Existence of positive solutions for boundary value problems of p-Laplacian difference equations

In this paper, by using the Avery-Peterson fixed point theorem, we investigate the existence of at least three positive solutions for a third order p-Laplacian difference equation. An example is given to illustrate our main results.

MSC:34B10, 34B15, 34J10.

The aim of this paper is to study the existence of positive solutions for a third order p-Laplacian difference equation

where

• $N>1$ an integer;

• $a,c>0$, and $b,d\ge 0$ with $ad+ac(N+3)+bc>0$;

• f and q are continuous and positive;

• ${\varphi }_p$ is called p-Laplacian, ${\varphi }_p(x)={|x|}^{p-2}x$ with $p>1$, its inverse function is denoted by ${\varphi }_q(x)$ with ${\varphi }_q(x)={|x|}^{q-2}x$ with $1/p+1/q=1$;

• ${\sum }_{i=r}^{s}x(i)=0$ if $r,s\in \mathbb{Z}$ and $s<r$, where ℤ is the integer set, denote $[r,s]=\{r,r+1,\dots ,s\}$ for $r,s\in \mathbb{Z}$ with $r\le s$.

Difference equations, the discrete analog of differential equations, have been widely used in many fields such as computer science, economics, neural network, ecology, cybernetics, etc. [1]. In the past decade, the existence of positive solutions for the boundary value problems (BVPs) of the difference equations has been extensively studied; to mention a few references, see [1–13] and the references therein. Also there has been much interest shown in obtaining the existence of positive solutions for the third order p-Laplacian dynamic equations on time scales. To mention a few papers along these lines, see [14–18].

We now discuss briefly several of the appropriate papers on the topic.

Liu [10] studied the following second order p-Laplacian difference equation with multi-point boundary conditions:

The sufficient conditions to guarantee the existence of at least three positive solutions of the above multi-point boundary value problem were established by using a new fixed point theorem obtained in [19].

Liu [12] studied the following boundary value problem:

By using the five functionals fixed point theorem [20], Liu obtained the existence criteria of at least three positive solutions.

Therefore, in this paper, we will consider the existence of at least three positive solutions for the third order p-Laplacian difference equation (1.1) by using the Avery-Peterson fixed point theorem [3].

Throughout this paper we assume that the following condition holds:

(C1) $f:[0,N]\times [0,+\mathrm{\infty })\times \mathbb{R}\to (0,+\mathrm{\infty })$ and $q:[0,N]\to (0,+\mathrm{\infty })$ are continuous.

This paper is organized as follows. In Section 2, we give some preliminary lemmas which are key tools for our proof. The main result is given in Section 3. Finally, in Section 4, we give an example to demonstrate our result.

In this section we present some lemmas, which will be needed in the proof of the main result.

Let γ and θ be nonnegative continuous convex functionals on $\mathcal{P}$, α be a nonnegative continuous concave functional on $\mathcal{P}$ and ψ be a nonnegative continuous functional on $\mathcal{P}$. Then for positive real numbers t, v, w, and z, we define the following convex sets of $\mathcal{P}$:

and a closed set

The following fixed point theorem is fundamental and important to the proof of our main result.

Lemma 2.1 ([3])

Let $\mathbb{B}$ be a real Banach space and $\mathcal{P}\subset \mathbb{B}$ be a cone in $\mathbb{B}$. Let γ, θ be nonnegative continuous convex functionals on $\mathcal{P}$, let α be a nonnegative continuous concave functional on $\mathcal{P}$, and let ψ be a nonnegative continuous functional on $\mathcal{P}$ satisfying $\psi (\lambda y)\le \lambda \psi (y)$ for all $0\le \lambda \le 1$, such that for some positive numbers z and M,

Suppose that $T:\overline{\mathcal{P}(\gamma ,z)}\to \overline{P(\gamma ,z)}$ is completely continuous and there exist positive numbers t, v, and w with $0<t<v<w$ such that

1. (i)

