DocumentCode
184431
Title
Realtime ECG baseline removal: An isoelectric point estimation approach
Author
Guven, Onur ; Eftekhar, Amir ; Hoshyar, Reza ; Frattini, Giovanni ; Kindt, Wilko ; Constandinou, Timothy G.
Author_Institution
Dept. of Electr. & Electron. Eng., Imperial Coll. London, London, UK
fYear
2014
fDate
22-24 Oct. 2014
Firstpage
29
Lastpage
32
Abstract
This paper presents a novel method for ECG baseline drift removal while preserving the integrity of the ST segment. Baseline estimation is achieved by tracking 3 isoelectric points within the ECG waveform as fiducial markers used in an interpolation filter. These points are determined relative to the QRS complex, which is extracted using a known method (Pan-Tompkins algorithm). The proposed algorithm has been tested extensively using synthetic signals and also validated with real data. The synthetic signals assume a 2mV p-p ECG signal and 300 μV p-p baseline drift in the presence of noise artefacts including EMG pickup (20 dB - max. 200 μV), and residual power-line interference (50 μV p-p). The results show a maximum (worst-case ST-segment distortion) error of 34.7 μV (mean), 27.8 μV (median) and 21.2 μV (std. dev.) across 50 randomly generated synthetic ECG signals each containing 100 heartbeats. Validation of the algorithm applied to signals from the MIT-BIH arrhythmia databases reveals maximum error per P-T interval with mean, median and std. dev. of 34.4 μV, 35.2 μV and 9.6 μV respectively with suppressed motion artefacts.
Keywords
electrocardiography; electromyography; interpolation; medical signal detection; medical signal processing; signal denoising; EMG pickup; MIT-BIH arrhythmia databases; Pan-Tompkins algorithm; QRS complex; fiducial markers; gain 20 dB; interpolation filter; isoelectric point estimation approach; isoelectric point tracking; motion artefact suppression; noise artefact suppression; randomly generated synthetic ECG signals; realtime ECG baseline drift removal; residual power-line interference; voltage 2 mV; voltage 200 muV; voltage 300 muV; voltage 50 muV; worst-case ST-segment distortion error; Accuracy; Databases; Electrocardiography; Electromyography; Estimation; Heart beat; Noise;
fLanguage
English
Publisher
ieee
Conference_Titel
Biomedical Circuits and Systems Conference (BioCAS), 2014 IEEE
Conference_Location
Lausanne
Type
conf
DOI
10.1109/BioCAS.2014.6981637
Filename
6981637
Link To Document