AFRGDB V2.3: The Updated Gravity Database for Africa using RTM Technique
Abd-Elmotaal, H., Seitz, K., Kühtreiber, N., Heck, B., Kutterer, H. (2024). AFRGDB V2.3: The Updated Gravity Database for Africa using RTM Technique. EKB Journal Management System, 43(2), 43-51. doi: 10.21608/jaet.2022.149901.1219
Hussein A. Abd-Elmotaal; Kurt Seitz; Norbert Kühtreiber; Bernhard Heck; Hansjörg Kutterer. "AFRGDB V2.3: The Updated Gravity Database for Africa using RTM Technique". EKB Journal Management System, 43, 2, 2024, 43-51. doi: 10.21608/jaet.2022.149901.1219
Abd-Elmotaal, H., Seitz, K., Kühtreiber, N., Heck, B., Kutterer, H. (2024). 'AFRGDB V2.3: The Updated Gravity Database for Africa using RTM Technique', EKB Journal Management System, 43(2), pp. 43-51. doi: 10.21608/jaet.2022.149901.1219
Abd-Elmotaal, H., Seitz, K., Kühtreiber, N., Heck, B., Kutterer, H. AFRGDB V2.3: The Updated Gravity Database for Africa using RTM Technique. EKB Journal Management System, 2024; 43(2): 43-51. doi: 10.21608/jaet.2022.149901.1219

AFRGDB V2.3: The Updated Gravity Database for Africa using RTM Technique

Journal of Advanced Engineering Trends
Volume 43, Issue 2, July 2024, Page 43-51  XML PDF (2 MB)
Document Type: Original Article
DOI: 10.21608/jaet.2022.149901.1219
View on SCiNiTO View on SCiNiTO
Authors
Hussein A. Abd-Elmotaal email orcid 1; Kurt Seitz2; Norbert Kühtreiber3; Bernhard Heck2; Hansjörg Kutterer2
1Civil Engineering Department, Faculty of Engineering, Minia University
2Karlsruhe Institute of Technology, Germany
3Graz University of Technology, Austria
Abstract
In the framework of the activities of the IAG sub-commission on gravity and geoid in Africa, it is needed to have a uniform gridded gravity data set to determine the earth’s mathematical surface (the geoid) in Africa using Stokes’ integral in either the frequency or space domain. The available gravity data set for Africa consists of land point gravity data as well as shipborne and altimetry-derived gravity anomaly data. The available gravity data set has significantly large gaps, while in some particular areas the distribution is fairly dense. Also the shipborne and altimetry data have a line structure (along tracks). This leads to a problem in determining a reasonable empirical covariance function, and consequently limits the capability of the used least-squares prediction technique. Filtering the available gravity data and degrading the ocean gravity data took place to overcome this problem. The establishment of the updated gravity database for Africa has been carried-out using the well-known RTM reduction technique, employing a weighted least-squares prediction technique. The land gravity data get the highest precision, while the shipborne and altimetry gravity data get a moderate precision. The data gaps are filled with gravity anomalies derived from the GOCE_DIR_R5 global reference model, getting the lowest precision within the prediction technique. The weighted least-squares prediction technique is thus carried-out to estimate gridded gravity anomalies. The updated gravity database AFRGDB_V2.3 has been established after performing the proper RTM restore step. The precision of the developed gravity database is tested on internal and external levels.
Keywords
Africa; RTM reduction technique; gravity database; geoid determination; weighted least-squares prediction
Supplementary Files
Statistics
Article View: 141
PDF Download: 141