mathematics Mathematics is a field of study that discovers and organizes methods, Mathematical theory, theories and theorems that are developed and Mathematical proof, proved for the needs of empirical sciences and mathematics itself. There are many ar ...

, the axiom of determinacy (abbreviated as AD) is a possible

axiom An axiom, postulate, or assumption is a statement that is taken to be true, to serve as a premise or starting point for further reasoning and arguments. The word comes from the Ancient Greek word (), meaning 'that which is thought worthy or ...

for

set theory Set theory is the branch of mathematical logic that studies Set (mathematics), sets, which can be informally described as collections of objects. Although objects of any kind can be collected into a set, set theory – as a branch of mathema ...

introduced by Jan Mycielski and Hugo Steinhaus in 1962. It refers to certain two-person topological games of length ω. AD states that every game of a certain type is determined; that is, one of the two players has a winning strategy. Steinhaus and Mycielski's motivation for AD was its interesting consequences, and suggested that AD could be true in the smallest natural model L(R) of a set theory, which accepts only a weak form of the

axiom of choice In mathematics, the axiom of choice, abbreviated AC or AoC, is an axiom of set theory. Informally put, the axiom of choice says that given any collection of non-empty sets, it is possible to construct a new set by choosing one element from e ...

(AC) but contains all real and all

ordinal number In set theory, an ordinal number, or ordinal, is a generalization of ordinal numerals (first, second, th, etc.) aimed to extend enumeration to infinite sets. A finite set can be enumerated by successively labeling each element with the leas ...

s. Some consequences of AD followed from theorems proved earlier by Stefan Banach and Stanisław Mazur, and Morton Davis. Mycielski and Stanisław Świerczkowski contributed another one: AD implies that all sets of

real number In mathematics, a real number is a number that can be used to measure a continuous one- dimensional quantity such as a duration or temperature. Here, ''continuous'' means that pairs of values can have arbitrarily small differences. Every re ...

s are Lebesgue measurable. Later Donald A. Martin and others proved more important consequences, especially in

descriptive set theory In mathematical logic, descriptive set theory (DST) is the study of certain classes of "well-behaved" set (mathematics), subsets of the real line and other Polish spaces. As well as being one of the primary areas of research in set theory, it has a ...

. In 1988, John R. Steel and W. Hugh Woodin concluded a long line of research. Assuming the existence of some uncountable cardinal numbers analogous to ℵ₀, they proved the original conjecture of Mycielski and Steinhaus that AD is true in L(R).

Types of games that are determined

The axiom of determinacy refers to games of the following specific form: Consider a subset ''A'' of the Baire space ω^ω of all infinite sequences of

natural number In mathematics, the natural numbers are the numbers 0, 1, 2, 3, and so on, possibly excluding 0. Some start counting with 0, defining the natural numbers as the non-negative integers , while others start with 1, defining them as the positive in ...

s. Two players alternately pick natural numbers :''n''₀, ''n''₁, ''n''₂, ''n''₃, ... That generates the sequence ⟨''n''_''i''⟩_''i''∈ω after infinitely many moves. The player who picks first wins the game if and only if the sequence generated is an element of ''A''. The axiom of determinacy is the statement that all such games are determined. Not all games require the axiom of determinacy to prove them determined. If the set ''A'' is clopen, the game is essentially a finite game, and is therefore determined. Similarly, if ''A'' is a

closed set In geometry, topology, and related branches of mathematics, a closed set is a Set (mathematics), set whose complement (set theory), complement is an open set. In a topological space, a closed set can be defined as a set which contains all its lim ...

