Tribonacci Word

In mathematics, the Rauzy fractal is a fractal set associated with the Tribonacci substitution

: $s(1)=12,\ s(2)=13,\ s(3)=1 \,.$

It was studied in 1981 by Gérard Rauzy, with the idea of generalizing the dynamic properties of the Fibonacci morphism.
That fractal set can be generalized to other maps over a 3-letter alphabet, generating other fractal sets with interesting properties, such as periodic tiling of the plane and self-similarity in three homothetic parts.

Definitions

Tribonacci word

The infinite tribonacci word is a word constructed by iteratively applying the ''Tribonacci'' or ''Rauzy map'' : $s(1)=12$, $s(2)=13$, $s(3)=1$.Lothaire (2005) p.525Pytheas Fogg (2002) p.232 It is an example of a morphic word.
Starting from 1, the Tribonacci words are:Lothaire (2005) p.546
* $t_0 = 1$
* $t_1 = 12$
* $t_2 = 1213$
* $t_3 = 1213121$
* $t_4 = 1213121121312$
We can show that, for $n>2$, $t_n = t_t_t_$; hence the name " Tribonacci".

Fractal construction

Consider, now, the space $R^3$ with cartesian coordinates (x,y,z).
The Rauzy fractal is constructed this way:Pytheas Fogg (2002) p.233

1) Interpret the sequence of letters of the infinite Tribonacci word as a sequence of unitary vectors of the space, with the following rules (1 = direction x, 2 = direction y, 3 = direction z).

2) Then, build a "stair" by tracing the points reached by this sequence of vectors (see figure). For example, the first points are:
* $1 \Rightarrow (1, 0, 0)$
* $2 \Rightarrow (1, 1, 0)$
* $1 \Rightarrow (2, 1, 0)$
* $3 \Rightarrow (2, 1, 1)$
* $1 \Rightarrow (3, 1, 1)$
etc...Every point can be colored according to the corresponding letter, to stress the self-similarity property.

3) Then, project those points on the contracting plane (plane orthogonal to the main direction of propagation of the points, none of those projected points escape to infinity).

Properties

* Can be tiled by three copies of itself, with area reduced by factors $k$, $k^2$ and $k^3$ with $k$ solution of $k^3+k^2+k-1=0$: $\scriptstyle$.
* Stable under exchanging pieces. We can obtain the same set by exchanging the place of the pieces.
* Connected and simply connected. Has no hole.
* Tiles the plane periodically, by translation.
* The matrix of the Tribonacci map has $x^3 - x^2 - x -1$ as its characteristic polynomial. Its eigenvalues are a real number $\beta = 1.8392$, called the Tribonacci constant, a Pisot number, and two complex conjugates $\alpha$ and $\bar \alpha$ with $\alpha \bar \alpha=1/\beta$.
* Its boundary is fractal, and the Hausdorff dimension of this boundary equals 1.0933, the solution of $2, \alpha, ^+, \alpha, ^=1$.

Variants and generalization

For any unimodular substitution of Pisot type, which verifies a coincidence condition (apparently always verified), one can construct a similar set called "Rauzy fractal of the map". They all display self-similarity and generate, for the examples below, a periodic tiling of the plane.

Image:Rauzy1.png, s(1)=12, s(2)=31, s(3)=1
Image:Rauzy2.png, s(1)=12, s(2)=23, s(3)=312
Image:Rauzy3.png, s(1)=123, s(2)=1, s(3)=31
Image:Rauzy4.png, s(1)=123, s(2)=1, s(3)=1132

See also

* List of fractals

References

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External links

{{Commons category, Rauzy fractals

Topological properties of Rauzy fractals

Substitutions, Rauzy fractals and tilings, Anne Siegel, 2009

Rauzy fractals for free group automorphisms, 2006

Pisot Substitutions and Rauzy fractals

Numberphile video about Rauzy fractals and Tribonacci numbers

Fractals