摘要:The objective of model reference adaptive control systems is to drive the trajectories of an uncertain dynamical system to the trajectories of a given reference model capturing a desired closed-loop system performance. To this end, most adaptive control signals take the form ua(t) = −ŴT(t)σ(x(t)), where x(t) ∈ ℝndenotes the state vector of an uncertain dynamical system, σ:ℝn→ ℝsdenotes a known basis function, and Ŵ(t) ∈ ℝs×mdenotes an estimation of the unknown weight matrix W ∈ ℝs×msatisfyingsmupdate laws (heremdenotes the number of control inputs). In this paper, we focus on a class of reduced-order, computationally less expensive, model reference adaptive control systems that are only predicated on a scalar update law. Specifically, our contribution is to utilize a command governor architecture in order to improve transient performance of this class of adaptive control systems. We prove the stability of the overall closed-loop system using Lyapunov stability theory and we also present an illustrative numerical example for demonstrating the efficacy of the proposed architecture.
关键词:KeywordsUncertain dynamical systemsreduced-order model reference adaptive controltransient performance improvementstability analysis
