Abstract
Abstract. Lake ice, as part of the Essential Climate Variable (ECV) lakes, is an important indicator to monitor climate change and global warming. The spatio-temporal extent of lake ice cover, along with the timings of key phenological events such as freeze-up and break-up, provide important cues about the local and global climate. We present a lake ice monitoring system based on the automatic analysis of Sentinel-1 Synthetic Aperture Radar (SAR) data with a deep neural network. In previous studies that used optical satellite imagery for lake ice monitoring, frequent cloud cover was a main limiting factor, which we overcome thanks to the ability of microwave sensors to penetrate clouds and observe the lakes regardless of the weather and illumination conditions. We cast ice detection as a two class (frozen, non-frozen) semantic segmentation problem and solve it using a state-of-the-art deep convolutional network (CNN).We report results on two winters (2016–17 and 2017–18) and three alpine lakes in Switzerland. The proposed model reaches mean Intersection-over-Union (mIoU) scores >90% on average, and >84% even for the most difficult lake. Additionally, we perform cross-validation tests and show that our algorithm generalises well across unseen lakes and winters.
Highlights
Climate change is one of the main challenges humanity is facing today, calling for new methods to quantify and monitor the rapid change in global and local climatic conditions
We address the problem of lake ice detection from Sentinel-1 Synthetic Aperture Radar (SAR) data, as an alternative to optical satellite data which is impaired by clouds
Note that mean Intersection-over-Union (mIoU) drops by almost 25% when VV is left out, while it drops by only 3.7% without VH, confirming the significance of polarisation VV for lake ice detection
Summary
Climate change is one of the main challenges humanity is facing today, calling for new methods to quantify and monitor the rapid change in global and local climatic conditions. Tom et al (2018) proposed a machine learning-based semantic segmentation approach for lake ice detection using low spatial-resolution (250m1000m) optical satellite data (MODIS and VIIRS). Geldsetzer et al (2010) used RADARSAT-2 SAR data to monitor ice cover in lakes during the spring melt period in the Yukon area of the Canadian Arctic They put forward a threshold-based classification methodology and observed that the HH and HV backscatter from the lake ice have significant temporal variability and interlake diversity. Tom et al (2018) proposed a machine learning-based methodology for lake ice detection using low resolution optical satellite images.
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