TY - GEN
T1 - Wearable insole pressure sensors for automated detection and classification of slip-trip-loss of balance events in construction workers
AU - Antwi-Afari, Maxwell Fordjour
AU - Li, Heng
AU - Seo, Joon Oh
AU - Lee, Sang Hyun
AU - Edwards, David John
AU - Lok Wong, Arnold Yu
PY - 2018/3/29
Y1 - 2018/3/29
N2 - A fall on the same level is a leading causes of non-fatal injuries among construction workers. Previous research reveals that such incidents are associated with slip, trip and loss of balance (STL) events often caused by unsafe site conditions (e.g., slippery floors, obstacles on the path and uneven surfaces). Consequently, detecting STL events enable site management to identify these hazards and employ suitable risk mitigation "control" measures. This research examined foot plantar pressure distribution for automated detection and classification of STL events using wearable insole pressure sensors. Three volunteers participated in a laboratory controlled simulated experiment that examined different types of STL events, while the corresponding foot plantar pressure data were collected from wearable insole pressure sensors. Diverse features (e.g., time- And frequency-domains, and spatial-temporal features) were extracted from the foot plantar pressure distribution data, which was used to associate different pressure patterns with each type of STL event. Four machine learning classifiers [i.e., artificial neural network (ANN), decision tree (DT), K-nearest neighbor (KNN), and support vector machine (SVM)] were evaluated to select the best classifier. Cross validation results revealed that at approximately 85% of classification accuracy, the KNN classifier achieved the most accurate result using 0.64s window size, indicating a great potential to use the proposed approach to automate fall risk detection. Overall, this method would allow construction managers to understand how workers react to unsafe conditions associated with STL events, so as to minimize the fundamental causes of STL events and thus to reduce non-fatal fall injuries in construction.
AB - A fall on the same level is a leading causes of non-fatal injuries among construction workers. Previous research reveals that such incidents are associated with slip, trip and loss of balance (STL) events often caused by unsafe site conditions (e.g., slippery floors, obstacles on the path and uneven surfaces). Consequently, detecting STL events enable site management to identify these hazards and employ suitable risk mitigation "control" measures. This research examined foot plantar pressure distribution for automated detection and classification of STL events using wearable insole pressure sensors. Three volunteers participated in a laboratory controlled simulated experiment that examined different types of STL events, while the corresponding foot plantar pressure data were collected from wearable insole pressure sensors. Diverse features (e.g., time- And frequency-domains, and spatial-temporal features) were extracted from the foot plantar pressure distribution data, which was used to associate different pressure patterns with each type of STL event. Four machine learning classifiers [i.e., artificial neural network (ANN), decision tree (DT), K-nearest neighbor (KNN), and support vector machine (SVM)] were evaluated to select the best classifier. Cross validation results revealed that at approximately 85% of classification accuracy, the KNN classifier achieved the most accurate result using 0.64s window size, indicating a great potential to use the proposed approach to automate fall risk detection. Overall, this method would allow construction managers to understand how workers react to unsafe conditions associated with STL events, so as to minimize the fundamental causes of STL events and thus to reduce non-fatal fall injuries in construction.
UR - http://www.scopus.com/inward/record.url?scp=85049174899&partnerID=8YFLogxK
UR - https://ascelibrary.org/doi/10.1061/9780784481288.008
U2 - 10.1061/9780784481288.008
DO - 10.1061/9780784481288.008
M3 - Conference publication
AN - SCOPUS:85049174899
T3 - Construction Research Congress 2018: Safety and Disaster Management - Selected Papers from the Construction Research Congress 2018
SP - 73
EP - 83
BT - Construction Research Congress 2018
A2 - Harper, Christofer
A2 - Lee, Yongcheol
A2 - Harris, Rebecca
A2 - Berryman, Charles
A2 - Wang, Chao
PB - American Society of Civil Engineers (ASCE)
T2 - Construction Research Congress 2018: Safety and Disaster Management, CRC 2018
Y2 - 2 April 2018 through 4 April 2018
ER -