Abstract
This work shows improvements of geoid undulation values obtained from a high-resolution Global Geopotential Model (GGM), applied to local urban areas. The methodology employed made use of a Residual Terrain Model (RTM) to account for the topographic masses effect on the geoid. This effect was computed applying the spherical tesseroids approach for mass discretization. The required numerical integration was performed by 2-D integration with 1DFFT technique that combines DFT along parallels with direct numerical integration along meridians. In order to eliminate the GGM commission error, independent geoid undulations values obtained from a set of GNSS/leveling stations are employed. A corrector surface from the associated geoid undulation differences at the stations was generated through a polynomial regression model. The corrector surface, in addition to the GGM commission error, also absorbs the GNSS/leveling errors as well as datum inconsistencies and systematic errors of the data. The procedure was applied to five Mexican urban areas that have a geodetic network of GNSS/leveling points, which range from 166 to 811. Two GGM were evaluated: EGM2008 and XGM2019e_2159. EGM2008 was the model that showed relatively better agreement with the GNSS/leveling stations having differences with RMSE values in the range of 8–60 cm and standard deviations of 5–8 cm in four of the networks and 17 cm in one of them. The computed topographic masses contribution to the geoid were relatively small, having standard deviations on the range 1–24 mm. With respect to corrector surface estimations, they turned out to be fairly smooth yielding similar residuals values for two geoid models. This was also the case for the most recent Mexican gravity geoid GGM10. For the three geoid models, the second order polynomial regression model performed slightly better than the first order with differences up to 1 cm. These two models produced geoid correction residuals with a standard deviation in one test area of 14 cm while for the others it was of about 4–7 cm. However, the kriging method that was applied for comparison purposes produced slightly smaller values: 8 cm for one area and 4–6 cm for the others.
Highlights
Global Geopotential Models (GGM) have become an essential tool in geodesy as well as in other Earth Sciences and engineering field applications
A comparison of geoid undulation (N) values, as produced by the geoid models EGM2008, XGM2019e_2159, and GGM10 with respect to the corresponding values N obtained from Global NavigationSatellite System (GNSS)/leveling, was made
By observing the mean values of the geoid differences, we can appreciate that all the models have local biases ranging from −60 cm of EGM2008 at Merida region to 90 cm of GGM10 at Mexico City
Summary
Global Geopotential Models (GGM) have become an essential tool in geodesy as well as in other Earth Sciences and engineering field applications. It can be reduced by employing a Residual Terrain Model (RTM) through a Gravity Forward. A TGFM is produced by the gravitational potential generated by the attraction of the Earth’s topographic masses These masses are composed (constituent) mainly by rock, sand, water, and ice. TGFM models such as DTM2006.0 [22] and EARTH2014 [28] are given in terms of spherical harmonic coefficients and can be evaluated at any location on the. The numerical analysis is made on five Mexican urban areas
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
