MULTI-head self-attention-based recurrent neural network with dwarf mongoose optimization algorithm-espoused QRS detector design

QRS detection is the essential electrocardiogram (ECG) analysis procedure. A reliable QRS recognition system that achieves high accuracy despite a typical QRS morphologies and significant noise is required for ECG data gathered by wearable devices. Most contemporary systems seek fast execution durat...

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Veröffentlicht in:	Signal, image and video processing image and video processing, 2024-07, Vol.18 (5), p.4935-4944
Hauptverfasser:	Malathi, S. R., Kumar, P. Vijay
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Sprache:	eng
Schlagworte:	Accuracy Algorithms Computer Imaging Computer Science Design optimization Disintegration Electrocardiography Energy consumption Error detection Image Processing and Computer Vision Morphology Multimedia Information Systems Neural networks Optimization algorithms Original Paper Pattern Recognition and Graphics Recurrent neural networks Sensitivity analysis Signal,Image and Speech Processing Vision Wearable technology
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description	QRS detection is the essential electrocardiogram (ECG) analysis procedure. A reliable QRS recognition system that achieves high accuracy despite a typical QRS morphologies and significant noise is required for ECG data gathered by wearable devices. Most contemporary systems seek fast execution durations and minimal energy consumption while attaining high prediction rates. To minimize these issues, this research article presents an approach of multi-head self-attention-based recurrent neural network with dwarf mongoose optimization algorithm-espoused QRS detector design (MHSARNN-QRS) is proposed. Initially, ECG data are taken from MIT/BIH arrhythmia dataset (MIT-AD). Every disintegrated signal is transmitted to multi-head self-attention-based recurrent neural network (MHSARNN) to examine morphologies and predict QRS like correct and incorrect. Then, the QRS wave is located through dwarf mongoose optimization algorithm by reducing probability of neglected identification improves the detection performance. The performance of proposed MHSARNN-QRS method is evaluated using accuracy, sensitivity, specificity, detection error rate, computation time, f1-score, positive prediction, and time for processing a single record (s) and single beat (ms) are analyzed. Performance of the MHSARNN-QRS approach attains high sensitivity, lower single record, lower single beat, and greater accuracy compared with existing methods.
doi_str_mv	10.1007/s11760-024-03145-w
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A reliable QRS recognition system that achieves high accuracy despite a typical QRS morphologies and significant noise is required for ECG data gathered by wearable devices. Most contemporary systems seek fast execution durations and minimal energy consumption while attaining high prediction rates. To minimize these issues, this research article presents an approach of multi-head self-attention-based recurrent neural network with dwarf mongoose optimization algorithm-espoused QRS detector design (MHSARNN-QRS) is proposed. Initially, ECG data are taken from MIT/BIH arrhythmia dataset (MIT-AD). Every disintegrated signal is transmitted to multi-head self-attention-based recurrent neural network (MHSARNN) to examine morphologies and predict QRS like correct and incorrect. Then, the QRS wave is located through dwarf mongoose optimization algorithm by reducing probability of neglected identification improves the detection performance. 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subjects	Accuracy Algorithms Computer Imaging Computer Science Design optimization Disintegration Electrocardiography Energy consumption Error detection Image Processing and Computer Vision Morphology Multimedia Information Systems Neural networks Optimization algorithms Original Paper Pattern Recognition and Graphics Recurrent neural networks Sensitivity analysis Signal,Image and Speech Processing Vision Wearable technology
title	MULTI-head self-attention-based recurrent neural network with dwarf mongoose optimization algorithm-espoused QRS detector design
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