Terradynamically streamlined shapes in animals and robots enhances traversability through densely cluttered terrain

TL;DR

This study demonstrates that terradynamically streamlined body shapes in animals and robots improve their ability to traverse densely cluttered terrain by facilitating body reorientation and reducing resistance, with implications for robotics and biological understanding.

Contribution

The paper reveals that terradynamically streamlined shapes enable better terrain traversal in animals and robots, introducing a novel roll maneuver and demonstrating its effectiveness without complex control systems.

Findings

Cockroaches use a novel roll maneuver to traverse narrow gaps.

Adding a rounded shell to robots improves obstacle navigation.

Streamlined shapes reduce terrain resistance and enhance mobility.

Abstract

Many animals, modern aircraft, and underwater vehicles use streamlined body shapes that reduce fluid dynamic drag to achieve fast and effective locomotion in air and water. Similarly, numerous small terrestrial animals move through cluttered terrain where 3-D, multi-component obstacles like grass, shrubs, vines, and leaf litter resist motion, but it is unknown whether their body shape plays a major role in traversal. Few ground vehicles or terrestrial robots have used body shape to effectively traverse cluttered terrain. Here, we challenged forest-floor-dwelling discoid cockroaches possessing a thin, rounded body to traverse tall, narrowly spaced, vertical, grass-like compliant beams. Animals displayed high traversal performance (79 +/- 12% probability and 3.4 +/- 0.7 s time). Although we observed diverse traversal strategies, cockroaches primarily (48 +/- 9 % probability) used a novel roll maneuver, allowing them to rapidly traverse obstacle gaps narrower than half body width (2.0 +/- 0.5 s traversal time). Reduction of body roundness by addition of artificial shells nearly inhibited roll maneuvers and decreased traversal performance. Inspired by this discovery, we added a thin, rounded exoskeletal shell to a legged robot with a nearly cuboidal body, common to many existing terrestrial robots. Without adding sensory feedback or changing the open-loop control, the rounded shell enabled the robot to traverse beam obstacles with gaps narrower than shell width via body roll. Terradynamically streamlined shapes can reduce terrain resistance and enhance traversability by assisting effective body reorientation via distributed mechanical feedback. Our findings highlight the need to consider body shape to improve robot mobility in real-world terrain often filled with clutter, and to develop better locomotor-ground contact models to understand interaction with complex terrain.