2. General theory and motivation

There are a number of different ways of developing the theoretical framework which describes the capacity of a WEC to absorb power from an incoming plane wave. One such approach (see Mei Reference Mei1983) is summarised below. A plane monochromatic wave of wavelength $\lambda = 2 {\rm \pi}/k$, angular frequency $\omega$ and amplitude $A$ travelling in the positive $x$ direction on water of depth $h$ is described by the velocity potential

(2.1)\begin{equation} \phi_{pw}(x,y,z) ={-}\frac{ \mathrm{i} A g}{\omega} \,\mathrm{e}^{\mathrm{i} k x} \psi_0(z), \end{equation}

where $\omega = \sqrt {gk \tanh kh}$ is the assumed radian frequency of motion, related to the wavenumber $k$, and $\psi _0(z) = \cosh k(z+h)/\cosh kh$ is the depth eigenfunction associated with propagating waves. Thus, inviscid incompressible linearised water wave theory is in operation and a time factor of $\mathrm {e}^{-\mathrm {i} \omega t}$ has been suppressed so that $\phi _{pw}$ is a solution of the governing equations

(2.2)\begin{equation} \nabla^2 \phi = 0, \quad \mbox{in the fluid},\end{equation}

with

(2.3)\begin{equation} \phi_z = 0, \quad \mbox{on } z={-}h, \end{equation}

and

(2.4)\begin{equation} \phi_{z} - (\omega^2/g) \phi = 0, \quad \mbox{on } z=0. \end{equation}

The mean (time-averaged over a period) flux of energy per unit length of wave crest contained in the plane wave is calculated from

(2.5)\begin{equation} {\mathbb{P}}_{pw} = \tfrac12 \mathrm{Re} \left\{ \int_{{-}h}^0 \mathrm{i} \omega \rho \phi_{pw} \frac{\partial \phi_{pw}^\ast}{\partial x} \, {\textrm{d} x} \right\} = \tfrac12 \rho g |A|^2 c_g, \end{equation}

where the asterisk denotes complex conjugation and $c_g = \textrm {d} \omega / \textrm {d} k = \frac 12 (\omega /k)(1+2kh/ \sinh 2 kh)$ is the group velocity.

The incident plane wave defined by (2.1) can be expressed as the sum of incoming and outgoing circular waves by writing (e.g. Mei Reference Mei1983)

(2.6)\begin{equation} \phi_{pw}(r,\theta,z) = \phi_{in}(r,\theta,z) + \phi_{out}(r,\theta,z), \end{equation}

where

(2.7)\begin{equation} \phi_{in} ={-}\frac{ \mathrm{i} A g}{2 \omega} \psi_0(z) \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n H_n^{(2)}(kr) \cos n \theta \end{equation}

and

(2.8)\begin{equation} \phi_{out} ={-}\frac{ \mathrm{i} A g}{2 \omega} \psi_0(z) \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n H_n^{(1)}(kr) \cos n \theta, \end{equation}

where $\epsilon _0 = 1$ and $\epsilon _n = 2$ for $n \geq 1$. The mean flux of energy to/from infinity attributed to the $n$th circular component of (2.8)/(2.7) has the value $P_n =(\epsilon _n \lambda /2{\rm \pi} ) {\mathbb {P}}_{pw}$. Contrasting font styles indicate different dimensions of ${\mathbb {P}}_{pw}$ and $P_n$ (units of kW m$^{-1}$ and kW, respectively).

Consider plane waves incident upon a device which we assume for simplicity is symmetric with respect to the incident wave heading. Then far away from the device

(2.9)\begin{equation} \phi(r,\theta,z) \sim \phi_{pw}(r,\theta,z)-\frac{ \mathrm{i} A g}{\omega} \psi_0(z) \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n a_{n,0} H_n^{(1)}(kr) \cos n \theta, \end{equation}

where $a_{n,0}$ are coefficients determined by the shape and dynamics of the device as well as the wave frequency. When written as

(2.10)\begin{equation} \phi = \phi_{in} - \frac{\mathrm{i} g A}{2 \omega} \psi_0(z) \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n (2 a_{n,0} + 1) H_n^{(1)}(kr) \cos n \theta, \end{equation}

it can be seen that the power lost to the device is

(2.11)\begin{equation} P = \frac{{\mathbb{P}}_{pw}\lambda}{2 {\rm \pi}} \sum_{n=0}^\infty \epsilon_n ( 1 - |2 a_{n,0} +1|^2 ). \end{equation}

It follows that a non-absorbing device (including fixed, freely floating or constrained to move with sprung mooring lines) must have scattering coefficients $a_{n,0} \equiv a_{n,0}^S$, say, satisfying $|2 a_{n,0}^S + 1| = 1$.

