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Truncation errors and modified equations for the lattice Boltzmann method<i>via</i>the corresponding Finite Difference schemes

Thomas Bellotti

2023ESAIM. Mathematical modelling and numerical analysis21 citationsDOIOpen Access PDF

Abstract

Lattice Boltzmann schemes are efficient numerical methods to solve a broad range of problems under the form of conservation laws. However, they suffer from a chronic lack of clear theoretical foundations. In particular, the consistency analysis and the derivation of the modified equations are still open issues. This has prevented, until today, to have an analogous of the Lax equivalence theorem for lattice Boltzmann schemes. We propose a rigorous consistency study and the derivation of the modified equations for any lattice Boltzmann scheme under acoustic and diffusive scalings. This is done by passing from a kinetic (lattice Boltzmann) to a macroscopic (Finite Difference) point of view at a fully discrete level in order to eliminate the non-conserved moments relaxing away from the equilibrium. We rewrite the lattice Boltzmann scheme as a multi-step Finite Difference scheme on the conserved variables, as introduced in our previous contribution. We then perform the usual analyses for Finite Difference by exploiting its precise characterization using matrices of Finite Difference operators. Though we present the derivation of the modified equations until second-order under acoustic scaling, we provide all the elements to extend it to higher orders, since the kinetic-macroscopic connection is conducted at the fully discrete level. Finally, we show that our strategy yields, in a more rigorous setting, the same results as previous works in the literature.

Topics & Concepts

Lattice Boltzmann methodsMathematicsFinite differenceBhatnagar–Gross–Krook operatorHPP modelBoltzmann equationLattice gas automatonBoltzmann constantLattice (music)Conservation lawApplied mathematicsScalingStatistical physicsMathematical analysisPhysicsQuantum mechanicsDirect simulation Monte CarloAlgorithmDynamic Monte Carlo methodGeometryStatisticsAcousticsThermodynamicsReynolds numberStochastic cellular automatonMonte Carlo methodTurbulenceCellular automatonLattice Boltzmann Simulation StudiesAerosol Filtration and Electrostatic PrecipitationAerodynamics and Fluid Dynamics Research
Truncation errors and modified equations for the lattice Boltzmann method<i>via</i>the corresponding Finite Difference schemes | Litcius