Distributed Nonlinear Control of Networked Two-Wheeled Robots under Adversarial Interactions
This addresses secure control of networked mobile robots in adversarial environments, representing an incremental improvement in resilient distributed control methods.
This paper tackles distributed trajectory tracking for networks of nonholonomic mobile robots under adversarial information exchange by developing an exact global input-output feedback linearization scheme and a resilient desired-signal construction method. The approach suppresses adversarial influence with sufficient redundancy, recovering nominal tracking performance, and maintains bounded tracking errors otherwise, with simulation results validating the analysis and showing cyclic networks offer superior resilience.
This paper studies distributed trajectory tracking for networks of nonholonomic mobile robots under adversarial information exchange. An exact global input--output feedback linearization scheme is developed to regulate planar position outputs, yielding linear error dynamics without prescribing internal state trajectories. To mitigate corrupted neighbor information, a resilient desired-signal construction is proposed that combines local redundancy with trusted in-neighbor signals, without requiring adversary detection or isolation. When sufficient redundancy is available, the method suppresses adversarial influence and recovers nominal tracking performance. If redundancy conditions are violated, adversarial effects enter as bounded disturbances and the tracking error remains ultimately bounded. Simulation results on star, cyclic, and path topologies validate the analysis and demonstrate the superior resilience of cyclic networks due to distributed information propagation.