Existence of positive solution to a coupled system of singular fractional difference equations via fractional sum boundary value conditions

In this article, we study a coupled system of singular fractional difference equations with fractional sum boundary conditions. A sufficient condition of the existence of positive solutions is established by employing the upper and lower solutions of the system and using Schauder’s fixed point theorem. Finally, we provide an example to illustrate our results.

Fractional difference calculus is a powerful tool for studying problems in many fields such as biology, mechanics, control systems, ecology, electrical networks and other areas (see [1,2,3,4,5,6,7,8,9,10] and the references therein). Particularly, this calculus can be used to study stability of discrete fractional systems [11] and impulsive fractional difference equations [12]. Recently, fractional differences have been utilized in several research works such as a study of fuzzy fractional discrete-time diffusion equation [13], and a study of an image encryption technique based on the fractional chaotic maps [14]. The study of approximating solutions of fractional equations is an important topic in this area. Recently, many researchers presented the method to find approximating solutions of some fractional integro-differential equations (see [15,16,17,18,19,20]).

Basic definitions and properties of fractional difference calculus were presented by Goodrich and Peterson [21]. In addition, there are other research works dealing with fractional difference boundary value problems which have helped to build up some of the basic theory of this area (see [22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47] and references cited therein).

The boundary value problems for systems of fractional difference equations have been studied by some researchers; see [48,49,50,51,52,53] and references cited therein. For example, Pan et al. [48] proposed the system of fractional difference equations

for \(t \in \mathbb{N}_{0,b+1}:=\{0,1,2,\dots ,b+1\}\) where \(b \in \mathbb{N}_{0}\), with the difference boundary conditions

where \(1<\mu ,\nu \leq 2\), \(0<\beta \leq 1\), and \(f,g:\mathbb{R} \rightarrow \mathcal{R}\) are continuous functions.

Goodrich [51] studied the coupled system of fractional difference equations

for \(t \in \mathbb{N}_{0,b+1}\), with the nonlinearities satisfying no growth conditions

where \(1<\nu \leq 2\), \(1<\mu \leq 2\), \(\lambda _{1},\lambda _{2}>0\), and \(H_{1},H_{2}\) are continuous functions.

In this paper, we aim to study the coupled system of singular fractional difference equations

with fractional sum boundary conditions

where \(t\in \mathbb{N}_{0,T}:=\{0,1,\dots ,T\}\), \(0<\lambda _{i}<\frac{ \varGamma (\alpha _{i})}{(T+\alpha _{i})^{\underline{\alpha _{i}-1}} \sum_{s=0}^{T}(T+\theta _{i}+1-\sigma (s))^{\underline{\theta _{i}-1}}g_{i}(s+ \alpha _{1}-1)(s+\alpha _{i}-1)^{\underline{\alpha _{i}-1}}}\), \(\alpha _{i}\in (1, 2], \beta _{i},\theta _{i}\in (0,1]\), \(g_{i}\in C (\mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}, \mathbb{R}^{+} ) \) are given functions, \(F_{i}:\mathbb{N}_{\alpha _{1}-1,T+\alpha _{1}-1} \times \mathbb{N}_{\alpha _{2}-1,T+\alpha _{1}}\times (0,+\infty ) \times (0,+\infty ) \rightarrow [0,+\infty )\) are are continuous and may be singular at \(u_{i}=0\) and \(t=\alpha _{i}-2,T+\alpha _{i}\) where \(i=1,2\).

This paper is organized as follows. In the next section, we present some definitions and basic lemmas. In Sect. 3, we prove the existence of solutions of the boundary value problem (1.5)–(1.6) by employing the upper and lower solutions of the system and Schauder’s fixed point theorem. An example and application of our results are presented in the last section.

As the following, we provide some notations, definitions, and lemmas which are used in the main results.

Definition 2.1

The generalized falling function is defined by \(t^{\underline{\alpha }}:=\frac{\varGamma (t+1)}{\varGamma (t+1-\alpha )}\), for any t and α for which the right-hand side is defined. If \(t+1-\alpha \) is a pole of the Gamma function and \(t+1\) is not a pole, then \(t^{\underline{\alpha }}=0\).

