Low-regret control for a fractional wave equation with incomplete data

Baleanu, Dumitru; Joseph, Claire; Mophou, Gisèle

doi:10.1186/s13662-016-0970-8

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Published: 21 September 2016

Low-regret control for a fractional wave equation with incomplete data

Advances in Difference Equations volume 2016, Article number: 240 (2016) Cite this article

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Abstract

We investigate in this manuscript an optimal control problem for a fractional wave equation involving the fractional Riemann-Liouville derivative and with missing initial condition. For this purpose, we use the concept of no-regret and low-regret controls. Assuming that the missing datum belongs to a certain space we show the existence and the uniqueness of the low-regret control. Besides, its convergence to the no-regret control is discussed together with the optimality system describing the no-regret control.

1 Introduction

Let us consider $N \in\mathbb{N}^{*}$ and Ω a bounded open subset of $\mathbb{R}^{N}$ possessing the boundary ∂Ω of class $C^{2}$. When the time $T>0$, we consider $Q = \Omega\times\, ]0,T[$ and $\Sigma= \partial \Omega \times\, ]0,T[ $ and we discuss the fractional wave equation:

$$ \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}y(x,t) - \Delta y(x,t) = v(x,t),\quad (x,t) \in Q, \\ y(\sigma,t) = 0, \quad (\sigma,t) \in\Sigma, \\ I^{2-\alpha} y(x,0^{+}) = y^{0},\quad x \in\Omega , \\ \frac{\partial}{\partial t}I^{2-\alpha }y(x,0^{+}) = g, \quad x \in \Omega , \end{array}\displaystyle \right . $$

(1)

such that $3/2 < \alpha<2$, $y^{0} \in H^{2}(\Omega )\cap H^{1}_{0}(\Omega ) $, $I^{2-\alpha }y(x,0^{+})=\lim_{t \to0} I^{2-\alpha }y(x,t)$ and $\frac{\partial}{\partial t} I^{2-\alpha }y(x, 0^{+})=\lim_{t \to0} \frac{\partial}{\partial t}I^{2-\alpha }y(x,t)$ where the fractional integral $I^{\alpha}$ of order α and the fractional derivative $D^{\alpha}_{\mathrm{RL}}$ of order α are within the Riemann-Liouville sense. The function g is unknown and belongs to $L^{2}(\Omega )$ and the control $v \in L^{2}(Q)$.

Since the initial condition is unknown, the system (1) is a fractional wave equations with missing data. Such equations are used to model pollution phenomena. In this system g represents the pollution term.

According to the data, we know that system (1) admits a unique solution $y(v,g) = y(x,t;v,g)$ in $L^{2}((0,T);H^{1}_{0}(\Omega )) \subset L^{2}(Q)$ [1]. Hence, we can define the following functional:

$$ J(v,g) = \bigl\Vert y(v,g) - z_{d} \bigr\Vert ^{2}_{L^{2}(Q)} + N \Vert v \Vert ^{2}_{L^{2}(Q)}, $$

(2)

where $z_{d} \in L^{2}(Q)$ and $N>0$.

In this manuscript, we discuss the optimal control problem, namely

$$ \inf_{v \in L^{2}(Q)} J(v,g), \quad \forall g\in L^{2}(\Omega). $$

(3)

If the function g is given, namely $g=g_{0}\in L^{2}(\Omega)$, then system (1) is completely determined and problem (3) becomes a classical optimal control problem [2]. Such a problem was studied by Mophou and Joseph [1] with a cost function defined with a final observation. Actually, the authors proved that one can approach the fractional integral of order $0<2-\alpha<1/2$ of the state at final time by a desired state by acting on a distributed control. For more literature on fractional optimal control, we refer to [3–11] and the references therein.

Since the function g is unknown, the optimal control problem (3) has no sense because $L^{2}(\Omega)$ is of infinite dimension. So, to solve this problem, we proceed as Lions [12, 13] for the control of partial differential equations with integer time derivatives and missing data. This means that we use the notions of no-regret and low-regret controls. There are many works using these concepts in the literature. In [14] for instance, Nakoulima et al. utilized these concepts to control distributed linear systems possessing missing data. A generalization of this approach can be found in [15] for some nonlinear distributed systems possessing incomplete data. Jacob and Omrane used the notion of no-regret control to control a linear population dynamics equation with missing initial data [16]. Recently, Mophou [17] used these notions to control a fractional diffusion equation with unknown boundary condition. For more literature on such control we refer to [18–23] and the references therein.

In our paper, we show that the low-regret control problem associated to (1) admits a unique solution which converges toward the no-regret control. We provide the singular optimality system for the no-regret control.

Below we present the organization of our manuscript. In the following section, we show briefly some results about fractional derivatives and preliminary results on the existence and uniqueness of solution to fractional wave equations. In Section 3, we investigate the no-regret and low-regret control problems corresponding to (1).

2 Preliminaries

Below, we give briefly some results about fractional calculus and some existence results about fractional wave equations.

Definition 2.1

[24, 25]

If $f : \mathbb{R}_{+} \to\mathbb{R}$ is a continuous function on $\mathbb{R}_{+}$, and $\alpha>0$, then the expression of the Riemann-Liouville fractional integral of order α is

$$I^{\alpha} f(t) = \frac{1}{\Gamma(\alpha)} \int_{0}^{t} (t-s) ^{\alpha-1} f(s)\,ds, \quad t>0. $$

Definition 2.2

[25, 26]

The form of the left Riemann-Liouville fractional derivative of order $0\leq n-1< \alpha<n$, $n\in\mathbb{N}$ of f is given by

$$D^{\alpha}_{\mathrm{RL}}f(t) = \frac{1}{\Gamma (n-\alpha)}\cdot \frac{d^{n}}{dt^{n}} \int_{0}^{t} (t-s)^{n-1-\alpha }f(s)\,ds, \quad t >0. $$

Definition 2.3

[25, 26]

The left Caputo fractional derivative of order $0\leq n-1< \alpha<n$, $n\in\mathbb{N}$ of f is given by

$$ D^{\alpha}_{\mathrm{C}}\, f(t) = \frac{1}{\Gamma (n-\alpha)} \int_{0}^{t} (t-s)^{n-1-\alpha } f^{(n)}(s) \,ds, \quad t>0. $$

(4)

We mention that in the above two definitions we consider $f : \mathbb {R}_{+} \to \mathbb{R}$.

Definition 2.4

[25–27]

Let $f:\mathbb{R}_{+} \to\mathbb{R}$, $0\leq n-1< \alpha<n$, $n\in \mathbb{N}$. Then the right Caputo fractional derivative of order α of f is

$$ \mathcal{D}^{\alpha}_{\mathrm {C}}f(t) = \frac{(-1)^{n}}{\Gamma (n-\alpha )} \int_{t}^{T} (s-t)^{n-1-\alpha } f^{(n)}(s) \,ds,\quad 0< t< T . $$

(5)

In all above definitions we assume that the integrals exist.

Lemma 2.5

[1]

Let $y \in\mathcal{C}^{\infty}( \overline{Q})$ and $\varphi\in \mathcal{C}^{\infty }( \overline{Q})$. Then we have

$$\begin{aligned}& \int_{Q} \bigl( D^{\alpha }_{\mathrm{RL}}y(x,t) - \Delta y(x,t)\bigr) \varphi(x,t)\,dx\,dt \\& \quad = \int_{\Omega } \varphi(x,T)\frac{\partial}{\partial t} I^{2 -\alpha }y(x,T) \,dx - \int_{\Omega }\varphi(x,0)\frac{\partial}{\partial t}I^{2 -\alpha }y \bigl(x,0^{+}\bigr)\,dx \\& \qquad {}- \int_{\Omega } I^{2-\alpha }y(x,T)\frac{\partial\varphi}{\partial t} (x,T) \,dx + \int_{\Omega } I^{2-\alpha }y(x,0)\frac{\partial\varphi}{\partial t} (x,0) \,dx \\& \qquad {}+ \int_{\Sigma}y (\sigma,s) \frac{\partial\varphi}{\partial\nu} (\sigma,s)\,d\sigma \,dt - \int_{\Sigma}\frac{\partial y}{\partial\nu}(\sigma,s) \varphi(\sigma,s) \,d \sigma \,dt \\& \qquad {}+ \int_{Q} y(x,t) \bigl( \mathcal{D}_{\mathrm{C}}^{\alpha }\, \varphi(x,t) - \Delta \varphi(x,t)\bigr)\,dx \,dt. \end{aligned}$$

(6)

In the following we give some results that will be use to prove the existence of the low-regret and no-regret controls.

