Efficient reduced-basis treatment of nonaffine and nonlinear partial differential equations

Issue		ESAIM: M2AN Volume 41, Number 3, May-June 2007


Page(s)		575 - 605
DOI		10.1051/m2an:2007031
Published online		02 August 2007

M2AN, Vol. 41, N°3, pp. 575-605
DOI: 10.1051/m2an:2007031

Efficient reduced-basis treatment of nonaffine and nonlinear partial differential equations

Martin A. Grepl¹, Yvon Maday^{2, 3}, Ngoc C. Nguyen⁴ and Anthony T. Patera⁵

¹ Massachusetts Institute of Technology, Room 3-264, Cambridge, MA, USA.
² Université Pierre et Marie Curie-Paris6, UMR 7598 Laboratoire Jacques-Louis Lions, B.C. 187, 75005 Paris, France. maday@ann.jussieu.fr
³ Division of Applied Mathematics, Brown University.
⁴ Massachusetts Institute of Technology, Room 37-435, Cambridge, MA, USA.
⁵ Massachusetts Institute of Technology, Room 3-266, Cambridge, MA, USA.

(Received April 5, 2006. Revised November 1st, 2006. Published online 2 August 2007.)

Abstract
In this paper, we extend the reduced-basis approximations developed earlier for linear elliptic and parabolic partial differential equations with affine parameter dependence to problems involving (a) nonaffine dependence on the parameter, and (b) nonlinear dependence on the field variable. The method replaces the nonaffine and nonlinear terms with a coefficient function approximation which then permits an efficient offline-online computational decomposition. We first review the coefficient function approximation procedure: the essential ingredients are (i) a good collateral reduced-basis approximation space, and (ii) a stable and inexpensive interpolation procedure. We then apply this approach to linear nonaffine and nonlinear elliptic and parabolic equations; in each instance, we discuss the reduced-basis approximation and the associated offline-online computational procedures. Numerical results are presented to assess our approach.

Mathematics Subject Classification. 35J25, 35J60, 35K15, 35K55.

Key words: Reduced-basis methods, parametrized PDEs, non-affine parameter dependence, offine-online procedures, elliptic PDEs, parabolic PDEs, nonlinear PDEs.

© EDP Sciences, SMAI 2007

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