Randomness via infinite computation and effective descriptive set theory

Abstract

We study randomness beyond Π11-randomness and its Martin-Löf type variant, introduced in MR2340241 and further studied in Continuous-higher-randomness. The class given by the infinite time Turing machines ( s), introduced by Hamkins and Kidder, is strictly between Π11 and Σ12. We prove that the natural randomness notions associated to this class have several desirable properties resembling those of the classical random notions such as Martin-Löf randomness, and randomness notions defined via effective descriptive set theory such as Π11-randomness. For instance, mutual randoms do not share information and can be characterized as in van Lambalgen's theorem. We also obtain some differences to the hyperarithmetic setting. Already at the level of Σ12, some properties of randomness notions are independent Infinite-computations. Towards the results about randomness, we prove the following analogue to a theorem of Sacks. If a real is infinite time Turing computable relative to all reals in some given set of reals with positive Lebesgue measure, then it is already infinite time Turing computable. As a technical tool, we prove facts of independent interest about random forcing over admissible sets and increasing unions of admissible sets. These results are also useful for more efficient proofs of some classical results about hyperarithmetic sets.