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http://dx.doi.org/10.1007/s13534-018-0081-4

Simultaneous monitoring of motion ECG of two subjects using Bluetooth Piconet and baseline drift  

Dave, Tejal (Instrumentation and Control Engineering Department, Sarvajanik College of Engineering & Technology, Gujarat Technological University (GTU))
Pandya, Utpal (Instrumentation and Control Engineering Department, Sarvajanik College of Engineering & Technology, Gujarat Technological University (GTU))
Publication Information
Biomedical Engineering Letters / v.8, no.4, 2018 , pp. 365-371 More about this Journal
Abstract
Uninterrupted monitoring of multiple subjects is required for mass causality events, in hospital environment or for sports by medical technicians or physicians. Movement of subjects under monitoring requires such system to be wireless, sometimes demands multiple transmitters and a receiver as a base station and monitored parameter must not be corrupted by any noise before further diagnosis. A Bluetooth Piconet network is visualized, where each subject carries a Bluetooth transmitter module that acquires vital sign continuously and relays to Bluetooth enabled device where, further signal processing is done. In this paper, a wireless network is realized to capture ECG of two subjects performing different activities like cycling, jogging, staircase climbing at 100 Hz frequency using prototyped Bluetooth module. The paper demonstrates removal of baseline drift using Fast Fourier Transform and Inverse Fast Fourier Transform and removal of high frequency noise using moving average and S-Golay algorithm. Experimental results highlight the efficacy of the proposed work to monitor any vital sign parameters of multiple subjects simultaneously. The importance of removing baseline drift before high frequency noise removal is shown using experimental results. It is possible to use Bluetooth Piconet frame work to capture ECG simultaneously for more than two subjects. For the applications where there will be larger body movement, baseline drift removal is a major concern and hence along with wireless transmission issues, baseline drift removal before high frequency noise removal is necessary for further feature extraction.
Keywords
Ambulatory Electrocardiogram (AECG); $Bluetooth^{TM}$ Piconet; Wireless communication; Noise removal Root mean square deviation (RMSD); Serial port profile (SPP);
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