English

Discrete Vector Bundles with Connection

Differential Geometry 2026-04-24 v3 Numerical Analysis Mathematical Physics math.MP Numerical Analysis

Abstract

We develop a combinatorial theory of vector bundles with connection on locally ordered simplicial complexes. This is a first step towards a discrete exterior calculus for bundle-valued forms. The basic building block is the discrete exterior covariant derivative, a forward-difference operator defined on bundle-valued cochains. Many standard objects in differential geometry (e.g., curvature, connection 1-forms, gauge transformations) can be understood via the discrete covariant derivative operator, with their defining formulas identical to the smooth setting. These discrete objects satisfy all of the expected algebraic identities, such as naturality with respect to simplicial maps, and a Bianchi identity for discrete curvature. We also show that flat discrete connections determine a cochain complex that computes twisted de Rham cohomology in a local coefficient system determined by the discrete vector bundle, with twisted Poincare duality (of densities) being one application. Finally, a coarsening operation applied to bundle-valued cochains provides a direct and concrete comparison with the recent framework for discrete bundles of Christiansen and Hu.

Keywords

Cite

@article{arxiv.2104.10277,
  title  = {Discrete Vector Bundles with Connection},
  author = {Daniel Berwick-Evans and Anil N. Hirani and Mark D. Schubel},
  journal= {arXiv preprint arXiv:2104.10277},
  year   = {2026}
}

Comments

Title changed to "Discrete Vector Bundles with Connection". We updated the framework to use locally ordered simplicial complexes. New additions include discrete connection 1-forms, gauge transformations, and proofs that flat connections compute twisted de Rham cohomology (discrete twisted Poincare duality). The Christiansen-Hu relationship is refactored as a coarsening procedure

R2 v1 2026-06-24T01:23:08.810Z