Proof. The implication $(i) \Rightarrow (ii)$ is obvious. We next prove that $(ii)$ implies $(iii)$ . To this end, let $x\in X$ be such that the set

$$ \begin{align*}\{(S_{a_{1}(n)}x,\dots,S_{a_{d}(n)}x)\colon n\in\mathbb{Z}\}\end{align*} $$

is dense in $X^{d}$ . Then, for any $m\in \mathbb {Z}^{k}$ , the set

$$ \begin{align*}X(x,m):=\{(S_{a_{1}(n)+m}x,\dots,S_{a_{d}(n)+m}x)\colon n\in\mathbb{Z}\}\end{align*} $$

is also dense in $X^{d}$ . Now, for any nonempty open subsets $U,V_{1},\dots ,V_{d}$ of X, by the minimality of $(X,S_{1},\dots ,S_{k})$ , we may find some $m\in \mathbb {Z}^{k}$ such that $S_{m}x\in U,$ and since $X(x,m)$ is dense in $X^{d}$ , there exists $n\in \mathbb {Z}$ such that $S_{a_{i}(n)+m}x\in V_{i}$ for all $1\leq i\leq d$ . Therefore, the set

$$\begin{align*}U \cap S_{-a_{1}(n)}V_{1}\cap \dots\cap S_{-a_{d}(n)}V_{d}\end{align*}$$

contains the point $T_{m}x$ ; hence, it is nonempty.

It remains to show that $(iii)$ implies $(i)$ . Let $\mathcal {F}$ be a countable basis of the topology of X and define

It follows from $(iii)$ that $\Omega $ is a dense $G_{\delta }$ set. Moreover, the set

$$\begin{align*}\{(S_{a_{1}(n)}x,\dots,S_{a_{d}(n)}x)\colon n\in\mathbb{Z}\}\end{align*}$$

is dense in $X^{d}$ for every $x\in \Omega $ .

Proof. $(i)$ and $(iv)$ follow directly from the definitions.

To show $(ii)$ , first note that for all $x \in X$ , $g_1 \in G_1$ , and $g_2\in G_2$ , the point $(x,S_{g_1}x,S_{g_2}x,S_{g_1+g_2}x)$ belongs to $\mathbf {RP}_{G_2^{\Delta }}(\mathbf {RP}_{G_1}(X))$ (here, we naturally identify this point with $((x,S{g_1}x),(S_{g_2}x,S_{g_1+g_2}x))$ ). Therefore, $\boldsymbol{Q}_{G_1,G_2}(X)\subseteq \mathbf {RP}_{G_2^{\Delta }}(\mathbf {RP}_{G_1}(X))$ . For the converse inclusion, it suffices to show that for any $(x,y)\in \mathbf {RP}_{G_1}(X)$ and any $g_2\in G_2$ , we have $(x,y,S_{g_2}x,S_{g_2}y)\in \boldsymbol{Q}_{G_1,G_2}(X)$ . Let $\epsilon>0$ and choose $0<\delta <\epsilon $ so that if $z,z'\in X$ and $\rho (z,z')<\delta $ , then $\rho (S_{g_2}z,S_{g_2}z')<\epsilon $ . We can find $x'\in X$ and $g_1\in G_1$ such that $\rho ((x',S_{g_1}x'),(x,y))<\delta $ . It follows that $( x',S_{g_1}x',S_{g_2}x',S_{g_1+g_2}x')$ is at distance at most $\epsilon $ of $(x,y,S_{g_2}x,S_{g_2}y)$ . Since $\epsilon>0$ is arbitrary, we conclude that $(x,y,S_{g_2}x,S_{g_2}y)\in \boldsymbol{Q}_{G_1,G_2}(X)$ as desired.

$(iii)$ follows immediately from $(ii)$ .

Proof. Note that by Lemma 2.2 $(iv)$ , the inclusion $\boldsymbol{Q}_{G,H}(X)\subseteq \boldsymbol{Q}_{\mathbb {Z}^k,\mathbb {Z}^k}(X)$ always holds. In addition, if G is transitive, since $\mathbf {RP}_{G}(X)=X\times X=\mathbf {RP}_{\mathbb {Z}^k}(X)$ , Lemma 2.2 $(iii)$ implies that $\boldsymbol{Q}_{G,H}(X)=\boldsymbol{Q}_{\mathbb {Z}^k,H}(X)$ . Using $(i)$ and $(iii)$ of Lemma 2.2, we get $\boldsymbol{Q}_{G,G}(X)=\boldsymbol{Q}_{\mathbb {Z}^k,\mathbb {Z}^k}(X),$ from where $\mathbf {RP}_{G,G}(X)=\mathbf {RP}_{\mathbb {Z}^k,\mathbb {Z}^k}(X)$ .

