English

Machine learning-based input-augmented Koopman modeling and predictive control of nonlinear processes

Systems and Control 2024-08-06 v1 Systems and Control

Abstract

Koopman-based modeling and model predictive control have been a promising alternative for optimal control of nonlinear processes. Good Koopman modeling performance significantly depends on an appropriate nonlinear mapping from the original state-space to a lifted state space. In this work, we propose an input-augmented Koopman modeling and model predictive control approach. Both the states and the known inputs are lifted using two deep neural networks (DNNs), and a Koopman model with nonlinearity in inputs is trained within the higher-dimensional state-space. A Koopman-based model predictive control problem is formulated. To bypass non-convex optimization induced by the nonlinearity in the Koopman model, we further present an iterative implementation algorithm, which approximates the optimal control input via solving a convex optimization problem iteratively. The proposed method is applied to a chemical process and a biological water treatment process via simulations. The efficacy and advantages of the proposed modeling and control approach are demonstrated.

Keywords

Cite

@article{arxiv.2408.02315,
  title  = {Machine learning-based input-augmented Koopman modeling and predictive control of nonlinear processes},
  author = {Zhaoyang Li and Minghao Han and Dat-Nguyen Vo and Xunyuan Yin},
  journal= {arXiv preprint arXiv:2408.02315},
  year   = {2024}
}
R2 v1 2026-06-28T18:03:59.161Z