A tutorial assessment of atmospheric height uncertainties for high-precision satellite altimeter missions to monitor ocean currents
Abstract
Information from a number of sources is synthesized, and an error budget is deduced giving the projected overall height uncertainty correction for a suggested next-generation high-precision radar altimeter. Uncertainties deriving from the wet and dry troposphere, clouds, and the ionosphere are reviewed. It is assumed that the next generation of precision altimeters will be dual-frequency (13.5 and 6 GHz) and will be designed to correct for the ionospheric error. The altimeter-carrying satellite will have a nadir pointing near coincident-beam dual-frequency microwave radiometer for mitigating the wet tropospheric uncertainty. Whereas there are a number of caveats, the combined uncertainty in the height correction due to the atmosphere for the suggested system should be nominally 3 cm rms compared with at least 6 cm associated with the Seasat-A mission. Improvements in height resolution of the kind discussed here are considered vital for future satellite missions designed to monitor ocean currents.
- Publication:
-
IEEE Transactions on Geoscience and Remote Sensing
- Pub Date:
- October 1982
- DOI:
- Bibcode:
- 1982ITGRS..20..418G
- Keywords:
-
- Atmospheric Effects;
- Error Analysis;
- Ocean Currents;
- Radio Altimeters;
- Satellite Observation;
- Atmospheric Attenuation;
- Atmospheric Scattering;
- Cloud Cover;
- Earth Ionosphere;
- Precipitation (Meteorology);
- Rain;
- Refractivity;
- Seasat Satellites;
- Troposphere;
- Water Vapor