Title :
Strongly convex attainable sets and low complexity finite-state controllers
Author :
Weber, Andreas ; Reissig, Gunther
Author_Institution :
Dept. Aerosp. Eng., Univ. of the Fed. Armed Forces Munich, Neubiberg, Germany
Abstract :
We present several novel results related to the concept of strong convexity, culminating in sufficient conditions for attainable sets of continuous-time nonlinear dynamical systems to be strongly convex. Based on these results, we propose a method to over-approximate attainable sets by intersections of supporting balls, which greatly improves upon the accuracy of previously proposed approximations based on supporting halfspaces. The latter advantage can be exploited, for example, when the method is used in algorithms that compute discrete abstractions of continuous plants. As we demonstrate by an example, the design of finite-state controllers can then be based on coarser state space quantizations, which directly translates into a reduced complexity of the controllers.
Keywords :
computational complexity; continuous time systems; nonlinear dynamical systems; set theory; state-space methods; continuous-time nonlinear dynamical systems; low complexity finite-state controllers; reduced controller complexity; state space quantization; strongly convex attainable sets; Aerospace electronics; Approximation methods; Australia; Automata; Complexity theory; Quantization (signal); Vectors;
Conference_Titel :
Control Conference (AUCC), 2013 3rd Australian
Conference_Location :
Fremantle, WA
Print_ISBN :
978-1-4799-2497-4
DOI :
10.1109/AUCC.2013.6697248
