Selection principle explained

In mathematics, a selection principle is a rule assertingthe possibility of obtaining mathematically significant objects by selecting elements from given sequences of sets. The theory of selection principlesstudies these principles and their relations to other mathematical properties.Selection principles mainly describe covering properties, measure- and category-theoretic properties, and local properties in topological spaces, especially function spaces. Often, the characterization of a mathematical property using a selection principle is a nontrivial task leading to new insights on the characterized property.

The main selection principles

In 1924, Karl Menger^[1] introduced the following basis property for metric spaces: Every basis of the topology contains a sequence of sets with vanishing diameters that covers the space. Soon thereafter, Witold Hurewicz^[2] observed that Menger's basis property is equivalent to the following selective property: for every sequence of open covers of the space, one can select finitely many open sets from each cover in the sequence, such that the family of all selected sets covers the space.Topological spaces having this covering property are called Menger spaces.

Hurewicz's reformulation of Menger's property was the first important topological property described by a selection principle. Let

and

be classes of mathematical objects.In 1996, Marion Scheepers^[3] introduced the following selection hypotheses,capturing a large number of classic mathematical properties:

S_1(A,B)

: For every sequence

l{U}_1,l{U}_2,\ldots

of elements from the class

, there are elements

U_1\inl{U}_1,U_2\inl{U}_2,...

such that

\{U_{n:n\inN\}\inB}

S_fin(A,B)

: For every sequence

l{U}_1,l{U}_2,\ldots

of elements from the class

, there are finite subsets

l{F}_{1\subseteql{U}}_1,l{F}_{2\subseteql{U}}_2,...

such that

	infty
cup
	n=1

l{F}_n\inB

In the case where the classes

and

consist of covers of some ambient space, Scheepers also introduced the following selection principle.

U_fin(A,B)

: For every sequence

l{U}_1,l{U}_2,\ldots

of elements from the class

, none containing a finite subcover, there are finite subsets

l{F}_{1\subseteql{U}}_1,l{F}_{2\subseteql{U}}_2,...

such that

\{cupl{F}_1,cupl{F}_2,...c\}\inB

Later, Boaz Tsaban identified the prevalence of the following related principle:

\binom{A

}: Every member of the class

includes a member of the class

The notions thus defined are selection principles. An instantiation of a selection principle, by considering specific classes

and

, gives a selection (or: selective) property. However, these terminologies are used interchangeably in the literature.

Variations

For a set

A\subsetX

and a family

l{F}

of subsets of

, the star of
A

in
l{F}

is the set

St(A,l{F})=cup\{F\inl{F}:A\capF ≠ \emptyset\}

In 1999, Ljubisa D.R. Kocinac introduced the following star selection principles:^[4]

	*(A,B)
S
	1

: For every sequence

l{U}_1,l{U}_2,\ldots

of elements from the class

, there are elements

U_1\inl{U}_1,U_2\inl{U}_2,...

such that

\{St(U_n,l{U}_{n):n\inN\}\inB}

	*(A,B)
S
	fin

: For every sequence

l{U}_1,l{U}_2,\ldots

of elements from the class

, there are finite subsets

l{F}_{1\subseteql{U}}_1,l{F}_{2\subseteql{U}}_2,...

such that

\{St(cupl{F}_n,l{U}_{n):n\inN\}\inB}

The star selection principles are special cases of the general selection principles. This can be seen by modifying the definition of the family

accordingly.

Covering properties

Covering properties form the kernel of the theory of selection principles. Selection properties that are not covering properties are often studied by using implications to and from selective covering properties of related spaces.

Let

be a topological space. An open cover of

is a family of open sets whose union is the entire space

For technical reasons, we also request that the entire space

is not a member of the cover. The class of open covers of the space

is denoted by

. (Formally,

O(X)

, but usually the space

is fixed in the background.) The above-mentioned property of Menger is, thus,

S_fin(O,O)

. In 1942, Fritz Rothberger considered Borel's strong measure zero sets, and introduced a topological variation later called Rothberger space (also known as C
''

space). In the notation of selections, Rothberger's property is the property

S₁(O,O)

An open cover

l{U}

is point-cofinite if it has infinitely many elements, and every point

x\inX

belongs to all but finitely many sets

U\inl{U}

. (This type of cover was considered by Gerlits and Nagy, in the third item of a certain list in their paper. The list was enumerated by Greek letters, and thus these covers are often called \gamma

-covers.) The class of point-cofinite open covers of

is denoted by

\Gamma

. A topological space is a Hurewicz space if it satisfies

U_fin(O,\Gamma)

An open cover

l{U}

is an \omega

-cover if every finite subset of

is contained in some member of

l{U}

. The class of

\omega

-covers of

is denoted by

\Omega

. A topological space is a γ-space if it satisfies

\binom{\Omega

By using star selection hypotheses one obtains properties such as star-Menger (

	*(O,O)
S
	fin

), star-Rothberger (

	*(O,O)
S
	1

) and star-Hurewicz (

	*(O,\Gamma)
S
	fin

The Scheepers Diagram

There are 36 selection properties of the form

\Pi(A,B)

, for

\Pi\in\{S_1,S_fin,U_fin,l(~~r)\}

and

A,B\in\{O,\Gamma,\Omega\}

. Some of them are trivial (hold for all spaces, or fail for all spaces). Restricting attention to Lindelöf spaces, the diagram below, known as the Scheepers Diagram,^[5] presents nontrivial selection properties of the above form, and every nontrivial selection property is equivalent to one in the diagram. Arrows denote implications.

