On non-approximability for quadratic programs

This paper studies the computational complexity of the following type of quadratic programs: given an arbitrary matrix whose diagonal elements are zero, find x is an element of {- 1, 1}(n) that maximizes x(T) Mx. This problem recently attracted attention due to its application in various clustering settings, as well as an intriguing connection to the famous Grothendieck inequality. It is approximable to within a factor of O(log n), and known to be NP-hard to approximate within any factor better than 13/11 - epsilon for all epsilon > 0. We show that it is quasi-NP-hard to approximate to a factor better than O (log(gamma) n) for some gamma > 0. The integrality gap of the natural semidefinite relaxation for this problem is known as the Grothendieck constant of the complete graph, and known to be Theta(log n). The proof of this fact was nonconstructive, and did not yield an explicit problem instance where this integrality gap is achieved. Our techniques yield an explicit instance for which the integrality gap is Omega(log n/log log n), essentially answering one of the open problems of Alon et al. [AMMN].