Existence and uniqueness of fixed point for mixed monotone ternary operators with application

Abstract

In this paper, partial order theory is used to study the fixed point of a mixed monotone ternary operator $A:P\times P\times P\to P$. The existence and uniqueness of a fixed point are obtained without assuming the operators to be compact or continuous. In the end, the application to an integral equation is presented. Our results unify, generalize, and complement various known comparable results from the current literature.

MSC:47H05, 47H10.

1 Introduction

Fixed point theory has fascinated hundreds of researchers since 1922 with the celebrated Banach fixed point theorem. It is well known that mixed monotone operators were introduced by Guo and Lakshmikantham [1] in 1987. Later, Bhaskar and Lakshmikantham [2] introduced the notion of a coupled fixed point and proved some coupled fixed point results under certain conditions, in a complete metric space endowed with a partial order. Their study has not only important theoretical meaning but also wide applications in engineering, nuclear physics, biological chemistry technology, etc. (see [1–8] and the references therein).

Very recently, Harjani et al. [9] have established the existence results of coupled fixed point for mixed monotone operators, and further obtained their applications to integral equations. Berinde and Borcut [10] have introduced the concept of a triple fixed point and proved some related theorems for contractive type operators in partially ordered metric spaces. Zhai [11] has considered mixed monotone operators with convexity and get the existence and uniqueness of a fixed point ($A(u,u)=u$ type) without assuming the operator to be compact or continuous.

Motivated by the work reported in [9–11], the aim of this paper is to discuss the existence and uniqueness of a fixed point ($A(u,u,u)=u$ type) for mixed monotone ternary operators in the context of ordered metric spaces. Our results unify, generalize, and complement various known comparable results from the current literature.

The rest of the paper is organized as follows. In Section 2, we recall some basic definitions and notations which will be used in the sequel. The existence and uniqueness of a fixed point for mixed monotone ternary operators (without assuming the operators to be compact or continuous) are obtained in Section 3. We also present an application in Section 4 to an integral equation to illustrate our results.

2 Preliminaries

In this section, we recall some standard definitions and notations needed in the following section. For the convenience of the reader, we suggest that one refers to [1, 2, 10–14] for details.

Throughout this paper, unless otherwise specified, suppose that $(E,\parallel \cdot \parallel )$ is a real Banach space which is partially ordered by a cone $P\subset E$, i.e., $x\le y$ if and only if $y-x\in P$. If $x\le y$ and $x\ne y$, then we denote $x<y$ or $y>x$. By θ we denote the zero element of E. Recall that a non-empty closed convex set $P\subset E$ is a cone if it satisfies (i) $x\in P$, $\lambda \ge 0\Rightarrow \lambda x\in P$; (ii) $x\in P$, $-x\in P\Rightarrow x=\theta$.

Further, P is called normal if there exists a constant $N>0$ such that, for all $x,y\in E$, $\theta \le x\le y$ implies $\parallel x\parallel \le N\parallel y\parallel$; in this case N is called the normality constant of P. If $x_1,x_2\in E$, the set $[x_1,x_2]=\{x\in E\mid x_1\le x\le x_2\}$ is called the order interval between $x_1$ and $x_2$.

Definition 2.1 (see [10])

$A:P\times P\to P$ is said to be a mixed monotone operator if $A(x,y)$ is monotone non-decreasing in x and monotone non-increasing in y, that is, for any $x,y\in P$,

$$\begin{array}{r}{x}_1,x_2\in P,x_1\le x_2\Rightarrow A(x_1,y)\le A(x_2,y),\\ y_1,y_2\in P,y_1\le y_2\Rightarrow A(x,y_2)\le A(x,y_1).\end{array}$$

(2.1)

Definition 2.2 (see [11])

An element $x\in P$ is called a fixed point of $A:P\times P\to P$ if

$$A(x,x)=x.$$

Definition 2.3 (see [10])

$A:P\times P\times P\to P$ is said to be a mixed monotone operator if $A(x,y,z)$ is monotone non-decreasing in x, z and monotone non-increasing in y, that is, for any $x,y,z\in P$

$$\begin{array}{c}{x}_1,x_2\in P,x_1\le x_2\Rightarrow A(x_1,y,z)\le A(x_2,y,z),\hfill \\ y_1,y_2\in P,y_1\le y_2\Rightarrow A(x,y_1,z)\ge A(x,y_2,z),\hfill \\ z_1,z_2\in P,z_1\le z_2\Rightarrow A(x,y,z_1)\le A(x,y,z_2).\hfill \end{array}$$

(2.2)

Definition 2.4 An element $x\in P$ is called a fixed point of $A:P\times P\times P\to P$ if

$$A(x,x,x)=x.$$

3 Main results

In this section we consider the existence and uniqueness of a fixed point for mixed monotone ternary operators in ordered Banach spaces. Our first main result is the following.

