期刊论文详细信息
REMOTE SENSING OF ENVIRONMENT 卷:112
Correction of aerosol effects on multi-temporal images acquired with constant viewing angles: Application to Formosat-2 images
Article
Hagolle, O.1,2  Dedieu, G.2  Mougenot, B.2  Debaecker, V.2  Duchemin, B.2  Meygret, A.1 
[1] CNES, F-31401 Toulouse 4, France
[2] CESBIO, Unite Mixte CNES CNRS IRD UPS, F-31401 Toulouse 4, France
关键词: atmospheric correction;    aerosols;    multi-temporal measurement;    ven mu s;    formosat-2;    constant viewing angle;   
DOI  :  10.1016/j.rse.2007.08.016
来源: Elsevier
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【 摘 要 】

This paper presents a new method developed for the atmospheric correction of the images that will be acquired by the Ven mu s satellite after its launch expected in early 2010. Every two days, the Ven mu s mission will provide 10 m resolution images of 50 sites, in 12 narrow spectral bands ranging from 415 run to 910 nm. The sun-synchronous Ven mu s orbit will have a 2-day repeat cycle, and the images of a given site will always be acquired from the same place, at the same local hour, with constant observation angles. Thanks to these characteristics, the directional effects will be considerably reduced since only the solar angles will slowly vary with time. The algorithm that will be implemented for the atmospheric correction of Ven mu s data is being developed using both radiative transfer simulations and the actual data acquired by the Formosat-2 satellite. Because of its one-day sun-synchronous repeat cycle, Formosat-2 acquires images with a sun-viewing geometry close to the one Ven mu s will offer. With this geometry, reflectance time series are free from directional effects on the short term, a feature which reduces the number of unknowns to retrieve. The atmospheric corrections algorithm exploits this feature and the two following assumptions: - Aerosol optical properties vary quickly with time but slowly with location. - Surface reflectances vary quickly with location but slowly with time. Consequently, the top of atmosphere reflectance short term variations (10 to 15 days) are mainly due to the variations of aerosol optical properties, and it is thus possible to use these variations to characterise the atmospheric aerosols and to retrieve surface reflectances. This paper first describes the aerosol inversion method we developed and its results when applied to simulations. In the second part, we show the first tests of the method against three data sets acquired by Formosat-2 images with constant observation angles. Aeronet sun photometers measurements were available on all sites. Formosat-2 estimates of optical thickness compare favourably with Aeronet in situ measurements, leading to a noticeable improvement of the smoothness of time series of surface reflectances after atmospheric correction. (c) 2007 Elsevier Inc. All rights reserved.

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