In mathematics, a Ramsey cardinal is a certain kind of large cardinal number introduced by and named after Frank P. Ramsey, whose theorem, called Ramsey's theorem establishes that ÃÂ enjoys a certain property that Ramsey cardinals generalize to the uncountable case.
Let [ú]<sup><ÃÂ</sup> denote the set of all finite subsets of ú. A cardinal number ú is called Ramsey if, for every function
there is a set A of cardinality ú that is homogeneous for f. That is, for every n, the function f is constant on the subsets of cardinality n from A. A cardinal ú is called ineffably Ramsey if A can be chosen to be a stationary subset of ú. A cardinal ú is called virtually Ramsey if for every function
there is C, a closed and unbounded subset of ú, so that for every û in C of uncountable cofinality, there is an unbounded subset of û that is homogenous for f; slightly weaker is the notion of almost Ramsey where homogenous sets for f are required of order type û, for every û < ú.
The existence of any of these kinds of Ramsey cardinal is sufficient to prove the existence of 0<sup>#</sup>, or indeed that every set with rank less than ú has a sharp. This in turn implies the falsity of the Axiom of Constructibility of Kurt Gödel.
Every measurable cardinal is a Ramsey cardinal, and every Ramsey cardinal is a Rowbottom cardinal.
A property intermediate in strength between Ramseyness and measurability is existence of a ú-complete normal non-principal ideal I on ú such that for every and for every function
there is a set B â A not in I that is homogeneous for f. This is strictly stronger than ú being ineffably Ramsey.
A regular cardinal ú is Ramsey if and only if for any set A â ú, there is a transitive set M ⨠ZFC<sup>âÂÂ</sup> (i.e. ZFC without the axiom of powerset) of size ú with A â M, and a nonprincipal ultrafilter U on the Boolean algebra P(ú) â© M such that: