Finite-time transitions in optimal control and non-equilibrium relaxation

TL;DR

This paper investigates finite-time optimal control of a colloidal particle, revealing a sharp transition in control strategy linked to a dynamical phase transition in nonequilibrium relaxation.

Contribution

It introduces a theoretical and experimental framework connecting control strategy transitions to dynamical phase transitions in nonequilibrium systems.

Findings

Identifies a sharp transition in control strategy at a critical duration.

Links control cost to a rate function in nonequilibrium relaxation.

Demonstrates the transition through both theory and experiments.

Abstract

We theoretically and experimentally study finite-time optimal control of a colloidal particle steered through a spatially inhomogeneous environment, modeled by a position-dependent energetic cost at the final state. The competition between this state-dependent penalty and path-dependent dissipation gives rise to a sharp transition in the control strategy at a critical control duration. We further show that this transition can be linked to a dynamical phase transition in nonequilibrium relaxation after a quench, where the control cost maps onto the rate function governing rare trajectories.