For example, consider a rigid vertical cylinder extending through the depth of the fluid for which the potential everywhere in the fluid domain may be written (e.g. MacCamy & Fuchs Reference MacCamy and Fuchs1954)

(2.12)\begin{equation} \phi(r,\theta,z) ={-}\frac{ \mathrm{i} A g}{\omega} \psi_0(z) \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n \left( J_n(kr) - \frac{J_n'(ka)}{{H_n^{(1)}}'(ka)} H_n^{(1)}(kr) \right) \cos n \theta, \end{equation}

wherein $a_{n,0}^S = -J_n'(ka)/{H_n^{(1)}}'(ka)$ and it is confirmed that $|2a_{n,0}^S+1| = 1$.

More importantly, (2.11) tells us that a device with the capacity to absorb energy can extract up to the maximum mean power, $P_n$, from the $n$th circular component of the wave field if its dynamics can be orchestrated to meet the condition $a_{n,0} = -\frac 12$. For this is to happen the device must have the capacity to radiate waves through motions responsible for absorbing wave energy in the $n$th circular mode, i.e. in proportion to $\cos n \theta$. For example, rigid-body heave motion of an axisymmetric device radiates waves in the zeroth circular mode, and so its maximum power absorption is limited to $P_{max} = P_0$, whilst surge and pitch motions radiate in the $n=1$ circular mode giving rise to a maximum of $P_{max} = P_1$; combined heave and surge/pitch provides a maximum of $P_{max} = P_0+P_1$. Thus we recover the well-known theoretical limits derived independently by Newman (Reference Newman1976), Evans (Reference Evans1976) and Budal & Falnes (Reference Budal and Falnes1977) and summarised in the abstract.

The capacity to absorb energy in excess of these limits thus lies in the ability to radiate in multiple circular modes. This is a well-understood concept, and approaches to exploit this have been made by Newman (Reference Newman1979), Haren & Mei (Reference Haren and Mei1979) and Ancellin et al. (Reference Ancellin, Dong, Jean and Dias2020) for elongated attenuator WEC devices and when WECs are comprised of multiple distinct absorbers such as those of Garnaud & Mei (Reference Garnaud and Mei2009) and Wolgamot, Taylor & Eatock Taylor (Reference Wolgamot, Taylor and Eatock Taylor2012). In both cases the operation is characterised by multiple degrees of freedom.

In this paper we apply the principle to axisymmetric devices by imagining that a WEC device is fitted with a large number ($N$, say) of narrow vertical paddles across its surface which oscillate normal to that surface. These paddles could be hinged along a level below the water surface or perhaps operate with a linear piston-like motion directed from the vertical axis. We suppose the paddles have the capacity to convert hydrodynamic forces into useful power.

The $N$ paddles could be connected to their own springs and dampers and operate independently from one another. However, for the moment, let us imagine that the paddle operation can be designed to oscillate as a superposition of $M+1$ (say) modes which, when absorbing, radiate in the far field with a variation of $\cos n \theta$ for $0 \leq n \leq M$. For example, the $n=0$ mode corresponds to the paddles operating synchronously and, in the $n=1$ mode, the paddle oscillation is modulated by $\cos \theta$. Then it is possible, in principle at least, to design the paddle springs and dampers such that

(2.13)\begin{equation} P_{max} = \frac{{\mathbb{P}}_{pw}\lambda}{{\rm \pi} } \left(M+ \tfrac12 \right). \end{equation}

In this paper we focus on a circular cylinder extending through the depth covered with narrow vertical paddles with the capacity to absorb, but do not suppose the type of complicated engineering solutions or control theory suggested above is needed to operate the paddles (see figure 1). Instead, each paddle is supposed to operate independently with its own spring and damper and the paper explores strategies to design the springs and damper characteristics with a view to developing power beyond that available to an equivalent cylinder operating in rigid-body motion thereby showing that (2.13) is theoretically attainable. This investigation is assisted by the development of a continuum approximation to the arrangement of narrow paddles across the surface of the cylinder. The accuracy of this approximation is assessed against an exact description of the hydrodynamic/mechanical problem for a finite number of paddles.

Figure 1. Sketch of an axisymmetric device: (a) bird's-eye view of the device with hinged paddles; (b) section of the device with hinged paddles; (c) section of the device with piston-like paddles.

The aim of the current work is to highlight the potential for a single axisymmetric device fitted with multiple paddles to absorb power in excess of the power from rigid-body motion. It does not, however, address the important issue of adding motion constraints in order that the underlying linearised water wave framework is not compromised.

