Existence results of nonlocal boundary value problem for a nonlinear fractional differential coupled system involving fractional order impulses

In this paper, we study the nonlocal boundary value problem for a nonlinear fractional differential coupled system with fractional order impulses. Applying Nonlinear Alternative of Leray–Schauder, we obtain some new existence results for this system. As application, an interesting example is given to illustrate the effectiveness of our main result.

In describing some phenomena and processes of many fields such as physics, chemistry, aerodynamics, electrodynamics of a complex medium, polymer rheology, capacitor theory, electrical circuits, biology, control theory, fitting of experimental data, and so on, the fractional order calculus is an excellent and more accurate tool than the integral order calculus. For example, in physics, we use Newtons’ law \(\eta \varepsilon '(t)=\sigma (t)\) to describe the mechanics of viscous fluids, where \(\sigma (t)\) and \(\varepsilon (t)\) denote stress and strain at time t, respectively, and η is the viscosity of the material. However, we need to employ Nuttings’ law [1] \(\eta D_{0^{+}} ^{k}\varepsilon '(t)=\sigma (t)\) (\(k\in (n-1,n)\), \(n\in \mathbb{N}\)) to deal with the mechanics of viscous fluids involving some possible interpolation properties. As a consequence, the subject of fractional differential equations is gaining much importance and attention. There have been many papers focused on boundary value problems of fractional ordinary differential equations (see [1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31]). Especially, the nonlocal boundary value problems have been widely studied by many scholars because of their extensive applications in, e.g., blood flow problems, chemical engineering, thermo-elasticity, underground water flow, population dynamics, and so forth. The nonlocal boundary value problems of fractional-order differential equations constitute a class of very interesting and important problems. Such boundary value problems have been investigated in [8,9,10,11,12,13,14, 24, 25, 30].

In addition, the theory of impulse differential equations has seen significant development in recent years and played a very important role in modern applied mathematical models of real processes arising in phenomena studied in physics, population dynamics, chemical technology and biotechnology. Recently, some scholars have begun to study the boundary value problems for impulsive fractional differential equations (see [1, 15,16,17,18,19,20,21,22,23,24,25,26, 30, 32]). As is well known, the study on fractional differential coupled systems is more complicated and challenged than the study on a single fractional differential equation. Recently, some scholars began to investigate fractional differential coupled systems and obtained some good results (see [8, 12, 13, 24, 26, 31]). However, there are few papers on the impulsive fractional order coupled systems with nonlocal boundary conditions and impulses. Therefore, in this paper, we consider the following four-point boundary value problem for nonlinear fractional differential coupling system with fractional order impulses of the form

where \(J=[0,1]\), \(1<\alpha \), \(\beta <2\), \(0< p\), \(q,\gamma _{1},\gamma _{2}, \delta _{1},\delta _{2},z,w<1\), \({}^{C}D_{0^{+}}^{\alpha }\), \({}^{C}D_{0^{+}} ^{\beta }\), \({}^{C}D_{0^{+}}^{p}\), \({}^{C}D_{0^{+}}^{q}\), \({}^{C}D_{0^{+}} ^{\gamma _{1}}\), and \({}^{C}D_{0^{+}}^{\gamma _{2}}\) are the Caputo fractional derivatives; \({}^{\mathrm{LR}}D_{0^{+}}^{\delta _{1}}\) and \({}^{\mathrm{LR}}D_{0^{+}} ^{\delta _{2}}\) are the Riemann–Liouville fractional derivatives; \(f,g\in C(J\times R^{2},R)\), \(J_{1k},J_{2k}\in C(R,R)\), and \(\{t_{k}\}\) satisfies \(0=t_{0}< t_{1}<\cdots <t_{n}<t_{n+1}=1\), \({}^{C}D_{0^{+}}^{\gamma _{1}}x(t_{k}^{+})\), \({}^{C}D_{0^{+}}^{\gamma _{1}}x(t _{k}^{-})\), \({}^{C}D_{0^{+}}^{\gamma _{2}}y(t_{k}^{+})\), \({}^{C}D_{0^{+}} ^{\gamma _{2}}y(t_{k}^{-})\) all exist, \({}^{C}D_{0^{+}}^{\gamma _{1}}x(t _{k}^{-})= {}^{C}D_{0^{+}}^{\gamma _{1}}x(t_{k})\), \({}^{C}D_{0^{+}}^{ \gamma _{2}}y(t_{k}^{-})= {}^{C}D_{0^{+}}^{\gamma _{1}}y(t_{k})\), \(k=1,2,\ldots ,n\).

