Subexponential LPs Approximate Max-Cut

Abstract

We show that for every > 0, the degree-n Sherali-Adams linear program (with (O(n)) variables and constraints) approximates the maximum cut problem within a factor of (12+'), for some '() > 0. Our result provides a surprising converse to known lower bounds against all linear programming relaxations of Max-Cut, and hence resolves the extension complexity of approximate Max-Cut for approximation factors close to 12 (up to the function '()). Previously, only semidefinite programs and spectral methods were known to yield approximation factors better than 12 for Max-Cut in time 2o(n). We also show that constant-degree Sherali-Adams linear programs (with poly(n) variables and constraints) can solve Max-Cut with approximation factor close to 1 on graphs of small threshold rank: this is the first connection of which we are aware between threshold rank and linear programming-based algorithms. Our results separate the power of Sherali-Adams versus Lov\'asz-Schrijver hierarchies for approximating Max-Cut, since it is known that (12+) approximation of Max Cut requires (n) rounds in the Lov\'asz-Schrijver hierarchy. We also provide a subexponential time approximation for Khot's Unique Games problem: we show that for every > 0 the degree-(n q) Sherali-Adams linear program distinguishes instances of Unique Games of value ≥ 1-' from instances of value ≤ ', for some '( ) >0, where q is the alphabet size. Such guarantees are qualitatively similar to those of previous subexponential-time algorithms for Unique Games but our algorithm does not rely on semidefinite programming or subspace enumeration techniques.