Deep Koopman Economic Model Predictive Control of a Pasteurisation Unit

TL;DR

This paper introduces a deep Koopman operator-based economic model predictive control approach for a pasteurization unit, significantly improving prediction accuracy and reducing operational costs through neural network-learned linear dynamics.

Contribution

It develops a novel deep Koopman model for nonlinear system linearization, enabling efficient economic MPC with improved accuracy and cost savings over traditional methods.

Findings

45% improvement in open-loop prediction accuracy

32% reduction in total economic cost

10.2% less electrical energy consumption

Abstract

This paper presents a deep Koopman-based Economic Model Predictive Control (EMPC) for efficient operation of a laboratory-scale pasteurization unit (PU). The method uses Koopman operator theory to transform the complex, nonlinear system dynamics into a linear representation, enabling the application of convex optimization while representing the complex PU accurately. The deep Koopman model utilizes neural networks to learn the linear dynamics from experimental data, achieving a 45% improvement in open-loop prediction accuracy over conventional N4SID subspace identification. Both analyzed models were employed in the EMPC formulation that includes interpretable economic costs, such as energy consumption, material losses due to inadequate pasteurization, and actuator wear. The feasibility of EMPC is ensured using slack variables. The deep Koopman EMPC and N4SID EMPC are numerically validated on a nonlinear model of multivariable PU under external disturbance. The disturbances include feed pump fail-to-close scenario and the introduction of a cold batch to be pastuerized. These results demonstrate that the deep Koopmand EMPC achieves a 32% reduction in total economic cost compared to the N4SID baseline. This improvement is mainly due to the reductions in material losses and energy consumption. Furthermore, the steady-state operation via Koopman-based EMPC requires 10.2% less electrical energy. The results highlight the practical advantages of integrating deep Koopman representations with economic optimization to achieve resource-efficient control of thermal-intensive plants.