A General High-Order Multi-Domain Hybrid DG/WENO-FD Method for Hyperbolic Conservation Laws

Journal Home
Volume 39 - 2021
- Vol. 39, Issue 2 pp.159-310
- Vol. 39, Issue 1 pp.1-158
Volume 38 - 2020
- Vol. 38, Issue 6 pp.827-984
- Vol. 38, Issue 5 pp.683-826
- Vol. 38, Issue 4 pp.547-682
- Vol. 38, Issue 3 pp.395-546
- Vol. 38, Issue 2 pp.239-394
- Vol. 38, Issue 1 pp.1-238
Volume 37 - 2019
- Vol. 37, Issue 6 pp.739-936
- Vol. 37, Issue 5 pp.579-738
- Vol. 37, Issue 4 pp.437-578
- Vol. 37, Issue 3 pp.297-436
- Vol. 37, Issue 2 pp.151-296
- Vol. 37, Issue 1 pp.1-150
Volume 36 - 2018
- Vol. 36, Issue 6 pp.761-902
- Vol. 36, Issue 5 pp.627-760
- Vol. 36, Issue 4 pp.469-626
- Vol. 36, Issue 3 pp.331-468
- Vol. 36, Issue 2 pp.159-330
- Vol. 36, Issue 1 pp.1-158
Volume 35 - 2017
- Vol. 35, Issue 6 pp.693-838
- Vol. 35, Issue 5 pp.547-692
- Vol. 35, Issue 4 pp.381-546
- Vol. 35, Issue 3 pp.245-380
- Vol. 35, Issue 2 pp.121-244
- Vol. 35, Issue 1 pp.1-120
Volume 34 - 2016
- Vol. 34, Issue 6 pp.573-738
- Vol. 34, Issue 5 pp.451-572
- Vol. 34, Issue 4 pp.339-450
- Vol. 34, Issue 3 pp.223-338
- Vol. 34, Issue 2 pp.113-222
- Vol. 34, Issue 1 pp.1-112
Volume 33 - 2015
- Vol. 33, Issue 6 pp.557-684
- Vol. 33, Issue 5 pp.443-556
- Vol. 33, Issue 4 pp.341-442
- Vol. 33, Issue 3 pp.227-340
- Vol. 33, Issue 2 pp.113-226
- Vol. 33, Issue 1 pp.1-112
Volume 32 - 2014
- Vol. 32, Issue 6 pp.601-720
- Vol. 32, Issue 5 pp.491-600
- Vol. 32, Issue 4 pp.371-490
- Vol. 32, Issue 3 pp.215-370
- Vol. 32, Issue 2 pp.107-214
- Vol. 32, Issue 1 pp.1-106
Volume 31 - 2013
- Vol. 31, Issue 6 pp.549-662
- Vol. 31, Issue 5 pp.439-548
- Vol. 31, Issue 4 pp.335-438
- Vol. 31, Issue 3 pp.221-334
- Vol. 31, Issue 2 pp.107-220
- Vol. 31, Issue 1 pp.1-106
Volume 30 - 2012
- Vol. 30, Issue 6 pp.565-683
- Vol. 30, Issue 5 pp.449-564
- Vol. 30, Issue 4 pp.337-448
- Vol. 30, Issue 3 pp.223-336
- Vol. 30, Issue 2 pp.101-222
- Vol. 30, Issue 1 pp.1-100
Volume 29 - 2011
- Vol. 29, Issue 6 pp.605-719
- Vol. 29, Issue 5 pp.491-604
- Vol. 29, Issue 4 pp.367-490
- Vol. 29, Issue 3 pp.243-366
- Vol. 29, Issue 2 pp.131-242
- Vol. 29, Issue 1 pp.1-130
Volume 28 - 2010
- Vol. 28, Issue 6 pp.725-912
- Vol. 28, Issue 5 pp.569-724
