On the Theorem of Uniform Recovery of Random Sampling Matrices

Abstract

We consider two theorems from the theory of compressive sensing. Mainly a theorem concerning uniform recovery of random sampling matrices, where the number of samples needed in order to recover an s-sparse signal from linear measurements (with high probability) is known to be m s( s)3 N. We present new and improved constants together with what we consider to be a more explicit proof. A proof that also allows for a slightly larger class of m× N-matrices, by considering what we call low entropy. We also present an improved condition on the so-called restricted isometry constants, δs, ensuring sparse recovery via 1-minimization. We show that δ2s<4/41 is sufficient and that this can be improved further to almost allow for a sufficient condition of the type δ2s<2/3.