Rotational controls and uniqueness of constrained viscosity solutions of Hamilton-Jacobi PDE

Abstract

The classical inward pointing condition (IPC) for a control system whose state x is constrained in the closure C:= of an open set prescribes that at each point of the boundary x∈ ∂ the intersection between the dynamics and the interior of the tangent space of at x is nonempty. Under this hypothesis, for every system trajectory x(.) on a time-interval [0,T], possibly violating the constraint, one can construct a new system trajectory x(.) that satisfies the constraint and whose distance from x(.) is bounded by a quantity proportional to the maximal deviation d:=dist(,x([0,T])). When (IPC) is violated, the construction of such a constrained trajectory is not possible in general. However, for a control system of the form x=f1(x)u1+f2(x)u2, we prove in this paper that a "higher order" inward pointing condition involving Lie brackets of the dynamics' vector fields allows for a novel construction of a constrained trajectory x(.) whose distance from the reference trajectory x(.) is bounded by a quantity proportional to d. Our method requires a further assumption of non-positiveness of a sort of curvature and is based on the implementation of a suitable "rotating" control strategy. As an application, we establish the continuity up to the boundary of the value function V of a classical optimal control problem, a continuity that allows to regard V as the unique constrained viscosity solution of the corresponding Bellman equation.

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