Theorem 3.1 Let E be a real Banach space and let P be a normal cone in E. $A:P\times P\times P\to P$ is a mixed monotone ternary operator which satisfies the following:

(H₁) for $t\in (0,1)$, $x,y\in P$, there exists $\alpha (t,x,y)\in (1,+\mathrm{\infty })$, such that

$$A(tx,y,tx)\le t^{\alpha (t,x,y)}A(x,y,x);$$

(3.1)

(H₂) there exist $u_0,v_0,m_0\in P$, $r\in (0,1)$, such that

$$\begin{array}{c}{u}_0\le r{v}_0,m_0\le r{v}_0,\hfill \\ A(u_0,v_0,m_0)\ge u_0,A(v_0,u_0,v_0)\le v_0,A(m_0,v_0,u_0)\ge m_0,\hfill \\ A(u_0,v_0,u_0)\ge u_0,A(m_0,v_0,m_0)\ge m_0.\hfill \end{array}$$

(3.2)

Then A has a unique fixed point $u^{\ast }$ in $[u_0,r{v}_0]\cap [m_0,r{v}_0]$. Moreover, constructing successively the sequences

$$\begin{array}{c}{x}_n=A(x_{n-1},y_{n-1},z_{n-1}),y_n=A(y_{n-1},x_{n-1},y_{n-1}),\hfill \\ z_n=A(z_{n-1},y_{n-1},x_{n-1}),n=1,2,\dots ,\hfill \end{array}$$

for any initial values $x_0,y_0,z_0\in [u_0,r{v}_0]\cap [m_0,r{v}_0]$, we have

$$\parallel x_n-u^{\ast }\parallel \to 0,\parallel y_n-u^{\ast }\parallel \to 0,\parallel z_n-u^{\ast }\parallel \to 0$$

as $n\to \mathrm{\infty }$.

Proof Let $w_0=r{v}_0$, $\epsilon =r^{\alpha (r,v_0,u_0)-1}$. Then $w_0\ge u_0$, $\epsilon \in (0,1)$, and

$$\begin{array}{c}A(w_0,u_0,w_0)=A(r{v}_0,u_0,r{v}_0)\le r^{\alpha (r,v_0,u_0)}A(v_0,u_0,v_0)\hfill \\ \phantom{A(w_0,u_0,w_0)}\le r^{\alpha (r,v_0,u_0)}{v}_0=r^{\alpha (r,v_0,u_0)-1}\cdot r{v}_0=\epsilon w_0\le w_0,\hfill \end{array}$$

(3.3)

$$A(u_0,w_0,m_0)=A(u_0,r{v}_0,m_0)\ge A(u_0,v_0,m_0)\ge u_0,$$

(3.4)

$$A(m_0,w_0,u_0)=A(m_0,r{v}_0,u_0)\ge A(m_0,v_0,u_0)\ge m_0.$$

(3.5)

Construct successively the sequences

$$\begin{array}{c}{u}_n=A(u_{n-1},w_{n-1},m_{n-1}),w_n=A(w_{n-1},u_{n-1},w_{n-1}),m_n=A(m_{n-1},w_{n-1},u_{n-1}),\hfill \\ w_n^{\prime }=\frac{1}{\epsilon }A(w_{n-1}^{\prime },u_{n-1},w_{n-1}^{\prime }),w_0^{\prime }=w_0,n=1,2,\dots .\hfill \end{array}$$

From (3.3)-(3.5) and the mixed monotonicity of A, we have

$$u_0\le u_1\le u_2\le \cdots \le u_n\le \cdots \le w_n\le \cdots \le w_1\le w_0,$$

(3.6)

$$m_0\le m_1\le m_2\le \cdots \le m_n\le \cdots \le w_n\le \cdots \le w_1\le w_0.$$

(3.7)

Next we prove that

$$u_0\le w_n^{\prime }\le w_0.$$

(3.8)

From (3.2) and (3.3),

$$\begin{array}{c}{w}_1^{\prime }=\frac{1}{\epsilon }A(w_0,u_0,w_0)\le \frac{1}{\epsilon }\cdot \epsilon w_0=w_0,\hfill \\ w_1^{\prime }=\frac{1}{\epsilon }A(w_0,u_0,w_0)\ge \frac{1}{\epsilon }A(u_0,v_0,u_0)\ge \frac{1}{\epsilon }{u}_0\ge u_0,\hfill \\ w_2^{\prime }=\frac{1}{\epsilon }A(w_1^{\prime },u_1,w_1^{\prime })\le \frac{1}{\epsilon }A(w_0,u_0,w_0)\le \frac{1}{\epsilon }\cdot \epsilon w_0=w_0,\hfill \\ w_2^{\prime }=\frac{1}{\epsilon }A(w_1^{\prime },u_1,w_1^{\prime })\ge \frac{1}{\epsilon }A(u_0,v_0,u_0)\ge \frac{1}{\epsilon }{u}_0\ge u_0.\hfill \end{array}$$

Suppose that when $n=k$, we have

$$u_0\le w_k^{\prime }\le w_0,$$

then when $n=k+1$, note that $u_k\le w_0=r{v}_0\le v_0$, we obtain

$$\begin{array}{c}{w}_{k+1}^{\prime }=\frac{1}{\epsilon }A(w_k^{\prime },u_k,w_k^{\prime })\le \frac{1}{\epsilon }A(w_0,u_0,w_0)\le \frac{1}{\epsilon }\cdot \epsilon w_0=w_0,\hfill \\ w_{k+1}^{\prime }=\frac{1}{\epsilon }A(w_k^{\prime },u_k,w_k^{\prime })\ge \frac{1}{\epsilon }A(u_0,v_0,u_0)\ge \frac{1}{\epsilon }{u}_0\ge u_0.\hfill \end{array}$$

By mathematical induction, we know that (3.8) holds. The same procedure may easily be adapted to obtain

$$m_0\le w_n^{\prime }\le w_0.$$

(3.9)

