Proof. Immediate.

Proof. Use change of variables and integration by parts.

Proof. Chose $M_{0}$ such that $k(r)\leq r$ for all $r\geq M_{0}$ . If $M\geq M_{0}$ , take $R=k^{-1}(M)$ and

$$\begin{align*}g(t)=u_{R} *\frac{\delta_{0}+\delta_{1/M}+\delta_{2/M}+\ldots+\delta_{(M-1)/M}}{M}\end{align*}$$

with $u_{R}$ as in Lemma 2.2, $*$ denoting convolution and $\delta _{t}$ the Dirac delta measure at t. We observe that

$$\begin{align*}\hat{g}(r)= \begin{cases}\hat{u}_{R}(jM)&\text{if }r=jM \text{ for some }j\in{\mathbb Z},\\ 0&\text{otherwise.} \end{cases}\end{align*}$$

Conditions (i) and (ii) are immediate. Condition (iv) follows on choosing $\mathcal {I}$ to be the collection of intervals

$$\begin{align*}[jM^{-1}-R^{-1}/2,jM^{-1}+R^{-1}/2] \ \text{with }0\leq j\leq M-1.\end{align*}$$

We now look at condition (iii). We have

$$ \begin{align*} \sum_{r\neq 0}& \frac{k(|r|)}{|r|}|\hat{g}(r)|^{2} =\sum_{j\neq 0}\frac{k(|jM|)}{|jM|}|\hat{g}(jM)|^{2}\\ & =\sum_{1\leq |j|<R/M} \frac{k(|jM|)}{|jM|}|\hat{u}_{R}(jM)|^{2} +\sum_{|j|\geq R/M} \frac{k(|jM|)}{|jM|}|\hat{u}_{R}(jM)|^{2}. \end{align*} $$

We bound the two sums separately. Since $s^{-1}k(s)$ decreases as s increases, we have

$$\begin{align*}\frac{1}{M}\int_{(j-1)M}^{jM-1}\frac{k(s)}{s}\,ds\geq \frac{k(jM)}{jM}\end{align*}$$

for $j\geq 2$ . Thus, since $|\hat {u}_{R}(r)|\leq 1$ and $k(M)\leq M$ ,

$$ \begin{align*} \sum_{1\leq |j|<R/M}& \frac{k(|jM|)}{|jM|}|\hat{u}_{R}(jM)|^{2} \leq 2\sum_{1\leq j<R/M} \frac{k(jM)}{jM}\\ &\leq 2+\frac{2}{M}\int_{M}^{R}\frac{k(s)}{s}\,ds \leq 2+\frac{2}{M}\int_{M}^{R}\alpha^{-1} k'(s)\,ds \end{align*} $$

from Lemma 2.1 (iii). But

$$\begin{align*}\int_{M}^{R}k'(s)\,ds=k(R)-k(M)\leq k(R)=M,\end{align*}$$

so

$$\begin{align*}\sum_{1\leq |j|<R/M} \frac{k(|jM|)}{|jM|}|\hat{u}_{R}(jM)|^{2} \leq 2+2\alpha^{-1}. \end{align*}$$

Since $s^{-1}k(s)$ decreases and $k(R)=M$ , Lemma 2.2 (ii) yields

$$ \begin{align*} \sum_{|j|\geq R/M}& \frac{k(|jM|)}{|jM|}|\hat{u}_{R}(jM)|^{2} \leq\sum_{|j|\geq R/M}\frac{k(R)}{R}|\hat{u}_{R}(jM)|^{2}\\ &\leq 2\sum_{j \geq R/M}\frac{M}{R} \beta_{1}^{2}\frac{R^{2}}{(jM)^{2}} =2\beta_{1}^{2}M^{-1}R \sum_{j \geq R/M}\frac{1}{j^{2}}=A_{2} \end{align*} $$

for an appropriate constant $A_{2}$ . Condition (iv) follows.

Proof. Observe that if $0\leq \theta \leq 1$ ,

$$\begin{align*}(|a|+\theta |b|+\theta |c|)^{2} \leq |a|^{2}+3\theta(|a|^{2}+|b|^{2}+|c|^{2}).\end{align*}$$

Thus induction on m gives

$$\begin{align*}\sum_{|j|\leq n} \left(|b_{j}|+ \sum_{1\leq |s|\leq m}\frac{|b_{j-s}|}{s^{2}}\right)^{2} \leq \prod_{s=1}^{m}\left(1+\frac{9}{s^{2}}\right) \sum_{|j|\leq n+m}|b_{j}|^{2}.\end{align*}$$

Since

$$\begin{align*}B=\prod_{s=1}^{\infty}\left(1+\frac{9}{s^{2}}\right)=\frac{3\pi^{2}}{2} \leq \frac{2^{4}}{9},\end{align*}$$

we obtain the required result.

