Addition of a peristaltic wave improves multi-legged locomotion performance on complex terrains

TL;DR

This paper introduces a peristaltic wave in multi-legged robot locomotion, significantly enhancing obstacle-climbing and terrain traversal capabilities on complex terrains, beyond traditional two-wave templates.

Contribution

It proposes a novel peristaltic actuation mechanism for multi-legged robots, improving their ability to navigate complex terrains and climb obstacles comparable to their height.

Findings

Peristaltic wave improves obstacle-climbing performance.

Peristalsis significantly enhances traversal on rugose terrains.

The new actuation mechanism enables all-terrain multi-legged locomotion.

Abstract

Characterized by their elongate bodies and relatively simple legs, multi-legged robots have the potential to locomote through complex terrains for applications such as search-and-rescue and terrain inspection. Prior work has developed effective and reliable locomotion strategies for multi-legged robots by propagating the two waves of lateral body undulation and leg stepping, which we will refer to as the two-wave template. However, these robots have limited capability to climb over obstacles with sizes comparable to their heights. We hypothesize that such limitations stem from the two-wave template that we used to prescribe the multi-legged locomotion. Seeking effective alternative waves for obstacle-climbing, we designed a five-segment robot with static (non-actuated) legs, where each cable-driven joint has a rotational degree-of-freedom (DoF) in the sagittal plane (vertical wave) and a linear DoF (peristaltic wave). We tested robot locomotion performance on a flat terrain and a rugose terrain. While the benefit of peristalsis on flat-ground locomotion is marginal, the inclusion of a peristaltic wave substantially improves the locomotion performance in rugose terrains: it not only enables obstacle-climbing capabilities with obstacles having a similar height as the robot, but it also significantly improves the traversing capabilities of the robot in such terrains. Our results demonstrate an alternative actuation mechanism for multi-legged robots, paving the way towards all-terrain multi-legged robots.