English

The Hilbert's-Tenth-Problem Operator

Logic 2019-08-20 v2 Number Theory

Abstract

For a ring RR, Hilbert's Tenth Problem HTP(R)HTP(R) is the set of polynomial equations over RR, in several variables, with solutions in RR. We view HTPHTP as an operator, mapping each set WW of prime numbers to HTP(Z[W1])HTP(\mathbb Z[W^{-1}]), which is naturally viewed as a set of polynomials in Z[X1,X2,]\mathbb Z[X_1,X_2,\ldots]. For W=W=\emptyset, it is a famous result of Matiyasevich, Davis, Putnam, and Robinson that the jump   ⁣\emptyset~\!' is Turing-equivalent to HTP(Z)HTP(\mathbb Z). More generally, HTP(Z[W1])HTP(\mathbb Z[W^{-1}]) is always Turing-reducible to WW', but not necessarily equivalent. We show here that the situation with W=W=\emptyset is anomalous: for almost all WW, the jump WW' is not diophantine in Z[W1]\mathbb Z[W^{-1}]. We also show that the HTPHTP operator does not preserve Turing equivalence: even for complementary sets UU and U\overline{U}, HTP(Z[U1])HTP(\mathbb Z[U^{-1}]) and HTP(Z[U1])HTP(\mathbb Z[\overline{U}^{-1}]) can differ by a full jump. Strikingly, reversals are also possible, with V<TWV<_T W but HTP(Z[W1])<THTP(Z[V1])HTP(\mathbb Z[W^{-1}]) <_T HTP(\mathbb Z[V^{-1}]).

Keywords

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}
}
R2 v1 2026-06-22T23:27:56.248Z