Electronic intelligence development for wearable applications
Hännikäinen, J. (2006)
Hännikäinen, J.
Tampere University of Technology
2006
Sähkötekniikan osasto - Department of Elecrical Engineering
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Julkaisun pysyvä osoite on
https://urn.fi/URN:NBN:fi:tty-200902201015
https://urn.fi/URN:NBN:fi:tty-200902201015
Tiivistelmä
In recent years there has been an enormous growth in the diversity and market penetration of small electronics appliances. Nowadays, people commonly carry such devices as mobile phones, Personal Digital Assistants (PDAs), and electronic sports accessories as an essential part of daily life. These devices are typically carried in pockets or bags and handheld when in use. User Interface (UI) devices are located on strategic parts of the body such as the wrist to facilitate free and easy access to them. An ease-of-use solution for carrying the increasing number of such personal devices is to embed or integrate them into clothing and accessories. Such solutions are known as wearable electronics systems and they are becoming essential aids for people in a wide range of applications areas such as communication, maintenance and repair, and location and navigation.
This trend has caused a growing need to create smaller and lighter devices which can be unobtrusively integrated and embedded in clothing. To achieve this, suitable applications for mobile environments as well as specific clothing-like technologies for their design and implementation need to be developed.
This study investigated specific applications utilising clothing as electronics platforms to ascertain whether usable clothing platform applications can be designed and implemented. This was done by implementing five wearable electronics application prototypes as clothing platforms: a fully functional smart clothing prototype for survival in arctic environments, two electrical heating prototypes to maintain users thermal comfort conditions, a personal positioning vest for fishing, and a bioimpedance measurement suit for Total Body Water (TBW) estimation. For the implementation, application-specific solutions were utilized. Functionality, user acceptance, and usability of prototypes were verified. Usability evaluations were also made for a specific location and information service application. This was done to elicit the importance of usability evaluations in the wearable electronics field and also to evaluate user acceptance of the new technological devices and applications.
Specific materials required for the construction of comfortable clothing platform applications are Electrically Conductive Fiber (ECF) yarns, which are used in power and data transfer as well as in sensing elements. In addition, a concept of button component encasing for electronics components has been developed. Here, the components are hidden and connected to the clothes in a tailored way. Flexible Printed Wiring Board (PWB) is also utilized as a platform for a wearable antenna to achieve wearer comfort in wireless data transmission applications.
The implemented prototypes proved functional and it was demonstrated that such systems could be constructed utilizing clothing platforms. To ensure user acceptance, the usability of the systems and end user needs were considered key elements in the design process.
This trend has caused a growing need to create smaller and lighter devices which can be unobtrusively integrated and embedded in clothing. To achieve this, suitable applications for mobile environments as well as specific clothing-like technologies for their design and implementation need to be developed.
This study investigated specific applications utilising clothing as electronics platforms to ascertain whether usable clothing platform applications can be designed and implemented. This was done by implementing five wearable electronics application prototypes as clothing platforms: a fully functional smart clothing prototype for survival in arctic environments, two electrical heating prototypes to maintain users thermal comfort conditions, a personal positioning vest for fishing, and a bioimpedance measurement suit for Total Body Water (TBW) estimation. For the implementation, application-specific solutions were utilized. Functionality, user acceptance, and usability of prototypes were verified. Usability evaluations were also made for a specific location and information service application. This was done to elicit the importance of usability evaluations in the wearable electronics field and also to evaluate user acceptance of the new technological devices and applications.
Specific materials required for the construction of comfortable clothing platform applications are Electrically Conductive Fiber (ECF) yarns, which are used in power and data transfer as well as in sensing elements. In addition, a concept of button component encasing for electronics components has been developed. Here, the components are hidden and connected to the clothes in a tailored way. Flexible Printed Wiring Board (PWB) is also utilized as a platform for a wearable antenna to achieve wearer comfort in wireless data transmission applications.
The implemented prototypes proved functional and it was demonstrated that such systems could be constructed utilizing clothing platforms. To ensure user acceptance, the usability of the systems and end user needs were considered key elements in the design process.
Kokoelmat
- Väitöskirjat [4865]