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Measures of maximal entropy of bounded density shifts

Published online by Cambridge University Press:  20 February 2024

FELIPE GARCÍA-RAMOS
Affiliation:
Institute of Physics, Universidad Autonoma de San Luis Potosi, San Luis Potosi, Mexico (e-mail: [email protected]) Institute of Mathematics, Jagiellonian University, Krakow, Małopolska, Poland (e-mail: [email protected])
RONNIE PAVLOV*
Affiliation:
University of Denver, Mathematics, Denver, Colorado, USA
CARLOS REYES
Affiliation:
Institute of Physics, Universidad Autonoma de San Luis Potosi, San Luis Potosi, Mexico (e-mail: [email protected])
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Abstract

We find sufficient conditions for bounded density shifts to have a unique measure of maximal entropy. We also prove that every measure of maximal entropy of a bounded density shift is fully supported. As a consequence of this, we obtain that bounded density shifts are surjunctive.

Type
Original Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

1 Introduction

The concept of entropy is of particular interest when trying to define formally how a system behaves at equilibrium. Given a dynamical system, we say that an invariant measure is a uniform equilibrium state if it achieves the maximal possible entropy. It has been of interest to physicists and mathematicians to determine whether a system has a unique equilibrium state or not. When this happens, some mathematicians say the system is intrinsically ergodic and some physicists say the system does not have phase transition.

In this paper, we are interested in trying to determine if bounded density shifts are intrinsically ergodic. Bounded density shifts were introduced by Stanley in [Reference Stanley22]. These subshifts are defined somewhat similarly to the classical $\beta $ -shifts in that they both are hereditary [Reference Kwietniak14], meaning that membership in the shift is preserved under coordinatewise reduction of letters. Whereas $\beta $ -shifts are ‘bounded from above’ by a specific sequence coming from a $\beta $ -expansion, bounded density shifts are restricted by length-dependent bounds on the sums of letters in subwords.

Stanley proved characterizations of when bounded density shifts are shifts of finite type, sofic, or specified, which are remarkably similar to those proved in [Reference Schmeling21] for $\beta $ -shifts.

A very effective way of proving that a transitive $\beta $ -shift is intrinsically ergodic is using the Climenhaga–Thompson decomposition [Reference Climenhaga and Thompson9] (see §2.3), which uses specification of a sub-language. Using this powerful result, one can prove that $\beta $ -shifts (and their factors) are intrinsically ergodic in a few lines (see [Reference Climenhaga and Thompson9, §3.1]).

Proving that bounded density shifts are intrinsically ergodic seems more mysterious. In this paper, we also use the Climenhaga–Thompson theorem to prove a fairly general sufficient condition (Theorem 3.5). The main application of the result is the following.

Theorem 1.1. Let $X_f\subset \{0,\ldots ,m\}^{\mathbb {Z}}$ be a bounded density shift and $\alpha _{f}$ its limiting gradient. If $\alpha _{f}> \sum _{i=1}^{ m } {i}/({i+1})$ , then $X_f$ is intrinsically ergodic.

It is not difficult to find examples with this property. For a binary shift, all we need is $\alpha _{f}>1/2$ . Furthermore, we do not know if any bounded density subshift fails to satisfy the conditions of Theorem 3.5 (Question 3.7). We conjecture that the answer of this question is positive at least for binary subshifts and that every bounded density shift is intrinsically ergodic.

This is not the first paper to study intrinsic ergodicity of bounded density shifts. This has been done in [Reference Climenhaga and Pavlov8, Reference Pavlov19]. Our hypotheses are also much simpler and provide proofs of intrinsic ergodicity for new classes of bounded density shifts.

Furthermore, we prove that every measure of maximal entropy of a bounded density shift (with positive entropy) is fully supported. This property is sometimes known as entropy minimality because it is equivalent to having lower topological entropy on every proper subshift. As a consequence of this, we prove that synchronized bounded density shifts are always intrinsically ergodic and we also obtain surjunctivity of bounded density shifts. In the last section of the paper, we prove that these shifts possess universality properties.

2 Definitions and preliminary results

2.1 Subshifts

We devote this section to collect some basic definitions in symbolic dynamics. For a broader introduction to subshifts, languages, and their properties, see [Reference Lind and Marcus15]. Let $\mathcal {A}$ be a finite set of symbols. We say that w is a word if there exists $n\in \mathbb {N}$ such that $w\in \mathcal {A}^n$ and we denote the length of w by $\vert w \vert $ . Let $\varepsilon $ denote the empty word, that is, the word with no symbols.

A word u is a subword of w if $u = w_kw_{k+1} \cdots w_{l}$ for some $1 \leq k \leq l \leq \vert w \vert $ . For words $w^{(1)}, \ldots , w^{(n)}$ , we use $w^{(1)} \cdots w^{(n)}$ to represent their concatenation. We say that a word u is a prefix of w if $u = w_1 \cdots w_{k}$ for some $1 \leq k \leq \vert w \vert $ and a suffix if $u = w_k \cdots w_{\vert w \vert }$ for some $1\leq k \leq \vert w \vert $ , denote by $\text {Suf}(w)$ and $\text {Pre}(w)$ the sets of non-empty suffixes and prefixes, respectively, for w.

We endow $\mathcal {A}^{\mathbb {Z}}$ with the product topology. When describing a point $x\in \mathcal {A}^{\mathbb {Z}}$ as a sequence, we use a dot to indicate the central position as follows: $x = \cdots x_{-1}.x_{0}x_{1} \cdots $ , where $x_i$ to represent the ith coordinate of x. We represent intervals of integers with $[i,j]$ , and $x_{[i,j]}=x_ix_{i+1}\cdots x_j$ .

The shift map $\sigma : \mathcal {A}^{\mathbb {Z}} \rightarrow \mathcal {A}^{\mathbb {Z}}$ is defined by $\sigma (x) = \cdots x_{-1}x_0.x_1x_2 \cdots $ . We say that a set $X \subseteq \mathcal {A}^{\mathbb {Z}} $ is a subshift if it is closed and invariant under $\sigma $ .

For any subshift X, let

$$ \begin{align*} \mathcal{L}_n(X)=\{ w\in \mathcal{A}^n:\text{ there exists } x\in X\text{ and } i,j\in \mathbb{Z} \text{ such that } x_{[i,j]} = w \}. \end{align*} $$

We define ${\mathcal {L}}(X) = \bigcup _{i=0}^{\infty } {\mathcal {L}}_n(X)$ as the language of the subshift X. Given a word w and $k\in \mathbb {Z}$ , we define its cylinder set as $[w]_k = \lbrace x \in X : x_{[k,k+\vert w \vert -1]} = w \rbrace $ . The cylinder sets form a basis of the topology of $\mathcal {A}^{\mathbb {Z}}$ .