3. A cylindrical WEC: governing equations

A vertical cylinder of radius $a$ centred on the $z$ axis extends through a fluid of density $\rho$ and depth $h$ with a mean free surface on $z=0$. An array of $N \gg 1$ identical narrow vertical paddles are attached to the surface of the cylinder having width $2 {\rm \pi}a/N$ assumed to be much smaller than their length $c$ (no larger than the fluid depth, $h$) and the wavelength $\lambda$. The angular coordinate of the centre of the $n$th paddle is denoted $\theta _n = (2 n-1){\rm \pi} /N$, $n = 1,2,\ldots ,N$. Each rigid paddle can move in a radial direction along its central axial plane and the motion of the $n$th paddle is resisted by a linear spring with spring constant $\kappa _n$ and a linear damper with damping rate $\gamma _n$ through which power is extracted. In motion, the $n$th paddle oscillates through a small displacement (linear or angular) $S_n(t) = \mathrm {Re} \{ \sigma _n \,\mathrm {e}^{-\mathrm {i} \omega t} \}$ where the time dependence of radian frequency $\omega$ has been assumed.

The motion of the fluid is governed by a potential $\phi (r,\theta ,z)$ which satisfies (2.2), (2.3) and (2.4). Additionally, the kinematic condition connecting the velocity of the fluid to that of the paddles normal to the cylinder surface is written

(3.1)\begin{equation} \left. \frac{\partial \phi}{\partial r} \right|_{r=a} ={-} \mathrm{i} \omega \sigma_n \,f(z)\cos(\theta-\theta_n), \quad -h < z < 0, \ \theta_n - {\rm \pi}/N < \theta < \theta_n + {\rm \pi}/N, \end{equation}

for $n = 1,2,\ldots , N$ and $\cos (\theta -\theta _n)$ is a geometric factor due to the curvature of the paddle surface. In (3.1), $\,f(z)$ encodes the spatial variation of the displacement along the length of the paddle. For example, a paddle operating in a radial piston-like motion along a submerged extent $c \leq h$ will be defined by $\,f(z) = 1$, $-c < z < 0$ and $\,f(z) = 0$, $-h < z < -c$ whereas a paddle operating as a hinged flap pivoted along its bottom edge along $z=-c$ ($c < h$) would be defined by

(3.2)\begin{equation} \,f(z) = \left\{ \begin{array}{@{}ll} z+c, & -c < z < 0,\\ 0, & -h < z <{-}c. \end{array} \right. \end{equation}

The equation of motion for the $n$th paddle is expressed by

(3.3)\begin{equation} - \omega^2 {\mathcal{M}} (2 {\rm \pi}a/N) \sigma_n ={-}(\kappa_n + {\mathcal{C}}(2 {\rm \pi}a/N)) \sigma_n + \mathrm{i} \omega \gamma_n \sigma_n + X_n, \end{equation}

where ${\mathcal {M}}$ is the mass (or moment of inertia) per unit width, ${\mathcal {C}}$ accounts for any buoyancy restoring force (or moment) per unit width present and

(3.4)\begin{equation} X_n ={-}\mathrm{i} \omega \rho \int_{{-}h}^0 \int_{\theta_n - {\rm \pi}/N}^{\theta_n+{\rm \pi} /N} \phi(a,\theta,z) \,f(z) \cos (\theta - \theta_n) a \, \textrm{d} \theta \, \textrm{d} z \end{equation}

is the hydrodynamic wave force (or moment). The cosine terms appearing in (3.1) and (3.4) are geometrical factors arising from the component normal to the assumed curved surface of the paddles.

When $N$ is large and the width of the paddle, $2 {\rm \pi}a/N$, is small with respect to the wavelength $\lambda$ and the length of the paddle $c$, we assume that $\sigma _n$ may be replaced by discrete evaluations, $\sigma (\theta _n)$, of a continuous function $\sigma (\theta )$ allowing (3.1) to be approximated by

(3.5)\begin{equation} \left. \frac{\partial \phi}{\partial r} \right|_{r=a} ={-} \mathrm{i} \omega \sigma(\theta) \,f(z), \quad -h < z < 0, \ 0 < \theta \leq 2 {\rm \pi}. \end{equation}

Similarly, we let $\kappa _n = \kappa (\theta _n) (2 {\rm \pi}a/N)$ and $\gamma _n = \gamma (\theta _n) (2 {\rm \pi}a/N)$, where $\kappa$ and $\gamma$ are continuous functions representing the spring force (or torque) and damping rate per unit width, whilst (3.4) becomes

(3.6)\begin{equation} X_n = \frac{2 a {\rm \pi}}{N} X(\theta_n) \approx{-} \mathrm{i} \omega \rho \frac{2 a {\rm \pi}}{N} \int_{{-}h}^0 \phi(a,\theta_n,z) \,f(z) \, \textrm{d} z. \end{equation}

Then the $N$ discrete equations of motion for the $N$ paddles in (3.3) are approximated by the $\theta$-continuous equation of motion:

(3.7)\begin{equation} [\kappa(\theta) + {\mathcal{C}} - \omega^2 {\mathcal{M}} -\mathrm{i} \omega \gamma(\theta)] \sigma(\theta) = X(\theta), \quad 0 < \theta \leq 2 {\rm \pi}. \end{equation}

It follows that the combined dynamic and kinematic boundary condition on $r=a$ is

