Outage-optimized distributed quantizers for multicast beamforming

We consider a slow-fading multicast channel with one T-antenna transmitter and K single-antenna receivers with the goal of minimizing channel outage probability using quantized beamforming. Our focus is on a distributed limited feedback scenario where each receiver can only quantize and send feedback information regarding its own receiving channels. A classical result in point-to-point quantized beamforming is that a necessary and sufficient condition for full diversity is to have ⌈log2 T⌉ bits from the receiver. We first generalize this result to multicast beamforming systems and show that a necessary and sufficient condition to achieve full diversity for all receivers is to have ⌈log2 T⌉ bits from each receiver. Also, for a two-receiver system and with R feedback bits per receiver, we show that the outage performance with quantized beamforming is within O(2-R/32T2)dBs of the performance with full channel state information at the transmitter (CSIT). This constitutes, in the context of multicast channels, the first example of a distributed limited feedback scheme whose performance can provably approach the performance with full CSIT.

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