Proof. By contradiction, suppose that there are two distinct rectangular patterns p and q whose sequence of bottom labels is X and sequence of left labels is Y. Since p and q are distinct, there exists a position $k\in \mathbb {N}^2$ such that $p_k\neq q_k$ . Consider such a position in the support of p and q which minimizes the norm $\Vert k\Vert _1$ . Since the position is minimal, every tile at position smaller in norm is the same in both patterns. In particular, it implies that and . The set of Wang tile ${\mathcal {T}}_n$ is SW-deterministic. This implies that and . Since the four labels of the Wang tiles are the same, we must have $p_k=q_k$ , a contradiction. We conclude the uniqueness of the rectangular pattern.

Proof. The following is a bijection from the labels of the Ammann set of 16 Wang tiles and the labels of the tiles in ${\mathcal {T}}_1$ :

$$ \begin{align*} 1 \mapsto 112,\quad 2 \mapsto 111,\quad 3 \mapsto 001, \quad 4 \mapsto 011, \quad 5 \mapsto 012, \quad 6 \mapsto 000. \end{align*} $$

See Figure 10 (note that the order of the tiles is not the same).

Proof. When rotating the tiles of ${\mathcal {T}}_n$ by half a turn and applying the map $\sigma $ on the resulting labels, we may observe that yellow tiles become blue tiles and vice versa, white tiles are mapped to white tiles, junction tiles are mapped to junction tiles and green tiles are mapped to green tiles.

Proof. Let us show that ${\mathcal {T}}_n^{\prime }$ is SW-deterministic. Let $s,t\in {\mathcal {T}}_n^{\prime }$ be such that and for some vectors $u=(u_0,u_1,u_2),v=(v_0,v_1,v_2)\in V_n$ .

• • If $u_0=0$ , $v_0=0$ , then $s,t\in J^{\prime }_n$ .

• • If $u_0=1$ , $v_0=1$ , then $s,t\in W_n$ .

• • If $u_0=0$ , $v_0=1$ , $u_1=0$ and $v_2=n$ , then $s,t\in B^{\prime }_n$ .

• • If $u_0=0$ , $v_0=1$ , $u_1=0$ and $v_2=\overline {n}$ , then $s,t\in G_n$ .

• • If $u_0=0$ , $v_0=1$ , $u_1=1$ and $v_2=n$ , then $s,t\in A_n$ .

• • If $u_0=0$ , $v_0=1$ , $u_1=1$ and $v_2=\overline {n}$ , then $s,t\in Y_n$ .

• • If $u_0=1$ , $v_0=0$ , $v_1=0$ and $u_2=n$ , then $s,t\in \widehat {B^{\prime }_n}$ .

• • If $u_0=1$ , $v_0=0$ , $v_1=0$ and $u_2=\overline {n}$ , then $s,t\in \widehat {G_n}$ .

• • If $u_0=1$ , $v_0=0$ , $v_1=1$ and $u_2=n$ , then $s,t\in \widehat {A_n}$ .

• • If $u_0=1$ , $v_0=0$ , $v_1=1$ and $u_2=\overline {n}$ , then $s,t\in \widehat {Y_n}$ .

One can observe that each of the subsets $W_n$ , $B^{\prime }_n$ , $G_n$ , $Y_n$ , $A_n$ , $J^{\prime }_n$ is SW-deterministic. By symmetry, $\widehat {B^{\prime }_n}$ , $\widehat {G_n}$ , $\widehat {Y_n}$ and $\widehat {A_n}$ are SW-deterministic. We conclude that $s=t$ . Thus, ${\mathcal {T}}_n^{\prime }$ is SW-deterministic. Using a similar argument, one can observe that ${\mathcal {T}}_n^{\prime }$ is NE-deterministic. By restriction, the subset ${\mathcal {T}}_n\subset {\mathcal {T}}_n^{\prime }$ is SW- and NE-deterministic.

However, ${\mathcal {T}}_n$ is neither NW- nor SE-deterministic because the subset $J_n$ is neither NW- nor SE-deterministic. By extension, the extended set ${\mathcal {T}}_n^{\prime }$ is neither NW- nor SE-deterministic.

Proof. The three items follow from the definition. We prove that $\tau _n$ is injective. Assume that $xyz\neq x'y'z'$ . We want to show that $\tau _n(xyz)\neq \tau _n(x'y'z')$ . If $x\neq x'$ , then the images are distinct because their lengths are different. If $x=x'$ and $y\neq y'$ , then the images are distinct because the second digit of their first item satisfies $x{-}y{+}1\neq x{-}y'{+}1$ . If $x=x'$ , $y=y'$ and $z\neq z'$ , then the images are distinct because there are $z-x$ occurrences of ${*}{*}n$ in the image of $\tau _n(xyz)$ .

Proof. Assume $v=00i$ with $0\leq i\leq \overline {n}$ . The following three cases occur.

• • If $i=0$ , then the sequence of bottom labels is $\tau _n(000) = 01\overline {n}\cdot (11\overline {n})^n$ , the sequence of top labels is $(112)^n$ and the right-most right label is $01\overline {n}$ .

