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BOUNDARY PARAMETRIZATION AND THE TOPOLOGY OF TILES

Published online by Cambridge University Press:  19 October 2016

SHIGEKI AKIYAMA
Affiliation:
Institute of Mathematics, University of Tsukuba, 1-1-1 Tennodai, Tsukuba, Ibaraki, Japan (zip:350-8571) email akiyama@math.tsukuba.ac.jp
BENOÎT LORIDANT
Affiliation:
Lehrstuhl Mathematik und Statistik, Montanuniversität Leoben, Franz Josef Straße 18, A-8700 Leoben, Austria email loridant@geometrie.tuwien.ac.at
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Abstract

As an application of the boundary parametrization developed in our previous papers, we propose a new method to deduce information on the connected components of the interior of tiles. This gives a systematic way to study the topology of a certain class of self-affine tiles. An example due to Bandt and Gelbrich is examined to prove the efficiency of the method.

Type
Article
Copyright
© 2016 by The Editorial Board of the Nagoya Mathematical Journal  

1 Introduction

The topology of self-affine tiles has attracted attention from many researchers (see [Reference DekkingDek82a, Reference KenyonKen92, Reference Gröchenig and HaasGH94, Reference Lagarias and WangLW96b, Reference Bandt and GelbrichBG94, Reference Bandt and WangBW01]). This is strongly motivated by the construction of Markov partitions (see [Reference SinaĭSin68, Reference Adler and WeissAW70, Reference BowenBow70, Reference BowenBow78, Reference AdlerAdl98]). After some pioneering works (see [Reference DekkingDek82b, Reference KenyonKen92]), dual tilings of $\unicode[STIX]{x1D6FD}$ -numeration (see [Reference ThurstonThu89, Reference PraggastisPra92]) and geometric realizations of Pisot substitutions (see [Reference RauzyRau82, Reference Arnoux and ItoAI01]) were systematically studied. The topology of self-affine tiles also shows up in the study of mathematical models of quasicrystals, which initiated a field of research called “mathematics of aperiodic order”, going back to Penrose’s construction (see [Reference KenyonKen96, Reference SolomyakSol97, Reference Baake and MoodyBM04, Reference Kellendonk, Lenz and SavinienKLS15]). It further has connections to theoretical computer science and number theory, and has applications in multiresolution analysis in wavelet expansions (see [Reference Gröchenig and MadychGM92, Reference StrichartzStr93, Reference Gröchenig and HaasGH94, Reference WangWan02, Reference CurryCur06]).

We proposed in [Reference Akiyama and LoridantAL11] a standard method to parametrize the boundary of self-affine tiles, aiming at giving broad applications of its fine topological study. So far, several applications to prove or disprove the homeomorphy to the closed disk of several classes of tiles have been performed in [Reference Akiyama and LoridantAL10] and [Reference LoridantLor16]. Boundary parametrization also gives a way to approximate the boundary by a special substitution. Although such studies have already appeared in many articles, we stress that our method is a systematic approach to these questions. In this article, we wish to continue this program. We would like to present a new application of our parametrization in order to obtain information on the interior components of non-disklike tiles.

The topology of non-disklike tiles can be very intricate. We can find several, but not many, papers treating this case. Necessary conditions for the disklikeness of the interior components of self-affine tiles with disconnected interior were given in [Reference Ngai and TangNT04, Reference Ngai and TangNT05]. In [Reference Loridant and ThuswaldnerLT08, Reference Bernat, Loridant and ThuswaldnerBLT10], the interior components of the fundamental domain associated with the complex base $-2+i$ were described in terms of attractors of graph-directed self-similar sets. In [Reference Ngai and NguyenNN03], the cut points of the Heighway dragon were computed and its interior components were shown to be disklike. Moreover, the finitely many shapes of the interior components of the Levy dragon were studied in [Reference Bailey, Kim and StrichartzBKS02, Reference AlsterAls10].

Our idea is to have a close look at the set of identifications appearing in our parametrization. In this paper, we introduce a mild class of identifications which satisfies a noncrossing condition. Under this condition and from the computation of the winding number of a given point, we can define an outer identification. This identification is of special importance, because it produces an interior component by taking a pair of such identifications. Then, from the graph of identifications, we can read the distribution of interior components. The boundary of these is a Jordan closed curve given as explicit continuous images of an interval. An important point is that all of the introduced concepts are checkable by algorithm. Finally, we examine our theory by examples. Basically, we may reproduce similar results to those in [Reference Ngai and NguyenNN03] by our method. As it takes many computations for each example, we illustrate our result by giving a concrete computation of a fractal tile due to Bandt and Gelbrich. We can identify the set of cut points and pick an interior component as the interior of a concrete Jordan closed curve (see Theorem 7). We end this paper by giving some examples where the noncrossing condition is violated.

2 Fundamental facts on the boundary parametrization

We recall some fundamental facts on our parametrization method for the boundary of self-affine tiles developed in [Reference Akiyama and LoridantAL11]. Let $A$ be an expanding real $d\times d$ matrix; that is, the eigenvalues of $A$ are greater than $1$ in modulus, and ${\mathcal{D}}\subset \mathbb{R}^{d}$ a finite set. Then, there is a unique nonempty compact self-affine set  ${\mathcal{T}}={\mathcal{T}}(A,{\mathcal{D}})$ satisfying

$$\begin{eqnarray}A{\mathcal{T}}={\mathcal{T}}+{\mathcal{D}}=\mathop{\bigcup }_{a\in {\mathcal{D}}}({\mathcal{T}}+a)\end{eqnarray}$$

(see [Reference HutchinsonHut81]). ${\mathcal{T}}$ is called a self-affine tile if it is equal to the closure of its interior. It satisfies the tiling property if there is a tiling set ${\mathcal{J}}\subset \mathbb{R}^{d}$ such that

$$\begin{eqnarray}\mathop{\bigcup }_{s\in {\mathcal{J}}}({\mathcal{T}}+s)=\mathbb{R}^{d}\qquad \text{and}\qquad \unicode[STIX]{x1D706}_{d}(({\mathcal{T}}+s)\cap ({\mathcal{T}}+s^{\prime }))=0\quad \text{for all }s\neq s^{\prime }\in {\mathcal{J}}.\end{eqnarray}$$

Fundamental properties of self-affine tiles were studied in [Reference Gröchenig and HaasGH94, Reference Lagarias and WangLW96a, Reference Lagarias and WangLW96b]. If $A$ has integer coefficients and ${\mathcal{D}}\subset \mathbb{Z}^{d}$ is a complete residue system of $\mathbb{Z}^{d}$ modulo $A\mathbb{Z}^{d}$ , then ${\mathcal{T}}$ satisfies the tiling property for some sublattice ${\mathcal{J}}$ of $\mathbb{Z}^{d}$ [Reference Lagarias and WangLW97]. Conditions under which ${\mathcal{J}}=\mathbb{Z}^{d}$ are investigated in [Reference Gröchenig and HaasGH94, Reference VinceVin00]. We then say that ${\mathcal{T}}$ is an integral self-affine $\mathbb{Z}^{d}$ -tile.

A powerful tool in the study of an integral self-affine $\mathbb{Z}^{d}$ -tile ${\mathcal{T}}={\mathcal{T}}(A,{\mathcal{D}})$ is the boundary automaton. For a set $U\subset \mathbb{Z}^{d}$ , we define the following automaton $G(U)$ .

  • The set of vertices is $U$ .

  • There is an edge $s\xrightarrow[{}]{a|a^{\prime }}s^{\prime }$ ( $s,s^{\prime }\in U,a,a^{\prime }\in {\mathcal{D}}$ ) if and only if $As+a^{\prime }=s+a$ . We may simply write $s\xrightarrow[{}]{a}s^{\prime }\in G(U)$ . (This determines $a^{\prime }$ uniquely.)

Taking for $U$ the set

$$\begin{eqnarray}{\mathcal{S}}:=\{s\in \mathbb{Z}^{d}\setminus \{0\};{\mathcal{T}}\cap ({\mathcal{T}}+s)\neq \emptyset \},\end{eqnarray}$$

we obtain the boundary automaton $G({\mathcal{S}})$ . By compactness of ${\mathcal{T}}$ , ${\mathcal{S}}$ is finite. There exist algorithms to compute $G({\mathcal{S}})$ from the data $(A,{\mathcal{D}})$ (see, for example, [Reference Scheicher and ThuswaldnerST03]). This automaton gives a way to express the boundary as the attractor of a graph-directed iterated function system (GIFS) (see [Reference Mauldin and WilliamsMW88]).

Proposition 2.1. Given an integral self-affine $\mathbb{Z}^{d}$ -tile ${\mathcal{T}}={\mathcal{T}}(A,{\mathcal{D}})$ and its boundary automaton $G({\mathcal{S}})$ , the boundary $\unicode[STIX]{x2202}{\mathcal{T}}$ satisfies

$$\begin{eqnarray}\unicode[STIX]{x2202}{\mathcal{T}}=\mathop{\bigcup }_{s\in {\mathcal{S}}}B_{s},\end{eqnarray}$$

where for all $s\in {\mathcal{S}}$ ,

$$\begin{eqnarray}B_{s}=\mathop{\bigcup }_{s\xrightarrow[{}]{a}s^{\prime }\in G({\mathcal{S}})}A^{-1}(B_{s^{\prime }}+a).\end{eqnarray}$$

Moreover, $B_{s}={\mathcal{T}}\cap ({\mathcal{T}}+s)$ , and for two sequences of digits $(a_{i})_{i\geqslant 1}$ , $(a_{i}^{\prime })$ , we have

$$\begin{eqnarray}\mathop{\sum }_{n\geqslant 1}A^{-n}a_{n}=s+\mathop{\sum }_{n\geqslant 1}A^{-n}a_{n}^{\prime }\end{eqnarray}$$

if and only if there is an infinite walk

$$\begin{eqnarray}s\xrightarrow[{}]{a_{1}|a_{1}^{\prime }}s_{1}\xrightarrow[{}]{a_{2}|a_{2}^{\prime }}\cdots \in G({\mathcal{S}}).\end{eqnarray}$$

Usually, the boundary automaton contains a great deal of redundant information, due to the existence of multiple points in the tiling. This often makes $G({\mathcal{S}})$ too large to perform our parametrization method. We make the following assumptions.

Assumption 1. There exists a set ${\mathcal{R}}\subset {\mathcal{S}}$ such that the following holds.

  • $G({\mathcal{R}})$ is strongly connected; that is, its incidence matrix

    $$\begin{eqnarray}\mathbf{C}=(c_{s,s^{\prime }})_{s,s^{\prime }\in {\mathcal{R}}}\quad \text{with }c_{s,s^{\prime }}=\#\{s^{\prime }\xrightarrow[{}]{}s\in G({\mathcal{R}})\}\end{eqnarray}$$
    is irreducible.
  • $G({\mathcal{R}})$ is a GIFS for $\unicode[STIX]{x2202}{\mathcal{T}}$ ; that is,

    (2.1) $$\begin{eqnarray}\left\{\!\begin{array}{@{}rcl@{}}\unicode[STIX]{x2202}{\mathcal{T}}\ & =\ & \displaystyle \mathop{\bigcup }_{s\in {\mathcal{R}}}K_{s},\\ K_{s}\ & =\ & \displaystyle \mathop{\bigcup }_{s\xrightarrow[{}]{a}s^{\prime }\in G({\mathcal{R}})}A^{-1}(K_{s^{\prime }}+a)\quad (s\in {\mathcal{R}}).\end{array}\right.\end{eqnarray}$$
    In this case, $K_{s}\subset {\mathcal{T}}\cap ({\mathcal{T}}+s)$ .

Remark 2.2. In many applications, a subset of the contact set constructed in [Reference Gröchenig and HaasGH94]) can be used as a good candidate for such a smaller set ${\mathcal{R}}\subset {\mathcal{S}}$ and leads to the contact automaton. If $A$ is a similarity matrix of factor $\unicode[STIX]{x1D706}$ and $\unicode[STIX]{x1D6FD}$ is the largest root of the incidence matrix of the contact automaton, it is well known (see [Reference Duvall, Keesling and VinceDKV00]) that the Hausdorff dimension of $\unicode[STIX]{x2202}{\mathcal{T}}$ is given by the formula

$$\begin{eqnarray}\dim _{\text{H}}\unicode[STIX]{x2202}{\mathcal{T}}=\frac{\log \unicode[STIX]{x1D6FD}}{\log \unicode[STIX]{x1D706}}.\end{eqnarray}$$

As $G({\mathcal{R}})$ is strongly connected, there is a strictly positive left eigenvector $(u_{s})_{s\in {\mathcal{R}}}$ of length $1$ associated to the Perron–Frobenius eigenvalue $\unicode[STIX]{x1D6FD}$ of its incidence matrix. The parametrization $C:[0,1]\rightarrow \unicode[STIX]{x2202}{\mathcal{T}}$ is obtained by subdividing the interval $[0,1]$ proportionally to the automaton $G({\mathcal{R}})$ . In particular, a subinterval of length $u_{s}$ is mapped to $K_{s}$ for each $s\in {\mathcal{R}}$ . To this effect, we order the boundary pieces $K_{s}$ around the boundary, as well as the subpieces $A^{-1}(K_{s^{\prime }}+a)$ constituting $K_{s}$ .

