TY - JOUR
T1 - Distributed Control of Islanded DC Microgrids
T2 - A Passivity-Based Game Theoretical Approach
AU - Fu, Zao
AU - Cenedese, Carlo
AU - Cucuzzella, Michele
AU - Yu, Wenwu
AU - Scherpen, Jacquelien M. A.
N1 - Publisher Copyright:
Authors
PY - 2024/6/6
Y1 - 2024/6/6
N2 - In this article, we consider a dc microgrid composed of distributed generation units (DGUs) trading energy among each other, where the energy price depends on the total current generated by all the DGUs. We then use a Cournot aggregative game to describe the self-interested interaction among the DGUs, where each DGU aims at minimizing the deviation with respect to the given reference signals and maximizing the revenue from the sale of the generated power. Thus, we design a fully distributed continuous-time equilibrium-seeking algorithm to compute the generalized Nash equilibrium (GNE) of the game. We interconnect the designed decision-making algorithm with the dynamics of the microgrid in a passive way, and, by leveraging passivity theory, we prove the convergence of the closed-loop system trajectory to a feasible operating point that is also a Nash equilibrium of the collective aggregative game. Finally, we present extensive simulation results that validate the proposed distributed optimal control scheme, showing excellent performance.
AB - In this article, we consider a dc microgrid composed of distributed generation units (DGUs) trading energy among each other, where the energy price depends on the total current generated by all the DGUs. We then use a Cournot aggregative game to describe the self-interested interaction among the DGUs, where each DGU aims at minimizing the deviation with respect to the given reference signals and maximizing the revenue from the sale of the generated power. Thus, we design a fully distributed continuous-time equilibrium-seeking algorithm to compute the generalized Nash equilibrium (GNE) of the game. We interconnect the designed decision-making algorithm with the dynamics of the microgrid in a passive way, and, by leveraging passivity theory, we prove the convergence of the closed-loop system trajectory to a feasible operating point that is also a Nash equilibrium of the collective aggregative game. Finally, we present extensive simulation results that validate the proposed distributed optimal control scheme, showing excellent performance.
KW - DC microgrids
KW - Decentralized control
KW - Decision making
KW - distributed optimization
KW - energy trading
KW - game theory
KW - Games
KW - Heuristic algorithms
KW - Microgrids
KW - passivity
KW - Power transmission lines
KW - Vectors
UR - http://www.scopus.com/inward/record.url?scp=85195422785&partnerID=8YFLogxK
U2 - 10.1109/TCST.2024.3405711
DO - 10.1109/TCST.2024.3405711
M3 - Article
AN - SCOPUS:85195422785
SN - 1063-6536
SP - 1
EP - 16
JO - IEEE Transactions on Control Systems Technology
JF - IEEE Transactions on Control Systems Technology
ER -