English

Platonic Transformers: A Solid Choice For Equivariance

Computer Vision and Pattern Recognition 2025-10-09 v2 Artificial Intelligence Machine Learning Image and Video Processing

Abstract

While widespread, Transformers lack inductive biases for geometric symmetries common in science and computer vision. Existing equivariant methods often sacrifice the efficiency and flexibility that make Transformers so effective through complex, computationally intensive designs. We introduce the Platonic Transformer to resolve this trade-off. By defining attention relative to reference frames from the Platonic solid symmetry groups, our method induces a principled weight-sharing scheme. This enables combined equivariance to continuous translations and Platonic symmetries, while preserving the exact architecture and computational cost of a standard Transformer. Furthermore, we show that this attention is formally equivalent to a dynamic group convolution, which reveals that the model learns adaptive geometric filters and enables a highly scalable, linear-time convolutional variant. Across diverse benchmarks in computer vision (CIFAR-10), 3D point clouds (ScanObjectNN), and molecular property prediction (QM9, OMol25), the Platonic Transformer achieves competitive performance by leveraging these geometric constraints at no additional cost.

Keywords

Cite

@article{arxiv.2510.03511,
  title  = {Platonic Transformers: A Solid Choice For Equivariance},
  author = {Mohammad Mohaiminul Islam and Rishabh Anand and David R. Wessels and Friso de Kruiff and Thijs P. Kuipers and Rex Ying and Clara I. Sánchez and Sharvaree Vadgama and Georg Bökman and Erik J. Bekkers},
  journal= {arXiv preprint arXiv:2510.03511},
  year   = {2025}
}
R2 v1 2026-07-01T06:16:25.817Z