Theorem 2.1

([22])

Assume the following factorial functions are well defined. If \(t\leq r\), then \(t^{\underline{\alpha }}\leq r^{\underline{\alpha }}\) for any \(\alpha >0\).

Definition 2.2

For \(\alpha >0\) and f defined on \(\mathbb{N}_{a}\), the α-order fractional sum of f is defined by

where \(t\in \mathbb{N}_{a+\alpha }\) and \(\sigma (s)=s+1\).

Definition 2.3

For \(\alpha >0\) and f defined on \(\mathbb{N}_{a}\), the α-order Riemann–Liouville fractional difference of f is defined by

where \(t \in \mathbb{N}_{a+N-\alpha }\) and \(N \in \mathbb{N}\) is chosen so that \(0\leq {N-1}<\alpha \leq N\).

Theorem 2.2

([22])

Let \(0\leq N-1<\alpha \leq N\). Then

for some \(C_{i}\in \mathbb{R}\), with \(1\leq i\leq N\).

We next propose a lemma dealing with a solution of a linear variant of the boundary value problem (1.5).

Lemma 2.1

For \(i,j\in \{1,2\}\) and \(i\neq j\), let \(0<\varLambda <1, \mathcal{P}(h _{1},h_{2}),\mathcal{Q}(h_{1},h_{2})\geq \varLambda \), \(0<\lambda _{i}<\frac{ \varGamma (\alpha _{i})}{(T+\alpha _{i})^{\underline{\alpha _{i}-1}} \sum_{s=0}^{T}(T+\theta _{i}+1-\sigma (s))^{\underline{\theta _{i}-1}}g_{i}(s+ \alpha _{1}-1)(s+\alpha _{i}-1)^{\underline{\alpha _{i}-1}}}\), \(\alpha _{i}\in (1, 2], \theta _{i}\in (0, 1]\) be given constants, \(h_{i}\in C (\mathbb{N}_{\alpha _{i}-1,T+\alpha _{i}-1}, \mathbb{R} )\), \(g_{i}\in C (\mathbb{N}_{\alpha _{i}-2,T+ \alpha _{i}}, \mathbb{R}^{+} )\) given functions, and let \(\phi _{i}(u_{1},u_{2})\) be given functionals. The problem

has the unique solution

where

Proof

For \(i,j\in \{1,2\}\) where \(i\neq j\), using Lemma 2.2 and the fractional sum of order \(\alpha \in (1,2]\) for (2.1), we obtain

for \(t\in \mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}\). Using the boundary condition (2.2), this implies that

Then, we have

Taking the fractional sum of order \(0<\theta _{i}\leq 1\) for (2.11), we obtain

for \(t\in \mathbb{N}_{\alpha _{i}+\theta _{i}-2,T+\alpha _{i}+\theta _{i}}\). From the boundary condition (2.3), we find that

and

After solving the system of equations (2.13) and (2.14), we have

and

where \(\varLambda ,{\mathcal{P}(h_{1},h_{2})}\) and \({\mathcal{Q}(h_{1},h _{2})}\) are defined in (2.6)–(2.8), respectively.

Finally, substituting \(C_{11}\) and \(C_{12}\) into (2.11), we obtain (2.4) and (2.5). The proof of this lemma is complete. □

Corollary 2.1

Problem (2.1)–(2.3) has the unique solution which is of the from

for \(t_{i}\in \mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}\), where

with

and

Lemma 2.2

For \(i,j\in \{1,2\}\), \(i\neq j\) and letting \(0<\varLambda <1\), \(\mathcal{P}(h_{1},h_{2}),\mathcal{Q}(h_{1},h_{2})\geq \varLambda \), \(0<\lambda _{i}<\frac{\varGamma (\alpha _{i})}{(T+\alpha _{i})^{\underline{ \alpha _{i}-1}} \sum_{s=0}^{T}(T+\theta _{i}+1-\sigma (s))^{\underline{ \theta _{i}-1}}g_{i}(s+\alpha _{1}-1)(s+\alpha _{i}-1)^{\underline{\alpha _{i}-1}}}\), the Green’s functions are defined by (2.18)–(2.20) and satisfy:

