1. Introduction

Partial differential equations are commonly used to describe two-dimensional plane stable field equations like steady concentration distributions, stable temperature distributions, electrostatic field equations, steady current field equations without rotation, and steady flow equations without rotation [1,2,3,4]. The optimal control problems governed by elliptic partial differential equations also play an important role in physical engineering, biological engineering, and social sciences areas, see [5,6,7,8,9,10]. Since the 1970s, the numerical approximation methods for optimal control problems have all received increasing attention. The main research methods are the finite difference method [11], finite element method [12,13,14,15], finite volume element method [16], and spectral method [17,18,19].

The optimal control problem [6,7] is a mathematical problem in which the minimum value of an objective function is determined under differential equation constraints. Finding a numerical solution is essential because it is challenging to find an analytical solution to a problem of this nature. In this paper, we look at a Dirichlet boundary optimal control problem on a complex connected domain that is governed by elliptic equations. The form is as follows:

(1)$\underset{u\in U_{ad}}{min}J\left(y,u\right):=\frac{1}{2}{∥y-y_d∥}_{L^2\left(\Omega \right)}^2+\frac{\alpha }{2}{∥u∥}_{L^2\left(\partial {\Omega }_1\right)}^2,$

(2)$\begin{array}{c}\hfill \left\{\begin{array}{cc}-\Delta y=f,\hfill & \mathrm{in}\Omega ,\hfill \\ y=u,\hfill & \mathrm{on}\partial {\Omega }_1,\hfill \\ \frac{\partial y}{\partial n_2}=0,\hfill & \mathrm{on}\partial {\Omega }_2.\hfill \end{array}\right.\end{array}$

The set $\Omega \subset R^2$ denotes a bounded complex connected domain with boundary $\Gamma =\partial {\Omega }_1\cup \partial {\Omega }_2$. Equation (2) is a state equation, y is the state variable, $u\in \partial {\Omega }_1$ is the Dirichlet boundary control variable, $\alpha >0$ is a regularization parameter, and $y_d\in H^1\left(\Omega \right)$, $f\in H^1\left(\Omega \right)$. $n_2$ is the outer unit normal of the boundary $\partial {\Omega }_2$. $U_{ad}$ is the admissible control set which is assumed to be of box type

$u\in U_{ad}:=\left\{u\in H^{1/2}\left(\partial {\Omega }_1\right):u_a\le u\le u_b\right\}$

This optimal Dirichlet boundary control problem can be used to describe the cooling process of concrete dam pouring [20]. $\partial {\Omega }_1$ is the pipe boundary on which the cold water enters and is therefore a Dirichlet boundary control condition. $\Omega$ indicates the region where the cold water acts, and $y_d$ is the ideal state; the goal is to control the temperature of the cold water so that the temperature $y\in \Omega$ is infinitely close to $y_d$. Note that there is no heat exchange on $\partial {\Omega }_2$ and hence a homogeneous Neumann boundary condition.

Dirichlet boundary control problems are more challenging than Neumann control or distributed control problems in general, both theoretically and numerically. However, the Dirichlet situation is attracting an increasing number of researchers. For example, the semilinear elliptic Dirichlet boundary control problem with pointwise control constraints in a convex, polygonal, open domain is studied and the $1-1/p$ convergence order of control is derived in [21]. The authors in [22] considered Dirichlet boundary control problems posed on smooth domains and obtained that the error order of control is ${h\left|lnh\right|}^{1/2}$. Based on a mixed variation scheme, the authors in [23] used a mixed finite element method to approximate the optimal control problem posed on both polygonal and general smooth domains. The authors in [24] used local mesh refinement toward the boundary by standard finite element discretizations and arrived second-order convergence. [25] also derived second-order convergence for elliptic Dirichlet boundary control but in finite dimensional control space. Numerical analysis for elliptic control problems can be found in [21,26,27,28]. For more details, one may refer to [12,29,30] and the references therein. In addition, for finite element approximations of distributed and Neumann boundary optimal control problems one can see [31,32,33,34,35], and for other numerical methods, one may refer to [36,37,38,39].

