期刊
IEEE OPEN JOURNAL OF ENGINEERING IN MEDICINE AND BIOLOGY
卷 3, 期 -, 页码 78-85出版社
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/OJEMB.2022.3174806
关键词
Feature extraction; Biomedical monitoring; Morphology; Parameter estimation; Physiology; Task analysis; Monitoring; Dynamic time warping; fiducial point; photoplethysmography; interbeat intervals; wearable sensors
This paper proposes a Boosted-SpringDTW method for feature extraction and accurate estimation of physiological parameters from physiological signals. Experimental results demonstrate that this method achieves high accuracy and stability in identifying fiducial points and estimating IBI.
Goal: To achieve high-quality comprehensive feature extraction from physiological signals that enables precise physiological parameter estimation despite evolving waveform morphologies. Methods: We propose Boosted-SpringDTW, a probabilistic framework that leverages dynamic time warping (DTW) and minimal domain-specific heuristics to simultaneously segment physiological signals and identify fiducial points that represent cardiac events. An automated dynamic template adapts to evolving waveform morphologies. We validate Boosted-SpringDTW performance with a benchmark PPG dataset whose morphologies include subject- and respiratory-induced variation. Results: Boosted-SpringDTW achieves precision, recall, and F1-scores over 0.96 for identifying fiducial points and mean absolute error values less than 11.41 milliseconds when estimating IBI. Conclusion: Boosted-SpringDTW improves F1-Scores compared to two baseline feature extraction algorithms by 35% on average for fiducial point identification and mean percent difference by 16% on average for IBI estimation. Significance: Precise hemodynamic parameter estimation with wearable devices enables continuous health monitoring throughout a patients' daily life.
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