English

Faster SDP hierarchy solvers for local rounding algorithms

Data Structures and Algorithms 2015-03-20 v2

Abstract

Convex relaxations based on different hierarchies of linear/semi-definite programs have been used recently to devise approximation algorithms for various optimization problems. The approximation guarantee of these algorithms improves with the number of {\em rounds} rr in the hierarchy, though the complexity of solving (or even writing down the solution for) the rr'th level program grows as nΩ(r)n^{\Omega(r)} where nn is the input size. In this work, we observe that many of these algorithms are based on {\em local} rounding procedures that only use a small part of the SDP solution (of size nO(1)2O(r)n^{O(1)} 2^{O(r)} instead of nΩ(r)n^{\Omega(r)}). We give an algorithm to find the requisite portion in time polynomial in its size. The challenge in achieving this is that the required portion of the solution is not fixed a priori but depends on other parts of the solution, sometimes in a complicated iterative manner. Our solver leads to nO(1)2O(r)n^{O(1)} 2^{O(r)} time algorithms to obtain the same guarantees in many cases as the earlier nO(r)n^{O(r)} time algorithms based on rr rounds of the Lasserre hierarchy. In particular, guarantees based on O(logn)O(\log n) rounds can be realized in polynomial time. We develop and describe our algorithm in a fairly general abstract framework. The main technical tool in our work, which might be of independent interest in convex optimization, is an efficient ellipsoid algorithm based separation oracle for convex programs that can output a {\em certificate of infeasibility with restricted support}. This is used in a recursive manner to find a sequence of consistent points in nested convex bodies that "fools" local rounding algorithms.

Keywords

Cite

@article{arxiv.1207.4372,
  title  = {Faster SDP hierarchy solvers for local rounding algorithms},
  author = {Venkatesan Guruswami and Ali Kemal Sinop},
  journal= {arXiv preprint arXiv:1207.4372},
  year   = {2015}
}

Comments

30 pages, 8 figures

R2 v1 2026-06-21T21:37:50.875Z