• • If $1\leq i\leq n$ , then the sequence of bottom labels is $\tau _n(00i) = 01n\cdot (11n)^{i-1}\cdot (11\overline {n})^{n+1-i}$ , the sequence of top labels is $(111)^i\cdot (112)^{n-i}$ and the right-most right label is $01\overline {n}$ .

• • If $i=n+1$ , then the sequence of bottom labels is $\tau _n(00i) = 01n\cdot (11n)^{n}$ , the sequence of top labels is $(111)^{n}$ and the right-most right label is $00\overline {n}$ .

The $n+1$ tiles of the strip for the three cases are illustrated in Figure 12. We observe that the last blue tile (the blue horizontal stripe tile with left label $00n$ ) is used in the strip only when $i=n+1$ .

Figure 12

Horizontal strip with bottom word $\tau _n(00i)$ with $0\leq i\leq n$ .

Assume $v=01i$ with $1\leq i\leq \overline {n}$ . The following two cases occur.

• • If $1\leq i\leq n$ , then the sequence of bottom labels is $\tau _n(01i) = 00n\cdot (11n)^{i-1}\cdot (11\overline {n})^{n+1-i}$ , the sequence of top labels is $(111)^i\cdot (112)^{n-i}$ and the right-most right label is $01n$ .

• • If $i=n+1$ , then the sequence of bottom labels is $\tau _n(00i) = 00n\cdot (11n)^{n}$ , the sequence of top labels is $(111)^{n}$ and the right-most right label is $00n$ .

The $n+1$ tiles of the strip for the two cases are illustrated in Figure 13.

Figure 13

Horizontal strip with bottom word $\tau _n(01i)$ with $1\leq i\leq n+1$ .

Assume $v=11i$ with $1\leq i\leq \overline {n}$ . The following three cases occur.

• • If $i=1$ , then the sequence of bottom labels is $\tau _n(111) = 01\overline {n}\cdot (11\overline {n})^{n-1}$ , the sequence of top labels is $(112)^{n-1}$ and the right-most right label is $01n$ .

• • If $2\leq i\leq n$ , then the sequence of bottom labels is $\tau _n(11i) = 01n\cdot (11n)^{i-2}\cdot (11\overline {n})^{n+1-i}$ , the sequence of top labels is $(111)^{i-1}\cdot (112)^{n-i}$ and the right-most right label is $01n$ .

• • If $i=n+1$ , then the sequence of bottom labels is $\tau _n(11i) = 01n\cdot (11n)^{n-1}$ , the sequence of top labels is $(111)^{n-1}$ and the right-most right label is $00n$ .

The n tiles of the strip for the three cases are illustrated in Figure 14.

Figure 14

Horizontal strip with bottom word $\tau _n(11i)$ with $1\leq i\leq n+1$ .

Proof. Let $u,v\in V_n$ . For every tile in ${\mathcal {T}}_n^{\prime }$ , the left label starts with $0$ if and only if the right label starts with 0, and, symmetrically, the bottom label starts with 0 if and only if the top label starts with 0. Since we have $\tau _n(V_n)\subset \{00n,01n,01\overline {n}\}\cdot \{11n,11\overline {n}\}^*$ , any valid rectangular pattern with tiles in ${\mathcal {T}}_n^{\prime }$ whose sequence of bottom labels is $\tau _n(v)$ and sequence of left labels is $\tau _n(u)$ can be split into four disjoint regions: a junction tile at the bottom left corner, a row of horizontal stripe tiles at the bottom, a column of vertical stripe tiles on the left and a rectangular pattern of white tiles for the remaining rectangle; see Figure 15.

(Existence) Let $u,v,\alpha ,\beta \in V_n$ be such that . First, we show that the junction tile at the bottom left corner of the rectangular pattern with bottom labels $\tau _n(v)$ and left labels $\tau _n(u)$ is one of the 9 junction tile in ${\mathcal {T}}_n^{\prime }$ . For every $u,v\in V_n$ , we have $\tau _n(u),\tau _n(v)\in \{00n,01n,01\overline {n}\}\cdot (V_n)^*$ . For every $x,y\in \{00n,01n,01\overline {n}\}$ , there exists a unique junction tile in ${\mathcal {T}}_n^{\prime }$ with bottom label x and left label y.

It remains to show the existence of tiles from ${\mathcal {T}}_n^{\prime }$ to cover the bottom row, the left column and the region of white tiles while respecting the label constraints; see Figure 15. Again, we proceed case by case.

Suppose that t is a junction tile in ${\mathcal {T}}_n^{\prime }$ ; that is, $u,v\in \{00n,01n,01\overline {n}\}$ . We have $|\tau _n(u)|=|\tau _n(v)|=n+1$ . In order to formalize the argument that follows, it is practical to define the following two maps on the subset $\{00n,01n,01\overline {n}\}\subset V_n$ :

$$\begin{align*}\begin{array}{rccl} \sigma:&\{00n,01n,01\overline{n}\}&\to& V_n\\ &00n &\mapsto& 01\overline{n},\\ &01n &\mapsto& 01n,\\ &01\overline{n}&\mapsto& 00n, \end{array} \quad \text{ and } \quad \begin{array}{rccl} \mu:&\{00n,01n,01\overline{n}\}&\to& V_n\\ &00n &\mapsto& 000,\\ &01n &\mapsto& 001,\\ &01\overline{n}&\mapsto& 011. \end{array} \end{align*}$$

