The caterpillar-bot consists of two layers of polymer, which respond differently when exposed to heat. The bottom layer contracts when exposed to heat and the top layer expands when exposed to heat. (Image: Shuang Wu, NC State University)

Researchers at North Carolina State University have demonstrated a caterpillar-like soft robot that can move forward, backward, and even dip under narrow spaces. The caterpillar-bot’s movement is driven by a novel pattern of silver nanowires that use heat to control the way the robot bends.

“A caterpillar’s movement is controlled by local curvature of its body — its body curves differently when it pulls itself forward than it does when it pushes itself backward,” said NC State’s Yong Zhu. “We’ve drawn inspiration from the caterpillar’s biomechanics to mimic that local curvature, and use nanowire heaters to control similar curvature and movement in the caterpillar-bot.

“Engineering soft robots that can move in two different directions is a significant challenge in soft robotics,” Zhu added. “The embedded nanowire heaters allow us to control the movement of the robot in two ways. We can control which sections of the robot bend by controlling the pattern of heating in the soft robot. And we can control the extent to which those sections bend by controlling the amount of heat being applied.”

The caterpillar-bot consists of two layers of polymer, which respond differently when exposed to heat. The bottom layer contracts when exposed to heat; the top layer expands when exposed to heat. A pattern of silver nanowires is embedded in the expanding layer of polymer. The pattern includes multiple lead points where researchers can apply an electric current. The researchers can control which sections of the nanowire pattern heat up by applying an electric current to different lead points, and can control the amount of heat by applying more or less current.

“We demonstrated that the caterpillar-bot is capable of pulling itself forward and pushing itself backward,” said NC State’s Shuang Wu. “In general, the more current we applied, the faster it would move in either direction. However, we found that there was an optimal cycle, which gave the polymer time to cool — effectively allowing the ‘muscle’ to relax before contracting again. If we tried to cycle the caterpillar-bot too quickly, the body did not have time to ‘relax’ before contracting again, which impaired its movement.”

They also demonstrated that the caterpillar-bot’s movement could be controlled to the point where users were able steer it under a very low gap. In essence, the researchers could control both forward and backward motion as well as how high the robot bent upward at any point in that process.

“This approach to driving motion in a soft robot is highly energy efficient, and we’re interested in exploring ways that we could make this process even more efficient,” said Zhu. “Additional next steps include integrating this approach to soft robot locomotion with sensors or other technologies for use in various applications — such as search-and-rescue devices.”

For more information, contact Matt Shipman at This email address is being protected from spambots. You need JavaScript enabled to view it..