一种解决遥感正/逆问题的新方法

K. Stamnes, Wei Li, S. Stamnes, Yongxiang Hu, Yingzhen Zhou, N. Chen, Yongzhen Fan, B. Hamre, Xiaomei Lu, Yuping Huang, C. Weimer, Jennifer H. Lee, X. Zeng, J. Stamnes
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引用次数: 1

摘要

从介质反射或通过介质传输或由于内部源而由介质发射的电磁(EM)信号的反演可用于研究各种散射/吸收/发射材料的光学和物理性质。这些介质包括行星大气和表面(包括水/雪/冰)以及植物冠层。在许多情况下,从这种介质中产生的信号可以用线性传输方程来描述,在电磁辐射的情况下是辐射传递方程(RTE)。RTE的解可以作为正演模型来求解逆问题,以确定产生紧急(反射/传输/发射)电磁信号的介质状态参数。基于相关RTE的解,开发了一种新的方法来确定来自这种分层、多层介质的逐层贡献对紧急信号的贡献。作为如何应用这种方法的一个具体例子,从多层大气反射的辐射被用来解决与天基激光雷达系统的EM探测相关的问题。在单散射盛行的情况下,这些解决方案与使用标准激光雷达方法获得的结果一致,但这种新方法也可以在光学厚度、多重散射气溶胶和云层中产生可靠的结果,而传统激光雷达方法无法提供这些结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A novel approach to solve forward/inverse problems in remote sensing applications
Inversion of electromagnetic (EM) signals reflected from or transmitted through a medium, or emitted by it due to internal sources can be used to investigate the optical and physical properties of a variety of scattering/absorbing/emitting materials. Such media encompass planetary atmospheres and surfaces (including water/snow/ice), and plant canopies. In many situations the signals emerging from such media can be described by a linear transport equation which in the case of EM radiation is the radiative transfer equation (RTE). Solutions of the RTE can be used as a forward model to solve the inverse problem to determine the medium state parameters giving rise to the emergent (reflected/transmitted/emitted) EM signals. A novel method is developed to determine layer-by-layer contributions to the emergent signals from such stratified, multilayered media based on the solution of the pertinent RTE. As a specific example of how this approach may be applied, the radiation reflected from a multilayered atmosphere is used to solve the problem relevant for EM probing by a space-based lidar system. The solutions agree with those obtained using the standard lidar approach for situations in which single scattering prevails, but this novel approach also yields reliable results for optically thick, multiple scattering aerosol and cloud layers that cannot be provided by the traditional lidar approach.
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