Sum-of-Squares Hierarchies for Binary Polynomial Optimization

We consider the sum-of-squares hierarchy of approximations for the problem of minimizing a polynomial f over the boolean hypercube B-n = {0, 1}(n). This hierarchy provides for each integer r is an element of N a lower bound f(r) on the minimum fmin of f, given by the largest scalar lambda for which the polynomial f-lambda is a sum-of-squares on B-n with degree at most 2r. We analyze the quality of these bounds by estimating the worst-case error f(min) - f((r)) in terms of the least roots of the Krawtchouk polynomials. As a consequence, for fixed t is an element of[0, 1/2], we can show that this worst-case error in the regime r approximate to t center dot n is of the order 1/2-root t(1 - t) as n tends to infinity. Our proof combines classical Fourier analysis on B-n with the polynomial kernel technique and existing results on the extremal roots of Krawtchouk polynomials. This link to roots of orthogonal polynomials relies on a connection between the hierarchy of lower bounds f((r)) and another hierarchy of upper bounds f((r)), for which we are also able to establish the same error analysis. Our analysis extends to the minimization of a polynomial over the q-ary cube (Z/qZ)(n).