Enhanced Satellite Analytics for Mussel Platform Census Using a Machine-Learning Based Approach

Mussel platforms are big floating structures made of wood (normally about 20 m × 20 m or even a bit larger) that are used for aquaculture. They are used for supporting the growth of mussels in suitable marine waters. These structures are very common near the Galician coastline. For their maintenance...

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Bibliographic Details
Published in:Electronics (Basel) 2024-07, Vol.13 (14), p.2782
Main Authors: Martín-Rodríguez, Fernando, Álvarez-Sabucedo, Luis M., Santos-Gago, Juan M., Fernández-Barciela, Mónica
Format: Article
Language:English
Subjects:
Aquaculture
Aquaculture industry
Artificial neural networks
Census
Censuses
Floating structures
Frequencies
Machine learning
Marine environment
Mussels
Neural networks
Remote sensing
Satellite imagery
Satellite observation
Satellite tracking
Satellites
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Summary:Mussel platforms are big floating structures made of wood (normally about 20 m × 20 m or even a bit larger) that are used for aquaculture. They are used for supporting the growth of mussels in suitable marine waters. These structures are very common near the Galician coastline. For their maintenance and tracking, it is quite convenient to be able to produce a periodic census of these structures, including their current count and position. Images from Earth observation satellites are, a priori, a convenient choice for this purpose. This paper describes an application capable of automatically supporting such a census using optical images taken at different wavelength intervals. The images are captured by the two Sentinel 2 satellites (Sentinel 2A and Sentinel 2B, both from the Copernicus Project). The Copernicus satellites are run by the European Space Agency, and the produced images are freely distributed on the Internet. Sentinel 2 images include thirteen frequency bands and are updated every five days. In our proposal, remote-sensing normalized (differential) indexes are used, and machine-learning techniques are applied to multiband data. Different methods are described and tested. The results obtained in this paper are satisfactory and prove the approach is suitable for the intended purpose. In conclusion, it is worth noting that artificial neural networks turn out to be particularly good for this problem, even with a moderate level of complexity in their design. The developed methodology can be easily re-used and adapted for similar marine environments.
ISSN:2079-9292
2079-9292
DOI:10.3390/electronics13142782