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Wearable vital signal monitoring prototype based on capacitive body channel communication

Wearable vital signal monitoring prototype based on capacitive body channel communication
Wearable vital signal monitoring prototype based on capacitive body channel communication

Wireless body area network (WBAN) provides a means for seamless individual health monitoring without imposing restrictive limitations on normal daily routines. To date, Radio Frequency (RF) transceivers have been the technology of choice, however, drawbacks such as vulnerability to body shadowing effects, higher power consumption due to omnidirectional radiation and security concerns, have prompted the adoption of transceivers that use the human body channel for communication. In this paper, a vital signal monitoring transceiver prototype based on the human body channel communication (HBC), using commercially available chipsets is presented. RF and HBC communications are briefly reviewed and compared, and different schemes of HBC are introduced. A circuit model that represents the human body channel is then discussed and simulations are presented to illustrate the influence of the return path capacitance and receiver terminations on the path loss. The architecture of the transceiver prototype is then introduced where it is designed at a 21 MHz IEEE 802.15.6 standard-compliant carrier frequency. Finally, the performance of the transceiver, including the bit error rate (BER) and power efficiency, are characterized. Path loss is measured for two different scenarios, where variations of up to 5 dB were observed due to environmental effects. Energy efficiency measured at a maximum data-rate of 1.3 Mbps was found to be 8.3 nJ/b.

Human body communication, Internet of Bodies, path loss simulation, vital signal monitoring, wearable prototype
IEEE
Huang, Qi
2e55afa8-93da-4360-89e1-062e9e644314
Alkhayer, Waseem
d2be9ae1-261f-49ea-8827-10e649d6fa25
Fouda, Mohammed E.
2e057c7d-98c9-4dcc-80de-25d74b0e2549
Celik, Abdulkadir
f8e72266-763c-4849-b38e-2ea2f50a69d0
Eltawil, Ahmed M.
5eb9e965-5ec8-4da1-baee-c3cab0fb2a72
Huang, Qi
2e55afa8-93da-4360-89e1-062e9e644314
Alkhayer, Waseem
d2be9ae1-261f-49ea-8827-10e649d6fa25
Fouda, Mohammed E.
2e057c7d-98c9-4dcc-80de-25d74b0e2549
Celik, Abdulkadir
f8e72266-763c-4849-b38e-2ea2f50a69d0
Eltawil, Ahmed M.
5eb9e965-5ec8-4da1-baee-c3cab0fb2a72

Huang, Qi, Alkhayer, Waseem, Fouda, Mohammed E., Celik, Abdulkadir and Eltawil, Ahmed M. (2022) Wearable vital signal monitoring prototype based on capacitive body channel communication. In BHI-BSN 2022 - IEEE-EMBS International Conference on Biomedical and Health Informatics and IEEE-EMBS International Conference on Wearable and Implantable Body Sensor Networks - Proceedings. IEEE.. (doi:10.1109/BSN56160.2022.9928512).

Record type: Conference or Workshop Item (Paper)

Abstract

Wireless body area network (WBAN) provides a means for seamless individual health monitoring without imposing restrictive limitations on normal daily routines. To date, Radio Frequency (RF) transceivers have been the technology of choice, however, drawbacks such as vulnerability to body shadowing effects, higher power consumption due to omnidirectional radiation and security concerns, have prompted the adoption of transceivers that use the human body channel for communication. In this paper, a vital signal monitoring transceiver prototype based on the human body channel communication (HBC), using commercially available chipsets is presented. RF and HBC communications are briefly reviewed and compared, and different schemes of HBC are introduced. A circuit model that represents the human body channel is then discussed and simulations are presented to illustrate the influence of the return path capacitance and receiver terminations on the path loss. The architecture of the transceiver prototype is then introduced where it is designed at a 21 MHz IEEE 802.15.6 standard-compliant carrier frequency. Finally, the performance of the transceiver, including the bit error rate (BER) and power efficiency, are characterized. Path loss is measured for two different scenarios, where variations of up to 5 dB were observed due to environmental effects. Energy efficiency measured at a maximum data-rate of 1.3 Mbps was found to be 8.3 nJ/b.

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More information

Published date: 2022
Additional Information: Publisher Copyright: © 2022 IEEE.
Venue - Dates: 2022 IEEE-EMBS International Conference on Wearable and Implantable Body Sensor Networks, BSN 2022, , Ioannina, Greece, 2022-09-27 - 2022-09-30
Keywords: Human body communication, Internet of Bodies, path loss simulation, vital signal monitoring, wearable prototype
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Identifiers

Local EPrints ID: 504830
URI: http://eprints.soton.ac.uk/id/eprint/504830
DOI: doi:10.1109/BSN56160.2022.9928512
PURE UUID: 97fc54bf-e0ce-46ee-84df-76ba1303f799
ORCID for Abdulkadir Celik: ORCID iD orcid.org/0000-0001-9007-9979

Catalogue record

Date deposited: 19 Sep 2025 16:35
Last modified: 20 Sep 2025 02:30

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Contributors

Author: Qi Huang
Author: Waseem Alkhayer
Author: Mohammed E. Fouda
Author: Abdulkadir Celik ORCID iD
Author: Ahmed M. Eltawil

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