Abstract
The paper is about a methodology to combine a noisy satellite-only global gravity field model (GGM) with other noisy datasets to estimate a local quasi-geoid model using weighted least-squares techniques. In this way, we attempt to improve the quality of the estimated quasi-geoid model and to complement it with a full noise covariance matrix for quality control and further data processing. The methodology goes beyond the classical remove–compute–restore approach, which does not account for the noise in the satellite-only GGM. We suggest and analyse three different approaches of data combination. Two of them are based on a local single-scale spherical radial basis function (SRBF) model of the disturbing potential, and one is based on a two-scale SRBF model. Using numerical experiments, we show that a single-scale SRBF model does not fully exploit the information in the satellite-only GGM. We explain this by a lack of flexibility of a single-scale SRBF model to deal with datasets of significantly different bandwidths. The two-scale SRBF model performs well in this respect, provided that the model coefficients representing the two scales are estimated separately. The corresponding methodology is developed in this paper. Using the statistics of the least-squares residuals and the statistics of the errors in the estimated two-scale quasi-geoid model, we demonstrate that the developed methodology provides a two-scale quasi-geoid model, which exploits the information in all datasets.
Highlights
We investigate the combination of a noisy satellite-only global gravity model (GGM) with noisy highresolution datasets to estimate a local quasi-geoid model using weighted leastsquares techniques
We investigated different approaches to estimate a local spherical radial basis function (SRBF) model of the disturbing potential using weighted least squares from a high-resolution dataset and a low-resolution dataset
The low-resolution dataset represents a satellite-only spherical harmonic model of the global gravity field equipped with a full noise covariance matrix
Summary
We investigate the combination of a noisy satellite-only global gravity model (GGM) with noisy highresolution datasets (e.g. terrestrial gravity anomalies) to estimate a local quasi-geoid model using weighted leastsquares techniques. Some numerical aspects were studied in Ågren (2004) and Ellmann (2004), in particular numerical instabilities when estimating the spectral weights, which naturally arise in local applications We follow another approach to local quasi-geoid modelling, which uses least-squares techniques to estimate the parameters of a local spherical radial basis function (SRBF) model of the disturbing potential from the available datasets. Some aspects related to the combination of data with different bandwidths have been discussed in Panet et al (2011); Naeimi (2013); Bentel and Schmidt (2016); Lieb et al (2016); Lieb (2017) They do not cover numerical studies about the combination of a GGM with full noise covariance matrix with high-resolution noisy datasets.
Sign-in/Register to view highlights & summary 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 callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