Proof of Lemma 2.5. We start by bounding $\sum _{2^{n}\leq r<2^{n+1}}\tilde {g}(r)^{2}$ . Set

$$\begin{align*}\tilde{g}_{1}(r)= |\hat{g}(r)|+\sum_{1\leq s\leq 2^{n-1}}\frac{|\hat{g}(r-s)|}{s^{2}} \ \text{and} \ \tilde{g}_{2}(r)= \sum_{2^{n-1}<s}\frac{|\hat{g}(r-s)|}{s^{2}}.\end{align*}$$

By Lemma 2.6,

$$\begin{align*}\sum_{2^{n}\leq r<2^{n+1}}\tilde{g}_{1}(r)^{2} \leq B\sum_{2^{n-1}\leq r<2^{n+1}+2^{n-1}}|\hat{g}(r)|^{2}.\end{align*}$$

We know that $|\hat {g}(r-s)|\leq 1$ , so

$$\begin{align*}\tilde{g}_{2}(r)\leq \sum_{s>2^{n-1}}\frac{1}{s^{2}}\leq 2^{-n+2}\end{align*}$$

and thus

$$\begin{align*}\sum_{2^{n}\leq r<2^{n+1}}\tilde{g}_{2}(r)^{2}\leq 2^{-n+4}.\end{align*}$$

Since $\tilde {g}=\tilde {g}_{1}+\tilde {g}_{2}$ , it follows that

$$ \begin{align*} \sum_{2^{n}\leq r<2^{n+1}}\tilde{g}(r)^{2}& =\sum_{2^{n}\leq r<2^{n+1}}\big(\tilde{g}_{1}(r)+\tilde{g}_{2}(r)\big)^{2}\\ &\leq 4\sum_{2^{n}\leq r<2^{n+1}} (\tilde{g}_{1}(r)^{2}+\tilde{g}_{2}(r)^{2})\\ &\leq 2^{6}\sum_{2^{n-1}\leq r<2^{n+1}+2^{n-1}}|\hat{g}(r)|^{2} +2^{-n+6}. \end{align*} $$

By considering sums over $-2^{n+1}<r\leq -2^{n}$ in the same manner, we obtain

$$\begin{align*}\sum_{2^{n}\leq |r|<2^{n+1}}\tilde{g}(r)^{2} \leq 2^{7}\sum_{2^{n-1}\leq |r|<2^{n+2}}|\hat{g}(r)|^{2} +2^{-n+7}.\end{align*}$$

Next we observe that there are constants $K_{1}$ and $K_{2}$ such that

$$\begin{align*}K_{1}\frac{k(2^{n})}{2^{n}}\geq \frac{k(|r|)}{|r|} \geq K_{2}\frac{k(2^{n})}{2^{n}}\end{align*}$$

for all $2^{n-1}\leq |r|<2^{n+1}$ ; so, taking $B_{1}=2^{7}K_{1}/K_{2}$ , we have

$$\begin{align*}\sum_{2^{n}\leq |r|<2^{n+1}}\frac{k(|r|)}{|r|}\tilde{g}(r)^{2} \leq B_{1}\sum_{2^{n-1}\leq |r|<2^{n+2}} \frac{k(|r|)}{|r|}|\hat{g}(r)|^{2} +2^{-n+7}.\end{align*}$$

Thus

$$ \begin{align*} \sum_{r\neq 0}& \frac{k(|r|)}{|r|}\tilde{g}(r)^{2} \leq B_{2}+\sum_{|r|\geq 4}\frac{k(|r|)}{|r|}\tilde{g}(r)^{2}\\ & =B_{2}+\sum_{n=2}^{\infty} \sum_{2^{n}\leq |r|<2^{n+1}}\frac{k(|r|)}{|r|}\tilde{g}(r)^{2}\\ &\leq B_{2}+B_{1}\sum_{n=2}^{\infty} \sum_{2^{n-1}\leq |r|<2^{n+2}}\frac{k(|r|)}{|r|}|\hat{g}(r)|^{2}\\ &\leq B_{2}+B_{1}\sum_{r\neq 0} \frac{k(|r|)}{|r|}|\hat{g}(r)|^{2} \leq K \end{align*} $$

for appropriate choices of constants $B_{2}$ and K.

