A Non-oscillatory Multi-Moment Finite Volume Scheme with Boundary Gradient Switching |
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Authors: | Xi Deng Ziyao Sun Bin Xie Kensuke Yokoi Chungang Chen Feng Xiao |
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Affiliation: | 1.Department of Mechanical Engineering,Tokyo Institute of Technology,Yokohama,Japan;2.School of Engineering,Cardiff University,Cardiff,UK;3.School of Human Settlement and Civil Engineering & State Key Laboratory for Strength and Vibration of Mechanical Structures,Xi’an Jiaotong University,Xi’an,China |
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Abstract: | In this work we propose a new formulation for high-order multi-moment constrained finite volume (MCV) method. In the one-dimensional building-block scheme, three local degrees of freedom (DOFs) are equidistantly defined within a grid cell. Two candidate polynomials for spatial reconstruction of third-order are built by adopting one additional constraint condition from the adjacent cells, i.e. the DOF at middle point of left or right neighbour. A boundary gradient switching (BGS) algorithm based on the variation-minimization principle is devised to determine the spatial reconstruction from the two candidates, so as to remove the spurious oscillations around the discontinuities. The resulted non-oscillatory MCV3-BGS scheme is of fourth-order accuracy and completely free of case-dependent ad hoc parameters. The widely used benchmark tests of one- and two-dimensional scalar and Euler hyperbolic conservation laws are solved to verify the performance of the proposed scheme in this paper. The MCV3-BGS scheme is very promising for the practical applications due to its accuracy, non-oscillatory feature and algorithmic simplicity. |
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