English

Reduced complexities for sequences over finite alphabets

Combinatorics 2025-09-22 v1 Formal Languages and Automata Theory

Abstract

Letting ww denote a finite, nonempty word, let red(w)\text{red}(w) denote the word obtained from ww by replacing every subword ss of ww of the form ccccc \cdots c for a given character cc (such that there is no character immediately to the left or right of ss equal to cc) with cc. Complexity functions for infinite words play important roles within combinatorics on words, and this leads us to introduce and investigate variants of the factor and abelian complexity functions using the given reduction operation. By enumerating words vv and ww of a given length n0n \geq 0 and associated with an infinite sequence over a finite alphabet such that red(v)\text{red}(v) and red(w)\text{red}(w) are equal or otherwise equivalent in some specified way, by analogy with the factor and abelian complexity functions, this may be seen as producing simplified versions of previously introduced complexity functions. We prove a recursion for the reduced factor complexity function ρtred\rho_{\mathbf{t}}^{\text{red}} for the Thue-Morse sequence t\mathbf{t}, giving us that (ρtred(n):nN)(\rho_{\mathbf{t}}^{\text{red}}(n) : n \in \mathbb{N}) is a 22-regular sequence, we prove an explicit evaluation for the reduced factor complexity function ρfred\rho_{\mathbf{f}}^{\text{red}} for the (regular) paperfolding sequence f\mathbf{f}, together with an evaluation for the reduced abelian complexity function ρfab,red\rho_{\mathbf{f}}^{\text{ab}, \text{red}} for f\mathbf{f}. We conclude with open problems concerning ρtab,red\rho_{\mathbf{t}}^{\text{ab}, \text{red}}.

Keywords

Cite

@article{arxiv.2509.16034,
  title  = {Reduced complexities for sequences over finite alphabets},
  author = {John M. Campbell and James Currie and Narad Rampersad},
  journal= {arXiv preprint arXiv:2509.16034},
  year   = {2025}
}

Comments

18 pages

R2 v1 2026-07-01T05:45:56.254Z