Theorem 2.6

[1]

Let $3/2 <\alpha <2$, $y^{0} \in H^{2}(\Omega)\cap H^{1}_{0}(\Omega )$, $y^{1} \in L^{2}(\Omega )$ and $v \in L^{2}(Q)$. Then the problem

$$ \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}y(x,t) - \Delta y(x,t) = v(x,t),\quad (x,t) \in Q, \\ y(\sigma,t) = 0,\quad (\sigma,t) \in\Sigma, \\ I^{2-\alpha} y(x,0^{+}) = y^{0},\quad x \in\Omega , \\ \frac{\partial}{\partial t}I^{2-\alpha }y(x,0^{+}) = y^{1},\quad x \in \Omega \end{array}\displaystyle \right . $$

(7)

has a unique solution $y\in L^{2}((0,T); H^{1}_{0}(\Omega))$. Moreover, the following estimates hold:

$$\begin{aligned}& \Vert y \Vert _{L^{2}((0,T);H^{1}_{0}(\Omega ))} \leq \Delta\bigl( \bigl\Vert y^{0}\bigr\Vert _{H^{1}_{0}(\Omega )} + \bigl\Vert y^{1}\bigr\Vert _{L^{2}(\Omega )}+\Vert v\Vert _{L^{2}(Q)}\bigr), \end{aligned}$$

(8)

$$\begin{aligned}& \bigl\Vert I^{2-\alpha }y\bigr\Vert _{C([0,T];H^{1}_{0}(\Omega ))} \leq \Pi \bigl( \bigl\Vert y^{0}\bigr\Vert _{H^{1}_{0}(\Omega )} +\bigl\Vert y^{1} \bigr\Vert _{L^{2}(\Omega )} + \Vert v \Vert _{L^{2}(Q)} \bigr), \end{aligned}$$

(9)

$$\begin{aligned}& \biggl\Vert \frac{\partial}{\partial t}I^{2-\alpha }y \biggr\Vert _{C([0,T];L^{2}(\Omega ))} \leq\Theta\bigl( \bigl\Vert y^{0}\bigr\Vert _{H^{2}(\Omega )} + \bigl\Vert y^{1}\bigr\Vert _{L^{2}(\Omega )} + \Vert v \Vert _{L^{2}(Q)}\bigr), \end{aligned}$$

(10)

with

$$\begin{aligned}& \Delta=\max \biggl( C\sqrt{ \frac{2T^{2\alpha -3}}{(2\alpha -3)}}, C \sqrt{ \frac{T^{\alpha -1}}{(\alpha -1)}}, C \sqrt{\frac{2 T^{\alpha }}{ \alpha (\alpha -1)}} \biggr), \\& \Pi= \sup \biggl(C\sqrt{2},C \sqrt{2T^{2-\alpha }}, C \sqrt{ \frac{2T^{3-\alpha }}{(3-\alpha )}} \biggr), \end{aligned}$$

and

$$\Theta=\max \bigl(\sqrt{2}C T^{\alpha -1},\sqrt{2}C \bigr). $$

Consider the fractional wave equation involving the left Caputo fractional derivative of order $3/2<\alpha <2$:

$$ \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{C}}\, y(x,t) - \Delta y(x,t) = f,\quad (x,t)\in Q, \\ y(\sigma,t) = 0,\quad (\sigma,t)\in\Sigma, \\ y(x,0) = 0,\quad x\in\Omega, \\ \frac{\partial y}{\partial t}(x,0) = 0,\quad x\in\Omega, \end{array}\displaystyle \right . $$

(11)

where $f \in L^{2}(Q)$.

Theorem 2.7

Let $f \in L^{2}(Q)$. Then problem (11) has a unique solution $y \in C([0,T]; H^{1}_{0}(\Omega ))$. Moreover, $\frac{\partial y}{\partial t} \in C([0,T];L^{2}(\Omega ))$ and there exists $C>0$ in such a way that

$$ \| y \|_{C([0,T];H^{1}_{0}(\Omega ))} \leq C \sqrt{\frac{T^{\alpha -1}}{\alpha -1}} \| f \|_{L^{2}(Q)} $$

(12)

and

$$ \biggl\Vert \frac{\partial y}{\partial t} \biggr\Vert _{C([0,T];L^{2}(\Omega ))} \leq C \sqrt{ \frac{T^{2\alpha -3}}{2\alpha -3}} \| f \|_{L^{2}(Q)}. $$

(13)

Proof

Below we proceed as was mentioned in [28]. □

Corollary 2.8

Let $3/2<\alpha <2$ and $\phi\in L^{2}(Q)$. Consider the fractional wave equation:

$$ \left \{ \textstyle\begin{array}{l} \mathcal{D}^{\alpha}_{\mathrm{C}}\, \psi(x,t) - \Delta\psi(x,t) = \phi,\quad (x,t)\in\mathcal{Q}, \\ \psi(\sigma,t) = 0,\quad (\sigma,t)\in\Sigma, \\ \psi(x,T) = 0,\quad x\in\Omega, \\ \frac{\partial\psi}{\partial t} (x,T) = 0 ,\quad x\in\Omega, \end{array}\displaystyle \right . $$

(14)

where $\mathcal{D}^{\alpha}_{\mathrm{C}}$ is the right Caputo fractional derivative of order $1<\alpha<2 $. Then (14) has a unique solution ${\psi} \in\mathcal{C}([0,T]; H^{1}_{0}(\Omega ))$. Moreover, $\frac{\partial\psi}{\partial t} \in C([0,T];L^{2}(\Omega ))$, and there exists $C>0$ fulfilling

$$ \| {\psi} \|_{C([0,T];H^{1}_{0}(\Omega ))} \leq C \sqrt{\frac{T^{\alpha -1}}{\alpha -1}} \|{\phi} \|_{L^{2}(Q)} $$

(15)

and

$$ \biggl\Vert \frac{\partial\psi}{\partial t} \biggr\Vert _{C([0,T];L^{2}(\Omega ))} \leq C \sqrt{ \frac{T^{2\alpha -3}}{2\alpha -3}} \| {\phi} \|_{L^{2}(Q)}. $$

(16)

Proof

If we make the change of variable $t \to T-t$ in (14), then we conclude that $\hat{\psi}(t)=\psi(T-t)$ verifies

$$ \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{C}}\, \hat{\psi} - \Delta\hat{\psi} = \hat {\phi} \quad \mbox{in } Q, \\ \hat{\psi} = 0 \quad \mbox{on } \Sigma, \\ \hat{\psi}(0) = 0 \quad \mbox{in } \Omega, \\ \frac{\partial\hat{\psi}}{\partial t} (0) = 0 \quad \mbox{in } \Omega , \end{array}\displaystyle \right . $$

(17)

where $\hat{\phi}(t)=\phi(T-t)$ and $D^{\alpha}_{\mathrm{C}}$ is the left Caputo fractional derivative of order $3/2< \alpha <2$. Because $T-t \in[0,T]$ when $t \in[0,T]$, we say that $\hat{\phi} \in L^{2}(Q)$ due to the fact that $\phi\in L^{2}(Q)$. It then suffices to use Theorem 2.7 to conclude. □

We also need some trace results.

Lemma 2.9

[1]

Let $f \in L^{2}(Q)$ and $y \in L^{2}(Q)$ such that $D^{\alpha}_{\mathrm {RL}}y - \Delta y =f$. Then:

(i)
$y_{|\partial\Omega }$ and $\frac{\partial y}{\partial\nu }_{| \partial\Omega }$ exist and belong to $H^{-2}((0,T);H^{-1/2}(\partial \Omega ))$ and $H^{-2}((0,T);H^{-3/2}(\partial\Omega ))$ respectively.
(ii)
$I^{2-\alpha }y \in C([0,T];L^{2}(\Omega ))$.
(iii)
$\frac{\partial}{\partial t} I^{2-\alpha }y \in C([0,T];H^{-1}(\Omega ))$.

3 Existence and uniqueness of no-regret and low-regret controls

Below, we show the existence and the uniqueness of the no-regret control and the low-regret control problem for system (1).

Lemma 3.1

Let $v \in L^{2}(Q)$ and $g \in L^{2}(\Omega )$. Then we have

$$\begin{aligned} J(v,g) =&J(0,g)+J(v,0)-J(0,0) \\ &{}+ 2 \int_{Q} \bigl[y(0,g)-y(0,0)\bigr] \bigl[y(v,0)-y(0,0)\bigr] \,dt \,dx. \end{aligned}$$

(18)

Here J denotes the functional given by (2) and $y(v,g)=y(x,t;v,g) \in L^{2}(0,T;H^{1}_{0}(\Omega )) \subset L^{2}(Q)$ is the solution of (1).

Proof

Let us consider $y(v,0)=y(x,t;v,0)$, $y(0,g)=y(x,t;0,g)$, and $y(0,0)=y(x,t;0,0)$ be the solutions of

$$\begin{aligned}& \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}y(v,0) - \Delta y(v,0) = v \quad \mbox{in } Q , \\ y = 0 \quad \mbox{on } \Sigma, \\ I^{2-\alpha} y(0;v,0) = y^{0} \quad \mbox{in } \Omega , \\ \frac{\partial}{\partial t} I^{2-\alpha }y(0;v,0) = 0 \quad \mbox{in } \Omega, \end{array}\displaystyle \right . \end{aligned}$$

(19)

$$\begin{aligned}& \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}y(0,g) - \Delta y(0,g) = 0 \quad \mbox{in } Q, \\ y = 0\quad \mbox{on }\Sigma , \\ I^{2-\alpha} y(0;0,g) = y^{0} \quad \mbox{in } \Omega, \\ \frac{\partial}{\partial t} I^{2-\alpha }y(0;0,g) = g \quad \mbox{in } \Omega, \end{array}\displaystyle \right . \end{aligned}$$

(20)

and

$$ \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}y(0,0) - \Delta y(0,0) = 0\quad \mbox{in } Q, \\ y = 0 \quad \mbox{on } \Sigma, \\ I^{2-\alpha} y(0;0,0) = y^{0} \quad \mbox{in } \Omega, \\ \frac{\partial}{\partial t} I^{2-\alpha }y(0;0,0) = 0 \quad \mbox{in } \Omega, \end{array}\displaystyle \right . $$

(21)

where $I^{2-\alpha }y(0;v,g) = \lim_{t \to0^{+}} I^{2-\alpha }y(x,t;v,g)$ and $\frac{\partial}{\partial t} I^{2-\alpha }y(0;v,g) = \lim_{t \to0^{+}} \frac{\partial}{\partial t} I^{2-\alpha }y(x,t;v,g)$.

