Proof. By Proposition 2.2, for each $\psi $ -invariant Radon probability measure $\mu $ , we have that

(24) $$ \begin{align} h_{\mu}(\psi) & = \mu(Y_1)h_{\mu_{Y_1}}(\psi|_{Y_1}) + \cdots + \mu(Y_j)h_{\mu_{Y_j}}(\psi|_{Y_j}) \nonumber \\ & \leq \mu(Y_1)h(\psi|_{Y_1}) + \cdots + \mu(Y_j)h(\psi|_{Y_j}) \nonumber \\ & \leq \max_{i = 1,\ldots,j} h(\psi|_{Y_i}), \end{align} $$

where we used Proposition 2.4 in the first inequality. Hence,

(25) $$ \begin{align} h(\psi) & = \sup_{\mu} h_{\mu}(\psi) \nonumber \\ & \leq \max_{i = 1,\ldots,j} h(\psi|_{Y_i}) \nonumber \\ & \leq h(\psi). \end{align} $$

Proof. To prove that

(28) $$ \begin{align} \sup_{\mu} h_{\mu}(\psi) \leq \lim_{l \to \infty} h(\psi|_{C_l}), \end{align} $$

it is sufficient to show that, given a $\psi $ -invariant Radon probability measure $\mu $ , there exists l such that

(29) $$ \begin{align} h_{\mu}(\psi) \leq h(\psi|_{C_l}) \end{align} $$

since

(30) $$ \begin{align} h(\psi|_{C_l}) \leq \lim_{l \to \infty} h(\psi|_{C_l}). \end{align} $$

In fact, it is enough to show that there exists l such that

(31) $$ \begin{align} h_{\mu}(\psi^n) \leq h(\psi|_{C_l}^n) + 2 + \log(2) \end{align} $$

for each natural number n, since

(32) $$ \begin{align} h_{\mu}(\psi) & = \frac{1}{n} h_{\mu}(\psi^n) \nonumber \\ & \leq \frac{1}{n} h(\psi|_{C_l}^n) + \frac{2 + \log(2)}{n} \nonumber \\ & \leq h(\psi|_{C_l}) + \frac{2 + \log(2)}{n}, \end{align} $$

where we used Proposition 2.2 in the first equality and Proposition 2.3 in the second inequality. Hence, inequality (29) follows by taking the limit as n goes to the infinity. To show inequality (31), take a finite measurable partition $\mathcal {P}$ such that

(33) $$ \begin{align} h_{\mu}(\psi^n) \leq h_{\mu}(\psi^n, \mathcal{P}) + 1. \end{align} $$

For each $P \in \mathcal {P}$ , chose $C_P \subset P$ compact such that

(34) $$ \begin{align} \mu(P \backslash C_P) \leq \frac{1}{2N(\mathcal{P}) \log N(\mathcal{P})}, \end{align} $$

where $N(\mathcal {P})$ is the cardinality of $\mathcal {P}$ . Since $X = \bigcup _{l = 0}^{\infty } C_l$ , $\mu (X) = 1$ , and $C_l \subset C_{l+1}$ for each l, it follows that

(35) $$ \begin{align} \lim_{l \to \infty} \mu(C_l) = 1. \end{align} $$

Thus, we can choose l such that

(36) $$ \begin{align} \mu(X \backslash C_l) \leq \frac{1}{2N(\mathcal{P}) \log N(\mathcal{P})} \end{align} $$

and define

(37) $$ \begin{align} C_P^l = C_P \cap C_l. \end{align} $$

It follows that

(38) $$ \begin{align} \mu(P \backslash C_P^l ) & = \mu(P \cap (C_P^l)^c ) \nonumber \\ & = \mu(P \cap (C_P \cap C_l)^c ) \nonumber \\ & = \mu(P \cap ((C_P)^c \cup (C_l)^c) ) \nonumber \\ & = \mu( (P \cap (C_P)^c) \cup (P \cap (C_l)^c) ) \nonumber \\ & \leq \mu(P \cap (C_P)^c) + \mu(P \cap (C_l)^c) \nonumber \\ & \leq \mu(P \backslash C_P ) + \mu(X \backslash C_l ) \nonumber \\ & \leq \frac{1}{N(\mathcal{P}) \log N(\mathcal{P})}. \end{align} $$

