Data-Driven Model Order Reduction for Continuous- and Discrete-Time Nonlinear Systems

Model order reduction simplifies high-dimensional dynamical systems by deriving lower-dimensional models that preserve essential system characteristics. These techniques are crucial to controller design for complex systems while significantly reducing computational costs. Nevertheless, constructing effective reduced-order models (ROMs) poses considerable challenges, particularly for dynamical systems characterized by highly nonlinear terms. These challenges are further exacerbated when the actual system model is unavailable, a scenario frequently encountered in real-world applications. In this work, we propose a data-driven framework for the construction of ROMs for both continuous- and discrete-time nonlinear dynamical systems with unknown mathematical models. By leveraging two sets of data collected from the system, referred to as two input-state trajectories, we first construct a data-based closed-loop representation of the system. We then establish a similarity relation between the output trajectories of the original system and those of its data-driven ROM employing the notion of simulation functions (SFs), thereby enabling a formal characterization of their closeness. To achieve this, we propose data-dependent semidefinite programs as sufficient conditions to simultaneously construct both ROMs and SFs, while offering correctness guarantees. We demonstrate that the obtained data-driven ROMs can be employed for synthesizing controllers that ensure the unknown system satisfies high-level logic properties. This is accomplished by first designing controllers for the data-driven ROMs and then translating the results back to the original system through an interface function. We evaluate the efficacy of our data-driven findings through four benchmark case studies involving unknown dynamics with highly nonlinear terms.