Since $v \in L^{2}(Q)$, $y^{0} \in H^{1}_{0}(\Omega ) \cap H^{2}(\Omega )$ and $g \in L^{2}(\Omega )$, we see from Theorem 2.6 that $y(v,0)$, $y(0,g)$ and $y(0,0)$ belong to $L^{2}((0,T);H^{1}_{0}(\Omega ))$.

Observing that

$$\begin{aligned}& J(v,0) = \int_{Q} \bigl[y(v,0)-z_{d}\bigr] \bigl[y(v,0)-z_{d}\bigr]\,dt \,dx + N\| v \|_{L^{2}(Q)}^{2}, \end{aligned}$$

(22a)

$$\begin{aligned}& J(0,g) = \int_{Q} \bigl[y(0,g)-z_{d}\bigr] \bigl[y(0,g)-z_{d}\bigr]\,dt \,dx, \end{aligned}$$

(22b)

$$\begin{aligned}& J(0,0) = \int_{Q} \bigl[y(0,0)-z_{d}\bigr] \bigl[y(0,0)-z_{d}\bigr]\,dt \,dx, \end{aligned}$$

(22c)

and using the fact that

$$y(v,g)=y(v,0)+y(0,g)-y(0,0), $$

we have

$$\begin{aligned} J(v,g) =& \bigl\Vert y(v,g)-z_{d}\bigr\Vert ^{2}_{L^{2}(Q)} + N\Vert v\Vert _{L^{2}(Q)}^{2} \\ =& \bigl\Vert y(v,0)+y(0,g)-y(0,0)-z_{d} \bigr\Vert _{L^{2}(Q)}^{2} + N\Vert v \Vert _{L^{2}(Q)}^{2} \\ =& J(v,0)+2 \int_{Q} \bigl[y(v,0)-z_{d}\bigr] \bigl[y(0,g)-y(0,0)\bigr]\,dt \,dx \\ &{} + \bigl\Vert y(0,g)-y(0,0)-z_{d} \bigr\Vert _{L^{2}(Q)}^{2} \\ =& J(v,0)+2 \int_{Q} \bigl[y(v,0)-y(0,0)\bigr] \bigl[y(0,g)-y(0,0)\bigr] \,dt \,dx \\ &{} + 2 \int_{Q} \bigl[y(0,0)-z_{d}\bigr] \bigl[y(0,g)-y(0,0)\bigr]\,dt \,dx+\bigl\Vert y(0,g)-y(0,0)-z_{d} \bigr\Vert _{L^{2}(Q)}^{2}. \end{aligned}$$

Using

$$\begin{aligned} \bigl\Vert y(0,g)-y(0,0)-z_{d} \bigr\Vert _{L^{2}(Q)}^{2} =&J(0,g)+J(0,0) \\ &{}-2 \int_{Q} \bigl[y(0,0)-z_{d}\bigr] \bigl[y(0,g)-y(0,0)\bigr]\,dt \,dx-2J(0,0), \end{aligned}$$

we conclude that

$$\begin{aligned} J(v,g) =& J(0,g)+J(v,0) - J(0,0) \\ &{}+2 \int_{\Omega } \int_{0}^{T} \bigl[y(v,0)-y(0,0)\bigr] \bigl[y(0,g)-y(0,0)\bigr]\,dt \,dx. \end{aligned}$$

□

Lemma 3.2

Let $v \in L^{2}(Q)$ and $g \in L^{2}(\Omega )$. Then we have

$$ J(v,g)=J(0,g)+J(v,0)-J(0,0)+ 2 \int_{\Omega } g \zeta(x,0;v) \,dx, $$

(23)

where $\zeta(v)=\zeta(x,t;v) \in C([0,T];H^{1}_{0}(\Omega ))$ be solution of

$$ \left \{ \textstyle\begin{array}{l} \mathcal{D}^{\alpha }_{\mathrm{C}} \, \zeta(v) - \Delta\zeta(v) = y(v,0)-y(0,0)\quad \textit{in } Q, \\ \zeta = 0 \quad \textit{on } \Sigma, \\ \zeta(x,T;v) = 0\quad \textit{in } \Omega, \\ \frac{\partial\zeta}{\partial t}(x,T;v) = 0 \quad \textit{in } \Omega. \end{array}\displaystyle \right . $$

(24)

Proof

Since $y(v,0)-y(0,0) \in L^{2}(Q)$, from Proposition 2.8, we know that the system (24) admits a unique solution $\zeta(v) \in C([0,T];H^{1}_{0}(\Omega ))$. Also, there exists $C>0$ such that

$$ \bigl\Vert \zeta(v) \bigr\Vert _{C([0,T];H^{1}_{0}(\Omega ))} \leq C \sqrt{ \frac {T^{\alpha -1}}{\alpha -1}} \bigl\Vert y(v,0)-y(0,0) \bigr\Vert _{L^{2}(Q)} $$

(25)

and

$$ \biggl\Vert \frac{\partial\zeta}{\partial t} (v) \biggr\Vert _{\mathcal{C} ([0,T];L^{2}(\Omega ))} \leq C \sqrt{\frac{T^{2\alpha -3}}{2\alpha -3}} \bigl\Vert y(v,0)-y(0,0) \bigr\Vert _{L^{2}(Q)}. $$

(26)

Set $z = y(g,0)-y(0,0)$. Then z verifies

$$ \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}z - \Delta z = 0 \quad \mbox{in } Q, \\ z = 0 \quad \mbox{on } \Sigma, \\ I^{2-\alpha} z(0) = 0 \quad \mbox{in } \Omega , \\ \frac{\partial}{\partial t} I^{2-\alpha }z(0) = g \quad \mbox{in } \Omega. \end{array}\displaystyle \right . $$

(27)

Since $g\in L^{2}(\Omega)$, it follows from Theorem 2.6 that $z\in L^{2}((0,T);H^{1}_{0}(\Omega))$, $I^{2-\alpha}z \in C([0,T], H^{1}_{0}(\Omega))$, and $\frac{\partial}{\partial t}I^{2-\alpha}z \in C([0,T],L^{2}(\Omega))$. So, if we multiply the first equation of (24) by z utilizing the fractional integration by parts provided by Lemma 2.5, we conclude

$$\begin{aligned}& \int_{Q} \bigl(y(v,0)-y(0,0)\bigr)z \,dt \,dx \\& \quad = \int_{Q} \bigl(\mathcal{D}^{\alpha }_{\mathrm{C}} \, \zeta(v)-\Delta\zeta(v)\bigr)z \,dt \,dx \\& \quad = \int_{\Omega } \zeta(x,0;v)\frac{\partial}{\partial t}I^{2-\alpha }z(0) \,dx . \end{aligned}$$

(28)

Thus, replacing z by $(y(0,g)-y(0,0))$, we obtain

$$\int_{Q} \bigl[y(v,0)-y(0,0)\bigr] \bigl[y(0,g)-y(0,0)\bigr] \,dt \,dx = \int_{\Omega } \zeta(x,0;v)g \,dx, $$

and (18) becomes

$$J(v,g)-J(0,g)=J(v,0)-J(0,0)+ 2 \int_{\Omega } \zeta(x,0;v)g \,dx. $$

□

Now we consider the no-regret control problem:

$$ \inf_{v \in L^{2}(Q)} \sup_{g \in L^{2}(\Omega )} \bigl(J(v,g)-J(0,g)\bigr). $$

(29)

From (23), this problem is equivalent to the following one:

$$ \inf_{v \in L^{2}(Q)} \sup_{g \in L^{2}(\Omega )} \biggl[ J(v,0)-J(0,0)+ 2 \int_{\Omega } \zeta(x,0;v)g \,dx \biggr]. $$

(30)

As the space $L^{2}(\Omega )$ is a vector space, the no-regret control exists only if

$$ \sup_{g \in L^{2}(\Omega )} \biggl( \int_{\Omega } \zeta (x,0;v)g \,dx \biggr) = 0. $$

(31)

This implies that the no-regret control belongs to $\mathcal{U}$ defined by

$$\mathcal{U} = \biggl\{ v \in L^{2}(Q) \Big| \biggl( \int_{\Omega } \zeta(x,0;v)g \,dx \biggr) = 0, \forall g\in L^{2}(\Omega) \biggr\} . $$

As a result such control should be carefully investigated. So, we proceed by penalization. For all $\gamma>0$, we discuss the low-regret control problem:

$$ \inf_{v \in L^{2}(Q)} \sup_{g \in L^{2}(\Omega )} \bigl(J(v,g)-J(0,g)-\gamma\| g \|^{2}_{L^{2}(\Omega )}\bigr). $$

(32)

According to (23), the problem (32) is equivalent to the following problem:

$$\inf_{v \in L^{2}(Q)} \biggl[ J(v,0)-J(0,0)+ 2\sup_{g \in L^{2}(\Omega )} \biggl( \int_{\Omega } \zeta(x,0;v)g \,dx - \frac {\gamma}{2} \| g \|^{2}_{L^{2}(\Omega )} \biggr) \biggr]. $$

Using the Legendre-Fenchel transform, we conclude

$$2\gamma\sup_{g \in L^{2}(\Omega )} \biggl( \int_{\Omega } \frac {1}{\gamma}\zeta(x,0;v)g \,dx - \frac{1}{\gamma}\frac {\gamma}{2} \| g \|^{2}_{L^{2}(\Omega )} \biggr) = \frac{1}{\gamma} \bigl\Vert \zeta(\cdot,0;v) \bigr\Vert ^{2}_{L^{2}(\Omega )}, $$

and problem (32) becomes: For any $\gamma>0$, find $u^{\gamma} \in L^{2}(Q)$ such that

$$ J_{\gamma}\bigl(u^{\gamma}\bigr)= \inf _{v \in L^{2}(Q)} J_{\gamma}(v), $$

(33)

where

$$ J_{\gamma}(v) = J(v,0)-J(0,0) + \frac{1}{\gamma} \bigl\Vert \zeta (\cdot,0;v) \bigr\Vert ^{2}_{L^{2}(\Omega )}. $$

(34)

Proposition 3.3

Let $\gamma>0$. Then (33) has a unique solution $u^{\gamma}$, called a low-regret control.