Local properties

Selection principles also capture important local properties.

Let

be a topological space, and

y\inY

. The class of sets

in the space

that have the point

in their closure is denoted by

\Omega_y

. The class

	ctbl
\Omega
	y

consists of the countable elements of the class

\Omega_y

. The class of sequences in

that converge to

is denoted by

\Gamma_y

A space

is Fréchet–Urysohn if and only if it satisfies

\binom{\Omega_y

} for all points

y\inY

A space

is strongly Fréchet–Urysohn if and only if it satisfies

1(\Omega_y,\Gamma_y)

for all points

y\inY

A space

has countable tightness if and only if it satisfies

\binom{\Omega_y

} for all points

y\inY

A space

has countable fan tightness if and only if it satisfies

S_fin

(\Omega_y,\Omega_y)

for all points

y\inY

A space

has countable strong fan tightness if and only if it satisfies

S₁

(\Omega_y,\Omega_y)

for all points

y\inY

Topological games

There are close connections between selection principles and topological games.

The Menger game

Let

be a topological space. The Menger game

G_fin(O,O)

played on

is a game for two players, Alice and Bob. It has an inning per each natural number

. At the

n^th

inning, Alice chooses an open cover

l{U}_n

,and Bob chooses a finite subset

l{F}_n

l{U}

. If the family

	infty
cup
	n=1

l{F}_n

is a cover of the space

, then Bob wins the game. Otherwise, Alice wins.

A strategy for a player is a function determining the move of the player, given the earlier moves of both players. A strategy for a player is a winning strategy if each play where this player sticks to this strategy is won by this player.

A topological space is

S_fin(O,O)

if and only if Alice has no winning strategy in the game

G_fin(O,O)

played on this space.

be a metric space. Bob has a winning strategy in the game

G_fin(O,O)

played on the space

if and only if the space

\sigma

-compact.^[6] ^[7]

Note that among Lindelöf spaces, metrizable is equivalent to regular and second-countable, and so the previous result may alternatively be obtained by considering limited information strategies.^[8] A Markov strategy is one that only uses the most recent move of the opponent and the current round number.

be a regular space. Bob has a winning Markov strategy in the game

G_fin(O,O)

played on the space

if and only if the space

\sigma

-compact.

be a second-countable space. Bob has a winning Markov strategy in the game

G_fin(O,O)

played on the space

if and only if he has a winning perfect-information strategy.

In a similar way, we define games for other selection principles from the given Scheepers Diagram. In all these cases a topological space has a property from the Scheepers Diagram if and only if Alice has no winning strategy in the corresponding game.^[9] But this does not hold in general: Let

be the family of k-covers of a space. That is, such that every compact set in the space is covered by some member of the cover.Francis Jordan demonstrated a space where the selection principle

S_1(K,O)

holds, but Alice has a winning strategy for the game

G_1(K,O)

^[10]

Examples and properties

Every

S_fin(O,O)

space is a Lindelöf space.

Every σ-compact space (a countable union of compact spaces) is

U_fin(O,\Gamma)

\binom{\Omega

}\Rightarrow\text_(\mathbf,\mathbf)\Rightarrow\text_(\mathbf,\mathbf).

\binom{\Omega

}\Rightarrow\text_(\mathbf,\mathbf)\Rightarrow\text_(\mathbf,\mathbf).

Assuming the Continuum Hypothesis, there are sets of real numbers witnessing that the above implications cannot be reversed.
Every Luzin set is

S_fin(O,O)

but no

U_fin(O,\Gamma)

.^[11] ^[12]

Every Sierpiński set is Hurewicz.^[13]

Subsets of the real line

(with the induced subspace topology) holding selection principle properties, most notably Menger and Hurewicz spaces, can be characterized by their continuous images in the Baire space

N^N

. For functions

f,g\inN^N

, write

f\leq^*g

f(n)\leqg(n)

for all but finitely many natural numbers

. Let

be a subset of

N^N

. The set

is bounded if there is a function

g\inN^N

such that

f\leq^*g

for all functions

f\inA

. The set

is dominating if for each function

f\inN^N

there is a function

g\inA

such that

f\leq^*g

A subset of the real line is

S_fin(O,O)

if and only if every continuous image of that space into the Baire space is not dominating.^[14]

A subset of the real line is

U_fin(O,\Gamma)

if and only if every continuous image of that space into the Baire space is bounded.

Connections with other fields

General topology

Every

S_fin(O,O)

space is a D-space.^[15] Let P be a property of spaces. A space

is productively P if, for each space

with property P, the product space

X x Y

has property P.

