1 Introduction
1.1 Uniform Diophantine approximation
The classical metric Diophantine approximation is concerned with the question of how well a real number can be approximated by rationals. A qualitative answer is provided by the fact that the set of rationals is dense in the reals. Dirichlet pioneered the quantitative study by showing that, for any
$x\in \mathbb {R}$
and
$Q>1,$
there exists
$(p,q)\in \mathbb {Z}\times \mathbb {N}$
such that
$$ \begin{align} |qx-p|\le \frac{1}{Q}\quad\text{and}\quad q < Q. \end{align} $$
The result serves as a start point of the metric theory in Diophantine approximation. An easy application yields the following corollary: for any
$x\in \mathbb {R},$
there exists infinitely many
$(p,q)\in \mathbb {Z} \times \mathbb {N}$
such that
$$ \begin{align*} |qx-p|\le \frac{1}{q}. \end{align*} $$
This corollary claims that
$|qx-p|$
is small compared with q, while Dirichlet’s original theorem in equation (1.1) provides a uniform estimate of
$|qx-p|$
in terms of Q. These two kinds of approximations are referred to as uniform approximation and asymptotic, respectively. See [Reference Waldschmidt, Goldfeld, Jorgenson, Jones, Ramakrishnan, Ribet and Tate28] for more of an account on the related subject.
In this article, we are interested in the numbers which are approached in a uniform or asymptotic way by an orbit (in a dynamical system) with a prescribed speed. Let
$(X, T, \mu )$
be a measure-preserving dynamical system, where
$(X,d)$
is a metric space,
$T\colon X\to X$
is a Borel transformation, and
$\mu $
is a T-invariant Borel probability measure on X. As is well known, Birkhoff’s ergodic theorem [Reference Walters29] implies that, in an ergodic dynamical system, for almost all
$y\in X$
, the set
$$ \begin{align*} \Big\{x\in X\colon \liminf_{n\to\infty}d(T^{n}(x),y)=0\Big\} \end{align*} $$
is of full
$\mu $
-measure. The result, which gives a qualitative characterization of the distributions of the T-orbits in X, can be regarded as a counterpart of the density property of rational numbers in the reals. It leads naturally to the quantitative study of the distributions of the T-orbits.
The shrinking target problem in dynamical system
$(X,T)$
aims at a quantitative study of Birkhoff’s ergodic theorem, which investigates the set
$$ \begin{align*} W_y(T,\psi)= \{x\in X\colon d(T^{n}(x),y)<\psi(n) \text{ for infinitely many } n\in \mathbb{N}\}, \end{align*} $$
where
$\psi \colon \mathbb {N}\to \mathbb {R}$
is a positive function such that
$\psi (n)\to 0$
as
$n\to \infty $
and
$y\in X.$
Hill and Velani [Reference Hill and Velani13] studied the Hausdorff dimension of the set
$$ \begin{align*} \{x\in X\colon d(T^{n}(x),y)<e^{-\tau n} \text{ for infinitely many } n\in \mathbb{N}\} \end{align*} $$
in the system
$(X,T)$
with T an expanding rational map of degree greater than or equal to 2 and X the corresponding Julia set, where
$\tau>0.$
See [Reference Tan and Wang26] for more information.
Representations of real numbers are often induced by dynamical systems or algorithms, and thus the related Diophantine approximation problems are in the nature of dynamical system, fractal geometry, and number theory. An active topic of research lies in studying the approximation of real numbers in dynamical systems by the orbits of the points. Recently, many researchers have studied the Hausdorff dimension of the set
$W_y(T,\psi )$
in the corresponding dynamical system under different expansions, and obtained many significant results [Reference Li, Wang, Wu and Xu19, Reference Shen and Wang24, Reference Shi, Tan and Zhou25, Reference Tan and Zhou27]. Marked by the famous mass transfer principle established by Beresnevich and Velani [Reference Beresnevich and Velani2], studies on the asymptotic approximation properties of orbits in dynamical systems are relatively mature. However, there are few results on the uniform approximation properties of orbits.
Let
$(X,T)$
be an exponentially mixing system with respect to the probability measure
$\mu $
, and let
$\psi \colon \mathbb {N}\to \mathbb {R}$
be a positive function satisfying that
$\psi (n)\to 0$
as
$n\to \infty $
. Kleinbock, Konstantous, and Richter [Reference Kleinbock, Konstantoulas and Richter17] studied the Lebesgue measure of the set of real numbers
$x\in X$
with the property that, for every sufficiently large integer
$N,$
there is an integer n with
$1\le n\le N$
such that the distance between
$T^{n}(x)$
and a fixed y is at most
$\psi (N),$
that is,
$$ \begin{align*} {\mathcal{U}(\psi)}&=\{x\in[0,1)\colon\text{ for all }N\gg1,\text{ there exists }n\in[1,N],\\ &\quad\ \ \ \text{ such that }|T^{n}(x)-y|<\psi(N)\}. \end{align*} $$
They gave the sufficient conditions for
$\mathcal {U}(\psi )$
to be of zero or full measure. Although the Khintchine type 0-1 law of the set
$\mathcal {U}(\psi )$
has not been established, the work has aroused the interest of researchers (see [Reference Ganotaki and Persson9, Reference Kirsebom, Kunde and Persson16, Reference Kleinbock and Rao18] for the related studies). Bugeaud and Liao [Reference Bugeaud and Liao5] investigated the size of the set
$$ \begin{align*} \{x\in[0,1)\colon\text{ for all }N\gg1,\text{ there exists }n\in[1,N],\text{ such that }T_\beta^{n}(x) <|I_{N}(0)|^{\hat{\nu}}\} \end{align*} $$
in
$\beta $
-dynamical systems from the perspective of Hausdorff dimension, where
$T_\beta $
is the
$\beta $
-transformation on
$[0,1)$
defined by
$T_\beta (x)=\beta x \text { mod }1, I_N(0)$
denotes the basic interval of order N which contains the point 0, and
$\hat {\nu }$
is a non-negative real number. For more information related to the uniform approximation properties, see [Reference Kim and Liao15, Reference Zheng and Wu33] and the references therein.
In this paper, we shall investigate the uniform approximation properties of the orbits under the Gauss transformation.
The Gauss transformation
$T\colon [0,1) \to [0,1)$
is defined as
$$ \begin{align*} T(0)=0,\quad T(x)= \frac{1}{x}(\mod\! 1)\quad \text{for } x \in (0,1). \end{align*} $$
Additionally, each irrational number
$x\in [0,1)$
can be uniquely expanded into the following form:
$$ \begin{align} x=\frac{1}{a_{1}(x)+\frac{1}{a_{2}(x)+\ddots+\frac{1}{a_{n}+T^{n}(x)}}} =\frac{1}{a_{1}(x)+\frac{1}{a_{2}(x)+\frac{1}{a_{3}(x)+\ddots}}}, \end{align} $$
with
$a_{n}(x)=\lfloor {1}/({T^{n-1}(x)})\rfloor $
, called the nth partial quotient of x (here
$\lfloor \cdot \rfloor $
denotes the greatest integer less than or equal to a real number and
$T^0$
denotes the identity map). For simplicity of notation, we write equation (1.2) as
$$ \begin{align} x=[a_{1}(x),a_{2}(x),\ldots,a_{n}(x)+T^{n}(x)]=[a_{1}(x),a_{2}(x),a_{3}(x),\ldots]. \end{align} $$
As was shown by Philipp [Reference Philipp21], the system
$([0,1),T)$
is exponentially mixing with respect to the Gauss measure
$\mu $
given by
$d\mu =dx/(1+x)\log 2.$
Thus, the above result of [Reference Kleinbock, Konstantoulas and Richter17] applies for the Gauss measure of the set
$\mathcal {U}(\psi )$
in the system of continued fractions. In consequence, we shall focus on the size of
$\mathcal {U}(\psi )$
in dimension.
The dimension of sets
${\mathcal {U}(\psi )}$
depend on the choice of the given point y. In this paper, we will consider a class of quadratic irrational numbers
$y={(\sqrt {i^{2}+4}-i)}/{2}=[i,i,\ldots ]$
with
$i\in \mathbb {N}$
, and calculate the Hausdorff dimension of the set
$$ \begin{align*} {\mathcal{U}(\hat{\nu})}=&\ \{x\in[0,1)\colon \text{ for all } N\gg1, \text{ there exists } n\in[1,N],\\ &\ \ \text{ such that } |T^{n}(x)-y|<|I_{N}(y)|^{\hat{\nu}}\}. \end{align*} $$
For
$\beta \in [0,1]$
, let
$s(\beta ,{g(y)})$
denote the solution of
$$ \begin{align*} P\bigg(T,-s\bigg(\log |T'|+\frac{\beta}{1-\beta}\log {g(y)}\bigg)\bigg)=0, \end{align*} $$
where
$P(T,\phi )$
is the pressure function with potential
$\phi $
in the continued fraction system
$([0,1),T)$
,
$T'$
is the derivative of T, and
$\log g(y)$
is the limit
$\lim _{n}\log q_{n}(y)/n$
which equals
$\log (({i+\sqrt {i^{2}+4}})/{2})$
by Lemma 2.1(3).
Theorem 1.1. Given a non-negative real number
$\hat {\nu },$
we have
$$ \begin{align*} \dim_{H}{\mathcal{U}(\hat{\nu})}=\left\{\! \begin{array}{ll} s\bigg(\dfrac{4\hat{\nu}}{(1+\hat{\nu})^{2}},{\dfrac{i+\sqrt{i^{2}+4}}{2}}\bigg) &\quad \text{if } 0\leq \hat{\nu}\leq 1, \\ 0 &\quad\text{otherwise.} \end{array} \right. \end{align*} $$
Throughout the paper,
$\dim _{H}$
denotes the Hausdorff dimension of a set.
We now turn to the discussion of two approximation exponents which are relevant to asymptotic/uniform Diophantine approximation. For
$x\in [0,1),$
we define the asymptotic approximation exponent of x by
$$ \begin{align*}\nu(x)=\sup \{\nu\ge 0\colon |T^{n}(x)-y|<|I_n(y)|^{\nu}\text{ for infinitely many } n\in \mathbb{N}\} \end{align*} $$
and the uniform approximation exponent by
$$ \begin{align*} \hat{\nu}(x)= \sup &\{\hat{\nu}\ge 0\colon \text{ for all } N\gg1,\\ &\ \ \text{ there exists } n\in[1,N], \text{ such that } |T^{n}(x) - y|<|I_N(y)|^{\hat{\nu}}\}, \end{align*} $$
where
$I_N(y)$
denotes the basic interval of order N which contains
$y.$
The exponents
$\nu (x)$
and
$\hat {\nu }(x)$
are analogous to the exponents introduced in [Reference Amou and Bugeaud1], see also [Reference Bugeaud and Laurent4, Reference Bugeaud and Liao5]. By the definitions of
$\nu (x)$
and
$\hat {\nu }(x)$
, it is readily checked that
$\hat {\nu }(x)\le \nu (x)$
for all
$x\in [0,1).$
Actually, applying Philipp’s result [Reference Philipp21], we deduce that
$\nu (x)=0$
for Lebesgue almost all
$x\in [0,1)$
(see Lemma 3.1). Li et al [Reference Li, Wang, Wu and Xu19] studied the multifractal properties of the asymptotic exponent
$\nu (x)$
and showed that for
$0\le \nu \le +\infty ,$
$$ \begin{align} \dim_{H}\{x\in[0,1)\colon \nu(x)\ge \nu\}=s\bigg(\frac{\nu}{1+\nu},{\frac{i+\sqrt{i^{2}+4}}{2}}\bigg). \end{align} $$
We will denote by
$E(\hat {\nu })$
the level set of the uniform approximation exponent:
$$ \begin{align*}E(\hat{\nu})=\{x\in[0,1)\colon \hat{\nu}(x)=\hat{\nu}\}.\end{align*} $$
Theorem 1.2. Given a non-negative real number
$\hat {\nu },$
we have
$$ \begin{align*}\dim_{H}E(\hat{\nu})=\dim_{H}\{x\in[0,1)\colon \hat{\nu}(x)\ge\hat{\nu}\}=\dim_{H}{\mathcal{U}(\hat{\nu})}.\end{align*} $$
Actually, Theorems 1.1 and 1.2 follow from the following more general result which gives the Hausdorff dimension of the set
$$ \begin{align*} E(\hat{\nu},\nu)=\{x\in[0,1)\colon \hat{\nu}(x)=\hat{\nu},~\nu(x)=\nu\}. \end{align*} $$
Theorem 1.3. Given two non-negative real numbers
$\hat {\nu }$
and
$\nu $
with
$\hat \nu \le \nu $
, we have
$$ \begin{align*} \dim_{H}E(\hat{\nu},\nu) =\left\{\begin{array}{@{}ll} 1 &\quad\!\!\text{if }\ \nu=0,\\ s\bigg(\dfrac{\nu^{2}}{(1+\nu)(\nu-\hat{\nu})},{\dfrac{i+\sqrt{i^{2}+4}}{2}}\bigg) &\quad\!\!\text{if }\ 0\le\hat{\nu}\le\dfrac{\nu}{1+\nu}<\nu\leq\infty, \\ 0 &\quad\!\!\text{otherwise.} \end{array} \right. \end{align*} $$
Here, we take
${\nu ^{2}}/({(1+\nu )(\nu -\hat {\nu })}) = 1$
when
$\nu =\infty $
.
Let us make the following remarks regarding Theorems 1.1–1.3.
-
• Following the same line as the proofs of Theorems 1.1–1.3, these results remain valid for any quadratic irrational number y, see Remark 4.7 for more information.
-
• The fractal sets
${\mathcal {U}(\hat {\nu })}, E(\hat {\nu })$
, and
$E(\hat {\nu },\nu )$
are not the so-called limsup sets, and thus we cannot obtain a natural covering to estimate the upper bound of the Hausdorff dimensions of the sets
${\mathcal {U}(\hat {\nu })}$
and
$E(\hat {\nu },\nu )$
. To overcome this difficulty, we need a better understanding on the fractal structure of these sets; the previous work of Bugeaud and Liao [Reference Bugeaud and Liao5] helps.
Combining equation (1.4) and Theorem 1.3, we obtain the dimension of the level set related to the asymptotic exponent
$\nu (x)$
.
Corollary 1.4. Given a non-negative real number
$\nu ,$
we have
$$ \begin{align*} \dim_{H}\{x\in[0,1)\colon \nu(x)=\nu\}= s\bigg(\frac{\nu}{1+\nu},{\frac{i+\sqrt{i^{2}+4}}{2}}\bigg). \end{align*} $$
1.2 Run-length function
Applying the main ideas of the proofs of Theorems 1.1 and 1.3, we characterize the multifractal properties of run-length function in continued fractions.
The run-length function was initially introduced in a mathematical experiment of coin tossing, which counts the consecutive occurrences of ‘heads’ in n times trials. This function has been extensively studied for a long time. For
$x\in [0,1],$
let
$r_n(x)$
be the dyadic run-length function of
$x,$
namely, the longest run of 0s in the first n digits of the dyadic expansion of
$x.$
Erdös and Rényi [Reference Erdös and Rényi7] did a pioneer work on the asymptotic behavior of
$r_n(x)\colon $
for Lebesgue almost all
$x\in [0,1],$
$$ \begin{align*} \lim_{n\to\infty}\frac{r_n(x)}{\log_2 n}=1. \end{align*} $$
Likewise, we define the run-length function in the continued fraction expansion: for
$n\ge 1$
, the nth maximal run-length function of x is defined as
$$ \begin{align*} R_{n}(x)=\max\{l\geq1\colon a_{i+1}(x)=\cdots=a_{i+l}(x) \text{ for some } 0 \leq i\leq n-l\}. \end{align*} $$
Wang and Wu [Reference Wang and Wu30] considered the metric properties of
$R_{n}(x)$
and proved that
$$ \begin{align*} \lim_{n\to\infty}\frac{R_{n}(x)}{\log_{({\sqrt{5}+1})/{2}} n} = \frac{1}{2} \end{align*} $$
for almost all
$x\in [0,1).$
They also studied the following exceptional sets
$$ \begin{align*} F (\{\varphi(n)\}_{n=1}^{\infty}) &= \bigg\{x\in[0,1)\colon \lim_{n\to\infty}\frac{R_{n}(x)}{\varphi(n)}=1\bigg\},\\ G (\{\varphi(n)\}_{n=1}^{\infty}) &= \bigg\{x\in[0,1)\colon \limsup\limits_{n\to\infty}\frac{R_{n}(x)}{\varphi(n)}=1\bigg\}, \end{align*} $$
where
$\varphi \colon \mathbb {N} \to \mathbb {R}^{+}$
is a non-decreasing function. They showed that:
-
(1) if
$\lim _{n\to \infty } ({\varphi (n+\varphi (n))}/{\varphi (n)}) = 1$
, then
$\dim _{H}F (\{\varphi (n)\}_{n=1}^{\infty })=1;$
-
(2) if
$\liminf _{n\to \infty } ({\varphi (n)}/{n}) = \beta \in [0,1],$
then
$\dim _{H}G (\{\varphi (n)\}_{n=1}^{\infty }) = s (\beta ,({\sqrt {5}+1})/{2})$
.