The finite volume element method (FVEM) is a discretization technique for partial differential equations. It is widely employed in the numerical approximation of some problems for partial differential equations because of its local conservative property and other appealing properties, such as robustness with unstructured meshes. For instance, the authors in [40] analyzed the spatially semidiscrete piecewise linear finite volume element method for parabolic equations in a convex polygonal domain in the plane. Two-grid finite volume element discretization techniques were presented for the two-dimensional second-order nonself-adjoint and indefinite linear elliptic problems and the two-dimensional second-order nonlinear elliptic problems in [41]. A priori error estimates for a semidiscrete piecewise linear finite volume element approximation to a second-order wave equation in a two-dimensional convex polygonal domain is discussed in [42]. More applications of the finite volume element method can be referred to [43,44,45,46,47,48,49,50] and the references therein.

The combination of the finite volume element method with other numerical methods can generate competitive numerical methods for solving partial differential equation problems. For example, an immersed finite volume element method was used to solve the elliptic interface problems in [51]. A one-parameter family of discontinuous Galerkin finite volume element methods was applied to approximate the solution of a class of second-order linear elliptic problems in [52]. The Fourier finite volume element method was employed to study two-dimensional quasigeostrophic equations on a sphere in [53]. The authors in [54] utilized the Fourier finite volume element method to give the numerical experiments of two classes of Dirichlet and distributed optimal control problems driven by elliptic PDEs on complex connected domains. The main concept behind the Fourier finite volume element approach is to employ the finite volume element method in the radial direction while applying the Fourier expansion in the azimuthal direction. In the radial direction, choose linear finite element and piecewise constant function spaces for the trial and test function spaces, respectively. The control for the variational inequality is generated employing a variational discretization technique (see [55]). As a result, the two-dimensional optimal control problem can be simplified to a sequence of one-dimension problems. A desired result can be obtained by this procedure.

Generally, the Dirichlet boundary optimal control problem is typically challenging to achieve a high order in two-dimensional environments. The purpose of this article is to provide a related theoretical explanation of this problem, as a prior work on numerical simulation [54] demonstrates that the Fourier finite element approach can reduce the error order of Dirichlet boundary control on complex connected domains. In addition, it is worth noting that, in contrast to [25], the Dirichlet boundary control space in this work possesses infinite dimensions.

To the best of our knowledge, this is the first study to estimate the convergence order of the Dirichlet boundary control problem using the Fourier finite volume element approach on complex connected domains. The error of Dirichlet boundary control consists of two parts: The Fourier truncation error and the one-dimensional finite volume element error. The Fourier finite volume element approach is applied to reduce a two-dimensional optimal control problem to a group of one-dimensional problems, with the Dirichlet boundary acting as an interval endpoint at which a quadratic interpolation scheme can be implemented so that Dirichlet boundary control can be reached to higher order convergence. It is pointed out here that this proving method can also be extended to the parabolic problem.

The outline for this paper is provided below. In Section 2, we deduce the optimal control problem and corresponding optimality conditions. In order to solve the elliptic problem, the Fourier finite volume element method is introduced in Section 3. In Section 4, the Fourier finite volume element method is used to demonstrate the convergence order of the Dirichlet boundary control. A few examples are given in Section 5 to help illustrate the theoretical analysis. Some recommendations are made toward the end of Section 6.

2. Optimality System

For $m\ge 0$ and $1\le s\le \infty$, applying the standard notation $W^{m,s}$ for Sobolev space on $\Omega$ with $\left|\right|·{\left|\right|}_{m,s,\Omega }$ and denoting by $H^m\left(\Omega \right)$ with norm $\left|\right|·{\left|\right|}_{m,\Omega }$ and seminorm ${|·|}_{m,\Omega }$ for $s=2$. That is,

$W^{m,s}\left(\Omega \right):=\left\{v\in L^s\left(\Omega \right),|D^{\alpha }v\in L^s\left(\Omega \right),\forall \alpha \in {\mathbb{Z}}_{+}^n,\left|\alpha \right|\le m\right\},$

${∥v∥}_{W^{m,s}\left(\Omega \right)}={\left(\sum _{\left|\alpha \right|\le m}{\int }_{\Omega }{\left|D^{\alpha }v\right|}^{s}dx\right)}^{\frac{1}{\mathrm{s}}},{\left|v\right|}_{W^{m,s}\left(\Omega \right)}={\left(\sum _{\left|\alpha \right|=m}{\int }_{\Omega }{\left|D^{\alpha }v\right|}^{s}dx\right)}^{\frac{1}{\mathrm{s}}},$

We use $\left(·,·\right)$ for the $L^2\left(\Omega \right)$-inner product, ${⟨·,·⟩}_{\partial {\Omega }_1}$ for the $L^2\left(\partial {\Omega }_1\right)$-inner product, ${\left(·,·\right)}_Q$ for the $L^2\left(Q\right)$-inner product, ${⟨·,·⟩}_{{\Gamma }_1}$ for the $L^2\left({\Gamma }_1\right)$-inner product, and ${\left(·,·\right)}_I$ for the $L^2\left(I\right)$-inner product.