Notice that $\alpha =\mu (v)$ and $\beta =\mu (u)$ and $\sigma $ is an involution. Also, if $v\in \{00n,01n,01\overline {n}\}$ , then $\tau _n\circ \mu (v)=\sigma (v)\cdot (11\overline {n})^n$ . From Lemma 5.2, there exists a unique choice of tiles for the bottom row whose sequence of top labels is $(111)^n$ and right-most right label is $01\overline {n}$ if $v=00n$ , $01n$ if $v=01n$ , $00n$ if $v=01\overline {n}$ . In other words, the right-most right label of the bottom row is $\sigma (v)$ . Symmetrically, there exists a unique choice of tiles for the left column whose sequence of right labels is $(111)^n$ and top-most top label is $\sigma (u)$ . Since the bottom row is of length n, and white tiles increase the last digit by one, the remaining region can be uniquely filled with white tiles such that the sequence of right labels of the rectangular pattern is $\sigma (v)\cdot (11\overline {n})^n=\tau _n\circ \mu (v)=\tau _n(\alpha )$ . Symmetrically, the sequence of top labels of the rectangular pattern is $\sigma (u)\cdot (11\overline {n})^n=\tau _n\circ \mu (u)=\tau _n(\beta )$ .

Suppose that is a white tile in ${\mathcal {T}}_n^{\prime }$ ; that is, $u=11j$ with $1\leq j\leq n$ and $v=11i$ with $1\leq i\leq n$ . Also, $\alpha =11\overline {j}$ and $\beta =11\overline {i}$ . We have $|\tau _n(u)|=|\tau _n(v)|=n$ . From Lemma 5.2, there exists a unique choice of tiles for the bottom row whose sequence of top labels is $(111)^{i-1}\cdot (112)^{n-i}$ and right-most right label is $01n$ . From a symmetric version of Lemma 5.2, there exists a unique choice of tiles for the left column whose sequence of right labels is $(111)^{j-1}\cdot (112)^{n-j}$ and top-most top label is $01n$ . The remaining region can be uniquely filled with white tiles. In this case, the sequence of right labels of the rectangular pattern is $01n\cdot (11n)^{j-1}\cdot (11\overline {n})^{n-j}=\tau _n(11\overline {j})=\tau _n(\alpha )$ . Symmetrically, the sequence of top labels of the rectangular pattern is $01n\cdot (11n)^{i-1}\cdot (11\overline {n})^{n-i}=\tau _n(11\overline {i})=\tau _n(\beta )$ .

Suppose that t is a horizontal stripe tile in ${\mathcal {T}}_n^{\prime }$ . We have $u=00j\text { with }0\leq j\leq n$ or $u=01j\text { with }1\leq j\leq n$ . Also $v\in \{11n,11\overline {n}\}$ . Let

$$\begin{align*}\beta= \begin{cases} 111 & \text{ if } u=00j\text{ with }0\leq j\leq n,\\ 112 & \text{ if } u=01j\text{ with }1\leq j\leq n, \end{cases} \quad \text{ and } \quad \alpha= \begin{cases} 00\overline{j} & \text{ if } v=11n,\\ 01\overline{j} & \text{ if } v=11\overline{n}. \end{cases} \end{align*}$$

Also, $|\tau _n(u)|=n+1$ and $|\tau _n(v)|=n$ . There are two cases for v:

• • If $v=11n$ , then from Lemma 5.2, there exists a unique choice of tiles for the bottom row whose sequence of top labels is $(111)^{n-1}$ and right-most right label is $01n$ .

• • If $v=11\overline {n}$ , then from Lemma 5.2, there exists a unique choice of tiles for the bottom row whose sequence of top labels is $(111)^{n-1}$ and right-most right label is $00n$ .

There are two cases for u:

• • If $u=00j$ with $0\leq j\leq n$ , then from the symmetric version of Lemma 5.2, there exists a unique choice of tiles for the left column whose sequence of right labels is $(111)^{j}\cdot (112)^{n-j}$ and top-most top label is $01\overline {n}$ .

• • If $u=01j$ with $1\leq j\leq n$ , then from the symmetric version of Lemma 5.2, there exists a unique choice of tiles for the left column whose sequence of right labels is $(111)^{j}\cdot (112)^{n-j}$ and top-most top label is $01n$ .

Thus, the remaining region can be uniquely filled with white tiles, and the sequence of right labels of the rectangular pattern is

$$\begin{align*}\tau_n(\alpha)= \begin{cases} 01n\cdot(11n)^{j}\cdot(11\overline{n})^{n-j}=\tau_n(00\overline{j}) & \text{ if } v=11n,\\ 00n\cdot(11n)^{j}\cdot(11\overline{n})^{n-j}=\tau_n(01\overline{j}) & \text{ if } v=11\overline{n}. \end{cases} \end{align*}$$

Symmetrically, the sequence of top labels of the rectangular pattern is

$$\begin{align*}\tau_n(\beta)= \begin{cases} 01\overline{n}\cdot(11\overline{n})^{n-1}=\tau_n(111) & \text{ if } u=00j \text{ with } 0\leq j\leq n,\\ 01n\cdot(11\overline{n})^{n-1}=\tau_n(112) & \text{ if } u=01j\text{ with }1\leq j\leq n. \end{cases} \end{align*}$$

Suppose that t is a vertical stripe tile in ${\mathcal {T}}_n^{\prime }$ . A rectangular pattern respecting the constraints can be obtained by taking the image under reflection of the rectangular pattern constructed above for when t is a horizontal stripe tile in ${\mathcal {T}}_n^{\prime }$ .

