Cross-positive linear maps, positive polynomials and sums of squares

Abstract

A linear map between matrix spaces is called cross-positive if it is positive on orthogonal pairs (U,V) of positive semidefinite matrices in the sense that U,V:=Tr(UV)=0 implies (U),V≥0, and is completely cross-positive if all its ampliations In are cross-positive. (Completely) cross-positive maps arise in the theory of operator semigroups, where they are sometimes called exponentially-positive maps, and are also important in the theory of affine processes on symmetric cones in mathematical finance. To each as above a bihomogeneous form is associated by p(x,y)=yT(xxT)y. Then is cross-positive if and only if p is nonnegative on the variety of pairs of orthogonal vectors \(x,y) xTy=0\. Moreover, is shown to be completely cross-positive if and only if p is a sum of squares modulo the principal ideal (xTy). These observations bring the study of cross-positive maps into the powerful setting of real algebraic geometry. Here this interplay is exploited to prove quantitative bounds on the fraction of cross-positive maps that are completely cross-positive. Detailed results about cross-positive maps mapping between 3× 3 matrices are given. Finally, an algorithm to produce cross-positive maps that are not completely cross-positive is presented.