Let $Y:=\left\{v\in H^1\left(\Omega \right){,v|}_{\partial {\Omega }_1}=u\right\}$ and $V:=\left\{v\in H^1\left(\Omega \right){,v|}_{\partial {\Omega }_1}=0\right\}$; the weak formulation of the state Equation (2) reads: find $y\in Y$ such that

(3)$a\left(y,v\right)=\left(f,v\right),\forall v\in V,$

$a\left(y,v\right)={\int }_{\Omega }\nabla y·\nabla vdx.$

Then, the optimal control problem (1) and (2) can be described as: Find $\left(y,u\right)\in Y\times U_{ad}$

(4)$\begin{array}{c}\hfill \left(P\right)\left\{\begin{array}{c}\underset{u\in U_{ad}}{min}J\left(y,u\right):=\frac{1}{2}{∥y-y_d∥}_{L^2\left(\Omega \right)}^2+\frac{\alpha }{2}{∥u∥}_{L^2\left(\partial {\Omega }_1\right)}^2,\hfill \\ s.t.a\left(y,v\right)=\left(f,v\right),\forall v\in V.\hfill \end{array}\right.\end{array}$

Suppose that $\left(\overline{y},\overline{u}\right)$ is the optimal solution. This is due to the fact that the control problem is strictly convex and satisfies the existence and uniqueness requirements of the solution in the constrained state Equation (2). Then, using the Lagrange multiplier method [5,7] to construct Lagrange function

$L\left(y,u,p\right)=J\left(y,u\right)-{\int }_{\Omega }\left(-\Delta y-f\right)pdx-{\int }_{\partial {\Omega }_1}\left(y-u\right)pds-{\int }_{\partial {\Omega }_2}\left(\frac{\partial y}{\partial n_2}\right)pds.$

We take the  Fréchet  derivative with respect to the state  y and choose a special $p\left(u\right)$, such that

(5)$L_y\left(y\left(u\right),u,p\right)=0.$

The adjoint state equation can be obtained as follows:

(6)$\begin{array}{c}\hfill \left\{\begin{array}{cc}-\Delta p=\overline{y}-y_d,\hfill & \mathrm{in}\Omega ,\hfill \\ p=0,\hfill & \mathrm{on}\partial {\Omega }_1,\hfill \\ \frac{\partial p}{\partial n_2}=0,\hfill & \mathrm{on}\partial {\Omega }_2.\hfill \end{array}\right.\end{array}$

The weak form of the adjoint state equation reads:

(7)$a\left(p,v\right)=\left(\overline{y}-y_d,v\right),\forall v\in V.$

We take the Fréchet derivative with respect to u. Then, the variation inequality, that is, the optimality condition is obtained:

(8)${⟨\alpha \overline{u}-\frac{\partial \overline{p}}{\partial n_1},u-\overline{u}⟩}_{\partial {\Omega }_1}\ge 0,\forall u\in U_{ad},$

That is, the necessary and sufficient condition for control $\overline{u}\in U_{ad}$ to be optimal is that it satisfies the variation inequality (8).                                                                                                                                                         

Taken together, the following theorem holds.

3. Fourier Finite Volume Element Method

3.1. Polar Coordinates Transform

Given the definition of the arbitrary bounded annular domain

$\Omega =\left\{\left(x_1,x_2\right):g_1\left(x_1,x_2\right)\le x_1^2+x_2^2\le g_2\left(x_1,x_2\right)\right\},$

$\partial {\Omega }_1=\left\{\left(x_1,x_2\right):x_1^2+x_2^2=g_1\left(x_1,x_2\right)\right\},\partial {\Omega }_2=\left\{\left(x_1,x_2\right):x_1^2+x_2^2=g_2\left(x_1,x_2\right)\right\},$

$\partial {\Omega }_1\to {\Gamma }_1:r=R_1\left(\theta \right),\partial {\Omega }_2\to {\Gamma }_2:r=R_2\left(\theta \right),\theta \in \left[0,2\pi \right),$

