IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing (Jan 2021)

ExtremeEarth Meets Satellite Data From Space

  • Desta Haileselassie Hagos,
  • Theofilos Kakantousis,
  • Vladimir Vlassov,
  • Sina Sheikholeslami,
  • Tianze Wang,
  • Jim Dowling,
  • Claudia Paris,
  • Daniele Marinelli,
  • Giulio Weikmann,
  • Lorenzo Bruzzone,
  • Salman Khaleghian,
  • Thomas Kraemer,
  • Torbjorn Eltoft,
  • Andrea Marinoni,
  • Despina-Athanasia Pantazi,
  • George Stamoulis,
  • Dimitris Bilidas,
  • George Papadakis,
  • George Mandilaras,
  • Manolis Koubarakis,
  • Antonis Troumpoukis,
  • Stasinos Konstantopoulos,
  • Markus Muerth,
  • Florian Appel,
  • Andrew Fleming,
  • Andreas Cziferszky

DOI
https://doi.org/10.1109/JSTARS.2021.3107982
Journal volume & issue
Vol. 14
pp. 9038 – 9063

Abstract

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Bringing together a number of cutting-edge technologies that range from storing extremely large volumes of data all the way to developing scalable machine learning and deep learning algorithms in a distributed manner and having them operate over the same infrastructure poses unprecedented challenges. One of these challenges is the integration of European Space Agency (ESA)'s Thematic Exploitation Platforms (TEPs) and data information access service platforms with a data platform, namely Hopsworks, which enables scalable data processing, machine learning, and deep learning on Copernicus data, and development of very large training datasets for deep learning architectures targeting the classification of Sentinel images. In this article, we present the software architecture of ExtremeEarth that aims at the development of scalable deep learning and geospatial analytics techniques for processing and analyzing petabytes of Copernicus data. The ExtremeEarth software infrastructure seamlessly integrates existing and novel software platforms and tools for storing, accessing, processing, analyzing, and visualizing large amounts of Copernicus data. New techniques in the areas of remote sensing and artificial intelligence with an emphasis on deep learning are developed. These techniques and corresponding software presented in this article are to be integrated with and used in two ESA TEPs, namely Polar and Food Security TEPs. Furthermore, we present the integration of Hopsworks with the Polar and Food Security use cases and the flow of events for the products offered through the TEPs.

Keywords