Available in electronic format
Available in print format		 Mathematics of Computation
Journal of the American Mathematical Society
ISSN 1088-6842(e) ISSN 0025-5718(p)
Previous issue | Table of contents | Next issue
Articles in press | Recently posted articles | Most recent issue | All issues
Previous Article | Next Article
     

Fully adaptive multiresolution finite volume schemes for conservation laws

Author(s): Albert Cohen; Sidi Mahmoud Kaber; Siegfried Müller; Marie Postel.
Journal: Math. Comp. 72 (2003), 183-225.
MSC (2000): Primary 41A58, 65M50, 65M12
Posted: December 5, 2001
Retrieve article in: PDF DVI PostScript

Abstract | References | Similar articles | Additional information

Abstract: The use of multiresolution decompositions in the context of finite volume schemes for conservation laws was first proposed by A. Harten for the purpose of accelerating the evaluation of numerical fluxes through an adaptive computation. In this approach the solution is still represented at each time step on the finest grid, resulting in an inherent limitation of the potential gain in memory space and computational time. The present paper is concerned with the development and the numerical analysis of fully adaptive multiresolution schemes, in which the solution is represented and computed in a dynamically evolved adaptive grid. A crucial problem is then the accurate computation of the flux without the full knowledge of fine grid cell averages. Several solutions to this problem are proposed, analyzed, and compared in terms of accuracy and complexity.

References:

1.
Abgrall, R. (1997) Multiresolution analysis on unstructured meshes: applications to CFD, in Chetverushkin and al. eds. Experimentation, modeling and computation in flow, turbulence and combustion, vol.2, John Wiley & Sons.

2.
Arandiga, F. and R. Donat (1999) A class of nonlinear multiscale decomposition, to appear in Numerical Algorithms.

3.
Berger, M. J. and P. Collela (1989) Local adaptive mesh refinement for shock hydrodynamics, Journal of Computational Physics, 82, pp 64-84.

4.
Babuska, I. and B. Guo (1998) The h-p version of the finite element method for domains with curved boundaries, SIAM J. Numer. Anal. 25, 837-861. MR 89i:65111

5.
Bihari, B. and A. Harten (1997) Multiresolution schemes for the numerical solution of 2-D conservation laws, SIAM J. Sci. Comput. 18(2), 315-354. MR 98f:65092

6.
Carnicer, J.M., W. Dahmen and J.M. Peña (1996) Local decomposition of refinable spaces and wavelets Appl. Comput. Harmon. Anal. 3, 127-153. MR 97f:42050

7.
Cavaretta, A., W. Dahmen and C.A. Micchelli (1991), Stationary subdivision, Memoirs of AMS 453. MR 92h:65017

8.
Chiavassa, G. and R. Donat (1999) Numerical experiments with point value multiresolution for 2d compressible flows, Technical Report GrAN-99-4, University of Valencia.

9.
Cockburn, B., F. Coquel and P. Lefloch (1994) An error estimate for finite volume methods for multidimensional conservation laws, Math. Comp. 63, 77-103. MR 95d:65078

10.
Cohen, A. (2000) Wavelet methods in numerical analysis, Handbook of Numerical Analysis, vol. VII, P.G. Ciarlet and J.L. Lions, eds., North-Holland, Amsterdam, pp. 417-711. CMP 2001:08

11.
Cohen, A., W. Dahmen and R. DeVore (2001) Adaptive wavelet methods for elliptic operator equations: convergence rates, Math. Comp. 70, 27-75. CMP 2001:06
12.
Cohen, A., I. Daubechies and J.-C. Feauveau (1992) Biorthogonal bases of compactly supported wavelets, Comm. Pure and Applied Math. 45, 485-560. MR 93e:42044

13.
Cohen, A., N. Dyn, S.M. Kaber and M. Postel (2000) Multiresolution schemes on triangles for scalar conservation laws, J. Comp. Phys. 161, 264-286. MR 2000m:65168

14.
Cohen, A., S.M. Kaber and M. Postel (1999) Multiresolution analysis on triangles: application to conservation laws, in Finite volumes for complex applications II, R. Vielsmeier, F. Benkhaldoun and D. Hänel eds., Hermes, Paris.

15.
Dahmen, W. (1997) Wavelet and multiscale methods for operator equations, Acta Numerica 6, 55-228. MR 98m:65102

16.
Dahmen, W., B. Gottschlich-Müller and S. Müller (2000) Multiresolution Schemes for Conservation Laws, Numerische Mathematik DOI 10.1007/s00210000222

17.
Daubechies, I. (1992) Ten Lectures on Wavelets, SIAM, Philadelphia. MR 93e:42045

18.
DeVore, R. (1998) Nonlinear Approximation, Acta Numerica, 51-151. MR 2001a:41034

19.
Dyn, N. (1992) Subdivision algorithms in computer-aided geometric design, in: Advances in Numerical Analysis II, W.A. Light ed., Clarendon Press, Oxford.

