Proof. Because the cardinalities of the two sets are both $qq'$ , it is enough to show that, for $r\le m, n \le r+qq'-1$ ,

(3.2) $$ \begin{align} mv=nv \ \mathrm{in}\ \mathbb{T}^2 \Longrightarrow m=n. \end{align} $$

Note that $mv=nv$ in $\mathbb {T}^2$ is equivalent to

(3.3) $$ \begin{align} (m-n)p/{q}\in \mathbb{Z} \quad \mathrm{and}\quad (m-n)p'/{q'}\in\mathbb{Z}. \end{align} $$

Because p and q are relatively prime, q divides $m-n$ , and, similarly, $q'$ divides $m-n$ . Note that q and $q'$ are also relatively prime, so we have that $qq'$ divides $m-n$ , which is only possible when $m=n$ , since $|m-n|\le qq'-1$ .

Proof. Define $\mathcal {F}$ to be the set of points that are not $2\tilde {\delta } $ -close to the boundaries of any $R^{i,j}$ , in the following sense: that is,

(3.8) $$ \begin{align} \mathcal{F}=\bigcup_{\substack{0\le i\le q-1\\ 0\le j\le q'-1}} \left\{(x_1,x_2)\in \mathbb{T}^2 \left| \ \begin{aligned} &(i+2\tilde{\delta})/q \le x_1\le (i+1-2\tilde{\delta})/q,\\ &(j+2\tilde{\delta})/q'\le x_2\le (j+1-2\tilde{\delta})/q' \end{aligned}\right. \right\}\!. \end{align} $$

Note that, for $|m|\le |K|N$ , $m\alpha $ is $\tilde {\delta }-$ close to $m(p/q,p'/q')$ : that is,

(3.9) $$ \begin{align} |m\alpha_1-mp/q| &\le|m||\eta|/q \le \tilde{\delta}/q,\nonumber\\ |m\alpha_2-mp'/q'| &\le |m||\eta'|/q'\le \tilde{\delta}/q'. \end{align} $$

Starting from a point x in $\mathcal {F}$ , since the points in $\mathcal {F}$ are $2\tilde {\delta }$ -away from the boundaries of $R^{i,j}$ , the orbit $\{x+m\alpha \ | \ |m| \le |K|N-1\}$ stays $\tilde {\delta }$ -away from the boundaries of $R^{i,j}$ . By Lemma 3.1, for $|k|\le |K|-1$ , the orbit $\{x+m\alpha | \ kN\le m \le (k+1)N-1\}$ visits each $R^{i,j}$ exactly once and stays $\tilde {\delta }$ -away from the boundaries of the small rectangles in the tiling.

Since $\tilde {\delta }>|\delta |$ and $\tilde {\delta '}>|\delta '|$ , our target rectangle $B_L$ contains the center parts of $bb'$ small rectangles, and the orbit visits $B_L bb'$ times within a time range of N. Therefore, for $0\le k\le |K|$ ,

(3.10) $$ \begin{align} A_{kN}(x) &=kA_N(x)\nonumber\\ &=k(bb'-qq'll')\nonumber\\ &=k(bb'-(b+\delta)(b'+\delta'))\nonumber\\ &=-k(b\delta'+b'\delta+\delta\delta'). \end{align} $$

In view of the negative sign in the definition of $A_N(x)$ for $N<0$ in (1.1), the above identity holds for $-|K|<k<0$ with the same argument.

Proof. By choosing a subsequence of n, we can assume that

(4.3) $$ \begin{align} \ln \ln \ln q_n\ge \big(\tfrac{3}{2}\big)^4 n^2. \end{align} $$

The set S and its density. Consider the subsets of $\mathbb {T}^2$ for the choices of $\alpha =(\alpha _1, \alpha _2)$ given by

(4.4) $$ \begin{align} S=\bigcap_{m\ge 1}\bigcup_{n\ge m} \bigg(&\bigcup_{\substack{0\le p_n\le q_n-1\:\\(p_{n},q_{n})=1}} \bigg(\frac{p_{n}}{q_{n}}-\frac{1}{n (\ln q_n)^{2}q_{n}^2q^{\prime}_{n}},\frac{p_{n}}{q_{n}}+\frac{1}{n (\ln q_n)^{2}q_{n}^2q^{\prime}_{n}}\bigg)\nonumber\\ &\times \bigcup_{\substack{0\le p^{\prime}_n\le q^{\prime}_n-1:\\(p^{\prime}_{n},q^{\prime}_{n})=1}} \bigg(\frac{p^{\prime}_{n}}{q^{\prime}_{n}}-\frac{1}{n (\ln q_n)^{2}q_{n}^2q^{\prime}_{n}},\frac{p^{\prime}_{n}}{q^{\prime}_{n}}+\frac{1}{n (\ln q_n)^{2}q_{n}^2q^{\prime}_{n}}\bigg) \bigg). \end{align} $$

