Èȵã´ó¹Ï

BUFFALO, N.Y. – Robots excel at many things, but having a good sense of touch is not among them. Whether dropping items or pinching them too tightly which crushes the object, many robots struggle with these basic skills that humans have mastered.

Over the years scientists have equipped robots with cameras and other tools that enable the machines to better sense objects. But a simple and cost-effective solution remains elusive.

A new electronic textile (E-textile), under development at the University at Buffalo, aims to address this problem. The technology, described in a study published July 30 in , mimics how nerves in our hands sense pressure and slipping while grasping objects.

“The applications are very exciting…,” says Jun Liu, PhD, assistant professor in the UB Department of Mechanical and Aerospace Engineering in the School of Engineering and Applied Sciences. “The technology could be used in manufacturing tasks like assembling products and packaging them – basically any situation where humans and robots collaborate. It could also help improve robotic surgery tools and prosthetic limbs.”

Liu, also a core faculty member of UB’s RENEW Institute, is the study’s corresponding author. Additional authors include Ehsan Esfahani, PhD, associate professor in the UB Department of Mechanical and Aerospace Engineering, several UB students, and a former UB PhD student from Liu’s group who is now a postdoctoral scholar at the University of Chicago.

“Our sensor functions like human skin — it’s flexible, highly sensitive, and uniquely capable of detecting not just pressure, but also subtle slip and movement of objects,” says Vashin Gautham, a PhD candidate in the Liu research group and first author of the study. “It’s like giving machines a real sense of touch and grip, and this breakthrough could transform how robots, prosthetics, and human-machine interaction systems interact with the world around them.”

Researchers integrated the sensing system onto a pair of 3D-printed robotic fingers, which are mounted to a compliant robotic gripper developed by Esfahani’s group.

“The integration of this sensor allows the robotic gripper to detect slippage and dynamically adjust its compliance and grip force, enabling in-hand manipulation tasks that were previously difficult to achieve,” says Esfahani.

For example, when researchers tried to pull a copper weight from the fingers, the gripper sensed this and immediately tightened its grip.

“This sensor is the missing component that brings robotic hands one step closer to functioning like a human hand,” Esfahani adds. The slight movement of the object causes friction between the two materials, which in turn generates direct-current (DC) electricity — a phenomenon known as the tribovoltaic effect.

Researchers measured the sensing system’s response time, and found it comparable to human capabilities. For example, it took the system from .76 milliseconds to 38 milliseconds to respond, depending on the experiment. Human touch receptors typically react between 1 and 50 milliseconds.

“The system is incredibly fast, and well within the biological benchmarks set forth by human performance,” says Liu. “We found that the stronger or faster the slip, the stronger the response is from the sensor – this is fortuitous because it makes it easier to build control algorithms to enable the robot to act with precision.”

The research team is planning additional testing of the sensing system, including integrating a form of artificial intelligence known as reinforcement learning that could further improve the robot’s dexterity.

The study was supported with funding from the University at Buffalo Center of Excellence in Materials Informatics.