Some fixed point theorems for rational Geraghty contractive mappings in ordered b-metric spaces

Shahkoohi, Rogheieh J; Razani, Abdolrahman

doi:10.1186/1029-242X-2014-373

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Published: 26 September 2014

Some fixed point theorems for rational Geraghty contractive mappings in ordered b-metric spaces

Rogheieh J Shahkoohi¹ &
Abdolrahman Razani¹

Journal of Inequalities and Applications volume 2014, Article number: 373 (2014) Cite this article

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Abstract

In this paper, new classes of rational Geraghty contractive mappings in the setup of b-metric spaces are introduced. Moreover, the existence of some fixed point for such mappings in ordered b-metric spaces are investigated. Also, some examples are provided to illustrate the results presented herein. Finally, an application of the main result is given.

MSC:47H10, 54H25.

1 Introduction

Using different forms of contractive conditions in various generalized metric spaces, there is a large number of extensions of the Banach contraction principle [1]. Some of such generalizations are obtained via rational contractive conditions. Recently, Azam et al. [2] established some fixed point results for a pair of rational contractive mappings in complex valued metric spaces. Also, in [3], Nashine et al. proved some common fixed point theorems for a pair of mappings satisfying certain rational contractions in the framework of complex valued metric spaces. In [4], the authors proved some unique fixed point results for an operator T satisfying certain rational contractive condition in a partially ordered metric space. In fact, their results generalize the main result of Jaggi [5].

Ran and Reurings started the studying of fixed point results on partially ordered sets in [6], where they gave many useful results in matrix equations. Recently, many researchers have focused on different contractive conditions in complete metric spaces endowed with a partial order and obtained many fixed point results in such spaces. For more details on fixed point results in ordered metric spaces we refer the reader to [7, 8] and [9].

Czerwik in [10] introduced the concept of a b-metric space. Since then, several papers dealt with fixed point theory for single-valued and multi-valued operators in b-metric spaces (see, e.g., [11–16] and [17, 18]).

Definition 1 Let X be a (nonempty) set and $s \geq 1$ be a given real number. A function $d : X \times X \to R^{+}$ is a b-metric if the following conditions are satisfied:

(b₁) $d (x, y) = 0$ iff $x = y$ ,

(b₂) $d (x, y) = d (y, x)$ ,

(b₃) $d (x, z) \leq s [d (x, y) + d (y, z)]$

for all $x, y, z \in X$ .

In this case, the pair $(X, d)$ is called a b-metric space.

Definition 2 [19]

Let $(X, d)$ be a b-metric space.

(a)
A sequence ${x_{n}}$ in X is called b-convergent if and only if there exists $x \in X$ such that $d (x_{n}, x) \to 0$ as $n \to \infty$ .
(b)
${x_{n}}$ in X is said to be b-Cauchy if and only if $d (x_{n}, x_{m}) \to 0$ , as $n, m \to \infty$ .
(c)
The b-metric space $(X, d)$ is called b-complete if every b-Cauchy sequence in X is b-convergent.

The following example (corrected from [20]) illustrates that a b-metric need not be a continuous function.

Example 1 Let $X = N \cup {\infty}$ and $d : X \times X \to R$ be defined by

d (m, n) = {\begin{matrix} 0, & if m = n, \\ | \frac{1}{m} - \frac{1}{n} |, & if one of m, n is even and the other is even or \infty, \\ 5, & if one of m, n is odd and the other is odd (and m \neq n) or \infty, \\ 2, & otherwise . \end{matrix}

Then $d (m, p) \leq \frac{5}{2} (d (m, n) + d (n, p))$ for all $m, n, p \in X$ . Thus, $(X, d)$ is a b-metric space (with $s = 5 / 2$ ). Let $x_{n} = 2 n$ for each $n \in N$ . So $d (2 n, \infty) = \frac{1}{2 n} \to 0$ as $n \to \infty$ that is, $x_{n} \to \infty$ , but $d (x_{n}, 1) = 2 ↛ 5 = d (\infty, 1)$ as $n \to \infty$ .

Lemma 1 [21]

Let $(X, d)$ be a b-metric space with $s \geq 1$ , and suppose that ${x_{n}}$ and ${y_{n}}$ are b-convergent to x and y, respectively. Then

\frac{1}{s^{2}} d (x, y) \leq \underset{n \to \infty}{lim inf} d (x_{n}, y_{n}) \leq \underset{n \to \infty}{lim sup} d (x_{n}, y_{n}) \leq s^{2} d (x, y) .

Moreover, for each $z \in X$ , we have

\frac{1}{s} d (x, z) \leq \underset{n \to \infty}{lim inf} d (x_{n}, z) \leq \underset{n \to \infty}{lim sup} d (x_{n}, z) \leq s d (x, z) .

Let $S$ denote the class of all real functions $β : [0, + \infty) \to [0, 1)$ satisfying the condition

β (t_{n}) \to 1 implies that t_{n} \to 0, as n \to \infty .

In order to generalize the Banach contraction principle, Geraghty proved the following.

Theorem 1 [22]

Let $(X, d)$ be a complete metric space, and let $f : X \to X$ be a self-map. Suppose that there exists $β \in S$ such that

d (f x, f y) \leq β (d (x, y)) d (x, y)

holds for all $x, y \in X$ . Then f has a unique fixed point $z \in X$ and for each $x \in X$ the Picard sequence ${f^{n} x}$ converges to z.

Amini-Harandi and Emami [23] generalized the result of Geraghty to the framework of a partially ordered complete metric space as follows.

Theorem 2 Let $(X, d, ⪯)$ be a complete partially ordered metric space. Let $f : X \to X$ be an increasing self-map such that there exists $x_{0} \in X$ with $x_{0} ⪯ f x_{0}$ . Suppose that there exists $β \in S$ such that

d (f x, f y) \leq β (d (x, y)) d (x, y)

holds for all $x, y \in X$ with $y ⪯ x$ . Assume that either f is continuous or X is such that if an increasing sequence ${x_{n}}$ in X converges to $x \in X$ , then $x_{n} ⪯ x$ for all n. Then f has a fixed point in X. Moreover, if for each $x, y \in X$ there exists $z \in X$ comparable with x and y, then the fixed point of f is unique.

In [24], some fixed point theorems for mappings satisfying Geraghty-type contractive conditions are proved in various generalized metric spaces. As in [24], we will consider the class ℱ of functions $β : [0, \infty) \to [0, 1 / s)$ such that

β (t_{n}) \to \frac{1}{s} implies that t_{n} \to 0, as n \to \infty .

Theorem 3 [24]

Let $s > 1$ , and let $(X, D, s)$ be a complete metric type space. Suppose that a mapping $f : X \to X$ satisfies the condition

D (f x, f y) \leq β (D (x, y)) D (x, y)

for all $x, y \in X$ and some $β \in F$ . Then f has a unique fixed point $z \in X$ , and for each $x \in X$ the Picard sequence ${f^{n} x}$ converges to z in $(X, D, s)$ .

Also, by unification of the recent results obtained by Zabihi and Razani [25] we have the following result.

Theorem 4 Let $(X, ⪯)$ be a partially ordered set and suppose that there exists a b-metric d on X such that $(X, d)$ is a b-complete b-metric space (with parameter $s > 1$ ). Let $f : X \to X$ be an increasing mapping with respect to ⪯ such that there exists an element $x_{0} \in X$ with $x_{0} ⪯ f (x_{0})$ . Suppose there exists $β \in F$ such that

s d (f x, f y) \leq β (d (x, y)) M (x, y) + L N (x, y)

(1.1)

for all comparable elements $x, y \in X$ , where $L \geq 0$ ,

M (x, y) = max {d (x, y), \frac{d (x, f x) d (y, f y)}{1 + d (f x, f y)}}

and

N (x, y) = min {d (x, f x), d (x, f y), d (y, f x), d (y, f y)} .

If f is continuous, or, whenever ${x_{n}}$ is a nondecreasing sequence in X such that $x_{n} \to u \in X$ , one has $x_{n} ⪯ u$ for all $n \in N$ , then f has a fixed point. Moreover, the set of fixed points of f is well ordered if and only if f has one and only one fixed point.

