Wearable Vital Signal Monitoring Prototype Based on Capacitive Body Channel Communication

2022 IEEE-EMBS International Conference on Wearable and Implantable Body Sensor Networks (BSN) Pub Date : 2022-09-27 DOI:10.1109/BSN56160.2022.9928512

Qi Huang, Waseem Alkhayer, M. Fouda, Abdulkadir Celik, A. Eltawil

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引用次数: 3

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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基于电容式身体通道通信的可穿戴生命信号监测样机

无线体域网络(WBAN)提供了一种不受日常生活限制的无缝个人健康监测手段。迄今为止，射频(RF)收发器一直是首选技术，然而，诸如易受人体阴影效应的影响，由于全向辐射和安全问题导致的更高功耗等缺点促使采用使用人体信道进行通信的收发器。本文介绍了一种基于人体信道通信(HBC)的生命信号监测收发器原型，该收发器采用市售芯片组。对射频通信和HBC通信进行了简要的回顾和比较，并介绍了不同的HBC通信方案。然后讨论了一个代表人体通道的电路模型，并给出了仿真来说明返回路径电容和接收器终端对路径损耗的影响。然后介绍了收发器原型的架构，其中它被设计为符合21 MHz IEEE 802.15.6标准的载波频率。最后，对收发器的误码率和功率效率等性能进行了分析。在两种不同的情况下测量了路径损耗，其中由于环境影响观察到高达5db的变化。在1.3 Mbps的最大数据速率下测量的能源效率为8.3 nJ/b。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2022 IEEE-EMBS International Conference on Wearable and Implantable Body Sensor Networks (BSN)

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