ToRoS:设计机器人皮肤的拓扑优化方法

Juan Montes Maestre, R. Hinchet, Stelian Coros, Bernhard Thomaszewski
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摘要

软机器人在操纵易碎或可变形的物体、人机交互和探索难以到达的地形方面具有独特的优势。然而,设计能够产生大的、有针对性的变形的软体机器人是具有挑战性的。在本文中,我们提出了一种设计软机器人的新方法,该方法将基于优化的设计与简单且具有成本效益的制造过程相结合。我们的方法围绕着机器人皮肤的概念——带有3d打印增强图案的薄织物,可以增强和控制普通的硅胶致动器。通过解耦形状控制和驱动,我们的方法实现了更简单和经济高效的制造过程。与以前依赖经验设计启发式生成所需变形的方法不同,我们的方法自动发现复杂的强化模式,无需任何领域知识或人为干预。这是通过将加固设计作为一个非线性约束优化问题,并使用一种新颖的三场拓扑优化方法来实现的,该方法是为3d打印加固的织物量身定制的。我们通过设计能够进行各种运动(如弯曲、收缩、扭曲及其组合)的软机器人驱动器来展示我们方法的潜力。我们还展示了我们的机器人皮肤在机器人抓取与软三指抓手和运动任务的软四足机器人的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
ToRoS: A Topology Optimization Approach for Designing Robotic Skins
Soft robotics offers unique advantages in manipulating fragile or deformable objects, human-robot interaction, and exploring inaccessible terrain. However, designing soft robots that produce large, targeted deformations is challenging. In this paper, we propose a new methodology for designing soft robots that combines optimization-based design with a simple and cost-efficient manufacturing process. Our approach is centered around the concept of robotic skins---thin fabrics with 3D-printed reinforcement patterns that augment and control plain silicone actuators. By decoupling shape control and actuation, our approach enables a simpler and cost-efficient manufacturing process. Unlike previous methods that rely on empirical design heuristics for generating desired deformations, our approach automatically discovers complex reinforcement patterns without any need for domain knowledge or human intervention. This is achieved by casting reinforcement design as a nonlinear constrained optimization problem and using a novel, three-field topology optimization approach tailored to fabrics with 3D-printed reinforcements. We demonstrate the potential of our approach by designing soft robotic actuators capable of various motions such as bending, contraction, twist, and combinations thereof. We also demonstrate applications of our robotic skins to robotic grasping with a soft three-finger gripper and locomotion tasks for a soft quadrupedal robot.
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