Entrywise Low-Rank Approximation and Matrix p → q Norms via Global Correlation Rounding

Abstract

Given a matrix A, the goal of the entrywise low-rank approximation problem is to find argmin \|A-B\|p over all rank-k matrices B, where \| · \|p is the entrywise p norm. When p = 2 this well-studied problem is solved by the singular value decomposition, but for p ≠ 2 the problem becomes computationally challenging. For every even p > 2 and every fixed k, we give the first polynomial-time approximation scheme for this problem, improving on the (3 + ) approximation of Ban, Bhattiprolu, Bringmann, Kolev, Lee, and Woodruff, the bi-criteria approximation of Woodruff and Yasuda, and the additive approximation scheme of Anderson, Bakshi, and Hopkins. Prior algorithmic approaches based on sketching and column selection, which yielded a polynomial-time approximation scheme in the p < 2 setting, face concrete barriers when p > 2. Instead, we use the Sherali-Adams hierarchy of convex programs, and in so doing establish a blueprint for how to use convex hierarchies to design polynomial-time approximation schemes for continuous optimization problems. We use the same algorithmic strategy to give a new family of additive approximation algorithms for matrix p → q norms, which are intimately related to small-set expansion and quantum information. In particular, we give the first nontrivial additive approximation algorithms in the regime p < 2 < q.