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Journal of Engineering Mathematics

Erschienen in:

31.07.2020

Discrete scattering by two staggered semi-infinite defects: reduction of matrix Wiener–Hopf problem

verfasst von: Basant Lal Sharma

Erschienen in: Journal of Engineering Mathematics | Ausgabe 1/2020

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Abstract

As an extension of the discrete Sommerfeld problems on lattices, the scattering of a time-harmonic wave is considered on an infinite square lattice when there exists a pair of semi-infinite cracks or rigid constraints. Due to the presence of stagger, also called offset, in the alignment of the defect edges the asymmetry in the problem leads to a matrix Wiener–Hopf kernel that cannot be reduced to scalar Wiener–Hopf in any known way. In the corresponding continuum model the same problem is a well-known formidable one which possesses certain special structure with exponentially growing elements on the diagonal of kernel. From this viewpoint the present paper tackles a discrete analog of the same by reformulating the Wiener–Hopf problem and reducing it to a finite set of linear algebraic equations; the coefficients of which can be found by an application of the scalar Wiener–Hopf factorization. The considered discrete paradigm involving lattice waves is relevant for modern applications of mechanics and physics at small length scales.

Vorheriger Artikel Properties of boundary-layer flow solutions for non-Newtonian fluids with non-linear terms of first and second-order derivatives

Nächster Artikel The radially symmetric Green’s function for Dirichlet problem of Pennes equation outside of a circular domain

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For convenience of writing some long expressions, the notation \({A}^\dagger \) is adopted to denote the reciprocal, multiplicative inverse of A (for matrix functions, it denotes the inverse matrix function while for non-zero real functions, it is simply the algebraic reciprocal).

Here, for the multiplicative factorization of an admissible f, \(f({z})=f_+({z})f_-({z})\) with \(f_+({z})=\sum _{m\in {\mathbb {Z}}^+}f_m{z}^{-m}\) and \(f_-({z})=\sum _{m\in {\mathbb {Z}}^-\cup \{0\}}f_m{z}^{-m}\); note that \(m=0\) is in general present in the Fourier expansion of multiplicative factors. Typically, depending on f a property \(f_+(1/z)=f_-(z)\) can be also be incorporated so that \(f_+(\infty )=f_-(\infty )\).

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Titel: Discrete scattering by two staggered semi-infinite defects: reduction of matrix Wiener–Hopf problem
verfasst von: Basant Lal Sharma
Publikationsdatum: 31.07.2020
Verlag: Springer Netherlands
Erschienen in: Journal of Engineering Mathematics / Ausgabe 1/2020
Print ISSN: 0022-0833
Elektronische ISSN: 1573-2703
DOI: https://doi.org/10.1007/s10665-020-10054-7

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