Under the above Assumption 1, let $p=|{\mathcal{R}}|$ , and let ${\mathcal{R}}=:\{s^{1},\ldots ,s^{p}\}$ . This orders the states of $G({\mathcal{R}})$ arbitrarily from $1$ to $p$ . Similarly, for each $i\in \{1,\ldots ,p\}$ , we order all of the edges starting from $s^{i}$ arbitrarily, from $\mathbf{1}$ to $\mathbf{o}_{\mathbf{m}}$ . Here, $\mathbf{o}_{\mathbf{m}}$ is the total number of edges starting from $s^{i}$ , without reference to $i$ for the sake of simplicity. We call the resulting automaton an ordered extension of $G({\mathcal{R}})$ and write it as $G({\mathcal{R}})^{o}$ . In other words, the mapping

$$\begin{eqnarray}\begin{array}{@{}c@{}}G({\mathcal{R}})^{o}\rightarrow G({\mathcal{R}})\\ i\xrightarrow[{}]{a|a^{\prime }||\mathbf{o}}j=:(i;\mathbf{o})\mapsto s^{i}\xrightarrow[{}]{a|a^{\prime }}s^{j}\end{array}\end{eqnarray}$$

is a bijection. We can extend this mapping to the walks of arbitrary length in $G({\mathcal{R}})$ (possibly infinite walks),

$$\begin{eqnarray}\begin{array}{@{}c@{}}G({\mathcal{R}})^{o}\rightarrow G({\mathcal{R}}),\\ (i;\mathbf{o}_{\mathbf{1}},\mathbf{o}_{\mathbf{2}},\ldots )\mapsto s^{i}\xrightarrow[{}]{a_{1}}s^{j_{1}}\xrightarrow[{}]{a_{2}}s^{j_{2}}\ldots ,\end{array}\end{eqnarray}$$

whenever $i\xrightarrow[{}]{a_{1}|a_{1}^{\prime }||\mathbf{o}_{\mathbf{1}}}j_{1}\xrightarrow[{}]{a_{2}|a_{2}^{\prime }||\mathbf{o}_{\mathbf{2}}}j_{2}\ldots \in G({\mathcal{R}})^{o}$ . Finally, we define the natural onto mapping,

$$\begin{eqnarray}\begin{array}{@{}c@{}}\unicode[STIX]{x1D713}:G({\mathcal{R}})^{o}\rightarrow \unicode[STIX]{x2202}{\mathcal{T}},\\ v\mapsto \mathop{\sum }_{n\geqslant 1}A^{-n}a_{n},\end{array}\end{eqnarray}$$

whenever $v:s\xrightarrow[{}]{a_{1}|a_{1}^{\prime }||\mathbf{o}_{\mathbf{1}}}s_{1}\xrightarrow[{}]{a_{2}|a_{2}^{\prime }||\mathbf{o}_{\mathbf{2}}}s_{2}\ldots$ is an infinite walk in $G({\mathcal{R}})^{o}$ . The automaton $G({\mathcal{R}})^{o}$ induces a $\unicode[STIX]{x1D6FD}$ -number system $\unicode[STIX]{x1D719}^{(1)}:[0,1]\rightarrow G({\mathcal{R}})^{o}$ of Dumont–Thomas type [Reference Dumont and ThomasDT89]. The following compatibility conditions ensure the continuity of the parametrization.

Definition 2.3. (Compatibility conditions)

We call $G({\mathcal{R}})^{o}$ a compatible ordered extension of $G({\mathcal{R}})$ if

(2.2) $$\begin{eqnarray}\displaystyle \unicode[STIX]{x1D713}(i;\overline{\mathbf{o}_{\mathbf{m}}}) & = & \displaystyle \unicode[STIX]{x1D713}(i+1;\overline{\mathbf{1}})\quad (1\leqslant i\leqslant p-1),\end{eqnarray}$$
(2.3) $$\begin{eqnarray}\displaystyle \unicode[STIX]{x1D713}(p;\overline{\mathbf{o}_{\mathbf{m}}}) & = & \displaystyle \unicode[STIX]{x1D713}(1;\overline{\mathbf{1}}),\end{eqnarray}$$
(2.4) $$\begin{eqnarray}\displaystyle \unicode[STIX]{x1D713}(i;\mathbf{o},\overline{\mathbf{o}_{\mathbf{m}}}) & = & \displaystyle \unicode[STIX]{x1D713}(i;\mathbf{o}+\mathbf{1},\overline{\mathbf{1}})\quad (1\leqslant i\leqslant p,\mathbf{1}\leqslant \mathbf{o}<\mathbf{o}_{\mathbf{m}}).\end{eqnarray}$$

We denote by $\overline{\mathbf{o}}$ the infinite repetition of $\mathbf{o},\mathbf{o},\ldots .$ Whether an ordered extension is compatible or not can be checked algorithmically. In [Reference Akiyama and LoridantAL11], we proved the following result by taking $C:=\unicode[STIX]{x1D6F9}\circ \unicode[STIX]{x1D719}^{(1)}$ .

Theorem 2.4. [Reference Akiyama and LoridantAL11, Theorem 1]

Let ${\mathcal{T}}={\mathcal{T}}(A,{\mathcal{D}})$ be an integral self-affine $\mathbb{Z}^{d}$ -tile, and let the set ${\mathcal{R}}$ satisfy the above assumptions. Let $\unicode[STIX]{x1D6FD}$ be the Perron–Frobenius eigenvalue of the incidence matrix of $G({\mathcal{R}})$ . Moreover, suppose that there exists a compatible ordered extension of $G({\mathcal{R}})$ . Then, there exist a Hölder continuous onto mapping $C:[0,1]\rightarrow \unicode[STIX]{x2202}T$ with $C(0)=C(1)$ and a sequence $(\unicode[STIX]{x1D6E5}_{n})_{n\geqslant 0}$ of polygonal curves with the following properties.

  1. (1) $\lim _{n\rightarrow \infty }\unicode[STIX]{x1D6E5}_{n}=\unicode[STIX]{x2202}T$ (Hausdorff metric).

  2. (2) Denote by $V_{n}$ the set of vertices of $\unicode[STIX]{x1D6E5}_{n}$ . For all $n\in \mathbb{N}$ , $V_{n}\subset V_{n+1}\subset C(\mathbb{Q}(\unicode[STIX]{x1D6FD})\cap [0,1])$ (i.e., the vertices have $\mathbb{Q}(\unicode[STIX]{x1D6FD})$ -addresses in the parametrization).

Remark 2.5. The polygonal approximations $\unicode[STIX]{x1D6E5}_{n}$ appear in a natural way together with the parametrization. $\unicode[STIX]{x1D6E5}_{0}$ is obtained by joining by straight line segments the points

$$\begin{eqnarray}\unicode[STIX]{x1D713}(1;\overline{\mathbf{1}}),\unicode[STIX]{x1D713}(2;\overline{\mathbf{1}}),\ldots ,\unicode[STIX]{x1D713}(p;\overline{\mathbf{1}}),\unicode[STIX]{x1D713}(1;\overline{\mathbf{1}})\end{eqnarray}$$

in this order. In general, let $w_{1}^{(n)},\ldots ,w_{m_{n}}^{(n)}$ be the walks of length $n$ in the automaton $G({\mathcal{R}})^{o}$ , written in the lexicographical order, from $(1;\underbrace{\mathbf{1},\ldots ,\mathbf{1}}_{n\,\text{times}})$ to $(p;\underbrace{\mathbf{o}_{\mathbf{m}},\ldots ,\mathbf{o}_{\mathbf{m}}}_{n\,\text{times}})$ . Let us denote by $(i;\mathbf{o}_{\mathbf{1}},\ldots ,\mathbf{o}_{\mathbf{n}})\& \overline{\mathbf{1}}$ the concatenated walk $(i;\mathbf{o}_{\mathbf{1}},\ldots ,\mathbf{o}_{\mathbf{n}},\overline{\mathbf{1}})$ . Then, $\unicode[STIX]{x1D6E5}_{n}$ is obtained by joining by straight line segments the points

$$\begin{eqnarray}\unicode[STIX]{x1D713}(w_{1}^{(n)}\& \overline{\mathbf{1}}),\ldots ,\unicode[STIX]{x1D713}(w_{m_{n}}^{(n)}\& \overline{\mathbf{1}}),\unicode[STIX]{x1D713}(w_{1}^{(n)}\& \overline{\mathbf{1}})\end{eqnarray}$$

in this order. Each vertex of $\unicode[STIX]{x1D6E5}_{n}$ corresponds to an infinite walk ending up in a cycle of $G({\mathcal{R}})$ . Thus, these are images of fixed points of contractions,

$$\begin{eqnarray}(f_{a_{1}}\circ \ldots \circ f_{a_{l}})\left(\text{Fix}(f_{a_{l+1}}\circ \ldots \circ f_{a_{l+n}})\right),\end{eqnarray}$$

where $f_{a}(x):=A^{-1}(x+a)$ for each $a\in {\mathcal{D}}$ .

3 Winding number

The winding number is defined for a simple closed curve $J$ and a point $x_{0}\not \in J$ in [Reference AlexandrovAle98, Part 1, Chapter II] to show Jordan’s curve theorem.

Assumption 2. We suppose that in each step of the approximation, our standard parametrization gives a simple closed polygonal curve $\unicode[STIX]{x1D6E5}_{n}$ .

This was shown to be the case for many examples, as in [Reference Akiyama and LoridantAL11] or at the end of this article. Then, we can employ the same definition

$$\begin{eqnarray}W(x_{0},\unicode[STIX]{x2202}{\mathcal{T}})=\frac{1}{2\unicode[STIX]{x1D70B}}\int _{\unicode[STIX]{x2202}{\mathcal{T}}}d(angle(x-x_{0}))\end{eqnarray}$$

for the winding number of $x_{0}$ around $J=\unicode[STIX]{x2202}{\mathcal{T}}$ , where the right-hand side is the limit as the broken lines $\unicode[STIX]{x1D6E5}_{n}$ converge to the boundary in the Hausdorff metric. Since $\{x_{0}\}$ and $\unicode[STIX]{x2202}{\mathcal{T}}$ are closed sets, they are separated by a positive distance if $x_{0}\not \in \unicode[STIX]{x2202}{\mathcal{T}}$ . Therefore, if the approximation of $\unicode[STIX]{x2202}{\mathcal{T}}$ by broken lines is fine enough, then $W(x_{0},\unicode[STIX]{x2202}{\mathcal{T}})$ is computed as a finite sum and the above $W(x_{0},\unicode[STIX]{x2202}{\mathcal{T}})$ is well-defined. Clearly, $W(x_{0},\unicode[STIX]{x2202}{\mathcal{T}})=1$ (resp. 0) if $x_{0}$ is an inner point of ${\mathcal{T}}$ (resp. outside of ${\mathcal{T}}$ ).

Using the encircling method introduced by Akiyama and Sadahiro in [Reference Akiyama and SadahiroAS98], we can give a covering of $\unicode[STIX]{x2202}{\mathcal{T}}$ by a finite number of disks whose union does not contain $x_{0}$ . By this method, we can deduce how many steps of approximation by broken lines are necessary to compute the winding number $W(x_{0},\unicode[STIX]{x2202}{\mathcal{T}})$ when $x_{0}\not \in \unicode[STIX]{x2202}{\mathcal{T}}$ . This gives an easy application of the boundary parametrization, described by the following theorem. Given a self-affine tile ${\mathcal{T}}$ satisfying Assumptions 1 and 2, and $x_{0}\in \unicode[STIX]{x2202}{\mathcal{T}}$ , a computer calculation can decide whether $x_{0}$ is an inner point of ${\mathcal{T}}$ or of $\mathbb{R}^{2}\setminus {\mathcal{T}}$ .

Theorem 1. For a given point $x_{0}\not \in \unicode[STIX]{x2202}T$ , there is an algorithm to tell whether $x_{0}$ is an inner point of ${\mathcal{T}}$ or of $\mathbb{R}^{2}\setminus {\mathcal{T}}$ .

