Optimal Motions of an Elastic Structure under Finite-Dimensional Distributed Control

Abstract

An optimal control problem for longitudinal motions of a thin elastic rod is considered. We suppose that a normal force, which changes piecewise constantly along the rod's length, is applied to the cross-section so that the positions of force jumps are equidistantly placed along the length. Additionally, external loads act at the rod ends. These distributed force and boundary loads are considered as control functions of the dynamic system. Given initial and terminal states at fixed time instants, the problem is to minimize the mean mechanical energy stored in the rod during its motion. We replace the classical wave equation with a variational problem solved via traveling waves defined on a special time-space mesh. For a uniform rod, the shortest admissible time horizon is estimated exactly, and the exact optimal control law is symbolically found in a recurrent way.