A Study on Intrabody Communication for Personal Healthcare Monitoring System

The body itself can be used to conduct sensor data to a central hub. In this report, electrocardiogram data were sent from the chest region to the left wrist for subsequent transmission in a telehealth configuration. Two modulation schemes (Quadrative Phase Shift Keying [QPSK] and Binary Phase Shift...

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Veröffentlicht in:	Telemedicine journal and e-health 2008-10, Vol.14 (8), p.851-857
Hauptverfasser:	Alshehab, Abdullah, Kobayashi, Nao, Ruiz, Jordi, Kikuchi, Ryosuke, Shimamoto, Shigeru, Ishibashi, Hiroshi
Format:	Artikel
Sprache:	eng
Schlagworte:	Biosensing Techniques - instrumentation Company business management Computer Communication Networks - instrumentation E-health Health care industry HEALTHCOM 2008 Humans Management Monitoring, Ambulatory - instrumentation Monitoring, Physiologic - instrumentation Monitoring, Physiologic - methods Patient monitoring Physiologic monitoring Sensitivity and Specificity Services Signal Processing, Computer-Assisted - instrumentation Technology application Telemedicine - instrumentation Telemetry - instrumentation Telemetry - methods
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container_title	Telemedicine journal and e-health
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creator	Alshehab, Abdullah Kobayashi, Nao Ruiz, Jordi Kikuchi, Ryosuke Shimamoto, Shigeru Ishibashi, Hiroshi
description	The body itself can be used to conduct sensor data to a central hub. In this report, electrocardiogram data were sent from the chest region to the left wrist for subsequent transmission in a telehealth configuration. Two modulation schemes (Quadrative Phase Shift Keying [QPSK] and Binary Phase Shift Keying [BPSK]) could be used for the intrabody communication. With the body as a conductor of signal up to 2.4G Hz and a decrease in transmission power, the optimal carrier frequency shifted to a lower range of 75 MHz–150 MHz. Both QPSK and BPSK performed well. In this paper we propose the use of intrabody communication (IBC) for a personal health monitoring system employing inexpensive, lightweight, miniature sensor platforms. Body area networks (BANs) with physiological sensors could improve current healthcare services and at the same time significantly reduce costs to public health systems. We are primarily looking to reduce the transmission power consumption of the wireless communication links by using very low power IBC to connect the BAN sensors, a change that has also been shown to increase the durability of the sensors. There has been no specific study carried out to date on the optimal modulation scheme for such IBC. For this reason, we investigated the transmission characteristics of the human body as a conductor of signal up to 2.4 GHz by considering different transmitter power consumption and data transmission rates. We believe that an optimal modulation scheme for IBC would allow an increase of the data transmission bit rate in our personal health monitoring system model. Therefore, we evaluated the performance of two different modulation schemes, QPSK and BPSK. Our experiment is conducted with point-to-point communication between an electrocardiogram sensor located in the chest region and a central hub located on the left wrist.
doi_str_mv	10.1089/tmj.2008.0102
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In this report, electrocardiogram data were sent from the chest region to the left wrist for subsequent transmission in a telehealth configuration. Two modulation schemes (Quadrative Phase Shift Keying [QPSK] and Binary Phase Shift Keying [BPSK]) could be used for the intrabody communication. With the body as a conductor of signal up to 2.4G Hz and a decrease in transmission power, the optimal carrier frequency shifted to a lower range of 75 MHz–150 MHz. Both QPSK and BPSK performed well. In this paper we propose the use of intrabody communication (IBC) for a personal health monitoring system employing inexpensive, lightweight, miniature sensor platforms. Body area networks (BANs) with physiological sensors could improve current healthcare services and at the same time significantly reduce costs to public health systems. We are primarily looking to reduce the transmission power consumption of the wireless communication links by using very low power IBC to connect the BAN sensors, a change that has also been shown to increase the durability of the sensors. There has been no specific study carried out to date on the optimal modulation scheme for such IBC. For this reason, we investigated the transmission characteristics of the human body as a conductor of signal up to 2.4 GHz by considering different transmitter power consumption and data transmission rates. We believe that an optimal modulation scheme for IBC would allow an increase of the data transmission bit rate in our personal health monitoring system model. Therefore, we evaluated the performance of two different modulation schemes, QPSK and BPSK. 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We are primarily looking to reduce the transmission power consumption of the wireless communication links by using very low power IBC to connect the BAN sensors, a change that has also been shown to increase the durability of the sensors. There has been no specific study carried out to date on the optimal modulation scheme for such IBC. For this reason, we investigated the transmission characteristics of the human body as a conductor of signal up to 2.4 GHz by considering different transmitter power consumption and data transmission rates. We believe that an optimal modulation scheme for IBC would allow an increase of the data transmission bit rate in our personal health monitoring system model. Therefore, we evaluated the performance of two different modulation schemes, QPSK and BPSK. 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subjects	Biosensing Techniques - instrumentation Company business management Computer Communication Networks - instrumentation E-health Health care industry HEALTHCOM 2008 Humans Management Monitoring, Ambulatory - instrumentation Monitoring, Physiologic - instrumentation Monitoring, Physiologic - methods Patient monitoring Physiologic monitoring Sensitivity and Specificity Services Signal Processing, Computer-Assisted - instrumentation Technology application Telemedicine - instrumentation Telemetry - instrumentation Telemetry - methods
title	A Study on Intrabody Communication for Personal Healthcare Monitoring System
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