Superconvergence and the Numerical Flux: a Study Using the Upwind-Biased Flux in Discontinuous Galerkin Methods

doi:10.1007/s42967-019-00049-2

Abstract

Abstract: One of the benefcial properties of the discontinuous Galerkin method is the accurate wave propagation properties. That is, the semi-discrete error has dissipation errors of order 2k + 1 (≤ Ch^2k+1) and order 2k + 2 for dispersion (≤ Ch^2k+2). Previous studies have concentrated on the order of accuracy, and neglected the important role that the error constant, C, plays in these estimates. In this article, we show the important role of the error constant in the dispersion and dissipation error for discontinuous Galerkin approximation of polynomial degree k, where k = 0, 1, 2, 3. This gives insight into why one may want a more centred fux for a piecewise constant or quadratic approximation than for a piecewise linear or cubic approximation. We provide an explicit formula for these error constants. This is illustrated through one particular fux, the upwind-biased fux introduced by Meng et al., as it is a convex combination of the upwind and downwind fuxes. The studies of wave propagation are typically done through a Fourier ansatz. This higher order Fourier information can be extracted using the smoothness-increasing accuracy-conserving (SIAC) flter. The SIAC flter ties the higher order Fourier information to the negative-order norm in physical space. We show that both the proofs of the ability of the SIAC flter to extract extra accuracy and numerical results are unafected by the choice of fux.

Key words: Discontinuous Galerkin, Smoothness-increasing accuracy-conserving (SIAC) fltering, Superconvergence

CLC Number:

65M60

Daniel J. Frean, Jennifer K. Ryan. Superconvergence and the Numerical Flux: a Study Using the Upwind-Biased Flux in Discontinuous Galerkin Methods[J]. Communications on Applied Mathematics and Computation, 2020, 2(3): 461-486.

