An integrated deep learning and object-based image analysis approach for mapping debris-covered glaciers

Daniel Jack Thomas, B. Robson, A. Racoviteanu
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引用次数: 1

Abstract

Evaluating glacial change and the subsequent water stores in high mountains is becoming increasingly necessary, and in order to do this, models need reliable and consistent glacier data. These often come from global inventories, usually constructed from multi-temporal satellite imagery. However, there are limitations to these datasets. While clean ice can be mapped relatively easily using spectral band ratios, mapping debris-covered ice is more difficult due to the spectral similarity of supraglacial debris to the surrounding terrain. Therefore, analysts often employ manual delineation, a time-consuming and subjective approach to map debris-covered ice extents. Given the increasing prevalence of supraglacial debris in high mountain regions, such as High Mountain Asia, a systematic, objective approach is needed. The current study presents an approach for mapping debris-covered glaciers that integrates a convolutional neural network and object-based image analysis into one seamless classification workflow, applied to freely available and globally applicable Sentinel-2 multispectral, Landsat-8 thermal, Sentinel-1 interferometric coherence, and geomorphometric datasets. The approach is applied to three different domains in the Central Himalayan and the Karakoram ranges of High Mountain Asia that exhibit varying climatic regimes, topographies and debris-covered glacier characteristics. We evaluate the performance of the approach by comparison with a manually delineated glacier inventory, achieving F-score classification accuracies of 89.2%–93.7%. We also tested the performance of this approach on declassified panchromatic 1970 Corona KH-4B satellite imagery in the Manaslu region of Nepal, yielding accuracies of up to 88.4%. We find our approach to be robust, transferable to other regions, and accurate over regional (>4,000 km2) scales. Integrating object-based image analysis with deep-learning within a single workflow overcomes shortcomings associated with convolutional neural network classifications and permits a more flexible and robust approach for mapping debris-covered glaciers. The novel automated processing of panchromatic historical imagery, such as Corona KH-4B, opens the possibility of exploiting a wealth of multi-temporal data to understand past glacier changes.
一种集成深度学习和基于对象的图像分析方法,用于绘制碎片覆盖的冰川
评估冰川变化和随后的高山储水量变得越来越有必要,为了做到这一点,模型需要可靠和一致的冰川数据。这些数据通常来自全球清单,通常由多时相卫星图像构成。然而,这些数据集也有局限性。虽然使用光谱波段比可以相对容易地绘制干净的冰,但由于冰上碎屑与周围地形的光谱相似性,绘制碎屑覆盖的冰就比较困难了。因此,分析人员通常采用手工描绘,这是一种耗时且主观的方法来绘制碎片覆盖的冰范围。鉴于冰川上碎屑在高山地区(如高山亚洲)日益普遍,需要一种系统、客观的方法。目前的研究提出了一种将卷积神经网络和基于物体的图像分析集成到一个无缝分类工作流程中的测绘碎片覆盖冰川的方法,该方法适用于免费和全球适用的Sentinel-2多光谱、Landsat-8热、Sentinel-1干涉相干性和地形学数据集。该方法应用于喜马拉雅中部和亚洲高山喀喇昆仑山脉的三个不同区域,这些区域表现出不同的气候制度、地形和碎屑覆盖的冰川特征。我们通过与人工绘制的冰川清单进行比较来评估该方法的性能,f分分类准确率达到89.2%-93.7%。我们还在尼泊尔马纳斯卢地区解密的1970全色Corona KH-4B卫星图像上测试了这种方法的性能,准确度高达88.4%。我们发现我们的方法是稳健的,可转移到其他地区,并在区域(>4,000平方公里)尺度上准确。将基于对象的图像分析与深度学习集成在一个工作流程中,克服了卷积神经网络分类的缺点,并为绘制碎片覆盖的冰川提供了更灵活、更强大的方法。新型的全色历史图像自动处理技术,如Corona KH-4B,开启了利用丰富的多时间数据来了解过去冰川变化的可能性。
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