三维生物力学模型,无需使用力传感器即可对上肢和 L5/S1 关节进行动态分析

MİTHAT Yanikören, Sezcan Yilmaz, Ömer Gündoğdu
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引用次数: 0

摘要

在不破坏人体完整性的情况下,不可能直接测量作用在生物体关节上的反作用力和力矩。人体的 L5/S1 关节比其他关节有更高的损坏可能性。本研究旨在开发一种方法,只需使用运动学测量输入,而无需从双脚接触地面的点进行力测量,即可计算出作用在 L5/S1 和上肢关节上的净反作用力和力矩。为此,创建了适合人体解剖学的三维生物力学模型。运动学分析采用 Denavit-Hartenberg (DH) 方法进行。牛顿-欧勒(NE)迭代法用于反动态计算。关节运动的运动学测量输入是由受试者在一项实验研究中获得的,该实验研究涉及将某一负载从地面举起并降低到高处。通过将使用建议方法获得的结果与其他结果以及文献数据进行比较,对模型进行了验证。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

3D biomechanical model that can perform dynamic analysis of the upper extremity and L5/S1 joints without the use of force sensor

3D biomechanical model that can perform dynamic analysis of the upper extremity and L5/S1 joints without the use of force sensor

It is not possible to directly measure the reaction forces and moments acting on the joints in the living things without damaging the integrity of the body. L5/S1 joint in the human body have a higher damage potential than other joints. In this study, it is aimed to develop a method that can calculate the net reaction forces and moments acting on the L5/S1 and upper extremity joints by using only kinematic measurement inputs, without the need for force measurement from the points where the feet contact the ground. For this purpose, 3D biomechanical model suitable for human anatomy was created. Kinematic analyzes were performed using the Denavit–Hartenberg (DH) method. Iterative Newton–Euler (NE) method was used for inverse dynamic calculations. The kinematic measurement inputs of joint movements were obtained by the subject in an experimental study involving the lifting task a certain load from the ground and lowering it to a high place. The model was verified by comparing the results obtained using the proposed method with each other and with the literature data.

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