The rest of this paper is organized as follows. In Sect. 2, we recall some definitions and lemmas of the Caputo and Riemann–Liouville fractional calculus. In Sect. 3, we shall prove the existence of solutions for system (1.1). In Sect. 4, some examples are given to demonstrate the application of our main results. Finally, conclusions are given in Sect. 5 to simply recall our studies and results obtained.

Let \(C(J)\) be the Banach space of continuous functions from J to \(\mathbb{R}\) with the norm \(\|\psi \|_{C}=\sup_{t\in J}|\psi (t)|\). Define the function space \(\mathrm{PC}(J)\) by

Obviously, \(\mathrm{PC}(J)\) is a real Banach space equipped with the norm

Let \(X=\mathrm{PC}(J)\times \mathrm{PC}(J)\). It is easily to verify that X is a Banach space with the norm \(\|(u,v)\|=\max \{\|u\|_{\mathrm{PC}}, \|v\|_{\mathrm{PC}}\}\), \((u,v)\in X\).

For the readers’ convenience, we introduce some necessary definitions and lemmas. These definitions and properties can be found in the literature.

Definition 2.1

([32, 33])

The Riemann–Liouville fractional integral of order \(\alpha >0\) of a continuous function \(f: (a,\infty )\rightarrow R\) is defined by

provided that the right-hand side is pointwise defined on \((a,\infty )\).

Definition 2.2

([33])

The Riemann–Liouville fractional derivative of order \(\alpha >0\) of a continuous function \(f: (a,\infty )\rightarrow R\) is defined by

where \(n-1<\alpha \leq n\), provided that the right-hand side is pointwise defined on \((a,\infty )\).

Definition 2.3

([32, 33])

If \(f\in C^{n}((a,\infty ),R)\) and \(\alpha >0\), then the Caputo fractional derivative of order α is defined as

where \(n-1<\alpha \leq n\), provided that the right-hand side is pointwise defined on \((a,\infty )\).

Lemma 2.1

([33])

If \(u\in C^{n}[0,1]\), and \(\delta >0\), then

where \(n=-[-\delta ]\) and \([-\delta ]\) denotes the integer part of the real number −δ.

Lemma 2.2

([32, 33])

If \(\alpha ,\beta >0\), \(t\in [a,b]\) and \(u(t)\in L[a,b]\), then

Lemma 2.3

(see [34], pp. 36–39)

Let \(\alpha >0 \) and suppose n denotes the smallest integer greater than or equal to α. Then the following assertions hold:

1. (i)

   If \(\lambda >-1\), \(\lambda \neq \alpha -i\), \(i=1, 2, \ldots , n+1\), then for \(t\in [a,b]\),

   $$\begin{aligned} {}^{\mathrm{LR}}D_{a^{+}}^{\alpha }(t-a)^{\lambda }= \frac{\varGamma (\lambda +1)}{ \varGamma (\lambda -\alpha +1)}(t-a)^{\lambda -\alpha }. \end{aligned}$$
2. (ii)

   \({}^{\mathrm{LR}}D_{a^{+}}^{\alpha }(t-a)^{\alpha -i}=0\), \(i=1, 2, \ldots , n\).