2.2 Specification properties

A subshift X is specified if there exists $M \in \mathbb {N}$ such that for all $u,w \in \mathcal {L}(X)$ , there is a $v \in \mathcal {L}_M(X)$ such that $uvw \in \mathcal {L}(X)$ . Following [Reference Climenhaga and Thompson9], we also define specification for subsets of the language.

Let X be a subshift, $\mathcal {G} \subset \mathcal {L}(X)$ , and $t \in \mathbb {N}_0$ . We say that $\mathcal {G}$ has specification (with gap size t) if for all $m \in \mathbb {N}$ and $w^{(1)}, \ldots , w^{(m)} \in \mathcal {G}$ , there exists $v^{(1)}, \ldots , v^{(m-1)} \in \mathcal {L}_t(X)$ such that

$$ \begin{align*} w= w^{(1)}v^{(1)}w^{(2)}v^{(2)} \cdots v^{(m-1)}w^{(m)} \in {\mathcal{L}}(X). \end{align*} $$

Moreover, if the cylinder $[w]_0$ contains a periodic point of period exactly $\vert w \vert + t$ , then we say that $\mathcal {G}$ has periodic specification.

2.3 Measures of maximal entropy

For any subshift X, we denote by $M(X)$ the set of Borel probability measures on X. Equipped with the weak* topology, $M(X)$ is a compact topological space.

For any $\mu \in M(X)$ and any finite measurable partition $\xi $ of X, the entropy of $\xi $ (with respect to $\mu $ ), denoted by $H_\mu (\xi )$ , is defined by

$$ \begin{align*} H_\mu(\xi) = - \sum_{A \in \xi} \mu(A) \log \mu(A), \end{align*} $$

where terms with $\mu (A) = 0$ are omitted.

Given a subshift X, we denote the $\sigma $ -invariant Borel probability measures with $M(X,\sigma )$ . For $\mu \in M(X, \sigma )$ , the entropy of $\mu $ (for the shift map $\sigma $ ) is defined by

(1) $$ \begin{align} h_\mu(X) = \lim_{n \rightarrow \infty } \frac{-1}{n} \sum_{w \in \mathcal{L}_n(X)} \mu ( [w]_0) \log \mu ( [w]_0 ) = \lim_{n \rightarrow \infty } \frac{-1}{n} H_\mu(\xi^{(n)}), \end{align} $$

where $\xi ^{(n)}$ represents the partition of X into cylinder sets from the first n letters, that is, $\xi ^{(n)} = \{[w]_0 \ : \ w \in \mathcal {A}^n\}$ .

We note for future reference that $\xi ^{(n)} = \bigvee _{i = 0}^{n-1} \sigma ^{-i} \xi ^{(1)}$ , where $\xi ^{(1)}$ is the partition based on $x_0$ and $\vee $ is the join of partitions. We will later need to make use of the following basic facts about entropy; for proofs and general introduction to entropy theory, see [Reference Walters24].

Theorem 2.1. [Reference Walters24, Theorem 4.3]

For any subshift X, $\mu \in M(X)$ , and $\mathcal {\xi }$ , $\mathcal {\eta }$ finite partitions of X, $H_\mu ( \mathcal {\xi } \vee \mathcal {\eta } ) \leq H_\mu ( \xi ) + H_\mu ( \eta )$ .

Theorem 2.2. [Reference Walters24, Corollary 4.2.1]

For any subshift X and $\mu \in M(X)$ , if $\xi $ is a finite measurable partition of X with k sets, then $H_\mu (\xi ) \leq \log (k)$ , with equality only when $\mu (A) = k^{-1}$ for all $A \in \xi $ .

Theorem 2.3. [Reference Walters24, p. 184]

For any subshift X, finite measurable partition $\xi $ of X, measures $\mu _i \in M(X)$ , and $p_i \geq 0$ ( $1 \leq i \leq n$ ) with $\sum _{i = 1}^n p_i = 1$ , $H_{\sum _{i=1}^{n} p_i \mu _i }(\xi ) \geq \sum _{i=1}^n p_i H_{\mu _i}(\xi )$ .

By the well-known variational principle, the supremum of $h_\mu (X)$ over all $\mu \in M(X, \sigma )$ is the topological entropy $h_{\mathrm {top}}(X)$ of X. For any subshift X, we have that

(2) $$ \begin{align} h_{\mathrm{top}}(X)= \lim_{n \rightarrow \infty} \frac{1}{n} \log \vert \mathcal{L}_n(X) \vert. \end{align} $$

For general topological dynamical systems (TDSs), the supremum above may not be achieved. However, every subshift has at least one measure of maximal entropy, that is, $\nu \in M(X,\sigma )$ achieving the supremum above, meaning that $h_{\nu }(X) = h_{\mathrm {top}}(X)$ (e.g. see [Reference Walters24, Remark (2), p. 192]).

We say a subshift is intrinsically ergodic if there is only one (probability) measure of maximal entropy.

Every specified subshift is intrinsically ergodic [Reference Bowen1]. This result was generalized in several works, including [Reference Climenhaga and Thompson9, Reference Pavlov18]. Before stating the result, we need some extra definitions.

Given a collection of words $\mathcal {D} \subseteq \mathcal {L}(X)$ and $n \geq 1$ , we define $\mathcal {D}_n = \mathcal {D} \cap \mathcal {L}_n(X)$ . We denote the growth rate of $\mathcal {D}$ by

(3) $$ \begin{align} h(\mathcal{D}) = \limsup_{n \rightarrow \infty} \frac{1}{n} \log \vert \mathcal{D}_n \vert. \end{align} $$

Note that $h(\mathcal {L}(X))=h_{\mathrm {top}}(X).$

Following [Reference Climenhaga and Thompson9], we say that $\mathcal {L}(X)$ admits a decomposition $\mathcal {C}^p\mathcal {G} \mathcal {C}^s$ for $\mathcal {C}^p, \mathcal {G}, \mathcal {C}^s \subset \mathcal {L}(X)$ if every $w \in \mathcal {L}(X)$ can be written as $uvw$ for some $u \in \mathcal {C}^p$ , $v \in \mathcal {G}$ , $w \in \mathcal {C}^s$ . For such a decomposition, we define the collection of words $\mathcal {G}(M)$ for each $M \in \mathbb {N}$ by

(4) $$ \begin{align} \mathcal{G}(M) = \lbrace uvw \, : \, u \in \mathcal{C}^p , v \in \mathcal{G}, w \in \mathcal{C}^s, \vert u \vert \leq M, \vert w \vert \leq M \rbrace. \end{align} $$

Recall that Per $(n)$ denotes the set of points with period at most n under $\sigma $ .

