In mathematics, KR-theory is a variant of topological K-theory defined for spaces with an involution. It was introduced by , motivated by applications to the AtiyahâÂÂSinger index theorem for real elliptic operators.
A real space is a defined to be a topological space with an involution. A real vector bundle over a real space X is defined to be a complex vector bundle E over X that is also a real space, such that the natural maps from E to X and from ×E to E commute with the involution, where the involution acts as complex conjugation on . (This differs from the notion of a complex vector bundle in the category of Z/2Z spaces, where the involution acts trivially on .)
The group KR(X) is the Grothendieck group of finite-dimensional real vector bundles over the real space X.
Similarly to Bott periodicity, the periodicity theorem for KR states that KR<sup>p,q</sup> = KR<sup>p+1,q+1</sup>, where KR<sup>p,q</sup> is suspension with respect to R<sup>p,q</sup> = R<sup>q</sup> + iR<sup>p</sup> (with a switch in the order of p and q), given by
and B<sup>p,q</sup>, S<sup>p,q</sup> are the unit ball and sphere in R<sup>p,q</sup>.