Higher derivatives of the end-point map of a linear control system via adapted coordinates

Abstract

We study the end-point map of a control-linear system in a neighborhood of an arbitrarily chosen trajectory. In particular, we want to calculate the k-th order derivative of this map in a given direction. A priori it is a solution of a quite complicated ODE depending on all derivatives of order less or equal k. We prove that there exists a special coordinate system adapted to the geometry of the problem, which changes the system of ODEs describing all derivatives of the end-point map up to order k to equations of a control-affine (non-autonomous control-linear) system, with the direction of derivation playing the role of the new control. As an application we study controllability criteria for this system, obtaining first and second-order necessary optimality conditions of sub-Riemannian geodesics. In particular, for the case of an abnormal minimizer we can interpret Goh conditions as non-controllability conditions of this control-affine system for k=2. We make a hypothesis that for higher k's its non-controllability corresponds to recently obtained higher-order analogs of the Goh conditions [Boarotto, Monti, Palmurella, 2020], [Boarotto, Monti, a Socionovo, 2022].

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