Proof. Let $\epsilon>0$ be such that $B(y,\epsilon )\subseteq U$ . For $i\in \mathbb {N}$ , set $\epsilon _i=\epsilon /2^i$ . Construct a sequence $(\delta _i)_{i\in \mathbb {N}}$ , with $0<\delta _i<\epsilon _i$ and a sequence $(m_i,n_i)_{i\in \mathbb {N}}$ in $\mathbb {Z}\times \mathbb {Z}$ as follows: Let $n_1,m_1$ be such that $\rho (T^{n_1}x,x)<\epsilon _1$ , $\rho (T^{m_1}x,y)<\epsilon _1,$ and $\rho (T^{n_1+m_1}x,x)<\epsilon _1$ . Pick $0<\delta _2<\epsilon _2$ such that $\rho (z,z')<\delta _2$ implies that $\rho (T^a z,T^a z')<\epsilon _2$ for all $|a|\leq |n_1|+|m_1|$ . Take $n_2$ , $m_2$ such that $\rho (T^{n_2}x,x)< \delta _2$ , $\rho (T^{m_2}x,y)< \delta _2$ and $\rho (T^{n_2+m_2}x,x)<\delta _2$ . (We highlight here that the numbers $n_2, m_2$ can be taken to be arbitrarily large.) Note that the definition of $\delta _2$ implies that

$$ \begin{align*} &\rho(T^{n_2+n_1}x,x)< \epsilon_1+\epsilon_2, \ \rho(T^{n_2+n_1+m_1}x,x) < \epsilon_1+\epsilon_2, \ \rho(T^{n_2+m_2+n_1}x,x)<\epsilon_1+\epsilon_2, \\& \qquad\rho(T^{n_2+m_2+n_1+m_1}x,x)< \epsilon_1+\epsilon_2, \ \rho(T^{n_2+m_1}x,y) < \epsilon_1+\epsilon_2, \;\; \text{and}\;\; \rho(T^{n_2+m_2+m_1}x,y) < \epsilon_1+\epsilon_2. \end{align*} $$

So, if we set $R_1=\{n_1,n_1+m_1\}$ , $P_1=\{m_1\}$ , $R_2=\{n_2,n_2+m_2\}$ , we have that $\rho (T^{a+b}x,x)< \epsilon _1+\epsilon _2$ for all $a\in R_2$ and $b\in R_1$ , and $\rho (T^{a+c}x,y)<\epsilon _1+\epsilon _2$ for all $a\in R_2$ and $c\in P_1$ (here, R stands for ‘return’ and P for ‘passage’).

The idea of the proof is that return times associated with large indices are compatible with return times and passages associated with smaller indices. More precisely, inductively, suppose that we have defined $\delta _i$ , $m_i$ and $n_i$ for all $1\leq i\leq l$ for some $l\in \mathbb {N}$ , and for the set $R_i=\{n_i,n_i+m_i\}$ and $P_i=\{m_i\}$ , we have that if $a=r_{j_1}+\dots +r_{j_l}$ , with $r_{j_k}\in R_{j_k}$ , $j_1<\ldots < j_l$ , then $\rho (T^ax,x) <\sum _{t=1}^{l} \epsilon _{j_t} $ , and $\rho (T^{a+c}x,y)< \epsilon _k + \sum _{t=1}^{l} \epsilon _{j_t} $ if $c\in P_k$ , $k<j_1$ .

Let $0<\delta _{i+1}<\epsilon _{i+1}$ be such that $\rho (z,z')<\delta _{i+1}$ implies that $\rho (T^a z,T^a z')<\epsilon _{i+1}$ for all $|a|\leq |n_1|+|m_1|+\cdots + |n_i|+|m_i|$ . Then choose $n_{i+1}$ and $m_{i+1}$ such that $\rho (T^{n_{i+1}}x,x)< \delta _{i+1}$ , $\rho (T^{n_{i+1}+m_{i+1}}x,x)< \delta _{i+1},$ and $\rho (T^{m_{i+1}}x,y)< \delta _{i+1}$ , and set $R_{i+1}=\{n_{i+1}, n_{i+1}+m_{i+1}\}$ , $P_{i+1}=\{m_{i+1}\}$ .

We claim that if $a=r_{j_1}+r_{j_2}+\dots + r_{j_l}$ , with $r_{j_k}\in R_{j_k}$ , $j_1<\ldots < j_l\leq i+1$ , then $\rho (T^ax,x)< \sum _{t=1}^{l} \epsilon _{j_t} $ , and $\rho (T^{a+c}x,y)< \epsilon _k + \sum _{t=1}^{l} \epsilon _{j_t} $ if $c\in P_k$ , $k<j_1$ .