The aim of this paper is to present some fixed point theorems for rational Geraghty contractive mappings in partially ordered b-metric spaces. Our results extend some existing results in the literature.

2 Main results

Let ℱ denotes the class of all functions $β : [0, \infty) \to [0, \frac{1}{s})$ satisfying the following condition:

\underset{n \to \infty}{lim sup} β (t_{n}) = \frac{1}{s} implies that t_{n} \to 0, as n \to \infty .

Definition 3 Let $(X, d, ⪯)$ be a b-metric space. A mapping $f : X \to X$ is called a rational Geraghty contraction of type I if there exists $β \in F$ such that

d (f x, f y) \leq β (M (x, y)) M (x, y)

(2.1)

for all comparable elements $x, y \in X$ , where

M (x, y) = max {d (x, y), \frac{d (x, f x) d (y, f y)}{1 + d (x, y)}, \frac{d (x, f x) d (y, f y)}{1 + d (f x, f y)}} .

Theorem 5 Let $(X, ⪯)$ be a partially ordered set and suppose there exists a b-metric d on X such that $(X, d)$ is a b-complete b-metric space (with parameter $s > 1$ ). Let $f : X \to X$ be an increasing mapping with respect to ⪯ such that there exists an element $x_{0} \in X$ with $x_{0} ⪯ f (x_{0})$ . Suppose f is a rational Geraghty contraction of type I. If

(I)
f is continuous, or,
(II)
whenever ${x_{n}}$ is a nondecreasing sequence in X such that $x_{n} \to u \in X$ , one has $x_{n} ⪯ u$ for all $n \in N$ ,

then f has a fixed point.

Moreover, the set of fixed points of f is well ordered if and only if f has one and only one fixed point.

Proof Let $x_{n} = f^{n} (x_{0})$ for all $n \geq 0$ . Since $x_{0} ⪯ f (x_{0})$ and f is increasing, we obtain by induction that

x_{0} ⪯ f (x_{0}) ⪯ f^{2} (x_{0}) ⪯ \dots ⪯ f^{n} (x_{0}) ⪯ f^{n + 1} (x_{0}) ⪯ \dots .

We do the proof in the following steps.

Step I: We show that ${lim}_{n \to \infty} d (x_{n}, x_{n + 1}) = 0$ . Since $x_{n} ⪯ x_{n + 1}$ for each $n \in N$ , then by (2.1)

\begin{aligned} d (x_{n}, x_{n + 1}) & = d (f x_{n - 1}, f x_{n}) \\ \leq β (M (x_{n - 1}, x_{n})) M (x_{n - 1}, x_{n}), \end{aligned}

(2.2)

where

\begin{array}{rcl} M (x_{n - 1}, x_{n}) & = & max {d (x_{n - 1}, x_{n}), \frac{d (x_{n - 1}, f x_{n - 1}) d (x_{n}, f x_{n})}{1 + d (x_{n - 1}, x_{n})}, \\ \frac{d (x_{n - 1}, f x_{n - 1}) d (x_{n}, f x_{n})}{1 + d (f x_{n - 1}, f x_{n})}} \\ = & max {d (x_{n - 1}, x_{n}), \frac{d (x_{n - 1}, x_{n}) d (x_{n}, x_{n + 1})}{1 + d (x_{n - 1}, x_{n})}, \frac{d (x_{n - 1}, x_{n}) d (x_{n}, x_{n + 1})}{1 + d (x_{n}, x_{n + 1})}} \\ \leq & max {d (x_{n - 1}, x_{n}), d (x_{n}, x_{n + 1})} . \end{array}

If $max {d (x_{n - 1}, x_{n}), d (x_{n}, x_{n + 1})} = d (x_{n}, x_{n + 1})$ , then from (2.2),

\begin{aligned} d (x_{n}, x_{n + 1}) & \leq β (M (x_{n}, x_{n + 1})) d (x_{n}, x_{n + 1}) \\ < \frac{1}{s} d (x_{n}, x_{n + 1}) \\ < d (x_{n}, x_{n + 1}), \end{aligned}

(2.3)

which is a contradiction.

Hence, $max {d (x_{n - 1}, x_{n}), d (x_{n}, x_{n + 1})} = d (x_{n - 1}, x_{n})$ , so from (2.2),

d (x_{n}, x_{n + 1}) \leq β (M (x_{n - 1}, x_{n})) d (x_{n - 1}, x_{n}) .

(2.4)

Since ${d (x_{n}, x_{n + 1})}$ is a decreasing sequence, then there exists $r \geq 0$ such that ${lim}_{n \to \infty} d (x_{n}, x_{n + 1}) = r$ . We prove $r = 0$ . Suppose on contrary that $r > 0$ . Then, letting $n \to \infty$ , from (2.4) we have

r \leq lim_{n \to \infty} β (M (x_{n - 1}, x_{n})) r,

which implies that $\frac{1}{s} \leq 1 \leq {lim}_{n \to \infty} β (M (x_{n - 1}, x_{n}))$ . Now, as $β \in F$ we conclude that $M (x_{n - 1}, x_{n}) \to 0$ , which yields $r = 0$ , a contradiction. Hence, $r = 0$ . That is,

lim_{n \to \infty} d (x_{n - 1}, x_{n}) = 0 .

(2.5)

Step II: Now, we prove that the sequence ${x_{n}}$ is a b-Cauchy sequence. Suppose the contrary, i.e., ${x_{n}}$ is not a b-Cauchy sequence. Then there exists $ε > 0$ for which we can find two subsequences ${x_{m_{i}}}$ and ${x_{n_{i}}}$ of ${x_{n}}$ such that $n_{i}$ is the smallest index for which

n_{i} > m_{i} > i and d (x_{m_{i}}, x_{n_{i}}) \geq ε .

(2.6)

This means that

d (x_{m_{i}}, x_{n_{i} - 1}) < ε .

(2.7)

From (2.5) and using the triangular inequality, we get

ε \leq d (x_{m_{i}}, x_{n_{i}}) \leq s d (x_{m_{i}}, x_{m_{i} + 1}) + s d (x_{m_{i} + 1}, x_{n_{i}}) .

By taking the upper limit as $i \to \infty$ , we get

\frac{ε}{s} \leq \underset{i \to \infty}{lim sup} d (x_{m_{i} + 1}, x_{n_{i}}) .

(2.8)

The definition of $M (x, y)$ and (2.8) imply

\begin{matrix} \underset{i \to \infty}{lim sup} M (x_{m_{i}}, x_{n_{i} - 1}) \\ = \underset{i \to \infty}{lim sup} max {d (x_{m_{i}}, x_{n_{i} - 1}), \frac{d (x_{m_{i}}, f x_{m_{i}}) d (x_{n_{i} - 1}, f x_{n_{i} - 1})}{1 + d (x_{m_{i}}, x_{n_{i} - 1})}, \\ \frac{d (x_{m_{i}}, f x_{m_{i}}) d (x_{n_{i} - 1}, f x_{n_{i} - 1})}{1 + d (f x_{m_{i}}, f x_{n_{i} - 1})}} \\ = \underset{i \to \infty}{lim sup} max {d (x_{m_{i}}, x_{n_{i} - 1}), \frac{d (x_{m_{i}}, x_{m_{i} + 1}) d (x_{n_{i} - 1}, x_{n_{i}})}{1 + d (x_{m_{i}}, x_{n_{i} - 1})}, \\ \frac{d (x_{m_{i}}, x_{m_{i} + 1}) d (x_{n_{i} - 1}, x_{n_{i}})}{1 + d (x_{m_{i} + 1}, x_{n_{i}})}} \\ \leq ε . \end{matrix}

Now, from (2.1) and the above inequalities, we have

\begin{aligned} \frac{ε}{s} & \leq \underset{i \to \infty}{lim sup} d (x_{m_{i} + 1}, x_{n_{i}}) \\ \leq \underset{i \to \infty}{lim sup} β (M (x_{m_{i}}, x_{n_{i} - 1})) \underset{i \to \infty}{lim sup} M (x_{m_{i}}, x_{n_{i} - 1}) \\ \leq ε \underset{i \to \infty}{lim sup} β (M (x_{m_{i}}, x_{n_{i} - 1})), \end{aligned}

which implies that $\frac{1}{s} \leq {lim sup}_{i \to \infty} β (M (x_{m_{i}}, x_{n_{i} - 1}))$ . Now, as $β \in F$ we conclude that $M (x_{m_{i}}, x_{n_{i} - 1}) \to 0$ , which yields $d (x_{m_{i}}, x_{n_{i} - 1}) \to 0$ . Consequently,

d (x_{m_{i}}, x_{n_{i}}) \leq s d (x_{m_{i}}, x_{n_{i} - 1}) + s d (x_{n_{i} - 1}, x_{n_{i}}) \to 0,

which is a contradiction to (2.6). Therefore, ${x_{n}}$ is a b-Cauchy sequence. b-Completeness of X shows that ${x_{n}}$ b-converges to a point $u \in X$ .

