利用优化的时序卷积网络快速评估电力系统的暂态稳定性

IF 7.9 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Open Journal of Industry Applications Pub Date : 2024-07-10 DOI:10.1109/OJIA.2024.3426334
Mohamed Massaoudi;Tassneem Zamzam;Maymouna Ez Eddin;Ali Ghrayeb;Haitham Abu-Rub;Shady S. Refaat
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引用次数: 0

摘要

在当今的互联电网中,基于逆变器的资源的不可预测性极大地影响了电网的暂态稳定性。本文介绍了一种基于深度时空卷积网络(TCN)的高效暂态稳定状态预测方法。利用灰狼优化器(GWO)对 TCN 超参数进行微调,以提高所提模型的准确性。建议的模型可在故障发生的早期阶段提供有关瞬态电网状态的关键信息,从而采取适当的措施。拟议的 TCN-GWO 使用同步采样值和来自不同总线系统的合成值。在故障发生后的场景中,为确保所提方法的可靠性,在 TCN-GWO 模型中加入了高重要性特征的处理块协程。通过采用数字归因和数据缺失容错技术,所提出的算法释放了可扩展性和系统对运行可变性的适应性。利用 PowerWorld 模拟器,在 68 总线系统和美国东北部 25k 总线合成测试系统上对所提出的算法进行了评估,测试系统具有可信的突发事件。结果表明,在各种突发事件下,所提技术的性能优于同类最先进的暂态稳定性评估方法,故障排除后 0.64 秒内的总体准确率达到 99%。
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Fast Transient Stability Assessment of Power Systems Using Optimized Temporal Convolutional Networks
The transient power grid stability is greatly affected by the unpredictability of inverter-based resources of today's interconnected power grids. This article introduces an efficient transient stability status prediction method based on deep temporal convolutional networks (TCNs). A grey wolf optimizer (GWO) is utilized to fine-tune the TCN hyperparameters to improve the proposed model's accuracy. The proposed model provides critical information on the transient grid status in the early stages of fault occurrence, which may lead to taking the proper action. The proposed TCN-GWO uses both synchronously sampled values and synthetic values from various bus systems. In a postfault scenario, a copula of processing blocks is implemented to ensure the reliability of the proposed method where high-importance features are incorporated into the TCN-GWO model. The proposed algorithm unlocks scalability and system adaptability to operational variability by adopting numeric imputation and missing-data-tolerant techniques. The proposed algorithm is evaluated on the 68-bus system and the Northeastern United States 25k-bus synthetic test system with credible contingencies using the PowerWorld simulator. The obtained results prove the enhanced performance of the proposed technique over competitive state-of-the-art transient stability assessment methods under various contingencies with an overall accuracy of 99% within 0.64 s after the fault clearance.
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