\((X1)\) :

\(G_{i1}(t_{i}),G_{i2}(t_{i}) > 0\) for all \(t_{i}\in \mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}\);

\((X2)\) :

There exist two constants \(\omega _{i1},\omega _{i2}\) such that for all \((t_{i},s)\in \mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}\times \mathbb{N}_{0,T}\),

$$\begin{aligned} &\frac{t_{i}^{\underline{\alpha _{i}-1}}}{\varLambda }\sum_{\xi =0}^{T} \mathcal{H}_{ii}(\xi +\alpha _{i}-1,s) \leq G_{ii}(t_{i},s)\leq \omega _{ii} t_{i}^{\underline{\alpha _{i}-1}}, \end{aligned}$$

(2.29)

$$\begin{aligned} &\frac{t_{1}^{\underline{\alpha _{1}-1}}\lambda _{2}\varGamma (\alpha _{2})}{ \varLambda } \leq G_{12}(t_{1},s)\leq \omega _{12} t_{1}^{\underline{ \alpha _{1}-1}}, \end{aligned}$$

(2.30)

$$\begin{aligned} &\frac{t_{2}^{\underline{\alpha _{2}-1}}(T+\alpha _{2})^{\underline{ \alpha _{2}-1}}}{\varLambda } \leq G_{21}(t_{2},s)\leq \omega _{21} t _{2}^{\underline{\alpha _{2}-1}}; \end{aligned}$$

(2.31)

\((X3)\) :

\(u_{i}(t_{i}) \geq 0\) for all \(t_{i}\in \mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}\).

Proof

\((X1)\) is obvious. Here we only prove \((X2)\)–\((X3)\).

Since \(0<\varLambda <1\) and from the fact that \(\mathcal{H}_{i1}(\xi + \alpha _{1}-1,s),\mathcal{H}_{i2}(\xi +\alpha _{2}-1,s) \geq 0\) for all \((t_{i},s)\in \mathbb{N}_{\alpha _{i}-2,T+\alpha _{1}}\times \mathbb{N} _{0,T}\), we have

By the definition of \(\mathcal{K}_{i}(t_{i},s)\), we find that

Letting

we obtain, for all \((t_{i},s)\in \mathbb{N}_{\alpha _{i}-2,T+\alpha _{1}}\times \mathbb{N}_{0,T}\),

Consequently, by (2.32)–(2.34) and (2.41), this implies that \((X2)\) holds.

Next, we claim that \((X3)\) holds. By (2.4)–(2.5) with the conditions \(0<\varLambda <1\), \(\mathcal{P}(h_{1},h_{2}), \mathcal{Q}(h _{1},h_{2})\geq \varLambda \) and \(0<\lambda _{i}<\frac{\varGamma (\alpha _{i})}{(T+\alpha _{i})^{\underline{\alpha _{i}-1}} \sum_{s=0}^{T}(T+ \theta _{i}+1-\sigma (s))^{\underline{\theta _{i}-1}}g_{i}(s+\alpha _{1}-1)(s+ \alpha _{i}-1)^{\underline{\alpha _{i}-1}}}\), we have

and

so \((X3)\) holds. The proof is complete. □

The following theorems [54] are provided to study the existence of positive solution to the boundary value problem (1.5) in the next section.

Theorem 2.3

(Arzelá–Ascoli theorem)

A set of functions in \(C[a,b]\) with the sup norm is relatively compact if and only it is uniformly bounded and equicontinuous on \([a,b]\).

Theorem 2.4

If a set is closed and relatively compact, then it is compact.

Theorem 2.5

(Schauder’s fixed point theorem)

Let T be a continuous and compact mapping of a Banach space E into itself such that the set

is bounded. Then T has a fixed point.

