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Existence of solutions for a coupled system of fractional differential equations by means of topological degree theory
Advances in Difference Equations volume 2021, Article number: 309 (2021)
Abstract
This paper investigates the existence of solutions for a coupled system of fractional differential equations. The existence is proved by using the topological degree theory, and an example is given to show the applicability of our main result.
1 Introduction
In this manuscript, the following coupled system of fractional differential equations is discussed:
where \(1<\theta \leq 2\), \(\alpha >0\), \(\eta ,\xi \in (0,1]\), \(a_{j}\), \(b_{j}\), \(c_{j}\) (\(j=1,2\)) are real numbers with \(a_{j}\neq b_{j}+ c_{j}\) (\(j=1,2\)). Further \(f,\phi ,\psi : [0,1]\times \mathbb{R}\rightarrow [0,1]\), and \(h:[0,1]\times \mathbb{R}\times \mathbb{R}\rightarrow [0,1]\) are continuous functions, \(f(0,x(0))=0\), \(\frac{\partial ^{i}f(t,x(t))}{\partial t^{i}}|_{t=0}=0\) for \(i=1,2, \ldots , n-1\). \(D^{\theta }\) represents the Caputo fractional derivative of order θ.
Fractional differential equations are widely used in many fields such as chemistry, physics, biology, and optimization theory [1–4]. In addition, coupled systems of fractional differential equations have attracted particular concern from scholars considering their appearance in the mathematical modeling of physical phenomena like chaos synchronization [5], anomalous diffusion [6], disease models [7], and so on. The existence theory to fractional differential equations with integral boundary conditions has widespread applications in optimization theory, many researchers have studied [8–13], and the existence of solutions is the basis of studying the stability and numerical solutions of differential equations [14]. For the existence of solutions of fractional differential equations, the authors use diverse methods, such as fixed point theory [15–19], upper and lower solutions method [20], monotone iterative technique and Mawhin’s continuation theorem [21], and topological degree theory [22]. When studying the existing literature, we find that fractional differential equations with integral boundary conditions are not properly tested via topological degree theory. Thus we investigate the existence result to a coupled system of fractional differential equations(1.1) through applying topological degree theory.
Bashiri et al. [23]investigated the existence of solutions for fractional differential equations by means of the coupled fixed point theorem of Krasnoselskii type
where \(D^{\theta }\) denotes the Riemann–Liouville fractional derivative, \(\theta \in (0,1)\), \(\alpha >0\).
Ahmad et al. [24]established existence results as well as studied qualitative aspects of the proposed coupled system of fractional hybrid delay differential equations
where \(\mathcal{A}=[0,\tau ]\), \(^{C}D_{+0}, \tau >0\) is Caputo’s derivative, and \(r_{0}\), \(h_{0}\) are real numbers, while the delay parameter is denoted by \(\nu \in (0,1)\).
Muthaiah et al. [25]considered the existence and Hyers–Ulam type stability results for the nonlinear coupled system of Caputo–Hadamard type fractional differential equations
where \(^{C}D^{(\cdot )} \) denotes the Caputo–Hadamard fractional derivative, \(^{H}I^{(\cdot )} \) denotes the Hadamard fractional integrals, \(2<\varrho ,\varsigma \leq 3\), \(0<\varrho _{1}, \varsigma _{1}<1\), \(\alpha _{1}\), \(\alpha _{2}\), \(\beta _{1}\), \(\beta _{2}\) are real constants and \(\zeta _{j}\), \(\upsilon _{j}\), \(j=1,2,\ldots ,k-2\), are positive real constants. The consequence of existence is obtained by employing the alternative of Leray–Schauder and Krasnoselskii’s, whereas the uniqueness result is based on the principle of Banach contraction mapping.
Motivated especially by the aforementioned work, we consider the existence of solutions to a coupled system of fractional differential equations (1.1). According to our literature review, no scholars have studied equation (1.1), the results are entirely new. The remainder of this paper is as follows. In the second part, we display some definitions, facts, and results. We confirm the existence of solutions for system (1.1) in the third part. Finally, we provide an example to prove our results.
