Scalable multi-modal learning for cross-link channel prediction in massive IoT networks

Abstract

Tomorrow’s massive-scale IoT sensor networks are poised to drive uplink traffic demand, especially in areas of dense deployment. To meet this demand, however, network design- ers leverage tools that often require accurate estimates of Channel State Information (CSI), which incurs a high over- head and thus reduces network throughput. Furthermore, the overhead generally scales with the number of clients, and so is of special concern in such massive IoT sensor networks. While prior work has used transmissions over one frequency band to predict the channel of another frequency band on the same link, this paper takes the next step in the effort to reduce CSI overhead: predict the CSI of a nearby but distinct link. We propose Cross-Link Channel Prediction (CLCP), a technique that leverages multi-view representation learn- ing to predict the channel response of a large number of users, thereby reducing channel estimation overhead further than previously possible. CLCP’s design is highly practical, exploiting existing transmissions rather than dedicated chan- nel sounding or extra pilot signals. We have implemented CLCP for two different Wi-Fi versions, namely 802.11n and 802.11ax, the latter being the leading candidate for future IoT networks. We evaluate CLCP in two large-scale indoor scenarios involving both line-of-sight and non-line-of-sight transmissions with up to 144 different 802.11ax users. More- over, we measure its performance with four different channel bandwidths, from 20 MHz up to 160 MHz. Our results show that CLCP provides a 2× throughput gain over baseline and a 30% throughput gain over existing prediction algorithms.

Type
Publication
The 24th ACM Symposium on Theory, Algorithms, and Protocol Design for Mobile Networks and Computing (MobiHoc 23 - Best Paper Award)
Kun Woo Cho
Kun Woo Cho
Email: kwcho@princeton.edu

My research interests include wireless networked systems, smart surface, and AI-assisted networks.