The set above is clearly a $G_{\delta }$ set. It remains to show that S is a dense set in $\mathbb {T}^2$ . Note that $(\alpha _1,\alpha _2)\in S$ if and only if there exists a subsequence of n, denoted by $n_k$ , and two corresponding sequences of $p_{n_k}$ and $p^{\prime }_{n_k}$ , that are relatively prime to $q_{n_k}$ and $q^{\prime }_{n_k}$ , respectively, such that, for every k,

(4.5) $$ \begin{align} &\bigg\vert \alpha_{1}-\frac{p_{n_k}}{q_{n_k}}\bigg\vert< \frac{1}{{n_k} (\ln q_{n_k})^{2}q_{n_k}^2q^{\prime}_{n_k}}, \nonumber\\ &\bigg| \alpha_{2}-\frac{p^{\prime}_{n_k}}{q^{\prime}_{n_k}}\bigg|< \frac{1}{{n_k} (\ln q_{n_k})^{2}q_{n_k}q^{\prime 2}_{n_k}}. \end{align} $$

To see that S is dense, we will show that we can approximate any point in $\mathbb {T}^2$ well enough. Note that, for any given $\epsilon>0$ , there exists M depending on $\epsilon $ such that, for every $q_{n}\ge M$ and $q^{\prime }_{n}\ge M$ and every point $(\gamma ,\gamma ')$ in $\mathbb {T}^2$ , there exists $p_{n}$ coprime to $q_{n}$ and $p^{\prime }_{n}$ coprime to $q^{\prime }_{n}$ , with the property that

(4.6) $$ \begin{align} |p_{n}/q_{n}-\gamma|\le \epsilon/2,\quad |p^{\prime}_{n}/q^{\prime}_{n}-\gamma|\le \epsilon/2. \end{align} $$

This is possible because the bound on the gaps between two consecutive totatives of a given number M is of order $o(M)$ (see [Reference Montgomery and Vaughan13]). Now fix $n_0$ and $p_{n_0}$ , $p^{\prime }_{n_0}$ such that inequality (4.6) holds and assume that $n_0$ is large enough so that

(4.7) $$ \begin{align} \frac{1}{{n_0} (\ln q_{n_0})^{2}q_{n_0}^2q^{\prime}_{n_0}}<\epsilon/2. \end{align} $$

Starting with $k=0$ , by replacing $\epsilon $ with $\epsilon _k= {1}/{{n_k} (\ln q_{n_k})^{2}q_{n_k}^2q^{\prime }_{n_k}}$ and replacing $\gamma $ with ${p_{n_k}}/{q_{n_k}}$ in the argument for (4.6), we can inductively show the existence of $n_{k+1}$ such that the sequence of the intervals

$$ \begin{align*} \bigg[\frac{p_{n_k}}{q_{n_k}}-\frac{1}{2{n_k} (\ln q_{n_k})^{2}q_{n_k}^2q^{\prime}_{n_k}},\frac{p_{n_k}}{q_{n_k}}+\frac{1}{2{n_k} (\ln q_{n_k})^{2}q_{n_k}^2q^{\prime}_{n_k}}\bigg] \end{align*} $$

are nested. A similar result holds for the second coordinate. This proves the existence of $(\alpha _1,\alpha _2)\in [0,1)^2$ such that (4.5) holds with the coprime pairs $(p_{n_0},q_{n_0})$ and $(p^{\prime }_{n_0},q^{\prime }_{n_0})$ . By inequality (4.7),

$$ \begin{align*} |p_{n_0}/q_{n_0}-\alpha_1|<\epsilon/2,\quad |p^{\prime}_{n_0}/q^{\prime}_{n_0}-\alpha_2|<\epsilon/2. \end{align*} $$

Combining the inequality above with (4.6) for $n=n_0$ gives

$$ \begin{align*} |\alpha_1-\gamma|<\epsilon, \quad |\alpha_2-\gamma'|<\epsilon. \end{align*} $$

Hence, S is dense in $\mathbb {T}^2$ .

Preparation work. We need to show that there are different orders of magnitude for Birkhoff sums $A^{(1)}_N$ and $A^{(2)}_N$ along rigidity sequences .

We proceed with the essential value argument. For every $\alpha \in S$ , we can find a subsequence of n, and corresponding coprime numerators, such that (4.5) hold. For simplicity, we still denote the index by n.