Step III: u is a fixed point of f.

First, let f be continuous, so we have

u = lim_{n \to \infty} x_{n + 1} = lim_{n \to \infty} f x_{n} = f u .

Now, let (II) holds. Using the assumption on X we have $x_{n} ⪯ u$ . Now, we show that $u = f u$ . By Lemma 1

\begin{aligned} \frac{1}{s} d (u, f u) & \leq \underset{n \to \infty}{lim sup} d (x_{n + 1}, f u) \\ \leq \underset{n \to \infty}{lim sup} β (M (x_{n}, u)) \underset{n \to \infty}{lim sup} M (x_{n}, u), \end{aligned}

where

\begin{aligned} lim_{n \to \infty} M (x_{n}, u) & = lim_{n \to \infty} max {d (x_{n}, u), \frac{d (x_{n}, f x_{n}) d (u, f u)}{1 + d (x_{n}, u)}, \frac{d (x_{n}, f x_{n}) d (u, f u)}{1 + d (f x_{n}, f u)}} \\ = max {0, 0} \\ = 0 . \end{aligned}

Therefore, from the above relations, we deduce that $d (u, f u) = 0$ , so $u = f u$ .

Finally, suppose that the set of fixed point of f is well ordered. Assume to the contrary that u and v are two fixed points of f such that $u \neq v$ . Then by (2.1),

d (u, v) = d (f u, f v) \leq β (M (u, v)) M (u, v) = β (d (u, v)) d (u, v) < \frac{1}{s} d (u, v),

(2.9)

because

M (u, v) = max {d (u, v), \frac{d (u, u) d (v, v)}{1 + d (u, v)}} = d (u, v) .

So we get $d (u, v) < \frac{1}{s} d (u, v)$ , a contradiction. Hence $u = v$ , and f has a unique fixed point. Conversely, if f has a unique fixed point, then the set of fixed points of f is a singleton, and so it is well ordered. □

Definition 4 Let $(X, d)$ be a b-metric space. A mapping $f : X \to X$ is called a rational Geraghty contraction of type II if there exists $β \in F$ such that

d (f x, f y) \leq β (M (x, y)) M (x, y)

(2.10)

for all comparable elements $x, y \in X$ , where

\begin{array}{rcl} M (x, y) & = & max {d (x, y), \frac{d (x, f x) d (x, f y) + d (y, f y) d (y, f x)}{1 + s [d (x, f x) + d (y, f y)]}, \\ \frac{d (x, f x) d (x, f y) + d (y, f y) d (y, f x)}{1 + d (x, f y) + d (y, f x)}} . \end{array}

Theorem 6 Let $(X, ⪯)$ be a partially ordered set and suppose that there exists a b-metric d on X such that $(X, d)$ is a b-complete b-metric space. Let $f : X \to X$ be an increasing mapping with respect to ⪯ such that there exists an element $x_{0} \in X$ with $x_{0} ⪯ f (x_{0})$ . Suppose f is a rational Geraghty contractive mapping of type II. If

(I)
f is continuous, or,
(II)
whenever ${x_{n}}$ is a nondecreasing sequence in X such that $x_{n} \to u \in X$ , one has $x_{n} ⪯ u$ for all $n \in N$ ,

then f has a fixed point.

Moreover, the set of fixed points of f is well ordered if and only if f has one and only one fixed point.

Proof Set $x_{n} = f^{n} (x_{0})$ . Since $x_{0} ⪯ f (x_{0})$ and f is increasing, we obtain by induction that

x_{0} ⪯ f (x_{0}) ⪯ f^{2} (x_{0}) ⪯ \dots ⪯ f^{n} (x_{0}) ⪯ f^{n + 1} (x_{0}) ⪯ \dots .

We do the proof in the following steps.

Step I: We show that ${lim}_{n \to \infty} d (x_{n}, x_{n + 1}) = 0$ . Since $x_{n} ⪯ x_{n + 1}$ for each $n \in N$ , then by (2.10)

\begin{aligned} d (x_{n}, x_{n + 1}) & = d (f x_{n - 1}, f x_{n}) \\ \leq β (M (x_{n - 1}, x_{n})) M (x_{n - 1}, x_{n}) \\ \leq β (d (x_{n - 1}, x_{n})) d (x_{n - 1}, x_{n}) \\ < \frac{1}{s} d (x_{n - 1}, x_{n}) \\ \leq d (x_{n - 1}, x_{n}), \end{aligned}

(2.11)

because

\begin{array}{rcl} M (x_{n - 1}, x_{n}) & = & max {d (x_{n - 1}, x_{n}), \frac{d (x_{n - 1}, f x_{n - 1}) d (x_{n - 1}, f x_{n}) + d (x_{n}, f x_{n}) d (x_{n}, f x_{n - 1})}{1 + s [d (x_{n - 1}, f x_{n - 1}) + d (x_{n}, f x_{n})]}, \\ \frac{d (x_{n - 1}, f x_{n - 1}) d (x_{n - 1}, f x_{n}) + d (x_{n}, f x_{n}) d (x_{n}, f x_{n - 1})}{1 + d (x_{n - 1}, f x_{n}) + d (x_{n}, f x_{n - 1})}} \\ = & max {d (x_{n - 1}, x_{n}), \frac{d (x_{n - 1}, x_{n}) d (x_{n - 1}, x_{n + 1}) + d (x_{n}, x_{n + 1}) d (x_{n}, x_{n})}{1 + s [d (x_{n - 1}, x_{n}) + d (x_{n}, x_{n + 1})]}, \\ \frac{d (x_{n - 1}, x_{n}) d (x_{n - 1}, x_{n + 1}) + d (x_{n}, x_{n + 1}) d (x_{n}, x_{n})}{1 + d (x_{n - 1}, x_{n + 1}) + d (x_{n}, x_{n})}} \\ = & d (x_{n - 1}, x_{n}) . \end{array}

Therefore, ${d (x_{n}, x_{n + 1})}$ is decreasing. Then there exists $r \geq 0$ such that ${lim}_{n \to \infty} d (x_{n}, x_{n + 1}) = r$ . We will prove that $r = 0$ . Suppose to the contrary that $r > 0$ . Then, letting $n \to \infty$ , from (2.11)

\frac{1}{s} r \leq lim_{n \to \infty} β (d (x_{n - 1}, x_{n})) r,

which implies that $d (x_{n - 1}, x_{n}) \to 0$ . Hence, $r = 0$ , a contradiction. So,

lim_{n \to \infty} d (x_{n - 1}, x_{n}) = 0

(2.12)

holds true.

Step II: Now, we prove that the sequence ${x_{n}}$ is a b-Cauchy sequence. Suppose the contrary, i.e., ${x_{n}}$ is not a b-Cauchy sequence. Then there exists $ε > 0$ for which we can find two subsequences ${x_{m_{i}}}$ and ${x_{n_{i}}}$ of ${x_{n}}$ such that $n_{i}$ is the smallest index for which

n_{i} > m_{i} > i and d (x_{m_{i}}, x_{n_{i}}) \geq ε .

