吉林大学学报(工学版) ›› 2015, Vol. 45 ›› Issue (6): 1857-1862.doi: 10.13229/j.cnki.jdxbgxb201506019

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Lower limb joint angles of German shepherd dog during foot-ground contact in different gait patterns

QIAN Zhi-hui1, MIAO Huai-bin1, REN Lei1,2, REN Lu-quan1   

  1. 1.Key Laboratory of Bionic Engineering, Ministry of Education, Jilin University, Changchun, 130022, China;
    2.School of Mechanical, Aerospace and Civil Engineering, University of Manchester, Manchester M13 9PL,UK
  • Received:2014-07-04 Online:2015-11-01 Published:2015-11-01

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Abstract: The forelimb of German Shepherd Dog (GSD), a land quadruped animal, was selected as the subject, and the kinematical characteristics of each joint in for-lower limb under various gaits in the foot-ground impact phase were analyzed using optical three-dimensional motion capture technology. The focus is to reveal how does each fore-lower limb joint adjust and adapt to the ground impact. The analyses of joint movement sequence and joint angle variations show that GSD employs the coordination of multi-joint flexion motion of the fore-lower limb to buffer ground reaction force. Compared with metacarpal-phalangeal joint, the humeral joint, cubital joint and carpal joint of GSD play more important roles in ground impact absorption; while, the flexion motion of these three joints function in different contact phases. The flexion of carpal joint happens first, then the humeral joint, and finally the cubital joint. This may show that the coordination of multi-joint flexion of GSD has spatio-temporal characteristics. This study also finds that the initial contact angle between ground and GSD finger increases with the ground impact force. This adaptive adjustment may help GSD to prolong the cushion time during foot-ground impact phase, thus, decreasing the strength of ground reaction force.

Key words: engineering bionics, biomechanics, canine animal, joint angle, flexion motion, buffering

CLC Number: 

  • TB17
[1] 黄俊军,葛世荣,曹为. 多足步行机器人研究现状及展望[J]. 机床与液压,2008,36(5): 187-191.
Huang Jun-jun, Ge Shi-rong, Cao Wei. Multi-feet walk robot research and its forecast[J]. Machine Tool and Hydraulics,2008,36(5): 187-191.
[2] Miller D P. Multiple behaviour-controlled micro-robots for planetary surface-missions[C]∥Proceedings of the IEEE International Conference on Systems, Man and Cybemetics,USA,1990: 289-292.
[3] Delcomyn F, Nehon M E.Awhitectures for a biomimetie hexapod robot[J]. Robotics and Autonomom Systems,2000,30(1):5-15.
[4] Hirose S, Kato K. Study on quadruped walking robot in Tokyo institute of technology-future[C]∥IEEE International Conference on Robotics and Automation,San Francisco,2000:414-419.
[5] 马建旭,马培荪,杨保忠,等. 四足步行机器人中一种新型腿结构缓冲特性[J]. 上海交通大学学报,1999,33(7): 847-850.
Ma Jian-xu, Ma Pei-sun, Yang Bao-zhong,et al. Buffering of new walking mechanism in quadruped walking robot[J]. Journal of Shanghai Jiaotong University,1999,33(7):847-850.
[6] Zhang Z G, Fukuoka Y, Kimura H. Stable quadrupedal running based on a spring-loaded two-segment legged model[C]∥IEEE International Conference on Robotics & Automation, New Orieans,2004:2601-2606.
[7] Papadopoulos D, Buehler M. Stable running in a quadruped robot with compliant legs[C]∥IEEE International Conference on Robotics And Automation, San Francisco, 2000:444-449.
[8] Mennitto G, Bueheler M. CARL: a complaint articulated robot leg for dynamic locomotion[J]. Robotics and Autonomous Systems,1996,18(3):337-344.
[9] Marhefka D W, Orin D E. Intelligent control of quadruped gallops[J]. IEEE/ASME Transaction on Mechatronics,2003,8(4):446-456.
[10] Marghitu D B, Nalluri P. Nonlinear dynamic stability of normal and arthritic greyhounds[J]. Nonlinear Dynamics,1997,12(3):237-250.
[11] Abourachid A. A new way of analyzing symmetrical and asymmetrical gaits in quadrupeds[J]. C R Biologies,2003,326(7): 625-630.
[12] Chi K J. Functional implications of the mechanical inhomogeneity in mammalian paw pads[J]. Integrative and Comparative Biology,2003,43(6):827.
[13] 田为军,丛茜,金敬福. 德国牧羊犬的关节角及其地反力[J]. 吉林大学学报:工学版,2009,39(增刊1):227-231.
Tian Wei-jun, Cong Qian, Jin Jing-fu. Joint angles and ground reaction force of German shepherd dog[J]. Journal of Jilin University(Engineering and Technology Edition), 2009,39(Sup.1):227-231.
[14] 钱志辉,苗怀彬,商震,等. 基于多种步态的德国牧羊犬足-地接触分析[J]. 吉林大学学报:工学版,2014,44(6):1692-1697.
Qian Zhi-hui, Miao Huai-bin, Shang Zhen, et al. The foot-ground contact analysis of German shepherd dog based on normal walking, trotting and jumping gait[J]. Journal of Jilin University(Engineering and Technology Edition),2014,44(6):1692-1697.
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