Distributed control and passivity-based stability analysis for time-delayed DC microgrids

For cooperation among distributed generations in a DC microgrid (MG), distributed control is widely applied. However, the delay in distributed communication will result in steady-state bias and the risk of instability. This paper proposes a novel distributed control for time-delayed DC MGs to achieve accurate current proportional sharing and weighted average voltage regulation. Firstly, by utilizing an advanced observer based on the PI consensus algorithm, the steady-state bias problem is addressed. Then, using the passivity theory, stability analysis is conducted to reveal the principle of system instability caused by communication delay. On this basis, to offset the adverse effects of communication delay on the system stability, scattering transformation is introduced in the observer-based distributed control. Moreover, considering the potential delay from the measurement stage in real-life scenarios, the sufficient condition of the system stability is concluded by constructing the Lyapunov-Krasovskii functional. Finally, the performance of the proposed control and conclusions of stability analysis are verified by hardware-in-loop tests. A novel distributed control is proposed for time-delayed DC microgrids to achieve accurate current proportional sharing and weighted average voltage regulation. By passivity-based stability analysis, the principle of the system instability resulting from communication delay under the proposed control and the scattering transformation to improve system stability is revealed. Theorems for system stability in the scenarios with or without delays are presented. image