Proof

We recall that

$$J_{\gamma}(v) = J(v,0)-J(0,0) + \frac{1}{\gamma} \bigl\Vert \zeta ( \cdot,0;v) \bigr\Vert ^{2}_{L^{2}(\Omega )}\geq-J(0,0). $$

Thus, we can say that $\inf_{v \in L^{2}(Q)} J_{\gamma}$ exists. Let $(v_{n}) \in L^{2}(Q)$ be a minimizing sequence such that

$$ \lim_{n \to+ \infty} J_{\gamma}(v_{n}) = \inf_{v \in L^{2}(Q)} J_{\gamma}(v). $$

(35)

Then $y_{n} = y(x,t;v_{n},0)$ is a solution of (19) and $y_{n}$ satisfies

$$\begin{aligned}& D^{\alpha}_{\mathrm{RL}}y_{n}(x,t) - \Delta y_{n}(x,t) = v_{n}(x,t)\quad \mbox{in } Q , \end{aligned}$$

(36a)

$$\begin{aligned}& y_{n}(x,t) = 0 \quad \mbox{on } \Sigma, \end{aligned}$$

(36b)

$$\begin{aligned}& I^{2-\alpha } y_{n}(x,0) = y^{0} \quad \mbox{in } \Omega, \end{aligned}$$

(36c)

$$\begin{aligned}& \frac{\partial}{\partial t} I^{2-\alpha } y_{n} (x,0) = 0\quad \mbox{in } \Omega. \end{aligned}$$

(36d)

It follows from (35) that there exists $C(\gamma)>0$ independent of n such that

$$0 \leq J(v_{n},0) + \frac{1}{\gamma} \bigl\Vert \zeta( \cdot,0;v_{n}) \bigr\Vert ^{2}_{L^{2}(\Omega )} \leq C(\gamma) + J(0,0)=C(\gamma). $$

From the definition of $J(v_{n},0)$ we obtain

$$\begin{aligned}& \Vert v_{n} \Vert _{L^{2}(Q)} \leq C(\gamma), \end{aligned}$$

(37a)

$$\begin{aligned}& \bigl\Vert \zeta(\cdot,0;v_{n}) \bigr\Vert _{L^{2}(\Omega )} \leq \sqrt{\gamma} C(\gamma) . \end{aligned}$$

(37b)

Therefore, from Theorem 2.6, we know that there exists a constant C independent of n such that

$$\begin{aligned}& \Vert y_{n} \Vert _{L^{2}((0,T);H^{1}_{0}(\Omega ))} \leq C(\gamma) , \end{aligned}$$

(38a)

$$\begin{aligned}& \bigl\Vert I^{2-\alpha }y_{n} \bigr\Vert _{L^{2}((0,T);H^{1}_{0}(\Omega ))} \leq C(\gamma) , \end{aligned}$$

(38b)

$$\begin{aligned}& \biggl\Vert \frac{\partial}{\partial t} I^{2-\alpha }y_{n} \biggr\Vert _{L^{2}((0,T);L^{2}(\Omega ))} \leq C (\gamma). \end{aligned}$$

(38c)

Moreover, from (36a) and (37a), we have

$$ \bigl\Vert D^{\alpha}_{\mathrm{RL}}y_{n} - \Delta y_{n} \bigr\Vert _{L^{2}(Q)} \leq C(\gamma). $$

(39)

Consequently, there exist $u^{\gamma}\in L^{2}(Q)$, $y^{\gamma} \in L^{2}((0,T);H^{1}_{0}(\Omega ))$, $\delta\in L^{2}(Q)$, $\eta\in L^{2}((0,T); H^{1}_{0}(\Omega ))$, $\theta\in L^{2}((0,T);L^{2}(\Omega ))$ and we can extract subsequences of $(v_{n})$ and $(y_{n})$ (still called $(v_{n})$ and $(y_{n})$) such that:

$$\begin{aligned}& v_{n} \rightharpoonup u^{\gamma} \quad \mbox{weakly in } L^{2}(Q), \end{aligned}$$

(40a)

$$\begin{aligned}& D^{\alpha}_{\mathrm{RL}}y_{n} - \Delta y_{n} \rightharpoonup\delta\quad \mbox{weakly in } L^{2}(Q), \end{aligned}$$

(40b)

$$\begin{aligned}& y_{n} \rightharpoonup y^{\gamma} \quad \mbox{weakly in } L^{2}\bigl((0,T);H^{1}_{0}(\Omega )\bigr), \end{aligned}$$

(40c)

$$\begin{aligned}& I^{2-\alpha }y_{n} \rightharpoonup\eta\quad \mbox{weakly in } L^{2}\bigl([0,T],H^{1}_{0}(\Omega ) \bigr), \end{aligned}$$

(40d)

$$\begin{aligned}& \frac{\partial}{\partial t} I^{2-\alpha }y_{n} \rightharpoonup\theta \quad \mbox{weakly in } L^{2}\bigl((0,T);L^{2}(\Omega )\bigr). \end{aligned}$$

(40e)

The remaining part of the proof contains three steps.

Step 1: We show that $(u^{\gamma},y^{\gamma})$ fulfills (19).

Set $\mathbb{D}(Q)$, the set of $\mathcal{C}^{\infty}$ function on Q with compact support and denote by $\mathbb{D}^{\prime}(Q)$ its dual. Multiplying (36a) by $\varphi\in\mathbb{D} (Q)$ and using Lemma 2.5, (40a), and (40c), we prove as in [1] that

$$D^{\alpha }_{\mathrm{RL}}y_{n} - \Delta y_{n} \rightharpoonup D^{\alpha }_{\mathrm{RL}}y^{\gamma} - \Delta y^{\gamma}\quad \mbox{weakly in } \mathbb{D}'(Q). $$

From (40b) and the uniqueness of the limit, we conclude

$$ D^{\alpha }_{\mathrm{RL}}y^{\gamma} - \Delta y^{\gamma} = \delta\in L^{2}(Q). $$

(41)

Hence,

$$ D^{\alpha}_{\mathrm{RL}}y_{n} - \Delta y_{n} \rightharpoonup D^{\alpha }_{\mathrm{RL}}y^{\gamma} - \Delta y^{\gamma} \quad \mbox{weakly in } L^{2}(Q). $$

(42)

Then passing to the limit in (36a) and using (41) and (40a), we obtain

$$ D^{\alpha}_{\mathrm{RL}}y^{\gamma}(x,t) - \Delta y^{\gamma}(x,t) = u^{\gamma}(x,t),\quad (x,t) \in Q. $$

(43)

On the other hand, we have

$$\begin{aligned}& \int_{Q} I^{2-\alpha }y_{n}(x,t) \varphi(x,t) \,dt \,dx \\& \quad = \int_{\Omega } \int_{0}^{T} y_{n}(x,s) \biggl( \frac{1}{\Gamma (2-\alpha )} \int_{s}^{T} (t-s)^{1-\alpha } \varphi (x,t) \,dt \biggr) \,ds \,dx,\quad \forall\varphi\in\mathbb{D}(Q). \end{aligned}$$

Thus using (40c) and (40d), while passing to the limit, we get

$$\begin{aligned} \int_{Q} \eta\varphi(x,t) \,dt \,dx =& \int_{\Omega } \int_{0}^{T} y^{\gamma}(x,s) \biggl( \frac {1}{\Gamma (2-\alpha )} \int_{s}^{T} (t-s)^{1-\alpha } \varphi(x,t) \,dt \biggr) \,ds \,dx \\ =& \int_{Q} I^{2-\alpha }y^{\gamma}(x,t) \varphi(x,t) \,dt \,dx,\quad \forall\varphi\in\mathbb{D}(Q). \end{aligned}$$

This implies that

$$I^{2-\alpha }y^{\gamma}(x,t) =\eta\quad \mbox{in } Q. $$

Thus, (40d) becomes

$$ I^{2-\alpha }y_{n} \rightharpoonup I^{2-\alpha }y^{\gamma}\quad \mbox{weakly in } L^{2} \bigl([0,T],H^{1}_{0}(\Omega )\bigr). $$

(44)

In view of (44), we have

$$\frac{\partial}{\partial t} I^{2-\alpha }y_{n} \rightharpoonup \frac{\partial}{\partial t} I^{2-\alpha }y^{\gamma} \quad \mbox{weakly in } \mathbb{D}^{\prime}(Q), $$

and as we have (40e), we obtain

$$ \frac{\partial}{\partial t} I^{2-\alpha }y_{n} \rightharpoonup \frac{\partial}{\partial t} I^{2-\alpha }y^{\gamma} =\theta\quad \mbox{weakly in } L^{2}(Q). $$

(45)

Since $y^{\gamma} \in L^{2}(Q)$ and $D^{\alpha}_{\mathrm{RL}}y^{\gamma } - \Delta y^{\gamma}\in L^{2}(Q)$, in view of Lemma 2.9, we know that $y^{\gamma }_{|\partial\Omega }$ and $\frac{\partial y^{\gamma}}{\partial v}_{| \partial\Omega }$ exist and belong to $H^{-2}((0,T);H^{-1/2}(\partial\Omega )) $ and $H^{-2}((0,T);H^{-3/2}(\partial\Omega ))$, respectively. Moreover, we have $I^{2-\alpha }y^{\gamma}\in C([0,T];L^{2}(\Omega ))$ and $\frac{\partial}{\partial t}I^{2-\alpha }y^{\gamma} \in C([0,T];H^{-1}(\Omega ))$.