Defining

(39) $$ \begin{align} P^l = \bigcup_{P \in \mathcal{P}} P \backslash C_P^l, \end{align} $$

it follows that

(40) $$ \begin{align} \mu(P^l ) \leq \frac{1}{\log N(\mathcal{P})}. \end{align} $$

Define the following measurable partition:

(41) $$ \begin{align} \mathcal{P}_l = \{ C_P^l : P \in \mathcal{P} \} \cup \{P^l\} \end{align} $$

and the strongly admissible cover

(42) $$ \begin{align} \mathcal{A} = \{ C_P^l \cup P^l : P \in \mathcal{P} \}. \end{align} $$

We claim that

(43) $$ \begin{align} H_{\mu}(\mathcal{P}|\mathcal{P}_l) \leq 1. \end{align} $$

In fact, first note that $\mu (P | C_P^l ) = 1$ for every $P \in \mathcal {P}$ . Thus,

(44) $$ \begin{align} H_{\mu(.|C_P^l)}(\mathcal{P}) = 0 \end{align} $$

and therefore, by the definition of conditional entropy and by Proposition 2.1, it follows that

(45) $$ \begin{align} H_{\mu}(\mathcal{P}|\mathcal{P}_l) & = \mu(P^l)H_{\mu(.|P^l)}(\mathcal{P}) \nonumber \\ & \leq \mu(P^l)\log N(\mathcal{P}) \nonumber \\ & \leq 1. \end{align} $$

We claim that

(46) $$ \begin{align} N(\mathcal{P}_l^j) \leq 2^jN(\mathcal{A}^j), \end{align} $$

where $\mathcal {A}^j$ is the strongly admissible cover given by the following subsets:

(47) $$ \begin{align} (C_{P_0}^l \cup P^l) \cap \psi^{-n}(C_{P_1}^l \cup P^l) \cap \cdots \cap \psi^{-n(j-1)}(C_{P_{j-1}}^l \cup P^l), \end{align} $$

with $P_i \in \mathcal {P}$ for each i, and $\mathcal {P}_l^j$ is the measurable partition given by the following subsets:

(48) $$ \begin{align} Y_0 \cap \psi^{-n}(Y_1) \cap \cdots \cap \psi^{-n(j-1)}(Y_{j-1}), \end{align} $$

where $Y_i = C_{P_i}^l$ or $Y_i = P^l$ for each i. Let m be the cardinality of $\mathcal {P}$ and $\Lambda \subset \{1, \ldots , m\}^j$ such that its cardinality is $N(\mathcal {A}^j)$ and that

(49) $$ \begin{align} X = \bigcup_{\unicode{x3bb} \in \Lambda} (C_{P_{\unicode{x3bb}_0}}^l \cup P^l) \cap \cdots \cap \psi^{-n(j-1)}(C_{P_{\unicode{x3bb}_{j-1}}}^l \cup P^l), \end{align} $$

where $\unicode{x3bb} = (\unicode{x3bb} _0, \ldots , \unicode{x3bb} _{j-1})$ . Consider the map $f: \Lambda \times \{0,1\}^j \to \mathcal {P}_l^j$ given by

(50) $$ \begin{align} f(\unicode{x3bb},x) = Y_0 \cap \psi^{-n}(Y_1) \cap \cdots \cap \psi^{-n(j-1)}(Y_{j-1}) \end{align} $$

with

(51) $$ \begin{align} Y_i = \begin{cases} C_{P_{\unicode{x3bb}_i}}^l, & x_i = 1, \\ P^l, & x_i = 0, \end{cases} \end{align} $$

where $x = (x_0, \ldots , x_{j-1})$ . Since

(52) $$ \begin{align} X = \bigcup_{\unicode{x3bb} \in \Lambda, \, x \in \{0,1\}^j }f(\unicode{x3bb},x) \end{align} $$

and since $\mathcal {P}_l^j$ is a partition, it follows that the image of f contains every non-empty element of $\mathcal {P}_l^j$ , which implies the inequality (46). Now consider the strongly admissible cover of $C_l$ given by