In the study of Case (2), Wang and Wu studied essentially the Hausdorff dimension of the following set:
$$ \begin{align} G(\beta)=\bigg\{x\in[0,1)\colon \limsup_{n \to\infty}\frac{R_{n}(x)}{n}=\beta\bigg\}. \end{align} $$
Replacing the limsup of the quantity
$R_n(x)/n$
in equation (1.5) with liminf, we study the set
$$ \begin{align*} F(\alpha)=\bigg\{x\in[0,1)\colon \liminf_{n\to\infty}\frac{R_{n}(x)}{n}=\alpha\bigg\}, \end{align*} $$
and determine the Hausdorff dimension of the intersections of
$F(\alpha )\cap G(\beta ).$
As a corollary, we obtain the Hausdorff dimension of
$F(\alpha ).$
Theorem 1.5. For
$\alpha , \beta \in [0,1]$
with
$\alpha \leq \beta $
, we have
$$ \begin{align*} \dim_{H} (F(\alpha)\cap G(\beta))=\left\{\!\begin{array}{ll} 1 &\quad\text{if }\, \beta=0,\\ s\bigg(\dfrac{\beta^{2}(1-\alpha)}{\beta-\alpha},\dfrac{\sqrt{5}+1}{2}\bigg) &\quad\text{if }\, 0\leq \alpha\leq \dfrac{\beta}{1+\beta}<\beta\leq1, \\ 0 &\quad\text{otherwise.}\end{array} \right. \end{align*} $$
Theorem 1.6. For
$\alpha \in [0,1],$
we have
$$ \begin{align*} \dim_{H}F(\alpha)=\left\{\!\begin{array}{ll} s\bigg(4\alpha(1-\alpha),\dfrac{\sqrt{5}+1}{2}\bigg) &\quad \text{if }\, 0\leq \alpha\leq \dfrac{1}{2}, \\ 0 &\quad\text{otherwise.} \end{array} \right. \end{align*} $$
Throughout the paper, we use the following notation:
-
•
$y= ({\sqrt {i^{2}+4}-i})/{2} = [i,i,\ldots ]$
with
$i\in \mathbb {N};$
-
•
$\tau (i)= ({i+\sqrt {i^{2}+4}})/{2}$
,
$\zeta (i) = ({i-\sqrt {i^{2}+4}})/{2};$
-
•
$\xi = {\nu ^{2}}/{(1+\nu )(\nu -\hat {\nu })}$
with
$0\le \hat {\nu }<\nu .$
2 Preliminaries
2.1 Properties of continued fractions
This section is devoted to recalling some elementary properties in continued fractions. For more information on the continued fraction expansion, the readers are referred to [Reference Hardy and Wright12, Reference Khintchine14, Reference Schmidt22]. We also introduce some basic techniques for estimating the Hausdorff dimension of a fractal set (see [Reference Falconer8, Reference Schweiger23]).
For any irrational number
$x\in [0,1)$
with continued fraction expansion in equation (1.3), we write
${p_{n}(x)}/{q_{n}(x)} = [a_{1}(x),\ldots ,a_{n}(x)]$
and call it the nth convergent of
$x.$
With the conventions
$p_{-1}(x)=1, q_{-1}(x)=0, p_{0}(x)=0$
, and
$q_{0}(x)=1,$
we know that
$p_{n}(x)$
and
$q_{n}(x)$
satisfy the recursive relations [Reference Khintchine14]:
$$ \begin{align}\begin{aligned} p_{n+1}(x)&= a_{n+1}(x)p_{n}(x)+p_{n-1}(x),\\q_{n+1}(x) &= a_{n+1}(x)q_{n}(x)+q_{n-1}(x),\quad n\geq 0. \end{aligned}\end{align} $$
Clearly,
$q_{n}(x)$
is determined by
$a_{1}(x),\ldots ,a_{n}(x),$
so we also write
$q_{n}(a_{1}(x),\ldots ,a_{n}(x))$
instead of
$q_n(x)$
. We write
$a_{n}$
and
$q_n$
in place of
$a_{n}(x)$
and
$q_n(x)$
for simplicity when no confusion can arise.
Lemma 2.1. [Reference Khintchine14]
For
$n\geq 1$
and
$(a_{1},\ldots ,a_{n})\in \mathbb {N}^{n}$
, we have:
-
(1)
$q_{n}\geq 2^{({n-1})/{2}}$
and
$\prod _{k=1}^{n}a_{k}\leq q_{n}\leq \prod _{k=1}^{n}(a_{k}+1)$
; -
(2) for any
$k\ge 1,$
$$ \begin{align*} 1\leq \frac{q_{n+k}(a_{1},\ldots,a_{n},a_{n+1},\ldots,a_{n+k})} {q_{n}(a_{1},\ldots,a_{n})q_{k}(a_{n+1},\ldots,a_{n+k})}\leq 2; \end{align*} $$
-
(3) if
$a_1=a_2=\cdots =a_{n}=i$
, then
$$ \begin{align*} \frac{(\tau(i))^{n}}{2} \leq q_{n}(i,\ldots,i) =\frac{(\tau(i))^{n+1}- (\zeta(i))^{n+1}}{\tau(i)-\zeta(i)}\leq 2(\tau(i))^{n}. \end{align*} $$
Proof. For the convenience of readers, we give the proof.
(1) By the recursive relations in equation (2.1), we readily check that
$$ \begin{align*} \prod\limits_{k=1}^{n}a_{k}\leq q_{n}\leq \prod\limits_{k=1}^{n}(a_{k}+1). \end{align*} $$
Since
$a_n\ge 1$
for
$n\ge 1,$
we have
$$ \begin{align*} 1=q_0\le q_1<q_2<\cdots q_{n-1}<q_n. \end{align*} $$
By induction,
$q_n\ge 2^{({n-1})/{2}}$
for all
$n\ge 1$
; similarly
$p_n\ge 2^{({n-1})/{2}}$
.
(2) Induction on k: assuming that
$$ \begin{align*} 1\leq \frac{q_{n+k}(a_{1},\ldots,a_{n},a_{n+1},\ldots,a_{n+k})}{q_{n}(a_{1},\ldots,a_{n})q_{k}(a_{n+1},\ldots,a_{n+k})} \leq 2 \end{align*} $$
holds for all
$k\in \{1,\ldots ,m\}$
, we prove that the above inequality holds for
$k=m+1.$
Indeed, this is the case because
$$ \begin{align*} &q_{n+m+1}(a_{1},\ldots,a_{n},a_{n+1},\ldots,a_{n+m+1})\\ &\quad =a_{n + m+1}q_{n+m}(a_{1},\ldots,a_{n},a_{n+1},\ldots,a_{n+m})\\ & \qquad+ q_{n + m-1}(a_{1},\ldots,a_{n},a_{n+1},\ldots,a_{n+m-1})\\ &\quad \ge a_{n+m+1}q_{n}(a_{1},\ldots,a_{n})q_{m}(a_{n+1},\ldots,a_{n+m})\\ &\qquad+q_{n}(a_{1},\ldots,a_{n})q_{m-1}(a_{n+1},\ldots,a_{n+m-1})\\ & \quad =q_{n}(a_{1},\ldots,a_{n})q_{m+1}(a_{n+1},\ldots,a_{n+m+1}), \end{align*} $$
and
$$ \begin{align*} &q_{n+m+1}(a_{1},\ldots,a_{n},a_{n+1},\ldots,a_{n+m+1})\\&\quad = a_{n+m+1}q_{n+m}(a_{1},\ldots,a_{n},a_{n+1},\ldots,a_{n+m})\\&\qquad +q_{n+m-1}(a_{1},\ldots,a_{n},a_{n+1},\ldots,a_{n+m-1})\\&\quad \le 2a_{n+m+1}q_{n}(a_{1},\ldots,a_{n})q_{m}(a_{n+1},\ldots,a_{n+m})\\&\qquad +2q_{n}(a_{1},\ldots,a_{n})q_{m-1}(a_{n+1},\ldots,a_{n+m-1})\\&\quad =2q_{n}(a_{1},\ldots,a_{n})q_{m+1}(a_{n+1},\ldots,a_{n+m+1}). \end{align*} $$
(3) By the recursive relations in equation (2.1), we deduce that
$$ \begin{align*} \left(\!\! \begin{array}{cc} p_{n+1} & p_{n} \\ q_{n+1} & q_{n} \\ \end{array}\!\!\right)&=\left(\!\! \begin{array}{cc} p_{n} & p_{n-1} \\ q_{n} & q_{n-1} \\ \end{array}\!\!\right)\left(\!\!\begin{array}{cc} a_{n+1} & 1 \\ 1 & 0 \\ \end{array}\!\!\right)\\ & =\left(\!\!\begin{array}{cc} p_0 & p_{-1} \\ q_0 & q_{-1} \\ \end{array}\!\!\right)\left(\!\!\begin{array}{cc} a_{1} & 1 \\ 1 & 0 \\ \end{array}\!\!\right)\cdots\left(\!\!\begin{array}{cc} a_{n+1} & 1 \\ 1 & 0 \\ \end{array}\!\!\right)\\ &= \left(\!\!\begin{array}{cc} 0 & 1 \\ 1 & 0 \\ \end{array}\!\!\right)\left(\!\! \begin{array}{cc} a_{1} & 1 \\ 1 & 0 \\ \end{array}\!\!\right)\cdots\left(\!\!\begin{array}{cc} a_{n+1} & 1 \\ 1 & 0 \\ \end{array}\!\!\right). \end{align*} $$
Taking
$a_1=\cdots =a_n=a_{n+1}=i$
yields that
$$ \begin{align*}\left(\!\! \begin{array}{cc} p_{n+1} & p_{n} \\ q_{n+1} & q_{n} \\ \end{array}\!\!\right)=\left(\!\!\begin{array}{cc} 0 & 1 \\ 1 & 0 \\ \end{array}\!\!\right)\left(\!\! \begin{array}{cc} i & 1 \\ 1 & 0 \\ \end{array}\!\!\right)\cdots\left(\!\!\begin{array}{cc} i & 1 \\ 1 & 0 \\ \end{array}\!\!\right). \end{align*} $$
The symmetric matrix
$A=(\begin {smallmatrix} i & 1 \\ 1 & 0 \\ \end {smallmatrix})$
is diagonalizable:
$$ \begin{align*}P^{-1}AP=\left(\!\! \begin{array}{cc} \tau(i) & 0 \\ 0 & \zeta(i) \\ \end{array}\!\!\right) \end{align*} $$
with
$P=\big (\begin {smallmatrix} \tau (i) & \zeta (i) \\ 1 & 1 \\ \end {smallmatrix}\big )$
.
A direct calculation yields that
$$ \begin{align*} q_n(i,\ldots,i) =\frac{(\tau(i))^{n+1}- (\zeta(i))^{n+1}}{\tau(i)-\zeta(i)}. \end{align*} $$
Also,
$$ \begin{align*} \frac{(\tau(i))^{n+1}- (\zeta(i))^{n+1}}{\tau(i)-\zeta(i)}\le\frac{2(\tau(i))^{n+1}}{\tau(i)}=2(\tau(i))^{n}, \end{align*} $$
and, if n is even,
$$ \begin{align*} \frac{(\tau(i))^{n+1} - (\zeta(i))^{n+1}}{\tau(i)-\zeta(i)}\ge\frac{(\tau(i))^{n+1}}{2\tau(i)}=\frac{(\tau(i))^{n}}{2}; \end{align*} $$
if n is odd (since
$\zeta (i)\cdot \tau (i)=-1$
),
$$ \begin{align*} \frac{(\tau(i))^{n+1} - (\zeta(i))^{n+1}}{\tau(i)-\zeta(i)} =\frac{(\tau(i))^{2(n+1)}-1}{(\tau(i))^{n+2}+(\tau(i))^{n}} \ge\frac{(\tau(i))^{n}}{2}. \end{align*} $$
This completes the proof.
For
$n\geq 1$
and
$(a_{1},\ldots ,a_{n})\in \mathbb {N}^{n}$
, we write
$$ \begin{align*} I_{n}(a_{1},\ldots,a_{n})=\{x\in[0,1)\colon a_{k}(x)=a_{k}, 1\leq k\leq n\}, \end{align*} $$
and call it a basic interval of order n. The basic interval of order n which contains x will be denoted by
$I_{n}(x)$
, that is,
$I_{n}(x)=I_{n}(a_{1}(x),\ldots ,a_{n}(x))$
.
Lemma 2.2. [Reference Khintchine14]
For
$n\geq 1$
and
$(a_{1},\ldots ,a_{n})\in \mathbb {N}^{n},$
we have
$$ \begin{align} \frac{1}{2q_{n}^{2}}\leq|I_{n}(a_{1},\ldots,a_{n})|=\frac{1}{q_{n}(q_{n}+q_{n+1})}\leq\frac{1}{q_{n}^{2}}. \end{align} $$
Here and hereafter,
$|\cdot |$
denotes the length of an interval.
The next lemma describes the distribution of basic intervals
$I_{n+1}$
of order
$n+1$
inside an nth basic interval
$I_{n}.$
Lemma 2.3. [Reference Khintchine14]
Let
$I_{n}(a_{1},\ldots ,a_{n})$
be a basic interval of order
$n,$
which is partitioned into sub-intervals
$I_{n+1}(a_{1},\ldots ,a_{n},a_{n+1})$
with
$a_{n+1}\in \mathbb {N}.$
When n is odd, these sub-intervals are positioned from left to right, as
$a_{n+1}$
increases; when n is even, they are positioned from right to left.
The following lemma displays the relationship between the ball
$B(x,|I_{n}(x)|)$
and the basic interval
$I_{n}(x)$
.
Lemma 2.4. [Reference Bosma, Dajani, Kraaikamp, Denteneer, den Hollander and Verbiskiy3]
Let
$x=[a_{1},a_{2},\ldots ].$
We have:
-
(1) if
$a_{n}\neq 1,$
then
$B(x,|I_{n}(x)|)\subset \bigcup _{j=-1}^{3}I_{n}(a_{1},\ldots ,a_{n}+j);$
-
(2) if
$a_{n}=1$
and
$a_{n-1}\neq 1,$
then
$B(x,|I_{n}(x)|)\subset \bigcup _{j=-1}^{3}I_{n-1}(a_{1},\ldots ,a_{n-1}+j);$
-
(3) if
$a_{n}=1$
and
$a_{n-1}=1,$
then
$B(x,|I_{n}(x)|)\subset I_{n-2}(a_{1},\ldots ,a_{n-2}).$
2.2 Hausdorff dimension
The following two properties, namely, Hölder property and the mass distribution principle, are often used to estimate the Hausdorff dimension of a fractal set.
Lemma 2.5. [Reference Falconer8]
If
$f\colon X \to Y$
is an
$\alpha $
-Hölder mapping between metric spaces, that is, there exists
$c>0$
such that for all
$x_{1},x_{2}\in X$
,
$$ \begin{align*}d(f(x_{1}),f(x_{2}))\leq cd(x_{1},x_{2})^{\alpha},\end{align*} $$
then
$\dim _{H}f(X)\leq ({1}/{\alpha }) \dim _{H}X.$
Lemma 2.6. [Reference Falconer8]
Let
$E\subseteq [0,1]$
be a Borel set and
$\mu $
be a measure with
$\mu (E)> 0.$
If for every
$x \in E$
,
$$ \begin{align*}\liminf_{r \to 0}\frac{\log \mu(B(x,r))}{\log r} \geq s,\end{align*} $$
then
$ \dim _{H}E\geq s.$
We conclude this subsection by quoting a dimensional result related to continued fractions, which will be used in the proof of Theorem 1.3.
Let
$\mathbf {K}=\{k_{n}\}_{n= 1}^{\infty }$
be a subsequence of
$\mathbb {N}$
which is not cofinite. Let
$x=[a_{1},a_{2},\ldots ]$
be an irrational number in
$[0,1)$
. Eliminating all the terms
$a_{k_n}$
from the sequence
$a_1,a_2,\ldots $
, we obtain an infinite subsequence
$c_1,c_2,\ldots $
, and put
$\phi _{\mathbf {K}}(x)=y$
with
$y=[c_1,c_2,\ldots ]$
. In this way, we define a mapping
$\phi _{\mathbf {K}}\colon [0,1)\cap \mathbb {Q}^{c}\to [0,1)\cap \mathbb {Q}^{c}$
.
Let
$\{M_{n}\}_{n\geq 1}$
be a sequence with
$M_{n}\in \mathbb {N}$
,
$n\geq 1$
. Set
$$ \begin{align*} S(\{M_{n}\})= \{x\in [0,1)\cap \mathbb{Q}^{c}\colon 1\leq a_{n}(x)\leq M_{n} \text{ for all } n\geq 1\}. \end{align*} $$
Lemma 2.7. [Reference Chang and Chen6]
Suppose that
$\{M_{n}\}_{n=1}^{\infty }$
is a bounded sequence. If the sequence
$\mathbf {K}=\{k_{n}\}_{n=1}^{\infty }$
is of density zero in
$\mathbb {N}$
, then
$$ \begin{align*}\dim_{H}S(\{M_{n}\})=\dim_{H}\phi_{\mathbf{K}}S(\{M_{n}\}).\end{align*} $$
2.3 Pressure function and pre-dimensional number
We now introduce the notions of the pressure function and pre-dimensional number in the continued fraction dynamical system. For more details, we refer the reader to [Reference Hanus, Mauldin and Urbański11].
For
$\mathcal {A}$
a finite or infinite subset of
$\mathbb {N},$
we set
$$ \begin{align*} X_{\mathcal{A}}= \{x\in[0,1)\colon a_{n}(x)\in \mathcal{A} \text{ for all } n\geq 1\}. \end{align*} $$
The pressure function restricted to the subsystem
$(X_{\mathcal {A}},T)$
with potential
$\phi \colon [0,1)\to \mathbb {R} $
is defined as
$$ \begin{align} P_{\mathcal{A}}(T,\phi)=\lim_{n\to\infty} \frac{\log\sum\limits_{(a_{1},\ldots,a_{n})\in \mathcal{A}^{n}}\sup\limits_{x\in X_{\mathcal{A}}}\exp{S_n \phi([a_{1},\ldots,a_{n}+x])}}{n}, \end{align} $$
where
$S_{n}\phi (x)=\phi (x)+\cdots +\phi (T^{n-1}(x))$
denotes the ergodic sum of
$\phi $
. When
$\mathcal {A}=\mathbb {N}$
, we write
$P(T,\phi )$
for
$P_{\mathbb {N}}(T,\phi )$
.
The nth variation
$\textrm {Var}_{n}(\phi )$
of
$\phi $
is defined as
$$ \begin{align*} \textrm{Var}_{n}(\phi)=\sup \{|\phi(x)-\phi(y)|\colon I_{n}(x)=I_{n}(y)\}. \end{align*} $$
The following lemma shows the existence of the limit in equation (2.3).
Lemma 2.8. [Reference Walters29]
The limit defining
$P_{\mathcal {A}}(T,\phi )$
in equation (2.3) exists. Moreover, if
$\phi \colon [0,1)\rightarrow \mathbb {R}$
satisfies
$\textrm {Var}_{1}(\phi )<\infty $
and
$\textrm {Var}_{n}(\phi )\rightarrow 0$
as
$n\rightarrow \infty $
, the value of
$P_{\mathcal {A}}(T,\phi )$
remains the same even without taking the supremum over
$x\in X_{\mathcal {A}}$
in equation (2.3).
