A Franco-American team of researchers has created a robot capable of remaining upright when pushed.
U-M researcher Jessy Grizzle, who developed the control theory for the robot, said that the balancing ability programmed into the robot has many applications in the medical field, such as so-called smart prosthetics that adapt to the wearer, and physical rehabilitation aids to help people regain the ability to walk.
Bipedal robots, or two-legged walking machines, in existence today walk flat-footed, with an unnatural crouching or stomping gait, said Grizzle, professor of electrical engineering and computer science.
Up until RABBIT, scientists produced stability in two-legged walking machines largely through extensive trial and error experiments during development, Grizzle said. Current walking machines use large feet to avoid tipping over and do not require the robot’s control system to be endowed with a real understanding of the mechanics of walking or balance, Grizzle said. If you provided these robots with a pair of stilts or asked them to tiptoe across the room, they would just fall over.
RABBIT was built without feet. Its legs end like stilts so that it pivots on a point when it moves forward. “If you build a robot that pivots on a point you must understand how the different parts interact dynamically, or else it will fall over,” Grizzle said. If a robot has no feet, it’s impossible to “cheat.”
The U-M/French control theory for walking, which was published in a recent paper in the International Journal of Robotics Research, gives scientists an analytical method that can predict in advance how the robot will move, Grizzle said.
“The concept of stability is reduced to two formulas,” Grizzle said. “It’s a matter of understanding enough about the dynamics of walking and balance so that you can express with mathematical formulas how you want the robot to move, and then automatically produce the control algorithm that will induce the desired walking motion on the very fist try.”
RABBIT walking after disruption
Grizzle’s work has promising applications in designing human prosthetics.
“Our analytic method is very cost effective by reducing the amount of experimental work that goes into motion design,” Grizzle said. “If you can take properties of a patient, their height, weight, how the valid leg functions, maybe you could more quickly have the prosthetic adapt its characteristics to the person, instead of the person adapting his gait to the prosthetic, which is essentially what happens now. These things are dreams, we’re not there yet. But you need principles to get there.”
Other applications include rehabilitative walking aids for spinal injury patients, machines designed for home use that can climb stairs or robots for use in exploratory missions over rough terrain.
RABBIT is part of
Video of RABBIT shot by researchers during experiments shows a pair of mechanical legs walking in a circle while attached to a boom that keeps it from falling over sideways but does not guide or control its forward momentum.
When pushed from behind by researcher Eric Westervelt, formerly a student of Grizzle’s and now an assistant professor of mechanical engineering at
An animated video of RABBIT can be seen here.