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Large families of incomparable A-isols

Published online by Cambridge University Press:  12 March 2014

William S. Heck*
Affiliation:
Bell Telephone Laboratories, Incorporated, Holmdel New Jersey 07733

Extract

The set Λ of isols was extensively studied by Dekker and Myhill in [1]. Subsequently, Nerode [3] developed the theory of Λ(A), the set of isols relative to some recursively closed set of functions A.

One of the main areas of interest of [1] was the natural partial order on Λ. In this paper we will examine some of the properties of ≤A on Λ(A). We use the following notations: ∣A∣ is the cardinality of the set A, ⊃ denotes strict inclusion, (a) is the power set of the set a, c is the cardinality of the continuum, and ω = {0, 1, 2, …}. The terms A-isol, A-immune, A-r.e., A-incomparable, etc. all refer to the usual meaning of these words, only taken in the context of the recursively closed set A. ReqA(a) is the A-r.e.t. of which a is a representative. By identifying a finite natural number with the A-r.e.t. consisting of sets of a given finite cardinality we see that ωΛ(A); Λ(A) is said to be nontrivial iff ωΛ(A). The three results proven in this paper are:

  1. Theorem 1. If Λ(A) is nontrivial, thenΛ(A)∣ = c.

  2. Theorem 2. IfA∣ < c, then Λ(A) is nontrivial.

  3. Theorem 3. IfA∣ < c and∣ < c and Λ(A) − ω, then there is aΓ ⊆ Λ(A) − ω such that:

  • (a) ∣Γ∣ = c.

  • (b) Every member of Γ is A-incomparable with every member of Δ.

  • (c) Any two distinct members of Γ are A-incomparable.

Type
Research Article
Copyright
Copyright © Association for Symbolic Logic 1983

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References

REFERENCES

[1]Dekker, J. C. E. and Myhill, J., Recursive equivalence types, University of California Publications in Mathematics, New Series (3), Berkeley, California, 1960, pp. 67214.Google Scholar
[2]Heck, W., An independent principle of set theory and applications to isols, Ph.D. Thesis, Rutgers University, New Brunswick, New Jersey, 1977.Google Scholar
[3]Nerode, A., Arithmetically isolated sets and non-standard models, Proceedings of Symposia in Pure Mathematics, Vol. V, American Mathematical Society, Providence, Rhode Island, 1962.Google Scholar