20.
Gottschlich-Müller, B. and S. Müller (1999) Adaptive finite volume schemes for conservation laws based on local multiresolution techniques, in M. Fey and R. Jeltsch eds., Hyperbolic Problems: Theory, Numerics, Applications, Birkhäuser, Basel, pp. 385-394. MR 2000f:65112

21.
Harten, A. (1994) Adaptive multiresolution schemes for shock computations, J. Comp. Phys. 115, 319-338. MR 96d:65175

22.
Harten, A. (1995) Multiresolution algorithms for the numerical solution of hyperbolic conservation laws, Comm. Pure and Applied Math. 48, 1305-1342. MR 97e:65094

23.
Harten, A., B. Engquist, S. Osher, and S.R. Chakravarthy (1987) Uniformly high order accurate essentially non-oscillatory schemes III, J. Comp. Phys. 71, 231-303. MR 90a:65199

24.
Jaffard, S. (1991) Pointwise smoothness, two-microlocalization and wavelet coefficients, Publicacions Matemàtiques 35, 155-168. MR 92j:46057

25.
Kröner, D. (1997), Numerical schemes for conservation laws, Advances in Numerical Mathematics. Wiley-Teubner. MR 98b:65003

26.
LeVeque, R.J. (1992) Numerical methods for conservation laws, Birkhäuser Verlag, Basel. MR 92m:65106

27.
Lucier, B. (1986) A moving mesh numerical method for hyperbolic conservation laws, Math. Comp. 46, 59-69. MR 87m:65141

28.
Meyer, Y. (1990) Ondelettes et Opérateurs, Hermann, Paris, english tranlation by D.H. Salinger (1992), Cambridge University Press, Cambridge. MR 93i:42002; MR 93i:42003; MR 93i:42004

29.
Sanders, R. (1983) On convergence of monotone finite difference schemes with variable spatial differencing, Math. Comp. 40, 91-106. MR 84a:65075

30.
Sjögreen, B. (1995) Numerical experiments with the multiresolution scheme for the compressible Euler equations, J. Comp. Phys., 117, 251-261.

31.
Schröder-Pander, F. and T. Sonar (1995) Preliminary investigations on multiresolution analysis on unstructured grids, DLR Report IB 223-95 A 36, 1995, DLR Göttingen.

32.
L.J. Durlofsky, B. Engquist, and S. Osher (1992)
Triangle based adaptive stencils for the solution of hyperbolic conservation laws.
J. Comp. Phys., 98, 64-73.

33.
E. Godlewski and P-A. Raviart (1996)
Numerical Approximation of Hyperbolic Systems of Conservation Laws, volume 118.
Springer. MR 98d:65109

34.
S. M. Kaber and M. Postel (1999)
Finite volume schemes on triangles coupled with multiresolution analysis.
328, série I, 817,822. MR 2000a:65147

35.
A. Voss and S. Müller (1999)
A manual for the template class library igpm_t_lib.
Technical Report 197, IGPM, RWTH Aachen.

36.
J. Ballmann, F. Bramkamp, and S. Müller (2000)
Development of a flow solver employing local adaptation based on multiscale analysis on B-spline grids.
In Proceedings of 8th Annual Conf. of the CFD Society of Canada, June, 11 to 13, 2000 Montreal.

Similar Articles:

Retrieve articles in Mathematics of Computation with MSC (2000): 41A58, 65M50, 65M12

Retrieve articles in all Journals with MSC (2000): 41A58, 65M50, 65M12

Additional Information:

Albert Cohen
Affiliation: Laboratoire d'Analyse Numérique, Université Pierre et Marie Curie, BC 187, 75252 Paris cedex 05, France
Email: cohen@ann.jussieu.fr

Sidi Mahmoud Kaber
Affiliation: Laboratoire d'Analyse Numérique, Université Pierre et Marie Curie, BC 187, 75252 Paris cedex 05, France
Email: kaber@ann.jussieu.fr

Siegfried Müller
Affiliation: Institut für Geometrie und Praktische Mathematik, RWTH, Templergraben 55, D-52056 Aachen, Germany
Email: mueller@igpm.rwth-aachen.de

Marie Postel
Affiliation: Laboratoire d'Analyse Numérique, Université Pierre et Marie Curie, BC 187, 75252 Paris cedex 05, France
Email: postel@ann.jussieu.fr

DOI: 10.1090/S0025-5718-01-01391-6
PII: S 0025-5718(01)01391-6
Keywords: Conservation laws, finite volume schemes, adaptivity, multiresolution, wavelets.
Received by editor(s): May 30, 2000
Received by editor(s) in revised form: February 6, 2001.
Posted: December 5, 2001
Additional Notes: The work of S. Müller has been supported by the EU--TMR network ``Wavelets in Numerical Simulations''.
Copyright of article: Copyright 2001, American Mathematical Society

  AMS Website Logo Small Comments: webmaster@ams.org
© Copyright 2008, American Mathematical Society
Privacy Statement 		Search the AMSPowered by Google