(53) $$ \begin{align} \mathcal{A}_l = \{ (C_P^l \cup P_l) \cap C_l : P \in \mathcal{P} \}. \end{align} $$

We claim that

(54) $$ \begin{align} N(\mathcal{A}^j) \leq N(\mathcal{A}_l^j), \end{align} $$

where $\mathcal {A}_l^j$ is the strongly admissible cover given by the following subsets:

(55) $$ \begin{align} ((C_{P_0}^l \cup P^l) \cap C_l ) \cap \cdots \cap \psi^{-n(j-1)}((C_{P_{j-1}}^l \cup P^l) \cap C_l), \end{align} $$

with $P_i \in \mathcal {P}$ for each i. Let $\Delta \subset \{1, \ldots , m\}^j$ such that its cardinality is $N(\mathcal {A}_l^j)$ and that

(56) $$ \begin{align} C_l = \bigcup_{\delta \in \Delta} ((C_{P_{\delta_0}}^l \cup P^l) \cap C_l ) \cap \cdots \cap \psi^{-n(j-1)}((C_{P_{\delta_{j-1}}}^l \cup P^l) \cap C_l), \end{align} $$

where $\delta = (\delta _0, \ldots , \delta _{j-1})$ . Consider the map $g: \Delta \to \mathcal {A}^j$ given by

(57) $$ \begin{align} g(\delta) = (C_{P_{\delta_0}}^l \cup P^l) \cap \cdots \cap \psi^{-n(j-1)}(C_{P_{\delta_{j-1}}}^l \kern-0.5pt{\cup}\, P^l). \end{align} $$

Since $C_l^c \subset P^l$ and since $C_l$ is $\psi ^n$ -invariant, it follows that $C_l^c \subset g(\delta )$ for each $\delta $ and that

(58) $$ \begin{align} C_l = \bigg(\bigcup_{\delta \in \Delta} g(\delta) \bigg) \cap C_l. \end{align} $$

Hence,

(59) $$ \begin{align} X = C_l \cup C_l^c \subset \bigcup_{\delta \in \Delta} g(\delta) \end{align} $$

showing inequality (54). Taking the logarithm of inequalities (46) and (54), dividing by l, and taking the limit as l tends to infinity, it follows that

(60) $$ \begin{align} h_{\mu}(\psi^n,\mathcal{P}_l) & \leq h(\psi^n,\mathcal{A}) + \log(2) \nonumber \\ & \leq h(\psi|_{C_l}^n,\mathcal{A}_l) + \log(2) \nonumber \\ & \leq h(\psi|_{C_l}^n) + \log(2). \end{align} $$

From inequalities (33), (43), (62), and Proposition 2.1, it follows that

(61) $$ \begin{align} h_{\mu}(\psi^n) & \leq h_{\mu}(\psi^n,\mathcal{P}) + 1 \nonumber \\ & \leq h_{\mu}(\psi^n,\mathcal{P}_l) + H_{\mu}(\mathcal{P}|\mathcal{P}_l) + 1 \nonumber \\ & \leq h_{\mu}(\psi^n,\mathcal{P}_l) + 2 \nonumber \\ & \leq h(\psi|_{C_l}^n) + \log(2) + 2. \end{align} $$

To prove that

(62) $$ \begin{align} \lim_{l \to \infty} h(\psi|_{C_l}) \leq \sup_{\mu} h_{\mu}(\psi) \end{align} $$

for each $\varepsilon> 0$ , there exists l such that

(63) $$ \begin{align} \lim_{l \to \infty} h(\psi|_{C_l}) \leq h(\psi|_{C_l}) + \frac{\varepsilon}{2} \end{align} $$

and, by the variational principle of entropy for compact spaces, there exists a $\psi |_{C_l}$ -invariant Radon probability measure $\mu _l$ such that

