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The finite model property for various fragments of linear logic

Published online by Cambridge University Press:  12 March 2014

Yves Lafont
Yves Lafont*
Affiliation:
Institut de Mathématiques de Luminy, UPR 9016 du CNRS, 163 Avenue de Luminy, Case 930, 13288 Marseille Cedex 9, France, E-mail: lafont@iml.univ-mrs.fr
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Extract

To show that a formula A is not provable in propositional classical logic, it suffices to exhibit a finite boolean model which does not satisfy A. A similar property holds in the intuitionistic case, with Kripke models instead of boolean models (see for instance [11]). One says that the propositional classical logic and the propositional intuitionistic logic satisfy a finite model property. In particular, they are decidable: there is a semi-algorithm for provability (proof search) and a semi-algorithm for non provability (model search). For that reason, a logic which is undecidable, such as first order logic, cannot satisfy a finite model property.

The case of linear logic is more complicated. The full propositional fragment LL has a complete semantics in terms of phase spaces [2, 3], but it is undecidable [9]. The multiplicative additive fragment MALL is decidable, in fact PSPACE-complete [9], but the decidability of the multiplicative exponential fragment MELL is still an open problem. For affine logic, that is, linear logic with weakening, the situation is somewhat better: the full propositional fragment LLW is decidable [5].

Here, we show that the finite phase semantics is complete for MALL and for LLW, but not for MELL. In particular, this gives a new proof of the decidability of LLW. The noncommutative case is mentioned, but not handled in detail.

Type
Research Article
Information
The Journal of Symbolic Logic , Volume 62 , Issue 4 , December 1997 , pp. 1202 - 1208
Copyright
Copyright © Association for Symbolic Logic 1997

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References

REFERENCES

[1]Abrusci, V. M., Phase semantics and sequent calculus for pure noncommutative classical linear propositional logic, this Journal, vol. 56 (1991), pp. 14031451.Google Scholar
[2]Girard, J.-Y., Linear logic, Theoretical Computer Science, vol. 50 (1987), pp. 1102.CrossRefGoogle Scholar
[3]Girard, J.-Y., Linear logic: its syntax and semantics, Advances in linear logic (Girard, J.-Y., Lafont, Y., and Regnier, L., editors), London Mathematical Society Lecture Note Series, vol. 222, Cambridge University Press, 1995, pp. 142.CrossRefGoogle Scholar
[4]Kanovich, M., Simulating computations in second order non-commutative linear logic, manuscript, 1995.CrossRefGoogle Scholar
[5]Kopylov, A. P., Propositional linear logic with weakening is decidable, Proceedings of the 10th Annual IEEE Symposium on Logic in Computer Science, San Diego, California, IEEE Computer Society Press, 1995.Google Scholar
[6]Kopylov, A. P., The undecidability of second order linear affine logic, manuscript, 1995.Google Scholar
[7]Lafont, Y., The undecidability of second order linear logic without exponentials, this Journal, vol. 61 (1996), pp. 541548.Google Scholar
[8]Lafont, Y. and Scedrov, A., The undecidability of second order multiplicative linear logic, Information and Computation, vol. 125 (1996), pp. 4651.CrossRefGoogle Scholar
[9]Lincoln, P., Mitchell, J., Scedrov, A., and Shankar, N., Decision problems for propositional linear logic, Annals of Pure and Applied Logic, vol. 56 (1992), pp. 239311.CrossRefGoogle Scholar
[10]Okada, M., Girard's phase semantics and a higher order cut-elimination proof, available by anonymous ftp on iml. univ-mrs. fr, in pub/okada, 1994.Google Scholar
[11]Troelstra, A. S. and van Dalen, D., Constructivism in mathematics, an introduction, vol. 1, Studies in logic and the foundations of mathematics, vol. 121, North-Holland, 1988.Google Scholar