Difference between revisions of "Kagemoto and Yue Interaction Theory"

\includegraphics[height=5.5cm]{floe_tri}

\caption{Plan view of the relation between two bodies.} (fig:floe_tri)

The scattered potential of body <math>\Delta_j</math> can be expanded in

cylindrical eigenfunctions,

\phi_j^\mathrm{S} (r_j,\theta_j,z) &= \mathrm{e}^{\alpha z} \sum_{\nu = -

\theta_j} \mathrm{d}\eta,

where the coefficients <math>A_{0 \nu}^j</math> for the propagating modes are

discrete and the coefficients <math>A_{\nu}^j (\cdot)</math> for the decaying

modes are functions. <math>H_\nu^{(1)}</math> and <math>K_\nu</math> are the Hankel function

respectively, both of order <math>\nu</math> as defined in [[abr_ste]].  

The incident potential upon body <math>\Delta_j</math> can be expanded in

cylindrical eigenfunctions,  

\infty}^{\infty} D_{\mu}^j (\eta) I_\mu (\eta r_j) \mathrm{e}^{\mathrm{i}\mu

\theta_j} \mathrm{d}\eta,

the modified Bessel function respectively, both of the first kind and

order <math>\mu</math>. To simplify the notation, from now on <math>\psi(z,\eta)</math> will

\psi(z,\eta) = \cos \eta z + \alpha / \eta \, \sin \eta z.

===The interaction in water of infinite depth===

Following the ideas of [[kagemoto86]], a system of equations for the unknown

coefficients and coefficient functions of the scattered wavefields

will be developed. This system of equations is based on transforming the

scattered potential of <math>\Delta_j</math> into an incident potential upon

<math>\Delta_l</math> (<math>j \neq l</math>). Doing this for all bodies simultaneously,

and relating the incident and scattered potential for each body, a system

of equations for the unknown coefficients will be developed.  

The scattered potential <math>\phi_j^{\mathrm{S}}</math> of body <math>\Delta_j</math> needs to be

represented in terms of the incident potential <math>\phi_l^{\mathrm{I}}</math>

(fig:floe_tri) we can see that this can be accomplished by using

\citet[eq. 9.1.79]{abr_ste},

which is valid provided that <math>r_l < R_{jl}</math>. This limitation

only requires that the escribed cylinder of each body <math>\Delta_l</math> does

not enclose any other origin <math>O_j</math> (<math>j \neq l</math>). However, the

expansion of the scattered and incident potential in cylindrical

eigenfunctions is only valid outside the escribed cylinder of each

body. Therefore the condition that the

origin <math>O_j</math> (<math>j \neq l</math>) is superseded by the more rigorous

restriction that the escribed cylinder of each body may not contain any

the scattered potential of <math>\Delta_j</math> can be expressed in terms of the

\phi_j^{\mathrm{S}} (r_l,\theta_l,z) &=

&= \mathrm{e}^{\alpha z} \sum_{\mu = -\infty}^{\infty} \Big[ \sum_{\nu = -

(\nu-\mu) \vartheta_{jl}} \Big] J_\mu (\alpha r_l) \mathrm{e}^{\mathrm{i}\mu \theta_l}\\

\Big[ \sum_{\nu = - \infty}^{\infty} A_{\nu}^j (\eta) (-1)^\mu K_{\nu-\mu}

\vartheta_{jl}} \Big] I_\mu (\eta r_l) \mathrm{e}^{\mathrm{i}\mu \theta_l} \mathrm{d}\eta.

expanded in the eigenfunctions corresponding to the incident wavefield upon

<math>\Delta_l</math>. A detailed illustration of how to accomplish this will be given

later. Let <math>D_{l0\mu}^{\mathrm{In}}</math> denote the coefficients of this

corresponding to the decaying modes (which are identically zero) of

the incoming eigenfunction expansion for <math>\Delta_l</math>. The total

&= \mathrm{e}^{\alpha z} \sum_{\mu = -\infty}^{\infty} \Big[

(\nu - \mu) \vartheta_{jl}} \Big] J_\mu (\alpha r_l) \mathrm{e}^{\mathrm{i}\mu \theta_l}\\

R_{jl}) \mathrm{e}^{\mathrm{i}(\nu - \mu) \vartheta_{jl}} \Big] I_\mu (\eta r_l)

\mathrm{e}^{\mathrm{i}\mu \theta_l} \mathrm{d}\eta.

The coefficients of the total incident potential upon <math>\Delta_l</math> are

\begin{subequations} (inc_coeff)

R_{jl}) \mathrm{e}^{\mathrm{i}(\nu - \mu) \vartheta_{jl}}.