(64) $$ \begin{align} h(\psi|_{C_l}) < h_{\mu_l}(\psi|_{C_l}) + \frac{\varepsilon}{2}. \end{align} $$

Considering the following $\psi $ -invariant Radon probability measure $\mu $ given by

(65) $$ \begin{align} \mu(A) = \mu_l(A \cap C_l), \end{align} $$

it follows that

(66) $$ \begin{align} h_{\mu}(\psi) = h_{\mu_l}(\psi|_{C_l}). \end{align} $$

By the previous inequalities, it follows that

(67) $$ \begin{align} \lim_{l \to \infty} h(\psi|_{C_l}) & < h_{\mu}(\psi) + \varepsilon \nonumber \\ & \leq \sup_{\mu} h_{\mu}(\psi) + \varepsilon. \end{align} $$

Since $\varepsilon $ is arbitrary, we obtain inequality (62).

Proof. For each $\psi $ -invariant Radon probability measure $\mu $ , we have that

(71) $$ \begin{align} h_{\mu}(\psi) = \mu(X)h_{\mu_X}(\psi|_{X}) + \mu(Y \backslash X )h_{\mu_{Y \backslash X}}(\psi|_{Y \backslash X}). \end{align} $$

Since $\mathcal {R}_{\psi |_{Y \backslash X}} = \emptyset $ , by the Poincaré recurrence theorem, it follows that $\mu _{Y \backslash X} = 0$ and thus that $h_{\mu _{Y \backslash X}}(\psi |_{Y \backslash X}) = 0$ . Hence,

(72) $$ \begin{align}h_{\mu}(\psi) \leq h_{\mu_X}(\psi|_{X}) \end{align} $$

and thus it follows that

(73) $$ \begin{align} \sup_{\mu} h_{\mu}(\psi) = \sup_{\mu_X} h_{\mu_X}(\psi|_{X}), \end{align} $$

and the result follows from Theorem 2.7.

Proof. Consider the map $\theta : N(T,K)_0 \to \mbox {Aut}(T)$ , given by $\theta (g) = C_g|_T$ . Since $\theta $ is continuous and $N(T,K)_0$ is connected, it follows that the image $\mbox {Im}(\theta )$ is also connected. Since $\mbox {Aut}(T)$ is discrete and $\mbox {Id}_T = \theta (1) \in \mbox {Im}(\theta )$ , it follows that $\mbox {Im}(\theta ) = \{\mbox {Id}_T\}$ . This implies that $N(T,K)_0 \subset Z(T,K)$ . Since $N(T,K)_0 \subset K_0$ , it follows that

(79) $$ \begin{align} N(T,K)_0 \subset Z(T,K) \cap K_0 = Z(T,K_0) = T, \end{align} $$

where we used Proposition 3.4 in the last equality. However, it is immediate that $T \subset N(T,K)_0$ .

For the second claim, let $g \in K$ and note that, since K is compact, its Lie algebra $\frak {k}$ is reducible. Thus,

(80) $$ \begin{align} \frak{k} = \frak{z}(\frak{k}) \oplus [\frak{k},\frak{k}], \end{align} $$

where $\frak {z}(\frak {k})$ is the center of $\frak {k}$ and $\frak {s} = [\frak {k},\frak {k}]$ is a semi-simple ideal of $\frak {k}$ . Since K is compact, it follows that $\mbox {Ad}(g)$ is a semi-simple automorphism of $\frak {s}$ . By Proposition 3.3, there exists a regular element $X \in \frak {s}$ such that $\mbox {Ad}(g)X = X$ . By Proposition 3.2, the centralizer $\frak {h}$ of X in $\frak {s}$ is a Cartan subalgebra of $\frak {s}$ , such that $\mbox {Ad}(g)\frak {h} = \frak {h}$ . Hence, $\frak {z} = \frak {z}(\frak {k}) \oplus \frak {h}$ is a Cartan subalgebra of $\frak {k}$ such that $\mbox {Ad}(g)\frak {z} = \frak {z}$ . Denoting $Z = \langle \exp (\frak {z}) \rangle $ , it follows that