(2.13)

This means that

d (x_{m_{i}}, x_{n_{i} - 1}) < ε .

(2.14)

As in the proof of Theorem 5, we have

\frac{ε}{s} \leq \underset{i \to \infty}{lim sup} d (x_{m_{i} + 1}, x_{n_{i}}) .

(2.15)

From the definition of $M (x, y)$ and the above limits,

\begin{matrix} \underset{i \to \infty}{lim sup} M (x_{m_{i}}, x_{n_{i} - 1}) \\ = \underset{i \to \infty}{lim sup} max {d (x_{m_{i}}, x_{n_{i} - 1}), \\ \frac{d (x_{m_{i}}, f x_{m_{i}}) d (x_{m_{i}}, f x_{n_{i} - 1}) + d (x_{n_{i} - 1}, f x_{n_{i} - 1}) d (x_{n_{i} - 1}, f x_{m_{i}})}{1 + s [d (x_{m_{i}}, f x_{m_{i}}) + d (x_{n_{i} - 1}, f x_{n_{i} - 1})]}, \\ \frac{d (x_{m_{i}}, f x_{m_{i}}) d (x_{m_{i}}, f x_{n_{i} - 1}) + d (x_{n_{i} - 1}, f x_{n_{i} - 1}) d (x_{n_{i} - 1}, f x_{m_{i}})}{1 + d (x_{m_{i}}, f x_{n_{i} - 1}) + d (x_{n_{i} - 1}, f x_{m_{i}})}} \\ = \underset{i \to \infty}{lim sup} max {d (x_{m_{i}}, x_{n_{i} - 1}), \\ \frac{d (x_{m_{i}}, x_{m_{i} + 1}) d (x_{m_{i}}, x_{n_{i}}) + d (x_{n_{i} - 1}, x_{n_{i}}) d (x_{n_{i} - 1}, x_{m_{i} + 1})}{1 + s [d (x_{m_{i}}, x_{m_{i} + 1}) + d (x_{n_{i} - 1}, x_{n_{i}})]}, \\ \frac{d (x_{m_{i}}, x_{m_{i} + 1}) d (x_{m_{i}}, x_{n_{i}}) + d (x_{n_{i} - 1}, x_{n_{i}}) d (x_{n_{i} - 1}, x_{m_{i} + 1})}{1 + d (x_{m_{i}}, x_{n_{i}}) + d (x_{n_{i} - 1}, x_{m_{i} + 1})}} \\ \leq ε . \end{matrix}

Now, from (2.10) and the above inequalities, we have

\begin{aligned} \frac{ε}{s} & \leq \underset{i \to \infty}{lim sup} d (x_{m_{i} + 1}, x_{n_{i}}) \leq \underset{i \to \infty}{lim sup} β (M (x_{m_{i}}, x_{n_{i} - 1})) \underset{i \to \infty}{lim sup} M (x_{m_{i}}, x_{n_{i} - 1}) \\ \leq ε \underset{i \to \infty}{lim sup} β (M (x_{m_{i}}, x_{n_{i} - 1})), \end{aligned}

which implies that $\frac{1}{s} \leq {lim sup}_{i \to \infty} β (M (x_{m_{i}}, x_{n_{i} - 1}))$ . Now, as $β \in F$ we conclude that ${x_{n}}$ is a b-Cauchy sequence. b-Completeness of X shows that ${x_{n}}$ b-converges to a point $u \in X$ .

Step III: u is a fixed point of f.

First, let f be continuous, so we have

u = lim_{n \to \infty} x_{n + 1} = lim_{n \to \infty} f x_{n} = f u .

Now, let (II) hold. Using the assumption on X we have $x_{n} ⪯ u$ . Now, we show that $u = f u$ . By Lemma 1

\begin{aligned} \frac{1}{s} d (u, f u) & \leq \underset{n \to \infty}{lim sup} d (x_{n + 1}, f u) \\ \leq \underset{n \to \infty}{lim sup} β (M (x_{n}, u)) \underset{n \to \infty}{lim sup} M (x_{n}, u) \\ = 0, \end{aligned}

because

\begin{array}{rcl} lim_{n \to \infty} M (x_{n}, u) & = & lim_{n \to \infty} max {d (x_{n}, u), \frac{d (x_{n}, f x_{n}) d (x_{n}, f u) + d (u, f u) d (u, f x_{n})}{1 + s [d (x_{n}, f x_{n}) + d (u, f u)]}, \\ \frac{d (x_{n}, f x_{n}) d (x_{n}, f u) + d (u, f u) d (u, f x_{n})}{1 + d (x_{n}, f u) + d (x_{n}, f u)}} \\ = & max {0, 0} \\ = & 0 . \end{array}

Therefore, $d (u, f u) = 0$ , so $u = f u$ . □

Definition 5 Let $(X, d)$ be a b-metric space. A mapping $f : X \to X$ is called a rational Geraghty contraction of type III if there exists $β \in F$ such that

d (f x, f y) \leq β (M (x, y)) M (x, y)

(2.16)

for all comparable elements $x, y \in X$ , where

\begin{array}{rcl} M (x, y) & = & max {d (x, y), \frac{d (x, f x) d (y, f y)}{1 + s [d (x, y) + d (x, f y) + d (y, f x)]}, \\ \frac{d (x, f y) d (x, y)}{1 + s d (x, f x) + s^{3} [d (y, f x) + d (y, f y)]}} . \end{array}

Theorem 7 Let $(X, ⪯)$ be a partially ordered set and suppose that there exists a b-metric d on X such that $(X, d)$ is a b-complete b-metric space. Let $f : X \to X$ be an increasing mapping with respect to ⪯ such that there exists an element $x_{0} \in X$ with $x_{0} ⪯ f (x_{0})$ . Suppose f is a rational Geraghty contractive mapping of type III. If

(I)
f is continuous, or,
(II)
whenever ${x_{n}}$ is a nondecreasing sequence in X such that $x_{n} \to u \in X$ , one has $x_{n} ⪯ u$ for all $n \in N$ ,

then f has a fixed point.

Moreover, the set of fixed points of f is well ordered if and only if f has one and only one fixed point.

Proof Set $x_{n} = f^{n} (x_{0})$ .

Step I: We show that ${lim}_{n \to \infty} d (x_{n}, x_{n + 1}) = 0$ . Since $x_{n} ⪯ x_{n + 1}$ for each $n \in N$ , then by (2.16)

\begin{aligned} d (x_{n}, x_{n + 1}) & = d (f x_{n - 1}, f x_{n}) \\ \leq β (M (x_{n - 1}, x_{n})) M (x_{n - 1}, x_{n}) \\ \leq β (d (x_{n - 1}, x_{n})) d (x_{n - 1}, x_{n}) \\ < \frac{1}{s} d (x_{n - 1}, x_{n}) \\ \leq d (x_{n - 1}, x_{n}), \end{aligned}

(2.17)

because

\begin{array}{rcl} M (x_{n - 1}, x_{n}) & = & max {d (x_{n - 1}, x_{n}), \frac{d (x_{n - 1}, f x_{n - 1}) d (x_{n}, f x_{n})}{1 + s [d (x_{n - 1}, x_{n}) + d (x_{n - 1}, f x_{n}) + d (x_{n}, f x_{n - 1})]}, \\ \frac{d (x_{n - 1}, f x_{n}) d (x_{n - 1}, x_{n})}{1 + s d (x_{n - 1}, f x_{n - 1}) + s^{3} [d (x_{n}, f x_{n - 1}) + d (x_{n}, f x_{n})]}} \\ = & max {d (x_{n - 1}, x_{n}), \frac{d (x_{n - 1}, x_{n}) d (x_{n}, x_{n + 1})}{1 + s [d (x_{n - 1}, x_{n}) + d (x_{n - 1}, x_{n + 1}) + d (x_{n}, x_{n})]}, \\ \frac{d (x_{n - 1}, x_{n + 1}) d (x_{n - 1}, x_{n})}{1 + s d (x_{n - 1}, x_{n}) + s^{3} [d (x_{n}, x_{n}) + d (x_{n}, x_{n + 1})]}} \\ \leq & max {d (x_{n - 1}, x_{n}), \frac{d (x_{n - 1}, x_{n}) s [d (x_{n}, x_{n - 1}) + d (x_{n - 1}, x_{n + 1})]}{s [d (x_{n - 1}, x_{n}) + d (x_{n - 1}, x_{n + 1}) + d (x_{n}, x_{n})]}} \\ = & d (x_{n - 1}, x_{n}) . \end{array}

Therefore, ${d (x_{n}, x_{n + 1})}$ is decreasing. Similar to what we have done in Theorems 5 and 6, we have

lim_{n \to \infty} d (x_{n - 1}, x_{n}) = 0 .

