UMD Robot Bird Takes Maneuverability to New Level
First independently controllable wings make more realistic flight possible.
COLLEGE PARK, Md.—In this age of advanced technology, how hard could it be to develop a robotic bird that flies by flapping its wings? Despite the apparent simplicity of the idea, it’s very hard—if you want the bird to actually fly.
And how hard could it be to make a robot bird whose wings can flap independently of each other? So hard that it’s been a breakthrough that’s been out of reach for engineers—until now.
University of Maryland Professors S. K. Gupta and Hugh Bruck and their students have developed and demonstrated a new robotic bird, “Robo Raven,” whose wings flap completely independently of each other, and also can be programmed to perform any desired motion, enabling the bird to perform aerobatic maneuvers. This is the first time a robotic bird with these capabilities has been built and successfully flown.
What makes building robotic birds so difficult? Not only is there a long trial and error process, but every error leads to a crash, often one that is fatal to the robot. This makes design iterations painfully slow.
Gupta, a professor in Mechanical Engineering and the Institute for Systems Research in the A. James Clark School of Engineering, has been working on flapping-wing robotic birds for the better part of a decade. He and his graduate students, along with Mechanical Engineering Professor Hugh Bruck, first successfully demonstrated a flapping-wing bird in 2007. This bird used one motor to flap both wings together in simple motions. By 2010 the design had evolved over four successive models. The final bird in the series was able to carry a tiny video camera, could be launched from a ground robot, and could fly in winds up to 10 mph—important breakthroughs for robotic micro air vehicles that one day could be used for reconnaissance and surveillance. It even fooled a local hawk, which attacked the robot in mid-flight on more than one occasion.
But the limitation of simultaneous wing flapping restricted how well the robotic bird could fly. So Gupta decided to tackle the much thornier problem of creating a more versatile bird with wings that operated independently, just like real birds. An unsuccessful attempt in 2008 led to the project being shelved for a while. Then, in 2012, Gupta partnered with Bruck and their graduate students to try again.
“Our new robot, Robo Raven, is based on a fundamentally new design concept,” Gupta says. “It uses two programmable motors that can be synchronized electronically to coordinate motion between the wings.”
The challenge was that the two actuators required a bigger battery and an on-board micro controller, which initially made Robo Raven too heavy to fly.
“How did we get Robo Raven to ‘diet’ and lose weight?” Gupta asks. “We used advanced manufacturing processes such as 3D printing and laser cutting to create lightweight polymer parts.”
But smarter manufacturing and lighter parts were only part of the solution.
So the team did three more things to get Robo Raven airborne. They programmed motion profiles that ensured wings maintained optimal velocity while flapping to achieve the right balance between lift and thrust. They developed a way to measure aerodynamic forces generated during the flapping cycle, enabling them to evaluate a range of wing designs and quickly select the best one. Finally, the team performed system-level optimization to make sure all components worked well together and provided peak performance as an integrated system.
“We can now program any desired motion patterns for the wings,” Gupta says. “This allows us to try new in-flight aerobatics—like diving and rolling—that would have not been possible before, and brings us a big step closer to faithfully reproducing the way real birds fly.”
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Funding for the robotic birds project has been provided by the National Science Foundation, the Air Force Office of Scientific Research, the Army Research Laboratory, and the Army Research Office.
1) Robo Raven in flight. 2) Robo Raven’s wings flap completely independent of each other. 3) (L-R) Students Luke Roberts, John Gerdes, and Ariel Perez-Rosado with Robo Raven. CREDITS: University of Maryland.
Watch a video of Robo Raven in action: www.youtube.com/watch?v=mjOWpwbnmTw
S. K. Gupta writes about Robo Raven on his blog, Pursuit of Unorthodox Ideas: unorthodoxideas.blogspot.com/2013/04/robo-raven-step-towards-bird-inspired.html
View videos of Gupta’s early (simultaneous) flapping-wing robotic birds: terpconnect.umd.edu/~skgupta/UMdBird/
S. K. Gupta’s home page: www.isr.umd.edu/faculty/gupta
Hugh Bruck’s home page: terpconnect.umd.edu/~bruck/WAM-pub/
About the University of Maryland
The University of Maryland ranks among the top 20 public research universities in the nation, and is the closest in proximity to the nation’s capital. As the state’s flagship university, UMD educates the most talented students from Maryland and beyond. For more information, please visit:
The University of Maryland: www.umd.edu
The A. James Clark School of Engineering: www.eng.umd.edu
The Institute for Systems Research: www.isr.umd.edu
The Department of Mechanical Engineering: www.enme.umd.edu
301–405–6602 After 4 p.m. 301–706–8312