(81) $$ \begin{align} &\hspace{-32pt} gZg^{-1} = g\langle \exp(\frak{z}) \rangle g^{-1} \end{align} $$

(82) $$ \begin{align} & = \langle \exp(\mbox{Ad}(g)\frak{z}) \rangle \nonumber \\ & = \langle \exp(\frak{z}) \rangle \nonumber \\ & = Z. \end{align} $$

By Propositions 3.2 and 3.4, we have that Z is a maximal torus of $K_0$ and there exists $h \in K_0$ such that $T = hZh^{-1}$ . It follows that

(83) $$ \begin{align} &\hspace{-52pt}h^{-1}Th = Z \end{align} $$

(84) $$ \begin{align} &\qquad = gZg^{-1} \nonumber \\ &\qquad = gh^{-1}Thg^{-1}, \end{align} $$

which implies that

(85) $$ \begin{align}hgh^{-1}T(hgh^{-1})^{-1} = T, \end{align} $$

showing that $hgh^{-1} \in N(T,K)$ .

Proof. By Proposition 3.5, given $U \subset H$ a compact subgroup, there exists $h \in H_0$ such that $hUh^{-1} \subset K$ . Thus, for each $u \in U$ , we have that $huh^{-1} \in K$ . By Theorem 3.6, there exists $k \in K_0$ such that $khuh^{-1}k^{-1} \in N(T,K)$ , which implies that $u \in gN(T,K)g^{-1}$ , where $g = h^{-1}k^{-1} \in H_0$ .

Proof. Consider the map $\Psi : N/T \to N/T$ , given by $\Psi (\pi (g)) = \pi (\psi (g))$ , where $\pi : N \to N/T$ is the canonical projection. Since we have the following sequence:

(88) $$ \begin{align} \cdots \subset \Psi^2(G/T) \subset \Psi(G/T) \subset G/T \end{align} $$

and since $G/T$ is finite, there exists j such that $\Psi (\Gamma ) = \Gamma $ if $\Gamma = \Psi ^j(G/T)$ . Since $\Gamma $ is finite, it follows that $\Psi |_{\Gamma }$ is a bijection of $\Gamma $ and hence there exists a minimal natural number n such that $\Psi ^n|_{\Gamma } = \mathrm {Id}_{\Gamma }$ . Furthermore, we have that $\mathcal {R}_{\Psi } \subset \Gamma $ , which implies that $\mathcal {R}_{\psi } \subset \pi ^{-1}(\Gamma )$ , since $\pi (\mathcal {R}_{\psi }) \subset \mathcal {R}_{\Psi }$ by the definitions and by the continuity of the maps. Since $\pi ^{-1}(\Gamma )$ is closed, it follows that $\overline {\mathcal {R}_{\psi }} \subset \pi ^{-1}(\Gamma )$ . We have that

(89) $$ \begin{align} h(\psi) & = h(\psi|_{\overline{\mathcal{R}_{\psi}}}) \nonumber \\ & = h(\psi|_{\pi^{-1}(\Gamma)}) \nonumber \\ & = \frac{1}{n}h(\psi^n|_{\pi^{-1}(\Gamma)}). \end{align} $$

If $\Delta $ is any subset of N such that $\pi $ is a bijection between $\Delta $ and $\Gamma $ , then

(90) $$ \begin{align} \pi^{-1}(\Gamma) = \bigcup_{g \in \Delta} gT, \end{align} $$

which is a disjoint union. Since $\Psi ^n|_{\Gamma } = \mathrm {Id}_{\Gamma }$ , it follows that $\psi ^n(gT) = gT$ for $g \in \Delta $ , which implies, by Proposition 2.6, that

(91) $$ \begin{align} h(\psi) = \frac{1}{n} \max_{g \in \Delta} h(\psi^n|_{gT}). \end{align} $$

