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Pseudo-almost periodic solutions for first-order neutral differential equations
Advances in Difference Equations volume 2018, Article number: 114 (2018)
Abstract
In this paper, we study a class of first-order neutral differential equations with time-varying delays and coefficients. Employing the fixed point method and differential inequality techniques, easily verifiable delay-independent criteria are established to ensure the existence and global exponential stability of pseudo-almost periodic solutions for the addressed equations. These theoretical results are also supported with numerical simulations.
1 Introduction
In [1], Komanovskii and Nosov proposed the following first-order neutral differential equations:
to describe the distributed networks containing lossless transmission lines. Here f is a continuous function on \(\mathbb{R}^{2}\), Q is a continuous function on \(\mathbb{R}\), \(x (t)\) represents the state variable, \(r_{1} \) and \(r_{2}\) designate the transmission delays. The detailed biological explanations of the parameters of (1.1) can be found in [1, 2]. It is well known that the variation of the environment plays an important role in many biological and ecological dynamical systems. In particular, periodically varying environment and almost periodically varying environment are foundations for the theory of nature selection. Furthermore, (1.1) has been naturally generalized as the following first-order neutral differential equations with time-varying delays and coefficients:
where \(Q,P\in C(\mathbb{R}, (0, +\infty)), \tau_{1}, \tau_{2}\in C(\mathbb{R}, [0, +\infty))\) are bounded, and \(f\in C (\mathbb{R}\times \mathbb{R}, \mathbb{R})\).
Recently, the existence and stability of periodic solutions or pseudo-almost periodic solutions of (1.2) and its generalized equations have been extensively studied. For example, criteria ensuring the existence of periodic solutions are established in [3–9] and some sufficient conditions for the existence of pseudo-almost periodic (mild) solutions are obtained in [10, 11]. On the other hand, the global exponential stability of pseudo-almost periodic solutions plays a key role in characterizing the dynamical behavior of biological and ecological dynamical systems since the exponential convergence rate can be unveiled [12–20]. However, to the best of our knowledge, no such work has been performed on the dynamic analysis of pseudo-almost periodic solution of first-order neutral differential equations with time-varying delays and coefficients. With this motivation, our goal is to study the existence, uniqueness and global exponential stability of pseudo-almost periodic solutions of (1.2). Here, a new approach will be developed to obtain the global exponential convergence for the pseudo-almost periodic solutions.
Throughout this brief article, we denote
The initial condition associated with (1.2) is of the form
2 Preliminary results
In this section, a few lemmas, notations and assumptions are cited which will be used in Sect. 3.
Assume that \(\mathbb{B}(\mathbb{R},\mathbb{R} )\) represents the set of all bounded and continuous functions from \(\mathbb{R}\) to \(\mathbb{R} \). Then \((\mathbb{B}(\mathbb{R},\mathbb{R} ), \Vert \cdot \Vert )\) is a Banach space, where \(\Vert \cdot \Vert \) denotes the supremum norm \(\Vert w \Vert := \sup_{ t\in \mathbb{R}} \vert w (t) \vert \).
Definition 2.1
\(u(t)\in \mathbb{B}(\mathbb{R},\mathbb{R} )\) is said to be almost periodic on \(\mathbb{R}\) if, for any \(\varepsilon>0\), there exists a real number \(l=l(\varepsilon)>0 \) with the property that, for any interval with length \(l(\varepsilon)\), it is possible to find a number \(\delta=\delta(\varepsilon)\) in this interval such that \(\vert u(t+\delta)-u(t) \vert <\varepsilon \) for all \(t\in \mathbb{R}\).
Let \(AP(\mathbb{R},\mathbb{R} )\) be the set of the almost periodic functions from \(\mathbb{R}\) to \(\mathbb{R} \), and
A function \(\varphi\in{\mathbb{B}(\mathbb{R},\mathbb{R} )}\) is called pseudo-almost periodic if it can be expressed as \(\varphi=h+g\), where \(h\in{AP(\mathbb{R},\mathbb{R} )}\) and \(g\in{\mathit{PAP}_{0}(\mathbb{R},\mathbb{R} )}\). Furthermore, \((\mathit{PAP}(\mathbb{R},\mathbb{R} ), \Vert \cdot \Vert )\) is a Banach space and \(AP(\mathbb{R},\mathbb{R} )\) is a proper subspace of \(\mathit{PAP}(\mathbb{R},\mathbb{R} )\) [22].
