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Main Authors: Mostafa, Seraj Al Mahmud, Faruque, Omar, Wang, Chenxi, Yue, Jia, Purushotham, Sanjay, Wang, Jianwu
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2408.14674
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author Mostafa, Seraj Al Mahmud
Faruque, Omar
Wang, Chenxi
Yue, Jia
Purushotham, Sanjay
Wang, Jianwu
author_facet Mostafa, Seraj Al Mahmud
Faruque, Omar
Wang, Chenxi
Yue, Jia
Purushotham, Sanjay
Wang, Jianwu
contents Atmospheric gravity waves occur in the Earths atmosphere caused by an interplay between gravity and buoyancy forces. These waves have profound impacts on various aspects of the atmosphere, including the patterns of precipitation, cloud formation, ozone distribution, aerosols, and pollutant dispersion. Therefore, understanding gravity waves is essential to comprehend and monitor changes in a wide range of atmospheric behaviors. Limited studies have been conducted to identify gravity waves from satellite data using machine learning techniques. Particularly, without applying noise removal techniques, it remains an underexplored area of research. This study presents a novel kernel design aimed at identifying gravity waves within satellite images. The proposed kernel is seamlessly integrated into a deep convolutional neural network, denoted as gWaveNet. Our proposed model exhibits impressive proficiency in detecting images containing gravity waves from noisy satellite data without any feature engineering. The empirical results show our model outperforms related approaches by achieving over 98% training accuracy and over 94% test accuracy which is known to be the best result for gravity waves detection up to the time of this work. We open sourced our code at https://rb.gy/qn68ku.
format Preprint
id arxiv_https___arxiv_org_abs_2408_14674
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle gWaveNet: Classification of Gravity Waves from Noisy Satellite Data using Custom Kernel Integrated Deep Learning Method
Mostafa, Seraj Al Mahmud
Faruque, Omar
Wang, Chenxi
Yue, Jia
Purushotham, Sanjay
Wang, Jianwu
Computer Vision and Pattern Recognition
Atmospheric gravity waves occur in the Earths atmosphere caused by an interplay between gravity and buoyancy forces. These waves have profound impacts on various aspects of the atmosphere, including the patterns of precipitation, cloud formation, ozone distribution, aerosols, and pollutant dispersion. Therefore, understanding gravity waves is essential to comprehend and monitor changes in a wide range of atmospheric behaviors. Limited studies have been conducted to identify gravity waves from satellite data using machine learning techniques. Particularly, without applying noise removal techniques, it remains an underexplored area of research. This study presents a novel kernel design aimed at identifying gravity waves within satellite images. The proposed kernel is seamlessly integrated into a deep convolutional neural network, denoted as gWaveNet. Our proposed model exhibits impressive proficiency in detecting images containing gravity waves from noisy satellite data without any feature engineering. The empirical results show our model outperforms related approaches by achieving over 98% training accuracy and over 94% test accuracy which is known to be the best result for gravity waves detection up to the time of this work. We open sourced our code at https://rb.gy/qn68ku.
title gWaveNet: Classification of Gravity Waves from Noisy Satellite Data using Custom Kernel Integrated Deep Learning Method
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2408.14674