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arXiv:2404.18210v2 Announce Type: replace
Abstract: This paper presents a new distributed control approach for the voltage regulation problem in DC microgrids (MGs) comprised of interconnected distributed generators (DGs), distribution lines, and loads. First, we describe the closed-loop DC MG with a distributed controller as a networked system in which the DGs and lines are two subsystems interconnected via a static interconnection matrix. This matrix demonstrates the distributed controller gains as well as the communication topology of DC MG. To design the distributed controller gains, we use the dissipative properties of the subsystems and formulate a global linear matrix inequality (LMI) problem. To support the feasibility of global control design, we propose a local controller for each DG and line subsystem by formulating a local LMI problem. In contrast to existing controllers that segregate communication topology and controller gains, our proposed controller simultaneously designs both communication topology and distributed controllers. The proposed controller is also compositional, meaning that when a new subsystem is added to or removed from networked systems, the controller for the new subsystem is designed solely based on the dynamics of the new subsystem and the dissipativity information of its coupled subsystems. This ensures that the overall system remains stable during plug-and-play (PnP) operation.
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