Reversal-bounded multipushdown machines

doi:10.1016/S0022-0000(74)80027-9

Journal of Computer and System Sciences

Volume 8, Issue 3, June 1974, Pages 315-332

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Several representations of the recursively enumerable (r.e.) sets are presented. The first states that every r.e. set is the homomorphic image of the intersection of two linear context-free languages. The second states that every r.e. set is accepted by an on-line Turing acceptor with two pushdown stores such that in every computation, each pushdown store can make at most one reversal (that is, one change from “pushing” to “popping”). It is shown that this automata theoretic representation cannot be strengthened by restricting the acceptors to be deterministic multitape, nondeterministic one-tape, or nondeterministic multicounter acceptors. This provides evidence that reversal bounds are not a natural measure of computational complexity for multitape Turing acceptors.

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^*: This research was supported in part by the National Aeronautics and Space Administration under Grant No. NGR-22-007-176 and by the National Science Foundation under Grant No. NSF-GJ-30409. The results were announced at the Thirteenth Annual IEEE Symposium on Switching and Automata Theory, College Park, Maryland, October, 1972, and an extended abstract appears in the Conference Record. The first author held an NSF Graduate Fellowship while doing this research.

Journal of Computer and System Sciences

Reversal-bounded multipushdown machines*