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Difference between revisions of "Sierpiński game"

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Let $Y$ be a [[topological space]] and $X$ an uncountable subset of $Y$. Two players alternatively select subsets of $X$. Player I selects some uncountable subset $A_1$ of $X$. Player II answers by picking up an uncountable subset $B_1 \subset A_1$. Then again player I selects some uncountable set $A_2 \subset B_1$ and player II responds by selecting some uncountable subset $B_2 \subset A_2$. Playing this way the two players generate a decreasing sequence $P = (A_i,B_i)_{i \ge 1}$ of uncountable sets, which is called a play. By definition, player II wins this play if the intersection $\cap \bar B_i$ of the closures of $B_i$ in $Y$ is contained in $X$. Otherwise the play is won by player I. A given  "rule"  of selecting the moves of player II is called a winning strategy for player II if every play generated by this rule is won by this player.
 
Let $Y$ be a [[topological space]] and $X$ an uncountable subset of $Y$. Two players alternatively select subsets of $X$. Player I selects some uncountable subset $A_1$ of $X$. Player II answers by picking up an uncountable subset $B_1 \subset A_1$. Then again player I selects some uncountable set $A_2 \subset B_1$ and player II responds by selecting some uncountable subset $B_2 \subset A_2$. Playing this way the two players generate a decreasing sequence $P = (A_i,B_i)_{i \ge 1}$ of uncountable sets, which is called a play. By definition, player II wins this play if the intersection $\cap \bar B_i$ of the closures of $B_i$ in $Y$ is contained in $X$. Otherwise the play is won by player I. A given  "rule"  of selecting the moves of player II is called a winning strategy for player II if every play generated by this rule is won by this player.
  
If $Y$ is a Polish space (a completely metrizable and separable space, cf. also [[Vague topology]]; [[Descriptive set theory]]; [[Complete metric space]]; [[Separable space]]), then the existence of a winning strategy for player II implies that $X$ contains the [[Cantor discontinuum]] (and therefore contains continuum many points). On the other hand, if $X$ is a Suslin subset of $Y$ (cf. also [[Descriptive set theory]]), then player II has a winning strategy ([[#References|[a3]]]). Thus, every uncountable Suslin subset of a Polish space contains the [[Cantor discontinuum]]. For Borel subsets of the unit segment this was proved by P.S. Aleksandrov ([[#References|[a1]]] and [[Borel set]]) and F. Hausdorff ([[#References|[a2]]]) when they were verifying the truth of the [[continuum hypothesis]] for such subsets of the unit segment. W. Sierpiński ([[#References|[a5]]]) gave another proof of the same result. It was this proof of Sierpiński that made R. Telgársky ([[#References|[a6]]]) introduce the above game and name it after Sierpiński. Further information concerning the game of Sierpiński can be found in [[#References|[a3]]], [[#References|[a4]]] and [[#References|[a7]]].
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If $Y$ is a [[Polish space]] (a completely metrizable and separable space, cf. also [[Vague topology]]; [[Descriptive set theory]]; [[Complete metric space]]; [[Separable space]]), then the existence of a winning strategy for player II implies that $X$ contains the [[Cantor discontinuum]] (and therefore contains continuum many points). On the other hand, if $X$ is a Suslin subset of $Y$ (cf. also [[Descriptive set theory]]), then player II has a winning strategy ([[#References|[a3]]]). Thus, every uncountable Suslin subset of a Polish space contains the [[Cantor discontinuum]]. For Borel subsets of the unit segment this was proved by P.S. Aleksandrov ([[#References|[a1]]] and [[Borel set]]) and F. Hausdorff ([[#References|[a2]]]) when they were verifying the truth of the [[continuum hypothesis]] for such subsets of the unit segment. W. Sierpiński ([[#References|[a5]]]) gave another proof of the same result. It was this proof of Sierpiński that made R. Telgársky ([[#References|[a6]]]) introduce the above game and name it after Sierpiński. Further information concerning the game of Sierpiński can be found in [[#References|[a3]]], [[#References|[a4]]] and [[#References|[a7]]].
  
 
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Latest revision as of 19:20, 1 January 2021

Let $Y$ be a topological space and $X$ an uncountable subset of $Y$. Two players alternatively select subsets of $X$. Player I selects some uncountable subset $A_1$ of $X$. Player II answers by picking up an uncountable subset $B_1 \subset A_1$. Then again player I selects some uncountable set $A_2 \subset B_1$ and player II responds by selecting some uncountable subset $B_2 \subset A_2$. Playing this way the two players generate a decreasing sequence $P = (A_i,B_i)_{i \ge 1}$ of uncountable sets, which is called a play. By definition, player II wins this play if the intersection $\cap \bar B_i$ of the closures of $B_i$ in $Y$ is contained in $X$. Otherwise the play is won by player I. A given "rule" of selecting the moves of player II is called a winning strategy for player II if every play generated by this rule is won by this player.

If $Y$ is a Polish space (a completely metrizable and separable space, cf. also Vague topology; Descriptive set theory; Complete metric space; Separable space), then the existence of a winning strategy for player II implies that $X$ contains the Cantor discontinuum (and therefore contains continuum many points). On the other hand, if $X$ is a Suslin subset of $Y$ (cf. also Descriptive set theory), then player II has a winning strategy ([a3]). Thus, every uncountable Suslin subset of a Polish space contains the Cantor discontinuum. For Borel subsets of the unit segment this was proved by P.S. Aleksandrov ([a1] and Borel set) and F. Hausdorff ([a2]) when they were verifying the truth of the continuum hypothesis for such subsets of the unit segment. W. Sierpiński ([a5]) gave another proof of the same result. It was this proof of Sierpiński that made R. Telgársky ([a6]) introduce the above game and name it after Sierpiński. Further information concerning the game of Sierpiński can be found in [a3], [a4] and [a7].

References

[a1] P.S. Alexandrov, "Sur la puissance des ensembles mesurables B" C.R. Acad. Sci. Paris , 162 (1916) pp. 323–325
[a2] F. Hausdorff, "Die Mächtigkeit der Borelschen Mengen" Math. Ann. , 77 (1916) pp. 430–437
[a3] G. Kubicki, "On a game of Sierpiński" Colloq. Math. , 54 (1987) pp. 179–192
[a4] G. Kubicki, "On a modified game of Sierpiński" Colloq. Math. , 53 (1987) pp. 81–91
[a5] W. Sierpiński, "Sur le puissance des ensembles mesurables (B)" Fundam. Math. , 5 (1924) pp. 166–171
[a6] R. Telgárski, "On some topological games" , Proc. Fourth Prague Topological Symp. 1976, Part B: Contributed papers , Soc. Czech. Math. and Physicists (1977) pp. 461–472
[a7] R. Telgárski, "Topological games: On the 50th anniversary of the Banach–Mazur game" Rocky Mount. J. Math. , 17 (1987) pp. 227–276
How to Cite This Entry:
Sierpiński game. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Sierpi%C5%84ski_game&oldid=40188
This article was adapted from an original article by P.S. Kenderov (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article