A Configurable Hierarchical Architecture for Parallel Dynamic Contingency Analysis on GPUs

IF 3.3 Q3 ENERGY & FUELS

IEEE Open Access Journal of Power and Energy Pub Date : 2023-01-01 DOI:10.1109/OAJPE.2022.3227800

Cong Wang;Suangshuang Jin;Renke Huang;Qiuhua Huang;Yousu Chen

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引用次数: 3

Abstract

Dynamic contingency analysis (DCA) for modern power systems is fundamental to help researchers and operators look ahead of potential issues, arrange operational plans, and improve system stabilities. However, since the system size and the number of contingency scenarios continue to increase, pursuing more effective computational performance faces many difficulties, such as slow algorithms and limited computing resources. This research accelerates the intensive computations of massive DCAs by implementing a two-level hierarchical computing architecture on graphical processing units (GPUs). The performance of the designed method is examined using four test systems of different sizes and compared with a CPU-based parallel approach. The results show up to 2.8x speedup using one GPU and 4.2x speedup using two GPUs, respectively. More accelerations can be observed once more GPUs are configured. It demonstrates that the proposed architecture can significantly enhance the overall computational performance of massive DCAs while maintaining a strong scaling capability under various resource configurations.

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gpu并行动态偶然性分析的可配置层次结构

现代电力系统的动态应急分析(DCA)是帮助研究人员和操作人员提前发现潜在问题、安排运行计划和提高系统稳定性的基础。然而，随着系统规模和突发场景数量的不断增加，追求更有效的计算性能面临着许多困难，例如算法缓慢和计算资源有限。本研究通过在图形处理单元(gpu)上实现两级分层计算架构来加速大规模dca的密集计算。采用四个不同尺寸的测试系统对所设计方法的性能进行了测试，并与基于cpu的并行方法进行了比较。结果显示，使用一个GPU加速高达2.8倍，使用两个GPU加速高达4.2倍。一旦配置了更多的gpu，可以观察到更多的加速。结果表明，该架构可以显著提高大规模dca的整体计算性能，同时在各种资源配置下保持较强的扩展能力。

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

IEEE Open Access Journal of Power and Energy Multiple-

CiteScore

7.80

自引率

5.30%

发文量

审稿时长

10 weeks