For $M_n=\sqrt {n} (\ln q_n)^{2}q_{n}q^{\prime }_{n}$ , and for every $0\le m\le M_n$ (here we use weak inequalities to make writing easier),

(4.8) $$ \begin{align} \begin{aligned} \bigg|m\alpha_{1}-m\frac{p_{n}}{q_{n}}\bigg|&=m\bigg|\alpha_{1}-\frac{p_{n}}{q_{n}}\bigg|\le \frac{1}{\sqrt{n}q_{n}} \end{aligned} \end{align} $$

and

(4.9) $$ \begin{align} \begin{aligned} \bigg|m\alpha_{2}-m\frac{p^{\prime}_{n}}{q^{\prime}_{n}}\bigg|&=m\bigg|\alpha_{2}-\frac{p^{\prime}_{n}}{q^{\prime}_{n}}\bigg|\leq \frac{1}{\sqrt{n}q^{\prime}_{n}}. \end{aligned} \end{align} $$

For any $i,j \in \mathbb {N}$ , denote by $\mathcal {F}_{i,j}(q_{n},q^{\prime }_{n})$ the set of points $(x_{1},x_{2})$ satisfying

(4.10) $$ \begin{align} \frac{2}{\sqrt{n}q_{n}}+\frac{i}{q_{n}}\leq x_{1} \leq \frac{i+1}{q_{n}} -\frac{2}{\sqrt{n}q_{n}} \end{align} $$

and

(4.11) $$ \begin{align} \frac{2}{\sqrt{n}q^{\prime}_{n}}+\frac{j}{q^{\prime}_{n}}\leq x_{2} \leq \frac{j+1}{q^{\prime}_{n}} -\frac{2}{\sqrt{n}q^{\prime}_{n}}. \end{align} $$

Then the Haar measure of the set $\mathcal {F}_{i,j}$ has the lower bound

(4.12) $$ \begin{align} \mu \{\mathcal{F}_{i,j}(q_{n},q^{\prime}_{n})\}&\geq \bigg(1-\frac{4}{\sqrt{n}}\bigg)\bigg(1-\frac{4}{\sqrt{n}}\bigg)\frac{1}{q_{n}q^{\prime}_{n}} \end{align} $$

(4.13) $$ \begin{align} &\geq \frac{3}{4}\frac{1}{q^{\prime}_{n}q_{n}} \end{align} $$

for $n\ge 32^2$ .

Let

$$ \begin{align*} l_{1}=\frac{b_{n}+\delta_{n}}{q_{n}} \quad \mathrm{and} \quad l^{\prime}_1=\frac{b^{\prime}_{n}+\delta^{\prime}_{n}}{q^{\prime}_{n}}. \end{align*} $$

We now want to apply Lemma 3.3 to the first rectangle $B_1$ , with $\tilde {\delta }_n=\tilde {\delta }_n'={1}/{\sqrt {n}}$ , $K_n=\sqrt {n}(\ln q_n)^2$ and $N_n=q_n q^{\prime }_n$ . The inequalities (4.8) and (4.9) show that

$$ \begin{align*} |\eta_n|=\|q_n \alpha_1\|\le \frac{1}{{n}(\ln q_n)^2 q_n q^{\prime}_n}=\frac{\tilde{\delta}_n}{K_n N_n} \end{align*} $$

and

$$ \begin{align*} |\eta^{\prime}_n|=\|q^{\prime}_n \alpha_1\| \le \frac{1}{{n}(\ln q_n)^2 q_n q^{\prime}_n}=\frac{\tilde{\delta}^{\prime}_n}{K_n N_n}. \end{align*} $$

By inequalities (3.13) and (3.14), and recalling the assumption (4.3) that $q_n$ is large, we have that

(4.14) $$ \begin{align} |\delta_n|=\|q_n l_1\|\le \frac{1}{q_n(\ln\ln \ln q_n)}< \frac{1}{\sqrt{n} }=\tilde{\delta}_n \end{align} $$

and

(4.15) $$ \begin{align} |\delta^{\prime}_n|=\|q^{\prime}_n l^{\prime}_1\|\le \frac{1}{q_n(\ln\ln \ln q_n)^{1/2}}< \frac{1}{\sqrt{n}}=\tilde{\delta}^{\prime}_n. \end{align} $$

Hence, by applying Lemma 3.3 to $A^{(1)}$ for $x\in \mathcal {F}_{i,j}(q_{n},q^{\prime }_{n})$ ,

$$ \begin{align*} | A^{(1)}_{N_{n}}(x)| =| b_{n}b^{\prime}_{n}-q_{n}q^{\prime}_{n}l_{1}l^{\prime}_1|. \end{align*} $$

Thus, from (3.11),

$$ \begin{align*} | A^{(1)}_{N_{n}}(x)| &=| b_{n}b^{\prime}_{n}-q_{n}q^{\prime}_{n}l_{1}l^{\prime}_1| \\ &=| b_{n}b^{\prime}_{n}-(b_{n}+\delta_{n})(b^{\prime}_{n}+\delta^{\prime}_{n})| \\ &\le 2| b_{n}\delta^{\prime}_{n}+ b^{\prime}_{n}\delta_{n}| \\ &\le 2\times\text{ right-hand side of (3.11)} \\&= \frac{4}{(\ln \ln \ln q_n)^{1/2}} \end{align*} $$

and, similarly,

$$ \begin{align*} |A^{(1)}_{N_{n}}(x)|\geq \frac{l_1}{4(\ln q_n)^{2}}. \end{align*} $$

Therefore, for $x\in \mathcal {F}_{i,j}(q_{n},q^{\prime }_{n})$ ,

(4.16) $$ \begin{align} \frac{l_1}{4(\ln q_n)^{2}} \leq | A^{(1)}_{N_{n}}(x) | \leq \frac{4}{(\ln \ln \ln q_n)^{1/2}}. \end{align} $$

Inequality (4.16) means that we can approximate the interval $[-\sqrt {2n}, \sqrt {2n}]$ with a precision of $1/ (\ln \ln \ln q_n)^{1/2}$ by multiplying $A^{(1)}_{N_n}$ by a coefficient smaller than $\sqrt {2n}(\ln q_n)^2$ , which is used to obtain (4.19).

