English

The Ordered Zeckendorf Game

Number Theory 2026-03-31 v2 Combinatorics

Abstract

We introduce and analyze the ordered Zeckendorf game, a novel combinatorial two-player game inspired by Zeckendorf's Theorem, which guarantees a unique decomposition of every positive integer as a sum of non-consecutive Fibonacci numbers. Building on the original Zeckendorf game\ -- previously studied in the context of unordered multisets\ -- we impose a new constraint: all moves must respect the order of summands. The result is a richer and more nuanced strategic landscape that significantly alters game dynamics. Unlike the classical version, where Player 2 has a dominant strategy for all n>2n > 2, our ordered variant reveals a more balanced and unpredictable structure. In particular, we find that Player 1 wins for nearly all values n25n \leq 25, with a single exception at n=18n = 18. This shift in strategic outcomes is driven by our game's key features: adjacency constraints that limit allowable merges and splits to neighboring terms, and the introduction of a switching move that reorders pairs. We prove that the game always terminates in the Zeckendorf decomposition\ -- now in ascending order\ -- by constructing a strictly decreasing monovariant. We further establish bounds on game complexity: the shortest possible game has length exactly nZ(n)n - Z(n), where Z(n)Z(n) is the number of summands in the Zeckendorf decomposition of nn, while the longest game exhibits quadratic growth, with M(n)n22M(n) \sim \frac{n^2}{2} as nn \to \infty. Empirical simulations suggest that random game trajectories exhibit log-normal convergence in their move distributions. Overall, the ordered Zeckendorf game enriches the landscape of number-theoretic games, posing new algorithmic challenges and offering fertile ground for future exploration into strategic complexity, probabilistic behavior, and generalizations to other recurrence relations.

Keywords

Cite

@article{arxiv.2508.20222,
  title  = {The Ordered Zeckendorf Game},
  author = {Ivan Bortnovskyi and Michael Lucas and Steven J. Miller and Iana Vranesko and Ren Watson and Cameron White},
  journal= {arXiv preprint arXiv:2508.20222},
  year   = {2026}
}

Comments

17 pages, 5 figures

R2 v1 2026-07-01T05:09:11.195Z