An Improved Cutting Plane Method for Convex Optimization, Convex-Concave Games and its Applications

Abstract

Given a separation oracle for a convex set K ⊂ Rn that is contained in a box of radius R, the goal is to either compute a point in K or prove that K does not contain a ball of radius ε. We propose a new cutting plane algorithm that uses an optimal O(n ()) evaluations of the oracle and an additional O(n2) time per evaluation, where = nR/ε. This improves upon Vaidya's O( SO · n () + nω+1 ()) time algorithm [Vaidya, FOCS 1989a] in terms of polynomial dependence on n, where ω < 2.373 is the exponent of matrix multiplication and SO is the time for oracle evaluation. This improves upon Lee-Sidford-Wong's O( SO · n () + n3 O(1) ()) time algorithm [Lee, Sidford and Wong, FOCS 2015] in terms of dependence on . For many important applications in economics, = ((n)) and this leads to a significant difference between () and poly( ()). We also provide evidence that the n2 time per evaluation cannot be improved and thus our running time is optimal. A bottleneck of previous cutting plane methods is to compute leverage scores, a measure of the relative importance of past constraints. Our result is achieved by a novel multi-layered data structure for leverage score maintenance, which is a sophisticated combination of diverse techniques such as random projection, batched low-rank update, inverse maintenance, polynomial interpolation, and fast rectangular matrix multiplication. Interestingly, our method requires a combination of different fast rectangular matrix multiplication algorithms.