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Functionals defined by transfinite recursion

Published online by Cambridge University Press:  12 March 2014

W. W. Tait
W. W. Tait*
Affiliation:
Stanford University
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Extract

This paper deals mainly with quantifier-free second order systems (i.e., with free variables for numbers and functions, and constants for numbers, functions, and functionals) whose basic rules are those of primitive recursive arithmetic together with definition of functionals by primitive recursion and explicit definition. Precise descriptions are given in §2. The additional rules have the form of definition by transfinite recursion up to some ordinal ξ (where ξ is represented by a primitive recursive (p.r.) ordering). In §3 we discuss some elementary closure properties (under rules of inference and definition) of systems with recursion up to ξ. Let Rξ denote (temporarily) the system with recursion up to ξ. The main results of this paper are of two sorts:

Sections 5–7 are concerned with less elementary closure properties of the systems Rξ. Namely, we show that certain classes of functional equations in Rη can be solved in Rη for some explicitly determined η < ε(η) (the least ε-number > ξ). The classes of functional equations considered all have roughly the form of definition by recursion on the partial ordering of unsecured sequences of a given functional F, or on some ordering which is obtained from this by simple ordinal operations. The key lemma (Theorem 1) needed for the reduction of these equations to transfinite recursion is simply a sharpening of the Brouwer-Kleene idea.

Type
Research Article
Information
The Journal of Symbolic Logic , Volume 30 , Issue 2 , June 1965 , pp. 155 - 174
Copyright
Copyright © Association for Symbolic Logic 1965

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References

REFERENCES

[1]Goodstein, R. L., Recursive number theory, North-Holland Publishing Company (1957).Google Scholar
[2]Guard, J. R., Hierarchies of recursive arithmetics (abstract), Notices of the American Mathematical Society, vol. 9 (1962), p. 339.Google Scholar
[3]Kleene, S. C., Recursive functionals and quantifiers of finite types I, Transactions of the American Mathematical Society, vol. 91 (1959), pp. 152.Google Scholar
[4]Kreisel, G., Proof by transfinite induction and definition by transfinite recursion in quantifier-free systems (abstract), this Journal, vol. 24 (1959), pp. 322–3.Google Scholar
[5]Kreisel, G. and Tait, W. W., Induction and recursion (abstract), this Journal, vol. 25 (1960), p. 385.Google Scholar
[6]Parikh, R. J., Some generalizations of the notion of well-ordering (abstract), Notices of the American Mathematical Society, vol. 9 (1962), p. 412.Google Scholar
[7]Tait, W. W., Nested recursion, Mathematische Annalen, vol. 143 (1961), pp. 236250.CrossRefGoogle Scholar
[8]Tait, W. W., The substitution method, this Journal, vol. 30 (1965) pp. 175192.Google Scholar
[9]Tait, W. W., The no-counterexample interpretation. To appear.Google Scholar
[10]Hilbert, D. and Bernays, P., Grundlagen der Mathematik, Vol. II, Berlin, 1939.Google Scholar