Sturmian word

The Fibonacci word is an example of a Sturmian word. The start of the cutting sequence shown here illustrates the start of the word 0100101001.

In mathematics, a Sturmian word (Sturmian sequence or billiard sequence[1]), named after Jacques Charles François Sturm, is a certain kind of infinitely long sequence of characters. Such a sequence can be generated by considering a game of English billiards on a square table. The struck ball will successively hit the vertical and horizontal edges labelled 0 and 1 generating a sequence of letters.[2] This sequence is a Sturmian word.

Definition

Sturmian sequences can be defined strictly in terms of their combinatoric properties or geometrically as cutting sequences for lines of irrational slope or codings for irrational rotations. They are traditionally taken to be infinite sequences on the alphabet of the two symbols 0 and 1.

Combinatoric definitions

Sequences of low complexity

For an infinite sequence of symbols w, let σ(n) be the complexity function of w; i.e., σ(n) = the number of distinct subwords in w of length n. w is Sturmian if σ(n)=n+1 for all n.

Balanced sequences

A set X of binary strings is called balanced if the Hamming weight of elements of X takes at most two distinct values. That is, for any s\in X |s|1=k or |s|1=k' where |s|1 is the number of 1s in s.

Let w be an infinite sequence of 0s and 1s and let \mathcal L_n(w) denote the set of all length-n subwords of w. The sequence w is Sturmian if \mathcal L_n(w) is balanced for all n and w is not eventually periodic.

Geometric definitions

Cutting sequence of irrational

Let w be an infinite sequence of 0s and 1s. The sequence w is Sturmian if for some x\in[0,1) and some irrational \theta\in(0,\infty), w is realized as the cutting sequence of the line f(t)=\theta t+x.

Difference of Beatty sequences

Let w=(wn) be an infinite sequence of 0s and 1s. The sequence w is Sturmian if it is the difference of non-homogeneous Beatty sequences, that is, for some x\in[0,1) and some irrational \theta\in(0,1)

w_n = \lfloor n\theta + x\rfloor - \lfloor (n-1)\theta + x \rfloor

for all n or

w_n = \lceil n\theta + x\rceil - \lceil (n-1)\theta + x \rceil

for all n.

Coding of irrational rotation

Enlarge for animation showing the Sturmian sequence generated by an irrational rotation with θ0.2882 and x0.0789

For \theta\in [0,1), define T_\theta:[0,1)\to[0,1) by t\mapsto t+\theta\mod 1. For x\in[0,1) define the θ-coding of x to be the sequence (xn) where

x_n=\left\{\begin{array}{cl}1&\text{ if } T_\theta^n(x)\in [0,\theta)\\0&\text{ else}\end{array}\right..

Let w be an infinite sequence of 0s and 1s. The sequence w is Sturmian if for some x\in[0,1) and some irrational \theta\in(0,\infty), w is the θ-coding of x.

Discussion

Example

A famous example of a (standard) Sturmian word is the Fibonacci word;[3] its slope is 1/\phi, where \phi is the golden ratio.

Balanced aperiodic sequences

A set S of finite binary words is balanced if for each n the subset Sn of words of length n has the property that the Hamming weight of the words in Sn takes at most two distinct values. A balanced sequence is one for which the set of factors is balanced. A balanced sequence has at most n+1 distinct factors of length n.[4]:43 An aperiodic sequence is one which does not consist of a finite sequence followed by a finite cycle. An aperiodic sequence has at least n+1 distinct factors of length n.[4]:43 A sequence is Sturmian if and only if it is balanced and aperiodic.[4]:43

Slope and intercept

A sequence (a_n)_{n\in\mathbb{N}} over {0,1} is a Sturmian word if and only if there exist two real numbers, the slope \alpha and the intercept \rho, with \alpha irrational, such that

a_n=\lfloor\alpha(n+1)+\rho\rfloor -\lfloor\alpha n+\rho\rfloor-\lfloor\alpha\rfloor

for all n.[5]:284[6]:152 Thus a Sturmian word provides a discretization of the straight line with slope \alpha and intercept ρ. Without loss of generality, we can always assume 0<\alpha<1, because for any integer k we have

\lfloor(\alpha + k)(n + 1) + \rho\rfloor - \lfloor(\alpha+k)n + \rho\rfloor - \lfloor\alpha + k\rfloor = a_n.