On the other hand, from (3.1),

$$\begin{array}{c}{w}_1=A(w_0,u_0,w_0)=\epsilon \frac{1}{\epsilon }A(w_0,u_0,w_0)=\epsilon w_1^{\prime },\hfill \\ w_2=A(w_1,u_1,w_1)=A(\epsilon w_1^{\prime },u_1,\epsilon w_1^{\prime })\le {\epsilon }^{\alpha (\epsilon ,w_1^{\prime },u_1)}A(w_1^{\prime },u_1,w_1^{\prime })\hfill \\ \phantom{w_2}={\epsilon }^{\alpha (\epsilon ,w_1^{\prime },u_1)+1}\cdot \frac{1}{\epsilon }A(w_1^{\prime },u_1,w_1^{\prime })\hfill \\ \phantom{w_2}\le {\epsilon }^2{w}_2^{\prime }.\hfill \end{array}$$

Suppose that when $n=k$, we have $w_k\le {\epsilon }^k{w}_k^{\prime }$. Then when $n=k+1$, in view of (3.1), we obtain

$$\begin{array}{rcl}{w}_{k+1}& =& A(w_k,u_k,w_k)\le A({\epsilon }^k{w}_k^{\prime },u_k,{\epsilon }^k{w}_k^{\prime })\le {\left({\epsilon }^k\right)}^{\alpha ({\epsilon }^k,w_k^{\prime },u_k)}A(w_k^{\prime },u_k,w_k^{\prime })\\ =& {\epsilon }^{k\alpha ({\epsilon }^k,w_k^{\prime },u_k)+1}\cdot \frac{1}{\epsilon }A(w_k^{\prime },u_k,w_k^{\prime })\\ \le & {\epsilon }^{k+1}{w}_{k+1}^{\prime }.\end{array}$$

By mathematical induction, we have

$$w_n\le {\epsilon }^n{w}_n^{\prime },n=1,2,\dots .$$

(3.10)

By (3.6)-(3.10) we get

$$\begin{array}{c}\theta \le w_n-u_n\le {\epsilon }^n{w}_n^{\prime }-u_n\le {\epsilon }^n{w}_n^{\prime }-{\epsilon }^n{u}_n={\epsilon }^n(w_n^{\prime }-u_n)\le {\epsilon }^n(w_0-u_0),\hfill \\ \theta \le u_{n+p}-u_n\le w_n-u_n,\theta \le w_n-w_{n+p}\le w_n-u_n;\hfill \\ \theta \le w_n-m_n\le {\epsilon }^n{w}_n^{\prime }-m_n\le {\epsilon }^n{w}_n^{\prime }-{\epsilon }^n{m}_n={\epsilon }^n(w_n^{\prime }-m_n)\le {\epsilon }^n(w_0-m_0),\hfill \\ \theta \le m_{n+p}-m_n\le w_n-m_n.\hfill \end{array}$$

Noting that P is normal and $\epsilon \in (0,1)$, we have

$$\begin{array}{c}\parallel w_n-u_n\parallel \le N{\epsilon }^n\parallel w_0-u_0\parallel \to 0(\text{as }n\to \mathrm{\infty }),\hfill \\ \parallel w_n-m_n\parallel \le N{\epsilon }^n\parallel w_0-m_0\parallel \to 0(\text{as }n\to \mathrm{\infty }).\hfill \end{array}$$

Further,

$$\begin{array}{c}\parallel u_{n+p}-u_n\parallel \le N\parallel w_n-u_n\parallel \to 0(\text{as }n\to \mathrm{\infty }),\hfill \\ \parallel w_n-w_{n+p}\parallel \le N\parallel w_n-u_n\parallel \to 0(\text{as }n\to \mathrm{\infty }),\hfill \\ \parallel m_{n+p}-m_n\parallel \le N\parallel w_n-m_n\parallel \to 0(\text{as }n\to \mathrm{\infty }).\hfill \end{array}$$

Here N is the normality constant.

So, we can claim that $\{u_n\}$, $\{w_n\}$, and $\{m_n\}$ are Cauchy sequences. Since E is complete, there exist $u^{\ast },w^{\ast },m^{\ast }\in P$ such that

$$u_n\to u^{\ast },w_n\to w^{\ast },m_n\to m^{\ast }(\text{as }n\to \mathrm{\infty }).$$

By (3.6), (3.7), respectively, we know that

$$\begin{array}{c}{u}_0\le u_n\le u^{\ast }\le w^{\ast }\le w_n\le w_0,\hfill \\ m_0\le m_n\le m^{\ast }\le w^{\ast }\le w_n\le w_0,\hfill \end{array}$$

and then

$$\begin{array}{c}\theta \le w^{\ast }-u^{\ast }\le w_n-u_n\le {\epsilon }^n(w_0-u_0),\hfill \\ \theta \le w^{\ast }-m^{\ast }\le w_n-m_n\le {\epsilon }^n(w_0-m_0).\hfill \end{array}$$

Further, $\parallel w^{\ast }-u^{\ast }\parallel \le N{\epsilon }^n\parallel w_0-u_0\parallel \to 0$ (as $n\to \mathrm{\infty }$), and thus $w^{\ast }=u^{\ast }$. Similarly, we get $\parallel w^{\ast }-m^{\ast }\parallel \le N{\epsilon }^n\parallel w_0-m_0\parallel \to 0$ (as $n\to \mathrm{\infty }$), and thus $w^{\ast }=m^{\ast }$. Consequently, $w^{\ast }=u^{\ast }=m^{\ast }$. Then we obtain

$$u_{n+1}=A(u_n,w_n,m_n)\le A(u^{\ast },u^{\ast },u^{\ast })\le A(w_n,u_n,w_n)=w_{n+1}.$$

Letting $n\to \mathrm{\infty }$, then we get

$$A(u^{\ast },u^{\ast },u^{\ast })=u^{\ast }.$$

That is, $u^{\ast }$ is a fixed point of A in $[u_0,r{v}_0]\cap [m_0,r{v}_0]$.