- Vol. 28, Issue 4 pp.429-568
- Vol. 28, Issue 3 pp.289-428
- Vol. 28, Issue 2 pp.149-288
- Vol. 28, Issue 1 pp.1-148
Volume 27 - 2009
- Vol. 27, Issue 6 pp.677-834
- Vol. 27, Issue 5 pp.561-676
- Vol. 27, Issue 4 pp.425-560
- Vol. 27, Issue 2-3 pp.115-424
- Vol. 27, Issue 1 pp.1-114
Volume 26 - 2008
- Vol. 26, Issue 6 pp.767-892
- Vol. 26, Issue 5 pp.633-766
- Vol. 26, Issue 4 pp.471-632
- Vol. 26, Issue 3 pp.259-470
- Vol. 26, Issue 2 pp.123-258
- Vol. 26, Issue 1 pp.1-122
Volume 25 - 2007
- Vol. 25, Issue 6 pp.631-747
- Vol. 25, Issue 5 pp.497-630
- Vol. 25, Issue 4 pp.385-496
- Vol. 25, Issue 3 pp.243-384
- Vol. 25, Issue 2 pp.113-242
- Vol. 25, Issue 1 pp.1-112
Volume 24 - 2006
- Vol. 24, Issue 6 pp.675-790
- Vol. 24, Issue 5 pp.561-674
- Vol. 24, Issue 4 pp.451-560
- Vol. 24, Issue 3 pp.225-450
- Vol. 24, Issue 2 pp.113-224
- Vol. 24, Issue 1 pp.1-112
Volume 23 - 2005
- Vol. 23, Issue 6 pp.561-672
- Vol. 23, Issue 5 pp.449-560
- Vol. 23, Issue 4 pp.337-448
- Vol. 23, Issue 3 pp.225-336
- Vol. 23, Issue 2 pp.113-224
- Vol. 23, Issue 1 pp.1-112
Volume 22 - 2004
- Vol. 22, Issue 6 pp.777-920
- Vol. 22, Issue 5 pp.633-776
- Vol. 22, Issue 4 pp.489-632
- Vol. 22, Issue 3 pp.341-488
- Vol. 22, Issue 2 pp.145-340
- Vol. 22, Issue 1 pp.1-144
Volume 21 - 2003
- Vol. 21, Issue 6 pp.689-832
- Vol. 21, Issue 5 pp.545-688
- Vol. 21, Issue 4 pp.401-544
- Vol. 21, Issue 3 pp.257-400
- Vol. 21, Issue 2 pp.113-256
- Vol. 21, Issue 1 pp.1-112
Volume 20 - 2002
- Vol. 20, Issue 6 pp.561-672
- Vol. 20, Issue 5 pp.449-560
- Vol. 20, Issue 4 pp.337-448
- Vol. 20, Issue 3 pp.225-336
- Vol. 20, Issue 2 pp.113-224
- Vol. 20, Issue 1 pp.1-112
Volume 19 - 2001
- Vol. 19, Issue 6 pp.561-672
- Vol. 19, Issue 5 pp.449-560
- Vol. 19, Issue 4 pp.337-448
- Vol. 19, Issue 3 pp.225-336
- Vol. 19, Issue 2 pp.113-224
- Vol. 19, Issue 1 pp.1-112
Volume 18 - 2000
- Vol. 18, Issue 6 pp.561-672
- Vol. 18, Issue 5 pp.449-560
- Vol. 18, Issue 4 pp.337-448
- Vol. 18, Issue 3 pp.225-336
- Vol. 18, Issue 2 pp.113-224
- Vol. 18, Issue 1 pp.1-112
Volume 17 - 1999
- Vol. 17, Issue 6 pp.561-672
- Vol. 17, Issue 5 pp.449-560
- Vol. 17, Issue 4 pp.337-448
- Vol. 17, Issue 3 pp.225-336
