Proof Let $f\in \boldsymbol{\textsf{F}}$ . For each $n\in \omega $ , let

$$ \begin{align*} X_n=\left\{k\in\omega:\frac{1}{n+2}\le f(k)<\frac{1}{n+1}\right\} \end{align*} $$

and $N_n=|X_n|$ . Since $\mathcal I_f$ is tall, we have that $N_n<\infty $ for all $n\in \omega $ . Denote $M_n=\sum \limits _{i=0}^{n}N_i$ . Let $Y_0=[0,M_0)$ and $Y_n=[M_{n-1},M_{n})$ for each $n>0$ . It follows that $|X_n|=|Y_n|$ for all n. For each $n\in \omega $ , define

$$ \begin{align*} m_1^n \text{ by } f(m_1^n)=\max f[X_n] \end{align*} $$

and

$$ \begin{align*} m_j^n \text{ by } f(m_j^n)=\max f[X_n\setminus\{m_1^n,\ldots, m_{j-1}^n\}] \text{ for each } 1<j\le N_n. \end{align*} $$

For each $n\in \omega $ , define a bijection $h_n:X_n\to Y_n$ by

$$ \begin{align*} h_n(m_j^n) = M_{n-1} + j - 1 \text{ for each } 1\le j \le N_n. \end{align*} $$

For each $n\in \omega $ , define $f^{\prime }_n:Y_n\to \mathbb {Q}_+$ by

$$ \begin{align*} f^{\prime}_n(h_n(m_j^n))=f(m_j^n) \text{ for all } 1\le j\le N_n. \end{align*} $$

Let $f'=\bigcup _{n\in \omega }f^{\prime }_n$ . Define $F(f)=f'$ . It follows that $F(f)$ is nonincreasing by the definition of $f'$ . Then $\mathcal I_f\simeq \mathcal I_{F(f)}$ is witnessed by $h=\bigcup _{n\in \omega }h_n$ .

Next we show that F is Borel. For any $n\in \omega $ and $b>a\ge 0$ , define

$$ \begin{align*} U&=\{f\in\boldsymbol{\textsf{F}}_{\boldsymbol{\textsf{DST}}}:f(n)\in(a,b)\} \text{ and} \\U_q&=\{f\in\boldsymbol{\textsf{F}}_{\boldsymbol{\textsf{DST}}}:f(n)=q\} \text{ for all } q\in(a,b)\cap\mathbb Q_+. \end{align*} $$

It follows that U is a basic open set in $\boldsymbol{\textsf{F}}_{\boldsymbol{\textsf{DST}}}$ and $U=\bigcup _{q\in (a,b)\cap \mathbb Q_+}U_q$ . Fix n, U, q, and $U_q$ as above. By the definition of $\boldsymbol{\textsf{F}}_{\boldsymbol{\textsf{DST}}}$ , for each $f\in U_q$ we have that

$$ \begin{align*} f(i)\ge q \text{ for all } 0\le i<n \text{ and } f(j)\le q \text{ for all } j>n. \end{align*} $$

Let $A=\{q\}$ , $B=[q,+\infty )$ , and $C=[0,q]$ . It is easy to see that the set $A\times B^n\times C^\omega $ is Borel in $\mathbb {Q}_+^{\omega }$ . For each $K\in [\omega ]^{n+1}$ , let $P_K\subseteq \omega ^{n+1}$ be the set of all permutations of K (i.e., all bijections from K to K). For each $a=(a_0,a_1,\ldots ,a_n)\in P_K$ , define $S(a)=(S_0,S_1,\ldots ,S_n,\ldots )\in \mathcal P(\omega )^\omega $ by

$$ \begin{align*} S_{a_0}=A, S_{a_1}=\cdots=S_{a_n}=B \text{ and } S_j=C \text{ for all } j\not\in\{a_0,\ldots,a_n\}. \end{align*} $$

Denote $\prod S(a)=\prod _{i\in \omega }S_i.$ Then

$$ \begin{align*} F^{-1}(U)=\bigcup_{q\in(a,b)\cap\mathbb Q_+}F^{-1}(U_q)=\bigcup_{q\in(a,b)\cap\mathbb Q_+}\bigcup_{K\in[\omega]^{n+1}}\bigcup_{a\in P_K}\prod S(a). \end{align*} $$

It follows that $F^{-1}(U)$ is a Borel set and F is Borel.

Proof ( $\Rightarrow $ ): Let $\mathcal I_f,\mathcal I_g\in \boldsymbol{\textsf{summable ideals}}$ such that $\mathcal I_f\le _K\mathcal I_g$ . Then we have that

$$\begin{align*}\mathcal I_{F(f)}\simeq\mathcal I_f\le_K\mathcal I_g\simeq\mathcal I_{F(g)}.\end{align*}$$

It follows that $\mathcal I_{F(f)}\le _K\mathcal I_{F(g)}$ .

( $\Leftarrow $ ): Let $\mathcal I_f,\mathcal I_g\in \boldsymbol{\textsf{summable ideals}}$ such that $\mathcal I_f\not \le _K\mathcal I_g$ and $p:\omega \to \omega $ be a map. Let $e_1$ and $e_2$ be witnesses for $\mathcal I_f\simeq \mathcal I_{F(f)}$ and $\mathcal I_g\simeq \mathcal I_{F(g)}$ , respectively. By $\mathcal I_f\not \le _K\mathcal I_g$ , there exists $A\in \mathcal I_f$ such that

$$\begin{align*}(e_1^{-1}\circ p\circ e_2)^{-1}(A)\not\in\mathcal I_g.\end{align*}$$

Then we have that $e_1[A]\in \mathcal I_{F(f)}$ and

$$\begin{align*}e_2^{-1}(p^{-1}(e_1[A]))\not\in\mathcal I_g\Leftrightarrow p^{-1}(e_1[A])\not\in\mathcal I_{F(g)}.\end{align*}$$

Thus $\mathcal I_{F(f)}\not \le _K\mathcal I_{F(g)}$ .

