Multiple solutions of a p-Laplacian model involving a fractional derivative

Abstract

In this paper, we study the p-Laplacian model involving the Caputo fractional derivative with Dirichlet-Neumann boundary conditions. Using a fixed point theorem, we prove the existence of at least three solutions of the model. As an application, an example is included to illustrate the main results.

1 Introduction

In this paper, we are concerned with the multiple positive solutions of Dirichlet-Neumann boundary value problems for a type of fractional differential equation involving a p-Laplacian operator as the following form:

$$\{\begin{array}{c}{({\phi }_p{(}^C{D}^{\alpha }x(t)))}^{\prime }={\phi }_p(\lambda )f(t,x(t),x^{\prime }(t)),t\in (0,1),\hfill \\ k_{0}x(0)-k_{1}x(1)=0,\hfill \\ m_0{x}^{\prime }(0)-m_1{x}^{\prime }(1)=0,\hfill \\ x^{(r)}(0)=0,r=2,3,\dots ,n,\hfill \end{array}$$

(1)

where ${\phi }_p$ is the p-Laplacian operator, i.e., ${\phi }_p(s)={|s|}^{p-2}s$, $p>1$, and ${\phi }_q={\phi }_p^{-1}$, $\frac{1}{p}+\frac{1}{q}=1$; ${}^{C}D^{\alpha }$ is the standard Caputo derivative; $2\le n-1<\alpha \le n$, and n is an integer; $0<\lambda \in \mathbb{R}$, $k_i$, $m_i$ are constants, $i=0,1$; f is a given function.

It is well known that both the fractional differential equations and the p-Laplacian operator equations are widely used in the fields of different physical and natural phenomena, non-Newtonian mechanics, nonlinear elasticity and glaciology, combustion theory, population biology, complex geometry and patterns. Many researchers have extensively studied either the fractional differential equations or the p-Laplacian operator equations, respectively. For details of the theory and applications of the fractional differential equations or the p-Laplacian operator equations, see [1–15] and the references therein.

The authors of [13] studied the boundary value problem of fractional order

$$\{\begin{array}{c}{}^{C}D^{\alpha }u(t)=f(t,u(t),u^{\prime }(t)),t\in (0,1),1<\alpha \le 2,\hfill \\ u(0)+u^{\prime }(0)=0,\hfill \\ u(1)+u^{\prime }(1)=0.\hfill \end{array}$$

By means of the Schauder fixed point theorem and an extension of the Krasnosel’skii fixed point theorem in a cone, the existence of positive solutions is obtained.

In [14], the authors investigated the nonlinear boundary value problem of fractional differential equation

$$\{\begin{array}{c}{}^{C}D^{\alpha }x(t)=f(t,x(t),x^{\prime }(t)),t\in (0,1),\hfill \\ g_0(x(0),x^{\prime }(0))=0,\hfill \\ g_1(x(1),x^{\prime }(1))=0,\hfill \\ x^{″}(0)=x^{‴}(0)=\cdots =x^{(n)}=0.\hfill \end{array}$$

By means of the Amann theorem and the method of upper and lower solutions, some results on the multiple solutions are obtained.

Liu [15] was concerned with the mixed type multi-point boundary value problem

$$\{\begin{array}{c}{({\phi }_p(x^{\prime }(t)))}^{\prime }=-f(t,x(t),x^{\prime }(t)),t\in (0,1),\hfill \\ x(0)-\alpha x^{\prime }(0)={\lambda }_1,\hfill \\ x(1)-{\sum }_{i=1}^m{\beta }_{i}x({\xi }_i)={\lambda }_2,\hfill \end{array}$$

the existence of at least three positive solutions of the above mentioned boundary value problem is established.

Recently, a few researchers were devoted to the study of boundary value problems for the fractional differential equations with the p-Laplacian operator equations (see [16, 17]). In [16], some results on the existence and uniqueness of a solution for the following boundary value problem of a fractional differential equation are obtained:

$$\{\begin{array}{c}{({\phi }_p{(}^C{D}^{\alpha }x(t)))}^{\prime }=f(t,x(t)),t\in (0,1),\hfill \\ x(0)=r_{0}x(1),\hfill \\ x^{\prime }(0)=r_1{x}^{\prime }(1).\hfill \end{array}$$

Motivated by the above, the purpose of this paper is to establish the existence of multiple positive solutions to boundary value problems for a fractional differential equation involving a p-Laplacian operator (1). If p is an integer, the equation in (1) reduces to a standard nonlinear fractional differential equation. And it will become a standard p-Laplacian operator equation when α is an integer. Therefore, our results in this paper are the promotion and more general case of these two types of problems. By means of the fixed point theorem due to Avery and Peterson, we prove the results that there exist at least three positive solutions of the boundary value problem (1). As an application, an example is included to illustrate the main results.

