Power allocation algorithms for massive MIMO systems with multi-antenna users

Modern 5G wireless cellular networks use massive multiple-input multiple-output (MIMO) technology. This concept entails using an antenna array at a base station to concurrently service many mobile devices that have several antennas on their side. In this field, a significant role is played by the pr...

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Bibliographic Details
Published in:Wireless networks 2023-11, Vol.29 (8), p.3747-3768
Main Authors: Bobrov, Evgeny, Chinyaev, Boris, Kuznetsov, Viktor, Minenkov, Dmitrii, Yudakov, Daniil
Format: Article
Language:English
Subjects:
Algorithms
Antenna arrays
Antennas
Beamforming
Cellular communication
Communications Engineering
Computer Communication Networks
Computing time
Constraint modelling
Efficiency
Electrical Engineering
Engineering
IT in Business
MIMO communication
Networks
Optimization
Power management
Radio equipment
Signal processing
Wireless networks
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Summary:Modern 5G wireless cellular networks use massive multiple-input multiple-output (MIMO) technology. This concept entails using an antenna array at a base station to concurrently service many mobile devices that have several antennas on their side. In this field, a significant role is played by the precoding (beamforming) problem. During downlink, an important part of precoding is the power allocation problem that distributes power between transmitted symbols. In this paper, we consider the power allocation problem for a class of precodings that asymptotically work as regularized zero-forcing. Under some realistic assumptions, we simplify the spectral efficiency functional and obtain tractable expressions for it. We prove that equal power allocation provides optimum for the simplified functional with total power constraint (TPC). We propose low-complexity Intersection methods (IM) that improve equal power allocation in the case of per-antenna power constraints (PAPC). On simulations using Quadriga, the proposed IM method in combination with widely-studied water filling (WF) shows a significant gain in spectral efficiency while using a similar computing time as the reference equal power (EP) solution.
ISSN:1022-0038
1572-8196
DOI:10.1007/s11276-023-03442-1