English

5-regular graphs and the 3-dimensional rigidity matroid

Combinatorics 2025-06-30 v1

Abstract

A bar-joint framework (G,p)(G,p) in Euclidean dd-space is rigid if the only edge-length-preserving continuous motions arise from isometries of Rd\mathbb{R}^d. In the generic case, rigidity is determined by the generic dd-dimensional rigidity matroid of GG. The combinatorial nature of this matroid is well understood when d=1,2d=1,2 but open when d3d\geq 3. Jackson and Jord\'an 2005 characterised independence in this matroid for connected graphs with minimum degree at most d+1d+1 and maximum degree at most d+2d+2. Their characterisation is known to be false for (d+2)(d+2)-regular graphs when d4d\geq 4 but when d=3d=3 it remained open. Indeed they conjectured that their characterisation extends to 5-regular graphs when d=3d=3. The purpose of this article is to prove their conjecture. That is, we prove that every 5-regular graph that has at most 3n63n-6 edges in any subgraph on n3n\geq 3 vertices is independent in the generic 3-dimensional rigidity matroid.

Keywords

Cite

@article{arxiv.2506.22214,
  title  = {5-regular graphs and the 3-dimensional rigidity matroid},
  author = {Rebecca Monks and Anthony Nixon},
  journal= {arXiv preprint arXiv:2506.22214},
  year   = {2025}
}

Comments

26 pages, 3 figures

R2 v1 2026-07-01T03:36:29.309Z