2 Preliminaries

In this section, we give the definition of a fractional derivative and some lemmas, which will be used later.

Definition 2.1 [18]

Let $\alpha >0$ for a function $y:(0,+\mathrm{\infty })\to \mathbb{R}$. The fractional integral of order α of y is defined by

$$I^{\alpha }y(t)=\frac{1}{\mathrm{\Gamma }(\alpha )}{\int }_0^t{(t-s)}^{\alpha -1}y(s)\mathrm{d}s,$$

provided the integral exists. The Caputo derivative of a function $y:(0,+\mathrm{\infty })\to \mathbb{R}$ is given by

$${}^{C}D^{\alpha }y(t)=\frac{1}{\mathrm{\Gamma }(n-\alpha )}{\int }_0^t\frac{y^{(n)}(s)}{{(t-s)}^{\alpha +1-n}}\mathrm{d}s,$$

provided the right-hand side is pointwise defined on $(0,+\mathrm{\infty })$, where n is an integer, with $n=[\alpha ]+1$.

Γ denotes the gamma function, that is,

$$\mathrm{\Gamma }(\alpha )={\int }_0^{+\mathrm{\infty }}{e}^{-t}{t}^{\alpha -1}\mathrm{d}t.$$

From Definition 2.1, we can obtain the following lemma.

Lemma 2.1 Let $0<n-1<\alpha \le n$. If we assume $y\in C^n(0,1)\cap L[0,1]$, the fractional differential equation

$${}^{C}D^{\alpha }y(t)=0$$

has a unique solution

$$y(t)=\sum _{k=0}^{n-1}\frac{y^{(k)}(0)}{k!}{t}^k.$$

Throughout this paper, we always suppose the following condition holds.

(H0) The parameters in the boundary value problem (1) satisfy the following conditions:

$$2\le n-1<\alpha \le n,0<k_1<k_0,0<m_1<m_0.$$

Lemma 2.2 Suppose that (H0) holds and $h\in C[0,1]$. Then the boundary value problem

$$\{\begin{array}{c}{({\phi }_p{(}^C{D}^{\alpha }x(t)))}^{\prime }={\phi }_p(\lambda )h(t),t\in (0,1),\hfill \\ k_{0}x(0)-k_{1}x(1)=0,\hfill \\ m_0{x}^{\prime }(0)-m_1{x}^{\prime }(1)=0,\hfill \\ x^{(r)}(0)=0,r=2,3,\dots ,n\hfill \end{array}$$

(2)

has a unique solution

$$\begin{array}{rl}x(t)=& \frac{m_1}{m_0-m_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}\cdot (\frac{k_1}{k_0-k_1}+t){\int }_0^1{(1-\tau )}^{\alpha -2}{\phi }_q({\int }_0^{\tau }h(s)\mathrm{d}s)\mathrm{d}\tau \\ +\frac{k_1}{k_0-k_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha )}{\int }_0^1{(1-\tau )}^{\alpha -1}{\phi }_q({\int }_0^{\tau }h(s)\mathrm{d}s)\mathrm{d}\tau \\ +\frac{\lambda }{\mathrm{\Gamma }(\alpha )}{\int }_0^t{(t-\tau )}^{\alpha -1}{\phi }_q({\int }_0^{\tau }h(s)\mathrm{d}s)\mathrm{d}\tau .\end{array}$$

(3)

That is, every solution of (2) is also a solution of (3) and vice versa.

