Abstract
Sea level rise contribution from the Antarctic ice sheet is influenced by changes in glacier and ice shelf front position. Still, little is known about seasonal glacier and ice shelf front fluctuations as the manual delineation of calving fronts from remote sensing imagery is very time-consuming. The major challenge of automatic calving front extraction is the low contrast between floating glacier and ice shelf fronts and the surrounding sea ice. Additionally, in previous decades, remote sensing imagery over the often cloud-covered Antarctic coastline was limited. Nowadays, an abundance of Sentinel-1 imagery over the Antarctic coastline exists and could be used for tracking glacier and ice shelf front movement. To exploit the available Sentinel-1 data, we developed a processing chain allowing automatic extraction of the Antarctic coastline from Seninel-1 imagery and the creation of dense time series to assess calving front change. The core of the proposed workflow is a modified version of the deep learning architecture U-Net. This convolutional neural network (CNN) performs a semantic segmentation on dual-pol Sentinel-1 data and the Antarctic TanDEM-X digital elevation model (DEM). The proposed method is tested for four training and test areas along the Antarctic coastline. The automatically extracted fronts deviate on average 78 m in training and 108 m test areas. Spatial and temporal transferability is demonstrated on an automatically extracted 15-month time series along the Getz Ice Shelf. Between May 2017 and July 2018, the fronts along the Getz Ice Shelf show mostly an advancing tendency with the fastest moving front of DeVicq Glacier with 726 ± 20 m/yr.
Highlights
The coastline of the Antarctic continent consists of solid rock and dynamic glacier and ice shelf fronts
Our understanding of forces controlling calving front location (CFL) change is still limited as continuous Antarctic coastal-change time series are scarce [2]
As a manual delineated coastline from the Antarctic Digital Database (ADD) exists for the same date, it is shown in white for reference
Summary
The coastline of the Antarctic continent consists of solid rock and dynamic glacier and ice shelf fronts. If we want to understand the sea level rise contribution of Antarctica, besides many other parameters, current calving front dynamics have to be tracked In this way, recent changes in glacier and ice shelf front movement can be detected. Our understanding of forces controlling calving front location (CFL) change is still limited as continuous Antarctic coastal-change time series are scarce [2]. Since the launch of Sentinel-1 year-round, medium-resolution and weather independent imagery over the Antarctic coastline with weekly revisit times is available. To exploit this abundance of data, a novel automatic approach for coastline extraction is needed to continuously track glacier and ice front fluctuations. No automatic method exists to track dynamic glacier and ice shelf front change intra-annually
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
