TY - JOUR
T1 - Foundation Models for the Electric Power Grid
AU - Hamann, Hendrik
AU - Gjorgiev, Blazhe
AU - Brunschwiler, Thomas
AU - Martins, Leonardo
AU - Puech, Alban
AU - Varbella, Anna
AU - Weiss, Jonas
AU - Bernabe-Moreno, Juan
AU - Masse, Alexandre
AU - Choi, Seong
AU - Foster, Ian
AU - Hodge, Bri-Mathias
AU - Jain, Rishabh
AU - Kim, Kibaek
AU - Mai, Vincent
AU - Miralles, Francois
AU - De Montigny, Martin
AU - Ramos-Leanos, Octavio
AU - Supreme, Hussein
AU - Xie, Le
AU - Youssef, El-Nasser
AU - Zinflou, Arnaud
AU - Belyi, Alexander
AU - Bessa, Ricardo
AU - Bhattarai, Bishnu
AU - Schmude, Johannes
AU - Sobolevsky, Stanislav
PY - 2024
Y1 - 2024
N2 - Foundation models (FMs) currently dominate news headlines. They employ advanced deep learning architectures to extract structural information autonomously from vast datasets through self-supervision. The resulting rich representations of complex systems and dynamics can be applied to many downstream applications. Therefore, advances in FMs can find uses in electric power grids, challenged by the energy transition and climate change. This paper calls for the development of FMs for electric grids. We highlight their strengths and weaknesses amidst the challenges of a changing grid. It is argued that FMs learning from diverse grid data and topologies, which we call grid foundation models (GridFMs), could unlock transformative capabilities, pioneering a new approach to leveraging AI to redefine how we manage complexity and uncertainty in the electric grid. Finally, we discuss a practical implementation pathway and road map of a GridFM-v0, a first GridFM for power flow applications based on graph neural networks, and explore how various downstream use cases will benefit from this model and future GridFMs.
AB - Foundation models (FMs) currently dominate news headlines. They employ advanced deep learning architectures to extract structural information autonomously from vast datasets through self-supervision. The resulting rich representations of complex systems and dynamics can be applied to many downstream applications. Therefore, advances in FMs can find uses in electric power grids, challenged by the energy transition and climate change. This paper calls for the development of FMs for electric grids. We highlight their strengths and weaknesses amidst the challenges of a changing grid. It is argued that FMs learning from diverse grid data and topologies, which we call grid foundation models (GridFMs), could unlock transformative capabilities, pioneering a new approach to leveraging AI to redefine how we manage complexity and uncertainty in the electric grid. Finally, we discuss a practical implementation pathway and road map of a GridFM-v0, a first GridFM for power flow applications based on graph neural networks, and explore how various downstream use cases will benefit from this model and future GridFMs.
KW - AI-based power flow simulation
KW - data-driven power grid modeling
KW - energy transition
KW - foundation models
U2 - 10.1016/j.joule.2024.11.002
DO - 10.1016/j.joule.2024.11.002
M3 - Article
SN - 2542-4351
VL - 8
SP - 3245
EP - 3258
JO - Joule
JF - Joule
IS - 12
ER -