In this section, we aim to establish the existence result for problem (1.5)–(1.6). For each \(i,j \in \{1,2\}\) where \(i\neq j\), we let \(E_{i}:C ( \mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}, \mathbb{R} )\) be the Banach space for all functions on \(\mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}\).

Therefore, the product space \(\mathcal{C}=E_{1}\times E_{2}\) is a Banach space. We consider the spaces

for \(t_{i}\in \mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}\), and define the norm by

where

Let \({\mathcal{U}}=\mathcal{C}_{1}\cap \mathcal{C}_{2}\). Obviously, the space \(( {\mathcal{U}},\|(u_{1},u_{2})\|_{\mathcal{U}} )\) is also a Banach space with the norm

A positive solution of problem (1.5)–(1.6) is a pair of functions \((x_{1},x_{2})\in \mathcal{U}\) satisfying (1.5)–(1.6) with \(x_{i}(t_{i}) \geq 0\) for all \(t_{i}\in \mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}\) and \((x_{1},x_{2}) \neq (0,0)\).

From Lemmas 2.1 and 2.2, we obtain the following lemma.

Lemma 3.1

For \(t_{i}\in {\mathbb{N}}_{\alpha _{i}-2,T+\alpha _{i}}\), \(i,j\in \{1,2 \}\) and \(i \neq j\). If \((u_{1},u_{2} )\in \mathcal{U}\) satisfy

1. (i)

   \(u_{i}(\alpha _{i}-2)=0, u_{i}(T+\alpha _{i})=\lambda _{j} \Delta ^{-\theta _{j}}g_{j}(T+\alpha _{j}+\theta _{j})u_{j}(T+\alpha _{j}+ \theta _{j})\);

2. (ii)

   \(\Delta ^{\alpha _{i}}u_{i}(t_{i})\leq 0\) for all \(t_{i}\in \mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}\).

Then \(u_{i}(t_{i})\geq 0\).

In what follows, we give the definitions of the lower and upper solution of problem (1.5)–(1.6).

Definition 3.1

A pair of functions \((\chi _{1}^{*}(t_{1}),\chi _{2}^{*}(t_{2}) )\in \mathcal{U}\) is called a lower solution of problem (1.5)–(1.6) if it satisfies

Definition 3.2

A pair of functions \((\bar{\chi }_{1}^{*}(t_{1}),\bar{\chi }_{2} ^{*}(t_{2}) )\in \mathcal{U}\) is called an upper solution of problem (1.5)–(1.6), if it satisfies

The following assumptions are set throughout this paper: for \(i,j\in \{1,2\}\) and \(i\neq j\),

\((H1)\) :

\(0<\varLambda <1\) and \(\sum_{\xi =0}^{T}{\mathcal{H}}_{i,j}( \xi +\alpha _{i}-1,s)\geq 0\) for all \(s \in \mathbb{N}_{0,T}\).

\((H2)\) :

\(F_{i}\in C ( \mathbb{N}_{\alpha _{1}-1,T+\alpha _{1}-1} \times \mathbb{N}_{\alpha _{2}-1,T+\alpha _{2}-1}\times (0,+\infty ) \times (0,+\infty ),[0,+\infty ) )\) are decreasing in third and fourth variables, and

$$ F_{i} \bigl(t_{i},t_{j},t_{i}^{\underline{\alpha _{i}-1}},t_{j}^{\underline{ \alpha _{j}-1}} \bigr)\in l^{1}. $$

\((H3)\) :

For all \(\ell \in (0,1)\), there exist constants \(0<\rho _{i}<1\) such that, for any \((t_{1},t_{2},v_{1},v_{2})\in \mathbb{N}_{\alpha _{1}-1,T+ \alpha _{1}-1}\times \mathbb{N}_{\alpha _{2}-1,T+\alpha _{2}-1}\times (0,+ \infty ) \times (0,+\infty )\),

$$ F_{i} (t_{1},t_{2},\ell v_{1},\ell v_{2} )\leq \ell ^{-\rho _{i}} F_{i} (t_{1},t_{2},v_{1},v_{2} ). $$

\((H4)\) :

\(\varsigma _{i}\leq g_{i}(t_{i}) \leq {\mathcal{G}}_{i} \) for all \(t_{i}\in \mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}\).

