Hybrid Voltage Control in Distribution Networks Under Limited Communication Rates

TL;DR

This paper introduces a hybrid voltage control strategy for distribution networks that combines local and distributed methods, leveraging power electronics and partial primal-dual updates for adaptive, communication-efficient voltage regulation.

Contribution

It develops a novel hybrid voltage control approach that integrates local feedback with distributed coordination, enhancing adaptability and robustness under limited communication.

Findings

Improves voltage regulation by combining local and distributed controls.

Adapts dynamically to varying system conditions and communication outages.

Demonstrates effectiveness through numerical tests on realistic feeders.

Abstract

Voltage regulation in distribution networks is challenged by increasing penetration of distributed energy resources (DERs). Thanks to advancement in power electronics, these DERs can be leveraged to regulate the grid voltage by quickly changing the reactive power outputs. This paper develops a hybrid voltage control (HVC) strategy that can seamlessly integrate both local and distributed designs to coordinate the network-wide reactive power resources from DERs. \ws{By minimizing a special voltage mismatch objective, we achieve the proposed HVC architecture using partial primal-dual (PPD) gradient updates that allow for a distributed and online implementation}. The proposed HVC design improves over existing distributed approaches by integrating with local voltage feedback. As a result, it can dynamically adapt to varying system operating conditions while being fully cognizant to the instantaneous availability of communication links. Under the worst-case scenario of a total link outage, the proposed design naturally boils down to a surrogate local control implementation. Numerical tests on realistic feeder cases have been to corroborate our analytical results and demonstrate the algorithmic performance.