(3.8)\begin{equation} [\kappa(\theta) + {\mathcal{C}} - \omega^2 {\mathcal{M}} -\mathrm{i} \omega \gamma(\theta)] \left. \frac{\partial \phi}{\partial r} \right|_{r=a} ={-} \omega^2 \rho \,f(z) \int_{{-}h}^0 \phi(a,\theta,z) \,f(z) \, \textrm{d} z, \end{equation}

for $-h < z < 0$ and $0 < \theta \leq 2 {\rm \pi}$. We write this as

(3.9)\begin{equation} \varLambda(\theta) ha \left. \frac{\partial \phi}{\partial r} \right|_{r=a} = \,f(z) \int_{{-}h}^0 \phi(a,\theta,z) \,f(z) \, \textrm{d} z, \end{equation}

where

(3.10)\begin{equation} \varLambda(\theta) = \frac{{\mathcal{M}} - \omega^{{-}2}(\kappa(\theta) + {\mathcal{C}}) + \mathrm{i} \omega^{{-}1} \gamma(\theta)}{\rho h a}. \end{equation}

4. Solution for narrow paddles

Following the description of the plane wave in (2.1) we can write the full depth-dependent potential satisfying (2.2), (2.3) and (2.4) as the expansion

(4.1)\begin{equation} \phi(r,\theta,z) ={-}\frac{\mathrm{i} g A}{\omega} \sum_{m=0}^\infty \varphi_m(r,\theta) \psi_m(z) \end{equation}

over all depth eigenfunctions

(4.2)\begin{equation} \psi_m(z) = \cos k_m(z+h)/\cos (k_m h) \end{equation}

that arise from separating variables: $k_m$ are the increasing sequence of positive roots of $-\omega ^2/g = k_m \tan k_m h$ (e.g. Mei Reference Mei1983). The depth eigenfunctions defined in (4.2) alongside $\psi _0(z)$ defined after (2.1) with $k_0 = -\mathrm {i} k$ satisfy the orthogonality relation

(4.3)\begin{equation} \frac{1}{h} \int_{{-}h}^0 \psi_n(z) \psi_m(z) \, \textrm{d} z = N_n \delta_{mn}, \end{equation}

for all $n,m = 0,1,2,\ldots$, where

(4.4)\begin{equation} N_n = \tfrac12 ( 1+ \sin (2 k_n h)/(2k_n h))/\cos^2(k_n h). \end{equation}

The functions $\varphi _m(r,\theta )$ are given by

(4.5)\begin{equation} \varphi_0(r,\theta) = \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n ( J_n(kr) + a_{n,0} H_n^{(1)}(kr) ) \cos n \theta \end{equation}

and

(4.6)\begin{equation} \varphi_m(r,\theta) = \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n a_{n,m} K_n(k_m r) \cos n \theta, \end{equation}

for $m \geq 1$, and $K_n(\cdot )$ are modified Bessel functions.

We define

(4.7)\begin{equation} F_n = \frac{1}{h} \int_{{-}h}^0 \psi_n(z) \,f(z) \, \textrm{d} z, \quad n=0,1,\ldots, \end{equation}

as constants which can be calculated for a given $\,f(z)$. Using (4.1) in (3.9) gives

(4.8)\begin{equation} \varLambda(\theta) a \sum_{m=0}^\infty \frac{\partial \varphi_m}{\partial r} (a,\theta) \psi_m(z) = \,f(z) G(\theta), \end{equation}

where

(4.9)\begin{equation} G(\theta) = \frac{1}{h} \int_{{-}h}^0 \sum_{m=0}^\infty \varphi_m(a,\theta) \psi_m(z) \,f(z) \, \textrm{d} z = \sum_{m=0}^\infty F_m \varphi_m(a,\theta). \end{equation}

It follows after using (4.7) again that

(4.10)\begin{equation} \varLambda(\theta) a N_m \frac{\partial \varphi_m}{\partial r} (a,\theta) = F_m G(\theta), \quad 0 < \theta \leq 2 {\rm \pi}, \end{equation}

for all $m=0,1,\ldots$ and so

(4.11)\begin{equation} \frac{\partial \varphi_m}{\partial r}(a,\theta) = \frac{N_0 F_m}{N_m F_0} \frac{\partial \varphi_0}{\partial r}(a,\theta). \end{equation}

Application of this relation to (4.5) and (4.6) gives

(4.12)\begin{equation} a_{n,m} = \frac{k F_m N_0}{k_m F_0 N_m K_n'(k_ma)} (J_n'(ka) + a_{n,0} {H_n^{(1)}}'(ka)), \end{equation}

for $m \geq 1$, after equating coefficients of $\cos n \theta$. This important relation illustrates that the dependence of the fluid motion through the depth is set by the function $\,f(z)$ describing the vertical displacement of the paddle motion.

