Positive solutions for boundary value problems of fractional difference equations depending on parameters

We use the Krasnosel’skii fixed point theorem to obtain the sufficient conditions of the existence of two positive solutions for the boundary value problem of fractional difference equations depending on parameters.

MSC:26A33, 39A05, 39A12.

In this paper, we consider the boundary value problems of fractional difference equations depending on parameters of the form

where $t\in {[0,b]}_{{\mathbb{N}}_0}:=\{0,1,\dots ,b\}$, ${\lambda }_j>0$, $1<{\nu }_j⩽2$, $f_j:[0,+\mathrm{\infty })\times \cdots \times [0,+\mathrm{\infty })\to [0,+\mathrm{\infty })$ are continuous functions. For each j, we have that ${\psi }_j,{\varphi }_j:{\mathbb{R}}^{b+3}\to \mathbb{R}$ ($j=1,2,\dots ,n$) are given functions. We point out that fractional difference equations have been extensively studied in recent years. Systems of discrete fractional boundary value problems are also popular. In [1], the authors discussed the existence of positive solutions for coupled systems of nonlinear fractional difference equations:

where $\eta \in \{1,\dots ,N-1\}$, $n\in \{1,\dots ,N-1\}$, $N⩾4$, $\alpha ,\beta ,\lambda ,\mu >0$. In [2], Goodrich studied the following pair of discrete fractional boundary value problems:

where $t\in {[0,b]}_{{\mathbb{N}}_0}:=\{0,1,\dots ,b\}$, ${\lambda }_1,{\lambda }_2>0$, ${\nu }_1,{\nu }_2\in (1,2]$, it is the same as [1] when ${\nu }_1,{\nu }_2=2$. Goodrich obtained the existence of at least one positive solution to this problem by means of the Krasnosel’skii theorem for cones. We shall deduce the existence of at least two positive solutions to problem (1.1)-(1.2) in this paper. These results extend the results of [2].

The paper is organized as follows. In Section 2, we present basic definitions and demonstrate some lemmas in order to prove our main results. In Section 3, we establish some results for the existence of at least two solutions to problem (1.1)-(1.2), and we present an example to illustrate our main results.

For the convenience of the reader, we give some definitions and fundamental facts of the discrete fractional calculus, which can be found in [3–6] and their references.

Definition 2.1 [3]

We define

for any t and ν, for which the right-hand side is defined. We also appeal to the convention that if $t+1-\nu$ is a pole of the gamma function and $t+1$ is not a pole, then $t^{(\nu )}=0$.

Definition 2.2 [3]

The ν th fractional sum of a function f defined on the set ${\mathbb{N}}_a:=\{a,a+1,\dots \}$, for $\nu >0$, is defined to be

where $t\in \{a+\nu ,a+\nu +1,\dots \}=:{\mathbb{N}}_{a+\nu }$. We also define the ν th fractional difference for $\nu >0$ by

where $t\in {\mathbb{N}}_{a+\nu }$ and $0⩽N-1<\nu ⩽N$.

Lemma 2.3 [3]

Let t and ν be any numbers for which $t^{(\nu )}$ and $t^{(\nu -1)}$ are defined. Then

Lemma 2.4 [2]

Let $0⩽N-1<\nu ⩽N$. Then

for some $c_i\in R$, with $1⩽i⩽N$.

Lemma 2.5 [3]

Let $1<\nu ⩽2$ and $h:{[\nu -1,\nu +b-1]}_{{\mathbb{N}}_{\nu -1}}\to \mathbb{R}$ be given. The unique solution of the FBVP

is given by

where $G:{[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}\times {[0,b]}_{{\mathbb{N}}_0}\to R$ is defined by

Lemma 2.6 [2]

The Green’s function $G(t,s)$ given in Lemma  2.5 satisfies:

1. (i)

   $G(t,s)⩾0$ for each $(t,s)\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}\times {[0,b]}_{{\mathbb{N}}_0}$;

2. (ii)

   ${max}_{t\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}}G(t,s)=G(s+\nu -1,s)$ for each $s\in {[0,b]}_{{\mathbb{N}}_0}$;

3. (iii)

   there exists a number $\gamma \in (0,1)$ such that

   $$\underset{\frac{\nu +b}{4}⩽t⩽\frac{3(\nu +b)}{4}}{min}G(t,s)⩾\gamma \underset{t\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}}{max}G(t,s)=\gamma G(s+\nu -1,s)$$

for $s\in {[0,b]}_{{\mathbb{N}}_0}$.

