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Scientists Find Robotic Sensors May Be Able To Improve Prosthetics

Paisley (Scotland): A groundbreaking project to create advanced sensors for use in robotic systems has the potential to transform prosthetics and robotic limbs, according to a new study.

The research project, led by the University of the West of Scotland (UWS), Integrated Graphene Ltd, and supported by the Scottish Research Partnership in Engineering (SRPe) and the National Manufacturing Institute for Scotland (NMIS) Industry Doctorate Programme in Advanced Manufacturing, aims to develop sensors that improve robot dexterity and motor skills through the use of accurate pressure sensors that provide haptic feedback. Professor Des Gibson, Director of the Institute of Thin Films, Sensors and Imaging at UWS and project principal investigator, said: "Over recent years, the advancements in the robotics industry have been remarkable, however, due to a lack of sensory capabilities, robotic systems often fail to execute certain tasks easily. For robots to reach their full potential, accurate pressure sensors, capable of providing greater tactile ability, are required.

"Our collaboration with Integrated Graphene Ltd, has led to the development of advanced pressure sensor technology, which could help transform robotic systems." Made from 3D graphene foam, which offers unique capabilities when put under mechanical stress, the sensors use a piezoresistive approach, meaning when the material is put under pressure it dynamically changes its electric resistance, easily detecting and adapting to the range of pressure required, from light to heavy. Marco Caffio, co-founder and Chief Scientific Officer at Integrated Graphene said: "Gii, our novel 3D graphene foam, has the capability to mimic the sensitivity and feedback of human touch, which could have a transformative impact on how robotics can be used for a whole range of real-world applications from surgery to precision manufacturing. "We know the unique property of Gii makes it suitable for use in other applications like disease diagnostics and energy storage, so we're always very excited to be able to demonstrate its flexibility in projects like this one." Dr Carlos Garcia Nunez, School of Computing Engineering and Physical Sciences at UWS added: "Within robotics and wearable electronics the use of pressure sensors is a vital element, to provide either an information input system, or to give robotic systems human-like motor skills. An advanced material like 3D graphene foam offers excellent potential for use in such applications, due to its outstanding electrical, mechanical and chemical properties.

"Our work shines a light on the significant potential for this technology to revolutionise the robotics industry with dynamic pressure sensors."

Claire Ordoyno, Interim Director of SRPe, added: "The SRPe - NMIS Industrial Doctorate Programme brings together groundbreaking academic research with industry partners to drive forward innovation in engineering. These collaborative PhD projects not only enhance the Scottish engineering research landscape but produce innovation focussed, industry-ready PhD graduates, to feed the talent pipeline." —ANI

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