Iterative Refinement for p-norm Regression

Abstract

We give improved algorithms for the p-regression problem, x \|x\|p such that A x=b, for all p ∈ (1,2) (2,∞). Our algorithms obtain a high accuracy solution in Op(m|p-2|2p + |p-2|) Op(m13) iterations, where each iteration requires solving an m × m linear system, m being the dimension of the ambient space. By maintaining an approximate inverse of the linear systems that we solve in each iteration, we give algorithms for solving p-regression to 1 / poly(n) accuracy that run in time Op(m\ω, 7/3\), where ω is the matrix multiplication constant. For the current best value of ω > 2.37, we can thus solve p regression as fast as 2 regression, for all constant p bounded away from 1. Our algorithms can be combined with fast graph Laplacian linear equation solvers to give minimum p-norm flow / voltage solutions to 1 / poly(n) accuracy on an undirected graph with m edges in Op(m1 + |p-2|2p + |p-2|) Op(m43) time. For sparse graphs and for matrices with similar dimensions, our iteration counts and running times improve on the p-norm regression algorithm by [Bubeck-Cohen-Lee-Li STOC`18] and general-purpose convex optimization algorithms. At the core of our algorithms is an iterative refinement scheme for p-norms, using the smoothed p-norms introduced in the work of Bubeck et al. Given an initial solution, we construct a problem that seeks to minimize a quadratically-smoothed p norm over a subspace, such that a crude solution to this problem allows us to improve the initial solution by a constant factor, leading to algorithms with fast convergence.