Discrete-Time Approximations of Controlled Diffusions with Infinite Horizon Discounted and Average Cost
Abstract
We present discrete-time approximation of optimal control policies for infinite horizon discounted/ergodic control problems for controlled diffusions in \,. In particular, our objective is to show near optimality of optimal policies designed from the approximating discrete-time controlled Markov chain model, for the discounted/ergodic optimal control problems, in the true controlled diffusion model (as the sampling period approaches zero). To this end, we first construct suitable discrete-time controlled Markov chain models for which one can compute optimal policies and optimal values via several methods (such as value iteration, convex analytic method, reinforcement learning etc.). Then using a weak convergence technique, we show that the optimal policy designed for the discrete-time Markov chain model is near-optimal for the controlled diffusion model as the discrete-time model approaches the continuous-time model. This provides a practical approach for finding near-optimal control policies for controlled diffusions. Our conditions complement existing results in the literature, which have been arrived at via either probabilistic or PDE based methods.
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