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Robust norm equivalencies for diffusion problems

Author(s): Michael Griebel; Karl Scherer; Marc Alexander Schweitzer.
Journal: Math. Comp. 76 (2007), 1141-1161.
MSC (2000): Primary 65N55, 65F35; Secondary 65N30, 65F10
Posted: February 7, 2007
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Abstract: Additive multilevel methods offer an efficient way for the fast solution of large sparse linear systems which arise from a finite element discretization of an elliptic boundary value problem. These solution methods are based on multilevel norm equivalencies for the associated bilinear form using a suitable subspace decomposition. To obtain a robust iterative scheme, it is crucial that the constants in the norm equivalence do not depend or depend only weakly on the ellipticity constants of the problem.

In this paper we present such a robust norm equivalence for the model problem $ - \nabla \omega \nabla u=f$ with a scalar diffusion coefficient $ \omega$ in $ \Omega \subset \mathbb{R}^2$. Our estimates involve only very weak information about $ \omega$, and the results are applicable for a large class of diffusion coefficients. Namely, we require $ \omega$ to be in the Muckenhoupt class $ A_{1}(\Omega)$, a function class well-studied in harmonic analysis.

The presented multilevel norm equivalencies are a main step towards the realization of an optimal and robust multilevel preconditioner for scalar diffusion problems.

References:

1.
R. E. Alcouffe, A. Brandt, J. E. Dendy and J. W. Painter, The Multi-Grid Method for the Diffusion Equation with Strongly Discontinuous Coefficients, SIAM J. Sci. Comput. 2 (1981), 430-454. MR 639011 (82k:65072)

2.
S. Beuchler, R. Schneider, and C. Schwab, Multiresolution Weighted Norm Equivalences and Applications, Tech. Report 02-09, Prepreint-Reihe Sonderforschungsbereich 393 TU Chemnitz, 2002.

3.
F. Bornemann and H. Yserentant, A Basic Norm Equivalence for the Theory of Multilevel Methods, Numer. Math. 64 (1993), 455-476. MR 1213412 (94b:65155)

4.
D. Braess, Finite Elements: Theory, Fast Solvers, and Applications in Solid Mechanics, Cambridge University Press, 2001. MR 1827293 (2001k:65002)

5.
J. H. Bramble and Jinchao Xu, Some estimates for a weighted $ {L}^2$ projection, Mathematics of Computation 56 (1991), 463-476. MR 1066830 (91k:65140)

6.
A. Brandt, Multi-Level Adaptive Technique (MLAT) for Fast Numerical Solution to Boundary Value Problems, Proc. of the Third Int. Conf. on Numerical Methods in Fluid Mechanics, Univ. Paris 1972 (New York, Berlin, Heidelberg) (H. Cabannes and R. Teman, eds.), Springer, 1973.

7.
-, Multi-Level Adaptive Solutions to Boundary-Value Problems, Math. Comp. 31 (1977), 333-390. MR 0431719 (55:4714)

8.
-, Algebraic Multigrid Theory: The Symmetric Case, Preliminary Proceedings for the International Multigrid Conference (Copper Mountain, Colorado), April 1983.

9.
-, Algebraic Multigrid Theory: The Symmetric Case, Appl. Math. Comput. 19 (1986), 23-56. MR 849831 (87j:65042)

10.
A. Brandt, S. F. McCormick, and J. W. Ruge, Algebraic Multigrid for Automatic Multigrid Solutions with Application to Geodetic Computations, Technical Report, Institute for Computational Studies, Fort Collins, Colorado, October 1982.

11.
-, Algebraic Multigrid for Sparse Matrix Equations, Sparsity and Its Applications (D. J. Evans, ed.), Cambridge University Press, 1984.