Proof Suppose that $\mathcal I_f\in \boldsymbol{\textsf{summable ideals}}$ . Then $\lim \limits _{n \rightarrow \infty }f(n)=0$ and $\sum \limits _{n\in \omega }f(n)=\infty $ . Inductively take $\{k_n:n\in \omega \}$ such that for each $n\in \omega $ ,

1. (1) $k_n<k_{n+1}$ ,

2. (2) $f(m)<1/(n+1)$ for each $m\ge k_n$ , and

3. (3) $ u_f([k_n,k_{n+1}))\ge 1$ .

Suppose we have already constructed $\{k_j:j\le n\}$ such that (1)–(3) holds. Since $\lim _{n \rightarrow \infty }f(n)=0$ , we can find $k_{n+1}$ large enough such that (1) and (2) hold. By $\Sigma _{n\in \omega }f(n)=\infty $ we have $u_f([k_n,\infty ))=\infty $ , so we may find $k_{n+1}$ such that (3) holds. Denote $N_n:=u_f([k_n,k_{n+1}))\ge 1$ and $I_n:=[k_n,k_{n+1})$ for all $n\in \omega $ . Then

$$ \begin{align*} u_f(I_n)= N_n\ge 1. \end{align*} $$

Now let $\{\mathcal I_{f_m}:m\in \omega \}\subseteq \boldsymbol{\textsf{summable ideals}}$ . For each $m\in \omega $ , let $k^m_n$ , $I^m_n$ , $N^m_n$ be as above. Then for all $n,m\in \omega $ ,

$$ \begin{align*} u_{f_m}(I_n^m)= N_n^m\ge 1. \end{align*} $$

For each $n\in \omega $ , let $X_n=\prod \limits _{m<n} I^m_n\subseteq \omega ^n$ and $X=\bigcup \limits _{n\in \omega }X_n$ . Fix $n\in \omega $ . For any $(i_0,i_1,\ldots ,i_{n-1})\in X_n$ , define a function f by

$$ \begin{align*} f\big( (i_0,i_1,\ldots,i_{n-1}) \big)=\frac{\prod\limits_{m<n}f_m(i_m)}{\prod\limits_{m<n}N^m_n}. \end{align*} $$

Then

$$ \begin{align*} u_f(X_n) & =\displaystyle\sum\limits_{(i_0,\ldots,i_{n-1})\in X_n}f\big((i_0,\ldots,i_{n-1})\big)= \displaystyle\sum\limits_{i_0\in I^0_n, \ldots, i_{m}\in I^{n-1}_n}f\big((i_0,\ldots,i_{n-1})\big) \\ & =\frac{1}{\prod\limits_{m<n}N^m_n} \cdot \displaystyle\sum\limits_{i_0\in I^0_n, \cdots, i_{n-1}\in I^{n-1}_n}\left(\prod\limits_{m<n}f_m(i_m)\right)=\frac{1}{\prod\limits_{m<n}N^m_n} \cdot \prod\limits_{m<n}u_{f_m}(I^m_n) \\ & =1, \end{align*} $$

so $u_f(X)=\infty $ .

By (2), for all $n\in \omega $ we have that

$$ \begin{align*} f\big( (i_0,i_1,\ldots,i_{n-1}) \big)\le\frac{1}{(n+1)^n} \text{ for every } (i_0,i_1,\ldots,i_{n-1})\in X_n, \end{align*} $$

so $\mathcal I_f$ is tall.

We will show that for each $m\in \omega $ , $\mathcal I_{f_m}\le _{KB} \mathcal I_f$ . Fix $m\in \omega $ . Define $\pi _m:X\to \omega $ by

$$ \begin{align*} \pi_m\big((i_0,\ldots,i_{n-1})\big)=0, & n\le m, \\ \pi_m\big((i_0,\ldots,i_{n-1})\big)=i_m, & n> m, \end{align*} $$

Then $\left |\pi _m^{-1}(0)\right |<\infty $ and $u_f\left (\pi _m^{-1}(0)\right )<\infty $ . Let $i\in \omega \setminus \{0\}$ . If $i\in I^m_n$ for some $n\le m$ then $\pi _m^{-1}(i)=\emptyset $ . We assume that $i\in I^m_n$ for some $n>m$ . It follows that $\left |\pi _m^{-1}(i)\right |\le \left |X_n\right |<\infty $ and

$$ \begin{align*} u_f\left(\pi_m^{-1}(i)\right) & = u_f\Big(\big\{(i_0,\ldots,i_m,\ldots,i_{n-1})\in X:i_m=i\big\}\Big) \\ & =\frac{f_m(i)}{N^m_n}\cdot\sum\limits_{(i_{0},\ldots,i_{n-1})}\left(\frac{\prod\limits_{j< n,\ j\neq m}f_j(i_j)}{\prod\limits_{j<n,j\not=m}N^j_n}\right) = \frac{f_m(i)}{N^m_n}\le f_m(i). \end{align*} $$

Thus, for every $A\subseteq \omega \setminus \{0\}$ with $u_{f_m}(A)<\infty $ we have that $u_f\left (\pi ^{-1}_m(A)\right )\le u_{f_m}(A)<\infty $ .

