English

Neural Networks for Encoding Dynamic Security-Constrained Optimal Power Flow

Systems and Control 2022-07-15 v5 Machine Learning Systems and Control Optimization and Control

Abstract

This paper introduces a framework to capture previously intractable optimization constraints and transform them to a mixed-integer linear program, through the use of neural networks. We encode the feasible space of optimization problems characterized by both tractable and intractable constraints, e.g. differential equations, to a neural network. Leveraging an exact mixed-integer reformulation of neural networks, we solve mixed-integer linear programs that accurately approximate solutions to the originally intractable non-linear optimization problem. We apply our methods to the AC optimal power flow problem (AC-OPF), where directly including dynamic security constraints renders the AC-OPF intractable. Our proposed approach has the potential to be significantly more scalable than traditional approaches. We demonstrate our approach for power system operation considering N-1 security and small-signal stability, showing how it can efficiently obtain cost-optimal solutions which at the same time satisfy both static and dynamic security constraints.

Keywords

Cite

@article{arxiv.2003.07939,
  title  = {Neural Networks for Encoding Dynamic Security-Constrained Optimal Power Flow},
  author = {Ilgiz Murzakhanov and Andreas Venzke and George S. Misyris and Spyros Chatzivasileiadis},
  journal= {arXiv preprint arXiv:2003.07939},
  year   = {2022}
}

Comments

In proceedings of the 11th Bulk Power Systems Dynamics and Control Symposium (IREP 2022), July 25-30, 2022, Banff, Canada

R2 v1 2026-06-23T14:17:57.981Z