猫在四足机器人系统中加速奔跑时脊柱-骨盆运动匹配的动力学分析

2014 14th International Conference on Control, Automation and Systems (ICCAS 2014) Pub Date : 2014-12-18 DOI:10.1109/ICCAS.2014.6987756

Young Kook Kim, Jongwon Park, Byungho Yoon, Kyung-Soo Kim, Soohyun Kim

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引用次数: 0

摘要

在猫科动物驰骋的速度表现中，相对脊柱运动是提高运动速度的关键。为了证明这一点，我们观察了一只家猫，研究了它奔跑的步态模式。基于对家猫动态行为的测量，我们观察到通过脊柱节段的相关角速率变化，速度显著增加。为了支持四足系统的运动，采用二维平面动力学模型分析了后肢站立相位，验证了脊柱运动产生的外扭矩对增加运动方向上的地面反作用力起重要作用。为了验证这一分析，在拟合的相对角速度剖面的时间、相位和幅值3个参数变化的情况下，进行了后肢姿态的动态仿真。

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Dynamic analysis of the spinal-pelvic motion match during feline galloping for speed increase into quadruped robotic system

In terms of the speed performance in feline galloping, relative spinal motion is observed as a key role to increase the locomotion speed. In order to prove this, a domestic cat was observed to investigate galloping gait patterns of the feline. Based on the measurement of the dynamic behavior of a domestic cat, we observed a significant increase in speed through correlated angular rate changes of spinal segments. To support the motion into a quadruped system, the hindlimb stance phase was analyzed using a 2 dimensional planar dynamic model to verify that the external torque generated by spinal motion plays an important role in increasing the ground reaction force in the direction of movement. To verify the analysis, the dynamic simulation demonstrating the hindlimb stance was applied with 3 parameter variations: time, phase and the amplitude of the fitted relative angular velocity profile.

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2014 14th International Conference on Control, Automation and Systems (ICCAS 2014)

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