On a kind of time optimal control problem of the heat equation

In this paper, we consider a kind of time-varying bang–bang property of time optimal boundary controls for the heat equation. The time-varying bang–bang property in the interior domain has been considered in some papers, but regarding the time optimal boundary control problem it is still unsolved. In this paper, we determine that there exists at least one solution to the time optimal boundary control problem with time-varying controls.

Let \(\mathbb{R}_{+}=(0,+\infty)\), and let Ω be a nonempty open bounded domain in \(\mathbb{R}^{N}\) (\(N\geq1\)) with smooth boundary ∂Ω. Let \(\Gamma\subset\partial\Omega\) be a nonempty and open subset of ∂Ω. Consider the following controlled system:

Here, \(y_{0}\in L^{2}(\Omega)\) is a given function, and \(u\in L^{\infty}(\mathbb{R}_{+}; L^{2}(\Gamma))\) is the control. We denote the solution to (1.1) as \(y(\cdot; y_{0},u)\).

In this paper, we let

Denote the norm and inner product of \(L^{2}(\Omega)\) or \(L^{2}(\Gamma)\) as \(\|\cdot\|\) and \(\langle\cdot, \cdot\rangle\), respectively, and the open (or closed) ball of \(L^{2}(\Omega)\), with a center at 0 and a radius of \(r>0\), as \(B(0,r)\) (or \(\bar{B}(0,r)\)).

In industry and engineering, temperature control is a kind of important control, and time optimal control of heat equation is a typical case for temperature control. There are some optimal control problems: time optimal control problem and norm optimal control problem. They are important and interesting problems of optimal control theory. In [1], these optimal control problems have been considered.

Time optimal control problems was discussed by Egorov in 1963 and he proved a bang–bang property for his problem (see [2]), Fattorini discussed it independently in 1964 (see [3]). Then Balakrishnan proved a maximal principle for the optimal control and which can imply the bang–bang property (see [4]), Friedman discussed the time optimal control problem on Banach spaces (see [5]), Fattorini proved that the maximal principle in 1974 for some special Banach spaces. There are many other authors considering the time optimal control problem (see, e.g., [1, 6–15]). Regarding stochastic cases, norm optimal control problems were considered in [16, 17] for stochastic ordinary differential equations and in [18] for stochastic heat equations.

The reader can also refer to [19–21] for the equivalence of three kinds of optimal control problems. For some other interesting work, we refer the reader to [22–24]. The approximate controllability of system (1.1) has been studied in much work (see, e.g., [14, 25–28]). It is clear that, for each \(\varepsilon >0\), we have \(\|y(T; y_{0},0)\|\leq \varepsilon \) when T is large enough.

The bang–bang property has been studied in much work (see, e.g., [1, 11, 13, 14, 29–32]). However, regarding the time-varying bang–bang property, particularly in infinite-dimensional cases, there is only one paper [19] in which the authors considered a kind of time optimal control problem that involves an interior subset.

In this paper, we consider the time-varying bang–bang property of the heat equation that affects the boundary.

For a given function \(M(\cdot )\in L^{\infty}_{+}(\mathbb{R}_{+})\), we define

and

The time optimal control problem considered is as follows:

where \(\varepsilon>0\). In this problem, if \(u\in\mathcal{U}_{M(\cdot )}\) and \(y(T;y_{0}, u)\in\bar{B}(0,\varepsilon )\) for some \(t\in\mathbb{R}_{+}\), we call u an admissible control; if \(T^{*}\in\mathbb{R}_{+}\) and \(u^{*}\in\mathcal{U}_{M(\cdot)}\) satisfy \(y(T^{*};y_{0}, u^{*})\in\bar{B}(0,\varepsilon )\), we call \(T^{*}\) and \(u^{*}\) the optimal time and a time optimal control, respectively.

If \(y_{0}\in\bar{B}(0,\varepsilon )\), taking the control \(u=0\), then it is obvious that the optimal time \(T^{*}=0\), this is trivial. Hence, throughout this paper, we assume that

from which we see that if \(T^{*}\) exists, then \(T^{*}>0\).

The main result of this paper is in establishing the following time-varying bang–bang property of problem (1.3).

