Decentralized control using selectors for optimal steady-state operation with changing active constraints

• Published in: Journal of process control Vol. 137; p. 103194
• Main Authors: Bernardino, Lucas Ferreira, Skogestad, Sigurd
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.05.2024
• Subjects: Decentralized control; Optimal operation; Selectors; Decentralized control; Selectors; Optimal operation
• ISSN: 0959-1524
• DOI: 10.1016/j.jprocont.2024.103194

We study the optimal steady-state operation of processes where the active constraints change. The aim of this work is to eliminate or reduce the need for a real-time optimization layer, moving the optimization into the control layer by switching between appropriately selected controlled variables (CVs) in a simple way. The challenge is that the best CVs, or more precisely the reduced cost gradients associated with the unconstrained degrees of freedom, change with the active constraints. This work proposes a framework based on decentralized control that operates optimally in all active constraint regions, with region switching mediated by selectors. A key point is that the nullspace associated with the unconstrained cost gradient needs to be selected in accordance with the constraint directions so that selectors can be used. A main benefit is that the number of SISO controllers that need to be designed is only equal to the number of process inputs plus constraints. The main assumptions are that the unconstrained cost gradient is available online and that the number of constraints does not exceed the number of process inputs. The optimality and ease of implementation are illustrated in a simulated toy example with linear constraints and a quadratic cost function. In addition, the proposed framework is successfully applied to the nonlinear Williams–Otto reactor case study. •A simple decentralized control framework for optimal operation is proposed.•Framework is optimal for systems with fewer constraints than inputs.•Optimal operation of multivariable systems using feedback control and selectors.