Now multiplying (36a) by a function $\varphi\in C^{\infty }(\overline{Q})$ such that $\varphi_{|\partial\Omega }=0$ and $\varphi(x,T)=\frac{\partial\varphi}{\partial t}(x,T) =0$ in Ω, and integrating by parts over Q, we obtain

$$\begin{aligned} \int_{Q} v_{n}(x,t)\varphi(x,t)\,dx \,dt =& \int_{Q} \bigl( D^{\alpha }_{\mathrm{RL}}y_{n}(x,t) - \Delta y_{n}(x,t)\bigr) \varphi(x,t)\,dx\,dt \\ =& \int_{\Omega } y^{0} \frac{\partial\varphi}{\partial t} (x,0) \,dx \\ &{}+ \int_{Q} y_{n}(x,t) \bigl( \mathcal{D}_{\mathrm{C}}^{\alpha }\, \varphi(x,t) - \Delta\varphi(x,t)\bigr)\,dx \,dt \end{aligned}$$

because we have (36c) and (36d). Thus, using (40a) and (40c) while passing to the limit in the latter identity, we get

$$\begin{aligned} \int_{Q} u^{\gamma}(x,t)\varphi(x,t)\,dx \,dt =& \int_{\Omega } y^{0} \frac{\partial\varphi}{\partial t} (x,0) \,dx \\ &{}+ \int_{Q} y^{\gamma}(x,t) \bigl( \mathcal{D}_{\mathrm{C}}^{\alpha }\, \varphi(x,t) - \Delta\varphi(x,t)\bigr)\,dx \,dt, \end{aligned}$$

$\forall\varphi\in C^{\infty}(\overline{Q})$ such that $\varphi_{|\partial\Omega }=0$, $\varphi(T)=\frac{\partial\varphi}{\partial t} (T) =0$ in Ω, which, according to Lemma 2.5, can be rewritten as

$$\begin{aligned} \int_{Q} u^{\gamma}(x,t)\varphi(x,t)\,dx \,dt =& \int_{\Omega } y^{0} \frac{\partial\varphi}{\partial t} (x,0) \,dx \\ &{}+ \int_{Q} \bigl( D^{\alpha }_{\mathrm{RL}}y^{\gamma}(x,t) - \Delta y^{\gamma}(x,t)\bigr) \varphi(x,t)\,dx\,dt \\ &{}+ \biggl\langle \varphi(x,0), \frac{\partial}{\partial t} I^{2-\alpha }y^{\gamma}(x,0) \biggr\rangle _{H^{1}_{0}(\Omega ),H^{-1}(\Omega )} \\ &{}- \int_{\Omega } \frac{\partial\varphi}{\partial t} (x,0), I^{2-\alpha }y^{\gamma}(x,0) \,dx \\ &{}- \biggl\langle y^{\gamma}(\sigma,t), \frac{\partial\varphi }{\partial\nu}(\sigma,t) \biggr\rangle _{H^{-2}((0,T);H^{-1/2}(\partial\Omega )),H^{2}_{0}((0,T);H^{1/2}(\partial\Omega ))} , \end{aligned}$$

$\forall\varphi\in C^{\infty}(\overline{Q})$ such that $\varphi_{|\partial\Omega }=0$, $\varphi(T)=\frac{\partial\varphi}{\partial t} (T) =0$ in Ω.

Using (43), we obtain

$$\begin{aligned} 0 =& \int_{\Omega } y^{0} \frac{\partial\varphi}{\partial t}(x,0) \,dx \\ &{}+ \biggl\langle \varphi(x,0), \frac{\partial}{\partial t} I^{2-\alpha }y^{\gamma}(x,0) \biggr\rangle _{H^{1}_{0}(\Omega ),H^{-1}(\Omega )} \\ &{}- \int_{\Omega } \frac{\partial\varphi}{\partial t} (x,0) I^{2-\alpha }y^{\gamma}(x,0) \,dx \\ &{}- \biggl\langle y^{\gamma}(\sigma,t), \frac{\partial\varphi }{\partial\nu}(\sigma,t) \biggr\rangle _{H^{-2}((0,T);H^{-1/2}(\partial\Omega )),H^{2}_{0}((0,T);H^{1/2}(\partial\Omega ))} , \end{aligned}$$

(46)

$\forall\varphi\in C^{\infty}(\overline{Q})$ such that $\varphi_{|\partial\Omega }=0$, $\varphi(T)= \frac{\partial\varphi}{\partial t} (T) =0$ in Ω.

Choosing successively in (46) φ such that $\varphi(x,0)= \frac{\partial\varphi}{\partial t}(x,0)=0$ and $\varphi(x,0)=0$, we deduce that

$$\begin{aligned}& y^{\gamma}(x,t)=0,\quad (x,t) \in\Sigma, \end{aligned}$$

(47)

$$\begin{aligned}& I^{2-\alpha } y^{\gamma}(x,0)= y^{0},\quad x \in\Omega , \end{aligned}$$

(48)

and then

$$ \frac{\partial}{\partial t} I^{2-\alpha }y^{\gamma}(x,0) = 0,\quad x \in\Omega . $$

(49)

In view of (43), (47), (48), and (49), we see that $y^{\gamma}=y^{\gamma}(x,t;u^{\gamma},0)$ is a solution of (19).

Step 2: We show $\zeta_{n}=\zeta(x,t;v_{n})$ converges to $\zeta^{\gamma}=\zeta(x,t;u^{\gamma})$.

In view of (24), $\zeta_{n} = \zeta(x,t;v_{n})$ verifies

$$ \left \{ \textstyle\begin{array}{l} \mathcal{D}^{\alpha }_{\mathrm{C}}\, \zeta_{n} - \Delta\zeta_{n} = y(v_{n},0)-y(0,0)\quad \mbox{in } Q, \\ \zeta_{n} = 0 \quad \mbox{on } \Sigma, \\ \zeta_{n}(T) = 0 \quad \mbox{in } \Omega, \\ \frac{\partial}{\partial t} \zeta_{n}(T) = 0 \quad \mbox{in } \Omega. \end{array}\displaystyle \right . $$

(50)

Set $z_{n}=y(v_{n},0)-y(0,0)$. In view of (19) and (21), $z_{n}$ verifies

$$\left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}z_{n} - \Delta z_{n} = v_{n} \quad \mbox{in } Q, \\ z_{n} = 0\quad \mbox{on } \Sigma, \\ I^{2-\alpha} z_{n}(0) = 0 \quad \mbox{in } \Omega, \\ \frac{\partial}{\partial t}I^{2-\alpha }z_{n}(0) = 0 \quad \mbox{in } \Omega. \end{array}\displaystyle \right . $$

It follows, from Theorem 2.6 and (37a), that

$$\Vert z_{n}\Vert _{L^{2}((0,T);H^{1}_{0}(\Omega ))} = \bigl\Vert y_{n}(v_{n},0)-y(0,0) \bigr\Vert _{L^{2}((0,T);H^{1}_{0}(\Omega ))} \leq C( \gamma). $$

Hence, from Corollary 2.8, we deduce that

$$\begin{aligned}& \| \zeta_{n} \|_{C([0,T];H^{1}_{0}(\Omega ))} \leq C(\gamma), \end{aligned}$$

(51)

$$\begin{aligned}& \biggl\Vert \frac{\partial}{\partial t}\zeta_{n} \biggr\Vert _{C([0,T];L^{2}(\Omega ))} \leq C(\gamma) . \end{aligned}$$

(52)

Since the embedding of $C([0,T];H^{1}_{0}(\Omega ))$ into $L^{2}((0,T);H^{1}_{0}(\Omega))$ and the embedding of $C([0,T];L^{2}(\Omega ))$ into $L^{2}(Q)$ are continuous, we can conclude that there exists $\zeta^{\gamma} \in L^{2}((0,T);H^{1}_{0}(\Omega ))$ such that

$$ \zeta_{n} \rightharpoonup \zeta^{\gamma}\quad \mbox{weakly in } L^{2}\bigl((0,T);H^{1}_{0}(\Omega )\bigr) . $$

(53)

Therefore,

$$\frac{\partial}{\partial t}\zeta_{n} \rightharpoonup \frac{\partial}{\partial t} \zeta^{\gamma} \quad \mbox{weakly in } \mathbb{D}^{\prime}(Q) $$

and, consequently,

$$ \frac{\partial}{\partial t}\zeta_{n} \rightharpoonup \frac{\partial}{\partial t} \zeta^{\gamma} \quad \mbox{weakly in } L^{2}(Q) . $$

(54)

Since $\zeta^{\gamma}\in L^{2}((0,T);H^{1}_{0}(\Omega ))$ and $\frac {\partial}{\partial t}\zeta^{\gamma}\in L^{2}(Q)$, we see that $\zeta ^{\gamma}(0)$ and $\zeta^{\gamma}(T)$ belongs to $L^{2}(\Omega)$. In view of (50)₃, we have

$$ \zeta^{\gamma} (T)=0 \quad \mbox{in }\Omega $$

(55)

and in view of (50)₄ and (52), we set

$$ \frac{\partial}{\partial t}\zeta^{\gamma} (T)=0 \quad \mbox{in } \Omega. $$

(56)

