Identificador persistente para citar o vincular este elemento: http://hdl.handle.net/10553/113703
Título: A Motion and Illumination Resistant Non-contact Method using Undercomplete Independent Component Analysis and Levenberg-Marquardt Algorithm
Autores/as: Gupta, Ankit
Ravelo-García, Antonio G. 
Morgado-Dias, Fernando
Clasificación UNESCO: 3314 Tecnología médica
Palabras clave: Blind Source Separation
Blood Volume Pulse Extraction
Color
Dimensionality Reduction
Estimation, et al.
Fecha de publicación: 2022
Proyectos: LARSyS Robotics and Systems in Engineering and Science (Grant Number: M1420-01-0145-FEDER-000002)
Publicación seriada: IEEE Journal of Biomedical and Health Informatics 
Resumen: IEEEHeart Rate (HR) estimation is of utmost importance due to its applicability in diverse fields. Conventional methods for HR estimation require skin contact and are not suitable in certain scenarios such as sensitive skin or prolonged unobtrusive HR monitoring. Therefore remote photoplethysmography (rPPG) methods have become an active area of research. These methods utilize the facial videos acquired using a camera followed by extracting the Blood Volume Pulse (BVP) signal for heart rate calculation. The existing rPPG methods either utilized a single color channel or weighted color differences, which has certain limitations dealing with motion and illumination artifacts. This study considered BVP extraction as an undercomplete problem and proposed a method resistant to motion and illumination variation artifacts. This method is based on an undercomplete independent component analysis, aiming to estimate the unmixing matrix using a non-linear Cumulative Density Function (CDF) that has been optimized using the customized Levenberg-Marquardt algorithm. Therefore, the method is named U-LMA. The proposed method was tested under three scenarios: constrained, motion, and illumination variations scenarios. High Pearson correlation coefficient values and smaller lower-upper statistical limits of Bland-Altman plots justified the outstanding performance of the proposed U-LMA. Furthermore, its comparative analysis with the state-of-the-art methods demonstrated its efficacy and reliability, which was proven by the lowest error and highest correlation values (0.01 significance level). Additionally, higher accuracy satisfying the clinically accepted error differences also justified its clinical relevance.
URI: http://hdl.handle.net/10553/113703
ISSN: 2168-2194
DOI: 10.1109/JBHI.2022.3144677
Fuente: IEEE Journal of Biomedical and Health Informatics[ISSN 2168-2194], (Enero 2022)
Colección:Artículo preliminar
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