Proof. Since $A$ is an expanding matrix, we can find $k>0$ and $0<\unicode[STIX]{x1D706}<1$ such that $A^{-k}\mathbb{D}(0;1)\subset \unicode[STIX]{x1D706}\mathbb{D}(0;1)$ . Here, $\mathbb{D}(0;1)$ denotes the closed disk of center $0$ and radius $1$ . For the sake of simplicity, we write the proof under the assumption that $k=1$ . If $k>1$ , the argument below remains true by taking $A^{\prime }:=A^{k}$ and ${\mathcal{D}}^{\prime }={\mathcal{D}}+A{\mathcal{D}}+\cdots +A^{k-1}{\mathcal{D}}$ . Note that the associated tile ${\mathcal{T}}^{\prime }$ satisfies ${\mathcal{T}}^{\prime }={\mathcal{T}}$ .

Since ${\mathcal{T}}$ is compact, there is $r>0$ such that ${\mathcal{T}}\subset \mathbb{D}(0;r)=:\mathbb{D}_{r}$ . In particular, for all $m\geqslant 0$ ,

$$\begin{eqnarray}A^{-m}{\mathcal{T}}\subset A^{-m}\mathbb{D}_{r}\subset \unicode[STIX]{x1D706}^{m}\mathbb{D}_{r},\end{eqnarray}$$

the latter set being a closed disk of diameter $2r\unicode[STIX]{x1D706}^{m}$ . We show that $W(x_{0},\unicode[STIX]{x1D6E5}_{m})=W(x_{0},\unicode[STIX]{x2202}{\mathcal{T}})$ as soon as $m$ satisfies

$$\begin{eqnarray}2r\unicode[STIX]{x1D706}^{m}<\text{dist}(x_{0},\unicode[STIX]{x2202}{\mathcal{T}}).\end{eqnarray}$$

Indeed, iterating (2.1), for all $m\geqslant 1$ , we can write

(3.1) $$\begin{eqnarray}\displaystyle \left\{\begin{array}{@{}rcl@{}}\unicode[STIX]{x2202}{\mathcal{T}}\ & =\ & \displaystyle \mathop{\bigcup }_{s\in {\mathcal{R}}}K_{s},\\ K_{s}\ & =\ & \displaystyle \mathop{\bigcup }_{s\xrightarrow[{}]{a_{1}}s_{1}\xrightarrow[{}]{a_{2}}\cdots \xrightarrow[{}]{a_{m}}s_{m}\in G({\mathcal{R}})}\\ \ & \ & \qquad \left(A^{-m}K_{s_{m}}+A^{-1}a_{1}+\cdots +A^{-m}a_{m}\right)\quad (s\in {\mathcal{R}}).\end{array}\right. & & \displaystyle\end{eqnarray}$$

Using that $K_{s}\subset {\mathcal{T}}\subset \mathbb{D}_{r}$ for all $s\in {\mathcal{R}}$ , we obtain for all $m\geqslant 1$ that

$$\begin{eqnarray}\unicode[STIX]{x2202}{\mathcal{T}}\subset F_{m}:=\mathop{\bigcup }_{s\in {\mathcal{R}}}\mathop{\bigcup }_{s\xrightarrow[{}]{a_{1}}s_{1}\xrightarrow[{}]{a_{2}}\cdots \xrightarrow[{}]{a_{m}}s_{m}\in G({\mathcal{R}})}\left(\unicode[STIX]{x1D706}^{m}\mathbb{D}_{r}+A^{-1}a_{1}+\cdots +A^{-m}a_{m}\right).\end{eqnarray}$$

Therefore,

$$\begin{eqnarray}\displaystyle \text{dist}\left(x_{0},F_{m}\right) & = & \displaystyle \text{dist}\left(x_{0},\mathop{\bigcup }_{s\in {\mathcal{R}}}\mathop{\bigcup }_{s\xrightarrow[{}]{a_{1}}s_{1}\xrightarrow[{}]{a_{2}}\cdots \xrightarrow[{}]{a_{m}}s_{m}\in G({\mathcal{R}})}\right.\nonumber\\ \displaystyle & & \displaystyle \quad \qquad \left.\times \left(\unicode[STIX]{x1D706}^{m}\mathbb{D}_{r}+A^{-1}a_{1}+\cdots +A^{-m}a_{m}\right)\right)\nonumber\\ \displaystyle & = & \displaystyle \text{min}\left\{\text{dist}\left(x_{0},\unicode[STIX]{x1D706}^{m}\mathbb{D}_{r}+A^{-1}a_{1}+\cdots +A^{-m}a_{m}\right);\right.\nonumber\\ \displaystyle & & \displaystyle \qquad \left.s\in {\mathcal{R}},s\xrightarrow[{}]{a_{1}}s_{1}\xrightarrow[{}]{a_{2}}\cdots \xrightarrow[{}]{a_{m}}s_{m}\in G({\mathcal{R}})\right\}\nonumber\\ \displaystyle & {\geqslant} & \displaystyle \text{dist}(x_{0},\unicode[STIX]{x2202}{\mathcal{T}})-\text{diam}(\unicode[STIX]{x1D706}^{m}\mathbb{D}_{r})=\text{dist}(x_{0},\unicode[STIX]{x2202}{\mathcal{T}})-2r\unicode[STIX]{x1D706}^{m}.\nonumber\end{eqnarray}$$

The inequality is justified as follows. Each disk appearing in the lower union of (3.1) intersects $\unicode[STIX]{x2202}T$ , because

(3.2) $$\begin{eqnarray}A^{-1}a_{1}+\cdots +A^{-m}a_{m}+A^{-m}{\mathcal{T}}\subset A^{-1}a_{1}+\cdots +A^{-m}a_{m}+\unicode[STIX]{x1D706}^{m}\mathbb{D}_{r}\end{eqnarray}$$

and $(a_{1},\ldots ,a_{m})$ is a sequence of digits labeling a walk in $G({\mathcal{R}})$ .

By this inequality, the assumption that $x_{0}\notin \unicode[STIX]{x2202}{\mathcal{T}}$ ensures the existence of $m\geqslant 1$ such that $\text{dist}(x_{0},F_{m})>0$ . Let $N\geqslant 1$ be the least integer such that $x_{0}\notin F_{N}$ .

Now, let $w:=w_{k}^{(N)}:s\xrightarrow[{}]{a_{1}}s_{1}\xrightarrow[{}]{a_{2}}\cdots \xrightarrow[{}]{a_{N}}s_{N}$ be a walk of length $N$ in $G({\mathcal{R}})$ for some $1\leqslant k\leqslant m_{N}$ , as defined in Remark 2.5. The associated segment

$$\begin{eqnarray}\left[\unicode[STIX]{x1D713}(P(w\& \overline{\mathbf{1}})),\unicode[STIX]{x1D713}(P(w\& \overline{\mathbf{o}_{\mathbf{m}}}))\right]=\left[\unicode[STIX]{x1D713}(P(w_{k}^{(N)}\& \overline{\mathbf{1}})),\unicode[STIX]{x1D713}(P(w_{k+1}^{(N)}\& \overline{\mathbf{1}}))\right]\subset \unicode[STIX]{x1D6E5}_{N}\end{eqnarray}$$

is a subset of the disk $F_{w}:=\unicode[STIX]{x1D706}^{N}\mathbb{D}_{r}+A^{-1}a_{1}+\cdots +A^{-N}a_{N}$ , because its endpoints belong to this convex set by (3.2). (We define $w_{m_{N}+1}^{(N)}:=w_{1}^{(N)}$ .) Since these segments build up $\unicode[STIX]{x1D6E5}_{N}$ , we obtain that $\unicode[STIX]{x1D6E5}_{N}\subset F_{N}$ . In particular,

$$\begin{eqnarray}\text{dist}(x_{0},\unicode[STIX]{x1D6E5}_{N})>0.\end{eqnarray}$$

Moreover, for any $w:=s\xrightarrow[{}]{a_{1}}s_{1}\xrightarrow[{}]{a_{2}}\cdots \xrightarrow[{}]{a_{N}}s_{N}$ as above and any $w^{\prime }:=s\xrightarrow[{}]{a_{1}}s_{1}\xrightarrow[{}]{a_{2}}\cdots \xrightarrow[{}]{a_{n}}s_{n}$ with $n\geqslant N$ (that is, $w^{\prime }$ starts like $w$ ), the corresponding segment

$$\begin{eqnarray}\left[\unicode[STIX]{x1D713}(P(w^{\prime }\& \overline{\mathbf{1}})),\unicode[STIX]{x1D713}(P(w^{\prime }\& \overline{\mathbf{o}_{\boldsymbol{ m}}}))\right]\subset \unicode[STIX]{x1D6E5}_{N}\end{eqnarray}$$

remains in the disk $F_{w}$ , again by (3.2). It follows that the simple closed curve $\unicode[STIX]{x1D6E5}_{n}$ can be obtained by continuous deformation (homotopy) of $\unicode[STIX]{x1D6E5}_{N}$ inside $F_{N}$ . This homotopy fixes the vertices of $\unicode[STIX]{x1D6E5}_{N}$ .

We conclude that for all $n\geqslant N$ ,

$$\begin{eqnarray}W(x_{0},\unicode[STIX]{x1D6E5}_{n})=W(x_{0},\unicode[STIX]{x1D6E5}_{N})=W(x_{0},\unicode[STIX]{x2202}{\mathcal{T}}).\end{eqnarray}$$

This gives an algorithm to compute $W(x_{0},\unicode[STIX]{x2202}{\mathcal{T}})$ and decide whether $x_{0}$ is an inner point of ${\mathcal{T}}$ or of $\mathbb{R}\setminus {\mathcal{T}}$ .

Indeed, we can check by computer whether $x_{0}\in F_{m}$ or $x_{0}\notin F_{m}$ for $m=1,2,\ldots$ . Note that suitable $\unicode[STIX]{x1D706}$ and $r$ are computable from the matrix $A$ and the digit set ${\mathcal{D}}$ . The least $m\geqslant 1$ such that $x_{0}\notin F_{m}$ defines $N$ . Then, we can compute the winding number $W(x_{0},\unicode[STIX]{x1D6E5}_{N})$ . $\unicode[STIX]{x1D6E5}_{N}$ is a simple closed polygonal curve, whose vertices are computable because they are images of fixed points of contractions,

$$\begin{eqnarray}(f_{a_{1}}\circ \ldots \circ f_{a_{l}})\left(\text{Fix}(f_{a_{l+1}}\circ \ldots \circ f_{a_{l+n}})\right),\end{eqnarray}$$

where $f_{a}(x):=A^{-1}(x+a)$ for each $a\in {\mathcal{D}}$ (see Remark 2.5). The value ( $0$ or $1$ ) of this winding number indicates whether $x_{0}$ is an inner point of ${\mathcal{T}}$ or of its complement.◻

Note that without the knowledge of $x_{0}\not \in \unicode[STIX]{x2202}{\mathcal{T}}$ , there is no algorithm to tell whether a point lies in ${\mathcal{T}}$ or not [Reference DubeDub93].

4 Outer identifications

Let $C:[0,1]\rightarrow \unicode[STIX]{x2202}{\mathcal{T}}$ be the parametrization with $C(0)=C(1)$ .

Definition 4.1. A pair $(a,b)$ with $0<a<b<1$ is an identification if $C(a)=C(b)$ . Two identifications $(a,b)$ and $(c,d)$ are crossing if either $a<c<b<d$ or $c<a<d<b$ holds.

In this paper, we restrict to the case where no pairs of identifications are crossing. This is not the general case, as we mention in Section 7.