Proof (1) $\Rightarrow $ (2): Let $p:\omega \rightarrow \omega $ be a witness for $\mathcal I_f\le _K\mathcal I_g$ . We show that there exists $C>0$ such that $A[C]=\left \{n:u_g\left (p^{-1}(n)\right )\le C\cdot f(n)\right \}\in \mathcal I_f^*$ . Otherwise, $A[C]\not \in \mathcal I_f^*$ for every $C>0$ . Thus, we can find pairwise disjoint finite sets $\{a_n:1\le n<\omega \}$ such that for each $1\le n\in \omega $ ,

1. (i) $f(j)\le \frac {1}{n^2}$ for any $j\in a_n$ ,

2. (ii) $a_n\subseteq \omega \setminus A[n]$ , and

3. (iii) $\frac {1}{n^2}\le u_f(a_n)\le \frac {2}{n^2}$ .

By (ii),

$$\begin{align*}u_g\left(p^{-1}\left(a_n\right)\right)> n\cdot u_f\left(a_n\right) \ge \frac{1}{n}.\end{align*}$$

Let $B=\bigcup \limits _{1\le n<\omega }a_n$ . Then

$$ \begin{align*} u_f(B)\le\sum\limits_{n=1}\limits^\infty\frac{2}{n^2}<\infty, \text{and}\ u_g\left(p^{-1}(B)\right)\ge\sum\limits_{n=1}\limits^{\infty}\frac{1}{n}=\infty. \end{align*} $$

This contradicts the definition of p.

(2) $\Rightarrow $ (3): Let p and C be such that $A[C]\in \mathcal I_f^*$ and $p^{-1}(A[C])\in \mathcal I_g^*$ . Then $p^{-1}\left (\omega \setminus A[C]\right )\in \mathcal I_g$ . Take $M>C+1$ such that $u_g\left (p^{-1}\left (\omega \setminus A[C]\right )\setminus M\right )<1$ and $u_f\left ([0,M]\right )>2$ . Assume $l> M$ , $k_1>k_0\ge M$ with $u_g([k_0,k_1])>Mu_f([0,l])$ . Consider $t=[k_0,k_1]\setminus p^{-1}\left ([0,l]\right )$ . The proof is divided into two cases.

Case 1: $p(t)\cap A[C]=\emptyset $ .

Then $t\cap p^{-1}(A[C])=\emptyset $ . By $k_0\ge M$ , we have that $t\subset p^{-1}(\omega \setminus A[C])\setminus M$ . By the definition of M we have $u_g(t)<1$ . On the other hand we have

$$ \begin{align*} u_g\Big([k_0,k_1]\cap p^{-1}([0,l])\cap p^{-1}(\omega\setminus A[C])\Big)\le u_g\Big(p^{-1}(\omega\setminus A[C])\setminus M\Big)<1\end{align*} $$

and

$$ \begin{align*} u_g\Big([k_0,k_1]\cap p^{-1}([0,l])\cap p^{-1}(A[C])\Big)\le C\cdot u_f\Big([0,l]\cap A[C])\Big)\le C\cdot u_f([0,l]). \end{align*} $$

Thus

$$ \begin{align*} u_g\Big([k_0,k_1]\cap p^{-1}([0,l])\Big) & \le 1+C\cdot u_f([0,l]) \\ & = 2+C\cdot u_f([0,l])-1<(C+1)\cdot u_f([0,l])-1 \end{align*} $$

and

$$ \begin{align*} u_g(t)=u_g\Big([k_0,k_1]\setminus p^{-1}\left([0,l]\right)\Big) & = u_g([k_0,k_1])-u_g\Big([k_0,k_1]\cap p^{-1}([0,l])\Big) \\ &> M\cdot u_f([0,l])-((C+1)\cdot u_f([0,l])-1)>1. \end{align*} $$

A contradiction.

Case 2: $p(t)\cap A[C]\neq \emptyset $ .

Let $m\in t$ and $p(m)\in A[C]$ . Then $m\le k_1$ , $p(m)>l$ , and $u_g\left (p^{-1}(p(m))\right )\le C\cdot f(p(m))$ . By the monotonicity of f and g, we have

$$ \begin{align*} g(k_1)\le g(m)\le u_g\left(p^{-1}(p(m))\right)\le C\cdot f(p(m))\le C\cdot f(l)<M\cdot f(l). \end{align*} $$

(3) $\Rightarrow $ (4): Choose $k_0$ such that

$$ \begin{align*} u_g([M,k_0))=u_g([M,k_0-1])>M\cdot u_f([0,M]). \end{align*} $$

We recursively choose a sequence $k_0<k_1<\cdots $ such that for each i, $k_{i+1}$ is the minimal such that $u_g([k_i,k_{i+1}))\ge M\cdot f(M+1+i).$ Then we have

$$ \begin{align*} u_g([M,k_{i+1}))>M\cdot u_f([0,M])+M\cdot\sum\limits_{j=0}\limits^{i}f(M+1+j)=M\cdot u_f([0,M+1+i]). \end{align*} $$

Thus $g(k_{i+1}-1)\le M\cdot f(M+1+i)$ by the assumption of (3). The proof is divided into two cases.