In particular, using (4.12) in (4.5) and (4.6) allows us to express the general solution (4.1) in the form

(4.13)\begin{equation} \phi(r,\theta,z) ={-}\frac{\mathrm{i} g A}{\omega} \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n \phi_n(r,z) \cos n \theta, \end{equation}

where

(4.14)\begin{align} \phi_n(r,z) &= (J_n(kr) + a_{n,0} H_n^{(1)}(kr)) \psi_0(z) \nonumber\\ &\quad + (J_n'(ka) + a_{n,0} {H_n^{(1)}}'(ka)) \sum_{m=1}^\infty \frac{k F_m N_0 K_n(k_m r)}{k_m F_0 N_m K_n'(k_m a)} \psi_m(z) \end{align}

is expressed in terms of $a_{n,0}$ only.

We will also find it convenient to write

(4.15)\begin{equation} G(\theta) = \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n G_n \cos n \theta, \end{equation}

where, from the definition implied by its introduction in (4.8),

(4.16)\begin{equation} G_n = F_0 (J_n(ka) + a_{n,0} H_n^{(1)}(ka)) + \frac{ka N_0}{F_0} (J_n'(ka) + a_{n,0} {H_n^{(1)}}'(ka)) E_n, \end{equation}

and we have defined

(4.17)\begin{equation} E_n = \sum_{m=1}^\infty \frac{F_m^2 K_n(k_m a)}{k_ma N_m K_n'(k_m a)}. \end{equation}

4.1. Equal springs and dampers

We let $\kappa (\theta ) = \kappa$ and $\gamma (\theta ) = \gamma$ so that

(4.18)\begin{equation} \varLambda(\theta) = \frac{{\mathcal{M}} - (\kappa+ {\mathcal{C}})/\omega^2 + \mathrm{i} \gamma/\omega}{\rho h a} \equiv \varLambda_0, \end{equation}

say, is a constant and it follows that the boundary condition (3.9) applies to each circular wave component; thus,

(4.19)\begin{equation} \varLambda_0 h a \left. \frac{\partial \phi_n}{\partial r} \right|_{r=a} = \,f(z) \int_{{-}h}^{0} \phi_n(a,z) \,f(z) \, \textrm{d} z. \end{equation}

Substituting in (4.14), multiplying through by $\psi _0(z)$ and integrating over $-h < z < 0$ gives

(4.20)\begin{equation} k a \varLambda_0 (J_n'(ka) + a_{n,0} {H_n^{(1)}}'(ka)) N_0 = F_0 G_n, \end{equation}

where $G_n$ is given by (4.16). Note that integrating over $-h < z < 0$ with other depth functions $\psi _m(z)$ for $m \geq 1$ does not provide any new information as the dependence on the vertical has already been incorporated into the solution.

Thus we can calculate $a_{n,0}$ explicitly from substituting (4.16) into (4.20) and rearranging to get

(4.21)\begin{equation} a_{n,0} ={-} \frac{\varGamma_n J_n'(ka) - J_n(ka)}{\varGamma_n {H_n^{(1)}}'(ka) - H_n^{(1)}(ka)}, \end{equation}

where

(4.22)\begin{equation} \varGamma_n = \frac{k a N_0}{F_0^2} ( \varLambda_0 - E_n ). \end{equation}

The power generated by the paddles is subsequently calculated using (2.11). After some lengthy but routine algebra requiring the use of the following Wronksian identity for Bessel functions (Abramowitz & Stegun Reference Abramowitz and Stegun1964, § 9.1.16):

(4.23)\begin{equation} J_n(x) Y_n'(x) - J_n'(x) Y_n(x) = 2/({\rm \pi} x), \end{equation}

we find that

(4.24)\begin{equation} P = \frac{{\mathbb{P}}_{pw} \lambda}{2 {\rm \pi}} \left( \frac{8 N_0 \gamma}{{\rm \pi} \omega \rho h a F_0^2} \right) \sum_{n=0}^\infty \frac{\epsilon_n }{ |\varGamma_n {H_n^{(1)}}'(ka) - H_n^{(1)}(ka)|^2}. \end{equation}

Although explicit, the expression above for the power is not particularly informative. For example, the maximum power available to each circular mode, $P_n = \epsilon _n \lambda /2{\rm \pi}$, is not evident in the form given in (4.24), nor is it easy to see how (4.24) could be used to optimise $P$ with respect to the spring and damping parameters $\kappa$ and $\gamma$.

We can, however, derive expressions for $\kappa$ and $\gamma$ which maximise the power absorbed in any individual circular mode. This can be done in one of two ways. The first is to isolate the $m$th component, $P_m$, from the sum in (4.24) and then set $\partial P_m/\partial \kappa = \partial P_m/\partial \gamma = 0$.

