Omni-Roach: A legged robot capable of traversing multiple types of large obstacles and self-righting

TL;DR

Omni-Roach is a cockroach-inspired legged robot capable of traversing complex 3-D terrain and large obstacles by integrating multi-modal locomotion strategies and self-righting mechanisms, demonstrating high success rates in challenging environments.

Contribution

The paper introduces Omni-Roach, a novel robot that combines bio-inspired design and multi-functionality to improve obstacle traversal and self-righting capabilities.

Findings

Successfully traversed obstacles 1.1x body width apart

Self-righted within 4 seconds after overturning

Downward tail oscillation aids in beam gap traversal

Abstract

Robots excel at avoiding obstacles but struggle to traverse complex 3-D terrain with cluttered large obstacles. By contrast, insects like cockroaches excel at doing so. Recent research in our lab elucidated how locomotor transitions emerge from locomotor-environment interaction for diverse locomotor challenges abstracted from complex 3-D terrain and the strategies to overcome them. Here we built on these fundamental insights to develop a cockroach-inspired legged robot, Omni-Roach, that integrated these strategies to achieve multi-modal locomotion and provide a robophysical model to study the trade-off between multi-functionality and performance. The robot was based on the RHex design with six compliant legs and featured a rounded body with two wings that can open and a tail with pitch and yaw degrees of freedom. After two development and testing iterations, our robot was capable of overcoming all locomotor challenges with a high performance and success rate. It traversed cluttered rigid pillars only 1.1x robot body width apart, a 2.5x hip height bump, a 0.75x body length gap, densely cluttered flexible beams only 65% body width apart, and self-righted within 4 seconds. Systematic beam traversal experiments further revealed that a downward-pointing tail oscillating laterally helps roll the body into beam gaps and break frictional and interlocking contact to traverse. Our work highlights the usefulness of multi-functional appendages and exaptation for large obstacle traversal.