Theorem 2.4. (Climenhaga and Thompson [Reference Climenhaga and Thompson9])

Let X be a subshift whose language $\mathcal {L}(X)$ admits a decomposition $\mathcal {L}(X) = \mathcal {C}^p \mathcal {G} \mathcal {C}^s$ and suppose that the following conditions are satisfied:

  1. (1) $\mathcal {G}$ has specification;

  2. (2) $h(\mathcal {C}^p \cup \mathcal {C}^s) < h_{\mathrm {top}}(X)$ ;

  3. (3) for every $M \in \mathbb {N}$ , there exists $\tau $ such that given $v \in \mathcal {G}(M)$ , there exists words $u,w$ with $\vert u \vert \leq \tau , \, \vert w \vert \leq \tau $ for which $uvw \in \mathcal {G}$ .

Then X is intrinsically ergodic. Furthermore, if $\mathcal {G}$ has periodic specification, then

(5) $$ \begin{align} \mu_n = \frac{1}{\vert \mathrm{Per}(n)\vert} \sum_{x \in \mathrm{Per}(n)} \delta_x \end{align} $$

converges to the measure of maximal entropy in the weak* topology.

Remark. Using results from [Reference Pacifico, Yang and Yang17], Climenhaga explained in a blog post [Reference Climenhaga7] that condition (3) is actually not required to prove uniqueness of the measure of maximal entropy. However, this condition is not difficult to check for bounded density shifts with positive entropy (Lemma 3.4) and so we verify it regardless.

2.4 Bounded density shifts

Bounded density shifts were introduced in [Reference Stanley22] (see also [Reference Bruin2, Ch. 3.4]). Let $f : \mathbb {N}_0 \rightarrow [ 0 , \infty ) $ be a function. We say f is canonical if:

  • $f(0)=0$ ;

  • $f(m+1)\geq f(m)$ for all $m\geq 0$ ; and

  • $f(m+n)\leq f(m)+f(n)$ for all $n,m\in \mathbb {N}$ .

The bounded density shift associated to a canonical function, f, is defined as follows:

(6) $$ \begin{align} X_f = \bigg\lbrace x \in ( \mathbb{N}_0)^{\mathbb{Z}} : \text{ for all } p \in \mathbb{N} \text{ and } \text{ for all } i \in \mathbb{Z} \,\, \sum_{r=i}^{i+p-1} x_r \leq f(p) \bigg\rbrace. \end{align} $$

Note that $X_f$ is a subshift on the alphabet $\mathcal {A}=\{0,1,\ldots ,\lfloor f(1) \rfloor \}$ .

Actually, bounded density shifts can be defined for any function $f : \mathbb {N}_0 \rightarrow [ 0 , \infty )$ , but it was shown in [Reference Stanley22] that every bounded density shift can be defined by some canonical f.

Definition. Let $X_f$ be a bounded density shift, the limit

(7) $$ \begin{align} \lim_{n \rightarrow \infty} \frac{f(n)}{n} \end{align} $$

is called the limiting gradient and is denoted by $\alpha _{f}$ .

The existence of the limit is given by Fekete’s lemma and the definition of canonical function; furthermore, the limit is an infimum and so $f(n) \geq \alpha _{f} n$ for all n.

There exist bounded density shifts with $\alpha _{f}=0$ , but they are fairly trivial systems where the upper density of non-zero coordinates is always 0. A bounded density shift has positive topological entropy if and only if $\alpha _{f}>0$ (see [Reference Kwietniak14, Theorem 12]) if and only if it is coded (determined by a labeled irreducible graph with possibly countably many vertices) [Reference Stanley22, Theorem 3.1].

As we mentioned in the previous section, the specification property guarantees intrinsic ergodicity. For bounded density shifts, $X_f$ is specified with specification constant M if and only if $0^M$ is intrinsically synchronizing [Reference Stanley22, Theorem 5.1]. Bounded density shifts with positive topological entropy without specification can easily be constructed [Reference Stanley22].

As we mentioned in the previous section, the specification property guarantees intrinsic ergodicity. For bounded density shifts, $X_f$ is specified with specification constant M if and only if $0^M$ is intrinsically synchronizing [Reference Stanley22, Theorem 5.1]. There exist bounded density shifts with positive topological entropy without specification [Reference Stanley22].

A subshift X with alphabet $A=\{0,1,\ldots ,n\}$ is hereditary if every time there is $x\in X$ and $y\in A^{\mathbb {Z}}$ with $y_i\leq x_i$ $\text { for all } i\in \mathbb {Z}$ , then $y\in X$ . It is not difficult to check that bounded density shifts are hereditary.

3 Intrinsic ergodicity

In this section, we fix a binary bounded density shift $X_f$ . We define

$$ \begin{align*} \mathcal{G} = \bigg\lbrace w \in \mathcal{L}(X_f) : \text{ if } u \in \text{Pre}(w) \cup \text{Suf}(w), \text{ then } \frac{1}{\vert u \vert} \sum_{i=1}^{\vert u \vert } u_i < \alpha_{f} \bigg\rbrace \quad \text{and} \end{align*} $$
$$ \begin{align*} \mathcal{B} = \mathcal{C}^p = \mathcal{C}^s = \bigg\lbrace v \in \mathcal{L}(X_f) : \frac{1}{\vert v \vert} \sum_{i=1}^{\vert v \vert} v_i \geq \alpha_{f} \bigg\rbrace \cup \{ \epsilon \}, \end{align*} $$

where $\epsilon $ denotes the empty word.

Lemma 3.1. The language $\mathcal {L}(X_f)$ admits a decomposition $\mathcal {B} \mathcal {G} \mathcal {B}$ .

