Antarctic Time-Variable Regional Gravity Field Model Derived from Satellite Line-of-Sight Gravity Differences and Spherical Cap Harmonic Analysis

This study focuses on the development of a time-variable regional geo-potential model for Antarctica using the spherical cap harmonic analysis (SCHA) basis functions. The model is derived from line-of-sight gravity difference (LGD) measurements obtained from the GRACE-Follow-On (GFO) mission. The so...

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Published in:Remote Sensing
Main Authors: Mohsen Feizi, Mehdi Raoofian Naeeni, Jakob Flury
Format: Text
Language:English
Published: Multidisciplinary Digital Publishing Institute 2023
Subjects:
LGD
SCHA
time-variable gravity model
GFO
L2 JPL
Antarctic
Laplace
Antarc*
Antarctica
Online Access:https://doi.org/10.3390/rs15112815
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author Mohsen Feizi
Mehdi Raoofian Naeeni
Jakob Flury
author_facet Mohsen Feizi
Mehdi Raoofian Naeeni
Jakob Flury
author_sort Mohsen Feizi
collection MDPI Open Access Publishing
container_issue 11
container_start_page 2815
container_title Remote Sensing
container_volume 15
description This study focuses on the development of a time-variable regional geo-potential model for Antarctica using the spherical cap harmonic analysis (SCHA) basis functions. The model is derived from line-of-sight gravity difference (LGD) measurements obtained from the GRACE-Follow-On (GFO) mission. The solution of a Laplace equation for the boundary values over a spherical cap is used to expand the geo-potential coefficients in terms of Legendre functions with a real degree and integer order suitable for regional modelling, which is used to constrain the geo-potential coefficients using LGD measurements. To validate the performance of the SCHA, it is first utilized with LGD data derived from a L2 JPL (Level 2 product of the Jet Propulsion Laboratory). The obtained LGD data are used to compute the local geo-potential model up to Kmax = 20, corresponding to the SH degree and order up to 60. The comparison of the radial gravity on the Earth’s surface map across Antarctica with the corresponding radial gravity components of the L2 JPL is carried out using local geo-potential coefficients. The results of this comparison provide evidence that these basis functions for Kmax = 20 are valid across the entirety of Antarctica. Subsequently, the analysis proceeds using LGD data obtained from the Level 1B product of GFO by transforming these LGD data into the SCHA coordinate system and applying them to constrain the SCHA harmonic coefficients up to Kmax = 20. In this case, several independent LGD profiles along the trajectories of the satellites are devised to verify the accuracy of the local model. These LGD profiles are not employed in the inverse problem of determining harmonic coefficients. The results indicate that using regional harmonic basis functions, specifically spherical cap harmonic analysis (SCHA) functions, leads to a close estimation of LGD compared to the L2 JPL. The regional harmonic basis function exhibits a root mean square error (RMSE) of 3.71 × 10−4 mGal. This represents a substantial improvement over the ...
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genre Antarc*
Antarctic
Antarctica
genre_facet Antarc*
Antarctic
Antarctica
geographic Antarctic
Laplace
geographic_facet Antarctic
Laplace
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institution Open Polar
language English
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op_doi https://doi.org/10.3390/rs15112815
op_relation Environmental Remote Sensing
https://dx.doi.org/10.3390/rs15112815
op_rights https://creativecommons.org/licenses/by/4.0/
op_source Remote Sensing; Volume 15; Issue 11; Pages: 2815
