跟网型逆变器鲁棒稳定性分析：集成参数不确定性和区间时延的PI控制器整定

This paper presents a novel robust stability analysis framework for grid-following inverters subject to interval parametric uncertainties and unknown but bounded time delays. Prior works employing classical robust control strategies, such as H∞ control, μ-synthesis, and sliding mode control, often result in high-order or nonlinear controllers that are difficult to tune and implement in real-time inverter applications. Moreover, they typically address either parametric uncertainties or constant delays, but not their combined and varying effects. Model-free control approaches, including reinforcement learning and data-driven methods, offer adaptability but require extensive training data and computational effort, and often lack formal stability guarantees. In contrast to conventional delay-aware methods—such as Bode plot-based techniques, Lyapunov-Krasovskii functionals, and Smith Predictors—that either assume fixed parameter values or exhibit conservatism under uncertainty, the proposed approach employs a delay-dependent criterion integrated with value set and zero exclusion principles. The proposed method is simple, systematic, and non-conservative, enabling the complete determination of PI stabilizing gains without complex tuning. Simulation and experimental results verify its practical robustness and suitability for real-world inverter control.