{ "id": "1804.08724", "version": "v1", "published": "2018-04-23T20:29:16.000Z", "updated": "2018-04-23T20:29:16.000Z", "title": "Partitioned Factors in Christoffel and Sturmian Words", "authors": [ "Norman Carey", "David Clampitt" ], "categories": [ "math.DS" ], "abstract": "Borel and Reutenauer (2006) showed, \\emph{inter alia}, that a word $w$ of length $n>1$ is conjugate to a Christoffel word if and only if for $k=0,1, \\dots, n-1$, $w$ has $k+1$ distinct circular factors of length $k$. Sturmian words are the infinite counterparts to Christoffel words, characterized as aperiodic but of minimal complexity, i.e., for all $n \\in \\mathbb{N}$ there are $n+1$ factors of length $n$. Berth\\'{e} (1996) showed that the factors of a given length in the Sturmian case have at most 3 frequencies (probabilities). In this paper we extend to results on factors of both Christoffel words and Sturmian words under fixed partitionings (decompositions of factors of length $m$ into concatenations of words whose lengths are given by an ordered partition of $m$ into $k$ components). Any factor of a Sturmian word (respectively, circular factor of a Christoffel word) thus partitioned into $k$ elements belongs to one of $k+1$ equivalence classes (varieties). We show how to compute the sizes of the equivalence classes determined by an ordered partition in the case of Christoffel word, and show how to compute the frequencies of the classes in the case of Sturmian words. A version of the finitary case was proved in a very different context (expressed in musical and number-theoretical terms) by Clough and Myerson (1985, 1986); we use their terminology, \\emph{variety} and \\emph{multiplicity}.", "revisions": [ { "version": "v1", "updated": "2018-04-23T20:29:16.000Z" } ], "analyses": { "keywords": [ "sturmian word", "christoffel word", "partitioned factors", "equivalence classes", "ordered partition" ], "note": { "typesetting": "TeX", "pages": 0, "language": "en", "license": "arXiv", "status": "editable" } } }