- Vol. 17, Issue 2 pp.113-224
- Vol. 17, Issue 1 pp.1-112
Volume 16 - 1998
- Vol. 16, Issue 6 pp.481-576
- Vol. 16, Issue 5 pp.385-480
- Vol. 16, Issue 4 pp.289-384
- Vol. 16, Issue 3 pp.193-288
- Vol. 16, Issue 2 pp.97-192
- Vol. 16, Issue 1 pp.1-96
Volume 15 - 1997
- Vol. 15, Issue 4 pp.289-384
- Vol. 15, Issue 3 pp.193-288
- Vol. 15, Issue 2 pp.97-192
- Vol. 15, Issue 1 pp.1-96
Volume 14 - 1996
- Vol. 14, Issue 4 pp.291-386
- Vol. 14, Issue 3 pp.195-290
- Vol. 14, Issue 2 pp.99-194
- Vol. 14, Issue 1 pp.1-98
Volume 13 - 1995
- Vol. 13, Issue 4 pp.291-386
- Vol. 13, Issue 3 pp.193-290
- Vol. 13, Issue 2 pp.95-192
- Vol. 13, Issue 1 pp.1-94
Volume 12 - 1994
- Vol. 12, Issue 4 pp.291-386
- Vol. 12, Issue 3 pp.195-290
- Vol. 12, Issue 2 pp.98-194
- Vol. 12, Issue 1 pp.1-97
Volume 11 - 1993
- Vol. 11, Issue 4 pp.289-384
- Vol. 11, Issue 3 pp.193-288
- Vol. 11, Issue 2 pp.99-192
- Vol. 11, Issue 1 pp.1-98
Volume 10 - 1992
- Vol. 10, Issue 4 pp.291-387
- Vol. 10, Issue 3 pp.193-289
- Vol. 10, Issue 2 pp.97-193
- Vol. 10, Issue 1 pp.1-97
Volume 9 - 1991
- Vol. 9, Issue 4 pp.291-387
- Vol. 9, Issue 3 pp.193-289
- Vol. 9, Issue 2 pp.97-193
- Vol. 9, Issue 1 pp.1-96
Volume 8 - 1990
- Vol. 8, Issue 4 pp.289-381
- Vol. 8, Issue 3 pp.195-288
- Vol. 8, Issue 2 pp.99-194
- Vol. 8, Issue 1 pp.1-98
Volume 7 - 1989
- Vol. 7, Issue 4 pp.321-417
- Vol. 7, Issue 3 pp.227-320
- Vol. 7, Issue 2 pp.97-225
- Vol. 7, Issue 1 pp.1-96
Volume 6 - 1988
- Vol. 6, Issue 4 pp.293-382
- Vol. 6, Issue 3 pp.193-292
- Vol. 6, Issue 2 pp.97-192
- Vol. 6, Issue 1 pp.1-96
Volume 5 - 1987
- Vol. 5, Issue 4 pp.287-382
- Vol. 5, Issue 3 pp.191-286
- Vol. 5, Issue 2 pp.95-190
- Vol. 5, Issue 1 pp.1-94
Volume 4 - 1986
- Vol. 4, Issue 4 pp.289-382
- Vol. 4, Issue 3 pp.191-288
- Vol. 4, Issue 2 pp.97-190
- Vol. 4, Issue 1 pp.1-96
Volume 3 - 1985
- Vol. 3, Issue 4 pp.289-384
- Vol. 3, Issue 3 pp.193-288
- Vol. 3, Issue 2 pp.97-192
- Vol. 3, Issue 1 pp.1-96
Volume 2 - 1984
- Vol. 2, Issue 4 pp.287-381
- Vol. 2, Issue 3 pp.189-286
- Vol. 2, Issue 2 pp.93-188
- Vol. 2, Issue 1 pp.1-92
Volume 1 - 1983
- Vol. 1, Issue 4 pp.303-383
- Vol. 1, Issue 3 pp.195-302
- Vol. 1, Issue 2 pp.99-194
- Vol. 1, Issue 1 pp.1-98