(2.18)

Step II: Now, we prove that the sequence ${x_{n}}$ is a b-Cauchy sequence. Suppose the contrary, i.e., ${x_{n}}$ is not a b-Cauchy sequence. Then there exists $ε > 0$ for which we can find two subsequences ${x_{m_{i}}}$ and ${x_{n_{i}}}$ of ${x_{n}}$ such that $n_{i}$ is the smallest index for which

n_{i} > m_{i} > i and d (x_{m_{i}}, x_{n_{i}}) \geq ε .

(2.19)

This means that

d (x_{m_{i}}, x_{n_{i} - 1}) < ε .

(2.20)

From (2.18) and using the triangular inequality, we get

ε \leq d (x_{m_{i}}, x_{n_{i}}) \leq s d (x_{m_{i}}, x_{m_{i} + 1}) + s d (x_{m_{i} + 1}, x_{n_{i}}) .

By taking the upper limit as $i \to \infty$ , we get

\frac{ε}{s} \leq \underset{i \to \infty}{lim sup} d (x_{m_{i} + 1}, x_{n_{i}}) .

(2.21)

Using the triangular inequality, we have

d (x_{m_{i}}, x_{n_{i}}) \leq s d (x_{m_{i}}, x_{n_{i} - 1}) + s d (x_{n_{i} - 1}, x_{n_{i}}) .

Taking the upper limit as $i \to \infty$ in the above inequality and using (2.20) we get

\underset{i \to \infty}{lim sup} d (x_{m_{i}}, x_{n_{i}}) \leq ε s .

(2.22)

Again, using the triangular inequality, we have

d (x_{m_{i}}, x_{n_{i}}) \leq s d (x_{m_{i}}, x_{m_{i} + 1}) + s^{2} d (x_{m_{i} + 1}, x_{n_{i} - 1}) + s^{2} d (x_{n_{i} - 1}, x_{n_{i}}) .

Taking the upper limit as $i \to \infty$ in the above inequality and using (2.20) we get

\underset{i \to \infty}{lim sup} d (x_{m_{i} + 1}, x_{n_{i} - 1}) \geq \frac{ε}{s^{2}} .

(2.23)

From the definition of $M (x, y)$ and the above limits,

\begin{matrix} \underset{i \to \infty}{lim sup} M (x_{m_{i}}, x_{n_{i} - 1}) \\ = \underset{i \to \infty}{lim sup} max {d (x_{m_{i}}, x_{n_{i} - 1}), \frac{d (x_{m_{i}}, f x_{m_{i}}) d (x_{n_{i} - 1}, f x_{n_{i} - 1})}{1 + s [d (x_{m_{i}}, x_{n_{i} - 1}) + d (x_{m_{i}}, f x_{n_{i} - 1}) + d (x_{n_{i} - 1}, f x_{m_{i}})]}, \\ \frac{d (x_{m_{i}}, f x_{n_{i} - 1}) d (x_{m_{i}}, x_{n_{i} - 1})}{1 + s d (x_{m_{i}}, f x_{m_{i}}) + s^{3} [d (x_{n_{i} - 1}, f x_{m_{i}}) + d (x_{n_{i} - 1}, f x_{n_{i} - 1})]}} \\ = \underset{i \to \infty}{lim sup} max {d (x_{m_{i}}, x_{n_{i} - 1}), \frac{d (x_{m_{i}}, x_{m_{i} + 1}) d (x_{n_{i} - 1}, x_{n_{i}})}{1 + s [d (x_{m_{i}}, x_{n_{i} - 1}) + d (x_{m_{i}}, x_{n_{i}}) + d (x_{n_{i} - 1}, x_{m_{i} + 1})]}, \\ \frac{d (x_{m_{i}}, x_{n_{i}}) d (x_{m_{i}}, x_{n_{i} - 1})}{1 + s d (x_{m_{i}}, x_{m_{i} + 1}) + s^{3} [d (x_{n_{i} - 1}, x_{m_{i} + 1}) + d (x_{n_{i} - 1}, x_{n_{i}})]}} \\ \leq ε . \end{matrix}

Now, from (2.16) and the above inequalities, we have

\begin{aligned} \frac{ε}{s} & \leq \underset{i \to \infty}{lim sup} d (x_{m_{i} + 1}, x_{n_{i}}) \\ \leq \underset{i \to \infty}{lim sup} β (M (x_{m_{i}}, x_{n_{i} - 1})) \underset{i \to \infty}{lim sup} M (x_{m_{i}}, x_{n_{i} - 1}) \\ \leq ε \underset{i \to \infty}{lim sup} β (M (x_{m_{i}}, x_{n_{i} - 1})), \end{aligned}

which implies that $\frac{1}{s} \leq {lim sup}_{i \to \infty} β (M (x_{m_{i}}, x_{n_{i} - 1}))$ . Now, as $β \in F$ we conclude that ${x_{n}}$ is a b-Cauchy sequence. b-Completeness of X shows that ${x_{n}}$ b-converges to a point $u \in X$ .

Step III: u is a fixed point of f.

When f is continuous, the proof is straightforward.

Now, let (II) hold. By Lemma 1

\begin{aligned} \frac{1}{s} d (u, f u) & \leq \underset{n \to \infty}{lim sup} d (x_{n + 1}, f u) \\ \leq \underset{n \to \infty}{lim sup} β (M (x_{n}, u)) \underset{n \to \infty}{lim sup} M (x_{n}, u), \end{aligned}

where

\begin{array}{rcl} lim_{n \to \infty} M (x_{n}, u) & = & lim_{n \to \infty} max {d (x_{n}, u), \frac{d (x_{n}, f x_{n}) d (u, f u)}{1 + s [d (x_{n}, u) + d (x_{n}, f u) + d (u, f x_{n})]}, \\ \frac{d (x_{n}, f u) d (x_{n}, u)}{1 + s d (x_{n}, f x_{n}) + s^{3} [d (u, f u) + d (u, f x_{n})]}} \\ = & max {0, 0} \\ = & 0 . \end{array}

Therefore, from the above relations, we deduce that $d (u, f u) = 0$ , so $u = f u$ . □

If in the above theorems we take $β (t) = r$ , where $0 \leq r < \frac{1}{s}$ , then we have the following corollary.

Corollary 1 Let $(X, ⪯)$ be a partially ordered set and suppose that there exists a b-metric d on X such that $(X, d)$ is a b-complete b-metric space, and let $f : X \to X$ be an increasing mapping with respect to ⪯ such that there exists an element $x_{0} \in X$ with $x_{0} ⪯ f (x_{0})$ . Suppose that

d (f x, f y) \leq r M (x, y)

for all comparable elements $x, y \in X$ , where

M (x, y) = max {d (x, y), \frac{d (x, f x) d (y, f y)}{1 + d (x, y)}, \frac{d (x, f x) d (y, f y)}{1 + d (f x, f y)}}

or

\begin{array}{rcl} M (x, y) & = & max {d (x, y), \frac{d (x, f x) d (x, f y) + d (y, f y) d (y, f x)}{1 + s [d (x, f x) + d (y, f y)]}, \\ \frac{d (x, f x) d (x, f y) + d (y, f y) d (y, f x)}{1 + d (x, f y) + d (y, f x)}}, \end{array}

or

\begin{array}{rcl} M (x, y) & = & max {d (x, y), \frac{d (x, f x) d (y, f y)}{1 + s [d (x, y) + d (x, f y) + d (y, f x)]}, \\ \frac{d (x, f y) d (x, y)}{1 + s d (x, f x) + s^{3} [d (y, f x) + d (y, f y)]}} . \end{array}

If f is continuous, or, for any nondecreasing sequence ${x_{n}}$ in X such that $x_{n} \to u \in X$ one has $x_{n} ⪯ u$ for all $n \in N$ , then f has a fixed point.