It is easier, though, to use the theoretical framework developed in § 2 and impose $a_{m,0} = -\frac 12$ in (4.21) as a condition for maximum power absorption from the $m$th circular wave component and this yields the expression

(4.25)\begin{equation} \varGamma_m = \frac{H_m^{(2)}(ka)}{{H_m^{(2)}}'(ka)} = \frac{(J_m(ka) J_m'(ka) + Y_m(ka) Y_m'(ka)) + 2 \mathrm{i} /({\rm \pi} ka)} {|{H_m^{(2)}}'(ka)|^2}, \end{equation}

using (4.23) once again. The coefficients $a_{n,m}$ for $n \neq m$ are subsequently defined by (4.12).

Equating (4.25) with the definition of $\varGamma _n$ in (4.22) implies a complex condition to be satisfied by $\varLambda _0$, defined here by (4.18) and equating real and imaginary parts gives the conditions

(4.26)\begin{equation} \frac{\gamma}{\omega \rho ha} = \frac{2 F_0^2}{{\rm \pi} k^2 a^2 N_0 |{H_m^{(2)}}'(ka)|^2} \end{equation}

and

(4.27)\begin{equation} \frac{{\mathcal{M}} - \omega^{{-}2}(\kappa + {\mathcal{C}})}{\rho h a} = \frac{F_0^2(J_m(ka) J_m'(ka) + Y_m(ka) Y_m'(ka))} {ka N_0|{H_m^{(2)}}'(ka)|^2} + E_m. \end{equation}

These two equations define $\kappa$ and $\gamma$ for absorption of the maximum power, $P_m$, from the $m$th circular wave component.

4.2. Unequal springs and dampers

Let us now assume that the springs and dampers can vary with position around the cylinder so that the boundary condition (3.9) remains as

(4.28)\begin{equation} \varLambda(\theta) ha \left. \frac{\partial \phi}{\partial r} \right|_{r=a} = \,f(z) \int_{{-}h}^0 \phi(a,\theta,z) \,f(z) \, \textrm{d} z, \end{equation}

with

(4.29)\begin{equation} \varLambda(\theta) = \frac{{\mathcal{M}} - \omega^{{-}2}(\kappa(\theta) + {\mathcal{C}}) + \mathrm{i} \omega^{{-}1} \gamma(\theta)}{\rho h a} = \sum_{m=0}^\infty \epsilon_m \varLambda_m \cos m \theta ,\end{equation}

once expressed as a Fourier series. After substituting in the partial wave decomposition (4.13), multiplying by $\cos p \theta$ and integrating over $0 < \theta \leq 2 {\rm \pi}$, the result can be expressed either as

(4.30)\begin{equation} \frac12 \sum_{m=0}^\infty \epsilon_m \varLambda_m a \left[ \mathrm{i}^{|p-m|} \frac{\partial \phi_{|p-m|}}{\partial r} + \mathrm{i}^{p+m} \frac{\partial \phi_{p+m}}{\partial r} \right]_{r=a} = \,f(z) \mathrm{i}^p G_p, \end{equation}

where $G_p$ is defined by (4.16), or as

(4.31)\begin{equation} \frac12 \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n \left. \frac{\partial \phi_{n}}{\partial r} \right|_{r=a} a ( \varLambda_{|p-n|} + \varLambda_{p+n} ) = \,f(z) \mathrm{i}^p G_p, \end{equation}

depending on how one chooses to eliminate the summation variables through the orthogonality of the product of three cosines.

As in the previous section, there are two ways of proceeding. One is to imagine that the settings for the springs and dampers have been made such that $\varLambda _m$ are presumed known and then use the system above to determine $a_{n,0}$ and, subsequently, the power $P$. Substituting (4.14) and (4.16) into (4.31), multiplying by $\psi _0(z)$ and integrating over $-h < z < 0$ gives the system of equations

(4.32)\begin{align} &a_{p,0} \left[ H_p^{(1)}(ka) + \mathrm{i}^p \frac{ka N_0}{F_0^2} E_p {H_{p}^{(1)}}'(ka) \right] \nonumber\\ &\qquad - \frac{ka F_0^2}{2N_0} \sum_{n=0}^\infty a_{n,0} \epsilon_n \mathrm{i}^n {H_{n}^{(1)}}'(ka) ( \varLambda_{|p-n|} + \varLambda_{p+n} ) \nonumber\\ &\quad ={-}\left[ J_p(ka) + \mathrm{i}^p \frac{ka N_0}{F_0^2} E_p J_p'(ka) \right] + \frac{ka F_0^2}{2N_0} \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n J_n'(ka) ( \varLambda_{|p-n|} + \varLambda_{p+n} ), \end{align}

for $p=0,1,\ldots$. When $\varLambda _n = 0$ for $n \geq 1$ and $\varLambda (\theta ) = \varLambda _0$, a constant, (4.32) reduces to (4.21).

