Accelerating cluster dynamics simulation of fission gas behavior in nuclear fuel on deep computing unit–based heterogeneous architecture supercomputer

IF 3.5 3区计算机科学 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

International Journal of High Performance Computing Applications Pub Date : 2023-03-14 DOI:10.1177/10943420231162831

He Bai, Changjun Hu, Yuhan Zhu, Dandan Chen, Genshen Chu, Shuai Ren

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引用次数: 1

Abstract

High fidelity simulation of fission gas behavior is able to help us understand and predict the performance of nuclear fuel under different irradiation conditions. Cluster dynamics (CD) is a mesoscale simulation method which is rapidly developed in nuclear fuel research area in recent years, and it can effectively describe the microdynamic behavior of fission gas in nuclear fuel; however, due to the huge cost of computation needed for CD model solution, the application scenario of CD has been limited. Thus, how to design the acceleration algorithm for the given computing resources to improve the computing efficiency and simulation scale has become a key problem of CD simulation. In this work, we present an accelerating cluster dynamics model based on the spatially dependent cluster dynamics model, combined with multi optimization methods on a DCU (deep computing unit)-based heterogeneous architecture supercomputer. The correctness of the model is verified by comparing with experimental data and Xolotl—a software of SciDAC program from the U.S. Department of Energy’s Office of Science. Furthermore, our model implementation has a better computing performance than Xolotl’s GPU version. Our code has gained great strong/weak scaling performance with more than 72.75%/84.07% parallel efficiency on 1024 compute nodes. This work developed a new efficient model for CD simulation of fission gas in nuclear fuel.

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基于深度计算单元的异构结构超级计算机上核燃料裂变气体行为加速簇动力学模拟

对裂变气体行为的高保真模拟有助于我们了解和预测核燃料在不同辐照条件下的性能。簇动力学(CD)是近年来在核燃料研究领域迅速发展起来的一种中尺度模拟方法，它能有效地描述核燃料裂变气体的微动力学行为;然而，由于CD模型求解所需的巨大计算成本，限制了CD的应用场景。因此，如何在给定的计算资源下设计加速算法以提高计算效率和仿真规模成为CD仿真的关键问题。在此工作中，我们提出了一个基于空间依赖集群动力学模型的加速集群动力学模型，并结合基于DCU(深度计算单元)的异构架构超级计算机的多种优化方法。通过与实验数据和美国能源部科学办公室的SciDAC程序Xolotl-a软件的比较，验证了模型的正确性。此外，我们的模型实现比Xolotl的GPU版本具有更好的计算性能。我们的代码获得了很强/很弱的扩展性能，在1024个计算节点上并行效率超过72.75%/84.07%。本文为核燃料裂变气体的CD模拟建立了一种新的高效模型。

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

International Journal of High Performance Computing Applications 工程技术-计算机：跨学科应用

CiteScore

6.10

自引率

6.50%

发文量

审稿时长

>12 weeks

期刊介绍： With ever increasing pressure for health services in all countries to meet rising demands, improve their quality and efficiency, and to be more accountable; the need for rigorous research and policy analysis has never been greater. The Journal of Health Services Research & Policy presents the latest scientific research, insightful overviews and reflections on underlying issues, and innovative, thought provoking contributions from leading academics and policy-makers. It provides ideas and hope for solving dilemmas that confront all countries.