Revisiting the convergence rate of the Lasserre hierarchy for polynomial optimization over the hypercube

Abstract

We revisit the problem of minimizing a given polynomial f on the hypercube [-1,1]n. Lasserre's hierarchy (also known as the moment- or sum-of-squares hierarchy) provides a sequence of lower bounds \f(r)\r ∈ N on the minimum value f*, where r refers to the allowed degrees in the sum-of-squares hierarchy. A natural question is how fast the hierarchy converges as a function of the parameter r. The current state-of-the-art is due to Baldi and Slot [SIAM J. on Applied Algebraic Geometry, 2024] and roughly shows a convergence rate of order 1/r. Here we obtain closely related results via a different approach: the polynomial kernel method. We also discuss limitations of the polynomial kernel method, suggesting a lower bound of order 1/r2 for our approach.