用于动态安全评估的人工智能技术--调查

IF 10.7 2区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Miguel Cuevas, Ricardo Álvarez-Malebrán, Claudia Rahmann, Diego Ortiz, José Peña, Rodigo Rozas-Valderrama
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引用次数: 0

摘要

变流器并网发电(CIG)的日益普及正在改变着电力系统的动态,使其对快速而复杂的控制系统极为依赖。因此,定期评估这些系统在各种运行条件下的稳定性是确保安全运行的关键任务。然而,快速和慢速(机电)现象的同时模拟,以及关键运行条件数量的增加,将传统的动态安全评估(DSA)推向了极限。虽然动态安全评估已很好地实现了其目的,但在未来的电力系统中,电网上不同电压等级的电力电子设备数以千计,动态安全评估将难以为继。因此,减少稳定性研究所需的人力和计算工作量比以往任何时候都更为重要。为了应对这些挑战,近年来提出了几种利用人工智能(AI)的先进模拟技术。人工智能技术可以捕捉系统运行条件与其稳定性之间的非线性关系,而无需求解模拟系统的代数微分方程集,从而应对电力系统日益增加的不确定性和复杂性。一旦建立了这些关系,就可以针对各种情况及时、准确地评估系统稳定性。尽管数百篇研究文章证实,人工智能技术正在为快速评估稳定性铺平道路,但仍有许多问题和难题需要解决,特别是关于使用现有的基于人工智能的方法研究特定类型稳定性的相关性及其在现实世界中的应用。在此背景下,本文全面回顾了基于人工智能的电力系统稳定性评估技术。文章广泛讨论了不同的人工智能技术实现方法,如学习算法、输入数据的生成和处理,并结合实际情况进行了阐述。考虑到稳定性类型、所研究的系统和应用类型,还讨论了它们的实际应用。我们回顾了目前正在进行的研究工作以及迄今为止针对 DSA 提出的基于人工智能的技术,并将它们联系起来,相互关联。我们还讨论了用于稳定性研究的人工智能技术的优势、局限性、挑战和未来趋势。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Artificial intelligence techniques for dynamic security assessments - a survey

The increasing uptake of converter-interfaced generation (CIG) is changing power system dynamics, rendering them extremely dependent on fast and complex control systems. Regularly assessing the stability of these systems across a wide range of operating conditions is thus a critical task for ensuring secure operation. However, the simultaneous simulation of both fast and slow (electromechanical) phenomena, along with an increased number of critical operating conditions, pushes traditional dynamic security assessments (DSA) to their limits. While DSA has served its purpose well, it will not be tenable in future electricity systems with thousands of power electronic devices at different voltage levels on the grid. Therefore, reducing both human and computational efforts required for stability studies is more critical than ever. In response to these challenges, several advanced simulation techniques leveraging artificial intelligence (AI) have been proposed in recent years. AI techniques can handle the increased uncertainty and complexity of power systems by capturing the non-linear relationships between the system’s operational conditions and their stability without solving the set of algebraic-differential equations that model the system. Once these relationships are established, system stability can be promptly and accurately evaluated for a wide range of scenarios. While hundreds of research articles confirm that AI techniques are paving the way for fast stability assessments, many questions and issues must still be addressed, especially regarding the pertinence of studying specific types of stability with the existing AI-based methods and their application in real-world scenarios. In this context, this article presents a comprehensive review of AI-based techniques for stability assessments in power systems. Different AI technical implementations, such as learning algorithms and the generation and treatment of input data, are widely discussed and contextualized. Their practical applications, considering the type of stability, system under study, and type of applications, are also addressed. We review the ongoing research efforts and the AI-based techniques put forward thus far for DSA, contextualizing and interrelating them. We also discuss the advantages, limitations, challenges, and future trends of AI techniques for stability studies.

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来源期刊
Artificial Intelligence Review
Artificial Intelligence Review 工程技术-计算机:人工智能
CiteScore
22.00
自引率
3.30%
发文量
194
审稿时长
5.3 months
期刊介绍: Artificial Intelligence Review, a fully open access journal, publishes cutting-edge research in artificial intelligence and cognitive science. It features critical evaluations of applications, techniques, and algorithms, providing a platform for both researchers and application developers. The journal includes refereed survey and tutorial articles, along with reviews and commentary on significant developments in the field.
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