On proportional fairness of uplink spectral efficiency in cell‐free massive MIMO systems

Summary This paper is concerned with the proportional fairness (PF) of the spectral efficiency (SE) maximization of uplinks in a cell‐free (CF) massive multiple‐input multiple‐output (MIMO) system in which a large number of single‐antenna access points (APs) connected to a central processing unit (C...

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Bibliographic Details
Published in:International journal of communication systems 2020-09, Vol.33 (14), p.n/a
Main Authors: Quoc Pham, Viet, Hoang Kha, Ha, Ty Khanh, Le
Format: Article
Language:English
Subjects:
Antennas
cell‐free massive MIMO
Central processing units
Coefficients
Computer simulation
CPUs
Eigenvalues
gradient projection
Iterative algorithms
Matched filters
Maximization
MIMO (control systems)
Optimization
proportional fairness
Receivers & amplifiers
spectral efficiency
Uplinking
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Summary:Summary This paper is concerned with the proportional fairness (PF) of the spectral efficiency (SE) maximization of uplinks in a cell‐free (CF) massive multiple‐input multiple‐output (MIMO) system in which a large number of single‐antenna access points (APs) connected to a central processing unit (CPU) serve many single‐antenna users. To detect the user signals, the APs use matched filters based on the local channel state information while the CPU deploys receiver filters based on knowledge of channel statistics. We devise the maximization problem of the SE PF, which maximizes the sum of the logarithm of the achievable user rates, as a jointly nonconvex optimization problem of receiver filter coefficients and user power allocation subject to user power constraints. To handle the challenges associated with the nonconvexity of the formulated design problem, we develop an iterative algorithm by alternatively finding optimal filter coefficients at the CPU and transmit powers at the users. While the filter coefficient design is formulated as a generalized eigenvalue problem, the power allocation problem is addressed by a gradient projection (GP) approach. Simulation results show that the SE PF maximization not only offers approximately the achievable sum rates as compared to the sum‐rate maximization but also provides an improved trade‐off between the user rate fairness and the achievable sum rate. This paper is concerned with the proportional fairness (PF) of the spectral efficiency (SE) maximization of uplinks in a cell‐free massive multiple‐input multiple‐output system. We develop an iterative algorithm to solve the maximization problem of the SE PF which is formulated as a jointly nonconvex optimization problem of receiver filter coefficients and user power allocation subject to user power constraints. Simulation results show that the SE PF maximization provides an improved trade‐off between the user rate fairness and achievable sum rate.
ISSN:1074-5351
1099-1131
DOI:10.1002/dac.4534