In the following, we prove that $u^{\ast }$ is the unique fixed point of A in $[u_0,r{v}_0]\cap [m_0,r{v}_0]$. Suppose that there exists $x^{\ast }\in [u_0,r{v}_0]\cap [m_0,r{v}_0]$ such that $A(x^{\ast },x^{\ast },x^{\ast })=x^{\ast }$. Then $u_0\le x^{\ast }\le w_0$ and $m_0\le x^{\ast }\le w_0$. By mathematical induction and the mixed monotonicity of A, we have

$$u_{n+1}=A(u_n,w_n,m_n)\le x^{\ast }=A(x^{\ast },x^{\ast },x^{\ast })\le A(w_n,u_n,w_n)=w_{n+1}.$$

Then from the normality of P, we have $x^{\ast }=u^{\ast }$.

Moreover, constructing successively the sequences

$$\begin{array}{c}{x}_n=A(x_{n-1},y_{n-1},z_{n-1}),y_n=A(y_{n-1},x_{n-1},y_{n-1}),\hfill \\ z_n=A(z_{n-1},y_{n-1},x_{n-1}),n=1,2,\dots ,\hfill \end{array}$$

for any initial values $x_0,y_0,z_0\in [u_0,r{v}_0]\cap [m_0,r{v}_0]$, we have $u_n\le x_n$, $w_n\ge y_n$, $m_n\le z_n$, $n=1,2,\dots$ . Letting $n\to \mathrm{\infty }$ yields $x_n\to u^{\ast }$, $y_n\to u^{\ast }$, $z_n\to u^{\ast }$ as $n\to \mathrm{\infty }$. □

Remark 3.1 It is evident from (3.1) that for $t\in (0,1)$, $x,y\in P$, there exists $\alpha (t,\frac{1}{t}x,y)\in (1,+\mathrm{\infty })$, such that

$$A(\frac{1}{t}x,y,\frac{1}{t}x)\ge \frac{1}{t^{\alpha (t,\frac{1}{t}x,y)}}A(x,y,x).$$

(3.11)

Remark 3.2 Let $\alpha (t,x,y)$ be a constant $\alpha \in (1,+\mathrm{\infty })$, then Theorem 3.1 also holds.

Corollary 3.2 Let E be a real Banach space and let P be a normal cone in E. $A:P\times P\times P\to P$ is a mixed monotone ternary operator which satisfies (H₂) and, for $t\in (0,1)$, $x,y\in P$, there exists $\alpha \in (1,+\mathrm{\infty })$, such that $A(tx,y,tx)\le t^{\alpha }A(x,y,x)$. Then A has a unique fixed point $u^{\ast }$ in $[u_0,r{v}_0]\cap [m_0,r{v}_0]$. Moreover, constructing successively the sequences

$$\begin{array}{c}{x}_n=A(x_{n-1},y_{n-1},z_{n-1}),y_n=A(y_{n-1},x_{n-1},y_{n-1}),\hfill \\ z_n=A(z_{n-1},y_{n-1},x_{n-1}),n=1,2,\dots ,\hfill \end{array}$$

for any initial values $x_0,y_0,z_0\in [u_0,r{v}_0]\cap [m_0,r{v}_0]$, we have $u_n\le x_n$, $w_n\ge y_n$, $m_n\le z_n$, $n=1,2,\dots$ . Letting $n\to \mathrm{\infty }$ yields $x_n\to u^{\ast }$, $y_n\to u^{\ast }$, $z_n\to u^{\ast }$ as $n\to \mathrm{\infty }$.

Following the lines of the proof of Theorem 3.1, we obtain an immediate consequence.

Corollary 3.3 (see [11])

Let E be a real Banach space and let P be a normal cone in E. $A:P\times P\to P$ is a mixed monotone operator which satisfies the following:

(H₃) for $t\in (0,1)$, $x,y\in P$, there exists $\alpha (t,x,y)\in (1,+\mathrm{\infty })$, such that

$$A(tx,y)\le t^{\alpha (t,x,y)}A(x,y);$$

(H₄) there exist $u_0,v_0\in P$, $r\in (0,1)$, such that

$$u_0\le r{v}_0,A(u_0,v_0)\ge u_0,A(v_0,u_0)\le v_0.$$

Then A has a unique fixed point $u^{\ast }$ in $[u_0,r{v}_0]$. Moreover, constructing successively the sequences

$$x_n=A(x_{n-1},y_{n-1}),y_n=A(y_{n-1},x_{n-1}),n=1,2,\dots ,$$

for any initial values $x_0,y_0\in [u_0,r{v}_0]$, we have

$$\parallel x_n-u^{\ast }\parallel \to 0,\parallel y_n-u^{\ast }\parallel \to 0$$

as $n\to \mathrm{\infty }$.

