Periodic solutions of nonlinear control systems with switching: a Lie-algebraic and contraction approach

TL;DR

This paper develops a Lie-algebraic and contraction method to analyze periodic solutions in nonlinear control systems with switching, with applications to chemical reaction optimization.

Contribution

It introduces a novel approach combining Lie algebra and contraction theory to identify periodic solutions in bang-bang control systems, linking fixed points of exponential map compositions to system periodicity.

Findings

Established the equivalence between periodic solutions and fixed points of exponential compositions.

Applied the theory to chemical reaction models with constrained controls.

Simplified the problem using the Bendixson-Dulac theorem in planar cases.

Abstract

This paper is devoted to the analysis of periodic solutions of nonlinear control-affine systems with bang-bang controls. Such problems naturally arise in periodic optimal control with constrained inputs, which have, in particular, important applications in the performance optimization of chemical reactions. We reduce the problem of constructing a periodic solution to that of finding a fixed point of a composition of exponential maps. The latter problem is then addressed using the Baker-Campbell-Hausdorff-Dynkin (BCHD) formula. We establish the equivalence between periodic solutions of the original control system and those of an associated autonomous system involving iterated Lie brackets. In the planar case, applying the Bendixson-Dulac theorem allows us to further simplify the problem to finding the equilibria of this autonomous system. The developed theory is then applied to nonlinear chemical reaction models with constrained controls.