基于分布式学习复合Lyapunov函数的直流微电网集群大信号稳定性分析

doi:10.19595/j.cnki.1000-6753.tces.250466

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摘要直流微电网集群是由邻近多个小型直流微电网互联而成的复杂网络,通过网间灵活的功率流动能够提升供电的可靠性和经济性。然而,直流微电网本身具有低惯性和高阻抗“弱电网”的特性,集群结构会进一步降低系统阻尼,导致其在大扰动情况下易引发失稳。传统基于Lyapunov函数的大信号稳定性分析缺少构建能量泛函的通用方法,尤其对于集群系统的高阶和非线性复杂动态特性更为突出,而现有采用“分解-集结”式的分布式建模分析方法也存在保守性较高和Lyapunov函数建立困难的问题。为此,针对直流微电网集群,该文提出基于分布式学习复合Lyapunov函数的大信号稳定性分析方法。将集群系统描述为若干互联的微电网子系统,建立子系统的分布式等效大信号模型,借助分布式深度神经网络学习子系统的Lyapunov函数,进而构建集群的复合结构Lyapunov函数;根据具体算例对重要参数影响、拓扑扩展性和与同类方法的比较等方面进行数值分析,最后分别通过硬件在环实验和物理样机实验验证所提方法的有效性。

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关键词 ：直流微电网集群, 大信号稳定性, 分布式学习, 复合Lyapunov函数

Abstract：A DC microgrid cluster (DCMGC) is a complex network formed by the interconnections of multiple adjacent small DC microgrids, which can enhance power supply reliability and economic benefits through flexible inter-network power flow control. However, the stable operation of DCMGCs faces significant challenges. On one hand, the system features numerous power electronic interfaces between distributed energy resources (DERs), loads, and the DC bus. Among these, controlled load converters act as constant power loads (CPLs) with negative impedance characteristics from the bus perspective, which may cause voltage instability and power oscillations. The intermittent fluctuations of DERs caused by variable wind speed and solar irradiance, coupled with load-side demand changes and source-side topology variations (e.g., microgrid connection/ disconnection), endow DCMGCs with ‘weak-grid’ characteristics of low inertia and high impedance, severely challenging their large-signal stable operation. On the other hand, traditional Lyapunov-based large-signal stability analysis methods have limitations in constructing appropriate energy functionals as a general approach, especially for the high-order and nonlinear dynamics of DCMGCs. Meanwhile, existing ‘decomposition- aggregation’ distributed modeling methods suffer from high conservatism, leading to overly restrictive stability conditions.
This paper proposes a novel method for large-signal stability analysis based on a distributed learning composite Lyapunov function. First, the DCMGC system is modeled as interconnected microgrid subsystems, and distributed equivalent large-signal circuit models are established to reflect the dynamics and interactions of these subsystems. Then, the Lyapunov stability condition is used to customize the loss function, and the Lyapunov function of each subsystem is constructed via distributed deep neural network parallel learning. Subsequently, a composite Lyapunov function for the DCMGC is formed by integrating subsystem functions. Through case studies on a specific DCMGC topology, the impacts of circuit parameter changes, topology variations, and an increase in the number of microgrids on large-signal stability are analyzed. Finally, hardware-in-the-loop (HIL) and all-physical hardware experiments verify the effectiveness of the proposed method.
The following conclusions can be drawn. (1) The proposed distributed learning composite Lyapunov method combines data-driven with Lyapunov function theory and considers the distributed characteristics of the DCMGCs model. It enables parallel block-solving of subsystem Lyapunov functions in local state space, demonstrating excellent solvability. (2) Compared with the T-S method based on region of attraction (ROA) ‘domain’ information and Braton-Moser’s mixed potential function method based on criterion derivation, the proposed method offers significantly lower analytical conservatism, enabling more accurate and less restrictive stability assessment for DCMGC design and operation.

Key words： DC microgrid cluster large-signal stability distributed learning composite Lyapunov functions

收稿日期: 2025-03-24

PACS:	TM46
	TM712

基金资助:国家自然科学基金面上项目资助（52277169）

通讯作者: 刘宿城男,1981年生,博士,教授,研究方向为直流微电网与开关功率变换技术。E-mail: liusucheng@126.com

作者简介: 李龙男,1999年生,硕士研究生,研究方向为直流微电网。E-mail: lilonghaha2020@163.com

引用本文:

刘宿城, 李龙, 栾李, 周桃虎, 刘晓东. 基于分布式学习复合Lyapunov函数的直流微电网集群大信号稳定性分析[J]. 电工技术学报, 2026, 41(7): 2191-2207. Liu Sucheng, Li Long, Luan Li, Zhou Taohu, Liu Xiaodong. Large-Signal Stability Analysis Based on Distributed Learning Composite Lyapunov Functions for DC Microgrids Clusters. Transactions of China Electrotechnical Society, 2026, 41(7): 2191-2207.

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