Media Contacts

Office of Media Relations
2000 Pennsylvania Avenue NW
Suite 300
Washington, D.C. 20006

Phone: 202-994-6460
Fax: 202-994-9025
E-mail: [email protected]


Swimming Without a Trace—Building a Machine to Mimic What Sea Lions Naturally Do

A student of Dr. Leftwich observes a sea lion at the Smithsonian's National Zoo
Photo credit: William Atkins/The George Washington University

GW Professor Designs Robotic Foreflipper That Mimics Mammal’s Movement, Hoping it Will Aid Mechanical Innovation in Intelligence Community

August 10, 2015
Emily Grebenstein: [email protected], 202-994-3087
Kurie Fitzgerald: [email protected], 202-994-6461
WASHINGTON (Aug. 10, 2015)—At a maximum speed of 25 miles per hour, sea lions may not be the fastest-swimming mammal in the sea. But they are unrivaled when it comes to stealth—their signature clap-and-glide flipper motion propels them through water and leaves virtually no wake. 
Megan Leftwich, a George Washington University professor of mechanical and aerospace engineering, took notice of this anomaly during a visit to the Smithsonian National Zoo with her children in 2013. While other mammals use their tails or additional fins to help them swim, leaving wakes, sea lions flip and spin without the added help, and without the wake. Dr. Leftwich wondered how they did it and, being an engineer, she speculated whether researchers could replicate the motion. 
“Sea lions swim with their foreflippers, or front flippers, rather than their tail and their propulsive motion is barely detectable,” Dr. Leftwich said. “What we’re trying to do is apply this mechanism to man-made objects. Can we build an underwater vehicle that can go undetected?”
To answer this question, Dr. Leftwich and her team videotaped sea lions swimming at the Smithsonian's National Zoo to capture the foreflipper’s movement frame by frame and track points on their “arms” to mathematically describe the flapping motion. They used the mathematical description to design a plastic robotic arm that mimics a sea lion’s shoulder, elbow and wrist joints. 
Then, Dr. Leftwich 3-D scanned and printed a sea lion foreflipper to cover the “arm” with a silicone version of the skin to study the possible effect wrinkles and hairs have on the drag when swimming. These studies were conducted in GW’s Science and Engineering Hall using flow diagnostic techniques to chart the fluid’s movement and the forces it takes for a sea lion to move its foreflipper. 
Dr. Leftwich chronicled her research in a paper published last month in the Journal of Aero Aqua Bio-mechanisms. Her next step is to bring the robotic foreflipper to SLEWTHS (Science, Learning and Education With The Help of Sea Lions), a teaching aquarium in California, to test her experiment directly with animals in their natural habitat. 
“Observational studies like these are the first step in a research program that will lead to deep understanding of this unique swimming paradigm,” Dr. Leftwich said. “Now that we’ve done the preliminary studies at the National Zoo, we need to test the theories we’ve developed on foreflippers in a lab involving scientifically trained sea lions.”
Dr. Leftwich hopes her research may one day lead to larger machine-based underwater projects, such as searching for shipwrecks or disarming underwater bombs in autonomous vehicles. 
Multimedia Resources
Click here for photos 
Click here for video and here for b-roll 
Click here for Smithsonian video
School of Engineering and Applied Science
GW’s School of Engineering and Applied Science prepares engineers and computer scientists to address society’s technological challenges by offering outstanding undergraduate, graduate and professional educational programs, and by providing innovative, fundamental and applied research activities. The school has six academic departments, 11 research centers, 90 faculty and more than 2,500 undergraduate and graduate students. Core areas of excellence include biomedical engineering, cybersecurity, high performance computing and simulation of engineering systems, nanotechnologies, robotics and systems engineering.