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spelling ftmdpi:oai:mdpi.com:/2072-4292/15/11/2815/ 2025-01-16T19:39:19+00:00 Antarctic Time-Variable Regional Gravity Field Model Derived from Satellite Line-of-Sight Gravity Differences and Spherical Cap Harmonic Analysis Mohsen Feizi Mehdi Raoofian Naeeni Jakob Flury agris 2023-05-29 application/pdf https://doi.org/10.3390/rs15112815 EN eng Multidisciplinary Digital Publishing Institute Environmental Remote Sensing https://dx.doi.org/10.3390/rs15112815 https://creativecommons.org/licenses/by/4.0/ Remote Sensing; Volume 15; Issue 11; Pages: 2815 LGD SCHA time-variable gravity model GFO L2 JPL Text 2023 ftmdpi https://doi.org/10.3390/rs15112815 2023-08-01T10:16:02Z This study focuses on the development of a time-variable regional geo-potential model for Antarctica using the spherical cap harmonic analysis (SCHA) basis functions. The model is derived from line-of-sight gravity difference (LGD) measurements obtained from the GRACE-Follow-On (GFO) mission. The solution of a Laplace equation for the boundary values over a spherical cap is used to expand the geo-potential coefficients in terms of Legendre functions with a real degree and integer order suitable for regional modelling, which is used to constrain the geo-potential coefficients using LGD measurements. To validate the performance of the SCHA, it is first utilized with LGD data derived from a L2 JPL (Level 2 product of the Jet Propulsion Laboratory). The obtained LGD data are used to compute the local geo-potential model up to Kmax = 20, corresponding to the SH degree and order up to 60. The comparison of the radial gravity on the Earth’s surface map across Antarctica with the corresponding radial gravity components of the L2 JPL is carried out using local geo-potential coefficients. The results of this comparison provide evidence that these basis functions for Kmax = 20 are valid across the entirety of Antarctica. Subsequently, the analysis proceeds using LGD data obtained from the Level 1B product of GFO by transforming these LGD data into the SCHA coordinate system and applying them to constrain the SCHA harmonic coefficients up to Kmax = 20. In this case, several independent LGD profiles along the trajectories of the satellites are devised to verify the accuracy of the local model. These LGD profiles are not employed in the inverse problem of determining harmonic coefficients. The results indicate that using regional harmonic basis functions, specifically spherical cap harmonic analysis (SCHA) functions, leads to a close estimation of LGD compared to the L2 JPL. The regional harmonic basis function exhibits a root mean square error (RMSE) of 3.71 × 10−4 mGal. This represents a substantial improvement over the ... Text Antarc* Antarctic Antarctica MDPI Open Access Publishing Antarctic Laplace ENVELOPE(141.467,141.467,-66.782,-66.782) Remote Sensing 15 11 2815
spellingShingle LGD
SCHA
time-variable gravity model
GFO
L2 JPL
Mohsen Feizi
Mehdi Raoofian Naeeni
Jakob Flury
Antarctic Time-Variable Regional Gravity Field Model Derived from Satellite Line-of-Sight Gravity Differences and Spherical Cap Harmonic Analysis
title Antarctic Time-Variable Regional Gravity Field Model Derived from Satellite Line-of-Sight Gravity Differences and Spherical Cap Harmonic Analysis
title_full Antarctic Time-Variable Regional Gravity Field Model Derived from Satellite Line-of-Sight Gravity Differences and Spherical Cap Harmonic Analysis
title_fullStr Antarctic Time-Variable Regional Gravity Field Model Derived from Satellite Line-of-Sight Gravity Differences and Spherical Cap Harmonic Analysis
title_full_unstemmed Antarctic Time-Variable Regional Gravity Field Model Derived from Satellite Line-of-Sight Gravity Differences and Spherical Cap Harmonic Analysis
title_short Antarctic Time-Variable Regional Gravity Field Model Derived from Satellite Line-of-Sight Gravity Differences and Spherical Cap Harmonic Analysis
title_sort antarctic time-variable regional gravity field model derived from satellite line-of-sight gravity differences and spherical cap harmonic analysis
topic LGD
SCHA
time-variable gravity model
GFO
L2 JPL
topic_facet LGD
SCHA
time-variable gravity model
GFO
L2 JPL
url https://doi.org/10.3390/rs15112815

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