Climent-Pérez, Pau, Galán Cuenca, Alejandro, Garcia-d’Urso, Nahuel, Saval-Calvo, Marcelo, Azorin-Lopez, Jorge, Fuster-Guilló, Andrés
Simultaneous, vision-based fish instance segmentation, species classification and size regression
Climent-Perez P, Galán-Cuenca A, Garcia-d’Urso NE, Saval-Calvo M, Azorin-Lopez J, Fuster-Guillo A. 2024. Simultaneous, vision-based fish instance segmentation, species classification and size regression. PeerJ Computer Science 10:e1770 https://doi.org/10.7717/peerj-cs.1770
URI: http://hdl.handle.net/10045/140144
DOI: 10.7717/peerj-cs.1770
ISSN: 2376-5992
Abstract: 
Overexploitation of fisheries is a worldwide problem, which is leading to a large loss of diversity, and affects human communities indirectly through the loss of traditional jobs, cultural heritage, etc. To address this issue, governments have started accumulating data on fishing activities, to determine biomass extraction rates, and fisheries status. However, these data are often estimated from small samplings, which can lead to partially inaccurate assessments. Fishing can also benefit of the digitization process that many industries are undergoing. Wholesale fish markets, where vessels disembark, can be the point of contact to retrieve valuable information on biomass extraction rates, and can do so automatically. Fine-grained knowledge about the fish species, quantities, sizes, etc. that are caught can be therefore very valuable to all stakeholders, and particularly decision-makers regarding fisheries conservation, sustainable, and long-term exploitation. In this regard, this article presents a full workflow for fish instance segmentation, species classification, and size estimation from uncalibrated images of fish trays at the fish market, in order to automate information extraction that can be helpful in such scenarios. Our results on fish instance segmentation and species classification show an overall mean average precision (mAP) at 50% intersection-over-union (IoU) of 70.42%, while fish size estimation shows a mean average error (MAE) of only 1.27 cm.
Keywords:Fish size estimation, Species recognition, Segmentation, Computer vision, Deep learning
PeerJ
info:eu-repo/semantics/article