Model-driven deep neural network for enhanced direction finding with commodity 5G gNodeB
Abstract
Pervasive and high-accuracy positioning has become increasingly important as a fundamental enabler for intelligent connected devices in mobile networks. Nevertheless, current wireless networks heavily rely on pure model-driven techniques to achieve positioning functionality, often succumbing to performance deterioration due to hardware impairments in practical scenarios. Here we reformulate the direction finding or angle-of-arrival (AoA) estimation problem as an image recovery task of the spatial spectrum and propose a new model-driven deep neural network (MoD-DNN) framework. The proposed MoD-DNN scheme comprises three modules: a multi-task autoencoder-based beamformer, a coarray spectrum generation module, and a model-driven deep learning-based spatial spectrum reconstruction module. Our technique enables automatic calibration of angular-dependent phase error thereby enhancing the resilience of direction-finding precision against realistic system non-idealities. We validate the proposed scheme both using numerical simulations and field tests. The results show that the proposed MoD-DNN framework enables effective spectrum calibration and accurate AoA estimation. To the best of our knowledge, this study marks the first successful demonstration of hybrid data-and-model-driven direction finding utilizing readily available commodity 5G gNodeB.
Keywords
Cite
@article{arxiv.2412.10644,
title = {Model-driven deep neural network for enhanced direction finding with commodity 5G gNodeB},
author = {Shengheng Liu and Zihuan Mao and Xingkang Li and Mengguan Pan and Peng Liu and Yongming Huang and Xiaohu You},
journal= {arXiv preprint arXiv:2412.10644},
year = {2024}
}
Comments
To appear in ACM TOSN. A preliminary version of this article was presented at the AAAI'2024 Main Technical Track