Euclidean, Projective, Conformal: Choosing a Geometric Algebra for Equivariant Transformers

Abstract

The Geometric Algebra Transformer (GATr) is a versatile architecture for geometric deep learning based on projective geometric algebra. We generalize this architecture into a blueprint that allows one to construct a scalable transformer architecture given any geometric (or Clifford) algebra. We study versions of this architecture for Euclidean, projective, and conformal algebras, all of which are suited to represent 3D data, and evaluate them in theory and practice. The simplest Euclidean architecture is computationally cheap, but has a smaller symmetry group and is not as sample-efficient, while the projective model is not sufficiently expressive. Both the conformal algebra and an improved version of the projective algebra define powerful, performant architectures.

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Cite

Text

De Haan et al. "Euclidean, Projective, Conformal: Choosing a Geometric Algebra for Equivariant Transformers." NeurIPS 2023 Workshops: NeurReps, 2023.

Markdown

[De Haan et al. "Euclidean, Projective, Conformal: Choosing a Geometric Algebra for Equivariant Transformers." NeurIPS 2023 Workshops: NeurReps, 2023.](https://mlanthology.org/neuripsw/2023/haan2023neuripsw-euclidean/)

BibTeX

@inproceedings{haan2023neuripsw-euclidean,
  title     = {{Euclidean, Projective, Conformal: Choosing a Geometric Algebra for Equivariant Transformers}},
  author    = {De Haan, Pim and Cohen, Taco and Brehmer, Johann},
  booktitle = {NeurIPS 2023 Workshops: NeurReps},
  year      = {2023},
  url       = {https://mlanthology.org/neuripsw/2023/haan2023neuripsw-euclidean/}
}