Monica Allen Thursday, January 6, 2022 / Categories: Research Headlines, Climate, Fisheries & Seafood, Marine Science Researchers develop automated method to identify fish calls underwater Editor’s note: The following article was written by Sean Nealon at Oregon State University and adapted for NOAA Research. The Oregon State University news release is available online. CORVALLIS, Oregon. – A research team led by NOAA’s Cooperative Institute for Marine Ecosystem and Resource Studies at Oregon State University has developed an automated method that can accurately identify calls from a family of fishes. The method takes advantage of data collected by underwater microphones known as hydrophones and provides an efficient and inexpensive way to understand changes in the marine environment due to climate change and other human-caused influences, said researchers from the Cooperative Institute for Marine Ecosystem and Resource Studies. The findings were published in the journal Marine Ecology Progress Series. Hydrophones are increasingly being deployed in the world’s oceans. They offer advantages over other types of monitoring because they work at night, in low-visibility conditions and over long periods of time. But techniques to efficiently analyze data from hydrophones are not well developed. Hydrophones record fish sounds Hydrophone deployed in a tropical reef region within the National Park of American Samoa. Credit: Tim Clark/National Park Service. This new research led by Jill Munger when she was an undergraduate student, begins to change that. Munger came to Oregon State having worked more than 20 years in the corporate world. An avid scuba diver, she wanted to study the ocean. She received a fellowship from CIMERS to research underwater acoustics with Joe Haxel, who at the time was at the Hatfield Marine Science Center in Newport working with National Oceanic and Atmospheric Administration’s Pacific Marine Environmental Lab’s acoustic program. Haxel handed her a hard drive with 18,000 hours of acoustic data collected over 39 months in a tropical reef region within the National Park of American Samoa. American Samoa is a U.S. territory in the western Pacific Ocean. The data was collected via a 12-station hydrophone area maintained by NOAA and the National Park Service that is distributed throughout the world in water controlled by the United States. The hydrophones were designed and built by NOAA and CIMERS researchers at Hatfield Marine Science Center. Munger decided to focus on calls from damselfish, in part, because they are distinctive. They grind their teeth to create pops, clicks and chirps associated with aggressive behavior and nest defense. She compared the sound to purring kittens. Quickly, it became apparent to her that manually listening to the recordings was not going to work. “This is such a slow and tedious process,” she remembered thinking. “I have all this data, and I am just looking at a tiny, tiny portion of it. What’s happening in all the other parts that I haven’t had a chance to listen to?” A conversation with her brother, Daniel Herrera, a machine learning engineer, sparked an idea. Could they use machine learning to automate the analysis of the data? Machine learning algorithms build a model based on sample data, known as training data, to make predictions or decisions without being explicitly programmed to do so. Machine learning techniques have been used to automate processing of large amounts of data from passive acoustic monitoring devices that collected sound data from birds, bats and marine mammals. The techniques have been used for fish calls, but it is an underdeveloped area of science, Munger said. Damselfish gather over reef Damselfish bring bright blue color to a tropical reef region within the National Park of American Samoa. Credit: National Park System. In this case, the machine learning sample or training data was 400 to 500 damselfish calls Munger identified by manually listening to the hydrophone recordings. With that start, Herrera, a co-author of the paper, built a machine learning model that accurately identified 94% of damselfish calls. “We built a machine learning model on a relatively small set of training data and then applied it to an enormous set of data,” Munger said. “The implications for monitoring the environment are huge.” Munger, who now works in the lab of Scott Heppell, an associate professor in Oregon State’s Department of Fisheries, Wildlife, and Conservation Sciences in the College of Agricultural Sciences, believes machine learning will increasingly be used by scientists to monitor many species of fish in the ocean because it requires relatively little effort. “The benefit to observing fish calls over a long period of time is that we can start to understand how it’s related to changing ocean conditions, which influence our nation’s living marine resources,” Munger said. “For example, damselfish call abundance can be an indicator of coral reef health.” Munger received input from National Park Service staff on the biology of the damselfish and the reef habitats in close proximity to the hydrophone. Other co-authors of the paper are Haxel, Heppell, and Samara Haver, all of Oregon State; Lynn Waterhouse, formerly of John G. Shedd Aquarium in Chicago; Megan McKenna, formerly of Natural Sounds and Night Skies Division, National Park Service, Fort Collins, Colorado; and Jason Gedamke and Robert Dziak of NOAA’s Office of Science and Technology, Silver Spring, Maryland, and Pacific Marine Environmental Laboratory, Newport, respectively. Photos of damselfish and hydrophone: https://flic.kr/s/aHsmXbbend For more information, please contact Adi Hanein at NOAA's Pacific Marine Environmental Laboratory in Seattle at email@example.com or Sean Nealon at Oregon State University at firstname.lastname@example.org Previous Article Measuring salt in the ocean may be key to predicting hurricane intensity Next Article Wet, then dry extremes contributed to devastating Marshall Fire in Colorado Print 3848 Tags: fisheries PMEL acoustics Related articles Measuring salt in the ocean may be key to predicting hurricane intensity NOAA Research's top 5 stories from 2021 Atmospheric carbon dioxide rebounds as global pollution rates approach pre-Covid levels NOAA's Experimental Lake Erie Hypoxia Forecast is even more useful than anticipated Low-oxygen waters off Washington, Oregon coasts risk becoming large 'dead zones'