Geodesic
A Multiscale Model Reduction Method for Partial Differential Equations
ESAIM: Mathematical Modelling and Numerical Analysis , Multiscale problems and techniques. Special Issue, Tome 48 (2014) no. 2, pp. 449-474.

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We propose a multiscale model reduction method for partial differential equations. The main purpose of this method is to derive an effective equation for multiscale problems without scale separation. An essential ingredient of our method is to decompose the harmonic coordinates into a smooth part and a highly oscillatory part so that the smooth part is invertible and the highly oscillatory part is small. Such a decomposition plays a key role in our construction of the effective equation. We show that the solution to the effective equation is in H2, and can be approximated by a regular coarse mesh. When the multiscale problem has scale separation and a periodic structure, our method recovers the traditional homogenized equation. Furthermore, we provide error analysis for our method and show that the solution to the effective equation is close to the original multiscale solution in the H1 norm. Numerical results are presented to demonstrate the accuracy and robustness of the proposed method for several multiscale problems without scale separation, including a problem with a high contrast coefficient.

DOI : 10.1051/m2an/2013115
Classification : 35J15, 65N30
Keywords: model reduction, effective equation, multiscale PDE, harmonic coordinates, decomposition 
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     title = {A {Multiscale} {Model} {Reduction} {Method} for {Partial} {Differential} {Equations}},
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Ci, Maolin; Hou, Thomas Y.; Shi, Zuoqiang. A Multiscale Model Reduction Method for Partial Differential Equations. ESAIM: Mathematical Modelling and Numerical Analysis , Multiscale problems and techniques. Special Issue, Tome 48 (2014) no. 2, pp. 449-474. doi : 10.1051/m2an/2013115. http://geodesic.mathdoc.fr/articles/10.1051/m2an/2013115/

[1] G. Alessandrini and V. Nesi, Univalent σ-harmonic mappings. Arch. Rational Mech. Anal. 158 (2001) 155-171. | Zbl | MR

[2] G. Allaire and R. Brizzi, A multiscale finite element method for numerical homogenization. SIAM MMS 4 (2005) 790-812. | Zbl | MR

[3] A. Ancona, Some results and examples about the behavior of harmonic functions and Green's funtions with respect to second order elliptic operators. Nagoya Math. J. 165 (2002) 123-158. | Zbl | MR

[4] T. Arbogast, G. Pencheva, M.F. Wheeler and I. Yotov, A multiscale mortar mixed finite element method. SIAM MMS 6 (2007) 319-346. | MR | Zbl

[5] I. Babuška and E. Osborn, Generalized Finite Element Methods: Their Performance and Their Relation to Mixed Methods. SIAM J. Numer. Anal. 20 (1983) 510-536. | Zbl | MR

[6] I. Babuška, G. Caloz and E. Osborn, Special finite element methods for a class of second order elliptic problems with rough coefficients. SIAM J. Numer. Anal. 31 (1994) 945-981. | Zbl | MR

[7] M. Barrault, Y. Maday, N.C. Nguyen and A.T. Patera, An Empirical Interpolation Method: Application to Efficient Reduced-Basis Discretization of Partial Differential Equations. C.R. Acad. Sci. Paris Series I 339 (2004) 667-672. | Zbl | MR

[8] A. Bensoussan, J.-L. Lions and G. Papanicolaou, Asymptotic Analysis for Periodic Structure. North-Holland, Amsterdam (1978). | Zbl | MR

[9] S. Boyaval, C. Lebris, T. Lelièvre, Y. Maday, N. Nguyen and A. Patera, Reduced Basis Techniques for Stochastic Problems. Arch. Comput. Meth. Eng. 17 (2012) 435-454. | Zbl | MR

[10] Y. Chen, L.J. Durlofsky, M. Gerritsen and X.H. Wen, A coupled local-global upscaling approach for simulating flow in highly heterogeneous formations. Advances in Water Resources 26 (2003) 1041-1060.

