English

Graph Powers of Groups

Group Theory 2025-10-28 v2 Combinatorics

Abstract

The Lights Out Puzzle, played on a graph Γ\Gamma, has been studied using linear algebra over F2\mathbb{F}_2 and more generally over Z/kZ\mathbb{Z}/k\mathbb{Z}. We generalize the setting by allowing the states of vertices to be the elements of a group GG, where a \textit{click} in vertex vv multiplies the state of vv and its neighbors by an element gGg \in G on the right. Starting with the identity element eGe \in G for all vertices, the totality of all achievable state configurations forms a group GΓG^{\Gamma}. This group generalizes parallel products of group actions and provides a rich structure for analysis. For many graphs, which we term ``RA'' (reducible to abelian), the problem reduces -- regardless of GG -- to a linear algebra question over Z\mathbb{Z}. We discuss a chain of five different subgroups consisting of commutators and introduce techniques for showing that families of graphs are RA using each. In particular, using Heisenberg groups, we establish that a graph is RA precisely when a certain lattice spans ZΓ\mathbb{Z}^{|\Gamma|}. While most graphs appear to be RA, we show the odd-dimensional cube graphs Q2n+1Q_{2n+1} and folded cube graphs d\square_d, for dd odd or 2, are not.

Keywords

Cite

@article{arxiv.2502.05648,
  title  = {Graph Powers of Groups},
  author = {Gabe Cunningham and Igor Minevich},
  journal= {arXiv preprint arXiv:2502.05648},
  year   = {2025}
}

Comments

20 pages (16 pages of main text, 4 pages of appendices and bibliography), 3 figures, submitted to The Electronic Journal of Combinatorics

R2 v1 2026-06-28T21:37:23.386Z