Tails help leaping lizards – and robots – stay in control

now a graduate student in the Department of Organismic and Evolutionary Biology at Harvard University. “This research-based lab course … showed me how biologists and engineers can work together to benefit both fields.”

“This paper shows that research-based teaching leads to better learning and simultaneously can lead to cutting-edge research,” added Full, who last year briefed the U.S. House of Representative’s Science, Technology, Engineering and Mathematics (STEM) Education Caucus on this topic. “It also shows the competitive advantage of interdisciplinary approaches and how involvement of undergraduates in research can lead to innovation.”

The release notes that Full’s research over the past twenty years has revealed how the toe hairs of geckos assist them in climbing smooth vertical surfaces and, more recently, how their tails help to keep them from falling when they slip and to right themselves in mid-air.

The new research tested a 40-year-old hypothesis that the two-legged theropod dinosaurs — the ancestors of birds — used their tails as stabilizers while running or dodging obstacles or predators. In Full’s teaching laboratory, students noticed a lizard’s recovery after slipping during a leap and thought a study of stumbling would be a perfect way to test the value of a tail.

In the CiBER lab, Full and six of his students used high-speed videography and motion capture to record how a red-headed African Agama lizard handled leaps from a platform with different degrees of traction, from slippery to easily-gripped.

They coaxed the lizards to run down a track, vault off a low platform, and land on a vertical surface with a shelter on top. When the friction on the platform was reduced, lizards slipped, causing their bodies potentially to spin out of control.

When the researchers saw how the lizard used its tail to counteract the spin, they created a mathematical model as well as Tailbot — a toy car equipped with a tail and small gyroscope to sense body position – better to understand the animal’s skills. With a tail but no feedback from sensors about body position, Tailbot took a nose dive when driven off a ramp, mimicking a lizard’s take-off. When body position was sensed and fed back to the tail motor, however, Tailbot was able to stabilize its body in midair. The actively controlled tail effectively redirected the angular momentum of the body into the tail’s swing, as happens with leaping lizards, Full said.

Tailbot’s design pushed the boundaries of control in robotics in an area researchers call inertial assisted robotics, an attention-grabber at last September’s meeting of the International Conference on Intelligent Robots and Systems. The UC Berkeley researchers’ paper, presented by Libby and fellow mechanical engineering graduate student Evan Chang-Siu, was one of five finalists there among more than 2,000 robot studies.

“Engineers quickly understood the value of a tail,” Libby said, noting that when he dropped Tailbot nose-down, it was able to right itself before it had dropped a foot. “Robots are not nearly as agile as animals, so anything that can make a robot more stable is an advancement, which is why this work is so exciting.”

The release reports that Full and his students are now investigating the role of the tail in controlling pitch, roll, and yaw while running.

The work was funded by the National Science Foundation, including the NSF’s Integrative Graduate Education and Research Traineeship (IGERT) program, and the Micro Autonomous Systems Technologies (MAST) consortium, a large group of researchers funded in part by the U.S. Army Research Laboratory that is focused on creating autonomous sensing robots.

— Read more in Thomas Libby et al., “Tail-assisted pitch control in lizards, robots and dinosaurs,” Nature (4 January 2012) (doi:10.1038/nature10710)