Myhill isomorphism theorem

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In computability theory the Myhill isomorphism theorem, named after John Myhill, provides a characterization for two numberings to induce the same notion of computability on a set.

[edit] Myhill isomorphism theorem

Sets A and B of natural numbers are said to be recursively isomorphic if there is a total computable bijection f from the set of natural numbers to itself such that f(A) = B.

A set A of natural numbers is said to be one-one reducible to a set B if there is a total computable injection f on the natural numbers such that f(A) \subseteq B and f(\mathbb{N} \setminus A) \subseteq \mathbb{N} \setminus B.

Myhill's isomorphism theorem states that two sets A and B of natural numbers are recursively isomorphic if and only if A is one-reducible to B and B is one-reducible to A. The theorem is proved by an effective version of the argument used for the Schroeder-Bernstein theorem.

A corollary of Myhill's theorem is that two total numberings are one-equivalent if and only if they are computably isomorphic.

[edit] References

  • John Myhill: “Creative Sets”. Zeitschrift für mathematische Logik und Grundlagen der Mathematik, 1:97–108, 1955.
  • Rogers, H. The Theory of Recursive Functions and Effective Computability, MIT Press. ISBN 0-262-68052-1; ISBN 0-07-053522-1
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