Proof. Let $z \in \mathcal {L} ( X_f )$ . Define u to be the prefix of z in $\mathcal {B}$ of maximal length (which may be the empty word $\epsilon $ ) and denote its length by $M \geq 0$ . Let $z'$ be the maximal proper subword of z that does not overlap with u, that is, $z'=z_{[M+1, \vert z \vert ]}$ . Similarly, define w to be the suffix of $z'$ in $\mathcal {B}$ of maximal length (which may be the empty word $\epsilon $ ) and denote its length by $N \geq 0$ .

We write $y = z_{[M+1,\vert z \vert -N]}$ and assume for a contradiction that $y \notin \mathcal {G}$ . Then by definition, there exists a word $v \in \text {Pre}(y) \cup \text {Suf}(y)$ with

$$ \begin{align*} \frac{1}{\vert v \vert} \sum_{i=1}^{\vert v \vert} v_i \geq \alpha_{f}. \end{align*} $$

If $v \in \text {Pre}(y)$ , then $uv$ would be a prefix of z in $\mathcal {B}$ longer than u, contradicting minimality of u. Similarly, if $v \in \text {Suf}(y)$ , then $vw$ would be a suffix of $z'$ in $\mathcal {B}$ longer than w, contradicting minimality of w. Therefore, we have a contradiction and $y \in \mathcal {G}$ , and so $z = uyw \in \mathcal {B} \mathcal {G} \mathcal {B}$ .

Lemma 3.2. The set $\mathcal {G}$ has specification.

Proof. We will show that $\mathcal {G}$ has periodic specification with gap size $t=0$ . Let $ m \in \mathbb {N}$ , $w^{(1)}, \ldots , w^{(m)} \in \mathcal {G}$ , $v^{(a)}\in \text {Suf}(w^{(m)})$ , $v^{(b)}\in \text {Pre}(w^{(1)})$ and $z = v^{(a)}w^{(1)} \cdots w^{(m)}v^{(b)}$ . We compute

$$ \begin{align*} \sum_{i=1}^{|z|} z_i & = \sum_{i=1}^{|v^{(a)}|} v_{i}^{(a)} + \sum_{i=1}^{|w^{(1)}|} w_{i}^{(1)} + \cdots + \sum_{i=1}^{|w^{(m)}|} w_{i}^{(m)} + \sum_{i=1}^{|v^{(b)}|} v_{i}^{(b)} \\ & < |v^{(b)}| \alpha_{f} + |w^{(1)}| \alpha_{f} + \cdots + |w^{(m)}| \alpha_{f} +|v^{(b)}| \alpha_{f}\\ & = \alpha_{f} \bigg(|v^{(a)}| +\sum_{i=1}^{m} |w^{(i)}| +|v^{(b)}| \bigg) \\ & = \alpha_{f} |z| \\ & \leq f(|z|). \end{align*} $$

This implies that any periodic point made from concatenations of words from $\mathcal {G}$ is in $X_f$ . We conclude that $\mathcal {G}$ has periodic specification.

In the second part of the following proposition, we use techniques from Misiurewicz’s proof of the variational principle [Reference Misiurewicz16] to build measures with entropy higher or equal than that of a sub-language. These applications of the tools from [Reference Misiurewicz16] have already been noted in [Reference Burns, Climenhaga, Fisher and Thompson4, Proposition 5.1] and [Reference Pacifico, Yang and Yang17, Lemma 6.8].

Proposition 3.3. There exists $\mu \in M(X_f,\sigma )$ with $\sum _{i=0} ^{\lfloor f(1) \rfloor } i\mu ([i]_0) \geq \alpha _{f}$ and $h(\mathcal {B}) \leq h_\mu (X_f)$ .

Proof. For each $n \in \mathbb {N}$ and $w \in \mathcal {L}_n(X_f) \cap {\mathcal {B}}$ , consider the set:

$$ \begin{align*} K_n = \lbrace{}^\infty 0. w 0^\infty : w \in \mathcal{L}_n(X_f) \cap {\mathcal{B}} \rbrace. \end{align*} $$

By construction, $\vert K_n \vert = \vert \mathcal {L}_n(X_f) \cap {\mathcal {B}} \vert $ . Let $\nu _n \in M(X_f)$ be the atomic measure concentrated uniformly on the points of $K_n$ , that is,

$$ \begin{align*} \nu_n = \frac{1}{\vert K_n \vert} \sum_{x \in K_n} \delta_x. \end{align*} $$

Let $\mu _n \in M(X_f)$ be defined by

$$ \begin{align*} \mu_n = \frac{1}{n} \sum_{j=0}^{n-1} \nu_n \circ \sigma^{-j}. \end{align*} $$

Note that

$$ \begin{align*} \sum_{i=0} ^{\lfloor f(1) \rfloor} i\mu_n([i]_0) & = \sum_{i=0} ^{\lfloor f(1) \rfloor} \frac{i}{n} \sum_{j=0}^{n-1} \nu_n \circ \sigma^{-j} ([i]_0) \\ & = \sum_{i=0} ^{\lfloor f(1) \rfloor} \frac{i}{n} \sum_{j=1}^{n} \frac{\vert \{w\in \mathcal{L}_n(X_f) \cap \mathcal{B}: w_i=i \}\vert}{\vert K_n \vert} \\ & = \frac{1}{\vert K_n \vert} \sum_{w \in \mathcal{L}_n(X_f) \cap \mathcal{B}} \bigg( \frac{1}{n} \sum_{j=1}^{n} w_j \bigg) \\ & \geq \alpha_{f}. \end{align*} $$

Since $M(X_f)$ is compact (in the weak* topology), we can choose a subsequence such that

(8) $$ \begin{align} \lim_{j \rightarrow \infty} \frac{1}{n_j} \log \vert \mathcal{L}_{n_j} ( X_f) \cap \mathcal{B} \vert = \limsup_{n \rightarrow \infty} \frac{1}{n} \log \vert \mathcal{L}_n( X_f) \cap \mathcal{B} \vert = h(\mathcal{B}), \end{align} $$

and $\mu _{n_j}\rightarrow \mu \in M(X_f)$ . By the definition of $\mu _n$ , it is routine to check that $\mu \in M ( X_f, \sigma )$ , that is, $\mu $ is $\sigma $ -invariant.

