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Grzegorcyk's hierarchy and IepΣ1

Published online by Cambridge University Press:  12 March 2014

Gaisi Takeuti*
Affiliation:
Department of Mathematics, University of Illinois, Urbana, Illinois 61801, E-mail: takeuti@symcom.math.uiuc.edu

Extract

A proof-theoretic characterization of the primitive recursive functions is the Σ1-definable functions in IΣ1 as is shown in Mints [4], Parsons [5], and [8].

Then what is a proof-theoretic characterization of Grzegorzyk's hierarchy? First we discuss a related previous work. In Clote and Takeuti [2], we introduced a theory TAC that corresponds to the computational complexity class AC. TAC has a very weak form of induction. We assign a rank to a proof in TAC in the following way. The rank of a proof P in TAC is the nesting number of inductions used in P. Then TACi is defined to be the subtheory of TAC whose proof has a rank ≤ i. We proved that TACi corresponds to the class ACi.

In this paper we introduce a theory IepΣ1 which is equivalent to IΣ1. Then we define the rank of a proof in IepΣ1 as the nesting number of inductions in the proof and prove that the proofs with rank ≤ i correspond to Grzegorcyk's hierarchy for i > 0.

We also prove that the system that has proofs with rank 0 is actually equivalent to I Δ0. These facts are interesting since it is proved in [10] that the theory isomorphic to TAC by RSUV isomorphism is a conservative extension of I Δo. Therefore there is some analogy between the class AC and the primitive recursive functions.

Type
Research Article
Copyright
Copyright © Association for Symbolic Logic 1994

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References

REFERENCES

[1]Buss, S. R., Bounded arithmetic, Bibliopolis, 1986 (to appear).Google Scholar
[2]Clote, P. and Takeuti, G., First order bounded arithmetic and small boolean circuit complexity classes (to appear).Google Scholar
[3]Hájek, P. and Pudlák, P., Melamathematics of first-order arithmetic, Springer-Verlag, New York, 1993.CrossRefGoogle Scholar
[4]Mints, G. E., Quantifier-free and one-quantifier systems, Journal of Soviet Mathematics, vol. 1 (1973), pp. 7184.CrossRefGoogle Scholar
[5]Parsons, C., On a number-theoretic choice schema and its relations to induction, Intuitionism and Proof Theory, Proceedings of the Summer Conference at Buffalo N.Y. 1968, North-Holland, Amsterdam, 1970, pp. 459473.CrossRefGoogle Scholar
[6]Parikh, R., Existence and feasibility in arithmetic, Journal of Symbolic Logic, vol. 36 (1971), pp. 494508.CrossRefGoogle Scholar
[7]Rose, H. E., Subrecursion: functions and hierachies, Oxford University Press, London, 1984.Google Scholar
[8]Takeuti, G., Proof Theory, vol. 2nd ed, North-Holland, Amsterdam, 1975.Google Scholar
[9]Takeuti, G., RSUV isomorphisms, Proof theory and computational complexity (Colte, P. and Krájiĉek, J., editors), Oxford University Press, London, 1993, pp. 364386.Google Scholar
[10]Takeuti, G., RSUV isomorphisms for TACi, TNCi and TLS (to appear).Google Scholar