Advanced search
Publication Cover
Applicable Analysis
An International Journal
Volume 101, 2022 - Issue 11: Special issue on the occasion of Professor P. Robert Gilbert's 90th birthday
Submit an article Journal homepage
64
Views
0
CrossRef citations to date
0
Altmetric
Articles

Helmholtz equation for a Neumann condition on a curved boundary: spurious resonances

Armand WirginLMA, CNRS, UPR, 7051, Aix-Marseille Univ, Centrale Marseille, Marseille Cedex, FranceCorrespondence[email protected]
[email protected]
ORCID Iconhttps://orcid.org/0000-0002-4296-9122
ORCID Icon
Pages 3841-3857 | Received 11 Jan 2022, Accepted 09 Feb 2022, Published online: 03 Mar 2022

References

  • Wirgin A. Resonant amplified seismic response within a hill or mountain. 2020. Available from: arXiv:2002.00389v1.
  • Wirgin A. Resonant response of a soft semi-circular cylindrical basin to a SH seismic wave. Bull Seism Soc Am. 1995;85(1):285–299.
  • Sanchez-Sesma FJ, Luzon F. Can horizontal P waves be trapped and resonate in a shallow sedimentary basin? Geophys J Int. 1996;124:209–214.
  • Beskos DE, Dasgupta B, Vardoulakis IG. Vibration isolation using open or filled trenches, part 1: 2-D homogeneous soil. Comput Mech. 1986;1:43–63.
  • Conte E, Dente G. Screening of Rayleigh waves by open trenches. Proc. 3rd Int. Conf. Recent Adv. Geotech. Earthqu. Eng. Soil Dyn., II; Paper 11.18, St. Louis; 1995.
  • Tsaur D-H. Exact scattering and diffraction of antiplane shear waves by a vertical edge crack. Geophys J Int. 2010;181:1655–1664.
  • Lin G, Li Z-Y, Li J-B. Wave scattering and diffraction of subsurface cavities in layered half-space for incident SV-P and SH waves. Int J Numer Anal Methods Geomech. 2019;2019:1–22.
  • Sills LB. Scattering of horizontally-polarized shear waves by surface irregularities. Geophys J R Astr Soc. 1978;54:319–348.
  • Trifunac MD. Scattering of plane SH waves by a semi-cylindrical canyon. Earthqu Eng Struct Dynam. 1973;1:267–281.
  • Beskos DE. Boundary element methods in dynamic analysis. Appl Mech Revs. 1987;40(1):1–24.
  • Cao H, Lee VW. Scattering of plane SH waves by circular cylindrical canyons with variable depth-to-width ratio. Europ Earthqu Eng. 1989;2:29–32.
  • Cao H, Lee VW. Scattering and diffraction of plane P waves by circular cylindrical canyons with variable depth-to-width ratio. Soil Dyn Earthqu Eng. 1990;9(3):141–150.
  • Eslami AH, Anvar SA, Jahanandish M, et al. Effect of canyons and their interaction on ground response to vertically traveling SH waves. JSEE, II (2). 2009;0:71–81.
  • Lee VW. Scattering of plane SH waves by a semi-parabolic cylindrical canyon in an elastic half-space. Int J Geophys. 1990;100:79–86.
  • Lee V, Cao H. Diffraction of SV waves by circular canyons of various depths. J Eng Mech. 1989;115(9):0–00.
  • Manoogian ME, Lee VW. Application of the method of weighted residuals to the scattering and diffraction of elastic SH waves by surface and sub-surface topography of arbitrary shape. 11th WCEE; paper 1231, London: Elsevier; 1996.
  • Sanchez-Sesma FJ. Site effects on strong ground motion. Soil Dyn Earthqu Eng. 1987;6(2):131–137.
  • Sohrabi-Bidar A, Kamalian M, Jafari MK. Seismic response of 3-D Gaussian-shaped valleys to vertically propagating incident waves. Geophys J Int. 2010;183:1429–1442.
