A tutorial overview of model predictive control for continuous crystallization: current possibilities and future perspectives
Abstract
This paper presents a systematic approach to the advanced control of continuous crystallization processes using model predictive control. We provide a tutorial introduction to controlling complex particle size distributions by integrating population balance equations with detailed models of various continuous crystallizers. Since these high-fidelity models are often too complex for online optimization, we propose the use of data-driven surrogate models that enable efficient optimization-based control. Through two case studies, one with a low-complexity system allowing direct comparison with traditional methods and another involving a spatially distributed crystallizer, we demonstrate how our approach enables real-time model predictive control while maintaining accuracy. The presented methodology facilitates the use of complex models in a model-based control framework, allowing precise control of key particle size distribution characteristics, such as the median particle size and the width . This addresses a critical challenge in pharmaceutical and fine chemical manufacturing, where product quality depends on tight control of particle characteristics.
Cite
@article{arxiv.2506.17146,
title = {A tutorial overview of model predictive control for continuous crystallization: current possibilities and future perspectives},
author = {Collin R. Johnson and Kerstin Wohlgemuth and Sergio Lucia},
journal= {arXiv preprint arXiv:2506.17146},
year = {2026}
}