We only need to check the case $j_l=i+1$ . Assume that $r_{i+1}=n_{i+1}$ (the case $r_{i+1}=n_{i+1}+m_{i+1}$ is identical). Since $\rho (T^{n_{i+1}}x,x)< \delta _{i+1}$ , and $|a-n_{i+1}|\leq |n_1|+|m_1|+\dots +|n_i|+|m_i|$ , we get $\rho (T^{a}x,T^{a-n_{i+1}}x)< \epsilon _{i+1}$ . By induction, $\rho (T^{a-n_{i+1}}x,x)< \sum _{t=1}^{l-1}\epsilon _{j_t}$ , so the triangle inequality implies that $\rho (T^ax,x)<\sum _{t=1}^{l}\epsilon _{j_t}$ , as desired. The estimate of $\rho (T^{a+c}x,y)$ follows in a similar way.

Now set $a_i=n_{i+1}+\sum _{j=1}^i (n_j+m_j)$ . Note that we may further require the sequence $(a_i)_{i\in \mathbb {N}}$ to take infinitely many values (by choosing the $n_i$ ’s and $m_i$ ’s to go to infinity) and $a_{i+l}-a_i =n_{i+l+1} + \sum _{j=i+2}^{i+l} (n_{j}+m_j) +m_{i+1}$ . Hence, we can rewrite this as $a_{i+l}-a_i=r_{i+l+1}+\sum _{j=i+2}^{i+l} r_j + c$ , where $r_j\in R_j$ and $c\in P_{i+1}$ . It follows from the construction of the sequence $\{n_i,m_i:i \in \mathbb {N}\}$ that $\rho (T^{a_{i+l}-a_i}x,y)<\sum _{t=i+1}^{i+l+1}\epsilon _i< \epsilon $ , which implies that $T^{a_{i+l}-a_i}x\in U,$ as was to be shown.

Proof. The set $\Omega _i$ of $\tilde {x}\in X$ such that the set $\{(a,b,c):(\tilde {x},a,b,c)\in \boldsymbol{Q}_{T_i,T_i}(X) \}$ equals $\overline {\mathcal {F}_{T_{i},T_i}}(\tilde {x})$ is a dense $G_{\delta }$ set of points (see, for instance, [Reference Glasner26, Lemma 4.5]). Since $\pi $ is open, we can find $\tilde {x}\in U_{x_i}\cap \Omega _{i}$ and $\tilde {y}\in U_{x_i'}$ with $(\tilde {x},\tilde {y})\in R_{\pi }$ . Because $R_{\pi }\subseteq \mathbf {RP}_{T_i,T_i}(X)$ , we have that $(\tilde {x},\tilde {x},\tilde {y},\tilde {x})\in \boldsymbol{Q}_{T_i,T_i}(X)$ , and since $\tilde {x}\in \Omega $ , we obtain $(\tilde {x},\tilde {y},\tilde {x})\in \overline {\mathcal {F}_{T_{i},T_i}}(\tilde {x})$ . By Lemma 3.2, the set $\{ n\in \mathbb {Z}: T_i^n \tilde {x} \in U_{x_i'}\}$ contains a set of the form $\{a_r-a_{r'}:\;r>r'\}$ for some $\mathbb {Z}$ -valued sequence $(a_i)_{i\in \mathbb {N}}$ taking infinitely many values. In particular, the same is true for the set $\{n\in \mathbb {Z}: T_i^n U_{x_i}\cap U_{x_i'}\neq \emptyset \}$ . Let $\mu $ be a $\mathbb {Z}^k$ -invariant measure on X. By the minimality of $\langle S_1, \ldots , S_k\rangle $ , $\mu $ has full support. Consider the product system $(X_1\times \cdots \times X_d,\mathcal {B}(X)^{\otimes d},\mu ^{\otimes d},T_1\times \cdots \times T_d)$ and $U=U_{x_1}\times \cdots \times U_{x_d}$ . Then $\mu ^{\otimes d}(U)>0,$ and so by the proof of the Poincaré recurrence theorem, the set $\{n\in \mathbb {Z} : \mu ^{\otimes d}(U\cap (T_1\times \cdots \times T_d)^{-n}U)>0\}$ must intersect nontrivially every infinite set of the form $\{a_r-a_{r'}:\;r>r'\}$ . This implies that it has nonempty intersection with $\{n\in \mathbb {Z}: T_i^n U_{x_i}\cap U_{x_i'}\neq \emptyset \}.$ Picking now an $n\in \mathbb {Z}$ in the intersection, we get that $T_{i}^{n}U_{x_{i}}\cap U_{x^{\prime }_{i}}\neq \emptyset $ and $T_{j}^{n}U_{x_{j}}\cap U_{x_{j}}\neq \emptyset $ for all $1\leq j\leq d,$ as desired.