In order to classify the identifications, we need to compute the winding number of points with respect to subsets of the boundary $\unicode[STIX]{x2202}{\mathcal{T}}$ . We denote by $(\unicode[STIX]{x1D6E5}_{n})_{n\geqslant 0}$ the sequence of simple closed polygonal curves approximating $\unicode[STIX]{x2202}{\mathcal{T}}$ . For each $n$ , the vertices of $\unicode[STIX]{x1D6E5}_{n}$ are points $C(t_{k}^{(n)})\in \unicode[STIX]{x2202}{\mathcal{T}},k\in \{0,\ldots ,m_{n}\},$ where $0=t_{0}^{(n)}<t_{1}^{(n)}<\cdots <t_{m_{n}}^{(n)}=1$ . For an identification $(a,b)$ , we define

$$\begin{eqnarray}a_{n}:=\text{max}\{t_{k}^{(n)};t_{k}^{(n)}\leqslant a\},\quad b_{n}:=\text{min}\{t_{k}^{(n)};t_{k}^{(n)}\geqslant b\},\end{eqnarray}$$

Note that $(a_{n})_{n\geqslant 0}$ is increasing and converges to $a$ , whereas $(b_{n})_{n\geqslant 0}$ is decreasing and converges to $b$ . Let us consider

  1. (i) $C_{n}(a_{n},b_{n})$ , the closed polygonal curve obtained by joining the points $C(t_{k}^{(n)})$ consecutively for $a_{n}\leqslant t_{k}^{(n)}\leqslant b_{n}$ , and adding the segment $[C(b_{n}),C(a_{n})]$ ;

  2. (ii) $D_{n}(a_{n},b_{n})$ , the closed polygonal curve

    $$\begin{eqnarray}D_{n}(a_{n},b_{n})=\left(\unicode[STIX]{x1D6E5}_{n}\setminus C_{n}(a_{n},b_{n})\right)\,\cup \,[C(b_{n}),C(a_{n})].\end{eqnarray}$$

The curve $C_{n}(a_{n},b_{n})\setminus ]\!C(b_{n}),C(a_{n})\![$ is a subset of $\unicode[STIX]{x1D6E5}_{n}$ ; thus, $C_{n}(a_{n},b_{n})$ may intersect itself only along the added segment $[C(b_{n}),C(a_{n})]$ . This also holds for $D_{n}(a_{n},b_{n})$ . Moreover, in the Hausdorff metric, $(C_{n}(a_{n},b_{n}))_{n\geqslant 0}$ converges to $C([a,b])$ , while $(D_{n}(a_{n},b_{n}))_{n\geqslant 0}$ converges to $C([0,a])\cup C([b,1])$ .

Lemma 4.2. Let $y\in \mathbb{R}^{2}\setminus C([a,b])$ . Then, the sequence $(W(y,C_{n}(a_{n},b_{n})))_{n\geqslant 0}$ is eventually well-defined and constant of value either $0$ or $1$ .

Proof. We denote by $\text{dist}_{H}(A,B)$ the Hausdorff distance between two nonempty compact sets $A,B$ of $\mathbb{R}^{2}$ . Let $y\in \mathbb{R}^{2}\setminus C([a,b])$ , and let $\unicode[STIX]{x1D716}>0$ , such that $\text{dist}_{H}(\{y\},C([a,b]))>\unicode[STIX]{x1D716}$ . Let us choose integers as follows.

  • $N_{1}$ such that the Hausdorff distances

    $$\begin{eqnarray}\displaystyle & & \displaystyle \text{dist}_{H}(\unicode[STIX]{x1D6E5}_{n},\unicode[STIX]{x2202}{\mathcal{T}}),\quad \text{dist}_{H}(C_{n}(a_{n},b_{n}),C([a,b])),\quad \nonumber\\ \displaystyle & & \displaystyle \text{dist}_{H}(D_{n}(a_{n},b_{n}),C([0,a])\cup C([b,1]))\nonumber\end{eqnarray}$$
    are at most $\unicode[STIX]{x1D716}/4$ for all $n\geqslant N_{1}$ .
  • $N_{2}$ such that for all $n\geqslant N_{2}$ , the points $C(a_{n})$ and $C(b_{n})$ belong to the disk $\mathbb{D}(C(a);\unicode[STIX]{x1D716}/4)$ of center $C(a)=C(b)$ and radius $\unicode[STIX]{x1D716}/4$ .

Let $N:=\text{max}\{N_{1},N_{2}\}$ . Note that, by assumption, $y$ belongs to $\mathbb{R}^{2}\setminus C_{n}(a_{n},b_{n})$ for all $n\geqslant N$ .

We now fix $n\geqslant N$ . We show that $C_{n+1}(a_{n+1},b_{n+1})$ is obtained from $C_{n}(a_{n},b_{n})$ by continuous deformation (homotopy) avoiding $y$ . Indeed, the simple polygonal arcs

$$\begin{eqnarray}C_{n}(a_{n},b_{n})\setminus ]\!C(b_{n}),C(a_{n})\![\qquad \!\text{and}\qquad \!C_{n+1}(a_{n+1},b_{n+1})\setminus ]\!C(b_{n+1}),C(a_{n+1})\![\end{eqnarray}$$

are at most at $\unicode[STIX]{x1D716}/2$ -Hausdorff distance from each other; thus, there is a homotopy between these arcs that does not intersect the disk $\mathbb{D}(y;\unicode[STIX]{x1D716}/4)$ . Moreover, there exists a homotopy between the segments

$$\begin{eqnarray}[C(b_{n}),C(a_{n})]\qquad \text{and}\qquad [C(b_{n+1}),C(a_{n+1})]\end{eqnarray}$$

inside the disk $\mathbb{D}(C(a);\unicode[STIX]{x1D716}/2)$ , thus avoiding the disk $\mathbb{D}(y;\unicode[STIX]{x1D716}/4)$ .

We infer the existence of a homotopy between the polygonal curves $C_{n}(a_{n},b_{n})$ and $C_{n+1}(a_{n+1},b_{n+1})$ that avoids the point $y$ . Therefore, the winding number remains constant:

$$\begin{eqnarray}W(y,C_{n}(a_{n},b_{n}))=W(y,C_{n+1}(a_{n+1},b_{n+1})),\end{eqnarray}$$

for all $n\geqslant N$ .

We finally show that the winding number for $n=N$ is either $0$ or $1$ . This is due to the fact that $y$ lies outside the disk $\mathbb{D}(C(a);\unicode[STIX]{x1D716}/4)$ where the polygonal closed curve $C_{N}(a_{N},b_{N})$ may intersect itself.◻

A similar result holds for the winding numbers with respect to $D_{n}(a_{n},b_{n})$ .

Lemma 4.3. Let $y\in \mathbb{R}^{2}\setminus \left(C([0,a])\cup C([b,1])\right)$ . Then, the sequence $(W(y,D_{n}(a_{n},b_{n})))_{n\geqslant 0}$ is eventually well-defined and constant of value either $0$ or $1$ .

By the above lemmata, we can define the winding numbers

$$\begin{eqnarray}\displaystyle & & \displaystyle W(y,C([a,b])):=\lim _{n\rightarrow \infty }W(y,C_{n}(a_{n},b_{n}))\qquad \text{and}\quad \nonumber\\ \displaystyle & & \displaystyle W(y,C([0,a])\cup C([b,1])):=\lim _{n\rightarrow \infty }W(y,D_{n}(a_{n},b_{n})).\nonumber\end{eqnarray}$$

The next lemma asserts that the winding numbers defined with respect to the above fractal curves have the same expected properties as winding numbers with respect to polygonal curves.

Lemma 4.4. Let $L$ be either the curve $C([a,b])$ or the curve $C([0,a])\cup C([b,1])$ . Let $x,y\in \mathbb{R}^{2}$ belong to the same connected component of $\mathbb{R}^{2}\setminus L$ . Then,

$$\begin{eqnarray}W(x,L)=W(y,L).\end{eqnarray}$$

Proof. In the following, for $n\geqslant 0$ , $L_{n}$ denotes the polygonal curve $C_{n}(a_{n},b_{n})$ in the case $L=C([a,b])$ ) and the polygonal curve $D_{n}(a_{n},b_{n})$ in the case $L=C([0,a])\cup C([b,1])$ .

By Lemmas 4.2 and 4.3, there exists $n_{0}$ such that, for all $n\geqslant n_{0}$ , we have

$$\begin{eqnarray}W(x,L_{n})=W(x,L)\quad \text{and}\quad W(y,L_{n})=W(y,L).\end{eqnarray}$$

Since $x$ and $y$ belong to the same component $U$ of $\mathbb{R}^{2}\setminus L$ , there exists a simple arc $l:[0,1]\rightarrow U$ satisfying $l(0)=x$ and $l(1)=y$ . Let $\unicode[STIX]{x1D716}>0$ , such that $\text{dist}_{H}(l([0,1]),L)>\unicode[STIX]{x1D716}$ . Remember that $(L_{n})_{n\geqslant 0}$ converges to $L$ in Hausdorff distance. Thus, there exists $n_{1}\geqslant n_{0}$ satisfying

$$\begin{eqnarray}\text{dist}_{H}(l([0,1]),L_{n_{1}})\geqslant \unicode[STIX]{x1D716}.\end{eqnarray}$$

Therefore, $x$ and $y$ belong to the same connected component of $\mathbb{R}^{2}\setminus L_{n_{1}}$ . As $L_{n_{1}}$ is a polygonal curve, this implies that $W(x,L_{n_{1}})=W(y,L_{n_{1}})$ , and hence that $W(x,L)=W(y,L)$ .◻

Since we assume that no pairs of identifications are crossing, the following proposition holds (see Figure 1).

Figure 1. Proposition 4.5. In the above two cases, $C([a,b])$ is shown solid and $C([0,a])\cup C([b,1])$ is shown dashed. The intersection point is $C(a)=C(b)$ .

Proposition 4.5. There exist $w_{a,b},w_{a,b}^{\prime }\in \{0,1\}$ such that for all $t\in [0,a)\cup (b,1]$ and for all $t^{\prime }\in (a,b)$ ,

$$\begin{eqnarray}W(C(t),C([a,b]))=w_{a,b}\qquad \text{and}\qquad W(C(t^{\prime }),C([0,a])\cup C([b,1]))=w_{a,b}^{\prime }.\end{eqnarray}$$

Proof. We call $K:=C([a,b])$ and $J:=C([0,a]\cup [b,1])$ the connected subcurves of $\unicode[STIX]{x2202}{\mathcal{T}}$ . By the noncrossing assumption, we have

$$\begin{eqnarray}\displaystyle K\cap J & = & \displaystyle \{C(a)=C(b)\}=:\{x\},\nonumber\\ \displaystyle K & \subset & \displaystyle (\mathbb{R}^{2}\setminus J)\cup \{x\},\nonumber\\ \displaystyle J & \subset & \displaystyle (\mathbb{R}^{2}\setminus K)\cup \{x\}.\nonumber\end{eqnarray}$$

Note that $K\setminus \{x\}=C((a,b))$ ; hence, this set is connected. Similarly, $J\setminus \{x\}$ is connected. We call

  • $U$ the connected component of $\mathbb{R}^{2}\setminus J$ such that $K\setminus \{x\}\subset U$ ;

  • $V$ the connected component of $\mathbb{R}^{2}\setminus K$ such that $J\setminus \{x\}\subset V$ .

In particular, $K\subset U\cup \{x\}$ and $J\subset V\cup \{x\}$ . The proposition now follows from Lemma 4.4.◻

Definition 4.6. Let $(a,b)$ be an identification, and let $w_{a,b}$ be as in Proposition 4.5. We say that  $(a,b)$  is an outer identification if $w_{a,b}=w_{a,b}^{\prime }=0$ .

This case is illustrated on the left side of Figure 1.

Theorem 2. Given an identification of $C$ , we can decide whether it is an outer identification by an algorithm.

Proof. We show that we can compute $w_{a,b}$ (and similarly $w_{a,b}^{\prime }$ ) by an algorithm. This is proved by a slight modification of the proof of Theorem 1. Let $y:=C(t)$ for some $t\in [0,a)\cup (b,1]$ . Let $u_{n},v_{n}$ be the walks in $G({\mathcal{R}}^{o})$ satisfying

$$\begin{eqnarray}\unicode[STIX]{x1D719}^{(1)}(u_{n})=a_{n},\qquad \unicode[STIX]{x1D719}^{(1)}(v_{n})=b_{n}.\end{eqnarray}$$

Here, $\unicode[STIX]{x1D719}^{(1)}$ is the Dumont–Thomas number system defined on p. 5. Let $k,\unicode[STIX]{x1D706},r$ be as in the proof of Theorem 1. Again, we assume, without loss of generality, that $k=1$ . Then, for all $m\geqslant 1$ ,

$$\begin{eqnarray}\displaystyle C([a,b])\subset F_{m}^{\prime } & := & \displaystyle \mathop{\bigcup }_{s\in {\mathcal{R}}}\mathop{\bigcup }_{\substack{ w:=s\xrightarrow[{}]{d_{1}|\mathbf{o}_{\mathbf{1}}}s_{1}\xrightarrow[{}]{d_{2}|\mathbf{o}_{\mathbf{2}}}\cdots \xrightarrow[{}]{d_{m}|\mathbf{o}_{\mathbf{m}}}s_{m}\in G({\mathcal{R}})^{o}, \\ {u_{n}\leqslant }_{lex}w\leqslant _{lex}v_{n}}}\nonumber\\ \displaystyle & & \displaystyle \times \left(\unicode[STIX]{x1D706}^{m}\mathbb{D}_{r}+A^{-1}d_{1}+\cdots +A^{-m}d_{m}\right).\nonumber\end{eqnarray}$$

The following arguments from the proof of Theorem 1 remain valid:

$$\begin{eqnarray}\text{dist}(y,F_{m}^{\prime })\geqslant \text{dist}(y,C([a,b]))-2r\unicode[STIX]{x1D706}^{m},\end{eqnarray}$$

and we call $N\geqslant 1$ the least integer satisfying $y\notin F_{N}^{\prime }$ . Then, $\text{dist}(y,C_{N}(a_{N},b_{N}))>0$ , because $C_{N}(a_{N},b_{N})\subset F_{N}^{\prime }$ . Moreover, for any $n\geqslant N$ , the simple polygonal path $C_{n}(a_{n},b_{n})\setminus [C(a_{n}),C(b_{n})]$ (as well as the segment $[C(a_{n}),C(b_{n})]$ ) can be obtained by continuous deformation (homotopy) of $C_{N}(a_{N},b_{N})\setminus [C(a_{N}),C(b_{N})]$ (or of the segment $[C(a_{N}),C(b_{N})]$ , respectively) inside $F_{N}^{\prime }$ . These homotopies fix the vertices of $C_{N}(a_{N},b_{N})$ .

