Real-Time Epizootic Monitoring with Inception Deep Neural Network for Maritime Applications

Denis Krivoguz; Alexander Ioshpa; Sergei Chernyi; Anton Zhilenkov; Aleksandr Kustov; Ilya Moiseev; Mikhail Serebryakov; Tatiana Kaynova; Dmitry Vorontsov; Kristina Gritsenko

doi:10.7225/toms.v14.n01.002

Authors

Denis Krivoguz Southern Federal University, Rostov-on-Don, Russia
Alexander Ioshpa Southern Federal University, Rostov-on-Don, Russia
Sergei Chernyi St. Petersburg State Marine Technical University, St. Petersburg, Russia
Anton Zhilenkov St. Petersburg State Marine Technical University, St. Petersburg, Russia
Aleksandr Kustov St. Petersburg State Marine Technical University, St. Petersburg, Russia
Ilya Moiseev St. Petersburg State Marine Technical University, St. Petersburg, Russia
Mikhail Serebryakov St. Petersburg State Marine Technical University, St. Petersburg, Russia
Tatiana Kaynova St. Petersburg State Marine Technical University, St. Petersburg, Russia
Dmitry Vorontsov St. Petersburg State Marine Technical University, St. Petersburg, Russia
Kristina Gritsenko St. Petersburg State Marine Technical University, St. Petersburg, Russia

DOI:

https://doi.org/10.7225/toms.v14.n01.002

Keywords:

Computer vision, Epizootic, Deep learning, Artificial intelligence, Fish detection, Fish diseases

Abstract

This study explores the integration of artificial intelligence in aquaculture to differentiate healthy fish from those afflicted with diseases, aiming to establish a real-time, automated epizootic monitoring system. Utilizing the “Inception v3” convolutional neural network, we examined the model's efficacy in classifying fish based on their health status across two experiments focusing on data augmentation variability. Initial results without augmentation showed diseased fish detection with 86.7% accuracy and healthy fish detection with 86.9% accuracy. However, employing diverse augmentation techniques significantly enhanced detection accuracy to 96.9% for diseased fish and 96.7% for healthy specimens. These findings underscore the potential of computer vision technologies in revolutionizing epizootic monitoring in aquaculture by providing a non-invasive, accurate, and scalable solution to fish health management. The successful application of AI in this context could significantly contribute to the sustainability and productivity of aquaculture operations, underscoring a pivotal shift towards more advanced and humane practices in the industry.