Adaptive Power Flow Approximations With Second-Order Sensitivity Insights

IF 7.2 1区工程技术 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Transactions on Power Systems Pub Date : 2024-11-18 DOI:10.1109/TPWRS.2024.3499899

Paprapee Buason;Sidhant Misra;Jean-Paul Watson;Daniel K. Molzahn

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Abstract

The power flow equations are fundamental to power system planning, analysis, and control. However, the inherent non-linearity and non-convexity of these equations present formidable obstacles in problem-solving processes. To mitigate these challenges, recent research has proposed adaptive power flow linearizations that aim to achieve accuracy over wide operating ranges. The accuracy of these approximations inherently depends on the curvature of the power flow equations within these ranges, which necessitates considering second-order sensitivities. In this paper, we leverage second-order sensitivities to both analyze and improve power flow approximations. We evaluate the curvature across broad operational ranges and subsequently utilize this information to inform the computation of various sample-based power flow approximation techniques. Additionally, we leverage second-order sensitivities to guide the development of rational approximations that yield linear constraints in optimization problems. This approach is extended to enhance accuracy beyond the limitations of linear functions across varied operational scenarios.

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具有二阶敏感性洞察力的自适应功率流近似法

潮流方程是电力系统规划、分析和控制的基础。然而，这些方程固有的非线性和非凸性给解决问题的过程带来了巨大的障碍。为了缓解这些挑战，最近的研究提出了自适应潮流线性化，旨在在宽工作范围内实现精度。这些近似的准确性本质上取决于功率流方程在这些范围内的曲率，这就需要考虑二阶灵敏度。在本文中，我们利用二阶灵敏度来分析和改进功率流近似。我们在广泛的操作范围内评估曲率，并随后利用这些信息来通知各种基于样本的潮流近似技术的计算。此外，我们利用二阶灵敏度来指导在优化问题中产生线性约束的合理近似的发展。这种方法被扩展到提高精度，超越了线性函数在不同操作场景中的限制。

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 Transactions on Power Systems 工程技术-工程：电子与电气

CiteScore

15.80

自引率

7.60%

发文量

696

审稿时长

3 months

期刊介绍： The scope of IEEE Transactions on Power Systems covers the education, analysis, operation, planning, and economics of electric generation, transmission, and distribution systems for general industrial, commercial, public, and domestic consumption, including the interaction with multi-energy carriers. The focus of this transactions is the power system from a systems viewpoint instead of components of the system. It has five (5) key areas within its scope with several technical topics within each area. These areas are: (1) Power Engineering Education, (2) Power System Analysis, Computing, and Economics, (3) Power System Dynamic Performance, (4) Power System Operations, and (5) Power System Planning and Implementation.