Lower Bounds for Adaptive Sparse Recovery

Abstract

We give lower bounds for the problem of stable sparse recovery from /adaptive/ linear measurements. In this problem, one would like to estimate a vector x ∈ n from m linear measurements A1x,..., Amx. One may choose each vector Ai based on A1x,..., Ai-1x, and must output x* satisfying |x* - x|p ≤ (1 + ε) k-sparse x' |x - x'|p with probability at least 1-δ>2/3, for some p ∈ \1,2\. For p=2, it was recently shown that this is possible with m = O(1εk (n/k)), while nonadaptively it requires (1εk (n/k)). It is also known that even adaptively, it takes m = (k/ε) for p = 2. For p = 1, there is a non-adaptive upper bound of O(1ε k n). We show: * For p=2, m = ( n). This is tight for k = O(1) and constant ε, and shows that the n dependence is correct. * If the measurement vectors are chosen in R "rounds", then m = (R 1/R n). For constant ε, this matches the previously known upper bound up to an O(1) factor in R. * For p=1, m = (k/(ε · k/ε)). This shows that adaptivity cannot improve more than logarithmic factors, providing the analog of the m = (k/ε) bound for p = 2.