Proof. Let $\mathrm {F}(X)$ (respectively, $\mathrm {B}(X)$ ) be the family of countable closed (respectively, Borel) covers of the set X, and let $\mathrm {F}_{\Gamma} (X)$ (respectively, $\mathrm {B}_{\Gamma} (X)$ ) be the family of infinite closed (respectively, Borel) point-cofinite covers of the set X. The properties (1), $\mathsf {U}_{\mathrm {fin}}(\mathrm {B},\mathrm {B}_{\Gamma} )$ , and $\mathsf {S}_1(\mathrm {B}_{\Gamma} ,\mathrm {B}_{\Gamma} )$ are equivalent [Reference Scheepers and Tsaban16, Theorem 1]. For a family $\mathcal {U}$ of open sets, we have $\mathcal {U}\in \mathrm {PF}(X)$ if and only if

$$\begin{align*}\{\,U^{\mathtt{c}} : U\in\mathcal{U}\,\}\in\mathrm{F}_{\Gamma}(X). \end{align*}$$

It follows that $\mathsf {S}_1(\mathrm {PF},\mathrm {PF})=\mathsf {S}_1(\mathrm {F}_{\Gamma} ,\mathrm {F}_{\Gamma} )$ .

$(1)\Rightarrow (2)$ : Clearly, $\mathsf {S}_1(\mathrm {B}_{\Gamma} ,\mathrm {B}_{\Gamma} )$ implies $\mathsf {S}_1(\mathrm {F}_{\Gamma} ,\mathrm {F}_{\Gamma} )$ .

$(2)\Rightarrow (1)$ : A theorem of Bukovský–Recław–Repický [Reference Bukovský, Recław and Repický3, Corollary 5.3] asserts that

$$\begin{align*}\mathsf{U}_{\mathrm{fin}}(\mathrm{F},\mathrm{F}_{\Gamma})=\mathsf{U}_{\mathrm{fin}}(\mathrm{B},\mathrm{B}_{\Gamma}). \end{align*}$$

The usual argument [Reference Scheepers15, Proposition 11] shows that $\mathsf {S}_1(\mathrm {F}_{\Gamma} ,\mathrm {F}_{\Gamma} )$ implies $\mathsf {U}_{\mathrm {fin}}(\mathrm {F},\mathrm {F}_{\Gamma} )$ : If $\{\, C_n : n\in \mathbb {N}\}\in \mathrm {F}(X)$ and there is no finite subcover, then $\{\, \bigcup _{k=1}^n C_k : n\in \mathbb {N}\}\in \mathrm {F}_{\Gamma} (X)$ .

Proof. There is a sequence s such that the sets $\operatorname {im}(s_n)\setminus \operatorname {im}(s)$ are finite for all natural numbers n. By moving to a subsequence, we may assume that $\operatorname {im}(s)\subseteq \bigcup _{n=1}^\infty \operatorname {im}(s_n)$ . Suppose that $s=(a_1, a_2, \dotsc )$ . For each natural number n, since the sequence $s_n$ converges to the point p, every element other than p may appear in the sequence $s_n$ only finitely often. Thus, there is a tail $t_n$ of the sequence $s_n$ such that

$$\begin{align*}\operatorname{im}(t_n)\subseteq\{\,a_k : k\geq n\,\}\cup\{p\}. \end{align*}$$

Let U be a neighborhood of p. There is a natural number N such that

$$\begin{align*}\operatorname{im}(t_n)\subseteq\{\,a_k : k\geq n\,\}\cup\{p\}\subseteq U \end{align*}$$

for all natural numbers $n\ge N$ . Thus, the direct sum $t:=\bigsqcup _{n=1}^\infty t_n$ converges to the point p.

Proof. $(2)\Rightarrow (1)$ : This is the straightforward implication. For completeness, we reproduce its proof [Reference Tsaban and Zdomskyy20, Theorem 9].

