A first-ever stretchy electronic skin could equip robots and other devices with the same softness and touch sensitivity as human skin, researchers report.
The e-skin opens up new possibilities to perform tasks that require a great deal of precision and control of force and solves a major bottleneck in the emerging technology.
Existing e-skin technology loses sensing accuracy as the material stretches, but that is not the case with this new version.
“Much like human skin has to stretch and bend to accommodate our movements, so too does e-skin,” says Nanshu Lu, a professor in the Cockrell School of Engineering’s aerospace engineering and engineering mechanics department and lead author of the paper published in the journal Matter.
Lu envisions the stretchable e-skin as a critical component to a robot hand capable of the same level of softness and sensitivity in touch as a human hand.
This could be applied to medical care, where robots could check a patient’s pulse, wipe the body, or massage a body part.
Why is a robot nurse or physical therapist necessary? Around the world, millions of people are aging and in need of care, more than the global medical system can provide.
“In the future, if we have more elderly than available caregivers, it’s going to be a crisis worldwide,” Lu says. “We need to find new ways to take care of people efficiently and also gently, and robots are an important piece of that puzzle.”
Beyond medicine, human-caring robots could be deployed in disasters.
They could search for injured and trapped people in an earthquake or a collapsed building, for example, and apply on-the-spot care, such as administering CPR.
E-skin technology senses pressure from contact, letting the attached machine know how much force to use to, for example, grab a cup or touch a person. But, when conventional e-skin is stretched, it also senses that deformation.
That reading creates additional noise that skews the sensors’ ability to sense the pressure. That could lead to a robot using too much force to grab something.
In demonstrations, the stretchability allowed the researchers to create inflatable probes and grippers that could change shape to perform a variety of sensitive, touch-based tasks.
The inflated skin-wrapped probe was used on human subjects to capture their pulse and pulse waves accurately.
The deflated grippers can conformably hold on to a tumbler without dropping it, even when a coin is dropped inside. The device also pressed on a crispy taco shell without breaking it.
The key to this discovery is an innovative hybrid response pressure sensor that Lu and collaborators have been working on for years. While conventional e-skins are either capacitive or resistive, the hybrid response e-skin employs both responses to pressure.
Perfecting these sensors, and combining them with stretchable insulating and electrode materials, enabled this e-skin innovation.
Lu and her team are now working toward the potential applications. They are collaborating with Roberto Martin-Martin, assistant professor at the College of Natural Sciences’ computer science department, to build a robotic arm equipped with the e-skin.
The researchers and UT have filed a provisional patent application for the e-skin technology, and Lu is open to collaborating with robotics companies to bring it to market.