Control theory and splitting methods

Abstract

Our goal is to highlight some deep connections between numerical splitting methods and control theory. We consider evolution equations of the form x = f0(x) + f1(x), where f0 encodes non-reversible dynamics, motivating schemes that involve only forward flows of f0. In this context, a splitting method can be interpreted as a trajectory of the control-affine system x(t)=f0(x(t))+u(t)f1(x(t)), associated with a control u that is a finite sum of Dirac masses. The goal is then to find a control such that the flow generated by f0 + u(t)f1 is as close as possible to the flow of f0+f1. Using this interpretation and classical tools from control theory, we revisit well-known results on numerical splitting methods and prove several new ones. First, we show that there exist numerical schemes of arbitrary order involving only forward flows of f0, provided one allows complex coefficients for f1. Equivalently, for complex-valued controls, we prove that the Lie algebra rank condition is equivalent to small-time local controllability. Second, for real-valued coefficients, we show that the well-known order restrictions are linked to so-called "bad" Lie brackets from control theory, which are known to obstruct small-time local controllability. We investigate the conditions under which high-order methods exist, thanks to a basis of the free Lie algebra that we recently constructed.

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