Communication in Millimeter wave (mmWave) band relies on narrow beams due to directionality, high path loss, and shadowing. One can use beam alignment (BA) techniques to find and adjust the direction of these narrow beams. In this paper, BA at the base station (BS) is considered, where the BS sends a set of BA packets to scan different angular regions while the user listens to the channel and sends feedback to the BS for each received packet. It is assumed that the packets and feedback received at the user and BS, respectively, can be correctly decoded. Motivated by practical constraints such as propagation delay, a feedback delay for each BA packet is considered. At the end of the BA, the BS allocates a narrow beam to the user including its angle of departure for data transmission and the objective is to maximize the resulting expected beamforming gain. A general framework for studying this problem is proposed based on which a lower bound on the optimal performance as well as an optimality achieving scheme are obtained. Simulation results reveal significant performance improvements over the state-of-the-art BA methods in the presence of feedback delay.
翻译:毫米波( mmWave) 频段的通信依赖因方向性、 高路径丢失和阴影而形成的窄光束。 人们可以使用波束对齐技术查找和调整这些窄光束的方向。 在本文中, 基站的 BA (BS) 会考虑, BS 会发送一套 BA 包, 扫描不同的角区域, 而用户会收听频道, 并向 BS 发送每个接收的包的反馈。 假设用户和 BS 收到的包和反馈可以正确解码。 受传播延迟等实际限制的驱动, 每个 BA 包会考虑反馈延迟。 在 BA 末, BS 会给用户分配一个窄光束, 包括数据传输的起始角度, 目标是尽量扩大预期的成型收益。 正在提出一个研究该问题的一般框架, 在此基础上, 获得对最佳性能和最佳性能实现计划限制较低的总体框架。 模拟结果显示, 在反馈延迟的情况下, 州BA 方法的性能显著改善。