3. (iii)

   \({}^{\mathrm{LR}}D_{a^{+}}^{\beta }I_{a^{+}}^{\alpha }u(t)=I _{a^{+}}^{\alpha }u(t)\), for all \(t\in [a,b]\), \(\alpha \geq \beta \geq 0\).

Lemma 2.4

(Nonlinear Alternative Of Leray–Schauder [35])

Let X be a Banach space, C be a nonempty convex subset of X, Ω be an open subset of C with \(\theta \in {\varOmega }\). Suppose that \(T: \overline{ \varOmega }{\rightarrow }C\) is a completely continuous mapping. Then either

1. (i)

   the mapping T has a fixed point in Ω̅, or

2. (ii)

   there exists a \({u}\in \partial {\varOmega }\) and \(\lambda \in (0,1)\) with \(u=\lambda Tu\).

Lemma 2.5

Let \(h_{1}\in C(J)\). If \(\Delta _{1}\triangleq \frac{z^{1-\delta _{1}}}{ \varGamma (2-\delta _{1})}\neq 1\), then a function \(x\in \mathrm{PC}(J)\) is a solution of the boundary value problem

if and only if \(x\in \mathrm{PC}(J)\) is a solution of the integral equation

where

Proof

When \(t\in [0,t_{1}]\), from Lemma 2.1, we have

By \(x(0)=0\), we get \(u_{10}=0\). And it follows from (2.3) that

and

When \(t\in (t_{1},t_{2}]\), we similarly have

and

By (2.5), (2.8) and \({}^{C}D_{0^{+}}^{\gamma _{1}}x(t _{k}^{+})- {}^{C}D_{0^{+}}^{\gamma _{1}}x(t_{k}^{-})=J_{1k}(x(t_{k}))\), we obtain

In view of the continuity of x at \(t_{1}\), we have

When \(t\in (t_{k},t_{k+1}]\), \(k=2,3,\ldots ,n\), repeating the above calculation, we get

and

From (2.11) and (2.12), we have

Equations (2.9) and (2.12) give

Denoting \(t_{0}=0\), \(t_{n+1}=1\), and noticing \(0< z<1\), we know that there exists \(j\in \{0,1,\ldots ,n\}\) such that \(z\in (t_{j},t_{j+1}]\) and

Applying Lemmas 2.2–2.3 and (2.15), we obtain

Using \({}^{\mathrm{LR}}D_{0^{+}}^{\delta _{1}}x(z)=x(1)\), (2.12), (2.13), (2.14) and (2.16), we derive

Thus, for \((t_{k},t_{k+1}]\), \(k=0,1,2,\ldots ,n\), we have

Substituting (2.17) into (2.18), one can easily obtain (2.2). The proof is completed. □

Similarly, we conclude the following lemma.

Lemma 2.6

Let \(h_{2}\in \mathrm{PC}(J)\). If \(\Delta _{2}\triangleq \frac{w^{1-\delta _{2}}}{ \varGamma (2-\delta _{2})}\neq 1\), then a function \(y\in \mathrm{PC}(J)\) is a solution of the boundary value problem

if and only if \(y\in \mathrm{PC}(J)\) is a solution of the integral equation

where

In this section, we shall investigate the existence of solution for system (1.1) by employing the nonlinear alternative of Leray–Schauder.

Theorem 3.1

If the following conditions \((H_{1})\)–\((H_{6})\) hold, then the boundary value problem (1.1) has at least a pair of solutions. The conditions are:

\((H_{1})\) :

The functions \(f,g \in C(J\times R^{2},R)\), and \(J_{1k}, J_{2k}\in C(R,R)\), \(k=1,2,\ldots ,n\).