Proof The definition of the Caputo derivative implies that ${}^{C}D^{\alpha }x(0)=0$, and from (2) we have

$${\phi }_p{(}^C{D}^{\alpha }x(t))={\phi }_p(\lambda ){\int }_0^{t}h(s)\mathrm{d}s,\text{and}{}^C{D}^{\alpha }x(t)=\lambda {\phi }_q({\int }_0^{t}h(s)\mathrm{d}s).$$

So,

$$\begin{array}{rl}x(t)& =x(0)+x^{\prime }(0)t+\frac{x^{″}(0)}{2!}{t}^2+\cdots +\frac{x^{(n-1)}(0)}{(n-1)!}{t}^{n-1}+I^{\alpha }\lambda {\phi }_q({\int }_0^{t}h(s)\mathrm{d}s)\\ =x(0)+x^{\prime }(0)t+\frac{\lambda }{\mathrm{\Gamma }(\alpha )}{\int }_0^t{(t-\tau )}^{\alpha -1}{\phi }_q({\int }_0^{\tau }h(s)\mathrm{d}s)\mathrm{d}\tau .\end{array}$$

(4)

By using the property of the fractional derivatives and integrals, we can get

$$x^{\prime }(t)=x^{\prime }(0)+\frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}{\int }_0^t{(t-\tau )}^{\alpha -2}{\phi }_q({\int }_0^{\tau }h(s)\mathrm{d}s)\mathrm{d}\tau .$$

Then

$$\begin{array}{c}x(1)=x(0)+x^{\prime }(0)+\frac{\lambda }{\mathrm{\Gamma }(\alpha )}{\int }_0^1{(1-\tau )}^{\alpha -1}{\phi }_q({\int }_0^{\tau }h(s)\mathrm{d}s)\mathrm{d}\tau ,\hfill \\ x^{\prime }(1)=x^{\prime }(0)+\frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}{\int }_0^1{(1-\tau )}^{\alpha -2}{\phi }_q({\int }_0^{\tau }h(s)\mathrm{d}s)\mathrm{d}\tau .\hfill \end{array}$$

From the boundary condition $k_{0}x(0)-k_{1}x(1)=0$, and $m_0{x}^{\prime }(0)-m_1{x}^{\prime }(1)=0$, we can obtain that

(5)

(6)

Substituting (5) and (6) into (4), we can obtain that

$$\begin{array}{rcl}x(t)& =& \frac{m_1}{m_0-m_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}\cdot (\frac{k_1}{k_0-k_1}+t){\int }_0^1{(1-\tau )}^{\alpha -2}{\phi }_q({\int }_0^{\tau }h(s)\mathrm{d}s)\mathrm{d}\tau \\ +\frac{k_1}{k_0-k_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha )}{\int }_0^1{(1-\tau )}^{\alpha -1}{\phi }_q({\int }_0^{\tau }h(s)\mathrm{d}s)\mathrm{d}\tau \\ +\frac{\lambda }{\mathrm{\Gamma }(\alpha )}{\int }_0^t{(t-\tau )}^{\alpha -1}{\phi }_q({\int }_0^{\tau }h(s)\mathrm{d}s)\mathrm{d}\tau .\end{array}$$

The proof is completed. □

Let $E=C^1[0,1]$, $\parallel x\parallel =max\{{max}_{t\in [0,1]}|x(t)|,{max}_{t\in [0,1]}|x^{\prime }(t)|\}$, then $(E,\parallel \cdot \parallel )$ is a Banach space. Set

$$\begin{array}{rl}P=& \{x\in E|x(t)\ge 0,\underset{t\in [0,1]}{max}|x(t)|\le min\{\frac{k_0}{k_0-k_1}\underset{t\in [0,1]}{max}|x^{\prime }(t)|,\frac{k_0}{k_1}\underset{t\in [0,1]}{min}|x(t)|\},\\ x\text{ is monotone increasing and convex on }[0,1]\},\end{array}$$

then P is a cone on E.

Define the operator $T:P\to E$ by

(7)

It is clear that $x\in C^n[0,1]$ is the solution of the boundary value problem (1) if and only if $x\in E$ is the fixed point of the operator T.

Lemma 2.3 Suppose that (H0) holds and the function $f\in C([0,1]\times [0,+\mathrm{\infty })\times \mathbb{R},[0,+\mathrm{\infty }))$. Then $T:P\to P$ is completely continuous.

