Resumen

DE PAULA, M.  y  MARTINEZ, E.C.. Reinforcement learning using gaussian processes for discretely controlled continuous processes. Lat. Am. appl. res. [online]. 2013, vol.43, n.3, pp. 249-259. ISSN 1851-8796.

In many application domains such as autonomous avionics, power electronics and process systems engineering there exist discretely controlled continuous processes (DCCPs) which constitute a special subclass of hybrid dynamical systems. We introduce a novel simulation-based approach for DDCPs optimization under uncertainty using Reinforcement Learning with Gaussian Process models to learn the transitions dynamics descriptive of mode execution and an optimal switching policy for mode selection. Each mode implements a parameterized feedback control law until a stopping condition triggers. To deal with the size/dimension of the state space and a continuum of control mode parameters, Bayesian active learning is proposed using a utility function that trades off information content with policy improvement. Throughput maximization in a buffer tank subject to an uncertain schedule of several inflow discharges is used as case study addressing supply chain control in manufacturing systems.

Palabras llave : Hybrid Systems; Stochastic Systems; Optimization; Reinforcement Learning; Gaussian Processes.