We conclude that for all $n\geqslant N$ ,

$$\begin{eqnarray}W(y,C_{n}(a_{n},b_{n}))=W(y,C_{N}(a_{N},b_{N}))=W(y,C([a,b])).\end{eqnarray}$$

The algorithm for the computation of $w_{a,b}=W(y,C([a,b]))$ reads as follows. We can check by computer whether $y\in F_{m}^{\prime }$ or not for $m=1,2,\ldots .$ The least $m\geqslant 1$ such that $y\notin F_{m}^{\prime }$ defines $N$ . Then, we compute the winding number $W(y,C_{n}(a_{n},b_{n}))$ of $y$ with respect to the closed polygonal curve $C_{n}(a_{n},b_{n})$ . Its value is equal to $w_{a,b}$ .◻

5 Connected components of ${\mathcal{T}}^{\circ }$

In this section, we show that the set of outer identifications is in one to one correspondence with the set of connected components of ${\mathcal{T}}^{\circ }$ .

Theorem 3. Suppose that there are no crossing pairs of identifications. Moreover, let $(a,b)$ and $(c,d)$ be two outer identifications with $a<c<d<b$ such that there is no further identification $(x,y)$ with $a<x<y<c$ , $d<x<y<b$ or $a<x<c<d<y<b$ . Then, $C([a,c])\cup C([d,b])$ is a simple closed curve, and it is the boundary of a connected component of ${\mathcal{T}}^{\circ }$ . Therefore, the closure of this component is homeomorphic to a closed disk.

This theorem is illustrated in Figure 2.

Figure 2. Theorem 3. $C([a,c])$ is shown dotted and $C([d,b])$ is shown dashed. The intersection points correspond to $C(a)=C(b)$ and $C(c)=C(d)$ .

Proof. By assumption, the parametrization $C$ is injective on each segment $[a,c]$ and $[d,b]$ , and the simple closed arcs $C([a,c])$ and $C([d,b])$ meet only at the points $C(a)=C(b)$ and $C(c)=C(d)$ . It follows that $C([a,c])\cup C([d,b])$ is a simple closed curve.

We call this curve $L$ , and call its bounded complementary component $B$ . Then, $L=\unicode[STIX]{x2202}B$ by Jordan’s curve theorem. Let us show in two steps that $B\subset \text{int}({\mathcal{T}})$ .

  1. (1) We prove that $B\cap \unicode[STIX]{x2202}{\mathcal{T}}=\emptyset$ . Otherwise, there is $t$ such that

    $$\begin{eqnarray}x_{0}:=C(t)\in B\cap \unicode[STIX]{x2202}{\mathcal{T}},\end{eqnarray}$$
    and, by definition, $t\in [0,a)\cup (c,d)\cup (b,1]$ . First, suppose that $t\in [0,a)\cup (b,1]$ . By our assumptions, we can apply Proposition 4.5 and obtain that
    $$\begin{eqnarray}W(x_{0},C([a,b]))=w_{a,b}=0=w_{c,d}=W(x_{0},C([c,d])).\end{eqnarray}$$
    However, since $x_{0}$ is in the bounded component of the simple closed curve $L$ , its winding number with respect to $L$ is $W(x_{0},L)=1$ . It follows that
    $$\begin{eqnarray}0=W(x_{0},C([a,b]))=W(x_{0},C([c,d]))+W(x_{0},L)=0+1=1,\end{eqnarray}$$
    a contradiction. Hence, $t\notin [0,a)\cup (b,1]$ . In the same way, using the fact that $w_{a,b}^{\prime }=w_{c,d}^{\prime }=0$ , one can prove that $t\notin (c,d)$ . Therefore, we conclude that $B\cap \unicode[STIX]{x2202}{\mathcal{T}}=\emptyset$ .
  2. (2) We prove that $B\cap \text{int}({\mathcal{T}})\neq \emptyset$ . Suppose, on the contrary, that $B\cap \text{int}({\mathcal{T}})=\emptyset$ . Let $x\in L\setminus \{C(a)=C(b)\}$ , and let $\unicode[STIX]{x1D716}>0$ , such that

    $$\begin{eqnarray}\mathbb{D}(x,\unicode[STIX]{x1D716})\cap C([0,a]\cup [b,1])=\mathbb{D}(x,\unicode[STIX]{x1D716})\cap C([c,d])=\emptyset .\end{eqnarray}$$
    Since $L\subset \unicode[STIX]{x2202}{\mathcal{T}}$ , we have that $\text{int}({\mathcal{T}})\cap \mathbb{D}(x,\unicode[STIX]{x1D716})\neq \emptyset$ . Let $z$ be in this intersection. Then, by assumption, $z$ is in the unbounded complementary component of the simple closed curve $L$ ; hence, $W(z,L)=0$ . Moreover,
    $$\begin{eqnarray}W(z,C([0,a]\cup [b,1]))=W(x,C([0,a]\cup [b,1]))=w_{a,b}^{\prime }=0\end{eqnarray}$$
    and
    $$\begin{eqnarray}W(z,C([c,d]))=W(x,C([c,d]))=w_{c,d}=0.\end{eqnarray}$$
    We use here the fact that $(a,b)$ and $(c,d)$ are outer identifications. Therefore,
    $$\begin{eqnarray}W(z,\unicode[STIX]{x2202}{\mathcal{T}})=W(z,C([0,a]\cup [b,1]))+W(z,L)+W(z,C([c,d]))=0.\end{eqnarray}$$
    However, since $z$ is an inner point of ${\mathcal{T}}$ , we have $W(z,\unicode[STIX]{x2202}{\mathcal{T}})=1$ , a contradiction. We conclude that $B\cap \text{int}({\mathcal{T}})\neq \emptyset$ .

This proves that $B\subset \text{int}({\mathcal{T}})$ . Consequently, $B$ is a connected component of $\text{int}({\mathcal{T}})$ , as it is an open connected set of $\text{int}({\mathcal{T}})$ whose boundary is a subset of $\unicode[STIX]{x2202}{\mathcal{T}}$ . The fact that its closure is a topological disk follows from the theorem of Schönflies.◻

6 An example from Bandt and Gelbrich

This example can be found in [Reference Bandt and GelbrichBG94] and [Reference Bandt and WangBW01, Figure 4]. We depict it with its neighbors in Figure 3.

Figure 3. Example of Bandt and Gelbrich and its lattice tiling.

Figure 4. Boundary graph of the example of Bandt and Gelbrich.

The tile ${\mathcal{T}}$ satisfies the equation

$$\begin{eqnarray}A{\mathcal{T}}=\mathop{\bigcup }_{a\in {\mathcal{D}}}({\mathcal{T}}+a),\end{eqnarray}$$

where

(6.1) $$\begin{eqnarray}A=\left(\begin{array}{@{}cc@{}}0 & 3\\ 1 & 1\end{array}\right),\qquad {\mathcal{D}}=\left\{\left(\begin{array}{@{}c@{}}0\\ 0\end{array}\right),\left(\begin{array}{@{}c@{}}1\\ 0\end{array}\right),\left(\begin{array}{@{}c@{}}-1\\ 0\end{array}\right)\right\}.\end{eqnarray}$$

The tile ${\mathcal{T}}$ has the following neighbors:

(6.2) $$\begin{eqnarray}{\mathcal{S}}=\left\{\pm \left(\begin{array}{@{}c@{}}1\\ 0\end{array}\right),\pm \left(\begin{array}{@{}c@{}}-2\\ 1\end{array}\right),\pm \left(\begin{array}{@{}c@{}}-1\\ 1\end{array}\right),\pm \left(\begin{array}{@{}c@{}}-4\\ 2\end{array}\right),\pm \left(\begin{array}{@{}c@{}}-3\\ 1\end{array}\right)\right\}.\end{eqnarray}$$

The contact automaton and the boundary automaton can be computed via well-known algorithms (see, for example, [Reference Scheicher and ThuswaldnerST03]). The boundary automaton $G({\mathcal{S}})$ is depicted in Figure 4. The contact automaton $G({\mathcal{R}})$ is the restriction of the boundary automaton to the set

(6.3) $$\begin{eqnarray}{\mathcal{R}}=\left\{\pm \left(\begin{array}{@{}c@{}}1\\ 0\end{array}\right),\pm \left(\begin{array}{@{}c@{}}-2\\ 1\end{array}\right),\pm \left(\begin{array}{@{}c@{}}-1\\ 1\end{array}\right)\right\}.\end{eqnarray}$$

As $G({\mathcal{R}})$ is the contact automaton of ${\mathcal{T}}(A,{\mathcal{D}})$ , $\unicode[STIX]{x2202}{\mathcal{T}}$ is the solution of the GIFS (2.1). Since $\text{det}(A)<0$ , the orientation of the boundary pieces changes at each iteration of (2.1). We model this flipping by doubling the number of states of the contact automaton (see also [Reference Akiyama and LoridantAL10, Section 2]) as follows.

  • For each state $s\in {\mathcal{R}}$ , we create the states $s$ and $\overline{s}$ .

  • For each transition $s\xrightarrow[{}]{a|a^{\prime }}s^{\prime }\in G({\mathcal{R}})$ , we create the transitions $s\xrightarrow[{}]{a|a^{\prime }}\overline{s^{\prime }}$ and $\overline{s}\xrightarrow[{}]{a|a^{\prime }}s^{\prime }$ .

The resulting automaton then has 12 states. It is also a GIFS for the boundary, but each boundary part $K_{s}$ is duplicated ( $K_{s}=K_{\overline{s}}$ ). This automaton can be ordered as in Figure 5 to perform the boundary parametrization. We denote by $R:=\{1,2,\ldots ,\overline{5},\overline{6}\}$ the set of states of this ordered extension $G({\mathcal{R}})^{o}$ . It follows that $\unicode[STIX]{x2202}{\mathcal{T}}$ satisfies

$$\begin{eqnarray}\left\{\!\!\!\begin{array}{@{}rcl@{}}\unicode[STIX]{x2202}{\mathcal{T}}\ & =\ & \displaystyle \mathop{\bigcup }_{i=1}^{6}K_{i},\\ K_{i}\ & =\ & \displaystyle \mathop{\bigcup }_{i\xrightarrow[{}]{a||\mathbf{o}}j\in G({\mathcal{R}})^{o}}A^{-1}(K_{j}+a)\quad (i\in R).\end{array}\right.\end{eqnarray}$$

Note that

$$\begin{eqnarray}K_{s^{1}}^{\prime }=K_{1}=K_{\overline{1}},\ldots ,K_{s^{6}}^{\prime }=K_{6}=K_{\overline{6}}.\end{eqnarray}$$

Figure 5. Ordered extension $G({\mathcal{R}})^{o}$ for the example of Bandt and Gelbrich.

The following theorem justifies Assumptions 1 and 2.

Theorem 4. Let ${\mathcal{T}}={\mathcal{T}}(A,{\mathcal{D}})$ be the self-affine tile associated to the data (6.1). Let $\unicode[STIX]{x1D6FD}:=\frac{1+\sqrt{13}}{2}$ . Then, there exist a $C:[0,1]\rightarrow \unicode[STIX]{x2202}{\mathcal{T}}$ Hölder continuous onto mapping with $C(0)=C(1)$ and a hexagon $Q\subset \mathbb{R}^{2}$ with the following properties. Let $({\mathcal{T}}_{n})_{n\geqslant 0}$ be the sequence of approximations of ${\mathcal{T}}$ associated to $Q$ ; that is, ${\mathcal{T}}_{0}:=Q$ and, for $n\geqslant 1$ , ${\mathcal{T}}_{n}$ is defined by

$$\begin{eqnarray}A{\mathcal{T}}_{n}:=\mathop{\bigcup }_{a\in {\mathcal{D}}}({\mathcal{T}}_{n-1}+a).\end{eqnarray}$$

Then, we have the following.

