A well-conditioned integral equation for iterative solution of scattering problems with a variable Leontovitch boundary condition

Pernet, Sébastien

Pernet, Sébastien

ESAIM: Mathematical Modelling and Numerical Analysis - Modélisation Mathématique et Analyse Numérique, Tome 44 (2010), p. 781-801 / Harvested from Numdam

Access to full text
Full (PDF)
Full (DJVU)

Résumé

The construction of a well-conditioned integral equation for iterative solution of scattering problems with a variable Leontovitch boundary condition is proposed. A suitable parametrix is obtained by using a new unknown and an approximation of the transparency condition. We prove the well-posedness of the equation for any wavenumber. Finally, some numerical comparisons with well-tried method prove the efficiency of the new formulation.

Publié le : 2010-01-01

MR 2683583 | Zbl 1205.78025

DOI : https://doi.org/10.1051/m2an/2010023
Classification: 65R20, 15A12, 65N38, 65F10, 65Z05

@article{M2AN_2010__44_4_781_0,
     author = {Pernet, S\'ebastien},
     title = {A well-conditioned integral equation for iterative solution of scattering problems with a variable Leontovitch boundary condition},
     journal = {ESAIM: Mathematical Modelling and Numerical Analysis - Mod\'elisation Math\'ematique et Analyse Num\'erique},
     volume = {44},
     year = {2010},
     pages = {781-801},
     doi = {10.1051/m2an/2010023},
     mrnumber = {2683583},
     zbl = {1205.78025},
     language = {en},
     url = {http://dml.mathdoc.fr/item/M2AN_2010__44_4_781_0}
}

Pernet, Sébastien. A well-conditioned integral equation for iterative solution of scattering problems with a variable Leontovitch boundary condition. ESAIM: Mathematical Modelling and Numerical Analysis - Modélisation Mathématique et Analyse Numérique, Tome 44 (2010) pp. 781-801. doi : 10.1051/m2an/2010023. http://gdmltest.u-ga.fr/item/M2AN_2010__44_4_781_0/

Bibliographie

[1] F. Alouges, S. Borel and D. Levadoux, A stable well conditioned integral equation for electromagnetism scattering. J. Comput. Appl. Math. 204 (2007) 440-451. | Zbl 1127.78005

[2] X. Antoine and H. Barucq, Microlocal diagonalization of strictly hyperbolic pseudodifferential systems and application to the design of radiation conditions in electromagnetism. SIAM J. Appl. Math. 61 (2001) 1877-1905. | Zbl 0983.35138

[3] X. Antoine and M. Darbas, Generalized combined field integral equations for the iterative solution of the three-dimensional Helmholtz equation. ESAIM: M2AN 41 (2007) 147-167. | Numdam | Zbl 1123.65117

[4] A. Bendali, M'B Fares and J. Gay, A boundary-element solution of the Leontovitch problem. IEEE Trans. Antennas Propagat. 47 (1999) 1597-1605. | Zbl 0949.78017

[5] Y. Boubendir, Techniques de décomposition de domaine et méthode d'équations intégrales. Ph.D. Thesis, INSA, France (2002).

[6] A. Buffa, Hodge decomposition on the boundary of a polyhedron: the multi-connected case. Math. Mod. Meth. Appl. Sci. 11 (2001) 1491-1504. | Zbl 1014.58002

[7] A. Buffa and R. Hiptmair, Galerkin Boundary Element Methods for Electromagnetic Scattering, in Computational Methods in Wave Propagation, M. Ainsworth, P. Davies, D.B. Duncan, P.A. Martin and B. Rynne Eds., Lecture Notes in Computational Science and Engineering 31, Springer-Verlag (2003) 83-124. | Zbl 1055.78013

[8] F. Cakoni, D. Colton and P. Monk, The electromagnetic inverse scattering problem for partially coated Lipschitz domains. Proc. Royal. Soc. Edinburgh 134A (2004) 661-682. | Zbl 1071.78021

[9] S.L. Campbell, I.C.F. Ipsen, C.T. Kelley, C.D. Meyer and Z.Q. Xue, Convergence estimates for solution of integral equations with GMRES. Tech. Report CRSC-TR95-13, North Carolina State University, Center for Research in Scientific Computation, USA (1995). | Zbl 0859.65137

[10] S.L. Campbell, I.C.F. Ipsen, C.T. Kelley and C.D. Meyer, GMRES and the Minimal Polynomial. BIT Numerical Mathematics 36 (1996) 664-675. | Zbl 0865.65017

[11] H.S. Christiansen, Résolution des équations intégrales pour la diffraction d'ondes acoustiques et électromagnétiques - Stabilisation d'algorithmes itératifs et aspects de l'analyse numérique. Ph.D. Thesis, Centre de Mathématiques Appliquées, UMR 7641, CNRS/École polytechnique, France (2002).

