Abstract
In this work, a nonlinear model predictive controller is developed for a batch polymerization process. The physical model of the process is parameterized along a desired trajectory resulting in a trajectory linearized piecewise model (a multiple linear model bank) and the parameters are identified for an experimental polymerization reactor. Then, a multiple model adaptive predictive controller is designed for thermal trajectory tracking of the MMA polymerization. The input control signal to the process is constrained by the maximum thermal power provided by the heaters. The constrained optimization in the model predictive controller is solved via genetic algorithms to minimize a DMC cost function in each sampling interval.
Highlights
Model predictive control (MPC), is a model based on advanced process control (APC) technique that has been proved to be very successful in controlling highly complex dynamic systems
This paper presents a constrained model predictive control of an MMA reactor, based on the genetic algorithm optimization
The population is the foundation of evolution of a genetic algorithm
Summary
Model predictive control (MPC), is a model based on advanced process control (APC) technique that has been proved to be very successful in controlling highly complex dynamic systems. When there are constraints over the control inputs (i.e. actuators) and/or process states, which is often the case, an online (i.e. real-time) constrained optimization problem has to be solved in each sampling interval, even if the plant model is linear and time invariant. This online optimization usually requires a high computational power; since chemical processes are typically of slow dynamics, such controllers have been designed and implemented on various chemical plants with great success. Due to recent advancements of computational hardware and software tools, the usage of MPC is rapidly expanding to other control domains including electrical machines, renewable energy, aerospace and automotive control systems
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