Subscribe to RSS
Download PDF
DOI: 10.1055/s-0038-1633863
Wearable Systems for Health Care Applications
Publication History
Publication Date:
05 February 2018 (online)
Summary
Objectives: Wearable systems can be broadly defined as mobile electronic devices that can be unobtrusively embedded in the user’s outfit as part of the clothing or an accessory. In particular, unlike conventional mobile systems, they can be operational and accessed without or with very little hindrance to user activity. To this end they are able to model and recognize user activity, state, and the surrounding situation: a property, referred to as context sensitivity. Wearable systems range from micro sensors seamlessly integrated in textiles through consumer electronics embedded in fashionable clothes and computerized watches to belt worn PCs with a head mounted display. The wearable computing concept is part of a broader framework of ubiquitous computing that aims at invisibly enhancing our environment with smart electronic devices.
The goal of the paper is to provide a broad overview of wearable technology and its implications for health related applications.
Methods: We begin by summarizing the vision behind wearable computing. We then describe a framework for wearable computing architecture and the main technological aspects. Finally we show how specific properties of wearable systems can be used in different health related application domains.
Results: Wearable computing is an emerging concept building upon the success of today’s mobile computing and communication devices. Due to rapid technological progress it is currently making a transition from a pure research stage to practical applications. Many of those applications are in health related domains, in particular, health monitoring, mobile treatment and nursing.
Conclusions: Within the next couple of years wearable systems and more general ubiquitous computing will introduce profound changes and new application types to health related systems. In particular they will prove useful in improving the quality and reducing the cost of caring for the aging population.
-
References
- 1 Starner T. The challenges of wearable computing: Part 1 and 2. IEEE Micro 2001; 21 (04) 44-67.
- 2 Mann S. Smart clothing. The wearable computer and wearcam. Personal Technologies 1997; 1: 1
- 3 Pentland A. Wearable intelligence. Scientific American 1998; 276: 1
- 4 Dey AK, Salber D, Abowd GD, Futakawa M. The conference assistant: Combining context awareness with wearable computing. ISWC 1999; 21-28.
- 5 Cottet D, Grzyb J, Kirstein T, Tröster G. Electrical Characterization of Textile Transmission Lines. IEEE Transactions on Advanced Packaging 2003; 26 (02) 182-90.
- 6 Götz A, Gràcia I, Cané C, Morrissey A, Alderman J. Manufacturing and Packaging of Sensors for Their Integration in a Vertical MCM Microsystem for Biomedical Applications. IEEE Journal of Microelectromechanical Systems 2001; 10 (04) 569-79.
- 7 Tummala RR. Fundamentals of Microsystems Packaging. McGraw-Hill; 2001
- 8 Lukowicz P, Anliker U, Ward J, Tröster G, Hirt E, Neufelt C. AMON: A Wearable Medical Computer for High Risk Patients. ISWC 2002: Proceedings of the 6th International Symposium on Wearable Computers, Oct. 7-10. 2002: 133-134.
- 9 Marculescu D. et al. Electronic Textiles: A Platform for Pervasive Computing, Proceedings of the IEEE. 2003; 91: 12
- 10 Philips. www.extra.research.philips.com/euprojects/myheart/
- 11 Kirstein T, Lawrence M, Tröster G. Functional Electrical Stimulation (FES) with Smart Textile Electrodes. Proc Wearable Systems for e-Health Workshop. Pisa, Italy: 2003. Dec 11-14.
- 12 Weiser M. The computer for the 21st century. Scientific American 1991; 265 (03) 66-75.
- 13 Barber C, Haniff DJ, Woolley SI. Contrasting paradigms for the development of wearable computers. IBM Systems J 1999; 38 (04) 551-65.
- 14 wearit. www.tzi.de/wearIT-at-work/