   $\{y\in \mathcal{P}(\alpha ,v;\theta ,w;\gamma ,z)|\alpha (y)>v\}\ne \mathrm{\varnothing }$ and $\alpha (Ty)>v$ for $y\in \mathcal{P}(\alpha ,v;\theta ,w;\gamma ,z)$;

2. (ii)

   $\alpha (Ty)>v$ for $y\in \mathcal{P}(\alpha ,v;\gamma ,z)$ with $\theta (Ty)>w$;

3. (iii)

   $0\notin R(\psi ,t;\gamma ,z)$ and $\psi (Ty)<t$ for $y\in R(\psi ,t;\gamma ,z)$ with $\psi (y)=t$.

Then T has at least three fixed points $y_1,y_2,y_3\in \overline{\mathcal{P}(\gamma ,z)}$ such that

Let $h(n)$ ($n\in [0,N]$) be a positive sequence. Consider the following BVP:

Lemma 2.2 If y is a solution of BVP (2.1), then there exists unique $n_0\in [0,N+1]$ such that $\mathrm{\Delta }y(n_0)>0$ and $\mathrm{\Delta }y(n_0+1)\le 0$.

Proof Suppose y satisfies (2.1). It follows that

The BCs in (2.1) imply that

and

It follows that

and

Similarly, we get

The BCs in (2.1) imply that

and

Since $a,b\ge 0$, and $c,d>0$ with $ad+ac(N+3)+bc>0$ and $h(n)$ a positive sequence, one can easily see that $\mathrm{\Delta }y(0)>0$ and $\mathrm{\Delta }y(N+2)\le 0$. It follows from $\mathrm{\Delta }y(0)>0$, $\mathrm{\Delta }y(N+2)\le 0$, and the fact that $\mathrm{\Delta }y(n)$ is decreasing on $[0,N+2]$ that there exists unique $n_0\in [0,N+1]$ such that $\mathrm{\Delta }y(n_0)>0$ and $\mathrm{\Delta }y(n_0+1)\le 0$. The proof is complete. □

Lemma 2.3 If y is a solution of BVP (2.1), then $y(0)\ge 0$, $y(N+3)\ge 0$, and $y(n)>0$ for all $n\in [1,N+2]$.

Proof We get from Lemma 2.2 the result that there exists unique $n_0\in [0,N]$ such that $\mathrm{\Delta }y(n_0)>0$ and $\mathrm{\Delta }y(n_0+1)\le 0$. It follows from (2.1) that

Then

with

It follows from $h(n)$ being positive, $\mathrm{\Delta }y(n_0)>0$, and $\mathrm{\Delta }y(n_0+1)\le 0$ that

So $y(n)\ge min\{y(0),y(N+3)\}$ for all $n\in [0,N+3]$. From BCs in BVP (2.1), we get

Then

Hence $y(n)>0$ for all $n\in [1,N+2]$. The proof is complete. □

Lemma 2.4 If y is a solution of BVP (2.1), then

where ${\sigma }_n=min\{\frac{n}{N+3},\frac{N+3-n}{N+3}\}$.

Proof It follows from Lemma 2.2 and Lemma 2.3 that $y(n)\ge 0$ for $n\in [0,N+3]$. Suppose that $y(n_0)=max\{y(n):n\in [0,N+3]\}$. Since $\mathrm{\Delta }y(0)>0$ and $\mathrm{\Delta }y(N+1)\le 0$, we get $n_0\in [1,N+1]$. For $n\in [1,n_0]$, it is easy to see that

Since ${\mathrm{\Delta }}^{2}y(n)=-{\varphi }_q({\sum }_{s=0}^{n-1}h(s))<0$ for all $n\in [0,N+1]$, we get $\mathrm{\Delta }y(s)\le \mathrm{\Delta }y(j)$ for all $s\ge j$. Then $-(n_0-n){\sum }_{s=0}^{n-1}\mathrm{\Delta }y(s)+n{\sum }_{s=n}^{n_0-1}\mathrm{\Delta }y(s)\le 0$. It follows that $\frac{y(n_0)-y(0)}{n_0}n+y(0)-y(n)\le 0$. Then

