Chen, Yueli ORCID: https://orcid.org/0009-0005-0428-4041; Li, Shile; Wang, Lingxiao; Mittermeier, Magdalena ORCID: https://orcid.org/0000-0002-8668-281X; Bernier, Monique ORCID: https://orcid.org/0000-0002-7812-4965 et Ludwig, Ralf (2024). Retrieving freeze-thaw states using deep learning with remote sensing data in permafrost landscapes. International Journal of Applied Earth Observation and Geoinformation , vol. 126 . p. 103616. DOI: 10.1016/j.jag.2023.103616.
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The soil freeze–thaw (FT) cycle is a critical component of the terrestrial cryosphere and plays a significant role in hydrological, ecological, climatic, and biogeochemical processes within permafrost landscapes. The FT states can be monitored with in-situ field measurements, but these procedures are costly and limited to single chosen sites. Remote sensing data provides the opportunity to collect information repeatedly across extensive geographical areas. To explore a more effective way to monitor the FT states in the terrestrial cryosphere, in this study, we used microwave and optical remote sensing data and introduced the Deep Learning approach to simulate the soil FT states in the western part of Nunavik, Canada. Two networks, Multilayer Perceptron (MLP) and Convolutional Neural Network (CNN), were trained and tested with over 35,000 and approximately 54,000 randomly selected data samples, respectively. The trained CNN networks outperformed the MLP networks, achieving the highest testing accuracy of 95.67% and the highest validation accuracy of 87.28% based on ground truth data from 32 measurement stations from all seasons across the year. This study proposed the reference periods concept for convenient labeling in data preparation and tested different combinations of influence variables to achieve better transferability of the method for future studies. Our findings offer a more effective way to monitor FT states in the terrestrial cryosphere, offering valuable insights into the consequences of climate change on permafrost landscapes. Moreover, the suggested deep learning approach can be easily expanded when additional input sources are accessible. This expansion has the potential to further improve the model's performance for the FT retrieval.
Type de document: | Article |
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Mots-clés libres: | freeze-thaw state; permafrost landscape; sentinel-1; backscatter; deep learning; Convolutional Neural Network (CNN) |
Centre: | Centre Eau Terre Environnement |
Date de dépôt: | 31 juill. 2024 20:20 |
Dernière modification: | 31 juill. 2024 20:20 |
URI: | https://espace.inrs.ca/id/eprint/15503 |
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