Proof of Theorem 3.1.

Our goal here is to find, for every $\epsilon> 0,$ a point $(z_1, \ldots , z_d)$ and an integer n so that $(x_1, \ldots , x_d)$ is close to $(z_1, \ldots , z_d)$ and $(y_1, \ldots , y_d)$ is close to $(T^n z_1, \ldots , T^n z_d).$ We do so by induction on the coordinates. To this end, fix $\epsilon>0$ and set . Suppose that we have constructed $\epsilon _{r+1},\dots ,\epsilon _{d}>0$ for some $1\leq r\leq d-1$ . We let $0<\epsilon _{r}<\epsilon _{r+1}/2$ to be a number such that for any $z_{r+1}\in X$ with $\rho (y_{r+1},z_{r+1})<\epsilon _{r}$ , there exists $x^{\prime }_{r+1}\in X$ with $\rho (x^{\prime }_{r+1},x_{r+1})<\epsilon _{r+1}/2$ such that $(x^{\prime }_{r+1},z_{r+1})\in R_{\pi _{r+1}}$ . The existence of such $\epsilon _{r}$ follows from the assumptions that $(x_{r+1},y_{r+1})\in R_{\pi _{r+1}}$ , and that the map $X\mapsto Y_{{r+1}}=X/R_{\pi _{r+1}}$ is open.

For $1\leq r\leq d$ , we say that Property r holds if there exist $z_{1},\dots ,z_{d}\in X$ and $n\in \mathbb {Z}$ such that

• • $\rho (x_{i},z_{i})<\epsilon _{r}$ for all $1\leq i\leq r$ ;

• • $\rho (y_{i},z_{i})<\epsilon _{r}$ for all $r+1\leq i\leq d$ ;

• • $\rho (y_{i},T_{i}^{n}z_{i})<\epsilon _{r}$ for all $1\leq i\leq d$ .

By Lemma 3.3, setting $x_j=y_j, 1\leq j\leq d, x_1'=x_1,$ and $U_z=B(z,\epsilon _1)$ for $z=y_1, \ldots , y_d, x_1,$ for $-n$ , we have that Property 1 holds. Now suppose that Property r holds for some $1\leq r\leq d-1$ . Since $(x_{r+1},y_{r+1})\in R_{\pi _{r+1}}$ and $\rho (y_{r+1},z_{r+1})<\epsilon _{r}$ , by the construction of $\epsilon _{r}$ , there exists $x^{\prime }_{r+1}\in X$ with $\rho (x^{\prime }_{r+1},x_{r+1})<\epsilon _{r+1}/2$ such that $(x^{\prime }_{r+1},z_{r+1})\in R_{\pi _{r+1}}$ . Let . Take $0<\delta <\delta '$ such that for all $x,y\in X$ , if $\rho (x,y)<\delta $ , then $\rho (T^{n}x,T^{n}y)<\delta '$ (n is the one from Property r above). By Lemma 3.3, there exist $z^{\prime }_{1},\dots ,z^{\prime }_{d}\in X$ and $n'\in \mathbb {Z}$ such that

• • $\rho (z_{i},z^{\prime }_{i})<\delta $ for all $1\leq i\leq d, i\neq r+1$ ;

• • $\rho (z_{i},T_{i}^{n'}z^{\prime }_{i})<\delta $ for all $1\leq i\leq d, i\neq r+1$ ;

• • $\rho (x^{\prime }_{r+1},z^{\prime }_{r+1})<\delta $ ;

• • $\rho (z_{r+1},T_{r+1}^{n'}z^{\prime }_{r+1})<\delta $ .

Then for all $1\leq i\leq r$ ,

$$ \begin{align*}\rho(x_{i},z^{\prime}_{i})\leq \rho(x_{i},z_{i})+\rho(z_{i},z^{\prime}_{i})<\epsilon_{r}+\delta\leq\epsilon_{r+1}.\end{align*} $$

For all $r+2\leq i\leq d$ ,

$$ \begin{align*}\rho(y_{i},z^{\prime}_{i})\leq \rho(y_{i},z_{i})+\rho(z_{i},z^{\prime}_{i})<\epsilon_{r}+\delta\leq\epsilon_{r+1}.\end{align*} $$

Moreover,

$$ \begin{align*}\rho(x_{r+1},z^{\prime}_{r+1})\leq \rho(x_{r+1},x^{\prime}_{r+1})+\rho(x^{\prime}_{r+1},z^{\prime}_{r+1})<\epsilon_{r+1}/2+\delta\leq\epsilon_{r+1}.\end{align*} $$