2 Preliminaries
In this part, we recollect a number of facts, definitions, and conclusions. Let \(C([0,1]\times \mathbb{R}, [0,1])\) represent the space of all continuous functions \(f,\phi ,\psi : [0,1]\times \mathbb{R}\rightarrow [0,1]\), and let \(C([0,1]\times \mathbb{R}\times \mathbb{R}, [0,1])\) express the class of functions \(h: [0,1]\times \mathbb{R}\times \mathbb{R}\rightarrow [0,1]\) such that
-
(1)
the map \(t\rightarrow h(t,x,y)\) is measurable for each \(x,y\in \mathbb{R}\),
-
(2)
the map \(x\rightarrow h(t,x,y)\) is continuous for each \(x\in \mathbb{R}]\),
-
(3)
the map \(y\rightarrow h(t,x,y)\) is continuous for each \(y\in \mathbb{R}\).
Let X be a Banach space and \(\mathbb{B}\subset P(X)\), where \(P(X)\) stands for the family of all bounded subsets of X. Next, we introduce some concepts.
Definition 2.1
([26])
The Kuratowski measure of noncompactness \(\alpha : \mathbb{B}\rightarrow \mathbb{R_{+}}\) is defined as
Definition 2.2
([26])
Let \(\mathcal{F}: \Omega \rightarrow X\) be a continuous bounded map, where \(\Omega \subseteq X\). Then \(\mathcal{F}\) is
\((1)\) α-Lipschitz if there exists \(k\geq 0\), therefore \(\alpha (\mathcal{F}(S))\leq k\alpha (S)\) for all bounded subsets \(S\subseteq \Omega \);
\((2)\) strict α-contraction if there exists \(0\leq k<1\) such that \(\alpha (\mathcal{F}(S))\leq k\alpha (S)\) for all bounded subsets \(S\subseteq \Omega \);
\((3)\) α-condensing if \(\alpha (\mathcal{F}(S))< \alpha (S)\) for all bounded subsets \(S\subseteq \Omega \) with \(\alpha (S)>0\). In other words, \(\alpha (\mathcal{F}(S))\geq \alpha (S)\) implies \(\alpha (S)=0\).
All classes of strict α-contraction \(\mathcal{F}: \Omega \rightarrow X\) and all classes of α-condensing maps \(\mathcal{F}: \Omega \rightarrow X\) are represented by \(\Lambda C_{\alpha }(\Omega )\) and \(C_{\alpha }(\Omega )\), respectively. Then \(\Lambda C_{\alpha }(\Omega )\subset C_{\alpha }(\Omega )\) and each \(\mathcal{F}\in C_{\alpha }(\Omega )\) is α-Lipschitz with constant \(k=1\). Moreover, \(\mathcal{F}: \Omega \rightarrow X\) is Lipschitz whenever there is \(k>0\), therefore
Further, \(\mathcal{F}\) will be a strict contraction if \(k<1\).
Proposition 2.3
([27])
If \(\mathcal{F}, \mathcal{G} : \Omega \rightarrow X\) are α-Lipschitz with respective constants \(k_{1}\) and \(k_{2}\), then \(\mathcal{F}+\mathcal{G}\) is α-Lipschitz with constant \(k_{1}+k_{2}\).
Proposition 2.4
([27])
If \(\mathcal{F }: \Omega \rightarrow X\) is Lipschitz with constant k, then \(\mathcal{F}\) is α-Lipschitz with the equal constant k.
Proposition 2.5
([27])
If \(\mathcal{F} : \Omega \rightarrow X\) is compact, then \(\mathcal{F}\) is α-Lipschitz with constant \(k=0\).