For
$0<\alpha <1$
and
$i\in \mathbb {N}$
, we define
$$ \begin{align*} \widehat{s}_{n}(\mathcal{A},\alpha,{\tau(i)}) = \inf \bigg\{\rho \geq 0\colon \sum\limits_{a_{1},\ldots,a_{n}\in \mathcal{A}} \bigg(\frac{1}{(\tau(i))^{{n\alpha}/({1-\alpha})}q_{n}(a_{1},\ldots,a_{n})}\bigg)^{2\rho}\leq 1\bigg\}. \end{align*} $$
Following [Reference Wang and Wu31], we call
$\widehat {s}_{n}(\mathcal {A},\alpha ,{\tau (i)})$
the nth pre-dimensional number with respect to
$\mathcal {A}$
and
$\alpha $
. The properties of pre-dimensional numbers are presented in the following lemmas; the original ideas for the proofs date back to Good [Reference Good10] (see also [Reference Mauldin and Urbański20]).
Lemma 2.9. [Reference Wang and Wu31]
Let
$\mathcal {A}$
be a finite or infinite subset of
$\mathbb {N}.$
For
$0<\alpha <1$
and
$i\in \mathbb {N}$
, the limit
$\lim _{n\to \infty }\widehat {s}_{n}(\mathcal {A},\alpha ,{\tau (i)})$
exists, denoted by
$s(\mathcal {A},\alpha ,{\tau (i)})$
.
By equation (2.2) and the definition of
$\widehat {s}_{n}(\mathcal {A},\alpha ,{\tau (i)}),$
we know
$0\le \widehat {s}_{n}(\mathcal {A},\alpha ,{\tau (i)})\le 1.$
Furthermore, Lemma 2.9 implies that
$0\le s(\mathcal {A},\alpha ,{\tau (i)})\le 1.$
Lemma 2.10. [Reference Wang and Wu31]
For any
$B{\kern-1pt}\in{\kern-1pt} \mathbb {N},$
put
$\mathcal {A}_{B}{\kern-1pt}={\kern-1pt}\{1,\ldots ,B\}.$
The limit
$\lim _{B \to \infty }s(\mathcal {A}_{B}, \alpha ,{\tau (i)})$
exists, and is equal to
$s(\mathbb {N},\alpha ,{\tau (i)})$
.
Similarly to pre-dimensional numbers
$\{\widehat {s}_{n}(\mathcal {A},\alpha ,{\tau (i)}{)}\},$
we define
$$ \begin{align*} s_{n}(\mathcal{A},\alpha,{\tau(i)})= \inf \bigg\{\rho \geq 0\!\colon \sum\limits_{a_{1},\ldots,a_{n-\lfloor n\alpha\rfloor}\in \mathcal{A}}\! \bigg(\frac{1}{q_{n}(a_{1},\ldots,a_{n-\lfloor na\rfloor},i,\ldots,i)}\bigg)^{2\rho}\leq 1\bigg\}. \end{align*} $$
Remark 2.11. We remark that
$$ \begin{align*}\sum\limits_{a_{1},\ldots,a_{n}\in \mathcal{A}} \bigg(\frac{1}{(\tau(i))^{{n\alpha}/({1-\alpha}}) q_{n}(a_{1},\ldots,a_{n})}\bigg)^{2\widehat{s}_{n}(\mathcal{A},\alpha,{\tau(i)})}\leq 1\end{align*} $$
and
$$ \begin{align*}\sum_{a_{1},\ldots,a_{n-\lfloor n\alpha\rfloor}\in \mathcal{A}} \bigg(\frac{1}{q_{n}(a_{1},\ldots,a_{n-\lfloor n\alpha\rfloor},i,\ldots,i)}\bigg)^{2s_{n}(\mathcal{A},\alpha,{\tau(i)})}\leq1,\end{align*} $$
with equalities holding when
$\mathcal {A}$
is finite.
By Lemmas 2.9 and 2.10, we have the following result.
Lemma 2.12. Let
$\mathcal {A}$
be a finite or infinite subset of
$\mathbb {N}.$
For
$0<\alpha <1$
and
$i\in \mathbb {N},$
we have
$$ \begin{align*}\lim_{n\to\infty}s_{n}(\mathcal{A},\alpha,{\tau(i)})=s(\mathcal{A},\alpha,{\tau(i)}).\end{align*} $$
In particular, if
$\mathcal {A}=\mathbb {N},$
then
$$ \begin{align*}\lim_{n\to\infty}s_{n}(\mathbb{N},\alpha,{\tau(i)})=s(\mathbb{N},\alpha,{\tau(i)}).\end{align*} $$
Proof. For
$\varepsilon>0$
and n large enough, we have
$$ \begin{align} 2^{(({n-\lfloor n\alpha\rfloor})/{2}) \varepsilon}>64, \end{align} $$
$$ \begin{align} \frac{3}{(1-\alpha)(n\alpha-1)}+\frac{\log 4}{n\alpha-1}<\varepsilon, \end{align} $$
$$ \begin{align} |\widehat{s}_{n}(\mathcal{A},\alpha,{\tau(i)})-s(\mathcal{A},\alpha,{\tau(i)})|<\frac{\varepsilon}{2}. \end{align} $$
On the one hand, by Remark 2.11, we deduce that
$$ \begin{align*} 1 \ge&\! \sum_{a_1,\ldots,a_{n-\lfloor n\alpha\rfloor}\in \mathcal{A}}\!\!\bigg(\frac{1}{q_{n}(a_1,\ldots,a_{n-\lfloor n\alpha\rfloor},i,\ldots,i)}\bigg)^{2s_{n}(\mathcal{A},\alpha,{\tau(i)})} \\ \ge &\! \sum_{a_1,\ldots,a_{n-\lfloor n\alpha\rfloor}\in \mathcal{A}}\!\! \bigg(\frac{1}{2q_{n-\lfloor n\alpha\rfloor}(a_1,\ldots,a_{n-\lfloor n\alpha\rfloor})q_{\lfloor n\alpha\rfloor}(i,\ldots,i)}\bigg)^{2s_{n}(\mathcal{A},\alpha,{\tau(i)})}\\ \ge &\! \sum_{a_1,\ldots,a_{n-\lfloor n\alpha\rfloor}\in \mathcal{A}}\!\!\bigg(\frac{1}{4q_{n-\lfloor n\alpha\rfloor}(a_1,\ldots,a_{n-\lfloor n\alpha\rfloor}) (\tau(i))^{({\alpha}/({1-\alpha})) (n-\lfloor n\alpha\rfloor)}}\bigg)^{\!2s_{n}(\mathcal{A},\alpha,{\tau(i)})}\\ \ge &\! \sum_{a_1,\ldots,a_{n-\lfloor n\alpha\rfloor}\in \mathcal{A}}\!\!\bigg(\frac{1}{q_{n-\lfloor n\alpha\rfloor}(a_1,\ldots,a_{n-\lfloor n\alpha\rfloor}) (\tau(i))^{({\alpha}/({1-\alpha}))(n-\lfloor n\alpha\rfloor)}}\bigg)^{\!2s_{n}(\mathcal{A},\alpha,{\tau(i)})+\varepsilon}, \end{align*} $$
where the second inequality holds by Lemma 2.1(2); the third inequality is right by Lemma 2.1(3) and the fact that
$({\alpha }/({1-\alpha }))(n-\lfloor n\alpha \rfloor )\ge \lfloor n\alpha \rfloor $
for
$n\in \mathbb {N};$
the last inequality is true by Lemma 2.1(1) and equation (2.4). This means that
$$ \begin{align*}s_{n}(\mathcal{A},\alpha,{\tau(i)})+\frac{\varepsilon}{2}\ge \widehat{s}_{n-\lfloor n\alpha\rfloor}(\mathcal{A},\alpha,{\tau(i)}).\end{align*} $$
On the other hand, we have
$$ \begin{align*} 1 \ge &\! \sum_{a_1,\ldots,a_{n-\lfloor n\alpha\rfloor}\in \mathcal{A}}\!\!\bigg(\frac{1}{q_{n-\lfloor n\alpha\rfloor}(a_1,\ldots,a_{n-\lfloor n\alpha\rfloor}) (\tau(i))^{({\alpha}/({1-\alpha})) (n-\lfloor n\alpha\rfloor)}}\bigg)^{\!2\widehat{s}_{n-\lfloor n\alpha\rfloor}(\mathcal{A},\alpha,{\tau(i)})}\\ \ge &\! \sum_{a_1,\ldots,a_{n-\lfloor n\alpha\rfloor}\in \mathcal{A}}\!\!\bigg(\frac{1}{q_{n-\lfloor n\alpha\rfloor}(a_1,\ldots,a_{n-\lfloor n\alpha\rfloor}) (\tau(i))^{\lfloor n\alpha\rfloor+{1}/{(1-\alpha)}}}\bigg)^{\!2\widehat{s}_{n-\lfloor n\alpha\rfloor}(\mathcal{A},\alpha,{\tau(i)})}\\ \ge &\! \sum_{a_1,\ldots,a_{n-\lfloor n\alpha\rfloor}\in \mathcal{A}}\!\!\bigg(\frac{1}{q_{n}(a_1,\ldots,a_{n-\lfloor n\alpha\rfloor},i,\ldots,i)}\bigg)^{\!2\widehat{s}_{n-\lfloor n\alpha\rfloor}(\mathcal{A},\alpha,{\tau(i)})+\varepsilon}, \end{align*} $$
where the second inequality is obtained by
$({\alpha }/({1-\alpha }))(n-\lfloor n\alpha \rfloor )\le \lfloor n\alpha \rfloor + {1}/({1-\alpha })$
for
$n\in \mathbb {N}$
; the last inequality holds by Lemma 2.1(3) and equation (2.5). This implies that
$$ \begin{align*}s_{n}(\mathcal{A},\alpha,{\tau(i)})\le \widehat{s}_{n-\lfloor n\alpha\rfloor}(\mathcal{A},\alpha,{\tau(i)})+\frac{\varepsilon}{2}.\end{align*} $$
Thus, by equation (2.6), we obtain that
$$ \begin{align*}|s_{n}(\mathcal{A},\alpha,{\tau(i)})-s(\mathcal{A},\alpha,{\tau(i)})|<\varepsilon\end{align*} $$
for n large enough. This completes the proof.
For simplicity, write
$s_{n}(\alpha ,{\tau (i)})$
for
$s_{n}(\mathbb {N},\alpha ,{\tau (i)}), s(\alpha ,{\tau (i)})$
for
$s(\mathbb {N},\alpha ,{\tau (i)}).$
Lemma 2.13. [Reference Wang and Wu31]
For
$ 0<\alpha <1$
and
$i\in \mathbb {N}$
, we have:
-
(1)
$s(\alpha ,{\tau (i)})>\tfrac 12$
; -
(2)
$s(\alpha ,{\tau (i)})$
is non-increasing and continuous with respect to
$\alpha $
; -
(3)
$\lim _{\alpha \to 0}{s(\alpha ,{\tau (i)})}=1$
and
$\lim _{\alpha \to 1}{s(\alpha ,{\tau (i)})}=\tfrac 12.$
From a point of view of a dynamical system,
$s(\alpha ,{\tau (i)})$
can be regarded as the solution to the pressure function [Reference Wang, Wu and Xu32]
$$ \begin{align*}P\bigg(T,-s\bigg(\log |T'|+\frac{\alpha}{1-\alpha}\log{\tau(i)}\bigg)\bigg)=0.\end{align*} $$
Furthermore, by Lemma 2.13, we may extend
$s(\alpha ,{\tau (i)})$
to
$[0,1]$
as follows:
$$ \begin{align} s(\alpha,{\tau(i)})=\left\{\! \begin{array}{ll} 1, &\quad \alpha=0, \\ s(\alpha,{\tau(i)}), &\quad 0<\alpha <1, \\ \frac{1}{2}, &\quad \alpha=1. \end{array} \right. \end{align} $$
3 Proof of Theorem 1.3: upper bound
Recall that
$y=[i,i,\ldots ]$
with
$i\in \mathbb {N}.$
In this section, we devote to estimating the upper bound of
$E(\hat {\nu },\nu )$
.
We first consider the case
$\nu =0$
.
Lemma 3.1.
$\nu (x)=0$
for Lebesgue almost all
$x\in [0,1).$
Proof. Since
$\sum _{n=1}^{\infty }|I_n(y)|^{{1}/{m}}<\infty $
, we obtain by [Reference Philipp21, Theorem 2B] that the set
$$ \begin{align*} \{x\in[0,1)\colon |T^{n}(x)-y|<|I_{n}(y)|^{{1}/{m}} \text{ for infinitely many }n\in \mathbb{N}\} \end{align*} $$
is of measure zero. Now,
$$ \begin{align*} &\{x\in[0,1)\colon \nu(x)>0\}\subseteq\bigcup_{m=1}^{\infty}\bigg\{x\in[0,1)\colon \nu(x)>\frac{1}{m}\bigg\}\\ &\quad \subseteq\bigcup_{m=1}^{\infty}\{x\in[0,1)\colon |T^{n}(x)-y|<|I_{n}(y)|^{{1}/{m}} \text{ for infinitely many }n\in \mathbb{N}\}. \end{align*} $$
Hence,
$\{x\in [0,1)\colon \nu (x)>0\}$
is a null set. This completes the proof.
We now aim to determine the upper bound of
$\dim _{H}E(\hat {\nu },\nu )$
for
$0<\nu \le +\infty .$
Lemma 3.2. Let
$x\in E(\hat {\nu },\nu )$
, where
$v>0$
. If the continued fraction expansion of x is not periodic, there exist two ascending sequences
$\{n_k\}_{k=1}^{\infty }$
and
$\{m_k\}_{k=1}^{\infty }$
depending on x such that:
-
(1)
$n_k<m_k<n_{k+1}<m_{k+1}$
for
$k\ge 1$
; -
(2)
$a_{n_k+1}(x)=\cdots =a_{m_k}(x)=i$
for
$k\ge 1;$
-
(3)
$\liminf _{k\to \infty } (({m_k-n_k})/{n_{k+1}}) =\hat {\nu }$
,
$\limsup _{k\to \infty } (({m_k-n_k})/{n_k})=\nu .$
Proof. For
$x=[a_{1}(x),a_{2}(x),\ldots ]\in E(\hat {\nu },\nu )$
, we define two sequences
$\{n_{k}'\}_{k\geq 1}$
and
$\{m_{k}'\}_{k\geq 1}$
as follows:
$$ \begin{align*} m_{0}'=0,~ n_k'&=\min\{n\ge m_{k-1}'\colon a_{n+1}(x)=i\},\\ m_k'&=\max\{n\ge n_k'\colon a_{n_k'+1}(x)=\cdots=a_{n}(x)=i\}. \end{align*} $$
The fact that
$\nu (x)>0$
guarantees the existence of
$n_k'$
, and thus
$m_k'$
is well defined since the continued fraction expansion of x is not periodic. Further, for all
$k\ge 1,$
we have that
$n_k'\le m_k'<n_{k+1}'$
and
$$ \begin{align} |T^{n_k'}(x)-y|<|I_{m_k'-n_k'}(y)|. \end{align} $$
$$ \begin{align} |T^{n_k'}(x)-y|&>|I_{m_k'-n_k'+2}(\underbrace{ i,\ldots, i}_{m_k-n_k+1},i+1)|\ge \frac{1}{2q_{m_k'-n_k'+2}^{2}(i,\ldots,i,i+1)}\nonumber \\ &>\frac{1}{8(i+2)^{2}q_{m_k'-n_k'}^{2}(i,\ldots,i)}\ge \frac{1}{8(i+2)^{2}}|I_{m_k'-n_k'}(y)|. \end{align} $$
We also have
$\limsup _{k\to \infty }(m_{k}'-n_{k}')= +\infty $
since
$\nu (x)>0$
. We then choose a subsequence of
$\{(n_k', m_k')\}_{k\geq 1}$
as follows: put
$(n_{1},m_{1})=(n^{\prime }_{1},m^{\prime }_{1});$
having chosen
$(n_{k}, m_k)=(n_{j_{k}}', m_{j_{k}}')$
, we set
$j_{k+1}=\min \{j>j_k\colon m_{j}'-n_{j}'> m_{k}-n_{k}\}$
and put
$(n_{k+1},m_{k+1})=(n_{j_{k+1}}', m_{j_{k+1}}')$
. We claim that
$$ \begin{align*} \liminf_{k\to\infty}\frac{m_k-n_k}{n_{k+1}}=\hat{\nu}(x),\quad \limsup_{k\to\infty}\frac{m_k-n_k}{n_k}=\nu(x). \end{align*} $$
To prove the first assertion, we write
$\liminf _{n\to \infty } (({m_k-n_k})/{n_{k+1}}) =a.$
For
$\varepsilon>0,$
there is a subsequence
$\{k_j\}_{j=1}^{\infty }$
such that
$$ \begin{align*} m_{k_j}-n_{k_{j}}\le (a+\varepsilon)n_{{k_j}+1}. \end{align*} $$
Putting
$N=n_{k_j}-1$
, we have for all
$n\in [1,N]$
that
$$ \begin{align*} |T^{n}(x)-y|\ge\frac{1}{2(i+2)^{2}}|I_{m_{k_j}-n_{k_j}}(y)|>|I_{n_{k_j+1}}(y)|^{a+2\varepsilon}>|I_{N}(y)|^{a+3\varepsilon}, \end{align*} $$
where the second inequality holds by the following fact: by Lemmas 2.2 and 2.1(3), we deduce
$$ \begin{align*} {\lim_{n\to\infty}\frac{-\log|I_n(y)|}{2n}=\lim_{n\to\infty}\frac{\log q_n(y)}{n}=\log\tau(i).} \end{align*} $$
We get that
$\hat {\nu }(x)\le a+3\varepsilon $
by the definition of
$\hat {\nu }(x)$
.
However, when
$k\gg 1$
, we have
$$ \begin{align*} m_{k}-n_{k}\ge (a-\varepsilon)n_{k+1}. \end{align*} $$
For
$n_k\le N<n_{k+1}$
,
$$ \begin{align*} |T^{n_{k}}(x)-y|\le|I_{m_k-n_k}(y)|<|I_{n_{k+1}}(y)|^{a-\varepsilon}<|I_{N}(y)|^{a-\varepsilon}. \end{align*} $$
From here, we deduce that
$\hat {\nu }(x)\ge a-\varepsilon $
.
Letting
$\varepsilon \to 0$
, we complete the proof of the first assertion; the second one can be proved in a similar way.
