A New Adaptive Deep Learning based Reduced Order Model for Hybrid-Type Parabolic PDEs: Rigorous Error Analysis and Applications

TL;DR

This paper introduces adaptive deep learning surrogate models based on Deep Orthogonal Decomposition for parameterized parabolic PDEs, providing rigorous error analysis and demonstrating efficiency on industrial benchmark problems.

Contribution

It extends the DOD method to time-dependent problems, introduces two novel adaptive deep learning models, and establishes theoretical links between performance and problem regularity.

Findings

The DOD-based models outperform traditional POD in hybrid-type problems.

Theoretical analysis links model performance to the regularity of an optimal map.

Demonstrated effectiveness on a catalyst filter benchmark problem.

Abstract

This contribution proposes novel data-driven surrogate modeling approaches for parameterized parabolic PDEs, where the parameter dependence can be split into two parts with different decay behavior of the Kolmogorov $N$-width. Such problems naturally arise in many industrial flow processes with dominant advection or traveling fronts in the solution trajectories. To tackle this challenge, we extend the Deep Orthogonal Decomposition (DOD) method, recently introduced for related stationary problems, to the time-dependent setting. We introduce and rigorously analyze two DOD based approaches: Our approach is based on two novel adaptive deep learning-based surrogate models: The DOD-DL-ROM method which is a Reduced Order Model (ROM) that leverages the adaptive nature of DOD, and the DOD+DFNN method, which combines DOD with a generic Deep Feed-Forward Neural Network (DFNN). On the theory side, we generalize data-driven POD-based ROM arguments to the DOD setting, establishing a quantitative link between online performance and the regularity of an associated optimal map. Furthermore, we identify specific problem size and error tolerance requirements for DOD-based ROMs to outperform POD-based ROMs in hybrid-type problem classes, which is crucial for efficient computation. The significance of this work lies in its potential to accelerate the solution of complex PDEs, enabling faster design and optimization of industrial processes. The proposed approaches are demonstrated on a catalyst filter benchmark problem, showcasing their effectiveness and comparing favorably to traditional POD-based methods.