Tensor field networks: Rotation- and translation-equivariant neural networks for 3D point clouds
About
We introduce tensor field neural networks, which are locally equivariant to 3D rotations, translations, and permutations of points at every layer. 3D rotation equivariance removes the need for data augmentation to identify features in arbitrary orientations. Our network uses filters built from spherical harmonics; due to the mathematical consequences of this filter choice, each layer accepts as input (and guarantees as output) scalars, vectors, and higher-order tensors, in the geometric sense of these terms. We demonstrate the capabilities of tensor field networks with tasks in geometry, physics, and chemistry.
Nathaniel Thomas, Tess Smidt, Steven Kearnes, Lusann Yang, Li Li, Kai Kohlhoff, Patrick Riley• 2018
Related benchmarks
| Task | Dataset | Result | Rank | |
|---|---|---|---|---|
| Molecular property prediction | QM9 (test) | mu0.064 | 229 | |
| 3D Shape Classification | ModelNet40 (test) | -- | 227 | |
| Classification | ModelNet40 | Accuracy62.64 | 108 | |
| Molecular property prediction | QM9 | Cv0.101 | 80 | |
| Atomic force prediction | MD17 (test) | -- | 22 | |
| Dynamics Prediction | N-body 1500 (train) | Prediction Error (1,2,0)5.86 | 13 | |
| Dynamics Prediction | N-body 500 (train) | Prediction Error (1,2,0)11.54 | 13 | |
| Point Cloud Classification | ModelNet40 v1.0 (Random) | Accuracy87.6 | 12 | |
| Point Cloud Classification | ModelNet40 Attack v1.0 | Accuracy87.6 | 12 | |
| Point Cloud Classification | ModelNet40 Clean v1.0 | Accuracy87.6 | 12 |
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