However, we have that

(92) $$ \begin{align} \psi^n(gt) & = (gt)^{k^n} \nonumber \\ & = gtgtgt\cdots gtgtgt \nonumber \\ & = g^{k^n}g^{1-k^n}tg^{k^n-1}g^{2-k^n}tg^{k^n-2}g^{3-k^n}t\cdots g^3g^{-2}tg^2g^{-1}tgt \nonumber \\ & = g^{k^n}\phi^{k^n-1}(t)\phi^{k^n-2}(t)\cdots \phi^2(t)\phi(t)t, \end{align} $$

where $\phi : T \to T$ is the automorphism given by $\phi (t) = g^{-1}tg$ . Since $\psi ^n(gt) \in gT$ , it follows that $g^{k^n} \in gT$ and hence $g^{k^n-1} \in T$ . Thus, it follows that

(93) $$ \begin{align} g^{-1}\psi^n(gt) = g^{k^n-1}\varphi(t), \end{align} $$

where

(94) $$ \begin{align} \varphi(t) = \phi^{k^n-1}(t)\phi^{k^n-2}(t)\cdots \phi^2(t)\phi(t)t \end{align} $$

is an endomorphism of T. In fact, we have that

(95) $$ \begin{align} \varphi(t_1t_2) & = \phi^{k^n-1}(t_1t_2)\cdots \phi^2(t_1t_2)\phi(t_1t_2)t_1t_2 \nonumber \\ & = \phi^{k^n-1}(t_1)\phi^{k^n-1}(t_2)\cdots \phi^2(t_1)\phi^2(t_2)\phi(t_1)\phi(t_2)t_1t_2 \nonumber \\ & = \phi^{k^n-1}(t_1)\cdots \phi^2(t_1)\phi(t_1)t_1\phi^{k^n-1}(t_2)\cdots \phi^2(t_2)\phi(t_2)t_2 \nonumber \\ & = \varphi(t_1)\varphi(t_2), \end{align} $$

where we used that T is abelian. By the conjugation given in equation (93) and by Proposition 2.5, it follows that

(96) $$ \begin{align} h(\psi^n|_{gT}) & = h(L_{g^{k^n-1}} \circ \varphi) \nonumber \\ & = h(\varphi) \nonumber \\ & = \sum_{\unicode{x3bb}} \log|\unicode{x3bb}|, \end{align} $$

where the summation is taken over all eigenvalues $\unicode{x3bb} $ of $d\varphi _1$ satisfying $|\unicode{x3bb} |> 1$ . Since

(97) $$ \begin{align} d\varphi_1 = d\phi^{k^n-1}_1 + \cdots + d\phi^2_1 + d\phi_1 + \mathrm{Id}, \end{align} $$

it follows that

(98) $$ \begin{align} \unicode{x3bb} = \rho^{k^n-1} + \cdots + \rho^2 + \rho + 1, \end{align} $$

where $\rho $ is an eigenvalue of $d\phi _1$ . We claim that $\phi $ has finite order. In fact, consider the homomorphism $\theta : N \to \mathrm {Aut}(T)$ , given by $\theta (g) = C_g|_T$ . Since $\theta $ is continuous, T is connected, $\mathrm {Aut}(T)$ is discrete, and $\theta (1) = \mbox {Id}_T$ , it follows that $T \subset \ker (\theta )$ . Thus, we can consider the induced homomorphism $\Theta : N/T \to \mathrm {Aut}(T)$ , given by $\Theta (\pi (g)) = \theta (g)$ . Since $N/T$ is finite, it follows that $\mathrm {Im}(\Theta )$ is finite, which implies that $\Theta (\pi (g)) = \theta (g) = \phi $ has finite order. It follows that $|\rho | = 1$ and thus

(99) $$ \begin{align} |\unicode{x3bb}| \leq |\rho|^{k^n-1} + \cdots + |\rho|^2 + |\rho| + 1 = k^n. \end{align} $$

By equation (96), it follows that

(100) $$ \begin{align} h(\psi^n|_{gT}) \leq \dim(T)\log(k^n). \end{align} $$

By equation (91) and since $\theta (1) = \mbox {Id}_T$ , it follows that

(101) $$ \begin{align} h(\psi) = \frac{1}{n} \max_{g \in \Delta} h(\psi^n|_{gT}) = \dim(T)\log(k), \end{align} $$

completing the proof.

