Title :
Noise reduction in gridded airs brightness temperature grids using the MODIS Obscov algorithm
Author :
Chapman, David ; Halem, Milton ; Nguyen, Phuong ; Avery, Jeff
Author_Institution :
Univ. of Maryland Baltimore County, Baltimore, MD, USA
Abstract :
We have adapted the MODIS Observation Coverage (Obscov) algorithm to the gridding of the AIRS L1b calibrated brightness temperatures, and developed a “Numeric-Obscov” implementation capable of utilizing the AIRS Tophat PSF dataset [1, 2]. We show that Obscov significantly reduces AIRS gridded-artifacts from a day to a season over winter 2005. The Obscov algorithm provides a physically accurate gridding model using spatial response information within the IFOV. Previously, Obscov has been used with an approximate triangular PSF, to allow for billions of integrals to be calculated per daily grid. We evaluated the Obscov algorithm via inter-comparison with MODIS-Aqua. Over a day, RMS noise is improved at high latitudes at 0.5°×1°. When averaged over a week or more, RMS noise is reduced globally by almost 40%.
Keywords :
geophysical techniques; optical transfer function; radiometry; remote sensing; AD 2005; AIRS L1b calibrated brightness temperature; AIRS Tophat PSF dataset; AIRS gridded-artifact; IFOV; MODIS Obscov algorithm; MODIS Observation Coverage; MODIS-Aqua; Numeric-Obscov implementation; RMS noise; approximate triangular PSF; gridded AIRS brightness temperature grid; gridding model; noise reduction; spatial response information; Brightness temperature; Clouds; Detectors; MODIS; Noise; Shape; AIRS; Gridding; MODIS; Obscov; Tophat;
Conference_Titel :
Geoscience and Remote Sensing Symposium (IGARSS), 2012 IEEE International
Conference_Location :
Munich
Print_ISBN :
978-1-4673-1160-1
Electronic_ISBN :
2153-6996
DOI :
10.1109/IGARSS.2012.6352333