For the second rectangle $B_2$ , by (3.15) and (3.16) for individual summands (see the comment at the end of Lemma 3.5), and using the more strict bound (3.16) and the assumption (4.3) that $q_n$ is large, we obtain similar inequalities to (4.14) and (4.15): that is,

$$ \begin{align*} \|q_{n} l_2\|\le \frac{3}{2 q^{\prime}_n(\ln\ln\ln q_n)^{{1}/{4}}}< \frac{1}{\sqrt{n}}=\tilde{\delta}_n \end{align*} $$

and

$$ \begin{align*} \|q^{\prime}_{n} l^{\prime}_2\|\le \frac{3}{2 q_n(\ln\ln\ln q_n)^{{1}/{4}}}< \frac{1}{\sqrt{n}}=\tilde{\delta}^{\prime}_n. \end{align*} $$

Therefore, we can apply Lemma (3.3) to $A^{(2)}$ , and we obtain the estimation

(4.17) $$ \begin{align} | A^{(2)}_{N_{2n}}(x) | \leq \frac{3}{(\ln q_{2n})^{3}}, \end{align} $$

(4.18) $$ \begin{align} \frac{1}{4(\ln \ln \ln q_{2n+1})^{1/4}}\le| A^{(2)}_{N_{2n+1}}(x) | \leq \frac{3}{(\ln \ln \ln q_{2n+1})^{1/4}}. \end{align} $$

Argument for the case of $(a,0)$ . For $a\in \mathbb {R}$ and $\epsilon>0$ , by (4.16) and (4.17), we can first choose n large enough, and then $K_{2n}=K_{2n}(a, \epsilon )$ with $|K_{2n}| \leq \sqrt {2n}(\ln q_{2n})^{2}$ such that

(4.19) $$ \begin{align} | K_{2n}A^{(1)}_{N_{2n}}(x)-a | \le \frac{4}{(\ln \ln \ln q_{2n})^{1/2}} \leq \frac{1}{\sqrt{2}}\epsilon, \end{align} $$

(4.20) $$ \begin{align} | K_{2n}A^{(2)}_{N_{2n}}(x) | \le \frac{3\sqrt{2n}(\ln q_{2n})^{2}}{(\ln q_{2n})^{3}} \leq \frac{3\sqrt{2n}}{\ln q_{2n}}\le \frac{3\sqrt{2n}}{2n}\le \frac{1}{\sqrt{2}}\epsilon, \end{align} $$

where we use that $\ln q_n\ge n$ , which follows from assumption (4.3) at the beginning of the proof.

Finally, by combining the two inequalities above, for $N=K_{2n}N_{2n}=K_{2n}q_{2n}q^{\prime }_{2n}$ , $x\in \mathcal {F}_{i,j}(q_{2n},q_{2n}')\subset R^{i,j}_{2n}$ , we get

$$ \begin{align*} A_{N}(x)=K_{2n}(A^{(1)}_{N_{2n}}(x), A^{(2)}_{N_{2n}}(x)), \end{align*} $$

which implies that

(4.21) $$ \begin{align} | A_{N}(x)-(a,0) | \leq \epsilon. \end{align} $$

So

(4.22) $$ \begin{align} &\mathcal{F}_{i,j}(q_{2n},q_{2n}') \cap T_{\alpha}^{-N}(\mathcal{F}_{i,j}(q_{2n},q_{2n}')\nonumber\\ &\quad\subset \ T_{\alpha}^{-N}(R^{i,j}_{2n})\cap R_{2n}^{i,j}\cap \{x\in [0,1)^{2}, | A_{N}(x)-(a,0)|\}\leq \epsilon \}. \end{align} $$

Note that N is a multiple of $q_{2n}q^{\prime }_{2n}$ , so at time N the rational vector $N(q_{2n}, q^{\prime }_{2n})$ returns to the origin. Because $N(q_{2n}, q^{\prime }_{2n})$ approximates $N\alpha $ really well, by inequality (4.8) and (4.9),

$$ \begin{align*} \mu ( \mathcal{F}_{i,j}(q_{2n},q_{2n}')\cap T_{\alpha}^{-N}( \mathcal{F}_{i,j}(q_{2n},q_{2n}')))&\geq \bigg(1-\frac{1}{\sqrt{2n}}\bigg)\bigg(1-\frac{1}{\sqrt{2n}}\bigg)\mu ( \mathcal{F}_{i,j}(q_{2n},q_{2n}')), \\ &\geq \frac{1}{2q_{2n}q_{2n}'}>0. \end{align*} $$