Proof. Replace h by $\tilde h=\delta ^{-1}h$ in Lemma 2.5.

Proof. Observe that it suffices to find a $\tilde {F}$ satisfying conditions (ii), (iii), (iv) and (v) with $\epsilon $ replaced by a sufficiently small $\tilde {\epsilon }$ and then taking $F=\big (\hat {F}(0)\big )^{-1}\tilde {F}$ . We therefore ignore condition (i).

We observe that, since f is infinitely differentiable, we can find a $C>1$ with $|\hat {f}(r)|\leq Cr^{-2}$ for $r\neq 0$ . Let K be as in Lemma 2.7, and choose N sufficiently large that $C^{-2}K^{-1}\delta \epsilon /2>\gamma _{r}$ for all $r\geq N$ . Now let M be an integer with $M>Q$ , to be fixed later, take g to be the corresponding function satisfying the conditions of Lemma 2.7 and set $F(t)=g(t)f(t)$ . Conditions (iv) and (v) are immediate.

Since $f\in C^{\infty }$ , we have $\hat {f}\in l^{1}$ . Further, $\hat {g}(0)=1$ and $\hat {g}(r-j)=0$ for $1\leq |r-j|<M$ , so

$$\begin{align*}|\hat{F}(r)-\hat{f}(r)| =\left|\sum_{j\neq r}\hat{f}(j)\hat{g}(r-j)\right| \leq \sum_{|r-j|\geq M}|\hat{f}(j)| \leq\sum_{|j|\geq M-Q}|\hat{f}(j)| \end{align*}$$

and condition (ii) will hold provided only that M is sufficiently large.

Since N is fixed, we may also choose M sufficiently large

$$\begin{align*}\sum_{1\leq |r|\leq N}\gamma_{r}\frac{k(|r|)}{|r|}|\hat{F}(r)|^{2} \leq \frac{\epsilon}{2}+ \sum_{1\leq |r|\leq N}\gamma_{r}\frac{k(|r|)}{|r|}|\hat{f}(r)|^{2}\end{align*}$$

so, automatically,

$$\begin{align*}\sum_{1\leq |r|\leq N}\gamma_{r}\frac{k(|r|)}{|r|}|\hat{F}(r)|^{2} \leq \frac{\epsilon}{2}+ \sum_{r\neq 0}\gamma_{r}\frac{k(|r|)}{|r|}|\hat{f}(r)|^{2}.\end{align*}$$

Now, $|\hat {f}|\leq Cr^{-2}$ for $r\neq 0$ and $|\hat {F}(r)|\leq \tilde {g}(r)$ , so, using Lemma 2.7, we have

$$ \begin{align*} \sum_{|r|>N}\gamma_{r}\frac{k(|r|)}{|r|}|\hat{F}(r)|^{2} &\leq \frac{\epsilon}{2C^{2}K\delta^{-1}} \sum_{|r|>N}\frac{k(|r|)}{|r|}|\hat{F}(r)|^{2}\\ & \leq \frac{\epsilon}{2C^{2}K\delta^{-1}} \sum_{|r|>N}\frac{k(|r|)}{|r|}\tilde{g}(r)^{2}\\ & \leq \frac{\epsilon}{2K\delta^{-1}} \sum_{r\neq 0}\frac{k(|r|)}{|r|}\tilde{g}(r)^{2} \leq\frac{\epsilon}{2}. \end{align*} $$

Combining this result with the final formula of the previous paragraph, we see that condition (iii) holds and the proof is complete.

Proof of Theorem 1.5. Take $f_{0}=1$ . By Lemma 2.8, we can find a sequence of positive function $f_{n}\in C^{\infty }({\mathbb T})$ with the following properties:

1. (i) _n $\hat {f}_{n}(0)=1$ .

2. (ii) _n $|\hat {f}_{n}(r)-\hat {f}_{n-1}(r)|\leq 2^{-n}$ for all $|r|\leq n$ .

