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利用优化模板模型进行稳态行走过程中的质心运动学重建。

Center of mass kinematic reconstruction during steady-state walking using optimized template models.

机构信息

Aerospace & Mechanical Engineering Department, University of Notre Dame, Notre Dame, Indiana, United States of America.

出版信息

PLoS One. 2024 Nov 5;19(11):e0313156. doi: 10.1371/journal.pone.0313156. eCollection 2024.

DOI:10.1371/journal.pone.0313156
PMID:39499675
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11537374/
Abstract

Template models, such as the Bipedal Spring-Loaded Inverted Pendulum and the Virtual Pivot Point, have been widely used as low-dimensional representations of the complex dynamics in legged locomotion. Despite their ability to qualitatively match human walking characteristics like M-shaped ground reaction force (GRF) profiles, they often exhibit discrepancies when compared to experimental data, notably in overestimating vertical center of mass (CoM) displacement and underestimating gait event timings (touchdown/ liftoff). This paper hypothesizes that the constant leg stiffness of these models explains the majority of these discrepancies. The study systematically investigates the impact of stiffness variations on the fidelity of model fittings to human data, where an optimization framework is employed to identify optimal leg stiffness trajectories. The study also quantifies the effects of stiffness variations on salient characteristics of human walking (GRF profiles and gait event timing). The optimization framework was applied to 24 subjects walking at 40% to 145% preferred walking speed (PWS). The findings reveal that despite only modifying ground forces in one direction, variable leg stiffness models exhibited a >80% reduction in CoM error across both the B-SLIP and VPP models, while also improving prediction of human GRF profiles. However, the accuracy of gait event timing did not consistently show improvement across all conditions. The resulting stiffness profiles mimic walking characteristics of ankle push-off during double support and reduced CoM vaulting during single support.

摘要

模板模型,如双足 Spring-Loaded 倒立摆和虚拟枢轴点,已被广泛用作腿部运动中复杂动力学的低维表示。尽管它们能够定性地匹配人类行走的特征,如 M 形地面反作用力 (GRF) 曲线,但与实验数据相比,它们经常存在差异,特别是在高估垂直质心 (CoM) 位移和低估步态事件时间(触地/离地)方面。本文假设这些模型的恒定腿部刚度解释了这些差异的大部分原因。该研究系统地研究了刚度变化对模型拟合人类数据的保真度的影响,其中采用优化框架来确定最佳腿部刚度轨迹。该研究还量化了刚度变化对人类行走特征(GRF 曲线和步态事件时间)的影响。优化框架应用于 24 名以 40%至 145%的偏好行走速度(PWS)行走的受试者。研究结果表明,尽管仅在一个方向上修改地面力,变刚度模型在 B-SLIP 和 VPP 模型中都使 CoM 误差降低了>80%,同时还改善了对人类 GRF 曲线的预测。然而,步态事件时间的准确性并非在所有条件下都一致得到改善。所得的刚度曲线模拟了在双支撑期间踝关节推离和在单支撑期间 CoM 上升减少的行走特征。

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本文引用的文献

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Running Gait and Control of Quadruped Robot Based on SLIP Model.基于SLIP模型的四足机器人奔跑步态与控制
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Virtual pivot point: Always experimentally observed in human walking?虚拟枢轴点:在人类行走中始终被实验观察到?
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Humans prioritize walking efficiency or walking stability based on environmental risk.人类会根据环境风险优先考虑行走效率或行走稳定性。
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