English

Reflection on the reflection complexity

Combinatorics 2025-11-18 v1

Abstract

The factor complexity Cu{\mathcal C}_{\mathbf u} of a sequence u=u0u1u2{\mathbf u} = u_0u_1u_2 \cdots over a finite alphabet counts the number of factors of length nn occurring in u\mathbf u, i.e., Cu(n)=#Ln(u){\mathcal C}_{\mathbf u}(n) = \#{\mathcal L}_n(\mathbf u), where Ln(u)={uiui+1ui+n1:iN}{\mathcal L}_n({\mathbf u)}= \{u_iu_{i+1}\cdots u_{i+n-1}: i \in \mathbb N\}. Two factors of Ln(u){\mathcal L}_n(\mathbf u) are said to be equivalent if one factor is the reversal of the other one. Recently, Allouche et al. introduced the reflection complexity rur_{\mathbf u} which counts the number of non-equivalent factors of Ln(u)\mathcal{L}_n(\mathbf u). They formulated the following conjecture: a sequence u\mathbf u is eventually periodic if and only if ru(n+2)=ru(n)r_{\mathbf u}(n+2) = r_{\mathbf u}(n) for some nNn \in \mathbb N. Here we prove the conjecture and characterize the sequences for which ru(n+2)=ru(n)+1r_{\mathbf u}(n+2) = r_{\mathbf u}(n)+1 for every nNn \in \mathbb N and also the sequences for which the equality is satisfied for every sufficiently large nNn \in \mathbb N.

Keywords

Cite

@article{arxiv.2511.12358,
  title  = {Reflection on the reflection complexity},
  author = {Lubomíra Dvořáková and Edita Pelantová},
  journal= {arXiv preprint arXiv:2511.12358},
  year   = {2025}
}
R2 v1 2026-07-01T07:39:20.605Z