Every separable productively paracompact space is

U_fin(O,\Gamma)

Assuming the Continuum Hypothesis, every productively Lindelöf space is productively

U_fin(O,\Gamma)

^[16]

be a

\binom{\Omega

} subset of the real line, and

be a meager subset of the real line. Then the set

A+M=\{a+x:a\inA,x\inM\}

is meager.^[17]

Measure theory

Every

S₁(O,O)

subset of the real line is a strong measure zero set.

Function spaces

Let

be a Tychonoff space, and

C(X)

be the space of continuous functions

f\colonX\toR

with pointwise convergence topology.

satisfies

\binom{\Omega

} if and only if

C(X)

is Fréchet–Urysohn if and only if

C(X)

is strong Fréchet–Urysohn.^[18]

satisfies

S₁(\Omega,\Omega)

if and only if

C(X)

has countable strong fan tightness.^[19]

satisfies

S_fin(\Omega,\Omega)

if and only if

C(X)

has countable fan tightness.^[20]

Notes and References

Menger. Karl. Einige Überdeckungssätze der Punktmengenlehre. Sitzungsberichte der Wiener Akademie. 1924. 133. 421–444. 50.0129.01. Reprinted in Selecta Mathematica I (2002),,, pp. 155-178.
Hurewicz. Witold. Über eine verallgemeinerung des Borelschen Theorems. Mathematische Zeitschrift. 1926. 24. 1. 401–421. 10.1007/bf01216792. 119867793.
Scheepers. Marion. Combinatorics of open covers I: Ramsey theory. Topology and Its Applications. 1996. 69. 31–62. 10.1016/0166-8641(95)00067-4. free.
Kocinac. Ljubisa D. R.. Star selection principles: a survey. Khayyam Journal of Mathematics. 2015. 1. 82–106.
Miller. Arnold. Scheepers. Marion. Szeptycki. Paul. 1996. Combinatorics of open covers II. Topology and Its Applications. 73. 3. 241–266. 10.1016/S0166-8641(96)00075-2. Just. Winfried. math/9509211. 14946860.
Scheepers. Marion. 1995-01-01. A direct proof of a theorem of Telgársky. Proceedings of the American Mathematical Society. 123. 11. 3483–3485. 10.1090/S0002-9939-1995-1273523-1. 0002-9939. free.
Telgársky. Rastislav. 1984-06-01. On games of Topsoe.. Mathematica Scandinavica. 54. 170–176. 10.7146/math.scand.a-12050. 1903-1807. free.
Steven . Clontz . Applications of limited information strategies in Menger's game . Commentationes Mathematicae Universitatis Carolinae . Charles University in Prague, Karolinum Press . 58 . 2 . 2017-07-31 . 0010-2628 . 10.14712/1213-7243.2015.201 . 225–239 . free .
Pawlikowski. Janusz. Undetermined sets of point-open games. Fundamenta Mathematicae. 144. 3. 279–285. 0016-2736. 1994.
Jordan . Francis . On the instability of a topological game related to consonance . Topology and Its Applications . Elsevier BV . 271 . 2020 . 0166-8641 . 10.1016/j.topol.2019.106990 . 106990 . 213386675 . free .
Rothberger. Fritz. 1938. Eine Verschärfung der Eigenschaft C. Fundamenta Mathematicae. 30. 50–55. 10.4064/fm-30-1-50-55. free.
Hurewicz. Witold. 1927. Über Folgen stetiger Funktionen. Fundamenta Mathematicae. 9. 193–210. 10.4064/fm-9-1-193-210. free.
Fremlin. David. Miller. Arnold. On some properties of Hurewicz, Menger and Rothberger. Fundamenta Mathematicae. 1988. 129. 17–33. 10.4064/fm-129-1-17-33. free.
Recław. Ireneusz. 1994. Every Lusin set is undetermined in the point-open game. Fundamenta Mathematicae. 144. 43–54. 10.4064/fm-144-1-43-54. free.
Aurichi. Leandro. D-Spaces, Topological Games, and Selection Principles. Topology Proceedings. 2010. 36. 107–122.
Szewczak. Piotr. Tsaban. Boaz. Product of Menger spaces, II: general spaces. 1607.01687. math.GN. 2016.
Galvin. Fred. Miller. Arnold.
\gamma

-sets and other singular sets of real numbers. Topology and Its Applications. 1984. 17. 2. 145–155. 10.1016/0166-8641(84)90038-5. free.
Gerlits. J.. Nagy. Zs.. Some properties of
C(X)

, I. Topology and Its Applications. 1982. 14. 2. 151–161. 10.1016/0166-8641(82)90065-7. free.
Sakai. Masami. Property
C''

and function spaces. Proceedings of the American Mathematical Society. 1988. 104. 9. 917–919. 10.1090/S0002-9939-97-03897-5. free.
1986. Hurewicz spaces, analytic sets and fan-tightness of spaces of functions. Soviet Math. Dokl.. 2. 396–399. Arhangel'skii. Alexander.

Selection principle explained

The main selection principles

Variations

Covering properties

The Scheepers Diagram

Local properties

Topological games

The Menger game

Examples and properties

Connections with other fields

General topology

Measure theory

Function spaces

See also

Notes and References