Omega-categorical theory

In mathematical logic, an omega-categorical theory is a theory that has exactly one countably infinite model up to isomorphism. Omega-categoricity is the special case κ = $\aleph _{0}$ = ω of κ-categoricity, and omega-categorical theories are also referred to as ω-categorical. The notion is most important for countable first-order theories.

Equivalent conditions for omega-categoricity[edit]

Many conditions on a theory are equivalent to the property of omega-categoricity. In 1959 Erwin Engeler, Czesław Ryll-Nardzewski and Lars Svenonius, proved several independently.^[1] Despite this, the literature still widely refers to the Ryll-Nardzewski theorem as a name for these conditions. The conditions included with the theorem vary between authors.^[2]^[3]

Given a countable complete first-order theory T with infinite models, the following are equivalent:

The theory T is omega-categorical.
Every countable model of T has an oligomorphic automorphism group (that is, there are finitely many orbits on Mⁿ for every n).
Some countable model of T has an oligomorphic automorphism group.^[4]
The theory T has a model which, for every natural number n, realizes only finitely many n-types, that is, the Stone space S_n(T) is finite.
For every natural number n, T has only finitely many n-types.
For every natural number n, every n-type is isolated.
For every natural number n, up to equivalence modulo T there are only finitely many formulas with n free variables, in other words, for every n, the nth Lindenbaum–Tarski algebra of T is finite.
Every model of T is atomic.
Every countable model of T is atomic.
The theory T has a countable atomic and saturated model.
The theory T has a saturated prime model.

Examples[edit]

The theory of any countably infinite structure which is homogeneous over a finite relational language is omega-categorical.^[5] More generally, the theory of the Fraïssé limit of any uniformly locally finite Fraïssé class is omega-categorical.^[6] Hence, the following theories are omega-categorical:

The theory of dense linear orders without endpoints (Cantor's isomorphism theorem)
The theory of the Rado graph
The theory of infinite linear spaces over any finite field
The theory of atomless Boolean algebras

Notes[edit]

^ Rami Grossberg, José Iovino and Olivier Lessmann, A primer of simple theories
^ Hodges, Model Theory, p. 341.
^ Rothmaler, p. 200.
^ Cameron (1990) p.30
^ Macpherson, p. 1607.
^ Hodges, Model theory, Thm. 7.4.1.

References[edit]

Cameron, Peter J. (1990), Oligomorphic permutation groups, London Mathematical Society Lecture Note Series, vol. 152, Cambridge: Cambridge University Press, ISBN 0-521-38836-8, Zbl 0813.20002
Chang, Chen Chung; Keisler, H. Jerome (1989) [1973], Model Theory, Elsevier, ISBN 978-0-7204-0692-4
Hodges, Wilfrid (1993), Model theory, Cambridge: Cambridge University Press, ISBN 978-0-521-30442-9
Hodges, Wilfrid (1997), A shorter model theory, Cambridge: Cambridge University Press, ISBN 978-0-521-58713-6
Macpherson, Dugald (2011), "A survey of homogeneous structures", Discrete Mathematics, 311 (15): 1599–1634, doi:10.1016/j.disc.2011.01.024, MR 2800979
Poizat, Bruno (2000), A Course in Model Theory: An Introduction to Contemporary Mathematical Logic, Berlin, New York: Springer-Verlag, ISBN 978-0-387-98655-5
Rothmaler, Philipp (2000), Introduction to Model Theory, New York: Taylor & Francis, ISBN 978-90-5699-313-9

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[primer-1] Rami Grossberg, José Iovino and Olivier Lessmann, A primer of simple theories

[Hodges341-2] Hodges, Model Theory, p. 341.

[Rothmaler-3] Rothmaler, p. 200.

[Cam30-4] Cameron (1990) p.30

[Macpherson1607-5] Macpherson, p. 1607.

[6] Hodges, Model theory, Thm. 7.4.1.

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