Difference between revisions of "Category:Infinite Array"
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− | = Introduction = | + | == Introduction == |
An infinite array is a structure in which the scattering body repeats periodically to infinity in both directions. Making use of the periodicity of the structure as well as that of the incident wave, the problem can be reduced to having to solve for one body. The scattered potential of all other bodies is obtained by simple phase shift. | An infinite array is a structure in which the scattering body repeats periodically to infinity in both directions. Making use of the periodicity of the structure as well as that of the incident wave, the problem can be reduced to having to solve for one body. The scattered potential of all other bodies is obtained by simple phase shift. | ||
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to the infinite array and travel along it. | to the infinite array and travel along it. | ||
− | = Literature Survey = | + | == Literature Survey == |
There are two approaches to the solution of wave scattering by an infinite array, methods based on | There are two approaches to the solution of wave scattering by an infinite array, methods based on | ||
Line 28: | Line 28: | ||
In the present context of water wave propagation and its interaction | In the present context of water wave propagation and its interaction | ||
− | with flexible surface structures, | + | with flexible surface structures, [[Chou 1998]] has investigated |
the effect of an infinite doubly-periodic array of elastic plates | the effect of an infinite doubly-periodic array of elastic plates | ||
on wave propagation. In the modelling of the plate equations, | on wave propagation. In the modelling of the plate equations, | ||
Line 36: | Line 36: | ||
(as considered here), but also, by setting the stiffness to zero, | (as considered here), but also, by setting the stiffness to zero, | ||
pure tensional effects which would describe, for example, periodic arrays of | pure tensional effects which would describe, for example, periodic arrays of | ||
− | taught membranes. | + | taught membranes. The doubly-periodic configuration allows significant simplification |
− | |||
in the solution procedure by applying Floquet's theorem to reduce | in the solution procedure by applying Floquet's theorem to reduce | ||
the problem to one on a finite domain with periodic boundary | the problem to one on a finite domain with periodic boundary | ||
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number of distinct plane waves propagating away from the array at | number of distinct plane waves propagating away from the array at | ||
certain discrete angles will occur. In the context of water waves and | certain discrete angles will occur. In the context of water waves and | ||
− | fixed periodic arrays, | + | fixed periodic arrays, [[Twersky 1952]] was able to solve the problem |
of a periodic array of vertical circular cylinders. The uniformity of | of a periodic array of vertical circular cylinders. The uniformity of | ||
the configuration in the depth coordinate implies that the resulting | the configuration in the depth coordinate implies that the resulting | ||
equations also describe two-dimensional acoustic wave scattering, in | equations also describe two-dimensional acoustic wave scattering, in | ||
− | this case by circular cylinders. The problem of | + | this case by circular cylinders. The infinite periodic-array problem in the context of water |
+ | waves was considered by [[Spring and Monkmeyer 1975]], [[Miles 1983]], although | ||
+ | the mathematical techniques for handling such arrays have a much older | ||
+ | provenance dating back to early twentieth century work on diffraction | ||
+ | gratings, e.g. [[von Ignatowsky 1914]]. All of the methods | ||
+ | developed were for scattering bodies that have simple cylindrical | ||
+ | geometry. This leads to a great simplification because the solution | ||
+ | to the scattering problem can be found by separation of variables. If we | ||
+ | want to consider scattering by a periodic array of scatterers of arbitrary | ||
+ | geometry we require a modification to these scattering theories. | ||
+ | |||
+ | |||
+ | The problem of [[Twersky 1952]], who | ||
used Schlomilch series to sum slowly-convergent series involving | used Schlomilch series to sum slowly-convergent series involving | ||
− | Hankel functions, was re-considered by Linton and Evans [[ | + | Hankel functions, was re-considered by Linton and Evans [[Linton and Evans 1993]] who |
used a so-called multipole method. For periodic arrays of rectangular | used a so-called multipole method. For periodic arrays of rectangular | ||
