2011
DOI: 10.1002/fld.2532
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Implicit finite element schemes for the stationary compressible Euler equations

Abstract: SUMMARY A semi‐implicit finite element scheme and a Newton‐like solver are developed for the stationary compressible Euler equations. Since the Galerkin discretization of the inviscid fluxes is potentially oscillatory and unstable, the troublesome antidiffusive part is constrained within the framework of algebraic flux correction. A generalization of total variation diminishing (TVD) schemes is employed to blend the original Galerkin scheme with its nonoscillatory low‐order counterpart. Unlike standard TVD lim… Show more

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Cited by 29 publications
(17 citation statements)
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“…Hyperbolic solvers can be applied to the equations governing the gas phase, while scalar dissipation is feasible for the pressureless conservation laws of the particulate phase. The design of the artificial diffusion operator for the gas phase can be found in [4,2,9,18]. Therefore it remains to define the stabilization of the particulate phase.…”
Section: Discretizationmentioning
confidence: 99%
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“…Hyperbolic solvers can be applied to the equations governing the gas phase, while scalar dissipation is feasible for the pressureless conservation laws of the particulate phase. The design of the artificial diffusion operator for the gas phase can be found in [4,2,9,18]. Therefore it remains to define the stabilization of the particulate phase.…”
Section: Discretizationmentioning
confidence: 99%
“…which makes it possible to prescribe boundary conditions in a weak sense [9,18]. In our algorithm, the weak form of the Galerkin discretization (27) serves as the second-order scheme, while the stabilization is still based on (24).…”
Section: Second-order Schemementioning
confidence: 99%
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“…Their construction, e.g., in [18,16,17], is performed for transport equations and they are called flux-corrected transport (FCT) schemes (see also [7] for their application to compressible flows). These schemes can be used also for the discretization of time-dependent convection-diffusion equations, e.g., as in [4,11], where the convection-diffusion equations are part of population balance systems.…”
mentioning
confidence: 99%