An extension of general identities for 3D water-wave diffraction with application to the diffraction transfer matrix

Flavià, F. Fàbregas; Meylan, M. H.

Title: An extension of general identities for 3D water-wave diffraction with application to the diffraction transfer matrix
Creator: Flavià, F. Fàbregas; Meylan, M. H.
Relation: Applied Ocean Research Vol. 84, Issue March 2019, p. 279-290
Publisher Link: http://dx.doi.org/10.1016/j.apor.2018.12.013
Publisher: Elsevier
Resource Type: journal article
Date: 2019
Description: Interaction theories are used in numerous branches of physics to efficiently evaluate wave scattering by multiple obstacles. An example of these interaction theories is the direct matrix method introduced by Kagemoto and Yue [1], which enables fast computation of three-dimensional water-wave multiple-scattering problems. The building block of interaction theories is a mathematical operator that encapsulates the mapping between incident and scattered waves. This operator is generally referred to as T-matrix and satisfies both reciprocity and energy identities. In some branches of physics, such as acoustics and electromagnetism, these identities are well established; in hydrodynamics, however, they have only been derived for a T-matrix that maps two-dimensional incident and scattered water waves. In three dimensions, water waves can be represented as a series expansion of cylindrical eigenfunctions. In this paper, we use this representation of water waves to derive the reciprocity and energy identities satisfied by the T-matrix of the direct matrix method, known as Diffraction Transfer Matrix (dtm). The identities derived herein represent an extension of existing general relations between two diffraction solutions. We show that this extension can be applied to verify the accuracy of the dtm entries, thereby increasing the reliability of existing schemes for computing the dtm. We present results for the dtm of two geometrically different isolated obstacles, as well as for the dtm of an asymmetric array. Finally, we demonstrate that the results presented herein can be extended to floating bodies found in a wide range of ocean engineering problems.
Subject: multiple scattering; interaction theory; direct matrix method; diffraction transfer matrix; boundary element method
Identifier: http://hdl.handle.net/1959.13/1414683
Identifier: uon:36798
Identifier: ISSN:0141-1187
Language: eng
Full Text
Reviewed

Hits: 1544
Visitors: 1806
Downloads: 279

		Thumbnail	File	Description	Size	Format
View Details Download			ATTACHMENT02	Author final version	725 KB	Adobe Acrobat PDF	View Details Download