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A word is called closed if it has a prefix which is also its suffix and there is no internal occurrences of this prefix in the word. In this paper we study words that are rich in closed factors, i.e., which contain the maximal possible…

Combinatorics · Mathematics 2023-01-05 Olga Parshina , Svetlana Puzynina

We study the relation between the palindromic and factor complexity of infinite words. We show that for uniformly recurrent words one has P(n)+P(n+1) \leq \Delta C(n) + 2, for all n \in N. For a large class of words it is a better estimate…

Combinatorics · Mathematics 2007-05-23 Peter Baláži , Zuzana Masáková , Edita Pelantová

In this paper we prove that for any infinite word W whose set of factors is closed under reversal, the following conditions are equivalent: (I) all complete returns to palindromes are palindromes; (II) P(n) + P(n+1) = C(n+1) - C(n) + 2 for…

Combinatorics · Mathematics 2010-04-08 Michelangelo Bucci , Alessandro De Luca , Amy Glen , Luca Q. Zamboni

Two results on palindromicity of bi-infinite words in a finite alphabet are presented. The first is a simple, but efficient criterion to exclude palindromicity of minimal sequences and applies, in particular, to the Rudin-Shapiro sequence.…

Mathematical Physics · Physics 2019-07-17 Michael Baake

We prove a number of results on the structure and enumeration of palindromes and antipalindromes. In particular, we study conjugates of palindromes, palindromic pairs, rich words, and the counterparts of these notions for antipalindromes.

Formal Languages and Automata Theory · Computer Science 2016-09-13 Chuan Guo , Jeffrey Shallit , Arseny M. Shur

The palindromic length of the finite word $v$ is equal to the minimal number of palindromes whose concatenation is equal to $v$. It was conjectured in 2013 that for every infinite aperiodic word $x$, the palindromic length of its factors is…

Combinatorics · Mathematics 2025-09-16 Josef Rukavicka

We introduce two classes of morphisms over the alphabet $A=\{0,1\}$ whose fixed points contain infinitely many antipalindromic factors. An antipalindrome is a finite word invariant under the action of the antimorphism…

Combinatorics · Mathematics 2019-06-17 Petr Ambrož , Zuzana Masáková , Edita Pelantová

We study the palindromic complexity of infinite words $u_\beta$, the fixed points of the substitution over a binary alphabet, $\phi(0)=0^a1$, $\phi(1)=0^b1$, with $a-1\geq b\geq 1$, which are canonically associated with quadratic non-simple…

Combinatorics · Mathematics 2016-08-16 L'ubomíra Balková , Zuzana Masáková

In this paper we study the privileged complexity function of the Thue-Morse word. We prove a recursive formula describing this function, and using the formula we show that the function is unbounded and that the values of the function have…

Combinatorics · Mathematics 2015-07-23 Jarkko Peltomäki

In this paper we explore various interconnections between rich words, Sturmian words, and trapezoidal words. Rich words, first introduced in arXiv:0801.1656 by the second and third authors together with J. Justin and S. Widmer, constitute a…

Combinatorics · Mathematics 2010-04-08 Aldo de Luca , Amy Glen , Luca Q. Zamboni

Given a finite word u, we define its palindromic length |u|_{pal} to be the least number n such that u=v_1v_2... v_n with each v_i a palindrome. We address the following open question: Does there exist an infinite non ultimately periodic…

Combinatorics · Mathematics 2012-10-25 Anna E. Frid , Svetlana Puzynina , Luca Zamboni

Recently, a new characterization of Lyndon words that are also perfectly clustering was proposed by Lapointe and Reutenauer (2024). A word over a ternary alphabet {a,b,c} is called perfectly clustering Lyndon if and only if it is the…

Combinatorics · Mathematics 2024-06-25 Mélodie Lapointe , Nathan Plourde-Hébert

Any finite word $w$ of length $n$ contains at most $n+1$ distinct palindromic factors. If the bound $n+1$ is reached, the word $w$ is called rich. The number of rich words of length $n$ over an alphabet of cardinality $q$ is denoted…

Combinatorics · Mathematics 2019-03-26 Josef Rukavicka

In [A. Frid, S. Puzynina, L.Q. Zamboni, \textit{On palindromic factorization of words}, Adv. in Appl. Math. 50 (2013), 737-748], it was conjectured that any infinite word whose palindromic lengths of factors are bounded is ultimately…

Formal Languages and Automata Theory · Computer Science 2016-06-21 Michelangelo Bucci , Gwenaël Richomme

Let S be a finite set of words over an alphabet Sigma. The set S is said to be complete if every word w over the alphabet Sigma is a factor of some element of S*, i.e. w belongs to Fact(S*). Otherwise if S is not complete, we are interested…

Formal Languages and Automata Theory · Computer Science 2010-04-26 Gabriele Fici , Elena V. Pribavkina , Jacques Sakarovitch

For any finite field $\mathbb{F}$ and any positive integer $n$ we count the number of monic polynomials of degree $n$ over $\mathbb{F}$ with nonzero constant coefficient and a self-reciprocal factor of any specified degree. An application…

Number Theory · Mathematics 2022-10-31 Geoffrey Price , Katherine Thompson

A palindromic periodicity is a factor of an infinite word $(ps)^\omega$ where $p$ and $s$ are palindromes and the factor has length at least $|ps|$, for example, $accabaccab$. In this paper we describe several ways in which a palindromic…

Combinatorics · Mathematics 2024-05-02 Jamie Simpson

Palindromes are those reduced words of free products of groups that coincide with their reverse words. We prove that a free product of groups $G$ has infinite palindromic width, provided that $G$ is not the free product of two cyclic groups…

Group Theory · Mathematics 2007-05-23 Valery Bardakov , Vladimir Tolstykh

We study infinite words u over an alphabet A satisfying the property P : P(n)+ P(n+1) = 1+ #A for any n in N, where P(n) denotes the number of palindromic factors of length n occurring in the language of u. We study also infinite words…

Combinatorics · Mathematics 2013-02-12 Lubomira Balkova , Edita Pelantova , Stepan Starosta

We say a finite word $x$ is a palindromic periodicity if there exist two palindromes $p$ and $s$ such that $|x| \geq |ps|$ and $x$ is a prefix of the word $(ps)^\omega = pspsps\cdots$. In this paper we examine the palindromic periodicities…

Combinatorics · Mathematics 2024-08-13 Gabriele Fici , Jeffrey Shallit , Jamie Simpson