We will use techniques from the proof of the variational principle in [Reference Misiurewicz16] to prove that

(9) $$ \begin{align} h_\mu ( X_f) \geq \limsup_{n \rightarrow \infty} \frac{1}{n} \log \vert \mathcal{L}_n (X_f) \cap \mathcal{B} \vert = h(\mathcal{B}). \end{align} $$

First, since $\sum _{i=0} ^{\lfloor f(1) \rfloor } i\mu _{n_j}([i]_0) \geq \alpha _{f}$ and $\mu _{n_j} \rightarrow \mu $ , we also have that $\sum _{i=0} ^{\lfloor f(1) \rfloor } i\mu ([i]_0) \geq \alpha _{f}$ . Consider the partition given by the alphabet $\xi = \lbrace [0]_0, \ldots , [\lfloor f(1) \rfloor ]_0 \rbrace $ . Since all $w \in \mathcal {L}_{n_j}(X_f) \cap \mathcal {B}$ have equal measure $\nu _{n_j}([w]_0) = |K_{n_j}|^{-1}$ and all other $w \in \mathcal {A}^n_j$ have $\nu _{n_j}([w]_0) = 0$ , by Theorem 2.2,

(10) $$ \begin{align}\hspace{-10pt} H_{\nu_{n_j}} \bigg( \bigvee_{i=0}^{n_j-1} \sigma^{-i} \xi \bigg) = - \sum_{w \in \mathcal{L}_{n_j}( X_f) {\cap \mathcal{B}}} \nu_{n_j}([w]_0)\log \nu_{n_j}([w]_0) { = \log}|\mathcal{L}_{n_j}( X_f) \cap \mathcal{B}|. \end{align} $$

Let $q,n \in \mathbb {N}$ with $1 < q < n$ and define $a(t) = \lfloor ({n-t})/{q}\rfloor $ for $0 \leq t < q$ . Note that $a(0) \geq a(1) \geq \cdots \geq a(q-1)$ . For every $0 \leq t \leq q-1$ , we define

$$ \begin{align*} S_t = \lbrace 0 , 1 , \ldots , t-1 , t + a(t)q, t+a(t)q+1, \ldots, n-1 \rbrace. \end{align*} $$

So, for any such t, we can rewrite $\lbrace 0, 1, \ldots , n-1 \rbrace $ as follows:

(11) $$ \begin{align} \lbrace 0, 1, \ldots , n-1 \rbrace = \lbrace t + rq + i \vert 0 \leq r < a(t), 0 \leq i < q \rbrace \cup S_t. \end{align} $$

Observe that

$$ \begin{align*} t + a(t)q = t + \bigg\lfloor \frac{n-t}{q}\bigg\rfloor q \geq t + \bigg( \frac{n-t}{q} - 1 \bigg) q = t+ n -t -q = n-q. \end{align*} $$

Thus, the cardinality of $S_t$ is at most $2q$ .

Using equation (11), we get

(12) $$ \begin{align} \bigvee_{i=0}^{n_j-1} \sigma^{-i} \xi = \bigg( \bigvee_{r=0}^{a(t)-1} \sigma^{-(rq+t)} \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg) \vee \bigvee_{l \in S_t} \sigma^{-l} \xi. \end{align} $$

Combining equations (10), (12), and Theorem 2.1, we obtain

(13) $$ \begin{align} \log \vert \mathcal{L}_{n_j} ( X_f) \cap \mathcal{B} \vert & = H_{\nu_{n_j}} \bigg( \bigvee_{i=0}^{n_j-1} \sigma^{-i} \xi \bigg) \nonumber \\ & \leq \sum_{r=0}^{a(t)-1} H_{\nu_{n_j}} \bigg( \sigma^{-(rq+t)} \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg) + \sum_{l \in S_t} H_{\nu_{n_j}} ( \sigma^{-l} \xi)\nonumber \\ & \leq \sum_{r=0}^{a(t)-1} H_{\nu_{n_j} \circ \sigma^{-(rq+t)}} \bigg( \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg) + 2q \log (l). \end{align} $$

For the inequality $\sum _{l \in S_t} H_{\nu _{n_j}}(\sigma ^{-l}\xi ) \leq 2q \log (l)$ , we apply Theorem 2.2. We note that for each $0 \leq t \leq q-1$ , we have

(14) $$ \begin{align} ( a(t)-1)q + t \leq \bigg\lfloor \frac{n-t}{q} - 1 \bigg\rfloor q + t = n - q. \end{align} $$

Summing the first term in the last line of equation (13) over t from $0$ to $q-1$ , and using that the numbers $\lbrace t+rq : 0 \leq t \leq q-1, 0 \leq r \leq a(t)-1 \rbrace $ are all distinct and are all no greater than $n-q$ , yields

(15) $$ \begin{align} \sum_{t=0}^{q-1} \bigg( \sum_{r=0}^{a(t)-1} H_{\nu_{n_j} \circ \sigma^{-(rq+t)}} \bigg( \bigvee_{i=0}^{q-1}\sigma^{-i} \xi \bigg) \bigg) & = \sum_{r=0}^{a(0)-1}H_{\nu_{n_j} \circ \sigma^{-(rq)}} \bigg( \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg) + \cdots \nonumber \\ & \quad \cdots + \sum_{r=0}^{a(q-1)-1} H_{\nu_{n_j} \circ \sigma^{-(rq+q-1)}} \bigg( \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg) \nonumber \\ &= \sum_{p=0}^{{n_j}-1} H_{\nu_{n_j} \circ \sigma^{-p}} \bigg( \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg). \end{align} $$

Using equations (13) and (15), we get

$$ \begin{align*} q \log \vert \mathcal{L}_{n_j} (X_f) \cap \mathcal{B} \vert \leq \sum_{p=0}^{n_j-1} H_{\nu_{n_j} \circ \sigma^{-p}} \bigg( \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg) + \frac{2q^2}{n_j} \log (l). \end{align*} $$

Now, we divide by $n_j$ and apply Theorem 2.3 (with $p_i = {1}/{n_j}$ ) to obtain

(16) $$ \begin{align} \frac{q}{n_j} \log \vert \mathcal{L}_{n_j} ( X_f) \cap \mathcal{B} \vert \leq H_{\mu_{n_j}} \bigg( \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg) + \frac{2q^2}{n_j^2} \log (l). \end{align} $$