[12] S. Christiansen and J.C. Nédélec, A preconditioner for the electric field integral equation based on Calderon formulas. SIAM J. Numer. Anal. 40 (2002) 1100-1135. | Zbl 1021.78010

[13] F. Collino, S. Ghanemi and P. Joly, Domain decomposition method for the Helmholtz equation: a general presentation. Comput. Methods Appl. Mech. Eng. 184 (2000) 171-211. | Zbl 0965.65134

[14] F. Collino, F. Millot and S. Pernet, Boundary-integral methods for iterative solution of scattering problems with variable impedance surface condition. PIER 80 (2008) 1-28.

[15] D. Colton and R. Kress, Inverse acoustic and electromagnetic scattering theory, Applied Mathematical Sciences 93. Springer, Berlin, Germany (1992). | Zbl 0760.35053

[16] M. Darbas, Préconditionneurs analytiques de type Calderon pour les formulations intégrales des problèmes de direction d'ondes. Ph.D. Thesis, INSA Toulouse, France (2004).

[17] M. Darbas, Generalized CFIE for the Iterative Solution of 3-D Maxwell Equations. Appl. Math. Lett. 19 (2006) 834-839. | Zbl 1135.78012

[18] M. Darbas, Some second-kind integral equations in electromagnetism. Preprint, Cahiers du Ceremade 2006-15 (2006) http://www.ceremade.dauphine.fr/preprints/CMD/2006-15.pdf.

[19] V. Frayssé, L. Giraud, S. Gratton and J. Langou, A Set of GMRES Routines for Real and Complex Arithmetics on High Performance Computers. CERFACS Technical Report, TR/PA/03/3 (2003) http://www.cerfacs.fr/algor/Softs/GMRES/index.html.

[20] J.-F. Lee, R. Lee and R.J. Burkholder, Loop star basis functions and a robust preconditioner for EFIE scattering problems. IEEE Trans. Antennas Propagat. 51 (2003) 1855-1863.

[21] M.A. Leontovitch, Approximate boundary conditions for the electromagnetic field on the surface of a good conductor, Investigations Radiowave Propagation part II. Academy of Sciences, Moscow, Russia (1978).

[22] J.R. Mautz and R.F. Harrington, A combined-source solution for radiation and scattering from a perfectly conducting body. IEEE Trans. Antennas Propag. AP-27 (1979) 445-454.

[23] F.A. Milinazzo, C.A. Zala, G.H. Brooke, Rational square-root approximations for parabolic equation algorithms. J. Acoust. Soc. Am. 101 (1997) 760-766.

[24] K.M. Mitzner, Numerical solution of the exterior scattering problem at eigenfrequencies of the interior problem. Int. Scientific Radio Union Meeting, Boston, USA (1968).

[25] P. Monk, Finite Element Methods for Maxwell's Equations, Numerical Mathematics and Scientific Computation. Oxford Science Publication, UK (2003). | Zbl 1024.78009

[26] Multifrontal Massively Parallel Solver, www.enseeiht.fr/lima/apo/MUMPS.

[27] J.C. Nédélec, Acoustic and Electromagnic Equations Integral Representation for Harmonic Problems. Springer, New York, USA (2001). | Zbl 0981.35002

[28] S.M. Rao, D.R. Wilton and A.W. Glisson, Electromagnetic scattering by surfaces of arbitrary shape. IEEE Trans. Antennas Propagat. AP-30 (1982) 409-418.

[29] V. Rokhlin, Diagonal form of translation operators for the Helmholtz equation in three dimensions. Appl. Comput. Harmon. Anal. 1 (1993) 82-93. | Zbl 0795.35021

[30] O. Steinbach and W.L. Wendland, The construction of some efficient preconditioners in the boundary element method. Adv. Comput. Math. 9 (1998) 191-216. | Zbl 0922.65076

[31] B. Stupfel, A hybrid finite element and integral equation domain decomposition method for the solution of the 3-D scattering problem. J. Comput. Phys. 172 (2001) 451-471. | Zbl 0992.78014