Learning Chern Numbers of Multiband Topological Insulators with Gauge Equivariant Neural Networks
Paper in proceeding, 2026

Equivariant network architectures are a well-established tool for predicting invariant or equivariant quantities. However, almost all learning problems considered in this context feature a global symmetry, i.e. each point of the underlying space is transformed with the same group element, as opposed to a local gauge symmetry, where each point is transformed with a different group element, exponentially enlarging the size of the symmetry group. We use gauge equivariant networks to predict topological invariants (Chern numbers) of multiband topological insulators for the first time. The gauge symmetry of the network guarantees that the predicted quantity is a topological invariant. A major technical challenge is that the relevant gauge equivariant networks are plagued by instabilities in their training, severely limiting their usefulness. In particular, for larger gauge groups the instabilities make training impossible. We resolve this problem by introducing a novel gauge equivariant normalization layer which stabilizes the training. Furthermore, we prove a universal approximation theorem for our model. We train on samples with trivial Chern number only but show that our model generalizes to samples with non-trivial Chern number and provide various ablations of our setup.

Author

Longde Huang

University of Gothenburg

Chalmers, Mathematical Sciences, Algebra and geometry

Oleksandr Balabanov

Stockholm University

Hampus Linander

Verses.ai

Mats Granath

University of Gothenburg

Daniel Persson

University of Gothenburg

Chalmers, Mathematical Sciences, Algebra and geometry

Jan Gerken

Chalmers, Mathematical Sciences, Algebra and geometry

University of Gothenburg

Advances in Neural Information Processing Systems

10495258 (ISSN)

Vol. 38 147997-148026

NeurIPS 2025
San Diego, CA, USA,

Subject Categories (SSIF 2025)

Geometry

Artificial Intelligence

More information

Latest update

7/14/2026