The Hilbert's-Tenth-Problem Operator
Logic
2019-08-20 v2 Number Theory
Abstract
For a ring , Hilbert's Tenth Problem is the set of polynomial equations over , in several variables, with solutions in . We view as an operator, mapping each set of prime numbers to , which is naturally viewed as a set of polynomials in . For , it is a famous result of Matiyasevich, Davis, Putnam, and Robinson that the jump is Turing-equivalent to . More generally, is always Turing-reducible to , but not necessarily equivalent. We show here that the situation with is anomalous: for almost all , the jump is not diophantine in . We also show that the operator does not preserve Turing equivalence: even for complementary sets and , and can differ by a full jump. Strikingly, reversals are also possible, with but .
Cite
@article{arxiv.1712.08686,
title = {The Hilbert's-Tenth-Problem Operator},
author = {Ken Kramer and Russell Miller},
journal= {arXiv preprint arXiv:1712.08686},
year = {2019}
}