Lemma 3.3. If
$0< {\nu }/({1+\nu }) < \hat {\nu }\le \infty , E(\hat {\nu },\nu )$
is at most countable and
$\dim _{H} E(\hat {\nu },\nu )=0.$
Proof. If
$x\in E(\hat {\nu },\nu )$
and its continued fraction expansion is not periodic, then by Lemma 3.2(2), there exist two sequences
$\{n_k\}_{k=1}^{\infty }$
and
$\{m_k\}_{k=1}^{\infty }$
depending on x such that
$$ \begin{align*}\liminf_{k\to\infty}\frac{m_k-n_k}{n_{k+1}}=\hat{\nu},\quad \limsup_{k\to\infty}\frac{m_k-n_k}{m_k}=\frac{\nu}{1+\nu}.\end{align*} $$
This yields
$\hat {\nu }\le {\nu }/({1+\nu })$
; the lemma follows.
We start with constructing of a covering of
$E(\hat {\nu },\nu )$
in the case where
$0\le \hat {\nu }\le {\nu }/({1+\nu }) < \infty $
and
$0<\nu \le \infty .$
Since
$E(0,\nu )$
is a subset of
$\{x\in [0,1)\colon \nu (x)=\nu \},$
by Corollary 1.4, we have
$\dim _{H}E(0,\nu )\le s ({\nu }/({1+\nu }),{\tau (i)})$
, which is the desired upper bound estimate. Hence, we only need to deal with the case
$0<\hat {\nu }\le {\nu }/({1+\nu }) < \nu \le \infty .$
Whence, given any x in the set
$E(\hat {\nu },\nu )$
with non-periodic continued fraction expansion, we associate x with two sequences
$\{n_k\}, \{m_k\}$
as in Lemma 3.2. The following properties hold.
-
(1) The sequence
$\{m_k\}$
grows exponentially, more precisely, there exists
$C>0$
, independent of x, such that when k is large enough, (3.3)
$$ \begin{align} k \leq C\log{m_{k}}. \end{align} $$
Indeed, we have that
$m_{k}-n_{k}\ge (\hat {\nu }/2)n_{k+1}$
for all large k, and thus,
$$ \begin{align*}m_{k}\ge \bigg(1+\frac{\hat{\nu}}2\bigg)n_{k} \ge \bigg(1+\frac{\hat{\nu}}2\bigg)m_{k-1}.\end{align*} $$
-
(2) Write
$\xi = {\nu ^{2}}/({(1+\nu )(\nu -\hat {\nu })})$
. For any
$\varepsilon>0$
, there exist infinitely many k such that (3.4)
$$ \begin{align} \sum_{i=1}^{k}(m_{i}-n_{i})\ge m_{k}(\xi-\varepsilon). \end{align} $$
To prove this, we apply a general form of the Stolz–Cesàro theorem which states that: if
$b_n$
tends to infinity monotonically,
$$ \begin{align*} \liminf_n\frac{a_n-a_{n-1}}{b_n-b_{n-1}}\le \liminf_n\frac{a_n}{b_n}\le \limsup_n\frac{a_n}{b_n} \le \limsup_n\frac{a_n-a_{n-1}}{b_n-b_{n-1}}. \end{align*} $$
We deduce from Lemma 3.2 that
$$ \begin{align*} \limsup_{k\to\infty}\frac{m_{k}}{n_{k}}=1+\nu \end{align*} $$
and
$$ \begin{align*} \liminf_{k\to\infty}\frac{m_{k}}{n_{k+1}} \ge \liminf_{k\to\infty}\frac{m_{k}-n_{k}}{n_{k+1}} \cdot\liminf_{k\to\infty}\frac{m_{k}}{m_{k}-n_{k}} =\frac{\hat{\nu}(1+\nu)}{\nu}. \end{align*} $$
Hence,
$$ \begin{align} &\liminf_k\frac{\sum_{i=1}^{k}(m_i-n_i)}{m_{k+1}}\ge \liminf_k\frac{m_k-n_k}{m_{k+1}-m_k}\notag\\ & \quad \ge \liminf_k\frac{m_k-n_k}{n_{k+1}}\cdot\frac{1}{\limsup_k ({m_{k+1}}/{n_{k+1}}) -\liminf_k ({m_k}/{n_{k+1}}) }\notag\\ &\quad\ge \frac{\hat{\nu}\nu}{ (\nu-\hat{\nu}) (1+\nu)}, \end{align} $$
and thus
$$ \begin{align*} \sum_{i=1}^{k}(m_{i}-n_{i})& \geq \bigg(\frac{\hat{\nu}\nu}{(\nu-\hat{\nu})(1+\nu)}-\frac{\varepsilon}{2}\bigg) m_{k}+(m_{k}-n_{k}) \end{align*} $$
holds for k large enough. However, there exist infinitely many k such that
$$ \begin{align*}m_k-n_k\ge \bigg(\frac{\nu}{1+\nu}-\frac{\varepsilon}{2}\bigg)m_k.\end{align*} $$
We then readily check that equation (3.4) holds for such k.
We now construct a covering of
$E(\hat {\nu },\nu )$
. To this end, we collect all sequences
$(\{n_{k}\}, \{m_{k}\})$
associated with some
$x\in E(\hat {\nu },\nu )$
as in Lemma 3.2 to form a set
$$ \begin{align*} \Omega = \{(\{n_{k}\},\{m_{k}\})\ \colon \text{ conditions (1) and (3) in Lemma~3.2 are fulfilled} \}. \end{align*} $$
For
$(\{n_{k}\},\{m_{k}\})\in \Omega $
, write
$$ \begin{align*} H(\{n_{k}\},\{m_{k}\})&=\{x\in[0,1)\colon \text{ condition (2) in Lemma~3.2 is fulfilled} \},\\\Lambda_{k, m_k}&= \{(n_1,m_1; \ldots; n_{k-1},m_{k-1};n_{k})\colon n_{1}< m_{1}<\cdots<m_{k-1}<n_{k}<m_k,\\& \qquad \text{equation~(3.4)}\text{ holds}\},\\\mathcal{D}_{n_1,m_1;\ldots;n_{k}, m_{k}}&= \{(\sigma_{1},\ldots,\sigma_{m_{k}})\in \mathbb{N}^{m_{k}}\colon \sigma_{n_{j}+1}=\cdots=\sigma_{m_{j}}=i \\&\qquad\text{for all }1\leq j\leq k \}. \end{align*} $$
Based on the previous analysis, we obtain a covering of
$E(\hat {\nu },\nu ),$
that is,
$$ \begin{align*} & E(\hat{\nu},\nu) \subseteq \bigcup_{(\{n_{k}\},\{m_{k}\})\in \Omega}H(\{n_{k}\},\{m_{k}\}) \\&\quad \subseteq\bigcap_{K=1}^{\infty} \bigcup_{k=K}^{\infty} \bigcup_{m_{k}\ge e^{{k}/{C}}} \bigcup_{(n_{1},m_{1},\ldots,m_{k-1},n_{k})\in\Lambda_{k, m_k}} \bigcup_{(a_{1},\ldots,a_{m_{k}})\in \mathcal{D}_{n_1,m_1;\ldots;n_{k}, m_{k}}}I_{m_{k}}(a_{1},\ldots,a_{m_{k}}). \end{align*} $$
For
$\varepsilon>0$
, putting
$t=s(\xi -\varepsilon ,{\tau (i)})+ ({\varepsilon }/{2})$
, we have that
$t>s(\xi ,{\tau (i)})$
and
$t>\tfrac 12$
by Lemma 2.13(2) and equation (2.7). We are now in a position to estimate
$\mathcal {H}^{t+ ({\varepsilon }/{2})}(E(\hat {\nu },\nu ))$
, the
$(t+ ({\varepsilon }/{2}))$
-dimensional Hausdorff measure of
$E(\hat {\nu },\nu )$
.
Lemma 3.4. For
$\varepsilon>0$
, we have
$\mathcal {H}^{t+ ({\varepsilon }/{2})} (E(\hat {\nu },\nu )) < +\infty .$
Proof. By Lemma 2.12, there exists
$K\in \mathbb {N}$
such that for all
$k\geq K,$
$$ \begin{align} s_{m_{k}}(\xi-\varepsilon,{\tau(i)})\leq t, \end{align} $$
$$ \begin{align} (4^{2t+\varepsilon}k)^{2C\log k}<2^{(({k-1})/{4})\varepsilon}. \end{align} $$
Writing
$\psi (m_{k})=m_{k}-\sum _{i=1}^{k}(m_{i}-n_{i})$
when
$m_{k}\geq K$
, we have that
$$ \begin{align*} &\sum\limits_{(a_{1},\ldots,a_{m_{k}})\in {\mathcal{D}_{n_1,m_1;\ldots;n_{k}, m_{k}}}} |I_{m_{k}}(a_{1},\ldots,a_{m_{k}})|^{t+ ({\varepsilon}/{2})}\\&\quad \leq\sum\limits _{(a_{1},\ldots,a_{m_{k}})\in {\mathcal{D}_{n_1,m_1;\ldots;n_{k}, m_{k}}}} \bigg(\frac{1}{q_{m_{k}}(a_{1},\ldots,a_{m_{k}})}\bigg)^{2t+\varepsilon}\\&\quad \leq\sum\limits_{a_{1},\ldots,a_{\psi(m_{k})}\in \mathbb{N}}2^{k(2t+\varepsilon)}\\& \qquad \times \bigg(\frac{1}{q_{\psi(m_{k})}(a_{1},\ldots, a_{\psi(m_{k})}) q_{m_{1}-n_{1}}(i,\ldots,i)\cdots q_{m_{k}-n_{k}}(i,\ldots,i)}\bigg)^{2t+\varepsilon}\\&\quad \leq\sum\limits _{a_{1},\ldots,a_{\psi(m_{k})}\in \mathbb{N}}4^{k(2t+\varepsilon)}\bigg(\frac{1}{q_{m_{k}}(a_{1},\ldots,a_{\psi(m_{k})},i,\ldots,i)}\bigg)^{2t+\varepsilon}\\&\quad \leq\sum\limits _{a_{1},\ldots,a_{m_{k}-\lfloor m_{k}(\xi-\varepsilon)\rfloor}\in \mathbb{N}} 4^{k(2t+\varepsilon)}\bigg(\frac{1}{q_{m_{k}}(a_{1},\ldots,a_{m_{k}-\lfloor m_{k}(\xi-\varepsilon)\rfloor},i,\ldots,i)}\bigg)^{2s_{m_{k}}(\xi-\varepsilon,{\tau(i)})+\varepsilon}\\&\quad \leq 4^{k(2t+\varepsilon)}\bigg(\frac{1}{2}\bigg)^{(({m_{k}-1})/{2})\varepsilon}, \end{align*} $$
where the first two inequalities hold by Lemmas 2.2 and 2.1; the penultimate one follows by equations (3.4) and (3.6); and the last one follows by Remark 2.11 and Lemma 2.1(1).
Therefore,
$$ \begin{align*} &\mathcal{H}^{t+ ({\varepsilon}/{2})} (E(\hat{\nu},\nu))\\&\quad\leq \liminf_{K\to\infty}\sum\limits_{k=K}^{\infty}\sum_{m_{k}= e^{{k}/{C}}}^{\infty} \sum_{(n_{1},m_{1},\ldots,m_{k-1},n_{k})\in\Lambda_{k, m_k}}\\&\qquad\times \sum\limits _{(a_{1},\ldots,a_{m_{k}})\in \mathcal{D}_{n_1,m_1;\ldots;n_{k}, m_{k}} }|I_{m_{k}}(a_{1},\ldots,a_{m_{k}})|^{t+ ({\varepsilon}/{2})}\\&\quad\leq\liminf_{K\to\infty}\sum\limits_{k=K}^{\infty} \sum\limits_{m_{k}=e^{{k}/{C}}}^{\infty} \sum_{n_{k}=1}^{m_{k}}\sum_{m_{k-1}=1}^{n_{k}}\cdots\sum\limits_{m_{1}=1}^{n_{2}} \sum\limits_{n_{1}=1}^{m_{1}}4^{k(2t+\varepsilon)}\bigg(\frac{1}{2}\bigg)^{(({m_{k}-1})/{2})\varepsilon}\\&\quad\leq\liminf_{K\to\infty}\sum\limits_{k=K}^{\infty} \sum\limits_{m_{k}=e^{{k}/{C}}}^{\infty}(4^{2t+\varepsilon}m_{k})^{2C\log m_{k}}\bigg(\frac{1}{2}\bigg)^{(({m_{k}-1})/{2})\varepsilon}\\&\quad\leq\liminf_{K\to\infty}\sum\limits_{k=K}^{\infty} \sum\limits_{m_{k}=e^{{k}/{C}}}^{\infty}\bigg(\frac{1}{2}\bigg)^{(({m_{k}-1}/{4})\varepsilon} \leq \frac{1}{1-({1}/{2})^{{\varepsilon}/{4}}} \sum\limits_{k=1}^{\infty} \bigg(\frac{1}{2^{\varepsilon}}\bigg)^{({e^{k/C} - 1})/{4}} < +\infty, \end{align*} $$
where the third and fourth inequalities follow from equations (3.3) and (3.7), respectively.
By Lemma 3.4, we obtain the desired inequality
$\dim _{H}E(\hat {\nu },\nu )\le s(\xi ,{\tau (i)})$
by letting
$\varepsilon \to 0$
.
Remark 3.5. In fact, the covering
$\bigcup _{(\{n_{k}\},\{m_{k}\})\in \Omega }H(\{n_{k}\},\{m_{k}\})$
of
$E(\hat {\nu },\nu )$
is also a covering of
$$ \begin{align*} E_{\ast}(\hat{\nu},\nu)=\{x\in[0,1]\colon \hat{\nu}(x)\ge\hat{\nu}, \nu(x)=\nu\}, \end{align*} $$
because
$\liminf _{k} (({m_k-n_k})/{n_{k+1}})\ge \hat {\nu }$
for
$(\{n_{k}\},\{m_{k}\})\in \Omega .$
It follows that
$\dim _{H}E_{\ast }(\hat {\nu },\nu ) \le s(\xi ,{\tau (i)}).$
4 Proof of Theorem 1.3: lower bound
In this section, we establish the lower bound of
$\dim _{H}E(\hat {\nu },\nu ).$
Since
$E(0,0)$
is of full Lebesgue measure and
$\dim _{H}E(\hat {\nu },\nu )=0$
for
$\hat {\nu }> {\nu }/({1+\nu }),$
we need only consider the cases
$0\le \hat {\nu }\le {\nu }/({1+\nu }) < \nu <\infty $
or
$\nu =\infty .$
Let us start by treating the case
$0\le \hat {\nu }\le {\nu }/({1+\nu }) <\nu <\infty $
. We claim that there exist two sequences of natural numbers
$\{n_{k}\}_{k=1}^{\infty }$
and
$\{m_{k}\}_{k=1}^{\infty }$
satisfying the following conditions:
-
(1)
$n_{k}< m_{k}< n_{k+1}$
and
$(m_{k}-n_{k})\leq (m_{k+1}-n_{k+1})$
for
$k\geq 1$
; -
(2)
$\lim _{k\to \infty } (({m_{k}-n_{k}})/{n_{k+1}})=\hat {\nu }$
; -
(3)
$\lim _{k\to \infty } (({m_{k}-n_{k}})/{n_{k}})=\nu $
.
Indeed, when
$\hat {\nu }>0$
, we may take
$$ \begin{align*}n_{1}=2,~ n_{k+1}=\bigg\lfloor \frac{\nu}{\hat{\nu}} \bigg(n_{k}+\frac{1}{\nu}\bigg)\bigg\rfloor + 2, m_{k} = \lfloor (1+\nu)n_{k}\rfloor + 1; \end{align*} $$
when
$\hat {\nu }=0$
, we may take
$$ \begin{align*} n_{k}= \lfloor(1+\nu)2^{2^{2{k}}}\rfloor + 2, m_{k} = \lfloor(1+\nu)n_{k}\rfloor+1. \end{align*} $$
From now on, we fix two such sequences
$\{n_{k}\}, \{m_{k}\}$
; for any
$B\ge i+1$
, we define
$$ \begin{align*} E(B) = &\{x\in[0,1)\colon 1\leq a_{n}(x)\leq B, a_{n_{k}+1}(x)=\cdots=a_{m_{k}}(x)=i, n\geq 1 \text{ and } k \geq 1\}. \end{align*} $$
The lower bound estimate of
$\dim _H E(\hat \nu ,\nu )$
will be established in the following way: we provide a lower bound of
$\dim _{H}E(B)$
; build an injective mapping f from
$E(B)$
to
$ E(\hat \nu ,\nu )$
and prove that f is dimension-preserving.
4.1 Lower bound of
$\dim _{H}E(B)$
Before proceeding, we cite an analogous definition of the pre-dimensional numbers. Let
$l_{k}=m_{k}-m_{k-1}$
for
$k\geq 1$
(
$m_{0}=0$
by convention). Let
$$ \begin{align*}\widetilde{f}_{k}(s,{\tau(i)}) =\sum\limits_{1\leq a_{m_{k-1}+1},\ldots,a_{n_{k}}\leq B} \bigg(\frac{1}{q_{l_{k}}(a_{m_{k-1}+1},\ldots,a_{n_{k}}, i,\ldots,i)}\bigg)^{2s}.\end{align*} $$
Recall
$\xi = {\nu ^{2}}/({(1+\nu )(\nu -\hat {\nu })})$
. We define
$\widetilde {s}_{l_{k}}(\mathcal {A}_{B},\xi ,\tau (i))$
to be the solution of the equation
$\widetilde {f}_{k}(s,\tau (i))=1$
.
