Speedability of computably approximable reals and their approximations
Abstract
An approximation of a real is a sequence of rational numbers that converges to the real. An approximation is left-c.e. if it is computable and nondecreasing and is d.c.e. if it is computable and has bounded variation. A real is computably approximable if it has some computable approximation, and left-c.e. and d.c.e. reals are defined accordingly. An approximation \as\s ∈ ω is speedable if there exists a nondecreasing computable function f such that the approximation \af(s)\s ∈ ω converges in a certain formal sense faster than \as\s ∈ ω. This leads to various notions of speedability for reals, e.g., one may require for a computably approximable real that either all or some of its approximations of a specific type are speedable. Merkle and Titov established the equivalence of several speedability notions for left-c.e. reals that are defined in terms of left-c.e. approximations. We extend these results to d.c.e. reals and d.c.e. approximations, and we prove that in this setting, being speedable is equivalent to not being Martin-L\"of random. Finally, we demonstrate that every computably approximable real has a computable approximation that is speedable.
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