An Exact Jacobian SDP Relaxation for Polynomial Optimization

Abstract

Given polynomials f(x), gi(x), hj(x), we study how to minimize f on the semialgebraic set S = x ∈ Rn: h1(x)=...=hm1(x) =0, g1(x) >= 0, ..., gm2(x) >= 0. Let fmin be the minimum of f on S. Suppose S is nonsingular and fmin is achievable on S,which is true generically. The paper proposes a new semidefinite programming (SDP) relaxation for this problem. First we construct a set of new polynomials 1(x), …, r(x), by using the Jacobian of f,hi,gj, such that the above problem is unchanged by adding new equations j(x)=0. Then we prove that for all N big enough, the standard N-th order Lasserre's SDP relaxation is exact for solving this equivalent problem, that is, it returns a lower bound that is equal to fmin. Some variations and examples are also shown.