Theorem 2.6
([27])
If \(\mathcal{F} : X\rightarrow X\) is α-condensing and
If Λ is a bounded set in X, so we have \(r>0\) such that \(\Lambda \subset B_{r}(0)\), then
Consequently, \(\mathcal{F}\) has at least one fixed point, and the set of the fixed points of \(\mathcal{F}\) lies in \(B_{r}(0)\).
Definition 2.7
([28])
The fractional integral of order \(\theta (\theta >0)\) of function \(f: [0,\infty )\rightarrow R\) is defined as
provided that the right-hand side is pointwise defined on \((0, \infty )\).
Definition 2.8
([28])
The Caputo fractional derivative of order \(\theta (\theta >0)\) of the function \(f:[0,\infty )\rightarrow R\) is defined by
where \(t>0\), \(n=[\theta ]+1\).
Lemma 2.9
([28])
Let \(\theta >0\), then the following result holds for fractional differential equations:
for arbitrary \(n=[\theta ]+1\), \([\theta ]\) indicates the integer part of the real number \(\theta >0\), \(C_{i}\in \mathbb{R}\), \(i=0,1,2,\ldots ,n-1\). \(D^{\theta }\) is a Caputo fractional derivative.
3 Main results
In this part, we discuss the existence result for (1.1).
The space \(X=C([0,1], \mathbb{R})\) of all continuous functions is a Banach space under the topological norm \(\| x\| =\sup \{| x(t)| : t\in [0,1]\}\) and the product space \(X\times X \) is a Banach space under the norm \(\| (x,y)\| =\| x\| +\| y \| \) or \(\| (x,y)\| =\max \{\| x\| ,\| y \| \}\).
In order to get the result of our result, we need the following hypotheses.
\((H_{1})\) For each \((t,x), (t,\bar{x}), (t,y), (t,\bar{y})\in [0,1]\times \mathbb{R}\), there exist constants \(\lambda _{1}, \lambda _{2}\in [0,1)\) such that
\((H_{2})\) For each \((t,x,y)\in \mathbb{R}\), there exist positive constants \(l_{h}^{1}\), \(l_{h}^{2}\), \(M_{h}\) and \(q_{1}\in [0,1)\) such that
\((H_{3})\) For each \((t,x)\in [0,1]\times \mathbb{R}\), there exist positive constants \(l_{f}\), \(M_{f}\) and \(q_{2}\in [0,1)\) such that
\((H_{4})\) For each \((t,x), (t,y)\in [0,1]\times \mathbb{R}\), there exist positive constants \(c_{\phi }\), \(c_{\psi }\), \(M_{\phi }\), \(M_{\psi }\), and \(q_{2}\in [0,1)\) such that
\((H_{5})\) For each \((t,x), (t,\bar{x}), (t,y), (t,\bar{y})\in [0,1]\times \mathbb{R}\), we have positive constants \(b_{\phi }, b_{\psi }\in [0,1)\) such that
Lemma 3.1
If \(f(0,x(0))=0\), \(\frac{\partial ^{i}f(t,x(t))}{\partial t^{i}}|_{t=0}=0\) for \(i=1,2,\ldots , n-1\), then the consequence of fractional differential equations (1.1) is a conclusion of the following system of integral equations:
Proof
Applying the fractional integrable operator \(I^{\theta }\) on the equation of system (1.1) and through applying Lemma 2.9, we get
By applying the initial conditions \(x'(0)=0\) and \(\frac{\partial ^{i}f(t,x(t))}{\partial t^{i}}|_{t=0}=0\), we obtain \(C_{1}=0\) and
Now, applying the boundary conditions \(a_{1}x(0)-b_{1}x(\eta )-c_{1}x(1)=\frac{1}{\Gamma (\theta )}\int _{0}^{1} (1-s)^{\theta -1}\phi (s, x(s))\,ds\) to (3.2), we have
By rearranging, we obtain
Thus equation (3.2) becomes
Analogously, following the same steps in the process for the second equation of system (1.1), we get
 □
Define the operator \(F, H, T : X\times X\rightarrow X\times X \) by
here \(F_{1}, F_{2}, H_{1}, H_{2}: X\rightarrow X\) are
Then the system of integral equations (3.1) can be written as an operator equation
and fixed points of the operator equation are results of system (1.1).
