When are dynamic relaying strategies necessary in half-duplex wireless networks?

TL;DR

This paper investigates when dynamic relaying strategies are necessary in half-duplex wireless networks to optimize the diversity-multiplexing tradeoff, identifying regimes where static or dynamic strategies suffice and proposing a generalized dynamic QMF scheme.

Contribution

It characterizes regimes requiring dynamic relaying in single relay channels and introduces a dynamic QMF strategy for more complex networks to achieve optimal DMT.

Findings

Static schedules suffice in some regimes, while dynamic schedules are necessary in others.

A new upper bound on the DMT is developed considering receiver-only CSI.

The dynamic QMF strategy achieves optimal DMT in multi-relay parallel channels.

Abstract

We study a simple question: when are dynamic relaying strategies essential in optimizing the diversity-multiplexing tradeoff (DMT) in half-duplex wireless relay networks? This is motivated by apparently two contrasting results even for a simple 3 node network, with a single half-duplex relay. When all channels are assumed to be i.i.d. fading, a static schedule where the relay listens half the time and transmits half the time combined with quantize-map-forward (QMF) relaying is known to achieve the full-duplex performance. However, when there is no direct link between source and destination, a dynamic-decode-forward (DDF) strategy is needed to achieve the optimal tradeoff. In this case, a static schedule is strictly suboptimal and the optimal tradeoff is significantly worse than the full-duplex performance. In this paper we study the general case when the direct link is neither as strong as the other links nor fully non-existent, and identify regimes where dynamic schedules are necessary and those where static schedules are enough. We identify 4 qualitatively different regimes for the single relay channel where the tradeoff between diversity and multiplexing is significantly different. We show that in all these regimes one of the above two strategies is sufficient to achieve the optimal tradeoff by developing a new upper bound on the best achievable tradeoff under channel state information available only at the receivers. A natural next question is whether these two strategies are sufficient to achieve the DMT of more general half-duplex wireless networks. We propose a generalization of the two existing schemes through a dynamic QMF (DQMF) strategy, where the relay listens for a fraction of time depending on received CSI but not long enough to be able to decode. We show that such a DQMF strategy is needed to achieve the optimal DMT in a parallel channel with two relays.