Abstract
The Ocean Aware project, led by Innovasea and funded through Canada's Ocean Supercluster, is developing a fish passage observation platform to monitor fish without the use of traditional tags. This will provide an alternative to standard tracking technology, such as acoustic telemetry fish tracking, which are often not appropriate for tracking at-risk fish species protected by legislation. Rather, the observation platform uses a combination of sensors including acoustic devices, visual and active sonar, and optical cameras. This will enable more in-depth scientific research and better support regulatory monitoring of at-risk fish species in fish passages or marine energy sites. Analysis of this data will require a robust and accurate method to automatically detect fish, count fish, and classify them by species in real-time using both sonar and optical cameras. To meet this need, we developed and tested an automated real-time deep learning framework combining state of the art convolutional neural networks and Kalman filters. First, we showed that an adaptation of the widely used YOLO machine learning model can accurately detect and classify eight species of fish from a public high resolution DIDSON imaging sonar dataset captured from the Ocqueoc River in Michigan, USA. Although there has been extensive research in the literature identifying particular fish such as eel vs. non-eel and seal vs. fish, to our knowledge this is the first successful application of deep learning for classifying multiple fish species with high resolution imaging sonar. Second, we integrated the Norfair object tracking framework to track and count fish using a public video dataset captured by optical cameras from the Wells Dam fish ladder on the Columbia River in Washington State, USA. Our results demonstrate that deep learning models can indeed be used to detect, classify species, and track fish using both high resolution imaging sonar and underwater video from a fish ladder. This work is a first step toward developing a fully implemented system which can accurately detect, classify and generate insights about fish in a wide variety of fish passage environments and conditions with data collected from multiple types of sensors.
Highlights
Fish are an essential part of marine ecosystems as well as human culture and industry
Final Results of Mask-RCNN Applying image augmentation during training improved the results of MASK-RCNN on the Ocqueoc River Dual-frequency Identification Sonar (DIDSON) dataset
These results demonstrate that it is feasible to detect and classify fish species using visual acoustic data from high resolution acoustic cameras like the DIDSON devices deployed on the Ocqueoc River
Summary
Fish are an essential part of marine ecosystems as well as human culture and industry. Pollution, overfishing, and habitat destruction result in population decrease, extinction, or replacement of species. Monitoring the frequency and abundance of fish species is necessary to inform conservation and regulatory efforts that ensure healthy ecosystems and fish stocks (Blemel et al, 2019; Hilborn et al, 2020). The number and distribution of different fish species can provide useful information about ecosystem health and can be used for tracking environmental change (Rathi et al, 2017). Techniques such as fish tagging, catch-and-release fishing, and video and image analysis can determine relative abundance and track population changes of fish
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