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Enabling FDD Massive MIMO through Deep Learning-based Channel Prediction

Information Theory 2019-01-14 v1 Machine Learning math.IT Machine Learning

Abstract

A major obstacle for widespread deployment of frequency division duplex (FDD)-based Massive multiple-input multiple-output (MIMO) communications is the large signaling overhead for reporting full downlink (DL) channel state information (CSI) back to the basestation (BS), in order to enable closed-loop precoding. We completely remove this overhead by a deep-learning based channel extrapolation (or "prediction") approach and demonstrate that a neural network (NN) at the BS can infer the DL CSI centered around a frequency fDLf_\text{DL} by solely observing uplink (UL) CSI on a different, yet adjacent frequency band around fULf_\text{UL}; no more pilot/reporting overhead is needed than with a genuine time division duplex (TDD)-based system. The rationale is that scatterers and the large-scale propagation environment are sufficiently similar to allow a NN to learn about the physical connections and constraints between two neighboring frequency bands, and thus provide a well-operating system even when classic extrapolation methods, like the Wiener filter (used as a baseline for comparison throughout) fails. We study its performance for various state-of-the-art Massive MIMO channel models, and, even more so, evaluate the scheme using actual Massive MIMO channel measurements, rendering it to be practically feasible at negligible loss in spectral efficiency when compared to a genuine TDD-based system.

Keywords

Cite

@article{arxiv.1901.03664,
  title  = {Enabling FDD Massive MIMO through Deep Learning-based Channel Prediction},
  author = {Maximilian Arnold and Sebastian Dörner and Sebastian Cammerer and Sarah Yan and Jakob Hoydis and Stephan ten Brink},
  journal= {arXiv preprint arXiv:1901.03664},
  year   = {2019}
}

Comments

Extended version of the conference paper submitted to SPAWC2019

R2 v1 2026-06-23T07:09:15.681Z