Impact of CSI on Distributed Space-Time Coding in Wireless Relay Networks

TL;DR

This paper investigates how channel state information impacts the effectiveness of distributed space-time coding in two-hop relay networks, proposing adaptive power allocation strategies for different CSIT scenarios to enhance diversity and power gains.

Contribution

It introduces a unified DSTC approach with optimized power allocation under various CSIT conditions, including perfect, partial, and statistical, with closed-form solutions for specific cases.

Findings

Power allocation is crucial for DSTC performance.

Proposed algorithms adapt to different CSIT levels.

Closed-form solutions simplify implementation in certain regimes.

Abstract

We consider a two-hop wireless network where a transmitter communicates with a receiver via $M$ relays with an amplify-and-forward (AF) protocol. Recent works have shown that sophisticated linear processing such as beamforming and distributed space-time coding (DSTC) at relays enables to improve the AF performance. However, the relative utility of these strategies depend on the available channel state information at transmitter (CSIT), which in turn depends on system parameters such as the speed of the underlying fading channel and that of training and feedback procedures. Moreover, it is of practical interest to have a single transmit scheme that handles different CSIT scenarios. This motivates us to consider a unified approach based on DSTC that potentially provides diversity gain with statistical CSIT and exploits some additional side information if available. Under individual power constraints at the relays, we optimize the amplifier power allocation such that pairwise error probability conditioned on the available CSIT is minimized. Under perfect CSIT we propose an on-off gradient algorithm that efficiently finds a set of relays to switch on. Under partial and statistical CSIT, we propose a simple waterfilling algorithm that yields a non-trivial solution between maximum power allocation and a generalized STC that equalizes the averaged amplified noise for all relays. Moreover, we derive closed-form solutions for M=2 and in certain asymptotic regimes that enable an easy interpretation of the proposed algorithms. It is found that an appropriate amplifier power allocation is mandatory for DSTC to offer sufficient diversity and power gain in a general network topology.