Combined wavelet transformation and radial basis neural networks for classifying life-threatening cardiac arrhythmias

Al–Fahoum, Amjed S.; Howitt, I.

doi:10.1007/bf02513350

Cited by 133 publications

(48 citation statements)

References 16 publications

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“…Take computerized ECG arrhythmia interpretation for an example. It has been confirmed that Hermite basis functions (HBFs) and wavelet energy descriptors are among those most competitive ones for feature characterization in discrimination analysis (Senhadii et al, 1995;Rasiah et al, 1997;AI-Farhoum & Howitt 1999;Lagerholm et al, 2000;Saxena et al, 2002;Linh et al, 2003;Engin 2007).…”

Section: Adaptive Physiological Signal Modellingmentioning

confidence: 99%

“…Actually, signal representation in time domain is legible but redundant, which may be evidenced by means of PCA (Geva 1998;Stamkopoulos et al, 1998). As a consequence, morphological analysis was generally combined with domain transformation, such as Hilbert transform (Bolton & Westphal 1981), HD (Rasiah et al, 1997;Lagerholm et al, 2000;Linh et al, 2003) and WT (Senhadii et al, 1995;AI-Farhoum & Howitt 1999;Saxena et al, 2002;Engin 2007), in those published paradigms of computerized physiological signal interpretation. Domain transformation, unlike direct morphological analysis, attempts to characterize physiological signals in an alternative space, where the genuine signal components are more discernible from noises and artefacts.…”

Section: Adaptive Physiological Signal Modellingmentioning

confidence: 99%

“…Thus a variety of successful applications have been reported on physiological signal processing and analysis, covering from adaptive denoising, compression, delineation to feature characterization, pattern recognition, and others. In terms of feature characterization, the investigators paid substantial attention on wavelet energy (Senhadii et al, 1995;AI-Farhoum & Howitt 1999), wavelet entropy (Rosso et al, 2001) and other energy-dense wavelet coefficients (Senhadii et al, 1995). In essence, wavelet transform can be considered as a kind of multirate filter banks.…”

Section: Wavelet Analysismentioning

confidence: 99%

See 2 more Smart Citations

Computerized Interpretation of Cardiovascular Physiological Signals

Li¹,

Vai²,

Ming³

2010

Decision Support Systems Advances In

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Section: Adaptive Physiological Signal Modellingmentioning

confidence: 99%

Section: Adaptive Physiological Signal Modellingmentioning

confidence: 99%

Section: Wavelet Analysismentioning

confidence: 99%

See 1 more Smart Citation

Computerized Interpretation of Cardiovascular Physiological Signals

Li¹,

Vai²,

Ming³

2010

Decision Support Systems Advances In

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“…Both the time and frequency representation can be possible due the scaling property. It has made the wavelet transform suitable for analysis of the non-stationary signals such as speech and ECG signals [17][18][19][20]. This work is confined to ECG signal which remains noisy and non-stationary using the wavelet transform.…”

Section: Feature Extraction Using Wavelet Transformmentioning

confidence: 99%

Machine Learning:An Effective Technique in Bio-Medical Signal Analysis and Classification

Mohanty

Palo

2017

IJMLNCE

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“…Miiiami et al combined the feature extraction by Fourier transform and a back-propagation neural network (BPN) [4], and detected the tachyarrhythmia in real-time. Fahoum et al combined the WT and an R,BF neural network (R,BFN), in order to detect life-threatening cardiac arrhythmias [5]. The purpose of these reports was to detect the abnormal waveform on the ECG.…”

mentioning

confidence: 99%

Evaluation of heart rate variability by using wavelet transform and a recurrent neural network

Fukuda

Nagata

Homma

et al.

2001 Conference Proceedings of the 23rd Annual International Conference of the IEEE Engineering in Medicine and Biology Society

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Abstract-The purpose of this paper is to evaluate the physical and mental stress based on the physiological index, and a new evaluation method of heart rate variability is proposed. This method combines the wavelet transform w^ith a recurrent neural network. The features of the proposed method are as follows: 1. The wavelet transform is utilized for the feature extraction so that the local change of heart rate variability in the time-frequency domain can be extracted. 2. In order to learn and evaluate the different patterns of heart rate variability caused by individual variations, body conditions, circadian rhythms and so on, a new^ recurrent neural netw^ork v^^hich incorporates a hidden Markov Model is used. In the experiments, a mental w^ork-load was given to five subjects, and the subjective rating scores of their mental stress were evaluated using heart rate variability. It w^as confirmed from the experiments that the proposed method could achieve high learning/evaluating performances. Keywords-Heart rate variability, Mental stress. Wavelet transform. Recurrent neural network. Hidden Markov model. I INTRODUCTIONAn electrocardiogram (ECG) is available for a basic physiological index which evaluates the change in patient's body condition and monitors physical and mental stress in his/her daily activities. The heart rate is complicated since it is affected by various factors such as a sinus node for a pacemaker, autononiic nerves, the endocrine system and so on. It is expected that the changes of these factors can be evaluated based on the analysis of Heart Rate Variability (HRV). In this paper, we propose a new evaluation method of HRV.HRV includes many frequency components, and various information can be obtained from them through the frequency domain analysis [1], [2]. In the report of Sayers, which is the pioneer research in this area, three peaks exist on the power spectrum of HRV. The lower frequency component (0.02 -0.06 [Hz]) is influenced by thermoregulation, and the middle frequency component (0.07 -0.14[Hz]) is influenced by blood pressure regulation, and the high frequency component (0.15 -0.5() [Hz]) is influenced by respiration respectively. However, if the power spectrum of HRV is calculated using fast Fourier transform, it expresses rough information in a fixed period of the time series signal, and the dynamic changes of the autononiic nerve activity cannot be expressed. It is difficult to analyze the nonstationary pattern of HRV using this method during the exercise. To overcome this difficulty. The wavelet transform (WT), which extracts local features of HRV in the time-frequency domain, is proposed [3].The changes in the spectrum pattern from physical and mental stress are different among individuals. The subjective feeling of the subjects is also different. These are the problems of the spectrum analysis of HRV. Most previous studies defined specified frequency ranges such as the low frequency component (LF) and the high frequency component (HF) on the power spectrum of HRV, and extracted a...

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Combined wavelet transformation and radial basis neural networks for classifying life-threatening cardiac arrhythmias

Cited by 133 publications

References 16 publications

Computerized Interpretation of Cardiovascular Physiological Signals

Computerized Interpretation of Cardiovascular Physiological Signals

Machine Learning:An Effective Technique in Bio-Medical Signal Analysis and Classification

Evaluation of heart rate variability by using wavelet transform and a recurrent neural network

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