Artificial skin could allow robots to feel like we do
Unlike the current system used to interconnect sensors in existing electronic skins, all the sensors in ACES can be connected to a common electrical conductor with each sensor operating independently. This allows ACES-enabled electronic skins to continue functioning as long as there is one connection between the sensor and the conductor, making them less vulnerable to damage. ACES' simple wiring system and remarkable responsiveness even with increasing numbers of sensors are key characteristics that will facilitate the scale-up of intelligent electronic skins for Artificial Intelligence AI applications in robots, prosthetic devices and other human machine interfaces.
For instance, pairing ACES with the transparent, self-healing and water-resistant sensor skin layer also recently developed by Asst Prof Tee's team, creates an electronic skin that can self-repair, like the human skin. This type of electronic skin can be used to develop more realistic prosthetic limbs that will help disabled individuals restore their sense of touch.
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Other potential applications include developing more intelligent robots that can perform disaster recovery tasks or take over mundane operations such as packing of items in warehouses. The NUS team is therefore looking to further apply the ACES platform on advanced robots and prosthetic devices in the next phase of their research. Materials provided by National University of Singapore. Note: Content may be edited for style and length.
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Science News. Faster than the human sensory nervous system "Humans use our sense of touch to accomplish almost every daily task, such as picking up a cup of coffee or making a handshake. Related Multimedia : YouTube video: Novel artificial nervous system gives robots an exceptional sense of touch. Ho, Benjamin C. A neuro-inspired artificial peripheral nervous system for scalable electronic skins.
Science Robotics , ; 4 32 : eaax DOI: ScienceDaily, 18 July National University of Singapore. New e-skin innovation gives robots and prosthetics an exceptional sense of touch: Unique sensor system responds 1, times faster than the human sense of touch, the fastest ever achieved for an e-skin.
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Scientists Have Created Artificial Electronic Skin That Can 'Feel' Like the Real Thing
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