TY - GEN
T1 - Millimeter Wave Full-Duplex Networks
T2 - 2023 Biennial Symposium on Communications, BSC 2023
AU - Liu, Shengbo
AU - Wu, Wen
AU - Fu, Liqun
AU - Qu, Kaige
AU - Ye, Qiang
AU - Zhuang, Weihua
AU - Shen, Sherman
N1 - Publisher Copyright:
© 2023 IEEE.
PY - 2023
Y1 - 2023
N2 - Full-duplex (FD) technique can remarkably boost the network capacity in the millimeter wave (mmWave) bands by enabling simultaneous transmission and reception. However, due to directional transmission and large bandwidth, the throughput and fairness performance of a mm Wave FD network are affected by deafness and directional hidden-node (HN) problems and severe residual self-interference (RSI). To address these challenges, this paper proposes a directional FD medium access control protocol, named DFDMAC to support typical directional FD transmission modes by exploiting FD to transmit control frames to reduce signaling overhead. Furthermore, a novel busy-tone mechanism is designed to avoid deafness and directional HN problems and improve fairness of channel access. To reduce the impact of RSI on link throughput, we formulate a throughput maximization problem for different FD transmission modes and propose a power control algorithm to obtain the optimal transmit power. Simulation results show that the proposed DFDMAC can improve the network throughput and fairness by over 60% and 32%, respectively, compared with the existing MAC protocol in IEEE 802.11ay. Moreover, the proposed power control algorithm can effectively enhance the network throughput.
AB - Full-duplex (FD) technique can remarkably boost the network capacity in the millimeter wave (mmWave) bands by enabling simultaneous transmission and reception. However, due to directional transmission and large bandwidth, the throughput and fairness performance of a mm Wave FD network are affected by deafness and directional hidden-node (HN) problems and severe residual self-interference (RSI). To address these challenges, this paper proposes a directional FD medium access control protocol, named DFDMAC to support typical directional FD transmission modes by exploiting FD to transmit control frames to reduce signaling overhead. Furthermore, a novel busy-tone mechanism is designed to avoid deafness and directional HN problems and improve fairness of channel access. To reduce the impact of RSI on link throughput, we formulate a throughput maximization problem for different FD transmission modes and propose a power control algorithm to obtain the optimal transmit power. Simulation results show that the proposed DFDMAC can improve the network throughput and fairness by over 60% and 32%, respectively, compared with the existing MAC protocol in IEEE 802.11ay. Moreover, the proposed power control algorithm can effectively enhance the network throughput.
UR - https://www.scopus.com/pages/publications/85168774803
U2 - 10.1109/BSC57238.2023.10201813
DO - 10.1109/BSC57238.2023.10201813
M3 - 会议稿件
AN - SCOPUS:85168774803
T3 - 2023 Biennial Symposium on Communications, BSC 2023
SP - 112
EP - 118
BT - 2023 Biennial Symposium on Communications, BSC 2023
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 4 July 2023 through 7 July 2023
ER -