Lemma 4.1. The limit
$\lim _{k\to \infty }\widetilde {s}_{l_{k}}(\mathcal {A}_{B},\xi ,{\tau (i)})$
exists, and is equal to
$s(\mathcal {A}_{B},\xi ,{\tau (i)}).$
Proof. By Lemma 2.12 and the fact
$l_{k}\to \infty $
as
$k\rightarrow \infty $
(cf. condition (1)), we deduce that, for any
$\varepsilon>0,$
when
$k\gg 1,$
$$ \begin{align} |s_{l_{k}}(\mathcal{A}_{B},\xi+\varepsilon,\tau(i))-s(\mathcal{A}_{B},\xi+\varepsilon,\tau(i))|<\frac{\varepsilon}{2}. \end{align} $$
Further, from conditions (2) and (3), we have that
$$ \begin{align*} \lim_{k\to\infty}\frac{m_{k}-n_{k}}{l_{k}} &=\lim_{k\to\infty}\frac{ (({m_k-n_k})/{m_k})\cdot ({m_k}/{n_k}) }{({m_k}/{n_k}) - (({m_{k-1}-n_{k-1}})/{n_k})\cdot ({m_{k-1}})/({m_{k-1} -n_{k-1}})} =\xi, \end{align*} $$
and thus for
$k\gg 1$
,
$$ \begin{align} \lfloor l_{k}(\xi-\varepsilon)\rfloor \leq m_{k}-n_{k}\leq \lfloor l_{k}(\xi+\varepsilon)\rfloor. \end{align} $$
Hence, by equations (4.1) and (4.2), we obtain that
$$ \begin{align*} &\sum\limits_{1\leq a_{1},\ldots,a_{n_{k}-m_{k-1}}\leq B} \bigg(\frac{1}{q_{l_{k}}(a_{1},\ldots,a_{n_{k}-m_{k-1}}, i,\ldots,i)}\bigg)^{2 (s(\mathcal{A}_{B}, \xi+\varepsilon,\tau(i))-\varepsilon)} \\ &\quad\geq\sum\limits_{1\leq a_{1},\ldots,a_{n_{k}-m_{k-1}}\leq B} \bigg(\frac{1}{q_{l_{k}}(a_{1},\ldots,a_{n_{k}-m_{k-1}}, i,\ldots,i)}\bigg)^{2s_{l_{k}}(\mathcal{A}_{B}, \xi+\varepsilon,\tau(i))-\varepsilon}\\ &\quad\geq\sum\limits_{1\leq a_{1},\ldots,a_{l_{k}-\lfloor l_{k}(\xi+\epsilon)\rfloor}\leq B} \bigg(\frac{1}{q_{l_{k}}(a_{1},\ldots,a_{l_{k}-\lfloor l_{k}(\xi+\varepsilon)\rfloor}, i,\ldots,i)}\bigg)^{2s_{l_{k}}(\mathcal{A}_{B}, \xi+\varepsilon,{\tau(i)})-\varepsilon}\\ &\quad\geq\bigg(\frac{1}{q_{l_{k}}(B,\ldots,B)}\bigg)^{-\varepsilon}\geq\tau(B)^{l_{k}\varepsilon}\geq 1, \end{align*} $$
where
$\tau (B)= ({B+\sqrt {B^{2}+4}})/{2}.$
Moreover, we get that
$$ \begin{align*} &\sum\limits_{1\leq a_{1},\ldots,a_{n_{k}-m_{k-1}}\leq B} \bigg(\frac{1}{q_{l_{k}}(a_{1},\ldots,a_{n_{k}-m_{k-1}}, i,\ldots,i)}\bigg)^{2 (s(\mathcal{A}_{B}, \xi-\varepsilon,\tau(i))+\varepsilon)} \\ &\quad\leq\sum\limits_{1\leq a_{1},\ldots,a_{l_{k}-\lfloor l_{k}(\xi-\varepsilon)\rfloor}\leq B} \bigg(\frac{1}{q_{l_{k}}(a_{1},\ldots,a_{l_{k}-\lfloor l_{k}(\xi-\varepsilon)\rfloor}, i,\ldots,i)}\bigg)^{2s_{l_{k}}(\mathcal{A}_{B}, \xi-\varepsilon,\tau(i))+\varepsilon}\\ &\quad\leq\bigg(\frac{1}{q_{l_{k}}(1,\ldots,1)}\bigg)^{\varepsilon}<1. \end{align*} $$
By the monotonicity of
$\widetilde {f}_{k}(s,{\tau (i)})$
with respect to s, we have
$$ \begin{align*}s(\mathcal{A}_{B},\xi+\varepsilon,\tau(i))-\varepsilon \le\widetilde{s}_{l_{k}}(\mathcal{A}_{B},\xi,{\tau(i)}) \le s(\mathcal{A}_{B},\xi-\varepsilon,\tau(i))+\varepsilon,\end{align*} $$
which completes the proof.
4.1.1 Supporting measure
We define a probability measure
$\mu $
on
$E(B)$
by distributing mass among the basic intervals. We introduce the symbolic space to code these basic intervals: write
$\mathcal {A}_{B}=\{1,\ldots ,B\}$
; for
$n\geq 1,$
set
$$ \begin{align*} \mathcal{B}_{n} = \{(\sigma_{1},\ldots,\sigma_{n})\in \mathcal{A}_{B}^{n}\colon\sigma_{j}=i \text{ for } n_{k}<j\leq m_{k} \text{ with some } k\geq 1\}. \end{align*} $$
Step I: For
$(a_{1},\ldots ,a_{m_{1}})\in \mathcal {B}_{m_{1}}$
, we define
$$ \begin{align*} \mu (I_{m_{1}}(a_{1},\ldots,a_{m_{1}})) = \bigg(\frac{1}{q_{l_{1}}(a_{1},\ldots,a_{m_{1}})}\bigg)^{2\widetilde{s}_{l_{1}}(\mathcal{A}_{B},\xi,{\tau(i)})}\end{align*} $$
and for
$1\leq n<m_{1}$
, set
$$ \begin{align*} \mu (I_{n}(a_{1},\ldots,a_{n})) = \sum\limits_{a_{n+1},\ldots,a_{m_{1}}}\mu (I_{m_{1}}(a_{1},\ldots,a_{n},a_{n+1},\ldots,a_{m_{1}})), \end{align*} $$
where the summation is taken over all
$(a_{n+1},\ldots ,a_{m_{1}})$
with
$(a_{1},\ldots ,a_{m_{1}})\in \mathcal {B}_{m_{1}}$
.
Step II: Assuming that
$\mu (I_{m_{k}}(a_{1},\ldots ,a_{m_{k}}))$
is defined for some
$k\geq 1$
, we define
$$ \begin{align*} &\mu(I_{m_{k+1}}(a_{1},\ldots,a_{m_{k+1}}))\\ &\quad = \mu(I_{m_{k}}(a_{1},\ldots,a_{m_{k}}))\cdot \bigg(\frac{1}{q_{l_{k+1}}(a_{m_{k}+1},\ldots,a_{m_{k+1}})}\bigg)^{2\widetilde{s}_{l_{k+1}}(\mathcal{A}_{B},\xi,{\tau(i)})} \end{align*} $$
and for
$m_{k}<n<m_{k+1}$
, set
$$ \begin{align*} \mu (I_{n}(a_{1},\ldots,a_{n})) = \sum\limits_{a_{n+1},\ldots,a_{m_{k+1}}} \mu (I_{m_{k+1}}(a_{1},\ldots,a_{n},a_{n+1},\ldots, a_{m_{k+1}})). \end{align*} $$
Likewise, the last summation is taken under the restriction that
$(a_{1},\ldots ,a_{m_{k+1}})\in \mathcal {B}_{m_{k+1}}.$
Step III: We have distributed the measure among basic intervals. By the definition of
$\widetilde {s}_{l_{k}}(\mathcal {A}_{B},\xi ,{\tau (i)})$
, we readily check the consistency: for
$n\geq 1$
and
$(a_{1},\ldots ,a_{n})\in \mathcal {B}_{n}$
,
$$ \begin{align*} \mu (I_{n}(a_{1},\ldots,a_{n})) = \sum\limits_{a_{n+1}}\mu (I_{n+1}(a_{1},\ldots,a_{n},a_{n+1})). \end{align*} $$
We then extend the measure to all Borel sets by Kolmogorov extension theorem. The extension measure is also denoted by
$\mu $
.
From the construction, we know that
$\mu $
is supported on
$E(B)$
and
$$ \begin{align*} \mu (I_{m_{k}}(a_{1},\ldots,a_{m_{k}}))=&\prod\limits_{j=1}^{k} \bigg(\frac{1}{q_{l_{j}}(a_{m_{j-1}+1},\ldots,a_{m_{j}})}\bigg)^{2\widetilde{s}_{l_{j}}(\mathcal{A}_{B},\xi,{\tau(i)})},\\ & \sum\limits_{a_{1}\in \mathcal{B}_{1}}\mu (I_{1}(a_{1})) = 1. \end{align*} $$
4.1.2 Hölder exponent of
$\boldsymbol \mu $
We shall start with the study of a basic interval.
For
$0<\varepsilon <{s(\mathcal {A}_{B},\xi ,{\tau (i)})}/{4}$
, by Lemmas 2.12, 4.1, and the fact that
$m_k$
grows exponentially, we can find
$K\in \mathbb {N}$
such that for any
$k, j\geq K,$
$$ \begin{align} |\widetilde{s}_{l_{k}}(\mathcal{A}_{B},\xi,{\tau(i)})-s(\mathcal{A}_{B},\xi,{\tau(i)})|<\varepsilon, \end{align} $$
$$ \begin{align} |\widetilde{s}_{l_{k}}(\mathcal{A}_{B},\xi,{\tau(i)})-s_j(\mathcal{A}_{B},\xi,{\tau(i)})|<\frac{\varepsilon\log 2}{2\log (B+1)}:=\varepsilon', \end{align} $$
and
$$ \begin{align} \max \{(B+1)^K,2^k\}\le \frac14 (q_{m_k}(a_1,\ldots,a_{m_k}))^\varepsilon. \end{align} $$
Lemma 4.2. Let
$n\ge m_K$
. For
$(a_{1}, \ldots , a_{n})\in \mathcal {B}_{n}$
, we have
$$ \begin{align*} \mu (I_{n}(a_{1},\ldots,a_{n}))\leq C_0\cdot |I_{n}(a_1,\ldots,a_n)|^{s(\mathcal{A}_{B},\xi,{\tau(i)})-3\varepsilon}, \end{align*} $$
where
$C_0=(B+1)^{2(l_1+\cdots +l_{K-1})}.$
Proof. To shorten notation, we will write
$\widetilde {s}_{l_{k}}, s_k$
and s instead of
$\widetilde {s}_{l_{k}}(\mathcal {A}_{B},\xi ,{\tau (i)}), s_k (\mathcal {A}_{B},\xi ,{\tau (i)})$
and
$s(\mathcal {A}_{B},\xi ,{\tau (i)})$
, respectively. Fixing
$(a_{1}, \ldots , a_{n})\in \mathcal {B}_{n}$
, we also write
$I_n$
for
$I_n(a_1,\ldots ,a_n)$
,
$q_n$
for
$q_n(a_1,\ldots ,a_n)$
, and
$q_{l_j}$
for
${q_{l_{j}}(a_{m_{j-1}+1},\ldots ,a_{m_{j}})}$
when no confusion can arise. The proof falls naturally into three parts according to the range of n.
Case 1:
$n=m_{k}$
for
$k\ge K$
. By Lemmas 2.2 and 2.3, equations (4.3), (4.5), and the fact
$q_{l_j}\le (B+1)^{l_j}$
, we obtain
$$ \begin{align*} \mu(I_{m_{k}})&=\prod\limits_{j=1}^{k} q_{l_j}^{-2\widetilde{s}_{l_j}}=\prod\limits_{j=1}^{K}q_{l_j}^{-2\widetilde{s}_{l_j}}\cdot\prod\limits_{j=K+1}^{k}q_{l_j}^{-2\widetilde{s}_{l_j}}\le C_0\prod\limits_{j=1}^{K}q_{l_j}^{-2(s-\varepsilon)}\cdot\prod\limits_{j=K+1}^{k}q_{l_j}^{-2(s-\varepsilon)}\\ &\leq C_{0}2^{2(k-1)}(q_{m_k})^{-2(s-\varepsilon)}\le \frac{C_{0}}4(q_{m_k})^{-2(s-2\varepsilon)}\leq C_{0}|I_{m_{k}}|^{s-2\varepsilon}. \end{align*} $$
Case 2:
$m_{k}<n< n_{k+1}$
for
$k\ge K$
. In this case, we have
$$ \begin{align*} \mu(I_n)&=\sum_{a_{n+1},\ldots,a_{m_{k+1}}}\mu(I_{m_{k+1}})=\sum_{{a_{n+1},\ldots,a_{m_{k+1}}}}\prod_{j=1}^{k+1}(q_{l_j})^{-2\widetilde{s}_{l_{j}}} \\ &= \prod_{j=1}^{k}(q_{l_j})^{-2\widetilde{s}_{l_{j}}}\cdot\sum_{{a_{n+1},\ldots,a_{m_{k+1}}}}(q_{l_{k+1}})^{-2\widetilde{s}_{l_{k+1}}}. \end{align*} $$
We have already seen in Case 1 that
$\prod _{j=1}^{k}(q_{l_j})^{-2\widetilde {s}_{l_{j}}}\le C_{0}2^{2(k-1)}(q_{m_k})^{-2(s-\varepsilon )}$
. Additionally,
$$ \begin{align*} \sum_{{a_{n+1},\ldots,a_{m_{k+1}}}} (q_{l_{k+1}})^{-2\widetilde{s}_{l_{k+1}}}&\le ({q_{n-m_{k}}(a_{m_{k}+1},\ldots,a_{n})})^{-2(s-\varepsilon)}\\ &\quad\cdot\sum_{{a_{n+1},\ldots,a_{n_{k+1}}}} ({q_{m_{k+1}-n}(a_{n+1},\ldots,a_{n_{k+1}},i,\ldots,i)})^{-2\widetilde{s}_{l_{k+1}}}. \end{align*} $$
We then obtain that
$$ \begin{align*} \mu(I_n)\le C_02^{2k}(q_n)^{-2(s-\varepsilon)}\cdot \sum_{a_{n+1},\ldots,a_{m_{k+1}}} ({q_{m_{k+1}-n}(a_{n+1},\ldots,a_{n_{k+1}},i,\ldots,i)})^{-2\widetilde{s}_{l_{k+1}}}. \end{align*} $$
Now we need an upper estimate of the last sum. By the definition of
$\widetilde {s}_{l_{k+1}}$
, we have that
$$ \begin{align*} &\sum\limits_{1\leq a^{\prime}_{m_{k}+1},\ldots,a^{\prime}_n,a_{n+1},\ldots,a_{n_{k+1}}\leq B} (q_{l_{k+1}}( a^{\prime}_{m_{k}+1},\ldots,a^{\prime}_n,a_{n+1},\ldots,a_{n_{k+1}},i,\ldots,i))^{-2\widetilde{s}_{l_{k+1}}}=1. \end{align*} $$
This yields that
$$ \begin{align*} &\sum_{{a^{\prime}_{m_k+1},\ldots,a^{\prime}_{n}}} ( q_{n-m_{k}}(a^{\prime}_{m_{k}+1},\ldots,a^{\prime}_{n}))^{-2\widetilde{s}_{l_{k+1}}}\\ &\qquad\times \sum_{{a_{n+1},\ldots,a_{n_{k+1}}}} (q_{m_{k+1}-n}(a_{n+1},\ldots,a_{n_{k+1}},i,\ldots,i))^{-2\widetilde{s}_{l_{k+1}}}\le 4. \end{align*} $$
We will bound the first sum from below to reach the desired upper estimate of the second sum. We consider two cases.
(1) If
$n-m_{k}< K$
,
$$ \begin{align*} \sum_{a^{\prime}_{m_{k}+1},\ldots,a^{\prime}_{n}} (q_{n-m_k}(a^{\prime}_{m_{k}+1},\ldots,a^{\prime}_{n}))^{-2\widetilde{s}_{l_{k+1}}} \geq (q_{n-m_k}(B,\ldots,B))^{-2}\geq( {B+1})^{-2K}. \end{align*} $$
And thus, by equation (4.5), we reach that
$$ \begin{align*} \mu(I_{n}) \leq C_{0}2^{2k+2}(B+1)^{2K} ({q_{n}} )^{-2(s-\varepsilon)}\le\frac{C_{0}}4(q_{m_k})^{-2(s-3\varepsilon)} \leq C_{0} |I_{n}|^{s-3\varepsilon}. \end{align*} $$
(2) If
$n-m_{k}\geq K$
, then, by equations (4.4), (4.5), and Remark 2.11, we have
$$ \begin{align*} &\sum_{a^{\prime}_{m_{k}+1},\ldots,a^{\prime}_{n}} (q_{n-m_k}(a^{\prime}_{m_{k}+1},\ldots,a^{\prime}_{n}))^{-2\widetilde{s}_{l_{k+1}}} \ge \sum_{a^{\prime}_{m_{k}+1},\ldots,a^{\prime}_{n}} (q_{n-m_k}(a^{\prime}_{m_{k}+1},\ldots,a^{\prime}_{n}))^{-2{s}_{n-m_k}-\varepsilon'}\\&\quad\ge\sum_{a^{\prime}_{m_{k}+1},\ldots,a^{\prime}_{n-\lfloor(n-m_k)\xi\rfloor}}({q_{n-m_{k}}(a^{\prime}_{m_{k}+1},\ldots,a^{\prime}_{n-\lfloor(n-m_k)\xi\rfloor}, i,\ldots,i)})^{-2s_{n-m_{k}}-\varepsilon'}\\&\quad\ge ({q_{n-m_{k}}(B,\ldots,B)})^{-\varepsilon'} \ge({B+1})^{-(n-m_{k})\varepsilon'} \ge({B+1})^{-n\varepsilon'} \ge2^{{-n\varepsilon}/{2}}. \end{align*} $$
Therefore,
$$ \begin{align*}\mu(I_{n}) \leq C_{0}2^{2k+2}2^{{n\varepsilon}/{2}} ({q_{n}} )^{-2(s-2\varepsilon)} \leq \frac{C_{0}}2({q_{n}})^{-2(s-3\varepsilon)} \leq C_{0}|I_{n}|^{s-3\varepsilon}. \end{align*} $$
Case 3:
$n_{k+1}\leq n<m_{k+1}$
for
$k\ge K$
. In this case, since
$(a_{n+1},\ldots ,a_{m_{k+1}})=(i,\ldots ,i),$
we have
$$ \begin{align*}\mu(I_{n}(a_{1},\ldots,a_{n}))=\mu(I_{m_{k+1}}(a_{1},\ldots,a_{m_{k+1}})),\end{align*} $$
then
$$ \begin{align*} \mu(I_{n}) \leq C_{0}|I_{m_{k+1}}|^{s-2\varepsilon} \leq C_{0}|I_{n}|^{s-2\varepsilon}. \end{align*} $$
These conclude the verification of the lemma.
