Litcius/Paper detail

Physiological characterization of electrodermal activity enables scalable near real-time autonomic nervous system activation inference

Md. Rafiul Amin, Rose T. Faghih

2022PLoS Computational Biology56 citationsDOIOpen Access PDF

Abstract

Electrodermal activities (EDA) are any electrical phxenomena observed on the skin. Skin conductance (SC), a measure of EDA, shows fluctuations due to autonomic nervous system (ANS) activation induced sweat secretion. Since it can capture psychophysiological information, there is a significant rise in the research work for tracking mental and physiological health with EDA. However, the current state-of-the-art lacks a physiologically motivated approach for real-time inference of ANS activation from EDA. Therefore, firstly, we propose a comprehensive model for the SC dynamics. The proposed model is a 3D state-space representation of the direct secretion of sweat via pore opening and diffusion followed by corresponding evaporation and reabsorption. As the input to the model, we consider a sparse signal representing the ANS activation that causes the sweat glands to produce sweat. Secondly, we derive a scalable fixed-interval smoother-based sparse recovery approach utilizing the proposed comprehensive model to infer the ANS activation enabling edge computation. We incorporate a generalized-cross-validation to tune the sparsity level. Finally, we propose an Expectation-Maximization based deconvolution approach for learning the model parameters during the ANS activation inference. For evaluation, we utilize a dataset with 26 participants, and the results show that our comprehensive state-space model can successfully describe the SC variations with high scalability, showing the feasibility of real-time applications. Results validate that our physiology-motivated state-space model can comprehensively explain the EDA and outperforms all previous approaches. Our findings introduce a whole new perspective and have a broader impact on the standard practices of EDA analysis.

Topics & Concepts

InferenceComputer scienceScalabilityArtificial intelligenceState spaceMachine learningRepresentation (politics)Pattern recognition (psychology)MathematicsPolitical scienceDatabaseStatisticsPoliticsLawNeural dynamics and brain functionEmotion and Mood RecognitionEEG and Brain-Computer Interfaces
Physiological characterization of electrodermal activity enables scalable near real-time autonomic nervous system activation inference | Litcius