Terahertz ultra-massive multiple-input multiple-output (THz UM-MIMO) is envisioned as one of the key enablers of 6G wireless systems. Due to the joint effect of its array aperture and small wavelength, the near-field region of THz UM-MIMO is greatly enlarged. The high-dimensional channel of such systems thus consists of a stochastic mixture of far and near fields, which renders channel estimation extremely challenging. Previous works based on uni-field assumptions cannot capture the hybrid far- and near-field features, thus suffering significant performance loss. This motivates us to consider hybrid-field channel estimation. We draw inspirations from fixed point theory to develop an efficient deep learning based channel estimator with adaptive complexity and linear convergence guarantee. Built upon classic orthogonal approximate message passing, we transform each iteration into a contractive mapping, comprising a closed-form linear estimator and a neural network based non-linear estimator. A major algorithmic innovation involves applying fixed point iteration to compute the channel estimate while modeling neural networks with arbitrary depth and adapting to the hybrid-field channel conditions. Simulation results verify our theoretical analysis and show significant performance gains over state-of-the-art approaches in the estimation accuracy and convergence rate.
翻译:Thererz UM-MIMO(THz UM-MIMO)是6G无线系统的关键推进器之一。由于其阵列孔径和小波长的联合效应,THz UM-MIMO(THz UM-MIMO)的近场区域面积大为扩大。因此,这些系统的高维通道由远地和近地的随机混合组成,使得频道估算极具挑战性。以前基于单地假设的工程无法捕捉远地和近地混合特征,从而遭受重大性能损失。这促使我们考虑混合地频道估计。我们从固定点理论中汲取灵感,以开发一个基于高效深层次的频道估计器,具有适应性复杂性和线性趋同的保证。借助传统或多层近似信息传递,我们将每个循环转换成一个契约性绘图,包括一个封闭式线性估计器和以非线性估计器为基础的神经网络。一项主要算创新涉及应用固定点来对频道估计的频道估计结果进行配置,同时进行模拟式的模拟和精确度分析,同时展示模型化轨道的轨道的精确度分析结果,并显示我们测深层分析结果。</s>