English

Is Distance Matrix Enough for Geometric Deep Learning?

Machine Learning 2024-10-22 v6 Artificial Intelligence

Abstract

Graph Neural Networks (GNNs) are often used for tasks involving the 3D geometry of a given graph, such as molecular dynamics simulation. While incorporating Euclidean distance into Message Passing Neural Networks (referred to as Vanilla DisGNN) is a straightforward way to learn the geometry, it has been demonstrated that Vanilla DisGNN is geometrically incomplete. In this work, we first construct families of novel and symmetric geometric graphs that Vanilla DisGNN cannot distinguish even when considering all-pair distances, which greatly expands the existing counterexample families. Our counterexamples show the inherent limitation of Vanilla DisGNN to capture symmetric geometric structures. We then propose kk-DisGNNs, which can effectively exploit the rich geometry contained in the distance matrix. We demonstrate the high expressive power of kk-DisGNNs from three perspectives: 1. They can learn high-order geometric information that cannot be captured by Vanilla DisGNN. 2. They can unify some existing well-designed geometric models. 3. They are universal function approximators from geometric graphs to scalars (when k2k\geq 2) and vectors (when k3k\geq 3). Most importantly, we establish a connection between geometric deep learning (GDL) and traditional graph representation learning (GRL), showing that those highly expressive GNN models originally designed for GRL can also be applied to GDL with impressive performance, and that existing complicated, equivariant models are not the only solution. Experiments verify our theory. Our kk-DisGNNs achieve many new state-of-the-art results on MD17.

Keywords

Cite

@article{arxiv.2302.05743,
  title  = {Is Distance Matrix Enough for Geometric Deep Learning?},
  author = {Zian Li and Xiyuan Wang and Yinan Huang and Muhan Zhang},
  journal= {arXiv preprint arXiv:2302.05743},
  year   = {2024}
}

Comments

NeurIPS 2023. This new version includes corrections of some minor typos and potentially unclear notations

R2 v1 2026-06-28T08:37:49.134Z