The PACE-MAPP algorithm: Simultaneous aerosol and ocean polarimeter products using coupled atmosphere-ocean vector radiative transfer

S. Stamnes, Michael Jones, James G. Allen, E. Chemyakin, A. Bell, J. Chowdhary, Xu Liu, S. Burton, B. van Diedenhoven, O. Hasekamp, J. Hair, Yongxiang Hu, C. Hostetler, R. Ferrare, K. Stamnes, B. Cairns
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引用次数: 1

Abstract

We describe the PACE-MAPP algorithm that simultaneously retrieves aerosol and ocean optical parameters using multiangle and multispectral polarimeter measurements from the SPEXone, Hyper-Angular Rainbow Polarimeter 2 (HARP2), and Ocean Color Instrument (OCI) instruments onboard the NASA Plankton, Aerosol, Cloud, ocean Ecosystem (PACE) observing system. PACE-MAPP is adapted from the Research Scanning Polarimeter (RSP) Microphysical Aerosol Properties from Polarimetry (RSP-MAPP) algorithm. The PACE-MAPP algorithm uses a coupled vector radiative transfer model such that the atmosphere and ocean are always considered together as one system. Consequently, this physically consistent treatment of the system across the ultraviolet, (UV: 300–400 nm), visible (VIS: 400–700 nm), near-infrared (NIR: 700–1100 nm), and shortwave infrared (SWIR: 1100–2400 nm) spectral bands ensures that negative water-leaving radiances do not occur. PACE-MAPP uses optimal estimation to simultaneously characterize the optical and microphysical properties of the atmosphere’s aerosol and ocean constituents, find the optimal solution, and evaluate the uncertainties of each parameter. This coupled approach, together with multiangle, multispectral polarimeter measurements, enables retrievals of aerosol and water properties across the Earth’s oceans. The PACE-MAPP algorithm provides aerosol and ocean products for both the open ocean and coastal areas and is designed to be accurate, modular, and efficient by using fast neural networks that replace the time-consuming vector radiative transfer calculations in the forward model. We provide an overview of the PACE-MAPP framework and quantify its expected retrieval performance on simulated PACE-like data using a bimodal aerosol model for observations of fine-mode absorbing aerosols and coarse-mode sea salt particles. We also quantify its performance for observations over the ocean of dust-laden scenes using a trimodal aerosol model that incorporates non-spherical coarse-mode dust particles. Lastly, PACE-MAPP’s modular capabilities are described, and we discuss plans to implement a new ocean bio-optical model that uses a mixture of coated and uncoated particles, as well as a thin cirrus model for detecting and correcting for sub-visual ice clouds.
PACE-MAPP算法:使用耦合大气-海洋矢量辐射传输的同时气溶胶和海洋极化计产品
我们描述了PACE- mapp算法,该算法使用来自NASA浮游生物、气溶胶、云、海洋生态系统(PACE)观测系统上的SPEXone、超角度彩虹偏振计2 (HARP2)和海洋颜色仪器(OCI)的多角度和多光谱偏振计测量数据同时检索气溶胶和海洋光学参数。PACE-MAPP是改编自研究扫描偏振仪(RSP)微物理气溶胶特性偏振仪(RSP- mapp)算法。PACE-MAPP算法使用一个耦合的矢量辐射传输模型,使大气和海洋始终被视为一个系统。因此,在紫外(UV: 300-400 nm)、可见光(VIS: 400-700 nm)、近红外(NIR: 700-1100 nm)和短波红外(SWIR: 1100-2400 nm)光谱波段上对系统进行物理一致的处理,确保不会发生负的水离开辐射。PACE-MAPP利用最优估计同时表征大气气溶胶和海洋成分的光学和微物理特性,找到最优解,并评估每个参数的不确定性。这种耦合方法与多角度、多光谱偏振仪测量相结合,可以检索地球海洋的气溶胶和水的特性。PACE-MAPP算法为公海和沿海地区提供气溶胶和海洋产品,通过使用快速神经网络取代正演模型中耗时的矢量辐射传输计算,该算法被设计成准确、模块化和高效的。我们概述了PACE-MAPP框架,并使用双峰气溶胶模型对精细模式吸收气溶胶和粗模式海盐颗粒的观测,量化了其在模拟pace -类数据上的预期检索性能。我们还使用包含非球形粗模态尘埃粒子的三模气溶胶模型,量化了其在海洋上的观测性能。最后,介绍了PACE-MAPP的模块化功能,并讨论了实施一种新的海洋生物光学模型的计划,该模型使用涂层和未涂层颗粒的混合物,以及用于检测和校正亚视觉冰云的薄卷云模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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