Case 1. $k_{i+1}-1=k_i$ . Clearly we have that $g(k_{i+1}-1)=u_g([k_i,k_{i+1}))= M\cdot f(M+1+i)$ .

Case 2. $k_{i+1}-1>k_i$ . By the definition of $k_{i+1}$ , we have $u_g([k_i,k_{i+1}-1))< M\cdot f(M+1+i).$ This implies that

$$\begin{align*}M\cdot f(M+1+i)\le u_g([k_i,k_{i+1}))&=u_g([k_i,k_{i+1}-1))+g(k_{i+1}-1)\\ &< 2M\cdot f(M+1+i).\end{align*}$$

Let $p:\omega \rightarrow \omega $ be an interval-to-one map such that $p^{-1}([0,M])=[0,k_0)$ and $p^{-1}(M+1+i)=[k_i,k_{i+1})$ for every i. Define

$$\begin{align*}C=\max\left\{2M,\max\left\{\frac{u_g(p^{-1}(n))}{u_f(n)}:n\le M\right\}\right\} \end{align*}$$

and

$$\begin{align*}c=\min\left\{M,\min\left\{\frac{u_g(p^{-1}(n))}{u_f(n)}:n\le M\right\}\right\}.\end{align*}$$

Then, for each $n\le M$ we have that

$$ \begin{align*} c\cdot f(n)\le\frac{u_g\left(p^{-1}(n)\right)}{f(n)}\cdot f(n)=u_g\left(p^{-1}(n)\right)=\frac{u_g\left(p^{-1}(n)\right)}{f(n)}\cdot f(n)\le C\cdot f(n). \end{align*} $$

(4) $\Rightarrow $ (7): For every $A\subseteq \omega $ , we have that

$$ \begin{align*} u_f(A)<\infty\Rightarrow u_g\left(p^{-1}(A)\right)\le C\cdot u_f(A)<\infty \end{align*} $$

and

$$ \begin{align*} u_g\left(p^{-1}(A)\right)<\infty\Rightarrow u_f(A)\le \frac{1}{c}\cdot u_g\left(p^{-1}(A)\right)<\infty. \end{align*} $$

(4) $\Rightarrow $ (5), (5) $\Rightarrow $ (1), (7) $\Rightarrow $ (1) are clear.

(5) $\Rightarrow $ (6): Let C be as in (5). Define $M=C$ . We will show that M is as desired. Let l, $k\in \omega $ with $u_g([0,k])>M\cdot u_f([0,l])$ . By the assumption of (5), $u_g\left (p^{-1}([0,l])\right )\le M\cdot u_f([0,l])$ , so $[0,k]\setminus p^{-1}([0,l])\neq \emptyset $ . Take $m\in [0,k]\setminus p^{-1}([0,l])$ . Then $m\le k$ and $p(m)>l$ . It follows that

$$ \begin{align*} g(k)\le g(m)\le u_g\left(p^{-1}(p(m))\right)\le M\cdot f(p(m))\le M\cdot f(l). \end{align*} $$

(6) $\Rightarrow $ (5): Choose $k_0$ such that

$$ \begin{align*} u_g([0,k_0))=u_g([0,k_0-1])>M\cdot f(0). \end{align*} $$

Recursively define a sequence $k_0<k_1<\cdots $ such that for each $i>0$ , $k_i$ is the minimal such that $u_g([k_{i-1},k_i))\ge M\cdot f(i).$ Then we have

$$ \begin{align*} u_g([0,k_i))>M\cdot\sum\limits_{j=0}\limits^{i}f(j)=M\cdot u_f([0,i]). \end{align*} $$

Thus $g(k_i-1)\le M\cdot f(i)$ by the assumption of (5). The proof is divided into two cases.

Case 1. $k_i-1=k_{i-1}$ . Clearly we have that $g(k_i-1)=u_g([k_{i-1},k_i))=M\cdot f(i)$ .

Case 2. $k_i-1>k_{i-1}$ . By the choice of $k_i$ , we have $u_g([k_{i-1},k_i-1))< M\cdot f(i)$ . This implies that

$$ \begin{align*} M\cdot f(i)\le u_g([k_i,k_{i+1}))=u_g([k_i,k_{i+1}-1))+g(k_{i+1}-1)< 2M\cdot f(i). \end{align*} $$

Let $p:\omega \rightarrow \omega $ be an interval-to-one map such that $p^{-1}(0)=[0,k_0)$ and $p^{-1}(i)=[k_{i-1},k_i)$ for every $i>0$ . It is easy to see that p and $C=2M$ .

Proof Fix $(t_0,q_0),(t_{1},q_{1})\in \Phi (s,p)$ . Define $(t,q)$ as follows. Define $I_0 = \big [q_0(k_s),q_0(k_s+1)\big )$ and $I_1 = \big [q_1(k_s),q_1(k_s+1)\big )$ and $I=I_0\times I_1$ .

Figure 2 An element $(s,p)$ of set $\Phi$ .

Fix $i\in \{0,1\}$ . Denote $N_i:= u_{t_i}\big (I_i)\ge 1.$ For every $(j_0,j_1)\in I$ , define t by

$$ \begin{align*} t\big((j_0,j_1)\big)=\frac{t_0(j_0)\cdot t_1(j_1)}{N_0\cdot N_1}. \end{align*} $$

Let $M=|I_1|\cdot |I_2|$ . We can find a bijection e from I to $[p(k_s)+1,p(k_s)+M]$ such that

$$ \begin{align*} t(e^{-1}(j))\ge t(e^{-1}(j+1)) \text{ for all } j\in[p(k_s)+1,p(k_s)+M]. \end{align*} $$

Let $q(k_s)=p(k_s)$ and $q(k_s+1)=p(k_s)+M + 1$ . Then

$$ \begin{align*} I=e^{-1}(\big[q(k_s),q(k_s+1)\big)). \end{align*} $$

Without loss of generality, we can regard I as $\big [q(k_s),q(k_s+1)\big )$ .

