Skater: A Novel Bi-modal Bi-copter Robot for Adaptive Locomotion in Air and Diverse Terrain

TL;DR

Skater is a versatile bi-modal bi-copter robot capable of adaptive flight and ground movement across diverse terrains, utilizing a lightweight design, vectored thrust for steering, and advanced control for stable navigation.

Contribution

The paper introduces Skater, a novel bi-copter robot with integrated aerial and ground capabilities, featuring a lightweight design, dynamic modeling, and nonlinear model predictive control for trajectory tracking.

Findings

Demonstrates stable movement on slippery surfaces.

Shows effective terrain traversal and steering.

Validates performance through real-world experiments.

Abstract

In this letter, we present a novel bi-modal bi-copter robot called Skater, which is adaptable to air and various ground surfaces. Skater consists of a bi-copter moving along its longitudinal direction with two passive wheels on both sides. Using a longitudinally arranged bi-copter as the unified actuation system for both aerial and ground modes, this robot not only keeps a concise and lightweight mechanism but also possesses exceptional terrain traversing capability and strong steering capacity. Moreover, leveraging the vectored thrust characteristic of bi-copters, the Skater can actively generate the centripetal force needed for steering, enabling it to achieve stable movement even on slippery surfaces. Furthermore, we model the comprehensive dynamics of the Skater, analyze its differential flatness, and introduce a controller using nonlinear model predictive control for trajectory tracking. The outstanding performance of the system is verified by extensive real-world experiments and benchmark comparisons.