Sum-of-squares chordal decomposition of polynomial matrix inequalities

Abstract

We prove decomposition theorems for sparse positive (semi)definite polynomial matrices that can be viewed as sparsity-exploiting versions of the Hilbert--Artin, Reznick, Putinar, and Putinar--Vasilescu Positivstellens\"atze. First, we establish that a polynomial matrix P(x) with chordal sparsity is positive semidefinite for all x∈ Rn if and only if there exists a sum-of-squares (SOS) polynomial σ(x) such that σ P is a sum of sparse SOS matrices. Second, we show that setting σ(x)=(x12 + ·s + xn2) for some integer suffices if P is homogeneous and positive definite globally. Third, we prove that if P is positive definite on a compact semialgebraic set K=\x:g1(x)≥ 0,…,gm(x)≥ 0\ satisfying the Archimedean condition, then P(x) = S0(x) + g1(x)S1(x) + ·s + gm(x)Sm(x) for matrices Si(x) that are sums of sparse SOS matrices. Finally, if K is not compact or does not satisfy the Archimedean condition, we obtain a similar decomposition for (x12 + … + xn2) P(x) with some integer ≥ 0 when P and g1,…,gm are homogeneous of even degree. Using these results, we find sparse SOS representation theorems for polynomials that are quadratic and correlatively sparse in a subset of variables, and we construct new convergent hierarchies of sparsity-exploiting SOS reformulations for convex optimization problems with large and sparse polynomial matrix inequalities. Numerical examples demonstrate that these hierarchies can have a significantly lower computational complexity than traditional ones.