Abstract
Automated electrocardiogram (ECG) analysis for arrhythmia detection plays a critical role in early prevention and diagnosis of cardiovascular diseases. Extracting powerful features from raw ECG signals for fine-grained diseases classification is still a challenging problem today due to variable abnormal rhythms and noise distribution. For ECG analysis, the previous research works depend mostly on heartbeat or single scale signal segments, which ignores underlying complementary information of different scales. In this paper, we formulate a novel end-to-end Deep Multi-Scale Fusion convolutional neural network (DMSFNet) architecture for multi-class arrhythmia detection. Our proposed approach can effectively capture abnormal patterns of diseases and suppress noise interference by multi-scale feature extraction and cross-scale information complementarity of ECG signals. The proposed method implements feature extraction for signal segments with different sizes by integrating multiple convolution kernels with different receptive fields. Meanwhile, joint optimization strategy with multiple losses of different scales is designed, which not only learns scale-specific features, but also realizes cumulatively multi-scale complementary feature learning during the learning process. In our work, we demonstrate our DMSFNet on two open datasets (CPSC_2018 and PhysioNet/CinC_2017) and deliver the state-of-art performance on them. Among them, CPSC_2018 is a 12-lead ECG dataset and CinC_2017 is a single-lead dataset. For these two datasets, we achieve the F1 score [Formula: see text] and [Formula: see text] which are higher than previous state-of-art approaches respectively. The results demonstrate that our end-to-end DMSFNet has outstanding performance for feature extraction from a broad range of distinct arrhythmias and elegant generalization ability for effectively handling ECG signals with different leads.
Highlights
C ARDIOVASCULAR diseases are the leading cause of death and disability on a global scale
The Acharya et al and MS-Convolutional Neural Networks (CNN) methods are surpassed by our approach in F1 score by 6.7% (0.828–0.761) and 3.1% (0.828–0.797)
Compared with time-incremental convolutional neural network (TI-CNN) (Yao et al.), our method increases by about 5.6% (0.828–0.772) in average F1 score
Summary
C ARDIOVASCULAR diseases are the leading cause of death and disability on a global scale. It is an important cause of death and disability, which seriously affects people’s health. ECG is the most basic, convenient and economical routine examination approach. It is very commonly performed for clinical medical screening of many cardiac diseases, such as judging arrhythmia, diagnosing myocardial ischemia, reflecting the structure of the heart, and provides important reference information for clinicians [1], [2]. Automated analysis of ECG provides auxiliary diagnostic information, and can monitor hearts situation for 24 hours, which is beneficial for mobile medical and remote diagnosis
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