English

Learning with Adaptive Conservativeness for Distributionally Robust Optimization: Incentive Design for Voltage Regulation

Systems and Control 2024-08-07 v1 Systems and Control

Abstract

Information asymmetry between the Distribution System Operator (DSO) and Distributed Energy Resource Aggregators (DERAs) obstructs designing effective incentives for voltage regulation. To capture this effect, we employ a Stackelberg game-theoretic framework, where the DSO seeks to overcome the information asymmetry and refine its incentive strategies by learning from DERA behavior over multiple iterations. We introduce a model-based online learning algorithm for the DSO, aimed at inferring the relationship between incentives and DERA responses. Given the uncertain nature of these responses, we also propose a distributionally robust incentive design model to control the probability of voltage regulation failure and then reformulate it into a convex problem. This model allows the DSO to periodically revise distribution assumptions on uncertain parameters in the decision model of the DERA. Finally, we present a gradient-based method that permits the DSO to adaptively modify its conservativeness level, measured by the size of a Wasserstein metric-based ambiguity set, according to historical voltage regulation performance. The effectiveness of our proposed method is demonstrated through numerical experiments.

Keywords

Cite

@article{arxiv.2408.02765,
  title  = {Learning with Adaptive Conservativeness for Distributionally Robust Optimization: Incentive Design for Voltage Regulation},
  author = {Zhirui Liang and Qi Li and Joshua Comden and Andrey Bernstein and Yury Dvorkin},
  journal= {arXiv preprint arXiv:2408.02765},
  year   = {2024}
}

Comments

This paper was accepted for publication and presentation in the Proceedings of the IEEE Control and Decision Conference in Milano, Italy 2024

R2 v1 2026-06-28T18:04:42.443Z