Argument for the case of $(0,a)$ . In the case of $(0,a)$ , we can use the odd terms $2n+1$ and repeat the argument above. Note that $A^{(2)}_{N_{2n+1}}$ is of order $(\ln \ln \ln q_{2n+1})^{1/4}$ , while $A^{(1)}_{N_{2n+1}}$ is of order $(\ln \ln \ln q_{2n+1})^{1/2}$ . Therefore, we can approximate any point in the interval $[-\sqrt {2n+1}, \sqrt {2n+1}]$ with a precision of $1/ (\ln \ln \ln q_{2n+1})^{1/4}$ after multiplying $A^{(2)}_{N_{2n+1}}$ by a coefficient $K_{2n+1}$ smaller than $\sqrt {2n+1}(\ln \ln \ln q_{2n+1})^{1/4}$ , while $K_{2n+1}A^{(1)}_{N_{2n+1}}$ is still small and of order $1/ (\ln \ln \ln q_{2n+1})^{1/4}$ . This gives two inequalities similar to (4.19) and (4.20), and the same argument for positive measure at time $2n+1$ follows through.

This finishes the proof of Lemma 4.1.

Proof. By Theorem 1.2, it suffices to prove that a similar conclusion in Lemma 4.1 holds after we substitute $R_{n}^{i,j}$ by any set B of positive measure. In fact, for any positive measure set B, there exists n large enough, such that

(4.23) $$ \begin{align} \mu (R^{i,j}_{n}\cap B)> \frac{7}{8}\frac{1}{q_{n}'q_{n}} \end{align} $$

for some $0\leq i\leq q_{n}-1$ and $0\leq j\leq q_{n}'-1$ , and thus we can expect a slightly weaker lower bound for a general positive measure set B.

For given $a\in \mathbb {R}$ , $\epsilon>0$ , choose n large enough such that inequality(4.23) holds, and denote $N=N(a,\epsilon )=K_{2n} N_{2n}=K_{2n}q_{2n}'q_{2n}$ , as in Lemma 4.1. By inequality(4.21),

(4.24) $$ \begin{align} \mathcal{F}_{i,j}(q_{2n},q_{2n}')\subset\{x\ | \ |A_N(x)-(a,0)|<\epsilon \}. \end{align} $$

Now, with standard measure computations, we are ready to show the desired bound

$$ \begin{align*} \mu(\mathcal{F}_{i,j}(q_{2n},q_{2n}')\cap T_{\alpha}^{-N}(B\cap R^{i,j}_{2n})\cap (B\cap R^{i,j}_{2n}))>0. \end{align*} $$

Let $\mathcal {X}=T_{\alpha }^{-N}(B\cap R^{i,j}_{2n})\cap (B\cap R^{i,j}_{2n})$ . Then we have the following bound for $\mu (\mathcal {X})$ : that is,

$$ \begin{align*} \mu (\mathcal{X})&=\mu (T_{\alpha}^{-N}(B\cap R^{i,j}_{2n})\cap (B\cap R^{i,j}_{2n})) \\ &=\mu (T_{\alpha}^{-N}(B\cap R^{i,j}_{2n}))+ \mu(B\cap R^{i,j}_{2n})-\mu(T_{\alpha}^{-N}(B\cap R^{i,j}_{2n})\cup (B\cap R^{i,j}_{2n})) \\ &\geq 2 \mu (B\cap R^{i,j}_{2n})-\mu(T_{\alpha}^{-N}(R_{2n}^{i,j})\cup R^{i,j}_{2n}) \\ & \geq \tfrac{7}{4}\mu (R_{2n}^{i,j})-\tfrac{5}{4}\mu(R_{2n}^{i,j}) \\ &=\tfrac{1}{2}\mu(R_{2n}^{i,j}), \end{align*} $$

where the inequality $\mu (T_{\alpha }^{-N}(R_{2n}^{i,j})\cup R^{i,j}_{2n})\le \tfrac 54\mu (R_{2n}^{i,j})$ comes from the fact that $T^{-N}_{\alpha }$ is close to identity, as $q_{2n}q^{\prime }_{2n}$ divides N(see (4.5)).