From (37b), we deduce that there exists $\rho\in L^{2}(\Omega )$ such that

$$ \zeta(\cdot,0;v_{n}) \rightharpoonup\rho\quad \mbox{weakly in } L^{2}(\Omega). $$

(57)

Multiplying the first equation of (50) by $\phi\in\mathbb {D}(Q)$ then, using the integration by parts given by Lemma 2.5, we obtain

$$\begin{aligned}& \int_{Q} \bigl(y(x,t;v_{n},0)-y(x,t;0,0)\bigr) \phi(x,t)\,dt \,dx \\& \quad = \int_{Q} \bigl[ D^{\alpha}_{\mathrm{RL}}\phi(x,t) - \Delta\phi (x,t) \bigr] \zeta_{n}(x,t)\,dt\,dx . \end{aligned}$$

Hence, using (40c) and (53) while passing to the limit in the latter identity, we have

$$\begin{aligned}& \int_{Q} \bigl(y\bigl(x,t;u^{\gamma},0\bigr)-y(x,t;0,0) \bigr) \phi(x,t)\,dt\,dx \\& \quad = \int_{Q} \bigl(D^{\alpha}_{\mathrm{RL}}\phi(x,t)- \Delta\phi(x,t)\bigr) \zeta^{\gamma }(x,t)\,dt\,dx, \quad \forall\phi\in \mathbb{D}(Q), \end{aligned}$$

(58)

which by using again Lemma 2.5 gives

$$\begin{aligned}& \int_{Q} \bigl(y\bigl(x,t;u^{\gamma},0\bigr)-y(x,t;0,0) \bigr) \phi(x,t)\,dt\,dx \\& \quad = \int_{Q} \bigl( \mathcal{D}^{\alpha}_{\mathrm{C}}\, \zeta^{\gamma}(x,t)- \Delta\zeta^{\gamma }(x,t)\bigr) \phi(x,t)\,dt \,dx,\quad \forall\phi\in\mathbb{D}(Q). \end{aligned}$$

This implies that

$$ \mathcal{D}^{\alpha}_{\mathrm{C}}\, \zeta^{\gamma}- \Delta\zeta ^{\gamma} = y\bigl(u^{\gamma },0\bigr)-y(0,0) \quad \mbox{in } Q. $$

(59)

Now, if we multiply the first equation of (50) by $\phi\in \mathcal{C}^{\infty}(\overline{Q})$ with $\phi_{|_{\partial\Omega }}=0$ and $I^{2-\alpha}\phi(0) = 0$ in Ω and integrating by parts over Q, we obtain

$$\begin{aligned}& \int_{Q} \bigl(y_{n}(x,t)-y(x,t;0,0)\bigr) \phi(x,t) \,dt\,dx \\& \quad = \int_{Q} \bigl( \mathcal{D}^{\alpha}_{\mathrm{C}}\, \zeta_{n}(x,t)- \Delta \zeta_{n}(x,t)\bigr) \phi (x,t)\,dt\,dx \\& \quad = \int_{Q} \bigl(D^{\alpha}_{\mathrm{RL}}\phi(x,t) - \Delta\phi (x,t) \bigr) \zeta _{n}(x,t)\,dt\,dx+ \int_{\Omega}\zeta(x,0,v_{n})\frac{\partial}{\partial t} I^{2-\alpha}\phi(0)\,dx. \end{aligned}$$

Using (40c), (53), and (57) while passing the latter identity to the limit, we obtain

$$\begin{aligned}& \int_{Q} \bigl(y^{\gamma}(x,t)-y(x,t;0,0)\bigr) \phi(x,t)\,dt\,dx \\& \quad = \int_{Q} \bigl(D^{\alpha}_{\mathrm{RL}}\phi(x,t) - \Delta\phi (x,t) \bigr) \zeta ^{\gamma}(x,t)\,dt\,dx+ \int_{\Omega}\rho\frac{\partial}{\partial t} I^{2-\alpha}\phi(0)\,dx, \\& \qquad \forall\phi\in\mathcal{C}^{\infty}(\overline{Q}) \mbox{ such that } \phi_{|_{\partial\Omega }}=0, I^{2-\alpha}\phi(0) =0 \mbox{ in } \Omega, \end{aligned}$$

(60)

which by using again Lemma 2.5, (55), (56), and (59) gives

$$\begin{aligned}& - \int_{\Sigma}\frac{\partial}{\partial\nu }\phi(\sigma,t)\zeta^{\gamma}( \sigma,t) \,d\sigma \,dt+ \int_{\Omega}\rho (x)\frac{\partial}{\partial t} I^{2-\alpha}\phi(0)\,dx \\& \quad = \int _{\Omega}\zeta^{\gamma}(0)\frac{\partial}{\partial t} I^{2-\alpha }\phi(0)\,dx \\& \qquad \forall\phi\in\mathcal{C}^{\infty}(\overline{Q}) \mbox{ such that } \phi _{|_{\partial\Omega }}=0, I^{2-\alpha}\phi(0) = 0 \mbox{ in } \Omega. \end{aligned}$$

Hence, choosing $\phi\in\mathcal{C}^{\infty}(\overline{Q})$, such that $\phi_{|_{\partial\Omega }}=0$, $I^{2-\alpha}\phi(0) = \frac{\partial }{\partial t} I^{2-\alpha}\phi(0)=0$, we get

$$ \zeta^{\gamma} = 0 \quad \mbox{on }\Sigma, $$

(61)

and then

$$ \zeta^{\gamma}(0) = \rho \quad \mbox{in }\Omega. $$

(62)

In view of (55), (56), (59), and (61), we see that $\zeta^{\gamma}= \zeta(u^{\gamma})$ is a solution of

$$ \left \{ \textstyle\begin{array}{l} \mathcal{D}^{\alpha }_{\mathrm{C}} \, \zeta^{\gamma} - \Delta\zeta^{\gamma} = y(u^{\gamma},0)-y(0,0) \quad \mbox{in } Q, \\ \zeta^{\gamma} = 0 \quad \mbox{on } \Sigma, \\ \zeta^{\gamma}(T) = 0 \quad \mbox{in } \Omega \\ \frac{\partial\zeta^{\gamma}}{\partial t}(T) = 0 \quad \mbox{in } \Omega . \end{array}\displaystyle \right . $$

(63)

Moreover, using (62), equation (57) becomes

$$ \zeta(\cdot,0;v_{n}) \rightharpoonup \zeta^{\gamma}(0)=\zeta\bigl(\cdot,0;u^{\gamma }\bigr)\quad \mbox{weakly in }L^{2}(\Omega ). $$

(64)

Step 3: The function $v \to J_{\gamma}(v)$ being lower semi-continuous, we have

$$J_{\gamma}\bigl(u^{\gamma}\bigr) \leq\liminf_{ n\to\infty} J_{\gamma}(v_{n}), $$

which in view of (35) implies that

$$J_{\gamma}\bigl(u^{\gamma}\bigr) = \inf_{ v \in L^{2}(Q)} J_{\gamma }(v). $$

The uniqueness of $u^{\gamma}$ comes from the fact that the functional $J_{\gamma}$ is strictly convex. □

Theorem 3.4

For any $\gamma>0$, let $u^{\gamma}$ be the low-regret control. Then there exist $q^{\gamma} \in L^{2}((0,T);H^{1}_{0}(\Omega ))$ and $p^{\gamma} \in\mathcal {C}([0,T];H^{1}_{0}(\Omega ))$ such that $(u^{\gamma},y^{\gamma}=y^{\gamma}(u^{\gamma},0),q^{\gamma },p^{\gamma})$ satisfies the following optimality system:

$$\begin{aligned}& \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}y^{\gamma} - \Delta y^{\gamma} = u^{\gamma} \quad \textit{in }Q, \\ y^{\gamma} = 0 \quad \textit{on } \Sigma , \\ I^{2-\alpha }y^{\gamma}(0) = y^{0} \quad \textit{in } \Omega , \\ \frac{\partial}{\partial t}I^{2-\alpha }y^{\gamma}(0) = 0 \quad \textit{in } \Omega , \end{array}\displaystyle \right . \end{aligned}$$

(65)

$$\begin{aligned}& \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}q^{\gamma} - \Delta q^{\gamma} = 0\quad \textit{in } Q, \\ q^{\gamma} = 0 \quad \textit{on } \Sigma , \\ I^{2-\alpha }q^{\gamma}(0) = 0 \quad \textit{in } \Omega , \\ \frac{\partial}{\partial t}I^{2-\alpha }q^{\gamma}(0) = \frac{1}{\sqrt{\gamma}} \zeta(0;u^{\gamma}) \quad \textit{in } \Omega, \end{array}\displaystyle \right . \end{aligned}$$

(66)

$$\begin{aligned}& \left \{ \textstyle\begin{array}{l} \mathcal{D}^{\alpha }_{\mathrm{C}}\, p^{\gamma} - \Delta p^{\gamma} = y^{\gamma }-z_{d} + \frac{1}{\sqrt{\gamma}} q^{\gamma} \quad \textit{in }Q , \\ p^{\gamma} = 0 \quad \textit{on } \Sigma, \\ p^{\gamma}(T) = 0 \quad \textit{in } \Omega, \\ \frac{\partial p^{\gamma}}{\partial t}(T) = 0 \quad \textit {in } \Omega, \end{array}\displaystyle \right . \end{aligned}$$

