Abstract
The geolocation of Advanced Very High Resolution Radiometer (AVHRR) data is known to be imprecise due to minor satellite position and orbit uncertainties. These uncertainties lead to distortions once the data are projected based on the provided orbit parameters. This can cause geolocation errors of up to 10 km per pixel which is an obstacle for applications such as time series analysis, compositing/mosaicking of images, or the combination with other satellite data. Therefore, a fusion of two techniques to match the data in orbit projection has been developed to overcome this limitation, even without the precise knowledge of the orbit parameters. Both techniques attempt to find the best match between small image chips taken from a reference water mask in the first, and from a median Normalized Difference Vegetation Index (NDVI) mask in the second round. This match is determined shifting around the small image chips until the best correlation between reference and satellite data source is found for each respective image part. Only if both attempts result in the same shift in any direction, the position in the orbit is included in a third order polynomial warping process that will ultimately improve the geolocation accuracy of the AVHRR data. The warping updates the latitude and longitude layers and the contents of the data layers itself remain untouched. As such, original sensor measurements are preserved. An included automated quality assessment generates a quality layer that informs about the reliability of the matching.
Highlights
Since 1978, the National Oceanic and Atmospheric Administration (NOAA) operated the Advanced Very High Resolution Radiometer (AVHRR) onboard its Television Infrared ObservationSatellite (TIROS) and NOAA satellite platforms
The second possibility is to apply the compromised TLEs that already come with the raw data model itself result in more precise geolocation accuracy especially under partly clouded conditions, and try to correct the resulting pixel shifts with hindsight as it was applied to the Canadian it is difficult toProcessing incorporate flight maneuvers executed during the overpass
The described procedure to improve geolocation accuracy relying on a two-step chip matching approach was applied to nearly 600 High-Resolution Picture Transmission (HRPT) datasets
Summary
Since 1978, the National Oceanic and Atmospheric Administration (NOAA) operated the Advanced Very High Resolution Radiometer (AVHRR) onboard its Television Infrared Observation. Since 2006, the AVHRR sensors are mounted aboard the Meteorological Operational Satellites (MetOp) operated by Eumetsat, delivering daily observations of the globe in visible, near infrared, and thermal wavelengths. Three different generations of AVHRR sensors have been developed over the decades, providing observations from four, five, and six spectral channels, respectively. The resolution of the High-Resolution Picture Transmission (HRPT) format data at nadir is around 1.1 km but widens up to 6.5 km with the observation angle, which spans to a maximum of ±55.4 degrees from the nadir [1].
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