Let $s_1, s_2, \dotsc $ be sequences in the space $\operatorname {C}_{\mathrm {p}}(X)$ that converge to a function $f\in \operatorname {C}_{\mathrm {p}}(X)$ . For each natural number n, suppose that

$$\begin{align*}s_n = (f^n_1,f^n_2,f^n_3,\dotsc). \end{align*}$$

Define a Borel function $\Psi \colon X\to {\mathbb {N}^{\mathbb {N}}}$ by

$$\begin{align*}\Psi(x)(n) := \min{\biggl\{\,k : (\forall m\ge k)\ |f^n_m(x)-f(x)|\le \frac{1}{n}\,\biggr\}}. \end{align*}$$

Let $g\in {\mathbb {N}^{\mathbb {N}}}$ be a $\le ^*$ -bound for the image $\Psi [X]$ . Then the sequence

$$\begin{align*}\bigsqcup_{n=1}^\infty(f^n_{g(n)},f^n_{g(n)+1},f^n_{g(n)+2},\dotsc) \end{align*}$$

converges to the function f.

$(1)\Rightarrow (2)$ : This is the main implication. By Lemma 2.2, it suffices to prove that the set X satisfies $\mathsf {S}_1(\mathrm {PF},\mathrm {PF})$ . Let $\mathcal {U}_1, \mathcal {U}_2, \dotsc \in \mathrm {PF}(X)$ . By thinning out the point-finite covers, we may assume that they are pairwise disjoint [Reference Scheepers15, Lemma 4]. For each set $U\in \bigcup _{n=1}^\infty \mathcal {U}_n$ , let $\mathcal {C}_U$ be a countable family of clopen sets with $\bigcup \mathcal {C}_U=U$ . For each natural number n, let

$$\begin{align*}\mathcal{V}_n := \bigcup_{U\in\mathcal{U}_n}\mathcal{C}_U. \end{align*}$$

Every set $C\in \mathcal {V}_n$ is contained in at most finitely many sets $U\in \mathcal {U}_n$ . Thus, the family $\mathcal {V}_n$ is infinite and point-finite. Let $s_n$ be a bijective enumeration of the family

$$\begin{align*}\{\,\chi_V : V\in\mathcal{V}_n\,\}. \end{align*}$$

The sequence $s_n$ is in $\operatorname {C}_{\mathrm {p}}(X)$ , and it converges to the constant function $0$ .

As the space $\operatorname {C}_{\mathrm {p}}(X)$ is $\alpha _1$ , there is for each n a tail $t_n$ of the sequence $s_n$ such that the sequence $s:=\bigsqcup _{n=1}^\infty t_n$ converges to $0$ . For each natural number n, pick a set $U_n\in \mathcal {U}_n$ with $\mathcal {C}_{U_n}\subseteq \operatorname {im}(t_n)$ . Then the family $\{\, U_n : n\in \mathbb {N}\}$ is infinite and point-finite.

Proof. For a finite sequence $s\in \{0,1\}^*$ , let $[s]$ be the basic clopen subset of the Cantor space ${\{0,1\}^{\mathbb {N}}}$ consisting of all functions extending s. Every open set in the space ${\{0,1\}^{\mathbb {N}}}$ is a disjoint union of basic clopen sets. A sequence $a_1, a_2, \dotsc $ in the set $\{0,1\}^*$ converges to $\infty $ in the space $\mathrm {T}(X)$ if, and only if, the set $\{\, [a_n] : n\in \mathbb {N}\}$ is point-finite in the space X [Reference Gerlits and Nagy6]. The argument in the proof of Theorem 2.4 applies.

Proof. $(1)\Rightarrow (2)$ : Obvious.

$(2)\Rightarrow (1)$ : Let $\mathcal {U}_1, \mathcal {U}_2, \dotsc $ be a sequence in $\mathrm {A}$ . Split the sequence into infinitely many disjoint sequences. For each natural number k, apply $\Pi (\mathrm {A},\mathrm {O}_k)$ to the kth sequence, to obtain a k-cover $\mathcal {V}_k$ . Then $\bigcup _{k=1}^\infty \mathcal {V}_k$ is an $\omega $ -cover, in accordance with the required property $\Pi (\mathrm {A},\Omega )$ .

Proof. Let X be a Hurewicz space. By Lemma 3.1, it suffices to prove that $\mathsf {S}_{\mathrm {fin}}({\Gamma} ,\mathrm {O}_k)$ holds for all natural numbers k. Fix a natural number k.

