TY - JOUR
T1 - Machine learning in marine ecology: an overview of techniques and applications
AU - Rubbens, Peter
AU - Brodie, Stephanie
AU - Cordier, Tristan
AU - Destro Barcellos, D
AU - Devos, Paul
AU - Fernandes-Salvador, Jose A.
AU - Fincham, Jennifer I.
AU - Gomes, Alessandra
AU - Handegard, Nils Olav
AU - Howell, Kerry
AU - Jamet, Cédric
AU - Kartveit, Kyrre Heldal
AU - Moustahfid, Hassan
AU - Parcerisas, Clea
AU - Politikos, Dimitris
AU - Sauzède, Raphaëlle
AU - Sokolova, Maria
AU - Uusitalo, Laura
AU - Van den Bulcke, L
AU - van Helmond, ATM
AU - Watson, Jordan T.
AU - Welch, Heather
AU - Beltran-Perez, Oscar
AU - Chaffron, Samuel
AU - Greenberg, David S.
AU - Kühn, Bernhard
AU - Kiko, Rainer
AU - Lo, Madiop
AU - Lopes, Rubens M.
AU - Möller, Klas Ove
AU - Michaels, William
AU - Pala, Ahmet
AU - Romagnan, Jean Baptiste
AU - Schuchert, Pia
AU - Seydi, Vahid
AU - Villasante, Sebastian
AU - Malde, Ketil
AU - Irisson, Jean Olivier
PY - 2023/9/26
Y1 - 2023/9/26
N2 - Machine learning covers a large set of algorithms that can be trained to identify patterns in data. Thanks to the increase in the amount of data and computing power available, it has become pervasive across scientific disciplines. We first highlight why machine learning is needed in marine ecology. Then we provide a quick primer on machine learning techniques and vocabulary. We built a database of ∼1000 publications that implement such techniques to analyse marine ecology data. For various data types (images, optical spectra, acoustics, omics, geolocations, biogeochemical profiles, and satellite imagery), we present a historical perspective on applications that proved influential, can serve as templates for new work, or represent the diversity of approaches. Then, we illustrate how machine learning can be used to better understand ecological systems, by combining various sources of marine data. Through this coverage of the literature, we demonstrate an increase in the proportion of marine ecology studies that use machine learning, the pervasiveness of images as a data source, the dominance of machine learning for classification-type problems, and a shift towards deep learning for all data types. This overview is meant to guide researchers who wish to apply machine learning methods to their marine datasets.
AB - Machine learning covers a large set of algorithms that can be trained to identify patterns in data. Thanks to the increase in the amount of data and computing power available, it has become pervasive across scientific disciplines. We first highlight why machine learning is needed in marine ecology. Then we provide a quick primer on machine learning techniques and vocabulary. We built a database of ∼1000 publications that implement such techniques to analyse marine ecology data. For various data types (images, optical spectra, acoustics, omics, geolocations, biogeochemical profiles, and satellite imagery), we present a historical perspective on applications that proved influential, can serve as templates for new work, or represent the diversity of approaches. Then, we illustrate how machine learning can be used to better understand ecological systems, by combining various sources of marine data. Through this coverage of the literature, we demonstrate an increase in the proportion of marine ecology studies that use machine learning, the pervasiveness of images as a data source, the dominance of machine learning for classification-type problems, and a shift towards deep learning for all data types. This overview is meant to guide researchers who wish to apply machine learning methods to their marine datasets.
U2 - 10.1093/icesjms/fsad100
DO - 10.1093/icesjms/fsad100
M3 - Article
SN - 1054-3139
VL - 80
SP - 1829
EP - 1853
JO - ICES Journal of Marine Science
JF - ICES Journal of Marine Science
IS - 7
ER -