(Uniqueness) Uniqueness follows from Lemma 2.1 and Lemma 4.3.

Proof. From Lemma 5.3, for every tile $t\in {\mathcal {T}}_n^{\prime }$ , the image ${\omega }_n^{\prime }(t)$ is a valid rectangular pattern over the Wang tiles ${\mathcal {T}}_n^{\prime }$ . Moreover, if $s\odot ^1t\in ({\mathcal {T}}_n^{\prime })^{*^2}$ is a valid horizontal domino, then ${\omega }_n^{\prime }(s\odot ^1t)$ is a valid rectangular pattern over the Wang tiles ${\mathcal {T}}_n^{\prime }$ . Similarly, if $s\odot ^2t\in ({\mathcal {T}}_n^{\prime })^{*^2}$ is a valid vertical domino, then ${\omega }_n^{\prime }(s\odot ^2t)$ is a valid rectangular pattern over the Wang tiles ${\mathcal {T}}_n^{\prime }$ . Thus, if $y\in {\Omega }_n^{\prime }$ is a valid configuration, then ${\omega }_n^{\prime }(y)$ is also a valid configuration. Therefore, ${\omega }_n^{\prime }(y)\in {\Omega }_n^{\prime }$ .

Proof. Let $n\geq 1$ be an integer. ( $\impliedby $ ) If $n=1$ , the set of antigreen tiles in ${\mathcal {T}}_1^{\prime }$ is $A_1\cup \widehat {A_1}=\{a_1^1,\widehat {a_1^1}\}$ . In Figure 17, we observe that $\omega _1^{\prime }(a_1^1)$ contains the junction tile $j_1^{1,1,0,0}\in {\mathcal {T}}_1^{\prime }\setminus {\mathcal {T}}_1$ and $\omega _1^{\prime }(\widehat {a_1^1})$ contains the junction tile $j_1^{0,0,1,1}\in {\mathcal {T}}_1^{\prime }\setminus {\mathcal {T}}_1$ .

( $\implies $ ) Let . The labels of the boundary of ${\omega }_n^{\prime }(t)$ are . Suppose that the pattern ${\omega }_n^{\prime }(t)$ contains a tile in ${\mathcal {T}}_n^{\prime }\setminus {\mathcal {T}}_n$ . We have $v\in V_n\setminus \{00\overline {n}\}$ . From Lemma 5.2, the bottom row of the pattern ${\omega }_n^{\prime }(t)$ does not contain the last blue tile. Also, $u\in V_n\setminus \{00\overline {n}\}$ . From the symmetric version of Lemma 5.2, the left column of the pattern ${\omega }_n^{\prime }(t)$ does not contain the last blue tile. From Lemma 5.2, the pattern ${\omega }_n^{\prime }(t)$ does not contain any antigreen (vertical or horizontal) stripe tile. Therefore, the pattern ${\omega }_n^{\prime }(t)$ must contain a junction tile in $J_n^{\prime }\setminus J_n=\{j_n^{1,1,0,0},j_n^{0,0,1,1}\}$ .

Suppose that ${\omega }_n^{\prime }(t)$ contains the junction tile $j_n^{1,1,0,0}$ . Therefore, we must have $\tau _n(v)\in 01\overline {n}\cdot (V_n)^*$ and $\tau _n(u)\in 00n\cdot (V_n)^*$ . Thus, $v\in \{000,111\}$ and $u=01j$ with $1\leq j\leq n$ . We proceed case by case.

• • Assume $v=000$ . The only tile $t\in {\mathcal {T}}_n^{\prime }$ with bottom label $v=000$ is a blue or green vertical stripe tile whose left label is $u=11n$ or $u=11\overline {n}$ , a contradiction.

• • Assume $v=111$ and $n>1$ . The only tile $t\in {\mathcal {T}}_n^{\prime }$ with bottom label $v=111$ is a white tile whose left label is $u=11i$ with $1\leq i\leq n$ , a contradiction.

• • Assume $v=111$ and $n=1$ . The only tile $t\in {\mathcal {T}}_1^{\prime }$ with bottom label $v=111$ is a white tile whose left label is $u=111$ , a blue horizontal stripe tile whose left label is $000$ or $001$ , or an antigreen tile $a_1^1$ whose left label is $011$ . Only the antigreen tile does not yield a contradiction with the value of u given above. Thus, $t=a_1^1$ .

Symmetrically, if ${\omega }_n^{\prime }(t)$ contains the junction tile $j_n^{0,0,1,1}$ , we conclude that $n=1$ and $t=\widehat {a_1^1}$ .