Let $\mathcal {U}_1, \mathcal {U}_2, \dotsc $ be a sequence in ${\Gamma} (X)$ . By moving to countably infinite subcovers, we may enumerate

$$\begin{align*}\mathcal{U}_n = \{\,U^n_m : m\in\mathbb{N}\,\} \end{align*}$$

for each n. For each n and m, we may replace the set $U^n_m$ with the smaller set

$$\begin{align*}U^1_m\cap U^2_m\cap\dotsb\cap U^n_m, \end{align*}$$

so that we may assume that

$$\begin{align*}U^1_m\supseteq U^2_m\supseteq U^3_m\supseteq\dotsb \end{align*}$$

for all natural numbers m. The refined covers $\mathcal {U}_n$ remain in ${\Gamma} (X)$ .

Let $g_0(m):=m$ for all m. We define, by induction, increasing functions $g_1,\dots ,g_k\in {\mathbb {N}^{\mathbb {N}}}$ . Let $l<k$ and assume that the function $g_l$ is defined. For natural numbers n, m, and i, let

$$ \begin{align*} V^{l,n}_i &:= \bigcap_{m=i}^{g_l(i)}U^n_m,\\ W^{l,n}_m &:= \bigcup\{\,V^{l,n}_i : n\le i, g_l(i)\le m\,\}. \end{align*} $$

For each l and n, the sets $W^{l,n}_m$ are increasing with m, and cover the space X. By the Hurewicz property, there is an increasing function $g_{l+1}\in {\mathbb {N}^{\mathbb {N}}}$ such that

$$\begin{align*}\{\, W^{l,n}_{g_{l+1}(n)} : n\in\mathbb{N}\}\in{\Gamma}(X). \end{align*}$$

This completes the inductive construction.

We will show that

$$\begin{align*}\{\,U^n_m : n\in\mathbb{N}, m\le g_k(n)\,\}\in\mathrm{O}_k(X). \end{align*}$$

Let $x_1,\dotsc ,x_k\in X$ . Since $\{\, W^{l,n}_{g_{l+1}(n)} : n\in \mathbb {N}\}\in {\Gamma} (X)$ for all $l=0,\dotsc ,k-1$ , there is a natural number N with

$$\begin{align*}x_1,\dots,x_k\in W^{l,n}_{g_{l+1}(n)} \end{align*}$$

for all $l=0,\dotsc ,k-1$ and all $n\ge N$ . Fix a number $n_0\ge N$ .

Since $x_1\in W^{k-1,n_0}_{g_{k}(n_0)}$ , there is $n_1$ with $n_0\le n_1,g_{k-1}(n_1)\le g_{k}(n_0)$ and

$$\begin{align*}x_1\in V^{k-1,n_0}_{n_1}=\bigcap_{m=n_1}^{g_{k-1}(n_1)}U^{n_0}_m. \end{align*}$$

Since $x_3\in W^{k-3,n_2}_{g_{k-2}(n_2)}$ , there is $n_3$ with $n_2\le n_3,g_{k-3}(n_3)\le g_{k-2}(n_2)$ and

$$\begin{align*}x_3\in V^{k-3,n_2}_{n_3}=\bigcap_{m=n_3}^{g_{k-3}(n_3)}U^{n_2}_m\subseteq \bigcap_{m=n_3}^{g_{k-3}(n_3)}U^{n_0}_m. \end{align*}$$

Since $x_k\in W^{0,n_{k-1}}_{g_{1}(n_{k-1})}$ , there is $n_k$ with $n_{k-1}\le n_k=g_{0}(n_k)\le g_{1}(n_{k-1})$ and

$$\begin{align*}x_k\in V^{0,n_{k-1}}_{n_k}=U^{n_{k-1}}_{n_k}\subseteq U^{n_0}_{n_k}. \end{align*}$$

It follows that $x_1,\dots ,x_k\in U^{n_0}_{n_k}$ , and $n_k\le g_k(n_0)$ .

Proof. The proof is similar to that of Lemma 3.1, once we observe that if $\{\, U_n : n\in \mathbb {N}\}$ is a k-groupable cover for all k, then it is $\omega $ -groupable. This follows easily from the fact that for each countable family $\{\,\mathcal {P}_k : k\in \mathbb {N}\,\}$ of partitions of $\mathbb {N}$ into finite sets, there is a partition $\mathcal {P}$ of $\mathbb {N}$ into finite sets that is eventually coarser than all of the given partitions, that is, such that for each k, all but finitely many members of the partition $\mathcal {P}$ contain a member of the partition $\mathcal {P}_k$ .

