English

Learning-assisted Stochastic Capacity Expansion Planning: A Bayesian Optimization Approach

Systems and Control 2024-07-18 v4 Machine Learning Systems and Control

Abstract

Solving large-scale capacity expansion problems (CEPs) is central to cost-effective decarbonization of regional-scale energy systems. To ensure the intended outcomes of CEPs, modeling uncertainty due to weather-dependent variable renewable energy (VRE) supply and energy demand becomes crucially important. However, the resulting stochastic optimization models are often less computationally tractable than their deterministic counterparts. Here, we propose a learning-assisted approximate solution method to tractably solve two-stage stochastic CEPs. Our method identifies low-cost planning decisions by constructing and solving a sequence of tractable temporally aggregated surrogate problems. We adopt a Bayesian optimization approach to searching the space of time series aggregation hyperparameters and compute approximate solutions that minimize costs on a validation set of supply-demand projections. Importantly, we evaluate solved planning outcomes on a held-out set of test projections. We apply our approach to generation and transmission expansion planning for a joint power-gas system spanning New England. We show that our approach yields an estimated cost savings of up to 3.8% in comparison to benchmark time series aggregation approaches.

Keywords

Cite

@article{arxiv.2401.10451,
  title  = {Learning-assisted Stochastic Capacity Expansion Planning: A Bayesian Optimization Approach},
  author = {Aron Brenner and Rahman Khorramfar and Dharik Mallapragada and Saurabh Amin},
  journal= {arXiv preprint arXiv:2401.10451},
  year   = {2024}
}
R2 v1 2026-06-28T14:21:07.097Z