Theorem 1.1

Assume that \(M(\cdot )\in L^{\infty}_{+}(\mathbb{R}_{+})\) and \(\varepsilon >0\). Then the following two conclusions are true:

1. (i)

   There exist at least one optimal time and time optimal control for problem (1.3);

2. (ii)

   Any time optimal control \(u^{*}\) for problem (1.3) satisfies the following time-varying bang–bang property:

   $$ \bigl\Vert u^{*}(t) \bigr\Vert _{L^{2}(\Gamma)}=M(t) \quad \textit{for a.e. } t\in \bigl(0, T^{*} \bigr) $$

   (1.4)

   and

   $$ \bigl\Vert y \bigl(T^{*};y_{0}, u^{*} \bigr) \bigr\Vert _{L^{2}(\Omega)}= \varepsilon. $$

   (1.5)

We organize this paper as follows. In Sect. 2, we prove the existence of optimal controls for problem (1.3) and discuss some properties of the optimal controls (see Lemma 2.1). Then we prove Theorem 1.1.

Lemma 2.1

For problem (1.3), the following two conclusions are true:

1. (i)

   There exists at least one optimal time \(T^{*}\) and time optimal control \(u^{*}\) for problem (1.3).

2. (ii)

   Any time optimal control \(u^{*}\) for problem (1.3) satisfies the following property:

   $$ \bigl\Vert u^{*}(t) \bigr\Vert _{L^{2}(\Gamma)}=M(t)\quad \textit{for a.e. } t\in \bigl(0, T^{*} \bigr). $$

   (2.1)

Proof

Let \(u=0\). Then, by the property of the heat equation, we have \(\| e^{\Delta T}y_{0}\|_{L^{2}(\Omega)}\rightarrow0\) as \(T\rightarrow\infty \), which implies that \(T^{*}<+\infty\) by the definition of \(T^{*}\) (see (1.3)).

Let \(\{T_{n}\}_{n=1}^{\infty}\), with \(T_{n}\geq T_{n+1}\) for all \(n\in \mathbb{N}\) such that

where \(T^{*}\) is defined as (1.3). Then there exists a sequence \(\{u_{n}\}_{n\geq1}\subset\mathcal {U}_{M(\cdot)}\) such that

Denote

Then

Since

there exists a subsequence of \(\{\tilde{u}_{n}\}_{n\geq1}\), still denoted thus, and \(v^{*}\in L^{\infty}(0,T_{1};L^{2}(\Gamma))\) such that

According to (2.3), there is a subsequence of \(\{\tilde{u}_{n}\} _{n\geq1}\), still denoted thus, such that

where \(y(\cdot; y_{0},\tilde{v}^{*})\) is the solution to the following system:

It follows from (2.2) and (2.4) that

Letting \(n\rightarrow\infty\), we obtain

which shows that \(v^{*}=\tilde{v}^{*}|_{(0,T^{*})}\) is an optimal control.

Next, we show that

By contradiction, there exist \(\delta_{0}>0\) and a measurable set \(E_{0}\subset(0,T^{*})\), with \(|E_{0}|>0\), such that

where \(|E_{0}|\) is the Lebesgue measure of \(E_{0}\). Then we have

According to (2.7), we can set

It is obvious that \(\zeta\in L^{\infty}(0,T; L^{2}(\Gamma))\). From (2.3), it is easily verified that

Since \(\|u_{n}(t)\|_{L^{2}(\Gamma)}\leq M(t)\) and \(\|\zeta(t)\| _{L^{2}(\Gamma)}\leq1\) for a.e. \(t\in(0,T^{*})\), it follows from (2.9) and (2.10) that

which contradicts (2.8).

Finally, let \(u^{*}\triangleq v^{*}\). Then (i) of this lemma follows from (2.5) and (2.6).

(ii) Since \(y_{0}\notin\bar{B}(0,\varepsilon )\), we see that \(T^{*}>0\). The proof is carried out in the following three steps.

Step 1. We show that \(y(T^{*}; y_{0}, u^{*})\in\partial B(0,\varepsilon )\).

Otherwise, we have \(y(T^{*}; y_{0},u^{*})\in B(0,\varepsilon )\), i.e., \(\|y(T^{*}; y_{0},u^{*})\|_{L^{2}(\Omega)}<\varepsilon \). For each \(\delta>0\), we have

Noting that

as \(\delta\rightarrow0\),

as \(\delta\rightarrow0\) and

as \(\delta\rightarrow0\), we obtain

This, together with \(y(T^{*}; y_{0},u^{*})\in B(0,\varepsilon )\), implies that, for a sufficiently small \(\delta>0\), we have

This shows that \(T^{*}-\delta\) is also an optimal time in (1.3), which contradicts the definition of \(T^{*}\).