Definition 2.2
(see [22, p. 59])
Suppose that \(\Omega \subset \mathbb{R}\) and K is any compact subset of Ω. Let \(\mathit{PAP}_{0}( \mathbb{R}\times \Omega ,\mathbb{R})\) consist of all bounded and continuous functions ϕ such that
uniformly with respect to \(z\in K\). Let \(\mathit{PAP} ( \mathbb{R}\times \Omega ,\mathbb{R} )\) designate all functions η of the form
where \(\phi_{2}\in \mathit{PAP}_{0}( \mathbb{R}\times \Omega ,\mathbb{R} )\), and \(\phi_{1}\) is an almost periodic function for t uniformly on Ω.
In order to study the pseudo-almost periodic solutions for (1.2), we shall assume that \(Q\in AP(\mathbb{R},\mathbb{R} )\), \(P , \tau_{1}, \tau_{2} \in \mathit{PAP}(\mathbb{R},\mathbb{R} )\), \(f\in \mathit{PAP} (\mathbb{R}\times \mathbb{R}, \mathbb{R})\), \(\tau_{1}\) and P are uniformly continuous on \(\mathbb{R}\), and
Lemma 2.1
(see [20, Lemma 2.3])
Set
Then B is a closed subset of \(\mathit{PAP}(\mathbb{R},\mathbb{R})\).
Lemma 2.2
Every solution \(x(t) \) of (1.2) with initial value condition (1.4) exists and is unique on \([0, +\infty)\).
Proof
Let us show initially that \(x (t )\) exists and is unique on \([0, r]\). In fact, for \(t\in [0, r]\), let
and
Then
and
Hence, \(x (t )\) exists and is unique on \([0, r]\). Consequently, the lemma follows from the induction. □
3 Main results
In this section, we establish the existence and global exponential stability of pseudo-almost periodic solutions of (1.2) by using the fixed point theorem and Lyapunov functional method.
Theorem 3.1
Assume that the following conditions hold.
- (\(A_{1}\)):
-
There exist a positive constant \(K^{*}\) and a bounded and continuous function \(\tilde{Q} :\mathbb{R}\rightarrow (0, +\infty)\) such that
$$e ^{-\int_{s}^{t}Q(u)\,du}\leq K^{*} e ^{ -\int_{s}^{t}\tilde{Q} (u)\,du}\quad \textit{for all } t,s \in \mathbb{R} \textit{ and }t-s\geq 0. $$ - (\(A_{2}\)):
-
There exist positive constants \(L^{f} \) and L such that
$$\begin{aligned} & \bigl\vert f(t,x_{1})-f(t,x_{2}) \bigr\vert \leq L^{f} \vert x_{1} - x_{2} \vert \quad \textit{for all } t,x_{1}, x_{2}\in \mathbb{R}, \end{aligned}$$(3.1)$$\begin{aligned} &\sup_{t\in \mathbb{R}} K^{*}\frac{ \vert Q(t)P(t) \vert +L^{f}}{\tilde{Q} (t)}\leq L, \quad L+P ^{+}< 1, \end{aligned}$$(3.2)and
$$\begin{aligned} \sup_{t\in \mathbb{R}} \biggl\{ -\tilde{Q} (t)+K^{*} \frac{ 1 }{1-P ^{+} } \bigl[ \bigl\vert P (t)Q (t) \bigr\vert + L^{f} \bigr] \biggr\} < 0 . \end{aligned}$$(3.3)Then Eq. (1.2) has a unique pseudo-almost periodic solution, and the solution \(x(t )\) of (1.2) with initial condition (1.4) converges exponentially to the pseudo-almost periodic solution as \(t\rightarrow+\infty\).
Proof
Set \(\varphi \in B \) and \(F(t,z)= \varphi(t-z) \). According to Theorem 5.3 in [22, p. 58] and Definition 2.2, the uniform continuity of φ entails that \(F \in \mathit{PAP}(\mathbb{R}\times \Omega, \mathbb{R})\) and F is continuous in \(z\in L\) and uniformly in \(t\in \mathbb{R}\) for all compact subset L of \(\Omega\subset \mathbb{R}\). This, together with \(\tau_{i} \in \mathit{PAP}(\mathbb{R},\mathbb{R})\) and Theorem 5.11 in [22, p. 60], involves
By Corollary 5.12 in [22, p. 61] and the fact that \(f\in \mathit{PAP} ( \mathbb{R}\times \mathbb{R}, \mathbb{R})\), we can show
For any \(\varphi\in B\), we consider an auxiliary equation
In view of the fact that \(M[Q]>0\), it follows from Theorem 2.3 in [23] that the system (3.4) has exactly one pseudo-almost periodic solution
where
Now, we define a mapping \(T:B\longrightarrow AP(\mathbb{R},\mathbb{R})\) as follows:
Next, we prove that the mapping T is a contraction mapping on B.
