FadeNet: Deep Learning-Based mm-Wave Large-Scale Channel Fading Prediction and its Applications

Vishnu V. Ratnam; Hao Chen; Sameer Pawar; Bingwen Zhang; Charlie Jianzhong Zhang; Young-Jin Kim; Soonyoung Lee; Minsung Cho; Sung-Rok Yoon

doi:10.1109/ACCESS.2020.3048583

IEEE Access (Jan 2021)

FadeNet: Deep Learning-Based mm-Wave Large-Scale Channel Fading Prediction and its Applications

Vishnu V. Ratnam,
Hao Chen,
Sameer Pawar,
Bingwen Zhang,
Charlie Jianzhong Zhang,
Young-Jin Kim,
Soonyoung Lee,
Minsung Cho,
Sung-Rok Yoon

Affiliations

Vishnu V. Ratnam: ORCiD; Standards and Mobility Innovation Laboratory, Samsung Research America, Plano, TX, USA
Hao Chen: ORCiD; Standards and Mobility Innovation Laboratory, Samsung Research America, Plano, TX, USA
Sameer Pawar: Standards and Mobility Innovation Laboratory, Samsung Research America, Plano, TX, USA
Bingwen Zhang: Standards and Mobility Innovation Laboratory, Samsung Research America, Plano, TX, USA
Charlie Jianzhong Zhang: Standards and Mobility Innovation Laboratory, Samsung Research America, Plano, TX, USA
Young-Jin Kim: Network Division, Network Automation Group, Samsung Electronics Company Ltd., Suwon, South Korea
Soonyoung Lee: Network Division, Network Automation Group, Samsung Electronics Company Ltd., Suwon, South Korea
Minsung Cho: Network Division, Network Automation Group, Samsung Electronics Company Ltd., Suwon, South Korea
Sung-Rok Yoon: ORCiD; Network Division, Network Automation Group, Samsung Electronics Company Ltd., Suwon, South Korea

DOI: https://doi.org/10.1109/ACCESS.2020.3048583
Journal volume & issue: Vol. 9
pp. 3278 – 3290

Abstract

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Accurate prediction of the large-scale channel fading is fundamental to planning and optimization in 5G millimeter-wave cellular networks. The current prediction methods, which are either too computationally expensive or inaccurate, are unsuitable for city-scale cell planning and optimization. This paper presents FadeNet, a convolutional neural-network enabled alternative for predicting large-scale fading with high computation speed and accuracy. By using carefully designed input features and neural-network architecture to capture topographical information, FadeNet accurately predicts the large-scale fading from a base station to each location in its coverage area. Evaluations on realistic data, derived from millimeter-wave cells across multiple cities, suggest that FadeNet can achieve a prediction accuracy of 5.6 decibels in root mean square error. In addition, by leveraging the parallel processing capabilities of a graphics processing unit, FadeNet can reduce the prediction time by 40X - 1000X in comparison to industry prevalent methods like ray-tracing. Generalizations of FadeNet, that can handle variable topographies and base station heights, and its use for optimal cell site selection are also explored.

Published in IEEE Access

ISSN: 2169-3536 (Online)
Publisher: IEEE
Country of publisher: United States
LCC subjects: Technology: Electrical engineering. Electronics. Nuclear engineering
Website: https://ieeexplore.ieee.org/xpl/RecentIssue.jsp?punumber=6287639

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