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Minimal upper bounds for arithmetical degrees

Published online by Cambridge University Press:  12 March 2014

Masahiro Kumabe*
Affiliation:
The University of the Air, 2-11, Wakaba, Mihama-Ku, Chiba 261, Japan

Extract

This paper was inspired by Lerman [14] in which he proved various properties of upper bounds for the arithmetical degrees. The degrees which are upper bounds for the arithmetical degrees were first studied by Hodes [5] and Enderton and Putnam [5]. Enderton and Putnam [5] showed that if a is an upper bound for the arithmetical degrees, then a(2) ≥ 0(ω). This area was further studied by Hodes [5], Knight, Lachlan and Soare [12], Jockusch and Simpson [12], and Sacks [17].

Enderton and Putnam [5] and Sacks [17] have combined to show that 0(ω) is the least degree in {a(2): a is an upper bound for the arithmetical degrees}. So there seem to be some analogies between the degrees of upper bounds for the arithmetical degrees and the degrees below 0(2). But Sacks [17] showed an important difference between these two structures; namely, the Turing jumps of upper bounds for the arithmetical degrees have no least element. In Lerman [14], a systematic investigation of properties of the jumps of upper bounds for the arithmetical degrees was suggested, which could lead to a definition of the jump operator over the elementary theory of the partial ordering of the degrees. Although Cooper [5] found a degree-theoretic definition of the jump operator, Lerman's plan is still interesting.

We say a degree a is generic if there is a representative A of a such that A is Cohen generic for the arithmetical sentences. By Jockusch [5], the statement that A is Cohen generic for the arithmetical sentences is equivalent to saying that for any arithmetical set S of binary strings, there is a σ extended by A such that σ is in S or no extension of σ is in S. First, we investigate the relation between generic degrees and upper bounds for the arithmetical degrees. In the case D(≤ 0′), the set of degrees below 0′, it is well known that any nonrecursive r.e. degree bounds a 1-generic degree (Cohen generic for Σ1 sentences). Jockusch and Ponser [12] showed that any degree a with a″ >T (a ∪ 0′)′ bounds a 1-generic degree.

Type
Research Article
Copyright
Copyright © Association for Symbolic Logic 1994

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References

REFERENCES

[1] Cooper, S. B., The strong anticupping property for recursively enumerable degrees, this Journal, vol. 54 (1989), pp. 527539.Google Scholar
[2] Cooper, S. B., The jump is definable in the structure of degrees of unsohablity (to appear).Google Scholar
[3] Enderton, H. B. and Putnam, H.. A note on the hyperarithmetical hierarchy, this Journal, vol. 35 (1970), pp. 429430.Google Scholar
[4] Hodes, H., Uniform upper bounds on ideals of Turing degrees, this Journal, vol. 43 (1978), pp. 601612.Google Scholar
[5] Hodes, H., Jumping to an uniform upper bound, Proceedings of the American Mathematical Society, vol. 85 (1982), pp. 600602.CrossRefGoogle Scholar
[6] Jockusch, C. G. Jr., Degrees of generic sets, Proceedings of London Mathematical Society Lecture Notes Series no. 45, Cambridge University Press, London and New York, 1980, pp. 110139.Google Scholar
[7] Jockusch, C. G. Jr. and Posner, D., Double jumps of minimal degrees, this Journal, vol. 43 (1978), pp. 715724.Google Scholar
[8] Jockusch, C. G. Jr. and Simpson, S. G., A degree-theoretic definition of the ramified analytical hierarchy, Annals of Mathematical Logic, vol. 10 (1975), pp. 132.CrossRefGoogle Scholar
[9] Knight, J., Lachlan, A. H., and Soare, R., TWO theorems on degrees of models of true arithmetic, this Journal, vol. 49 (1984), pp. 425436.Google Scholar
[10] Lachlan, A. H., The impossibility of finding relative complements for recursively enumerable degrees, this Journal, vol. 31 (1966), pp. 537569.Google Scholar
[11] Lachlan, A. H., Lower bounds for pairs of recursively enumerable degrees, Proceeedings of the London Mathematical Society, vol. 16 (1966), pp. 537569.CrossRefGoogle Scholar
[12] Lerman, M., Degrees of unsolvability, Perspectives in Mathematical Logic, Springer, Berlin, 1933.Google Scholar
[13] Lerman, M., On recursive linear orderings, Logic year 1979–80: The University of Connecticut, Lecture Notes in Mathematics, vol. 859, Springer-Verlag, Berlin, 1981, pp. 132142.CrossRefGoogle Scholar
[14] Lerman, M., Upper bound for the arithmetical degrees, Annals of Pure and Applied Logic, vol. 29 (1985), pp. 225254.CrossRefGoogle Scholar
[15] Posner, D., The upper semilattice of degrees ≤ 0′ is complemented, this Journal, vol. 46 (1981), pp. 705713.Google Scholar
[16] Posner, D. and Robinson, R. W., Degrees joining to 0′, this Journal, vol. 46 (1981), pp. 714722.Google Scholar
[17] Sacks, G. E., Forcing with perfect closed sets, Axiomatic set theory, Proceedings of Symposia in Pure Mathematics, vol. XII, Part 1 (Scott, Dana S., editor), American Mathematical Society, Providence, Rhode Island, 1971, pp. 331355.CrossRefGoogle Scholar
[18] Slaman, T. A. and Steel, J. R., Complementation in the Turing degrees, this Journal, vol. 54 (1989), pp. 160176.Google Scholar
[19] Yates, C. E. M., A minimal pair of recursively enumerable degrees, this Journal, vol. 31 (1966), pp. 159168.Google Scholar