Denote $\mathcal {Y}=\mathcal {F}_{i,j}(q_{2n},q_{2n}')$ . Note that $\mathcal {X}$ and $\mathcal {Y}$ are both subsets of $R^{i,j}_{2n}$ . By using the lower bound (4.12) of $\mu (\mathcal {Y})$ ,

$$ \begin{align*} \mu (\mathcal{X} \cap \mathcal{Y}) & =\mu(\mathcal{X})+\mu(\mathcal{Y})-\mu(\mathcal{X} \cup \mathcal{Y}) \\ & \geq \tfrac{1}{2}\mu(R_{2n}^{i,j})+\tfrac{3}{4}\mu(R_{2n}^{i,j})-\mu(R_{2n}^{i,j}) \\ & \geq \tfrac{1}{4}\mu (R_{2n}^{i,j}). \end{align*} $$

Finally, we obtain the bound

$$ \begin{align*} \mu (T_{\alpha}^{-N}(B\cap R^{i,j}_{2n})\cap (B\cap R^{i,j}_{2n})\cap \mathcal{F}_{i,j}(q_{2n},q_{2n}'))> \tfrac{1}{4}\mu (R_{2n}^{i,j})>0. \end{align*} $$

This proves that, for every $a\in \mathbb {R}$ , $(a,0)\in E(A)$ . Similarly, we can prove that $(0,a)$ belongs to $E(A)$ . By the subgroup property of essential value in Theorem 1.2, we have $E(A)=\mathbb {R}^2$ .

Proof. Define

$$ \begin{align*} \psi(q)= \begin{cases} 1/(q\ln \ln \ln q) &\text{if }q\text{ is prime and }\ln \ln \ln q\ge 1, \\ 0 & \text{otherwise.} \end{cases} \end{align*} $$

It suffices to check that conditions (i) and (ii) of Lemma 5.1 are satisfied for $\psi (q)$ .

Note that, if q is prime, we have $\varphi (q)=q-1$ (where $\varphi $ is Euler’s totient function). Then $\varphi (q)/q\geq 1/2$ , and condition (ii) of Lemma 5.1 is satisfied.

For condition (i), by the inequality of the sum of the reciprocals of primes

(5.2) $$ \begin{align} \sum\limits_{\substack{q \leq n \\ q \; \text{prime}}}\frac{1}{q} \geq \ln \ln (n+1)-\ln (\pi^{2}/6), \end{align} $$

we have

$$ \begin{align*} \begin{aligned} \sum\limits_{\substack{q \leq n \\ q \; \text{prime}}}\psi(q) &\geq \frac{1}{\ln \ln \ln n} \sum\limits_{\substack{q \leq n \\ q \; \text{prime}}}\frac{1}{q}\\ &\mathop{\geq}\limits_{(5.2)} \frac{\ln \ln (n+1)-\ln (\pi^{2}/6)}{\ln\ln\ln n} \to \infty \end{aligned} \end{align*} $$

as $\ n\rightarrow \infty $ , and thus condition (i) is also satisfied.

Proof of properties (1) and (5) of Lemma 3.4

By Corollary 5.2, we have that, for almost every $l\in (0,1]$ , there exists an increasing sequence of prime numbers $\{q_{n}\}$ such that $q_n\rightarrow \infty $ as $n\rightarrow \infty $ and

(5.3) $$ \begin{align} \| q_{n}l \| \leq \frac{1}{q_{n}\ln \ln \ln q_{n}}. \end{align} $$

This shows inequality (3.13) in property (5) of Lemma 3.4. By choosing a subsequence of $q_n$ , we can assume that $q_{n}\geq n^{2}$ and $\ln \ln \ln q_n\ge 1$ . By Dirichlet’s principle (the pigeonhole principle), if we divide the interval $[0,1]$ into m segments of equal length, then, for $m+1$ points, two of them must lie in the same segment. Thus, for every $l' \in [0,1]$ , for all $ n\in \mathbb {N}$ , there exists $ q^{\prime }_{n}\in \mathbb {N}$ such that

(5.4) $$ \begin{align} 1\le q^{\prime}_{n}\le q_{n}(\ln \ln \ln q_{n})^{1/2} \end{align} $$

and

(5.5) $$ \begin{align} \| q^{\prime}_{n}l' \| \leq \frac{1}{q_{n}(\ln \ln \ln q_{n})^{1/2}}. \end{align} $$

This is inequality (3.14) in property (5) of Lemma 3.4. By Khintchine’s convergence theorem (see, for example, [Reference Lang12, Ch. II, Theorem 4]), for almost every $l'\in (0,1]$ , there exists a constant $C(l')$ such that $\|kl'\|\ge C(l')/k^2$ for all $k\in \mathbb {N}$ , and hence inequality (5.5) implies that $q^{\prime }_n\rightarrow \infty $ as $n\rightarrow \infty $ for almost every $l'\in (0,1]$ . This proves property (1) of Lemma 3.4.

Proof of the right-hand side of (3.11)

Combining (5.3) and (5.5) gives

$$ \begin{align*}q^{\prime}_{n}\| q_{n}l \| + q_{n} \| q^{\prime}_{n} l'\| \leq \frac{2}{(\ln \ln \ln q_{n})^{1/2}}.\end{align*} $$

Since $b_n$ , $b^{\prime }_n$ are, respectively, the closest integers to $q_n l$ and $q^{\prime }_n l'$ for $l,l'\in (0,1]$ , we have $b_n\le q_n$ and $b^{\prime }_n\le q^{\prime }_n$ , and thus we obtain the right-hand side of (3.11) from the inequality above.

