Abstract
Continuous observation of climate indicators, such as trends in lake freezing, is important to understand the dynamics of the local and global climate system. Consequently, lake ice has been included among the Essential Climate Variables (ECVs) of the Global Climate Observing System (GCOS), and there is a need to set up operational monitoring capabilities. Multi-temporal satellite images and publicly available webcam streams are among the viable data sources capable of monitoring lake ice. In this work we investigate machine learning-based image analysis as a tool to determine the spatio-temporal extent of ice on Swiss Alpine lakes as well as the ice-on and ice-off dates, from both multispectral optical satellite images (VIIRS and MODIS) and RGB webcam images. We model lake ice monitoring as a pixel-wise semantic segmentation problem, i.e., each pixel on the lake surface is classified to obtain a spatially explicit map of ice cover. We show experimentally that the proposed system produces consistently good results when tested on data from multiple winters and lakes. Our satellite-based method obtains mean Intersection-over-Union (mIoU) scores > 93%, for both sensors. It also generalises well across lakes and winters with mIoU scores > 78% and >80% respectively. On average, our webcam approach achieves mIoU values of ≈87% and generalisation scores of ≈71% and ≈69% across different cameras and winters respectively. Additionally, we generate and make available a new benchmark dataset of webcam images (Photi-LakeIce) which includes data from two winters and three cameras.
Highlights
Climate change is one of the main challenges for humanity today and there is a great necessity to observe and understand the climate dynamics and quantify its past, present, and future state [1,2]
To detect lake ice from MODIS and VIIRS optical satellite imagery, we proposed a simple, generic machine learning-based approach that achieves high accuracy for all tested lakes
Though we focused on Swiss Alpine lakes, the proposed approach is very straight-forward and the results could hopefully be directly applied to other lakes with similar conditions, in Switzerland and abroad, and possibly to other sensors with similar characteristics
Summary
Climate change is one of the main challenges for humanity today and there is a great necessity to observe and understand the climate dynamics and quantify its past, present, and future state [1,2] Lake observables such as ice duration, freeze-up, and break-up dynamics etc. The European Space Agency (ESA) encourages climate research and long-term trend analysis through the Climate Change Initiative (CCI [4], CCI+ [5]). This consortium recently addressed the following variables: Lake water level, lake water extent, lake surface water temperature, lake ice, and lake water reflectance. A previous 50-year (1951–2000) study [10] based on Canadian lakes confirmed the earlier break-up trend but reported less of a clear trend for freeze-up dates
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