Proof. From Lemma 5.4, the map ${\omega }_n^{\prime }$ defines a $2$ -dimensional substitution ${\Omega }_n^{\prime }\to {\Omega }_n^{\prime }$ . From Lemma 5.5, ${\omega }_n^{\prime }(x)\in {\Omega }_n$ for every configuration $x\in {\Omega }_n$ . Thus, ${\omega }_n^{\prime }({\Omega }_n)\subseteq {\Omega }_n$ . The restriction of ${\omega }_n^{\prime }$ to ${\Omega }_n$ is ${\omega }_n$ , so that ${\omega }_n({\Omega }_n)\subseteq {\Omega }_n$ . Since ${\Omega }_n$ is a subshift, it is closed under the shift. Therefore, $\overline {{\omega }_n({\Omega }_n)}^\sigma \subset {\Omega }_n$ .

Proof. Suppose that $u\in V_n\setminus Z_n$ and $v=11\overline {n}$ . We have $|\tau _n(u)|=|\tau _n(v)|=n$ . Since $v=11\overline {n}$ , then from Lemma 5.2, there exists a unique choice of tiles for the bottom row whose sequence of top labels is $(111)^{n-1}$ and right-most right label is $00n$ . There are two cases to consider for u:

• • If $u=11j$ with $1\leq j\leq n$ , then from a symmetric version of Lemma 5.2, there exists a unique choice of tiles for the left column whose sequence of right labels is $(111)^{j-1}\cdot (112)^{n-j}$ .

• • If $u=11\overline {n}$ , then from a symmetric version of Lemma 5.2, there exists a unique choice of tiles for the left column whose sequence of right labels is $(111)^{n-1}$ .

In both cases, the remaining region of the rectangular pattern can be uniquely filled with white tiles. The sequence of right labels of the rectangular pattern starts with $00n$ . Such a sequence cannot be written as an image under the map $\tau _n$ because there is no $\alpha \in V_n$ such that $\tau _n(\alpha )$ starts with $00n$ and is of length n.

Suppose that $u\in M_n\cap Z_n=\{00n,00\overline {n},01n,01\overline {n}\}$ and $v=00\overline {n}$ . We have $|\tau _n(u)|=|\tau _n(v)|=n+1$ . From Lemma 5.2, there exists a unique choice of tiles for the bottom row whose sequence of top labels is $(111)^n$ . Since $v=00\overline {n}$ , from a symmetric version of Lemma 5.2, there exists a unique choice of tiles for the left column whose sequence of right labels is $(111)^n$ and top-most top label is $00\overline {n}$ . Since the bottom row is of length n, and white tiles increase the last digit by one, the remaining region can be uniquely filled with white tiles. Since the sequence of top labels of the rectangular pattern starts with $00\overline {n}$ , it cannot be written as an image under the map $\tau _n$ .

Suppose that $u\in \{00\overline {n},01\overline {n}\}$ and $v\in M_n\setminus Z_n=\{11n,11\overline {n}\}$ . We have $|\tau _n(u)|=n+1$ and $|\tau _n(v)|=n$ . From Lemma 5.2, there exists a unique choice of tiles for the bottom row whose sequence of top labels is $(111)^n$ . Symmetrically, there exists a unique choice of tiles for the left column whose sequence of right labels is $(111)^n$ and top-most top label is in $\{00n,00\overline {n}\}$ . The remaining region can be uniquely filled with white tiles. The sequence of top labels is in $\{00n,00\overline {n}\}\cdot (11\overline {n})^{n-1}$ . Such a sequence cannot be written as an image under the map $\tau _n$ because there is no $\alpha \in V_n$ such that $\tau _n(\alpha )$ starts with $00n$ or $00\overline {n}$ and is of length n.

Suppose that $u=11\overline {n}$ and $v\in V_n\setminus Z_n$ , or $u=00\overline {n}$ and $v\in M_n\cap Z_n$ , or $u\in M_n\setminus Z_n$ and $v\in \{00\overline {n},01\overline {n}\}$ . A rectangular pattern respecting the constraints can be obtained by taking the image under reflection of the rectangular pattern constructed above.

Proof. Let $u,v\in V_n$ . ( $\implies $ ) We show the contrapositive – namely, that if (5.5) does not hold, then there is no rectangular pattern with $\tau _n(u)$ as the sequence of labels on the left and $\tau _n(v)$ as the sequence of labels at the bottom. If (5.5) does not hold, then

$$ \begin{align*} (u,v)\in &\big((Z_n \times V_n\setminus Z_n)\cup (V_n\setminus Z_n \times Z_n)\cup (Z_n \times Z_n)\big)\\ &\qquad\qquad\setminus \big( (M_n\cap Z_n\times M_n\cap Z_n) \cup(M_n\setminus Z_n\times Z_n) \cup(Z_n\times M_n\setminus Z_n) \big) \\ &=(Z_n \times V_n\setminus (M_n\cup Z_n))\cup (V_n\setminus (M_n\cup Z_n) \times Z_n) \cup(Z_n \times Z_n\setminus M_n) \cup(Z_n\setminus M_n \times Z_n). \end{align*} $$

There are four cases to consider:

• • Assume $u\in Z_n$ and $v\in V_n\setminus (M_n\cup Z_n)$ . We have $v=11j$ with $1\leq j<n$ . From Lemma 5.2, the bottom row of the rectangular pattern has at least one label $112$ on its top. Since the difference between the last digit of the top label and the last digit of the bottom label of a white tile is 1 and the maximal last digit of a white tile in ${\mathcal {T}}_n$ is $\overline {n}$ , the height of the white tile region is at most $n-1$ ; see Figure 18. Thus, $|\tau _n(u)|\leq n$ . This is incompatible with $u\in Z_n$ because $u\in Z_n$ implies that $|\tau _n(u)|=n+1$ .