Proof By the definition of the operator T, it is easy to see $(Tx)(t)\ge 0$ for any $t\in [0,1]$. And using the property of the fractional integrals and derivatives, we can get that

$$\begin{array}{rl}{(Tx)}^{\prime }(t)=& \frac{m_1}{m_0-m_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}{\int }_0^1{(1-\tau )}^{\alpha -2}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \\ +\frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}{\int }_0^t{(t-\tau )}^{\alpha -2}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \\ \ge & 0.\end{array}$$

And

$${(Tx)}^{″}(t)=\frac{\lambda }{\mathrm{\Gamma }(\alpha -2)}{\int }_0^t{(t-\tau )}^{\alpha -3}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \ge 0.$$

Then Tx is nonnegative, monotone increasing and convex on $[0,1]$. They imply that

$$\begin{array}{c}\underset{t\in [0,1]}{max}|(Tx)(t)|=\underset{t\in [0,1]}{max}(Tx)(t)=(Tx)(1),\hfill \\ \underset{t\in [0,1]}{max}|{(Tx)}^{\prime }(t)|=\underset{t\in [0,1]}{max}{(Tx)}^{\prime }(t)={(Tx)}^{\prime }(1),\hfill \end{array}$$

and

$$\underset{t\in [0,1]}{min}(Tx)(t)=(Tx)(0),\underset{t\in [0,1]}{min}{(Tx)}^{\prime }(t)={(Tx)}^{\prime }(0).$$

Therefore

$$\underset{t\in [0,1]}{max}|(Tx)(t)|=(Tx)(1)=\frac{k_0}{k_1}(Tx)(0)=\frac{k_0}{k_1}\underset{t\in [0,1]}{min}|(Tx)(t)|.$$

And

$$\begin{array}{c}\underset{t\in [0,1]}{max}|(Tx)(t)|\hfill \\ =(Tx)(1)\hfill \\ =\frac{m_1}{m_0-m_1}\cdot \frac{k_0}{k_0-k_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}{\int }_0^1{(1-\tau )}^{\alpha -2}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \hfill \\ +\frac{k_0}{k_0-k_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha )}{\int }_0^1{(1-\tau )}^{\alpha -1}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \hfill \\ \le \frac{m_1}{m_0-m_1}\cdot \frac{k_0}{k_0-k_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}{\int }_0^1{(1-\tau )}^{\alpha -2}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \hfill \\ +\frac{k_0}{k_0-k_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}{\int }_0^1{(1-\tau )}^{\alpha -2}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \hfill \\ =\frac{k_0}{k_0-k_1}\cdot \frac{m_0}{m_0-m_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}{\int }_0^1{(1-\tau )}^{\alpha -2}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \hfill \\ =\frac{k_0}{k_0-k_1}\cdot {(Tx)}^{\prime }(1)\hfill \\ =\frac{k_0}{k_0-k_1}\underset{t\in [0,1]}{max}|{(Tx)}^{\prime }(t)|.\hfill \end{array}$$

Then

$$\underset{t\in [0,1]}{max}|(Tx)(t)|\le min\{\frac{k_0}{k_0-k_1}\underset{t\in [0,1]}{max}|{(Tx)}^{\prime }(t)|,\frac{k_0}{k_1}\underset{t\in [0,1]}{min}|(Tx)(t)|\}.$$

Thus, $Tx\in P$, so $T:P\to P$.

It is easy to prove that T is continuous and compact if the conditions of the lemma hold.

The proof is complete. □

For convenience of the readers, we provide some background material from the theory of cones in Banach spaces and the Avery-Peterson fixed point theorem.

Definition 2.2 Let E be a Banach space and let $P\subset E$ be a cone. A continuous map γ is called a concave (resp. convex) functional on P if and only if $\gamma (tx+(1-t)y)\ge t\gamma (x)+(1-t)\gamma (y)$ (resp. $\gamma (tx+(1-t)y)\le t\gamma (x)+(1-t)\gamma (y)$) for all $x,y\in P$ and $0<t<1$.

Let β and ρ be nonnegative continuous convex functionals on a cone P, let ω be a nonnegative continuous concave functional on a cone P, and let ψ be a nonnegative continuous functional on a cone P. Then, for positive real numbers a, b, c and d, we define the following convex sets:

$$\begin{array}{c}P(\beta ;d)=\{x\in P|\beta (x)<d\},\overline{P}(\beta ;d)=\{x\in P|\beta (x)\le d\};\hfill \\ P(\beta ,\omega ;b,d)=\{x\in P|\beta (x)\le d,\omega (x)\ge b\};\hfill \\ P(\beta ,\rho ,\omega ;b,c,d)=\{x\in P|\beta (x)\le d,\rho (x)\le c,\omega (x)\ge b\};\hfill \\ R(\beta ,\psi ;a,d)=\{x\in P|\beta (x)\le d,\psi (x)\ge a\}.\hfill \end{array}$$

Lemma 2.4 (Avery-Peterson fixed point theorem [19])

Let P be a cone in a real Banach space E. Let β and ρ be nonnegative continuous convex functionals on P, let ω be a nonnegative continuous concave functional on P, and let ψ be a nonnegative continuous functional on P satisfying $\psi (kx)\le k\psi (x)$ for $0<k<1$, such that for some positive numbers M and d, $\omega (x)\le \psi (x)$ and $\parallel x\parallel \le M\beta (x)$ for all $x\in \overline{P}(\beta ,d)$.

