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一种基于机器学习的概率计算框架,用于量化簇状张拉整体结构驱动的不确定性。

A machine learning-based probabilistic computational framework for uncertainty quantification of actuation of clustered tensegrity structures.

作者信息

Ge Yipeng, He Zigang, Li Shaofan, Zhang Liang, Shi Litao

机构信息

College of Aerospace Engineering, Chongqing University, Chongqing, 400044 People's Republic of China.

Department of Civil and Environmental Engineering, University of California at Berkeley, Berkeley, CA 74720 USA.

出版信息

Comput Mech. 2023 Mar 5:1-20. doi: 10.1007/s00466-023-02284-0.

DOI:10.1007/s00466-023-02284-0
PMID:37359778
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9985701/
Abstract

Clustered tensegrity structures integrated with continuous cables are lightweight, foldable, and deployable. Thus, they can be used as flexible manipulators or soft robots. The actuation process of such soft structure has high probabilistic sensitivity. It is essential to quantify the uncertainty of actuated responses of the tensegrity structures and to modulate their deformation accurately. In this work, we propose a comprehensive data-driven computational approach to study the uncertainty quantification (UQ) and probability propagation in clustered tensegrity structures, and we have developed a surrogate optimization model to control the flexible structure deformation. An example of clustered tensegrity beam subjected to a clustered actuation is presented to demonstrate the validity of the approach and its potential application. The three main novelties of the data-driven framework are: (1) The proposed model can avoid the difficulty of convergence in nonlinear Finite Element Analysis (FEA), by two machine learning methods, the Gauss Process Regression (GPR) and Neutral Network (NN). (2) A fast real-time prediction on uncertainty propagation can be achieved by the surrogate model, and (3) Optimization of the actuated deformation comes true by using both Sequence Quadratic Programming (SQP) and Bayesian optimization methods. The results have shown that the proposed data-driven computational approach is powerful and can be extended to other UQ models or alternative optimization objectives.

摘要

集成连续缆索的簇状张拉整体结构重量轻、可折叠且可展开。因此,它们可用作柔性机械手或软机器人。这种软结构的驱动过程具有很高的概率敏感性。量化张拉整体结构驱动响应的不确定性并精确调节其变形至关重要。在这项工作中,我们提出了一种全面的数据驱动计算方法来研究簇状张拉整体结构中的不确定性量化(UQ)和概率传播,并且我们开发了一个替代优化模型来控制柔性结构变形。给出了一个受簇状驱动的簇状张拉整体梁的例子,以证明该方法的有效性及其潜在应用。数据驱动框架的三个主要创新点是:(1)所提出的模型可以通过高斯过程回归(GPR)和神经网络(NN)这两种机器学习方法避免非线性有限元分析(FEA)中的收敛困难。(2)替代模型可以实现对不确定性传播的快速实时预测,并且(3)通过使用序列二次规划(SQP)和贝叶斯优化方法实现驱动变形的优化。结果表明,所提出的数据驱动计算方法很强大,并且可以扩展到其他UQ模型或替代优化目标。

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