\((H_{2})\) :

For all \(u_{i},v_{i}\in R\) (\(i=1,2\)), \(t\in R\), there exist some constants \(L_{i}, \hat{L}_{i}>0\) (\(i=1,2\)) such that

$$\begin{aligned} & \bigl\vert f(t,u_{1},v_{1})-f(t,u_{2},v_{2}) \bigr\vert \leq L_{1} \vert u_{1}-u_{2} \vert +L_{2} \vert v _{1}-v_{2} \vert , \\ & \bigl\vert g(t,u_{1},v_{1})-g(t,u_{2},v_{2}) \bigr\vert \leq \hat{L}_{1} \vert u_{1}-u_{2} \vert + \hat{L}_{2} \vert v_{1}-v_{2} \vert . \end{aligned}$$

\((H_{3})\) :

\(N\triangleq \sup_{t\in [0,1]}|f(t,0,0)|\) and \(\hat{N}\triangleq \sup_{t\in [0,1]}|g(t,0,0)|\) all exist.

\((H_{4})\) :

\(0<\Delta _{1}=\frac{z^{1-\delta _{1}}}{\varGamma (2- \delta _{1})}<1\), \(0<\Delta _{2}=\frac{w^{1-\delta _{2}}}{\varGamma (2- \delta _{2})}<1\).

\((H_{5})\) :

For any \(u, v\in R\), there exist some constants \(M_{k}, \hat{M}_{k}>0\), \(k=1,2,\ldots ,n\), such that

$$\begin{aligned} \bigl\vert J_{1k}(u) \bigr\vert \leq M_{k} \vert u \vert , \qquad \bigl\vert J_{2k}(v) \bigr\vert \leq \hat{M}_{k} \vert v \vert . \end{aligned}$$

\((H_{6})\) :

\(\kappa _{1}\triangleq \mathcal{M}_{1}+\mathcal{N} _{1}<1\) and \(\kappa _{2}\triangleq \mathcal{M}_{2}+\mathcal{N}_{2}<1\), where

$$\begin{aligned} &\mathcal{M}_{1}=(L_{1}+L_{2}) \biggl( \frac{1}{\varGamma (\alpha +1)}+\frac{1}{(1- \Delta _{1})\varGamma (\alpha -\delta _{1}+1)} +\frac{1}{(1-\Delta _{1}) \varGamma (\alpha +1)} \biggr), \\ &\mathcal{N}_{1}=\frac{\varGamma (2-\gamma _{1})}{1-\Delta _{1}} \biggl(\frac{2}{t _{1}^{1-\gamma _{1}}}+ \frac{1}{z^{\delta _{1}}\varGamma (1-\delta _{1})}+2- \Delta _{1} \biggr) \sum _{i=1}^{n}M_{i}, \\ &\mathcal{M}_{2}=(\hat{L}_{1}+\hat{L}_{2}) \biggl(\frac{1}{\varGamma ( \beta +1)}+\frac{1}{(1-\Delta _{2})\varGamma (\beta -\delta _{2}+1)} +\frac{1}{(1- \Delta _{2})\varGamma (\beta +1)} \biggr), \\ &\mathcal{N}_{2}=\frac{\varGamma (2-\gamma _{2})}{1-\Delta _{2}} \biggl(\frac{2}{t _{1}^{1-\gamma _{2}}}+ \frac{1}{w^{\delta _{2}}\varGamma (1-\delta _{2})}+2- \Delta _{2} \biggr) \sum _{i=1}^{n}\hat{M}_{i}. \end{aligned}$$

Proof

Let \(\varOmega =\{(x,y)\in X: \|(x,y)\|< r\}\), where \(X=\mathrm{PC}(J)\times \mathrm{PC}(J)\) and \(r\geq \max \{\frac{N\mathcal{M}_{1}}{1-\kappa _{1}},\frac{ \hat{N}\mathcal{M}_{2}}{1-\kappa _{2}} \}\). Then \(\overline{\varOmega }=\{(x,y)\in X: \|(x,y)\|\leq r\}\), \(\partial \varOmega =\{(x,y)\in X: \|(x,y)\|=r\}\). According to Lemmas 2.5–2.6, we define the operator \(T:\overline{\varOmega }{\rightarrow }X\) as follows:

where

and

Thus, the existence of solution for system (1.1) is equivalent to the existence of a fixed point for the operator T defined by (3.1)–(3.5). Now we shall apply Lemma 2.4 to prove that T has a fixed point \((x^{*}(t),y^{*}(t))\in \overline{ \varOmega }\). Firstly, we need to show that \(T:\overline{\varOmega }{\rightarrow }X\) is completely continuous. In fact, for all \((x,y)\in \overline{ \varOmega }\), \(t\in J=[0,1]\), from conditions \((H_{1})\)–\((H_{5})\), we have

Similarly, we also have

Estimates (3.6) and (3.7) indicate that T is uniformly bounded and \(T(\overline{\varOmega })\subset \overline{\varOmega }\).

Next, we show that operator T is equicontinuous, that is, for any \(\epsilon >0\), \(\tau _{2},\tau _{1}\in J=[0,1]\), \((x,y)\in \overline{ \varOmega }\), there exists \(\delta =\delta (\epsilon )>0\) such that, when \(|\tau _{2}-\tau _{1}|<\delta \), we have \(\|T(x,y)(\tau _{2})-T(x,y)(\tau _{1})\|<\epsilon \). Indeed, for any \(\tau _{1},\tau _{2}\in [0,1]\), without loss of generality, let \(\tau _{1}<\tau _{2}\) and \(|\tau _{2}- \tau _{1}|<\xi \), where \(\xi =\min_{0\leq i\leq n}\{t_{i+1}-t_{i}\}\), \(t_{0}=0\), \(t_{n+1}=1\). Similar to (3.6), we have

where \(\tau _{1}<\eta <\tau _{2}\), \(\rho _{1}= (L_{1}r+L_{2}r+N ) (\frac{1}{\varGamma (\alpha )} +\frac{1}{(1-\Delta _{1})\varGamma ( \alpha -\delta _{1}+1)} +\frac{1}{(1-\Delta _{1})\varGamma (\alpha +1)} ) +\frac{r\varGamma (2-\gamma _{1})}{1-\Delta _{1}} (\frac{2}{t_{1} ^{1-\gamma _{1}}}+\frac{1}{z^{\delta _{1}}\varGamma (1-\delta _{1})}+1 ) \sum_{i=1}^{n}M_{i}\). Similar to (3.8), one has

where \(\rho _{2}= (\hat{L}_{1}r+\hat{L}_{2}r+\hat{N} ) (\frac{1}{ \varGamma (\beta )} + \frac{1}{(1-\Delta _{2})\varGamma (\beta -\delta _{2}+1)} +\frac{1}{(1- \Delta _{2})\varGamma (\beta +1)} ) +\frac{r\varGamma (2-\gamma _{2})}{1- \Delta _{2}} (\frac{2}{t_{1}^{1-\gamma _{2}}}+\frac{1}{w^{\delta _{2}} \varGamma (1-\delta _{2})}+1 ) \sum_{i=1}^{n}\hat{M}_{i}\).

Take \(\delta =\min \{\xi ,\frac{\epsilon }{\rho _{1}},\frac{\epsilon }{ \rho _{1}}\}\). According to (3.8) and (3.9), we conclude that, for any \(\epsilon >0\), \(\tau _{2},\tau _{1}\in J=[0,1]\), \((x,y)\in \overline{\varOmega }\), there exists \(\delta >0\) such that \(\|T(x,y)(\tau _{2})-T(x,y)(\tau _{1})\|<\epsilon \) if \(|\tau _{2}-\tau _{1}|<\delta \), namely, operator T is equicontinuous. Hence, by the Arzela–Ascoli theorem, we know that \(T:\overline{\varOmega }{\rightarrow }\overline{\varOmega }\) is completely continuous.

