Abstract
The use of a large-scale antenna array (LSAA) has become an important characteristic of multi-antenna communication systems to achieve beamforming gains such as in designing millimeter-wave (mmWave) systems to combat severe propagation losses. In such applications, each antenna element has to be driven by a radio frequency (RF) chain for the implementation of fully-digital beamformers, significantly increasing the hardware cost, complexity, and power consumption. Therefore, constant-modulus analog beamforming (CMAB) becomes a viable solution. In this paper, we consider the scaled analog beamforming (SAB) or constant-modulus analog beamforming (CMAB) architecture and design the system parameters by solving two variants of beampattern matching problem. In the first case, both the magnitude and phase of the beampattern are matched to the given desired beampattern whereas in the second case, only the magnitude of the beampattern is matched. Both the beampattern matching problems are cast as a variant of the constant-modulus least-squares (CLS) problem. We provide efficient algorithms based on the alternating majorization-minimization (AMM) framework that combines the alternating minimization and the MM frameworks and the conventional-cyclic coordinate descent (C-CCD) algorithms to solve the problem in each case. We also propose algorithms based on a new modified-CCD (M-CCD) based approach. For all the developed algorithms we prove convergence to a Karush-Kuhn-Tucker (KKT) point (or a stationary point). Numerical results demonstrate that the proposed algorithms converge faster than the state-of-the-art solutions. Among all the algorithms, the M-CCD-based algorithms have faster convergence when evaluated in terms of the number of iterations and the AMM-based algorithms offer lower complexity.
Highlights
In multi-antenna communication systems, an antenna array is employed at the transmitter and/or at the receiver to achieve beamforming, performance gains
Algorithms: We propose efficient algorithms specializing on the MM and the cyclic coordinate descent (CCD) optimization frameworks to the considered problem formulations
We studied the problem of designing constantmodulus analog beamforming (CMAB) systems equipped with large-scale antenna arrays (LSAAs)
Summary
In multi-antenna communication systems, an antenna array is employed at the transmitter and/or at the receiver to achieve beamforming, performance gains. The beamforming vector is constrained to have constant-modulus entries, where the magnitude of each entry corresponds to the gain contribution from the VGA In this case, the transmitted signals present low Peak-to-Average-Ratio (PAR) and they enable the use of power-efficient nonlinear amplifiers at the transmitter’s side. The transmitted signals present low Peak-to-Average-Ratio (PAR) and they enable the use of power-efficient nonlinear amplifiers at the transmitter’s side This characteristic is highly desirable in LSAA-based systems [7], [8] because they do not require highly linear PAs which are necessary for the fully-digital beamforming implementation [9], [10]. The analog beamforming architectures have several other advantages, for example, adjusting only the phases of the beamforming vector constrains the power required to drive an antenna element to be a constant These gains are more appealing when the transmitter/receiver employs an LSAA
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