论文信息 - An extension to the split-window technique giving improved atmospheric correction and total water vapour

An extension to the split-window technique giving improved atmospheric correction and total water vapour

Abstract Satellite remote sensing of ocean and lake surface temperature is of considerable importance for climate research, but the main problem with thermal infrared measurements is the determination of the atmospheric correction. We present a novel extension to the split-window method to retrieve the total atmospheric transmittance, and demonstrate the use of this information in improved algorithms for sea surface temperature (SST) and total column content of water vapour. Simulation studies, using radiosonde profiles and an atmospheric transmission model, show that the new SST algorithm has an intrinsic precision of ∼01 degKr.m.s. (representing an improvement by a factor of 2-4 over conventional algorithms) and that atmospheric water vapour content can be retrieved with an accuracy of ∼ 5 per cent independent of its absolute value. We also discuss potential sources of error and future applications of the technique.

Andrew Harris | I. Mason | A. Harris | I. M. Mason

[1] Peter J. Minnett,et al. Satellite multichannel infrared measurements of sea surface temperature of the N.E. Atlantic Ocean using AVHRR/2 , 1984 .

[2] I. J. Barton,et al. Dual channel satellite measurements of sea surface temperature , 1983 .

[3] E. Paul McClain,et al. Multiple Atmospheric-Window Techniques for Satellite-Derived Sea Surface Temperatures , 1981 .

[4] E. Paul McClain,et al. Global sea surface temperatures and cloud clearing for aerosol optical depth estimates , 1989 .

[5] P. Schluessel,et al. Satellite-derived low-level atmospheric water vapour content from synergy of AVHRR with HIRS , 1989 .

[6] T. Phulpin,et al. Atmospheric correction of infrared measurements of sea surface temperature using channels at 3.7, 11 and 12 Μm , 1980 .