3. (iii) _n $\displaystyle { \sum _{r\neq 0}\gamma _{r}\frac {k(|r|)}{|r|}|\hat {f}_{n}(r)|^{2} \leq 1-2^{-n}.}$

4. (iv) _n There is a finite collection of intervals ${\mathcal I}_{n}$ such that

   $$\begin{align*}\bigcup_{I\in {\mathcal I}_{n}}I\supseteq \operatorname{supp} f_{n}, \ \text{but}\ \bigcup_{I\in {\mathcal I}_{n}}h(|I|)\leq 2^{-n}.\end{align*}$$

5. (v) _n $\operatorname {supp} f_{n-1}\subseteq \operatorname {supp} f_{n}$ .

Standard theorems now tell us that the measures $f_{n}m$ (where m is Lebesgue measure) converge weakly to a probability measure $\mu $ with $\operatorname {supp}\mu \subseteq \operatorname {supp} f_{n}$ and that $\mu $ has the properties we require.

Proof. We set $R_{p}=k^{-1}(p^{2}L(p))$ and

$$\begin{align*}g_{p}(t)=\frac{1}{PL(p)}u_{R_{p}} *\frac{\delta_{0}+\delta_{1/p}+\delta_{2/p}+\ldots+\delta_{(p-1)/p}}{p},\end{align*}$$

with $u_{R}$ as in Lemma 2.2.

Conditions (i) and (ii) are immediate. Condition (v) follows on choosing $\mathcal {I}_{p}$ to be the collection of intervals

$$\begin{align*}[jp^{-1}-h^{-1}(p^{-2}L(p)^{-1})/2, jp^{-1}+h^{-1}(p^{-2}L(p)^{-1})/2] \ \text{with }1\leq j\leq p.\end{align*}$$

Before looking at conditions (iv) and (iii), we note that

$$\begin{align*}\hat{g}_{p}(r)= \begin{cases}\frac{1}{pL(p)}\hat{u}_{R_{p}}(r) &\text{if }p \text{ divides }r,\\ 0&\text{otherwise} \end{cases}.\end{align*}$$

Condition (iii) follows from condition (ii) of Lemma 2.2, which yields

$$ \begin{align*} |\hat{g}_{p}(r)| &\leq\frac{1}{pL(p)}|\hat{u}_{R_{p}}(r)| \leq \frac{\beta_{3}}{pL(p)} R_{p}^{3} |r|^{-3}\\ &=\frac{\beta_{3}}{pL(p)} \big(k^{-1}(p^{2}L(p)\big))^{3} |r|^{-3} \leq \frac{\beta_{3}}{pL(p)} k^{-1}(p^{3})^{3} |r|^{-3}\\ &\leq \frac{\beta_{3}}{p}p^{9/\alpha}|r|^{-3} \leq Bp^{-1}|r|^{-2}\leq Br^{-2} \end{align*} $$

for $|r|\geq p^{9/\alpha }$ , where B is some appropriate constant.

To check condition (iv), we first observe that, if $1\leq |r|\leq R$ , then

$$ \begin{align*} k(|r|)L(|r|)&\leq k(R_{p})L(R_{p})=p^{2}L(p)L\big(k^{-1}(p^{2}L(p))\big) \leq p^{2}L(p)L(k^{-1}(p^{3}))\\ &\leq p^{2}L(p)L(p^{3/\alpha})\leq Cp^{2}L(p^{2}) \end{align*} $$

so that

$$\begin{align*}\frac{C}{k(|r|)L(|r|)}\geq\frac{1}{p^{2}L(p)^{2}}\geq |\hat{g}(r)|^{2}.\end{align*}$$

On the other hand, if $r\geq R$ , then choosing $q>(1+\alpha ^{-1})/2$ using condition (ii) of Lemma 2.2, we have

$$\begin{align*}|\hat{g}(r)|^{2}\leq \beta_{q}^{2} R_{p}^{2q} |r|^{-2q}\end{align*}$$

and

$$\begin{align*}k(|r|)L(|r|)\leq \frac{|r|^{1+\alpha^{-1}}}{R_{p}^{1+\alpha^{-1}}}k(R_{p})L(R_{p})\end{align*}$$

so

$$\begin{align*}\frac{C \beta_{q}^{2}}{k(|r|)L(|r|)}\geq |\hat{g}(r)|^{2}.\end{align*}$$

Thus condition (iv) holds for an appropriate A.

