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Communication Challenges in On-Body and
Body-to-Body Wearable Wireless
Networks—A Connectivity Perspective
Received: 15 May 2017; Accepted: 30 June 2017; Published: 6 July 2017
Abstract: Wearable wireless networks (WWNs) offer innovative ways to connect humans and/or objects anywhere, anytime, within an infinite variety of applications. WWNs include three levels of communications: on-body, body-to-body and off-body communication. Successful communication in on-body and body-to-body networks is often challenging due to ultra-low power consumption,
processing and storage capabilities, which have a significant impact on the achievable throughput and packet reception ratio as well as latency.
Consequently, all these factors make it difficult to opt for an appropriate technology to optimize communication performance, which predominantly depends on the given application. In particular, this work emphasizes the impact of coarse-grain factors (such as dynamic and diverse mobility, radio-link and signal propagation, interference management, data dissemination schemes, and routing approaches) directly affecting the communication performance in WWNs. Experiments have been performed on a real testbed to investigate
the connectivity behavior on two wireless communication levels: on-body and body-to-body.
It is concluded that by considering the impact of above-mentioned factors, the general perception of using specific technologies may not be correct. Indeed, for on-body communication, by using the IEEE 802.15.6 standard (which is specifically designed for on-body communication), it is observed that while operating at low transmission power under realistic conditions, the connectivity can be significantly low, thus, the transmission power has to be tuned carefully. Similarly, for body-to-body communication in an indoor environment, WiFi IEEE 802.11n also has a high threshold of end-to-end disconnections beyond two hops (approximately 25 m). Therefore, these facts promote the use
of novel technologies such as 802.11ac, NarrowBand-IoT (NB-IoT) etc. as possible candidates for body-to-body communications as a part of the Internet of humans concept.
https://stop007crimes.files.wordpress.com/2018/04/technologies-05-00043-v2.pdf
ALSO SEE
https://stop007crimes.files.wordpress.com/2018/04/technologies-05-00043-g001.png
https://stop007crimes.files.wordpress.com/2018/04/technologies-05-00043-v2.pdf
Article
Communication Challenges in On-Body and
Body-to-Body Wearable Wireless
Networks—A Connectivity Perspective
Received: 15 May 2017; Accepted: 30 June 2017; Published: 6 July 2017
Abstract: Wearable wireless networks (WWNs) offer innovative ways to connect humans and/or objects anywhere, anytime, within an infinite variety of applications. WWNs include three levels of communications: on-body, body-to-body and off-body communication. Successful communication in on-body and body-to-body networks is often challenging due to ultra-low power consumption,
processing and storage capabilities, which have a significant impact on the achievable throughput and packet reception ratio as well as latency.
Consequently, all these factors make it difficult to opt for an appropriate technology to optimize communication performance, which predominantly depends on the given application. In particular, this work emphasizes the impact of coarse-grain factors (such as dynamic and diverse mobility, radio-link and signal propagation, interference management, data dissemination schemes, and routing approaches) directly affecting the communication performance in WWNs. Experiments have been performed on a real testbed to investigate
the connectivity behavior on two wireless communication levels: on-body and body-to-body.
It is concluded that by considering the impact of above-mentioned factors, the general perception of using specific technologies may not be correct. Indeed, for on-body communication, by using the IEEE 802.15.6 standard (which is specifically designed for on-body communication), it is observed that while operating at low transmission power under realistic conditions, the connectivity can be significantly low, thus, the transmission power has to be tuned carefully. Similarly, for body-to-body communication in an indoor environment, WiFi IEEE 802.11n also has a high threshold of end-to-end disconnections beyond two hops (approximately 25 m). Therefore, these facts promote the use
of novel technologies such as 802.11ac, NarrowBand-IoT (NB-IoT) etc. as possible candidates for body-to-body communications as a part of the Internet of humans concept.
https://stop007crimes.files.wordpress.com/2018/04/technologies-05-00043-v2.pdf
ALSO SEE
https://stop007crimes.files.wordpress.com/2018/04/technologies-05-00043-g001.png
https://stop007crimes.files.wordpress.com/2018/04/technologies-05-00043-v2.pdf
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