Efficient Data-Driven Predictive Control of Nonlinear Chemical Processes using Reduced-Order Koopman Modeling

Incorporating physical knowledge into the Koopman modeling framework can enhance the accuracy and interpretability of the resulting models, leading to physics-enabled Koopman models. One approach to integrating physical knowledge is through the selection and construction of lifting functions based on known system dynamics. By incorporating domain-specific knowledge of the chemical reactions, mass and energy balances, and other fundamental principles governing the process, the lifting functions can be tailored to capture the underlying physics accurately. For instance, the selection of lifting functions can be guided by reaction kinetics, heat transfer mechanisms, and mass transfer phenomena specific to the chemical process. Additionally, constraints and relationships derived from physical laws can be incorporated into the model formulation to ensure that the Koopman model aligns with the known behavior of the system. By combining data-driven techniques with domain expertise, physics-enabled Koopman models can provide a more robust and reliable representation of the process dynamics.

The proposed reduced-order Koopman MPC approach can be adapted to handle processes with varying dynamics at different operating conditions by employing a hybrid modeling strategy. In scenarios where the process exhibits distinct behaviors under different operating conditions, multiple local Koopman models can be developed to capture the diverse dynamics. By partitioning the operating space into regions with similar dynamics, local Koopman models can be trained to represent the system behavior within each region. During operation, an adaptive control strategy can be implemented to switch between the local Koopman models based on the current operating conditions. This adaptive approach allows the control system to effectively handle the varying dynamics of the process and ensure optimal performance across different operating regimes. By combining the reduced-order Koopman modeling with adaptive control techniques, the system can adapt to changes in dynamics and maintain stable and efficient operation.

Beyond Proper Orthogonal Decomposition (POD), several other model reduction techniques can be explored to further enhance the computational efficiency of the Koopman-based predictive control scheme. Some alternative methods include: Balanced Truncation: This technique focuses on retaining the most relevant system dynamics while discarding less significant modes. By balancing controllability and observability, balanced truncation can lead to more efficient reduced-order models. Singular Value Decomposition (SVD): SVD can be used to identify dominant modes in the system and construct a reduced-order model based on these modes. By capturing the most influential dynamics, SVD can help streamline the control system design. Model Order Reduction via Krylov Subspace Methods: Krylov subspace methods, such as the Arnoldi algorithm, can be utilized to generate reduced-order models by projecting the system dynamics onto a lower-dimensional subspace. This approach can effectively reduce the computational complexity of the Koopman-based control scheme. System Identification Techniques: Leveraging system identification methods, such as AutoRegressive Moving Average (ARMA) modeling or state-space representation, can also aid in developing compact and efficient reduced-order models for predictive control applications. By fitting data-driven models to the system dynamics, these techniques can offer additional avenues for model reduction in the Koopman framework.