  • Stone SF, Ghosh ML, Mal AK. Diffraction of antiplane shear waves by an edge crack. J Appl Mech ASME. 1980;47:359–362.
  • Tsaur D-H, Chang K-H. An analytical approach for the scattering of SH waves by a symmetrical V-shaped canyon: shallow case. Geophys J Int. 2008;174:255–264.
  • Tsaur D-H, Chang K-H, Hsu M-S. An analytical approach for the scattering of SH waves by a symmetrical V-shaped canyon: deep case. Geophys J Int. 2010;183:1501–1511.
  • Wong HL. Effect of surface topography on the diffraction of P, SV and Rayleigh waves. Bull Seism Soc Am. 1982;72(4):1167–1183.
  • Wong HL, Jennings C. Effects of canyon topography on strong ground motion. Bull Seism Soc Am. 1975;65(5):1239–1257.
  • Zhang N, Gao Y, Cai Y, et al. Scattering of SH waves induced by a non-symmetrical V-shaped canyon. Geophys J Int. 2012;191:243–256.
  • Rodriguez-Castellano A, Sanchez-Sesma FJ, Ortiz-Aleman M, et al. Least square approach to simulate wave propagation in irregular profiles using the indirect boundary element method. Soil Dyn Earthqu Eng. 2011;31:385–390.
  • Nowak PS. Effect of nonuniform seismic input on arch dams. 1988. Earthqu. Eng. Res. Lab. Rept. (EERL 88-03, Cal Tech, Pasadena).
  • Nowak PS, Hall JF. Direct boundary element method for dynamics in a half-space. Bull Seism Soc Am. 1993;83(5):1373–1390.
  • Liu YJ, Mukherjee S, Nishimura N, et al. Recent advances and emerging applications of the boundary element method. Appl Mech Rev. 2011;64:03100103101031001–1 –031001–38.
  • Manolis GD, Dineva PS. Elastic waves in continuous and discontinuous geological media by boundary integral equation methods: A review. Soil Dyn Earthqu Eng. 2015;70:11–29.
  • Manolis GD, Dineva PS, Rangelov TV, et al. Seismic wave propagation in non-homogeneous elastic media by boundary elements. Berlin: Springer; 2016.
  • Bard P-Y, Bouchon M. The two-dimensional resonance of sediment-filled valleys. Bull Seism Soc Am. 1985;75(2):519–541.
  • Bendali A, Fares M. Boundary integral equation methods in acoustic scattering. 2007. Available from: http://www.math.univ-toulouse.fr/Archive-MIP/publis/files/07.05.pdf.
  • Buchanan JL, Gilbert RP, Wirgin A, et al. Marine acoustics. Philadelphia (PA): SIAM; 2004.
  • Chen IL, Chen JT, Kuo SR, et al. A new method for true and spurious eigensolutions of arbitrary cavities using the combined Helmholtz exterior integral equation formulation method. J Acoust Soc Am. 2001;109(3):982–998.
  • Chen IL, Chen JT, Liang MT. Analytical study and numerical experiments for radiation and scattering problems using the CHIEF method. J Sound Vibr. 2001;248(5):809–828.
  • Gilbert RP, Xu Y. The seamount problem. In: Angell TS, Cook LP, Kleinman RE, et al., editors. Nonlinear problems in applied mathematics. Philadelphia: SIAM; 1996. p. 140–149.
  • Moshen A, Hesham M. A method for selecting CHIEF points in acoustic scattering. Canad Acoust. 2004;32(1):5–12.
  • Schenck HA. Improved integral formulation for acoustic radiation problems. J Acoust Soc Am. 1968;44(1):41–58.
  • Tadeu A, Godihno L, Santos P. Performance of the BEM solution in 3D acoustic wave scattering. Advan Eng Softw. 2001;32:629–639.
  • Bolomey JC, Tabbara W. Sur la résolution numérique de l'équation des ondes pour des problèmes complémentaires. C R Acad Sci (Paris). 1970;271:933–936.
