Modeling Running via Optimal Control for Shoe Design.

IF 1.7 4区 医学 Q4 BIOPHYSICS Journal of Biomechanical Engineering-Transactions of the Asme Pub Date : 2024-04-01 DOI:10.1115/1.4064405
Sarah C Fay, A E Hosoi
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Abstract

Shoe manufacturing technology is advancing faster than new shoe designs can viably be evaluated in human subject trials. To aid in the design process, this paper presents a model for estimating how new shoe properties will affect runner performance. This model assumes runners choose their gaits to optimize an intrinsic, unknown objective function. To learn this objective function, a simple two-dimensional mechanical model of runners was used to predict their gaits under different objectives, and the resulting gaits were compared to data from real running trials. The most realistic model gaits, i.e., the ones that best matched the data, were obtained when the model runners minimized the impulse they experience from the ground as well as the mechanical work done by their leg muscles. Using this objective function, the gait and thus performance of running under different shoe conditions can be predicted. The simple model is sufficiently sensitive to predict the difference in performance of shoes with disruptive designs but cannot distinguish between existing shoes whose properties are fairly similar. This model therefore is a viable tool for coarse-grain exploration of the design space and identifying promising behaviors of truly novel shoe materials and designs.

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通过优化控制建立跑步模型,用于鞋类设计
制鞋技术的发展速度远远快于对新鞋设计进行人体试验评估的速度。为了帮助设计过程,本文提出了一个模型,用于估计新鞋的性能将如何影响跑步者的表现。该模型假定跑步者选择步态是为了优化一个未知的内在目标函数。为了学习这个目标函数,我们使用了一个简单的跑步者二维机械模型来预测他们在不同目标下的步态,并将得出的步态与实际跑步试验的数据进行比较。当模型中的跑步者最大限度地减少来自地面的冲力以及腿部肌肉所做的机械功时,就能获得最真实的模型步态,即与数据最匹配的步态。利用这一目标函数,可以预测不同鞋子条件下的步态和跑步表现。这个简单的模型具有足够的灵敏度,可以预测具有破坏性设计的鞋子在性能上的差异,但无法区分特性相当相似的现有鞋子。因此,该模型是粗粒度探索设计空间和识别真正新型鞋子材料和设计的可行工具。
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来源期刊
CiteScore
3.40
自引率
5.90%
发文量
169
审稿时长
4-8 weeks
期刊介绍: Artificial Organs and Prostheses; Bioinstrumentation and Measurements; Bioheat Transfer; Biomaterials; Biomechanics; Bioprocess Engineering; Cellular Mechanics; Design and Control of Biological Systems; Physiological Systems.
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