Suppose that $T:\overline{P}(\beta ;d)\to \overline{P}(\beta ;d)$ is completely continuous and there exist positive numbers a, b and c with $a<b$ such that

(A1) $\{x\in P(\beta ,\rho ,\omega ;b,c,d)|\omega (x)>b\}\ne \varphi$, and $\omega (Tx)>b$ for all $x\in P(\beta ,\rho ,\omega ;b,c,d)$;

(A2) $\omega (Tx)>b$ for all $x\in P(\beta ,\omega ;b,d)$ with $\rho (Tx)>c$;

(A3) $0\notin R(\beta ,\psi ;a,d)$ and $\psi (Tx)<a$ for $x\in R(\beta ,\psi ;a,d)$ with $\psi (x)=a$.

Then T has at least three fixed points $x_1,x_2,x_3\in \overline{P}(\beta ;d)$ such that $\beta (x_i)<d$, $i=1,2,3$; $\omega (x_1)>b$; $\psi (x_2)>a$, with $\omega (x_2)<b$; and $\psi (x_3)<a$.

3 Multiple positive solutions of the boundary value problems

In this section, we establish the existence of multiple positive solutions of the boundary value problem (1).

Denote

$$M=\frac{k_0}{k_0-k_1},r_0=\frac{k_1}{k_0-k_1}\cdot \frac{\mathrm{\Gamma }(\alpha +q-1)}{\mathrm{\Gamma }(\alpha +q)},$$

and

$$\begin{array}{c}{r}_1=\frac{(m_0-m_1)\mathrm{\Gamma }(\alpha +q-1)}{\lambda m_0\mathrm{\Gamma }(q)},r_2=\frac{(k_0-k_1)(m_0-m_1)\mathrm{\Gamma }(\alpha +q)}{\lambda k_1{m}_0\mathrm{\Gamma }(q)},\hfill \\ r_3=\frac{(k_0-k_1)}{k_0}{r}_1.\hfill \end{array}$$

Then $M>1$, $r_0>0$, $0<r_3<r_1$, and $r_2>0$ if (H0) holds. And $r_{2}b<r_{1}d$, $r_{3}a<r_{1}d$ if $0<a<b<r_{0}d$.

Theorem 3.1 Suppose that (H0) holds, there exist constants a, b, c, d such that $0<a<b<\frac{k_1}{k_0}c\le r_{0}d<d$, and $f\in C([0,1]\times [0,+\mathrm{\infty })\times \mathbb{R},[0,+\mathrm{\infty }))$ satisfies the following conditions:

(H1) $0\le f(t,u,v)\le {\phi }_p(r_{1}d)$ for any $(t,u,v)\in [0,1]\times [0,Md]\times [0,d]$;

(H2) $f(t,u,v)>{\phi }_p(r_{2}b)$ for any $(t,u,v)\in [0,1]\times [b,c]\times [0,d]$;

(H3) $0\le f(t,u,v)\le {\phi }_p(r_{3}a)$ for any $(t,u,v)\in [0,1]\times [\frac{k_1}{k_0}a,a]\times [0,d]$.

Then the boundary value problem (1) has at least three positive solutions $x_1,x_2,x_3\in \overline{P}(\beta ;d)$, and the solutions are increasing and convex on $[0,1]$. Moreover, for any $t\in [0,1]$,

$$\begin{array}{c}0\le x_i^{\prime }(t)<d,i=1,2,3;x_1(t)>b;\hfill \\ \underset{t\in [0,1]}{max}{x}_2(t)>a,\mathit{\text{with}}\underset{t\in [0,1]}{min}{x}_2(t)<b;\mathit{\text{and}}{x}_3(t)<a.\hfill \end{array}$$

Proof Define the nonnegative continuous convex functionals β, ρ and the nonnegative continuous functional ψ, the nonnegative continuous concave functional ω on the cone P by

$$\begin{array}{c}\beta (x)=\underset{t\in [0,1]}{max}|x^{\prime }(t)|,\rho (x)=\underset{t\in [0,1]}{max}|x(t)|,\hfill \\ \psi (x)=\underset{t\in [0,1]}{max}|x(t)|,\text{and}\omega (x)=\underset{t\in [0,1]}{min}|x(t)|.\hfill \end{array}$$

Obviously, $\psi (kx)=k\psi (x)$ for any $k\in (0,1)$, $x\in P$.

