Randomness via effective descriptive set theory

Hjorth, Greg; Nies, André

doi:10.1112/jlms/jdm022

Cited by 26 publications

(68 citation statements)

References 9 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…We mainly deal with what is called Π 1 1 -randomness and Σ 1 1 -genericity. The notion of Π 1 1 -randomness goes back to Sacks [Sac90] and Kechris [Kec75], and it started to be studied formally by Hjorth and Nies [HN07]. It is a notion of interest because of some remarkable properties shared with no other randomness notion.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Higher Randomness and Genericity

Greenberg

Monin

2017

Forum of Mathematics, Sigma

View full text Add to dashboard Cite

show abstract

Section: Introductionmentioning

confidence: 99%

“…Sacks (see [Sac90,IV2.5]) was the first to define the notion of Π 1 1 -randomness and show it is distinct from ∆ 1 1 -randomness. An important advance in the theory of 'higher randomness' was made by Hjorth and Nies in [HN07]. They used the analogy between computably enumerable and Π 1 randomness.…”

Section: Introductionmentioning

confidence: 99%

Higher Randomness and Genericity

Greenberg

Monin

2017

Forum of Mathematics, Sigma

View full text Add to dashboard Cite

show abstract

“…We are pursuing the notion of ITRM-randomness in ongoing work. In contrast to strong Π 1 1 -randomness ( [8], [17]), it will be shown below that there is no universal ITRM-test.…”

Section: Definitionmentioning

confidence: 99%

“…Since its introduction, several variants of this general approach to defining randomness have been considered; a recent example is the work of Hjorth and Nies on Π 1 1 -randomness and a Π 1 1 version of ML-randomness, which led to interesting connections with descriptive set theory ( [8]). …”

Section: Introductionmentioning

confidence: 99%

Randomness and degree theory for infinite time register machines1

Carl

2016

COM

View full text Add to dashboard Cite

A concept of randomness for infinite time register machines (ITRMs) is defined and studied. In particular, we show that for this notion of randomness, computability from mutually random reals implies computability and that an analogue of van Lambalgen's theorem holds. This is then applied to obtain results on the structure of ITRMdegrees. Finally, we consider autoreducibility for ITRMs and show that randomness implies non-autoreducibility. This is an expanded and amended version of [4].

show abstract

“…In particular, to have this notion make sense, we need a notion of "machine" which takes in finite elements and outputs finite elements. One solution to this problem was proposed in [4], which introduced the notion of a Π 1 1 -machine and showed that the analogous notion of Kolmogorov randomness agrees with the notion of passing Π 1 1 Martin-Löf tests. Feedback machines provide another natural notion of a finite machine that performs a meta-computation.…”

Section: F Kolmogorov Complexitymentioning

confidence: 99%

Feedback Turing Computability, and Turing Computability as Feedback

Freer

Lubarsky

2015

2015 30th Annual ACM/IEEE Symposium on Logic in Computer Science

View full text Add to dashboard Cite

Abstract-The notion of a feedback query is a natural generalization of choosing for an oracle the set of indices of halting computations. Notice that, in that setting, the computations being run are different from the computations in the oracle: the former can query an oracle, whereas the latter cannot. A feedback computation is one that can query an oracle, which itself contains the halting information about all feedback computations. Although this is self-referential, sense can be made of at least some such computations. This threatens, though, to obliterate the distinction between con-and divergence: before running a computation, a machine can ask the oracle whether that computation converges, and then run it if and only if the oracle says "yes." This would quickly lead to a diagonalization paradox, except that a new distinction is introduced, this time between freezing and non-freezing computations. The freezing computations are even more extreme than the divergent ones, in that they prevent the dovetailing on all computations into a single run.In this paper, we study feedback around Turing computability. In one direction, we examine feedback Turing machines, and show that they provide exactly hyperarithmetic computability. In the other direction, Turing computability is itself feedback primitive recursion (at least, one version thereof).We also examine parallel feedback. Several different notions of parallelism in this context are identified. We show that parallel feedback Turing machines are strictly stronger than sequential feedback TMs, while in contrast parallel feedback p.r. is the same as sequential feedback p.r.

show abstract

Randomness via effective descriptive set theory

Cited by 26 publications

References 9 publications

Higher Randomness and Genericity

Higher Randomness and Genericity

Randomness and degree theory for infinite time register machines1

Feedback Turing Computability, and Turing Computability as Feedback

Contact Info

Product

Resources

About