Remark

Conditions \((H2)\)–\((H3)\) imply that \(F_{i}\) have a power singularity at \(u_{i}=0\) for \(i=1,2\).

Theorem 3.1

Suppose that \((H{1})\)–\((H4)\) hold. Then problem (1.5)–(1.6) has at least one positive solution \((u_{1}^{*},u_{2}^{*} )\), which satisfies

where \({\mathcal{G}}:= \max \lbrace {\mathcal{G}}_{1}, {\mathcal{G}}_{2} \rbrace , \varsigma:=\max \lbrace \varsigma _{1},\varsigma _{2} \rbrace , {\mathcal{L}}^{\rho }:=\max \lbrace {\mathcal{L}}_{1}^{\rho _{1}},{\mathcal{L}}_{2}^{\rho _{2}} \rbrace \),

with

and \(\omega _{i,j}, {\mathcal{H}}_{i,j}, i,j=1,2 \) are defined in the previous section. In particular, if \({\mathcal{L}}=1\), then \((t_{1}^{\underline{\alpha _{1}-1}},t_{2}^{ \underline{\alpha _{2}-1}} ) \) is a positive solution of problem (1.5)–(1.6).

Proof

Define the cone

and the operator \(\mathcal{T}:{\mathcal{U}}\times {\mathcal{U}}\rightarrow {\mathcal{U}}\) by

for all \((u_{1},u_{2})\in \mathcal{P}\) and

where \(G_{i1}(t_{i},s)\) and \(G_{i2}(t_{i},s)\) are defined in (2.17)–(2.20).

Firstly, we claim that \(\mathcal{T}\) is well defined and \(\mathcal{T}( \mathcal{P})\subset \mathcal{P}\). By Lemma 2.1 and \((H1)\)–\((H4)\), we obtain

On the other hand, we have

and

Next, taking the fractional difference of order \(0<\beta _{i}\leq 1\) for (3.4), we have

By the same arguments as before and since \(\Delta ^{\beta _{i}}{\mathcal{K} _{i}}(t_{i},s)\leq {\mathcal{K}_{i}}(t_{i},s)\), we obtain

and

On the other hand, we have

and

Thus it follows from (2.5)–(2.7) and (2.9)–(2.12) that \(\mathcal{T}\) is well defined and \(\mathcal{T}(\mathcal{P})\subset \mathcal{P}\).

Furthermore, by Lemma 2.2, we obtain

We let

Since \(( t_{1}^{\underline{\alpha _{1}-1}},t_{2}^{\underline{ \alpha _{2}-1}} ), ({\mathcal{T}}_{1} ( t_{1}^{\underline{ \alpha _{1}-1}},t_{2}^{\underline{\alpha _{2}-1}} ),{\mathcal{T}} _{2} ( t_{1}^{\underline{\alpha _{1}-1}},t_{2}^{\underline{\alpha _{2}-1}} ) )\in {\mathcal{P}}\), we have

Let

Then, by (3.14)–(3.17) and \((H3)\), we obtain

So, it follows from (3.13) and (3.16)–(3.19) that

and

Thus, it follows from (3.18)–(3.21) that \((\bar{\chi }_{1}^{*},\bar{\chi }_{2}^{*} ), ( \chi _{1}^{*},\chi _{2}^{*} )\) are lower and upper solutions of problem (1.5)–(1.6), and \((\bar{\chi }_{1}^{*},\bar{ \chi }_{2}^{*} ), ( \chi _{1}^{*},\chi _{2}^{*} ) \in {\mathcal{P}}\).

