Deep Learning Predictive Band Switching in Wireless Networks
Abstract
In cellular systems, the user equipment (UE) can request a change in the frequency band when its rate drops below a threshold on the current band. The UE is then instructed by the base station (BS) to measure the quality of candidate bands, which requires a measurement gap in the data transmission, thus lowering the data rate. We propose an online-learning based band switching approach that does not require any measurement gap. Our proposed classifier-based band switching policy instead exploits spatial and spectral correlation between radio frequency signals in different bands based on knowledge of the UE location. We focus on switching between a lower (e.g., 3.5 GHz) band and a millimeter wave band (e.g., 28 GHz), and design and evaluate two classification models that are trained on a ray-tracing dataset. A key insight is that measurement gaps are overkill, in that only the relative order of the bands is necessary for band selection, rather than a full channel estimate. Our proposed machine learning based policies achieve roughly 30% improvement in mean effective rates over those of the industry standard policy, while achieving misclassification errors well below 0.5% and maintaining resilience against blockage uncertainty.
Cite
@article{arxiv.1910.05305,
title = {Deep Learning Predictive Band Switching in Wireless Networks},
author = {Faris B. Mismar and Ahmad AlAmmouri and Ahmed Alkhateeb and Jeffrey G. Andrews and Brian L. Evans},
journal= {arXiv preprint arXiv:1910.05305},
year = {2020}
}
Comments
31 pages, 15 figures, revised and resubmitted to IEEE Transactions on Wireless Communications on October 2, 2019, March 9, 2020, July 2, 2020, and September 1, 2020