$\frac{\partial }{\partial x_1}=cos\theta \frac{\partial }{\partial r}-\frac{sin\theta }{r}\frac{\partial }{\partial \theta },\frac{\partial }{\partial x_2}=sin\theta \frac{\partial }{\partial r}+\frac{cos\theta }{r}\frac{\partial }{\partial \theta }.$

The Laplacian operator $\Delta$ in the polar coordinates is

$\Delta =\frac{{\partial }^2}{\partial r^2}+\frac{1}{r}\frac{\partial }{\partial r}+\frac{1}{r^2}\frac{{\partial }^2}{\partial {\theta }^2},$

$n_1=-\left(\frac{cos\theta +\frac{R_1^{\prime }\left(\theta \right)}{R_1\left(\theta \right)}sin\theta }{\sqrt{1+{\left(\frac{R_1^{\prime }\left(\theta \right)}{R_1\left(\theta \right)}\right)}^2}},\frac{sin\theta -\frac{R_1^{\prime }\left(\theta \right)}{R_1\left(\theta \right)}cos\theta }{\sqrt{1+{\left(\frac{R_1^{\prime }\left(\theta \right)}{R_1\left(\theta \right)}\right)}^2}}\right),n_2=\left(\frac{cos\theta +\frac{R_2^{\prime }\left(\theta \right)}{R_2\left(\theta \right)}sin\theta }{\sqrt{1+{\left(\frac{R_2^{\prime }\left(\theta \right)}{R_2\left(\theta \right)}\right)}^2}},\frac{sin\theta -\frac{R_2^{\prime }\left(\theta \right)}{R_2\left(\theta \right)}cos\theta }{\sqrt{1+{\left(\frac{R_2^{\prime }\left(\theta \right)}{R_2\left(\theta \right)}\right)}^2}}\right),$

$\frac{\partial y\left(x_1,x_2\right)}{\partial n_1}=\left(\frac{\partial y\left(x_1,x_2\right)}{\partial x_1},\frac{\partial y\left(x_1,x_2\right)}{\partial x_2}\right)·n_1=-\frac{\frac{\partial y\left(rcos\theta ,rsin\theta \right)}{\partial r}-\frac{R_1^{\prime }\left(\theta \right)}{R_1^2\left(\theta \right)}\frac{\partial y\left(rcos\theta ,rsin\theta \right)}{\partial \theta }}{\sqrt{1+{\left(\frac{R_1^{\prime }\left(\theta \right)}{R_1\left(\theta \right)}\right)}^2}},$

In the polar coordinates, the optimal control problem (4) can be redescribed as: Find $\left(y,u\right)\in Y_f\times U_{adf}$ such that

(12)$\begin{array}{c}\hfill \left(P\left(r,\theta \right)\right)\left\{\begin{array}{c}\underset{u\in U_{adf}}{min}J\left(y,u\right):=\frac{1}{2}{∥y-y_d∥}_{L^2\left(Q\right)}^2+\frac{\alpha }{2}{∥u∥}_{L^2\left({\Gamma }_1\right)}^2,\hfill \\ s.t.A\left(y,v\right)={\left(f,v\right)}_Q,\forall v\in V_f,\hfill \end{array}\right.\end{array}$

$A\left(y,v\right)={\int }_{Q}r\frac{\partial y}{\partial r}\frac{\partial v}{\partial r}drd\theta -{\int }_Q\frac{1}{r}\frac{{\partial }^{2}y}{\partial {\theta }^2}vdrd\theta ,$

${\left(f,v\right)}_Q={\int }_{Q}fvrdrd\theta ,$

The optimality system (9) can be written as

(13a)$\begin{array}{cc}\hfill & A\left(\overline{y},v\right)={\left(f,v\right)}_Q,\forall v\in V_f,\hfill \end{array}$

(13b)$\begin{array}{cc}\hfill & A\left(\overline{p},w\right)={\left(\left(\overline{y}-y_d\right),w\right)}_Q,\forall w\in V_f,\hfill \end{array}$

(13c)$\begin{array}{cc}\hfill & {⟨\alpha \overline{u}\sqrt{R_1^{\prime }{\left(\theta \right)}^2+R_1^2\left(\theta \right)}+\left(\frac{\partial \overline{p}}{\partial r}-\frac{R_1^{\prime }\left(\theta \right)}{R_1^2\left(\theta \right)}\frac{\partial \overline{p}}{\partial \theta }\right)R_1\left(\theta \right),u-\overline{u}⟩}_{{\Gamma }_1}\ge 0,\forall u\in U_{adf}.\hfill \end{array}$

