Abstract
Buffer-aided (BA) relaying improves the diversity of cooperative networks often at the cost of increasing end-to-end packet delays. This characteristic renders BA relaying unsuitable for delay-sensitive applications. However, the increased diversity makes BA relaying appealing for ultra-reliable communications. Towards enabling ultra-reliable low-latency communication (URLLC), we aim at enhancing BA relaying for supporting delay-sensitive applications. In this paper, reliable full-duplex (FD) network operation is targeted and for this purpose, hybrid relay selection algorithms are formulated, combining BA successive relaying (SuR) and delay- and diversity-aware (DDA) half-duplex (HD) algorithms. In this context, a hybrid FD DDA algorithm is presented, namely LoLa4SOR, switching between SuR and HD operation. Additionally, a low-complexity distributed version is given, namely d-LoLa4SOR, providing a trade-off among channel state information requirements and performance. The theoretical analysis shows that the diversity of LoLa4SOR equals to two times the number of available relays $K$ , i.e., $2K$ , when the buffer size $L$ is greater than or equal to 3. Comparisons with other HD, SuR and hybrid algorithms reveal that LoLa4SOR offers superior outage and throughput performance while, the average delay is reduced due to SuR-based FD operation and the consideration of buffer state information for relay-pair selection. d-LoLa4SOR, as one of the few distributed algorithms in the literature, has a reasonable performance that makes it a more practical approach.
Highlights
The results show that FD operation through LoLa4SOR offers reduced outages and increased throughput, while its delay is significantly reduced compared to HD relaying
The efficient operation of 5G networks depends on cooperative schemes that can support a broad range of applications with diverse requirements
LoLa4SOR, a low-latency successive opportunistic relay selection algorithm was proposed, achieving reduced packet delays, without suffering diversity losses that are inherent in delay-aware buffer-aided relay selection algorithms
Summary
T HE RAPID increase of mobile data traffic and the emerging Internet-of-Things (IoT) applications [2] accelerate the need for developing low-complexity algorithms offering reliable connectivity and low end-toend latency [3]. In case the successive transmission is infeasible, the transmission switches to single link selection, where the time-slot is allocated for the transmission of a packet by the source or a relay, following a similar procedure to [16]. In this way, IRI is avoided and the probability of a complete network outage is significantly reduced
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