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arxiv: 2410.21583 · v1 · pith:OTJRJNCHnew · submitted 2024-10-28 · 🧮 math.NA · cs.NA· physics.comp-ph· physics.flu-dyn

Scalable physics-guided data-driven component model reduction for steady Navier-Stokes flow

classification 🧮 math.NA cs.NAphysics.comp-phphysics.flu-dyn
keywords scalescomponentflowlargeapplicationchallengecromindustry
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Computational physics simulation can be a powerful tool to accelerate industry deployment of new scientific technologies. However, it must address the challenge of computationally tractable, moderately accurate prediction at large industry scales, and training a model without data at such large scales. A recently proposed component reduced order modeling (CROM) tackles this challenge by combining reduced order modeling (ROM) with discontinuous Galerkin domain decomposition (DG-DD). While it can build a component ROM at small scales that can be assembled into a large scale system, its application is limited to linear physics equations. In this work, we extend CROM to nonlinear steady Navier-Stokes flow equation. Nonlinear advection term is evaluated via tensorial approach or empirical quadrature procedure. Application to flow past an array of objects at moderate Reynolds number demonstrates $\sim23.7$ times faster solutions with a relative error of $\sim 2.3\%$, even at scales $256$ times larger than the original problem.

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