− | cylinders extending uniformly through the depth, Fernyhough and Evans [[ | + | cylinders extending uniformly through the depth, Fernyhough and Evans [[Fernyhough and Evans 1995]], |
used domain decomposition and mode matching to derive an | used domain decomposition and mode matching to derive an | ||
integral equation formulation to the problem. In order to consider more | integral equation formulation to the problem. In order to consider more | ||
Line 66: | Line 77: | ||
the Green function consists of a series involving Hankel functions | the Green function consists of a series involving Hankel functions | ||
which is slowly convergent and unsuitable for numerical computation. | which is slowly convergent and unsuitable for numerical computation. | ||
− | Hence | + | Hence [[Linton 1998]] compared a number of different representations of |
the periodic Green function, designed to increase the convergence | the periodic Green function, designed to increase the convergence | ||
− | characteristics. Porter and Evans | + | characteristics. [[Porter and Evans 1999]] used the work of [[Linton 1998]] |
to compute so-called Rayleigh-Bloch waves (or trapped waves) along a | to compute so-called Rayleigh-Bloch waves (or trapped waves) along a | ||
periodic array of cylinders of arbitrary cross-section. A number of | periodic array of cylinders of arbitrary cross-section. A number of | ||
papers in recent years have concentrated on similar ideas, to those of | papers in recent years have concentrated on similar ideas, to those of | ||
− | Porter and Evans | + | [[Porter and Evans 1999]], a primary motivation being the connection between |
large wave responses in large finite arrays of cylinders and the trapped | large wave responses in large finite arrays of cylinders and the trapped | ||
− | waves in infinite periodic arrays (see Maniar and Newman | + | waves in infinite periodic arrays (see [[Maniar and Newman 1997]]). |
− | == [[Infinite Array Green Function]] methods == | + | === [[Infinite Array Green Function]] methods === |
After [[Removing the Depth Dependence]] and the water wave problem reduces to [[Helmholtz's Equation]]. | After [[Removing the Depth Dependence]] and the water wave problem reduces to [[Helmholtz's Equation]]. | ||
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absolutely convergent). | absolutely convergent). | ||
− | == [[Interaction Theory for Infinite Arrays]] methods == | + | === [[Interaction Theory for Infinite Arrays]] methods === |
We can use [[:Category:Interaction Theory|Interaction Theory]] to solve for and infinite array. | We can use [[:Category:Interaction Theory|Interaction Theory]] to solve for and infinite array. |
Latest revision as of 05:41, 28 April 2009
Introduction
An infinite array is a structure in which the scattering body repeats periodically to infinity in both directions. Making use of the periodicity of the structure as well as that of the incident wave, the problem can be reduced to having to solve for one body. The scattered potential of all other bodies is obtained by simple phase shift.
The infinite array is often used as an approximation for a finite array as its solution is very much simpler. Besides allowing the approximation of quantities associated with particular bodies in the array (the forces upon the body, e.g.), it also directly provides information about the far field away from the array.
The infinite-array problem is also often met in other applications, for example in acoustic of electromagnetic scattering, where it is also termed diffraction grating.
There is a vast literature on this problem dating back to early twentieth century work. Recently, a solution was suggested in Peter, Meylan, and Linton 2006 which, in particular, applies to arbitrary scatterers.
Associated with infinite arrays is the phenomenon of Rayleigh-Bloch Waves, which are waves which are bound to the infinite array and travel along it.
Literature Survey
There are two approaches to the solution of wave scattering by an infinite array, methods based on Infinite Array Green Function and methods based on Interaction Theory. Also there are two problems which may be considered. The first is to determine the scattering by an incident plate wave and the second is to determine what waves are supported by the structure in the absense of wave forcing (called in the water wave context Rayleigh-Bloch Waves).
The problem of determining the scattering of waves by periodic arrays of obstacles subject to wave forcing has received considerable research attention and spans a broad range of physical disciplines including solid-state physics, acoustics, optics, etc. In many applications, the interest centres on arrangements which are periodic in two directions (for example, the study of crystallography).