Theorem 3.4 Let E be a real Banach space and let P be a normal cone in E. $A:P\times P\times P\to P$ is a mixed monotone ternary operator which satisfies (3.1) and

(H₅) for $R\in (1,+\mathrm{\infty })$, $x,y,z\in P$ there exist $\alpha (\frac{1}{R},Rx,y,z),\alpha (\frac{1}{R},x,y,Rz)\in (1,+\mathrm{\infty })$ such that

$$A(Rx,y,z)\ge R^{\alpha (\frac{1}{R},Rx,y,z)}A(x,y,z),$$

(3.12)

$$A(x,y,Rz)\ge R^{\alpha (\frac{1}{R},x,y,Rz)}A(x,y,z);$$

(3.13)

(H₆) there exist $u_0,v_0,m_0\in P$, $R\in (1,+\mathrm{\infty })$, such that

$$\begin{array}{c}{v}_0\ge R{u}_0,v_0\ge R{m}_0,\hfill \\ A(u_0,v_0,m_0)\ge u_0,A(v_0,u_0,v_0)\le v_0,A(m_0,v_0,u_0)\ge m_0,\hfill \\ A(u_0,v_0,u_0)\ge u_0,A(m_0,v_0,m_0)\ge m_0.\hfill \end{array}$$

(3.14)

Then the operator equation $A(w,w,w)=bw$ has a unique solution $w^{\ast }$ in $[R{u}_0,v_0]\cap [R{m}_0,v_0]$, where $b=min\{R^{\alpha (\frac{1}{R},R{u}_0,v_0,m_0)-1},R^{\alpha (\frac{1}{R},m_0,v_0,R{u}_0)-1}\}$. Moreover, constructing successively the sequences

$$\begin{array}{c}{x}_n=b^{-1}A(x_{n-1},y_{n-1},z_{n-1}),y_n=b^{-1}A(y_{n-1},x_{n-1},y_{n-1}),\hfill \\ z_n=b^{-1}A(z_{n-1},y_{n-1},x_{n-1}),n=1,2,\dots ,\hfill \end{array}$$

for any initial values $x_0,y_0,z_0\in [R{u}_0,v_0]\cap [R{m}_0,v_0]$, we have

$$\parallel x_n-w^{\ast }\parallel \to 0,\parallel y_n-w^{\ast }\parallel \to 0,\parallel z_n-w^{\ast }\parallel \to 0$$

as $n\to \mathrm{\infty }$.

Remark 3.3 Two comments with respect to conditions (3.12) and (3.13) are in order:

1. (a)

   A sufficient condition on A for (3.12) to be satisfied is that for $t\in (0,1)$, $x,y,z\in P$, there exists $\alpha (t,x,y,z)\in (1,+\mathrm{\infty })$, such that

   $$A(tx,y,z)\le t^{\alpha (t,x,y,z)}A(x,y,z).$$
2. (b)

   A sufficient condition on A for (3.13) to be satisfied is that for $t\in (0,1)$, $x,y,z\in P$, there exists $\alpha (t,x,y,z)\in (1,+\mathrm{\infty })$, such that

   $$A(x,y,tz)\le t^{\alpha (t,x,y,z)}A(x,y,z).$$

Proof of Theorem 3.4 Let $w_0=R{u}_0$. Then $v_0\ge w_0$. Note that $b>1$, from (3.12)-(3.14),

$$\begin{array}{c}A(w_0,v_0,m_0)=A(R{u}_0,v_0,m_0)\ge R^{\alpha (\frac{1}{R},R{u}_0,v_0,m_0)}A(u_0,v_0,m_0)\hfill \\ \phantom{A(w_0,v_0,m_0)}=R^{\alpha (\frac{1}{R},R{u}_0,v_0,m_0)-1}RA(u_0,v_0,m_0)\ge bR{u}_0=b{w}_0\ge w_0,\hfill \end{array}$$

(3.15)

$$A(v_0,w_0,v_0)=A(v_0,R{u}_0,v_0)\le A(v_0,u_0,v_0)\le v_0,$$

(3.16)

$$\begin{array}{c}A(m_0,v_0,w_0)=A(m_0,v_0,R{u}_0)\ge R^{\alpha (\frac{1}{R},m_0,v_0,R{u}_0)}A(m_0,v_0,u_0)\hfill \\ \phantom{A(m_0,v_0,w_0)}=R^{\alpha (\frac{1}{R},m_0,v_0,R{u}_0)-1}RA(m_0,v_0,u_0)\ge bA(m_0,v_0,u_0)\ge b{m}_0\ge m_0.\hfill \end{array}$$

(3.17)

Set $B(x,y,z)=b^{-1}A(x,y,z)$, $x,y,z\in P$. Then from the above inequalities, we have

$$\begin{array}{c}B(w_0,v_0,m_0)=b^{-1}A(w_0,v_0,m_0)\ge b^{-1}b{w}_0=w_0,\hfill \\ B(v_0,w_0,v_0)=b^{-1}A(v_0,w_0,v_0)\le b^{-1}{v}_0\le v_0,\hfill \\ B(m_0,v_0,w_0)=b^{-1}A(m_0,v_0,w_0)\ge b^{-1}b{m}_0=m_0.\hfill \end{array}$$

(3.18)

Also, construct successively the sequences

$$\begin{array}{c}{w}_n=B(w_{n-1},v_{n-1},m_{n-1}),v_n=B(v_{n-1},w_{n-1},v_{n-1}),m_n=B(m_{n-1},v_{n-1},w_{n-1}),\hfill \\ v_n^{\prime }=bB(v_{n-1}^{\prime },w_{n-1},v_{n-1}^{\prime }),v_0^{\prime }=v_0,n=1,2,\dots .\hfill \end{array}$$

