Machine learning – An approach for consistent rock glacier mapping and inventorying – Example of Austria

Rock glaciers (RG) are landforms that occur in high latitudes or elevations and — in their active state — consist of a mixture of rock debris and ice. Despite serving as a form of groundwater storage, they are an indicator for the occurrence of (former) permafrost and therefore carry significance in...

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Bibliographic Details
Published in:Applied Computing and Geosciences
Main Authors: Georg H. Erharter, Thomas Wagner, Gerfried Winkler, Thomas Marcher
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier 2022
Subjects:
Rock glacier inventory
Permafrost
Hydrological catchment
Digital mapping
Machine learning
Image segmentation
Geography. Anthropology. Recreation
G
Geology
QE1-996.5
Electronic computers. Computer science
QA75.5-76.95
Ice
permafrost
Online Access:https://doi.org/10.1016/j.acags.2022.100093
https://doaj.org/article/5de8f1e93f24495bb14ef83418c01084
Description
Summary:Rock glaciers (RG) are landforms that occur in high latitudes or elevations and — in their active state — consist of a mixture of rock debris and ice. Despite serving as a form of groundwater storage, they are an indicator for the occurrence of (former) permafrost and therefore carry significance in the research for the ongoing climate change. For these reasons, the past years have shown rising interest in the establishment of RG inventories to investigate the extent of permafrost and quantify water storages. Creating these inventories, however, usually involves manual, laborious, and subjective mapping of the landforms based on aerial image - and digital elevation model analysis. We propose an approach for RG mapping based on supervised machine learning which can help to increase the mapping efficiency and permits rapid RG mapping in vast and not yet covered areas. We found deep convolutional artificial neural networks (ANN) that are specifically designed for image segmentation (U-Net architecture) to be well suited for this classification problem. The general workflow consists of training the ANNs with orthophotos and slope maps of digital elevation models as input. The output (RG label-maps) is derived from a recently published RG inventory of the Austrian Alps that features 5769 individual RGs and was compiled manually by several scientists. To increase the generalization capabilities, we use live data augmentation during training. Based on this inventory, the ANNs have learned the average expert opinion and the RG map generated by the ANN can be used to increase the consistency and completeness of already existing RG inventories. Moreover, this ANN approach might be valuable for other landform mapping tasks beyond rock glaciers (e.g., other mass movements).

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