, then the game is determined. By the Borel determinacy theorem, games whose winning set is a

Borel set In mathematics, a Borel set is any subset of a topological space that can be formed from its open sets (or, equivalently, from closed sets) through the operations of countable union, countable intersection, and relative complement. Borel sets ...

are determined. It follows from the existence of sufficiently

large cardinal In the mathematical field of set theory, a large cardinal property is a certain kind of property of transfinite cardinal numbers. Cardinals with such properties are, as the name suggests, generally very "large" (for example, bigger than the least ...

s that AD holds in L(R) and that a game is determined if it has a projective set as its winning set (see Projective determinacy). The axiom of determinacy implies that for every subspace ''X'' of the

real numbers In mathematics, a real number is a number that can be used to measurement, measure a continuous variable, continuous one-dimensional quantity such as a time, duration or temperature. Here, ''continuous'' means that pairs of values can have arbi ...

, the Banach–Mazur game BM(''X'') is determined, and consequently, that every set of reals has the property of Baire.

Incompatibility with the axiom of choice

Under assumption of the axiom of choice, we present two separate constructions of counterexamples to the axiom of determinacy. It follows that the axiom of determinacy and the axiom of choice are incompatible.

Using a well-ordering of the continuum

The set ''S''₁ of all first player strategies in an ω-game ''G'' has the same

cardinality The thumb is the first digit of the hand, next to the index finger. When a person is standing in the medical anatomical position (where the palm is facing to the front), the thumb is the outermost digit. The Medical Latin English noun for thum ...

as the continuum. The same is true for the set ''S''₂ of all second player strategies. Let ''SG'' be the set of all possible sequences in ''G'', and ''A'' be the subset of sequences of ''SG'' that make the first player win. With the axiom of choice we can

well order In mathematics, a well-order (or well-ordering or well-order relation) on a Set (mathematics), set is a total ordering on with the property that every non-empty subset of has a least element in this ordering. The set together with the orderin ...

the continuum, and we can do so in such a way that any proper initial portion has lower cardinality than the continuum. We use the obtained well ordered set ''J'' to index both ''S''₁ and ''S''₂, and construct ''A'' such that it will be a counterexample. We start with empty sets ''A'' and ''B''. Let ''α'' ∈ ''J'' be the index of the strategies in ''S''₁ and ''S''₂. We need to consider all strategies ''S''₁ = _{''α''∈''J''} of the first player and all strategies ''S''₂ = _{''α''∈''J''} of the second player to make sure that for every strategy there is a strategy of the other player that wins against it. For every strategy of the player considered we will generate a sequence that gives the other player a win. Let ''t'' be the time whose axis has length ℵ₀ and which is used during each game sequence. We create the counterexample ''A'' by transfinite recursion on ''α'': # Consider the strategy s₁(''α'') of the first player. # Apply this strategy on an ω-game, generating (together with the first player's strategy s₁(''α'')) a sequence ⟨''a''₁, ''b''₂, ''a''₃, ''b''₄, ...,a_''t'', ''b''_''t''+1, ...⟩, which does not belong to ''A''. This is possible, because the number of choices for ⟨''b''₂, ''b''₄, ''b''₆, ...⟩ has the same cardinality as the continuum, which is larger than the cardinality of the proper initial portion of ''J.'' # Add this sequence to ''B'' to indicate that s₁(''α'') loses (on ⟨''b''₂, ''b''₄, ''b''₆, ...⟩). # Consider the strategy s₂(''α'') of the second player. # Apply this strategy on an ω-game, generating (together with the second player's strategy ''s''₂(''α'')) a sequence ⟨''a''₁, ''b''₂, ''a''₃, ''b''₄, ..., a_''t'', ''b''_''t''+1, ...⟩, which does not belong to ''B.'' This is possible, because the number of choices for ⟨''a''₁, ''a''₃, ''a''₅, ...⟩ has the same cardinality as the continuum, which is larger than the cardinality of the proper initial portion of ''J.'' # Add this sequence to ''A'' to indicate that ''s''₂(''α'') loses (on ⟨''a''₁, ''a''₃, ''a''₅, ...⟩). # Process all possible strategies of ''S''₁ and ''S''₂ with transfinite induction on ''α.'' For all sequences that are not in ''A'' or ''B'' after that, decide arbitrarily whether they belong to ''A'' or to ''B,'' so that ''B'' is the complement of ''A.'' Once this has been done, prepare for an ω-game ''G''. For a given strategy ''s''₁ of the first player, there is an ''α'' ∈ ''J'' such that ''s''₁ = ''s''₁(''α''), and ''A'' has been constructed such that ''s''₁(''α'') fails (on certain choices ⟨''b''₂, ''b''₄, ''b''₆, ...⟩ of the second player). Hence, ''s''₁ fails. Similarly, any other strategy of either player also fails.

