Augmented Gravity Field Modelling by Combining EIGEN_6C4 and Topographic Potential Models
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Published:2023-07-06
Issue:13
Volume:15
Page:3418
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ISSN:2072-4292
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Container-title:Remote Sensing
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language:en
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Short-container-title:Remote Sensing
Author:
Zhang Panpan12, Bao Lifeng2, Ma Yange1, Liu Xinyu3
Affiliation:
1. College of Civil Engineering, Henan University of Engineering, Zhengzhou 451191, China 2. State Key Laboratory of Geodesy and Earth’s Dynamics, Innovation Academy for Precision Measurement, Science and Technology, Chinese Academy of Sciences, Wuhan 430077, China 3. Institute of Geospatial Information, Information Engineering University, Zhengzhou 450001, China
Abstract
One of the key goals of geodesy is to study the fine structure of the Earth’s gravity field and construct a high-resolution gravity field model (GFM). Aiming at the current insufficient resolution problem of the EIGEN_6C4 model, the refined ultra-high degree models EIGEN_3660 and EIGEN_5480 are determined with a spectral expansion approach in this study, which is to augment EIGEN_6C4 model using topographic potential models (TPMs). A comparative spectral evaluation for EIGEN_6C4, EIGEN_3660, and EIGEN_5480 models indicates that the gravity field spectral powers of EIGEN_3660 and EIGEN_5480 models outperform the EIGEN_6C4 model after degree 2000. The augmented models EIGEN_3660 and EIGEN_5480 are verified using the deflection of the vertical (DOV) of China and Colorado, gravity data from Australia and mainland America, and GNSS/leveling in China. The validation results indicate that the accuracy of EIGEN_3660 and EIGEN_5480 models in determining height anomaly, DOV, and gravity anomaly outperform the EIGEN_6C4 model, and the EIGEN_5480 model has optimal accuracy. The accuracy of EIGEN_5480 model in determining south–north component and east–west component of the DOV in China has been improved by about 21.1% and 23.1% compared to the EIGEN_6C4 model, respectively. In the mountainous Colorado, the accuracy of EIGEN_5480 model in determining south–north component and east–west component of the DOV has been improved by about 28.2% and 35.2% compared to EIGEN_6C4 model, respectively. In addition, gravity value comparison results in Australia and mainland America indicate that the accuracy of the EIGEN_5480 model for deriving gravity anomalies is improved by 16.5% and 11.3% compared to the EIGEN_6C4 model, respectively.
Funder
National Natural Science Foundation of China Henan Province Science and Technology Research Project
Subject
General Earth and Planetary Sciences
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