Theorem 3.2
The operator F is Lipschitz with constant k. Therefore F is α-Lipschitz with the equal constant k and meets the following growth condition:
Proof
Now, we shall display that the operator F is Lipschitz with constant k. Let \(x_{1}, x_{2}\in X\), then we get
By using conditions (\(H_{1}\)) and (\(H_{5}\)), we can write
where \(k_{1}=\lambda _{1}+ \frac{(| b_{1}| +| c_{1}| ) \lambda _{1}}{| a_{1}-(b_{1}+c_{1})| }+ \frac{b_{\phi }}{| a_{1}-(b_{1}+c_{1})| \Gamma (\theta +1)}\).
Similarly,
where \(k_{2}=\lambda _{2}+ \frac{(| b_{2}| +| c_{2}| ) \lambda _{2}}{| a_{2}-(b_{2}+c_{2})| }+ \frac{b_{\psi }}{| a_{2}-(b_{2}+c_{2})| \Gamma (\theta +1)}\). Thus
where \(k=\max (\lambda _{1}+ \frac{(| b_{1}| +| c_{1}| ) \lambda _{1}}{| a_{1}-(b_{1}+c_{1})| }+ \frac{b_{\phi }}{| a_{1}-(b_{1}+c_{1})| \Gamma (\theta +1)}, \lambda _{2}+ \frac{(| b_{2}| +| c_{2}| ) \lambda _{2}}{| a_{2}-(b_{2}+c_{2})| }+ \frac{b_{\psi }}{| a_{2}-(b_{2}+c_{2})| \Gamma (\theta +1)} )\). Then F satisfies the Lipschitz condition, thus F is Lipschitz with constant k. According to Proposition 2.4, F is α-Lipschitz with constant k.
Moreover, we get
By \((H_{3})\) and \((H_{4})\), we have
Similarly,
Hence it follows that
where
 □
Theorem 3.3
The operator \(H: X\times X\rightarrow X\times X\) is continuous and meets the following growth condition:
Proof
Consider a bounded subset of \(X \times X\) as
Let \(\{(x_{n},y_{n})\}\) be a sequence in \(B_{r}\) such that \((x_{n},y_{n})\rightarrow (x,y)\) as \(n\rightarrow \infty \). To show that H is continuous, we consider
From the continuity of h, it follows that
For every \(t\in [0,1]\), by applying \((H_{2})\), and the Lebesgue dominated convergent theorem, we can get
The same as the other terms approach 0 as \(n\rightarrow \infty \), thus
Then \(H_{1}\) is continuous. By the same steps as above, one lightly gets that
That is, \(H_{2}\) is continuous. From (3.3) and (3.4), we have
which means that H is continuous.
Moreover, by \((H_{2})\), we have
Similarly,
Thus
where \(l=\max \{l_{h}^{1},l_{h}^{2}\}\in [0,1)\), \(L_{h}=\max ( \frac{1}{\Gamma (\theta +1)}+ \frac{| b_{2}| +| c_{2}| }{| a_{2}-(b_{2}+c_{2})| \Gamma (\theta +1)}, \frac{1}{\Gamma (\theta +1)}+ \frac{| b_{1}| +| c_{1}| }{| a_{1}-(b_{1}+c_{1})| \Gamma (\theta +1)})\), \(L_{H}=(1+(\frac{1}{\Gamma (\alpha +1)})^{q_{1}})L_{h}\), \(M_{H}=2L_{h}M_{h}\). Hence H satisfies the growth condition. □
Theorem 3.4
The operator \(H: X \times X\rightarrow X \times X\) is compact.