Define the function \(\mathcal{F}^{*}_{i}\) and the operator \(\mathcal{T}^{*}\) in \(\mathcal{U}\) by

where

It follows from the assumption that \(\mathcal{F}^{*}_{i}:{\mathbb{N}} _{\alpha _{1}-1,T+\alpha _{1}-1}\times {\mathbb{N}}_{\alpha _{2}-1,T+ \alpha _{2}-1}\times [0,\infty )\times [0,\infty )\rightarrow [0, \infty )\) are continuous. Consider the following problem:

For \(i,j\in \{1,2\}, i\neq j\) and for all \((u_{1},u_{2} ) \in \mathcal{U}\), by (3.22) we obtain

By the same argument, we obtain \(\vert \Delta ^{\beta _{i}}{\mathcal{T}} _{i}^{*} (u_{1},u_{2} )(t_{1},t_{2}) \vert \leq (T+ \alpha _{i})^{\underline{\alpha _{i}-1}}{\mathcal{G}}{\mathcal{L}}\).

Thus,

Consequently, we have

which implies that \({\mathcal{T}}^{*}\) is uniformly bounded. Moreover, it follows from the continuity of \({\mathcal{F}}^{*}_{i}\) and the uniform continuity of \(G_{i1}(t_{i},s),G_{i2}(t_{i},s) \) and \((H2)\) that \(\mathcal{T}^{*}:{\mathcal{U}}\times {\mathcal{U}}\rightarrow {\mathcal{U}}\) is continuous.

Let \({\mathcal{E}}\subset {\mathcal{U}}\times {\mathcal{U}}\) be bounded. By the Arzelá–Ascoli theorem and Theorem 2.4, we easily know that \({\mathcal{T}^{*}}({\mathcal{E}})\) is equicontinuous. Therefore \({\mathcal{T}^{*}}\) is completely continuous. Hence, by using Schauder’s fixed point theorem, \({\mathcal{T}^{*}}\) has at least one fixed point \(( u_{1}^{*},u_{2}^{*} )\) such that \(( u_{1}^{*},u _{2}^{*} )={\mathcal{T}^{*}} ( u_{1}^{*},u_{2}^{*} )\).

Next, we will show that

Firstly, we will prove that \(( u_{1}^{*},u_{2}^{*} ) \leq ( \chi _{1}^{*},\chi _{2}^{*} )\). Suppose \(( u _{1}^{*},u_{2}^{*} ) > ( \chi _{1}^{*},\chi _{2}^{*} )\). According to the definition of \({\mathcal{F}^{*}_{i}}\), we have

On the other hand, since \(( \chi _{1}^{*},\chi _{2}^{*} )\) is an upper solution of problem (1.5), we have

Letting \(z_{i}(t_{i})=\chi _{i}^{*}(t_{i})-u_{i}^{*}(t_{i})\), and from (3.28)–(3.29), it implies that

Furthermore, since \(( \chi _{1}^{*},\chi _{2}^{*} )\) is an upper solution of problem (1.5) and \(( u_{1}^{*},u_{2} ^{*} ) \) is a fixed point of \({\mathcal{T}^{*}}\), we have

By Lemma 3.1, we have

So, \(( u_{1}^{*}(t_{1}),u_{2}^{*}(t_{2}) )\leq ( \chi _{1}^{*}(t_{1}),\chi _{2}^{*}(t_{2}) )\) for all \(t_{i} \in {\mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}}\), which contradicts \(( u_{1}^{*},u_{2}^{*} )> ( \chi _{1}^{*},\chi _{2} ^{*} )\). Therefore we have \(( u_{1}^{*},u_{2}^{*} ) \leq ( \chi _{1}^{*},\chi _{2}^{*} )\) for all \(t_{i} \in {\mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}}\).

In the same argument, we have \(( u_{1}^{*}(t_{1}),u_{2}^{*}(t _{2}) )\geq ( \bar{\chi }_{1}^{*}(t_{1}),\bar{\chi }_{2} ^{*}(t_{2}) )\) for all \(t_{i} \in {\mathbb{N}_{\alpha _{i}-2,T+ \alpha _{i}}}\).