In general, it is possible to relate the total incident and scattered

that body in isolation. There exist diffraction transfer operators

<math>B_l</math> that relate the coefficients of the incident and scattered

<center><math> (eq_B)

A_l = B_l (D_l), \quad l=1, \ldots, N,

where <math>A_l</math> are the scattered modes due to the incident modes <math>D_l</math>.

In the case of a countable number of modes, (i.e. when

the depth is finite), <math>B_l</math> is an infinite dimensional matrix. When

the modes are functions of a continuous variable (i.e. infinite

depth), <math>B_l</math> is the kernel of an integral operator.

For the propagating and the decaying modes respectively, the scattered

potential can be related by diffraction transfer operators acting in the

following ways,

B_{l\nu\mu}^\mathrm{pd} (\xi) D_{\mu}^l (\xi) \mathrm{d}\xi,\\

D_{\mu}^l (\xi) \mathrm{d}\xi.

The superscripts <math>\mathrm{p}</math> and <math>\mathrm{d}</math> are used to distinguish

between propagating and decaying modes, the first superscript denotes the kind

of scattered mode, the second one the kind of incident mode.

If the diffraction transfer operators are known (their calculation

will be discussed later), the substitution of

equations  (inc_coeff) into equations  (diff_op) give the

required equations to determine the coefficients and coefficient

R_{jl}) \mathrm{e}^{\mathrm{i}(\nu - \mu) \vartheta_{jl}} \Big] \mathrm{d}\xi,

  H_{\nu-\mu}^{(1)} (\alpha R_{jl}) \mathrm{e}^{\i

R_{jl}) \mathrm{e}^{\mathrm{i}(\nu - \mu) \vartheta_{jl}}\Big] \mathrm{d}\xi,

<math>n \in \mathds{Z},\, l = 1, \ldots, N</math>. It has to be noted that all

equations are coupled so that it is necessary to solve for all

scattered coefficients and coefficient functions simultaneously.  

For numerical calculations, the infinite sums have to be truncated and

the integrals must be discretised. Implying a suitable truncation, the

matrices which can be assembled in a big matrix <math>\mathbf{B}_l</math>,

\mathbf{B}_l = \left[  

\begin{matrix}{cc} \mathbf{B}_l^{\mathrm{pp}} & \mathbf{B}_l^{\mathrm{pd}}\\

the infinite depth diffraction transfer matrix.

Truncating the coefficients accordingly, defining <math>{\bf a}^l</math> to be the

coefficients of the ambient wavefield, and making use of a coordinate

=for the propagating modes, and=

for the decaying modes, a linear system of equations

{\bf a}_l = {\bf \hat{B}}_l \Big( {\bf d}_l^{\mathrm{In}} +

where the left superscript <math>\mathrm{t}</math> indicates transposition.

The matrix <math>{\bf \hat{B}}_l</math> denotes the infinite depth diffraction

transfer matrix <math>{\bf B}_l</math> in which the elements associated with

integration weights depending on the discretisation of the continuous variable.

While \citeauthor{kagemoto86}'s interaction theory was valid for

geometry. This step was performed by [[goo90]] who came up with an

explicit method to calculate the diffraction transfer matrices for bodies of

arbitrary geometry in the case of finite depth. Utilising a Green's

However, the representation of the scattered potential which

finite depth Green's function given by [[black75]] and

on applying Graf's addition theorem to the eigenfunction

representation of the free surface finite depth Green's function given

by [[john2]]. Their representation allowed the scattered potential to be

represented in the eigenfunction expansion with the cylindrical

mean centre position of the body.

An outline of this method for water of finite

depth is given by [[kashiwagi00]]. We will present

for the source strength distribution function. However,

for the total velocity potential.

 

require the representation of the infinite depth free surface Green's

function in cylindrical eigenfunctions,

<center><math> (green_inf)

G(r,\theta,z;s,\varphi,c) &= \frac{\mathrm{i}\alpha}{2} \,  \mathrm{e}^{\alpha (z+c)}

\sum_{\nu=-\infty}^{\infty} H_\nu^{(1)}(\alpha r) J_\nu(\alpha s) \mathrm{e}^{\mathrm{i}\nu

(\theta - \varphi)}\\ &\quad + \frac{1}{\pi^2} \int\limits_0^{\infty}

\psi(z,\eta) \frac{\eta^2}{\eta^2+\alpha^2} \psi(c,\eta)

\sum_{\nu=-\infty}^{\infty} K_\nu(\eta r) I_\nu(\eta s) \mathrm{e}^{\mathrm{i}\nu

(\theta - \varphi)} \mathrm{d}\eta,

<math>r > s</math>, given by [[malte03]].