Now we study the Hölder exponent for the measure of a general ball
$B(x,r)$
.
Lemma 4.3. For
$x\in E(B)$
and
$r>0$
small enough, we have
$$ \begin{align*}\mu(B(x,r))\leq C_{0}\cdot r^{s(\mathcal{A}_{B},\xi,{\tau(i)})-4\varepsilon}.\end{align*} $$
Proof. Let
$x=[a_{1},a_{2},\ldots ]$
be its continued fraction expansion. Let
$n\ge K+2$
be the integer such that
$$ \begin{align*}|I_{n+1}(a_{1},\ldots,a_{n+1})|\leq r<|I_{n}(a_{1},\ldots,a_{n})|.\end{align*} $$
Therefore, it follows from Lemmas 2.4 and 4.2 that
$$ \begin{align*} \mu(B(x,r))&\leq \mu(I_{n-2}(a_{1},\ldots,a_{n-2})) \leq C_{0}\cdot|I_{n-2}(a_{1},\ldots,a_{n-2})|^{s(\mathcal{A}_{B},\xi,{\tau(i)})-3\varepsilon} \\& \le C_{0}(B+1)^{6}\cdot |I_{n+1}(a_{1},\ldots,a_{n+1})|^{s(\mathcal{A}_{B},\xi,{\tau(i)})-3\varepsilon} \\& \le C_{0} \cdot |I_{n+1}(a_{1},\ldots,a_{n+1})|^{s(\mathcal{A}_{B},\xi,{\tau(i)})-4\varepsilon} \le C_{0}\cdot r^{s(\mathcal{A}_{B},\xi,{\tau(i)})-4\varepsilon}.\\[-3pc] \end{align*} $$
Applying mass distribution principle (see Lemma 2.6), letting
$\varepsilon \to 0$
, we conclude that
$$ \begin{align*}\dim_{H}E(B)\geq s(\mathcal{A}_{B},\xi,{\tau(i)}).\end{align*} $$
4.2 Lower bound of
$\dim _{H}E(\hat{\nu}, \nu)$
We build a mapping f from
$E(B)$
to
$ E(\hat{\nu} ,\nu )$
and prove that f is dimension-preserving.
Fix an integer
$d>B$
. For
$x=[a_{1},a_{2},\ldots ]$
in
$E(B)$
, we remark that the continued fraction of x is the concatenation of
$\mathbb B_0=[a_1,\ldots ,a_{n_1}]$
and the blocks
$$ \begin{align*}\mathbb B_k=[\,\underbrace{ i,\ldots, i}_{m_k-n_k}, a_{m_{k}+1}, \ldots, a_{n_{k+1}}] \quad (k=1,2,\ldots).\end{align*} $$
In the block
$\mathbb B_k$
, from the beginning, we insert a digit d after each
$m_k-n_k$
digits to obtain a new block
$\mathbb B_k'$
, that is,
$$ \begin{align*}\mathbb B^{\prime}_k=[ d, i,\ldots, i, d, a_{m_{k}+1}, \ldots, a_{m_{k}+(m_k-n_k)}, d, \ldots, a_{n_{k+1}}].\end{align*} $$
Concatenating the blocks
$\mathbb B_0, \mathbb B^{\prime }_1, \mathbb B^{\prime }_2,\ldots $
, we get
$[\mathbb B_0, \mathbb B^{\prime }_1, \mathbb B^{\prime }_2,\ldots ]$
, which is a continued fraction expansion of some
$\bar {x}$
. We then define
$f(x)=\bar {x}.$
Let
${\mathbf {K}}=\{k_n\}\subset \mathbb N$
be the collection of the occurrences of the digit d in the continued expansion of
$\bar x$
. It is trivially seen that
$\mathbf K$
is independent of the choice of
$x\in E(B)$
, and, in the notation of Lemma 2.7,
$\phi _{\mathbf {K}}(\bar x)=x$
for
$x\in E(B)$
.
Let
$h_k$
be the length of the block
$\mathbb B^{\prime }_k.$
Noting that the number of the inserted digit d is at most
$({n_{k+1}-m_{k}})/({m_{k}-n_{k}}) + 1=o(h_k)$
in the block
$\mathbb B^{\prime }_k$
, we readily check that
$\mathbf K$
is a subset of
$\mathbb N$
of density zero. Hence, by Lemma 2.7, we have
$$ \begin{align*} \dim_{H}f (E(B))=\dim_{H}E(B). \end{align*} $$
It remains to prove that
$f (E(B))$
is a Cantor subset of
$E(\hat {\nu },\nu ).$
Lemma 4.4.
$f (E(B))\subset E(\hat {\nu },\nu ).$
Proof. Fix
$\bar {x}\in f (E(B))$
.
For
$\varepsilon>0$
and n large enough, there exists some k such that
$(\sum _{j=0}^{k-1}h_j)\leq n<(\sum _{j=0}^{k}h_j)$
. From the construction, we deduce that if
$n=(\sum _{j=0}^{k-1}h_j)+1$
, then
$$ \begin{align*}|T^{n}(\bar{x})-y|<|I_{m_{k}-n_{k}}(y)|\le|I_{n}(y)|^{\nu-\varepsilon},\end{align*} $$
where the last inequality holds by the fact
$\lim _k ({\sum _{j=0}^{k-1}h_j}/{n_k})=1;$
if
$(\sum _{j=0}^{k-1}h_j)< n<(\sum _{j=0}^{k}h_j),$
then
$$ \begin{align*}|T^{n}(\bar{x})-y|\ge \frac{1}{2(d+2)^{2}}|I_{m_{k}-n_{k}}(y)|\ge|I_n(y)|^{\nu+\varepsilon}.\end{align*} $$
We then prove that
$\nu (\bar {x})=\nu $
by the arbitrariness of
$\varepsilon .$
However, for
$(\sum _{j=0}^{k-1}h_j)\leq N<(\sum _{j=0}^{k}h_j)$
with k large enough, we pick
$n=(\sum _{j=0}^{k-1}h_j)+1$
to obtain that
$$ \begin{align*}|T^{n}(\bar{x})-y|<|I_{m_{k}-n_{k}}(y)|\le|I_{\sum_{j=0}^{k}h_j}(y)|^{\hat{\nu}-\varepsilon}<|I_{N}(y)|^{\hat{\nu}-\varepsilon}.\end{align*} $$
When
$N=(\sum _{j=0}^{k}h_j)$
, for all
$n\in [1,N],$
we have that
$$ \begin{align*}|T^{n}(\bar{x})-y|\ge\frac{1}{2(d+2)^{2}}|I_{m_{k}-n_{k}}(y)|\ge|I_{N}(y)|^{\hat{\nu}+\varepsilon}.\end{align*} $$
We prove that
$\hat {\nu }(\bar {x})=\hat {\nu }.$
Hence,
$\bar {x}\in E(\hat {\nu },\nu ),$
as desired.
Consequently, for
$0\le \hat {\nu }\le {\nu }/({1+\nu }) <\nu <\infty ,$
we have
$\dim _{H}E(\hat {\nu },\nu )\geq s(\mathcal {A}_{B}, \xi ,{\tau (i)})$
.
Letting
$B\rightarrow \infty $
yields
$\dim _{H}E(\hat {\nu },\nu )\geq s(\xi ,{\tau (i)})$
, where
$\xi = {\nu ^{2}}/({(1+\nu )(\nu -\hat {\nu })})$
.
We conclude this section by determining the lower bound of
$\dim _{H}E(\hat {\nu }, +\infty ).$
We first study the case
$0<\hat {\nu }<1$
. Let
$$ \begin{align*} n_{1}=2,\quad n_{k+1}=n_{k}^{k}+2n_{k},\quad m_0=0,\quad m_{k}= \lfloor\hat{\nu}n_{k}^{k}\rfloor + n_{k},\quad B_{k}= \lfloor m_{k}\log m_{k}\rfloor. \end{align*} $$
Thus,
$$ \begin{align*} \lim_{k\to\infty}\frac{m_{k}-n_{k}}{n_{k+1}}=\hat{\nu},\quad \lim_{k\to\infty}\frac{m_{k}-n_{k}}{n_{k}}=\infty,\quad \lim_{k\to\infty}\frac{m_{k}-n_{k}}{m_{k}}=1. \end{align*} $$
Define
$$ \begin{align*} E=\{x\in[0,1)\colon a_{n}(x)\le B_k \text{ if } m_{k}<n\le n_{k+1} \text{ for some } k; \ a_n(x)=i \text{ otherwise}\}. \end{align*} $$
As before, for any
$x=[a_1,a_2,\ldots ]$
in
$E,$
we construct an element
$\bar {x}:=f(x)\colon $
insert a digit
$B_k+1$
after positions
$n_{k}$
and
$m_{k}+i(m_{k}-n_{k}), 0\leq i\leq t_{k}$
in the continued fraction expansion of x, where
$t_{k}=\max \{t\in \mathbb {N}\colon m_{k}+t(m_{k}-n_{k})< n_{k+1}\}$
; the resulting sequence is the continued fraction of
$\bar x$
.
The method establishing the lower bound of
$\dim _{H}E(B)$
applies to show that
${\dim _{H}E\geq 1/2 .}$
Moreover,
$f(E)$
is a subset of
$E(\hat {\nu }, +\infty ).$
It remains to prove that the Hausdorff dimension of
$f(E)$
coincides with the one of E. To this end, we shall show that
$f^{-1}$
is a
$(1-\varepsilon )$
-Hölder mapping for any
$\varepsilon>0$
. We remark that Lemma 2.7 may not apply directly here since
$\{B_{k}\}$
is an unbounded sequence.
Lemma 4.5. For
$\varepsilon>0, f^{-1}$
is a
$(1-\varepsilon )$
-Hölder mapping.
Proof. We write
$$ \begin{align*} m_{k}'=m_{k}+\sum_{l=1}^{k-1}(t_{l}+2),\quad n_{k}'=n_{k}+\sum_{l=1}^{k-1}(t_{l}+2), \end{align*} $$
and define the marked set
$$ \begin{align*} \mathbf{K}= \{m_{k}'+i(m_{k}-n_{k})+1\colon 0\leq i \leq t_{k}, k\geq 1\}\cup \{ n_{k}'\colon k\geq 1\}. \end{align*} $$
Let
$\Delta _{n}=\sharp \{i\leq n\colon i\in \mathbf {K}\}$
, where
$\sharp $
denotes the cardinality of a finite set. Let
$k\in \mathbb {N}$
such that
$m_{k}'\leq n<m_{k+1}'$
. We have
$$ \begin{align*} \frac{\Delta_{n}\log B_{k}}{n} &\leq\frac{(\sum_{l=1}^{k-1}(t_{l}+2)+ ({n-m_{k}'})/({m_{k}-n_{k}}) +1)\log B_{k}}{n}\\ &\leq \frac{(\sum_{l=1}^{k-1}(t_{l}+2)+1)\log B_{k}}{m_{k}'}+\frac{\log B_{k}}{m_{k}-n_{k}}+\frac{\log B_{k}}{m_{k}}\to 0. \end{align*} $$
So there exists
$K\in \mathbb {N}$
, such that for
$k\geq K$
and
$n\geq m_{K}',$
$$ \begin{align} (B_{k}+2)^{2\Delta_{n}+4}<2^{(n-1)\varepsilon}. \end{align} $$
For
$\overline {x_{1}}=f(x_{1})$
and
$\overline {x_{2}}=f(x_{2})$
in
$f(E),$
we assume without loss of generality that
$$ \begin{align*} |\overline{x_{1}}-\overline{x_{2}}|<\frac{1}{2(B_{K}+2)^{2}q^{2}_{m_{K}'}(\overline{x_{1}})}; \end{align*} $$
otherwise,
$|f^{-1}(\overline {x_{1}})-f^{-1}(\overline {x_{2}})|<C|\overline {x_{1}}-\overline {x_{2}}|^{1-\varepsilon }$
for some
$C,$
as desired. Let
$$ \begin{align*}n=\min\{j\geq 1\colon a_{j+1}(\overline{x_{1}})\neq a_{j+1}(\overline{x_{2}})\}.\end{align*} $$
By Lemma 2.2, we have
$m_{k}'\leq n<m_{k+1}'$
for some
$k\geq K$
and
$n+1<n_{k+1}'.$
Assume that
$\overline {x_{1}}>\overline {x_{2}}$
and n is even (the same conclusion can be drawn for the remaining cases). There exist
$1\leq \tau _{n+1}(\overline {x_{1}})<\sigma _{n+1}(\overline {x_{2}}) \leq B_{k}+1$
such that
$\overline {x_{1}}\in I_{n+1}(a_{1},\ldots ,a_{n},\tau _{n+1}(\overline {x_{1}}))$
,
$\overline {x_{2}}\in I_{n+1}(a_{1},\ldots ,a_{n},\sigma _{n+1}(\overline {x_{2}})).$
Combining Lemma 2.3 and the construction yields that
$\overline {x_{1}}-\overline {x_{2}}$
is greater than the length of basic interval
$I_{n+2}(a_{1},\ldots ,a_{n},\sigma _{n+1}(\overline {x_{2}}),B_{k}+1).$
This implies that
$$ \begin{align*} \overline{x_{1}}-\overline{x_{2}}\geq |I_{n+2}(a_{1},\ldots,a_{n},\sigma_{n+1}(\overline{x_{2}}),B_{k}+1)| \geq \frac{1}{2(B_{k}+2)^{4}q^{2}_{n}}. \end{align*} $$
Furthermore, noting that
$f^{-1}(\overline {x_{1}}), f^{-1}(\overline {x_{2}})\in I_{n-\Delta _{n}}(c_{1},\ldots ,c_{n-\Delta _{n}}),$
where
$(c_{1},\ldots , c_{n-\Delta _{n}})$
is obtained by eliminating all the terms
$a_i$
with
$i\in \mathbf {K}$
from
$(a_1,\ldots ,a_n)$
, we conclude that
$$ \begin{align*} |f^{-1}(\overline{x_{1}})-f^{-1}(\overline{x_{2}})|&\leq |I_{n-\Delta_{n}}(a_{1},\ldots,a_{n-\Delta_{n}})| \\&\leq \frac{1}{q^{2}_{n-\Delta_{n}}} \leq(B_{k}+2)^{2\Delta_{n}}\frac{1}{q^{2}_{n}} \leq2|\overline{x_{1}}-\overline{x_{2}}|^{1-\varepsilon}, \end{align*} $$
where the penultimate inequality follows by equation (4.6). This completes the proof.
Now we deduce that
$\dim _{H}E(\hat {\nu },\infty )\geq ({1-\varepsilon })/{2}$
by Lemma 2.5. Letting
$\varepsilon \to 0$
, we establish that
$\dim _{H}E(\hat {\nu },\infty )\geq \tfrac 12$
when
$0<\hat \nu <1$
. A slight change in the proof actually shows that the estimate
$\dim _{H}E(\hat {\nu },\infty )\geq \tfrac 12$
also works for
$\hat \nu =0$
or
$1$
. Indeed, when
$\hat {\nu }=0,$
we may take
$$ \begin{align*} n_{k}=2^{2^{2k}},\quad m_{k}=n_{k}^{2},\quad B_{k}=2^{n_{k}}; \end{align*} $$
when
$\hat {\nu }=1,$
we may take
$$ \begin{align*} m_{k}=(k+1)!,\quad n_{1}=1,\quad n_{k+1}=m_{k}+\frac{m_{k}}{\log m_{k}},\quad B_{k}=\lfloor2^{\sqrt{m_{k}}}\rfloor. \end{align*} $$
Remark 4.6. Combining Remark 3.5 and the fact
$$ \begin{align*} E(\hat{\nu},\nu)\subseteq E_{\ast}(\hat{\nu},\nu)=\{x\in[0,1]\colon \hat{\nu}(x)\ge\hat{\nu},~\nu(x)=\nu\}, \end{align*} $$
we have
$\dim _{H}E_{\ast }(\hat {\nu },\nu )=s(\xi ,{\tau (i)}).$
Remark 4.7. By Lagrange’s theorem, any quadratic irrational number
$y_1$
is represented by a periodic continued fraction expansion, that is,
$$ \begin{align*}{y_1=[a_1(y_1),a_2(y_1),\ldots,a_{k_0}(y_1),\overline{a_{k_{0}+1}(y_1),\ldots,a_{k_{0}+h}(y_1)}]}\end{align*} $$
for some positive integers
$k_{0}$
and
$h.$
By Lemma 2.1(2), we readily check that the limit
$\lim _n (({\log q_{n}(y_1)})/{n})$
exists, denoted by
$\log g(y_1).$
However, unlike in the special
$y=[i,i,\ldots ]$
, we cannot obtain a closed-form expression for
$\log g(y_1)$
.
In Theorem 1.3, we replace
$y=[i,i,\ldots ]$
by a general quadratic irrational number
$y_1$
and consider the Hausdorff dimension of the corresponding set
$E(\hat {\nu },\nu ).$
We obtain that
$$ \begin{align*} \dim_{H}E(\hat{\nu},\nu) =\left\{\!\begin{array}{ll} 1 & \ \ \ \text{if }~ \nu=0,\\ s\bigg(\dfrac{\nu^{2}}{(1+\nu)(\nu-\hat{\nu})},g(y_1)\bigg) & \ \ \ \text{if }~ 0\le\hat{\nu}\le\dfrac{\nu}{1+\nu}<\nu\leq\infty, \\ 0 & \ \ \ \text{otherwise,} \end{array} \right. \end{align*} $$
where
$s ({\nu ^{2}}/({(1+\nu )(\nu -\hat {\nu })}),g(y_1))$
is the solution to
$$ \begin{align*}{P\bigg(T,-s\bigg(\log |T'|+\frac{\alpha}{1-\alpha}\log{g(y_1)}\bigg)\bigg)=0}\end{align*} $$
with
$\alpha = {\nu ^{2}}/({(1+\nu )(\nu -\hat {\nu })}).$
The proof can be established following the same line as for the original theorem, with some crucial modifications as follows.
