Affiliation:
1. Systems Engineering Research Group , University of Oulu , Pentti Kaiteran katu 1, 90570 Oulu , Finland
Abstract
Abstract
This paper is devoted to the analysis of fundamental limitations regarding closed-loop control performance of discrete-time nonlinear systems subject to hard constraints (which are nonlinear in state and manipulated input variables). The control performance for the problem of interest is quantified by the decline (decay) of the generalized energy of the controlled system. The paper develops (upper and lower) barriers bounding the decay of the system’s generalized energy, which can be achieved over a set of asymptotically stabilizing feedback laws. The corresponding problem is treated without the loss of generality, resulting in a theoretical framework that provides a solid basis for practical implementations. To enhance understanding, the main results are illustrated in a simple example.
Subject
Applied Mathematics,Engineering (miscellaneous),Computer Science (miscellaneous)
Reference18 articles.
1. Al’brekht, E.G. (1961). On the optimal stabilization of nonlinear systems, Journal of Applied Mathematics and Mechanics25(5): 1254–1266.10.1016/0021-8928(61)90005-3
2. Aranda-Escolástico, E., Salt, J., Guinaldo, M., Chacón, J. and Dormido, S. (2018). Optimal control for aperiodic dual-rate systems with time-varying delays, Sensors18(5): 1–19.10.3390/s18051491
3. Bemporad, A., Torrisit, F.D. and Morarit, M. (2000). Performance analysis of piecewise linear systems and model predictive control systems, IEEE Conference on Decision and Control, Sydney, NSW, Australia, pp. 4957–4962.
4. Boyd, S., El-Ghaoui, L., Feron, E. and Balakrishnan, V. (1994). Linear Matrix Inequalities in System and Control Theory, SIAM, Philadelphia, PA.10.1137/1.9781611970777
5. Buhl, M. and Lohmann, B. (2009). Control with exponentially decaying Lyapunov functions and its use for systems with input saturation, European Control Conference, Budapest, Hungary, pp. 3148–3153.