 

the source strength distribution <math>\varsigma^j</math> so that the scattered

<center><math> (int_eq_1)

\phi_j^\mathrm{S}(\mathbf{y}) = \int\limits_{\Gamma_j} G

immersed surface of body <math>\Delta_j</math>. The source strength distribution

function <math>\varsigma^j</math> can be found by solving an

integral equation. The integral equation is described in

(green_inf) into  (int_eq_1), the scattered potential can

<center><math>\begin{matrix}

&\phi_j^\mathrm{S}(r_j,\theta_j,z) = \mathrm{e}^{\alpha z} \sum_{\nu = -

\infty}^{\infty} \bigg[ \frac{\mathrm{i}\alpha}{2}

\int\limits_{\Gamma_j} \mathrm{e}^{\alpha c} J_\nu(\alpha s) \mathrm{e}^{-\mathrm{i}\nu

\varphi} \varsigma^j(\mathbf{\zeta})

\mathrm{d}\sigma_\mathbf{\zeta} \bigg] H_\nu^{(1)} (\alpha r_j) \mathrm{e}^{\mathrm{i}\nu \theta_j}\\

& \, + \int\limits_{0}^{\infty} \psi(z,\eta) \sum_{\nu = -

\infty}^{\infty} \bigg[ \frac{1}{\pi^2} \frac{\eta^2

}{\eta^2 + \alpha^2} \int\limits_{\Gamma_j} \psi(c,\eta) I_\nu(\eta s)

\mathrm{e}^{-\mathrm{i}\nu \varphi} \varsigma^j({\bf{\zeta}})

\mathrm{d}\sigma_{\bf{\zeta}} \bigg] K_\nu (\eta r_j) \mathrm{e}^{\mathrm{i}\nu \theta_j} \mathrm{d}\eta,

\end{matrix}</math></center>

where  

<math>\mathbf{\zeta}=(s,\varphi,c)</math> and <math>r>s</math>.

This restriction implies that the eigenfunction expansion is only valid

outside the escribed cylinder of the body.

The columns of the diffraction transfer matrix are the coefficients of

the eigenfunction expansion of the scattered wavefield due to the

different incident modes of unit-amplitude. The elements of the

diffraction transfer matrix of a body of arbitrary shape are therefore given by

\begin{subequations} (B_elem)

({\bf B}_j)_{pq} &= \frac{\mathrm{i}\alpha}{2} \int\limits_{\Gamma_j}

\mathrm{e}^{\alpha c} J_p(\alpha s) \mathrm{e}^{-\mathrm{i}p \varphi} \varsigma_q^j(\mathbf{\zeta})

({\bf B}_j)_{pq} &= \frac{1}{\pi^2} \frac{\eta^2}{\eta^2 +

\alpha^2} \int\limits_{\Gamma_j} \psi(c,\eta) I_p(\eta s) \mathrm{e}^{-\mathrm{i}p

\begin{subequations} (test_modes_inf)

\phi_q^{\mathrm{I}}(s,\varphi,c) &=  \mathrm{e}^{\alpha c} H_q^{(1)} (\alpha

s) \mathrm{e}^{\mathrm{i}q \varphi}\\

\phi_q^{\mathrm{I}}(s,\varphi,c) &= \psi(c,\eta) K_q (\eta s) \mathrm{e}^{\mathrm{i}q \varphi}

The additional angular dependence caused by the rotation of the

incident potential can be factored out of the normal derivative of the

incident potential such that

\frac{\partial \phi_{q\beta}^{\mathrm{I}}}{\partial n} =

\frac{\partial \phi_{q}^{\mathrm{I}}}{\partial n}

\mathrm{e}^{\mathrm{i}q \beta},

where <math>\phi_{q\beta}^{\mathrm{I}}</math> is the rotated incident potential.

strength distribution function is linear, the source strength

\varsigma_{q\beta}^j = \varsigma_q^j \, \mathrm{e}^{\mathrm{i}q \beta}.

This is also the source strength distribution function of the rotated

body due to the standard incident modes.  

The elements of the diffraction transfer matrix <math>\mathbf{B}_j</math> are

given by equations  (B_elem). Keeping in mind that the body is

matrix of the rotated body are given by

\begin{subequations} (B_elem_rot)

(\mathbf{B}_j^\beta)_{pq} &= \frac{\mathrm{i}\alpha}{2} \int\limits_{\Gamma_j}

\mathrm{e}^{\alpha c} J_p(\alpha s) \mathrm{e}^{-\mathrm{i}p (\varphi+\beta)}

\varsigma_{q\beta}^j(\mathbf{\zeta}) \mathrm{d}\sigma_\mathbf{\zeta},\\

=and=  

(\mathbf{B}_j^\beta)_{pq} &= \frac{1}{\pi^2} \frac{\eta^2}{\eta^2 +

\alpha^2} \int\limits_{\Gamma_j} \psi(c,\eta) I_p(\eta s) \mathrm{e}^{-\mathrm{i}p

(\varphi+\beta)} \varsigma_{q\beta}^j(\mathbf{\zeta}) \mathrm{d}\sigma_\mathbf{\zeta},

for the propagating and decaying modes respectively.  

