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Definability in low simple theories

Published online by Cambridge University Press:  12 March 2014

Ziv Shami*
Affiliation:
Department of Mathematics and Statistics, McMaster University, 1280 Main Street West, Hamilton, Ontario, Canada L8S 4K1, E-mail:[email protected]

Extract

In 1978 Shelah introduced a new class of theories, called simple (see [Shi]) which properly contained the class of stable theories. Shelah generalized part of the theory of forking to the simple context. After approximately 15 years of neglecting the general theory (although there were works by Hrushovski on finite rank with a definability assumption, as well as deep results on specific simple theories by Cherlin, Hrushovski, Chazidakis, Macintyre and Van den dries, see [CH], [CMV], [HP1], [HP2], [ChH]) there was a breakthrough, initiated with the work of Kim ([K1]). Kim proved that almost all the technical machinery of forking developed in the stable context could be generalized to simple case. However, the theory of multiplicity (i.e., the description of the (bounded) set of non forking extensions of a given complete type) no longer holds in the context of simple theories. Indeed, by contrast to simple theories, stable theories share a strong amalgamation property of types, namely if p and q are two “free” complete extensions over a superset of A, and there is no finite equivalence relation over A which separates them, then the conjunction of p and q is consistent (and even free over A.) In [KP] Kim and Pillay proved a weak version of this property for any simple theory, namely “the Independence Theorem for Lascar strong types”. This was a weaker version both because of the requirement that the sets of parameters of the types be mutually independent, as well as the use of Lascar strong types instead of the usual strong types. A very fundamental and interesting problem is whether the independence theorem can be proved for any simple theory, using only the usual strong types. In 1997 Buechler proved ([Bu]) the strong-type version of the independence theorem for an important subclass of simple theories, namely the class of low theories (which includes the class of stable theories and the class of supersimple theories of finite D-rank.)

Type
Research Article
Copyright
Copyright © Association for Symbolic Logic 2000

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References

REFERENCES

[Bu]Buechler, S., Lascar strong types in some simple theories, this Journal, to appear.Google Scholar
[CK]Chang, C. C. and Keisler, H. J., Model Theory, North Holland, 1977.Google Scholar
[CMV]Chazidakis, Z., Van den Dries, L., and Macintyre, A.J., Definable sets over finite fields, Journal fur die Reine und Angewandte Mathematik, vol. 427 (1992), pp. 107135.Google Scholar
[CH]Chazidakis, Z. and Hrushovski, E., Model theory of difference fields, 1996, preprint.Google Scholar
[ChH]Cherlin, G. and Hrushovski, E., Lie coordinatized structures, in preparation.Google Scholar
[HP1]Hrushovski, E. and Pillay, A., Groups definable in local fields and pseudo-finite fields, Israel Journal of Mathematics, vol. 85 (1994), pp. 203262.CrossRefGoogle Scholar
[HP2]Hrushovski, E. and Pillay, A., Definable subgroups of algebraic groups over finite fields, Journal fur die Reine und Angewandte Mathematik, vol. 462 (1995), pp. 6991.Google Scholar
[Kl]Kim, B., Forking in simple unstable theories, Journal of the London Mathematical Society, (to appear).Google Scholar
[K2]Kim, B., A note on Lascar strong types in simple theories, 1997, preprint.CrossRefGoogle Scholar
[KP]Kim, B. and Pillay, A., Simple theories, Annals of Pure and Applied Logic, (1997).Google Scholar
[L]Lascar, D., On the categoricity of models of a complete theory, this Journal, vol. 47 (1982), pp. 249403.Google Scholar
[Sh2]Shelah, S., Simple Unstable Theories, Annals of Mathematical Logic, vol. 19 (1980), pp. 177203.CrossRefGoogle Scholar
[Sh1]Shelah, S., Classification theory, North Holland, Amsterdam, 1990, revised.Google Scholar