(67)

and

$$ Nu^{\gamma}+ p^{\gamma}=0 \quad \textit{in }Q. $$

(68)

Proof

Equations (43), (47), (48), and (49) give (65). To characterize the low-regret control $u^{\gamma }$, we use the Euler-Lagrange optimality conditions:

$$ \frac{d}{dk} J_{\gamma}\bigl(u^{\gamma}+k \bigl(v-u^{\gamma}\bigr)\bigr)\big|_{k=0} =0,\quad \forall v \in L^{2}(Q). $$

(69)

After some calculations, we obtain

$$\begin{aligned}& \int_{Q} \bigl(y\bigl(u^{\gamma},0\bigr)-z_{d} \bigr) \bigl(y(v,0)-y\bigl(u^{\gamma},0\bigr)\bigr)\,dt \,dx + \int_{Q} Nu^{\gamma}\bigl(v-u^{\gamma}\bigr)\,dt \,dx \\& \quad {} + \frac{1}{\gamma} \int _{\Omega } \bigl( \zeta\bigl(x,0;u^{\gamma}\bigr), \zeta \bigl(x,0;v-u^{\gamma}\bigr) \bigr)\,dx =0,\quad \forall v \in L^{2}(Q), \end{aligned}$$

(70)

where from (24), $\zeta(v-u^{\gamma})=\zeta(x,t;v-u^{\gamma }) \in C([0,T];H^{1}_{0}(\Omega ))$ is a solution of

$$ \left \{ \textstyle\begin{array}{l} \mathcal{D}^{\alpha } \zeta(v-u^{\gamma})-\Delta\zeta(v-u^{\gamma }) = y(v,0)-y^{\gamma} (u^{\gamma},0) \quad \mbox{in } Q, \\ \zeta(v-u^{\gamma}) = 0 \quad \mbox{on } \Sigma , \\ \zeta(T;v-u^{\gamma}) = 0 \quad \mbox{in } \Omega, \\ \frac{\partial\zeta}{\partial t} (T;v-u^{\gamma}) = 0 \quad \mbox{in } \Omega. \end{array}\displaystyle \right . $$

(71)

Let $z(v-u^{\gamma})=y(x,t;v,0)- y^{\gamma}(x,t;u^{\gamma},0)$ be the state associated to $(v-u^{\gamma})\in L^{2}(Q)$. Then in view of (19), $z=z(v-u^{\gamma})\in L^{2}((0,T);H^{1}_{0}(\Omega))$ is a solution of

$$ \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}z - \Delta z = v-u^{\gamma} \quad \mbox{in } Q, \\ z = 0\quad \mbox{on } \Sigma , \\ I^{2-\alpha }z(0) = 0 \quad \mbox{in } \Omega, \\ \frac{\partial}{\partial t}I^{2-\alpha }z(0) = 0 \quad \mbox{in } \Omega. \end{array}\displaystyle \right . $$

(72)

To interpret (70), we introduce $q^{\gamma}= q^{\gamma }(u^{\gamma},0)$ as a solution of equation (66). As $\frac{1}{\sqrt{\gamma}} \zeta(\cdot,0;u^{\gamma}) \in L^{2}(\Omega )$, according to Theorem 2.6, $q^{\gamma}$ is unique and belongs to $L^{2}((0,T); H^{1}_{0}(\Omega ))$. Moreover,

$$ \bigl\Vert q^{\gamma}\bigr\Vert _{L^{2}((0,T);H^{1}_{0}(\Omega ))} \leq \frac{C}{\sqrt {\gamma}} \bigl\Vert \zeta\bigl(0;u^{\gamma}\bigr) \bigr\Vert _{L^{2}(\Omega )}, $$

(73)

where $C>0$ is a positive constant independent of γ.

Multiplying the first equation of (71) by $\frac {1}{\sqrt{\gamma}}q^{\gamma}$ and using Lemma 2.5, we obtain

$$\int_{\Omega }\frac{1}{{\gamma}}\zeta\bigl(x,0;v-u^{\gamma} \bigr)\zeta \bigl(x,0;u^{\gamma}\bigr)\,dx= \int_{Q} \bigl( y(v,0)-y\bigl(u^{\gamma},0\bigr)\bigr) \frac{1}{\sqrt{\gamma}}q^{\gamma}\,dt \,dx, $$

which combining with (70) gives

$$\begin{aligned}& \int_{Q} \bigl[ y(v,0)-y\bigl(u^{\gamma},0\bigr) \bigr] \biggl[\biggl(y\bigl(u^{\gamma},0\bigr)-z_{d}+ \frac{1}{\sqrt{\gamma}}q^{\gamma}\biggr) \biggr] \,dt\,dx \\& \quad {}+ \int_{Q} Nu^{\gamma}\bigl(v-u^{\gamma}\bigr)\,dt \,dx=0,\quad \forall v \in L^{2}(Q). \end{aligned}$$

(74)

Now, let $p^{\gamma}$ verify (67). Then, in view of Corollary 2.8, $p^{\gamma}\in C([0,T]; H^{1}_{0}(\Omega ))$, and $\frac {\partial }{\partial t}p^{\gamma}\in C([0,T]; L^{2}(\Omega ))$ since $y^{\gamma}-z_{d}+\frac{1}{\sqrt{\gamma}}q^{\gamma}\in L^{2}(Q)$.

Thus, multiplying the first equation of (72) by $p^{\gamma}$, a solution of (67), then, utilizing the fractional integration by parts provided by Lemma 2.5, we conclude

$$\int_{Q} z\bigl(v-u^{\gamma}\bigr) \bigl( \mathcal{D}_{\mathrm{C}}^{\alpha } \, p^{\gamma}- \Delta p^{\gamma}\bigr) \,dx \,dt= \int_{Q} \bigl(v-u^{\gamma}\bigr)p^{\gamma}\,dx \,dt. $$

Replacing in the latter identity $z(v-u^{\gamma})$ by $y(x,t;v,0)-y^{\gamma }(x,t;u^{\gamma},0)$, which is a solution of (72), we obtain

$$\begin{aligned}& \int_{Q} \bigl(v-u^{\gamma}\bigr)p^{\gamma}\,dx \,dt \\& \quad = \int_{Q} \bigl[ y(x,t;v,0)-y^{\gamma} \bigl(x,t;u^{\gamma},0\bigr) \bigr] \biggl[\biggl(y^{\gamma} \bigl(u^{\gamma},0\bigr)-z_{d}+ \frac{1}{\sqrt{\gamma}}q^{\gamma} \biggr) \biggr] \,dt\,dx, \end{aligned}$$

which combining with (74) gives

$$\int_{Q} \bigl(Nu^{\gamma}+p^{\gamma}\bigr) \bigl(v-u^{\gamma}\bigr)\,dx\,dt=0,\quad \forall v \in L^{2}(Q). $$

Consequently $Nu^{\gamma}+p^{\gamma}=0$ in Q. □

Proposition 3.5

For any $\gamma>0$, let $u^{\gamma}$ be the low-regret control. Then $u^{\gamma}$ converges to u, a solution of the no-regret problem (30).

Proof

As $u^{\gamma}$ is a solution of (33), we have

$$J_{\gamma}\bigl(u^{\gamma}\bigr) \leq J_{\gamma}(0)=0, $$

because in view of (24), $\zeta(0)=\zeta(x,t;0)=0$ in Q. It then follows from the definition of $J_{\gamma}$ given by (34) that

$$\begin{aligned}& \bigl\Vert y\bigl(u^{\gamma},0\bigr)-z_{d} \bigr\Vert ^{2}_{L^{2}(Q)} + N\bigl\Vert u^{\gamma}\bigr\Vert ^{2}_{L^{2}(Q)} + \frac {1}{\gamma} \bigl\Vert \zeta\bigl( \cdot,0;u^{\gamma}\bigr) \bigr\Vert ^{2}_{L^{2}(\Omega )} \\& \quad \leq J(0,0) = \bigl\Vert y(0,0)-z_{d} \bigr\Vert ^{2}_{L^{2}(Q)}. \end{aligned}$$

Therefore, we deduce that

$$\begin{aligned}& \bigl\Vert y\bigl(u^{\gamma},0\bigr)\bigr\Vert _{L^{2}(Q)} \leq \bigl\Vert y(0,0)-z_{d} \bigr\Vert _{L^{2}(Q)}, \end{aligned}$$

(75a)

$$\begin{aligned}& \bigl\Vert u^{\gamma}\bigr\Vert _{L^{2}(Q)} \leq\frac{1}{N} \bigl\Vert y(0,0)-z_{d} \bigr\Vert _{L^{2}(Q)}, \end{aligned}$$

(75b)

$$\begin{aligned}& \bigl\Vert \zeta\bigl(\cdot,0;u^{\gamma}\bigr) \bigr\Vert _{L^{2}(\Omega )} \leq\sqrt {\gamma}\bigl\Vert y(0,0)-z_{d} \bigr\Vert _{L^{2}(Q)} . \end{aligned}$$

(75c)

Hence from (75b) and (65)₁, we have

$$ \bigl\Vert D^{\alpha}_{\mathrm{RL}}y\bigl(u^{\gamma},0\bigr)- \Delta y\bigl(u^{\gamma},0\bigr) \bigr\Vert _{L^{2}(Q)} \leq \frac{1}{N}\bigl\Vert y(0,0)-z_{d} \bigr\Vert _{L^{2}(Q)}. $$

(76)