Similarly, if $n\in [n_0,N+2]$, we get

Then

 □

Lemma 2.5 If y is a solution of BVP (2.1), then

where $A_h$ satisfies the equation

Proof The proof follows from Lemma 2.2 and is omitted. □

Lemma 2.6 If y is a solution of BVP (2.1), then there exists an $n_0\in [0,N]$ such that

Proof It follows from Lemma 2.2 that there is $n_0\in [0,N+1]$ such that $\mathrm{\Delta }y(n_0)>0$ and $\mathrm{\Delta }y(n_0+1)\le 0$, $\mathrm{\Delta }y(n)>0$ for all $n\in [0,n_0]$ and $\mathrm{\Delta }y(n)\le 0$ for all $n\in [n_0+1,N+2]$. Then

there exists $\xi \in (n_0,n_0+1]$ such that

Then

It is easy to see from (2.1) that

Here $A_h=\mathrm{\Delta }y(0)$. So (2.6)-(2.8) imply that

Then

We get

Lemma 2.3 implies that $B_h=y(0)\ge 0$. Furthermore, one has from (2.6)

On the other hand, by a discussion similar to Lemma 2.2 and Lemma 2.3, we have ${\overline{A}}_h=\mathrm{\Delta }y(N+2)$, ${\overline{B}}_h=y(N+3)$ with

and

It follows that

So

Then

We get

One has from Lemma 2.3 ${\overline{B}}_h=y(N+3)\ge 0$. Therefore

Hence

 □

Let $h(n)=q(n)f(n,y(n),\mathrm{\Delta }y(n))$. Then $A_y$ satisfies the following equation:

Let $\mathbb{B}={\mathbb{R}}^{N+4}$. We call $x\le y$ for $x,y\in \mathbb{B}$ if $x(n)\le y(n)$ for all $n\in [0,N+3]$.

Define the norm

It is easy to see that $\mathbb{B}$ is a semi-ordered real Banach space.

Choose

where ${\sigma }_n=min\{\frac{n}{N+3},\frac{N+3-n}{N+3}\}$. Then $\mathcal{P}$ is a cone in $\mathbb{B}$.

Define the operator $T:\mathcal{P}\to \mathbb{B}$ by

for $y\in \mathcal{P}$, $n\in [0,N+3]$. Then

Lemma 2.7 Suppose that (C1) holds. Then

1. (i)

   Ty satisfies the following:

   $$\{\begin{array}{l}\mathrm{\Delta }[{\varphi }_p({\mathrm{\Delta }}^2(Ty)(n))]+q(n)f(n,y(n),\mathrm{\Delta }y(n))=0,0<n<N,\\ a(Ty)(0)-b\mathrm{\Delta }(Ty)(0)=0,c(Ty)(N+3)+d\mathrm{\Delta }(Ty)(N+2)=0,\\ {\mathrm{\Delta }}^2(Ty)(0)=0.\end{array}$$

   (2.11)
2. (ii)

   $Ty\in \mathcal{P}$ for each $y\in \mathcal{P}$.

3. (iii)

   y is a solution of BVP (1.1) if and only if y is a solution of the operator equation $y=Ty$.

4. (iv)

   $T:\mathcal{P}\to \mathcal{P}$ is completely continuous.

Proof

1. (i)

   By the definition of Ty, we get (2.11).

2. (ii)

   Note the definition of $\mathcal{P}$. Since (C1) holds, for $y\in \mathcal{P}$, (2.11), Lemma 2.2, Lemma 2.3 and Lemma 2.4 imply that $\mathrm{\Delta }(Ty)(n)$ is decreasing on $[0,N+2]$ and $(Ty)(n)\ge {\sigma }_n{max}_{n\in [0,N+3]}(Ty)(n)$ for all $n\in [0,N+3]$. Together with (2.11), it follows that $Ty\in \mathcal{P}$.

