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Energy‐efficient hybrid beamforming for millimeter‐wave‐based massive multiple‐input multiple‐output system.

Authors :
Biru, Selam
Mishra, Satyasis
Singh, Ram Sewak
Chura, Shanko
Satapathy, Sunita
Source :
International Journal of Communication Systems. 5/25/2024, Vol. 37 Issue 8, p1-27. 27p.
Publication Year :
2024

Abstract

Summary: The advanced wireless communication system requires abridged energy consumption, enhanced data rate, and good signal coverage. The massive MIMO technology for 5G systems has been developed to accommodate several users simultaneously with superior throughput. The claim for high data rate wireless communication services is expanding quickly as time goes. Thus, the key difficulty is that as the number of users grows, the number of phase shifters grows as well, causing the system to consume more power; as a result, the system's energy efficiency decreases. Hybrid beamforming has recently emerged as an attractive technique for millimeter‐wave (mmWave) communication systems. The analog beamformer in the RF domain and digital beamformer in the baseband are coupled through a minimal number of RF chains in hybrid beamforming architecture. Hybrid beamforming utilizes fewer RF (radio frequency) chains than the total number of antennas to have a lower energy consumption design. The hybrid beamforming for a mmWave‐based massive MIMO system through different phase shifter selection mechanisms is proposed to achieve the highest energy efficiency for mmWave communications systems. The fully connected with phase shifter selection, sub‐connected with phase shifter selection (SPSS), and fully connected and sub‐connected with phase shifter selection with halved and doubled switches are considered for this research. The simulation results show the SPSS with halved switch outperforms on energy efficiency. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
10745351
Volume :
37
Issue :
8
Database :
Academic Search Index
Journal :
International Journal of Communication Systems
Publication Type :
Academic Journal
Accession number :
176635692
Full Text :
https://doi.org/10.1002/dac.5743