Corollary 2 Let $(X, ⪯)$ be a partially ordered set and suppose that there exists a b-metric d on X such that $(X, d)$ is a b-complete b-metric space, and let $f : X \to X$ be an increasing mapping with respect to ⪯ such that there exists an element $x_{0} \in X$ with $x_{0} ⪯ f (x_{0})$ . Suppose

d (f x, f y) \leq a d (x, y) + b \frac{d (x, f x) d (y, f y)}{1 + d (x, y)} + c \frac{d (x, f x) d (y, f y)}{1 + d (f x, f y)}

or

\begin{array}{rcl} d (f x, f y) & \leq & a d (x, y) + b \frac{d (x, f x) d (x, f y) + d (y, f y) d (y, f x)}{1 + s [d (x, f x) + d (y, f y)]} \\ + c \frac{d (x, f x) d (x, f y) + d (y, f y) d (y, f x)}{1 + d (x, f y) + d (y, f x)}, \end{array}

or

\begin{array}{rcl} d (f x, f y) & \leq & a d (x, y) + b \frac{d (x, f x) d (y, f y)}{1 + s [d (x, y) + d (x, f y) + d (y, f x)]} \\ + c \frac{d (x, f y) d (x, y)}{1 + s d (x, f x) + s^{3} [d (y, f x) + d (y, f y)]} \end{array}

for all comparable elements $x, y \in X$ , where $a, b, c \geq 0$ and $0 \leq a + b + c < \frac{1}{s}$ .

If f is continuous, or, for any nondecreasing sequence ${x_{n}}$ in X such that $x_{n} \to u \in X$ one has $x_{n} ⪯ u$ for all $n \in N$ , then f has a fixed point.

Corollary 3 Let $(X, ⪯, d)$ be an ordered b-complete b-metric space, and let $f : X \to X$ be an increasing mapping with respect to ⪯ such that there exists an element $x_{0} \in X$ with $x_{0} ⪯ f^{m} (x_{0})$ and

d (f^{m} x, f^{m} y) \leq β (M (x, y)) M (x, y)

for all comparable elements $x, y \in X$ , where

M (x, y) = max {d (x, y), \frac{d (x, f^{m} x) d (y, f^{m} y)}{1 + d (x, y)}, \frac{d (x, f^{m} x) d (y, f^{m} y)}{1 + d (f^{m} x, f^{m} y)}}

or

\begin{array}{rcl} M (x, y) & = & max {d (x, y), \frac{d (x, f^{m} x) d (x, f^{m} y) + d (y, f^{m} y) d (y, f^{m} x)}{1 + s [d (x, f^{m} x) + d (y, f^{m} y)]}, \\ \frac{d (x, f^{m} x) d (x, f^{m} y) + d (y, f^{m} y) d (y, f^{m} x)}{1 + d (x, f^{m} y) + d (y, f^{m} x)}}, \end{array}

or

\begin{array}{rcl} M (x, y) & = & max {d (x, y), \frac{d (x, f^{m} x) d (y, f^{m} y)}{1 + s [d (x, y) + d (x, f^{m} y) + d (y, f^{m} x)]}, \\ \frac{d (x, f^{m} y) d (x, y)}{1 + s d (x, f^{m} x) + s^{3} [d (y, f^{m} x) + d (y, f^{m} y)]}} \end{array}

for some positive integer m.

If $f^{m}$ is continuous, or, for any nondecreasing sequence ${x_{n}}$ in X such that $x_{n} \to u \in X$ one has $x_{n} ⪯ u$ for all $n \in N$ , then f has a fixed point.

Let Ψ be the family of all nondecreasing functions $ψ : [0, \infty) \to [0, \infty)$ such that

lim_{n \to \infty} ψ^{n} (t) = 0

for all $t > 0$ .

Lemma 2 If $ψ \in Ψ$ , then the following are satisfied.

(a)
$ψ (t) < t$ for all $t > 0$ ;
(b)
$ψ (0) = 0$ .

As an example $ψ_{1} (t) = k t$ , for all $t \geq 0$ , where $k \in [0, 1)$ , and $ψ_{2} (t) = ln (t + 1)$ , for all $t \geq 0$ , are in Ψ.

Theorem 8 Let $(X, ⪯)$ be a partially ordered set and suppose that there exists a b-metric d on X such that $(X, d)$ is a b-complete b-metric space, and let $f : X \to X$ be an increasing mapping with respect to ⪯ such that there exists an element $x_{0} \in X$ with $x_{0} ⪯ f (x_{0})$ . Suppose that

s d (f x, f y) \leq ψ (M (x, y)),

(2.24)

where

M (x, y) = max {d (x, y), \frac{d (x, f x) d (y, f y)}{1 + d (x, y)}, \frac{d (x, f x) d (y, f y)}{1 + d (f x, f y)}}

for all comparable elements $x, y \in X$ . If f is continuous, then f has a fixed point. Moreover, the set of fixed points of f is well ordered if and only if f has one and only one fixed point.

Proof Since $x_{0} ⪯ f (x_{0})$ and f is increasing, we obtain by induction that

x_{0} ⪯ f (x_{0}) ⪯ f^{2} (x_{0}) ⪯ \dots ⪯ f^{n} (x_{0}) ⪯ f^{n + 1} (x_{0}) ⪯ \dots .

Putting $x_{n} = f^{n} (x_{0})$ , we have

x_{0} ⪯ x_{1} ⪯ x_{2} ⪯ \dots ⪯ x_{n} ⪯ x_{n + 1} ⪯ \dots .

If there exists $n_{0} \in N$ such that $x_{n_{0}} = x_{n_{0} + 1}$ then $x_{n_{0}} = f x_{n_{0}}$ and so we have nothing to prove. Hence, we assume that $d (x_{n}, x_{n + 1}) > 0$ , for all $n \in N$ .

In the following steps, we will complete the proof.

Step I: We will prove that

lim_{n \to \infty} d (x_{n}, x_{n + 1}) = 0 .

Using condition (2.24), we obtain

d (x_{n + 1}, x_{n}) \leq s d (x_{n + 1}, x_{n}) = s d (f x_{n}, f x_{n - 1}) \leq ψ (M (x_{n}, x_{n - 1})),

because

\begin{array}{rcl} M (x_{n - 1}, x_{n}) & = & max {d (x_{n - 1}, x_{n}), \frac{d (x_{n - 1}, f x_{n - 1}) d (x_{n}, f x_{n})}{1 + d (x_{n - 1}, x_{n})}, \\ \frac{d (x_{n - 1}, f x_{n - 1}) d (x_{n}, f x_{n})}{1 + d (f x_{n - 1}, f x_{n})}} \\ = & max {d (x_{n - 1}, x_{n}), \frac{d (x_{n - 1}, x_{n}) d (x_{n}, x_{n + 1})}{1 + d (x_{n - 1}, x_{n})}, \frac{d (x_{n - 1}, x_{n}) d (x_{n}, x_{n + 1})}{1 + d (x_{n}, x_{n + 1})}} \\ \leq & max {d (x_{n - 1}, x_{n}), d (x_{n}, x_{n + 1})} . \end{array}

If $max {d (x_{n - 1}, x_{n}), d (x_{n}, x_{n + 1})} = d (x_{n}, x_{n + 1})$ , then

\begin{array}{rcl} d (x_{n}, x_{n + 1}) & \leq & s d (x_{n}, x_{n + 1}) = s d (f x_{n - 1}, x_{n}) \\ \leq & ψ (M (x_{n - 1}, x_{n})) < M (x_{n - 1}, x_{n}) \leq d (x_{n}, x_{n + 1}), \end{array}

(2.25)

which is a contradiction. Hence, $max {d (x_{n - 1}, x_{n}), d (x_{n}, x_{n + 1})} = d (x_{n - 1}, x_{n})$ , so from (2.25),

\begin{array}{rcl} d (x_{n}, x_{n + 1}) & \leq & s d (x_{n}, x_{n + 1}) = s d (f x_{n - 1}, x_{n}) \\ \leq & ψ (M (x_{n - 1}, x_{n})) < M (x_{n - 1}, x_{n}) \leq d (x_{n - 1}, x_{n}) . \end{array}

(2.26)

Hence,

d (x_{n}, x_{n + 1}) \leq s d (x_{n}, x_{n + 1}) \leq ψ (d (x_{n - 1}, x_{n})) .

