Monitoring river discharge from space: An optimization approach with uncertainty quantification for small ungauged rivers

IF 11.1 1区 地球科学 Q1 ENVIRONMENTAL SCIENCES
Daniel Scherer, Christian Schwatke, Denise Dettmering, Florian Seitz
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Abstract

The number of in-situ stations measuring river discharge, one of the Essential Climate Variables (ECV), is declining steadily, and numerous basins have never been gauged. With the aim of improving data availability worldwide, we propose an easily applicable and transferable approach to estimate reach-scale discharge solely using remote sensing data that is suitable for filling gaps in the in-situ network. We combine 20 years of satellite altimetry observations with high-resolution satellite imagery via a hypsometric function to observe large portions of the reach-scale bathymetry. The high-resolution satellite images, which are classified using deep learning image segmentation, allow for detecting small rivers (narrower than 100 m) and can capture small width variations. The unobserved part of the bathymetry is estimated using an empirical width-to-depth function. Combined with precise satellite-derived slope measurements, river discharge is calculated at multiple consecutive cross-sections within the reach. The unknown roughness coefficient is optimized by minimizing the discharge differences between the cross-sections. The approach requires minimal input and approximate boundary conditions based on expert knowledge but is not dependent on calibration. We provide realistic uncertainties, which are crucial for data assimilation, by accounting for errors and uncertainties in the different input quantities. The approach is applied globally to 27 river sections with a median normalized root mean square error of 12% and a Nash–Sutcliffe model efficiency of 0.560. On average, the 90% uncertainty range includes 91% of the in-situ measurements.

从空间监测河流排放:针对无测站小河流的不确定性量化优化方法
作为基本气候变量(ECV)之一,测量河流排水量的原位站数量正在持续下降,许多流域从未进行过测量。为了提高全球数据的可用性,我们提出了一种易于应用和转移的方法,即仅利用适合于填补现场网络空白的遥感数据来估算到达尺度的排水量。我们将 20 年的卫星测高观测数据与高分辨率卫星图像结合起来,通过湿度测量功能观测到了大部分河段的水深。利用深度学习图像分割技术对高分辨率卫星图像进行分类,可以检测到小河流(窄于 100 米),并能捕捉到较小的宽度变化。水深测量中未观测到的部分使用经验宽度-深度函数进行估算。结合精确的卫星坡度测量结果,计算出河段内多个连续断面的河流排放量。通过最小化横截面之间的排水量差异来优化未知的粗糙度系数。该方法只需最少的输入和基于专家知识的近似边界条件,但不依赖校准。通过考虑不同输入量的误差和不确定性,我们提供了对数据同化至关重要的现实不确定性。该方法在全球 27 个河段得到应用,归一化均方根误差中值为 12%,纳什-苏特克利夫模型效率为 0.560。平均而言,90% 的不确定性范围包括 91% 的现场测量值。
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来源期刊
Remote Sensing of Environment
Remote Sensing of Environment 环境科学-成像科学与照相技术
CiteScore
25.10
自引率
8.90%
发文量
455
审稿时长
53 days
期刊介绍: Remote Sensing of Environment (RSE) serves the Earth observation community by disseminating results on the theory, science, applications, and technology that contribute to advancing the field of remote sensing. With a thoroughly interdisciplinary approach, RSE encompasses terrestrial, oceanic, and atmospheric sensing. The journal emphasizes biophysical and quantitative approaches to remote sensing at local to global scales, covering a diverse range of applications and techniques. RSE serves as a vital platform for the exchange of knowledge and advancements in the dynamic field of remote sensing.
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