Lossless Linear Analog Compression

Abstract

We establish the fundamental limits of lossless linear analog compression by considering the recovery of random vectors x∈ Rm from the noiseless linear measurements y=Ax with measurement matrix A∈ Rn× m. Specifically, for a random vector x∈ Rm of arbitrary distribution we show that x can be recovered with zero error probability from n>∈fdimMB(U) linear measurements, where dimMB(·) denotes the lower modified Minkowski dimension and the infimum is over all sets U⊂eq Rm with P[x∈ U]=1. This achievability statement holds for Lebesgue almost all measurement matrices A. We then show that s-rectifiable random vectors---a stochastic generalization of s-sparse vectors---can be recovered with zero error probability from n>s linear measurements. From classical compressed sensing theory we would expect n≥ s to be necessary for successful recovery of x. Surprisingly, certain classes of s-rectifiable random vectors can be recovered from fewer than s measurements. Imposing an additional regularity condition on the distribution of s-rectifiable random vectors x, we do get the expected converse result of s measurements being necessary. The resulting class of random vectors appears to be new and will be referred to as s-analytic random vectors.