Computer Science

Computer Science ›› 2026, Vol. 53 ›› Issue (2): 342-348.doi: 10.11896/jsjkx.241200083

• Artificial Intelligence • Previous Articles     Next Articles

Human Motion Recognition Algorithm Based on Wearable Sensors

JIANG Lei1, WANG Zi1, YANG Rong2,3, HAN Wanglin1   

  1. 1 College of Artificial Intelligence,China University of Mining and Technology,Beijing 100083,China
    2 National Research Center for Rehabilitation Technical Aid,Beijing 100176,China
    3 Beijing Key Laboratory of Rehabilitation Technical Aids for Old-Age Disability,Beijing 100176,China
  • Received:2024-12-20 Revised:2025-01-18 Published:2026-02-10
  • About author:JIANG Lei,born in 1982,associate professor,master’s supervisor.His main research interests include artificial intelligence,adaptive control and exo-skeleton robotics.
    YANG Rong,born in 1987,senior engineer.Her main research interests include automatic control,brain-computer interface,pattern recognition and signal processing.
  • Supported by:
    2023 Development Program for Key Laboratories and Engineering Technology Research Centers of the Ministry of Civil Affairs.

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Abstract: Against the backdrop of global aging,knee exoskeletons are widely used in the maintenance of knee joint health and rehabilitation training for the elderly.Knee exoskeletons often employ embedded devices for the recognition of lower limb motion states,which requires finding a balance between the selection and layout of sensors,and the accuracy and computational complexity of algorithms.Therefore,this paper studies a human motion recognition algorithm suitable for knee exoskeletons,which uses two inertial measurement units(IMUs) on the thigh and lower leg to collect lower limb motion data.The recognition method includes three steps:feature combination,feature selection,and motion state recognition.It optimizes feature representation through cross-method feature combination.The improved One-vs.-Rest(OvR) strategy is applied to address motion recognition issues,within which a fusion algorithm combining Relief with Pearson correlation coefficients and a machine learning backward selection method is used for feature selection to reduce computational complexity,and historical information along with other state data are integrated into the model training to further enhance accuracy.The model classifies six types of daily motion states with an accuracy rate of up to 97.76%.Experimental results verify that the proposed algorithm can accurately and quickly recognize lower limb motion states under the limitation of a limited number of sensors,providing an accurate and low computational requirement solution for precise detection and real-time control of knee exoskeletons.

Key words: Motion recognition, IMU sensors, Feature combination, Machine learning, OvR cascade framework

CLC Number: 

  • TP242
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