Realizing High Power Full Duplex in Millimeter Wave System: Design, Prototype and Results

Realizing High Power Full Duplex in Millimeter Wave System: Design, Prototype and Results

Full duplex (FD) communication is considered as a promising technology in the development of 5G-advanced and 6G systems as it theoretically doubles the capability of channel. However, this improvement relying on a simultaneously bidirectional manner of communication induces intrinsic self-interferen...

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Bibliographic Details
Published in:IEEE journal on selected areas in communications Vol. 41; no. 9; p. 1
Main Authors: Yu, Bin, Qian, Chen, Lee, Juho, Shao, Shihai, Shen, Ying, Pan, Wensheng, Lin, Peng, Zhang, Zhiya, Kim, Sundo, Hu, Su, Lee, Kwonjong, Jung, Jungsoo, Choi, Sunghyun, Sun, Chengjun
Format: Journal Article
Language:English
Published: New York IEEE 01-09-2023
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
5G mobile communication
Antennas
Backhaul networks
Beamforming
Field tests
Floors
Full duplex
Integrated access and Backhaul
Interference
Interference cancellation
Milimeter Wave
Millimeter waves
Prototype
Prototypes
Radio frequency
Self-interference Cancellation
Transceivers
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Summary:Full duplex (FD) communication is considered as a promising technology in the development of 5G-advanced and 6G systems as it theoretically doubles the capability of channel. However, this improvement relying on a simultaneously bidirectional manner of communication induces intrinsic self-interference (SI) demanding to be fully cancelled, which is generally intractable. This challenge is minimized in the scenario of integrated access and backhaul (IAB) networks operated in millimeter wave (mmW) band, as its transceivers are stationary and the complexity of SI is greatly reduced by beamforming technique. As a matter of fact, FD can be a pioneering technique to unlock the full potential mmW-based IAB network by releasing its suffering of the half-duplex inefficiency. This article presents the design principle and validation of a practical SI cancellation (SIC) technique in the case of high transmission power class in mmW-based IAB networks. The proposed technique sequentially eliminates SI from the spatial, RF, and digital domains that reduces the SI down to the noise floor. To validate the technique, a prototype system is developed in accordance with 5G IAB specifications and field tests are conducted. Results suggest that the designed mmW SIC transceiver significantly reduces residual-interference to noise ratio (R-INR) to 2.1 dB or less. Additionally, a system-level simulation is conducted in line with 5G IAB evaluation methodology, which explores the potential performance gain of the proposed technique in presence of cross-link interference (CLI). Results indicate that the method could yield a cell throughput gain of about 84%, compared to the current time division duplex deployment.
ISSN:0733-8716
1558-0008
DOI:10.1109/JSAC.2023.3287609