Because

$$\rho (x)=\underset{t\in [0,1]}{max}|x(t)|\le \frac{k_0}{k_0-k_1}\underset{t\in [0,1]}{max}|x^{\prime }(t)|=M\underset{t\in [0,1]}{max}|x^{\prime }(t)|=M\beta (x).$$

Then

$$\parallel x\parallel =max\{\underset{t\in [0,1]}{max}|x(t)|,\underset{t\in [0,1]}{max}|x^{\prime }(t)|\}=max\{\rho (x),\beta (x)\}\le M\beta (x)\text{for }x\in P.$$

Following from the proof of Lemma 2.3, we can get that $Tx\in P$, $(Tx)(t)\ge 0$, Tx is increasing and convex on $[0,1]$.

For any $x\in \overline{P}(\beta ;d)$ implies that $x(t)\ge 0$, $\beta (x)={max}_{t\in [0,1]}|x^{\prime }(t)|\le d$, and

$$\rho (x)=\underset{t\in [0,1]}{max}|x(t)|\le M\underset{t\in [0,1]}{max}|x^{\prime }(t)|=\beta (x)\le M\beta (x)\le Md.$$

By the condition (H1), we have $0\le f(t,x(t),x^{\prime }(t))\le {\phi }_p(r_{1}d)$. Hence,

$$\begin{array}{rl}\beta (Tx)=& \underset{t\in [0,1]}{max}{(Tx)}^{\prime }(t)={(Tx)}^{\prime }(1)\\ =& \frac{m_0}{m_0-m_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}{\int }_0^1{(1-\tau )}^{\alpha -2}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \\ \le & \frac{m_0}{m_0-m_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}\cdot r_{1}d\cdot {\int }_0^1{(1-\tau )}^{\alpha -2}{\tau }^{q-1}\mathrm{d}\tau \\ =& \frac{m_0}{m_0-m_1}\cdot \frac{\lambda \mathrm{\Gamma }(q)}{\mathrm{\Gamma }(\alpha +q-1)}\cdot r_{1}d\\ =& d.\end{array}$$

Therefore $Tx\in \overline{P}(\beta ;d)$. By Lemma 2.3, $T:\overline{P}(\beta ;d)\to \overline{P}(\beta ;d)$ is a completely continuous operator.

Let $x_0=\frac{b+c}{2}$, then $\rho (x_0)=x_0=\frac{b+c}{2}\le c$, $\beta (x_0)=0\le d$, and $\omega (x_0)=x_0=\frac{b+c}{2}>b$, so

$$x_0\in \{x\in P(\beta ,\rho ,\omega ;b,c,d)|\omega (x)>b\}\ne \varphi .$$

For any $x\in P(\beta ,\rho ,\omega ;b,c,d)$, it follows from the condition (H2), $f(t,x(t),x^{\prime }(t))>{\phi }_p(r_{2}b)$. By the proof of Lemma 2.3 and (7), we can get

$$\begin{array}{rcl}\omega (Tx)& =& \underset{t\in [0,1]}{min}|(Tx)(t)|=(Tx)(0)\\ =& \frac{m_1}{m_0-m_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}\cdot \frac{k_1}{k_0-k_1}{\int }_0^1{(1-\tau )}^{\alpha -2}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \\ +\frac{k_1}{k_0-k_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha )}{\int }_0^1{(1-\tau )}^{\alpha -1}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \\ >& \frac{m_1}{m_0-m_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha )}\cdot \frac{k_1}{k_0-k_1}{\int }_0^1{(1-\tau )}^{\alpha -1}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \\ +\frac{k_1}{k_0-k_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha )}{\int }_0^1{(1-\tau )}^{\alpha -1}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \\ =& \frac{m_0}{m_0-m_1}\cdot \frac{k_1}{k_0-k_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha )}{\int }_0^1{(1-\tau )}^{\alpha -1}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \\ \ge & \frac{m_0}{m_0-m_1}\cdot \frac{k_1}{k_0-k_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha )}\cdot r_{2}b\cdot {\int }_0^1{(1-\tau )}^{\alpha -1}{\tau }^{q-1}\mathrm{d}\tau \\ =& \frac{m_0}{m_0-m_1}\cdot \frac{k_1}{k_1-k_0}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha )}\cdot \frac{\mathrm{\Gamma }(\alpha )\mathrm{\Gamma }(q)}{\mathrm{\Gamma }(\alpha +q)}{r}_{2}b\\ =& b.\end{array}$$

