Finite convergence of sum-of-squares hierarchies for the stability number of a graph

Abstract

We investigate a hierarchy of semidefinite bounds (r)(G) for the stability number α(G) of a graph G, based on its copositive programming formulation and introduced by de Klerk and Pasechnik [ SIAM J. Optim. 12 (2002), pp.875--892], who conjectured convergence to α(G) in r=α(G)-1 steps. Even the weaker conjecture claiming finite convergence is still open. We establish links between this hierarchy and sum-of-squares hierarchies based on the Motzkin-Straus formulation of α(G), which we use to show finite convergence when G is acritical, i.e., when α(G e)=α(G) for all edges e of G. This relies, in particular, on understanding the structure of the minimizers of the Motzkin-Straus formulation and showing that their number is finite precisely when G is acritical. Moreover we show that these results hold in the general setting of the weighted stable set problem for graphs equipped with positive node weights. In addition, as a byproduct we show that deciding whether a standard quadratic program has finitely many minimizers does not admit a polynomial-time algorithm unless P=NP.