We will also use that

(17) $$ \begin{align} \lim_{k \rightarrow \infty} H_{\mu_{n_{j_k}}} \bigg( \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg) = H_\mu \bigg( \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg), \end{align} $$

which is obtained using the definition of weak* convergence. Then, combining equations (16) and (17) yields

$$ \begin{align*} qh(\mathcal{B}) & = \lim_{k \rightarrow \infty} \frac{q}{n_{j_k}} \log \vert \mathcal{L}_{n_{j_k}} ( X_f) \cap \mathcal{B} \vert \\ & \leq \lim_{k \rightarrow \infty} H_{\mu_{n_{j_k}}} \bigg( \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg) + \lim_{k \rightarrow \infty} \frac{2q^2}{n_{j_k}} \log (l) \\ & = H_\mu \bigg( \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg). \end{align*} $$

Now, by definition of $h_{\mu }(X_f)$ ,

$$ \begin{align*} h(B) \leq \lim_{q \rightarrow \infty} {\frac{1}{q}} H_\mu \bigg( \bigvee_{i=0}^{q-1} \sigma^{-i} \xi \bigg) = h_\mu(X_f).\\[-40pt] \end{align*} $$

Lemma 3.4. For every $M \in \mathbb {N}$ , there exists $\tau $ such that given $v \in \mathcal {G}(M)$ , there exist words $u,w$ with $\vert u \vert \leq \tau $ , $\vert w \vert \leq \tau $ for which $uvw \in \mathcal {G}$ .

Proof. Let $M \in \mathbb {N}$ and $v \in \mathcal {G}(M)$ . This implies that there exist $u', w' \in \mathcal {B}, v' \in \mathcal {G}$ such that $v = u' v' w'$ and $\vert u' \vert \leq M, \vert w' \vert \leq M$ . Choose $u=w=0^\tau $ , with $\tau = \lceil {2M \lfloor f(1) \rfloor }/{\alpha _{f}} \rceil $ .

Let $z \in \text {Pre}(0^{ \tau }u'v'w'0^{ \tau })$ . Consider the following sets, $N_1 = [ 1 , \tau ] $ , $N_2 = [ \tau + 1 , \tau + \vert u' \vert ] \cup [ \tau + \vert u' v' \vert +1, \tau + \vert u'v'w' \vert ] $ , and $N_3 = [ \tau + \vert u' \vert +1, \tau + \vert u'v' \vert ]$ . Note that $N_2$ corresponds to the section where $u'$ and $w'$ appear and $N_3$ where $v'$ appears. Also, we can assume that $\vert z \vert \geq \tau $ (otherwise we are considering that $z \in \text {Pre}(0^\tau )$ ), then

$$ \begin{align*} \frac{1}{\vert z \vert} \sum_{i=1}^{\vert z \vert} z_i &= \frac{1}{\vert z \vert } \bigg( \sum_{i \in N_1 \cap [1, \vert z \vert ] } z_i + \sum_{i \in N_2 \cap [1, \vert z \vert ] } z_i + \sum_{i \in N_3 \cap [1, \vert z \vert ] } z_i \bigg) \\ & = \frac{1}{\vert z \vert } \bigg( \frac{\vert N_1 \cap [1, \vert z \vert ] \vert}{\vert N_1 \cap [1, \vert z \vert ] \vert} \sum_{i \in N_2 \cap [1, \vert z \vert ] } z_i \,\, + \,\, \frac{\vert N_3 \cap [1, \vert z \vert ] \vert}{\vert N_3 \cap [1, \vert z \vert ] \vert} \sum_{i \in N_3 \cap [ 1, \vert z \vert]} z_i \bigg) \\ & \leq \frac{1}{\vert z \vert} \bigg( \frac{\vert N_1 \cap [1, \vert z \vert ] \vert}{\vert N_1 \cap [1, \vert z \vert ] \vert} 2M \lfloor f(1) \rfloor + \alpha_{f} \vert N_3 \cap [1, \vert z \vert ] \vert \bigg) \\ & = \frac{1}{\vert z \vert} \bigg( \vert N_1 \cap [1, \vert z \vert ] \vert \frac{2M \lfloor f(1) \rfloor}{\tau} + \alpha_{f} \vert N_3 \cap [1, \vert z \vert ] \vert \bigg) \\ & \leq \frac{1}{\vert z \vert} ( \alpha_{f} \vert N_1 \cap [1, \vert z \vert ] \vert + \alpha_{f} \vert N_3 \cap [1, \vert z \vert ] \vert ) \\ & = \alpha_{f} \bigg( \frac{\vert N_1 \cap [1, \vert z \vert ] \vert + \vert N_3 \cap [1, \vert z \vert ] \vert }{\vert z \vert } \bigg)\\ & \leq \alpha_{f}. \end{align*} $$

Here, the first inequality holds since $v' \in \mathcal {G}$ , the second equality holds because $\vert N_1 \cap [1,\vert z \vert ] \vert = \tau $ (using $\vert z \vert \geq \tau $ ), and the second inequality holds since $\tau \geq {2M \lfloor f(1) \rfloor }/{\alpha _{f}}$ .

The proof for $z \in \text {Suf}(0^{ \tau }u'v'w'0^{ \tau })$ is similar.

Theorem 3.5. Let $X_f$ be a bounded density shift. If every measure of maximal entropy $\mu $ has the property that $\sum _{i} ^{\lfloor f(1) \rfloor } i\mu ([i]_0) < \alpha _{f}$ , then $X_f$ is intrinsically ergodic and

(18) $$ \begin{align} \mu_n = \frac{1}{\vert \mathrm{Per}(n)\vert} \sum_{x \in \mathrm{Per}(n)} \delta_x \end{align} $$

converges to the measure of maximal entropy in the weak* topology.

Proof. If $\alpha _{f}=0$ , then since all sequences have frequency $0$ of non- $0$ symbols, the unique invariant measure is the delta measure of $^\infty 0^{\infty } $ .

If $\alpha _{f}>0$ , we will obtain the result using Theorem 2.4. First note that $\mathcal {B}= \mathcal {C}^p = \mathcal {C}^s$ . Using Lemma 3.1, we obtain $\mathcal {L}(X) = \mathcal {C}^p \mathcal {G} \mathcal {C}^s$ . Now we will check the numbered hypotheses of Theorem 2.4.

  1. (1) Lemma 3.2 gives us that $\mathcal {G}$ has specification.

  2. (2) Let $\mu '$ be the measure constructed in Lemma 3.3. By hypothesis, it cannot be a measure of maximal entropy. Thus, $h(\mathcal {C}^p \cup \mathcal {C}^s) = h(\mathcal {B}) \leq h_{\mu '}(X_f)< h_{\mathrm {top}}(X_f)$ .

  3. (3) We obtain this property using Lemma 3.4.

