The Change-of-Measure Method, Block Lewis Weights, and Approximating Matrix Block Norms

Abstract

Given a matrix A ∈ Rk × n, a partitioning of [k] into groups S1,…,Sm, an outer norm p, and a collection of inner norms such that either p 1 and p1,…,pm 2 or p1=…=pm=p 1/ n, we prove that there is a sparse weight vector β ∈ Rm such that Σi=1m βi · \|ASix\|pip ≈1 Σi=1m \|ASix\|pip, where the number of nonzero entries of β is at most Op,pi(-2n(1,p/2)( n)2((n/))). When p1…,pm 2, this weight vector arises from an importance sampling procedure based on the block Lewis weights, a recently proposed generalization of Lewis weights. Additionally, we prove that there exist efficient algorithms to find the sparse weight vector β in several important regimes of p and p1,…,pm. Our results imply a O(-1n)-linear system solve iteration complexity for the problem of minimizing sums of Euclidean norms, improving over the previously known O(m(1/)) iteration complexity when m n. Our main technical contribution is a substantial generalization of the change-of-measure method that Bourgain, Lindenstrauss, and Milman used to obtain the analogous result when every group has size 1. Our generalization allows one to analyze change of measures beyond those implied by D. Lewis's original construction, including the measure implied by the block Lewis weights and natural approximations of this measure.

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