Abstract
The fundamental challenge of the millimeter-wave (mmWave) frequency band is the sensitivity of the radio channel to blockages, which gives rise to unstable connectivity and impacts the reliability of a system. To this end, multi-point connectivity is a promising approach for ensuring the desired rate and reliability requirements. A robust beamformer design is proposed to improve the communication reliability by exploiting the spatial macro-diversity and a pessimistic estimate of rates over potential link blockage combinations. Specifically, we provide a blockage-aware algorithm for the weighted sum-rate maximization (WSRM) problem with parallel beamformer processing across distributed remote radio units (RRUs). Combinations of non-convex and coupled constraints are handled via successive convex approximation (SCA) framework, which admits a closed-form solution for each SCA step, by solving a system of Karush-Kuhn-Tucker (KKT) optimality conditions. Unlike the conventional coordinated multi-point (CoMP) schemes, the proposed blockage-aware beamformer design has, per-iteration, computational complexity in the order of RRU antennas instead of system-wide joint transmit antennas. This leads to a practical and computationally efficient implementation that is scalable to any arbitrary multi-point configuration. In the presence of random blockages, the proposed schemes are shown to significantly outperform baseline scenarios and result in reliable mmWave communication.
Highlights
T HE proliferation of ever-increasing data-intensive wireless applications along with spectrum shortage motivates the investigation of millimeter-wave communication for the upcoming 5th-generation (5G) New Radio (NR) and beyond cellular systems [1], [2]
The additive white Gaussian noise (AWGN) noise is set to −72 dBm/Hz, carrier-frequency fc = 28 GHz, and a 20 MHz frequency band is assumed to be fully reused across all remote radio units (RRUs)
We studied the trade-off between achievable rate and reliability in mmWave access by exploiting the multiantenna spatial diversity and coordinated multi-point (CoMP) connectivity
Summary
T HE proliferation of ever-increasing data-intensive wireless applications along with spectrum shortage motivates the investigation of millimeter-wave (mmWave) communication for the upcoming 5th-generation (5G) New Radio (NR) and beyond cellular systems [1], [2]. The fundamental challenge is the sensitivity of mmWave radio channel to blockages due to reduced diffraction, higher path and penetration loss [3], [4]. These lead to rapid degradation of signal strength and give rise to unstable and unreliable connectivity. The presence of such frequent and long duration blockages significantly reduces the experienced quality-of-service (QoS) [4] To overcome such challenges, use of coordinated multi-point (CoMP) schemes, where the users are concurrently connected to multiple remote radio units (RRUs), are highly useful for providing more robust and resilient communication [5]–[15]. It is envisioned that multi-connectivity schemes by utilizing the multi-antenna spatial redundancy via geographically separated transceivers will be of high importance in future mmWave systems [16]
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