In model theory, the age of a structure (or model) A is the class of all finitely generated structures that are embeddable in A (i.e. isomorphic to substructures of A). This concept is central in the construction of a Fraïssé limit. The main point of Fraïssé's construction is to show how one can approximate a structure by its finitely generated substructures. Thus for example the age of any dense linear order without endpoints (DLO), [math]\displaystyle{ \langle\mathbb{Q},\lt \rangle }[/math] is precisely the set of all finite linear orderings, which are distinguished up to isomorphism only by their size. Thus the age of any DLO is countable. This shows in a way that a DLO is a kind of limit of finite linear orderings.
One can easily see that any class K that is an age of some structure satisfies the following two conditions:
Fraïssé proved the converse result: when K is any non-empty countable set of finitely generated σ-structures (with σ a signature) that has the above two properties, then it is an age of a countable structure.
Furthermore, suppose that K happens to satisfy the following additional property.
In that case, there is a unique countable structure, up to isomorphism, that has age K and is homogeneous. In this context, 'homogeneous' means that any isomorphism between two finitely generated substructures can be extended to an automorphism of the whole structure. Again, an example of this situation is the ordered set of rational numbers [math]\displaystyle{ \langle\mathbb{Q},\lt \rangle }[/math]. It is the unique (up to isomorphism) homogeneous countable structure whose age is the set of all finite linear orderings. Note that the ordered set of natural numbers [math]\displaystyle{ \langle\mathbb{N},\lt \rangle }[/math] has the same age as a DLO, but it is not homogeneous since if we map {1, 3} to {5, 6}, it would not extend to any automorphism f since there should be an element between [math]\displaystyle{ f(1)=5 }[/math] and [math]\displaystyle{ f(3)=6 }[/math]. The same applies to integers.