Journal
SIAM JOURNAL ON NUMERICAL ANALYSIS
Volume 47, Issue 1, Pages 622-645Publisher
SIAM PUBLICATIONS
DOI: 10.1137/060656164
Keywords
large eddy simulation; turbulence; artificial viscosity; Smagorinsky model
Categories
Funding
- AFOSR [F49620-00-1-0299, F49620-03-1-0243, FA9550-05-1-0449]
- NSF [DMS-0322852, DMS-0513542, DMS-0209309]
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In this paper, we present a rigorous numerical analysis for a bounded artificial viscosity model (tau = mu delta(sigma)a(delta parallel to del(s)u parallel to(F))del(s)u) for the numerical simulation of turbulent flows. In practice, the commonly used Smagorinsky model (tau= (c(s)delta)(2)parallel to del(s)u parallel to(F)del(s)u) is overly dissipative and yields unphysical results. To date, several methods for clipping the Smagorinsky viscosity have proven useful in improving the physical characteristics of the simulated flow. However, such heuristic strategies strongly rely upon a priori knowledge of the flow regime. The bounded artificial viscosity model relies on a highly nonlinear, but monotone and smooth, semilinear elliptic form for the artificial viscosity. For this model, we have introduced a variational computational strategy, provided finite element error convergence estimates, and included several computational examples indicating its improvement on the overly diffusive Smagorinsky model.
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