Stabilized finite‐element computation of compressible flow with linear and quadratic interpolation functions

Kotteda, V. M. Krushnarao; Mittal, Sanjay

doi:10.1002/fld.3894

Cited by 11 publications

(20 citation statements)

References 40 publications

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“…Results are presented for the refined mesh driven by the subscales-based error estimation measured with the scaled L 2 −norm. This flow corresponds accurately to the referenced result in [34], so that, the approximation achieved by the subscales-driven AMR of the compressible flow solver is satisfactory.…”

Section: Differentially Heated Cavitysupporting

confidence: 64%

“…at the center of the element and/or at the nodes). Instead, the subscales at the element boundaries (34) are defined by the inter-element jump operator, and therefore, the contribution of neighbor elements must be accounted for. This type of calculation is inconvenient for parallel implementations of the AMR strategy, in which neighboring elements may be located on a different partition of the computational domain.…”

Section: Approximation For the Subscales At The Element Boundariesmentioning

confidence: 99%

“…Let us first explain how the boundary subscales are developed. Expanding (34) and writing it for each equation of the compressible problem, results in…”

Section: Approximation For the Subscales At The Element Boundariesmentioning

confidence: 99%

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Variational multiscale error estimators for the adaptive mesh refinement of compressible flow simulations

Bayona-Roa

Codina

Baiges

2018

Computer Methods in Applied Mechanics and Engineering

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This article investigates an explicit a-posteriori error estimator for the finite element approximation of the compressible Navier-Stokes equations. The proposed methodology employes the Variational Multi-Scale framework, and specifically, the idea is to use the variational subscales to estimate the error. These subscales are defined to be orthogonal to the finite element space, dynamic and non-linear, and both the subscales in the interior of the element and on the element boundaries are considered. Another particularity of the model is that we define some norms that lead to a dimensionally consistent measure of the compressible flow solution error inside each element; a scaled L 2 −norm, and the calculation of a physical entropy measure, are both studied in this work. The estimation of the error is used to drive the adaptive mesh refinement of several compressible flow simulations. Numerical results demonstrate good accuracy of the local error estimate and the ability to drive the adaptative mesh refinement to minimize the error through the computational domain.

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Section: Differentially Heated Cavitysupporting

confidence: 64%

Section: Approximation For the Subscales At The Element Boundariesmentioning

confidence: 99%

See 1 more Smart Citation

Variational multiscale error estimators for the adaptive mesh refinement of compressible flow simulations

Bayona-Roa

Codina

Baiges

2018

Computer Methods in Applied Mechanics and Engineering

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“…This type of shock capturing operator was introduced by Hughes and Mallet (1986) and later by Le Beau and Tezduyar (1991) into the SUPG compressible flow formulation. Mittal and Tezduyar (1998), Mittal (1998), Hughes et al (2010), and Kotteda and Mittal (2014) continued developing shock capturing stabilized formulations. In contrast with previous formulations (e.g.…”

Section: Multi-scale Finite Element Approximationmentioning

confidence: 99%

“…Adequate physical solutions are found using both the residual-based and the orthogonal projection-based shock capturing methods. Overshoots are smoothed according to the benchmarked solutions (Mittal and Tezduyar, 1998;Rispoli and Saavedra, 2006;Tezduyar and Senga, 2006;Kotteda and Multi-scale finite element approximation Mittal, 2014). Figure 8 shows the steady state contours for density and velocity magnitude solved with the anisotropic orthogonal projection-based shock capturing method and the mesh composed by P 2 elements.…”

Section: ¼ 29 Inviscid Shock Reflectionmentioning

confidence: 99%

Variational multi-scale finite element approximation of the compressible Navier-Stokes equations

Bayona-Roa

Baiges

Codina

2016

International Journal of Numerical Methods for Heat &Amp; Fluid Flow

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Purpose - The purpose of this paper is to apply the variational multi-scale framework to the finite element approximation of the compressible Navier-Stokes equations written in conservation form. Even though this formulation is relatively well known, some particular features that have been applied with great success in other flow problems are incorporated. \ud \ud Design/methodology/approach - The orthogonal subgrid scales, the non-linear tracking of these subscales, and their time evolution are applied. Moreover, a systematic way to design the matrix of algorithmic parameters from the perspective of a Fourier analysis is given, and the adjoint of the non-linear operator including the volumetric part of the convective term is defined. Because the subgrid stabilization method works in the streamline direction, an anisotropic shock capturing method that keeps the diffusion unaltered in the direction of the streamlines, but modifies the crosswind diffusion is implemented. The artificial shock capturing diffusivity is calculated by using the orthogonal projection onto the finite element space of the gradient of the solution, instead of the common residual definition. Temporal derivatives are integrated in an explicit fashion. \ud \ud Findings - Subsonic and supersonic numerical experiments show that including the orthogonal, dynamic, and the non-linear subscales improve the accuracy of the compressible formulation. The non-linearity introduced by the anisotropic shock capturing method has less effect in the convergence behavior to the steady state. \ud \ud Originality/value - A complete investigation of the stabilized formulation of the compressible problem is addressed.Peer ReviewedPostprint (author's final draft

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Finite Element Computation of Buzz Instability in Supersonic Air Intakes

Kotteda

Mittal

2016

Advances in Computational Fluid-Structure Interaction and Flow Simulation

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Stabilized finite‐element computation of compressible flow with linear and quadratic interpolation functions

Cited by 11 publications

References 40 publications

Variational multiscale error estimators for the adaptive mesh refinement of compressible flow simulations

Variational multiscale error estimators for the adaptive mesh refinement of compressible flow simulations

Variational multi-scale finite element approximation of the compressible Navier-Stokes equations

Finite Element Computation of Buzz Instability in Supersonic Air Intakes

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