Abstract
Cell-free massive MIMO systems consist of many distributed access points with simple components that jointly serve the users. In millimeter wave bands, only a limited set of predetermined beams can be supported. In a network that consolidates these technologies, downlink analog beam selection stands as a challenging task for the network sum-rate maximization. Low-cost digital filters can improve the network sum-rate further. In this work, we propose low-cost joint designs of analog beam selection and digital filters. The proposed joint designs achieve significantly higher sum-rates than the disjoint design benchmark. Supervised machine learning (ML) algorithms can efficiently approximate the input-output mapping functions of the beam selection decisions of the joint designs with low computational complexities. Since the training of ML algorithms is performed off-line, we propose a well-constructed joint design that combines multiple initializations, iterations, and selection features, as well as beam conflict control, i.e., the same beam cannot be used for multiple users. The numerical results indicate that ML algorithms can retain 99-100% of the original sum-rate results achieved by the proposed well-constructed designs.
Highlights
C ELL-FREE massive MIMO networks thrive on the idea of jointly and coherently serving a proportionally small number of users by a large number of simple multi-antenna access points (APs)
We propose low-cost joint design algorithms for analog beam selection and digital beamforming in the downlink transmission of a mm-wave cell-free mMIMO system consisting of multiple antenna APs and single antenna users
The proposed joint design solutions achieve significant network sum-rate gains compared to the naive disjoint design of analog beam selection, which is based on the direct link (DL) power metrics of the users, and digital precoder
Summary
C ELL-FREE massive MIMO (mMIMO) networks thrive on the idea of jointly and coherently serving a proportionally small number of users by a large number of simple multi-antenna access points (APs). We propose low-cost joint design algorithms for analog beam selection and digital beamforming in the downlink transmission of a mm-wave cell-free mMIMO system consisting of multiple antenna APs and single antenna users. YETIS et al.: JOINT ANALOG BEAM SELECTION AND DIGITAL BEAMFORMING IN MM-WAVE CELL-FREE MASSIVE MIMO SYSTEMS on an external aid, e.g., location information of the users, but only on the sum-rate metrics of the users. The proposed joint design solutions achieve significant network sum-rate gains compared to the naive disjoint design of analog beam selection, which is based on the direct link (DL) power metrics of the users, and digital precoder. Online beam selection by an ML algorithm which is succeeded by digital precoder designs are one-time-only, i.e., no for-loops, and this approach can mirror our proposed well-constructed designs. The proposed ML based approach can achieve 99-100% of the original sum-rate results achieved by the well-constructed designs
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