English

Outage Efficient Strategies for Network MIMO with Partial CSIT

Information Theory 2016-11-17 v1 math.IT

Abstract

We consider a multi-cell MIMO downlink (network MIMO) where BB base-stations (BS) with MM antennas connected to a central station (CS) serve KK single-antenna user terminals (UT). Although many works have shown the potential benefits of network MIMO, the conclusion critically depends on the underlying assumptions such as channel state information at transmitters (CSIT) and backhaul links. In this paper, by focusing on the impact of partial CSIT, we propose an outage-efficient strategy. Namely, with side information of all UT's messages and local CSIT, each BS applies zero-forcing (ZF) beamforming in a distributed manner. For a small number of UTs (KMK\leq M), the ZF beamforming creates KK parallel MISO channels. Based on the statistical knowledge of these parallel channels, the CS performs a robust power allocation that simultaneously minimizes the outage probability of all UTs and achieves a diversity gain of B(MK+1)B(M-K+1) per UT. With a large number of UTs (KMK \geq M), we propose a so-called distributed diversity scheduling (DDS) scheme to select a subset of \Ks\Ks UTs with limited backhaul communication. It is proved that DDS achieves a diversity gain of BK\Ks(M\Ks+1)B\frac{K}{\Ks}(M-\Ks+1), which scales optimally with the number of cooperative BSs BB as well as UTs. Numerical results confirm that even under realistic assumptions such as partial CSIT and limited backhaul communications, network MIMO can offer high data rates with a sufficient reliability to individual UTs.

Keywords

Cite

@article{arxiv.1001.2421,
  title  = {Outage Efficient Strategies for Network MIMO with Partial CSIT},
  author = {Mari Kobayashi and Sheng Yang and Merouane Debbah and Jean-Claude Belfiore},
  journal= {arXiv preprint arXiv:1001.2421},
  year   = {2016}
}

Comments

26 pages, 8 figures, submitted to IEEE Trans. on Signal Processing

R2 v1 2026-06-21T14:34:46.928Z