Wu-Jung Lee Principal Oceanographer Affiliate Assistant Professor, Electrical + Computer Engineering leewj@uw.edu Phone 206-685-3904 |
Biosketch
I am interested in the use of sound by both human and animals to observe and understand the environment. My research spans two primary areas: acoustical oceanography, where I develop and apply active acoustic sensing techniques to infer properties of the ocean interior; and animal echolocation, where I combine experimental and computational approaches to understand the closed-loop sensorimotor feedback in echolocating bats and dolphins. In both areas, I focus on two fundamental aspects for achieving high confidence active acoustic sensing: 1) sampling what can we do to collect better information? and 2) inference how do we make reliable interpretation of echo information? Under these overarching themes, I am working to expand acoustic sensing capability for marine ecosystem monitoring at large temporal and spatial scales, and use echolocating animals as biological models to inspire adaptive sampling strategies in an active acoustic context.
Department Affiliation
Acoustics |
Education
B.S. Electrical Engineering and Life Sciences, National Taiwan University, 2005
Ph.D. Oceanographic Engineering, Massachusetts Institution of Technology/Woods Hole Oceanographic Institution Joint Program in Applied Ocean Physics and Engineer, 2013
Videos
Understanding Echoes: A Keynote Lecture at the Acoustical Society of America Meeting In this keynote lecture to the ASA Meeting in Denver, Lee discusses work with both engineered and biological sonar systems to enable effective extraction and interpretation of information embedded in the echoes. Presented are data-driven methodologies and open-source software tools to tackle challenges imposed by large volumes of echosounder data rapidly accumulating across the global ocean. Lee stresses the pivotal role of collaborations in the emerging field. |
More Info |
23 May 2022
|
|||||||
By sending out sounds and analyzing the returning echoes, both humans and animals use active acoustic sensing systems to probe and understand the environment. High-frequency sonar systems, or echosounders, are the workhorse for observing fish and zooplankton in the ocean. Toothed whales and bats navigate and forage via echolocation in the air and under water. In this talk, I will discuss our work with both engineered and biological sonar systems to enable effective extraction and interpretation of information embedded in the echoes. We are developing data-driven methodologies and open-source software tools to tackle challenges imposed by large volumes of echosounder data rapidly accumulating across the global ocean. Using echolocating toothed whales as a model, we are combining experimental and computational approaches to understand biological processing of echo information. Throughout the talk, I will highlight the pivotal role of collaboration in my professional and personal development, and discuss efforts by colleagues and myself to cultivate a sense of community in our field. |
Publications |
2000-present and while at APL-UW |
Interoperable and scalable echosounder data processing with Echopype Lee, W.-J., L. Setiawan, C. Tuguinay, E. Mayorga, and V. Staneva, "Interoperable and scalable echosounder data processing with Echopype," ICES J. Mar. Sci., EOR, doi:10.1093/icesjms/fsae133, 2024. |
More Info |
12 Oct 2024 |
|||||||
Echosounders are high-frequency sonar systems used to sense fish and zooplankton underwater. Their deployment on a variety of ocean observing platforms is generating vast amounts of data at an unprecedented speed from the oceans. Efficient and integrative analysis of these data, whether across different echosounder instruments or in combination with other oceanographic datasets, is crucial for understanding marine ecosystem response to the rapidly changing climate. Here we present Echopype, an open-source Python software library designed to address this need. By standardizing data as labeled, multi-dimensional arrays encoded in the widely embraced netCDF data model following a community convention, Echopype enhances the interoperability of echosounder data, making it easier to explore and use. By leveraging scientific Python libraries optimized for distributed computing, Echopype achieves computational scalability, enabling efficient processing in both local and cloud computing environments. Echopype's modularized package structure further provides a unified framework for expanding support for additional instrument raw data formats and incorporating new analysis functionalities. We plan to continue developing Echopype by supporting and collaborating with the echosounder user community, and envision that the growth of this package will catalyze the integration of echosounder data into broader regional and global ocean observation strategies. |
Beluga whale (Delphinapterus leucas) acoustic foraging behavior and applications for long term monitoring Castellote, M., A. Mooney, R. Andrews, S. Deruiter, W.-J. Lee, M. Ferguson, and P. Wade, "Beluga whale (Delphinapterus leucas) acoustic foraging behavior and applications for long term monitoring," PLOS One, 16, doi:10.1371/journal.pone.0260485, 2021. |
More Info |
30 Nov 2021 |
|||||||
Cook Inlet, Alaska, is home to an endangered and declining population of 279 belugas (Delphinapterus leucas). Recovery efforts highlight a paucity of basic ecological knowledge, impeding the correct assessment of threats and the development of recovery actions. In particular, information on diet and foraging habitat is very limited for this population. Passive acoustic monitoring has proven to be an efficient approach to monitor beluga distribution and seasonal occurrence. Identifying acoustic foraging behavior could help address the current gap in information on diet and foraging habitat. To address this conservation challenge, eight belugas from a comparative, healthy population in Bristol Bay, Alaska, were instrumented with a multi-sensor tag (DTAG), a satellite tag, and a stomach temperature transmitter in August 2014 and May 2016. DTAG deployments provided 129.6 hours of data including foraging and social behavioral states. A total of 68 echolocation click trains ending in terminal buzzes were identified during successful prey chasing and capture, as well as during social interactions. Of these, 37 click trains were successfully processed to measure inter-click intervals (ICI) and ICI trend in their buzzing section. Terminal buzzes with short ICI (minimum ICI < 8.98 ms) and consistently decreasing ICI trend (ICI increment range < 1.49 ms) were exclusively associated with feeding behavior. This dual metric was applied to acoustic data from one acoustic mooring within the Cook Inlet beluga critical habitat as an example of the application of detecting feeding in long-term passive acoustic monitoring data. This approach allowed description of the relationship between beluga presence, feeding occurrence, and the timing of spawning runs by different species of anadromous fish. Results reflected a clear preference for the Susitna River delta during eulachon (Thaleichthys pacificus), Chinook (Oncorhynchus tshawytscha), pink (Oncorhynchus gorbuscha), and coho (Oncorhynchus kisutch) salmon spawning run periods, with increased feeding occurrence at the peak of the Chinook and pink salmon runs. |
Accelerating marine ecological research using OOI echo sounder data Lee, W.-J., "Accelerating marine ecological research using OOI echo sounder data," in Ocean Observatories Initiative (OOI) Science Plan: Exciting Science Opportunities Using OOI Data, by OOI Facility Board, Narragansett, RI, 2021, 134 pp. |
1 Jan 2021 |
In The News
Echolocation is nature’s built-in sonar. Here’s how it works. National Geographic, Liz Langley From beluga whales to bats and even to humans, many animals make sounds that bounce back from objects to help with navigation and hunting. |
3 Feb 2021
|
Big data and fisheries acoustics ICES (International Council for the Exploration of the Seas) News Big data is one of the next steps in the evolution of fisheries acoustics. These data provide unprecedented observations of the aquatic environment but with this abundance of data comes the costs of storage, access and discoverability, processing and analysis, and interpretation. |
15 Sep 2020
|
Scientists unravel the ocean's mysteries with cloud computing UW Information Technology, Elizabeth Sharpe The OOI Cabled Array is delivering data on a scale that was previously not possible. More than 140 instruments are working simultaneously. |
8 Nov 2018
|