Contraction based stabilization of nonlinear singularly perturbed systems and application to high gain feedback
For control theorists and engineers, this provides a more flexible stabilization method for multi-time-scale systems, relaxing constraints of traditional Lyapunov-based approaches.
This paper proposes a contraction theory-based framework for stabilizing nonlinear singularly perturbed systems, achieving bounded tracking error without requiring interconnection conditions or smallness of the perturbation parameter. The method extends the class of contracting systems and is combined with high gain feedback for approximate feedback linearization.
Recent development of contraction theory based analysis of singularly perturbed system has opened the door for inspecting differential behavior of multi time-scale systems. In this paper a contraction theory based framework is proposed for stabilization of singularly perturbed systems. The primary objective is to design a feedback controller to achieve bounded tracking error for both standard and non-standard singularly perturbed systems. This framework provides relaxation over traditional quadratic Lyapunov based method as there is no need to satisfy interconnection conditions during controller design algorithm. Moreover, the stability bound does not depend on smallness of singularly perturbed parameter. Combined with high gain scaling, the proposed technique is shown to assure contraction of approximate feedback linearizable systems. These findings extend the class of nonlinear systems which can be made contracting.