Finally, we prove that condition (ii) of Lemma 2.4 is not true. In fact, for all \((\overline{x}, \overline{y})\in \partial \varOmega \), \(0<\lambda <1\) and \(t\in [0,1]\), analogous to (3.6) and (3.7), we have

and

Estimates (3.10) and (3.11) imply that \(\|\lambda T( \overline{x},\overline{y})\|<\|(\overline{x},\overline{y})\|=r\), that is, \((\overline{x},\overline{y})\neq \lambda T(\overline{x}, \overline{y})\), for all \((\overline{x},\overline{y})\in \partial \varOmega \). According to Lemma 2.4, we know that the boundary value problem (1.1) has a pair of solutions \((x^{*},y^{*}) \in \overline{\varOmega }\). The proof is completed. □

Consider the following four-point boundary value problem for nonlinear fractional differential coupling system with fractional order impulses:

Take \(\alpha =\frac{5}{4}\), \(\beta =\frac{7}{4}\), \(p=\frac{1}{2}\), \(q=\frac{3}{4}\), \(\gamma _{1}=\frac{1}{3}\), \(\gamma _{2}=\frac{2}{3}\), \(\delta _{1}=\frac{1}{5}\), \(\delta _{2}=\frac{3}{5}\), \(n=2\), \(t_{1}= \frac{1}{6}\), \(t_{2}=\frac{5}{6}\), \(z=\frac{1}{7}\), \(w=\frac{4}{7}\), \(f(t,u,v)=\frac{\sin (\pi t)+u+v}{100}\), \(g(t,u,v)=\frac{e^{t}+\arctan (u^{2}+v^{2})}{100}\), \(J_{11}(u)=J_{22}(u)=\frac{u^{2}}{200}\), \(J_{12}(u)=J_{21}(u)=\frac{\sqrt[3]{u}}{100}\). Obviously, \(f,g\in C(J \times R^{2},R)\), \(J_{11}, J_{12}, J_{21}, J_{22}\in C(R,R)\). By a simple calculation, we have

that is, \(L_{1}=L_{2}=\hat{L}_{1}=\hat{L}_{2}=\frac{1}{100}\), \(M_{1}=\hat{M}_{2}=\frac{1}{100}\), \(M_{2}=\hat{M}_{1}=\frac{1}{300}\), \(N=\frac{1}{100}\), \(\hat{N}=\frac{e}{100}\). Therefore, we obtain

Thus, conditions \((H_{1})\)–\((H_{6})\) of Theorem 3.1 hold. Then (4.1) has at least a pair of solutions.

In describing some phenomena and processes of many fields such as physics, chemistry, aerodynamics, electrodynamics of a complex medium, polymer rheology, capacitor theory, electrical circuits, biology, control theory, fitting of experimental data, and so on, the fractional differential equation is better and more accurate than the integral-order differential equations. So the study of fractional differential equations has attracted the eyes of many scholars. Especially, the nonlocal boundary value problems have been widely studied by many researchers because of their extensive applications in, e.g., blood flow problems, chemical engineering, thermo-elasticity, underground water flow, population dynamics, and so forth. In this paper, we consider the nonlocal boundary value problem for a nonlinear fractional differential coupled system with fractional order impulses. We obtain some new sufficient criteria for the existence of solutions by use of the Leray–Schauder alternative theorem.

Acknowledgements

The authors thank the referees for a number of suggestions which have improved many aspects of this article.

Availability of data and materials

Not applicable.

This work was supported by the National Natural Sciences Foundation of Peoples Republic of China under Grant (Nos. 11161025, 11661047).

Authors and Affiliations

1. Department of Applied Mathematics, Kunming University of Science and Technology, Kunming, China

   Kaihong Zhao & Hui Huang

Contributions

The authors read and approved the final manuscript.

Corresponding author

Correspondence to Kaihong Zhao.

Competing interests

The authors declare to have no competing interests.

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