Design and evolution of a modular tensegrity robot platform

• Published in: 2014 IEEE International Conference on Robotics and Automation (ICRA) pp. 3483 - 3489
• Main Authors: Bruce, Jonathan, Caluwaerts, Ken, Iscen, Atil, Sabelhaus, Andrew P., SunSpiral, Vytas
• Format: Conference Proceeding
• Language: English
• Published: IEEE 01.05.2014
• Subjects: DC motors; Electron tubes; Robot sensing systems; Robustness; Shape; Springs
• ISSN: 1050-4729; 2577-087X
• DOI: 10.1109/ICRA.2014.6907361

NASA Ames Research Center is developing a compliant modular tensegrity robotic platform for planetary exploration. In this paper we present the design and evolution of the platform's main hardware component, an untethered, robust tensegrity strut, with rich sensor feedback and cable actuation. Each strut is a complete robot, and multiple struts can be combined together to form a wide range of complex tensegrity robots. Our current goal for the tensegrity robotic platform is the development of SUPERball, a 6-strut icosahedron underactuated tensegrity robot aimed at dynamic locomotion for planetary exploration rovers and landers, but the aim is for the modular strut to enable a wide range of tensegrity morphologies. SUPERball is a second generation prototype, evolving from the tensegrity robot ReCTeR, which is also a modular, lightweight, highly compliant 6-strut tensegrity robot that was used to validate our physics based NASA Tensegrity Robot Toolkit (NTRT) simulator. Many hardware design parameters of the SUPERball were driven by locomotion results obtained in our validated simulator. These evolutionary explorations helped constrain motor torque and speed parameters, along with strut and string stress. As construction of the hardware has finalized, we have also used the same evolutionary framework to evolve controllers that respect the built hardware parameters.