Proof. By the prime number theorem or the much more easily obtained Chebychev inequality (see, for example, [Reference Nair7]), there exists a strictly positive constant K such that if n is large enough, the number of elements in

$$\begin{align*}P(n)=\{p\in P\,:\,2^{n}\leq p<2^{n+1}\}\end{align*}$$

exceeds $Kn^{-1}2^{n}$ . Thus, if n is large enough,

$$ \begin{align*} \sum_{p\in P(n)}\frac{1}{pL(p)}&\geq K\frac{2^{n}}{n}\times\frac{1}{2^{n+1}L(2^{n+1})} \geq \frac{K}{2}\times\frac{2^{n+1}}{(n+1)2^{n+1}L(2^{n+1})}\\ &\geq \frac{K}{2}\int_{2^{n+1}}^{2^{n+2}}\frac{1}{xL(x)\log x}\,dx, \end{align*} $$

and the result follows.

Proof. It is sufficient to prove the result with (i) replaced by

(i) $' \hat {g}(0)\geq 1$ .

To this end, we choose $M_{1}$ such that

$$\begin{align*}\frac{1}{rL(r)}\leq\frac{1}{2}.\end{align*}$$

If $M\geq M_{1}$ , we consider the sequence of consecutive primes $p(1)$ , $p(2)$ , …starting with $p(1)$ , the smallest prime greater than M.

By Lemma 4.2 and our choice of $M_{1}$ , we can find an N such that $1\leq \sum _{j=1}^{N}\tfrac {1}{p(j)L\big (p(j)\big )}\leq 2$ . We set $g=\sum _{j=1}^{N}g_{p(j)}$ , where the $g_{p(j)}$ are as in Lemma 4.1. Conditions (i) $'$ , (ii) and (iv) can be read off directly from conditions (i), (ii) and (v) of that lemma.

We now wish to bound $|\hat {g}(r)|$ . We observe that

$$\begin{align*}|\hat{g}(r)|\leq\sum_{p(j)\leq |r|^{\alpha/9}}|\hat{g}_{p(j)}(r)| +\sum_{|r|^{\alpha/9}\leq p(j)\leq |r|}|\hat{g}_{p(j)}(r)|\end{align*}$$

and bound the two sums separately. By condition (iii) of Lemma 4.1,

$$ \begin{align*} \sum_{p(j)\leq r^{\alpha/9}}|\hat{g}_{p(j)}(r)| &\leq \sum_{p(j)\leq r^{\alpha/9}}B|r|^{-2} \leq B r^{-1}\\ &=B\left(\frac{k(|r|)}{|r|}\right)^{1/2} \left(\frac{L(|r|)}{|r|}\right)^{1/2} \frac{1}{\sqrt{k(|r|)L(|r|)}} \leq B_{1}\frac{1}{\sqrt{k(|r|)L(|r|)}} \end{align*} $$

for an appropriate $B_{1}$ since $k(|r|)|r|^{-1}$ and $L(|r|)|r|^{-1}$ decrease with $|r|$ .

On the other hand, there can be at most $9/\alpha $ distinct primes $r\geq p(j)\geq r^{\alpha /9}$ with $\hat {g}_{p(j)}(r)\neq 0$ (since the $p(j)$ must divide r, we write $p(j)|r$ when this happens), so, using condition (iv) of Lemma 4.1,

$$ \begin{align*}\sum_{|r|\geq p(j)>|r|^{\alpha/9}}&|\hat{g}_{p(j)}(r)| =\sum_{r\geq p(j)>r^{\alpha/9},p(j)|r}|\hat{g}_{p(j)}(r)|\\ &\leq \sum_{r\geq p(j)>r^{\alpha/9},r|p(j)} \frac{A}{\big(k(|r|)L(|r|)\big)^{1/2}} \leq \frac{9A\alpha^{-1}}{\big(k(|r|)L(|r|)\big)^{1/2}} \end{align*} $$

and we are done.

Proof. We can choose $\tilde {h}=A'\eta ^{-1}h$ and $\tilde {L}$ such that $\tilde {L}(x)/L(x)\rightarrow 0$ so that the conditions of Theorem 1.6 still hold. We now apply Lemma 4.3 with and h replaced by $\tilde {h}$ and L by $\tilde {L}$ .

Proof. As in the first paragraph of the proof of Lemma 2.8, we observe that we can replace condition (i) by the weaker condition $|\hat {F}(0)-1|<\epsilon $ .

Now let g be as in Lemma 4.4, with $\eta $ and M to be determined. Set $F(t)=f(t)g(t)$ . Conditions (iii) and (iv) are immediate. We know that there exists a C such that $|\hat {f}(r)|\leq Cr^{-4}$ , so, provided N is large enough,

$$\begin{align*}|\hat{f}(r)|\leq \frac{\epsilon}{2}\big(k(|r|)L(|r|)\big)^{-1/2}\end{align*}$$

whenever $|r|\geq N$ .