3. (iii)

   It is easy to see from (2.11) that y is a solution of BVP (1.1) if and only if y is a solution of the operator equation $y=Ty$.

4. (iv)

   It suffices to prove that T is continuous on $\mathcal{P}$ and T is relative compact.

We divide the proof into three steps:

Step 1. For each bounded subset $D\subset \mathcal{P}$, prove that $A_y$ is bounded in ℝ for $y\in \overline{D}$

Denote

and

It follows from (2.9) in the proof of Lemma 2.6 that

Hence $A_y$ is bounded in ℝ.

Step 2. For each bounded subset $D\subset \mathcal{P}$, and each $y_0\in D$, it is easy to prove that T is continuous at $y_0$.

Step 3. For each bounded subset $D\subset \mathcal{P}$, prove that T is relative compact on D.

In fact, for each bounded subset $\mathrm{\Omega }\subseteq D$ and $y\in \mathrm{\Omega }$. Suppose

and Step 1 implies that there exists a constant $M_2>0$ such that $A_y<M_2$. Then

where $f_{M_1}(s)={max}_{u\le M_1,|x|\le M_1}q(j)f(s,u,x)$. Similarly, one has

It follows that T Ω is bounded. Since $\mathbb{B}={\mathbb{R}}^{N+4}$, one knows that T Ω is relative compact. Steps 1, 2, and 3 imply that T is completely continuous. □

In this section, our objective is to establish the existence of at least three positive solutions for BVP (1.1) by using the Avery-Peterson fixed point theorem [3].

Choose $[\frac{N+3}{2}]>k>0$, where $[x]$ denotes the largest integer not greater than x, and denote ${\sigma }_k=min\{\frac{k}{N+3},\frac{N+3-k}{N+3}\}$.

Define the functionals on $\mathcal{P}:\mathcal{P}\to [0,+\mathrm{\infty })$ by

For $y\in \mathcal{P}$ and $n\in [0,N+3]$ we have

i.e.,

So,

Hence, we obtain

Let

Theorem 3.1 Suppose that (C1) holds. If there are positive numbers

such that the following conditions are satisfied:

(C2) $f(n,y(n),\mathrm{\Delta }y(n))\le {\varphi }_p(\frac{z}{\mathrm{\Omega }})$ for all $(n,y(n),\mathrm{\Delta }y(n))\in [0,N+3]\times [0,(N+3+\frac{b}{a})z]\times [-z,z]$;

(C3) $f(n,y(n),\mathrm{\Delta }y(n))>{\varphi }_p(\frac{v}{\mathrm{\Lambda }})$ for all $(n,y(n),\mathrm{\Delta }y(n))\in [k,N+3-k]\times [v,\frac{v}{{\sigma }_k}]\times [-z,z]$;

(C4) $f(n,y(n),\mathrm{\Delta }y(n))<\frac{a}{(N+3)a+b}{\varphi }_p(\frac{t}{\mathrm{\Omega }})$ for all $(n,y(n),\mathrm{\Delta }y(n))\in [0,N+3]\times [0,t]\times [-z,z]$,

then BVP (1.1) has at least three positive solutions.

Proof We choose positive numbers t, v, $w=\frac{v}{{\sigma }_k}$, z with $t<v<\frac{v}{{\sigma }_k}<z$, ${\varphi }_p(\frac{v}{\mathrm{\Lambda }})\le min\{{\varphi }_p(\frac{z}{\mathrm{\Omega }}),\frac{a}{(N+3)a+b}{\varphi }_p(\frac{t}{\mathrm{\Omega }})\}$. Next we show that all the conditions of Lemma 2.1 are satisfied.

It is clear that for $y\in P$ and $\lambda \in [0,1]$, there are $\alpha (y)\le \psi (y)$, $\psi (\lambda y)=\lambda \psi (y)$. From (3.2), we have $\parallel y\parallel \le (N+3+\frac{b}{a})\gamma (y)$. Furthermore, $\psi (0)=0<t$ and therefore $0\notin R(\psi ,t;\gamma ,z)$.