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Printed Elastronics for Wireless Wearable Electronics

Tutkimustuotos: Konferenssiesitys, posteri tai abstrakti

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Printed Elastronics for Wireless Wearable Electronics. / Mäntysalo, Matti.

2019. Julkaisun esittämispaikka: International Conference of Polymeric and Organic Materials in Yamagata University, Yonezawa, Japani.

Tutkimustuotos: Konferenssiesitys, posteri tai abstrakti

Harvard

Mäntysalo, M 2019, 'Printed Elastronics for Wireless Wearable Electronics' Artikkeli esitetty International Conference of Polymeric and Organic Materials in Yamagata University, Yonezawa, Japani, 17/12/19 - 20/12/19, .

APA

Mäntysalo, M. (2019). Printed Elastronics for Wireless Wearable Electronics. Julkaisun esittämispaikka: International Conference of Polymeric and Organic Materials in Yamagata University, Yonezawa, Japani.

Vancouver

Mäntysalo M. Printed Elastronics for Wireless Wearable Electronics. 2019. Julkaisun esittämispaikka: International Conference of Polymeric and Organic Materials in Yamagata University, Yonezawa, Japani.

Author

Mäntysalo, Matti. / Printed Elastronics for Wireless Wearable Electronics. Julkaisun esittämispaikka: International Conference of Polymeric and Organic Materials in Yamagata University, Yonezawa, Japani.

Bibtex - Lataa

@conference{0205566c54eb40aea0d77c41cd27c144,
title = "Printed Elastronics for Wireless Wearable Electronics",
abstract = "Quantified self-tools and eHealth services based on the Internet-of-Things (IoT) and big-data analyses have a great potential. In these kind of systems, wearable wireless sensor nodes are used to measure different physiological parameters and activities like movement, pressure wave, muscle activity, heart activity, body temperature, etc. The key elements for such a development are: 1) cloud computing, big-data analyses, and development of new health markers, and 2) development of unobtrusive cost-effective sensor nodes. This presentation focuses on the latter by presenting an intelligent, conformable, user friendly physiological monitoring platform for continual nonintrusive wireless monitoring. To reach the full potential of wearables, electronics hardware must become soft, light-weight, thin, conformable to the body and, especially, inexpensive to manufacture. The proposed approach is based on low-cost printing processes enabling the wider exploitation of the results, i.e. affordable disposable sensors and e-textiles. Printing elastronic (elastic electronic) components like antennas, interconnects, electrodes, temperature sensors, and pressure sensors on low-cost soft and biocompatible substrates, like thermoplastic polyurethane (TPU), enables continuous (24/7) monitoring. This presentation will focus on utilization of inkjet and screen printing technologies in wireless wearable elastronics fabrication.",
author = "Matti M{\"a}ntysalo",
year = "2019",
month = "12",
language = "English",
note = "null ; Conference date: 17-12-2019 Through 20-12-2019",
url = "http://ipomy.yz.yamagata-u.ac.jp/2nd/",

}

RIS (suitable for import to EndNote) - Lataa

TY - CONF

T1 - Printed Elastronics for Wireless Wearable Electronics

AU - Mäntysalo, Matti

PY - 2019/12

Y1 - 2019/12

N2 - Quantified self-tools and eHealth services based on the Internet-of-Things (IoT) and big-data analyses have a great potential. In these kind of systems, wearable wireless sensor nodes are used to measure different physiological parameters and activities like movement, pressure wave, muscle activity, heart activity, body temperature, etc. The key elements for such a development are: 1) cloud computing, big-data analyses, and development of new health markers, and 2) development of unobtrusive cost-effective sensor nodes. This presentation focuses on the latter by presenting an intelligent, conformable, user friendly physiological monitoring platform for continual nonintrusive wireless monitoring. To reach the full potential of wearables, electronics hardware must become soft, light-weight, thin, conformable to the body and, especially, inexpensive to manufacture. The proposed approach is based on low-cost printing processes enabling the wider exploitation of the results, i.e. affordable disposable sensors and e-textiles. Printing elastronic (elastic electronic) components like antennas, interconnects, electrodes, temperature sensors, and pressure sensors on low-cost soft and biocompatible substrates, like thermoplastic polyurethane (TPU), enables continuous (24/7) monitoring. This presentation will focus on utilization of inkjet and screen printing technologies in wireless wearable elastronics fabrication.

AB - Quantified self-tools and eHealth services based on the Internet-of-Things (IoT) and big-data analyses have a great potential. In these kind of systems, wearable wireless sensor nodes are used to measure different physiological parameters and activities like movement, pressure wave, muscle activity, heart activity, body temperature, etc. The key elements for such a development are: 1) cloud computing, big-data analyses, and development of new health markers, and 2) development of unobtrusive cost-effective sensor nodes. This presentation focuses on the latter by presenting an intelligent, conformable, user friendly physiological monitoring platform for continual nonintrusive wireless monitoring. To reach the full potential of wearables, electronics hardware must become soft, light-weight, thin, conformable to the body and, especially, inexpensive to manufacture. The proposed approach is based on low-cost printing processes enabling the wider exploitation of the results, i.e. affordable disposable sensors and e-textiles. Printing elastronic (elastic electronic) components like antennas, interconnects, electrodes, temperature sensors, and pressure sensors on low-cost soft and biocompatible substrates, like thermoplastic polyurethane (TPU), enables continuous (24/7) monitoring. This presentation will focus on utilization of inkjet and screen printing technologies in wireless wearable elastronics fabrication.

M3 - Paper, poster or abstract

ER -