Snow Mapping from Passive Microwave Brightness Temperature and MODIS Snow Product with Machine learning Approaches
Snow cover is one of the cryosphere's most critical components, representing a vital geophysical variable for climate and hydrology. Monitoring snow cover in Arctic regions has gained increasing significance, particularly considering recent climate warming. Given the complex spatiotemporal vari...
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ftunivwaterloo:oai:uwspace.uwaterloo.ca:10012/20288 2024-02-11T10:01:10+01:00 Snow Mapping from Passive Microwave Brightness Temperature and MODIS Snow Product with Machine learning Approaches Du, Jiayi 2024-01-12 http://hdl.handle.net/10012/20288 en eng University of Waterloo http://hdl.handle.net/10012/20288 Master Thesis 2024 ftunivwaterloo 2024-01-27T23:58:41Z Snow cover is one of the cryosphere's most critical components, representing a vital geophysical variable for climate and hydrology. Monitoring snow cover in Arctic regions has gained increasing significance, particularly considering recent climate warming. Given the complex spatiotemporal variability, inconvenience of transportation, and the remote locations of many snow-covered areas, remote sensing emerges as an ideal technique for data collection to monitor snow cover across various spatiotemporal scales. In contrast to optical remote sensing, passive microwave (PMW) and active microwave (AMW) satellite sensors remain unaffected by clouds and solar illumination, making them widely employed in snow detection. PMW observations have lower spatial resolution and high temporal resolution than AMW, which are suitable for large-scale snow mapping. Integrating optical data and PMW data can significantly enhance the quality of snow cover information. Various machine learning (ML) methods have been pivotal in environmental remote-sensing research in recent years. With the surge in Earth observation big data and the rapid advancements in ML techniques, an array of innovative methods has emerged to facilitate environmental monitoring on a global scale. Thus, a snow-monitoring method has been proposed based on multi-source remote sensing data and ML. The brightness temperature (Tb) data derived from the Advanced Microwave Scanning Radiometer E/2 (AMSR-E/2) Level 3 product and Moderate Resolution Imaging Spectroradiometer (MODIS) snow product serves as the reference for snow cover area (SCA). This study predominantly selects Oct, Dec, Feb, and Apr from 2012 to 2022 as the study periods. The research uses three ML methods, Logistic Regression (LR), Random Forest (RF) and Support Vector Machine (SVM), for snow cover detection based on PMW and MODIS data in the Arctic. The overall accuracy (The ratio of correctly classified as snow plus correctly classified as non-snow points to the total number of points) of ML models in ... Master Thesis Arctic University of Waterloo, Canada: Institutional Repository Arctic |
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University of Waterloo, Canada: Institutional Repository |
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ftunivwaterloo |
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English |
description |
Snow cover is one of the cryosphere's most critical components, representing a vital geophysical variable for climate and hydrology. Monitoring snow cover in Arctic regions has gained increasing significance, particularly considering recent climate warming. Given the complex spatiotemporal variability, inconvenience of transportation, and the remote locations of many snow-covered areas, remote sensing emerges as an ideal technique for data collection to monitor snow cover across various spatiotemporal scales. In contrast to optical remote sensing, passive microwave (PMW) and active microwave (AMW) satellite sensors remain unaffected by clouds and solar illumination, making them widely employed in snow detection. PMW observations have lower spatial resolution and high temporal resolution than AMW, which are suitable for large-scale snow mapping. Integrating optical data and PMW data can significantly enhance the quality of snow cover information. Various machine learning (ML) methods have been pivotal in environmental remote-sensing research in recent years. With the surge in Earth observation big data and the rapid advancements in ML techniques, an array of innovative methods has emerged to facilitate environmental monitoring on a global scale. Thus, a snow-monitoring method has been proposed based on multi-source remote sensing data and ML. The brightness temperature (Tb) data derived from the Advanced Microwave Scanning Radiometer E/2 (AMSR-E/2) Level 3 product and Moderate Resolution Imaging Spectroradiometer (MODIS) snow product serves as the reference for snow cover area (SCA). This study predominantly selects Oct, Dec, Feb, and Apr from 2012 to 2022 as the study periods. The research uses three ML methods, Logistic Regression (LR), Random Forest (RF) and Support Vector Machine (SVM), for snow cover detection based on PMW and MODIS data in the Arctic. The overall accuracy (The ratio of correctly classified as snow plus correctly classified as non-snow points to the total number of points) of ML models in ... |
format |
Master Thesis |
author |
Du, Jiayi |
spellingShingle |
Du, Jiayi Snow Mapping from Passive Microwave Brightness Temperature and MODIS Snow Product with Machine learning Approaches |
author_facet |
Du, Jiayi |
author_sort |
Du, Jiayi |
title |
Snow Mapping from Passive Microwave Brightness Temperature and MODIS Snow Product with Machine learning Approaches |
title_short |
Snow Mapping from Passive Microwave Brightness Temperature and MODIS Snow Product with Machine learning Approaches |
title_full |
Snow Mapping from Passive Microwave Brightness Temperature and MODIS Snow Product with Machine learning Approaches |
title_fullStr |
Snow Mapping from Passive Microwave Brightness Temperature and MODIS Snow Product with Machine learning Approaches |
title_full_unstemmed |
Snow Mapping from Passive Microwave Brightness Temperature and MODIS Snow Product with Machine learning Approaches |
title_sort |
snow mapping from passive microwave brightness temperature and modis snow product with machine learning approaches |
publisher |
University of Waterloo |
publishDate |
2024 |
url |
http://hdl.handle.net/10012/20288 |
geographic |
Arctic |
geographic_facet |
Arctic |
genre |
Arctic |
genre_facet |
Arctic |
op_relation |
http://hdl.handle.net/10012/20288 |
_version_ |
1790596927382880256 |