3.2. Fourier Expansion and Truncation

Since the solution $y\left(r,\theta \right)$ of (11) is periodic in $\theta$, it can be written as:

(14)$y\left(r,\theta \right)=\sum _{\left|m\right|=0}^{\infty }{y}_m\left(r\right)e^{im\theta },$

Taking an truncation [57] to (14),

(15)$y_f\left(r,\theta \right)=\sum _{\left|m\right|=0}^M{y}_m\left(r\right)e^{im\theta }.$

Substitute (15) into (11), we can obtain

(16)$\begin{array}{c}\hfill \left\{\begin{array}{cc}-\left(\frac{{\partial }^2{y}_f}{\partial r^2}+\frac{1}{r}\frac{\partial y_f}{\partial r}+\frac{1}{r^2}\frac{{\partial }^2{y}_f}{\partial {\theta }^2}\right)=f_f,\hfill & \mathrm{in}Q,\hfill \\ y_f=u_f,\hfill & \mathrm{on}{\Gamma }_1,\hfill \\ \frac{\partial y_f}{\partial r}=0,\frac{R_2^{\prime }\left(\theta \right)}{R_2^2\left(\theta \right)}\frac{\partial y_f}{\partial \theta }=0,\hfill & \mathrm{on}{\Gamma }_2,\hfill \end{array}\right.\end{array}$

The optimal control problem $\left(P\right)$ can be redescribed as: Find $\left(y_f,u_f\right)\in Y_f\times U_{adf}$ such that

(17)$\begin{array}{c}\hfill \left(P_f\right)\left\{\begin{array}{c}\underset{u_f\in U_{adm}}{min}J\left(y_f,u_f\right):=\frac{1}{2}{∥y_f-y_{d_f}∥}_{L^2\left(Q\right)}^2+\frac{\alpha }{2}{∥u_f∥}_{L^2\left({\Gamma }_1\right)}^2,\hfill \\ s.t.A\left(y_f,v_f\right)={\left(f_f,v_f\right)}_Q,\forall v_f\in V_f,\hfill \end{array}\right.\end{array}$

Obviously, (16) can be rewritten as:

(18)$\begin{array}{c}\hfill \left\{\begin{array}{cc}-\left(\frac{d^2{y}_m}{d{r}^2}+\frac{1}{r}\frac{d{y}_m}{dr}-\frac{m^2}{r^2}{y}_m\right)=f_m,\hfill & \mathrm{in}Q,\hfill \\ y_m=u_m,\hfill & \mathrm{on}{\Gamma }_1,\hfill \\ \frac{d{y}_m}{dr}=0,\frac{R_2^{\prime }\left(\theta \right)}{R_2^2\left(\theta \right)}{y}_m=0,\hfill & \mathrm{on}{\Gamma }_2,\hfill \end{array}\right.\end{array}$

We now give the process of deriving the boundary conditions on ${\Gamma }_2$ of (11), (16) and (18):

Correspondingly, the adjoint state equation of (18) is

(19)$\begin{array}{c}\hfill \left\{\begin{array}{cc}-\left(\frac{d^2{p}_m}{d{r}^2}+\frac{1}{r}\frac{d{p}_m}{dr}-\frac{m^2}{r^2}{p}_m\right)=f_m,\hfill & \mathrm{in}Q,\hfill \\ p_m=0,\hfill & \mathrm{on}{\Gamma }_1,\hfill \\ \frac{d{p}_m}{dr}=0,\frac{R_2^{\prime }\left(\theta \right)}{R_2^2\left(\theta \right)}{p}_m=0,\hfill & \mathrm{on}{\Gamma }_2,\hfill \end{array}\right.\end{array}$

The weak forms of (18) and (19) are as follows:

(20a)$\begin{array}{cc}\hfill & A_m\left({\overline{y}}_m,v_m\right)={\left(f_m,v_m\right)}_Q,\forall v_m\in V_f,\hfill \end{array}$

(20b)$\begin{array}{cc}\hfill & A_m\left({\overline{p}}_m,w_m\right)={\left(\left({\overline{y}}_m-y_{d_m}\right),w_m\right)}_Q,\forall w_m\in V_f,\hfill \end{array}$

