Abstract
Automatically producing Arctic sea ice charts from Sentinel-1 synthetic aperture radar (SAR) images is challenging for convolutional neural networks (CNNs) due to ambiguous backscattering signatures. The number of pixels viewed by the CNN model in the input image used to generate an output pixel, or the receptive field, is important to detect large features or physical objects such as sea ice and correctly classify them. In addition, a noise phenomenon is present in the Sentinel-1 ESA Instrument Processing Facility (IPF) v2.9 SAR data, particularly in subswath transitions, visible as long vertical lines and grained particles resembling small sea ice floes. To overcome these two challenges, we suggest adjusting the receptive field of the popular U-Net CNN architecture used for semantic segmentation. It is achieved by symmetrically adding additional blocks of convolutional, pooling and upsampling layers in the encoder and decoder of the U-Net, constituting an increase in the number of levels. This shows great improvements in the performance and in the homogeneity of predictions. Second, training models on SAR data noise-corrected with an enhanced technique has demonstrated a significant increase in model performance and enabled better predictions in uncertain regions. An eight-level U-Net trained on the alternative noise-corrected SAR data is presented to be capable of correctly predicting many ambiguous SAR signatures and increased the performance by 8.44% points compared with the regular U-Net trained on the ordinary ESA IPF v2.9 noise-corrected SAR data. This is the first installment of this multi-series installment of articles related to AI applied to sea ice (in short AI4SeaIce).
Highlights
The past decade has shown a growing political and commercial interest in the Arctic and its waters
These models were only trained on the Nansen Environmental and Remote Sensing Center (NERSC) noise correction, as it had proven to be superior in models 1-8
This study presents the issue of ambiguous Synthetic Aperture Radar (SAR) backscatter signatures on sea ice predictions in regions of fully covered sea ice for Convolutional Neural Networks (CNN) models utilizing only Sentinel-1 SAR data
Summary
The past decade has shown a growing political and commercial interest in the Arctic and its waters. In [13], the authors attempted to improve the results from [8] by using different spatial windows to train a model, indicating a positive impact of increasing the effective spatial receptive field This is evident when we consider that the ice analysts are capable of inspecting entire SAR images, contrary to the models, which may give ice analysts an advantage, as shown on example Fig. 3. This paper investigates the effects of applying an alternative SAR noise correction scheme [14], developed by the Nansen Environmental and Remote Sensing Center (NERSC), and increasing the number of layers, and the size of the associated receptive field of the U-Net model architecture. White pixels in all images are Not a Number (NaN) values, representing areas with no data and masked land
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