Approximation by generalized impedance boundary conditions of a transmission problem in acoustic scattering

Xavier Antoine; Hélène Barucq

ESAIM: Mathematical Modelling and Numerical Analysis (2010)

  • Volume: 39, Issue: 5, page 1041-1059
  • ISSN: 0764-583X

Abstract

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This paper addresses some results on the development of an approximate method for computing the acoustic field scattered by a three-dimensional penetrable object immersed into an incompressible fluid. The basic idea of the method consists in using on-surface differential operators that locally reproduce the interior propagation phenomenon. This approach leads to integral equation formulations with a reduced computational cost compared to standard integral formulations coupling both the transmitted and scattered waves. Theoretical aspects of the problem and numerical experiments are reported to analyze the efficiency of the method and precise its validity domain.

How to cite

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Antoine, Xavier, and Barucq, Hélène. "Approximation by generalized impedance boundary conditions of a transmission problem in acoustic scattering." ESAIM: Mathematical Modelling and Numerical Analysis 39.5 (2010): 1041-1059. <http://eudml.org/doc/194290>.

@article{Antoine2010,
abstract = { This paper addresses some results on the development of an approximate method for computing the acoustic field scattered by a three-dimensional penetrable object immersed into an incompressible fluid. The basic idea of the method consists in using on-surface differential operators that locally reproduce the interior propagation phenomenon. This approach leads to integral equation formulations with a reduced computational cost compared to standard integral formulations coupling both the transmitted and scattered waves. Theoretical aspects of the problem and numerical experiments are reported to analyze the efficiency of the method and precise its validity domain. },
author = {Antoine, Xavier, Barucq, Hélène},
journal = {ESAIM: Mathematical Modelling and Numerical Analysis},
keywords = {Helmholtz equation; acoustics; integral equations; generalized impedance boundary conditions; existence and uniqueness results.; existence and uniqueness results.},
language = {eng},
month = {3},
number = {5},
pages = {1041-1059},
publisher = {EDP Sciences},
title = {Approximation by generalized impedance boundary conditions of a transmission problem in acoustic scattering},
url = {http://eudml.org/doc/194290},
volume = {39},
year = {2010},
}

TY - JOUR
AU - Antoine, Xavier
AU - Barucq, Hélène
TI - Approximation by generalized impedance boundary conditions of a transmission problem in acoustic scattering
JO - ESAIM: Mathematical Modelling and Numerical Analysis
DA - 2010/3//
PB - EDP Sciences
VL - 39
IS - 5
SP - 1041
EP - 1059
AB - This paper addresses some results on the development of an approximate method for computing the acoustic field scattered by a three-dimensional penetrable object immersed into an incompressible fluid. The basic idea of the method consists in using on-surface differential operators that locally reproduce the interior propagation phenomenon. This approach leads to integral equation formulations with a reduced computational cost compared to standard integral formulations coupling both the transmitted and scattered waves. Theoretical aspects of the problem and numerical experiments are reported to analyze the efficiency of the method and precise its validity domain.
LA - eng
KW - Helmholtz equation; acoustics; integral equations; generalized impedance boundary conditions; existence and uniqueness results.; existence and uniqueness results.
UR - http://eudml.org/doc/194290
ER -