$A_m\left(y_m,v_m\right)={\int }_{Q}r\frac{d{y}_m}{dr}\frac{d{v}_m}{dr}drd\theta +{\int }_Q\frac{m^2}{r}{y}_m{v}_{m}drd\theta .$

From the above, $\theta \in \left[0,2\pi \right),$ and $y_m\left(r\right)=\frac{1}{2\pi }{\int }_0^{2\pi }y\left(r,\theta \right)e^{-im\theta }d\theta$. Consider the Fourier interpolation at point ${\theta }_k=\frac{2\pi ·k}{M}(k=1,2,3,···,M)$:

(21)$y_m\left(r\right)=\frac{1}{2\pi }{\int }_0^{2\pi }y\left(r,\theta \right)e^{-im\theta }d\theta \sim \frac{1}{M}\sum _{k=1}^M{y}_m\left(r,{\theta }_k\right)e^{-im{\theta }_k},$

Denoting $y_{m_k}\left(r\right)=y_m\left(r,{\theta }_k\right)$, correspondingly, (15) becomes

(22)$y_{f_{\tau }}=\sum _{\left|m\right|=0}^M\left(\frac{1}{M}\sum _{k=1}^M{y}_{m_k}\left(r\right)e^{-im{\theta }_k}\right)e^{im\theta },$

3.3. Finite Volume Element Method

For any fixed $k=1,2,···,M$, ${\Gamma }_1=R_1\left(\theta \right)\times (0,2\pi )$ becomes to ${\Gamma }_{1_k}=R_1\left({\theta }_k\right)$, ${\Gamma }_2=R_2\left(\theta \right)\times (0,2\pi )$ to ${\Gamma }_{2_k}=R_2\left({\theta }_k\right)$, and $I=\left(R_1\left(\theta \right),R_2\left(\theta \right)\right)$ to $I_k=\left(R_1\left({\theta }_k\right),R_2\left({\theta }_k\right)\right)$. Let $Y_{m_k}:=\left\{v\in H^1\left(I_k\right),v=u_{m_k}on{\Gamma }_{1_k}\right\}$, $U_{ad{m}_k}:=\left\{u\in H^{1/2}\left({\Gamma }_{1_k}\right):u_a\le u\le u_b\right\}$, $V_{m_k}:=\left\{v\in H^1\left(I_k\right),v=0on{\Gamma }_{1_k}\right\}$, and $Y_{f_{\tau }}:={\displaystyle \underset{k=1}{\overset{M}{⨂}}}{Y}_{m_k}$, $U_{ad{f}_{\tau }}:={\displaystyle \underset{k=1}{\overset{M}{⨂}}}{U}_{ad{m}_k}$, $V_{f_{\tau }}:={\displaystyle \underset{k=1}{\overset{M}{⨂}}}{V}_{m_k}$. Define some norms and seminorm as follows:

${∥v∥}_{L^2\left(I_k\right)}={\left(v,v\right)}_{I_k}^{\frac{1}{2}}:={\left({\int }_{R_1\left({\theta }_k\right)}^{R_2\left({\theta }_k\right)}r{\left|v\right|}^{2}dr\right)}^{\frac{1}{2}},\forall v\in V_{m_k},$

${\left|v\right|}_{H^1\left(I_k\right)}={\left(\frac{\partial v}{\partial r},\frac{\partial v}{\partial r}\right)}_{I_k}^{\frac{1}{2}}:={\left({\int }_{R_1\left({\theta }_k\right)}^{R_2\left({\theta }_k\right)}r{\left|\frac{\partial v}{\partial r}\right|}^{2}dr\right)}^{\frac{1}{2}},\forall v\in V_{m_k},$

${∥u∥}_{L^2\left({\Gamma }_{1_k}\right)}={\left(u,u\right)}_{{\Gamma }_{1_k}}^{\frac{1}{2}}:={\left(R_1\left({\theta }_k\right){\left|u\left(R_1\left({\theta }_k\right),\left({\theta }_k\right)\right)\right|}^2\right)}^{\frac{1}{2}},\forall u\in U_{ad{m}_k}.$

It is easy to prove that these norms are well defined. There holds:

${∥v_{f_{\tau }}∥}_{L^2\left(Q\right),\tau }={\left(\frac{1}{M}\sum _{k=1}^M{∥v∥}_{L^2\left(I_k\right)}^2\right)}^{\frac{1}{2}},\forall v_{f_{\tau }}\in Y_{f_{\tau }},$

