Rapid Dataset-Free Self-Calibration for Heat Flux-Based Core Body Temperature Sensors

• Published in: IEEE access Vol. 13; pp. 61048 - 61055
• Main Authors: Hashimoto, Yuki, Tada, Soto, Nishida, Yoshifumi
• Format: Journal Article
• Language: English
• Published: Piscataway IEEE 01.01.2025; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Air flow; Body temperature; Calibration; Core body temperature; Datasets; Heat; Heat flux; Heat tolerance; Heat transfer; Heating systems; Mathematical models; Numerical models; Numerical simulation; Parameter identification; Probes; reference-free calibration; Self calibration; Sensors; single-heat-flux method; Skin; Temperature distribution; Temperature measurement; Temperature sensors; Thickness measurement; wearable sensors; Wearable technology
• ISSN: 2169-3536; 2169-3536
• DOI: 10.1109/ACCESS.2025.3556405

This study presents a reference-free calibration method for wearable core body temperature sensors based on the single-heat-flux approach, eliminating the need for a pre-constructed dataset and reducing the required calibration time. In conventional single-heat-flux methods, calibration relies on invasive measurements or numerically generated datasets and typically requires at least 1 h, posing practical challenges. In contrast, the proposed method identifies calibration parameters directly from measured temperature data within approximately 1500 s, which is much quicker than the 3600 s required by existing methods. We validated our method through numerical simulations considering factors such as skin thickness and acceptable measurement errors. These simulations confirmed that the proposed approach reliably achieves adequate calibration without prior dataset construction. Furthermore, we conducted a human subject experiment under resting conditions, where ambient and core body temperature fluctuations, along with heat tolerance responses, were minimal. The results demonstrate that our method can achieve clinically sufficient accuracy in estimating core body temperature, even in the presence of environmental perturbations such as introduced airflow. While the proposed method currently assumes stable conditions and may face challenges in highly dynamic environments involving intense physical activity or significant thermal changes, it marks a critical step toward more accessible and practical wearable core body temperature monitoring. Future work will focus on validating the method with a larger cohort of subjects and integrating additional physiological sensors to enhance reliability and broaden applicability.