In this paper we study the notion of first-order part of a computational problem, first introduced in [17], which captures the "strongest computational problem with codomain N that is Weihrauch reducible to f". This operator is very useful to prove separation results, especially at the higher levels of the Weihrauch lattice. We explore the first-order part in relation with several other operators already known in the literature. We also introduce a new operator, called unbounded finite parallelization, which plays an important role in characterizing the first-order part of parallelizable problems. We show how the obtained results can be used to explicitly characterize the first-order part of several known problems.(c) 2023 Elsevier B.V. All rights reserved.
Algebraic properties of the first-order part of a problem
Valenti, Manlio
2023-01-01
Abstract
In this paper we study the notion of first-order part of a computational problem, first introduced in [17], which captures the "strongest computational problem with codomain N that is Weihrauch reducible to f". This operator is very useful to prove separation results, especially at the higher levels of the Weihrauch lattice. We explore the first-order part in relation with several other operators already known in the literature. We also introduce a new operator, called unbounded finite parallelization, which plays an important role in characterizing the first-order part of parallelizable problems. We show how the obtained results can be used to explicitly characterize the first-order part of several known problems.(c) 2023 Elsevier B.V. All rights reserved.| File | Dimensione | Formato | |
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