  1. (1) $\lim _{n\rightarrow \infty }{\mathcal{T}}_{n}={\mathcal{T}}$ and $\lim _{n\rightarrow \infty }\unicode[STIX]{x2202}{\mathcal{T}}_{n}=\unicode[STIX]{x2202}{\mathcal{T}}$ (in Hausdorff metric).

  2. (2) Denote by $V_{n}$ the set of vertices of $\unicode[STIX]{x2202}{\mathcal{T}}_{n}$ . For all $n\in \mathbb{N}$ , $V_{n}\subset V_{n+1}\subset C(\mathbb{Q}(\unicode[STIX]{x1D6FD})\cap [0,1])$ (i.e., the vertices have $\mathbb{Q}(\unicode[STIX]{x1D6FD})$ -addresses in the parametrization).

  3. (3) For all $n\geqslant 0$ , $\unicode[STIX]{x2202}{\mathcal{T}}_{n}$ is a simple closed curve.

Proof. $G({\mathcal{R}})^{o}$ is the union of two strongly connected components. Each component has the same irreducible incidence matrix $\mathbf{C}$ , whose Perron–Frobenius eigenvalue $\unicode[STIX]{x1D6FD}=\frac{1+\sqrt{13}}{2}$ is the largest root of the characteristic polynomial $x^{6}-8x^{4}+16x^{2}-9$ . Therefore, the incidence matrix $\mathbf{D}$ of $G({\mathcal{R}})^{o}$ has a strictly positive left eigenvector $\mathbf{u}=(u_{1},\ldots ,u_{6},u_{\overline{1}},\ldots ,u_{\overline{6}})$ associated to $\unicode[STIX]{x1D6FD}$ , which can be chosen such that $u_{1}+\cdots +u_{6}=1$ . This is sufficient to perform the parametrization procedure (see [Reference Akiyama and LoridantAL10] for more details). We just need to check the compatibility conditions of Definition 2.3 with $p=12$ , together with the additional compatibility condition

(6.4) $$\begin{eqnarray}\unicode[STIX]{x1D713}(6;\overline{\mathbf{o}_{\mathbf{m}}})=\unicode[STIX]{x1D713}(1;\overline{\mathbf{1}}).\end{eqnarray}$$

Here, $\unicode[STIX]{x1D713}$ is naturally defined as in Section 2. All of these compatibility conditions consist of showing that pairs of digit sequences $(a_{n})_{n\geqslant 1}$ and $(a_{n}^{\prime })_{n\geqslant 1}$ lead to the same boundary point; that is,

$$\begin{eqnarray}\mathop{\sum }_{n\geqslant 1}A^{-n}a_{n}=\mathop{\sum }_{n\geqslant 1}A^{-n}a_{n}^{\prime }.\end{eqnarray}$$

This can be checked on the automata depicted in Figures 7 and 8. We refer to Proposition 6.3 for the construction of these automata. Applying Theorem 2.4, we obtain the existence of the Hölder parametrization $C:[0,1]\rightarrow \unicode[STIX]{x2202}T$ with $C(0)=C(1)$ .

The hexagon $Q$ is defined in Proposition 6.1 and depicted in Figure 10. The first part of Item (1) is then just the consequence that ${\mathcal{T}}$ is the attractor of the iterated function system (IFS) $\{x\mapsto A^{-1}(x+a)\}_{a\in {\mathcal{D}}}$ .

The second part of Item (1) as well as Item (2) can be proved as in [Reference Akiyama and LoridantAL11, Proposition 5.7]. This consists of showing for all $n\geqslant 0$ that $\unicode[STIX]{x2202}{\mathcal{T}}_{n}$ is equal to $\unicode[STIX]{x1D6E5}_{n}$ , the sequence of boundary approximations given by Theorem 2.4.

Item (3) can be proved similarly to [Reference Akiyama and LoridantAL11, Proposition 5.6]. The proof relies on the fact that the hexagon $Q$ induces a tiling by its translations in which the neighboring tiles have a one-dimensional intersection (see Proposition 6.1 and Figure 10). One then uses the property that $A^{n}{\mathcal{T}}_{n}$ is a connected union of translations of the hexagon $Q$ and has therefore, as well as ${\mathcal{T}}_{n}$ , a connected interior.◻

Proposition 6.1. For $i\in \{1,2,3,4,5,6\}$ , let $C_{i}:=\unicode[STIX]{x1D713}(i;\overline{\mathbf{1}})$ , and let $[C_{1},\ldots ,C_{6},C_{1}]$ be the polygonal curve obtained by joining the points $C_{1},\ldots ,C_{6},C_{1}$ in this order. Then, $[C_{1},\ldots ,C_{6},C_{1}]$ is a simple closed curve. Let $Q$ be the closure of its bounded complementary component. Then, $Q$ tiles $\mathbb{R}^{2}$ by $\mathbb{Z}^{2}$ . Moreover, the neighbors of $Q$ in this tiling are the tiles $Q+s$ with $s\in {\mathcal{R}}$ , and

$$\begin{eqnarray}\unicode[STIX]{x2202}Q=\mathop{\bigcup }_{s\in {\mathcal{R}}}Q\cap (Q+s).\end{eqnarray}$$

Proof. We compute

$$\begin{eqnarray}\displaystyle & & \displaystyle C_{1}=(1,-1/3),\qquad C_{2}=(0,1/3),\qquad C_{3}=(-1,2/3),\quad \nonumber\\ \displaystyle & & \displaystyle C_{4}=(-1,1/3),\qquad C_{5}=(0,-1/3),\qquad C_{6}=(1,-2/3).\nonumber\end{eqnarray}$$

Joining the points $C_{1},C_{2},\ldots ,C_{6},C_{1}$ in this order yields a simple closed curve. The closure of the bounded component of its complement in $\mathbb{R}^{2}$ is a hexagon $Q$ depicted in Figure 10. Consider the quadrilateral $H_{1}$ with vertices $C_{6},C_{1},C_{2},C_{3}$ and the quadrilateral $H_{2}$ with vertices $C_{3},C_{4},C_{5},C_{6}$ . Then $H_{1}\cup (H_{2}+(-1,1))$ is a parallelogram which obviously tiles the plane by $\mathbb{Z}^{2}$ . It follows that $Q$ itself tiles the plane by $\mathbb{Z}^{2}$ .◻

As mentioned in the proof of Theorem 4, checking the compatibility conditions $\unicode[STIX]{x1D713}(w)=\unicode[STIX]{x1D713}(w^{\prime })$ in Definition 2.3 amounts to proving equalities of the form $\sum _{n\geqslant 1}A^{-n}a_{n}=\sum _{n\geqslant 1}A^{-n}a_{n}^{\prime }$ for sequences of digits $(a_{n}),(a_{n}^{\prime })$ . Moreover, for topological purposes, we look for all pairs of parameters $(t,t^{\prime })$ with $t\neq t^{\prime }\in [0,1)$ fulfilling $C(t)=C(t^{\prime })$ (noninjectivity points). This requires us to find all pairs $(w,w^{\prime })$ of walks $w,w^{\prime }\in G({\mathcal{R}})^{o}$ satisfying $\unicode[STIX]{x1D713}(w)=\unicode[STIX]{x1D713}(w^{\prime })$ other than the pairs $(w,w^{\prime })$ of walks considered in the compatibility conditions. The right context for these computations is the framework of Büchi automata.

Definition 6.2. Let ${\mathcal{A}}=(S,\unicode[STIX]{x1D6EC},E)$ be an automaton; that is, $S$ is a finite set of states, $\unicode[STIX]{x1D6EC}$ is a finite set of labels and $E\subset S\times \unicode[STIX]{x1D6EC}\times S$ is the set of transitions. Note that for $(t,l,t^{\prime })\in E$ , we usually write $t\xrightarrow[{}]{l}t^{\prime }$ . Let $I,F\subset S$ . Then, $(S,\unicode[STIX]{x1D6EC},E,I,F)$ is called a Büchi automaton with the set of initial states $I$ and the set of final states $F$ . An infinite walk

$$\begin{eqnarray}V:t_{1}\xrightarrow[{}]{l_{1}}t_{2}\xrightarrow[{}]{l_{2}}\cdots\end{eqnarray}$$

in the automaton ${\mathcal{A}}$ is called admissible if it starts from a state of $I$ ( $t_{1}\in I$ ) and visits $F$ infinitely often. (This means that $\{t_{n};n\geqslant 1\}\cap F$ is infinite.)

A Büchi automaton ${\mathcal{I}}^{\unicode[STIX]{x1D713}}$ collects all pairs $(w,w^{\prime })$ of distinct walks $w,w^{\prime }$ in $G({\mathcal{S}})$ (Figure 4) whose sequences of labels $(a_{n}),(a_{n}^{\prime })$ fulfill $\sum _{n\geqslant 1}A^{-n}a_{n}=\sum _{n\geqslant 1}A^{-n}a_{n}^{\prime }$ (Figure 6). To infer from this automaton the pairs of parameters $(t,t^{\prime })$ satisfying $t\neq t^{\prime }$ and $C(t)=C(t^{\prime })$ , we transfer it to Büchi automata built up from $G({\mathcal{R}})^{o}$ . A Büchi automaton ${\mathcal{A}}^{\unicode[STIX]{x1D713}}$ collects all pairs $(w,w^{\prime })$ of distinct walks $w,w^{\prime }\in G({\mathcal{R}})^{o}$ satisfying $\unicode[STIX]{x1D713}(w)=\unicode[STIX]{x1D713}(w^{\prime })$ and corresponding to different sequences of digits $(a_{n}),(a_{n}^{\prime })$ (Figure 7). Another Büchi automaton ${\mathcal{A}}^{sl}$ collects all pairs $(w,w^{\prime })$ of distinct walks $w,w^{\prime }\in G({\mathcal{R}})^{o}$ satisfying $\unicode[STIX]{x1D713}(w)=\unicode[STIX]{x1D713}(w^{\prime })$ and corresponding to the same sequence of digits $(a_{n}),(a_{n}^{\prime })=(a_{n})$ (Figure 8). Erasing from ${\mathcal{A}}^{\unicode[STIX]{x1D713}}\cup {\mathcal{A}}^{sl}$ the pairs of walks $(w,w^{\prime })$ corresponding to the compatibility conditions (Definition 2.3), we obtain the desired pairs of walks associated with all pairs of parameters $(t,t^{\prime })$ with $t\neq t^{\prime }\in [0,1)$ and fulfilling $C(t)=C(t^{\prime })$ . This operation of “erasing” is related to the so-called complementation of Büchi automata, which can be a difficult task in general. However, it turns out to be easy in our example (see Definition 6.4, Proposition 6.5 and the paragraph between them).

Figure 6. Example of Bandt and Gelbrich: automaton ${\mathcal{I}}^{\unicode[STIX]{x1D713}}$ .

Figure 7. Example of Bandt and Gelbrich: automaton ${\mathcal{A}}^{\unicode[STIX]{x1D713}}$ .

Figure 8. Example of Bandt and Gelbrich: automaton ${\mathcal{A}}^{sl}$ .

Proposition 6.3. Let $w\neq w^{\prime }$ infinite walks in $G({\mathcal{R}})^{o}$ with

$$\begin{eqnarray}w:i\xrightarrow[{}]{a_{1}||\mathbf{o}_{\mathbf{1}}}\cdots\end{eqnarray}$$

and

$$\begin{eqnarray}w^{\prime }:j\xrightarrow[{}]{a_{1}^{\prime }||{\mathbf{o}_{\boldsymbol{ 1}}}^{\prime }}\cdots \,,\end{eqnarray}$$

where $i,j\in \{1,2,3,4,5,6\}$ . Then, $\unicode[STIX]{x1D713}(w)=\unicode[STIX]{x1D713}(w^{\prime })$ if and only if, up to permutation of $w$ and $w^{\prime }$ , one of the following holds.

  • $i=j$ and

    (6.5) $$\begin{eqnarray}i|i\xrightarrow[{}]{\mathbf{o}_{\mathbf{1}}||\mathbf{o}_{\mathbf{1}}^{\prime }}\cdots\end{eqnarray}$$
    is an admissible walk in ${\mathcal{A}}^{\unicode[STIX]{x1D713}}$ depicted in Figure 7.
  • The walk

    (6.6) $$\begin{eqnarray}i|j\xrightarrow[{}]{\mathbf{o}_{\mathbf{1}}||\mathbf{o}_{\mathbf{1}}^{\prime }}\cdots\end{eqnarray}$$
    is an admissible walk in ${\mathcal{A}}^{sl}$ depicted in Figure 8.

