Abstract
Polar mesocyclones (PMCs) and their intense subclass polar lows (PLs) are relatively small atmospheric vortices that form mostly over the ocean in high latitudes. PLs can strongly influence deep ocean water formation since they are associated with strong surface winds and heat fluxes. Detection and tracking of PLs are crucial for understanding the climatological dynamics of PLs and for the analysis of their impacts on other components of the climatic system. At the same time, visual tracking of PLs is a highly time-consuming procedure that requires expert knowledge and extensive examination of source data.There are known procedures involving deep convolutional neural networks (DCNNs) for the detection of large-scale atmospheric phenomena in reanalysis data that demonstrate a high quality of detection. However, one cannot apply these procedures to satellite data directly since, unlike reanalyses, satellite products register all the scales of atmospheric vortices. It is also known that DCNNs were originally designed to be scale-invariant. This leads to the problem of filtering of the scale of detected phenomena. There are other problems to be solved, such as low signal-to-noise ratio of satellite data, and an unbalanced number of negative (without PLs) and positive (where a PL is presented) classes in a satellite dataset.In our study, we propose a deep learning approach for the detection of PLs and PMCs in remote sensing data, which addresses class imbalance and scale filtering problems. We also outline potential solutions for other problems, along with promising improvements to the presented approach.
Highlights
Polar mesocyclones (PMCs) are high-latitude atmospheric vortices that form mostly over the ocean
The rest of the paper is organized as follows: in section 2, we describe the source data and the database of polar lows (PLs) we use; in section 3, we overview the preprocessing of the source data and our method for the detection of PLs that we developed based on deep convolutional neural networks (DCNN); in section 4, we present the results of the application of our methodology
A novel method for the identification of PLs in satellite mosaics is presented. This method is based on a DCNN named RetinaNet, which was proposed for the visual object detection task
Summary
Polar mesocyclones (PMCs) are high-latitude atmospheric vortices that form mostly over the ocean. PMCs are relatively small and short-living: their sizes vary from 200 to 1000 km, and lifetime typically does not exceed 36 hours [1]. The intense subclass of PMCs, namely polar lows (PLs) characterizes by strong winds and high surface fluxes [2]. Despite their small sizes, PLs can cause rough seas and may deliver dangerous weather conditions for engineering infrastructure, mostly due to their explosive formation and unpredictable behavior. PMCs and PLs were shown recently to influence ocean convection, and deep water formation significantly [3,4,5]. Reliable identification and tracking of PLs and PMCs are vital for their quantification as well as for assessing their impact on the ocean circulation of various scales
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