We will show that $(t,q)\in \Phi (s,p)$ and $(t_i,q_i)\unlhd _{(s,p)} (t,q)$ for $i\in \{0,1\}$ .

(1) $(t,q)\in \Phi (s,p)$ :

Use

$$ \begin{align*} u_t(I)=\displaystyle\sum\limits_{(j_0,j_1)\in I} \frac{t_0(j_0)\cdot t_1(j_1)}{N_0\cdot N_1}= 1 \end{align*} $$

and

$$ \begin{align*} t\big((j_0,j_1)\big)=\frac{t_0(j_0)\cdot t_1(j_1)}{N_0\cdot N_1} \le \frac{1}{N_0\cdot N_1}\cdot\frac{1}{k_s^2}\le\frac{1}{k_s} \text{ for all } (j_0,j_1)\in I. \end{align*} $$

(2) $(t_i,q_i)\unlhd _{(s,p)} (t,q)$ for $i\in \{0,1\}$ :

Let $\pi _0$ and $\pi _1$ be the projection map onto the first coordinate and second coordinate, respectively. For any $j\in I_0$ , we have that

$$ \begin{align*} \pi^{-1}_{0}(j)=\left\{(j,j_{1}):j_{1}\in I_1\right\} \end{align*} $$

and

$$ \begin{align*} u_t\left(\pi_{0}^{-1}(j)\right)= \frac{t_{0}(j)}{N_{0}}\cdot\displaystyle\sum\limits_{j_{1}\in I_1}\frac{t_1(j_1)}{N_1} = \frac{t_{0}(j)}{N_{0}}\le t_{0}(j). \end{align*} $$

Similarly, we have $u_t\left (\pi _{1}^{-1}(j)\right )\le t_{1}(j)$ .

Proof Enumerate

$$\begin{align*}\Phi=\{(s_i,p_i),i\in\omega\}.\end{align*}$$

Enumerate

$$\begin{align*}\widetilde{\Phi}(s_i,p_i)=\left\{\left(t^{(s_i,p_i)}_j,q^{(s_i,p_i)}_j\right):j\in\omega\right\}\end{align*}$$

in such way that $(t^{(s_i,p_i)}_j,q^{(s_i,p_i)}_j)\unlhd _{(s_i,p_i)}(t^{(s_i,p_i)}_k,q^{(s_i,p_i)}_k)$ for all $j<k$ .

Define $\rho _+:\omega ^\omega \to \mathbb H$ as follows. For every $g\in \omega ^\omega $ and $i\in \omega $ , let

$$ \begin{align*} \rho_+(g)((s_i,p_i))=\Big(t^{(s_i,p_i)}_{g(i)},q^{(s_i,p_i)}_{g(i)}\Big). \end{align*} $$

Define $\rho _-:\mathbb H\to \omega ^\omega $ as follows. For every $h\in \mathbb H$ and $i\in \omega $ , let

$$ \begin{align*} h((s_i,p_i))=\Big(t^{(s_i,p_i)}_{\rho_-(h)(i)},q^{(s_i,p_i)}_{\rho_-(h)(i)}\Big) \text{ for all } i\in\omega. \end{align*} $$

We claim that

$$ \begin{align*} \forall h\in \mathbb H~\forall g\in\omega^\omega(\rho_-(h)\le^* g\Rightarrow h\leq^\circ \rho_+(g)). \end{align*} $$

Suppose $h\in \mathbb H$ , $g\in \omega ^\omega $ , and $\rho _-(h)\le ^*g$ . There is $n\in \omega $ such that for each $i\ge n$ we have $\rho _-(h)(i)\le g(i)$ . Then $h((s_i,p_i))\unlhd _{(s_i,p_i)} \rho _+(g)((s_i,p_i))$ for all but finitely many $i\in \omega $ , i.e., $h\leq ^\circ \rho _+(g)$ .

Proof Define $\rho _+:\mathbb H\to \boldsymbol{\textsf{ST}}$ as follows. Define $q_{-1}\in \omega ^1$ by $q_{-1}(1)=0$ and $t_{-1}(0)=1$ . For each $h\in \mathbb H$ , let $(t_0^h,q_0^h)=h((t_{-1},q_{-1}))$ and $(t^h_{n+1},q^h_{n+1})=h((t^h_n,q^h_n))$ for all $n\in \omega $ . Let $g=\bigcup \limits _{n\in \omega } t^h_n$ and $\rho _+(h)=\mathcal I_g$ . Since $q_{-1}=(q_{-1}(1))$ , we have that $q_0^h=(q_0^h(1),q_0^h(2))$ , and

$$ \begin{align*} q_n^h=(q_n^h(1),q_n^h(2),\ldots,q_n^h(n+2)) \text{ for } n\in\omega \text{, i.e., } k_{t_n^h}=n+2 \end{align*} $$

(see ( $*$ ) at the beginning of Section 4 for the definition of $k_{t_n^h}$ ).

