Phase Transition in the One-bit Johnson-Lindenstrauss Lemma

Abstract

The Johnson-Lindenstrauss Lemma (J-L Lemma) is a cornerstone of dimension reduction techniques. We study it in the one-bit context, namely we consider the unit sphere S N-1, with normalized geodesic metric, and map a finite set X ⊂ SN-1 into the Hamming cube Hm = \0,1\m, with normalized Hamming metric. We find that for 0< δ <1, and m> n2δ2 there is a δ-RIP from X into Hm. This is surprising as the value of m is virtually identical to best known bound linear J-L Lemma. In both the linear and one-bit case, the maps are randomly constructed. We show that the probability of Bm being a δ-RIP satisfies a phase transition. It passes from probability of nearly zero to nearly one with a very small change in m. Our proof relies on delicate properties of Bernoulli random variables.