However, we also have the opportunity to design the settings of springs and dampers to control the device performance and so we treat $\varLambda _m$ as unknown and proceed as if $a_{n,0}$ are prescribed. Following the same procedure as above but with (4.30) replacing (4.31) leads to

(4.33)\begin{equation} \frac{ka N_0}{2 F_0^2} \sum_{m=0}^\infty \epsilon_m \varLambda_m ( Q_{|p-m|} + Q_{p+m} ) = \frac{\mathrm{i}^p G_p}{F_0} \quad p = 0,1,\ldots, \end{equation}

where $Q_n = \mathrm {i}^n (J_n'(ka) + a_{n,0} {H_n^{(1)}}'(ka))$. With a view to reaching the limit (2.13) set out in the introduction, albeit via a different route, we set $a_{n,0} = -\frac 12$ for $n \leq M$ and $a_{n,0} = -J_{n}'(ka)/{H_{n}^{(1)}}'(ka)$ for $n > M$ (corresponding to a non-absorbing cylinder; see § 2) so that

(4.34)\begin{equation} Q_n = \left\{ \begin{array}{@{}ll} \tfrac12 \mathrm{i}^n {H_n^{(2)}}'(ka), & n \leq M, \\ 0, & n > M, \end{array} \right. \end{equation}

and the right-hand side of (4.33) is

(4.35)\begin{equation} \frac{\mathrm{i}^p G_p}{F_0} = \left\{ \begin{array}{@{}ll} \tfrac12 \mathrm{i}^p (H_p^{(2)}(ka) + (ka N_0/F_0^2) E_p {H_{p}^{(2)}}'(ka)), & p \leq M, \\ {2 \mathrm{i}^{p+1} /({\rm \pi} ka {H_p^{(1)}}')}, & p > M. \end{array} \right. \end{equation}

The infinite system of (4.33) is then subject, for numerical purposes, to truncation subject to suitable convergence for a given $M$.

The process above describes how to fix the values of $\varLambda _m$ by tuning for maximum power from the first $M+1$ circular modes at a specified frequency. At other frequencies $a_{n,0}$ will need to be determined from (4.32) in terms of the fixed values of $\varLambda _m$.

Other design strategies could be adopted. For example, there may be benefits to distributing the capacity to absorb the maximum power from different circular modes across a range of frequencies. This might mitigate against overloading the device at a single frequency and could improve its overall performance in real sea states. It is not yet clear from the theory developed above how to design $\varLambda _m$ for such an outcome, other than perhaps by brute-force numerical optimisation.

5. A discrete paddle calculation

The previous sections have concentrated on a continuum description of the paddle motion and this has allowed us to develop particular strategies for selecting spring and damper settings. It is possible to construct solutions for the original arrangement of $N$ discrete paddles. Although this does not lead to the same mathematical insight, it will allow the accuracy of the continuum description of the absorbing cylinder to be assessed.

What follows is a standard linear decomposition method (e.g. Mei Reference Mei1983) in which we write

(5.1)\begin{equation} \phi = \phi_S + \sum_{q=1}^N (-\mathrm{i} \omega \sigma_q) \phi_R^{(q)}, \end{equation}

where $\phi _S$ is the scattering problem, subject to an incident plane wave (2.1) and satisfying

(5.2)\begin{equation} \left. \frac{\partial \phi_S}{\partial r} \right|_{r=a} = 0, \quad 0 < \theta \leq 2 {\rm \pi},\ -h < z < 0, \end{equation}

whilst $\phi _R^{(q)}$ is the radiation potential associated with the forced motion of the $q$th paddle and satisfying

(5.3)\begin{equation} \left. \frac{\partial \phi_R^{(q)}}{\partial r} \right|_{r=a} = \left\{ \begin{array}{@{}ll} \,f(z) \cos(\theta-\theta_q), & \theta_q - {\rm \pi}/N < \theta < \theta_q+{\rm \pi} /N, \\ 0, & \mbox{otherwise.} \end{array} \right. \end{equation}

The solution to the scattering problem for $\phi _S$ is given in (2.12) with $a_{n,0} \equiv a_{n,0}^S = -J_n'(ka)/H_{n}^{(1)}(ka)$. We can take advantage of the earlier theory to write the general expansion for the radiation potential as

(5.4)\begin{align} \phi_R^{(q)} = \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n b_{n,0}^{(q)} \left[ H_n^{(1)}(kr) \psi_0(z) + {H_n^{(1)}}'(ka) \sum_{m=1}^\infty \frac{k N_0 F_m K_n(k_m r)}{k_m N_m F_0 K_n'(k_ma)} \psi_m(z) \right] \cos n \theta, \end{align}

which takes account of the depth dependence $\,f(z)$ of the paddle. Using (5.4) in (5.3) and the orthogonality of $\cos n \theta$ and $\psi _m(z)$ determines the expansion coefficients as

