The content discusses the development of a novel limiting approach for discontinuous Galerkin (DG) methods to ensure that the solution remains continuously bounds-preserving. The key points are:
Typical limiting approaches in DG methods only guarantee bounds-preservation at discrete nodal locations, which is not sufficient for many applications where the solution needs to be evaluated at arbitrary locations.
The proposed approach extends the "squeeze" limiter of Zhang and Shu to continuously enforce general algebraic constraints on the high-order DG solution.
A modified formulation for the constraint functionals is introduced, which can guarantee a continuously bounds-preserving solution with only a single spatial minimization problem per element.
An efficient numerical optimization procedure is presented to solve the required minimization problem, although global convergence is not mathematically guaranteed due to the non-convexity of the problem.
The proposed approach is applied to high-order unstructured DG discretizations of hyperbolic conservation laws, ranging from scalar transport to compressible gas dynamics.
The key properties of the proposed scheme, including bounds-preservation and continuity, are rigorously proven.
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arxiv.org
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