Rogers semilattices of punctual numberings

Bazhenov, Nikolay; Mustafa, Manat; Ospichev, Sergei

doi:10.1017/s0960129522000093

Math. Struct. Comp. Sci.

2022

DOI: 10.1017/s0960129522000093

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Rogers semilattices of punctual numberings

Nikolay Bazhenov

Manat Mustafa

Sergei Ospichev

Abstract: The paper works within the framework of punctual computability, which is focused on eliminating unbounded search from constructions in algebra and infinite combinatorics. We study punctual numberings, that is, uniform computations for families S of primitive recursive functions. The punctual reducibility between numberings is induced by primitive recursive functions. This approach gives rise to upper semilattices of degrees, which are called Rogers pr-semilattices. We show that any infinite, uniformly primitiv… Show more

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2024

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Cited by 2 publications

References 32 publications

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Computably enumerable equivalence relations via primitive recursive reductions

Kalmurzayev,

Bazhenov,

Iskakov

2024

Journal of Logic and Computation

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The complexity classification of computably enumerable equivalence relations (or ceers, for short) has received much attention in the recent literature. A measure of complexity is typically provided by an appropriate notion of a reduction. Given binary relations $R$ and $S$ on natural numbers, a total function $f$ is a reduction from $R$ to $S$ if for arbitrary $x$ and $y$, the conditions $x~R~y$ and $f(x)~S~f(y)$ are always equivalent. If the function $f$ can be chosen primitive recursive, then we say that $R$ is primitively recursively reducible to $S$, denoted by $R \leq _{pr} S$. We investigate the degree structure $(\textbf {Ceers},\leq _{pr})$ of $\leq _{pr}$-degrees of ceers. We examine when pairs of incomparable degrees have an infimum and a supremum. In particular, we show that $(\textbf {Ceers},\leq _{pr})$ is neither an upper semilattice nor a lower semilattice. We also study first-order definable subclasses of $(\textbf {Ceers},\leq _{pr})$. In particular, we prove that the set of equivalences that have only finitely many classes is definable in $(\textbf {Ceers},\leq _{pr})$. Finally, we show that the structure of $\leq _{pr}$-degrees of computably enumerable preorders has a hereditarily undecidable theory.

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Computably enumerable equivalence relations via primitive recursive reductions

Kalmurzayev,

Bazhenov,

Iskakov

2024

Journal of Logic and Computation

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Undecidability of the degree structure of primitive recursive m-reducibility

Kalmurzayev,

Bazhenov,

Iskakov

2024

Journal of Logic and Computation

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Rogers semilattices of punctual numberings

Cited by 2 publications

References 32 publications

Computably enumerable equivalence relations via primitive recursive reductions

Computably enumerable equivalence relations via primitive recursive reductions

Undecidability of the degree structure of primitive recursive m-reducibility

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