利用全局、局部和随状态变化的应变参数化,建立软硬混合机器人的低阶模型

Anup Teejo Mathew, Daniel Feliu-Talegon, Abdulaziz Y Alkayas, Frederic Boyer, Federico Renda
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引用次数: 0

摘要

由于需要对软体机器人进行快速准确的分析,因此需要简化阶次模型(ROM)。在这些模型中,基于应变的简化模型(ROM)是通过对应变的离散化来捕捉机器人的构型。基于 Cosserat 杆的几何精确可变应变参数化,我们开发了一种只需最少自由度就能表示机器人状态的 ROM:几何可变应变(GVS)模型。该模型允许在同一数学框架下对开链、支链或闭链软硬混合机器人进行静态和动态分析。本文首次提出了通用软硬混合机器人的完整 GVS 建模框架。基于可变应变场的马格努斯展开,我们开发了一种计算系统拉格朗日动力学的高效递归算法。为了将软链接离散化,我们引入了状态和时间相关基,这是最一般形式的应变基。我们将独立基础分为全局基础和局部基础。我们提出了以节点值为广义坐标的 "类有限元 "局部应变基础。最后,我们利用四个实际应用来说明所开发模型的潜力。我们认为,软机器人领域将利用本研究提出的综合框架来分析各种特定的机器人系统。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Reduced order modeling of hybrid soft-rigid robots using global, local, and state-dependent strain parameterization
The need for fast and accurate analysis of soft robots calls for reduced order models (ROM). Among these, the relative reduction of strain-based ROMs follows the discretization of the strain to capture the configurations of the robot. Based on the geometrically exact variable strain parametrization of the Cosserat rod, we developed a ROM that necessitates a minimal number of degrees of freedom to represent the state of the robot: the Geometric Variable Strain (GVS) model. This model allows the static and dynamic analysis of open-, branched-, or closed-chain soft-rigid hybrid robots, all under the same mathematical framework. This paper presents for the first time the complete GVS modeling framework for a generic hybrid soft-rigid robot. Based on the Magnus expansion of the variable strain field, we developed an efficient recursive algorithm for computing the Lagrangian dynamics of the system. To discretize the soft link, we introduce state- and time-dependent basis, which is the most general form of strain basis. We classify the independent bases into global and local bases. We propose “FEM-like” local strain bases with nodal values as their generalized coordinates. Finally, using four real-world applications, we illustrate the potential of the model developed. We think that the soft robotics community will use the comprehensive framework presented in this work to analyze a wide range of specific robotic systems.
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