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用于向后四足行走的自适应控制。IV. 站立和摆动期间的后肢动力学。

Adaptive control for backward quadrupedal walking. IV. Hindlimb kinetics during stance and swing.

作者信息

Perell K L, Gregor R J, Buford J A, Smith J L

机构信息

Department of Physiological Science, University of California, Los Angeles 90024-1568.

出版信息

J Neurophysiol. 1993 Dec;70(6):2226-40. doi: 10.1152/jn.1993.70.6.2226.

DOI:10.1152/jn.1993.70.6.2226
PMID:8120579
Abstract
  1. Hindlimb step-cycle kinetics of forward (FWD) and backward (BWD) walking in adult cats were assessed. The hindlimb was modeled as a linked system of rigid bodies and inverse-dynamics techniques were used to calculate hip, knee, and ankle joint kinetics. For swing, net torque at each joint was divided into three components: gravitational, motion dependent, and a generalized muscle torque. For stance, vertical and horizontal components of the ground-reaction force applied at a point on the paw (center of pressure) were added to the torque calculations. Muscle torque profiles were matched to electromyograms (EMGs) recorded from hindlimb muscles. 2. Torque profiles for BWD swing were the approximate time reversal of those for FWD swing. At each joint, the net torque during swing was small because the mean motion-dependent and muscle torque components counteracted each other. At the hip a flexor muscle torque persisted except for a brief extensor muscle torque late in FWD swing and at the onset of BWD swing. At the knee the muscle torque was relatively negligible except for a peak flexor muscle torque late in FWD swing and early in BWD swing. At the ankle there was a midswing transition from a flexor to an extensor muscle torque during FWD swing and the reverse was true for BWD swing. 3. The vertical ground-reaction force was greater for the forelimbs than the hindlimbs during FWD stance; the reverse was true for BWD stance. Thus the hindlimbs bore a greater percentage (66%) of body weight than the forelimbs during BWD stance, and the forelimbs bore a greater percentage (59%) during FWD stance. For most of FWD stance, the hindlimb exerted a small propulsive ground-reaction force, but for BWD stance the hindlimb first exerted a braking force and then a propulsive force, with the transition occurring after midstance (59% of stance). 4. At the hip the ground-reaction force vector was oriented anteriorly and then posteriorly to the estimated joint center with a midstance transition during FWD stance. The muscle torque and joint power patterns showed similar transitions, changing from extensor and power generation to flexor and power absorption, respectively. For most of BWD stance the ground-reaction force vector was oriented anteriorly to the joint center and was counter-balanced by a large extensor muscle torque; nonetheless, power was absorbed because the hip flexed.(ABSTRACT TRUNCATED AT 400 WORDS)
摘要
  1. 评估了成年猫向前(FWD)和向后(BWD)行走时后肢的步周期动力学。后肢被建模为刚体的链接系统,并使用逆动力学技术来计算髋、膝和踝关节的动力学。对于摆动期,每个关节的净扭矩分为三个分量:重力、运动相关和广义肌肉扭矩。对于支撑期,施加在爪子上一点(压力中心)的地面反作用力的垂直和水平分量被添加到扭矩计算中。肌肉扭矩曲线与从后肢肌肉记录的肌电图(EMG)相匹配。2. BWD摆动期的扭矩曲线大致是FWD摆动期扭矩曲线的时间反转。在每个关节处,摆动期的净扭矩较小,因为平均运动相关扭矩分量和肌肉扭矩分量相互抵消。在髋关节处,除了FWD摆动后期和BWD摆动开始时短暂的伸肌扭矩外,屈肌扭矩持续存在。在膝关节处,除了FWD摆动后期和BWD摆动早期的屈肌扭矩峰值外,肌肉扭矩相对可忽略不计。在踝关节处,FWD摆动期在摆动中期从屈肌扭矩过渡到伸肌扭矩,BWD摆动期则相反。3. 在FWD支撑期,前肢的垂直地面反作用力大于后肢;BWD支撑期则相反。因此,在BWD支撑期,后肢承担的体重百分比(66%)大于前肢,而在FWD支撑期,前肢承担的百分比(59%)更大。在FWD支撑期的大部分时间里,后肢施加的推进地面反作用力较小,但在BWD支撑期,后肢首先施加制动力,然后是推进力,转变发生在支撑中期之后(支撑期的59%)。4. 在髋关节处,地面反作用力矢量在FWD支撑期先向前然后向后指向估计的关节中心,并在支撑中期发生转变。肌肉扭矩和关节功率模式显示出类似的转变,分别从伸肌和产生功率转变为屈肌和吸收功率。在BWD支撑期的大部分时间里,地面反作用力矢量向前指向关节中心,并由大的伸肌扭矩平衡;尽管如此,由于髋关节屈曲,功率仍被吸收。(摘要截断于400字)

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