Near-Field Wideband Beamforming for Extremely Large Antenna Arrays

from arxiv, The near-field beam split effect, a fundamental change from large antenna array to extremely large antenna array, is revealed and addressed. We also define a more accurate metric called effective Rayleigh distance to divide the near-field and far-field regions. Simulation codes will be provided after publication: http://oa.ee.tsinghua.edu.cn/dailinglong/publications/publications.html

The natural integration of extremely large antenna arrays (ELAAs) and terahertz (THz) communications can potentially achieve Tbps data rates in 6G networks. However, due to the extremely large array aperture and wide bandwidth, a new phenomenon called "near-field beam split" emerges. This phenomenon causes beams at different frequencies to focus on distinct physical locations, leading to a significant gain loss of beamforming. To address this challenging problem, we first harness a piecewise-far-field channel model to approximate the complicated near-field wideband channel. In this model, the entire large array is partitioned into several small sub-arrays. While the wireless channel's phase discrepancy across the entire array is modeled as near-field spherical, the phase discrepancy within each sub-array is approximated as far-field planar. Built on this approximation, a phase-delay focusing (PDF) method employing delay phase precoding (DPP) architecture is proposed. Our PDF method could compensate for the intra-array far-field phase discrepancy and the inter-array near-field phase discrepancy via the joint control of phase shifters and time delayers, respectively. Theoretical and numerical results are provided to demonstrate the efficiency of the proposed PDF method in mitigating the near-field beam split effect.Finally, we define and derive a novel metric termed the "effective Rayleigh distance" by the evaluation of beamforming gain loss. Compared to classical Rayleigh distance, the effective Rayleigh distance is more accurate in determining the near-field range for practical communications.

翻译：超大天线阵列与太赫兹通信的自然融合有望在6G网络中实现Tbps的数据速率。然而，由于超大的阵列孔径和宽带特性，出现了一种被称为“近场波束分裂”的新现象。该现象导致不同频率的波束聚焦于不同的物理位置，从而引起波束成形增益的显著损失。为解决这一挑战性问题，我们首先利用分段远场信道模型来近似复杂的近场宽带信道。在该模型中，整个大型阵列被划分为若干小型子阵列。虽然整个阵列上的无线信道相位差异被建模为近场球面波，但每个子阵列内的相位差异则被近似为远场平面波。基于这一近似，我们提出了一种采用延迟相位预编码架构的相位延迟聚焦方法。我们的PDF方法能够通过相位调节器和延时器的联合控制，分别补偿子阵列内部的远场相位差异和子阵列之间的近场相位差异。通过理论和数值结果，我们验证了所提PDF方法在缓解近场波束分裂效应方面的有效性。最后，通过评估波束成形增益损失，我们定义并推导了一个新颖的度量标准——“有效瑞利距离”。与传统瑞利距离相比，有效瑞利距离能更准确地确定实际通信中的近场范围。