Optimal Drift Rate Control and Impulse Control for a Stochastic Inventory/Production System

Abstract

In this paper, we consider joint drift rate control and impulse control for a stochastic inventory system under long-run average cost criterion. Assuming the inventory level must be nonnegative, we prove that a \(0,q,Q,S),\μ(x): x∈[0, S]\\ policy is an optimal joint control policy, where the impulse control follows the control band policy (0,q,Q,S), that brings the inventory level up to q once it drops to 0 and brings it down to Q once it rises to S, and the drift rate only depends on the current inventory level and is given by function μ(x) for the inventory level x∈[0,S]. The optimality of the \(0,q,Q,S),\μ(x): x∈[0,S]\\ policy is proven by using a lower bound approach, in which a critical step is to prove the existence and uniqueness of optimal policy parameters. To prove the existence and uniqueness, we develop a novel analytical method to solve a free boundary problem consisting of an ordinary differential equation (ODE) and several free boundary conditions. Furthermore, we find that the optimal drift rate μ(x) is firstly increasing and then decreasing as x increases from 0 to S with a turnover point between Q and S.