TrendMD

References

1. Adjerid, S., Baccouch, M.:A superconvergent local discontinuous Galerkin method for elliptic problems. J. Sci. Comput. 52(1), 113-152 (2012)
2. Adjerid, S., Devine, K.D., Flaherty, J.E., Krivodonova, L.:A posteriori error estimation for discontinuous Galerkin solutions of hyperbolic problems. Comput. Methods Appl. Mech. Eng. 191(11), 1097-1112 (2002)
3. Ainsworth, M.:Dispersive and dissipative behaviour of high order discontinuous Galerkin fnite element methods. J. Comput. Phys. 198(1), 106-130 (2004)
4. Cao, W., Zhang, Z., Zou, Q.:Superconvergence of discontinuous Galerkin methods for linear hyperbolic equations. SIAM J. Numer. Anal. 52(5), 2555-2573 (2014)
5. Cao, W., Li, D., Yang, Y., Zhang, Z.:Superconvergence of discontinuous Galerkin methods based on upwind-biased fuxes for 1D linear hyperbolic equations. ESAIM Math. Model. Numer. Anal. 51(2), 467-486 (2017)
6. Cheng, Y., Chou, C.-S., Li, F., Xing, Y.:L2 stable discontinuous Galerkin methods for one-dimensional two-way wave equations. Math. Comput. 86, 121-155 (2014)
7. Cockburn, B., Luskin, M., Shu, C.-W., Süli, E.:Enhanced accuracy by post-processing for fnite element methods for hyperbolic equations. Math. Comput. 72(242), 577-606 (2003)
8. Cockburn, B., Shu, C.-W.:TVB Runge-Kutta local projection discontinuous Galerkin fnite element method for conservation laws. ii. General framework. Math. Comput. 52(186), 411-435 (1989)
9. Guo, W., Zhong, X., Qiu, J.-M.:Superconvergence of discontinuous Galerkin and local discontinuous Galerkin methods:eigen-structure analysis based on Fourier approach. J. Comput. Phys. 235, 458-485 (2013)
10. Hu, F.Q., Atkins, H.L.:Eigensolution analysis of the discontinuous Galerkin method with nonuniform grids:I. One space dimension. J. Comput. Phys. 182(2), 516-545 (2002)
11. Ji, L., van Slingerland, P., Ryan, J., Vuik, K.:Superconvergent error estimates for position-dependent smoothness-increasing accuracy-conserving (SIAC) post-processing of discontinuous Galerkin solutions. Math. Comput. 83(289), 2239-2262 (2014)
12. Ji, L., Xu, Y., Ryan, J.K.:Accuracy-enhancement of discontinuous Galerkin solutions for convection-difusion equations in multiple-dimensions. Math. Comput. 81(280), 1929-1950 (2012)
13. Ji, L., Ryan, J.K.:Smoothness-increasing accuracy-conserving (SIAC) flters in Fourier space. In:Kirby, R.M., Berzins, M., Hesthaven, J.S. (eds.) Spectral and High Order Methods for Partial Diferential Equations ICOSAHOM 2014, pp. 415-423. Springer, Cham (2015)
14. Krivodonova, L., Qin, R.:An analysis of the spectrum of the discontinuous Galerkin method. Appl. Numer. Mathematics 64, 1-18 (2013)
15. Meng, X., Shu, C.-W., Wu, B.:Optimal error estimates for discontinuous Galerkin methods based on upwind-biased fuxes for linear hyperbolic equations. Math. Comput. 85, 1225-1261 (2016)
16. Meng, X., Ryan, J.K.:Discontinuous Galerkin methods for nonlinear scalar hyperbolic conservation laws:divided diference estimates and accuracy enhancement. Numer. Math. 136(1), 27-73 (2017)
17. Meng, X., Ryan, J.K.:Divided diference estimates and accuracy enhancement of discontinuous Galerkin methods for nonlinear symmetric systems of hyperbolic conservation laws. IMA J. Numer. Anal. 38(1), 125-155 (2017)
18. Ryan, J.K., Shu, C.-W., Atkins, H.:Extension of a post processing technique for the discontinuous Galerkin method for hyperbolic equations with application to an aeroacoustic problem. SIAM J. Sci. Comput. 26(3), 821-843 (2005)
19. Sherwin, S.:Dispersion analysis of the continuous and discontinuous Galerkin formulations. In:Cockburn B., Karniadakis G.E., Shu C.-W. (eds) Discontinuous Galerkin Methods, pp. 425-431. Springer, Berlin (2000)
20. Van Slingerland, P., Ryan, J.K., Vuik, C.:Position-dependent smoothness-increasing accuracy-conserving (SIAC) fltering for improving discontinuous Galerkin solutions. SIAM J. Sci. Comput. 33(2), 802-825 (2011)
21. Yang, H., Li, F., Qiu, J.:Dispersion and dissipation errors of two fully discrete discontinuous Galerkin methods. J. Sci. Comput. 55(3), 552-574 (2013)
22. Yang, Y., Shu, C.-W.:Discontinuous Galerkin method for hyperbolic equations involving δ-singularities:negative-order norm error estimates and applications. Numer. Math. 124(4), 753-781 (2013)
23. Yang, Y., Shu, C.-W.:Analysis of optimal superconvergence of discontinuous Galerkin method for linear hyperbolic equations. SIAM J. Numer. Anal. 50(6), 3110-3133 (2012)
24. Zhang, M., Shu, C.-W.:An analysis of three diferent formulations of the discontinuous Galerkin method for difusion equations. Math. Models Methods Appl. Sci. 13(03), 395-413 (2003)
25. Zhong, X., Shu, C.-W.:Numerical resolution of discontinuous Galerkin methods for time dependent wave equations. Comput. Methods Appl. Mech. Eng. 200(41), 2814-2827 (2011)

[1]	Steven Jöns, Claus, Dieter Munz. An Approximate Riemann Solver for Advection–Difusion Based on the Generalized Riemann Problem [J]. Communications on Applied Mathematics and Computation, 2020, 2(3): 515-539.
[2]	Qiang Du, Lili Ju, Jianfang Lu, Xiaochuan Tian. A Discontinuous Galerkin Method with Penalty for One-Dimensional Nonlocal Difusion Problems [J]. Communications on Applied Mathematics and Computation, 2020, 2(1): 31-55.
[3]	Can Li, Shuming Liu. Local Discontinuous Galerkin Scheme for Space Fractional Allen-Cahn Equation [J]. Communications on Applied Mathematics and Computation, 2020, 2(1): 73-91.
[4]	Paola Antonietti, Claudio Canuto, Marco Verani. An Adaptive hp-DG-FE Method for Elliptic Problems: Convergence and Optimality in the 1D Case [J]. Communications on Applied Mathematics and Computation, 2019, 1(3): 309-331.
[5]	Jianguo Huang, Xuehai Huang. A Two-Level Additive Schwarz Preconditioner for Local C⁰ Discontinuous Galerkin Methods of Kirchhof Plates [J]. Communications on Applied Mathematics and Computation, 2019, 1(2): 167-185.
[6]	Yong Liu, Chi-Wang Shu, Mengping Zhang. Superconvergence of Energy-Conserving Discontinuous Galerkin Methods for Linear Hyperbolic Equations [J]. Communications on Applied Mathematics and Computation, 2019, 1(1): 101-116.