English

Convex separation from convex optimization for large-scale problems

Quantum Physics 2017-01-06 v2 Optimization and Control

Abstract

We present a scheme, based on Gilbert's algorithm for quadratic minimization [SIAM J. Contrl., vol. 4, pp. 61-80, 1966], to prove separation between a point and an arbitrary convex set SRnS\subset\mathbb{R}^{n} via calls to an oracle able to perform linear optimizations over SS. Compared to other methods, our scheme has almost negligible memory requirements and the number of calls to the optimization oracle does not depend on the dimensionality nn of the underlying space. We study the speed of convergence of the scheme under different promises on the shape of the set SS and/or the location of the point, validating the accuracy of our theoretical bounds with numerical examples. Finally, we present some applications of the scheme in quantum information theory. There we find that our algorithm out-performs existing linear programming methods for certain large scale problems, allowing us to certify nonlocality in bipartite scenarios with upto 4242 measurement settings. We apply the algorithm to upper bound the visibility of two-qubit Werner states, hence improving known lower bounds on Grothendieck's constant KG(3)K_G(3). Similarly, we compute new upper bounds on the visibility of GHZ states and on the steerability limit of Werner states for a fixed number of measurement settings.

Keywords

Cite

@article{arxiv.1609.05011,
  title  = {Convex separation from convex optimization for large-scale problems},
  author = {Stephen Brierley and Miguel Navascues and Tamas Vertesi},
  journal= {arXiv preprint arXiv:1609.05011},
  year   = {2017}
}

Comments

Added reference to the related paper arXiv:1609.06269

R2 v1 2026-06-22T15:51:50.539Z