[11] Z. Chen and T.Y. Hou, A mixed multiscale finite element method for elliptic problems with oscillating coefficients. Math. Comput. 72 (2002) 541-576. | Zbl | MR

[12] C.C. Chu, I. Graham and T.Y. Hou, A New multiscale finite element method for high-contrast elliptic interface problems. Math. Comput. 79 (2010) 1915-1955. | Zbl | MR

[13] Weinan E and B. Engquist, The heterogeneous multi-scale methods. Commun. Math. Sci. 1 (2003) 87-133. | Zbl | MR

[14] Y. Efendiev, J. Galvis and X.H. Wu, Multiscale finite element methods for high-contrast problems using local spectral basis functions. J. Comput. Phys. 230 (2011) 937-955. | MR

[15] Y. Efendiev, V. Ginting, T. Hou and R. Ewing, Accurate multiscale finite element methods for two-phase flow simulations. J. Comput. Phys. 220 (2006) 155-174. | Zbl | MR

[16] Y. Efendiev and T. Hou, Multiscale finite element methods. Theory and applications. Springer (2009). | Zbl | MR

[17] Y. Efendiev, T.Y. Hou and X.H. Wu, Convergence of a nonconforming multiscale finite element method. SIAM J. Num. Anal. 37 (2000) 888-910. | Zbl | MR

[18] Y. Efendiev, J. Galvis and T.Y. Hou, Generalized multiscale finite element methods (GMsFEM). Accepted by JCP (2013). | MR

[19] J. Galvis and Y. Efendiev, Domain decomposition preconditioners for multiscale flows in high-contrast media: Reduced dimension coarse spaces. SIAM MMS 8 (2009) 1621-1644. | MR

[20] I.G. Graham, P.O. Lechner and R. Scheichl, Domain decomposition for multiscale PDEs. Numer. Math. 106 (2007) 589-626. | Zbl | MR

[21] T.Y. Hou and X.H. Wu, A multiscale finite element method for elliptic problems in composite materials and porous media. J. Comput. Phys. 134 (1997) 169-189. | Zbl | MR

[22] T.Y. Hou, X.H. Wu and Z. Cai, Convergence of a multiscale finite element method for elliptic problems with rapidly oscillating coefficients. Math. Comput. 68 (1999) 913-943. | Zbl | MR

[23] T. Hughes, G. Feijoo, L. Mazzei and J. Quincy, The variational multiscale method - a paradigm for computational mechanics. Comput. Methods Appl. Mech. Engrg. 166 (1998) 3-24. | Zbl | MR

[24] P. Jenny, S.H. Lee and H. Tchelepi, Multi-scale finite volume method for elliptic problems in subsurface flow simulation. J. Comput. Phys. 187 (2003) 47-67. | Zbl

[25] Y. Maday, Proceedings of the International Conference Math., Madrid. European Mathematical Society, Zurich (2006).

[26] A. Maugeri, D.K. Palagachev and L.G. Softova. Elliptic and parabolic equations with discontinuous coefficients. Math. Research 109, Wiley-VCH (2000). | Zbl | MR

[27] D.W. Mclaughlin, G.C. Papanicolaou and O.R. Pironneau, Convetion of mircrostructure and related problems. SIAM J. Appl. Math. 45 (1985) 780-797. | Zbl | MR

[28] S. Moskow and M. Vogelius, First-oder corrections to the homogenised eigenvalues of a periodic composite medium. A convergence proof. Proc. Roy. Soc. Edinburgh. 127A (1997) 1263-1299. | Zbl | MR

[29] H. Owhadi and L. Zhang, Metric based up-scaling. Commun. Pure Appl. Math. LX (2007) 675-723. | Zbl | MR

[30] H. Owhadi and L. Zhang, Homogenization of parabolic equations with a continuum of space and time scales. SIAM J. Numer. Anal. 46 (2007) 1-36. | Zbl | MR

[31] G. Rozza, D.B.P. Huynh and A.T. Patera, Reduced basis approximation and a posteriori error estimation for affinely parametrized elliptic coercive partial differential equations. Application to transport and continuum mechanics. Arch. Comput. Methods Eng. 15 (2008) 229-275. | MR

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