Reduced and mixed precision turbulent flow simulations using explicit finite difference schemes

IF 6.2 2区计算机科学 Q1 COMPUTER SCIENCE, THEORY & METHODS

Future Generation Computer Systems-The International Journal of Escience Pub Date : 2025-09-08 DOI:10.1016/j.future.2025.108111

Bálint Siklósi , Pushpender K. Sharma , David J. Lusher , István Z. Reguly , Neil D. Sandham

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Abstract

The use of reduced and mixed precision computing has gained increasing attention in high-performance computing (HPC) as a means to improve computational efficiency, particularly on modern hardware architectures like GPUs. In this work, we explore the application of mixed precision arithmetic in compressible turbulent flow simulations using explicit finite difference schemes. We extend the OPS and OpenSBLI frameworks to support customizable precision levels, enabling fine-grained control over precision allocation for different computational tasks. Through a series of numerical experiments on the Taylor–Green vortex benchmark, we demonstrate that mixed precision strategies, such as half-single and single-double combinations, can offer significant performance gains without compromising numerical accuracy. However, pure half-precision computations result in unacceptable accuracy loss, underscoring the need for careful precision selection. Our results show that mixed precision configurations can reduce memory usage and communication overhead, leading to notable speedups, particularly on multi-CPU and multi-GPU systems.

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使用显式有限差分格式的简化和混合精度湍流模拟

在高性能计算（HPC）中，使用简化和混合精度计算作为提高计算效率的一种手段已经引起了越来越多的关注，特别是在像gpu这样的现代硬件架构上。在这项工作中，我们探讨了使用显式有限差分格式的混合精度算法在可压缩湍流模拟中的应用。我们扩展了OPS和OpenSBLI框架，以支持可定制的精度级别，从而可以对不同计算任务的精度分配进行细粒度控制。通过Taylor-Green涡旋基准的一系列数值实验，我们证明了混合精度策略，如半单和单双组合，可以在不影响数值精度的情况下提供显着的性能提升。然而，纯半精度计算导致不可接受的精度损失，强调需要仔细的精度选择。我们的结果表明，混合精度配置可以减少内存使用和通信开销，从而显著提高速度，特别是在多cpu和多gpu系统上。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Future Generation Computer Systems-The International Journal of Escience 工程技术-计算机：理论方法

CiteScore

19.90

自引率

2.70%

发文量

376

审稿时长

10.6 months

期刊介绍： Computing infrastructures and systems are constantly evolving, resulting in increasingly complex and collaborative scientific applications. To cope with these advancements, there is a growing need for collaborative tools that can effectively map, control, and execute these applications. Furthermore, with the explosion of Big Data, there is a requirement for innovative methods and infrastructures to collect, analyze, and derive meaningful insights from the vast amount of data generated. This necessitates the integration of computational and storage capabilities, databases, sensors, and human collaboration. Future Generation Computer Systems aims to pioneer advancements in distributed systems, collaborative environments, high-performance computing, and Big Data analytics. It strives to stay at the forefront of developments in grids, clouds, and the Internet of Things (IoT) to effectively address the challenges posed by these wide-area, fully distributed sensing and computing systems.