Title of article
Arrhythmia Classification of ECG Signals Using Hybrid Features
Author/Authors
Anwar, Syed Muhammad Department of Software Engineering - University of Engineering and Technology - Taxila, Pakistan , Gul, Maheen Department of Computer Engineering - University of Engineering and Technology - Taxila, Pakistan , Majid, Muhammad Department of Computer Engineering - University of Engineering and Technology - Taxila, Pakistan , Alnowami, Majdi Department of Nuclear Engineering - King Abdulaziz University - Jeddah, Saudi Arabia
Pages
8
From page
1
To page
8
Abstract
Automatic detection and classification of life-threatening arrhythmia plays an important part in dealing with various cardiac
conditions. In this paper, a novel method for classification of various types of arrhythmia using morphological and dynamic
features is presented. Discrete wavelet transform (DWT) is applied on each heart beat to obtain the morphological features. It
provides better time and frequency resolution of the electrocardiogram (ECG) signal, which helps in decoding important
information of a quasiperiodic ECG using variable window sizes. RR interval information is used as a dynamic feature. .e
nonlinear dynamics of RR interval are captured using Teager energy operator, which improves the arrhythmia classification.
Moreover, to remove redundancy, DWT subbands are subjected to dimensionality reduction using independent component
analysis, and a total of twelve coefficients are selected as morphological features. .ese hybrid features are combined and fed to
a neural network to classify arrhythmia. .e proposed algorithm has been tested over MIT-BIH arrhythmia database using
13724 beats and MIT-BIH supraventricular arrhythmia database using 22151 beats. .e proposed methodology resulted in an
improved average accuracy of 99.75% and 99.84% for class- and subject-oriented scheme, respectively, using three-fold
cross validation.
Keywords
ECG , DWT , Hybrid , MIT-BIH
Journal title
Computational and Mathematical Methods in Medicine
Serial Year
2018
Full Text URL
Record number
2610234
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