By induction,

\begin{aligned} d (x_{n + 1}, x_{n}) & \leq ψ (d (x_{n}, x_{n - 1})) \leq ψ^{2} (d (x_{n - 1}, x_{n - 2})) \\ \leq \dots \leq ψ^{n} (d (x_{1}, x_{0})) . \end{aligned}

(2.27)

As $ψ \in Ψ$ , we conclude that

lim_{n \to \infty} d (x_{n}, x_{n + 1}) = 0 .

(2.28)

Step II: Now, we prove that the sequence ${x_{n}}$ is a b-Cauchy sequence. Suppose the contrary, i.e., ${x_{n}}$ is not a b-Cauchy sequence. Then there exists $ε > 0$ for which we can find two subsequences ${x_{m_{i}}}$ and ${x_{n_{i}}}$ of ${x_{n}}$ such that $n_{i}$ is the smallest index for which

n_{i} > m_{i} > i and d (x_{m_{i}}, x_{n_{i}}) \geq ε .

(2.29)

This means that

d (x_{m_{i}}, x_{n_{i} - 1}) < ε .

(2.30)

From (2.29) and using the triangular inequality, we get

ε \leq d (x_{m_{i}}, x_{n_{i}}) \leq s d (x_{m_{i}}, x_{m_{i} + 1}) + s d (x_{m_{i} + 1}, x_{n_{i}}) .

Taking the upper limit as $i \to \infty$ , we get

\frac{ε}{s} \leq \underset{i \to \infty}{lim sup} d (x_{m_{i} + 1}, x_{n_{i}}) .

(2.31)

From the definition of $M (x, y)$ and the above limits,

\begin{matrix} \underset{i \to \infty}{lim sup} M (x_{m_{i}}, x_{n_{i} - 1}) \\ = \underset{i \to \infty}{lim sup} max {d (x_{m_{i}}, x_{n_{i} - 1}), \frac{d (x_{m_{i}}, f x_{m_{i}}) d (x_{n_{i} - 1}, f x_{n_{i} - 1})}{1 + d (x_{m_{i}}, x_{n_{i} - 1})}, \\ \frac{d (x_{m_{i}}, f x_{m_{i}}) d (x_{n_{i} - 1}, f x_{n_{i} - 1})}{1 + d (f x_{m_{i}}, f x_{n_{i} - 1})}} \\ = \underset{i \to \infty}{lim sup} max {d (x_{m_{i}}, x_{n_{i} - 1}), \frac{d (x_{m_{i}}, x_{m_{i} + 1}) d (x_{n_{i} - 1}, x_{n_{i}})}{1 + d (x_{m_{i}}, x_{n_{i} - 1})}, \\ \frac{d (x_{m_{i}}, x_{m_{i} + 1}) d (x_{n_{i} - 1}, x_{n_{i}})}{1 + d (x_{m_{i} + 1}, x_{n_{i}})}} \\ \leq ε . \end{matrix}

Now, from (2.24) and the above inequalities, we have

\begin{aligned} ε & = s \cdot \frac{ε}{s} \leq s \underset{i \to \infty}{lim sup} d (x_{m_{i} + 1}, x_{n_{i}}) \\ \leq \underset{i \to \infty}{lim sup} ψ (M (x_{m_{i}}, x_{n_{i} - 1})) \\ \leq ψ (ε) < ε, \end{aligned}

which is a contradiction. Consequently, ${x_{n}}$ is a b-Cauchy sequence. b-Completeness of X shows that ${x_{n}}$ b-converges to a point $u \in X$ .

Step III: Now we show that u is a fixed point of f,

u = lim_{n \to \infty} x_{n + 1} = lim_{n \to \infty} f x_{n} = f u,

as f is continuous. □

Theorem 9 Under the same hypotheses as Theorem 8, without the continuity assumption of f, assume that whenever ${x_{n}}$ is a nondecreasing sequence in X such that $x_{n} \to u \in X$ , $x_{n} ⪯ u$ for all $n \in N$ . Then f has a fixed point.

Proof By repeating the proof of Theorem 8, we construct an increasing sequence ${x_{n}}$ in X such that $x_{n} \to u \in X$ . Using the assumption on X we have $x_{n} ⪯ u$ . Now we show that $u = f u$ . By (2.24) we have

d (f u, x_{n}) = d (f u, f x_{n - 1}) \leq ψ (M (u, x_{n - 1})),

(2.32)

where

\begin{aligned} M (u, x_{n - 1}) & = max {d (u, x_{n - 1}), \frac{d (u, f u) d (x_{n - 1}, f x_{n - 1})}{1 + d (f u, f x_{n - 1})}, \frac{d (u, f u) d (x_{n - 1}, f x_{n - 1})}{1 + d (u, x_{n - 1})}} \\ = max {d (u, x_{n - 1}), \frac{d (u, f u) d (x_{n - 1}, x_{n})}{1 + d (f u, x_{n})}, \frac{d (u, f u) d (x_{n - 1}, x_{n})}{1 + d (u, x_{n - 1})}} . \end{aligned}

Letting $n \to \infty$ ,

\underset{n \to \infty}{lim sup} M (u, x_{n - 1}) = 0 .

(2.33)

Again, taking the upper limit as $n \to \infty$ in (2.32) and using Lemma 1 and (2.33),

\begin{aligned} \frac{1}{s} d (f u, u) & \leq \underset{n \to \infty}{lim sup} d (f u, x_{n}) \\ \leq \underset{n \to \infty}{lim sup} ψ (M (u, x_{n - 1})) \\ = 0 . \end{aligned}

So we get $d (f u, u) = 0$ , i.e., $f u = u$ . □

Remark 1 In Theorems 8 and 9, we can replace $M (x, y)$ by the following:

\begin{array}{rcl} M (x, y) & = & max {d (x, y), \frac{d (x, f x) d (x, f y) + d (y, f y) d (y, f x)}{1 + s [d (x, f x) + d (y, f y)]}, \\ \frac{d (x, f x) d (x, f y) + d (y, f y) d (y, f x)}{1 + d (x, f y) + d (y, f x)}} \end{array}

or

\begin{array}{rcl} M (x, y) & = & max {d (x, y), \frac{d (x, f x) d (y, f y)}{1 + s [d (x, y) + d (x, f y) + d (y, f x)]}, \\ \frac{d (x, f y) d (x, y)}{1 + s d (x, f x) + s^{3} [d (y, f x) + d (y, f y)]}} . \end{array}

Example 2 Let $X = {0, 1, 3}$ and define the partial order ⪯ on X by

⪯ : = {(0, 0), (1, 1), (3, 3), (0, 3), (3, 1), (0, 1)} .

Consider the function $f : X \to X$ given as

f = (\begin{array}{ccc} 0 & 1 & 3 \\ 3 & 1 & 1 \end{array}),

which is increasing with respect to ⪯. Let $x_{0} = 0$ . Hence, $f (x_{0}) = 3$ , so $x_{0} ⪯ f x_{0}$ . Define first the b-metric d on X by $d (0, 1) = 6$ , $d (0, 3) = 9$ , $d (1, 3) = \frac{1}{2}$ , and $d (x, x) = 0$ . Then $(X, d)$ is a b-complete b-metric space with $s = \frac{18}{13}$ . Let $β \in F$ is given by

β (t) = \frac{13}{18} e^{\frac{- t}{9}}, t \geq 0

and $β (0) \in [0, \frac{13}{18})$ . Then

d (f 0, f 3) = d (3, 1) = \frac{1}{2} \leq β (M (0, 3)) M (0, 3) = 9 β (9) .

