Abstract
Design/methodology/approach-Functional clothes combining textiles, wireless devices, electronics, communication technologies, and software have attracted considerable attention in recent years. The integration of pervasive small wireless sensor signaling systems, electrical circuits, Bluetooth Low Energy, and smart electrical devices on garment surfaces using conductive threads is usually limited by the conductivity, washability, durability, and manufacturing process of the material. The iBeacon works using low-energy Bluetooth technology. It can pinpoint the location of and send notifications about items. The iBeacon is controlled by the Bluetooth ARM processor. Related electronic control circuits are placed on the fabric findings-The locating information from the iBeacon is controlled using a small wireless sensor based on electronic circuits. The iBeacon location models are controlled using Bluetooth Low Energy (Bluetooth 4.0 and Bluetooth Smart), which senses the location and nursing activities of the children. The children can be located in a variety of locations including inside a house, at school, or in the supermarket originality/value-In this paper, iBeacon construction models were successfully implemented. Functional iBeacon positioning children’s garments, such as suits, jackets, and skirts, were realized using four hardware components and one software component.
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References
Post, E.R., Orth, M., Russo, P.R., Gershenfeld, N.: E-broidery: design and fabrication of textile-based computing. IBM Syst. J. 39, 840–860 (2000)
Reichl, H., Kallmayer, C., Linz, T.: Electronic textiles in arts. In: Aarts, E.H.L., Encarnacao, J.L. (eds.) True Visions the Emergence of Ambient Intelligence, Wearable Computing Lab, pp. 115–132. Springer, Heidelberg (2006)
Berzowska, J.: Personal technologies: memory and intimacy through physical computing. Al Soc. 20, 446–461 (2006)
Mura, G.: Wearable technologies for emotion communication. METUJFA 25(1), 153–161 (2008)
Pandian, P.S., Mohanavelu, K., Safeer, K.P., et al.: Smart vest: wearable multi-parameter remote physiological monitoring system. Med. Eng. Phys. 30(4), 466–477 (2008)
Berzowka, J., Bromley, M.: Soft Computation Through Conductive Textiles (2007). www.xslabs.net/papers/ifftio7-berzowska-AQ.pdf. Accessed April 2010
Nakad, Z.S.: “Architectures for e-textiles”, Ph.D. thesis, Virginia Poytechnic Institute, Blacksburg, VA (2003)
Yavuz, K., Taneer, A., Ender, Y.B., et al.: Active T-shirt. Int. J. Clothing Sci. Technol. 23(4), 249–256 (2011)
Schaar, A.K., Ziefle, M.: Smart clothing: perceived benefits vs. perceived fears. In: ODONGHUE J. The Fifth International Conference on Pervasive Computing Technologies for Healthcare (Pervasive Health). Dublin: Institute for Computer Sciences, pp. 601–608 (2011)
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Hong, W., Miao, Y. (2021). Children’s Garments Based Near Filed Positioning Safety Oriented to Intelligence. In: Ahram, T.Z., Falcão, C.S. (eds) Advances in Usability, User Experience, Wearable and Assistive Technology. AHFE 2021. Lecture Notes in Networks and Systems, vol 275. Springer, Cham. https://doi.org/10.1007/978-3-030-80091-8_11
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