Scalable Physical Source-to-Field Inference with Hypernetworks
Abstract
We present a generative model that amortises computation for the field and potential around e.g.~gravitational or electromagnetic sources. Exact numerical calculation has either computational complexity $\mathcal{O}(M\times{}N)$ in the number of sources $M$ and evaluation points $N$, or requires a fixed evaluation grid to exploit fast Fourier transforms. Using an architecture where a hypernetwork produces an implicit representation of the field or potential around a source collection, our model instead performs as $\mathcal{O}(M + N)$, achieves relative error of $\sim\!4\%-6\%$, and allows evaluation at arbitrary locations for arbitrary numbers of sources, greatly increasing the speed of e.g.~physics simulations. We compare with existing models and develop two-dimensional examples, including cases where sources overlap or have more complex geometries, to demonstrate its application.
Cite
Text
James et al. "Scalable Physical Source-to-Field Inference with Hypernetworks." Transactions on Machine Learning Research, 2026.Markdown
[James et al. "Scalable Physical Source-to-Field Inference with Hypernetworks." Transactions on Machine Learning Research, 2026.](https://mlanthology.org/tmlr/2026/james2026tmlr-scalable/)BibTeX
@article{james2026tmlr-scalable,
title = {{Scalable Physical Source-to-Field Inference with Hypernetworks}},
author = {James, Berian and Pollok, Stefan and Peis, Ignacio and Baker, Elizabeth Louise and Frellsen, Jes and Bjørk, Rasmus},
journal = {Transactions on Machine Learning Research},
year = {2026},
url = {https://mlanthology.org/tmlr/2026/james2026tmlr-scalable/}
}