Abstract
We consider the problem of asymptotic convergence to invariant sets in interconnected nonlinear dynamical systems. Standard approaches often require that the invariant sets be uniformly attracting, e.g., stable in the Lyapunov sense. This, however, is neither a necessary requirement nor is always useful. Systems may, for instance, be inherently unstable (e.g., intermittent, itinerant, meta-stable) or the problem statement may include requirements that cannot be satisfied with stable solutions. This is often the case in general optimization problems and in nonlinear parameter identification or adaptation. Conventional techniques for these cases either rely on detailed knowledge of the system's vector-fields or require boundedness of its states. The presently proposed method relies only on estimates of the input-output maps and steady-state characteristics. The method requires the possibility of representing the system as an interconnection of a stable and contracting part with an unstable and exploratory part. We illustrate with examples how the method can be applied to problems of analyzing the asymptotic behavior of locally unstable systems as well as to problems of parameter identification and adaptation in the presence of nonlinear parametrizations. The relation of our results to conventional small-gain theorems is discussed.
Highlights
Small-Gain theorems are widely recognized as effective tools for the analysis of asymptotic behavior of the cascades and interconnections of linear and nonlinear systems [1], [2]
They are especially advantageous in those situations when mathematical models of systems are uncertain, and only estimates of the input-output properties of each component are available
As the methods of control expand from purely engineering applications into wider areas of science, there is a need for maintaining behavior that fail to obey the usual notion of Lyapunov stability [8]
Summary
Small-Gain theorems are widely recognized as effective tools for the analysis of asymptotic behavior of the cascades and interconnections of linear and nonlinear systems [1], [2]. They are especially advantageous in those situations when mathematical models of systems are uncertain, and only estimates of the input-output properties of each component are available. The latter property together with the notions of input-output and input-to-state stability [1], [3], [4] makes the small-gain technique a promising instrument in the analysis of complex biological and physical systems, see for instance, [5], [6], [7]. Are few examples of systems in which explorative, searching rather than Lyapunov-unstable behavior is considered useful or inherent
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