Extensive analysis of the lattice Boltzmann method on shifted stencils

Hosseini, Seyed Ali; Coreixas, Christophe; Darabiha, Nasser; Thévenin, Dominique

doi:10.1103/physreve.100.063301

Cited by 32 publications

(27 citation statements)

References 70 publications

(115 reference statements)

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“…A stability analysis [64,65] could clarify the exact limits of the scheme. An obvious way to further increase the Mach number is to incorporate statically shifted [22,66] or dynamically shifted lattices [25]. Future works should thoroughly investigate the path to extend the velocity sets to higher velocities in three dimensions, while keeping the number of discrete velocities lower than 125.…”

Section: Discussionmentioning

confidence: 99%

Semi-Lagrangian lattice Boltzmann method for compressible flows

et al. 2020

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This work thoroughly investigates a semi-Lagrangian lattice Boltzmann (SLLBM) solver for compressible flows. In contrast to other LBM for compressible flows, the vertices are organized in cells, and interpolation polynomials up to fourth order are used to attain the off-vertex distribution function values. Differing from the recently introduced Particles on Demand (PoD) method [Dorschner, Bösch, and Karlin, Phys. Rev. Lett. 121, 130602 (2018)], the method operates in a static, nonmoving reference frame. Yet the SLLBM in the present formulation grants supersonic flows and exhibits a high degree of Galilean invariance. The SLLBM solver allows for an independent time step size due to the integration along characteristics and for the use of unusual velocity sets, like the D2Q25, which is constructed by the roots of the fifth-order Hermite polynomial. The properties of the present model are shown in diverse example simulations of a two-dimensional Taylor-Green vortex, a Sod shock tube, a two-dimensional Riemann problem, and a shock-vortex interaction. It is shown that the cell-based interpolation and the use of Gauss-Lobatto-Chebyshev support points allow for spatially high-order solutions and minimize the mass loss caused by the interpolation. Transformed grids in the shock-vortex interaction show the general applicability to nonuniform grids.

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Section: Discussionmentioning

confidence: 99%

Semi-Lagrangian lattice Boltzmann method for compressible flows

et al. 2020

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“…Hence, the above equilibrium states do recover some of the third- and fourth-order moments of the Maxwell–Boltzmann distribution. While fourth-order equilibrium moments do not have any impact on the isothermal macroscopic behaviour (but only on the numerical stability [11,12,76,78]), third-order ones are required to recover the correct viscous stress tensor [see equation (2.2)]. Indeed, considering the standard second-order equilibrium [by imposing Mpqeq=0 for p + q ≥ 3 in equation (2.9)], macroscopic errors related to the viscous stress tensor ΔΠ pq are normalΔΠ20=∂xfalse(M30eqfalse)+∂yfalse(M21eqfalse), normalΔΠ11=∂xfalse(M21eqfalse)+∂yfalse(M12eqfalse)2emand2emnormalΔΠ02=∂xfalse(M12eqfalse)+∂yfalse(M03eq<...>…”

Section: Discrete Equilibrium and Macroscopic Behaviourmentioning

confidence: 99%

“…Later, several authors performed LSA of the LBM, which significantly improved the understanding of its numerical properties and stability limits [8,9,16,60,67,68,75,102]. In addition, a number of works investigated the behaviour of collision models operating in a particular moment space (raw [8,61,70], Hermite [9,16,64], central [70,72] and central Hermite [77]) or based on a regularization step [11,76–78]. These studies were usually presented in their own framework, and using different methodologies, which prevents any general comparison of the results obtained for each collision model.…”

Section: Linear Stability Analyses Of the Discrete Velocity Boltzmann Equationmentioning

confidence: 99%

“…Interestingly, this upper stability limit can be shown to depend on both the lattice and the type of equilibrium (polynomial, entropic, etc.). In addition, it does not seem to be impacted by either the collision model [11,12,76], or the numerical discretization [74].

Figure 4Mach number (Ma) corresponding to the linear stability limit of the D2Q9-BGK-DVBE, for various angles ϕ of the mean flow and ν = 10 −6 .…”

Section: Linear Stability Analyses Of the Discrete Velocity Boltzmann Equationmentioning

confidence: 99%

“…In fact, by adopting a different type of equilibrium, e.g. the entropic formulation obtained by minimizing the H-functional under the constraint of density and momentum conservation [134], this limitation could be alleviated but at the cost of part of the physics [76]. To improve both the physical and numerical properties of LBMs, one could include correction terms for the velocity-dependent errors that remain in the definition of the viscous stress tensor [26,47,77,85,92–95].…”

Section: Further Investigationsmentioning

confidence: 99%

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Impact of collision models on the physical properties and the stability of lattice Boltzmann methods

Coreixas

Wissocq

Chopard

et al. 2020

Phil. Trans. R. Soc. A.

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The lattice Boltzmann method (LBM) is known to suffer from stability issues when the collision model relies on the BGK approximation, especially in the zero viscosity limit and for non-vanishing Mach numbers. To tackle this problem, two kinds of solutions were proposed in the literature. They consist in changing either the numerical discretization (finite-volume, finite-difference, spectral-element, etc.) of the discrete velocity Boltzmann equation (DVBE), or the collision model. In this work, the latter solution is investigated in detail. More precisely, we propose a comprehensive comparison of (static relaxation time based) collision models, in terms of stability, and with preliminary results on their accuracy, for the simulation of isothermal high-Reynolds number flows in the (weakly) compressible regime. It starts by investigating the possible impact of collision models on the macroscopic behaviour of stream-and-collide based D2Q9-LBMs, which clarifies the exact physical properties of collision models on LBMs. It is followed by extensive linear and numerical stability analyses, supplemented with an accuracy study based on the transport of vortical structures over long distances. In order to draw conclusions as generally as possible, the most common moment spaces (raw, central, Hermite, central Hermite and cumulant), as well as regularized approaches, are considered for the comparative studies. LBMs based on dynamic collision mechanisms (entropic collision, subgrid-scale models, explicit filtering, etc.) are also briefly discussed. This article is part of the theme issue ‘Fluid dynamics, soft matter and complex systems: recent results and new methods’.

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