Better bounds on finite-order Grothendieck constants

Abstract

Grothendieck constants KG(d) bound the advantage of d-dimensional strategies over 1-dimensional ones in a specific optimisation task. They have applications ranging from approximation algorithms to quantum nonlocality. However, apart from d=2, their values are unknown. Here, we exploit a recent Frank-Wolfe approach to provide good candidates for lower bounding some of these constants. The complete proof relies on solving difficult binary quadratic optimisation problems. For d∈\3,4,5\, we construct specific rectangular instances that we can solve to certify better bounds than those previously known; by monotonicity, our lower bounds improve on the state of the art for d≤slant9. For d∈\4,7,8\, we exploit elegant structures to build highly symmetric instances achieving even greater bounds; however, we can only solve them heuristically. We also recall the standard relation with violations of Bell inequalities and elaborate on it to interpret generalised Grothendieck constants KG(d2) as the advantage of complex d-dimensional quantum mechanics over real qubit quantum mechanics. Motivated by this connection, we also improve the bounds on KG(d2).