An Experimental Analysis of Overcoming Obstacle in Human Walking

In this paper, an experimental analysis of overcoming obstacle in human walking is carried out by means of a motion capture system. In the experiment, the lower body of an adult human is divided into seven segments, and three markers are pasted to each segment with the aim to obtain moving trajector...

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Bibliographic Details
Published inJournal of bionics engineering Vol. 11; no. 4; pp. 497 - 505
Main Authors Li, Tao, Ceccarelli, Marco, Luo, Minzhou, Laribi, Med Amine, Zeghloul, Said
Format Journal Article
LanguageEnglish
Published Singapore Elsevier Ltd 01.10.2014
Springer Singapore
Subjects
Artificial Intelligence
Biochemical Engineering
Bioinformatics
Biomaterials
Biomedical Engineering and Bioengineering
Biomedical Engineering/Biotechnology
biped robot
Engineering
human locomotion
motion capture
overcoming obstacle
walking gait
人形机器人
人类
力传感器
动作捕捉
反作用力
实验分析
移动轨迹
重力势能
human locomotion
walking gait
motion capture
biped robot
overcoming obstacle
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Summary:In this paper, an experimental analysis of overcoming obstacle in human walking is carried out by means of a motion capture system. In the experiment, the lower body of an adult human is divided into seven segments, and three markers are pasted to each segment with the aim to obtain moving trajectory and to calculate joint variation during walking. Moreover, kinematic data in terms of displacement, velocity and acceleration are acquired as well. In addition, ground reaction forces are measured using force sensors. Based on the experimental results, features of overcoming obstacle in human walking are analyzed. Experimental results show that the reason which leads to smooth walking can be identified as that the human has slight movement in the vertical direction during walking; the reason that human locomotion uses gravity effectively can be identified as that feet rotate around the toe joints during toe-off phase aiming at using gravitational potential energy to provide propulsion for swing phase. Furthermore, both normal walking gait and obstacle overcoming gait are characterized in a form that can provide necessary knowledge and useful databases for the implementation of motion planning and gait planning towards overcoming obstacle for humanoid robots.
Bibliography:22-1355/TB
In this paper, an experimental analysis of overcoming obstacle in human walking is carried out by means of a motion capture system. In the experiment, the lower body of an adult human is divided into seven segments, and three markers are pasted to each segment with the aim to obtain moving trajectory and to calculate joint variation during walking. Moreover, kinematic data in terms of displacement, velocity and acceleration are acquired as well. In addition, ground reaction forces are measured using force sensors. Based on the experimental results, features of overcoming obstacle in human walking are ana- lyzed. Experimental results show that the reason which leads to smooth walking can be identified as that the human has slight movement in the vertical direction during walking; the reason that human locomotion uses gravity effectively can be identified as that feet rotate around the toe joints during toe-off phase aiming at using gravitational potential energy to provide propulsion for swing phase. Furthermore, both normal walking gait and obstacle overcoming gait are characterized in a form that can provide necessary knowledge and useful databases for the implementation of motion planning and gait planning towards overcoming obstacle for humanoid robots.
Tao Li, Marco Ceccarelli, Minzhou Luo, Med Amine Laribi, Said Zeghloul( Institute of Advanced Manufacturing Technology, Hefei Institutes of Physical Science, Chinese Academy of Sciences, Changzhou 213164, P. R. China 2. Laboratory of Robotics and Mechatronics, University of Cassino and South Latium, Cassino 03043, Italy Institute PPRIME- DGMSC, CNRS-University of Poitiers- ENSMA, 15 Rue de l'HOtel Dieu, 86000, Poitiers, France)
human locomotion; overcoming obstacle; walking gait; biped robot; motion capture
ISSN:1672-6529
2543-2141
DOI:10.1016/S1672-6529(14)60062-7