Proof. If $g \in \mathcal {R}_{\psi }$ , then there exists $n_j \to \infty $ such that $\psi ^{n_j}(g) \to g$ . Defining $m_j = k^{n_j} - 1$ , it follows that

(102) $$ \begin{align} g^{m_j} = g^{k^{n_j} - 1} = \psi^{n_j}(g)g^{-1} \to 1, \end{align} $$

since $\psi ^{n_j}(g) = g^{k^{n_j}}$ . Now let A be the closure of the subgroup generated by g. It follows that A is a closed abelian subgroup of G. Hence, $A_0 = V \times T$ , where V is an euclidean space and T is the maximal torus of A. Since $g^{m_j} \to 1$ , there exists N such that $g^N \in A_0$ . Thus, $g^N = \exp (Y+Z)$ , with $Y \in \frak {v}$ and $Z \in \frak {t}$ , where $\frak {v}$ and $\frak {t}$ are the Lie algebras of respectively V and T. Writing $m_j = Nq_j + r_j$ , where $0 \leq r_j < N$ , it follows that $q_j \to \infty $ . Thus,

(103) $$ \begin{align} g^{m_j} = (g^N)^{q_j}g^{r_j} = \exp(q_jY)\exp(q_jZ)g^{r_j}. \end{align} $$

We have that

(104) $$ \begin{align} \exp(q_jZ)g^{r_j} \in \bigcup_{r = 0}^{N-1} (0 \times T)g^r, \end{align} $$

which is compact. Thus, there exists a subsequence $\exp (q_{j_l}Z)g^{r_{j_l}} \to h$ and hence

(105) $$ \begin{align} \exp(q_{j_l}Y) = g^{m_{j_l}}(\exp(q_{j_l}Z)g^{r_{j_l}})^{-1} \to h^{-1}. \end{align} $$

Since $q_{j_l} \to \infty $ , this implies that $Y = 0$ , which implies that $g^N = \exp (Z) \in 0 \times T$ and that $g^{-N} = \exp (-Z) \in 0 \times T$ . Hence,

(106) $$ \begin{align} A \subset \bigcup_{r = -N+1}^{N-1} (0 \times T)g^r, \end{align} $$

showing that A is compact.

Proof. Since $c : B_l \times N(T,K) \to C_l$ , given by $c(g,t) = gtg^{-1}$ is a continuous and surjective map and since $B_l \times N(T,K)$ is compact, it follows that $C_l$ is compact. We also have that $C_l \subset C_{l+1}$ for each l, since $B_l \subset B_{l+1}$ for each l, and that $C_l$ is $\psi $ -invariant, since

(111) $$ \begin{align} \psi(C_l) & = \bigcup_{g \in B_l} \psi(gN(T,K)g^{-1}) \nonumber \\ & = \bigcup_{g \in B_l} g\psi(N(T,K))g^{-1} \nonumber \\ & \subset \bigcup_{g \in B_l} gN(T,K)g^{-1} \nonumber \\ & = C_l. \end{align} $$

By Corollary 3.7, we have that

(112) $$ \begin{align} X = \bigcup_{g \in H_0} gN(T,K)g^{-1}, \end{align} $$

which implies that

(113) $$ \begin{align} X = \bigcup_{l=0}^{\infty} \bigcup_{g \in B_l} gN(T,K)g^{-1} \end{align} $$

since

(114) $$ \begin{align} H_0 = \bigcup_{l=0}^{\infty} B_l. \end{align} $$

By Propositions 2.4, 4.2, and Corollary 2.8, it follows that

(115) $$ \begin{align} h(\psi) = \sup_{\mu} h_{\mu}(\psi) = \lim_{l \to \infty} h(\psi|_{C_l}). \end{align} $$

