great compu...
We solve the ghost-gluon system of Yang-Mills theory using Graphics Processing Units (GPUs). Working...
This paper reviews the unusual computational requirements associated to numerical simulations of La...
We present the first GPU-based conjugate gradient (CG) solver for lattice QCD with domain-wall fermi...
This paper briefly describes the physics motivations and strategies of Lattice Gauge Theory (LGT), t...