Proof. $(1)\Rightarrow (2)$ : The proof of Peng’s Theorem 3.2, as written above, shows, for a prescribed number k, that for each k-element set F, there is a natural number N such that for each $n\ge N$ , there is a member of the finite set $\mathcal {F}_{n}=\{\,U^{n}_m : m\le g_k(n)\,\}$ that contains the set F. By thinning out the point-cofinite covers, we may assume that they are pairwise disjoint [Reference Scheepers15, Lemma 4], and consequently so are the finite sets $\mathcal {F}_{n}$ . Thus, $\bigcup _{n=1}^\infty \mathcal {F}_n\in \mathrm {O}_k^{\mathrm {\tiny gp}}$ . This proves $\mathsf {S}_{\mathrm {fin}}({\Gamma} ,\mathrm {O}_k^{\mathrm {\tiny gp}})$ for all k. Apply Lemma 3.3.

$(2)\Rightarrow (1)$ : $\Omega ^{\mathrm {\tiny gp}}\subseteq \Lambda ^{\mathrm {\tiny gp}}$ . It is known that $\mathsf {S}_{\mathrm {fin}}({\Gamma} ,\Lambda ^{\mathrm {\tiny gp}})=\mathsf {U}_{\mathrm {fin}}(\mathrm {O},{\Gamma} )$ [Reference Samet, Scheepers and Tsaban13, Theorem 6]. For completeness, we provide a proof that $\mathsf {S}_{\mathrm {fin}}({\Gamma} ,\Lambda ^{\mathrm {\tiny gp}})$ implies $\mathsf {U}_{\mathrm {fin}}(\mathrm {O},{\Gamma} )$ .

Assume that the space X satisfies $\mathsf {S}_{\mathrm {fin}}({\Gamma} ,\Lambda ^{\mathrm {\tiny gp}})$ . It suffices to prove that it satisfies $\mathsf {U}_{\mathrm {fin}}({\Gamma} ,{\Gamma} )$ . Given a sequence $\mathcal {U}_1, \mathcal {U}_2, \dotsc $ in ${\Gamma} (X)$ , we may (as in the proof of Theorem 3.2) assume that the covers get finer with n. Apply $\mathsf {S}_{\mathrm {fin}}({\Gamma} ,\Lambda ^{\mathrm {\tiny gp}})$ to obtain a cover $\mathcal {U}\in \Lambda ^{\mathrm {\tiny gp}}$ , with parts $\mathcal {P}_n$ (for $n\in \mathbb {N}$ ) witnessing that.

Let $\mathcal {F}_1\subseteq \mathcal {U}_1$ be a finite set refined by $\mathcal {P}_1$ , that is, such that for each set $U\in \mathcal {P}_1$ , there is a set $V\in \mathcal {F}_1$ with $U\subseteq V$ . The set $\mathcal {F}_1$ exists since the covers $\mathcal {U}_n$ get finer as n increases. Let $n_2$ be minimal with $\mathcal {P}_{n_2}\subseteq \bigcup _{n=2}^\infty \mathcal {U}_n$ , and let $\mathcal {F}_2\subseteq \mathcal {U}_2$ be a finite set refined by $\mathcal {P}_{n_2}$ . Let $n_3$ be minimal with $\mathcal {P}_{n_3}\subseteq \bigcup _{n=3}^\infty \mathcal {U}_n$ , and let $\mathcal {F}_3\subseteq \mathcal {U}_3$ be a finite set refined by $\mathcal {P}_{n_3}$ . Continuing in this manner, we obtain finite sets $\mathcal {F}_n\subseteq \mathcal {U}_n$ for $n\in \mathbb {N}$ , with $\{\, \bigcup \mathcal {F}_n : n\in \mathbb {N}\}\in {\Gamma} (X)$ .

Proof. If $X=\bigcup _{\alpha <\kappa } K_\alpha $ , then $X=\bigcup _{\alpha <\kappa } \overline {K_\alpha }$ .

Proof. Every open cover is refined by a cover $\mathcal {U}\in \mathrm {O}_{\mathcal {B}}(X)$ which, in turn, has the finite subcover $\sigma (\mathcal {U})$ .

Proof. We follow the steps of Scheepers’s proof [Reference Scheepers14, Theorem 1], removing what is not necessary.