Proof of property (2) of Lemma 3.4

Given $l\in (0,1]$ and the sequence of prime numbers $q_n$ as in the proof of property (1), we show that, for almost every $l' \in (0,1]$ and any infinite sequence of $q^{\prime }_n$ such that (5.5) hold, we have $(q_{n},q^{\prime }_{n})= 1$ when n is large enough. Then property (2) follows by choosing a subsequence of n.

Define

$$ \begin{align*} G_{n,k}=\bigg\{l' \in [0,1]\ \bigg|\ \| kl' \| \leq \frac{1}{q_{n}(\ln \ln \ln q_{n})^{1/2}} \bigg\} \end{align*} $$

and

$$ \begin{align*} G_{n}=\bigcup_{ k\in S_n } G_{n,k}, \end{align*} $$

where

$$ \begin{align*} S_n=\{ k\in \mathbb{N} \mid (k, q_n)\neq 1, \ k \leq q_{n}(\ln \ln \ln n)^{1/2}\} \end{align*} $$

denotes the set of k’s that violates the coprime condition. Note that, when $l'$ does not belong to $G_n$ , the corresponding $q^{\prime }_{n}$ that solves (5.4) and (5.5) is coprime to $q_n$ , so it suffices to show that almost every $l'$ belongs to at most finitely many $G_n$ .

Since $q_n$ is prime, if $(k,q_{n})\neq 1$ , then $(k,q_{n})=q_{n}$ and $q_{n}\mid k$ . So

$$ \begin{align*}\#S_n\leq (\ln \ln \ln q_{n})^{1/2}.\end{align*} $$

Thus,

$$ \begin{align*}\begin{aligned} \mu(G_{n})&\le \sum_{k\in S_n}\mu(G_{n,k})\\ &\leq \#S_n\cdot\frac{1}{q_{n}(\ln \ln \ln q_{n})^{1/2}}\\ &\leq\frac{ (\ln \ln \ln q_{n})^{1/2}}{q_{n}(\ln \ln \ln q_{n})^{1/2}}\\ &\leq \frac{1}{n^{2}}\\ \end{aligned} \end{align*} $$

and

$$ \begin{align*} \sum_{n=1}^{\infty} \mu (G_{n})\leq \sum_{n=1}^{\infty}\frac{1}{n^{2}}<\infty. \end{align*} $$

By the Borel–Cantelli lemma, almost every $l' \in (0,1]$ belongs to at most finitely many $G_n$ , which proves the coprime condition.

Proof of the left-hand side of (3.11)

By choosing a subsequence, we can assume that $q_{n}\geq 2 q_{n-1}$ , and, without loss of generality, we can also assume that $q_{n}l -b_{n}$ is positive for all n, that is,

$$ \begin{align*} 0< q_{n}l -p_{n} \leq \frac{1}{q_{n}\ln \ln \ln q_{n}}. \end{align*} $$

We show that, for almost every $l'\in (0,1]$ , there exist infinitely many pairs $(b^{\prime }_{n},q^{\prime }_{n})$ such that $ q^{\prime }_{n}l' -b^{\prime }_{n}$ are positive and smaller than $1/ (q_{n}\ln \ln \ln q_{n})$ .

Define $Q_0=q_0=0$ , $Q_n={q_{n}(\ln \ln \ln q_{n})^{1/2}}$ for $n\ge 1$ .

Define $\phi :\mathbb {N}^*\rightarrow (0,1]$ by

$$ \begin{align*} \phi(k)=\frac{1}{Q_n} \quad \text{for } Q_{n-1}< k \leq Q_{n}. \end{align*} $$

Then $\phi (k)$ is decreasing. Note that

$$ \begin{align*} \sum _{k=1}^{Q_n}\phi(k)=\sum_{i=1}^{n}\bigg(1-\frac{q_{i-1}(\ln \ln \ln q_{i-1})^{1/2}}{q_{i}(\ln \ln \ln q_{i})^{1/2}}\bigg )\ge \frac{n}{2}, \end{align*} $$

so $\sum \phi (k) $ diverges. By Lemma 5.3, for almost every $l'\in (0,1]$ , the number of pairs of solutions $(b',q')$ such that

$$ \begin{align*} 0 < q'l' -b' \leq \phi(q'), \quad 1\le q'<N, \end{align*} $$

is infinite. It is enough to note that $0<q'l-b'<\phi (q')$ means that

$$ \begin{align*} 0 < q'l' -b' \leq \frac{1}{q_{n}(\ln \ln \ln q_{n})^{1/2}}, \quad q_{n-1} (\ln \ln \ln q_{n-1})^{1/2} < q' \le q_{n}(\ln \ln \ln q_{n})^{1/2} \end{align*} $$

for some n. These solutions can be indexed by a subsequence of n, and we omit the subindex and still denote them by $(b^{\prime }_n, q^{\prime }_n)$ .