Using a choice function

In this construction, the use of the axiom of choice is similar to the choice of socks as stated in the quote by Bertrand Russell at Axiom of choice#Quotations. In a ω-game, the two players are generating the sequence ⟨''a''₁, ''b''₂, ''a''₃, ''b''₄, ...⟩, an element in ω^ω, where our convention is that 0 is not a natural number, hence neither player can choose it. Define the function ''f'': ω^ω → ^ω such that ''f''(''r'') is the unique sequence of length ω with values are in whose first term equals 0, and whose sequence of runs (see

run-length encoding Run-length encoding (RLE) is a form of lossless data compression in which ''runs'' of data (consecutive occurrences of the same data value) are stored as a single occurrence of that data value and a count of its consecutive occurrences, rather th ...

) equals ''r.'' (Such an ''f'' can be shown to be injective. The image is the subset of ^ω of sequences that start with 0 and that are not eventually constant. Formally, ''f'' is the Minkowski question mark function, ^ω is the Cantor space and ω^ω is the Baire space.) Observe the equivalence relation on ^ω such that two sequences are equivalent if and only if they differ in a finite number of terms. This partitions the set into equivalence classes. Let ''T'' be the set of equivalence classes (such that ''T'' has the cardinality of the continuum). Define ''g'': ^ω → ''T'' that takes a sequence to its equivalence class. Define the complement of any sequence ''s'' in ^ω to be the sequence s₁ that differs in each term. Define the function ''h'': ''T'' → ''T'' such that for any sequence ''s'' in ^ω, ''h'' applied to the equivalence class of ''s'' equals the equivalence class of the complement of ''s'' (which is well-defined because if ''s'' and ''s are equivalent, then their complements are equivalent). One can show that ''h'' is an involution with no fixed points, and thus we have a partition of ''T'' into size-2 subsets such that each subset is of the form . Using the axiom of choice, we can choose one element out of each subset. In other words, we are choosing "half" of the elements of ''T,'' a subset that we denote by ''U'' (where U ⊆ T) such that ''t'' ∈ ''U'' iff ''h''(''t'') ∉ ''U.'' Next, we define the subset ''A'' ⊆ ω^ω in which 1 wins: ''A'' is the set of all ''r'' such that ''g''(''f''(''r'')) ∈ ''U.'' We now claim that neither player has a winning strategy, using a strategy-stealing argument. Denote the current game state by a finite sequence of natural numbers (so that if the length of this sequence is even, then 1 is next to play; otherwise 2 is next to play). Suppose that ''q'' is a (deterministic) winning strategy for 2. Player 1 can construct a strategy ''p'' that beats ''q'' as follows: Suppose that player 2 response (according to ''q'') to ⟨1⟩ is ''b''₁. Then 1 specifies in ''p'' that ''a''₁ = 1 + ''b''₁. (Roughly, 1 is now playing as 2 in a second parallel game; 1 winning set in the second game equals 2 winning set in the original game, and this is a contradiction. Nevertheless, we continue more formally.) Suppose that 2 response (always according to ''q'') to ⟨1 + ''b''₁⟩ is ''b''₂, and 2 response to ⟨1, ''b''₁, ''b''₂⟩ is ''b''₃. We construct ''p'' for 1, we only aim to beat ''q,'' and therefore only have to handle the response ''b''₂ to 1 first move. Therefore set 1 response to ⟨1 + ''b''₁, ''b''₂⟩ is ''b''₃. In general, for even ''n,'' denote 2 response to ⟨1 + b₁, ..., b_''n''−1⟩ by ''b''_''n'' and 2 response to ⟨1, ''b''₁, ..., ''b''_''n''⟩ by ''b''_''n''+1. Then 1 specify in ''p'' that 1 response to ⟨1 + ''b''₁, ''b''₂, ..., ''b''_''n''⟩ is ''b''_''n''+1. Strategy ''q'' is presumed to be winning, and game-result ''r'' in ω^ω given by ⟨1, ''b''₁, ...⟩ is one possible sequence allowed by ''q,'' so ''r'' must be winning for 2 and ''g''(''f''(''r'')) must not be in ''U.'' The game result ''r''' in ω^ω given by ⟨1 + ''b''₁, ''b''₂, ...⟩ is also a sequence allowed by ''q'' (specifically, ''q'' playing against ''p''), so ''g''(''f''(''r''')) must not be in ''U.'' However, ''f''(''r'') and ''f''(''r''') differ in all but the first term (by the nature of run-length encoding and an offset of 1), so ''f''(''r'') and ''f''(''r''') are in complement equivalent classes, so ''g''(''f''(''r'')), ''g''(''f''(''r''')) cannot both be in ''U,'' contradicting the assumption that ''q'' is a winning strategy. Similarly, suppose that ''p'' is a winning strategy for 1; the argument is similar but now uses the fact that equivalence classes were defined by allowing an arbitrarily large finite number of terms to differ. Let ''a''₁ be 1 first move. In general, for even ''n,'' denote 1 response to ⟨''a''₁, 1⟩ (if ''n'' = 2) or ⟨''a''₁, 1, ''a''₂, ..., ''a''_n−1⟩ by ''a''_''n'' and 1 response to ⟨''a''₁, 1 + ''a''₂, ... ''a''_''n''⟩ by ''a''_''n''+1. Then the game result ''r'' given by ⟨''a''₁, 1, ''a''₂, ''a''₃, ...⟩ is allowed by ''p'' so that ''g''(''f''(''r'')) must be in ''U''; also the game result ''r''' given by ⟨''a''₁, 1 + ''a''₂, ''a''₃, ...⟩ is also allowed by ''p'' so that ''g''(''f''(''r''')) must be in ''U.'' However, ''f''(''r'') and ''f''(''r''') differ in all but the first ''a''₁ + 1 terms, so they are in complement equivalent classes, therefore ''g''(''f''(''r'')) and ''g''(''f''(''r''')) cannot both be in ''U,'' contradicting that ''p'' is a winning strategy.