Thus, the condition (A1) in the Avery-Peterson theorem is satisfied.

For any $x\in P(\beta ,\omega ;b,d)$ with $\rho (Tx)>c$, i.e., $\rho (Tx)={max}_{t\in [0,1]}|(Tx)(t)|>c$. Then

$$\omega (Tx)=\underset{t\in [0,1]}{min}|(Tx)(t)|\ge \frac{k_1}{k_0}\underset{t\in [0,1]}{max}|(Tx)(t)|>\frac{k_1}{k_0}c>b.$$

Consequently, the condition (A2) in the Avery-Peterson theorem is satisfied.

It is clear that $\theta =0\notin R(\beta ,\psi ;a,d)$.

For any $x\in R(\beta ,\psi ;a,d)$ with $\psi (x)=a$, it implies that

$$\beta (x)=\underset{t\in [0,1]}{max}|x^{\prime }(t)|\le d$$

and

$$0\le x(t)\le \underset{t\in [0,1]}{max}x(t)=\psi (x)=a.$$

It is easy to get that

$$x(t)\ge \underset{t\in [0,1]}{min}x(t)\ge \frac{k_1}{k_0}\underset{t\in [0,1]}{max}x(t)=\frac{k_1}{k_0}a.$$

It follows from the condition (H3) that

$$0\le f(t,x(t),x^{\prime }(t))\le {\phi }_p(r_{3}a),$$

then we have

$$\begin{array}{rcl}\psi (Tx)& =& \underset{t\in [0,1]}{max}|(Tx)(t)|=(Tx)(1)\\ =& \frac{m_1}{m_0-m_1}\cdot \frac{k_0}{k_0-k_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}{\int }_0^1{(1-\tau )}^{\alpha -2}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \\ +\frac{k_0}{k_0-k_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha )}{\int }_0^1{(1-\tau )}^{\alpha -1}{\phi }_q\left({\int }_0^{\tau }f(s,x(s),x^{\prime }(s))\mathrm{d}s\right)\mathrm{d}\tau \\ <& \frac{k_0}{k_0-k_1}\cdot \frac{m_0}{m_0-m_1}\cdot \frac{\lambda }{\mathrm{\Gamma }(\alpha -1)}\cdot r_{3}a\cdot {\int }_0^1{(1-\tau )}^{\alpha -2}{\tau }^{q-1}\mathrm{d}\tau \\ =& \frac{k_0}{k_0-k_1}\cdot \frac{m_0}{m_0-m_1}\cdot \frac{\lambda \mathrm{\Gamma }(q)}{\mathrm{\Gamma }(\alpha +q-1)}\cdot r_{3}a\\ =& a.\end{array}$$

So, the condition (A3) in the Avery-Peterson theorem holds.

Therefore, the conditions in the Avery-Peterson theorem are satisfied, and we can obtain that there exist three positive fixed points $x_1,x_2,x_3\in \overline{P}(\beta ;d)$ for the operator T corresponding to positive solutions to the discrete second-order boundary value problem (1) such that

$$\begin{array}{c}\beta (x_i)<d,i=1,2,3;\omega (x_1)>b;\hfill \\ \psi (x_2)>a,\text{with }\omega (x_2)<b;\text{and}\psi (x_3)<a.\hfill \end{array}$$

By Lemma 2.3, we can get that the solutions are increasing and convex on $[0,1]$. Hence

$$\begin{array}{c}0\le x_i^{\prime }(t)<d,i=1,2,3;x_1(t)>b;\hfill \\ \underset{t\in [0,1]}{max}{x}_2(t)>a,\text{with }\underset{t\in [0,1]}{min}{x}_2(t)<b;\text{and}{x}_3(t)<a.\hfill \end{array}$$

 □

4 Example

In this section, we give an example to illustrate Theorem 3.1.