12.
J. E. Dendy, Black Box Multigrid, J. Comput. Phys. 48 (1982), 366-386. MR 684260 (84b:65097)

13.
M. Dryja, M. V. Sarkis, and O. B. Widlund, Multilevel Schwarz Methods for Elliptic Problems with Discontinuous Coefficients in Three Dimensions, Numer. Math. 72 (1996), 313-348. MR 1367653 (96h:65134)

14.
T. Grauschopf, M. Griebel, and H. Regler, Additive Multilevel-Preconditioners based on Bilinear Interpolation, Matrix Dependent Geometric Coarsening and Algebraic Multigrid Coarsening for Second Order Elliptic PDEs, Applied Numerical Mathematics 23(1) (1997), 63-96. MR 1438081 (97j:65193)

15.
W. Hackbusch, Ein iteratives Verfahren zur schnellen Auflösung elliptischer Randwertprobleme, Tech. Report 76-12, Mathematisches Institut, Universität zu Köln, 1976.

16.
-, A Fast Numerical Method for Elliptic Boundary Value Problems with Variable Coefficients, 2nd GAMM-Conf. Numer. Meth. Fl. Mech. (Köln) (E. H. Hirschel and W. Geller, eds.), Deutsche Forschungs- und Versuchsanstalt für Luft- und Raumfahrt, 1977, pp. 50-57.

17.
-, Multi-grid methods and applications, Springer, 1985.

18.
P. Oswald, On the Robustness of the BPX-Preconditioner with Respect to Jumps in the Coefficients, Math. Comp. 68 (1999), 633-650. MR 1620239 (99i:65143)

19.
J. W. Ruge and K. Stüben, Efficient Solution of Finite Difference and Finite Element Equations by Algebraic Multigrid, Multigrid Methods for Integral and Differential Equations (D. J. Paddon and H. Holstein, eds.), The Institute of Mathematics and its Applications Conference Series, Clarendon Press, 1985.

20.
E. M. Stein, Harmonic Analysis: Real-Variable Methods, Orthogonality and Oscillatory Integrals, Princeton University Press, 1993. MR 1232192 (95c:42002)

21.
U. Trottenberg, C. W. Osterlee, and A. Schüller, Multigrid, Appendix A: An Introduction to Algebraic Multigrid by K. Stüben, pp. 413-532, Academic Press, San Diego, 2001.

22.
W. L. Wan, T. F. Chan, and B. Smith, An Energy-Minimizing Interpolation for Robust Multigrid Methods, SIAM J. Sci. Comput. 21 (2000), no. 4, 1632-1649. MR 1756048 (2001a:65162)

23.
J. Wloka, Partielle Differentialgleichungen, Teubner, 1982. MR 652934 (84a:35002)

24.
J. Xu, Iterative Methods by Space Decomposition and Subspace Correction, SIAM Review 34 (1992), no. 4, 581-613. MR 1193013 (93k:65029)

25.
Jinchao Xu, Counter examples concerning a weighted $ {L}^{2}$ projection, Mathematics of Computation 57 (1991), 563-568. MR 1094965 (92b:65090)

26.
P. M. Zeeuw, Matrix-Dependent Prolongations and Restrictions in a Black-Box Multigrid Solver, J. Comput. Appl. Math. 33 (1990), 1-27. MR 1081238 (92c:65152)

27.
-, Acceleration of Iterative Methods by Coarse Grid Corrections, Ph.D. thesis, University of Amsterdam, 1997.

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Additional Information:

Michael Griebel
Affiliation: Institut für Numerische Simulation, Universität Bonn, Germany
Email: griebel@ins.uni-bonn.de

Karl Scherer
Affiliation: Institut für Angewandte Mathematik, Universität Bonn, Germany
Email: scherer@iam.uni-bonn.de

Marc Alexander Schweitzer
Affiliation: Institut für Numerische Simulation, Universität Bonn, Germany
Email: m.a.schweitzer@ins.uni-bonn.de

DOI: 10.1090/S0025-5718-07-01973-4
PII: S 0025-5718(07)01973-4
Keywords: Norm equivalency, multilevel method, preconditioning, robustness
Received by editor(s): August 4, 2004
Received by editor(s) in revised form: August 3, 2006
Posted: February 7, 2007
Additional Notes: The authors were supported in part by the Sonderforschungsbereich 611 \emph{Singuläre Phänomene und Skalierung in Mathematischen Modellen} sponsored by the \emph{Deutsche Forschungsgemeinschaft}.
Copyright of article: Copyright 2007, American Mathematical Society

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