This shows that there are infinitely many n’s such that $q_{n}l -b_{n}$ and $q^{\prime }_{n}l' -b^{\prime }_{n}$ have the same sign.

It remains to show the lower bound for one of the distances. Here, we show it for $b_n|q^{\prime }_n l'-b^{\prime }_n|$ . By Khintchine’s convergence theorem, for almost every $l'\in (0,1]$ ,

$$ \begin{align*} \| kl' \| \geq \frac{1}{k(\ln k)^{3/2}} \end{align*} $$

for all k large enough (depending on $l'$ ). By the inequality $q^{\prime }_{n}\leq q_{n}(\ln \ln \ln q_{n})^{1/2}$ ,

(5.6) $$ \begin{align} \| q^{\prime}_{n}l' \|\geq \frac{1}{q^{\prime}_n(\ln q^{\prime}_n)^{3/2}} \geq \frac{1}{q_{n}(\ln q_{n})^{2}} \end{align} $$

for all n large enough, which gives the desired lower bound

$$ \begin{align*} b_{n}\| q^{\prime}_{n}l'\| \geq \frac{b_{n}}{q_{n}}\frac{1}{(\ln q_{n})^{2}}\geq \frac{l}{2(\ln q_{n})^{2}}.\\[-40pt] \end{align*} $$

Proof of property (4) of Lemma 3.4

The upper bound (5.4) for $q^{\prime }_{n}$ gives the right-hand side of property 4. The two inequalities (5.5) and (5.6) give that

$$ \begin{align*} \frac{1}{q^{\prime}_n(\ln q^{\prime}_n)^{3/2}}\le \| q^{\prime}_{n}l' \| \leq \frac{1}{q_{n}(\ln \ln \ln q_{n})^{1/2}}. \end{align*} $$

Using again the bound (5.4), we have that

$$ \begin{align*} \frac{q_{n}}{(\ln q_{n})^2}\le q^{\prime}_{n}.\\[-40pt] \end{align*} $$

Proof of Lemma 3.5

Similarly to the set of (4.4), we can prove that there exists a $G_\delta $ set of $l_2$ (also of $l^{\prime }_2)$ such that there exists a subsequence of n where

(5.7) $$ \begin{align} \frac{1}{2(\ln q_{2n})^{3}}< q^{\prime}_{2n}\lVert q_{2n}l_{2} \rVert < \frac{1}{(\ln q_{2n})^{3}} \end{align} $$

and

(5.8) $$ \begin{align} \frac{1}{2(\ln \ln \ln q_{2n+1})^{1/4}}< q^{\prime}_{2n+1}\lVert q_{2n+1}l_{2} \rVert < \frac{1}{(\ln \ln \ln q_{2n+1})^{1/4}}, \end{align} $$

and $l^{\prime }_{2}$ such that

(5.9) $$ \begin{align} q_{2n}\lVert q^{\prime}_{2n}l^{\prime}_{2} \rVert < \frac{1}{4(\ln q_{2n})^{3}} \end{align} $$

and

(5.10) $$ \begin{align} q_{2n+1}\lVert q^{\prime}_{2n+1}l^{\prime}_{2} \rVert < \frac{1}{4(\ln \ln \ln q_{2n+1})^{1/4}}. \end{align} $$

This shows that the individual terms in the sum in inequalities (3.15) and (3.16) satisfy the given bounds, and thus the final remark of Lemma 3.5 is proved. The above choice of $l_2$ (and $l_2'$ ) forms a dense set of $(0,1]$ , as we can approximate any given number well enough by a rational with a denominator that is large enough. From inequalities (5.7) and (5.9), we have the existence of $r_{2n}$ and $r^{\prime }_{2n}$ such that

$$ \begin{align*} \frac{1}{4(\ln q_{2n})^{3}}&\leq \frac{1}{2(\ln q_{2n})^{3}}-\frac{1}{4(\ln q_{2n})^{3}} \\ &\leq \lvert q^{\prime}_{2n}(q_{2n}l_{2}-r_{2n})+q_{2n}(q^{\prime}_{2n}l^{\prime}_{2}-r^{\prime}_{2n}) \rvert\\ &\leq \frac{1}{(\ln q_{2n})^{3}}+\frac{1}{4(\ln q_{2n})^{3}}\\ &\leq \frac{3}{2(\ln q_{2n})^{3}}. \end{align*} $$

Similarly, from inequalities (5.8) and (5.10), we have the existence of $r_{2n+1}$ and $r^{\prime }_{2n+1}$ such that

$$ \begin{align*} \frac{1}{4(\ln \ln \ln q_{2n+1})^{1/4}} &\leq \lvert q^{\prime}_{2n+1}(q_{2n+1}l_{2}-r_{2n+1})+q_{2n+1}(q^{\prime}_{2n+1}l^{\prime}_{2}-r^{\prime}_{2n+1}) \rvert \\ &\leq \frac{3}{2(\ln \ln \ln q_{2n+1})^{1/4}}.\\[-3.5pc] \end{align*} $$