E(n) Equivariant Message Passing Cellular Networks
Abstract
This paper introduces E(n)-Equivariant Message Passing Cellular Networks (EMPCNs), an extension of E(n)-Equivariant Graph Neural Networks to CW-complexes. Our approach addresses two aspects of geometric message passing networks: 1) enhancing their expressiveness by incorporating arbitrary cells, and 2) achieving this in a computationally efficient way with a decoupled EMPCNs technique. We demonstrate that EMPCNs achieve close to state-of-the-art performance on multiple tasks without the need for steerability, including many-body predictions and motion capture. Moreover, ablation studies confirm that decoupled EMPCNs exhibit stronger generalization capabilities than their non-topologically informed counterparts. These findings show that EMPCNs can be used as a scalable and expressive framework for higher-order message passing in geometric and topological graphs.
Cite
Text
Kovac et al. "E(n) Equivariant Message Passing Cellular Networks." ICML 2024 Workshops: GRaM, 2024.Markdown
[Kovac et al. "E(n) Equivariant Message Passing Cellular Networks." ICML 2024 Workshops: GRaM, 2024.](https://mlanthology.org/icmlw/2024/kovac2024icmlw-equivariant/)BibTeX
@inproceedings{kovac2024icmlw-equivariant,
title = {{E(n) Equivariant Message Passing Cellular Networks}},
author = {Kovac, Veljko and Bekkers, Erik J and Lio, Pietro and Eijkelboom, Floor},
booktitle = {ICML 2024 Workshops: GRaM},
year = {2024},
url = {https://mlanthology.org/icmlw/2024/kovac2024icmlw-equivariant/}
}