Respiratory Rate Estimation Combining Autocorrelation Function-Based Power Spectral Feature Extraction with Gradient Boosting Algorithm

Various machine learning models have been used in the biomedical engineering field, but only a small number of studies have been conducted on respiratory rate estimation. Unlike ensemble models using simple averages of basic learners such as bagging, random forest, and boosting, the gradient boostin...

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Bibliographic Details
Published in:Applied sciences Vol. 12; no. 16; p. 8355
Main Authors: Lee, Soojeong, Moon, Hyeonjoon, Son, Chang-Hwan, Lee, Gangseong
Format: Journal Article
Language:English
Published: Basel MDPI AG 01.08.2022
Subjects:
Algorithms
autocorrelation function-based power spectral feature extraction
Datasets
Electrocardiography
ensemble learning
gradient boosting technique
Heart failure
Intensive care
Machine learning
Methods
Patients
photolethysmogram
Pneumonia
Pulse oximetry
respiration rate prediction
Sensors
Wavelet transforms
ISSN:2076-3417, 2076-3417
Online Access:Get full text
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Summary:Various machine learning models have been used in the biomedical engineering field, but only a small number of studies have been conducted on respiratory rate estimation. Unlike ensemble models using simple averages of basic learners such as bagging, random forest, and boosting, the gradient boosting algorithm is based on effective iteration strategies. This gradient boosting algorithm is just beginning to be used for respiratory rate estimation. Based on this, we propose a novel methodology combining an autocorrelation function-based power spectral feature extraction process with the gradient boosting algorithm to estimate respiratory rate since we acquire the respiration frequency using the autocorrelation function-based power spectral feature extraction that finds the time domain’s periodicity. The proposed methodology solves overfitting for the training datasets because we obtain the data dimension by applying autocorrelation function-based power spectral feature extraction and then split the long-resampled wave signal to increase the number of input data samples. The proposed model provides accurate respiratory rate estimates and offers a solution for reliably managing the estimation uncertainty. In addition, the proposed method presents a more precise estimate than conventional respiratory rate measurement techniques.
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ISSN:2076-3417
2076-3417
DOI:10.3390/app12168355