Invariant uniformization
Abstract
Standard results in descriptive set theory provide sufficient conditions for a Borel set P ⊂eq NN × NN to admit a Borel uniformization, namely, when P has "small" sections or "large" sections. We consider an invariant analogue of these results: Given a Borel equivalence relation E and an E-invariant Borel set P with "small" or "large" sections, does P admit an E-invariant Borel uniformization? For a given Borel equivalence relation E, we show that every E-invariant Borel set P with "small" or "large" sections admits an E-invariant Borel uniformization if and only if E is smooth. We also compute the definable complexity of counterexamples in the case where E is not smooth, using category, measure, and Ramsey-theoretic methods. We provide two new proofs of a dichotomy of Miller classifying the pairs (E, P) such that P admits an E-invariant uniformization, for a Borel equivalence relation E and a Borel E-invariant set P with countable sections. In the process, we prove an 0-dimensional (G0, H0) dichotomy, generalizing dichotomies of Miller and Lecomte. We also show that the set of pairs (E, P) such that P has "large" sections and admits an E-invariant Borel uniformization is 12-complete; in particular, there is no analog of Miller's dichotomy for P with "large" sections. Finally, we consider a less strict notion of invariant uniformization, where we select a countable nonempty subset of each section instead of a single point.
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