In mathematical logic, and more specifically in model theory, an infinite structure that is totally ordered by is called an o-minimal structure if and only if every definable subset (with parameters taken from ) is a finite union of intervals and points.
O-minimality can be regarded as a weak form of quantifier elimination. A structure is o-minimal if and only if every formula with one free variable and parameters in is equivalent to a quantifier-free formula involving only the ordering, also with parameters in . This is analogous to the minimal structures, which are exactly the analogous property down to equality.
A theory is an o-minimal theory if every model of is o-minimal. It is known that the complete theory of an o-minimal structure is an o-minimal theory. This result is remarkable because, in contrast, the complete theory of a minimal structure need not be a strongly minimal theory, that is, there may be an elementarily equivalent structure that is not minimal.
O-minimal structures can be defined without recourse to model theory. Here we define a structure on a nonempty set in a set-theoretic manner, as a sequence such that
For a subset of , we consider the smallest structure containing such that every finite subset of is contained in . A subset of is called -definable if it is contained in ; in that case, is called a set of parameters for . A subset is called definable if it is -definable for some .
If has a dense linear order without endpoints on it, say , then a structure on is called o-minimal (with respect to ) if it satisfies the extra axioms
<ol start="6"> <li>the set < (={(x,y) â M<sup>2</sup> : x < y}) is in <li>the definable subsets of are precisely the finite unions of intervals and points. </ol>
The "o" stands for "order", since any o-minimal structure requires an ordering on the underlying set.
O-minimal structures originated in model theory and so have a simplerâÂÂbut equivalentâÂÂdefinition using the language of model theory. Namely, if is a language including a binary relation , and is an -structure where is interpreted to satisfy the axioms of a dense linear order, then is called an o-minimal structure if for any definable set there are finitely many open intervals in and a finite set such that
Examples of o-minimal theories are:
In the case of RCF, the definable sets are the semialgebraic sets. Thus the study of o-minimal structures and theories generalises real algebraic geometry. A major line of current research is based on discovering expansions of the real ordered field that are o-minimal. Despite the generality of application, one can show a great deal about the geometry of set definable in o-minimal structures. There is a cell decomposition theorem, Whitney and Verdier stratification theorems and a good notion of dimension and Euler characteristic.
Moreover, continuously differentiable definable functions in a o-minimal structure satisfy a generalization of à Âojasiewicz inequality, a property that has been used to guarantee the convergence of some non-smooth optimization methods, such as the stochastic subgradient method (under some mild assumptions).