Define $\rho _-:\boldsymbol{\textsf{ST}}\to \mathbb H$ as follows. For $\mathcal I_f\in \boldsymbol{\textsf{ST}}$ , take $0=m_1<m_2<\cdots <m_i<\cdots $ such that for each $i>0$ ,

$$ \begin{align*} u_f([m_i,m_{i+1}))\ge 1 \text{ and } f(j)\le \frac{1}{i} \text{ for every } j\ge m_i. \end{align*} $$

For each $n\ge 1$ , let $p(n)=m_n$ , $p_n=(p(1),\ldots ,p(n))$ , and $s_n=f\big |_{[0,p(n))}$ . For every $(t,q)\in \Phi $ with $q=(q(1),\ldots ,q(k_t))$ , let

$$ \begin{align*} p^{\prime}_t & =\big(q(1),\ldots,q(k_t),q(k_t)+p(k_t+1)-p(k_t)\big) \\ & =\big(p^{\prime}_t(1),\ldots,p^{\prime}_t(k_t),p^{\prime}_t(k_t+1)\big). \end{align*} $$

We have that:

• • $p^{\prime }_t(j)=q(j)$ for $1\le j\le k_t$ ,

• • $p^{\prime }_t(k_t+1)=q(k_t)+p(k_t+1)-p(k_t)$ , and

• • $s^{\prime }_t=t^\frown f\big |_{[p(k_t),p(k_t+1))}$ .

Then $(s^{\prime }_t,p^{\prime }_t)\in \Phi (t,q)$ (see Figure 3). Take $(s^*_t,p^*_t)\in \widetilde {\Phi }(t,q)$ such that $(s^{\prime }_t,p^{\prime }_t)\unlhd _{(t,q)}(s^*_t,p^*_t)$ . Define $\rho _- (\mathcal I_f)((t,q))=(s^*_t,p^*_t)$ .

Figure 3 The definition of $(s'_t, p'_t)$ in the proof of Lemma 5.3.

We claim that

$$ \begin{align*} \forall\mathcal I_f\in\boldsymbol{\textsf{ST}}~\forall h\in \mathbb H(\rho_-(\mathcal I_f)\leq^\circ h\Rightarrow\mathcal I_f\le_K \rho_+(h)). \end{align*} $$

Suppose $\mathcal I_f\in \boldsymbol{\textsf{ST}}$ , $h\in \mathbb H$ , and $\rho _-(\mathcal I_f)\leq ^\circ h$ . Let $\{s_n:n\in \omega \}$ and p be like in the definition of $\rho _-(\mathcal I_f)$ . Then we have that

$$ \begin{align*} \rho_-(\mathcal I_f)((t,q))\unlhd_{(t,q)}h((t,q)) \end{align*} $$

for all but finitely many $(t,q)\in \Phi $ . By the definition of $\rho _+$ , there exists $\{(t_n^h,q_n^h):n\in \omega \}$ . Then there is N such that for $n>N$ , we have that

$$\begin{align*}\rho_-(\mathcal I_f)((t_n^h,q_n^h))\unlhd_{(t_n^h,q_n^h)}h((t_n^h,q_n^h))=(t_{n+1}^h,q_{n+1}^h).\end{align*}$$

Since $\rho _-(\mathcal I_f)((t_n^h,q_n^h))=(s_{t_n^h}^*,p_{t_n^h}^*)$ , we have that

$$ \begin{align*} (s^{\prime}_{t_n^h},p^{\prime}_{t_n^h})\unlhd_{(t_n^h,q_n^h)}(s_{t_n^h}^*,p_{t_n^h}^*)\unlhd_{(t_n^h,q_n^h)}(t_{n+1}^h,q_{n+1}^h). \end{align*} $$

Then for each $n>N$ , there exists a map

$$\begin{align*}{\pi'}_n:[q_{n+1}^h(n+2),q_{n+1}^h(n+3))\to[p^{\prime}_{t_n^h}(n+2),p^{\prime}_{t_n^h}(n+3))\end{align*}$$

such that

$$ \begin{align*} u_{t_{n+1}^h}({\pi'}_n^{-1}(i))\le s^{\prime}_{t_n^h}(i) \text{ for all } i\in [p^{\prime}_{t_n^h}(n+2),p^{\prime}_{t_n^h}(n+3)). \end{align*} $$

Define $\sigma _n:[p^{\prime }_{t_n^h}(n+2),p^{\prime }_{t_n^h}(n+3))\to [p(n+2),p(n+3))$ by

$$ \begin{align*} \sigma_n(j)=j-p^{\prime}_{t_n^h}(n+2)+p(n+2) \text{ for all } j \in[p^{\prime}_{t_n^h}(n+2),p^{\prime}_{t_n^h}(n+3)). \end{align*} $$

Define $\pi _n=\sigma _n\circ {\pi '}_n$ for each $n>N$ . We have that

$$ \begin{align*} u_{t_{n+1}^h}(\pi_n^{-1}(i))\le s_{n+3}(i) \text{ for each } i\in [p(n+2),p(n+3)). \end{align*} $$

There exist $\pi _{-1}:[0,q_0^h(2))\to [0,p(2))$ and $c_{-1}>0$ such that

$$ \begin{align*} u_{t_0^h}(\pi_{-1}^{-1}(i))\le c_{-1}\cdot s_2(i) \text{ for each } i \in[0,p(2)). \end{align*} $$