Thus (3.27) holds. Hence \(( u_{1}^{*}(t_{1}),u_{2}^{*}(t _{2}) )\) is a positive solution of problem (1.5)–(1.6). From \(( (\bar{\chi }_{1} ^{*},\bar{\chi }_{2}^{*} ), ( \chi _{1}^{*},\chi _{2}^{*} ) )\in {\mathcal{P}}\) and (3.27), we obtain

This completes the proof. □

In this section, in order to illustrate our result, we consider the coupled system of singular fractional difference equations with fractional sum boundary conditions

where \(a_{i},b_{i},x_{i},y_{i}>0\), \(0< x_{i}+\frac{1}{3}a_{i}<1, 0<y _{i}+\frac{1}{2}b_{i}<1, i=1,2\), and, for \(t_{1}\in {\mathbb{N}}_{- \frac{2}{3},\frac{34}{3}}, t_{2}\in {\mathbb{N}}_{-\frac{1}{2}, \frac{23}{2}}\),

Here \(\alpha _{1}=\frac{4}{3}, \alpha _{2}=\frac{3}{2}, \beta _{1}= \frac{1}{2}, \beta _{2}=\frac{1}{3}, \theta _{1}=\frac{2}{3}, \theta _{2}=\frac{3}{4}, T=10\). We can find that

Clearly, \(\sum_{\xi =0}^{T}={\mathcal{H}}_{ij}(\xi +\alpha _{i}-1,s) \geq 0\) for all \(s\in {\mathbb{N}}_{0,10}\). So, \((H{1})\) holds.

For \(t_{1}\in {\mathbb{N}}_{-\frac{2}{3},\frac{34}{3}}, t_{2}\in {\mathbb{N}}_{-\frac{1}{2},\frac{23}{2}}\), we obtain that \(F_{1},F _{2}\) are decreasing in \(u_{i},\Delta ^{\alpha _{i}}u_{i}\), and

Therefore, \((H{2})\) holds.

For all \(\ell \in (0,1)\) and \((t_{1},t_{2},v_{1},v_{2})\in {\mathbb{N}} _{-\frac{2}{3},\frac{34}{3}}\times {\mathbb{N}}_{-\frac{1}{2}, \frac{23}{2}}\times (0,\infty ) \times (0,\infty )\), we have

Thus, \((H{3})\) holds. Also, \((H{4})\) holds for all \(t_{i}\in \mathbb{N}_{\alpha _{i}-2,T+\alpha _{i}}\) where

Hence, by Theorem 3.1, this problem has at least one positive solution \((u_{1}^{*},u_{2}^{*})\).

For a numerical example to show the existence of a positive solution, we give

We can find that \(\lambda _{1}=2.1, \lambda _{2}=3.8, \varLambda =0.041\), \({\mathcal{P}(F_{1},F_{2})}=6.697 \) and \({\mathcal{Q}(F_{1},F_{2})}=0.054\), then we have

for \(t_{1}\in {\mathbb{N}}_{-\frac{2}{3},\frac{34}{3}}, t_{2}\in {\mathbb{N}}_{-\frac{1}{2},\frac{23}{2}}\). Therefore, we obtain

In Fig. 1, the graphs of solutions \(u_{1}\) and \(u_{2}\) are plotted in a two-dimensional space.

The graph of \(u_{1}(t_{1})\) where \(t_{1}\in {\mathbb{N}} _{\frac{1}{3},\frac{34}{3}} \) and \(u_{2}(t_{2})\) where \(t_{2}\in {\mathbb{N}}_{\frac{1}{2},\frac{23}{2}}\)

Full size image

Not applicable.

This research was funded by King Mongkut’s University of Technology North Bangkok. Contract No. KMUTNB-ART-60-39. The last author would also like to thank Suan Dusit University for the support.

Authors and Affiliations

1. Department of Mathematics, Faculty of Applied Science, King Mongkut’s University of Technology North Bangkok, Bangkok, Thailand

   Chanon Promsakon & Saowaluck Chasreechai

2. Mathematics Department, Faculty of Science and Technology, Suan Dusit University, Bangkok, Thailand

   Thanin Sitthiwirattham

Contributions

The authors declare that they carried out all the work in this manuscript and read and approved the final manuscript.

Corresponding author

Correspondence to Thanin Sitthiwirattham.

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The authors declare that they have no competing interests.

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