The space X is regular and second countable. Let $\sigma $ be a winning strategy for Bob. Fix a countable base $\mathcal {B}$ for the topology of the space X. Let $\mathbb {N}^*$ be the set of finite sequences of natural numbers. We consider all possible games where Alice chooses her covers from the family $\mathrm {O}_{\mathcal {B}}(X)$ .

Since the base $\mathcal {B}$ is countable, the family $\{\,\sigma (\mathcal {U}) : \mathcal {U}\in \mathrm {O}_{\mathcal {B}}\,\}$ (the possible first responds of Bob) is countable, too. Choose elements $\mathcal {U}_1, \mathcal {U}_2, \dotsc \in \mathrm {O}_{\mathcal {B}}$ with

$$\begin{align*}\{\, \sigma(\mathcal{U}_n) : n\in\mathbb{N}\}=\{\,\sigma(\mathcal{U}) : \mathcal{U}\in\mathrm{O}_{\mathcal{B}}\,\}. \end{align*}$$

By induction, for a given natural number n and each sequence $s=(s_1,\dotsc ,s_n)\in \mathbb {N}^n$ , the family

$$\begin{align*}\{\,\sigma(\mathcal{U}_{s_1},\mathcal{U}_{s_1,s_2},\dotsc,\mathcal{U}_{s_1,\dotsc,s_n},\mathcal{U}) : \mathcal{U}\in\mathrm{O}_{\mathcal{B}}\,\} \end{align*}$$

is countable. Choose elements $\mathcal {U}_{{s_1,\dotsc ,s_n},1},\mathcal {U}_{{s_1,\dotsc ,s_n},2},\dotsc \in \mathrm {O}_{\mathcal {B}}$ with

$$\begin{align*}\{\,\sigma(\mathcal{U}_{s_1},\dotsc,\mathcal{U}_{s_1,\dotsc,s_n},\mathcal{U}_{{s_1,\dotsc,s_n},m}) : m\in\mathbb{N}\,\} = \{\,\sigma(\mathcal{U}_{s_1},\dotsc,\mathcal{U}_{s_1,\dotsc,s_n},\mathcal{U}) : \mathcal{U}\in\mathrm{O}_{\mathcal{B}}\,\}. \end{align*}$$

This completes our inductive construction.

By Lemma 4.2, for each sequence $s=({s_1,\dotsc ,s_n})\in \mathbb {N}^*$ , the set

$$\begin{align*}K_s := \bigcap_{m=1}^\infty \bigcup\sigma(\mathcal{U}_{s_1},\dotsc,\mathcal{U}_{{s_1,\dotsc,s_n}},\mathcal{U}_{{s_1,\dotsc,s_n},m}) \end{align*}$$

is relatively compact. By Lemma 4.1, it remains to see that $X=\bigcup _{s\in \mathbb {N}^*}K_s$ .

Assume that some element $x\in X$ is not in $\bigcup _{s\in \mathbb {N}^*}K_s$ .

1. (1) Since $x\notin K_{()}$ , there is $m_1$ with $x\notin \bigcup \sigma (\mathcal {U}_{m_1})$ .

2. (2) Since $x\notin K_{m_1}$ , there is $m_2$ with $x\notin \bigcup \sigma (\mathcal {U}_{m_1},\mathcal {U}_{m_1,m_2})$ .

3. (3) Since $x\notin K_{m_1,m_2}$ , there is $m_3$ with $x\notin \bigcup \sigma (\mathcal {U}_{m_1},\mathcal {U}_{m_1,m_2},\mathcal {U}_{m_1,m_2,m_3})$ .

4. (4) Etc.

Then the play

$$\begin{align*}\mathcal{U}_{m_1},\sigma(\mathcal{U}_{m_1}), \mathcal{U}_{m_1,m_2}, \sigma(\mathcal{U}_{m_1},\mathcal{U}_{m_1,m_2}), \mathcal{U}_{m_1,m_2,m_3}, \sigma(\mathcal{U}_{m_1},\mathcal{U}_{m_1,m_2},\mathcal{U}_{m_1,m_2,m_3}), \dotsc \end{align*}$$

is lost by Bob; a contradiction.