For every $m\le N$ , there exist $\pi _{m}:[q_m^h(m+2),q_m^h(m+3))\to [p(m+2),p(m+3))$ and $c_{m}>0$ such that

$$ \begin{align*} u_{t_{m+1}^h}(\pi_{m}^{-1}(i))\le c_{m}\cdot s_{m+3}(i) \text{ for each } i \in[p(m+2),p(m+3)). \end{align*} $$

Let $\pi =\bigcup \limits _{n\in \omega \cup \{-1\}}\pi _n$ and $C=\max \{1,c_{-1},c_{0},\ldots ,c_{N}\}$ . Then we have that

$$ \begin{align*} u_g(\pi^{-1}(i))\le C\cdot f(i) \text{ for } i\in\omega\ \mathrm{(see\ Figure\ 4)}.\end{align*} $$

Then $\pi $ witnesses $\mathcal I_f \le _K \mathcal I_g=\rho _+(h)$ by Theorem 4.1(5).

Proof Define $\rho _+:\boldsymbol{\textsf{ST}} \to \omega ^\omega $ as follows. For each $\mathcal I_g\in \boldsymbol{\textsf{ST}}$ and $n\ge 1$ , there exists $\rho _+(\mathcal I_g)$ such that

$$ \begin{align*} u_g\big(\big[\rho_+(\mathcal I_g)(n-1), \rho_+(\mathcal I_g)(n)\big)\big)\ge n^2. \end{align*} $$

Define $\rho _-: \omega ^\omega \to \boldsymbol{\textsf{ST}}$ as follows. For each $r\in \omega ^\omega $ , take a partition $(A_n^r:n\in \omega )$ of $\omega $ into successive finite intervals such that $|A^r_0|\ge 1$ ,

$$ \begin{align*} \text{min}(A^r_n)\ge r(n) \text{, and } |A^r_n|\ge \max\{n, |A^r_{n-1}|\} \text{ for each } n\in \omega\setminus \{0\}. \end{align*} $$

Then define $f_r:\omega \to \mathbb {Q}_+ $ by

$$ \begin{align*} f_r(k)=1/|A^r_n| \text{ where } n \text{ such that } k\in A^r_n. \end{align*} $$

Let $\rho _-(r)=\mathcal I_{f_r}$ .

We claim that

$$ \begin{align*} \forall r\in\omega^\omega~\forall\mathcal I_g\in\boldsymbol{\textsf{ST}} (\rho_-(r)\leq_K \mathcal I_g\Rightarrow r\le^* \rho_+(\mathcal I_g)). \end{align*} $$

Take arbitrary $r\in \omega ^\omega $ and $\mathcal I_g\in \boldsymbol{\textsf{ST}}$ such that $\mathcal I_{f_r}=\rho _-(r)\le _K \mathcal I_g$ . By Theorem 4.1(5), there exist a map $p:\omega \to \omega $ and $C>0$ such that

$$ \begin{align*} u_g(p^{-1}(i))\le C\cdot f_r(i) \text{ for all } i\in\omega. \end{align*} $$

By the Remark (above Figure 1), we may assume that p is a nondecreasing surjection and $p(i)\le i$ . Thus $\max p^{-1}(i)\ge i$ for all $i\in \omega $ . Then for large enough n, there is $j_n$ such that

$$ \begin{align*} u_g([0,j_n]) & =u_g\Big(p^{-1}\Big(\bigcup\limits_{0\le m\le n}A^r_m\Big)\Big)\le C\cdot u_{f_r}\Big(\bigcup\limits_{0\le m\le n}A^r_m\Big)= n\cdot C \le n^2 \\ & \le u_g\left(\big[\rho_+(\mathcal I_g)(n-1), \rho_+(\mathcal I_g)(n)\big)\right)\le u_g\left(\big[0, \rho_+(\mathcal I_g)(n)\big)\right). \end{align*} $$

Thus $j_n\le \rho _+(\mathcal I_g)(n)$ for large enough n. Then for large enough n we have that

$$ \begin{align*} r(n)\le\max\Big(\bigcup\limits_{0\le m\le n}A^r_m\Big)\le\max p^{-1}\Big(\bigcup\limits_{0\le m\le n}A^r_m\Big)= j_n. \end{align*} $$

Therefore we have that $r(n)\le j_n\le \rho _+(\mathcal I_g)(n)$ for large enough n.

Proof Combine Lemma 5.4 with Lemma 5.5.

Proof Let $\omega ^{\uparrow \omega }$ be all strictly increasing functions from $\omega $ to $\omega \setminus \{0\}$ . It suffices to show that $(\boldsymbol{\textsf{ST}}, \geq _K)\leq _{GT}\left (\omega ^{\uparrow \omega },\leq ^*\right )$ because $\left (\omega ^{\uparrow \omega },\leq ^*\right )\leq _{GT}(\omega ^\omega ,\leq ^*)$ .

Define $\rho _-: \boldsymbol{\textsf{ST}} \to \omega ^{\uparrow \omega }$ as follows. For each $\mathcal I_f\in \boldsymbol{\textsf{ST}}$ , define $\rho _-(\mathcal I_f)\in \omega ^{\uparrow \omega }$ by $\rho _-(\mathcal I_f)(0) = 1$ and

$$ \begin{align*} \rho_-(\mathcal I_f)(k)=\min\left\{n>\rho_-(\mathcal I_f)(k-1):\forall m\geq n \left(f(m)\leq \frac {1}{k}\right)\right\} \end{align*} $$

for all $k\ge 1$ .