Step 2. We show that \(\mathcal{R}(y_{0},T^{*})\cap\bar{B}(0,\varepsilon )\) has only one point.

Otherwise, there exist \(u_{1}, u_{2}\in\mathcal{U}_{M(\cdot)}\) such that

and

Denote

It is clear that \({\hat{u}}\in\mathcal{U}_{M(\cdot)}\) and that

Note that \(\bar{B}(0,\varepsilon )\) is a strictly convex subset of \(L^{2}(\Omega)\). Based on (2.11), (2.12) and (2.13), we have

since \({\hat{u}}\in\mathcal{U}_{M(\cdot)}\) according to (2.14) and (2.15), which contradicts the optimality of ε.

Step 3. We prove that any time optimal control \(u^{*}\) satisfies (2.1).

In fact, since \(\mathcal{R}(y_{0},T^{*})\cap\bar{B}(0,\varepsilon )\) has only one point, \(\{y(T;y_{0}, u^{*})\}=\mathcal{R}(y_{0},T^{*})\cap\bar{B}(0,\varepsilon )\). Since \(\mathcal{R}(y_{0},T^{*})\) and \(\bar{B}(0,\varepsilon )\) are two convex sets, according to the Hahn–Banach theorem, there exists \(\eta^{*}\in L^{2}(\Omega)\setminus\{0\}\) such that

This shows that

i.e.,

Here,

and

Let \(E_{0}\) be the set of the Lebesgue points of \(\widetilde{u}^{*}(\cdot)\) and \(M(\cdot)\) in \((0, T^{*})\). For each \(t_{0}\in E_{0}\), let

where \(\zeta\in L^{2}(\Gamma)\), with \(\|\zeta\|_{L^{2}(\Gamma)}\leq1\), and \(\lambda \in(0,\min\{t_{0},T^{*}-t_{0}\})\). By (2.17), we have

Letting \(\lambda\rightarrow0+\), we obtain

This implies that

from which we obtain

Noting that \({\widetilde{u}}^{*}\in\mathcal{U}_{1}\) and \(\eta^{*}\neq0\), according to (2.18) and (2.19), we obtain

This completes the proof of this lemma. □

Based on Lemma 2.1, we have the following result.

Corollary 2.2

Let and \(u_{2}^{*}\) be two optimal controls for problem (1.3). Then \(u_{1}^{*}= u_{2}^{*}\).

Following from Lemma 2.1, we can now prove Theorem 1.1.

Proof of Theorem 1.1

From (i) and (ii) of Lemma 2.1, we obtain (i) and (ii) of Theorem 1.1.

Finally, we show that \(\|y(T^{*}; y_{0}, u^{*})\|_{L^{2}(\Omega)}=\varepsilon \).

By contradiction, we suppose that \(y(T^{*}; y_{0},u^{*})\in B(0,\varepsilon )\), i.e., \(\|y(T^{*}; y_{0},u^{*})\|_{L^{2}(\Omega)}<\varepsilon \). For \(\delta>0\), we obtain

Noting that

as \(\delta\rightarrow0\),

as \(\delta\rightarrow0\) and

as \(\delta\rightarrow0\), we obtain

This, together with \(y(T^{*}; y_{0},u^{*})\in B(0,\varepsilon )\), implies that, for a sufficiently small \(\delta>0\), we have

This shows that \(T^{*}-\delta\) is also an optimal time in (1.3), which contradicts the definition of \(T^{*}\). Hence, \(\|y(T^{*}; y_{0},u^{*})\|_{L^{2}(\Omega)}=\varepsilon \). □

The author is grateful to the anonymous referees for their helpful comments and suggestions, which helped to greatly improve the presentation of this paper. There is no funding to acknowledge.

Authors and Affiliations

1. School of Mathematics and Statistics, Central South University, Changsha, P.R. China

   Yifan Zhang

Contributions

The author read and approved the final manuscript.

Corresponding author

Correspondence to Yifan Zhang.

Competing interests

The author declares to have no competing interests regarding the publication of this article.

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