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http://dx.doi.org/10.14695/KJSOS.2018.21.3.165

Development of Wearable Sensing and Feedback Product Design for Movement Monitoring  

Cho, Hyun-Seung (Institute of Symbiotic Life-TECH, Yonsei University)
Yang, Jin-Hee (Institute of Symbiotic Life-TECH, Yonsei University)
Lee, Kang-Hwi (College of Science and Technology, Kon-Kuk University)
Lee, Jeong-Hwan (College of Science and Technology, Kon-Kuk University)
Park, Su-Youn (Department of Clothing & Textiles, Yonsei University)
Choi, Hyeong-Ik (AboutDESIGN)
Jeon, Hak-Su (Cuby n Mom)
Lee, Joo-Hyeon (Department of Clothing & Textiles, Yonsei University)
Publication Information
Science of Emotion and Sensibility / v.21, no.3, 2018 , pp. 165-176 More about this Journal
Abstract
The objective of this study was to develop clothing-type wearable motion sensing and feedback systems to enhance children's sports by promoting visual and audio feedback. In this study, several applications, such as fabric sensors, sportswear integrated with various types of fabric sensors, and fabric-based motion sensing module design, as well as a visual and audio feedback system for gaining a better understanding of a child's interest in a type of exercise, were developed. An SWCNT-based stretchable fabric sensor was developed for motion sensing, and sportswear was designed using the fabric sensor that was integrated into the limbs of the garment. The sensing module was developed, and sensory performance was evaluated through a joint motion experiment for children. In addition, using the feedback system that was developed in the form of an accessory, the responses of light and sound were also examined based on the movement of the child who was wearing the sportswear prototypes. This study focused on the development and assessment of prototype designs for children's sportswear and accessory products that can help to ascertain a child's interest in a particular exercise.
Keywords
SWCNT-based Motion Sensor; Sensing Module; Visual and Audio Feedbacks; Derivation of Exercise Interest;
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Times Cited By KSCI : 1  (Citation Analysis)
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1 Cocharane, C., & Cayla, A. (2013). Polymer-based resistive sensors for smart textiles. In Tunde Kirstein (Eds.), Multidisciplinary know-how for smart-textiles developers, (pp. 129-153). Woodhead Publishing, London. DOI: 10.1533/9780857093530.1.129
2 Gioberto, G., & Dunne, L. (2014). Garment-integrated bend sensor, Electronics, 3, 564-581. DOI: 10.3390/electronics3040564   DOI
3 Kern, K., Schiele, B., Junker, H., Lukowicz, P., & Troster, G. (2003). Wearable sensing to annotate meeting recordings. In Personal and Ubiquitous Computing, Springer-Verlag, London. DOI: 10.1007/s00779-003-0242-y
4 Cho, H. S., Yang, J. H., Jeon, D. J., & Lee, J. H. (2017). Effect of the Shape and Attached Position of Fabric Sensors on the Sensing Performance of Limb-motion Sensing Clothes, Science of Emotion & Sensibility, 20(3), 141-150. DOI: 10.14695/KJSOS.2017.20.3.141   DOI
5 Lee, J. H., Lee, J. W., Choi, H. I., & Oh, S. C. (2017). A Development of product design and technology for the children's wearable sports gears responding to the segmental dynamics in a body by visual and audio feedbacks. Final Report of the Ministry of Trade, Industry and Energy's 2015 Design Innovation Capability Enhancement Project.
6 Soft Robotics Toolkit, "StretchSense", Retrieved from https://www.stretchsense.com
7 Yamada, T., Hayamizu, Y., Yamamoto, Y., Yomogida, Y., Izadi-Najafabadi, A., Futaba, D. N., & Hata K. (2011). A stretchable carbon nanotube strain sensor for human-motion detection, Nature Nanotechnology, 6(5), 296-301. DOI: 10.1038/nnano.2011.36   DOI