Classification of Sea Ice Types in the Arctic by Radar Echoes from SARAL/AltiKa

Renée Mie Fredensborg Hansen,Eero Rinne,Henriette Skourup

doi:10.3390/rs13163183

Renée Mie Fredensborg Hansen, Eero Rinne + Show 1 more

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https://doi.org/10.3390/rs13163183

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Journal: Remote sensing	Publication Date: Aug 11, 2021
Citations: 6	License type: CC BY 4.0

Affiliation: Finnish Meteorological Institute

Abstract

An important step in the sea ice freeboard to thickness conversion is the classification of sea ice types, since the ice type affects the snow depth and ice density. Studies using Ku-band CryoSat-2 have shown promise in distinguishing FYI and MYI based on the parametrisation of the radar echo. Here, we investigate applying the same classification algorithms that have shown success for Ku-band measurements to measurements acquired by SARAL/AltiKa at the Ka-band. Four different classifiers are investigated, i.e., the threshold-based, Bayesian, Random Forest (RF) and k-nearest neighbour (KNN), by using data from five 35 day cycles during Arctic mid-winter in 2014–2018. The overall classification performance shows the highest accuracy of 93% for FYI (Bayesian classifier) and 39% for MYI (threshold-based classifier). For all classification algorithms, more than half of the MYI cover falsely classifies as FYI, showing the difference in the surface characteristics attainable by Ka-band compared to Ku-band due to different scattering mechanisms. However, high overall classification performance (above 90%) is estimated for FYI for three supervised classifiers (KNN, RF and Bayesian). Furthermore, the leading-edge width parameter shows potential in discriminating open water (ocean) and sea ice when visually compared with reference data. Our results encourage the use of waveform parameters in the further validation of sea ice/open water edges and discrimination of sea ice types combining Ka- and Ku-band, especially with the planned launch of the dual-frequency altimeter mission Copernicus Polar Ice and Snow Topography Altimeter (CRISTAL) in 2027.

Highlights

Sea ice affects the Earth’s climate and recent studies show a decline in the ice formation, distribution and volume in the Arctic [1]
We investigated classifying sea ice types in the Arctic by altimeter mission carrying a pulse-limited Ka-band radar (AltiKa) Ka-band radar altimeter data, exploiting the fact that the radar echo shapes retrieved from first-year ice (FYI) and multi-year ice (MYI) are different
We investigated the radar echoes from AltiKa by using four different classifiers that are previously used for the same purpose on Ku-band data

Summary

Introduction

Sea ice affects the Earth’s climate and recent studies show a decline in the ice formation, distribution and volume in the Arctic [1]. Sea ice thickness data have previously been acquired by upward-looking sonar mounted on submarines and moorings (e.g., [6,7]) and electromagnetic induction sensors mounted on airborne platforms (e.g., [8,9]). While these observations are regionally and spatially limited, satellite altimetry (radar altimetry, in particular) provides near-global elevation measurements that contain information of surface roughness depicted as altimetric radar echoes from which the elevation of sea ice thickness can be inferred [1]

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