Authors: Jia-Rong Yeh, Ai-Hsien Li, Jiann-Shing Shieh, Yen-An Su, Chi-Yu Yang

Abstract:

In this paper, an automatic detecting algorithm for QRS complex detecting was applied for analyzing ECG recordings and five criteria for dangerous arrhythmia diagnosing are applied for a protocol type of automatic arrhythmia diagnosing system. The automatic detecting algorithm applied in this paper detected the distribution of QRS complexes in ECG recordings and related information, such as heart rate and RR interval. In this investigation, twenty sampled ECG recordings of patients with different pathologic conditions were collected for off-line analysis. A combinative application of four digital filters for bettering ECG signals and promoting detecting rate for QRS complex was proposed as pre-processing. Both of hardware filters and digital filters were applied to eliminate different types of noises mixed with ECG recordings. Then, an automatic detecting algorithm of QRS complex was applied for verifying the distribution of QRS complex. Finally, the quantitative clinic criteria for diagnosing arrhythmia were programmed in a practical application for automatic arrhythmia diagnosing as a post-processor. The results of diagnoses by automatic dangerous arrhythmia diagnosing were compared with the results of off-line diagnoses by experienced clinic physicians. The results of comparison showed the application of automatic dangerous arrhythmia diagnosis performed a matching rate of 95% compared with an experienced physician-s diagnoses.

Keywords: Signal processing, electrocardiography (ECG), QRS complex, arrhythmia.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1083767

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References:

[1] Rissam HS; Kishore S; Srivastava S; Bhatia ML; Trehan N AUTHOR, Evaluation of cardiac symptoms by trans-telephonic electrocardiographic monitoring (TTEM): preliminary experience. Indian Heart J 50(1):55-8, Jan-Feb 1998.
[2] I.K. Daskalov, I.I. Christov. Electrocardiogram signal preprocessing for automatic detection of QRS . Med Eng & Phys, 37-44, 1999.
[3] M. Bahoura, M. Hassani, M. Hubin, DSP implementation of wavelet transform for real time ECG wave forms detection and heart rate analysis, computer method & programs in biomedicine, 52: 35-44 , 1997.
[4] P. Jiapu and W. J. Tompkins., A Real-Time QRS Detection Algorithm, IEEE trans. on bio-medical engineering, 32(3): 230-236, March 1985.
[5] J. Lee, K. Jeong, J. Yoon; M. Lee, A Simple Real-Time QRS Detection Algorithm, 18th Annual Intern. Conference of the IEEE Engineering in Medicine and Biology Society, 4: 1396-1398, Nov. 1996.
[6] Saeid Reza Seydnejad and Richard I. Kitney, Real-Time Heart Rate Variability Extraction Using The Kaiser Window, IEEE Transactions on Biomedical Engineering, 44: 990-1005, Oct. 1997.
[7] G. M. Friesen, T. C. Jannett, M. A. Jadallah, S. L. Yates, S. R. Quint, and H. T. Nagle,A Comparison of the Noise Sensitivity of Nine QRS Detection Algorithms, IEEE Transactions on Biomedical Engineering, 37(1): 85-98, Jan 1990.
[8] Barbara Aehlert, RN, ECGs MADE EASY 2/e, Elsevier (Singapore) Pte Ltd.,2003.
[9] J. Enderle, S. Blanchard, and J. Bronzino, Introduction to Biomedical Engineering, Academic Press, 2000.
[10] R. Ganguli, Noise and Outlier Removal from Jet Engine Health Signals using Weighted FIR Median Hybrid Filters, Mechanical Systems and Signal Processing, 16(6) 967-978, 2002.
[11] G. Rizzoni, Principles and Applications of Electrical Engineering, 2nd.ed, The Ohio State University, 1996.