  • Bolomey JC, Tabbara W. Numerical aspects on coupling between complementary boundary value problems. IEEE Transactions on Antennas and Propagation. 1973;21(3):356–363.
  • Mautz JR, Harrington RF. H-field, E-field and combined field solutions for bodies of revolution. 1977. Tech. Rept. (RADC–TR-77-109), Rome Air Development Center.
  • Mautz JR, Harrington RF. H-field, E-field and combined field solutions for conducting bodies of revolution. Arch Electron Ubertragungstech. 1978;32:159–164.
  • Moshen AAK, Abdelmageed AK. The uniqueness problem of the surface integral equations of a conducting body in a layered medium. Prog Electromag Res. 1999;23:277–300.
  • Sebak AA, Shafai L. Performance of various integral equation formulations for numerical solution of scattering by impedance objects. Canad J Phys. 1984;62(6):320–333.
  • Smith PD. Finite element methods in scalar scattering problems. Colloquium on recent developments in high frequency electromagnetic field analysis by finite element methods. IEE Colloq. (Digest), 1983/48; London: 1983.
  • Wilton DR. Computational methods, Scattering. In: Pike R, Sabatier P, editors. chap. 1.5.5. London: Academic Press; 2002.
  • Xu W, Huang Z. Harmonic resonance mode analysis. IEEE Trans Power Deliv. 2005;20(2):1182–1190.
  • Amini S. An iterative method for the boundary element solution of the exterior acoustic problem. J Comput Appl Math. 1987;20:109–117.
  • Antoine X, Darbas M. Generalized combined field integral equations for the iterative solution of the three-dimensional Helmholtz equation. Math Model Num Anal. 2007;41(1):147–167.
  • Brakhage H, Werner P. Uber das Dirichletsche aussenraumproblem fur die Helmholtzsche Schwingungsgleichung. Archiv Math. 1965;16:325–329.
  • Burton AJ, Miller GF. The application of integral equation methods to the numerical solution of some exterior boundary-value problems. Proc Roy Soc London A. 1971;323:201–210.
  • Chandler-Wilde SN, Langdon S. A Galerkin boundary element method for high frequency scattering by convex polygons. 2006. (Reading U. Num. Anal. Rept. 7/06, Reading).
  • Cheng A, Hong Y. An overview of the method of fundamental solutions-Solvability, uniqueness, convergence, and stability. Eng Anal Bound Elem. 2020;120:118–152.
  • Zaman SI. A comprehensive review of boundary integral formulations of aoustic scattering problems. Science and Technology; Special Review, Sultan Qaboos U. 2000. p. 281–310.
  • Zhang Y-F, Zhou Z-S, Su Z-G, et al. An effective math model for eliminating interior resonance problems of EM scattering. Int J Microw SciTechnol. 2015;724702:00–00. DOI: 10.1155/2015/724702.
  • Wirgin A. On the constant constitutive parameter (e.g. mass density) assumption in integral equation approaches to (acoustic) wave scattering. 2019. Available from: arXiv:1903.09573v1.
  • Morse PM, Feshbach H. Methods of theoretical physics. New York (NY): McGraw Hill; 1953.
  • Mow CC, Pao YH. The diffraction of elastic waves and dynamic stress concentrations. 1971. (RAND Corp.Rept. R-482-PR, Santa Monica) .
  • Abramowitz M, Segun IA. Handbook of mathematical functions. New York (NY): Dover; 1968.
  • Wazwaz A-M. The regularization method for Fredholm integral equations of the first kind. Computers Math Applications. 2011;61(10):2981–2986.
  • Bates RHT, Wall DJN. Null field approach to scalar diffraction I general method. Phil Trans Roy Soc London 1. 1339;287:45–78.
  • Bolomey JC, Wirgin A. Numerical comparison of the Green's function and the Waterman and Rayleigh theories of scattering from a cylinder with arbitrary cross-section. Proc IEEE. 1974;121(8):794–804.
  • Wirgin A. The spurious resonance disease and how to cure it: application to the seismic response of a canyon. 2020. Available from: arXiv:2012.10989v1.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.