Dynamic workload prediction and distribution in numerical modeling of solidification on multi‐/manycore architectures

Abstract: Summary This work is a part of the global tendency to use modern computing systems for modeling the phase‐field phenomena. The main goal of this article is to improve the performance of a parallel application for the solidification modeling, assuming the dynamic intensity of computations in successive time steps when calculations are performed using a carefully selected group of nodes in the grid. A two‐step method is proposed to optimize the application for multi‐/manycore architectures. In the first step, th… Show more

“…The application's structure permits its parallelization by splitting the iteration of the outer loop across the available computing resources. The presented code results from the performance optimization method presented in our previous work 48 …”

Single‐ and multi‐GPU computing on NVIDIA‐ and AMD‐based server platforms for solidification modeling application

“…The application's structure permits its parallelization by splitting the iteration of the outer loop across the available computing resources. The presented code results from the performance optimization method presented in our previous work 48 …”

Single‐ and multi‐GPU computing on NVIDIA‐ and AMD‐based server platforms for solidification modeling application

“…Paper [5] is a part of the global tendency to use high performance computing (HPC) systems for modeling the phase‐field phenomena. This work aims to improve the performance of a parallel application for the solidification modeling with the dynamic intensity of computations in successive time steps when calculations are performed in selected nodes of the grid.…”

Taming next‐generation HPC systems: Run‐time system and algorithmic advancements

Performance exploration of various C/C++ compilers for AMD EPYC processors in numerical modeling of solidification