Distributed Resilience-Aware Control in Multi-Robot Networks
Abstract
Ensuring resilient consensus in multi-robot systems with misbehaving agents remains a challenge, as many existing network resilience properties are inherently combinatorial and globally defined. While previous works have proposed control laws to enhance or preserve resilience in multi-robot networks, they often assume a fixed topology with known resilience properties, or require global state knowledge. These assumptions may be impractical in physically-constrained environments, where safety and resilience requirements are conflicting, or when misbehaving agents share inaccurate state information. In this work, we propose a distributed control law that enables each robot to guarantee resilient consensus and safety during its navigation without fixed topologies using only locally available information. To this end, we establish a sufficient condition for resilient consensus in time-varying networks based on the degree of non-misbehaving or normal agents. Using this condition, we design a Control Barrier Function (CBF)-based controller that guarantees resilient consensus and collision avoidance without requiring estimates of global state and/or control actions of all other robots. Finally, we validate our method through simulations.
Cite
@article{arxiv.2504.03120,
title = {Distributed Resilience-Aware Control in Multi-Robot Networks},
author = {Haejoon Lee and Dimitra Panagou},
journal= {arXiv preprint arXiv:2504.03120},
year = {2025}
}
Comments
Accepted and will appear at 2025 IEEE Conference on Decision and Control (CDC)