Group-Algebraic Tensors: Provably-optimal Equivariant Learning and Physical Symmetry Discovery
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Computer Science > Machine Learning
arXiv:2605.20440 (cs)
[Submitted on 19 May 2026]
Title:Group-Algebraic Tensors: Provably-optimal Equivariant Learning and Physical Symmetry Discovery
Authors:Paulina Hoyos, Shashanka Ubaru, Dongsung Huh, Vasileios Kalantzis, Kenneth L. Clarkson, Misha Kilmer, Haim Avron, Lior Horesh
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Abstract:We introduce the $\star_G$ tensor algebra, in which any finite group $G$ defines the multiplication rule, making equivariance an intrinsic algebraic property rather than an architectural constraint. The framework rests on three machine-verified theoretical pillars: (i)~an Eckart-Young optimality guarantee for the $\star_G$-SVD: the first such result for symmetry-preserving tensor approximation, exact and polynomial-time; (ii)~a Kronecker factorization that composes multiple symmetries by replacing $F_G$ with $F_{G_1} \otimes F_{G_2}$ with no architectural redesign; and (iii)~a 600-line Lean~4 formalization of the $\star_G$ algebra. The framework provides capabilities that equivariant neural networks (ENNs) structurally cannot: a closed-form per-irreducible-representation decomposition of every prediction, and data-driven discovery of the symmetry group that best fits a dataset. As a non-trivial empirical demonstration, decomposing QM9 molecular geometry over the chiral octahedral subgroup of SO(3) recovers the Wigner--Eckart selection rules of angular momentum from data alone, with no quantum mechanical input: scalar properties are A$_1$-dominated, dipole components are T$_1$-dominated, the isotropic polarizability is uniquely insensitive to $l\!=\!1$ as the rank-2-trace decomposition $l\!=\!0 \oplus l\!=\!2$ requires, and the T$_1$/A$_1$ predictive-power ratio separates vector observables from scalar observables by a factor of five. On full QM9 (130{,}831 molecules), $\star_G$-SVD with ridge regression provides closed form predictions at $\sim50-90\times$ fewer parameters than parameter-matched MLPs. Algebraic equivariance thus complements architectural equivariance not as a faster-better-cheaper alternative but as a different mathematical affordance: provably-optimal symmetry-preserving compression, per-irrep interpretability, and data-driven physical discovery.
| Subjects: | Machine Learning (cs.LG); Artificial Intelligence (cs.AI); Rings and Algebras (math.RA) |
| Cite as: | arXiv:2605.20440 [cs.LG] |
| (or arXiv:2605.20440v1 [cs.LG] for this version) | |
| https://doi.org/10.48550/arXiv.2605.20440
arXiv-issued DOI via DataCite (pending registration)
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Submission history
From: Shashanka Ubaru [view email][v1] Tue, 19 May 2026 19:47:40 UTC (12,390 KB)
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