(5.5)\begin{equation} b_{n,0}^{(q)} = \frac{\mathrm{i}^{{-}n} F_0 C_{qn}}{2 {\rm \pi}k N_0 {H_n^{(1)}}'(ka)}, \end{equation}

where

(5.6)\begin{align} C_{qn} &= \int_{\theta_q-{\rm \pi} /N}^{\theta_q+ {\rm \pi}/N} \cos (\theta - \theta_q) \cos n \theta \, \textrm{d} \theta \nonumber\\ &= \left\{ \begin{array}{@{}ll} (\tfrac12\sin (2{\rm \pi} /N) +{\rm \pi} /N)\cos\theta_q, & n =1, \\ {\left( \dfrac{\sin ((n+1){\rm \pi} /N)}{n+1} + \dfrac{\sin ((n-1){\rm \pi} /N)}{n-1} \right)\cos(n \theta_q)}, & n \neq 1. \end{array} \right. \end{align}

The wave force upon the $p$th paddle is similarly decomposed as

(5.7)\begin{equation} X_p = X_{S,p} + \sum_{q=1}^N (-\mathrm{i} \omega \sigma_q) X_{R,p}^{(q)}, \end{equation}

where

(5.8)\begin{align} X_{S,p} &={-}\mathrm{i} \omega \rho \int_{{-}h}^0 \int_{\theta_p-{\rm \pi} /N}^{\theta_p+ {\rm \pi}/N} \phi_S(a,\theta,z) \cos (\theta - \theta_p) \,f(z) \, a \, \textrm{d} \theta\, \textrm{d} z \nonumber\\ &={-} \frac{2 \mathrm{i} \rho g h A F_0}{{\rm \pi} k} \sum_{n=0}^\infty \frac{\epsilon_n \mathrm{i}^n C_{pn}}{{H_n^{(1)}}'(ka)}, \end{align}

after use of a number of previous results. Similarly

(5.9)\begin{align} X_{R,p}^{(q)}&={-}\mathrm{i} \omega \rho \int_{{-}h}^0 \int_{\theta_p-{\rm \pi} /N}^{\theta_p+ {\rm \pi}/N} \phi_R^{(q)}(a,\theta,z) \cos (\theta - \theta_p) \,f(z) \, a \, \textrm{d} \theta\, \textrm{d} z \nonumber\\ &={-}\mathrm{i} \omega ha \rho \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n b_{n,0}^{(q)} \left[ H_n^{(1)}(k a) F_0 + {H_n^{(1)}}'(ka) \sum_{m=1}^\infty \frac{k N_0 F_m^2 K_n(k_m a)}{k_m N_m F_0 K_n'(k_ma)}\right] C_{pn}. \end{align}

It is common practice to decompose complex-valued radiation forces into real added inertia and radiation damping components:

(5.10)\begin{equation} X_{R,p}^{(q)} = \mathrm{i} \omega A_{pq} - B_{pq}. \end{equation}

The equation of motion for the $n$th paddle in (3.3) is now written

(5.11)\begin{align} ( \kappa_n + {\mathcal{C}}(2 {\rm \pi}a/N) - \mathrm{i} \omega \gamma_n -\omega^2 {\mathcal{M}} (2 {\rm \pi}a/N) ) \sigma_n -\sum_{m=1}^N ( \omega^2 A_{nm} +\mathrm{i} \omega B_{nm}) \sigma_m = X_{S,n}, \end{align}

for $n=1,2,\ldots ,N$. This represents an $N \times N$ system of equations for the unknown complex-valued paddle displacement amplitudes $\sigma _n$.

Subsequently, the power generated by the device can be calculated in at least two independent ways. One is to see from (5.1) and (5.4) that the total radiated wave potential is

(5.12)\begin{equation} \phi^R \sim \sum_{q=1}^N (-\mathrm{i} \omega \sigma_q) \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n b_{n,0}^{(q)} H_n^{(1)}(kr) \cos n \theta, \quad \mbox{as } kr \to \infty, \end{equation}

and use this with $\phi _S$ to calculate the power in outgoing circular waves and subtract it from that in the incoming circular waves:

(5.13)\begin{equation} \phi_{out} \sim \psi_0(z) \sum_{n=0}^\infty \epsilon_n \mathrm{i}^n \left(\sum_{q=1}^N (-\mathrm{i} \omega \sigma_q) b_{n,0}^{(q)}+\frac{ \mathrm{i} A g}{\omega}\frac{J_n'(ka)}{{H_n^{(1)}}'(ka)}\right) H_n^{(1)}(kr) \cos n \theta ,\end{equation}

as $kr \to \infty$, and so we can use expression (2.11) for the power, where

(5.14)\begin{equation} a_{n,0} = \frac{\omega^2 }{Ag}\sum_{q=1}^N \sigma_q b_{n,0}^{(q)}-\frac{J_n'(ka)}{{H_n^{(1)}}'(ka)}. \end{equation}

The other method is to calculate the power generated by each of the paddles and sum over all $N$ paddles, which results in

(5.15)\begin{equation} P = \frac{\omega^2}{2} \sum_{q=1}^N \gamma_q|\sigma_q|^2. \end{equation}

Both expressions are calculated numerically to check the accuracy of the numerical code and produce graphically indistinguishable results.