Computational biomechanics for a standing human body: Modal analysis and simulation

IF 2.2 4区医学 Q3 ENGINEERING, BIOMEDICAL

International Journal for Numerical Methods in Biomedical Engineering Pub Date : 2024-07-11 DOI:10.1002/cnm.3841

Goong Chen, Matthew M. Scully, Jingtong Huang, Alexey Sergeev, Jing Yang, Chunqiu Wei, Patrick Monday, Leon Cohen, Xingong Cheng, Sanyang Liu, Junmin Wang, Shuqin Zhou

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Abstract

We develop computational mechanical modeling and methods for the analysis and simulation of the motions of a human body. This type of work is crucial in many aspects of human life, ranging from comfort in riding, the motion of aged persons, sports performance and injuries, and many ergonomic issues. A prevailing approach for human motion studies is through lumped parameter models containing discrete masses for the parts of the human body with empirically determined spring, mass, damping coefficients. Such models have been effective to some extent; however, a much more faithful modeling method is to model the human body as it is, namely, as a continuum. We present this approach, and for comparison, we choose two digital CAD models of mannequins for a standing human body, one from the versatile software package LS-DYNA and another from open resources with some of our own adaptations. Our basic view in this paper is to regard human motion as a perturbation and vibration from an equilibrium position which is upright standing. A linear elastodynamic model is chosen for modal analysis, but a full nonlinear viscoelastoplastic extension is possible for full-body simulation. The motion and vibration of these two mannequin models is analyzed by modal analysis, where the normal vibration modes are determined. LS-DYNA is used as the supercomputing and simulation platform. Four sets of low-frequency modes are tabulated, discussed, visualized, and compared. Higher frequency modes are also selectively displayed. We have found that these modes of motion and vibration form intrinsic basic modes of biomechanical motion of the human body. This view is supported by our finding of the upright walking motion as a low-frequency mode in modal analysis. Such a “walking mode” shows the in-phase and out-of-phase movements between the legs and arms on the left and right sides of a human body, implying that this walking motion is spontaneous, likely not requiring any directives from the brain. Dynamic motions of CAD mannequins are also simulated by drop tests for comparisons and the validity of the models is discussed through Fourier frequency analysis. All computed modes of motion are collected in several sets of video animations for ease of visualization. Samples of LS-DYNA computer codes are also included for possible use by other researchers.

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站立人体的计算生物力学：模态分析与模拟

我们开发用于分析和模拟人体运动的计算机械建模和方法。这类工作对人类生活的许多方面都至关重要，包括乘车舒适度、老年人的运动、运动表现和损伤以及许多人体工程学问题。人体运动研究的一种普遍方法是通过包含离散质量的集合参数模型来研究人体各部分的运动，并根据经验确定弹簧、质量和阻尼系数。这种模型在一定程度上是有效的；然而，一种更忠实的建模方法是将人体作为一个连续体来建模。我们介绍了这种方法，为了进行比较，我们选择了两个站立人体模型的数字 CAD 模型，一个来自多功能软件包 LS-DYNA，另一个来自开放资源，并经过我们自己的一些调整。本文的基本观点是将人体运动视为从直立平衡位置开始的扰动和振动。在进行模态分析时，我们选择了线性弹性力学模型，但在进行全身模拟时，我们也可能采用完全非线性粘弹性扩展模型。这两个人体模型的运动和振动是通过模态分析来确定法向振动模态的。采用 LS-DYNA 作为超级计算和仿真平台。对四组低频模态进行了列表、讨论、可视化和比较。高频模式也有选择地显示出来。我们发现，这些运动和振动模式构成了人体生物力学运动的内在基本模式。在模态分析中，我们发现直立行走运动是一种低频模态，这为我们的观点提供了支持。这种 "行走模式 "显示了人体左右两侧腿部和手臂之间的同相和异相运动，意味着这种行走运动是自发的，很可能不需要大脑的任何指令。此外，还通过跌落测试模拟了 CAD 人体模型的动态运动，并通过傅里叶频率分析讨论了模型的有效性。所有计算出的运动模式都收集在几组视频动画中，以便于可视化。此外还包括 LS-DYNA 计算机代码样本，供其他研究人员使用。

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

International Journal for Numerical Methods in Biomedical Engineering ENGINEERING, BIOMEDICAL-MATHEMATICAL & COMPUTATIONAL BIOLOGY

CiteScore

4.50

自引率

9.50%

发文量

103

审稿时长

3 months

期刊介绍： All differential equation based models for biomedical applications and their novel solutions (using either established numerical methods such as finite difference, finite element and finite volume methods or new numerical methods) are within the scope of this journal. Manuscripts with experimental and analytical themes are also welcome if a component of the paper deals with numerical methods. Special cases that may not involve differential equations such as image processing, meshing and artificial intelligence are within the scope. Any research that is broadly linked to the wellbeing of the human body, either directly or indirectly, is also within the scope of this journal.