Degree Bounds for Positivstellensätze of general semialgebraic sets

Abstract

Let p denote the minimum of a polynomial p over a (general) compact semialgebraic set S ⊂eq Rn. A standard way to approximate p is via hierarchies built from Positivstellensätze, which certify nonnegativity of polynomials on S using sums of squares or other classes of globally nonnegative polynomials. As the degree of the certificate grows, the values generated by these hierarchies converge asymptotically to p. A natural question is, then, to determine explicit bounds on the certificate's degree needed to obtain a prescribed -approximation to p, or equivalently certify the positivity of f:=p - p + on S. We improve the current best degree bounds for Putinar's and Schmüdgen's SOS-Positivstellensatz over S. Also, we obtain degree bounds for Krivine--Stengle's and the recently introduced extended-Handelman's R+-Positivstellensätze over S; providing the first explicit degree bounds for linear optimization-based hierarchies over general compact semialgebraic sets. Our approach is based on a lift-and-project construction in which we add new variables to construct an algebraic representation of the distance to the set S using Łojasiewicz's inequality. This lets us lift the problem of certifying the positivity of f on the (complex) set S to the problem of certifying the positivity of a related polynomial F on a higher-dimensional hypercube. By projecting out the added variables, non-negativity certificates for F on the hypercube become non-negativity certificates for f on S. Our approach offers a unified methodology to obtain degree bounds for several Positivstellensatz-based hierarchies over general compact sets, narrowing the gap between results for the hypercube (or other simple sets) and more general semialgebraic sets.