All the Sturmian words corresponding to the same slope \alpha have the same set of factors; the word c_\alpha corresponding to the intercept \rho=0 is the standard word or characteristic word of slope \alpha.[5]:283 Hence, if 0<\alpha<1, the characteristic word c_\alpha is the first difference of the Beatty sequence corresponding to the irrational number \alpha.

The standard word c_\alpha is also the limit of a sequence of words (s_n)_{n \ge 0} defined recursively as follows:

Let [0; d_1+1, d_2, \ldots, d_n, \ldots] be the continued fraction expansion of \alpha, and define

where the product between words is just their concatenation. Every word in the sequence (s_n)_{n>0} is a prefix of the next ones, so that the sequence itself converges to an infinite word, which is c_\alpha.

The infinite sequence of words (s_n)_{n \ge 0} defined by the above recursion is called the standard sequence for the standard word c_\alpha, and the infinite sequence d = (d1, d2, d3, ...) of nonnegative integers, with d1 ≥ 0 and dn > 0 (n ≥ 2), is called its directive sequence.

A Sturmian word w over {0,1} is characteristic if and only if both 0w and 1w are Sturmian.[7]

Frequencies

If s is an infinite sequence word and w is a finite word, let μN(w) denote the number of occurrences of w as a factor in the prefix of s of length N+|w|-1. If μN(w) has a limit as N→∞, we call this the frequency of w, denoted by μ(w).[4]:73

For a Sturmian word s, every finite factor has a frequency. The three-distance theorem states that the factors of fixed length n have at most three distinct frequencies, and if there are three values then one is the sum of the other two.[4]:73

Non-binary words

For words over an alphabet of size k greater than 2, we define a Sturmian word to be one with complexity function n+k−1.[6]:6 They can be described in terms of cutting sequences for k-dimensional space.[6]:84 An alternative definition is as words of minimal complexity subject to not being ultimately periodic.[6]:85

Associated real numbers

A real number for which the digits with respect to some fixed base form a Sturmian word is a transcendental number.[6]:64,85

History

Although the study of Sturmian words dates back to Johann III Bernoulli (1772),[8][5]:295 it was Gustav A. Hedlund and Marston Morse in 1940 who coined the term Sturmian to refer to such sequences,[5]:295[9] in honor of the mathematician Jacques Charles François Sturm due to the relation with the Sturm comparison theorem.[6]:114

See also

References

  1. Hordijk, A.; Laan, D. A. (2001). "Bounds for Deterministic Periodic Routing sequences". Integer Programming and Combinatorial Optimization. Lecture Notes in Computer Science 2081. p. 236. doi:10.1007/3-540-45535-3_19. ISBN 978-3-540-42225-9.
  2. Győri, Ervin; Sós, Vera (2009). Recent Trends in Combinatorics: The Legacy of Paul Erdős. Cambridge University Press. p. 117. ISBN 0-521-12004-7.
  3. de Luca, Aldo (1995). "A division property of the Fibonacci word". Information Processing Letters 54 (6): 307312. doi:10.1016/0020-0190(95)00067-M.
  4. 1 2 3 4 5 Lothaire, M. (2002). "Sturmian Words". Algebraic Combinatorics on Words. Cambridge: Cambridge University Press. ISBN 0-521-81220-8. Zbl 1001.68093. Retrieved 2007-02-25.
  5. 1 2 3 4 Allouche, Jean-Paul; Shallit, Jeffrey (2003). Automatic Sequences: Theory, Applications, Generalizations. Cambridge University Press. ISBN 978-0-521-82332-6. Zbl 1086.11015.
  6. 1 2 3 4 5 6 Pytheas Fogg, N. (2002). Substitutions in dynamics, arithmetics and combinatorics. Lecture Notes in Mathematics 1794. Editors Berthé, Valérie; Ferenczi, Sébastien; Mauduit, Christian; Siegel, A. Berlin: Springer-Verlag. ISBN 3-540-44141-7. Zbl 1014.11015.
  7. Berstel, J.; Séébold, P. (1994), "A remark on morphic Sturmian words", RAIRO, Inform. Théor. Appl. 2 8 (3-4): 255–263, ISSN 0988-3754, Zbl 0883.68104
  8. J. Bernoulli III, Sur une nouvelle espece de calcul, Recueil pour les Astronomes, vol. 1, Berlin, 1772, pp. 255–284
  9. Morse, M.; Hedlund, G. A. (1940). "Symbolic Dynamics II. Sturmian Trajectories". American Journal of Mathematics 62 (1): 1–42. doi:10.2307/2371431. JSTOR 2371431.

Further reading

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