Abstract
In this effort we propose a data-driven learning framework for reduced order modeling of fluid dynamics. Designing accurate and efficient reduced order models for nonlinear fluid dynamic problems is challenging for many practical engineering applications. Classical projection-based model reduction methods generate reduced systems by projecting full-order differential operators into low-dimensional subspaces. However, these techniques usually lead to severe instabilities in the presence of highly nonlinear dynamics, which dramatically deteriorates the accuracy of the reduced-order models. In contrast, our new framework exploits linear multistep networks, based on implicit Adams–Moulton schemes, to construct the reduced system. The advantage is that the method optimally approximates the full order model in the low-dimensional space with a given supervised learning task. Moreover, our approach is non-intrusive, such that it can be applied to other complex nonlinear dynamical systems with sophisticated legacy codes. We demonstrate the performance of our method through the numerical simulation of a two-dimensional flow past a circular cylinder with Reynolds number Re = 100. The results reveal that the new data-driven model is significantly more accurate than standard projection-based approaches.
Highlights
The full order model (FOM) of realistic engineering applications in fluid dynamics often represents a large scale dynamic system
Balajewicz [15] studied the application of low dimensional modelling of shear flows; Ballarin [16] applied the proper orthogonal decomposition (POD)-Galerin to the parametrized steady incompressible Navier–Stokes equations (NSE); Xie [17] introduced filtered reduced order model (ROM) method for
Our viewpoint enables us to answer the common question—what is the best ROM dynamic system to approximate the full system for a given low-dimensional subspace? We demonstrate the performance of the new linear multistep neural network (LMNet)-ROM is better than
Summary
The full order model (FOM) of realistic engineering applications in fluid dynamics often represents a large scale dynamic system. The GP-ROM, in an offline stage, first constructs a reduced space and uses the Galerkin projection of the FOM operator to obtain a low-dimensional nonlinear dynamical system, i.e., ROM dynamics. The projection step requires that the full model operators have to be available in order to obtain the ROM dynamics This limits the applicability of projection based model reduction in situations where the full model is unknown [10,11]. For this reason, the GP-ROM are efficient for problems where the reduced operators must be constructed only once. Balajewicz [15] studied the application of low dimensional modelling of shear flows; Ballarin [16] applied the POD-Galerin to the parametrized steady incompressible Navier–Stokes equations (NSE); Xie [17] introduced filtered ROM method for
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