${∥u_{f_{\tau }}∥}_{L^2\left({\Gamma }_1\right),\tau }={\left(\frac{1}{M}\sum _{k=1}^M{∥u∥}_{L^2\left({\Gamma }_{1_k}\right)}^2\right)}^{\frac{1}{2}},\forall u_{f_{\tau }}\in U_{ad{f}_{\tau }}.$

The corresponding discrete norms are defined as follows:

${∥v_h∥}_{L^2\left(I_k\right)}={\left(v_h,v_h\right)}_{I_k}^{\frac{1}{2}}:={\left(\sum _{i=1}^N{\int }_{r_{i-1}\left({\theta }_k\right)}^{r_i\left({\theta }_k\right)}r{\left|v_h\right|}^{2}dr\right)}^{\frac{1}{2}},\forall v_h\in Y_{m_k}^h,$

${∥u_h∥}_{L^2\left({\Gamma }_{1_k}\right)}={\left(u_h,u_h\right)}_{{\Gamma }_{1_k}}^{\frac{1}{2}}:={\left(R_1\left({\theta }_k\right){\left|u_h\left(|R_1\left({\theta }_k\right),\left({\theta }_k\right)\right)\right|}^2\right)}^{\frac{1}{2}},\forall u_h\in U_{a{d}_{m_k}}.$

There holds:

${∥v_{f_h}∥}_{L^2\left(Q\right),\tau }={\left(\frac{1}{M}\sum _{k=1}^M{∥v_h∥}_{L^2\left(I_k\right)}^2\right)}^{\frac{1}{2}},\forall v_{f_h}\in Y_{f_{\tau }}^h,$

${∥u_{f_h}∥}_{L^2\left({\Gamma }_1\right),\tau }={\left(\frac{1}{M}\sum _{k=1}^M{∥u_h∥}_{L^2\left({\Gamma }_{1_k}\right)}^2\right)}^{\frac{1}{2}},\forall u_{f_h}\in U_{ad}^h.$

The definition of discrete functions and discrete spaces will be given later.

The cost functional with state Equation (18) becomes an optimal control problem over a one-dimensional fixed interval. From (18), it can be inferred that:

(23)$\begin{array}{c}\hfill \left\{\begin{array}{cc}-\left(\frac{d^2{y}_{m_k}}{d{r}^2}+\frac{1}{r}\frac{d{y}_{m_k}}{dr}-\frac{m^2}{r^2}{y}_{m_k}\right)=f_{m_k},\hfill & \mathrm{in}{I}_k=\left(R_1\left({\theta }_k\right),R_2\left({\theta }_k\right)\right),\hfill \\ y_{m_k}=u_{m_k},\hfill & \mathrm{on}{\Gamma }_{1_k},\hfill \\ \frac{d{y}_{m_k}}{dr}=0,\frac{R_2^{\prime }\left({\theta }_k\right)}{R_2^2\left({\theta }_k\right)}{y}_{m_k}=0,\hfill & \mathrm{on}{\Gamma }_{2_k},\hfill \end{array}\right.\end{array}$

The optimality system can be rewritten as:

(24a)$\begin{array}{cc}\hfill & A_{m_k}\left({\overline{y}}_{m_k},v_{m_k}\right)={\left(f_{m_k},v_{m_k}\right)}_{I_k},\forall v_{m_k}\in V_{m_k},\hfill \end{array}$

(24b)$\begin{array}{cc}\hfill & A_{m_k}\left({\overline{p}}_{m_k},w_{m_k}\right)={\left(\left({\overline{y}}_{m_k}-y_{d_{m_k}}\right),w_{m_k}\right)}_{I_k},\forall w_{m_k}\in V_{m_k},\hfill \end{array}$

(24c)$\begin{array}{cc}\hfill & {⟨\alpha {\overline{u}}_{m_k}\sqrt{R_1^{\prime }{\left({\theta }_k\right)}^2+R_1^2\left({\theta }_k\right)}+\frac{d{\overline{p}}_{m_k}}{dr}{R}_1\left({\theta }_k\right),u_{m_k}-{\overline{u}}_{m_k}⟩}_{{\Gamma }_{1_k}}\ge 0,\forall u_{m_k}\in U_{ad{m}_k},\hfill \end{array}$