  Figure 18

  The height of a valid vertical column made entirely of white tiles from ${\mathcal {T}}_n$ is at most $n-1$ if the bottom label of the bottom-most tile is $112$ or if the top label of the top-most tile is $11n$ .

  

• • Assume $u\in V_n\setminus (M_n\cup Z_n)$ and $v\in Z_n$ . This case also leads to a contradiction following an argument symmetric to the previous one.

• • Assume $u\in Z_n$ and $v\in Z_n\setminus M_n$ . We have $v=00j$ with $0\leq j<n$ or $v=01j$ with $1\leq j<n$ . In both cases, we have from Lemma 5.2 that the bottom row of the rectangular pattern has at least one label $112$ on its top. For the same reason as in the first item, the height of the rectangular pattern is $|\tau _n(u)|\leq n$ . This is incompatible with $u\in Z_n$ because $u\in Z_n$ implies that $|\tau _n(u)|=n+1$ .

• • Assume $u\in Z_n\setminus M_n$ and $v\in Z_n$ . This case also leads to a contradiction following an argument symmetric to the previous one.

( $\impliedby $ ) Let

Notice that $Q\subset P$ and

(5.6) $$ \begin{align} \begin{aligned} P\setminus Q &= (\{11\overline{n}\}\times V_n\setminus Z_n) \cup(V_n\setminus Z_n\times \{11\overline{n}\})\\ &\qquad\cup(\{00\overline{n}\}\times M_n\cap Z_n) \cup(M_n\cap Z_n\times \{00\overline{n}\})\\ &\qquad\cup(\{00\overline{n},01\overline{n}\}\times M_n\setminus Z_n) \cup(M_n\setminus Z_n\times \{00\overline{n},01\overline{n}\}). \end{aligned} \end{align} $$

We assume that (5.5) holds; that is, $(u,v)\in P$ . There are two cases to consider.

• • If $(u,v)\in Q$ , then, from Lemma 5.3, there exists a valid rectangular pattern with tiles in ${\mathcal {T}}_n^{\prime }$ whose left and bottom labels are respectively $\tau _n(u)$ and $\tau _n(v)$ .

• • If $(u,v)\in P\setminus Q$ , then using (5.6) and Lemma 5.7, there exists a valid rectangular pattern with tiles in ${\mathcal {T}}_n^{\prime }$ whose left and bottom labels are respectively $\tau _n(u)$ and $\tau _n(v)$ .

Proof. Let $\alpha ,\beta ,u,v\in V_n$ . ( $\impliedby $ ) The existence of the rectangular pattern was proved in Lemma 5.3.

( $\implies $ ) Suppose that there exists a valid rectangular pattern with tiles in ${\mathcal {T}}_n^{\prime }$ whose right, top, left and bottom labels are respectively $\tau _n(\alpha )$ , $\tau _n(\beta )$ , $\tau _n(u)$ and $\tau _n(v)$ . From Proposition 5.8, $(u,v)$ satisfies (5.5); that is $(u,v)\in P$ . From Lemma 5.7, $(u,v)$ does not satisfy (5.4) because all boundary words can be written as the image of $\tau _n$ . Thus, $(u,v)\notin P\setminus Q$ using (5.6). We conclude that $(u,v)\in Q$ . Thus, there exists $\alpha ',\beta '\in V_n$ such that . From Lemma 5.3, there exists a valid rectangular pattern with tiles in ${\mathcal {T}}_n^{\prime }$ whose right, top, left and bottom labels are respectively $\tau _n(\alpha ')$ , $\tau _n(\beta ')$ , $\tau _n(u)$ and $\tau _n(v)$ . From Lemma 2.1, we must have $\tau _n(\alpha ')=\tau _n(\alpha )$ and $\tau _n(\beta ')=\tau _n(\beta )$ because ${\mathcal {T}}_n^{\prime }$ is SW-deterministic from Lemma 4.3. Since $\tau _n$ is injective over the set $V_n$ , we have $\alpha =\alpha '$ and $\beta =\beta '$ .

Proof. Let $\alpha ,\beta ,u,v\in V_n$ . ( $\implies $ ) follows from Proposition 5.9 since ${\mathcal {T}}_n\subset {\mathcal {T}}_n^{\prime }$ .

( $\impliedby $ ) From Lemma 5.5, for every tile $t\in {\mathcal {T}}_n^{\prime }$ , the rectangular pattern ${\omega }_n^{\prime }(t)$ satisfies the boundary conditions, and it contains only the tiles from the set ${\mathcal {T}}_n$ .

Proof. The horizontal Rauzy graph restricted to tiles whose vertical edge labels are starting with zero is shown in Figure 20. An arc in the horizontal Rauzy graph links two tiles $s\to t$ if and only if the right label of tile s is equal to the left label of tile t. The graph allows to visualize the combinatorial structure between two consecutive junction tiles on the same horizontal row within a configuration of ${\Omega }_n^{\prime }$ .

