Observer-Based Adaptive Hybrid Feedback for Robust Global Attitude Stabilization of a Rigid Body

In this article, an observer-based adaptive hybrid attitude controller is presented that overcomes the topological obstructions associated with the global attitude stabilization. This hybrid controller consists of two major parts: an adaptive trimodal hybrid controller to eliminate unwinding phenomenon, and a centrally synergistic potential function. In the adaptive trimodal hybrid controller, the first logic variable selects, which quaternion representation of the desired attitude should be tracked. Furthermore, an adaptive technique is introduced to collaborate with the second logic variable to adapt the hysteresis width. The third logic variable controls the mismatch between the auxiliary dynamical system and the actual attitude. Moreover, an auxiliary dynamical system and a nonlinear angular velocity observer are presented whose outputs are utilized in the proposed feedback control law to attain the necessary damping. Furthermore, a new centrally synergistic potential function is presented to cooperate with the trimodal hybrid controller to overcome the topological obstruction associated with the vector bundle structure. The robust global asymptotic stability of the consequent closed-loop system is guaranteed through a Lyapunov analysis. A comparative analysis in simulations illustrates the effectiveness and superiority of the proposed control scheme.

Automated summary

An observer-based adaptive hybrid attitude controller is presented to overcome topological obstructions associated with global attitude stabilization. The controller consists of an adaptive trimodal hybrid controller and a centrally synergistic potential function, utilizing adaptive techniques and auxiliary dynamical systems to achieve robust global asymptotic stability. The controller demonstrates effectiveness and superiority in simulations, showcasing its potential for practical applications.