${\displaystyle A_{m_k}\left(y_{m_k},v_{m_k}\right)={\int }_{I_k}r\frac{d{y}_{m_k}}{dr}\frac{d{v}_{m_k}}{dr}dr+m^2{\int }_{I_k}\frac{1}{r}{y}_{m_k}{v}_{m_k}dr.}$

The optimal control problem $\left(P_f\right)$ can be redescribed as: Find $\left(y_{f_{\tau }},u_{f_{\tau }}\right)\in Y_{f_{\tau }}\times U_{ad{f}_{\tau }}$ such that

(25)$\begin{array}{c}\hfill \left(P_{f_{\tau }}\right)\left\{\begin{array}{c}\underset{u_{f_{\tau }}\in U_{ad{f}_{\tau }}}{min}J\left(y_{f_{\tau }},u_{f_{\tau }}\right):=\frac{1}{2}{∥y_{f_{\tau }}-y_{d_{f_{\tau }}}∥}_{L^2\left(Q\right),\tau }^2+\frac{\alpha }{2}{∥u_{f_{\tau }}∥}_{L^2\left({\Gamma }_1\right),\tau }^2,\hfill \\ s.t.A_{f_{\tau }}\left(y_{f_{\tau }},v_{f_{\tau }}\right)={\left(f_{f_{\tau }},v_{f_{\tau }}\right)}_{Q,\tau },\forall v_{f_{\tau }}\in V_{f_{\tau }},\hfill \end{array}\right.\end{array}$

For the purpose of finite volume element approximation of (24a), discretizing the interval $\left[R_1\left({\theta }_k\right),R_2\left({\theta }_k\right)\right]$ into a grid $T_h$ with nodes

$R_1\left({\theta }_k\right)=r_0\left({\theta }_k\right)<r_1\left({\theta }_k\right)<r_2\left({\theta }_k\right)<\cdots <r_{N-1}\left({\theta }_k\right)<r_N\left({\theta }_k\right)=R_2\left({\theta }_k\right).$

Denoting the mesh size $h_i\left({\theta }_k\right)=r_i\left({\theta }_k\right)-r_{i-1}\left({\theta }_k\right)$, and writing $I_{k_i}=\left[r_{i-1}\left({\theta }_k\right),r_i\left({\theta }_k\right)\right]$. Placing a dual grid $T_h^{*}$ with nodes

$R_1\left({\theta }_k\right)=r_0\left({\theta }_k\right)<r_{1/2}\left({\theta }_k\right)<r_{3/2}\left({\theta }_k\right)<\cdots <r_{N-1/2}\left({\theta }_k\right)<r_N\left({\theta }_k\right)=R_2\left({\theta }_k\right),$

Typical basis function ${\varphi }_i\left(r\right)$ on $I_{k_i}$ and ${\psi }_j\left(r\right)$ on $I_{k_j}^{*}$ are shown below

(26)$\begin{array}{cc}\hfill {\varphi }_i\left(r\right)& =\left\{\begin{array}{cc}1-h_i^{-1}\left|r-r_i\left({\theta }_k\right)\right|,\hfill & r_{i-1}\left({\theta }_k\right)\le r\le r_i\left({\theta }_k\right),\hfill \\ 1-h_{i+1}^{-1}\left|r-r_i\left({\theta }_k\right)\right|,\hfill & r_i\left({\theta }_k\right)\le r\le r_{i+1}\left({\theta }_k\right),\hfill \\ 0.\hfill & elsewhere.\hfill \end{array}\right.\hfill \end{array}$

(27)$\begin{array}{cc}\hfill {\psi }_j\left(r\right)& =\left\{\begin{array}{cc}1,\hfill & r\in I_j^{*},\hfill \\ 0.\hfill & r\notin I_j^{*}.\hfill \end{array}\right.\hfill \end{array}$

Now, let $Y_{m_k}^h$ be the standard linear finite element space defined on the $T_h$:

$Y_{m_k}^h=\left\{v\in C\left(I_k\right){:v|}_{I_k}\mathrm{is}\mathrm{piecewise}\mathrm{linear}\mathrm{function}\mathrm{for}\mathrm{all}{I}_k\in T_h\right\}$

$Y_{m_k}^{h*}=\left\{v\in L^2\left(I_k\right){:v|}_{I_k^{*}}\mathrm{is}\mathrm{piecewise}\mathrm{constant}\mathrm{function}\mathrm{for}\mathrm{all}{I}_k^{*}\in T_h^{*}\right\}.$