A hybrid half-duplex/full-duplex transmission scheme in relay-aided cellular networks
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- 作者:Hongbin Chen ; Feng Zhao
- 关键词:Relay ; aided cellular network ; Full ; duplex ; Half ; duplex ; Energy efficiency ; Spectral efficiency
- 刊名:EURASIP Journal on Wireless Communications and Networking
- 出版年:2017
- 出版时间:December 2017
- 年:2017
- 卷:2017
- 期:1
- 全文大小:964KB
- 刊物主题:Signal,Image and Speech Processing; Communications Engineering, Networks; Information Systems Applications (incl.Internet);
- 出版者:Springer International Publishing
- ISSN:1687-1499
- 卷排序:2017
文摘
In two-hop relay-aided cellular networks, both half-duplex (HD) and full-duplex (FD) transmission have been extensively studied. FD transmission can achieve twice throughput of HD transmission, but suffers from strong self-interference (SI), which may not be perfectly cancelled. In this paper, a hybrid HD/FD transmission scheme in a relay-aided cellular network is proposed, which not only utilizes the throughput advantage of FD but also weakens the negative effect of SI. The key idea is that a relay station (RS) switches between the HD and the FD modes based on the received signal-to-interference-plus-noise ratio (SINR). If the information rate of the base station (BS)-to-RS link is lower than a preset threshold, the RSs adopt the FD mode to guarantee the throughput; otherwise, the RSs adopt the HD mode to reduce the negative effect of SI. As FD transmission consumes more power than HD transmission, we try to maximize the system energy efficiency under the system spectral efficiency constraint and the transmit power constraints. It is difficult to solve this optimization problem directly, so the alternate optimization method is adopted to solve it, i.e., optimizing the transmit power of the BS and the transmit power of RSs in turn. Simulation results show that under perfect SI cancellation, the hybrid scheme can achieve higher energy efficiency than the HD mode by taking the throughput advantage of FD; while under poor SI cancellation, the hybrid scheme can greatly weaken the negative effect of SI and achieve higher energy efficiency than the FD mode.