Large-Scale Grid Optimization: the Workhorse of Future Grid Computations

Purpose of Review: The computation methods for modeling, controlling, and optimizing the transforming grid are evolving rapidly. We review and systemize knowledge for a special class of computation methods that solve large-scale power grid optimization problems. Recent Findings: We find that while mechanistic physics-based methods are leading the science in solving large-scale grid optimizations, data-driven techniques, especially physics constrained ones, are emerging as an alternative to solve otherwise intractable problems. We also find observable gaps in the field and ascertain these gaps from the paper’s literature review and by collecting and synthesizing feedback from industry experts. Summary: Large-scale grid optimizations are pertinent for, among other things, hedging against risk due to resource stochasticity, evaluating aggregated DERs’ impact on grid operation and design, and improving the overall efficiency of grid operation in terms of cost, reliability, and carbon footprint. We attribute the continual growth in scale and complexity of grid optimizations to a large influx of new spatial and temporal features in both transmission (T) and distribution (D) networks. Therefore, to systemize knowledge in the field, we discuss the recent advancements in T and D systems from the viewpoint of mechanistic physics-based and emerging data-driven methods. © 2023, The Author(s), under exclusive licence to Springer Nature Switzerland AG.