English

Muchnik degrees and cardinal characteristics

Logic 2023-06-22 v3

Abstract

For p[0,1]p \in [0,1] let D(p)\mathcal D(p) be the mass problem of infinite bit sequences~yy (i.e., {0,1}\{0,1\}-valued functions) such that for each computable bit sequence xx, the bit sequence xy x \leftrightarrow y has asymptotic lower density at most pp (where xyx \leftrightarrow y has a 11 in position nn iff x(n)=y(n)x(n) = y(n)). We show that all members of this family of mass problems parameterized by a real pp with 0<p<1/20 < p<1/2 have the same complexity in the sense of Muchnik reducibility. We prove this by showing Muchnik equivalence of the problems D(p)\mathcal D(p) with the mass problem IOE(22n)\mathrm{IOE}(2^ { 2^ n}). As a dual of the problem D(p)\mathcal D(p), define B(p)\mathcal B(p), for 0p<1/20 \le p < 1/2, to be the set of bit sequences yy such that ρ(xy)>p\underline \rho (x \leftrightarrow y) > p for each computable set~xx. We prove that the Medvedev (and hence Muchnik) complexity of the mass problems B(p)\mathcal B(p) is the same for all p(0,1/2)p \in (0, 1/2), by showing that they are Medvedev equivalent to the mass problem of functions bounded by 22n2^{2^ n} that are almost everywhere different from each computable function. Together with Joseph Miller, we obtain a proper hierarchy of the mass problems of type IOE\mathrm{IOE}: We study cardinal characteristics in the sense of set theory that are analogous to the highness properties above.

Cite

@article{arxiv.1712.00864,
  title  = {Muchnik degrees and cardinal characteristics},
  author = {Benoit Monin and André Nies},
  journal= {arXiv preprint arXiv:1712.00864},
  year   = {2023}
}

Comments

Updated April 2020, to appear in J. Symb. Logic

R2 v1 2026-06-22T23:05:11.773Z