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| Cardiac Disease Classification Based on 3D Matrix Features Utilizing Multi-Channel Heart Sound Signals |
| Fang Yu1#, Guo Zijian1, Leng Hongxia1, Liu Xing1, Wang Weibo1, Liu Dongbo1#*, Wu Xiaochen2* |
1(School of Electrical Engineering and Electronic Information, Xihua University, Chengdu 610039, China)
2(Cardiovascular Department,General Hospital of Western Command Theater,Chengdu 610083, China) |
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Abstract This study proposes a method for classifying cardiac diseases by extracting 3D matrix features from multi-channel heart sound signals, addressing the limitations of traditional methods that primarily utilize one-dimensional features from single-channel signals, which may overlook pathological correlations across different channels and cycles. First, a Butterworth filter was applied for noise reduction on the heart sound signals from each channel. The R-wave peaks were then located to segment the heart sounds, from which 15 effective time-frequency features, including Welch method power spectral energy, are extracted. Subsequently, these features were stacked into a 3D matrix with dimensions corresponding to the number of channels, cycles, and features, with the optimal cycle number determined to be 4. This 3D matrix was directly used as input for a CNN classifier. The method was tested on a dataset comprising 126 normal and 185 abnormal heart sounds, achieving an accuracy of 98.9%. Additionally, the method was validated on 126 clinical cases of congenital heart disease sounds and normal sounds, resulting in a classification accuracy of 93.9%. These experimental results indicated that the 3D matrix features could effectively capture pathological characteristics in the heart sound signals, improving the classification accuracy by 2.7% compared to single-channel features, providing valuable assistance for clinical cardiac treatment.
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Received: 06 December 2023
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Corresponding Authors:
*E-mail: liudb@mail.xhu.edu.cn; wxc1126@yeah.net
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