Predicting Path Loss Distributions of a Wireless Communication System for Multiple Base Station Altitudes From Satellite Images
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Date
2022
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Ieee
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Green Open Access
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Abstract
It is expected that unmanned aerial vehicles (UAVs) will play a vital role in future communication systems. Optimum positioning of UAVs, serving as base stations, can be done through extensive field measurements or ray tracing simulations when the 3D model of the region of interest is available. In this paper, we present an alternative approach to optimize UAV base station altitude for a region. The approach is based on deep learning; specifically, a 2D satellite image of the target region is input to a deep neural network to predict path loss distributions for different UAV altitudes. The neural network is designed and trained to produce multiple path loss distributions in a single inference; thus, it is not necessary to train a separate network for each altitude.
Description
Keywords
convolutional neural networks, deep learning, path loss estimation, UAV networks, Vehicle network, Aerial vehicle, UAV networks, Base stations, Convolutional neural network, Unmanned aerial vehicles (UAV), 3D modeling, Deep Learning, Vehicle to vehicle communications, convolutional neural networks, Deep neural networks, Path loss estimation, Satellite images, Path loss, Image segmentation, Convolutional Neural Networks, Loss estimation, Path Loss Estimation, Unmanned aerial vehicle network, deep learning, Deep learning, Loss distribution, path loss estimation, Antennas, Convolutional neural networks, UAV Networks
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Fields of Science
02 engineering and technology, 0202 electrical engineering, electronic engineering, information engineering
Citation
WoS Q
Scopus Q
Q3
OpenCitations Citation Count
2
Source
IEEE International Conference on Image Processing (ICIP) -- OCT 16-19, 2022 -- Bordeaux, FRANCE
Volume
Issue
Start Page
2471
End Page
2475
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CrossRef : 1
Scopus : 4
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2
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4
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