On the Distribution of Unweighted Minimum Knapsack Instances with Large SOS Rank

Abstract

We analyze the sum-of-squares rank of unweighted instances of the Minimum Knapsack (MK) problem, i.e., minimization of Σi=1n xi for 0/1 variables under the constraint Σi=1n xi ≥ q, with q ∈ R. Such instances have long served as a testbed for understanding the limitations of lift-and-project methods in Boolean optimization. For example, both the Lov\'asz-Schrijver and Sherali-Adams hierarchies require (maximal) rank n to solve them, already when q=1/2 is constant. The SOS hierarchy requires only sublinear rank O(n) to solve unweighted MK when q=1/2. On the other hand, when q is allowed to vary with~n, the SOS rank of the problem may become linear. Interestingly, this is known to happen both when q is large, and when q is very small (0<q ≤ 2-n). This raises the question of whether we should think of hard instances of unweighted MK as being typical for the SOS hierarchy, or as a consequence of very specific choices of the threshold parameter q. In this paper, we address this question by showing new upper and lower bounds on the SOS rank of unweighted MK in the whole regime of the parameter q. For n-q ≤ O(1), we show that the SOS rank is constant. In contrast, when q ≤ O(1), a linear rank is needed if q is exponentially close to an integer. As our main positive result, we show that linear rank is very rare for q ≤ O(1). This can be expressed in the language of smoothed analysis: after perturbing q by a Gaussian with mean 0 and variance σ2, the expected SOS rank of MK is O(n (n/σ)).