A Graph Neural Network Approach for Scalable Wireless Power Control
From MaRDI portal
Publication:6322367
arXiv1907.08487MaRDI QIDQ6322367
Author name not available (Why is that?)
Publication date: 19 July 2019
Abstract: Deep neural networks have recently emerged as a disruptive technology to solve NP-hard wireless resource allocation problems in a real-time manner. However, the adopted neural network structures, e.g., multi-layer perceptron (MLP) and convolutional neural network (CNN), are inherited from deep learning for image processing tasks, and thus are not tailored to problems in wireless networks. In particular, the performance of these methods deteriorates dramatically when the wireless network size becomes large. In this paper, we propose to utilize graph neural networks (GNNs) to develop scalable methods for solving the power control problem in -user interference channels. Specifically, a -user interference channel is first modeled as a complete graph, where the quantitative information of wireless channels is incorporated as the features of the graph. We then propose an interference graph convolutional neural network (IGCNet) to learn the optimal power control in an unsupervised manner. It is shown that one-layer IGCNet is a universal approximator to continuous set functions, which well matches the permutation invariance property of interference channels and it is robust to imperfect channel state information (CSI). Extensive simulations will show that the proposed IGCNet outperforms existing methods and achieves significant speedup over the classic algorithm for power control, namely, WMMSE. The code is available on https://github.com/yshenaw/Globecom2019.
Has companion code repository: https://github.com/zhuwenxing/Deep_Learning_Based_Power_Control
This page was built for publication: A Graph Neural Network Approach for Scalable Wireless Power Control
Report a bug (only for logged in users!)Click here to report a bug for this page (MaRDI item Q6322367)