Figure 20

Combinatorial structure between two consecutive junction tiles on the same horizontal row within a configuration of ${\Omega }_n^{\prime }$ . The nodes of the graph are placed such that any two tiles appearing in the same column have the same last digit for its left or right labels. The length of a path from a junction tile to a junction tile is n, $n+1$ or $n+2$ .

The right label of a junction tile is $000$ , $001$ or $011$ , which implies that the last digit of the right label of a junction tile is $0$ or $1$ . The left label of a junction tile is $00n$ , $01n$ or $01\overline {n}$ , which implies that the last digit of the left label of a junction tile is n or $\overline {n}$ . Since the last digit increases by 1 from the left label to the right label of every intermediate tile (a tile appearing in between two consecutive junction tiles in the same row), the number of tiles in between two consecutive junction tiles on the same row is at least $n-1$ and at most $\overline {n}-0=n+1$ . We conclude that the distance (number of edges in the Rauzy graph) between two consecutive junction tiles in the same row is n, $n+1$ or $n+2$ . In particular, it is at least n.

The bottom label of a junction tile is in the set $\{00n,01n,01\overline {n}\}$ . The bottom label of every intermediate tile is $11n$ or $11\overline {n}$ . Therefore, the sequence of bottom labels of the tiles between two consecutive junction tiles (including the left junction tile but not the right one) belongs to $\{00n,01n,01\overline {n}\} \cdot \{11n,11\overline {n}\}^*$ ; see Figure 20.

Proof. The horizontal Rauzy graph restricted to vertical edge labels starting with $1$ is shown in Figure 21. An arc in the horizontal Rauzy graph links two tiles $s\to t$ if and only if the right label of tile s is equal to the left label of tile t. The graph allows to visualize the combinatorial structure between two consecutive vertical stripe tiles on the same horizontal row within a configuration of ${\Omega }_n^{\prime }$ .

Figure 21

Combinatorial structure between two consecutive vertical stripe tile on the same horizontal row within a configuration of ${\Omega }_n^{\prime }$ . The length of a path from a vertical stripe tile to a vertical stripe tile is $n-1$ , n or $n+1$ .

The right label of a vertical stripe tile is $111$ or $112$ , which implies that the last digit of the right label of a vertical stripe tile is $1$ or $2$ . The left label of a vertical stripe tile is $11n$ or $11\overline {n}$ , which implies that the last digit of the left label of a vertical stripe tile is n or $\overline {n}$ . Since the last digit increases by 1 from the left label to the right label of every intermediate tile (a tile appearing in between two consecutive vertical stripe tiles in the same row), the number of tiles in between two consecutive vertical stripe tiles on the same row is at least $n-2$ and at most $\overline {n}-1=n$ . We conclude that the distance (number of edges in the Rauzy graph) between two consecutive vertical stripe tiles in the same row is $n-1$ , n or $n+1$ . In particular, it is at most $n+1$ .

Proof. (1) Let

$$ \begin{align*} E &= \{(\alpha_1\alpha_2\alpha_3, \beta_1 \beta_2 \beta_3, \gamma_1\gamma_2\gamma_3, \delta_1\delta_2\delta_3) \in{\mathcal{T}}_n^{\prime}\mid\alpha_1=0\}\subset {\mathcal{T}}_n^{\prime},\\ F &= \{(\alpha_1\alpha_2\alpha_3, \beta_1 \beta_2 \beta_3, \gamma_1\gamma_2\gamma_3, \delta_1\delta_2\delta_3) \in{\mathcal{T}}_n^{\prime}\mid\beta_1=0\}\subset {\mathcal{T}}_n^{\prime}. \end{align*} $$

Tiles in E have zero as the first coordinate of their right and left edge labels since $\alpha _1=\gamma _1$ . Tiles in F have zero as the first coordinate of their top and bottom edge labels since $\beta _1=\delta _1$ . Notice that we have $E\cup F \subset Y_n\cup \widehat {Y_n} \cup G_n\cup \widehat {G_n} \cup B_n^{\prime }\cup \widehat {B_n^{\prime }}\cup J_n^{\prime } \cup A_n\cup \widehat {A_n}$ and $E\cap F = J_n^{\prime }$ . Let $c\in {\Omega }_n^{\prime }$ be a valid configuration. The positions of tiles from E in c are contiguous rows; that is, there exists $B\subset \mathbb {Z}$ such that $c^{-1}(E)=\mathbb {Z}\times B$ . The positions of tiles from F in c are contiguous columns; that is, there exists $A\subset \mathbb {Z}$ such that $c^{-1}(F)=A\times \mathbb {Z}$ . Therefore, the set of positions of junction tiles in c is given by the Cartesian product of A and B:

$$\begin{align*}c^{-1}(J_n^{\prime}) = c^{-1}(E \cap F) = c^{-1}(E) \cap c^{-1}(F) = (\mathbb{Z}\times B) \cap (A\times\mathbb{Z}) = A\times B. \end{align*}$$

The fact that the sets A and B are the images of increasing maps $\mathbb {Z}\to \mathbb {Z}$ follows from observations (2) and (3) proved below.

