Distributed Circumnavigation Control with Dynamic Spacings for a Heterogeneous Multi-robot System
This addresses target entrapment scenarios for robotics applications, but it is incremental as it builds on existing circumnavigation control with a focus on heterogeneity.
The paper tackled the problem of coordinating a heterogeneous multi-robot system for circumnavigation with dynamic spacings based on robots' utilities, achieving stable control from random 3D positions as proven by theoretical analysis and experiments.
Circumnavigation control is useful in real-world applications such as entrapping a hostile target. In this paper, we consider a heterogeneous multi-robot system where robots have different physical properties, such as maximum movement speeds. Instead of equal-spacings, dynamic spacings according to robots' properties, which are termed utilities in this paper, will be more desirable in a scenario such as target entrapment. A distributed circumnavigation control algorithm based on utilities is proposed for any number of mobile robots from random 3D positions to circumnavigate a target. The dynamic spacings are subject to the variation of robots' utilities. The robots can only obtain the angular positions and utilities of their two neighbouring robots, so the control law is distributed. Theoretical analysis and experimental results are provided to prove the stability and effectiveness of the proposed control algorithm.