The main application of the previous result that we have is the following.

Corollary 3.6. Let $X_f$ be a bounded density shift. If $\alpha _{f}> \sum _{i=1}^{\lfloor f(1) \rfloor } ({i}/({i+1}))$ , then $\sum _{i} ^{\lfloor f(1) \rfloor } i\mu ([i]_0) < \alpha _{f}$ for every measure of maximal entropy $\mu $ . This implies that $X_f$ is intrinsically ergodic and

(19) $$ \begin{align} \mu_n = \frac{1}{\vert \mathrm{Per}(n)\vert} \sum_{x \in \mathrm{Per}(n)} \delta_x \end{align} $$

converges to the measure of maximal entropy in the weak* topology.

Proof. Using [Reference García-Ramos and Pavlov12, Corollary 4.6] and the fact that bounded density shifts are hereditary, we have that for any measure of maximal entropy,

$$ \begin{align*}\mu( [i]_0 )\leq \mu([i-1]_0).\end{align*} $$

Since $\mu $ is a probability measure, this implies that $\mu ([i]_0)\leq 1/(i+1)$ . Thus,

$$ \begin{align*} \sum_{i=1}^{\lfloor f(1) \rfloor} i \cdot \mu ([i]_0) \leq \sum_{i=1}^{\lfloor f(1) \rfloor} {i}/{i+1}. \end{align*} $$

We obtain the result using Theorem 3.5.

Remark. In particular, every binary bounded density shift with $\alpha _{f}> 1/2$ is intrinsically ergodic.

Furthermore, we suspect that the hypothesis of Theorem 3.5 may always be satisfied, at least for binary subshifts, leading to the following questions.

Question 3.7. Let X be a hereditary binary subshift with positive topological entropy. Is it true that for any measure of maximal entropy $\mu $ , we have that $\mu ([1]_0)<\sup _{\nu \in M(X)} \nu ([1]_0)$ ?

A reason to suspect Question 3.7 is true is that if X is hereditary and $\mu ([1]_0)$ achieves its (positive) supremum, then it should be possible to increase the entropy of $\mu $ by allowing a small proportion of randomly chosen $1$ symbols to change to $0$ s. Some circumstantial evidence is given by the class of $\mathcal {B}$ -free shifts, for which it is known that maximal entropy is achieved by such a procedure (cf. [Reference Kułaga-Przymus, Lemańczyk and Weiss13, Theorem 2.1.8]). We also ask the corresponding question for bounded density shifts on larger alphabets.

Question 3.8. Is it true that for every bounded density shift, we have that

$$ \begin{align*}\sum_{i} ^{\lfloor f(1) \rfloor} i\mu([i]_0) < \alpha_{f}\end{align*} $$

for every measure of maximal entropy?

One more natural question is whether we can prove stronger properties on the unique measure of maximal entropy via arguments such as those in [Reference Burns, Climenhaga, Fisher and Thompson4, Reference Pavlov19].

Question 3.9. Let $X_f$ be an intrinsically ergodic bounded density shift. Does the measure of maximal entropy have the K-property? Is it Bernoulli?

We do not know how to approach this question with current techniques. All arguments we are aware of which prove Bernoulli require connection to countable-state Markov shifts, which do not seem clear for bounded density shifts. Additionally, the usual argument to prove K-property (without Bernoulli) is to show that the product of $(X_f, \sigma )$ with itself has a unique measure of maximal entropy, but in general, Climenhaga–Thompson decompositions are not preserved under products and we do not see any reason that bounded density structure improves the situation. We note that purely being hereditary does not necessarily imply either property, as in [Reference Kułaga-Przymus, Lemańczyk and Weiss13], it was shown that for $\mathcal {B}$ -free shifts, the unique measure of maximal entropy factors onto the so-called Mirsky measure, which is of zero entropy; this precludes the K-property.

4 Entropy minimality and surjunctivity

We will now prove a property called entropy minimality for all bounded density shifts for $\alpha _{f}> 0$ using results from [Reference García-Ramos and Pavlov12]. We first need some definitions.

A subshift X is entropy minimal if every subshift strictly contained in X has lower topological entropy. Equivalently, X is entropy minimal if every measure of maximal entropy on X is fully supported.

Let X be a subshift and $v \in \mathcal {L}(X)$ . The extender set of v is defined by

$$ \begin{align*} E_{X_f}(v) = \lbrace y \in \lbrace 0 , 1, \ldots, \lfloor f(1) \rfloor \rbrace^{\mathbb{Z}} : y_{(-\infty,0]}vy_{[1, \infty )} \in X_f \rbrace. \end{align*} $$

Theorem 4.1. (García-Ramos and Pavlov [Reference García-Ramos and Pavlov12])

Let X be a subshift with $h_{\mathrm {top}}(X)>0$ , $\mu $ a measure of maximal entropy, and $v,w\in \mathcal {L}(X)$ . If $E_X(v)\subseteq E_X(w)$ , then

$$ \begin{align*} \mu(v)\leq \mu(w)e^{h_{\mathrm{top}}(X)(|w|-|v|)}. \end{align*} $$

Theorem 4.2. Every bounded density shift (with $\alpha _{f}>0$ ) is entropy minimal.

Proof. Let $X_f$ be a bounded density shift, $\mu \in M(X_f, \sigma )$ a measure of maximal entropy, and $w \in \mathcal {L}(X_f)$ . Since the topological entropy of $X_f$ is positive, then $1 \in \mathcal {L}(X_f)$ and $\mu ([1]_0)>0$ (otherwise $\mu ([0]_0)=1$ and the entropy cannot be positive). By Poincaré’s recurrence theorem, there exists $v'\in \mathcal {L}(X_f)$ for which $\mu ([v']_0)> 0$ and

$$ \begin{align*} \sum_{i=1}^{|v^{\prime}|} v^{\prime}_i> \sum_{i=1}^{|w|} w_i. \end{align*} $$

We can then define v which is coordinatewise less than or equal to w with

$$ \begin{align*}\sum_{i=1}^{|v|} v_i=\sum_{i=1}^{|w|} w_i. \end{align*} $$

By the fact that $X_f$ is hereditary, $E_{X_f}(v') \subset E_{X_f}(v)$ and so by Theorem 4.1, $\mu ([v])\geq \mu ([v'])>0$ .

