Health Monitoring System Based on Intra-Body Communication

• Published in: IOP Conference Series: Materials Science and Engineering
• Main Author: Razak A.H.A.; Ibrahim I.W.; Ayub A.H.; Amri M.F.; Hamzi M.H.; Halim A.K.; Ahmad A.; Al Junid S.A.M.
• Format: Conference paper
• Language: English
• Published: Institute of Physics Publishing 2015
• Online Access: https://www.scopus.com/inward/record.uri?eid=2-s2.0-84960868809&doi=10.1088%2f1757-899X%2f99%2f1%2f012028&partnerID=40&md5=3ae50638c80f22a5ed27793fb31d03ed

This paper presents a model of a Body Area Network (BAN) health monitoring system based on Intra-Body Communication. Intra-body Communication (IBC) is a communication technique that uses the human body as a medium for electrical signal communication. One of the visions in the health care industry is to provide autonomous and continuous self and the remote health monitoring system. This can be achieved via BAN, LAN and WAN integration. The BAN technology itself consists of short range data communication modules, sensors, controller and actuators. The information can be transmitted to the LAN and WAN via the RF technology such as Bluetooth, ZigBee and ANT. Although the implementations of RF communication have been successful, there are still limitations in term of power consumption, battery lifetime, interferences and signal attenuations. One of the solutions for Medical Body Area Network (MBANs) to overcome these issues is by using an IBC technique because it can operate at lower frequencies and power consumption compared to the existing techniques. The first objective is to design the IBC's transmitter and receiver modules using the off the shelf components. The specifications of the modules such as frequency, data rate, modulation and demodulation coding system were defined. The individual module were designed and tested separately. The modules was integrated as an IBC system and tested for functionality then was implemented on PCB. Next objective is to model and implement the digital parts of the transmitter and receiver modules on the Altera's FPGA board. The digital blocks were interfaced with the FPGA's on board modules and the discrete components. The signals that have been received from the transmitter were converted into a proper waveform and it can be viewed via external devices such as oscilloscope and Labview. The signals such as heartbeats or pulses can also be displayed on LCD. In conclusion, the IBC project presents medical health monitoring model that operates at the range of 21 MHz frequency and reduce the power consumption for a longer battery lifetime. © Published under licence by IOP Publishing Ltd.