Classification of Fram Strait Sea Ice by Synthetic Aperture Radar

Space-borne synthetic aperture radar (SAR) systems are essential for operational monitoring of sea ice in polar regions. Radar polarimetry is a powerful niche within remote sensing, allowing investigations of various sea ice types’ scattering properties. Full-polarimetric and compact polarimetry SAR...

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Bibliographic Details
Main Authors: Brekke, Camilla, Eltoft, Torbjørn, Johansson, A. Malin, Grahn, Jakob, Singha, Suman
Format: Conference Object
Language:English
Published: 2018
Subjects:
Online Access:https://elib.dlr.de/119064/
https://elib.dlr.de/119064/3/Brekke%20et%20al.%20Jan%202018.pdf
http://www.eorc.jaxa.jp/ALOS/en/conf/workshop/alos2_3rdpiws_2018jan.htm
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Summary:Space-borne synthetic aperture radar (SAR) systems are essential for operational monitoring of sea ice in polar regions. Radar polarimetry is a powerful niche within remote sensing, allowing investigations of various sea ice types’ scattering properties. Full-polarimetric and compact polarimetry SAR measurements may hence allow improved sea ice type characterization and discrimination capabilities aiding operational sea ice services. In this talk,we disseminate results from remote sensing measurements of sea ice collected under the Norwegian Young Sea Ice 2015 (N-ICE2015) field campaign that took place January to June 2015 in the Fram Strait. In particular, we focus on multifrequency SAR studies, involving acquisitions from ALOS-2 (L-band), Radarsat-2 (C-band), and TerraSAR-X (X-band), and give some directions for future research. First, an analysis of full-polarimetric L-, C-, and dual-polarization (HH/VV) X-band SAR data recorded over lead ice revealed that by combining the scattering entropy and co-polarization ratio we can successfully separate newly formed sea ice from open water and thicker sea ice within all three frequencies throughout the winter and spring season. The polarization difference exhibits less incidence angle dependency and shows to provide additional discrimination support. X- and L-band SAR acts complementary to the more regular acquisitions in C-band in terms of characterizing the newly formed sea ice types and surface structure. Second, asemi-coherent backscatter model is used to interpret the space-borne SAR data acquisitions of the Fram Strait sea ice. Specifically, full-polarimetric L-,C-, dual-polarization (HH/VV) and full-polarimetric X-band SAR is compared to model output. Constrained to simultaneous in-situ observations from the campaign, the model is able to reproduce the backscatter from lead ice and ice floes well for the individual frequency bands. For open water leads, unexpectedly high backscatter values are observed in L-band compared to C-band. Possible explanations relating to the sea ice formation process are discussed. Third, an automatic sea ice classification algorithm developed for near real-time services on full-polarimetric SAR measurements has been tested for X-, C-, and L-band data. Spatial and temporal coincident sea ice freeboard measurements of an airborne laser scanner as well as sea ice thickness data were used to validate the classification results. It was found that the number of multipolarization SAR parameters could be reduced from18 to 9, for all three frequencies, whilst still maintaining the 96.9% sea ice classification accuracy. The set of parameters that were found most useful in L-band was slightly different compared to those for the other two frequencies. Next, exploring a supervised classification scheme, we which to includemore full-polarimetric ALOS-2 L-band SAR scenes from the N-ICE campaign. Our goal is to investigate which multipolarization SAR parameters that are most useful for operational services, aiming at high accuracy sea ice classification under various environmental conditions and imaging geometries.