However, for all $1\leq i\leq d, i\neq r+1$ , since $\rho (z_{i},T_{i}^{n'}z_{i})<\delta $ , we have $\rho (T_{i}^{n}z_{i},T_{i}^{n+n'}z_{i})<\delta '$ and so

$$ \begin{align*}\rho(y_{i},T_{i}^{n+n'}z_{i})\leq \rho(y_{i},T_{i}^{n}z_{i})+\rho(T_{i}^{n}z_{i},T_{i}^{n+n'}z_{i})<\epsilon_{r}+\delta'\leq\epsilon_{r+1}.\end{align*} $$

Finally, since $\rho (z_{r+1},T_{r+1}^{n'}z_{r+1})<\delta $ , we have that $\rho (T_{r+1}^{n}z_{r+1},T_{r+1}^{n+n'}z_{r+1})<\delta '$ and so

$$ \begin{align*}\rho(y_{r+1},T_{r+1}^{n+n'}z_{r+1})\leq \rho(y_{r+1},T_{r+1}^{n}z_{r+1})+\rho(T_{r+1}^{n}z_{r+1},T_{r+1}^{n+n'}z_{r+1})<\epsilon_{r}+\delta'\leq\epsilon_{r+1}.\end{align*} $$

In conclusion, we have that that Property $r+1$ holds.

So it follows from induction that Property d holds, which means that there exist $(z_{1},\dots ,z_{d})\in X^{d}$ and $n\in \mathbb {Z}$ such that

$$ \begin{align*}\rho((x_{1},\dots,x_{d}),(z_{1},\dots,z_{d}))< \epsilon \text{ and } \rho((y_{1},\dots,y_{d}),(T_{1}^{n}z_{1},\dots,T_{d}^{n}z_{d}))<\epsilon.\end{align*} $$

Since $\epsilon $ is arbitrary, we have that $((x_{1},\dots ,x_{d}),(y_{1},\dots ,y_{d}))\in \mathbf {RP}_{T_{1}\times \dots \times T_{d}}(X^{d})$ .

Proof. The ‘only if’ part is straightforward. Now assume that $(Y^d,T_1\times \dots \times T_d)$ is transitive. By the O-diagram (Theorem 2.5), we may consider almost one-to-one extensions $\tilde {X}$ , $\tilde {Y}$ of X and Y, respectively, such that the projection $\tilde {\pi }\colon \tilde {X}\to \tilde {Y}$ is open. Note that $(\tilde {X},\tilde {T}_1),\dots ,(\tilde {X},\tilde {T}_d)$ and $(\tilde {Y}^d,\tilde {T}_1\times \dots \times \tilde {T}_d)$ are also transitive because this property is preserved under almost one-to-one extensions (see [Reference Akin and Glasner1]). We now show that $(\tilde {X}^d,\tilde {T}_1\times \dots \times \tilde {T}_d)$ is transitive, which implies that $(X^d,T_1\times \dots \times T_d)$ is transitive.

Note that since $\tilde {X}$ is an almost one-to-one extension of X, we have that $\tilde {X}/\mathbf {RP}_{\mathbb {Z}^k,\mathbb {Z}^k}(\tilde {X})$ and $X/\mathbf {RP}_{\mathbb {Z}^k,\mathbb {Z}^k}(X)$ are conjugate, so we have that $R_{\tilde {\pi }}$ is a subset of $\mathbf {RP}_{\mathbb {Z}^k,\mathbb {Z}^k}(\tilde {X})$ . To see this, by only assuming that $\tilde {\sigma }$ is proximal (which covers the almost one-to-one case), let q be the projection from $\tilde {X}$ to $X/\mathbf {RP}_{\mathbb {Z}^k,\mathbb {Z}^k}(X)$ . It suffices to show that $R_{q}\subseteq \mathbf {RP}_{\mathbb {Z}^k,\mathbb {Z}^k}(\tilde {X})$ . Let $\tilde {x},\tilde {x}'\in \tilde {X}$ with $q(\tilde {x})=q(\tilde {x}')$ . Then $(\tilde {\sigma }(\tilde {x}),\tilde {\sigma }(\tilde {x}'))\in \mathbf {RP}_{\mathbb {Z}^k,\mathbb {Z}^k}(X)$ . By the second part of Theorem 2.4, we can find $(\tilde {y}, \tilde {y}')\in \mathbf {RP}_{\mathbb {Z}^k,\mathbb {Z}^k}(\tilde {X})$ such that $ (\tilde {\sigma }(\tilde {y}),\tilde {\sigma }(\tilde {y}'))=(\tilde {\sigma }(\tilde {x}),\tilde {\sigma }(\tilde {x}'))$ . It follows that $(\tilde {x},\tilde {y}), (\tilde {x}',\tilde {y}') \in P(\tilde {X})$ (the proximal relation on $\tilde {X}$ ). Since $P(\tilde {X})\subseteq \mathbf {RP}_{\mathbb {Z}^k,\mathbb {Z}^k}(\tilde {X})$ , and this is an equivalence relation, we conclude $(\tilde {x},\tilde {x}')\in \mathbf {RP}_{\mathbb {Z}^k,\mathbb {Z}^k}(\tilde {X})$ .Footnote ⁵

