A novel approach for denoising electrocardiogram signals to detect cardiovascular diseases using an efficient hybrid scheme

Bing, Pingping; Liu, Wei; Zhai, Zhixing; Li, Jianghao; Guo, Zhiqun; Xiang, Yanrui; He, Binsheng; Zhu, Lemei

doi:10.3389/fcvm.2024.1277123

Front. Cardiovasc. Med.

2024

DOI: 10.3389/fcvm.2024.1277123

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A novel approach for denoising electrocardiogram signals to detect cardiovascular diseases using an efficient hybrid scheme

Pingping Bing,

Wei Liu,

Zhixing Zhai

et al.

Abstract: BackgroundElectrocardiogram (ECG) signals are inevitably contaminated with various kinds of noises during acquisition and transmission. The presence of noises may produce the inappropriate information on cardiac health, thereby preventing specialists from making correct analysis.MethodsIn this paper, an efficient strategy is proposed to denoise ECG signals, which employs a time-frequency framework based on S-transform (ST) and combines bi-dimensional empirical mode decomposition (BEMD) and non-local means (NLM… Show more

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Cited by 5 publications

References 37 publications

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Efficient Bayesian ECG denoising using adaptive covariance estimation and nonlinear Kalman Filtering

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2024

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Efficient Bayesian ECG denoising using adaptive covariance estimation and nonlinear Kalman Filtering

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Sci Rep

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Classification of cervical cancer using Dense CapsNet with Seg-UNet and denoising autoencoders

Yang,

Aydi,

Innab

et al. 2024

Sci Rep

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Cervical cancer is one of the deadly diseases that affects women, which requires periodic examinations to identify and treat any cancerous tumors at a preliminary stage. The most prevalent examination tool for cervical cancer prompt identification is the cervical smear (Pap smear) testing; however, due to human negligence, this examination method has an elevated probability of negative findings. Cervical cancer classification using machine learning (ML) and deep learning (DL) has been extensively studied to enhance the conventional diagnostic process. Robust classification results were achieved through the pre-segmented imagery in most current investigations. Conversely, cellular grouping makes reliable cervical cellular segmentation difficult. Additionally, the deep learning methods used in the existing works perform poorly on a multiclass classification when the data distribution is skewed, which is common in the cervical cancer dataset. To mitigate these restrictions in cervical cancer research, this proposed work uses a combination of four different deep-learning methods in various phases of this research. The proposed work is segregated into five phases: pre-processing, data augmentation, segmentation, feature extraction, and classification. Contrast maximization is performed in the pre-processing phase, and the images are augmented using Multi-modal Generative Adversarial Networks (m-GAN) in the second phase. In the third phase, cervical cancer images are segmented using the Seg-UNet model, which is forwarded to the feature extraction phase that employs denoising autoencoders. Finally, the classification is implemented using the Dense CapsNet model and applied to the SIPaKMeD dataset to categorize between normal, abnormal, and benign classes. The proposed system achieves an accuracy of 99.65%, which is higher than the other works in the literature.

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A novel approach for denoising electrocardiogram signals to detect cardiovascular diseases using an efficient hybrid scheme

Cited by 5 publications

References 37 publications

Efficient Bayesian ECG denoising using adaptive covariance estimation and nonlinear Kalman Filtering

Efficient Bayesian ECG denoising using adaptive covariance estimation and nonlinear Kalman Filtering

Enhancing understanding of stent-induced deformation in MCA aneurysms: a hemodynamic study

Classification of cervical cancer using Dense CapsNet with Seg-UNet and denoising autoencoders

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