Subspace Embedding and Linear Regression with Orlicz Norm

Abstract

We consider a generalization of the classic linear regression problem to the case when the loss is an Orlicz norm. An Orlicz norm is parameterized by a non-negative convex function G:R+→R+ with G(0)=0: the Orlicz norm of a vector x∈Rn is defined as \|x\|G=∈f\α>0Σi=1n G(|xi|/α)≤ 1\. We consider the cases where the function G(·) grows subquadratically. Our main result is based on a new oblivious embedding which embeds the column space of a given matrix A∈Rn× d with Orlicz norm into a lower dimensional space with 2 norm. Specifically, we show how to efficiently find an embedding matrix S∈Rm× n,m<n such that ∀ x∈Rd,(1/(d n)) · \|Ax\|G≤ \|SAx\|2≤ O(d2 n) · \|Ax\|G. By applying this subspace embedding technique, we show an approximation algorithm for the regression problem x∈Rd \|Ax-b\|G, up to a O(d2 n) factor. As a further application of our techniques, we show how to also use them to improve on the algorithm for the p low rank matrix approximation problem for 1≤ p<2.