Let $U,V$ be nonempty open subsets of $\tilde {X}^{d}$ . Our goal is to find $m\in \mathbb {N}$ such that $U\cap (\tilde {T}_{1}\times \dots \times \tilde {T}_{d})^{-m} V\neq \emptyset $ . Then $\tilde {\pi }^{\times d}(U)$ and $\tilde {\pi }^{\times d}(V)$ are nonempty open sets, where (d-times). Since $(\tilde {Y}^d,\tilde {T}_1\times \dots \times \tilde {T}_d)$ is transitive, there exist $(x_{1},\dots ,x_{d})\in U$ and $n\in \mathbb {Z}$ such that $\tilde {\pi }^{\times d}(\tilde {T}_1^nx_1,\ldots ,\tilde {T}_d^nx_{d})\in \tilde {\pi }^{\times d}(V)$ . That is, there exists $(x^{\prime }_{1},\dots ,x^{\prime }_{d})\in V$ such that $(\tilde {T}_i^nx_{i},x^{\prime }_{i})\in R_{\tilde {\pi }}$ for all $1\leq i\leq d$ . Let $\epsilon>0$ be such that $B((x_{1},\dots ,x_{d}),\epsilon )\subseteq U$ and $B((x^{\prime }_{1},\dots ,x^{\prime }_{d}),\epsilon )\subseteq V$ . Take $0<\delta <\epsilon $ so that $\rho (a,b)<\delta $ implies $\rho (\tilde {T}_i^{-n}a,\tilde {T}_i^{-n} b)<\epsilon $ for $1\leq i\leq d$ . Thanks to the transitivity of $\tilde {T}_i$ , using Corollary 2.3, we get that $\mathbf {RP}_{\mathbb {Z}^k,\mathbb {Z}^k}(\tilde {X})= \mathbf {RP}_{\tilde {T}_i,\tilde {T}_i}(\tilde {X})$ and thus $R_{\tilde {\pi }}\subseteq \mathbf {RP}_{\tilde {T}_i,\tilde {T}_i}(\tilde {X})$ for all $1\leq i\leq d$ . By Theorem 3.1, we obtain $((\tilde {T}_1^nx_{1},\dots ,\tilde {T}_d^nx_{d}),(x^{\prime }_{1},\dots ,x^{\prime }_{d}))\in \mathbf {RP}_{\tilde {T}_1\times \dots \times \tilde {T}_d}(\tilde {X}^d)$ . Therefore, there exist $(y_{1},\dots ,y_{d})\in \tilde {X}^d$ and $m\in \mathbb {Z}$ such that $\rho ((y_1,\ldots ,y_d), (\tilde {T}_1^nx_{1},\dots ,\tilde {T}_d^nx_{d}))<\delta $ and $\rho ((\tilde {T}_1^my_{1},\dots ,\tilde {T}_d^my_{d}),(x_1',\ldots ,x_d'))<\delta $ . It follows that $(\tilde {T}_1^{-n}y_{1},\dots , \tilde {T}_d^{-n}y_{d})\in U$ and $(\tilde {T}_1^{m+n}\tilde {T}_1^{-n}y_{1},\dots ,\tilde {T}_d^{m+n}\tilde {T}_d^{-n}y_{d})\in V$ . Therefore, $U\cap (\tilde {T}_{1}\times \dots \times \tilde {T}_{d})^{-(m+n)}V\neq \emptyset $ . We conclude that $(\tilde {X}^{d},\tilde {T}_{1}\times \dots \times \tilde {T}_{d})$ is transitive.

Proof of the forward direction of Theorem 1.6.