For all \(t\in \mathbb{R}\), (3.6) entails that \([x^{\varphi}(t)]' \) is bounded on \(\mathbb{R}\), and \(x^{\varphi}(t) \) is uniformly continuous on \(\mathbb{R}\). This, together with the uniform continuities of \(\tau_{1}\) and P, implies that \(P(t)\varphi(t-\tau_{1}(t))\in B\), and the mapping T is a self-mapping from B to B.
Furthermore, for all \(\varphi, \psi \in B \), (3.5), \((A_{1})\) and \((A_{2})\) yield
Thus, the mapping T is a contraction on B. Using Theorem 0.3.1 of [24], we see that the mapping T possesses a unique fixed point \(x^{*}\in B \), \(Tx^{*}=x^{*}\), i.e.,
which, together with (3.6) leads to
and \(x^{*}(t)\) is a pseudo almost periodic solution of equation (1.2).
Finally, we prove that \(x^{*}(t)\) is globally exponentially stable.
Suppose that \(x(t) \) is an arbitrary solution of (1.2) associated with initial value \(\phi\in C([-\tau, 0], \mathbb{R}) \). We trivially extend \(x(t) \) to \(\mathbb{R}\) by letting \(x(t) = x(-\tau) \) for \(t\in (-\infty, -\tau]\). Let
Then \(y(t)\) and \(Y(t)\) are bounded and continuous on \((-\infty, 0]\). From (1.2), we have
According to (3.3), it is possible to find a constant \(\lambda \in (0, \tilde{Q} ^{-} ) \) satisfying
Define
For any \(\varepsilon>0\), we can choose a sufficiently large constant M such that
and
In the following, we will show
Otherwise, there must exist \(\theta >0 \) such that
Furthermore,
for all \(\nu\in (- \infty , t]\), \(t \in(- \infty , \theta) \), which entails that
Note that
Multiplying both sides of (3.17) by \(e ^{ \int_{0}^{s}Q(u)\,du} \), and integrating it on \([0, t]\), we get
Thus, with the help of (3.8), (3.10), (3.11), (3.12), (3.14) and (3.16), we have
which contradicts the fact that \(\vert Y (\theta) \vert = M( \Vert \phi \Vert _{\xi}+\varepsilon)e^{-\lambda \theta}\). Hence, (3.13) holds. Letting \(\varepsilon\longrightarrow 0^{+}\) entails that
Then, arguing as in the proof of (3.15) and (3.16), in view of (3.18), we can show
and
which completes the proof. □
Remark 3.1
The results on periodic solutions or almost periodic solutions of (1.2) in references [1–11] are established under the condition that the decay term coefficient function \(Q(t)\) is not oscillating. In this paper, the assumption \((A_{1})\) relaxes the above technical condition. In fact, one can see Example 4.1 and Remark 4.1 for details.
4 An example and its numerical simulations
Example 4.1
Consider the following first-order neutral differential equations with time-varying delays and coefficients:
where
Then
and
which imply that (4.1) satisfies all conditions in Theorem 3.1. Hence, Eq. (4.1) has exactly one positive almost periodic solution \(x^{*}(t)\). The corresponding simulation results of the solutions are seen in Fig. 1.
Remark 4.1
It should be mentioned that there is no research on the global exponential convergence of the pseudo-almost periodic solution for first-order neutral differential equations with time-varying delays and coefficients. Moreover, because \(Q(t)=1 +2 \sin 200 t\) is oscillating on \(\mathbb{R}\), one can see that all results in Refs. [1–11] cannot be applied to illustrate that all solutions for (4.1) converge exponentially to \(x^{*}(t)\). We all know that the pseudo-almost periodic functions contain almost periodic functions, thus, the derived results are still novel if we reduce all time-varying delays and coefficients of (1.2) to periodic functions or almost periodic functions.
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Acknowledgements
We would like to thank the anonymous referees for their valuable comments, which led to an improvement in the presentation. This work was supported by the Natural Scientific Research Fund of Hunan Provincial of China (Grant Nos. 2018JJ2087, 2018JJ2372), Natural Scientific Research Fund of Hunan Provincial Education Department of China (Grant No. 17C1076), Zhejiang Provincial Natural Science Foundation of China (Grant No. LY18A010019) and Zhejiang Provincial Education Department Natural Science Foundation of China (Y201533862).
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Yu, Y., Gong, S. Pseudo-almost periodic solutions for first-order neutral differential equations. Adv Differ Equ 2018, 114 (2018). https://doi.org/10.1186/s13662-018-1568-0
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DOI: https://doi.org/10.1186/s13662-018-1568-0