The Jacobi MIMO Channel
Abstract
This paper presents a new fading model for MIMO channels, the Jacobi fading model. It asserts that , the transfer matrix which couples the inputs into outputs, is a sub-matrix of an random (Haar-distributed) unitary matrix. The (squared) singular values of follow the law of the classical Jacobi ensemble of random matrices; hence the name of the channel. One motivation to define such a channel comes from multimode/multicore optical fiber communication. It turns out that this model can be qualitatively different than the Rayleigh model, leading to interesting practical and theoretical results. This work first evaluates the ergodic capacity of the channel. Then, it considers the non-ergodic case, where it analyzes the outage probability and the diversity-multiplexing tradeoff. In the case where it is shown that at least degrees of freedom are guaranteed not to fade for any channel realization, enabling a zero outage probability or infinite diversity order at the corresponding rates. A simple scheme utilizing (a possibly outdated) channel state feedback is provided, attaining the no-outage guarantee. Finally, noting that as increases, the Jacobi model approaches the Rayleigh model, the paper discusses the applicability of the model in other communication scenaria.
Cite
@article{arxiv.1202.0305,
title = {The Jacobi MIMO Channel},
author = {Ronen Dar and Meir Feder and Mark Shtaif},
journal= {arXiv preprint arXiv:1202.0305},
year = {2012}
}
Comments
27 pages, 7 figures