First of all, we let ${\mathcal{B}}_j$ represent the Banach space of all maps from ${[{\nu }_j-2,\dots ,{\nu }_j+b]}_{{\mathbb{N}}_{{\nu }_j-2}}$ into ℝ when equipped with the usual maximum norm $\parallel \cdot \parallel$. Then, we put $\chi :={\mathcal{B}}_1\times {\mathcal{B}}_2\times \cdots \times {\mathcal{B}}_n$. By equipping χ with the norm

it follows that $(\chi ,\parallel \cdot \parallel )$ is a Banach space.

Now consider the operator $S:\chi \to \chi$ defined by

where we define $S_j:\chi \to {\mathcal{B}}_j$ by

where

Theorem 2.7 Let $f_j:[0,+\mathrm{\infty })\times \cdots \times [0,+\mathrm{\infty })\to [0,+\mathrm{\infty })$ and ${\varphi }_j,{\psi }_j\in C({[{\nu }_j-2,{\nu }_j+b]}_{{\mathbb{N}}_{{\nu }_j-2}},\mathbb{R})$ be given for $j=1,\dots ,n$, where $C({[{\nu }_j-2,{\nu }_j+b]}_{{\mathbb{N}}_{{\nu }_j-2}},\mathbb{R})$ stands for the continuous functions on ${[{\nu }_j-2,{\nu }_j+b]}_{{\mathbb{N}}_{{\nu }_j-2}}$. Then $y(t)=(y_1,\dots ,y_n)\in \chi$ is a solution of discrete FBVP (1.1)-(1.2) if and only if $y(t)$ is a fixed point of S.

Proof From Lemma 2.4, we find that a general solution to problem (1.1)-(1.2) is

From boundary condition (1.2), we get

so

On the other hand, applying boundary condition (1.2) to $y_j(t)$ implies that

so

Finally, we can get that

The opposite direction is obvious, so it is omitted. Consequently, we get that $y_j(t)$ is a solution of (1.1)-(1.2) if and only if $(y_1,\dots ,y_n)\in \chi$ is a fixed point of S, as desired. □

Lemma 2.8 The function ${\alpha }_j(t_j)$ is strictly decreasing in $t_j$ for $t_j\in {[{\nu }_j-2,{\nu }_j+b]}_{{\mathbb{N}}_{{\nu }_j-2}}$. In addition,

On the other hand, the function ${\beta }_j(t_j)$ is strictly increasing in $t_j$ for $t_j\in {[{\nu }_j-2,{\nu }_j+b]}_{{\mathbb{N}}_{{\nu }_j-2}}$. In addition,

Proof Note that for every $t_j\in {[{\nu }_j-2,{\nu }_j+b]}_{{\mathbb{N}}_{{\nu }_j-2}}$,

So, the first claim about ${\alpha }_j(t_j)$ holds. On the other hand,

It follows that

It may be shown in a similar way that ${\beta }_j(t)$ satisfies the properties given in the statement of this lemma. We omit the details. □

Corollary 1 Let $I_j=[\frac{b+{\nu }_j}{4},\frac{3(b+{\nu }_j)}{4}]$. There are constants $M_{{\alpha }_j},M_{{\beta }_j}\in (0,1)$ such that ${min}_{t_j\in I_j}{\alpha }_j(t_j)=M_{{\alpha }_j}\parallel {\alpha }_j\parallel$, ${min}_{t_j\in I_j}{\beta }_j(t_j)=M_{{\beta }_j}\parallel {\beta }_j\parallel$ for $j=1,2,\dots ,n$, where $\parallel \cdot \parallel$ is the usual maximum norm.

Theorem 2.9 [7]

Let ℬ be a Banach space, and let $P\subseteq \mathcal{B}$ be a cone in ℬ. Assume that $S_1$ and $S_2$ are open subsets of ℬ with $0\in S_1\subset {\overline{S}}_1\subset S_2$. Assume, further, that

is a completely continuous operator. If either

1. (1)

   $\parallel Tu\parallel ⩽\parallel u\parallel$, $u\in P\cap \partial S_1$, $\parallel Tu\parallel ⩾\parallel u\parallel$, $u\in P\cap \partial S_2$; or

2. (2)

   $\parallel Tu\parallel ⩾\parallel u\parallel$, $u\in P\cap \partial S_1$, $\parallel Tu\parallel ⩽\parallel u\parallel$, $u\in P\cap \partial S_2$.

Then T has a fixed point in $P\cap ({\overline{S}}_2\setminus S_1)$.

In this section, we present the theorems for the existence of at least two positive solutions to problem (1.1)-(1.2). In the sequel, we let

We now present the conditions that we presume in the sequel.