We also have

$$ \begin{align*} |\hat{F}(r)-\hat{f}(r)| &=\left|\sum_{j\neq 0}\hat{f}(j)\hat{g}(r-j)\right| \leq \sum_{j\neq 0}|\hat{f}(j)||\hat{g}(r-j)|\\ &\leq \sum_{j\neq 0,|r-j|\geq M}Cj^{-4}\rightarrow 0 \end{align*} $$

as $M\rightarrow \infty $ for each r, so, provided we take M large enough, we will have

$$\begin{align*}|\hat{F}(r)-\hat{f}(r)|\leq\epsilon\big(k(|r|)L(|r|)\big)^{-1/2}\end{align*}$$

for all $1\leq |r|\leq N$ and in addition $|\hat {F}(0)-1|<\epsilon $ .

Combining the results of the two previous paragraphs, we see that the required result will hold, provided we can ensure that

$$\begin{align*}|\hat{F}(r)-\hat{f}(r)|\leq \frac{\epsilon}{2}\big(k(|r|)L(|r|)\big)^{-1/2}\end{align*}$$

for all $|r|\geq N$ . We have

$$ \begin{align*} |\hat{F}(r)-\hat{f}(r)| &\leq \sum_{j\neq 0}|\hat{f}(j)||\hat{g}(r-j)|\\ &\leq \sum_{j\neq 0,|r-j|\leq r/2}Cj^{-4}|\hat{g}(r-j)| +\sum_{|r-j|> |r|/2}Cj^{-4}. \end{align*} $$

We estimate the two sums separately:

$$\begin{align*}\sum_{|r-j|> |r|/2}j^{-4}\leq C_{1}|r|^{-3} \leq \frac{\epsilon}{4}\big(k(|r|)L(|r|)\big)^{-1/2}\end{align*}$$

(with $C_{1}$ an appropriate constant) for all $|r|\geq N$ , provided only that we have taken N large enough.

On the other hand, we know that there is a constant $C_{2}$ such that

$$\begin{align*}k(|r|)L(|r|)\leq C_{2}^{2}k(|j|)L(|j|)\end{align*}$$

for all $|r-j|\leq |r|/2$ , so

$$ \begin{align*} \sum_{j\neq 0,|r-j|\leq |r|/2}&Cj^{-4}|\hat{g}(r-j)| \leq \sum_{j\neq 0,|r-j|\leq |r|/2}Cj^{-4} \frac{\eta}{\big(k(|r-j|)L(|r-j|)\big)^{1/2}}\\ &\leq \sum_{j\neq 0,|r-j|\leq |r|/2}C_{2}Cj^{-4} \frac{\eta}{\big(k(|r|)L(|r|)\big)^{1/2}}\\ &\leq \frac{\eta C_{2}C}{\big(k(|r|)L(|r|)\big)^{1/2}}\\ &\leq \frac{\epsilon}{4\big(k(|r|)L(|r|)\big)^{1/2}}, \end{align*} $$

provided only that we have choose $\eta $ sufficiently small. Condition (ii) follows.

Proof of Theorem 1.4. Take $f_{0}=1$ . By Lemma 4.5, we can find a sequence of positive function $f_{n}\in C^{\infty }({\mathbb T})$ with the following properties:

1. (i) _n $\hat {f}_{n}(0)=1$ .

2. (ii) _n $\displaystyle {|\hat {f}_{n}(r)-\hat {f}_{n-1}(r)|\leq \frac {2^{-n}}{\big (k(|r|)L(|r|)\big )^{1/2}}}$ .

3. (iii) _n There is a finite collection of intervals ${\mathcal I}_{n}$ such that

   $$\begin{align*}\bigcup_{I\in {\mathcal I}_{n}}I\supseteq \operatorname{supp} f_{n}, \ \text{but}\ \bigcup_{I\in {\mathcal I}_{n}}h(|I|)\leq 2^{-n}.\end{align*}$$

4. (iv) _n $\operatorname {supp} f_{n}\subseteq \operatorname {supp} f_{n-1}$ .

Standard theorems now tell us that the measures $f_{n}m$ (where m is Lebesgue measure) converge weakly to a probability measure $\mu $ with $\operatorname {supp}\mu \subseteq \operatorname {supp} f_{n}$ and that $\mu $ has the properties we require.