-
(1) In the proof of Lemma 3.2: two sequences
$\{n_{k}'\}_{k\geq 1}$
and
$\{m_{k}'\}_{k\geq 1}$
are modified as
$$ \begin{align*} m_{0}'=0,~ n_k'&=\min\{n\ge m_{k-1}'\colon a_{n+1}(x)=a_1(y_1)\},\\ m_k'&=\max\{n\ge n_k'\colon (a_{n_k'+1}(x),\ldots,a_{n}(x))=(a_1(y_1),\ldots,a_{n-n_k'}(y_1))\}. \end{align*} $$
The partial quotient
$a_{n}(y_1)$
of
$y_1$
is bounded uniformly in
$n,$
which guarantees that equations (3.1) and (3.2) hold.The limit
$$ \begin{align*}{\lim_{n\to\infty}\frac{-\log|I_n(y_1)|}{2n}=\lim_{n\to\infty}\frac{\log q_n(y_1)}{n}=\log g(y_1).}\end{align*} $$
-
(2) For
$B> \max \{a_1(y_1),\ldots ,a_{k_0+h}(y_1)\},$
the cantor-like subset
$E(B)$
is modified as
$$ \begin{align*} \begin{aligned} &\{x\in[0,1)\colon 1\leq a_{n}(x)\leq B, (a_{n_{k}+1}(x),\ldots,a_{m_{k}}(x))\\ &\quad =(a_1(y_1),\ldots,a_{m_{k}-n_{k}}(y_1)), n\geq 1, k\geq 1\}. \end{aligned} \end{align*} $$
5 Proofs of Theorems 1.1 and 1.2
In this section, we study the Hausdorff dimensions of the following sets:
$$ \begin{align*} E(\hat{\nu})=\{x\in[0,1)\colon \hat{\nu}(x)=\hat{\nu}\},\end{align*} $$
$$ \begin{align*} {\mathcal{U}(\hat{\nu})}= &\{x\in[0,1)\colon \text{for all } N\gg1, \text{there exists } n\in[1,N],\\ & \text{such that } |T^{n}(x)-y|<|I_N(y)|^{\hat{\nu}}\}. \end{align*} $$
A direct corollary of the definition is: if
$\hat {\nu }_1>\hat {\nu }\ge 0$
,
$$ \begin{align*} E(\hat{\nu}_1)\subseteq {\mathcal{U}(\hat{\nu})}\subseteq \{x\in[0,1)\colon \hat{\nu}(x)\ge\hat{\nu}\}. \end{align*} $$
Hence, the proofs of Theorems 1.1 and 1.2 will be divided into two parts: the upper bound of
$\dim _{H}\{x\in [0,1)\colon \hat {\nu }(x)\ge \hat {\nu }\}$
and the lower bound of
$\dim _{H}E(\hat {\nu })$
.
Lemma 3.1 combined with the fact
$E(0,0)\subset E(0)$
implies that the sets
$E(0), {\mathcal {U}(0)}$
, and
$\{x\in [0,1)\colon \hat {\nu }(x)\ge 0\}$
are of full Lebesgue measure; we only need to deal with the case
$\hat {\nu }>0.$
We start with the upper bound of
$\dim _{H}\{x\in [0,1)\colon \hat {\nu }(x)\ge \hat {\nu }\}.$
Lemma 5.1. If
$0<\hat {\nu }\le 1,$
we have
$$ \begin{align*} \dim_{H}\{x\in[0,1)\colon \hat{\nu}(x)\ge\hat{\nu}\}\le s\bigg(\frac{4\hat{\nu}}{(1+\hat{\nu})^{2}},{\tau(i)}\bigg). \end{align*} $$
If
$\hat {\nu }>1,$
then
$\dim _{H}\{x\in [0,1)\colon \hat {\nu }(x)\ge \hat {\nu }\}=0.$
Proof. For
$\varepsilon>0$
small enough, we define
$$ \begin{align*} E_\varepsilon(\hat{\nu},\nu) = \bigg\{x\in[0,1)\colon \hat{\nu}(x)\ge\hat{\nu}, \nu\le\nu(x)\le\frac{\nu+\varepsilon}{1-\varepsilon}\bigg\}. \end{align*} $$
Since
$$ \begin{align*} \{x\in[0,1)\colon \hat{\nu}(x)\ge\hat{\nu}\}\subseteq\bigcup_{\nu\in \mathbb{Q}^{+}}E_\varepsilon(\hat{\nu},\nu),\end{align*} $$
where
$\mathbb {Q}^{+}$
denotes the set of positive rational numbers, we have
$$ \begin{align*}\dim_{H}\{x\in[0,1)\colon \hat{\nu}(x)\ge\hat{\nu}\}\le\sup\ \{\dim_{H}E_\varepsilon(\hat{\nu},\nu)\colon \nu\in \mathbb{Q}^{+}\}. \end{align*} $$
If
$\hat {\nu }>1$
, the set
$E_\varepsilon (\hat {\nu },\nu )$
is at most countable by Lemmas 3.2 and 3.3, and
$\dim _{H}\{x\in [0,1)\colon \hat {\nu }(x)\ge \hat {\nu }\}=0.$
If
$0<\hat {\nu }\le 1,$
we obtain
$$ \begin{align*}\dim_{H}E_\varepsilon(\hat{\nu},\nu)\leq s\bigg(\frac{\nu^{2}}{(\nu-\hat{\nu}+\hat{\nu}\varepsilon+\varepsilon)(1+\nu)},{\tau(i)}\bigg)\end{align*} $$
in much the same way as the proof for the upper bound of
$\dim _{H}E(\hat {\nu },\nu )$
; we sketch the main differences as follows.
In Lemma 3.3,
$\limsup (({m_{k}-n_{k}})/{m_{k}})$
is estimated by
$$ \begin{align*} \frac{\nu}{1+\nu}\le\limsup\limits_{k\rightarrow\infty}\frac{m_{k}-n_{k}}{m_{k}}\leq\frac{\nu+\varepsilon}{1+\nu}. \end{align*} $$
Equations (3.4)–(3.7) are replaced by
$$ \begin{align*} \sum_{i=1}^{k}(m_{i}-n_{i}) \ge m_{k}\bigg(\frac{(\nu+\varepsilon)^{2}}{(\nu-\hat{\nu}+\hat{\nu}\varepsilon+\varepsilon)(1+\nu)}-\varepsilon\bigg), \end{align*} $$
$$ \begin{align*}1+\nu\le\limsup_{k\to\infty}\frac{m_k}{n_k}\le\frac{1+\nu}{1-\varepsilon},\end{align*} $$
$$ \begin{align*}\liminf_{k\to\infty}\frac{m_k}{n_{k+1}}\ge\frac{\hat{\nu}(1+\nu)}{\nu+\varepsilon},\end{align*} $$
$$ \begin{align*}\liminf_{k\to\infty}\frac{\sum_{i=1}^{k}(m_i-n_i)}{m_{k+1}} \ge \frac{\hat{\nu}(\nu+\varepsilon)(1-\varepsilon)}{(\nu-\hat{\nu}+\hat{\nu}\varepsilon+\varepsilon)(1+\nu)},\end{align*} $$
respectively. The set
$\Omega $
is replaced by
$$ \begin{align*} \bigg\{(\{n_{k}\},\{m_{k}\})\colon \liminf_{k\to\infty}\frac{m_{k}-n_{k}}{n_{k+1}}\ge\hat{\nu},&~\nu\leq\limsup_{k\to\infty} \frac{m_{k}-n_{k}}{n_{k}}\leq\frac{\nu+\varepsilon}{1-\varepsilon},\\ &n_k<m_k<n_{k+1} ~\text {for all} ~k\geq 1 \bigg\}. \end{align*} $$
Finally, since the function
${\nu ^{2}}/({(\nu -\hat {\nu }+\hat {\nu }\varepsilon +\varepsilon )(1+\nu )})$
of
$\nu $
attains its minimum at
$\nu = ({2\hat {\nu }-2(\hat {\nu }+1)\varepsilon })/({1-\hat {\nu }+(\hat {\nu }+1)\varepsilon })$
, we have by Lemma 2.13(2) that
$$ \begin{align*} \dim_{H}\{x\in[0,1)\colon \hat{\nu}(x)\ge\hat{\nu}\} &\leq \sup \bigg\{s\bigg(\frac{\nu^{2}}{(\nu-\hat{\nu}+\hat{\nu}\varepsilon+\varepsilon)(1+\nu)},{\tau(i)}\bigg)\colon \nu \in\mathbb{Q}^{+} \bigg\}\\ &\leq s\bigg(\frac{4 (\hat{\nu}-(\hat{\nu}+1)\varepsilon)}{(1+\hat{\nu}-(\hat{\nu}+1)\varepsilon)^{2}},{\tau(i)}\bigg) \rightarrow s\bigg(\frac{4\hat{\nu}}{(1+\hat{\nu})^{2}},{\tau(i)}\bigg) \end{align*} $$
as
$\varepsilon \to 0$
.
We now deal with the lower bound of the
$\dim _{H}E(\hat {\nu })$
for
$0<\hat {\nu }\le 1.$
Lemma 5.2. For
$0<\hat {\nu }\le 1,$
we have
$\dim _{H}E(\hat {\nu })\ge s(4\hat {\nu }/(1+\hat {\nu })^{2},\tau (i)).$
Proof. Noting that
$E(\hat {\nu },\nu )$
is a subset of
$E(\hat {\nu })$
for
$\nu \ge {\hat {\nu }}/({1-\hat {\nu }})$
(or
$\hat {\nu }\le {\nu }/({1+\nu })$
), we have
$$ \begin{align*} \dim_{H}E(\hat{\nu})\geq \dim_{H}E(\hat{\nu},\nu)=s\bigg(\frac{\nu^{2}}{(1+\nu)(\nu-\hat{\nu})},{\tau(i)}\bigg). \end{align*} $$
Since the function
${\nu ^{2}}/({(1+\nu )(\nu -\hat {\nu })})$
is continuous for
$\nu \in [{\hat {\nu }}/({1-\hat {\nu }}),\infty ],$
and attains its minimum at
$\nu = {2\hat {\nu }}/({1-\hat {\nu }}),$
so by Lemma 2.13(2), we have
$$ \begin{align*} \dim_{H}E(\hat{\nu})\geq\dim_{H}E\bigg(\hat{\nu}, \frac{2\hat{\nu}}{1- \hat{\nu}}\bigg)=s\bigg(\frac{4\hat{\nu}}{(1+\hat{\nu})^{2}},{\tau(i)}\bigg).\\[-42pt] \end{align*} $$
6 Proof of Theorem 1.5
In this section, we prove Theorem 1.5 by considering the upper and lower bounds of
$\dim _{H} (F(\alpha )\cap G(\beta ))$
. Recall that
$$ \begin{align*} F(\alpha)&=\bigg\{x\in[0,1)\colon \liminf_{n\to\infty}\frac{R_{n}(x)}{n}=\alpha\bigg\},\\ G(\beta)&=\bigg\{x\in[0,1)\colon \limsup_{n \to\infty}\frac{R_{n}(x)}{n}=\beta\bigg\}. \end{align*} $$
The proof of Theorem 1.5 goes along the lines as that of Theorem 1.3 with some minor modifications.
Noting that
$\{x\in [0,1)\colon \lim _{n\to \infty } ({R_{n}(x)}/{\log _{({\sqrt {5}+1})/{2}} n}) =\tfrac 12 \}\subset F(0)\cap G(0),$
we have
$F(0)\cap G(0)$
is of full Lebesgue measure. Furthermore, since
$F(\alpha )\cap G(1)\subset G(1)$
and
$F(0)\cap G(\beta )\subset G(\beta )$
, we have
$\dim _{H}F(\alpha )\cap G(1)\leq s(1,\tau (1))$
and
$\dim _{H} (F(0)\cap G(\beta ))\le s(\beta ,\tau (1))$
. We only need to consider the case
$0<\alpha \le \beta <1.$
6.1 Upper bound of
$\dim _{H} (F(\alpha )\cap G(\beta ))$
For
$x=[a_{1}(x),a_{2}(x),\ldots ]\in F(\alpha )\cap G(\beta )$
with non-periodic continued fraction expansion, we associate x with two sequences
$\{n_k\}$
and
$\{m_k\}$
that satisfy the following properties:
-
(1)
$n_k<m_k<n_{k+1}<m_{k+1}$
for
$k\ge 1$
; -
(2)
$a_{n_k}(x)=\cdots =a_{m_k}(x)$
for
$k\ge 1;$
-
(3)
$\liminf _{k\to \infty } (({m_k-n_k})/{n_{k+1}}) = {\alpha }/({1-\alpha }), \limsup _{k\to \infty }(({m_k-n_k})/{m_k})=\beta ;$
-
(4) the sequence
$\{m_k\}$
grows exponentially; -
(5) write
$\xi = ({\beta ^{2}(1-\alpha )})/({\beta -\alpha })$
. For any
$\varepsilon>0$
, there exist infinitely many k such that
$$ \begin{align*} \sum_{i=1}^{k}(m_{i}-n_{i}+1)\ge m_{k}(\xi-\varepsilon). \end{align*} $$
To this end, we define two ascending sequences
$\{n_{k}'\}$
and
$\{m_{k}'\}$
as follows:
$$ \begin{align*} n_{1}'=1,\quad &a_{n_{k}'}(x)= a_{n_{k}'+1}(x)= \cdots =a_{m_{k}'}(x)\neq a_{m_{k}'+1}(x), n_{k+1}'=m_{k}'+1. \end{align*} $$
Since
$\beta =\limsup R_n(x)/n>0$
, we have that
$\limsup _{k\to \infty }(m_{k}'-n_{k}')= +\infty $
, which enables us to pick a non-decreasing subsequence of
$\{(n_k', m_k')\}_{k\geq 1}\colon $
, put
$(n_{1},m_{1})=(n^{\prime }_{1},m^{\prime }_{1});$
having chosen
$(n_{k}, m_k)=(n_{j_{k}}', m_{j_{k}}')$
for
$k\ge 1$
, we set
$j_{k+1}=\min \{j>j_k\colon m_{j}'-n_{j}'> m_{k}-n_{k}\},$
and put
$(n_{k+1},m_{k+1})=(n_{j_{k+1}}', m_{j_{k+1}}')$
.
We readily check the following properties.
-
(a) The sequence
$\{m_{k}-n_{k}\}_{k\geq 1}$
is non-decreasing and
$\lim _{k\to \infty } (m_{k}-n_{k})= +\infty .$
-
(b) If
$m_{k}\leq n\leq n_{k+1}+(m_{k}-n_{k})$
for
$k\geq 1$
, then
$R_{n}(x)=m_{k}-n_{k}+1$
and
$$ \begin{align*} \frac{m_{k}-n_{k}+1}{n_{k+1}+(m_{k}-n_{k})}\leq \frac{R_{n}(x)}{n}\leq \frac{m_{k}-n_{k}+1}{m_{k}}. \end{align*} $$
-
(c) If
$n_{k+1}+(m_{k}-n_{k})<n< m_{k+1}$
for
$k\geq 1$
, then
$R_{n}(x)=n-n_{k+1}+1$
, and
$$ \begin{align*} \frac{m_{k}-n_{k}+1}{n_{k+1}+(m_{k}-n_{k})}\leq \frac{R_{n}(x)}{n}\leq \frac{m_{k+1}-n_{k+1}+1}{m_{k+1}}. \end{align*} $$
Properties (a) and (b) imply
$$ \begin{align} \alpha=\liminf_{n\to\infty}\frac{R_{n}(x)}{n} =\liminf_{k\rightarrow\infty}\frac{m_{k}-n_{k}+1}{n_{k+1}+(m_{k}-n_{k})} \end{align} $$
and
$$ \begin{align} \beta=\limsup_{n\to\infty}\frac{R_{n}(x)}{n} =\limsup_{k\rightarrow\infty}\frac{m_{k+1}-n_{k+1}+1}{m_{k+1}}. \end{align} $$
From equation (6.1), we obtain that
$$ \begin{align} \liminf_{k\to\infty}\frac{R_{n_{k+1}}(x)}{n_{k+1}}=\liminf_{k\to\infty}\frac{m_{k}-n_{k}+1}{n_{k+1}} =\frac{\alpha}{1-\alpha}, \end{align} $$
which combined with equation (6.2) yields
$\alpha /({1-\alpha })\le \beta $
, or equivalently
$\alpha \leq {\beta }/({1+\beta })$
. Thus, the set
$F(\alpha )\cap G(\beta )$
is at most countable when
$\alpha> {\beta }/({1+\beta })$
. Moreover, equation (6.3) implies that
$\{m_{k}\}_{k\geq 1}$
grows at least exponentially, namely, there exists
$C>0$
, independent of
$x,$
such that
$k \leq C\log {m_{k}}$
for k large enough. Further, by equations (6.2) and (6.3), we also have
$$ \begin{align*} \liminf_{k\to\infty}\frac{m_{k}}{n_{k+1}} \ge \liminf_{k\to\infty}\frac{m_{k}-n_{k}}{n_{k+1}} \cdot\liminf_{k\to\infty}\frac{m_{k}}{m_{k}-n_{k}} =\frac{\alpha}{\beta(1-\alpha)}, \end{align*} $$
which combined with the Stolz–Cesàro theorem implies that
$$ \begin{align*} \begin{split} \liminf_k\frac{\sum_{i=1}^{k-1}(m_i-n_i+1)}{m_{k}} \ge \frac{\alpha\beta(1-\beta)}{\beta-\alpha}, \end{split} \end{align*} $$
and thus, for
$\varepsilon>0$
and k large enough,
$$ \begin{align*} \sum_{i=1}^{k}(m_{i}-n_{i}+1)\geq \bigg(\frac{\alpha\beta(1-\beta)}{\beta-\alpha}-\frac{\varepsilon}{2}\bigg)m_{k}+(m_{k}-n_{k}+1). \end{align*} $$
Since there exist infinitely many k such that
$$ \begin{align} m_{k}-n_{k}+1\ge m_{k}\bigg(\beta-\frac{\varepsilon}{2}\bigg), \end{align} $$
property (5) holds for such k.
