Statistical feature embedding for heart sound classification

Adiban, Mohammad; BabaAli, Bagher; Shehnepoor, Saeedreza

doi:10.2478/jee-2019-0056

Cited by 11 publications

(7 citation statements)

References 46 publications

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“…Frequency which leads to the maximum spectrum [87], [88] Dominant frequency ratio Ratio of the maximun energy to the total energy [87], [88] Energy Spectral energy [38] Spectral roll-off Frequency below a specific percentage of the total spectral energy [32] Spectral centroid Average of magnitude spectrogram at each frame [32], [89] Specrtal flux Changing speed of the power spectrum [32] Power spectral density (PSD) Distribution of power in spectral components [46], [85], [89] Spectral entropy Shannon entropy of PSD [54], [86] Discrete cosine transform of Mel-scaled spectrogram [38], [75], [79], [86], [87], [93]- [95] Fractional Fourier transform-based Mel-frequency Mel-frequency from the fractional Fourier transform [43] Wavelet Wavelet transform Frequency analysis of a signal at various scales [59], [85], [89] Wavelet scattering transform "Wavelet convolution with nonlinear modulus and averaging scaling function" a (translation invariance and elastic deformation stability [96]) [96], [97] Wavelet synchrosqueezing transform Reassignment of wavelet coefficients [35] Tunable quality wavelet transform "Wavelet multiresolution analysis with a user-specified Q-factor, which is the ratio of the centre frequency to the bandwidth of the filters" b…”

Section: Dominant Frequency Valuementioning

confidence: 99%

“…The Naïve Bayes Classifier [41], [91], [102], [103] was widely used for heart sound classification due to its advantage of being easy-touse. Gaussian Mixture Models (GMMs) [53], [95] were used to estimate the data distribution by optimising the weights of Gaussian mixture components and mean and variance in each component. A Gaussian mixture-based HMM [38] was employed for heart sound classification considering the four sequential heart states, i. e., S1, systole, S2, and diastole.…”

Section: Dominant Frequency Valuementioning

confidence: 99%

“…4 presents a statistic of recent works from 2017 to 2022 that employ classic machine learning models for heart sound classification. SVMs have been very widely used for heart sound classification by learning a supporting hyperplane between classes [6], [33], [40], [41], [43], [46]- [48], [55], [60], [64], [75], [79], [85], [91]- [93], [95]- [97], [99], [100], [103]. Apart from linear projection between data samples and labels, SVMs can learn separating hyperplanes on non-linear data via non-linear kernels, such as radial basis function.…”

Section: Dominant Frequency Valuementioning

confidence: 99%

See 2 more Smart Citations

A Comprehensive Survey on Heart Sound Analysis in the Deep Learning Era

Zhao¹,

Chen²,

Nguyên³

et al. 2023

Preprint

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Heart sound auscultation has been demonstrated to be beneficial in clinical usage for early screening of cardiovascular diseases. Due to the high requirement of well-trained professionals for auscultation, automatic auscultation benefiting from signal processing and machine learning can help auxiliary diagnosis and reduce the burdens of training professional clinicians. Nevertheless, classic machine learning is limited to performance improvement in the era of big data. Deep learning has achieved better performance than classic machine learning in many research fields, as it employs more complex model architectures with stronger capability of extracting effective representations. Deep learning has been successfully applied to heart sound analysis in the past years. As most review works about heart sound analysis were given before 2017, the present survey is the first to work on a comprehensive overview to summarise papers on heart sound analysis with deep learning in the past six years 2017-2022. We introduce both classic machine learning and deep learning for comparison, and further offer insights about the advances and future research directions in deep learning for heart sound analysis.

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Section: Dominant Frequency Valuementioning

confidence: 99%

Section: Dominant Frequency Valuementioning

confidence: 99%

Section: Dominant Frequency Valuementioning

confidence: 99%

See 1 more Smart Citation

A Comprehensive Survey on Heart Sound Analysis in the Deep Learning Era

Zhao¹,

Chen²,

Nguyên³

et al. 2023

Preprint

View full text Add to dashboard Cite

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“…Traditional methods, such as support vector machine [5], i-vector [6] and hidden Markov model [7] are used to detect anomaly PCG signals in a supervised way. Deep learning methods based on Variational Auto-Encoder (VAE) [8], deep arXiv:2101.05443v1 [cs.SD] 14 Jan 2021 convolutional neural network [9,10] and recurrent neural network [11] are also used recently.…”

Section: Literature Reviewmentioning

confidence: 99%

Unsupervised Heart Abnormality Detection Based on Phonocardiogram Analysis with Beta Variational Auto-Encoders

Tian

Wang

2021

ICASSP 2021 - 2021 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)

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Heart Sound (also known as phonocardiogram (PCG)) analysis, is a popular way that detects cardiovascular diseases (CVDs). Most PCG analysis uses supervised way, which demands both normal and abnormal samples. This paper proposes a method of unsupervised PCG analysis that uses beta variational auto-encoder (β − VAE) to model the normal PCG signals. The best performed model reaches an AUC (Area Under Curve) value of 0.91 in ROC (Receiver Operating Characteristic) test for PCG signals collected from the same source. Unlike majority of β − VAEs that are used as generative models, the best-performed β − VAE has a β value smaller than 1. This fact demonstrates that the resampling process helps the improvements on anomaly PCG detection through reconstruction loss worth a heavier weight. Further investigations suggest that anomaly score based on reconstruction loss may be better than anomaly scores based on latent vectors of samples in PCG analysis based on VAE systems.

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“…With labels of normal and anomaly PCG signals, the PCG analysis can be considered as a classification problem. Classical machine learning techniques such as Support Vector Machine (SVM) ( 2 ), i-vector based dictionary learning method ( 3 ) and solutions based on Markov models ( 4 ) are used to solve the proposed problem besides deep learning algorithms ( 5 , 6 ). However, as a supervised problem, PCG data collected needs to cover all types of PCG abnormality, which is labor expensive.…”

Section: Introductionmentioning

confidence: 99%

Unsupervised Phonocardiogram Analysis With Distribution Density Based Variational Auto-Encoders

Tian

2021

Front. Med.

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This paper proposes an unsupervised way for Phonocardiogram (PCG) analysis, which uses a revised auto encoder based on distribution density estimation in the latent space. Auto encoders especially Variational Auto-Encoders (VAEs) and its variant β−VAE are considered as one of the state-of-the-art methodologies for PCG analysis. VAE based models for PCG analysis assume that normal PCG signals can be represented by latent vectors that obey a normal Gaussian Model, which may not be necessary true in PCG analysis. This paper proposes two methods DBVAE and DBAE that are based on estimating the density of latent vectors in latent space to improve the performance of VAE based PCG analysis systems. Examining the system performance with PCG data from the a single domain and multiple domains, the proposed systems outperform the VAE based methods. The representation of normal PCG signals in the latent space is also investigated by calculating the kurtosis and skewness where DBAE introduces normal PCG representation following Gaussian-like models but DBVAE does not introduce normal PCG representation following Gaussian-like models.

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Statistical feature embedding for heart sound classification

Cited by 11 publications

References 46 publications

A Comprehensive Survey on Heart Sound Analysis in the Deep Learning Era

A Comprehensive Survey on Heart Sound Analysis in the Deep Learning Era

Unsupervised Heart Abnormality Detection Based on Phonocardiogram Analysis with Beta Variational Auto-Encoders

Unsupervised Phonocardiogram Analysis With Distribution Density Based Variational Auto-Encoders

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