Proof. The proof is identical to that of Theorem 4.3, only that here we begin with a base of cardinality $\kappa $ . Here, the sequences s range over the set of sequences in $\kappa $ of length smaller than $\lambda $ .

Proof. As usual, we split the sequence of open covers to infinitely many disjoint sequences, and apply the property $\mathsf {S}_1(\mathrm {A},\mathrm {O})$ to each subsequence separately.

Proof. Let $\kappa <\operatorname {add}(\mathcal {N})$ and $X = \bigcup _{\alpha < \kappa }X_\alpha $ , where each space $X_\alpha $ satisfies $\mathsf {S}_1(\mathrm {A},\mathrm {O})$ . By Lemma 5.2, it suffices to show that the space X satisfies $\mathsf {S}_{n}(\mathrm {A},\mathrm {O})$ .

Let $\mathcal {U}_n=\{U^n_m : m\in \mathbb {N}\}\in \mathrm {A}(X)$ , for $n\in \mathbb {N}$ . For each ordinal number $\alpha <\kappa $ , as the space $X_\alpha $ satisfies $\mathsf {S}_1(\mathrm {A},\mathrm {O})$ , there is a function $f_\alpha \in {\mathbb {N}^{\mathbb {N}}}$ such that for each point $x\in X_\alpha $ , we have

$$\begin{align*}x\in U^n_{f_\alpha(n)} \end{align*}$$

for infinitely many n.

There is a function $S\colon \mathbb {N}\to [\mathbb {N}]^{<\!\!\infty }$ with $\left |S(n)\right | \leq n$ for all n, such that for each $\alpha <\kappa $ , we have

$$\begin{align*}\ f_\alpha(n) \in S(n) \end{align*}$$

for all but finitely many n. Then $\bigcup _{n=1}^\infty \{\,U^n_{m} : m\in S(n)\,\}\in \mathrm {O}(X)$ .

Proof. (1) Since the spaces are Lindelöf, we may restrict attention to countable covers, and the assumptions of Theorem 5.4 hold.

(2) A countably infinite subset of a point-cofinite cover is also a point-cofinite cover. Thus, we may restrict attention to countable point-cofinite covers. It is well known that every pair of point-cofinite covers has a joint refinement that is a point-cofinite cover. Indeed, let $\mathcal {U}$ and $\mathcal {V}$ be countable point-cofinite covers. Enumerate them $\mathcal {U}=\{\, U_n : n\in \mathbb {N}\}$ and $\mathcal {V}=\{\, V_n : n\in \mathbb {N}\}$ . Then $\{\, U_n\cap V_n : n\in \mathbb {N}\}\in \Gamma (X)$ . Theorem 5.4 applies.

Proof. Let $\kappa <\operatorname {add}(\mathcal {N})$ and $X = \bigcup _{\alpha < \kappa }X_\alpha $ , where each space $X_\alpha $ satisfies $\mathsf {U}_n(\Gamma ,\Gamma )$ . It suffices to show that the space X satisfies $\mathsf {U}_{n^2}(\Gamma ,\Gamma )$ , where the cardinality of the nth selected finite set is at most $n^2$ [Reference Tsaban19, Lemma 3.2].

Let $\mathcal {U}_n=\{U^n_m : m\in \mathbb {N}\}\in \Gamma (X)$ , for $n\in \mathbb {N}$ . For each $\alpha <\kappa $ , as the space $X_\alpha $ satisfies $\mathsf {U}_n(\Gamma ,\Gamma )$ , there is a function $S_\alpha \colon \mathbb {N}\to \prod _n[\mathbb {N}]^{\le n}$ such that for each point $x\in X_\alpha $ , we have

$$\begin{align*}x\in \bigcup_{m\in S_\alpha(n)}U^n_m \end{align*}$$

for infinitely many n.

There is a function $S\colon \mathbb {N}\to \prod _n[\mathbb {N}]^{\le n}$ with $\left |S(n)\right | \leq n$ for all n, such that for each $\alpha <\kappa $ , we have

$$\begin{align*}\ S_\alpha(n) \in S(n) \end{align*}$$

for all but finitely many n. For each natural number n, let $F_n:=\bigcup S(n)$ . Then $\left |F_n\right |\le n^2$ for all n, and $\{\, \bigcup _{m\in F_n}U^n_m : n\in \mathbb {N}\}\in \Gamma (X)$ .