Uniformization (set theory)

In set theory, the axiom of uniformization, a weak form of the axiom of choice, states that if $R$ is a subset of $X\times Y$ , where $X$ and $Y$ are Polish spaces, then there is a subset $f$ of $R$ that is a partial function from $X$ to $Y$ , and whose domain (in the sense of the set of all $x$ such that $f(x)$ exists) equals

\{x\in X|\exists y\in Y (x,y)\in R\}\,

Such a function is called a uniformizing function for $R$ , or a uniformization of $R$ .

Uniformization of relation R (light blue) by function f (red).

To see the relationship with the axiom of choice, observe that $R$ can be thought of as associating, to each element of $X$ , a subset of $Y$ . A uniformization of $R$ then picks exactly one element from each such subset, whenever the subset is nonempty. Thus, allowing arbitrary sets X and Y (rather than just Polish spaces) would make the axiom of uniformization equivalent to AC.

A pointclass $\boldsymbol{\Gamma}$ is said to have the uniformization property if every relation $R$ in $\boldsymbol{\Gamma}$ can be uniformized by a partial function in $\boldsymbol{\Gamma}$ . The uniformization property is implied by the scale property, at least for adequate pointclasses of a certain form.

It follows from ZFC alone that $\boldsymbol{\Pi}^1_1$ and $\boldsymbol{\Sigma}^1_2$ have the uniformization property. It follows from the existence of sufficient large cardinals that

$\boldsymbol{\Pi}^1_{2n+1}$ and $\boldsymbol{\Sigma}^1_{2n+2}$ have the uniformization property for every natural number $n$ .
Therefore, the collection of projective sets has the uniformization property.
Every relation in L(R) can be uniformized, but not necessarily by a function in L(R). In fact, L(R) does not have the uniformization property (equivalently, L(R) does not satisfy the axiom of uniformization).
- (Note: it's trivial that every relation in L(R) can be uniformized in V, assuming V satisfies AC. The point is that every such relation can be uniformized in some transitive inner model of V in which AD holds.)

References

Moschovakis, Yiannis N. (1980). Descriptive Set Theory. North Holland. ISBN 0-444-70199-0.

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