(L₁) ${lim}_{(y_1+\cdots +y_n)\to 0^{+}}\frac{f_j(y_1,\dots ,y_n)}{y_1+\cdots +y_n}=\mathrm{\infty }$ for $t_j\in {[{\nu }_j-2,{\nu }_j+b]}_{{\mathbb{N}}_{{\nu }_j-2}}$, $j=1,2,\dots ,n$.

(L₂) ${lim}_{(y_1+\cdots +y_n)\to \mathrm{\infty }}\frac{f_j(y_1,\dots ,y_n)}{y_1+\cdots +y_n}=\mathrm{\infty }$ for $t_j\in {[{\nu }_j-2,{\nu }_j+b]}_{{\mathbb{N}}_{{\nu }_j-2}}$, $j=1,2,\dots ,n$.

(L₃) ${lim}_{(y_1+\cdots +y_n)\to 0^{+}}\frac{f_j(y_1,\dots ,y_n)}{y_1+\cdots +y_n}=0$ for $t_j\in {[{\nu }_j-2,{\nu }_j+b]}_{{\mathbb{N}}_{{\nu }_j-2}}$, $j=1,2,\dots ,n$.

(L₄) ${lim}_{(y_1+\cdots +y_n)\to \mathrm{\infty }}\frac{f_j(y_1,\dots ,y_n)}{y_1+\cdots +y_n}=0$ for $t_j\in {[{\nu }_j-2,{\nu }_j+b]}_{{\mathbb{N}}_{{\nu }_j-2}}$, $j=1,2,\dots ,n$.

(G₁) The functionals ${\psi }_j$, ${\varphi }_j$ are linear. In particular, we assume that

for $c_{i-{\nu }_j+2}^j,d_{k-{\nu }_j+2}^j\in \mathbb{R}$, $j=1,\dots ,n$.

(G₂) For $j=1,2,\dots ,n$, there are

for each $s\in {[0,b]}_{{\mathbb{N}}_0}$, and in addition

(G₃) We have that each of ${\psi }_j({\alpha }_j)$, ${\psi }_j({\beta }_j)$, ${\varphi }_j({\alpha }_j)$, and ${\varphi }_j({\beta }_j)$ is nonnegative for $j=1,\dots ,n$.

Let $I:=[\frac{{\nu }_1+b}{4},\frac{3({\nu }_1+b)}{4}]\times \cdots \times [\frac{{\nu }_n+b}{4},\frac{3({\nu }_n+b)}{4}]$. In the sequel, we shall also make use of the cone

where $\gamma \in (0,1)$ is a constant defined by

where $M_{{\alpha }_j}$, $M_{{\beta }_j}$ come from Corollary 1 and ${\gamma }_j$ is associated by Lemma 2.6(iii) to $G_j(t_j,s)$, $j=1,2,\dots ,n$.

Lemma 3.1 Let S be the operator defined as in (2.2). Then $S:\kappa \to \kappa$.

Proof By means of (G₁), we get

for $(y_1,\dots ,y_n)\in \chi$.

By assumptions (G₂) and (G₃) together with the nonnegativity of $f_j(y_1,\dots ,y_n)$ and the fact that $(y_1,\dots ,y_n)\in \chi$, we can get ${\psi }_j(S_j(y_1,\dots ,y_n))⩾0$. By means of the same method, we obtain ${\varphi }_j(S_j(y_1,\dots ,y_n))⩾0$ for $j=1,2,\dots ,n$.

On the other hand, we show that

for $(y_1,\dots ,y_n)\in \chi$. In fact, by Lemma 2.6(iii), we have

where ${\tilde{\gamma }}_j=\{M_{{\alpha }_j},M_{{\beta }_j},{\gamma }_j\}$, $j=1,2,\dots ,n$.

Let $\gamma =min\{{\gamma }_1,\dots ,{\gamma }_n,M_{{\alpha }_1},\dots ,M_{{\alpha }_n},M_{{\beta }_1},\dots ,M_{{\beta }_n}\}$. Then we obtain

for $(y_1,\dots ,y_n)\in \chi$.

Finally, by the definitions $S_j$ ($j=1,2,\dots ,n$), it is clear that

So, we conclude that $S:\kappa \to \kappa$. This completes the proof. □

Lemma 3.2 Suppose that conditions (G₁)-(G₃) hold, and there exist two different positive numbers $r_1$, $r_2$, $r_1<r_2$, such that

Then the operator S has a fixed point $({\overline{y}}_1,\dots ,{\overline{y}}_n)\in \kappa$ such that