We want to prove that $E_{X_f}(v) \subseteq E_{X_f}(0^{\vert v \vert } w 0^{\vert v \vert })$ . Let $y \in E_{X_f}(v)$ , with $x = y_{(-\infty , 0]}.vy_{[1,\infty )}\in X_f$ and $x' = y_{(-\infty , 0]}.0^{\vert v \vert }w0^{\vert v \vert }y_{[1,\infty )}$ . Let $n<m\in \mathbb {Z}$ . We consider two cases, when $x^{\prime }_{[n,m]}$ is a subword of $0^{\vert v \vert } w 0^{\vert v \vert }$ and when it is not. If $x^{\prime }_{[n,m]}$ is a subword of $0^{\vert v \vert } w 0^{\vert v \vert }$ , then $x^{\prime }_{[n,m]} \in \mathcal {L}(X_f)$ since $w \in \mathcal {L}(X_f)$ [Reference Stanley22, Lemma 2.3]. Otherwise, there exists $p\in \mathbb {Z}$ such that

$$ \begin{align*} \sum_{i=n}^{m} x^{\prime}_i \leq \sum_{i=n+p}^{m+p} x_i \leq f(m-n). \end{align*} $$

This implies that $x^{\prime }_{[n,m]} \in \mathcal {L}(X_f)$ . Thus, $x' \in X_f$ and so $y \in E_{X_f}(0^{\vert v \vert }w0^{\vert v \vert })$ . Since y was arbitrary, $E_{X_f}(v) \subseteq E_{X_f}(0^{\vert v \vert }w0^{\vert v \vert })$ . Using Theorem 4.1, we conclude that

$$ \begin{align*} \mu([w]_0)\geq \mu([0^{\vert v \vert}w0^{\vert v \vert}]_0) \geq \mu([v]_0)e^{-{h_{\mathrm{top}}(X)(|w|-|v|)}}>0. \end{align*} $$

Therefore, $\mu $ is fully supported.

Let X be a subshift. A word $v \in \mathcal {L}(X)$ is intrinsically synchronizing if $uv,vw \in \mathcal {L}(X)$ , then $uvw \in \mathcal {L}(X)$ .

A subshift is synchronized if there exists $v \in \mathcal {L}(X)$ such that v is an intrinsically synchronizing word.

Every entropy minimal synchronized subshift is intrinsically ergodic [Reference García-Ramos and Pavlov12, Reference Thomsen23] and every synchronized subshift is coded [Reference Fiebig and Fiebig11]. Hence, we obtain the following corollary.

Corollary 4.3. Every synchronized bounded density shift is intrinsically ergodic.

Another application of entropy minimality is surjunctivity. Given a subshift X, we say $\phi :X\rightarrow X$ is a shift-endomorphism if it is continuous and it commutes with the shift. If a shift-endomorphism is bijective, we say it is a shift-automorphism.

A subshift X is said to be surjunctive if every injective shift-endomorphism of X is a shift-automorphism. Every full shift is surjunctive [Reference Coornaert10, Ch. 3]. The following result is known (e.g. see [Reference Ceccherini-Silberstein, Coornaert and Li5]) but it is not explicitly stated. We write the proof since the argument is simple.

Lemma 4.4. Every entropy minimal subshift is surjunctive.

Proof. Let X be a subshift and $\phi :X\rightarrow X$ an injective shift-endomorphism. This implies that $\phi (X)$ is a subshift which is topologically conjugate to X. Since topological entropy is conjugacy-invariant, $\phi (X)$ has the same topological entropy as X. If X is entropy minimal, then $\phi (X)=X$ .

Using this and Theorem 4.2, we obtain the following.

Corollary 4.5. Every bounded density shift with positive topological entropy is surjunctive.

5 Universality

A dynamical system is said to be universal if every system with smaller entropy can be embedded in the original system (this can be studied either in the topological or measure-theoretic category). For instance, measure-theoretic universality of the full shift follows from Krieger’s generator theorem. Results about both types (topological and measure-theoretical) of universality have been proved for systems with specification in [Reference Burguet3, Reference Chandgotia and Meyerovitch6, Reference Quas and Soo20], and we can prove a topological universality result for bounded density subshifts as well. We first need some basic definitions about topological dynamical systems.

A topological dynamical system is a pair $(X,T)$ , where X is a compact metrizable space and $T:X\to X$ is a continuous function. Let $(X,T)$ and $(X',T')$ be two topological dynamical systems. We say X and $X'$ are conjugated if there exists a homeomorphism $f: X\to X'$ such that $T'\circ f=f\circ T$ .

For any TDS $(X,T)$ , one can assign a topological entropy $h_{\mathrm {top}}(X,T)$ . When the system is a subshift, the notion coincides with the definition in §2.3. For the definition, see [Reference Walters24, Ch. 7].

Let $\gamma \in \mathbb {R}_+$ . We say a subshift X is $\gamma $ -universal if for any TDS with $h_{\mathrm {top}}(X_1,T_1)< \gamma $ , there is a subshift $X'\subset X$ such that $(X_1,T_1)$ is conjugated to $(X',\sigma ).$

Theorem 5.1. (Burguet [Reference Burguet3])

Every subshift X with specification is $h_{\mathrm {top}}({X})$ -universal.

Let $\alpha \in \mathbb {R}_+$ . We define $X_{\alpha }$ as the bounded density shift obtained with the function $f(n)=\lfloor n\alpha \rfloor $ . Using [Reference Stanley22, Theorem 1.3], we have that $X_\alpha $ has specification.

Given a bounded density shift $X_f$ , one can check that $X_{ \alpha _f} \subset X_f$ . Let $x \in X_{\alpha _f}$ , then for every $i \in \mathbb {Z}$ and for every $p \in \mathbb {N}$ , we have

$$ \begin{align*} \sum_{r=i}^{i+p-1} x_r \leq \lfloor p \alpha_f \rfloor \leq p \alpha_f \leq p \frac{f(p)}{p} \leq f(p). \end{align*} $$

Therefore, $x \in X_f$ and $X_{\alpha _f} \subset X_f$ .

Corollary 5.2. Let $X_f$ be a bounded density shift. We have that $X_f$ is $h_{\mathrm {top}}(X_{\alpha _f})$ - universal.

Acknowledgments

The authors would like to thank Dominik Kwietniak for rewarding conversations and insights, and the anonymous referee for their valuable comments. The first author was supported by the Excellence Initiative Strategic Program of the Jagiellonian University with grant number U1U/W16/NO/01.03. The second author gratefully acknowledges the support of a Simons Collaboration Grant.

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