Improved Algorithms for Adaptive Compressed Sensing

Abstract

In the problem of adaptive compressed sensing, one wants to estimate an approximately k-sparse vector x∈Rn from m linear measurements A1 x, A2 x,…, Am x, where Ai can be chosen based on the outcomes A1 x,…, Ai-1 x of previous measurements. The goal is to output a vector x for which \|x-x\|p C · k-sparse x' \|x-x'\|q\, with probability at least 2/3, where C > 0 is an approximation factor. Indyk, Price and Woodruff (FOCS'11) gave an algorithm for p=q=2 for C = 1+ε with ((k/ε) (n/k)) measurements and (*(k) (n)) rounds of adaptivity. We first improve their bounds, obtaining a scheme with (k · (n/k) +(k/ε) · (1/ε)) measurements and (*(k) (n)) rounds, as well as a scheme with ((k/ε) · (n (n/k))) measurements and an optimal ( (n)) rounds. We then provide novel adaptive compressed sensing schemes with improved bounds for (p,p) for every 0 < p < 2. We show that the improvement from O(k (n/k)) measurements to O(k (n/k)) measurements in the adaptive setting can persist with a better ε-dependence for other values of p and q. For example, when (p,q) = (1,1), we obtain O(kε · n 3 (1ε)) measurements.