In both automata, the gray states are the initial states and the double lined states are the final states.

Proof. By definition, $\unicode[STIX]{x1D713}(w)=\unicode[STIX]{x1D713}(w^{\prime })\;\Longleftrightarrow \;\sum _{n\geqslant 1}A^{-n}a_{n}=\sum _{n\geqslant 1}A^{-n}a_{n}^{\prime }$ . This point must belong to a boundary part $K_{s_{0}}$ for some $s_{0}\in {\mathcal{R}}$ . Suppose that the digit labels $(a_{n})_{n\geqslant 1}$ and $(a_{n}^{\prime })_{n\geqslant 1}$ are distinct, and let $m\geqslant 0$ be the least integer such that $a_{m+1}\neq a_{m+1}^{\prime }$ . By Proposition 2.1, there must be $(a_{n}^{\prime \prime })_{n\geqslant 1}\in {\mathcal{D}}^{\mathbb{N}}$ and walks

$$\begin{eqnarray}\begin{array}{@{}cccccccccc@{}}s_{0}~\, & \xrightarrow[{}]{a_{1}|a_{1}^{\prime \prime }}~\, & s_{1}~\, & \xrightarrow[{}]{a_{2}|a_{2}^{\prime \prime }}~\, & \cdots \,~\, & \xrightarrow[{}]{a_{m}|a_{m}^{\prime \prime }}~\, & s_{m}~\, & \xrightarrow[{}]{a_{m+1}|a_{m+1}^{\prime \prime }}~\, & s_{m+1}~\, & \xrightarrow[{}]{}\cdots \,,\\ s_{0}~\, & \xrightarrow[{}]{a_{1}^{\prime }=a_{1}|a_{1}^{\prime \prime }}~\, & s_{1}~\, & \xrightarrow[{}]{a_{2}^{\prime }=a_{2}|a_{2}^{\prime \prime }}~\, & \cdots \,~\, & \xrightarrow[{}]{a_{m}^{\prime }=a_{m}|a_{m}^{\prime \prime }}~\, & s_{m}~\, & \xrightarrow[{}]{a_{m+1}^{\prime }|a_{m+1}^{\prime \prime }}~\, & s_{m+1}^{\prime }~\, & \xrightarrow[{}]{}\cdots \end{array}\end{eqnarray}$$

in $G({\mathcal{S}})$ . As proved in [Reference Akiyama and LoridantAL11, Section 4], these pairs of walks are recognized as the admissible walks of a Büchi automaton ${\mathcal{I}}^{\unicode[STIX]{x1D713}}$ , depicted in Figure 6.

Note that some pairs of walks $(w,w^{\prime })$ recognized by ${\mathcal{I}}^{\unicode[STIX]{x1D713}}$ satisfy $w^{\prime }\in {\mathcal{G}}({\mathcal{S}})\setminus {\mathcal{G}}({\mathcal{R}})$ . However, it is easy to check that the corresponding digit sequence $(a_{n}^{\prime })_{n\geqslant 1}$ of such a $w^{\prime }$ does not appear as a digit sequence of any other walk of $G({\mathcal{S}})$ . We therefore delete these pairs of walks from ${\mathcal{I}}^{\unicode[STIX]{x1D713}}$ and obtain the automaton ${\mathcal{A}}^{\unicode[STIX]{x1D713}}$ of Figure 7. In this figure, we use for the states and edges the elements of the ordered extension $G({\mathcal{R}})^{o}$ . Pairs of infinite walks $(w,w^{\prime })$ , $w\neq w^{\prime }$ in $G({\mathcal{R}})^{o}$ both starting in $\{1,2,3,4,5,6\}$ , having distinct digit sequences $(a_{n})_{n\geqslant 1}\neq (a_{n}^{\prime })_{n\geqslant 1}$ and satisfying $\unicode[STIX]{x1D713}(w)=\unicode[STIX]{x1D713}(w^{\prime })$ , are of the form (6.5).

For $w\neq w^{\prime }$ infinite walks in $G({\mathcal{R}})^{o}$ with $\unicode[STIX]{x1D713}(w)=\unicode[STIX]{x1D713}(w^{\prime })$ and identical digit sequences $(a_{n})_{n\geqslant 1}=(a_{n}^{\prime })_{n\geqslant 1}$ , we construct the automaton ${\mathcal{A}}^{sl}$ as in [Reference Akiyama and LoridantAL11] and depict it in Figure 8.◻

The pairs $(w,w^{\prime })$ of walks $w,w^{\prime }\in G({\mathcal{R}})^{o}$ associated to the compatibility conditions (Definition 2.3) are called trivial identifications, according to the following definition.

Definition 6.4. Let $w\neq w^{\prime }$ be two walks of $G({\mathcal{R}})^{o}$ starting in $\{1,2,3,4,5,6\}$ and satisfying the equality $\unicode[STIX]{x1D713}(w)=\unicode[STIX]{x1D713}(w^{\prime })$ . We call the pair $(w,w^{\prime })$ trivial identification (in the Dumont–Thomas number system) if, up to permutation of $w$ and $w^{\prime }$ , there is a walk $w_{0}$ of length $n$ in $G({\mathcal{R}})^{o}$ such that

$$\begin{eqnarray}w=w_{0}\& \overline{\mathbf{o}_{\mathbf{m}}},\qquad w^{\prime }=w_{0}^{+}\& \overline{\mathbf{1}}.\end{eqnarray}$$

Here, $w_{0}^{+}$ is the next walk of length $n$ in lexicographical order in $G({\mathcal{R}})^{o}$ . By convention,

$$\begin{eqnarray}(6;\underbrace{\mathbf{o}_{\mathbf{m}},\ldots ,\mathbf{o}_{\mathbf{m}}}_{n\,\text{times}})^{+}:=(1;\underbrace{\mathbf{1},\ldots ,\mathbf{1}}_{n\,\text{times}}).\end{eqnarray}$$

By definition, the walks of a trivial identification are associated to the same parameter $t\in [0,1]$ in our parametrization. On the contrary, nontrivial identifications make the parametrization noninjective. Finding out the nontrivial identifications can be a difficult task: it is related to the complementation of Büchi automata. In our example, it is easy to see that ${\mathcal{A}}^{\unicode[STIX]{x1D713}}$ only gives rise to trivial identifications. Moreover, the identifications in ${\mathcal{A}}^{sl}$ depicted in the top part of Figure 8 only give rise to trivial identifications. However, in the bottom part, we can find the following nontrivial identifications.

Proposition 6.5. The pair $(w,w^{\prime })$ is a nontrivial identification in the Dumont–Thomas number system if and only if it is a pair of Figure 9, up to permutation of $w$ and $w^{\prime }$ . The associated points in $[0,1]$ are schematically represented in Figure 9 too. Here, for $i\in \{1,\ldots ,6\}$ , the circled number  stands for the parameter of $[0,1]$ associated with the walk $(i;\overline{\mathbf{1}})$ . No two pairs of identifications are crossing.

Figure 9. Nontrivial identifications in the example of Bandt and Gelbrich.

Proof. As mentioned above, ${\mathcal{A}}^{\unicode[STIX]{x1D713}}$ and the part of ${\mathcal{A}}^{sl}$ at the top of Figure 8 only give rise to trivial identifications. In the bottom part, we find the trivial identifications

$$\begin{eqnarray}\unicode[STIX]{x1D713}(1;\overline{\mathbf{o}_{\mathbf{m}}})=\unicode[STIX]{x1D713}(2;\overline{\mathbf{1}})\qquad \text{and}\qquad \unicode[STIX]{x1D713}(5;\overline{\mathbf{1}})=\unicode[STIX]{x1D713}(4;\overline{\mathbf{o}_{\mathbf{m}}}).\end{eqnarray}$$

The other identifications are nontrivial and are listed in Figure 9. ◻

This allows us to determine all of the cut points of ${\mathcal{T}}$ . These are the points $z\in {\mathcal{T}}$ such that ${\mathcal{T}}\setminus \{z\}$ is no more connected.

Theorem 5. Let ${\mathcal{T}}={\mathcal{T}}(A,{\mathcal{D}})$ be the tile associated to the data (6.1). For $i\in \{0,1,-1\}$ , we denote by $f_{i}(x)=A^{-1}(x+(i,0)^{T})$ the corresponding contraction. Then, the sequence of cut points of ${\mathcal{T}}$ reads as follows ( $n\geqslant 0$ ):

  1. (i) $f_{1}^{2n+2}((0,0)^{T})$ ;

  2. (ii) $f_{1}^{2n+3}((0,0)^{T})$ ;

  3. (iii) $f_{1}((0,0)^{T})$ ;

  4. (iv) $(0,0)^{T}$ ;

  5. (v) $f_{-1}^{2n+2}((0,0)^{T})$ ;

  6. (vi) $f_{-1}^{2n+3}((0,0)^{T})$ ;

  7. (vii) $f_{-1}((0,0)^{T})$ .

Proof. We show that each cut point corresponds to a nontrivial identification listed in Figure 9.

Figure 10. Example of Bandt and Gelbrich: hexagon $Q$ and associated tiling.

First, note that for every $t\in [0,1]$ , $C([0,1]\setminus \{t\})$ remains connected. (Remember that $C(0)=C(1)$ .)

Then, consider, for example, the identification $(R,R^{\prime })$ and the associated values $0<t_{R}<t_{R^{\prime }}<1$ . Denote $z:=C(t_{R})=C(t_{R^{\prime }})$ . Then, $C([0,1]\setminus \{t_{R},t_{R^{\prime }}\})=\unicode[STIX]{x2202}T\setminus \{z\}$ is no more connected: it consists of exactly two connected components, namely $C([0,t_{R})\cup (t_{R^{\prime }},1])$ and $C((t_{R},t_{R^{\prime }}))$ .

The corresponding sequence of digits is read off from Figure 5: $P(1;\mathbf{2},\overline{(\mathbf{1},\mathbf{3})})$ is labeled by the sequence of digits $1\overline{00}$ , which is the point $f_{1}(\text{Fix}(f_{0}))=(-1/3,1/3)$ , as $\text{Fix}(f_{0})=(0,0)^{T}$ . This corresponds to Item (iii) of the theorem.

This proof holds for every pair of identified walks of Figure 9. Item (i) corresponds to $(P_{n},P_{n}^{\prime })$ , Item (ii) corresponds to $(Q_{n},Q_{n}^{\prime })$ , and so on.◻

Furthermore, we can infer the following topological description of the boundary of ${\mathcal{T}}$ .

Theorem 6. The boundary $\unicode[STIX]{x2202}{\mathcal{T}}$ of the tile ${\mathcal{T}}={\mathcal{T}}(A,{\mathcal{D}})$ associated to the data (6.1) is a countable union of simple closed curves, together with two points. These are

  • the curves $C([a,c]\cup [d,b])$ , where $((a,b),(c,d))$ is any pair of consecutive nontrivial identifications; that is, $0<a<c<d<b<1$ and there is no identification $(e,f)$ satisfying $a<e<c$ and $d<f<b$ (see Figure 9);

  • the curve $C([t_{S},1]\cup [0,t_{R}]\cup [t_{R^{\prime }},t_{S^{\prime }}])$ , where $t_{S},t_{R},t_{R^{\prime }},t_{S^{\prime }}$ are associated to the walks $S,R,R^{\prime },S^{\prime }$ of Figure 9;

  • the points $\pm (0,1/3)$ .

Each curve intersects exactly two other curves, each at one point.

Proof. This result can be read off from Figure 9. If $((a,b),(c,d))$ is any pair of consecutive nontrivial identifications satisfying $0<a<c<d<b<1$ , then $C$ is injective on $[a,c]$ and on $[d,b]$ . Thus, $C([a,c])$ and $C([d,b])$ are two simple arcs meeting only at their extremities $C(a)=C(b)$ and $C(c)=C(d)$ . Their union is therefore a simple closed curve. It meets exactly two other curves, one at $C(a)=C(b)$ and the other one at $C(c)=C(d)$ .

Similarly, $C$ is injective on $[t_{S},1]\cup [0,t_{R}]$ (apart from the trivial identification $C(0)=C(1)$ ) and on $[t_{R^{\prime }},t_{S^{\prime }}]$ . Thus, $C([t_{S},1]\cup [0,t_{R}])$ and $C([t_{R^{\prime }},t_{S^{\prime }}])$ are two simple arcs meeting only at their extremities $C(t_{S})=C(t_{S^{\prime }})$ and $C(t_{R})=C(t_{R^{\prime }})$ . Their union is therefore a simple closed curve. It also meets exactly two other curves.

Figure 11. Example of Bandt and Gelbrich: boundary approximations.

