English

Machine Learning-assisted Dynamics-Constrained Day-Ahead Energy Scheduling

Systems and Control 2026-03-17 v3 Systems and Control

Abstract

TThe rapid expansion of inverter-based resources, such as wind and solar power plants, will significantly diminish the presence of conventional synchronous generators in fu-ture power grids with rich renewable energy sources. This transition introduces in-creased complexity and reduces dynamic stability in system operation and control, with low inertia being a widely recognized challenge. However, the literature has not thoroughly explored grid dynamic performance associated with energy scheduling so-lutions that traditionally only consider grid steady-state constraints. This paper will bridge the gap by enforcing grid dynamic constraints when conducting optimal energy scheduling; particularly, this paper explores locational post-contingency rate of change of frequency (RoCoF) requirements to accommodate substantial inertia reductions. This paper introduces a machine learning-assisted RoCoF-constrained unit commit-ment (ML-RCUC) model designed to ensure RoCoF stability after the most severe generator outage while maintaining operational efficiency. A graph-informed NN (GINN)-based RoCoF predictor is first trained on a high-fidelity simulation dataset to track the highest locational RoCoF, which is then reformulated as mixed-integer linear programming constraints that are integrated into the unit commitment model. Case studies, by solving the optimization problem ML-RCUC and validating its solutions with time-domain simulations, demonstrate that the proposed method can ensure loca-tional RoCoF stability with minimum conservativeness.

Keywords

Cite

@article{arxiv.2309.02650,
  title  = {Machine Learning-assisted Dynamics-Constrained Day-Ahead Energy Scheduling},
  author = {Mingjian Tuo and Xingpeng Li and Pascal Van Hentenryck},
  journal= {arXiv preprint arXiv:2309.02650},
  year   = {2026}
}
R2 v1 2026-06-28T12:13:45.465Z