Improved ALE mesh velocities for complex flows

Bakosi, József; Waltz, Jacob; Morgan, Nathaniel R.

doi:10.1002/fld.4403

Cited by 7 publications

(1 citation statement)

References 28 publications

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“…They only require information about the local Jacobians, and thus can be applied to meshes of any order (including linear meshes), element type, and dimension. The proposed methods can be applied to both monolithic ALE methods [19,20,21] to define their mesh velocity, and ALE methods that split the Lagrangian, mesh optimization and remap phases. They can also be applied to diffused interface methods, where ALE errors are decreased by shrinking the transition region of the volume fraction functions, or exact interface representation methods [22], where ALE errors can be decreased by obtaining better mesh resolution in the interface regions.…”

Section: Introductionmentioning

confidence: 99%

Simulation-Driven Optimization of High-Order Meshes in ALE Hydrodynamics

Dobrev,

Knupp,

Kolev

et al. 2020

Preprint

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In this paper we propose tools for high-order mesh optimization and demonstrate their benefits in the context of multi-material Arbitrary Lagrangian-Eulerian (ALE) compressible shock hydrodynamic applications. The mesh optimization process is driven by information provided by the simulation which uses the optimized mesh, such as shock positions, material regions, known error estimates, etc. These simulation features are usually represented discretely, for instance, as finite element functions on the Lagrangian mesh. The discrete nature of the input is critical for the practical applicability of the algorithms we propose and distinguishes this work from approaches that strictly require analytical information. Our methods are based on node movement through a high-order extension of the Target-Matrix Optimization Paradigm (TMOP) of [1]. The proposed formulation is fully algebraic and relies only on local Jacobian matrices, so it is applicable to all types of mesh elements, in 2D and 3D, and any order of the mesh. We discuss the notions of constructing adaptive target matrices and obtaining their derivatives, reconstructing discrete data in intermediate meshes, node limiting that enables improvement of global mesh quality while preserving space-dependent local mesh features, and appropriate normalization of the objective function. The adaptivity methods are combined with automatic ALE triggers that can provide robustness of the mesh evolution and avoid excessive remap procedures. The benefits of the new high-order TMOP technology are illustrated on several simulations performed in the high-order ALE application BLAST [2].

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