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Probabilities on finite models1

Published online by Cambridge University Press:  12 March 2014

Ronald Fagin
Ronald Fagin*
Affiliation:
Ibm Research Laboratory, San Jose, California 95193
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Extract

Let be a finite set of (nonlogical) predicate symbols. By an -structure, we mean a relational structure appropriate for . Let be the set of all -structures with universe {1, …, n}. For each first-order -sentence σ (with equality), let μ n (σ) be the fraction of members of for which σ is true. We show that μ n (σ) always converges to 0 or 1 as n → ∞, and that the rate of convergence is geometrically fast. In fact, if T is a certain complete, consistent set of first-order -sentences introduced by H. Gaifman [6], then we show that, for each first-order -sentence σ, μ n (σ) → n 1 iff T ⊩ ω. A surprising corollary is that each finite subset of T has a finite model. Following H. Scholz [8], we define the spectrum of a sentence σ to be the set of cardinalities of finite models of σ. Another corollary is that for each first-order -sentence a, either σ or ˜σ has a cofinite spectrum (in fact, either σ or ˜σ is “nearly always“ true).

Let be a subset of which contains for each in exactly one structure isomorphic to . For each first-order -sentence σ, let ν n (σ) be the fraction of members of which a is true. By making use of an asymptotic estimate [3] of the cardinality of and by our previously mentioned results, we show that v n(σ) converges as n → ∞, and that lim n ν n (σ) = lim n μ n (σ).If contains at least one predicate symbol which is not unary, then the rate of convergence is geometrically fast.

Type
Research Article
Information
The Journal of Symbolic Logic , Volume 41 , Issue 1 , March 1976 , pp. 50 - 58
Copyright
Copyright © Association for Symbolic Logic 1976

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Footnotes

2

The author is grateful to Robert Vaught, William Craig, and Ralph McKenzie for useful suggestions which improved readability.

1

This paper is based on a part of the author's doctoral dissertation [2] in the Department of Mathematics at the University of California, Berkeley. Part of this work was carried out while the author was a National Science Foundation Graduate Fellow; also, part of this work was supported by NSF grant GP-24532.

References

BIBLIOGRAPHY

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