人类及其他脊椎动物在跑步、小跑和跳跃时步频的决定因素。
The determinants of the step frequency in running, trotting and hopping in man and other vertebrates.
作者信息
Cavagna G A, Franzetti P, Heglund N C, Willems P
机构信息
Istituto di Fisiologia Umana, Università di Milano, Italy.
出版信息
J Physiol. 1988 May;399:81-92. doi: 10.1113/jphysiol.1988.sp017069.
Abstract
- During each step of running, trotting or hopping part of the gravitational and kinetic energy of the body is absorbed and successively restored by the muscles as in an elastic rebound. In this study we analysed the vertical motion of the centre of gravity of the body during this rebound and defined the relationship between the apparent natural frequency of the bouncing system and the step frequency at the different speeds. 2. The step period and the vertical oscillation of the centre of gravity during the step were divided into two parts: a part taking place when the vertical force exerted on the ground is greater than body weight (lower part of the oscillation) and a part taking place when this force is smaller than body weight (upper part of the oscillation). This analysis was made on running humans and birds; trotting dogs, monkeys and rams; and hopping kangaroos and springhares. 3. During trotting and low-speed running the rebound is symmetric, i.e. the duration and the amplitude of the lower part of the vertical oscillation of the centre of gravity are about equal to those of the upper part. In this case, the step frequency equals the frequency of the bouncing system. 4. At high speeds of running and in hopping the rebound is asymmetric, i.e. the duration and the amplitude of the upper part of the oscillation are greater than those of the lower part, and the step frequency is lower than the frequency of the system. 5. The asymmetry is due to a relative increase in the vertical push. At a given speed, the asymmetric bounce requires a greater power to maintain the motion of the centre of gravity of the body, Wext, than the symmetric bounce. A reduction of the push would decrease Wext but the resulting greater step frequency would increase the power required to accelerate the limbs relative to the centre of gravity, Wint. It is concluded that the asymmetric rebound is adopted in order to minimize the total power, Wext + Wint.
摘要
- 在跑步、小跑或跳跃的每一步中,身体的部分重力和动能会被肌肉吸收,并像弹性反弹一样依次恢复。在本研究中,我们分析了身体重心在这种反弹过程中的垂直运动,并确定了弹跳系统的表观固有频率与不同速度下的步频之间的关系。2. 步长周期和步长过程中重心的垂直振荡被分为两部分:一部分发生在施加在地面上的垂直力大于体重时(振荡的下部),另一部分发生在该力小于体重时(振荡的上部)。该分析针对跑步的人类和鸟类、小跑的狗、猴子和公羊,以及跳跃的袋鼠和跳兔进行。3. 在小跑和低速跑步时,反弹是对称的,即重心垂直振荡下部的持续时间和幅度大约等于上部的持续时间和幅度。在这种情况下,步频等于弹跳系统的频率。4. 在高速跑步和跳跃时,反弹是不对称的,即振荡上部的持续时间和幅度大于下部的持续时间和幅度,且步频低于系统频率。5. 这种不对称是由于垂直推力的相对增加。在给定速度下,不对称弹跳比对称弹跳需要更大的功率来维持身体重心的运动,即外部功率Wext。推力的减小会降低Wext,但由此产生的更高步频会增加相对于重心加速肢体所需的功率,即内部功率Wint。得出的结论是,采用不对称反弹是为了使总功率Wext + Wint最小化。
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