Volume 34, Issue 1

Jian Cheng, Kun Wang & Tiegang Liu

DOI: 10.4208/jcm.1510-m4512

J. Comp. Math., 34 (2016), pp. 30-48.

Published online: 2016-02

Preview Full PDF 709 2690

Export citation

Cited by

google scholar semantic scholar

Abstract

In this paper, a general high-order multi-domain hybrid DG/WENO-FD method, which couples a pth-order (p ≥ 3) DG method and a qth-order (q ≥ 3) WENO-FD scheme, is developed. There are two possible coupling approaches at the domain interface, one is non-conservative, the other is conservative. The non-conservative coupling approach can preserve optimal order of accuracy and the local conservative error is proved to be upmost third order. As for the conservative coupling approach, accuracy analysis shows the forced conservation strategy at the coupling interface deteriorates the accuracy locally to firstorder accuracy at the ‘coupling cell’. A numerical experiments of numerical stability is also presented for the non-conservative and conservative coupling approaches. Several numerical results are presented to verify the theoretical analysis results and demonstrate the performance of the hybrid DG/WENO-FD solver.

Keywords

Discontinuous Galerkin method Weighted essentially nonoscillatory scheme Hybrid methods high-order scheme

AMS Subject Headings

65M60 65M99 35L65.

Email address

chengjian@buaa.edu.cn (Jian Cheng)

wangkun@buaa.edu.cn (Kun Wang)

liutg@buaa.edu.cn (Tiegang Liu)

BibTex
RIS
TXT

@Article{JCM-34-30, author = {Cheng , Jian and Wang , Kun and Liu , Tiegang }, title = {A General High-Order Multi-Domain Hybrid DG/WENO-FD Method for Hyperbolic Conservation Laws}, journal = {Journal of Computational Mathematics}, year = {2016}, volume = {34}, number = {1}, pages = {30--48}, abstract = { In this paper, a general high-order multi-domain hybrid DG/WENO-FD method, which couples a pth-order (p ≥ 3) DG method and a qth-order (q ≥ 3) WENO-FD scheme, is developed. There are two possible coupling approaches at the domain interface, one is non-conservative, the other is conservative. The non-conservative coupling approach can preserve optimal order of accuracy and the local conservative error is proved to be upmost third order. As for the conservative coupling approach, accuracy analysis shows the forced conservation strategy at the coupling interface deteriorates the accuracy locally to firstorder accuracy at the ‘coupling cell’. A numerical experiments of numerical stability is also presented for the non-conservative and conservative coupling approaches. Several numerical results are presented to verify the theoretical analysis results and demonstrate the performance of the hybrid DG/WENO-FD solver.}, issn = {1991-7139}, doi = {https://doi.org/10.4208/jcm.1510-m4512}, url = {http://global-sci.org/intro/article_detail/jcm/9781.html} }

TY - JOUR T1 - A General High-Order Multi-Domain Hybrid DG/WENO-FD Method for Hyperbolic Conservation Laws AU - Cheng , Jian AU - Wang , Kun AU - Liu , Tiegang JO - Journal of Computational Mathematics VL - 1 SP - 30 EP - 48 PY - 2016 DA - 2016/02 SN - 34 DO - http://doi.org/10.4208/jcm.1510-m4512 UR - https://global-sci.org/intro/article_detail/jcm/9781.html KW - Discontinuous Galerkin method KW - Weighted essentially nonoscillatory scheme KW - Hybrid methods KW - high-order scheme AB - In this paper, a general high-order multi-domain hybrid DG/WENO-FD method, which couples a pth-order (p ≥ 3) DG method and a qth-order (q ≥ 3) WENO-FD scheme, is developed. There are two possible coupling approaches at the domain interface, one is non-conservative, the other is conservative. The non-conservative coupling approach can preserve optimal order of accuracy and the local conservative error is proved to be upmost third order. As for the conservative coupling approach, accuracy analysis shows the forced conservation strategy at the coupling interface deteriorates the accuracy locally to firstorder accuracy at the ‘coupling cell’. A numerical experiments of numerical stability is also presented for the non-conservative and conservative coupling approaches. Several numerical results are presented to verify the theoretical analysis results and demonstrate the performance of the hybrid DG/WENO-FD solver.

Jian Cheng, Kun Wang & Tiegang Liu. (2019). A General High-Order Multi-Domain Hybrid DG/WENO-FD Method for Hyperbolic Conservation Laws. Journal of Computational Mathematics. 34 (1). 30-48. doi:10.4208/jcm.1510-m4512

Copy to clipboard

BibteX RIS TXT

The citation has been copied to your clipboard