Since $y(u^{\gamma},0)$ is solution of (65), we see from Theorem 2.6 that there exists a constant C independent of γ such that

$$ \bigl\Vert y\bigl(u^{\gamma},0\bigr) \bigr\Vert _{L^{2}((0,T);H^{1}_{0}(\Omega ))} \leq \frac{C}{N}\bigl\Vert y(0,0)-z_{d} \bigr\Vert _{L^{2}(Q)}. $$

(77)

Thus there exist $u \in L^{2}(Q)$, $y \in L^{2}((0,T);H^{1}_{0}(\Omega ))$, $\delta \in L^{2}(Q)$, and subsequences extracted of $(u^{\gamma})$ and $(y^{\gamma })$ (still called $(u^{\gamma})$ and $(y^{\gamma})$) such that

$$\begin{aligned}& u^{\gamma} \rightharpoonup u \quad \mbox{weakly in } L^{2}(Q), \end{aligned}$$

(78a)

$$\begin{aligned}& y^{\gamma} \rightharpoonup y\quad \mbox{weakly in } L^{2} \bigl((0,T);H^{1}_{0}(\Omega )\bigr), \end{aligned}$$

(78b)

$$\begin{aligned}& D^{\alpha}_{\mathrm{RL}}y^{\gamma}- \Delta y^{\gamma } \rightharpoonup\delta\quad \mbox{weakly in } L^{2}(Q). \end{aligned}$$

(78c)

If we proceed as in pp.10 to 14, using (78a)-(78c), we show that $y=y(x,t;u,0)$ is such that

$$ \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}y - \Delta y = u \quad \mbox{in } Q, \\ y = 0 \quad \mbox{on } \Sigma, \\ I^{2-\alpha} y(x,0) = y^{0} \quad \mbox{in } \Omega, \\ \frac{\partial}{\partial t}I^{2-\alpha }y(x,0) = 0 \quad \mbox{in } \Omega, \end{array}\displaystyle \right . $$

(79)

and $\zeta=\zeta(x,t;u) \in\mathcal{C}([0,T];H^{1}_{0}(\Omega ))$ is a solution of

$$ \left \{ \textstyle\begin{array}{l} \mathcal{D}^{\alpha } \zeta-\Delta\zeta = y(u,0)-y(0,0)\quad \mbox{in } Q, \\ \zeta = 0 \quad \mbox{on } \Sigma, \\ \zeta(T) = 0 \quad \mbox{in } \Omega, \\ \frac{\partial\zeta}{\partial t} (T) = 0 \quad \mbox{in } \Omega . \end{array}\displaystyle \right . $$

(80)

Moreover, in view of (75c), we have

$$ \zeta\bigl(\cdot,0;u^{\gamma}\bigr) \to\zeta(\cdot,0;u)=0\quad \mbox{strongly in } L^{2}(\Omega ). $$

(81)

Consequently, $\int_{\Omega}g \zeta(x,0;u) \,dx=0$.

This implies that u is solution of the no-regret control problem (30). □

Theorem 3.6

Let us consider $u=\lim_{\gamma\to0} u^{\gamma}$ be the no-regret control corresponding to the state $y(u,0)$. Then there exist $q \in L^{2}((0,T);H^{1}_{0}(\Omega ))$ and $p \in\mathcal {C}([0,T];H^{1}_{0}(\Omega ))$ in such a way that $(u,y=y(u,0),q,p)$ fulfills the following optimality system:

$$\begin{aligned}& \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}y - \Delta y = u \quad \textit{in } Q , \\ y = 0 \quad \textit{on } \Sigma , \\ I^{2-\alpha }y(0) = y^{0} \quad \textit{in } \Omega , \\ \frac{\partial}{\partial t}I^{2-\alpha }y(0) = 0 \quad \textit{in } \Omega , \end{array}\displaystyle \right . \end{aligned}$$

(82)

$$\begin{aligned}& \left \{ \textstyle\begin{array}{l} D^{\alpha}_{\mathrm{RL}}q - \Delta q = 0 \quad \textit{in } Q , \\ q = 0 \quad \textit{on } \Sigma, \\ I^{2-\alpha }q(0) = 0 \quad \textit{in } \Omega, \\ \frac{\partial}{\partial t}I^{2-\alpha }q(0) = \tau_{1}\quad \textit{in } \Omega , \end{array}\displaystyle \right . \end{aligned}$$

(83)

$$\begin{aligned}& \left \{ \textstyle\begin{array}{l} \mathcal{D}^{\alpha }_{\mathrm{C}}\, p - \Delta p = y(u,0) - z_{d} + \tau_{2} \quad \textit{in } Q, \\ p = 0 \quad \textit{on } \Sigma, \\ p(T) = 0 \quad \textit{in } \Omega, \\ \frac{\partial p}{\partial t} (T) = 0 \quad \textit{in } \Omega, \end{array}\displaystyle \right . \end{aligned}$$

(84)

and

$$ Nu + p =0 \quad \textit{in }Q. $$

(85)

Proof

We have (82) (see system (79)).

From (75c), we get

$$\biggl\Vert \frac{1}{\sqrt{\gamma}}\zeta\bigl(0;u^{\gamma}\bigr) \biggr\Vert _{L^{2}(\Omega )} \leq\bigl\Vert y(0,0)-z_{d}\bigr\Vert _{L^{2}(Q)}. $$

Consequently, equation (73) becomes

$$ \bigl\Vert q^{\gamma}\bigr\Vert _{L^{2}((0,T);H^{1}_{0}(\Omega ))} \leq C \bigl\Vert y(0,0)-z_{d}\bigr\Vert _{L^{2}(Q)}. $$

(86)

Thus, there exist $\tau_{1} \in L^{2}(\Omega )$ and $q \in L^{2}(0,T;H^{1}_{0}(\Omega ))$ such that

$$\begin{aligned}& \frac{1}{\sqrt{\gamma}} \zeta\bigl(\cdot,0;u^{\gamma}\bigr) \rightharpoonup\tau _{1} \quad \mbox{weakly in }L^{2}(\Omega ), \end{aligned}$$

(87)

$$\begin{aligned}& q^{\gamma}\rightharpoonup q \quad \mbox{weakly in }L^{2}\bigl((0,T);H^{1}_{0}(\Omega )\bigr). \end{aligned}$$

(88)

Using (87) and (88) while passing to the limit in (66), we show as for the convergence of $y_{n}=y(v_{n},0)$ (see pp.10 to 12) that q satisfies (83).

From (68) and (75b), we have

$$\bigl\Vert p^{\gamma}\bigr\Vert _{L^{2}(Q)} \leq\bigl\Vert y(0,0)-z_{d}\bigr\Vert _{L^{2}(Q)}. $$

Therefore there exists $p\in L^{2}(Q)$ such that

$$ p^{\gamma}\rightharpoonup p \quad \mbox{weakly in }L^{2}(Q). $$

(89)

In view of (67) and (75a), we know that there exist $\tau_{2} \in L^{2}(Q)$ such that

$$ \frac{1}{\sqrt{\gamma}} q^{\gamma}\rightharpoonup \tau_{2}\quad \mbox{weakly in }L^{2}(Q). $$

(90)

Then we prove as for the convergence of $\zeta_{n}=\zeta(x,t;v_{n})$ (see pp.12 to 14) that p is solution of (84). Using (75b) and (89) while passing to the limit in (68), we conclude (85). □

4 Conclusions

We study an optimal control problem associated to a fractional wave equation involving Riemann-Liouville fractional derivative and with incomplete data. Actually, the initial condition is missing. In order to solve the problem, we assume that the missing data belongs to an infinite dimensional space. Using the notions of no-regret and low-regret controls, we show that when $3/2\leq\alpha\leq2$, such a control exists and is unique. Then we give the singular optimality system that characterizes the control.

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Acknowledgements

The authors are grateful to the referees for their valuable suggestions. The work was supported by the Région Martinique (FWI).

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Department of Mathematics, Faculty of Arts and Sciences, Çankaya University, Ankara, 06530, Turkey
Dumitru Baleanu
Institute of Space Sciences, Magurele-Bucharest, Romania
Dumitru Baleanu
Université des Antilles et de la Guyane, Campus Fouillole, 97159, Pointe-à-Pitre, Guadeloupe (FWI), France
Claire Joseph & Gisèle Mophou
Laboratoire MAINEGE, Université Ouaga 3S, 06 BP 10347, Ouagadougou 06, Burkina Faso
Gisèle Mophou

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Dumitru Baleanu
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Baleanu, D., Joseph, C. & Mophou, G. Low-regret control for a fractional wave equation with incomplete data. Adv Differ Equ 2016, 240 (2016). https://doi.org/10.1186/s13662-016-0970-8

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Received: 18 June 2016
Accepted: 12 September 2016
Published: 21 September 2016
DOI: https://doi.org/10.1186/s13662-016-0970-8

Keywords

Riemann-Liouville fractional derivative
Caputo fractional derivative
optimal control
no-regret control
low-regret control

Low-regret control for a fractional wave equation with incomplete data

Abstract

1 Introduction

2 Preliminaries

Definition 2.1

Definition 2.2

Definition 2.3

Definition 2.4

Lemma 2.5

Theorem 2.6

Theorem 2.7

Proof

Corollary 2.8

Proof

Lemma 2.9

3 Existence and uniqueness of no-regret and low-regret controls

Lemma 3.1

Proof

Lemma 3.2

Proof

Proposition 3.3

Proof

Theorem 3.4

Proof

Proposition 3.5

Proof

Theorem 3.6

Proof

4 Conclusions

References

Acknowledgements

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