References

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  1. X. Antoine, Conditions de Radiation sur le Bord. Ph.D. Thesis, No. d'ordre 395, Université de Pau et des Pays de l'Adour, France (1997).  
  2. X. Antoine, Fast approximate computation of a time-harmonic scattered field using the on-surface radiation condition method. IMA J. Appl. Math.66 (2001) 83.  
  3. X. Antoine and H. Barucq, On the construction of approximate boundary conditions for solving the interior problem of the acoustic scattering transmission problem, in Domain Decomposition Methods in Science and Engineering. R. Kornhuber, R. Hoppe, J. Periaux, O. Pironneau, O. Widlund, J. Xu, Eds., Springer Series. Lect. Notes Comput. Sci. Engrg.40 (2004) 133–140.  
  4. X. Antoine, H. Barucq and L. Vernhet, Approximate solution for the scattering of a time-harmonic wave by a homogeneous dissipative obstacle. Internal Report MIP 00-20, Laboratoire MIP, Toulouse (2000).  
  5. X. Antoine, H. Barucq and L. Vernhet, High-frequency asymptotic analysis of a dissipative transmission problem resulting in generalized impedance boundary conditions. Asymptot. Anal.26 (2001) 257.  
  6. X. Antoine, A. Bendali and M. Darbas, Analytic preconditioners for the electric field integral equation. Internat. J. Numer. Methods Engrg.61 (2004) 1310–1331.  
  7. X. Antoine, A. Bendali and M. Darbas, Analytic preconditioners for the boundary integral solution of the scattering of acoustic waves by open surfaces. J. Comput. Acoustics, Special Issue on High Performance Scientific Computing in Acoustics 13 (2005). To appear.  
  8. A. Bendali, Approximation par éléments Finis de surface de problèmes de diffraction des ondes électromagnétiques. Thèse de Doctorat, Université Paris VI (1984).  
  9. A. Bendali and M. Souilah, Consistency estimates for a double-layer potential and application to the numerical analysis of the boundary-element approximation of acoustic scattering by a penetrable object. Math. Comp.62 (1994) 65.  
  10. B. Carpinteri, I.S. Duff and L. Giraud, Experiments with sparse preconditioning of dense problems of electromagnetic applications. Technical Report TR/PA/00/04, CERFACS, France (2000).  
  11. B. Carpinteri, I.S. Duff and L. Giraud, Sparse pattern selection strategies for robust Frobenius norm minimization preconditioners in electromagnetism. Numer. Linear Algebra Appl.7 (2000) 667.  
  12. J. Chazarain and A. Piriou, Introduction to the Theory of Linear Partial Differential Equations. North-Holland, Amsterdam/New-York (1982).  
  13. K. Chen and P.J. Harris, Efficient preconditioners for iterative solution of the boundary element equations for the three-dimensional Helmholtz equation. Appl. Numer. Math.36 (2001) 475.  
  14. S.H. Christiansen and J.C. Nédélec, Des préconditionneurs pour la résolution numérique des équations intégrales de frontière de l'acoustique. C. R. Acad. Sci. Paris Sér. I Math.330 (2000) 617.  
  15. P.G. Ciarlet, Handbook of Numerical Analysis, Vol. II, Finite Element Methods (Part I). P.G. Ciarlet and J.-L. Lions, Eds., Elsevier Science Publisher, North-Holland, Amsterdam (1991).  
  16. D. Colton and R. Kress, Integral Equation Methods in Scattering Theory. Krieger Publishing Company (1992).  
  17. M. Costabel, Boundary integral operators on Lipschitz domains: elementary results. SIAM J. Math. Anal.19 (1988) 613.  
  18. M. Costabel and E. Stephan, A direct boundary integral equation method for transmission problems. J. Math. Anal. Appl.136 (1985) 367.  
  19. E. Darrigrand, Coupling of fast multipole method and microlocal discretization for the 3-D Helmholtz equation. J. Comput. Phys.181 (2002) 126.  
  20. E. Darve, The fast multipole method. I. Error analysis and asymptotic complexity. SIAM J. Numer. Anal.38 (2000) 98.  
  21. E. Darve, The fast multipole method: numerical implementation. J. Comput. Phys.160 (2000) 195.  
  22. R. Djellouli, C. Farhat, A. Macedo and R. Tezaur, Three-dimensional finite element calculations in acoustic solution scattering using arbitrarily convex artificial boundaries. Internat. J. Numer. Methods Engrg.53 (2002) 1461.  
  23. D.S. Jones, An improved surface radiation condition. IMA J. Appl. Math.48 (1992) 163.  
  24. R.E. Kleinman and P.A. Martin, On single integral equations for the transmission problem of acoustics. SIAM J. Appl. Math.48 (1988) 307.  
  25. G.A. Kriegsmann, A. Taflove and K.R. Umashankar, A new formulation of electromagnetic wave scattering using the on-surface radiation condition approach. IEEE Trans. Antennas Prop.35 (1987) 153.  
  26. D. Levadoux, Étude d'une équation intégrale adaptée à la résolution haute-fréquence de l'équation d'Helmholtz. Thèse de Doctorat, Université Paris VI (2001).  
  27. D. Levadoux and B. Michielsen, Nouvelles formulations intégrales pour les problèmes de diffraction d'ondes. ESAIM: M2AN38 (2004) 157–175.  
  28. J.C. Nédélec, Acoustic and Electromagnetic Equations, Integral Representations for Harmonic Problems. Springer-Verlag, New York. Appl. Math. Sci.144 (2001).  
  29. F. Rellich, Über das asymptotische verhalten der lösungen von Δu + λu = 0, in unendlichen gebieten, Jahresber. Deutch. Math. Verein53 (1943) 57.  
  30. V. Rokhlin, Rapid solution of integral equations of scattering theory in two dimensions. J. Comput. Phys.86 (1990) 414.  
  31. S.M. Rytov, Calcul du skin-effect par la méthode des perturbations. J. Phys. USSR2 (1940) 233.  
  32. Y. Saad, Iterative Methods for Sparse Linear Systems. PWS Pub. Co., Boston (1996).  
  33. T.B.A. Senior, Impedance boundary conditions for imperfectly conducting surface. Appl. Sci. Res. B.8 (1960) 418.  
  34. T.B.A. Senior, Approximate boundary conditions for homogeneous dielectric bodies. J. Electromagnet. Wave9 (1995) 1227.  
  35. T.B.A. Senior, Generalized boundary conditions for scalar fields. J. Acoust. Soc. Amer.97 (1995) 3473.  
  36. T.B.A. Senior and J.L. Volakis, Approximate Boundary Conditions in Electromagnetics. IEE Electromagnetic Waves, Serie 41, London (1995).  
  37. T.B.A. Senior, J.L. Volakis and S.R. Legault, Higher order impedance and absorbing boundary conditions. IEEE Trans. Antennas Prop.45 (1997) 107.  
  38. O. Steinbach and W.L. Wendland, The construction of some efficient preconditioners in the boundary element method. Adv. Comput. Math.9 (1998) 191.  
  39. L. Vernhet, Approximation par éléments finis de frontière de problèmes de diffraction d'ondes avec condition d'impédance. Ph.D. Thesis, Université de Pau et des Pays de l'Adour, No. 400, France (1997).  
  40. L. Vernhet, Boundary element solution of a scattering problem involving a generalized impedance boundary condition. Math. Methods Appl. Sci.22 (1999) 587.  
  41. D.S. Wang, Limits and validity of the impedance boundary condition on penetrable surfaces. IEEE. Trans. Antennas Prop.35 (1987) 453.  

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