The wearable electronics cost less than $100, and the text displays on a computer or smartphone.
PLOS - A glove fitted with wearable electronics can translate the American Sign Language alphabet and then wirelessly transmit the text for display on electronic devices ? all for less than $100, according to a study published July 12, 2017 in the open-access journal PLOS ONE by Timothy O'Connor and Darren Lipomi from University of California, San Diego, US, and colleagues.
Current methods for tracking human body positions include cameras as well as optical systems involving infrared emitters and receivers. Both can yield good results but the former uses a lot of power, while emitters and receivers are expensive and immovable. Wearable sensor systems avoid these constraints, and gloves in particular are intuitive human-machine interfaces. Gloves that track people's gestures could provide a more seamless interface for applications from virtual reality to telesurgery as well as for covert operations such as piloting aerial drones and controlling bomb-diffusing robots.
Overview of the gesture-decoding glove. Photo courtesy of Timothy O'Connor et al (2017).
Lipomi and colleagues built a glove that decodes the American Sign Language (ASL) alphabet and then wirelessly transmits the text to electronic devices. The glove has nine flexible strain sensors ? two on each finger and one on the thumb ? that detect knuckle articulation. A microprocessor computes the ASL letter for each gesture, and a Bluetooth radio transmits the text for display. The system cost less than $100 to build and has low power requirements.
The researchers found that the wearable electronic glove determined all 26 letters of the ASL alphabet accurately. Based on fatigue studies of the sensors, the system will translate ASL letters accurately after the knuckles are bent maximally 1,000 times. Moreover, the researchers found that data from the glove could also generate an accurate virtual display: when a real hand in the glove made the ASL gestures that spell "UCSD," a virtual hand mimicked them accurately. This, say the researchers, suggests new ways of using flexible, wearable electronics to interface with virtual environments. In addition, the glove can be a test system for evaluating the performance of new materials and stretchable hybrid electronics.
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In your coverage please use this URL to provide access to the freely available article in PLOS ONE: https://journals.
Citation: O'Connor TF, Fach ME, Miller R, Root SE, Mercier PP, Lipomi DJ (2017) The Language of Glove: Wireless gesture decoder with low-power and stretchable hybrid electronics. PLoS ONE 12(7): e0179766. https:/
Funding: This work was supported by the National Institutes of Health Director's New Innovator Award number 1DP2EB022358-01. An earlier prototype of the device that used conductive polymers as the strain sensors, and from which we drew inspiration for the device in its current form was supported by the Air Force Office of Scientific Research Young Investigator Program grant number FA9550-13-1-0156. Additional support was provided by the Center for Wearable Sensors in the Jacobs School of Engineering at the University of California San Diego, and member companies Qualcomm, Sabic, Cubic, Dexcom, Honda, Samsung, and Sony. T. F. O. acknowledges support from the National Defense Science and Engineering Graduate fellowship program sponsored by the Office of Navy Research. We also declare that the funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing Interests: The authors have declared that no competing interests exist.
Source: https://www.eurekalert.org/pub_releases/2017-07/p-lgw070617.php