Sublinear Time, Approximate Model-based Sparse Recovery For All

Abstract

We describe a probabilistic, sublinear runtime, measurement-optimal system for model-based sparse recovery problems through dimensionality reducing, dense random matrices. Specifically, we obtain a linear sketch u∈ M of a vector ∈ N in high-dimensions through a matrix ∈ M× N (M<N). We assume this vector can be well approximated by K non-zero coefficients (i.e., it is K-sparse). In addition, the nonzero coefficients of can obey additional structure constraints such as matroid, totally unimodular, or knapsack constraints, which dub as model-based sparsity. We construct the dense measurement matrix using a probabilistic method so that it satisfies the so-called restricted isometry property in the 2-norm. While recovery using such matrices is measurement-optimal as they require the smallest sketch sizes = O( (/)), the existing algorithms require superlinear runtime (N(N/K)) with the exception of Porat and Strauss, which requires O(β5ε-3K(N/K)1/β), ~β ∈ Z+, but provides an 1/1 approximation guarantee. In contrast, our approach features O( O(1) , ~ 2 2 (/) ) complexity where L ∈ Z+ is a design parameter, independent of , requires a smaller sketch size, can accommodate model sparsity, and provides a stronger 2/1 guarantee. Our system applies to "for all" sparse signals, is robust against bounded perturbations in u as well as perturbations on itself.