Figure 12. Example of Bandt and Gelbrich: approximation $C_{n}(a_{n},b_{n})$ ( $n=2,3,5,6,7,9$ ) for $(a,b)=(t_{S^{\prime }},t_{S})$ .

Figure 13. Example of Bandt and Gelbrich: approximation $D_{n}(a_{n},b_{n})$ ( $n=2,3,5,6,7,9$ ) for $(a,b)=(t_{S^{\prime }},t_{S})$ .

Figure 14. Example of Bandt and Gelbrich: approximation $C_{n}(a_{n},b_{n})\cup D_{n}(a_{n},b_{n})$ ( $n=2,3,5,6,7,9$ ) for $(a,b)=(t_{S^{\prime }},t_{S})$ .

Figure 15. Example of Bandt and Gelbrich: encircling $C_{n}(a_{n},b_{n})$ ( $n=2,3,4,5,6,7$ ) for $(a,b)=(t_{S^{\prime }},t_{S})$ .

Figure 16. Example of Bandt and Gelbrich: encircling $D_{n}(a_{n},b_{n})$ ( $n=2,3,4,5,6,7$ ) for $(a,b)=(t_{S^{\prime }},t_{S})$ .

The point $(0,1/3)$ corresponds to the infinite walk $(2;\overline{\mathbf{1}})$ and the point $(0,-1/3)$ corresponds to the infinite walk $(5;\overline{\mathbf{1}})$ . These are the two accumulation points of the sequence of simple closed curves.

The union of all these curves together with the two points is equal to $C([0,1])=\unicode[STIX]{x2202}{\mathcal{T}}$ ; hence, the description is complete.◻

We now pick up one of these simple closed curves and show that it is the boundary of an interior component.

Theorem 7. Let $0<t_{S^{\prime }}<t_{V^{\prime }}<t_{V}<t_{S}<1$ be associated to the infinite walks $S^{\prime },V^{\prime },V,S$ of Figure 9. Then, $C([t_{S^{\prime }},t_{V^{\prime }}]\cup [t_{V},t_{S}])$ is the boundary of an interior component of the tile ${\mathcal{T}}={\mathcal{T}}(A,{\mathcal{D}})$ defined by (6.1). The closure of this component is homeomorphic to a closed disk.

Proof. We apply Theorem 3. We just need to prove that $(S^{\prime },S)$ and $(V^{\prime },V)$ are outer identifications. This is done by checking that

$$\begin{eqnarray}w_{t_{S^{\prime }},t_{S}}=w_{t_{S^{\prime }},t_{S}}^{\prime }=1\qquad \text{and}\qquad w_{t_{V^{\prime }},t_{V}}=w_{t_{V^{\prime }},t_{V}}^{\prime }=1.\end{eqnarray}$$

The computations follow the algorithm of Theorem 2. For the identification $(S^{\prime },S)$ , we illustrate them in Figures 1216. By Proposition 4.5, we can choose rather arbitrarily the reference points on the boundary in order to compute the winding numbers. Let us choose vertices of the hexagon $Q$ as follows:

  • $t:=t_{C_{2}}$ ( $C_{2}=(0,1/3)$ ) to compute $w_{t_{S^{\prime }},t_{S}}=W(C(t),C([t_{S^{\prime }},t_{S}]))$ ;

  • $t^{\prime }:=t_{C_{5}}$ ( $C_{5}=(0,-1/3)$ ) to compute $w_{t_{S^{\prime }},t_{S}}^{\prime }=W(C(t^{\prime }),C([0,t_{S^{\prime }}]\cup [t_{S},1]))$ .

Figures 12 and 13 show the curves $C_{n}(a_{n},b_{n})$ and $D_{n}(a_{n},b_{n})$ that are used to compute these winding numbers. To determine which minimal value of $n$ gives us the right winding numbers, we apply the encircling method as described in the proof of Theorem 2. Here, if $||\cdot ||$ denotes the Euclidean norm, we have

$$\begin{eqnarray}||A^{-2}(x,y)||\leqslant {\textstyle \frac{2}{3}}||(x,y)||;\end{eqnarray}$$

hence, $k=2$ and $\unicode[STIX]{x1D706}=2/3$ are suitable. We refer to the proof of Theorem 1 for the definition of these quantities. This allows us to determine a value of $r$ for which ${\mathcal{T}}\subset \mathbb{D}(0;r)$ . Indeed, again with the notations of the proof of Theorem 1, $A^{\prime }=A^{2},{\mathcal{D}}^{\prime }=A{\mathcal{D}}+{\mathcal{D}}$ , and a point in ${\mathcal{T}}$ has the norm

$$\begin{eqnarray}\left\Vert \mathop{\sum }_{j\geqslant 1}(A^{\prime })^{-j}d_{j}\right\Vert \leqslant \text{max}_{d,d^{\prime }\in {\mathcal{D}}}\{||Ad+d^{\prime }||\}\cdot \mathop{\sum }_{j\geqslant 1}\left(\frac{2}{3}\right)^{j}=2\sqrt{2}.\end{eqnarray}$$

Performing the encircling method, we see that for $n=7$ the reference points lie outside of the covering by the disks (Figures 15 and 16). Computing the winding numbers of the reference points with respect to the approximations $C_{7}(a_{7},a_{7})$ and $D_{7}(a_{7},b_{7})$ , we obtain the value $1$ in both cases. Therefore, $(S,S^{\prime })$ is an outer identification.

Similar computations lead to $w_{t_{V^{\prime }},t_{V}}=w_{t_{V^{\prime }},t_{V}}^{\prime }=1$ ; that is, $(V^{\prime },V)$ is also an outer identification and Theorem 3 applies.◻

Remark 6.6. In fact, each simple closed curve of Theorem 6 is the boundary of an inner component. In other words, the tile ${\mathcal{T}}(A,{\mathcal{D}})$ is a countable union of topological closed disks, together with two points, and each disk intersects exactly two other disks, each at one point. Proving that all of the nontrivial identifications are outer makes use of the self-similarity of ${\mathcal{T}}$ and involves further computations on the parametrization. Therefore, we postpone the proof to a forthcoming paper.

Remark 6.7. Theorems 57 obtained by our general method can be compared with the work of Ngai and Nguyen [Reference Ngai and NguyenNN03], where the cut points of the Heighway dragon are computed and its interior components are shown to be disklike. To obtain this topological information, Ngai and Nguyen analyze precisely the behavior of $n$ -fold iterations ${\mathcal{P}}_{n}$ of the vertical unit segment ${\mathcal{P}}_{0}$ , whose limit in Hausdorff distance results in the Heighway dragon, and they describe the largest interior component of the Heighway dragon as the attractor of a GIFS. Our method also applies to this example (see Section 7.2), but we rather extract all the information directly from boundary approximations of the Heighway dragon, using our parametrization.

7 Further work

We give in this section several comments on the paper and present some ideas that will be worked out in forthcoming papers.

7.1 Description of interior components

We aim at developing methods in order to get very precise information on the wild topology of self-affine tiles, like the description of the boundary of interior components in terms of GIFSs (see [Reference Mauldin and WilliamsMW88]). Descriptions of this kind were obtained for the single examples of Figure 18 in [Reference Loridant and ThuswaldnerLT08, Reference Bernat, Loridant and ThuswaldnerBLT10] (canonical number system tile of $-2+i$ ) or in [Reference Ngai and NguyenNN03] (Heighway dragon). We rather use our general boundary parametrization tool.

7.2 Dealing with nontrivial identifications

In this paper, we restrict to the case where no pairs of identifications are crossing. This first step in the study of non-disklike tiles enables us to describe tiles with a reasonable topological complexity. Similar examples are the crystallographic replication tiles (see [Reference GelbrichGel94]) depicted in Figure 17. On the left is the Heighway dragon and on the right is a tile found in [Reference Loridant and LuoLL09, Figure 14]. They tile the plane with respect to the crystallographic groups $p4$ and $p2$ , respectively. A boundary approximation of the Heighway dragon obtained via the parametrization method can also be found in this figure.

Figure 17. Tiles with no crossing pairs of identifications.

Figure 18. Tiles with crossing pairs of identifications.

However, we find in the literature examples where pairs of identifications are crossing. In Figure 18, we depict two such tiles with a wilder topology. The tile at the top is a canonical number system tile, associated with the basis $-2+i$ (see [Reference GilbertGil81]). The intersection of the central tile with some of its neighbors is a Cantor set (see [Reference Duan, Liu and TangDLT09]). It has a large set of nontrivial identifications.

At the bottom, we represent an example with an intermediate topological complexity. This self-similar tile Limhex was originally given as a triomino (a polygon composed of regular triangles) tiling generated by a pseudo substitution by Socolar (see [Reference SocolarSoc]). The substitution rule is depicted in the middle of Figure 18. The substitution is not edge to edge, like the substitution rule of Penrose tiling. Taking the $n\text{th}$ iterate and shrinking by the ratio $1/2^{n}$ to renormalize, we obtain as a Hausdorff limit a fractal tile Limhex, whose IFS is given by

$$\begin{eqnarray}\displaystyle & \displaystyle f_{1}(z)=\frac{z}{2},\qquad f_{2}(z)=\frac{z-1}{2}, & \displaystyle \nonumber\\ \displaystyle & \displaystyle f_{3}(z)=\frac{z/w+w^{2}}{2},\qquad f_{4}(z)=-\frac{z/w+w^{2}}{2}, & \displaystyle \nonumber\end{eqnarray}$$

where $w=e^{i\unicode[STIX]{x1D70B}/3}$ . In Figure 18, we can see the attractor Limhex of this IFS (up to some translation) together with its neighbors in the aperiodic tiling it generates. Here, the intersection of the central tile with a neighbor is either a simple arc or a single point.

The coming step in our study will be to appropriately extend the definition of outer identification to such cases. Note that some identifications on the boundary of the tiles in Figure 18 do not contribute to a new interior component, but rather lead to a hole. We may call them inner identifications, but, for now, we are looking for typical examples in order to axiomatize and propose the next tractable class of such identifications.

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Figure 0

Figure 1. Proposition 4.5. In the above two cases, $C([a,b])$ is shown solid and $C([0,a])\cup C([b,1])$ is shown dashed. The intersection point is $C(a)=C(b)$.

Figure 1

Figure 2. Theorem 3. $C([a,c])$ is shown dotted and $C([d,b])$ is shown dashed. The intersection points correspond to $C(a)=C(b)$ and $C(c)=C(d)$.

Figure 2

Figure 3. Example of Bandt and Gelbrich and its lattice tiling.

Figure 3

Figure 4. Boundary graph of the example of Bandt and Gelbrich.

Figure 4

Figure 5. Ordered extension $G({\mathcal{R}})^{o}$ for the example of Bandt and Gelbrich.

Figure 5

Figure 6. Example of Bandt and Gelbrich: automaton ${\mathcal{I}}^{\unicode[STIX]{x1D713}}$.

Figure 6

Figure 7. Example of Bandt and Gelbrich: automaton ${\mathcal{A}}^{\unicode[STIX]{x1D713}}$.

Figure 7

Figure 8. Example of Bandt and Gelbrich: automaton ${\mathcal{A}}^{sl}$.

Figure 8

Figure 9. Nontrivial identifications in the example of Bandt and Gelbrich.

Figure 9

Figure 10. Example of Bandt and Gelbrich: hexagon $Q$ and associated tiling.

Figure 10

Figure 11. Example of Bandt and Gelbrich: boundary approximations.

Figure 11

Figure 12. Example of Bandt and Gelbrich: approximation $C_{n}(a_{n},b_{n})$ ($n=2,3,5,6,7,9$) for $(a,b)=(t_{S^{\prime }},t_{S})$.

Figure 12

Figure 13. Example of Bandt and Gelbrich: approximation $D_{n}(a_{n},b_{n})$ ($n=2,3,5,6,7,9$) for $(a,b)=(t_{S^{\prime }},t_{S})$.

Figure 13

Figure 14. Example of Bandt and Gelbrich: approximation $C_{n}(a_{n},b_{n})\cup D_{n}(a_{n},b_{n})$ ($n=2,3,5,6,7,9$) for $(a,b)=(t_{S^{\prime }},t_{S})$.

Figure 14

Figure 15. Example of Bandt and Gelbrich: encircling $C_{n}(a_{n},b_{n})$ ($n=2,3,4,5,6,7$) for $(a,b)=(t_{S^{\prime }},t_{S})$.

Figure 15

Figure 16. Example of Bandt and Gelbrich: encircling $D_{n}(a_{n},b_{n})$ ($n=2,3,4,5,6,7$) for $(a,b)=(t_{S^{\prime }},t_{S})$.

Figure 16

Figure 17. Tiles with no crossing pairs of identifications.

Figure 17

Figure 18. Tiles with crossing pairs of identifications.