Example 4.1 Consider the following Dirichlet-Neumann boundary value problem:

$$\{\begin{array}{c}{({|}^C{D}^{\frac{7}{3}}x(t){|}^C{D}^{\frac{7}{3}}x(t))}^{\prime }=f(t,x(t),x^{\prime }(t)),t\in (0,1),\hfill \\ 2x(0)-x(1)=0,\hfill \\ 3x^{\prime }(0)-x^{\prime }(1)=0,\hfill \\ x^{″}(0)=0,x^{‴}(0)=0,\hfill \end{array}$$

(8)

where

$$f(t,u,v)=\{\begin{array}{c}\frac{e^t}{10\text{,}000}+\frac{(35+34u-36u^2+72u^3){(\mathrm{\Gamma }(\frac{17}{6}))}^2}{135\pi }+\frac{v}{20\text{,}000},u\in [0,1],\hfill \\ \frac{e^t}{10\text{,}000}+\frac{(-7\text{,}730+10\text{,}391u-2\text{,}919u^2+278u^3){(\mathrm{\Gamma }(\frac{17}{6}))}^2}{60\pi }+\frac{v}{20\text{,}000},u\in [1,5],\hfill \\ \frac{e^t}{10\text{,}000}+\frac{(300+45u-u^2){(\mathrm{\Gamma }(\frac{17}{6}))}^2}{375\text{,}375\pi }+\frac{v}{20\text{,}000},u\in [5,+\mathrm{\infty }),\hfill \end{array}$$

and

$$\begin{array}{c}p=3,q=\frac{3}{2},\alpha =\frac{7}{3},k_0=2,k_1=1,\hfill \\ m_0=3,m_1=1,\lambda =1\text{in the boundary value problem (1)}.\hfill \end{array}$$

We choose $a=1$, $b=2$, $c=5$, $d=10$. We can easily get that $M=2>1$, $r_0=\frac{\mathrm{\Gamma }(\frac{17}{6})}{\mathrm{\Gamma }(\frac{23}{6})}$, $r_1=\frac{4\mathrm{\Gamma }(\frac{17}{6})}{3\sqrt{\pi }}$, $r_2=\frac{4\mathrm{\Gamma }(\frac{23}{6})}{3\sqrt{\pi }}$, $r_3=\frac{2\mathrm{\Gamma }(\frac{17}{6})}{3\sqrt{\pi }}$.

After some calculation, we can check that $f(t,u,v)$ satisfies following conditions:

1. (1)

   $0\le f(t,u,v)<\frac{160\mathrm{\Gamma }{(17/6)}^2}{\pi }+\frac{1}{1\text{,}000}<{\phi }_p(r_{1}d)=\frac{1\text{,}600\mathrm{\Gamma }{(17/6)}^2}{9\pi }$ for any $(t,u,v)\in [0,1]\times [0,Md]\times [0,d]$;

2. (2)

   $f(t,u,v)>\frac{60\mathrm{\Gamma }{(17/6)}^2}{\pi }+\frac{1}{1\text{,}000}>{\phi }_p(r_{2}b)=\frac{64\mathrm{\Gamma }{(23/6)}^2}{9\pi }$ for any $(t,u,v)\in [0,1]\times [b,c]\times [0,d]$;

3. (3)

   $0\le f(t,u,v)<\frac{4\mathrm{\Gamma }{(17/6)}^2}{9\pi }+\frac{1}{1\text{,}000}<{\phi }_p(r_{3}a)=\frac{\mathrm{\Gamma }{(17/6)}^2}{\pi }$ for any $(t,u,v)\in [0,1]\times [\frac{k_1}{k_0}a,a]\times [0,d]$.

Then all the conditions of Theorem 3.1 hold.

Hence, by Theorem 3.1, the boundary value problem (8) has at least three positive solutions $x_1$, $x_2$, $x_3$ such that

$$\begin{array}{c}0\le x_i^{\prime }(t)<10,i=1,2,3;\hfill \\ x_1(t)>2;\underset{t\in [0,1]}{max}{x}_2(t)>1,\text{with }\underset{t\in [0,1]}{min}{x}_2(t)<2;\text{and}{x}_3(t)<1.\hfill \end{array}$$