Soft Synergies: Model Order Reduction of Hybrid Soft-Rigid Robots via Optimal Strain Parameterization

IF 10.5 1区计算机科学 Q1 ROBOTICS

IEEE Transactions on Robotics Pub Date : 2024-12-25 DOI:10.1109/TRO.2024.3522182

Abdulaziz Y. Alkayas;Anup Teejo Mathew;Daniel Feliu-Talegon;Ping Deng;Thomas George Thuruthel;Federico Renda

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Abstract

Soft robots offer remarkable adaptability and safety advantages over rigid robots, but modeling their complex, nonlinear dynamics remains challenging. Strain-based models have recently emerged as a promising candidate to describe such systems, however, they tend to be high-dimensional and time-consuming. This article presents a novel model order reduction approach for soft and hybrid robots by combining strain-based modeling with proper orthogonal decomposition (POD). The method identifies optimal coupled strain basis functions—or mechanical synergies—from simulation data, enabling the description of soft robot configurations with a minimal number of generalized coordinates. The reduced order model (ROM) achieves substantial dimensionality reduction in the configuration space while preserving accuracy. Rigorous testing demonstrates the interpolation and extrapolation capabilities of the ROM for soft manipulators under static and dynamic conditions. The approach is further validated on a snake-like hyper-redundant rigid manipulator and a closed-chain system with soft and rigid components, illustrating its broad applicability. Moreover, the approach is leveraged for shape estimation of a real six-actuator soft manipulator using only two position markers, showcasing its practical utility. Finally, the ROM's dynamic and static behavior is validated experimentally against a parallel hybrid soft-rigid system, highlighting its effectiveness in representing the high-order model and the real system. This POD-based ROM offers significant computational speed-ups, paving the way for real-time simulation and control of complex soft and hybrid robots.

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软协同：基于最优应变参数化的混合软刚体机器人模型阶数降低

与刚性机器人相比，软体机器人具有显著的适应性和安全性优势，但对其复杂的非线性动力学建模仍然具有挑战性。基于应变的模型最近成为描述这类系统的一个有希望的候选，然而，它们往往是高维的且耗时的。本文提出了一种将应变建模与适当正交分解（POD）相结合的柔性和混合机器人模型降阶方法。该方法从仿真数据中识别出最优耦合应变基函数或机械协同作用，从而能够用最少数量的广义坐标描述软机器人构型。降阶模型（ROM）在保持精度的同时实现了配置空间的大幅度降维。严格的测试证明了ROM在静态和动态条件下对软机械臂的插补和外推能力。在蛇形超冗余刚性机械臂和软硬两种构件的闭链系统上进一步验证了该方法的适用性。此外，将该方法用于仅使用两个位置标记的实际六作动器软机械臂的形状估计，显示了其实用性。最后，在一个并联的软刚体混合系统上对ROM的动静态特性进行了实验验证，突出了其在高阶模型和实际系统中的有效性。这种基于pod的ROM提供了显著的计算加速，为复杂软机器人和混合机器人的实时仿真和控制铺平了道路。

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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来源期刊

IEEE Transactions on Robotics 工程技术-机器人学

CiteScore

14.90

自引率

5.10%

发文量

259

审稿时长

6.0 months

期刊介绍： The IEEE Transactions on Robotics (T-RO) is dedicated to publishing fundamental papers covering all facets of robotics, drawing on interdisciplinary approaches from computer science, control systems, electrical engineering, mathematics, mechanical engineering, and beyond. From industrial applications to service and personal assistants, surgical operations to space, underwater, and remote exploration, robots and intelligent machines play pivotal roles across various domains, including entertainment, safety, search and rescue, military applications, agriculture, and intelligent vehicles. Special emphasis is placed on intelligent machines and systems designed for unstructured environments, where a significant portion of the environment remains unknown and beyond direct sensing or control.