Global sensitivity analysis of simulated remote sensing polarimetric observations over snow

IF 3.2 3区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES
Matteo Ottaviani, Gabriel Harris Myers, Nan Chen
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引用次数: 0

Abstract

Abstract. This study presents a detailed theoretical assessment of the information content of passive polarimetric observations over snow scenes, using a global sensitivity analysis (GSA) method. Conventional sensitivity studies focus on varying a single parameter while keeping all other parameters fixed. In contrast, the GSA correctly addresses the covariance of state parameters across their entire parameter space, hence favoring a more correct interpretation of inversion algorithms and the optimal design of their state vectors. The forward simulations exploit a vector radiative transfer model to obtain the Stokes vector emerging at the top of the atmosphere for different solar zenith angles, when the bottom boundary consists of a vertically resolved snowpack of non-spherical grains. The presence of light-absorbing particulates (LAPs), either embedded in the snow or aloft in the atmosphere above in the form of aerosols, is also considered. The results are presented for a set of wavelengths spanning the visible (VIS), near-infrared (NIR), and shortwave infrared (SWIR) region of the spectrum. The GSA correctly captures the expected, high sensitivity of the reflectance to LAPs in the VIS–NIR and to grain size at different depths in the snowpack in the NIR–SWIR. With adequate viewing geometries, mono-angle measurements of total reflectance in the VIS–SWIR (akin to those of the Moderate Resolution Imaging Spectroradiometer, MODIS) resolve grain size in the top layer of the snowpack sufficiently well. The addition of multi-angle polarimetric observations in the VIS–NIR provides information on grain shape and microscale roughness. The simultaneous sensitivity in the VIS–NIR to both aerosols and snow-embedded impurities can be disentangled by extending the spectral range to the SWIR, which contains information on aerosol optical depth while remaining essentially unaffected when the same particulates are mixed with the snow. Multi-angle polarimetric observations can therefore (i) effectively partition LAPs between the atmosphere and the surface, which represents a notorious challenge for snow remote sensing based on measurements of total reflectance only and (ii) lead to better estimates of grain shape and roughness and, in turn, the asymmetry parameter, which is critical for the determination of albedo. The retrieval uncertainties are minimized when the degree of linear polarization is used in place of the polarized reflectance. The Sobol indices, which are the main metric for the GSA, were used to select the state parameters in retrievals performed on data simulated for multiple instrument configurations. Improvements in retrieval quality with the addition of measurements of polarization, multi-angle views, and different spectral channels reflect the information content, identified by the Sobol indices, relative to each configuration. The results encourage the development of new remote sensing algorithms that fully leverage multi-angle and polarimetric capabilities of modern remote sensors. They can also aid flight planning activities, since the optimal exploitation of the information content of multi-angle measurements depends on the viewing geometry. The better characterization of surface and atmospheric parameters in snow-covered regions advances research opportunities for scientists of the cryosphere and ultimately benefits albedo estimates in climate models.
雪地上空模拟遥感极坐标观测的全球敏感性分析
摘要本研究采用全局灵敏度分析(GSA)方法,对雪景上被动极坐标观测的信息含量进行了详细的理论评估。传统的灵敏度研究侧重于改变单一参数,而其他参数则保持不变。与此相反,全局灵敏度分析能正确处理整个参数空间的状态参数协方差,从而有利于更正确地解释反演算法和优化设计其状态向量。前向模拟利用矢量辐射传递模型,获得了不同太阳天顶角度下大气顶部出现的斯托克斯矢量,此时大气底部边界由垂直分辨的非球形颗粒雪堆组成。此外,还考虑了光吸收微粒(LAPs)的存在,这些微粒或嵌入雪中,或以气溶胶的形式存在于大气层的上方。结果显示了光谱中可见光 (VIS)、近红外 (NIR) 和短波红外 (SWIR) 波段的一组波长。在可见光-近红外波段,GSA 能正确捕捉到反射率对 LAPs 的预期高灵敏度;在近红外-短波红外波段,GSA 能正确捕捉到反射率对雪堆不同深度的颗粒大小的预期高灵敏度。在适当的观测几何条件下,VIS-SWIR 总反射率的单角度测量(类似于中分辨率成像分光仪的测量)可以很好地解析雪层顶层的粒度。在 VIS-NIR 中增加多角度偏振观测,可提供有关晶粒形状和微观粗糙度的信息。通过将光谱范围扩展到 SWIR,可将 VIS-NIR 同时对气溶胶和雪中杂质的敏感性区分开来,SWIR 包含气溶胶光学深度信息,而当相同颗粒与雪混合时,SWIR 基本不受影响。因此,多角度偏振测量观测可以:(i) 在大气和地表之间有效划分 LAPs,这对于仅基于全反射测量的雪地遥感来说是一个众所周知的挑战;(ii) 更好地估算颗粒形状和粗糙度,进而估算对确定反照率至关重要的不对称参数。如果用线性偏振度代替偏振反射率,检索的不确定性就会降到最低。索布尔指数是全球定位系统的主要衡量标准,在对多种仪器配置的模拟数据进行检索时用于选择状态参数。在增加偏振测量、多角度视图和不同光谱通道后,检索质量有所提高,这反映了索博尔指数所确定的相对于每种配置的信息含量。这些结果有助于开发新的遥感算法,充分利用现代遥感器的多角度和偏振测量能力。这些结果还有助于飞行规划活动,因为对多角度测量信息内容的最佳利用取决于观测几何形状。更好地确定积雪覆盖地区的地表和大气参数,将为冰冻圈科学家提供更多的研究机会,并最终有利于气候模型中的反照率估算。
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来源期刊
Atmospheric Measurement Techniques
Atmospheric Measurement Techniques METEOROLOGY & ATMOSPHERIC SCIENCES-
CiteScore
7.10
自引率
18.40%
发文量
331
审稿时长
3 months
期刊介绍: Atmospheric Measurement Techniques (AMT) is an international scientific journal dedicated to the publication and discussion of advances in remote sensing, in-situ and laboratory measurement techniques for the constituents and properties of the Earth’s atmosphere. The main subject areas comprise the development, intercomparison and validation of measurement instruments and techniques of data processing and information retrieval for gases, aerosols, and clouds. The manuscript types considered for peer-reviewed publication are research articles, review articles, and commentaries.
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