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Motivated by a conjecture of Frid, Puzynina, and Zamboni, we investigate infinite words with the property that for infinitely many n, every length-n factor is a product of two palindromes. We show that every Sturmian word has this property,…

Combinatorics · Mathematics 2015-09-18 Adam Borchert , Narad Rampersad

A closed word (a.k.a. periodic-like word or complete first return) is a word whose longest border does not have internal occurrences, or, equivalently, whose longest repeated prefix is not right special. We investigate the structure of…

Formal Languages and Automata Theory · Computer Science 2014-12-02 Golnaz Badkobeh , Gabriele Fici , Zsuzsanna Lipták

We prove that the property of being closed (resp., palindromic, rich, privileged trapezoidal, balanced) is expressible in first-order logic for automatic (and some related) sequences. It therefore follows that the characteristic function of…

Formal Languages and Automata Theory · Computer Science 2015-12-01 Luke Schaeffer , Jeffrey Shallit

If an infinite non-periodic word is uniformly recurrent or is of bounded repetition, then the limit of its periodicity complexity is infinity. Moreover, there are uniformly recurrent words with the periodicity complexity arbitrarily high at…

Formal Languages and Automata Theory · Computer Science 2019-12-18 Štěpán Holub

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

The prefix palindromic length $PPL_u(n)$ of an infinite word $u$ is the minimal number of concatenated palindromes needed to express the prefix of length $n$ of $u$. In a 2013 paper with Puzynina and Zamboni we stated the conjecture that…

Discrete Mathematics · Computer Science 2020-01-09 Anna E. Frid

We show that the number of length-n words over a k-letter alphabet having no even palindromic prefix is the same as the number of length-n unbordered words, by constructing an explicit bijection between the two sets. A slightly different…

Discrete Mathematics · Computer Science 2020-06-05 Daniel Gabric , Jeffrey Shallit

In this paper we study the asymptotic behaviour of two relatively new complexity functions defined on infinite words and their relationship to periodicity. Given a factor $u$ of an infinite word $x$, we say $u$ is closed if it is a letter…

Combinatorics · Mathematics 2023-01-04 O. Parshina , M. Postic

Trapezoidal words are finite words having at most n+1 distinct factors of length n, for every n>=0. They encompass finite Sturmian words. We distinguish trapezoidal words into two disjoint subsets: open and closed trapezoidal words. A…

Formal Languages and Automata Theory · Computer Science 2011-08-19 Gabriele Fici

Trapezoidal words are words having at most $n+1$ distinct factors of length $n$ for every $n\ge 0$. They therefore encompass finite Sturmian words. We give combinatorial characterizations of trapezoidal words and exhibit a formula for their…

Formal Languages and Automata Theory · Computer Science 2013-01-22 Michelangelo Bucci , Alessandro De Luca , Gabriele Fici

In this paper, we study combinatorial and structural properties of a new class of finite and infinite words that are 'rich' in palindromes in the utmost sense. A characteristic property of so-called "rich words" is that all complete returns…

Combinatorics · Mathematics 2010-03-16 Amy Glen , Jacques Justin , Steve Widmer , Luca Q. Zamboni

We study the notion of quasiperiodicity, in the sense of "coverability", for biinfinite words. All previous work about quasiperiodicity focused on right infinite words, but the passage to the biinfinite case could help to prove stronger…

Discrete Mathematics · Computer Science 2018-03-08 Florian Barbero , Guilhem Gamard , Anaël Grandjean

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

We prove that if a uniformly recurrent infinite word contains as a factor any finite permutation of words from an infinite family, then either this word is periodic, or its complexity (that is, the number of factors) grows faster than…

Combinatorics · Mathematics 2015-10-29 Anna E. Frid

A finite word u is said to be bordered if u has a proper prefix which is also a suffix of u, and unbordered otherwise. Ehrenfeucht and Silberger proved that an infinite word is purely periodic if and only if it contains only finitely many…

Formal Languages and Automata Theory · Computer Science 2015-01-30 Emilie Charlier , Tero Harju , Svetlana Puzynina , Luca Zamboni

We study the set of finite words with zero palindromic defect, i.e., words rich in palindromes. This set is factorial, but not recurrent. We focus on description of pairs of rich words which cannot occur simultaneously as factors of a…

Combinatorics · Mathematics 2018-01-09 Edita Pelantová , Štěpán Starosta

Rich words are characterized by containing the maximum possible number of distinct palindromes. Several characteristic properties of rich words have been studied; yet the analysis of repetitions in rich words still involves some interesting…

Combinatorics · Mathematics 2019-11-15 Aseem Raj Baranwal , Jeffrey Shallit

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

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

The avoidability, or unavoidability of patterns in words over finite alphabets has been studied extensively. A word (pattern) over a finite set is said to be unavoidable if, for all but finitely many words, there exists a morphism mapping…

Formal Languages and Automata Theory · Computer Science 2019-07-16 Paul Sauer