Convexifying positive polynomials and sums of squares approximation

Abstract

We show that if a polynomial f∈ R[x1,…,xn] is nonnegative on a closed basic semialgebraic set X=\x∈Rn:g1(x) 0,…,gr (x) 0\, where g1,…,gr∈R[x1,…,xn], then f can be approximated uniformly on compact sets by polynomials of the form σ0+(g1) g1+·s +(gr) gr, where σ0∈ R[x1,…,xn] and ∈R[t] are sums of squares of polynomials. In particular, if X is compact, and h(x):=R2-|x|2 is positive on X, then f=σ0+σ1 h+(g1) g1+·s +(gr) gr for some sums of squares σ0,σ1∈ R[x1,…,xn] and ∈R[t], where |x|2=x12+·s+xn2. We apply a quantitative version of those results to semidefinite optimization methods. Let X be a convex closed semialgebraic subset of Rn and let f be a polynomial which is positive on X. We give necessary and sufficient conditions for the existence of an exponent N∈N such that (1+|x|2)Nf(x) is a convex function on X. We apply this result to searching for lower critical points of polynomials on convex compact semialgebraic sets.