A Data and Model-Driven Deep Learning Approach to Robust Downlink Beamforming Optimization

Kai Liang;Gan Zheng;Zan Li;Kai-Kit Wong;Chan-Byoung Chae
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Abstract

This paper investigates the optimization of the probabilistically robust transmit beamforming problem with channel uncertainties in the multiuser multiple-input single-output (MISO) downlink transmission. This problem poses significant analytical and computational challenges. Currently, the state-of-the-art optimization method relies on convex restrictions as tractable approximations to ensure robustness against Gaussian channel uncertainties. However, this method not only exhibits high computational complexity and suffers from the rank relaxation issue but also yields conservative solutions. In this paper, we propose an unsupervised deep learning-based approach that incorporates the sampling of channel uncertainties in the training process to optimize the probabilistic system performance. We introduce a model-driven learning approach that defines a new beamforming structure with trainable parameters to account for channel uncertainties. Additionally, we employ a graph neural network to efficiently infer the key beamforming parameters. We successfully apply this approach to the minimum rate quantile maximization problem subject to outage and total power constraints. Furthermore, we propose a bisection search method to address the more challenging power minimization problem with probabilistic rate constraints by leveraging the aforementioned approach. Numerical results confirm that our approach achieves non-conservative robust performance, higher data rates, greater power efficiency, and faster execution compared to state-of-the-art optimization methods.
稳健下行波束成形优化的数据和模型驱动深度学习方法
本文研究了多用户多输入单输出(MISO)下行链路传输中具有信道不确定性的概率稳健发射波束成形问题的优化。这一问题在分析和计算方面都提出了巨大挑战。目前,最先进的优化方法依赖于凸限制作为可处理的近似值,以确保对高斯信道不确定性的鲁棒性。然而,这种方法不仅计算复杂度高,存在秩松弛问题,而且会产生保守解。在本文中,我们提出了一种基于无监督深度学习的方法,将信道不确定性采样纳入训练过程,以优化概率系统性能。我们引入了一种模型驱动的学习方法,该方法定义了一种新的波束成形结构,其可训练参数考虑了信道的不确定性。此外,我们还采用图神经网络来有效推断关键波束成形参数。我们成功地将这种方法应用于受中断和总功率约束的最小速率量化最大化问题。此外,我们还提出了一种分段搜索方法,利用上述方法解决具有概率速率约束的更具挑战性的功率最小化问题。数值结果证实,与最先进的优化方法相比,我们的方法实现了非保守的稳健性能、更高的数据速率、更高的功率效率和更快的执行速度。
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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