Disjunctive Sum of Squares
Provides a new theoretical framework for polynomial optimization that addresses scalability issues of sum-of-squares methods by keeping semidefinite constraints fixed in size.
Introduced disjunctive sum of squares for certifying polynomial nonnegativity, enabling parallel computation of low-degree algebraic identities. The method yields converging SDP-based hierarchies with fixed-size constraints for polynomial optimization, and was validated on polynomial, copositive, and combinatorial problems.
We introduce the concept of disjunctive sum of squares for certifying nonnegativity of polynomials. Unlike the popular sum of squares approach where nonnegativity is certified by a single algebraic identity, the disjunctive sum of squares approach certifies nonnegativity with multiple algebraic identities which can be found in parallel. Our main result is a disjunctive Positivstellensatz proving that we can keep the degree of each algebraic identity as low as the degree of the polynomial whose nonnegativity is in question. Based on this result, we construct a semidefinite programming based converging hierarchy of lower bounds for the problem of minimizing a polynomial over a compact basic semialgebraic set, where the size of the largest semidefinite constraint is fixed throughout the hierarchy. We further prove a second disjunctive Positivstellensatz which leads to an optimization-free hierarchy for polynomial optimization. We specialize this result to the problem of proving copositivity of matrices. Finally, we describe how the disjunctive sum of squares approach can be combined with a branch-and-bound algorithm and we present numerical experiments on polynomial, copositive, and combinatorial optimization problems.