From (3.18) and the mixed monotonicity of A, we have

$$w_0\le w_1\le w_2\le \cdots \le w_n\le \cdots \le v_n\le \cdots \le v_1\le v_0,$$

(3.19)

$$m_0\le m_1\le m_2\le \cdots \le m_n\le \cdots \le v_n\le \cdots \le v_1\le v_0.$$

(3.20)

Next we prove that

$$w_0\le v_n^{\prime }\le v_0,n=1,2,\dots .$$

(3.21)

By (3.11) and (3.14), we have

$$\begin{array}{rcl}A(w_0,v_0,w_0)& =& A(R{u}_0,v_0,R{u}_0)\ge R^{\alpha (\frac{1}{R},R{u}_0,v_0)}A(u_0,v_0,u_0)\\ \ge & RA(u_0,v_0,u_0)\\ \ge & R{u}_0\\ =& w_0.\end{array}$$

(3.22)

From (3.15)-(3.17) and (3.22),

$$\begin{array}{r}{v}_1^{\prime }=bB(v_0^{\prime },w_0,v_0^{\prime })=bB(v_0,w_0,v_0)=A(v_0,w_0,v_0)\le v_0,\\ v_1^{\prime }=bB(v_0^{\prime },w_0,v_0^{\prime })=bB(v_0,w_0,v_0)\ge bB(w_0,v_0,m_0)=A(w_0,v_0,m_0)\ge w_0,\\ v_2^{\prime }=bB(v_1^{\prime },w_1,v_1^{\prime })\le bB(v_0,w_0,v_0)=A(v_0,w_0,v_0)\le v_0,\\ v_2^{\prime }=bB(v_1^{\prime },w_1,v_1^{\prime })\ge bB(w_0,v_0,w_0)=A(w_0,v_0,w_0)=A(R{u}_0,v_0,R{u}_0)\ge w_0.\end{array}$$

Suppose that when $n=k$, we have

$$w_0\le v_k^{\prime }\le v_0,$$

then when $n=k+1$, recalling (3.16) and (3.22), we obtain

$$\begin{array}{c}{v}_{k+1}^{\prime }=bB(v_k^{\prime },w_k,v_k^{\prime })\le bB(v_0,w_0,v_0)=A(v_0,w_0,v_0)\le v_0,\hfill \\ v_{k+1}^{\prime }=bB(v_k^{\prime },w_k,v_k^{\prime })\ge bB(w_0,v_0,w_0)=A(w_0,v_0,w_0)=A(R{u}_0,v_0,R{u}_0)\ge w_0.\hfill \end{array}$$

By mathematical induction, we know that (3.21) holds. The same procedure may easily be adapted to obtain

$$m_0\le v_n^{\prime }\le v_0,n=1,2,\dots .$$

(3.23)

On the other hand, from (3.1),

$$\begin{array}{c}{v}_1=B(v_0,w_0,v_0)=\frac{1}{b}bB(v_0,w_0,v_0)=\frac{1}{b}bB(v_0^{\prime },w_0,v_0^{\prime })=\frac{1}{b}{v}_1^{\prime },\hfill \\ v_2=B(v_1,w_1,v_1)=B(\frac{1}{b}{v}_1^{\prime },w_1,\frac{1}{b}{v}_1^{\prime })\le {\left(\frac{1}{b}\right)}^{\alpha (\frac{1}{b},v_1^{\prime },w_1)}B(v_1^{\prime },w_1,v_1^{\prime })\hfill \\ \phantom{v_2}={\left(\frac{1}{b}\right)}^{\alpha (\frac{1}{b},v_1^{\prime },w_1)+1}bB(v_1^{\prime },w_1,v_1^{\prime })\le {\left(\frac{1}{b}\right)}^2{v}_2^{\prime }.\hfill \end{array}$$

Suppose that when $n=k$, we have $v_k\le {(\frac{1}{b})}^k{v}_k^{\prime }$. Then when $n=k+1$, in view of (3.1), we obtain

$$\begin{array}{rcl}{v}_{k+1}& =& B(v_k,w_k,v_k)\le B({\left(\frac{1}{b}\right)}^k{v}_k^{\prime },w_k,{\left(\frac{1}{b}\right)}^k{v}_k^{\prime })\\ \le & {\left({\left(\frac{1}{b}\right)}^k\right)}^{\alpha ({(\frac{1}{b})}^k,v_k^{\prime },w_k)}B(v_k^{\prime },w_k,v_k^{\prime })\\ \le & {\left(\frac{1}{b}\right)}^{k\alpha ({(\frac{1}{b})}^k,v_k^{\prime },w_k)+1}bB(v_k^{\prime },w_k,v_k^{\prime })\\ \le & {\left(\frac{1}{b}\right)}^{k+1}{v}_{k+1}^{\prime }.\end{array}$$

By mathematical induction, we have

$$v_n\le {\left(\frac{1}{b}\right)}^n{v}_n^{\prime },n=1,2,\dots .$$

(3.24)