We use Lemma 2.1 implicitly throughout the proof. Assume that $(T_1^n)_n,\ldots ,(T_d^n)_n$ are jointly transitive. Equivalently, for all $V_{0},\dots ,V_{d}$ nonempty and open subsets of $X,$ there exists $n\in \mathbb {Z}$ such that

(3.1) $$ \begin{align} V_{0}\cap T^{-n}_{1}V_{1}\cap\dots\cap T^{-n}_{d}V_{d}\neq \emptyset. \end{align} $$

To show $(i)$ , pick any $i\neq j,$ and let $U_0, U_1$ be nonempty opens sets. Setting $V_i=U_0, V_j=U_1$ and $V_k=X$ for all $k\in \{0,\ldots ,d\}\setminus \{i,j\},$ it follows from (3.1) that $T_i^{-n}V_i\cap T_j^{-n}V_j\neq \emptyset $ , or $U_0\cap (T_i^{-1}T_j)^{-n} U_1\neq \emptyset $ . To show $(ii)$ , pick any point x for which $\{(T_1^n x, \ldots , T_d^n x):\;n\in \mathbb {Z}\}$ is dense in $X.$ Then the point $(x,\ldots ,x)$ is a transitive point for $T_1\times \dots \times T_d$ .

Proof. Since $(X,R_{2}),\ldots , (X,R_{d})$ are transitive, by Corollary 2.3, we have $\mathbf {RP}_{R_{2},R_{2}}(X)=\ldots =\mathbf {RP}_{R_{d},R_{d}}(X)=\mathbf {RP}_{\mathbb {Z}^k,\mathbb {Z}^k}(X)$ , which is an equivalence relation since $(X,S_{1},\ldots ,S_{k})$ is minimal. By Proposition 3.4, it suffices to show that $(Y^{d-1},R_{2}\times \dots \times R_{d})$ is transitive, where $Y=X/\mathbf {RP}_{\mathbb {Z}^{k},\mathbb {Z}^{k}}(X)$ . By Theorem 2.4, we have that $(Y,S_1,\ldots ,S_k)$ is a rotation on a compact abelian group, and so we may write $T_i(y)=y+\alpha _i$ for $\alpha _i\in Y$ for $1\leq i \leq d$ . We can choose a metric $\rho $ on Y that is compatible with its topology, such that $S_1,\ldots ,S_k$ act as isometries on Y. Since $(X^{d},T_{1}\times \dots \times T_{d})$ is transitive, we get that $(Y^d,T_1\times \dots \times T_d)$ is transitive, and hence minimal. (This holds because rotations are distal, and in this class transitivity and minimality are equivalent conditions – for example, see [Reference Auslander2, Chapters 2 and 5].)

Take $y\in Y$ and $(y_2,\ldots ,y_d)\in Y^{d-1}$ . Since $(Y^d,T_1\times \cdots \times T_d)$ is minimal, given $\epsilon>0$ , there exists n such that $\rho (y+n\alpha _1,y)<\epsilon $ , and $\rho (y+n\alpha _i, y_i)<\epsilon $ , for all $2\leq i \leq d$ . It follows that

$$ \begin{align*}\rho(y+n(\alpha_i-\alpha_1) , y_i)\leq \rho(y+n(\alpha_i-\alpha_1) , y+n\alpha_i)+\rho(y+n\alpha_i, y_i)=\rho(y, y+n\alpha_1)+\rho(y+n\alpha_i, y_i)<2\epsilon\end{align*} $$

for all $2\leq i \leq d$ . As $\epsilon>0$ is arbitrary, we get that $(y_2,\ldots ,y_d)$ belongs to the orbit closure of $(y,\ldots ,y)\in X^{d-1}$ under $R_2\times \cdots \times R_d$ . Since $y_2,\ldots ,y_d$ are arbitrary, this orbit closure is all of $Y^{d-1}$ . We get that $(Y^{d-1},R_2\times \cdots \times R_d)$ is minimal, as it is the orbit closure of a point in an equicontinuous system. Proposition 3.4 allows us to conclude.

Proof. We use induction on N. Since $(X^{d},T_{1}\times \dots \times T_{d})$ is transitive, there exists $n_{1}\in \mathbb {Z}$ such that $T_{i}^{-n_{1}}R^{-1}_{1}V_{i}\cap V_{i}\neq \emptyset $ for all $1\leq i\leq d$ . Set . This completes the proof for the case $N=1$ .

Now assume that for some $N\geq 2$ , we have constructed $n_{1},\dots ,n_{N-1}\in \mathbb {N}$ with $n_{1}<\ldots <n_{N-1}$ , and for each $1\leq i\leq d$ a sequence of nonempty open sets $V_{i}\supseteq V^{(1)}_{i}\supseteq \ldots \supseteq V^{(N-1)}_{i}$ such that

$$ \begin{align*}T_{i}^{-n_{j}}R^{-1}_{j}V^{(m)}_{i}\subseteq V_{i} \text{ for all } 1\leq j\leq m, 1\leq m\leq N-1, 1\leq i\leq d.\end{align*} $$

