Retrieving 3D distributions of atmospheric particles using Atmospheric Tomography with 3D Radiative Transfer – Part 2: Local optimization

IF 3.2 3区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES
J. Loveridge, Aviad Levis, L. Di Girolamo, Vadim Holodovsky, Linda Forster, A. Davis, Y. Schechner
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引用次数: 2

Abstract

Abstract. Our global understanding of clouds and aerosols relies on the remote sensing of their optical, microphysical, and macrophysical properties using, in part, scattered solar radiation. Current retrievals assume clouds and aerosols form plane-parallel, homogeneous layers and utilize 1D radiative transfer (RT) models. These assumptions limit the detail that can be retrieved about the 3D variability in the cloud and aerosol fields and induce biases in the retrieved properties for highly heterogeneous structures such as cumulus clouds and smoke plumes. In Part 1 of this two-part study, we validated a tomographic method that utilizes multi-angle passive imagery to retrieve 3D distributions of species using 3D RT to overcome these issues. That validation characterized the uncertainty in the approximate Jacobian used in the tomographic retrieval over a wide range of atmospheric and surface conditions for several horizontal boundary conditions. Here, in Part 2, we test the algorithm's effectiveness on synthetic data to test whether the retrieval accuracy is limited by the use of the approximate Jacobian. We retrieve 3D distributions of a volume extinction coefficient (σ3D) at 40 m resolution from synthetic multi-angle, mono-spectral imagery at 35 m resolution derived from stochastically generated cumuliform-type clouds in (1 km)3 domains. The retrievals are idealized in that we neglect forward-modelling and instrumental errors, with the exception of radiometric noise; thus, reported retrieval errors are the lower bounds. σ3D is retrieved with, on average, a relative root mean square error (RRMSE) < 20 % and bias < 0.1 % for clouds with maximum optical depth (MOD) < 17, and the RRMSE of the radiances is < 0.5 %, indicating very high accuracy in shallow cumulus conditions. As the MOD of the clouds increases to 80, the RRMSE and biases in σ3D worsen to 60 % and −35 %, respectively, and the RRMSE of the radiances reaches 16 %, indicating incomplete convergence. This is expected from the increasing ill-conditioning of the inverse problem with the decreasing mean free path predicted by RT theory and discussed in detail in Part 1. We tested retrievals that use a forward model that is not only less ill-conditioned (in terms of condition number) but also less accurate, due to more aggressive delta-M scaling. This reduces the radiance RRMSE to 9 % and the bias in σ3D to −8 % in clouds with MOD ∼ 80, with no improvement in the RRMSE of σ3D. This illustrates a significant sensitivity of the retrieval to the numerical configuration of the RT model which, at least in our circumstances, improves the retrieval accuracy. All of these ensemble-averaged results are robust in response to the inclusion of radiometric noise during the retrieval. However, individual realizations can have large deviations of up to 18 % in the mean extinction in clouds with MOD ∼ 80, which indicates large uncertainties in the retrievals in the optically thick limit. Using less ill-conditioned forward model tomography can also accurately infer optical depths (ODs) in conditions spanning the majority of oceanic cumulus fields (MOD < 80), as the retrieval provides ODs with bias and RRMSE values better than −8 % and 36 %, respectively. This is a significant improvement over retrievals using 1D RT, which have OD biases between −30 % and −23 % and RRMSE between 29 % and 80 % for the clouds used here. Prior information or other sources of information will be required to improve the RRMSE of σ3D in the optically thick limit, where the RRMSE is shown to have a strong spatial structure that varies with the solar and viewing geometry.
使用具有三维辐射传输的大气层析成像技术检索大气粒子的三维分布-第2部分:局部优化
摘要我们对云和气溶胶的全球了解依赖于对其光学、微物理和宏观物理特性的遥感,部分利用散射的太阳辐射。目前的检索假设云和气溶胶形成平面平行的均匀层,并利用一维辐射传输(RT)模型。这些假设限制了在云和气溶胶场中可以检索到的三维可变性的细节,并导致了对高度非均质结构(如积云和烟羽)检索属性的偏差。在这项由两部分组成的研究的第一部分中,我们验证了一种层析成像方法,该方法利用多角度被动成像来检索物种的3D分布,并使用3D RT来克服这些问题。该验证的特点是,在大范围的大气和地面条件下,在几个水平边界条件下,层析成像检索中使用的近似雅可比矩阵的不确定性。这里,在第2部分中,我们将测试该算法在合成数据上的有效性,以测试使用近似雅可比矩阵是否会限制检索精度。我们从合成的多角度单光谱图像中检索了体积消光系数(σ3D)在40 m分辨率下的三维分布,这些图像来源于随机生成的1 km 3域的积雨云,分辨率为35 m。检索是理想化的,因为我们忽略了正向建模和仪器误差,除了辐射噪声;因此,报告的检索错误是下限。对于最大光学深度(MOD) < 17的云,平均相对均方根误差(RRMSE) < 20%,偏差< 0.1%,辐射度的RRMSE < 0.5%,表明在浅积云条件下具有很高的精度。当云的MOD增加到80时,σ3D的RRMSE和偏差分别恶化到60%和- 35%,辐射的RRMSE达到16%,表明不完全收敛。这是由于逆问题的弊病愈演愈烈,由RT理论预测的平均自由程不断减小,并在第1部分中进行了详细讨论。我们测试了使用前向模型的检索,该模型不仅不那么病态(就条件数量而言),而且由于更积极的delta-M缩放,准确性也较低。在MOD ~ 80的云团中,辐照度RRMSE降至9%,σ3D偏置降至- 8%,而σ3D的RRMSE没有改善。这说明了检索对RT模型的数值配置的显著敏感性,至少在我们的情况下,这提高了检索的准确性。所有这些集合平均结果对检索过程中包含的辐射噪声具有鲁棒性。然而,在MOD ~ 80的云中,单个实现的平均消光可能有高达18%的大偏差,这表明在光学厚度极限下的反演存在很大的不确定性。在大多数海洋积云场(MOD < 80)的条件下,使用较少病态的正反演模式层析成像也可以准确地推断光学深度(ODs),因为反演提供的ODs偏差和RRMSE值分别优于- 8%和36%。与使用1D RT的检索相比,这是一个显著的改进,对于这里使用的云,1D RT的OD偏差在- 30%到- 23%之间,RRMSE在29%到80%之间。在光学厚度极限下,提高σ3D的RRMSE需要先验信息或其他信息来源,其中RRMSE具有很强的空间结构,随太阳和观测几何形状的变化而变化。
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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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