By (3.19)-(3.24) we get

$$\begin{array}{c}\theta \le v_n-w_n\le {\left(\frac{1}{b}\right)}^n{v}_n^{\prime }-w_n\le {\left(\frac{1}{b}\right)}^n{v}_n^{\prime }-{\left(\frac{1}{b}\right)}^n{w}_n\hfill \\ \phantom{\theta }={\left(\frac{1}{b}\right)}^n(v_n^{\prime }-w_n)\le {\left(\frac{1}{b}\right)}^n(v_0-w_0),\hfill \\ \theta \le w_{n+p}-w_n\le v_n-w_n,\theta \le v_n-v_{n+p}\le v_n-w_n;\hfill \\ \theta \le v_n-m_n\le {\left(\frac{1}{b}\right)}^n{v}_n^{\prime }-m_n\le {\left(\frac{1}{b}\right)}^n{v}_n^{\prime }-{\left(\frac{1}{b}\right)}^n{m}_n\hfill \\ \phantom{\theta }={\left(\frac{1}{b}\right)}^n(v_n^{\prime }-m_n)\le {\left(\frac{1}{b}\right)}^n(v_0-m_0),\hfill \\ \theta \le m_{n+p}-m_n\le v_n-m_n,\theta \le v_n-v_{n+p}\le v_n-m_n.\hfill \end{array}$$

Note that P is normal and $b>1$, we have

$$\begin{array}{c}\parallel v_n-w_n\parallel \le N{\left(\frac{1}{b}\right)}^n\parallel v_0-w_0\parallel \to 0(\text{as }n\to \mathrm{\infty }),\hfill \\ \parallel v_n-m_n\parallel \le N{\left(\frac{1}{b}\right)}^n\parallel v_0-m_0\parallel \to 0(\text{as }n\to \mathrm{\infty }).\hfill \end{array}$$

Further,

$$\begin{array}{c}\parallel w_{n+p}-w_n\parallel \le N\parallel v_n-w_n\parallel \to 0(\text{as }n\to \mathrm{\infty }),\hfill \\ \parallel v_n-v_{n+p}\parallel \le N\parallel v_n-w_n\parallel \to 0(\text{as }n\to \mathrm{\infty }),\hfill \\ \parallel m_{n+p}-m_n\parallel \le N\parallel v_n-m_n\parallel \to 0(\text{as }n\to \mathrm{\infty }).\hfill \end{array}$$

Here N is the normality constant.

So, we can claim that $\{w_n\}$, $\{v_n\}$, and $\{m_n\}$ are Cauchy sequences. Since E is complete, there exist $w^{\ast },v^{\ast },m^{\ast }\in P$ such that

$$w_n\to w^{\ast },v_n\to v^{\ast },m_n\to m^{\ast }(\text{as }n\to \mathrm{\infty }).$$

By (3.19), (3.20), respectively, we know that

$$\begin{array}{c}{w}_0\le w_n\le w^{\ast }\le v^{\ast }\le v_n\le v_0,\hfill \\ m_0\le m_n\le m^{\ast }\le v^{\ast }\le v_n\le v_0,\hfill \end{array}$$

and then

$$\begin{array}{c}\theta \le v^{\ast }-w^{\ast }\le v_n-w_n\le {\left(\frac{1}{b}\right)}^n(v_0-w_0),\hfill \\ \theta \le v^{\ast }-m^{\ast }\le v_n-m_n\le {\left(\frac{1}{b}\right)}^n(v_0-m_0).\hfill \end{array}$$

Further, $\parallel v^{\ast }-w^{\ast }\parallel \le N{(\frac{1}{b})}^n\parallel v_0-w_0\parallel \to 0$ (as $n\to \mathrm{\infty }$), and thus $v^{\ast }=w^{\ast }$. Similarly, we get $\parallel v^{\ast }-m^{\ast }\parallel \le N{(\frac{1}{b})}^n\parallel v_0-m_0\parallel \to 0$ (as $n\to \mathrm{\infty }$), and thus $v^{\ast }=m^{\ast }$. Consequently, $w^{\ast }=v^{\ast }=m^{\ast }$. Then we obtain

$$w_{n+1}=B(w_n,v_n,m_n)\le B(w^{\ast },w^{\ast },w^{\ast })\le B(v_n,w_n,v_n)=v_{n+1}.$$

Letting $n\to \mathrm{\infty }$, we get

$$B(w^{\ast },w^{\ast },w^{\ast })=w^{\ast }.$$

That is, the operator equation $A(w,w,w)=bw$ has a unique solution $w^{\ast }$ in $[R{u}_0,v_0]\cap [R{m}_0,v_0]$.

In the following, we prove that $w^{\ast }$ is the unique solution of $A(w,w,w)=bw$ in $[R{u}_0,v_0]\cap [R{m}_0,v_0]$. Suppose that there exists $x^{\ast }\in [R{u}_0,v_0]\cap [R{m}_0,v_0]$ such that $A(x^{\ast },x^{\ast },x^{\ast })=b{x}^{\ast }$. Then $w_0\le x^{\ast }\le v_0$ and $m_0\le x^{\ast }\le v_0$. By mathematical induction and the mixed monotonicity of A, we have

$$w_{n+1}=B(w_n,v_n,m_n)\le x^{\ast }=B(x^{\ast },x^{\ast },x^{\ast })\le B(v_n,w_n,v_n)=v_{n+1}.$$

Then from the normality of P, we have $x^{\ast }=w^{\ast }$.

