Geometry Aware Meta-Learning Neural Network for Joint Phase and Precoder Optimization in RIS

Dahlia Devapriya, Sheetal Kalyani
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Abstract

In reconfigurable intelligent surface (RIS) aided systems, the joint optimization of the precoder matrix at the base station and the phase shifts of the RIS elements involves significant complexity. In this paper, we propose a complex-valued, geometry aware meta-learning neural network that maximizes the weighted sum rate in a multi-user multiple input single output system. By leveraging the complex circle geometry for phase shifts and spherical geometry for the precoder, the optimization occurs on Riemannian manifolds, leading to faster convergence. We use a complex-valued neural network for phase shifts and an Euler inspired update for the precoder network. Our approach outperforms existing neural network-based algorithms, offering higher weighted sum rates, lower power consumption, and significantly faster convergence. Specifically, it converges faster by nearly 100 epochs, with a 0.7 bps improvement in weighted sum rate and a 1.8 dBm power gain when compared with existing work.
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用于 RIS 中联合相位和前导器优化的几何感知元学习神经网络
在可重构智能表面(RIS)辅助系统中,基站前置编码器矩阵和 RIS 元素相移的联合优化涉及巨大的复杂性。在本文中,我们提出了一种复值几何感知元学习神经网络,它能最大限度地提高多用户多输入单输出系统中的加权和率。通过将复圆几何用于相移,将球面几何用于前置编码器,优化发生在黎曼流形上,从而加快了收敛速度。我们使用复值神经网络进行相移,并对前编码器网络进行欧拉启发更新。我们的方法优于现有的基于神经网络的算法,具有更高的加权总和率、更低的功耗和更快的收敛速度。具体来说,与现有算法相比,它的收敛速度快了近 100 个纪元,加权求和率提高了 0.7 bps,功耗增加了 1.8 dBm。
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