Active Sensing for Two-Sided Beam Alignment and Reflection Design Using Ping-Pong Pilots

Tao Jiang;Foad Sohrabi;Wei Yu
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引用次数: 1

Abstract

Beam alignment is an important task for millimeter-wave (mmWave) communication, because constructing aligned narrow beams both at the transmitter (Tx) and the receiver (Rx) is crucial in terms of compensating the significant path loss in very high-frequency bands. However, beam alignment is also a highly nontrivial task because large antenna arrays typically have a limited number of radio-frequency chains, allowing only low-dimensional measurements of the high-dimensional channel. This paper considers a two-sided beam alignment problem based on an alternating ping-pong pilot scheme between Tx and Rx over multiple rounds without explicit feedback. We propose a deep active sensing framework in which two long short-term memory (LSTM) based neural networks are employed to learn the adaptive sensing strategies (i.e., measurement vectors) and to produce the final aligned beamformers at both sides. In the proposed ping-pong protocol, the Tx and the Rx alternately send pilots so that both sides can leverage local observations to sequentially design their respective sensing and data transmission beamformers. The proposed strategy can be extended to scenarios with a reconfigurable intelligent surface (RIS) for designing, in addition, the reflection coefficients at the RIS for both sensing and communications. Numerical experiments demonstrate significant and interpretable performance improvement. The proposed strategy works well even for the challenging multipath channel environments.
利用乒乓球飞行员进行双侧光束对准和反射设计的主动传感
波束对准是毫米波(mmWave)通信的一项重要任务,因为在发射机(Tx)和接收机(Rx)上构建对准的窄波束对于补偿高频波段的显著路径损耗至关重要。然而,波束对准也是一项非常重要的任务,因为大型天线阵列通常具有有限数量的射频链,只能对高维信道进行低维测量。本文研究了一个基于多回合无显式反馈的Tx和Rx之间的交替乒乓导频方案的双边光束对准问题。我们提出了一个深度主动传感框架,其中使用两个基于长短期记忆(LSTM)的神经网络来学习自适应传感策略(即测量向量)并在两侧产生最终对齐的波束形成器。在拟议的乒乓协议中,Tx和Rx交替派遣飞行员,以便双方可以利用当地的观测结果依次设计各自的传感和数据传输波束形成器。提出的策略可以扩展到具有可重构智能表面(RIS)的场景中,用于设计RIS上的反射系数,以及用于传感和通信的反射系数。数值实验证明了显著和可解释的性能改进。所提出的策略即使在具有挑战性的多径信道环境中也能很好地工作。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
8.20
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