Towards computable flows and robust estimates for inf-sup stable FEM applied to the time-dependent incompressible Navier–Stokes equations

Schroeder, Philipp W.; Lehrenfeld, Christoph; Linke, Alexander; Lube, Gert

doi:10.1007/s40324-018-0157-1

Cited by 54 publications

(52 citation statements)

References 61 publications

(157 reference statements)

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“…Finite element error analysis for the L 2 -DG method can be found, for example, in [56,24]. For the H(div)-DG method, we refer to [60]. In the DG setting, discretely divergence-free functions are defined using the pressure-velocity coupling b h by…”

Section: Dg Formulationmentioning

confidence: 99%

“…Thus, pressure-robustness appears to be a prerequisite for accurate incompressible flow solvers at high Reynolds numbers. The arguments are supported by numerical analysis and numerical experiments.Indeed, the lack of pressure-robustness has been a rather hot research topic in the beginning of the history of finite element methods for CFD [55,31,62,38,25,35] -sometimes called poor mass conservation -and continued to be investigated for many years [33,57,34,60], often in connection with the so-called grad-div stabilisation [32,54,17,40,3,22]. Also, in the geophysical fluid dynamics community and in numerical astrophysics well-balanced schemes have been proposed to overcome similar issues for related Euler and shallow-water equations, especially in connection to nearly-hydrostatic and nearly-geostrophic flows; cf., for example, [20,21,11,44].However, only recently it was understood better that exactly the relaxation of the divergence constraint for incompressible flows, which was invented in classical mixed methods in order to construct discretely inf-sup stable discretisation schemes, introduces the lack of pressure-robustness, since it leads to a poor discretisation of the Helmholtz-Hodge projector [49].…”

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confidence: 99%

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On high-order pressure-robust space discretisations, their advantages for incompressible high Reynolds number generalised Beltrami flows and beyond

Gauger¹,

Linke²,

Schroeder³

2019

The SMAI Journal of Computational Mathematics

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An improved understanding of the divergence-free constraint for the incompressible Navier-Stokes equations leads to the observation that a semi-norm and corresponding equivalence classes of forces are fundamental for their nonlinear dynamics. The recent concept of pressure-robustness allows to distinguish between space discretisations that discretise these equivalence classes appropriately or not. This contribution compares the accuracy of pressure-robust and non-pressure-robust space discretisations for transient high Reynolds number flows, starting from the observation that in generalised Beltrami flows the nonlinear convection term is balanced by a strong pressure gradient. Then, pressurerobust methods are shown to outperform comparable non-pressure-robust space discretisations. Indeed, pressure-robust methods of formal order k are comparably accurate than non-pressure-robust methods of formal order 2k on coarse meshes. Investigating the material derivative of incompressible Euler flows, it is conjectured that strong pressure gradients are typical for non-trivial high Reynolds number flows. Connections to vortex-dominated flows are established. Thus, pressure-robustness appears to be a prerequisite for accurate incompressible flow solvers at high Reynolds numbers. The arguments are supported by numerical analysis and numerical experiments.Indeed, the lack of pressure-robustness has been a rather hot research topic in the beginning of the history of finite element methods for CFD [55,31,62,38,25,35] -sometimes called poor mass conservation -and continued to be investigated for many years [33,57,34,60], often in connection with the so-called grad-div stabilisation [32,54,17,40,3,22]. Also, in the geophysical fluid dynamics community and in numerical astrophysics well-balanced schemes have been proposed to overcome similar issues for related Euler and shallow-water equations, especially in connection to nearly-hydrostatic and nearly-geostrophic flows; cf., for example, [20,21,11,44].However, only recently it was understood better that exactly the relaxation of the divergence constraint for incompressible flows, which was invented in classical mixed methods in order to construct discretely inf-sup stable discretisation schemes, introduces the lack of pressure-robustness, since it leads to a poor discretisation of the Helmholtz-Hodge projector [49]. The reason is that the relaxation of the divergence constraint implies a relaxation of the L 2 -orthogonality between discretely divergence-free velocity test functions and arbitrary gradient fields. PRESSURE-ROBUSTNESS, HIGH REYNOLDS NUMBERS, BELTRAMI FLOWSWe only briefly remark that the question of an appropriate discretisation of the nonlinear convection term is intimately connected to the issue of numerical convection stabilisation techniques like upwinding or SUPG [56,14]. With the help of generalised Beltrami flows, we will demonstrate that in real-world flows the nonlinear convection term can be strong, even if the dynamics of the flow is not convectiondominated ...

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Section: Dg Formulationmentioning

confidence: 99%

mentioning

confidence: 99%

On high-order pressure-robust space discretisations, their advantages for incompressible high Reynolds number generalised Beltrami flows and beyond

Gauger¹,

Linke²,

Schroeder³

2019

The SMAI Journal of Computational Mathematics

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“…Remark 5 in [30]. We choose this method as it -compared to other standard discretization approachescombines features such as high order accuracy, important global and local conservation properties, energystability, polynomial, pressure and Re-semi-robustness, a minimal amount of numerical dissipation and computational efficiency [30,29,42]. Especially the combination of the robustness properties is hardly seen in other numerical discretization schemes.…”

Section: Space Discretizationmentioning

confidence: 99%

On reference solutions and the sensitivity of the 2D Kelvin–Helmholtz instability problem

Schroeder¹,

John²,

Lederer³

et al. 2019

Computers & Mathematics with Applications

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Two-dimensional Kelvin-Helmholtz instability problems are popular examples for assessing discretizations for incompressible flows at high Reynolds number. Unfortunately, the results in the literature differ considerably. This paper presents computational studies of a Kelvin-Helmholtz instability problem with high order divergence-free finite element methods. Reference results in several quantities of interest are obtained for three different Reynolds numbers up to the beginning of the final vortex pairing. A meshindependent prediction of the final pairing is not achieved due to the sensitivity of the considered problem with respect to small perturbations. A theoretical explanation of this sensitivity to small perturbations is provided based on the theory of self-organization of 2D turbulence. Possible sources of perturbations that arise in almost any numerical simulation are discussed.

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“…The resulting spatial discretisation has several benefits such as energy stability and pressure robustness [25,26] while allowing for efficient and high order accurate implementations [24,27].…”

Section: High-order Exactly Divergence-free Hybrid Discontinuous Galmentioning

confidence: 99%

Numerical benchmarking of fluid-rigid body interactions

et al. 2019

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We propose a fluid-rigid body interaction benchmark problem, consisting of a solid spherical obstacle in a Newtonian fluid, whose centre of mass is fixed but is free to rotate. A number of different problems are defined for both two and three spatial dimensions. The geometry is chosen specifically, such that the fluid-solid partition does not change over time and classical fluid solvers are able to solve the fluid-structure interaction problem. We summarise the different approaches used to handle the fluid-solid coupling and numerical methods used to solve the arising problems. The results obtained by the described methods are presented and we give reference intervals for the relevant quantities of interest.

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Towards computable flows and robust estimates for inf-sup stable FEM applied to the time-dependent incompressible Navier–Stokes equations

Cited by 54 publications

References 61 publications

On high-order pressure-robust space discretisations, their advantages for incompressible high Reynolds number generalised Beltrami flows and beyond

On high-order pressure-robust space discretisations, their advantages for incompressible high Reynolds number generalised Beltrami flows and beyond

On reference solutions and the sensitivity of the 2D Kelvin–Helmholtz instability problem

Numerical benchmarking of fluid-rigid body interactions

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