We also have that

(116) $$ \begin{align} \psi(c(g,t)) = c(g,\psi(t)), \end{align} $$

which means that the map c is a semi-conjugation between the map $\psi |_{C_l}$ and the map $\Psi : B_l \times N(T,K) \to B_l \times N(T,K)$ , given by $\Psi (g,t) = (g,\psi (t))$ . Since c is a continuous and surjective map and since $B_l \times N(T,K)$ is compact, it follows that

(117) $$ \begin{align} h(\psi|_{N(T,K)}) & \leq h(\psi|_{C_l}) \nonumber \\ & \leq h(\Psi) \nonumber \\ & = h(\psi|_{N(T,K)}), \end{align} $$

showing that

(118) $$ \begin{align} h(\psi|_{C_l}) = h(\psi|_{N(T,K)}) \end{align} $$

and thus that

(119) $$ \begin{align} h(\psi) = h(\psi|_{N(T,K)}), \end{align} $$

where we used equation (116).

Proof. Since G has a countable number of connected components, it follows that the family of all open subgroups H of G with a finite number of connected components is also countable, given by $\{H_0, H_1, H_2, \ldots , H_n, \ldots \}$ . We also have that

(121) $$ \begin{align} X_G = \bigcup_{n=0}^{\infty} X_{H_n}, \end{align} $$

where $X_G$ and $X_{H_n}$ are the union of all compact subgroups of respectively G and $H_n$ . By Proposition 4.3, we have that

(122) $$ \begin{align} X_{H_n} = \bigcup_{l=0}^{\infty} C_l^n, \end{align} $$

where each $C_l^n$ is a $\psi $ -invariant compact subset and $C_l^n \subset C_{l+1}^n$ for each l. Hence,

(123) $$ \begin{align} X_G = \bigcup_{l=0}^{\infty} C_l, \end{align} $$

where

(124) $$ \begin{align} C_l = \bigcup_{n=0}^l C_l^n \end{align} $$

is a $\psi $ -invariant compact subset and $C_l \subset C_{l+1}$ for each l, since

(125) $$ \begin{align} C_l^n \subset C_{\max\{l,n\}}^n \subset C_{\max\{l,n\}}. \end{align} $$

Now, for each l, we can write

(126) $$ \begin{align} \bigcup_{n=0}^l H_n = \bigcup_{i=0}^j G_i, \end{align} $$

where $\{G_0, G_1, \ldots , G_j\}$ is a family of disjoint connected components of G. There exists a positive integer m such that $\psi ^m(G_i) = G_i$ for each i. Thus,

(127) $$ \begin{align} h(\psi^m|_{\bigcup_{n=0}^l H_n}) & = h(\psi^m|_{\bigcup_{i=0}^j G_i}) \nonumber \\ & = \max_{i = 0,\ldots,j} h(\psi^m|_{G_i}) \nonumber \\ & \leq \max_{n = 0,\ldots,l} h(\psi^m|_{H_n}), \end{align} $$

where we used Proposition 2.6 in the second equality. Hence,

(128) $$ \begin{align} h(\psi|_{\bigcup_{n=0}^l H_n}) & = \frac{1}{m}h(\psi^m|_{\bigcup_{n=0}^l H_n}) \nonumber \\ & \leq \frac{1}{m}\max_{n = 0,\ldots,l} h(\psi^m|_{H_n}) \nonumber \\ & = \max_{n = 0,\ldots,l} h(\psi|_{H_n}) \nonumber \\ & \leq \sup_{H} h(\psi|_H). \end{align} $$

Therefore,

(129) $$ \begin{align} h(\psi) & = \lim_{l \to \infty} h(\psi|_{C_l}) \nonumber \\ & \leq \lim_{l \to \infty} h(\psi|_{\bigcup_{n=0}^l H_n}) \nonumber \\ & \leq \sup_{H} h(\psi|_H) \nonumber \\ & \leq h(\psi), \end{align} $$

where we used Proposition 4.2 and Corollary 2.8 in the first equality.

Proof. Immediate consequence of Propositions 4.1, 4.3, and 4.4.