期刊论文详细信息
REMOTE SENSING OF ENVIRONMENT 卷:159
Joint leaf chlorophyll content and leaf area index retrieval from Landsat data using a regularized model inversion system (REGFLEC)
Article
Houborg, Rasmus1  McCabe, Matthew F.1  Cescatti, Alessandro2  Gao, Feng3  Schull, Mitchell3  Gitelson, Anatoly4 
[1] King Abdullah Univ Sci & Technol, Water Desalinat & Reuse Ctr, Thuwal, Saudi Arabia
[2] European Commiss, Inst Environm & Sustainabil, Joint Res Ctr, Ispra, Italy
[3] USDA ARS, Hydrol & Remote Sensing Lab, Beltsville, MD USA
[4] Univ Nebraska, Sch Nat Resources, Ctr Adv Land Management Informat Technol, Lincoln, NE USA
关键词: Landsat;    Leaf chlorophyll;    LAI;    SAIL;    PROSPECT;    Canopy reflectance;    Model inversion;   
DOI  :  10.1016/j.rse.2014.12.008
来源: Elsevier
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【 摘 要 】

Leaf area index (LAI) and leaf chlorophyll content (Chl(l)) represent key biophysical and biochemical controls on water, energy and carbon exchange processes in the terrestrial biosphere. In combination, [LAI and Chi(1), provide critical information on vegetation density, vitality and photosynthetic potentials. However, simultaneous retrieval of LAI and Chl(l) from space observations is extremely challenging. Regularization strategies are required to increase the robustness and accuracy of retrieved properties and enable more reliable separation of soil, leaf and canopy parameters. To address these challenges, the REGularized canopy reFLECtance model (REGFLEC) inversion system was refined to incorporate enhanced techniques for exploiting ancillary LAI and temporal information derived from multiple satellite scenes. In this current analysis, REGFLEC is applied to a time-series of Landsat data. A novel aspect of the REGFLEC approach is the fact that no site-specific data are required to calibrate the model, which may be run in a largely automated fashion using information extracted entirely from image-based and other widely available datasets. Validation results, based upon in-situ LAI and Chl(l) observations collected over maize and soybean fields in central Nebraska for the period 2001-2005, demonstrate Chl(l) retrieval with a relative root-mean-square-deviation (RMSD) on the order of 19% (RMSD = 8.42 pg cm(-2)). While Chli retrievals were clearly influenced by the version of the leaf optical properties model used (PROSPECT), the application of spatio-temporal regularization constraints was shown to be critical for estimating Chl(l) with sufficient accuracy. REGFLEC also reproduced the dynamics of in-situ measured LAI well (r(2) = 0.85), but estimates were biased low, particularly over maize (LAI was underestimated by -36 %). This disparity may be attributed to differences between effective and true LAI caused by significant foliage clumping not being properly accounted for in the canopy reflectance model (SAIL). Additional advances in the retrieval of canopy biophysical and leaf biochemical constituents will require innovative use of existing remote sensing data within physically realistic canopy reflectance models along with the ability to exploit the enhanced spectral and spatial capabilities of upcoming satellite systems. (C) 2014 Elsevier Inc. All rights reserved.

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