Thus the additional angular dependence caused by the rotation of

the body can be factored out of the elements of the diffraction

transfer matrix. The elements of the diffraction transfer matrix

corresponding to the body rotated by the angle <math>\beta</math>,

<math>\mathbf{B}_j^\beta</math>, are given by

<center><math> (B_rot)

(\mathbf{B}_j^\beta)_{pq} = (\mathbf{B}_j)_{pq} \, \mathrm{e}^{\mathrm{i}(q-p) \beta}.

As before, <math>(\mathbf{B})_{pq}</math> is understood to be the element of

<math>\mathbf{B}</math> which corresponds to the coefficient of the <math>p</math>th scattered

  (B_rot) applies to propagating and decaying modes likewise.

\subsection{Representation of the ambient wavefield in the eigenfunction

In Cartesian coordinates centred at the origin, the ambient wavefield is

given by

\phi^{\mathrm{In}}(x,y,z) = A \frac{g}{\omega} \, \mathrm{e}^{\mathrm{i}\alpha (x

\cos \chi + y \sin \chi)+ \alpha z},

where <math>A</math> is the amplitude (in displacement) and <math>\chi</math> is the

angle between the <math>x</math>-axis and the direction in which the wavefield travels.

The interaction theory requires that the ambient wavefield, which is

all bodies, is represented in the eigenfunction expansion of an

\phi^{\mathrm{In}}(x,y,z) = A \frac{g}{\omega} \mathrm{e}^{\alpha z}

\sum_{\mu = -\infty}^{\infty} \mathrm{e}^{\mathrm{i}\mu (\pi/2 - \theta + \chi)}

J_\mu(\alpha r)

\cite[p. 169]{linton01}.

Since the local coordinates of the bodies are centred at their mean

centre positions <math>O_l = (O_x^l,O_y^l)</math>, a phase factor has to be defined

which accounts for the position from the origin. Including this phase

factor the ambient wavefield at the <math>l</math>th body is given

\phi^{\mathrm{In}}(r_l,\theta_l,z) = A \frac{g}{\omega} \, e^{\mathrm{i}\alpha (O_x^l

\cos \chi + O_x^l \sin \chi)} \, \mathrm{e}^{\alpha z}

\sum_{\mu = -\infty}^{\infty} \mathrm{e}^{\mathrm{i}\mu (\pi/2 -  \chi)}

J_\mu(\alpha r_l) \mathrm{e}^{\mathrm{i}\mu \theta_l}.

===Solving the resulting system of equations===  

After the coefficient vector of the ambient incident wavefield, the  

diffraction transfer matrices and the coordinate

transformation matrices have been calculated, the system of

equations  (eq_B_inf),

has to be solved. This system can be represented by the following

matrix equation,

\left[ \begin{matrix}{c}

{\bf a}_1\\ {\bf a}_2\\ \\ \vdots \\ \\ {\bf a}_N

\end{matrix} \right]

= \left[ \begin{matrix}{c}

\hat{{\bf B}}_1 {\bf d}_1^\mathrm{In}\\ \hat{{\bf B}}_2 {\bf

d}_2^\mathrm{In}\\ \\ \vdots \\ \\ \hat{{\bf B}}_N {\bf d}_N^\mathrm{In}

\end{matrix} \right]+

\left[ \begin{matrix}{ccccc}

\mathbf{0} & \hat{{\bf B}}_1 \trans {\bf T}_{21} & \hat{{\bf B}}_1

\trans {\bf T}_{31} & \dots & \hat{{\bf B}}_1 \trans {\bf T}_{N1}\\

\hat{{\bf B}}_2 \trans {\bf T}_{12} & \mathbf{0} & \hat{{\bf B}}_2

\trans {\bf T}_{32} & \dots & \hat{{\bf B}}_2 \trans {\bf T}_{N2}\\

& & \mathbf{0} & &\\

\vdots & & & \ddots & \vdots\\

\hat{{\bf B}}_N \trans {\bf T}_{1N} & & \dots & 

& \mathbf{0}

\end{matrix} \right]

\left[ \begin{matrix}{c}

{\bf a}_1\\ {\bf a}_2\\ \\ \vdots \\ \\ {\bf a}_N

\end{matrix} \right],

where <math>\mathbf{0}</math> denotes the zero-matrix which is of the same

dimension as <math>\hat{{\bf B}}_j</math>, say <math>n</math>. This matrix equation can be

easily transformed into a classical <math>(N \, n)</math>-dimensional linear system of

equations.