内陆水质遥感不确定性：问题综述

doi:10.11867/j.issn.1001-8166.2009.02.0150

内陆水质遥感是目前定量遥感领域的热点与难点，多种不确定性因素影响了内陆水质遥感的研究进展。较系统地总结了国内外近年来内陆水质遥感监测存在的突出问题与影响水质遥感监测精度的关键因素，具体从内陆水体光学特性的复杂性、大气校正的复杂性与水面反射光校正的不确定性、反演算法与生物光学模型的复杂性与区域性、现有传感器监测内陆水质在性能方面的局限性以及影响因素的复杂性与综合性几个方面进行了阐述，并指出了内陆水质遥感监测的研究重点与发展方向。

关键词: 内陆水体, 水质遥感, 不确定性, 遥感监测

Water quality remote sensing is the hot and difficult topic in the field of environment remote sensing. Various factors affect the improvement of inland water quality remote sensing precision. This paper comments on the outstanding problems existing in inland water quality remote sensing monitoring and some key factors influencing the water quality parameters information extraction precision both at home and abroad. The complexity of the optical characteristics of inland body embodies the independence of the water body components, the similarity of the characteristic spectrum and the coupling effects of water components signal and together with the temporal and spatial variation of the water optics. The uncertainty of atmosphere correction embodies the variation of atmospheric aerosol optical characteristics and the uncertainty of correction of reflected light from wave water surface. The complexity and regional characteristics of bio-optical models demand complex inversion algorithms. The scale effects and uncertainty of model validation are obvious for multi-source remote sensing data cooperative inversion. Inland water quality remote sensing differs from ocean color remote sensing, which demands remoted data with high spatial resolution, spectral resolution and temporal resolution. Therefore, the performance limitations of the available satellite sensors in inland water quality monitoring were discussed in detail. All the above-mentioned factors were complicated and integrated. The emphases and the development direction of inland water quality remote sensing were pointed out.

Key words: Inland water, Water quality remote sensing, Uncertainty, Remote sensing monitoring

中图分类号:

TP79

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摘要

Uncertainty Analysis of Inland Water Quality Remote Sensing: A Review