Analyzing Lower Limb Dynamics in Human Gait Using Average Value-Based Technique

4区工程技术 Q1 Mathematics

Mathematical Problems in Engineering Pub Date : 2024-04-25 DOI:10.1155/2024/7344011

Sithara Mary Sunny, K. S. Sivanandan, Arun P. Parameswaran, Baiju Thankachan, S. N

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引用次数: 0

Abstract

The motivation of this study is to develop effective and economical assistive technologies for people with physical disabilities. The novelty in this manuscript is the application of the average value-based technique to accurately represent the involved biomechanics of the lower limb joints during the human gait cycle. This mathematical formulation of lower limb joints’ biomechanics forms the first objective for modeling and final exoskeleton prototype development. To account for modeling the characteristics of human locomotion, the nth-order linear differential equation with constant coefficients is considered with appropriate modification. The physical characteristics of an individual are represented by the constant coefficients (P0, P1, P2, and P3) of the modified infinite series, which are obtained by processing experimental data collected using an optical technique. The differential terms of the infinite series are replaced by difference terms (δbavg, δ2bavg, and δ3bavg) since the data were captured as a set of digital values. The work presented here is based on the experimental results of individuals suitably categorized according to their physical nature like age and other physical structure. The optically monitored positional values of the lower limb joints of the individual subjects while they are completing the gait cycles are used for getting values of different terms of the model. The data collected through the conduct of experiments are used for finding the values of the terms of the differential equation. The model is effectively validated through experimental results. It was determined that the representation’s accuracy fell within the ±5% acceptable tolerance limit. The model is prepared for healthy as well as disabled persons, through which the disability is quantified. The resulting model can be used to develop assistive devices for people with physical disabilities. This results in the rehabilitation process and thereby helps the reintegration into society, subsequently allowing them to lead a normal life.

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利用基于平均值的技术分析人类步态中的下肢动态

这项研究的动机是为肢体残疾人开发有效、经济的辅助技术。本手稿的新颖之处在于应用了基于平均值的技术，以准确表示人体步态周期中下肢关节的相关生物力学。这种下肢关节生物力学数学表述是建模和最终外骨骼原型开发的首要目标。为了对人体运动特性进行建模，我们考虑对具有常数系数的 n 阶线性微分方程进行适当修改。个人的物理特征由修正无穷级数的常数系数（P0、P1、P2 和 P3）表示，这些常数系数是通过处理使用光学技术收集的实验数据获得的。无穷级数的差分项由差分项（δbavg、δ2bavg 和 δ3bavg）取代，因为数据是以一组数字值的形式采集的。这里介绍的工作是基于根据年龄和其他身体结构等身体特征对个人进行适当分类的实验结果。受试者在完成步态循环时下肢关节的光学监测位置值被用于获取模型中不同项的值。通过实验收集的数据用于求得微分方程的项值。实验结果对模型进行了有效验证。实验结果表明，模型的精确度在 ±5% 的可接受范围内。该模型既适用于健康人，也适用于残疾人。由此产生的模型可用于为身体残疾者开发辅助设备。这将有助于残疾人的康复，从而帮助他们重新融入社会，过上正常的生活。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Mathematical Problems in Engineering 工程技术-工程：综合

CiteScore

4.00

自引率

0.00%

发文量

2853

审稿时长

4.2 months

期刊介绍： Mathematical Problems in Engineering is a broad-based journal which publishes articles of interest in all engineering disciplines. Mathematical Problems in Engineering publishes results of rigorous engineering research carried out using mathematical tools. Contributions containing formulations or results related to applications are also encouraged. The primary aim of Mathematical Problems in Engineering is rapid publication and dissemination of important mathematical work which has relevance to engineering. All areas of engineering are within the scope of the journal. In particular, aerospace engineering, bioengineering, chemical engineering, computer engineering, electrical engineering, industrial engineering and manufacturing systems, and mechanical engineering are of interest. Mathematical work of interest includes, but is not limited to, ordinary and partial differential equations, stochastic processes, calculus of variations, and nonlinear analysis.