In the present context of water wave propagation and its interaction with flexible surface structures, Chou 1998 has investigated the effect of an infinite doubly-periodic array of elastic plates on wave propagation. In the modelling of the plate equations, Chou incorporates both bending stiffness and tension effects, so that the discussion of the results not only includes the case of pure bending of elastic plates in the absence of compression forces (as considered here), but also, by setting the stiffness to zero, pure tensional effects which would describe, for example, periodic arrays of taught membranes. The doubly-periodic configuration allows significant simplification in the solution procedure by applying Floquet's theorem to reduce the problem to one on a finite domain with periodic boundary conditions. Moreover, problems involving infinite doubly-periodic structures only offer information about the possibility of wave propagation throughout the array (in the form of so-called pass-bands or stop-bands) and cannot address the diffraction of plane waves from infinity.
For arrays which are periodic in one direction only, the situation is different and diffraction grating effects occur. Thus, for an incident plane wave of a particular given wave frequency, a finite number of distinct plane waves propagating away from the array at certain discrete angles will occur. In the context of water waves and fixed periodic arrays, Twersky 1952 was able to solve the problem of a periodic array of vertical circular cylinders. The uniformity of the configuration in the depth coordinate implies that the resulting equations also describe two-dimensional acoustic wave scattering, in this case by circular cylinders. The infinite periodic-array problem in the context of water waves was considered by Spring and Monkmeyer 1975, Miles 1983, although the mathematical techniques for handling such arrays have a much older provenance dating back to early twentieth century work on diffraction gratings, e.g. von Ignatowsky 1914. All of the methods developed were for scattering bodies that have simple cylindrical geometry. This leads to a great simplification because the solution to the scattering problem can be found by separation of variables. If we want to consider scattering by a periodic array of scatterers of arbitrary geometry we require a modification to these scattering theories.
The problem of Twersky 1952, who
used Schlomilch series to sum slowly-convergent series involving
Hankel functions, was re-considered by Linton and Evans Linton and Evans 1993 who
used a so-called multipole method. For periodic arrays of rectangular
cylinders extending uniformly through the depth, Fernyhough and Evans Fernyhough and Evans 1995,
used domain decomposition and mode matching to derive an
integral equation formulation to the problem. In order to consider more
general cylinder profiles, boundary integral methods are inevitable and
require the use of a periodic Green function. In its most basic form,
the Green function consists of a series involving Hankel functions
which is slowly convergent and unsuitable for numerical computation.
Hence Linton 1998 compared a number of different representations of
the periodic Green function, designed to increase the convergence
characteristics. Porter and Evans 1999 used the work of Linton 1998
to compute so-called Rayleigh-Bloch waves (or trapped waves) along a
periodic array of cylinders of arbitrary cross-section. A number of
papers in recent years have concentrated on similar ideas, to those of
Porter and Evans 1999, a primary motivation being the connection between
large wave responses in large finite arrays of cylinders and the trapped
waves in infinite periodic arrays (see Maniar and Newman 1997).
Infinite Array Green Function methods
After Removing the Depth Dependence and the water wave problem reduces to Helmholtz's Equation. In this context a method to solve using the Infinite Array Green Function was presented by Porter and Evans 1999. For the more complicated problem where the depth dependence cannot be removed the Infinite Array Green Function method was used by Wang, Meylan, and Porter 2006 to solve for an Infinite Array of Floating Elastic Plates. The majoy challenge is to deal with very slowly convergent series (series which are not absolutely convergent).
Interaction Theory for Infinite Arrays methods
We can use Interaction Theory to solve for and infinite array. In general, we still need to solve for the individual scatterers using the Green Function Solution Method and we also have to consider slowly convergent series. Interaction Theory for Infinite Arrays do have some advantages and probably offer a superior method to solve the problem.
Pages in category "Infinite Array"
The following 4 pages are in this category, out of 4 total.