Define $\rho _+: \omega ^{\uparrow \omega }\to \boldsymbol{\textsf{ST}} $ as follows. For each $x\in \omega ^{\uparrow \omega }$ , define $F:\omega ^{\uparrow \omega } \to \boldsymbol{\textsf{F}}_{\boldsymbol{\textsf{DST}}}$ by $F(x)(k)=1$ for all $0\leq k<x(1),$ and

$$ \begin{align*} F(x)(k)=\frac {1} {n} \text{ where } n \text{ is such that } k\in [x(n),x(n+1)). \end{align*} $$

Then $\mathcal I_{F(x)}$ is tall for each $x\in \omega ^{\uparrow \omega } $ . Let $\rho _+(x)=\mathcal I_{F(x)}$ .

We claim that

$$ \begin{align*} \forall \mathcal I_f\in \boldsymbol{\textsf{ST}}~ \forall x\in \omega^{\uparrow \omega}\left(\rho_-(\mathcal I_f)\leq^* x\Rightarrow \mathcal I_f\geq_K \rho_{+}(x)\right). \end{align*} $$

Let $\mathcal I_f\in \boldsymbol{\textsf{ST}}$ and $x\in \omega ^{\uparrow \omega }$ such that $\rho _-(\mathcal I_f)\leq ^* x$ . We will show that $f\leq ^* F(x)$ and then $\mathbf {id}: \omega \to \omega $ will be a witness for $\mathcal I_f\geq _K \mathcal I_{F(x)}$ . To see that $f\leq ^* F(x)$ , take $N>0$ such that

$$ \begin{align*} \rho_-(\mathcal I_f)(n)\leq x(n) \text{ for each } n\geq N. \end{align*} $$

Then for each $n\geq N$ and $k\in [x(n),x(n+1))$ we have $k\ge \rho _-(\mathcal I_f)(n)$ . By the definition of $\rho _-(\mathcal I_f)$ , we have $f(k)\leq \frac {1}{n}=F(x)(k)$ . It follows that $f\leq ^* F(x)$ .

Proof Define $\rho _-: \omega ^{\omega } \to \boldsymbol{\textsf{ST}}$ as follows. For each $x\in \omega ^{\omega } $ , take a partition $\{A^x_n: n\in \omega \setminus \{0\}\}$ of $\omega $ into successive finite intervals such that for all $n>0$ :

1. (1) $\min A^x_n\geq \min \{x(n), n\}$ and

2. (2) $|A^x_n|\geq n^2 (x(n)+1)$ .

Then define $g_x \in \boldsymbol{\textsf{F}}_{\boldsymbol{\textsf{DST}}}$ by

$$ \begin{align*} g_x(k)=\frac 1{n} \text{ where } n \text{ is such that } k\in A^x_n. \end{align*} $$

Let $\rho _-(x)=\mathcal I_{g_x}$ . It follows that $\rho _-(x)$ is tall for all $x\in \omega ^\omega $ .

Define $ \rho _+: \boldsymbol{\textsf{ST}}\to \omega ^{\omega }$ as follows. Suppose $\mathcal I_f\in \boldsymbol{\textsf{ST}}$ . For each $n>0$ , define $\rho _+(\mathcal I_f)$ by $\rho _+(\mathcal I_f)(0)=0$ and $\rho _+(\mathcal I_f)(n)=$

$$ \begin{align*} \min\left\{m \ge n+1: m\geq u_f\big(\big[0,\rho_+(\mathcal I_f)(n-1)\big]\big) ~\&~ \forall k\geq m\left(f(k)\leq \frac{1}{(n+1)^2}\right) \right\}. \end{align*} $$

We claim that

$$ \begin{align*} \forall \mathcal I_f\in \boldsymbol{\textsf{ST}}~ \forall x\in \omega^{ \omega}(\rho_-(x)\geq_K \mathcal I_f\Rightarrow x\leq^* \rho_+(\mathcal I_f)). \end{align*} $$

Let $\mathcal I_f\in \boldsymbol{\textsf{ST}}$ and $x\in \omega ^{\omega }$ such that $x\not \leq ^* \rho _+(\mathcal I_f)$ . Let $\rho _-(x)=\mathcal I_{g_x}$ . We will show for each $M>0$ , there are $l>M$ , $k_1>k_0\ge M$ such that:

1. (3) $u_{g_x}([k_0,k_1])>M\cdot u_f([0,l])$ and

2. (4) $g_x(k_1)>M\cdot f(l)$ .

Then, $\rho _-(x)\not \geq _K \mathcal I_f$ follows from Theorem 4.1. To prove (3) and (4), fix $M>0$ and let $n_0>M$ be such that $x(n_0)>\rho _+(\mathcal I_f)(n_0)$ . Define $l=\rho _+(\mathcal I_f)(n_0-1)$ and $k_0<k_1$ such that $[k_0, k_1]=A^x_{n_0}$ . It follows that $l>M$ , $k_1>k_0\ge M$ and

$$ \begin{align*} u_{g_x}([k_0,k_1])\geq n_0\cdot (x(n_0)+1)>n_0 \cdot x(n_0)> M\cdot u_f([0,l]). \end{align*} $$

Thus (3) holds. By the definition of l, we have that $f(l)\leq \frac {1}{n_0^2}$ and

$$ \begin{align*} g_x(k_1)=\frac{1}{n_0}=n_0\cdot\frac{1}{n_0^2}>M\cdot f(l). \end{align*} $$

Thus (4) holds.

Proof Use Lemmas 6.1 and 6.2.