Stochastic impulse control of non-smooth dynamics with partial observation and execution delay: application to an environmental restoration problem

TL;DR

This paper formulates and analyzes a stochastic impulse control problem with non-smooth dynamics, partial observations, and execution delays, applying it to environmental restoration and deriving explicit solutions for optimal policies.

Contribution

It introduces a novel control framework for non-smooth stochastic systems with delays and partial observations, providing analytical and numerical solutions.

Findings

Optimal policies prevent undesirable states effectively.

Explicit solutions for the Fokker-Planck and optimality equations.

Execution delays significantly impact control strategies.

Abstract

Non-smooth dynamics driven by stochastic disturbance arise in a wide variety of engineering problems. Impulsive interventions are often employed to control stochastic systems; however, the modeling and analysis subject to execution delay have been less explored. In addition, continuously receiving information of the dynamics is not always possible. In this paper, with an application to an environmental restoration problem, a continuous-time stochastic impulse control problem subject to execution delay under discrete and random observations is newly formulated and analyzed. The dynamics have a non-smooth coefficient modulated by a Markov chain, and eventually attain an undesirable state like a depletion due to the non-smoothness. The goal of the control problem is to find the most cost-efficient policy that can prevent the dynamics from attaining the undesirable state. We demonstrate that finding the optimal policy reduces to solving a non-standard system of degenerate elliptic equations, the optimality equation, which is rigorously and analytically verified in a simplified case. The associated Fokker-Planck equation for the controlled dynamics is derived and solved explicitly as well. The model is finally applied to numerical computation of a recent river environmental restoration problem. The optimality and Fokker-Planck equations are successfully computed, and the optimal policy and the probability density functions are numerically obtained. The impacts of execution delay are discussed to deeper analyze the model.