Diffraction by slender bodies

J. C. Engineer; J. R. King; R. H. Tew

doi:10.1017/S0956792598003441

Abstract

The scattering of high-frequency sound waves by two-dimensional curved boundaries has received much attention over the past few decades, with particular interest in the effects of tangential ray incidence. In the event that the radius of curvature is not small, an analysis near the point of tangency gives rise to the Fock–Leontovič equation for the local field amplitude which, in turn, matches the creeping field of Keller's geometrical theory of diffraction. If the radius of curvature is sufficiently small, however, then this analysis is not valid and it is necessary to solve the full Helmholtz equation in the presence of a parabolic boundary. Under these conditions, which are canonical for diffraction by a sufficiently slender body, results are presented for the case of a plane wave impinging upon an acoustically hard parabolic cylinder. This diffraction process engenders a creeping field at one tip of the slender body, which then propagates around the body to the other tip. Here its energy is partially reflected, partially transmitted and partially radiated out in a detached field. A full description of this is given, along with a discussion of the ‘blunt’ limit in which we show that not only do we get the traditional creeping field of Keller's geometrical theory of diffraction, but also an exponentially small backward-propagating creeping field not predicted by traditional ray methods.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Tew, R.H. Chapman, S.J. King, J.R. Ockendon, J.R. Smith, B.J. and Zafarullah, I. 2000. Scalar wave diffraction by tangent rays. Wave Motion, Vol. 32, Issue. 4, p. 363.

Tew, R. H. 2002. IUTAM Symposium on Diffraction and Scattering in Fluid Mechanics and Elasticity. Vol. 68, Issue. , p. 199.

Andronov, Ivan Viktorovitch and Bouche, Daniel 2011. FORWARD AND BACKWARD WAVES IN HIGH-FREQUENCY DIFFRACTION BY AN ELONGATED SPHEROID. Progress In Electromagnetics Research B, Vol. 29, Issue. , p. 209.

Ockendon, J. R. and Tew, R. H. 2012. Thin-Layer Solutions of the Helmholtz and Related Equations. SIAM Review, Vol. 54, Issue. 1, p. 3.

Andronov, Ivan V. Bouche, Daniel P. and Durufle, Marc 2012. High-Frequency Diffraction of a Plane Electromagnetic Wave by an Elongated Spheroid. IEEE Transactions on Antennas and Propagation, Vol. 60, Issue. 11, p. 5286.

Andronov, Ivan V. 2014. Strong Elongation Versus a Large Transverse Curvature in the Problems of High-Frequency Diffraction. IEEE Antennas and Wireless Propagation Letters, Vol. 13, Issue. , p. 826.

Andronov, I.V. 2014. High-frequency diffraction by an elliptic cylinder: the near field. Journal of Electromagnetic Waves and Applications, Vol. 28, Issue. 18, p. 2318.

Hewett, D.P. 2015. Tangent ray diffraction and the Pekeris caret function. Wave Motion, Vol. 57, Issue. , p. 257.

Andronov, Ivan V. 2015. Uniform Asymptotics for High-Frequency Diffraction by an Elliptic Cylinder. IEEE Antennas and Wireless Propagation Letters, Vol. 14, Issue. , p. 1204.

Andronov, Ivan Viktorovitch and Mittra, Raj 2015. RECENT ADVANCES IN THE ASYMPTOTIC THEORY OF DIFFRACTION BY ELONGATED BODIES (Invited Paper). Progress In Electromagnetics Research, Vol. 150, Issue. , p. 163.

Andronov, Ivan V. and Petrov, Vladimir E. 2016. Diffraction by an Impedance Strip at Almost Grazing Incidence. IEEE Transactions on Antennas and Propagation, Vol. 64, Issue. 8, p. 3565.

Markowskei, Audrey J. and Smith, Paul D. 2017. Measuring the effect of rounding the corners of scattering structures. Radio Science, Vol. 52, Issue. 5, p. 693.

Radjen, Anthony Gradoni, Gabriele and Tew, Richard 2019. Reflection and transmission of high-frequency acoustic, electromagnetic and elastic waves at a distinguished class of irregular, curved boundaries. IMA Journal of Applied Mathematics, Vol. 84, Issue. 6, p. 1203.

Korolkov, A. I. Shanin, A. V. and Belous, A. A. 2019. Diffraction by an Elongated Body of Revolution with Impedance Boundaries: the Boundary Integral Parabolic Equation Method. Acoustical Physics, Vol. 65, Issue. 4, p. 340.

TEW, R.H. 2019. Friedlander–Keller ray expansions and scalar wave reflection at canonically perturbed boundaries. European Journal of Applied Mathematics, Vol. 30, Issue. 1, p. 1.

Shanin, A.V. and Korolkov, A.I. 2019. Diffraction by an elongated body of revolution. A boundary integral equation based on the parabolic equation. Wave Motion, Vol. 85, Issue. , p. 176.

RADJEN, A. M. R. TEW, R. H. and GRADONI, G. 2023. Friedlander-Keller ray expansions in electromagnetism: Monochromatic radiation from arbitrary surfaces in three dimensions. European Journal of Applied Mathematics, Vol. 34, Issue. 6, p. 1187.

Andronov, Ivan 2023. Problems of High Frequency Diffraction by Elongated Bodies. Vol. 243, Issue. , p. 1.

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Diffraction by slender bodies

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