Large cardinals and the axiom of determinacy

The consistency of the axiom of determinacy is closely related to the question of the consistency of

axioms. By a theorem of Woodin, the consistency of

Zermelo–Fraenkel set theory In set theory, Zermelo–Fraenkel set theory, named after mathematicians Ernst Zermelo and Abraham Fraenkel, is an axiomatic system that was proposed in the early twentieth century in order to formulate a theory of sets free of paradoxes suc ...

without choice (ZF) together with the axiom of determinacy is equivalent to the consistency of Zermelo–Fraenkel set theory with choice (ZFC) together with the existence of infinitely many Woodin cardinals. Since Woodin cardinals are strongly inaccessible, if AD is consistent, then so are an infinity of inaccessible cardinals. Moreover, if to the hypothesis of an infinite set of Woodin cardinals is added the existence of a measurable cardinal larger than all of them, a very strong theory of Lebesgue measurable sets of reals emerges, as it is then provable that the axiom of determinacy is true in L(R), and therefore that ''every'' set of real numbers in L(R) is determined.

Projective ordinals

Yiannis Moschovakis introduced the ordinals δ, which is the upper bound of the length of Δ-norms (injections of a Δ set into the ordinals), where Δ is a level of the projective hierarchy. Assuming AD, all δ are initial ordinals, and we have , and for ''n'' < ω, the Suslin cardinal is equal to δ.V. G. Kanovei
The axiom of determinacy and the modern development of descriptive set theory
UDC 510.225; 510.223, Plenum Publishing Corporation (1988) p.270,282. Accessed 20 January 2023.

References

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