| Autor: |
Cheng CH; Department of Electrical and Electronic Engineering, Imperial College London, London SW7 2AZ, UK., Yuen Z; Department of Computer Science, University of Ottawa, Ottawa, ON K1H 8M5, Canada., Chen S; PanopticAI, Hong Kong Science and Technology Parks, New Territories, Hong Kong, China., Wong KL; PanopticAI, Hong Kong Science and Technology Parks, New Territories, Hong Kong, China., Chin JW; PanopticAI, Hong Kong Science and Technology Parks, New Territories, Hong Kong, China., Chan TT; PanopticAI, Hong Kong Science and Technology Parks, New Territories, Hong Kong, China., So RHY; PanopticAI, Hong Kong Science and Technology Parks, New Territories, Hong Kong, China.; Department of Industrial Engineering and Decision Analytics, The Hong Kong University of Science and Technology, Clear Water Bay, Kowloon, Hong Kong, China. |
| Abstrakt: |
Blood oxygen saturation (SpO 2 ) is an essential physiological parameter for evaluating a person's health. While conventional SpO 2 measurement devices like pulse oximeters require skin contact, advanced computer vision technology can enable remote SpO 2 monitoring through a regular camera without skin contact. In this paper, we propose novel deep learning models to measure SpO 2 remotely from facial videos and evaluate them using a public benchmark database, VIPL-HR. We utilize a spatial-temporal representation to encode SpO 2 information recorded by conventional RGB cameras and directly pass it into selected convolutional neural networks to predict SpO 2 . The best deep learning model achieves 1.274% in mean absolute error and 1.71% in root mean squared error, which exceed the international standard of 4% for an approved pulse oximeter. Our results significantly outperform the conventional analytical Ratio of Ratios model for contactless SpO 2 measurement. Results of sensitivity analyses of the influence of spatial-temporal representation color spaces, subject scenarios, acquisition devices, and SpO 2 ranges on the model performance are reported with explainability analyses to provide more insights for this emerging research field. |
