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Electronic 'Hairy Skin' Could Give Robots a More Human Sense of Touch (Video)

Robots and prosthetics are becoming ever more human-like, but the electronic skins designed to enhance their usefulness don't yet have the full range of tactile senses that we have

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Scientists have boosted the sensitivity of electronic skin by adding "hair." Credit: American Chemical Society. See how the sensor works in this Headline Science video.

Electronic-skin prototypes are stretchy, thin films that can sense temperature, pressure, and even monitor blood oxygen or alcohol levels. But most of these devices are missing a key feature of real skin that allows us to feel a wider range of conditions: hair. Now researchers have combined hair-like wires with electronic skin to make a more versatile sensor for robots, prosthetics, and other applications. Their report appears in the journal ACS Applied Materials & Interfaces

Related Article: Creating an Artificial Sense of Touch Through Electrical Stimuli

Robots and prosthetics are becoming ever more human-like, but the electronic skins designed to enhance their usefulness don't yet have the full range of tactile senses that we have. For example, they cannot "feel" a light breeze. But fine hair, which covers 95 percent of the human body, helps us feel the slightest wind. To capture that sensation, some researchers have developed separate sensors that mimic this fine hair by sensing and detecting air flow. However, that's about all these particular devices can do. Rongguo Wang, Lifeng Hao, and colleagues wanted to expand on this, combining the features of electronic skin and hair in a single device. 

The researchers created an array of artificial hairs with glass-coated, cobalt-based microwires, and embedded the ends of the wires in a silicon-rubber "skin." The "hairy skin" could repeatedly detect a range of pressures, including the landing of a fly, a light wind, and a ten-pound weight. And when used with a two-finger robot gripping a plastic block, the new sensor could "feel" slip and friction forces. 

The authors acknowledge funding from the National Natural Science Foundation of China

See how the sensor works in this Headline Science video.

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