(2) From Lemma 6.1, the distance between two consecutive occurrences of junction tiles in the same row is n, $n+1$ or $n+2$ . From Lemma 6.2, the distance between two consecutive occurrences of a vertical stripe tile (blue, green, yellow or antigreen) in the same row is $n-1$ , n or $n+1$ . Since vertical strips and junction tiles are vertically aligned, the difference between two consecutive elements of $A\subset \mathbb {Z}$ is n or $n+1$ . Also, if $a\in A$ , then $a+n\in A$ or $a+n+1\in A$ . Also $a-n\in A$ or $a-n-1\in A$ . Thus, A is the image of an increasing map $A:\mathbb {Z}\to \mathbb {Z}$ such that $A(k+1)-A(k)\in \{n,n+1\}$ for every $k\in \mathbb {Z}$ .

(3) From the symmetry of the set ${\mathcal {T}}_n^{\prime }$ of tiles, the same observation holds for the distance between consecutive junction tiles in the same column.

Proof. Let $c\in {\Omega }_n^{\prime }$ be a configuration. Let $A,B:\mathbb {Z}\to \mathbb {Z}$ be the two increasing maps from Lemma 6.3 such that $c^{-1}(J_n^{\prime })=A(\mathbb {Z})\times B(\mathbb {Z})$ . For every ${\boldsymbol {\ell }}=(\ell _1,\ell _2)\in \mathbb {Z}^2$ , the pattern appearing in c at support $[A(\ell _1),A(\ell _1+1)-1]\times [B(\ell _2),B(\ell _2+1)-1]$ is a rectangular pattern containing a unique junction tile at its bottom left corner.

Proof. From Lemma 6.1, the sequence of bottom labels of the tiles between two consecutive junction tiles (including the left junction tile but not the right one) belongs to $\{00n,01n,01\overline {n}\} \cdot \{11n,11\overline {n}\}^*$ .

In the bottom row of every return block within a configuration in ${\Omega }_n$ , there is no antigreen stripe tile, and the horizontal blue, green and yellow stripe tiles appear in this order: blue $\to $ green $\to $ yellow. Since the bottom label of a blue horizontal stripe tile is $11n$ and the bottom label of a green or yellow horizontal stripe tile is $11\overline {n}$ , the sequence of bottom labels of tiles in a horizontal row starting from a junction tile and ending before the next occurrence of a junction tile is in the set

$$\begin{align*}\{00n,01n,01\overline{n}\} \cdot (11n)^*(11\overline{n})^*. \end{align*}$$

Some more restrictions are imposed:

• • If it starts with $00n$ , the length of the sequence is $n+1$ . Indeed, if the bottom label of a junction tile is $00n$ , then its right label is $000$ with last digit $0$ . From Figure 24, the width of the return block containing this junction tile must be $n+1$ or $n+2$ . A return block of width $W=n+2$ is impossible from Proposition 6.4. Thus, the width of the return bock is $W=n+1$ .

• • Also, if it starts with $01\overline {n}$ , the next label is not $11n$ and has to be $11\overline {n}$ . Indeed $01\overline {n}$ is the bottom label of a junction tile with right label $011$ , and $011$ must be the left label of a yellow horizontal stripe tile with bottom label $11\overline {n}$ ; see Figure 24.

Restricting the sequences to those of lengths n or $\overline {n}$ , we have that the sequence of bottom labels of tiles in the bottom row of the return block r (from left to right) belongs to the set

$$ \begin{align*} & \{01\overline{n}\cdot (11\overline{n})^{i} \mid n-1\leq i\leq n\}\\ &\cup\{01n \cdot (11n)^{i}(11\overline{n})^{j} \mid i,j\geq0, n-1\leq i+j\leq n\}\\ &\cup\{00n \cdot (11n)^{i}(11\overline{n})^{j} \mid i,j\geq0, i+j=n \}\\ =\;&\{\tau_n(111), \tau_n(000)\}\\ &\cup\{\tau_n(00i)\mid 1\leq i \leq n+1\} \cup\{\tau_n(11i)\mid 2\leq i \leq n+1\}\\ &\cup\{\tau_n(01i)\mid 1\leq i \leq n+1\}\\ =\;&\tau(V_n).\\[-38pt] \end{align*} $$

Proof. Let $y\in {\Omega }_n$ be a configuration. From Proposition 6.4, the configuration y can be divided into return blocks, – that is, rectangular blocks of sizes $n\times n$ , $n\times \overline {n}$ , $\overline {n}\times n$ or $\overline {n}\times \overline {n}$ with a unique junction tiles at the bottom left corner; see Figure 23.

Let r be a return block appearing in y. From Lemma 6.5, the sequences of bottom labels of tiles in the bottom row of the return block r (from left to right) belong to the set $\tau _n(V_n)$ . By symmetry and since r is surrounded by returns blocks, this also holds for the right, top and left labels of r. Therefore, let $\alpha ,\beta ,\gamma ,\delta \in V_n$ such that the right, top, left and bottom labels of the return block r are respectively $\tau _n(\alpha )$ , $\tau _n(\beta )$ , $\tau _n(\gamma )$ and $\tau _n(\delta )$ . From Proposition 5.9, . From Lemma 5.3, there exists a unique rectangular pattern with these external labels. Thus, $r={\omega }_n^{\prime }(t)$ .