Moreover, constructing successively the sequences

$$\begin{array}{c}{x}_n=b^{-1}A(x_{n-1},y_{n-1},z_{n-1}),y_n=b^{-1}A(y_{n-1},x_{n-1},y_{n-1}),\hfill \\ z_n=b^{-1}A(z_{n-1},y_{n-1},x_{n-1}),n=1,2,\dots ,\hfill \end{array}$$

for any initial values $x_0,y_0,z_0\in [R{u}_0,v_0]\cap [R{m}_0,v_0]$, we have $w_n\le x_n$, $v_n\ge y_n$, $m_n\le z_n$, $n=1,2,\dots$ . Letting $n\to \mathrm{\infty }$ yields $x_n\to w^{\ast }$, $y_n\to w^{\ast }$, $z_n\to w^{\ast }$ as $n\to \mathrm{\infty }$. □

From the proof of Theorem 3.4, we can easily obtain the following conclusion.

Corollary 3.5 (see [11])

Let E be a real Banach space and let P be a normal cone in E. $A:P\times P\to P$ is a mixed monotone operator which satisfies (H₃) and

(H₇) there exist $u_0,v_0\in P$, $R\in (1,+\mathrm{\infty })$ such that

$$v_0\ge R{u}_0,A(u_0,v_0)\ge u_0,A(v_0,u_0)\le v_0.$$

Then the operator equation $A(w,w)=bw$ has a unique solution $w^{\ast }$ in $[R{u}_0,v_0]$, where $b=R^{\alpha (\frac{1}{R},R{u}_0,v_0)-1}$. Moreover, constructing successively the sequences

$$x_n=b^{-1}A(x_{n-1},y_{n-1}),y_n=b^{-1}A(y_{n-1},x_{n-1}),n=1,2,\dots ,$$

for any initial values $x_0,y_0\in [R{u}_0,v_0]$, we have

$$\parallel x_n-w^{\ast }\parallel \to 0,\parallel y_n-w^{\ast }\parallel \to 0$$

as $n\to \mathrm{\infty }$.

4 Application

As application of our results, we investigate the solvability of the following integral equation:

$$x(\tau )={\int }_0^{1}k(\tau ,s)[\frac{x^{{\alpha }_1}(s)}{1+x^{{\alpha }_2}(s)}+x^{{\alpha }_3}(s)]\mathrm{d}s$$

(4.1)

with ${\alpha }_1,{\alpha }_3>1$, ${\alpha }_2>0$.

Put $E=C[0,1]$ (the space of continuous functions defined on $[0,1]$ endowed with supremum norm). Let $P=\{x\in E\mid x(t)\ge 0,\mathrm{\forall }t\in [0,1]\}$, then E is a Banach space and P is a normal cone. Suppose that $k(\tau ,s):[0,1]\times [0,1]\to R^{++}$ ($R^{++}$ denotes the positive real numbers) is continuous and $0<{\int }_0^{1}k(\tau ,s)\mathrm{d}s\le \frac{1}{2}$. In the following, we prove that (4.1) has a unique solution.

Consider the integral operator $A:P\times P\times P\to P$ defined by

$$A(u,v,m)={\int }_0^{1}k(\tau ,s)[\frac{u^{{\alpha }_1}(s)}{1+v^{{\alpha }_2}(s)}+m^{{\alpha }_3}(s)]\mathrm{d}s$$

with ${\alpha }_1,{\alpha }_3>1$, ${\alpha }_2>0$.

It is clear that $A(u,v,m)$ is a mixed monotone ternary operator. We shall show that $A(u,v,m)$ satisfies (H₂) and for $t\in (0,1)$, $x,y\in P$, there exists $\alpha \in (1,+\mathrm{\infty })$, such that $A(tx,y,tx)\le t^{\alpha }A(x,y,x)$.

In fact, let $u_0(\tau )\equiv 0$, $m_0(\tau )\equiv 0$, $v_0(\tau )\equiv 1$, then

$$\begin{array}{c}A(u_0,v_0,u_0)=0\ge u_0,\hfill \\ A(v_0,u_0,v_0)=2{\int }_0^{1}k(\tau ,s)\mathrm{d}s\le 1.\hfill \end{array}$$

On the other hand, noting that for any $t\in (0,1)$, letting

$$\alpha =min\{{\alpha }_1,{\alpha }_3\}>1,$$

we obtain

$$\begin{array}{rcl}A(tx,y,tx)& =& {\int }_0^{1}k(\tau ,s)[\frac{t^{{\alpha }_1}{x}^{{\alpha }_1}(s)}{1+y^{{\alpha }_2}(s)}+t^{{\alpha }_3}{x}^{{\alpha }_3}(s)]\mathrm{d}s\\ \le & {\int }_0^{1}k(\tau ,s)[\frac{t^{\alpha }{x}^{{\alpha }_1}(s)}{1+y^{{\alpha }_2}(s)}+t^{\alpha }{x}^{{\alpha }_3}(s)]\mathrm{d}s\\ =& t^{\alpha }{\int }_0^{1}k(\tau ,s)[\frac{x^{{\alpha }_1}(s)}{1+y^{{\alpha }_2}(s)}+x^{{\alpha }_3}(s)]\mathrm{d}s\\ =& t^{\alpha }A(x,y,x).\end{array}$$

Hence, all the hypotheses of Corollary 3.2 are satisfied. The operator

$$A(u,v,m)={\int }_0^{1}k(\tau ,s)[\frac{u^{{\alpha }_1}(s)}{1+v^{{\alpha }_2}(s)}+m^{{\alpha }_3}(s)]\mathrm{d}s$$

has a unique fixed point in $[u_0,v_0]$, i.e., the integral equation (4.1) has a unique solution in $[u_0,v_0]$.