Accession Number : AD1042881


Title :   A Moving Discontinuous Galerkin Finite Element Method for Flows with Interfaces


Descriptive Note : Technical Report


Corporate Author : NAVAL RESEARCH LAB WASHINGTON DC WASHINGTON United States


Personal Author(s) : Corrigan,Andrew T ; Kercher,Andrew D ; Kessler,David A


Full Text : https://apps.dtic.mil/dtic/tr/fulltext/u2/1042881.pdf


Report Date : 07 Dec 2017


Pagination or Media Count : 43


Abstract : A moving discontinuous Galerkin finite element method with interface condition enforcement (MDG-ICE) is formulated for flows with discontinuous interfaces. The underlying weak formulation enforces the interface condition separately from the conservation law, so that the residual only vanishes upon satisfaction of both, while treating the discrete grid geometry as a variable. In contrast to the standard discontinuous Galerkin (DG) method, this method has both the means to detect, via interface condition enforcement, and satisfy, via grid movement, the conservation law and its associated interface condition. The method therefore directly fits interfaces, including shocks, preserving a high-order representation up to the interface, without requiring shock capturing or an upwind numerical flux to achieve stability. It can be generalized to flows with a-priori unknown interfaces with non-trivial topology and curved interface geometry as well as to an arbitrary number of spatial dimensions. Unsteady flows are represented in a manner similar to steady flows using a spacetime formulation. In addition to computing flows with interfaces, the method can represent point singularities in a flow field by degenerating cuboid elements. In general, the method works in conjunction with standard local grid operations, including edge collapse, to ensure that degenerate cells are removed. Test cases are presented for up to three-dimensional flows that provide an initial assessment of the stability and accuracy of the method.


Descriptors :   galerkin method , FINITE ELEMENT ANALYSIS , unsteady flow , flow fields , SHOCK TUBES , bow shock , steady flow , computational fluid dynamics , INVISCID FLOW , topology


Subject Categories : Fluid Mechanics


Distribution Statement : APPROVED FOR PUBLIC RELEASE