Embedding the Heisenberg group into a bounded dimensional Euclidean space with optimal distortion

Abstract

Let H := pmatrix 1 & R & R \\ 0 & 1 & R \\ 0 & 0 & 1 pmatrix denote the Heisenberg group with the usual Carnot-Carath\'eodory metric d. It is known (since the work of Pansu and Semmes) that the metric space (H,d) cannot be embedded in a bilipchitz fashion into a Hilbert space; however, from a general theorem of Assouad, for any 0 < < 1, the snowflaked metric space (H,d1-) embeds into an infinite-dimensional Hilbert space with distortion O( -1/2 ). This distortion bound was shown by Austin, Naor, and Tessera to be sharp for the Heisenberg group H. Assouad's argument allows 2 to be replaced by RD() for some dimension D() dependent on . Naor and Neiman showed that D could be taken independent of , at the cost of worsening the bound on the distortion to O( -1+cD ), where cD 0 as D ∞. In this paper we show that one can in fact retain the optimal distortion bound O( -1/2 ) and still embed into a bounded dimensional space RD, answering a question of Naor and Neiman. As a corollary, the discrete ball of radius R ≥ 2 in := pmatrix 1 & Z & Z \\ 0 & 1 & Z \\ 0 & 0 & 1 pmatrix can be embedded into a bounded-dimensional space RD with the optimal distortion bound of O(1/2 R). The construction is iterative, and is inspired by the Nash-Moser iteration scheme as used in the isometric embedding problem; this scheme is needed in order to counteract a certain ``loss of derivatives'' problem in the iteration.