Turnpike and Sparse Optimal Control for Semiautonomous Neural ODEs

Abstract

We study long-time optimal control of control-affine semiautonomous neural ordinary differential equations (SA-NODEs) with 1-regularized controls. Three results are established. First, optimal state-control pairs satisfy an exponential turnpike property: they remain exponentially close to a stationary optimal pair for most of the time horizon, with decay rate and prefactor independent of the horizon length T. Second, 1 penalisation induces one-sided temporal sparsity: optimal controls are active at full amplitude on an initial arc [0,T*] and vanish identically on (T*,T), where T* is independent of T for T large. Third, an integral turnpike estimate shows the time-averaged deviation from the stationary pair is bounded uniformly in T. The proofs combine dissipativity inequalities, uniform adjoint bounds via the Pontryagin optimality system, and a time-rescaling argument adapted to the semiautonomous architecture. Numerical experiments on a Duffing oscillator and a damped pendulum confirm the three-phase turnpike profile and the one-sided sparsity structure, and demonstrate a 30× parameter reduction over vanilla NODEs with no loss of stabilization performance.