Enabling More Users to Benefit from Near-Field Communications: From Linear to Circular Array

—Massive multiple-input multiple-output (MIMO) for 5G is evolving into the extremely large-scale antenna array (ELAA) to increase the spectrum efficiency by orders of magni- tude for 6G communications. ELAA introduces spherical-wave-based near-field communications, where channel capacity can be significantly improved for single-user and multi-user scenarios. Unfortunately, for the widely studied uniform linear array (ULA), the near-field regions at large incidence angles will be reduced. Thus, many users randomly distributed in a cell may fail to bene- fit from near-field communications. In this paper, we leverage the rotational symmetry of uniform circular array (UCA) to provide uniform and enlarged near-field region for all users in a cell, enabling more users to benefit from near-field communications. Specifically, by exploiting the geometrical relationship between UCA and user with the spherical-wave model, the near-field beamforming technique for UCA is developed for the first time. Based on the analysis of near-field beamforming, we reveal that UCA is able to provide a larger near-field region than ULA in terms of the effective Rayleigh distance. Moreover, based on the UCA beamforming property, a concentric-ring codebook is designed to realize efficient beamforming in the near-field region of UCA. In addition, we find out that UCA could generate orthogonal near-field beams along the same direction, which has the potential for further improvement of multi-user capacity compared with ULA. Simulation results are provided to verify the feasibility of UCA to enable more users to benefit from near-field communications by broadening the near-field region.

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