6.2 Covering of
$F(\alpha )\cap G(\beta )$
We collect all sequences
$(\{n_{k}\}, \{m_{k}\})$
associated with
$x\in F(\alpha )\cap G(\beta )$
as above to form a set
$$ \begin{align*} \Omega= \{(\{n_{k}\},\{m_{k}\})\colon \text{Properties } (1) ~\text{and} ~(3) \text{ are fulfilled}\}. \end{align*} $$
For
$(\{n_{k}\},\{m_{k}\})\in \Omega $
and
$\{b_{k}\}\subset \mathbb N$
, write
$$ \begin{align*} H(\{n_{k}\},\{m_{k}\})&= \{x\in[0,1)\colon \text{Property } (2) \text{ is fulfilled}\},\\ \Lambda_{k, m_k} &= \{(n_1,m_1; \ldots; n_{k-1},m_{k-1};n_{k})\colon n_{1}<m_{1}<\cdots<m_{k-1}<n_{k},\\ &\qquad \text{equation~(6.4)}\text{ holds}\},\\ \mathcal{D}_{n_1,m_1;\ldots;n_{k}, m_{k}}(\{b_{k}\})&= \{(\sigma_{1},\ldots,\sigma_{m_{k}})\in \mathbb{N}^{m_{k}}\colon \sigma_{n_{j}}=\cdots=\sigma_{m_{j}}=b_{j}\\ &\qquad\text{for all }1\leq j\leq k\}. \end{align*} $$
We obtain a covering of
$ F(\alpha )\cap G(\beta )$
:
$$ \begin{align*} \begin{aligned} F(\alpha)\cap G(\beta) &\subseteq \bigcup_{(\{n_{k}\},\{m_{k}\})\in \Omega}H(\{n_{k}\},\{m_{k}\}) \\ &\subseteq\bigcap_{K=1}^{\infty} \bigcup_{k=K}^{\infty}\bigcup_{m_{k}= e^{{k}/{C}}}^{\infty} \bigcup_{(n_{1},m_{1},\ldots,m_{k-1},n_{k})\in\Lambda_{k, m_k}} \bigcup_{(b_{1},\ldots,b_{k})\in \mathbb{N}^{k}} \\ &\quad\times\bigcup_{(a_{1},\ldots,a_{m_{k}})\in \mathcal{D}_{n_1,m_1;\ldots;n_{k}, m_{k}}(\{b_{k}\})}I_{m_{k}}(a_{1},\ldots,a_{m_{k}}). \end{aligned} \end{align*} $$
Writing
$t=s(\xi -\varepsilon ,{\tau (1)})+ ({\varepsilon }/{2})$
, we estimate the
$(t+ ({\varepsilon }/{2}))$
-dimensional Hausdorff measure of
$F(\alpha )\cap G(\beta )$
. Setting
$\psi (m_{k})=m_{k}-\sum _{i=1}^{k}(m_{i}-n_{i}+1),$
we have
$M=512\sum _{i=1}^{\infty } (\tau (i))^{-2t}.$
For sufficiently large k, we first have the following estimate:
$$ \begin{align} & \sum\limits_{b_{k}=1}^{\infty}\cdots\sum\limits_{b_{1}=1}^{\infty}\sum\limits_{(a_{1},\ldots,a_{m_{k}})\in \mathcal{D}_{n_{k}, m_{k}}(\{b_{k}\})}|I_{m_{k}}(a_{1},\ldots,a_{m_{k}})|^{t+ ({\varepsilon}/{2})}\nonumber\\[-1.5pt]&\quad\le\sum\limits_{b_{k}=1}^{\infty}\cdots\sum\limits_{b_{1}=1}^{\infty}\sum\limits_{a_{1},\ldots,a_{\psi(m_{k})}\in\mathbb{N}} 4^{k(t+ ({\varepsilon}/{2}))} \bigg(\frac{1}{q_{\psi(m_{k})}(a_{1},\ldots, a_{\psi(m_{k})})}\bigg)^{2t+\varepsilon}\nonumber\\[-1.5pt]&\qquad\times\prod_{j=1}^{k}\bigg(\frac{1}{q_{m_j-n_j+1}(b_j,\ldots,b_j)}\bigg)^{2t+\varepsilon}\nonumber\\[-1.5pt]&\quad\le4^{k(t+ ({\varepsilon}/{2}))} \sum\limits_{a_{1},\ldots,a_{\psi(m_{k})}\in\mathbb{N}}\bigg(\frac{1}{q_{\psi(m_{k})}(a_{1},\ldots,a_{\psi(m_{k})})}\bigg)^{2t+\varepsilon}\nonumber\\[-1.5pt]&\qquad\times\prod_{j=1}^{k} \bigg(\sum_{i=1}^{\infty}\bigg({1}/({q_{m_j-n_j+1}) (i,\ldots,i)}\bigg)^{2t+\varepsilon}\bigg)\nonumber\\[-1.5pt]&\quad\le(4^{t+({\varepsilon}/{2})}M)^{k} \sum\limits_{a_{1},\ldots,a_{\psi(m_{k})}\in\mathbb{N}}\bigg(\frac{1}{q_{\psi(m_{k})}(a_{1},\ldots,a_{\psi(m_{k})})}\bigg)^{2t+\varepsilon}\nonumber\\[-1.5pt]& \qquad \times \prod_{j=1}^{k} \bigg(\frac{1}{q_{m_j-n_j+1}(1,\ldots,1)}\bigg)^{2t+\varepsilon}\nonumber\\&\quad\le(16^{t+ ({\varepsilon}/{2})}M)^{k}\sum\limits_{a_{1},\ldots,a_{\psi(m_{k})}\in \mathbb{N}}\bigg(\frac{1}{q_{m_{k}}(a_{1},\ldots,a_{\psi(m_{k})},1,\ldots,1)}\bigg)^{2t+\varepsilon}\nonumber\\ &\quad\le(16^{t+ ({\varepsilon}/{2})}M)^{k}\nonumber\\ & \qquad \times \sum\limits_{a_{1},\ldots,a_{m_{k}-\lfloor m_{k}(\xi-\varepsilon)\rfloor}\in \mathbb{N}}\bigg(\frac{1}{q_{m_{k}}(a_{1},\ldots,a_{m_{k}-\lfloor m_{k}(\xi-\delta)\rfloor},1,\ldots,1)}\bigg)^{2s_{m_{k}}(\xi-\varepsilon,{\tau(1)})+\varepsilon}\nonumber\\&\quad\le(16^{t+ ({\varepsilon}/{2})}M)^{k}\bigg(\frac{1}{2}\bigg)^{(({m_{k}-1})/{2})\varepsilon}, \end{align} $$
where the third inequality holds since
$$ \begin{align*} \begin{split} \sum\limits_{i=1}^{\infty} \bigg(\frac{1}{q_{n}(i,\ldots,i)}\bigg)^{2t+\varepsilon} &=\bigg(\frac{1}{q_{n}(1,\ldots,1)}\bigg)^{2t+\varepsilon} \sum\limits_{i=1}^{\infty}\bigg(\frac{q_{n}(1,\ldots,1)}{q_{n}(i,\ldots,i)}\bigg)^{2t+\varepsilon}\\ &\le\bigg(\frac{1}{q_{n}(1,\ldots,1)}\bigg)^{2t+\varepsilon} \sum\limits_{i=1}^{\infty}\bigg(\frac{4\tau(1)}{\tau(i)}\bigg)^{2t+\varepsilon}; \end{split} \end{align*} $$
the penultimate one follows from equations (6.4) and (3.7), and the last one is by Remark 2.11 and Lemma 2.1(1).
Hence,
$$ \begin{align*} \begin{split} &\mathcal{H}^{t+ ({\varepsilon}/{2})} (F(\alpha)\cap G(\beta)) \leq \liminf_{K\to\infty}\sum\limits_{k=K}^{\infty}\sum_{m_{k}= e^{{k}/{C}}}^{\infty} \sum_{(n_{1},m_{1},\ldots,m_{k-1},n_{k})\in\Lambda_{k, m_k}}\sum\limits_{b_{k}=1}^{\infty}\cdots \sum\limits_{b_{1}=1}^{\infty}\\ &\qquad\times\sum\limits _{(a_{1},\ldots,a_{m_{k}})\in\mathcal{D}_{n_{k}, m_{k}}(\{b_{k}\})}|I_{m_{k}}(a_{1},\ldots,a_{m_{k}})|^{t+ ({\varepsilon}/{2})}\\ &\quad\overset{({6.5})}{\leq}\liminf_{K\to\infty}\sum\limits_{k=K}^{\infty}\sum\limits_{m_{k}=e^{{k}/{C}}}^{\infty} \sum_{n_{k}=1}^{m_{k}}\sum_{m_{k-1}=1}^{n_{k}}\cdots\sum\limits_{m_{1}=1}^{n_{2}} \sum\limits_{n_{1}=1}^{m_{1}}(16^{t+ ({\varepsilon}/{2})}M)^{k}\bigg(\frac{1}{2}\bigg)^{(({m_{k}-1})/{2})\varepsilon}\\ &\quad\leq\liminf_{K\to\infty}\sum\limits_{k=K}^{\infty} \sum\limits_{m_{k}=e^{{k}/{C}}}^{\infty}(16^{t + ({\varepsilon}/{2})}Mm_{k})^{2C\log m_{k}}\bigg(\frac{1}{2}\bigg)^{(({m_{k}-1})/{2})\varepsilon}\\ &\quad\leq\liminf_{K\to\infty}\sum\limits_{k=K}^{\infty} \sum\limits_{m_{k}=e^{{k}/{C}}}^{\infty}\bigg(\frac{1}{2}\bigg)^{(({m_{k}-1})/{4})\varepsilon} \leq \frac{1}{1-(\frac{1}{2})^{{\varepsilon}/{4}}}\sum\limits_{k=1}^{\infty} \bigg(\frac{1}{2^{\varepsilon}}\bigg)^{({e^{{k}/{C}}-1})/{4}} < +\infty, \end{split} \end{align*} $$
where the penultimate one holds since
$(16^{t+ ({\varepsilon }/{2})}Mk)^{2C\log k}<2^{(({k-1})/{4})\varepsilon }$
for k large enough.
6.3 Lower bound of
$\dim _{H} (F(\alpha )\cap G(\beta ))$
Note that
$F(\alpha )\cap F(\beta )$
is at most countable for
$\alpha> {\beta }/({1+\beta })$
; we assume that
$\alpha \le {\beta }/({1+\beta }).$
Let
$\{n_{k}\}$
and
$\{m_{k}\}$
be two strictly increasing sequences satisfying the following conditions:
-
(1)
$(m_{k}-n_{k})\leq (m_{k+1}-n_{k+1})$
and
$n_{k}< m_{k}< n_{k+1}$
for
$k\geq 1$
; -
(2)
$\lim _{k\to \infty }(({m_{k}-n_{k}})/{n_{k+1}}) = {\alpha }/({1-\alpha })$
; -
(3)
$\lim _{k\to \infty } (({m_{k}-n_{k}})/{m_{k}}) = \beta $
.
With the help of these sequences, we construct a Cantor subset of
$F(\alpha )\cap G(\beta )$
to provide a lower bound estimate of its dimension. The set
$E(B)$
is defined in much the same way as in §4.2, the only difference being that the digit i is replaced by the digit
$1$
; the mapping f is defined in exactly the same way. It remains to verify that the set
$f (E(B))$
is a subset of
$F(\alpha )\cap G(\beta ).$
Lemma 6.1. For any
$B\ge 2, f (E(B))\subset F(\alpha )\cap G(\beta ).$
Proof. Recall the definitions of
$$ \begin{align*}t_{k}=\max \{t\in \mathbb{N}\colon m_{k}+t(m_{k}-n_{k})< n_{k+1}\},\end{align*} $$
$$ \begin{align*}m_{k}'=m_{k}+\sum_{l=1}^{k-1}(t_{l}+2),\quad n_{k}'=n_{k}+\sum_{l=1}^{k-1}(t_{l}+2).\end{align*} $$
We know that
$$ \begin{align*} \lim_{k\to\infty}\frac{\sum_{l=1}^{k}(t_{l}+2)}{n_{k+1}}=0,\quad \lim_{k\to\infty}\frac{n_k}{n_{k}'}=\lim_{k\to\infty}\frac{m_k}{m_k'}=1. \end{align*} $$
For
$x\in f(E(B))$
, and
$m_{k}'\leq n<m_{k+1}'$
with
$k\in \mathbb {N},$
we have that
$$ \begin{align*} R_{n}(x)=\left\{\!\begin{array}{ll} m_{k}-n_{k}& \ \text{if } m_{k}'\leq n\leq n_{k+1}'+m_{k}-n_{k}, \\ n-n_{k+1}' & \ \text{if } n_{k+1}'+m_{k}-n_{k}< n< m_{k+1}' .\end{array} \right. \end{align*} $$
Observing that for
$n_{k+1}'+m_{k}-n_{k}< n< m_{k+1}',$
$$ \begin{align*} \frac{m_{k}-n_{k}}{n_{k+1}'+m_{k}-n_{k}}\leq\frac{R_{n}(x)}{n}=\frac{n-n_{k+1}'}{n}\leq\frac{m_{k+1}-n_{k+1}}{m_{k+1}'}, \end{align*} $$
we deduce that
$$ \begin{align*} \liminf_{n\to\infty}\frac{R_{n}(x)}{n} =\lim_{k\to\infty}\frac{R_{n_{k+1}'+m_{k}-n_{k}}(x)}{n_{k+1}'+m_{k}-n_{k}} =\lim_{k\to\infty}\frac{m_{k}-n_{k}}{n_{k+1}+m_{k}-n_{k}} =\alpha \end{align*} $$
and
$$ \begin{align*} \limsup_{n\to\infty}\frac{R_{n}(x)}{n} = \lim_{k\to\infty}\frac{m_{k+1}-n_{k+1}}{m_{k+1}'} = \lim_{k\to\infty}\frac{m_{k+1}-n_{k+1}}{m_{k+1}} =\beta. \end{align*} $$
Hence,
$x\in F(\alpha )\cap G(\beta )$
.
7 Proof of Theorem 1.6
The proof of Theorem 1.6 will be divided into two parts according as
$\alpha =0$
or
$0<\alpha \le 1.$
We first note that
$F(\alpha )\cap G(\beta )$
is at most countable for
$\alpha>\tfrac 12\ge {\beta }/({1+\beta })$
by equations (6.2) and (6.3). Moreover, since
$G(0)\subseteq F(0)$
and
$G(0)$
is of full Lebesgue measure, we have
$\dim _H F(0)=1$
. Hence, we only need to deal with the case
$0<\alpha \le \tfrac 12.$
Lower bound of
$F(\alpha )$
. Since
$F(\alpha )\cap G(\beta )\subseteq F(\alpha )$
for any
$\beta \geq {\alpha }/({1-\alpha })$
, we have
$$ \begin{align*} \dim_{H}F(\alpha)\geq \dim_{H}F(\alpha)\cap G(\beta)=s\bigg(\frac{\beta^{2}(1-\alpha)}{\beta-\alpha},{\tau(1)}\bigg). \end{align*} $$
The function
$({\beta ^{2}(1-\alpha )})/({\beta -\alpha })$
is continuous for
$\beta \in [{\alpha }/({1-\alpha }),1],$
and attains its minimum at the point
$\beta =2\alpha \ge {\alpha }/({1-\alpha }),$
so by Lemma 2.13(2), we obtain
$$ \begin{align*} \dim_{H}F(\alpha)\geq\dim_{H} (F(\alpha)\cap G(2\alpha)) = s(4\alpha(1-\alpha),{\tau(1)}). \end{align*} $$
Upper bound of
$F(\alpha )$
. For
$x\in F(\alpha ),$
there exists
$\beta _{0}\in (0,1]$
such that
$$ \begin{align*} \liminf_{n\to\infty}\frac{R_{n}(x)}{n}=\alpha,\quad \limsup_{n\to\infty}\frac{R_{n}(x)}{n}=\beta_{0}. \end{align*} $$
Then,
$0<\alpha \leq {\beta _{0}}/({1+\beta _{0}}) <\beta _{0}< 1$
or
$\beta _{0}=1$
. If
$0<\alpha \leq {\beta _{0}}/({1+\beta _{0}}) < \beta _{0}< 1$
, then for
$0<\varepsilon < ({\alpha (1-2\alpha )})/({2(1-\alpha )}),$
there exists
$\beta \in \mathbb {Q}^{+}$
such that
$0<\alpha \le {\beta _0}/({1+\beta _0}) \le \beta \leq \beta _{0}\leq \beta +\varepsilon < 1.$
Let
$$ \begin{align*} E_{\alpha,\beta,\epsilon}=\bigg\{x\in [0,1)\colon \liminf_{n\to\infty}\frac{R_{n}(x)}{n}=\alpha, \beta \leq \limsup_{n\to\infty}\frac{R_{n}(x)}{n} \leq \beta + \varepsilon < 1\bigg\}, \end{align*} $$
we have
$$ \begin{align*} F(\alpha)\subseteq \bigg(\bigcup_{\beta\in \mathbb{Q}^{+}}E_{\alpha,\beta,\varepsilon}\bigg)\cup (F(\alpha)\cap G(1)). \end{align*} $$
So
$\dim _{H}F(\alpha )\leq \max \{\tfrac 12, \sup \{\dim _{H}E_{\alpha ,\beta ,\varepsilon }\colon \beta \in \mathbb {Q}^{+}\}\}.$
It remains to estimate the upper bound of
$\dim _{H}E_{\alpha ,\beta ,\varepsilon }.$
Following the same line as the proof for the upper bound of
$\dim _{H} (F(\alpha )\cap G(\beta )),$
we obtain that
$$ \begin{align*}\dim_{H}E_{\alpha,\beta,\varepsilon}\leq s\bigg(\frac{\beta^{2}(1-\alpha)}{\beta-\alpha+\varepsilon},{\tau(1)}\bigg).\end{align*} $$
Thus, since the function
$({\beta ^{2}(1-\alpha )})/({\beta -\alpha +\epsilon })$
with respect to
$\beta $
attains its minimum at
$\beta =2(\alpha -\varepsilon )$
, we have that
$$ \begin{align*} \dim_{H}F(\alpha)&\leq \sup \bigg\{s\bigg(\frac{\beta^{2}(1-\alpha)}{\beta-\alpha+\varepsilon}\bigg)\colon\beta \in \mathbb{Q}^{+} \bigg\} \leq s (4(\alpha-\varepsilon)(1-\alpha),{\tau(1)})\\ &\rightarrow s (4\alpha(1-\alpha),{\tau(1)})\quad \text{as }\varepsilon\to 0. \end{align*} $$
Acknowledgements
This work is supported by NSFC Nos. 12171172 and 12201476. The authors would like to express their gratitude to Professors Bao-Wei Wang and Jian Xu for helpful discussions during the preparation of the paper.
