具有少量有源元件的毫米波无线通信中 RIS 辅助多输入多输出系统的信道估计

Walid K. Ghamry, Suzan Shukry
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引用次数: 0

摘要

在可重构智能表面(RIS)辅助毫米波(mmWave)无线通信系统中,精确的信道估计是一项重大挑战。由于 RIS 在发射和接收信号方面的限制,其完全被动的特性主要依赖于级联信道估计。虽然这种方法很有优势,但随着 RIS 元素数量的增加,信道系数也会呈指数级增长,从而导致昂贵的先导开销。为应对这一挑战,本文提出了一种两阶段独立信道估计框架。该框架包括在无源 RIS 中加入一些有源元件,使 RIS 能够接收和处理先导信号。通过利用信道相干时间的差异,用户设备(UE)和 RIS 之间的时变信道估计以及 RIS 和基站(BS)之间的伪静态信道估计可以分别进行。两阶段独立信道估计框架的工作原理如下:在第一阶段,通过利用为数不多的活动信元,在 RIS 估算 BS-RIS 信道。采用迭代加权方法来制定估计 BS-RIS 信号模型的数学优化问题。随后,提出了一种基于梯度下降(GD)的算法,以有效处理和解决优化问题。在第二阶段,UE-RIS 信道的估计是通过将接收信道的信号模型转换成一个类似的张量模型(称为并行因子 (PARAFAC))来实现的。转换之后,在 BS 上应用基于张量表示的最小二乘(LS)算法。考虑到最小先导开销、平均频谱效率和归一化均方误差 (NMSE),模拟结果证明了所提框架的有效性。与其他三种最先进的现有方案进行了比较分析。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Channel estimation for RIS-aided MIMO systems in MmWave wireless communications with a few active elements

Channel estimation for RIS-aided MIMO systems in MmWave wireless communications with a few active elements

Accurate channel estimation poses a significant challenge in the reconfigurable intelligent surface (RIS)-aided millimeter-wave (mmWave) wireless communication system. The fully passive nature of the RIS primarily relies on cascaded channel estimation, given its limitation in transmitting and receiving signals. Although the advantageous of this approach, the increase in the number of RIS elements leads to an exponential growth in the channel coefficient, resulting in costly pilot overhead. To address this challenge, the paper proposes a two-phase framework for separate channel estimation. The framework involves incorporating a few active elements within the passive RIS, enabling the reception and processing of pilot signals at the RIS. Through leveraging the difference in coherence time of the channel, the estimation of the time-varying channel among user equipment (UE) and RIS, as well as the estimation of the pseudo-static channel among RIS and base station (BS), can be performed separately. The two-phase separate channel estimation framework operates as follows: In the first phase, the BS-RIS channel is estimated at the RIS through the utilization of the few active elements. An iterative weighting methodology is employed to formulate the mathematical optimization problem for estimating the BS-RIS signal model. Subsequently, a proposed algorithm grounded on gradient descent (GD) is introduced to efficiently address and solve the optimization problem. In the second phase, the estimation of the UE-RIS channel is achieved by transforming the signal model of the received channel into an analogous tensor model known as Parallel Factor (PARAFAC). This transformation is followed by the application of the least squares (LS) algorithm within this tensor-based representation at BS. The effectiveness of the proposed framework is demonstrated through simulation findings, considering minimum pilot overhead, average spectral efficiency, and normalized mean square error (NMSE). A comparative analysis is performed with three other state-of-the-art existing schemes.

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