English

Resolution to Sutner's Conjecture

Combinatorics 2022-07-05 v3 Discrete Mathematics

Abstract

Consider a game played on a simple graph G=(V,E)G = (V,E) where each vertex consists of a clickable light. Clicking any vertex vv toggles the on/off state of vv and its neighbors. One wins the game by finding a sequence of clicks that turns off all the lights. When GG is a 5×55 \times 5 grid, this game was commercially available from Tiger Electronics as Lights Out. Sutner was one of the first to study these games mathematically. He found that when d(G)=dim(ker(A+I))d(G) = \text{dim}(\text{ker}(A + I)) over the field GF(2)GF(2), where AA is the adjacency matrix of GG, is 0 all initial configurations are solvable. When investigating n×nn \times n grid graphs, Sutner conjectured that d2n+1=2dn+δn,δn{0,2},δ2n+1=δnd_{2n+1} = 2d_{n} + \delta_{n}, \delta_{n} \in \{0,2\}, \delta_{2n+1} = \delta_{n}, where dn=d(G)d_n = d(G) for GG an n×nn \times n grid graph. We resolve this conjecture in the affirmative. We use results from Sutner that give dnd_n as the GCD of two polynomials in the ring Z2[x]\mathbb{Z}_2[x]. We then apply identities from Hunziker, Machiavelo, and Park that relate the polynomials of (2n+1)×(2n+1)(2n+1) \times (2n+1) grids and n×nn \times n grids. Finally, we use a result from Ore about the GCD of two products. Together these results allow us to prove Sutner's conjecture. We then go further and show for exactly which values of nn δn\delta_n is 0 or 2.

Keywords

Cite

@article{arxiv.2202.09878,
  title  = {Resolution to Sutner's Conjecture},
  author = {William Boyles},
  journal= {arXiv preprint arXiv:2202.09878},
  year   = {2022}
}

Comments

7 pages, 1 figure

R2 v1 2026-06-24T09:46:41.725Z