利用深度学习从大地遥感卫星图像中自动提取第三极地区的冰川湖泊

IF 11.1 1区 地球科学 Q1 ENVIRONMENTAL SCIENCES
Qian Tang , Guoqing Zhang , Tandong Yao , Marc Wieland , Lin Liu , Saurabh Kaushik
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引用次数: 0

摘要

青藏高原及其周边地区通常被称为 "第三极地区",是北极和南极地区之外最大的冰库。随着冰川的减薄和后退,第三极地区的冰川湖泊正在迅速扩大。Landsat 卫星系列得益于长期存档数据和合适的空间分辨率(1990 年以来为 30 米),是最常用的冰川湖泊测绘工具。然而,由于湖泊边界上的山影、湿冰、冰冻湖泊和积雪覆盖,利用 Landsat 图像绘制高质量、大尺度和多时相冰川湖泊清单的同质地图在很大程度上依赖于目测和人工编辑,这既耗时又耗力。深度学习方法已被应用于第三极和其他地区的冰川湖泊提取,但这些方法要么集中在没有大规模应用的小型试验场,要么集中在极地地区。在这项研究中,对几种经典的深度卷积神经网络进行了评估,采用 Mobilenetv3 主干网的 DeepLabv3+ 表现最佳,平均交集大于联合(mIoU)的准确率高达 94.8%,损失误差低至 0.4%。在山影、结冰或部分结冰的湖泊、湿冰和河流接触等具有挑战性的条件下,所提出的方法都表现出很强的鲁棒性,而且无需大量人工校正。与人工划界相比,模型预测的精确率为 86%,召回率为 85%,F1 分数为 85%。模型提取的区域与人工划定的区域有很强的相关性(r2 = 0.97,斜率 = 0.94),预测区域的交集大于联合(IoU > 0.8)。基于所开发的自动模型在 2020 年对第三极地区的大尺度冰川湖泊绘图进行了测试,结果表明该模型性能良好,共绘制出 29 429 个面积大于 0.0054 平方公里的冰川湖泊,总面积达 1779.9 平方公里(包括非冰川湖泊)。本研究中训练的模型可进行微调,以用于全球其他山区冰川湖泊的大规模测绘。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Automatic extraction of glacial lakes from Landsat imagery using deep learning across the Third Pole region

The Tibetan Plateau and surroundings, commonly referred to as the Third Pole region, has the largest ice store outside the Arctic and Antarctic regions. Glacial lakes in the Third Pole region are expanding rapidly as glaciers thin and retreat. The Landsat satellite series is the most popular for mapping glacial lakes, benefiting from long-term archived data and suitable spatial resolution (30 m since ∼1990). However, the homogeneous mapping of high-quality, large-scale, and multi-temporal glacial lake inventories using Landsat imagery relies heavily on visual inspection and manual editing due to mountain shadows, wet ice, frozen lakes, and snow cover on lake boundaries, which is time consuming and labour-intensive. Deep learning methods have been applied to glacial lake extraction in the Third Pole and other regions, yet these methods are either concentrated on small test sites without large-scale applications or in polar regions. In this study, several classical deep convolutional neural networks were evaluated, and the DeepLabv3+ with Mobilenetv3 backbone performed best, with a high accuracy of mean intersection over union (mIoU) of 94.8 % and a low loss error of 0.4 %. The proposed method demonstrated robustness in challenging conditions such as mountain shadows, frozen or partially frozen lakes, wet ice and river contact, all without requiring extensive manual correction. Compared with manual delineation, the model's prediction has a precision rate of 86 %, recall rate of 85 %, and F1-score of 85 %. The area extracted by the model shows a strong correlation with the manual delineation (r2 = 0.97, slope = 0.94) and a high intersection over union (IoU > 0.8) of the predicted areas. A test of large-scale glacial lake mapping based on the developed automated model in 2020 across the Third Pole region shows the robust performance with 29,429 glacial lakes larger than 0.0054 km2 with a total area of ∼1779.9 km2 (including non-glacier-fed lakes). The model trained in this study can be fine-tuned for large-scale mapping of glacial lakes in other mountain regions worldwide.

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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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