立定直跳中足部力量及功的估算方法。

IF 1.1 4区 医学 Q4 ENGINEERING, BIOMEDICAL
Kundan Joshi, Blake M Ashby
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引用次数: 0

摘要

实验动作捕捉研究通常认为脚是一个单一的刚体,即使脚有26块骨头和30个关节。研究足部刚体偏差的方法多种多样。本研究比较了远端足力(DFP)、足力不平衡(FPI)和2段足模型3种方法,研究了立定垂直跳起跳阶段的足力和功。6名身体活跃的参与者每人从起始位置跨越两个相邻的力平台进行6次站立垂直跳跃,以使作用在足跖指关节(MTP)上的地面反作用力被分散。运动开始后不久,DFP表现为能量吸收阶段,随后是能量产生阶段。与DFP相比,FPI具有更小的功率吸收和更大的功率产生的相似模式。MTP关节主要在2节段模型中产生动力。使用DFP时净足功为-4.0 (1.0)J,使用FPI时为1.8 (1.1)J,使用MTP时为5.1 (0.5)J。结果表明,MTP关节只是足部力量的一个来源,DFP和FPI在跳跃和其他动作中的差异有待进一步研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Methods of Estimating Foot Power and Work in Standing Vertical Jump.

Experimental motion capture studies have commonly considered the foot as a single rigid body even though the foot contains 26 bones and 30 joints. Various methods have been applied to study rigid body deviations of the foot. This study compared 3 methods: distal foot power (DFP), foot power imbalance (FPI), and a 2-segment foot model to study foot power and work in the takeoff phase of standing vertical jumps. Six physically active participants each performed 6 standing vertical jumps from a starting position spanning 2 adjacent force platforms to allow ground reaction forces acting on the foot to be divided at the metatarsophalangeal (MTP) joints. Shortly after movement initiation, DFP showed a power absorption phase followed by a power generation phase. FPI followed a similar pattern with smaller power absorption and a larger power generation compared to DFP. MTP joints primarily generated power in the 2-segment model. The net foot work was -4.0 (1.0) J using DFP, 1.8 (1.1) J using FPI, and 5.1 (0.5) J with MTP. The results suggest that MTP joints are only 1 source of foot power and that differences between DFP and FPI should be further explored in jumping and other movements.

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来源期刊
Journal of Applied Biomechanics
Journal of Applied Biomechanics 医学-工程:生物医学
CiteScore
2.00
自引率
0.00%
发文量
47
审稿时长
6-12 weeks
期刊介绍: The mission of the Journal of Applied Biomechanics (JAB) is to disseminate the highest quality peer-reviewed studies that utilize biomechanical strategies to advance the study of human movement. Areas of interest include clinical biomechanics, gait and posture mechanics, musculoskeletal and neuromuscular biomechanics, sport mechanics, and biomechanical modeling. Studies of sport performance that explicitly generalize to broader activities, contribute substantially to fundamental understanding of human motion, or are in a sport that enjoys wide participation, are welcome. Also within the scope of JAB are studies using biomechanical strategies to investigate the structure, control, function, and state (health and disease) of animals.
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