Extended Impedance Modal Analysis of Internal Dynamics in Grid-Following Inverters

摘要

As the penetration of Grid-Following inverters (GFL) in power systems continues to increase, the dynamic characteristics of power systems undergo significant transformations. Recently, modal analysis based on the impedance model (MAI) has been utilized to evaluate the interaction between GFLs and the power grid through impedance/admittance participation factors (PF). However, MAI relies on the impedance model that characterizes the input-output behavior of the ports, treating the GFL as a single integrated entity. This approach limits its ability to reveal the complex dynamic coupling mechanism between different control loops inside the GFL. In this paper, we propose an extended impedance modal analysis (EMAI) method. Firstly, the equivalent dynamics of the GFL are decomposed into two components: the synchronous dynamic dominated by the phase-locked loop (PLL) and the electromagnetic dynamic dominated by the current control loop (CCL). The PF and participation ratios (PR) of these two dynamic components are then calculated to identify the dominant dynamics of the system. Building on this, we introduce the explicit parameter participation factors (PPF) to further pinpoint the key parameters of the dominant control loop, which provides a way for enhancing system stability. Finally, the effectiveness of the proposed method is validated through the simulation of the modified 14-bus and 68-bus systems. The EMAI method enables the analysis of the dynamic characteristics of each control loop in the GFL based on the impedance model. It can effectively identify the critical control loops influencing system stability without requiring the construction of a full state-space model, demonstrating its broad applicability and value.