TY - GEN
T1 - Enhancing Human-Centric Physiological Data-Driven Heat Stress Assessment in Construction through a Transfer Learning-Based Approach
AU - Ojha, Amit
AU - Sharifironizi, Ali
AU - Liu, Yizhi
AU - Jebelli, Houtan
N1 - Publisher Copyright:
© 2024 ASCE.
PY - 2024
Y1 - 2024
N2 - Recent advances in physiological sensors and machine learning have led to the development of non-invasive heat stress monitoring frameworks that can continuously and objectively assess the heat stress levels of workers in the field by analyzing their physiological data. However, variations in the statistical distribution of physiological data due to individual differences in responses to stressors negatively impact the accuracy of the assessment. To address this issue, this study proposed a transfer learning-based framework to improve the performance of non-invasive heat stress monitoring. The framework utilizes autoencoder and domain adaptation-based transfer learning techniques to reduce the deviation of the statistical distributions of physiological data across different individuals, leading to a more robust assessment of workers' heat stress levels. To evaluate the effectiveness of the framework, physiological data was collected from 14 subjects performing roofing tasks with different heat stress exposure levels (low, medium, and high). Results showed that the proposed framework had a more robust performance on physiological data with distributional shifts, achieving an accuracy of over 89.9% in assessing heat stress levels across different subjects, a 6.3% improvement compared to existing frameworks. This study contributes to the advancement of heat stress assessment for construction workers.
AB - Recent advances in physiological sensors and machine learning have led to the development of non-invasive heat stress monitoring frameworks that can continuously and objectively assess the heat stress levels of workers in the field by analyzing their physiological data. However, variations in the statistical distribution of physiological data due to individual differences in responses to stressors negatively impact the accuracy of the assessment. To address this issue, this study proposed a transfer learning-based framework to improve the performance of non-invasive heat stress monitoring. The framework utilizes autoencoder and domain adaptation-based transfer learning techniques to reduce the deviation of the statistical distributions of physiological data across different individuals, leading to a more robust assessment of workers' heat stress levels. To evaluate the effectiveness of the framework, physiological data was collected from 14 subjects performing roofing tasks with different heat stress exposure levels (low, medium, and high). Results showed that the proposed framework had a more robust performance on physiological data with distributional shifts, achieving an accuracy of over 89.9% in assessing heat stress levels across different subjects, a 6.3% improvement compared to existing frameworks. This study contributes to the advancement of heat stress assessment for construction workers.
UR - https://www.scopus.com/pages/publications/85188707796
UR - https://www.scopus.com/pages/publications/85188707796#tab=citedBy
U2 - 10.1061/9780784485262.017
DO - 10.1061/9780784485262.017
M3 - Conference contribution
AN - SCOPUS:85188707796
T3 - Construction Research Congress 2024, CRC 2024
SP - 157
EP - 167
BT - Advanced Technologies, Automation, and Computer Applications in Construction
A2 - Shane, Jennifer S.
A2 - Madson, Katherine M.
A2 - Mo, Yunjeong
A2 - Poleacovschi, Cristina
A2 - Sturgill, Roy E.
PB - American Society of Civil Engineers
T2 - Construction Research Congress 2024, CRC 2024
Y2 - 20 March 2024 through 23 March 2024
ER -