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Abstract classes with few models have ‘homogeneous-universal’ models

Published online by Cambridge University Press:  12 March 2014

J. Baldwin
Affiliation:
Department of Mathematics, University of Illinois, Chicago, Box 4348, Chicago IL 60680
S. Shelah
Affiliation:
Department of Mathematics, Hebrew University of Jerusalem, Jesusalem, Israel

Extract

This paper is concerned with a class K of models and an abstract notion of submodel ≤. Experience in first order model theory has shown the desirability of finding a ‘monster model’ to serve as a universal domain for K. In the original constructions of Jónsson and Fraïssé, K was a universal class and ordinary substructure played the role of ≤. Working with a cardinal λ satisfying λ<λ = λ guarantees appropriate downward Löwenheim-Skolem theorems; the existence and uniqueness of a homogeneous-universal model appears to depend centrally on the amalgamation property. We make this apparent dependence more precise in this paper.

The major innovation of this paper is the introduction of a weaker notion (chain homogeneous-universal) to replace the natural notion of (K, <)-homogeneous-universal model. Modulo a weak extension of ZFC (provable if V = L), we show (Corollary 5.24) that a class K obeying certain minimal restrictions satisfies a fundamental dichotomy. For arbitrarily large λ, either K has the maximal number of models in power λ or K has a unique chain homogeneous-universal model of power λ. We show (5.25) in a class with amalgamation this dichotomy holds for the notion of K-homogeneous-universal model in the more normal sense.

The methods here allow us to improve our earlier results [5] in two other ways: certain requirements on all chains of a given length are replaced by requiring winning strategies in certain games; the notion of a canonically prime model is avoided. A full understanding of these extensions requires consideration of the earlier papers but we summarize them quickly here.

Type
Research Article
Copyright
Copyright © Association for Symbolic Logic 1995

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References

REFERENCES

[1]Karlowicz, M.Engelking, A., Some theorems of set theory and their topological consequences, Fundamenta Mathematica, vol. 57 (1965), pp. 275285.Google Scholar
[2]Albert, M. and Grossberg, R., Rich models, this Journal, vol. 55 (1990), pp. 12921298.Google Scholar
[3]Avraham, U., Shelah, S., and Solovay, R., Squares with diamonds and Souslin trees with special squares, Fundamenta Mathematica, vol. 127 (1987), pp. 133162.CrossRefGoogle Scholar
[4]Baldwin, J.T. and Shelah, S., The primal framework: I, Annals of Pure and Applied Logic, vol. 46 (1990), pp. 235264.CrossRefGoogle Scholar
[5]Baldwin, J.T. and Shelah, S., The primal framework II: Smoothness, Annals of Pure and Applied Logic, vol. 55 (1991), pp. 134.CrossRefGoogle Scholar
[6]Beller, A. and Litman, A., A strengthening of Jensen's □ principles, this Journal, vol. 45 (1980), pp. 251264.Google Scholar
[7]Makowsky, J. A., Abstract embedding relations, Model-theoretic logics (Barwise, J. and Feferman, S., editors), Springer-Verlag, 1985, pp. 747792.Google Scholar
[8]Shelah, S., Reflection of stationary sets and successor of singulars, preprint 351: to appear in Archive for mathematical logic.Google Scholar
[9]Shelah, S., On the number of nonisomorphic models of cardinality λ Lλ-equivalent to a fixed model, Notre Dame Journal of Formal Logic, vol. 22 (1981), pp. 510.CrossRefGoogle Scholar
[10]Shelah, S., Models with second order properties IV, A general method and eliminating diamonds, Annals of Mathematical Logic, vol. 38 (1983), pp. 183212.Google Scholar
[11]Shelah, S., Remarks on squares, Around classification theory of models, Springer-Verlag, 1986, Springer Lecture Notes 1182.CrossRefGoogle Scholar
[12]Shelah, S., Nonelementary classes II, Classification theory, Chicago 1985 (Baldwin, J., editor), Springer-Verlag, 1987, Springer Lecture Notes 1292.Google Scholar
[13]Shelah, S., Universal classes: Part 1, Classification theory, Chicago 1985 (Baldwin, J., editor), Springer-Verlag, 1987, Springer Lecture Notes 1292, pp. 264419.Google Scholar