Motion-Driven Neural Optimizer for Prophylactic Braces Made by Distributed Microstructures

Xingjian Han, Yu Jiang, Weiming Wang, Guoxin Fang, Simeon Gill, Zhiqiang Zhang, Shengfa Wang, Jun Saito, Deepak Kumar, Zhongxuan Luo, Emily Whiting, Charlie C. L. Wang
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Abstract

Joint injuries, and their long-term consequences, present a substantial global health burden. Wearable prophylactic braces are an attractive potential solution to reduce the incidence of joint injuries by limiting joint movements that are related to injury risk. Given human motion and ground reaction forces, we present a computational framework that enables the design of personalized braces by optimizing the distribution of microstructures and elasticity. As varied brace designs yield different reaction forces that influence kinematics and kinetics analysis outcomes, the optimization process is formulated as a differentiable end-to-end pipeline in which the design domain of microstructure distribution is parameterized onto a neural network. The optimized distribution of microstructures is obtained via a self-learning process to determine the network coefficients according to a carefully designed set of losses and the integrated biomechanical and physical analyses. Since knees and ankles are the most commonly injured joints, we demonstrate the effectiveness of our pipeline by designing, fabricating, and testing prophylactic braces for the knee and ankle to prevent potentially harmful joint movements.
分布式微结构预防性支架的运动驱动神经优化器
关节损伤及其长期后果给全球健康造成了巨大负担。可穿戴的预防性护具是一种极具吸引力的潜在解决方案,它可以通过限制与损伤风险相关的关节运动来降低关节损伤的发生率。考虑到人体运动和地面反作用力,我们提出了一个计算框架,通过优化微结构和弹性的分布来设计个性化支架。由于不同的护具设计会产生不同的反作用力,从而影响运动学和动力学分析结果,因此优化过程被表述为一个可微分的端到端流水线,其中微结构分布的设计域被参数化为神经网络。微结构的优化分布是通过一个自学过程获得的,该过程根据精心设计的损耗集以及综合生物力学和物理分析来确定网络系数。由于膝关节和踝关节是最常受伤的关节,我们通过设计、制造和测试膝关节和踝关节的预防性支架来防止潜在的有害关节运动,从而证明了我们管道的有效性。
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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