Proof
Let Ω be a bounded subset of \(B_{r}\subseteq X \times X\) and \(\{(x_{n},y_{n})\}\) be a sequence in Ω, through applying the growth condition of H, it is obvious that \(H(\Omega )\) is uniformly bounded in \(X \times X\). Now, we need to reveal that H is equicontinuous. Let \(0\leq t\leq \tau \leq 1\), then we obtain
Similarly,
Taking limit as \(t\rightarrow \tau \), we get
and
which implies that
This reveals that \(H(x,y)\) is equicontinuous. \(H(x,y)\) is compact by the Arzelá–Ascoli theorem. Hence, according to Proposition 2.5, H is α-Lipschitz with constant zero. □
Theorem 3.5
If \((H_{1})\)–\((H_{5})\) hold and
then coupled system (1.1) has at least one solution \((x,y)\in X\times X\). And the solution set of (1.1) is bounded in \(X\times X\).
Proof
From Theorem 3.2 and \(k\in [0,1)\), F is α-Lipschitz with constant \(k\in [0,1)\), according to Theorem 3.4, H is α-Lipschitz with constant 0. By Proposition 2.3 and Definition 2.2, T is a strict α-contraction with constant k. Hence, T is α-condensing. Then, we think over the following set:
We have to reveal that R is bounded in \(X\times X\). Let \((x,y)\in R\), then by applying the growth conditions of Theorem 3.2 and Theorem 3.3, we have
thus
where \(q_{1},q_{2}\in [0,1)\). Thus R is bounded in \(X \times X\). According to Theorem 2.6, there exists \(r>0\) such that \(R\subset B_{r}(0)\), then
Therefore, T has at least one fixed point, then coupled system (1.1) has at least one solution. □
4 Examples
This part, we have the following example account for our main results.
Example 4.1
Give thought to the following equation:
where \(h=\frac{e^{-\pi t}}{10}+ \frac{\cos | y(t)| +\sin | y(t)| }{51+t^{2}}\), \(\theta = \frac{3}{2}\), \(a_{1}=\frac{1}{4}\), \(b_{1}=\frac{1}{2}\), \(c_{1}=6\), \(a_{2}= \frac{1}{5}\), \(b_{2}=\frac{1}{7}\), \(c_{2}=8\), \(\eta =\xi =\frac{1}{2}\). Let \(\zeta =\frac{1}{5}\), then by routine calculation, we can have \(c_{\phi }=b_{\phi }=\frac{1}{2}\), \(c_{\psi }=b_{\psi }=\frac{1}{5}\), \(M_{ \phi }=M_{\psi }=0\), \(l_{h}^{1}=l_{h}^{2}=\frac{1}{51}\), \(M_{h}= \frac{1}{10}\), \(l_{f}=\frac{1}{10}\), \(M_{f}=0\), \(\lambda _{1}=\lambda _{2}= \frac{1}{10}\). Thus assumptions \((H_{1})-(H_{5})\) hold, and
Next,
thus F is α-Lipschitz with the constant 0.160, and thus H is α-Lipschitz with the constant zero, which means that T is α-Lipschitz with the constant 0.160. Since
then, by routine calculation, we obtain \(L_{F}=0.216\), \(L_{H}=2.380\), \(M_{F}=0\), \(M_{H}=0.238\).
Thus
then R is bounded, through Theorem 3.5, then problem (4.1) has at least one solution.
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The authors are very grateful to the referees for their very helpful comments and suggestions, which greatly improved the presentation of this paper.
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This research is funded by the National Natural Science Foundation of P.R. China (No:11661037).
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Xie, J., Duan, L. Existence of solutions for a coupled system of fractional differential equations by means of topological degree theory. Adv Differ Equ 2021, 309 (2021). https://doi.org/10.1186/s13662-021-03457-y
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DOI: https://doi.org/10.1186/s13662-021-03457-y
MSC
- 34B15
- 34B18
- 34B37
- 58E30
Keywords
- Fractional differential equations
- Boundary value problems
- Topological degree theory
- Coupled systems