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Multifidelity computing for coupling full and reduced order models

Shady E. Ahmed, Omer San, Kursat Kara, Rami M. Younis, Adil Rasheed

2021PLoS ONE26 citationsDOIOpen Access PDF

Abstract

Hybrid physics-machine learning models are increasingly being used in simulations of transport processes. Many complex multiphysics systems relevant to scientific and engineering applications include multiple spatiotemporal scales and comprise a multifidelity problem sharing an interface between various formulations or heterogeneous computational entities. To this end, we present a robust hybrid analysis and modeling approach combining a physics-based full order model (FOM) and a data-driven reduced order model (ROM) to form the building blocks of an integrated approach among mixed fidelity descriptions toward predictive digital twin technologies. At the interface, we introduce a long short-term memory network to bridge these high and low-fidelity models in various forms of interfacial error correction or prolongation. The proposed interface learning approaches are tested as a new way to address ROM-FOM coupling problems solving nonlinear advection-diffusion flow situations with a bifidelity setup that captures the essence of a broad class of transport processes.

Topics & Concepts

MultiphysicsInterface (matter)Computer scienceCoupling (piping)FidelityHigh fidelityNonlinear systemComputational scienceDistributed computingFinite element methodPhysicsMechanical engineeringParallel computingEngineeringMaximum bubble pressure methodQuantum mechanicsAcousticsTelecommunicationsThermodynamicsBubbleModel Reduction and Neural NetworksFluid Dynamics and Vibration AnalysisFluid Dynamics and Turbulent Flows
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