Adaptive Millimeter Wave Beam Alignment for Dual-Polarized MIMO Systems

Abstract

Fifth-generation wireless systems are expected to employ multiple-antenna communication at millimeter wave (mm Wave) frequencies using small cells within heterogeneous cellular networks. The high path loss of mm Wave and the physical obstructions make communication challenging. To compensate for the severe path loss, mm Wave systems may employ a beam alignment algorithm that facilitates highly directional transmission by aligning the beam direction of multiple antenna arrays. This paper discusses a mm Wave system employing dual-polarized antennas. First, we propose a practical soft-decision beam alignment (soft-alignment) algorithm that exploits orthogonal polarizations. By sounding the orthogonal polarizations in parallel, the equality criterion of the Welch bound for training sequences is relaxed. Second, the analog beamforming system is adapted to the directional characteristics of the mm Wave link, assuming a high Ricean K-factor and poor scattering environment. A soft-alignment algorithm enables the mm Wave system to align a large number of narrow beams to the channel subspace in an attempt to effectively scan the mm Wave channel. Third, we propose a method to efficiently adapt the number of channel sounding observations to the specific channel environment based on an approximate probability of beam misalignment. Simulation results show that the proposed soft-alignment algorithm with adaptive sounding time effectively scans the channel subspace of a mobile user by exploiting polarization diversity.