Compressible lattice Boltzmann methods with adaptive velocity stencils: An interpolation-free formulation
Autor: | Christophe Coreixas, Jonas Latt |
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Jazyk: | angličtina |
Rok vydání: | 2020 |
Předmět: |
Fluid Flow and Transfer Processes
Operability Discretization Computer science Mechanical Engineering Computational Mechanics Lattice Boltzmann methods FOS: Physical sciences Computational Physics (physics.comp-ph) Condensed Matter Physics Grid 01 natural sciences Compressible flow 010305 fluids & plasmas symbols.namesake Mach number Mechanics of Materials 0103 physical sciences symbols Compressibility Applied mathematics 010306 general physics Physics - Computational Physics Interpolation |
Popis: | Adaptive lattice Boltzmann methods (LBMs) are based on velocity discretizations that self-adjust to local macroscopic conditions such as velocity and temperature. While this feature improves the accuracy and the stability of LBMs for large velocity and temperature fluctuations, it also strongly impacts the efficiency of the algorithm due to space interpolations that are required to get populations at grid nodes. To avoid this defect, the present work proposes new formulations of adaptive LBMs for the simulation of compressible flows which do not rely anymore on space interpolations, hence, drastically improving their parallel efficiency for the simulation of high-speed compressible flows. To reach this goal, the adaptive phase discretization is restricted to particular states that are compliant with the efficient "collide and stream" algorithm, and as a consequence it does not require additional interpolation steps. The development of proper state-adaptive solvers with on-grid propagation imposes new restrictions and challenges on the discrete stencils, namely the need for an extended operability range allowing for the transition between two phase discretizations. Achieving the minimum operability range for discrete polynomial equilibria requires rather large stencils (e.g. D2Q81, D2Q121) and is therefore not competitive for compressible flow simulations. However, as shown in the article, the use of numerical equilibria can provide for overlaps in the operability ranges of neighboring discrete shifts at acceptable cost using the D2Q21 lattice. Through several numerical validations, the present approach is shown to allow for an efficient realization of discrete state-adaptive LBMs for high Mach number flows even in the low viscosity regime. Submitted for publication in Physics of Fluids |
Databáze: | OpenAIRE |
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