Performance of FFT methods in local gravity field modelling
Abstract
Fast Fourier transform (FFT) methods provide a fast and efficient means of processing large amounts of gravity or geoid data in local gravity field modelling. The FFT methods, however, has a number of theoretical and practical limitations, especially the use of flat-earth approximation, and the requirements for gridded data. In spite of this the method often yields excellent results in practice when compared to other more rigorous (and computationally expensive) methods, such as least-squares collocation. The good performance of the FFT methods illustrate that the theoretical approximations are offset by the capability of taking into account more data in larger areas, especially important for geoid predictions. For best results good data gridding algorithms are essential. In practice truncated collocation approaches may be used. For large areas at high latitudes the gridding must be done using suitable map projections such as UTM, to avoid trivial errors caused by the meridian convergence. The FFT methods are compared to ground truth data in New Mexico (xi, eta from delta g), Scandinavia (N from delta g, the geoid fits to 15 cm over 2000 km), and areas of the Atlantic (delta g from satellite altimetry using Wiener filtering). In all cases the FFT methods yields results comparable or superior to other methods.
- Publication:
-
Progress in the Determination of the Earth's Gravity Field
- Pub Date:
- June 1989
- Bibcode:
- 1989pdeg.rept..100F
- Keywords:
-
- Data Processing;
- Fast Fourier Transformations;
- Geodesy;
- Gravitational Fields;
- Mathematical Models;
- Satellite Altimetry;
- Algorithms;
- Collocation;
- Least Squares Method;
- Spherical Harmonics;
- Geophysics