Monitoring Bare Soil Freeze–Thaw Process Using GPS-Interferometric Reflectometry: Simulation and Validation

Frozen soil and permafrost affect ecosystem diversity and productivity as well as global energy and water cycles. Although some space-based Radar techniques or ground-based sensors can monitor frozen soil and permafrost variations, there are some shortcomings and challenges. For the first time, we u...

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Published in:Remote Sensing
Main Authors: Xuerui Wu, Shuanggen Jin, Liang Chang
Format: Article in Journal/Newspaper
Language:English
Published: MDPI AG 2017
Subjects:
Q
Online Access:https://doi.org/10.3390/rs10010014
https://doaj.org/article/7b14abbfbe9f498e8a86431685b7efb1
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spelling ftdoajarticles:oai:doaj.org/article:7b14abbfbe9f498e8a86431685b7efb1 2023-05-15T17:57:38+02:00 Monitoring Bare Soil Freeze–Thaw Process Using GPS-Interferometric Reflectometry: Simulation and Validation Xuerui Wu Shuanggen Jin Liang Chang 2017-12-01T00:00:00Z https://doi.org/10.3390/rs10010014 https://doaj.org/article/7b14abbfbe9f498e8a86431685b7efb1 EN eng MDPI AG https://www.mdpi.com/2072-4292/10/1/14 https://doaj.org/toc/2072-4292 2072-4292 doi:10.3390/rs10010014 https://doaj.org/article/7b14abbfbe9f498e8a86431685b7efb1 Remote Sensing, Vol 10, Iss 1, p 14 (2017) GPS-IR multipath permittivity soil freeze–thaw process Science Q article 2017 ftdoajarticles https://doi.org/10.3390/rs10010014 2022-12-31T04:02:06Z Frozen soil and permafrost affect ecosystem diversity and productivity as well as global energy and water cycles. Although some space-based Radar techniques or ground-based sensors can monitor frozen soil and permafrost variations, there are some shortcomings and challenges. For the first time, we use GPS-Interferometric Reflectometry (GPS-IR) to monitor and investigate the bare soil freeze–thaw process as a new remote sensing tool. The mixed-texture permittivity models are employed to calculate the frozen and thawed soil permittivities. When the soil freeze/thaw process occurs, there is an abrupt change in the soil permittivity, which will result in soil scattering variations. The corresponding theoretical simulation results from the forward GPS multipath simulator show variations of GPS multipath observables. As for the in-situ measurements, virtual bistatic radar is employed to simplify the analysis. Within the GPS-IR spatial resolution, one SNOTEL site (ID 958) and one corresponding PBO (plate boundary observatory) GPS site (AB33) are used for analysis. In 2011, two representative days (frozen soil on Doy of Year (DOY) 318 and thawed soil on DOY 322) show the SNR changes of phase and amplitude. The GPS site and the corresponding SNOTEL site in four different years are analyzed for comparisons. When the soil freeze/thaw process occurred and no confounding snow depth and soil moisture effects existed, it exhibited a good absolute correlation (|R| = 0.72 in 2009, |R| = 0.902 in 2012, |R| = 0.646 in 2013, and |R| = 0.7017 in 2014) with the average detrended SNR data. Our theoretical simulation and experimental results demonstrate that GPS-IR has potential for monitoring the bare soil temperature during the soil freeze–thaw process, while more test works should be done in the future. GNSS-R polarimetry is also discussed as an option for detection. More retrieval work about elevation and polarization combinations are the focus of future development. Article in Journal/Newspaper permafrost Directory of Open Access Journals: DOAJ Articles Remote Sensing 10 2 14
institution Open Polar
collection Directory of Open Access Journals: DOAJ Articles
op_collection_id ftdoajarticles
language English
topic GPS-IR
multipath
permittivity
soil freeze–thaw process
Science
Q
spellingShingle GPS-IR
multipath
permittivity
soil freeze–thaw process
Science
Q
Xuerui Wu
Shuanggen Jin
Liang Chang
Monitoring Bare Soil Freeze–Thaw Process Using GPS-Interferometric Reflectometry: Simulation and Validation
topic_facet GPS-IR
multipath
permittivity
soil freeze–thaw process
Science
Q
description Frozen soil and permafrost affect ecosystem diversity and productivity as well as global energy and water cycles. Although some space-based Radar techniques or ground-based sensors can monitor frozen soil and permafrost variations, there are some shortcomings and challenges. For the first time, we use GPS-Interferometric Reflectometry (GPS-IR) to monitor and investigate the bare soil freeze–thaw process as a new remote sensing tool. The mixed-texture permittivity models are employed to calculate the frozen and thawed soil permittivities. When the soil freeze/thaw process occurs, there is an abrupt change in the soil permittivity, which will result in soil scattering variations. The corresponding theoretical simulation results from the forward GPS multipath simulator show variations of GPS multipath observables. As for the in-situ measurements, virtual bistatic radar is employed to simplify the analysis. Within the GPS-IR spatial resolution, one SNOTEL site (ID 958) and one corresponding PBO (plate boundary observatory) GPS site (AB33) are used for analysis. In 2011, two representative days (frozen soil on Doy of Year (DOY) 318 and thawed soil on DOY 322) show the SNR changes of phase and amplitude. The GPS site and the corresponding SNOTEL site in four different years are analyzed for comparisons. When the soil freeze/thaw process occurred and no confounding snow depth and soil moisture effects existed, it exhibited a good absolute correlation (|R| = 0.72 in 2009, |R| = 0.902 in 2012, |R| = 0.646 in 2013, and |R| = 0.7017 in 2014) with the average detrended SNR data. Our theoretical simulation and experimental results demonstrate that GPS-IR has potential for monitoring the bare soil temperature during the soil freeze–thaw process, while more test works should be done in the future. GNSS-R polarimetry is also discussed as an option for detection. More retrieval work about elevation and polarization combinations are the focus of future development.
format Article in Journal/Newspaper
author Xuerui Wu
Shuanggen Jin
Liang Chang
author_facet Xuerui Wu
Shuanggen Jin
Liang Chang
author_sort Xuerui Wu
title Monitoring Bare Soil Freeze–Thaw Process Using GPS-Interferometric Reflectometry: Simulation and Validation
title_short Monitoring Bare Soil Freeze–Thaw Process Using GPS-Interferometric Reflectometry: Simulation and Validation
title_full Monitoring Bare Soil Freeze–Thaw Process Using GPS-Interferometric Reflectometry: Simulation and Validation
title_fullStr Monitoring Bare Soil Freeze–Thaw Process Using GPS-Interferometric Reflectometry: Simulation and Validation
title_full_unstemmed Monitoring Bare Soil Freeze–Thaw Process Using GPS-Interferometric Reflectometry: Simulation and Validation
title_sort monitoring bare soil freeze–thaw process using gps-interferometric reflectometry: simulation and validation
publisher MDPI AG
publishDate 2017
url https://doi.org/10.3390/rs10010014
https://doaj.org/article/7b14abbfbe9f498e8a86431685b7efb1
genre permafrost
genre_facet permafrost
op_source Remote Sensing, Vol 10, Iss 1, p 14 (2017)
op_relation https://www.mdpi.com/2072-4292/10/1/14
https://doaj.org/toc/2072-4292
2072-4292
doi:10.3390/rs10010014
https://doaj.org/article/7b14abbfbe9f498e8a86431685b7efb1
op_doi https://doi.org/10.3390/rs10010014
container_title Remote Sensing
container_volume 10
container_issue 2
container_start_page 14
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