Finite Class Bayesian Inference System for Circle and Linear Walking Gait Event Recognition Using Inertial Measurement Units

Accurate and fast human motion pattern recognition is the key to ensuring lower limb assistive devices' appropriate assistance. The research on human motion pattern recognition of lower limb assistive devices mainly focuses on sagittal gait. The motion pattern such as circular walking (CW) is a...

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Bibliographic Details
Published in:IEEE transactions on neural systems and rehabilitation engineering 2020-12, Vol.28 (12), p.2869-2879
Main Authors: Sheng, Wentao, Zha, Fusheng, Guo, Wei, Qiu, Shiyin, Sun, Lining, Jia, Wangqiang
Format: Article
Language:English
Subjects:
Algorithms
Assistive devices
Bayes methods
Bayesian analysis
Bayesian inference system
Decision making
Finite class
Foot
Gait
gait event
gait recognition
Heels
Human motion
Inertial platforms
Legged locomotion
Pattern recognition
Statistical inference
Walking
walking activity
Wearable sensors
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Summary:Accurate and fast human motion pattern recognition is the key to ensuring lower limb assistive devices' appropriate assistance. The research on human motion pattern recognition of lower limb assistive devices mainly focuses on sagittal gait. The motion pattern such as circular walking (CW) is asymmetric about the sagittal plane of the body. CW is common in daily living. However, the recognition algorithm of CW is rarely reported. Since lower limb assistive devices interact with humans, lacking the capability of recognizing CW is dangerous. Thus, to realize the accurate and fast recognition of CW, this article proposed a finite class Bayesian interference system (FC-BesIS). FC-BesIS is designed to recognize walking activities (linear walking and CW) and gait events (heel contact, load response, mid stance, terminal stance, pre-swing, initial swing, mid swing, and terminal swing). A finite class method which reduces the number of potential classes according to elimination rules before decision-making is introduced. Elimination rules are designed based on likelihood estimation and sensor information. The experiments show that walking activities and gait events can be accurately and fastly recognized by FC-BesIS. The experiments also show that the performance of FC-BesIS in mean recognition accuracy (MRA) and mean decision time (MDT) is improved compared with BesIS. The MRA of walking activities and gait events are 100% and 97.38%, respectively. The MDT of walking activities and gait events are 28.19 ms and 33.94 ms, respectively. Overall, FC-BesIS has been proved to be an accurate and fast recognition algorithm for human motion patterns using wearable sensors.
ISSN:1534-4320
1558-0210
DOI:10.1109/TNSRE.2020.3032703