Abstract
Full-duplex (FD) transmissions have emerged as a spectrally efficient technology with the evolution of enhanced self-interference (SI) suppression techniques. However, the FD transmission mode (TM) may not consistently outperform the half-duplex (HD) TM due to the residual SI. In contrast, an adaptive FD/HD transmission scheme utilizes the advantages of both FD and HD TM. This paper proposes an adaptive FD/HD transmission scheme for a cooperative device-to-device (C-D2D) communications system wherein cellular uplink data is relayed through a D2D transmitter (DT). Additionally, a joint DT and TM selection algorithm is introduced to identify the best relay and favorable TM for the multiuser C-D2D system. Further, a probabilistic mathematical framework is developed to evaluate the proposed adaptive FD/HD transmission scheme. The analytical expressions of D2D and cellular outage probability for each TM (FD/HD) have been derived. Results show that FD TM performs better than HD TM when a maximum of two D2D users mapped to a cellular user. However, a trade-off between FD and HD TM is observed for a large number of D2D users. Specifically, when the cellular outage constraint is low, HD TM performs better than FD TM, whereas FD TM outperforms HD TM for high cellular outage constraint.
Highlights
The ever-increasing demand for wireless services such as high definition video on demand, cloud-based gaming, and virtual reality have considerably increased the traffic between the base station (BS) and the back-haul networks
Rearranging (31), DTi is equidistant2 from BS, and the distance is set to 500m, whereas the distance between cellular user (CU)-BS and a DTi−DRi is set to
This paper proposed an orthogonal frequency division multiple access (OFDMA)-based adaptive FD/HD CD2D communications system with the best D2D user selection
Summary
The ever-increasing demand for wireless services such as high definition video on demand, cloud-based gaming, and virtual reality have considerably increased the traffic between the base station (BS) and the back-haul networks To accommodate this colossal capacity demand, researchers in industry and academia are augmenting the development of multiple communication technologies such as device-to-device (D2D) communications, full-duplex (FD) radios, and multicarrier adaptive systems. These superior technologies provide a higher data rate, wider coverage area, ultra-reliability, and low latency for the fifth-generation (5G) and beyond cellular networks [1].
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