Let $U_{i}:=R^{-1}_{N}V_{i}^{(N-1)}$ . Since $(X^{d},T_{1}\times \dots \times T_{d})$ is transitive, there exists $n_{N}\in \mathbb {N}$ with $n_{N}>n_{N-1}$ such that $T_{i}^{-n_{N}}U_{i}\cap V_{i}\neq \emptyset $ for all $1\leq i\leq d$ . This implies that

$$ \begin{align*}V_i\cap T_{i}^{-n_{N}}R^{-1}_{N}V_{i}^{(N-1)}=V_i\cap T_{i}^{-n_{N-1}}U_{i}\neq \emptyset.\end{align*} $$

Let

$$ \begin{align*}V_{i}^{(N)}:=V_{i}^{(N-1)}\cap (T_{i}^{-n_{N}}R^{-1}_{N})^{-1}V_{i}.\end{align*} $$

Then $V_{i}^{(N)}\subseteq V_{i}^{(N-1)}$ is a nonempty open set and $T_{i}^{-n_{N}}R^{-1}_{N}V^{(N)}_{i}\subseteq V_{i}$ . Since $V_{i}^{(N)}\subseteq V_{i}^{(N-1)}$ , we also have that

$$ \begin{align*}T_{i}^{-n_{j}}R^{-1}_{j}V^{(N)}_{i}\subseteq V_{i} \text{ for all } 1\leq j\leq N-1, 1\leq i\leq d.\end{align*} $$

This completes the induction step, and we are done by setting $\tilde {V}_{i}:=V_{i}^{(N)}$ .

Proof of the inverse direction of Theorem 1.6.

There is nothing to prove when $d=1$ . Now we assume that Theorem 1.6 holds for $d-1$ for some $d\geq 2$ , and we prove it for d. By Proposition 3.5, conditions (i) and (ii) imply that $(X^{d-1},T_2T_1^{-1}\times \dots \times T_{d}T_{1}^{-1})$ is transitive. However, we have that $(T_{i}T_{1}^{-1})^{-1}(T_{j}T_{1}^{-1})=T_{i}^{-1}T_{j}$ is transitive for all $1\leq i,j\leq d, i\neq j$ . So, by induction hypothesis, we have that $((T_{2}T_{1}^{-1})^{n})_n,\ldots ,((T_{d}T_{1}^{-1})^{n})_n$ are jointly transitive.

For $m=(m_1,\dots ,m_k)\in \mathbb {Z}^k$ , recall that $S_{m}=S_1^{m_1}\cdot \ldots \cdot S_k^{m_k}$ . Let $U,V_{1},\dots ,V_{d}$ be open and nonempty. We wish to show that there exists $n\in \mathbb {Z}$ such that

$$ \begin{align*}U\cap T_{1}^{-n}V_{1}\cap\dots\cap T^{-n}_{d}V_{d}\neq \emptyset.\end{align*} $$

Since $(X,S_{1},\dots ,S_{k})$ is minimal, there exists a finite set $F\subseteq \mathbb {Z}^k$ such that $X=\bigcup _{r\in F} S_{r}U$ . By assumption (ii) and Lemma 3.6, there exist nonempty open sets $\tilde {V}_1,\dots ,\tilde {V}_d$ and for all $r\in F$ , some $n_r\in \mathbb {Z}$ , such that

$$\begin{align*}(T_{1}\times\dots \times T_{d})^{n_{r}} (S_{r}\times\dots\times S_{r} (\tilde{V}_1\times\dots\times \tilde{V}_d))\subseteq V_1 \times\dots\times V_d\end{align*}$$

for all $r\in F$ . Since $(T_{2}T_{1}^{-1})^{n},\dots ,(T_{d}T_{1}^{-1})^{n}$ are jointly transitive, we can find $m=m(F)\in \mathbb {Z}$ such that

$$\begin{align*}\tilde{V}_1 \cap (T_{2}T_1^{-1})^{-m}\tilde{V}_2\cap\dots\cap (T_{d}T_1^{-1})^{-m}\tilde{V}_d \neq \emptyset. \end{align*}$$

Take $x\in \tilde {V}_1$ such that $T_i^mT_1^{-m}x\in \tilde {V}_i$ for all $2\leq i\leq d$ , and write $y=T_1^{-m}x$ . Let $r\in F$ be such that $z:=S_{r}y\in U$ . Then $T_{i}^{m+n_r}z=T_i^{m+n_r}S_{r}y=T_i^{n_r}S_{r}(T_{i}T_{1}^{-1})^{m}x\in T_i^{n_r}S_{r}(\tilde {V}_{i})\subseteq V_{i}$ for all $1\leq i\leq d$ . It follows that $z\in U\cap T_1^{-(m+n_r)}V_1\cap \dots \cap T_d^{-(m+n_r)}V_d$ .