Distributed Collision-Free Motion Coordination on a Sphere: A Conic Control Barrier Function Approach
Abstract
This letter studies a distributed collision avoidance control problem for a group of rigid bodies on a sphere. A rigid body network, consisting of multiple rigid bodies constrained to a spherical surface and an interconnection topology, is first formulated. In this formulation, it is shown that motion coordination on a sphere is equivalent to attitude coordination on the 3-dimensional Special Orthogonal group. Then, an angle-based control barrier function that can handle a geodesic distance constraint on a spherical surface is presented. The proposed control barrier function is then extended to a relative motion case and applied to a collision avoidance problem for a rigid body network operating on a sphere. Each rigid body chooses its control input by solving a distributed optimization problem to achieve a nominal distributed motion coordination strategy while satisfying constraints for collision avoidance. The proposed collision-free motion coordination law is validated via simulation.
Keywords
Cite
@article{arxiv.2003.13363,
title = {Distributed Collision-Free Motion Coordination on a Sphere: A Conic Control Barrier Function Approach},
author = {Tatsuya Ibuki and Sean Wilson and Aaron D. Ames and Magnus Egerstedt},
journal= {arXiv preprint arXiv:2003.13363},
year = {2020}
}