This is because

\begin{aligned} M (0, 3) & = max {d (0, 3), \frac{d (0, f 0) d (3, f 3)}{1 + d (f 0, f 3)}, \frac{d (0, f 0) d (3, f 3)}{1 + d (0, 3)}} \\ = max {d (0, 3), \frac{d (0, 3) d (3, 1)}{1 + d (3, 1)}, \frac{d (0, 3) d (3, 1)}{1 + d (0, 3)}} = 9 . \end{aligned}

Also,

d (f 0, f 1) = d (3, 1) = \frac{1}{2} \leq β (M (0, 1)) M (0, 1) = 6 β (6),

because

\begin{aligned} M (0, 1) & = max {d (0, 1), \frac{d (0, f 0) d (1, f 1)}{1 + d (f 0, f 1)}, \frac{d (0, f 0) d (1, f 1)}{1 + d (0, 1)}} \\ = max {d (0, 1), \frac{d (0, 3) d (1, 1)}{1 + d (3, 1)}, \frac{d (0, 3) d (1, 1)}{1 + d (0, 1)}} = 6 . \end{aligned}

Also,

d (f 1, f 3) = d (1, 1) = 0 \leq β (M (1, 3)) M (1, 3) .

Hence, f satisfies all the assumptions of Theorem 5 and thus it has a fixed point (which is $u = 1$ ).

Example 3 Let $X = [0, 1]$ be equipped with the usual order and b-complete b-metric given by $d (x, y) = | x - y |^{2}$ with $s = 2$ . Consider the mapping $f : X \to X$ defined by $f (x) = \frac{1}{16} x^{2} e^{- x^{2}}$ and the function β given by $β (t) = \frac{1}{4}$ . It is easy to see that f is an increasing function and $0 \leq f (0) = 0$ . For all comparable elements $x, y \in X$ , by the mean value theorem, we have

\begin{aligned} d (f x, f y) & = | \frac{1}{16} x^{2} e^{- x^{2}} - \frac{1}{16} y^{2} e^{- y^{2}} |^{2} \\ \leq \frac{1}{8} | x^{2} e^{- x^{2}} - y^{2} e^{- y^{2}} |^{2} \\ \leq \frac{1}{8} | x - y |^{2} \leq \frac{1}{4} d (x, y) = β (d (x, y)) d (x, y) \\ \leq β (M (x, y)) M (x, y) . \end{aligned}

So, from Theorem 5, f has a fixed point.

Example 4 Let $X = [0, 1]$ be equipped with the usual order and b-complete b-metric d be given by $d (x, y) = | x - y |^{2}$ with $s = 2$ . Consider the mapping $f : X \to X$ defined by $f (x) = \frac{1}{4} ln (x^{2} + 1)$ and the function $ψ \in Ψ$ given by $ψ (t) = \frac{1}{4} t$ , $t \geq 0$ . It is easy to see that f is increasing and $0 \leq f (0) = 0$ . For all comparable elements $x, y \in X$ , using the mean value problem, we have

\begin{aligned} d (f x, f y) & = | \frac{1}{4} ln (x^{2} + 1) - \frac{1}{4} ln (y^{2} + 1) |^{2} \\ \leq \frac{1}{4} | x - y |^{2} \\ = \frac{1}{4} d (x, y) = ψ (d (x, y)) \leq ψ (M (x, y)), \end{aligned}

so, using Theorem 8, f has a fixed point.

3 Application

In this section, we present an application where Theorem 8 can be applied. This application is inspired by [9] (also, see [26] and [27]).

Let $X = C ([0, T])$ be the set of all real continuous functions on $[0, T]$ . We first endow X with the b-metric

d (u, v) = max_{t \in [0, T]} {(| u (t) - v (t) |)}^{p}

for all $u, v \in X$ where $p > 1$ . Clearly, $(X, d)$ is a complete b-metric space with parameter $s = 2^{p - 1}$ . Secondly, $C ([0, T])$ can also be equipped with a partial order given by

x ⪯ y iff x (t) \leq y (t) for all t \in [0, T] .

Moreover, as in [9] it is proved that $(C ([0, T]), ⪯)$ is regular, that is, whenever ${x_{n}}$ in X is an increasing sequence such that $x_{n} \to x$ as $n \to \infty$ , we have $x_{n} ⪯ x$ for all $n \in N \cup {0}$ .

Consider the first-order periodic boundary value problem

{\begin{cases} x^{'} (t) = f (t, x (t)), \\ x (0) = x (T), \end{cases}

(3.1)

where $t \in I = [0, T]$ with $T > 0$ and $f : [0, T] \times R \to R$ is a continuous function.

A lower solution for (3.1) is a function $α \in C^{1} [0, T]$ such that

{\begin{cases} α^{'} (t) \leq f (t, α (t)), \\ α (0) \leq α (T), \end{cases}

(3.2)

where $t \in I = [0, T]$ .

Assume that there exists $λ > 0$ such that for all $x, y \in X$ we have

| f (t, x (t)) + λ x (t) - f (t, y (t)) - λ y (t) | \leq \frac{λ}{2^{p - 1}} \sqrt[p]{ln (| x (t) - y (t) |^{p} + 1)} .

(3.3)

Then the existence of a lower solution for (3.1) provides the existence of an unique solution of (3.1).

Problem (3.1) can be rewritten as

{\begin{cases} x^{'} (t) + λ x (t) = f (t, x (t)) + λ x (t), \\ x (0) = x (T) . \end{cases}

Consider

{\begin{cases} x^{'} (t) + λ x (t) = δ (t) = F (t, x (t)), \\ x (0) = x (T), \end{cases}

where $t \in I$ .

Using the variation of parameters formula, we get

x (t) = x (0) e^{- λ t} + \int_{0}^{t} e^{- λ (t - s)} δ (s) d s,

(3.4)

which yields

x (T) = x (0) e^{- λ T} + \int_{0}^{T} e^{- λ (T - s)} δ (s) d s .

Since $x (0) = x (T)$ , we get

x (0) [1 - e^{- λ T}] = e^{- λ T} \int_{0}^{T} e^{λ (s)} δ (s) d s

or

x (0) = \frac{1}{e^{λ T} - 1} \int_{0}^{T} e^{λ s} δ (s) d s .

Substituting the value of $x (0)$ in (3.4) we arrive at

x (t) = \int_{0}^{T} G (t, s) δ (s) d s,

where

G (t, s) = {\begin{cases} \frac{e^{λ (T + s - t)}}{e^{λ T} - 1}, & 0 \leq s \leq t \leq T, \\ \frac{e^{λ (s - t)}}{e^{λ T} - 1}, & 0 \leq t \leq s \leq T . \end{cases}

Now define the operator $S : C [0, T] \to C [0, T]$ by

S x (t) = \int_{0}^{T} G (t, s) F (s, x (s)) d s .

The mapping S is nondecreasing [26]. Note that if $u \in C [0, T]$ is a fixed point of S then $u \in C^{1} [0, T]$ is a solution of (3.1).

Let $x, y \in X$ . Then we have

\begin{aligned} 2^{p - 1} | S x (t) - S y (t) | & = 2^{p - 1} | \int_{0}^{T} G (t, s) F (s, x (s)) d s - \int_{0}^{T} G (t, s) F (s, y (s)) d s | \\ \leq 2^{p - 1} \int_{0}^{T} | G (t, s) | [| F (s, x (s)) - F (s, y (s)) |] d s \\ \leq 2^{p - 1} \int_{0}^{T} | G (t, s) | \frac{λ}{2^{p - 1}} \sqrt[p]{ln (| x (t) - y (t) |^{p} + 1)} d s \\ \leq λ \sqrt[p]{ln (d (x, y) + 1)} [\int_{0}^{t} \frac{e^{λ (T + s - t)}}{e^{λ T} - 1} d s + \int_{t}^{T} \frac{e^{λ (s - t)}}{e^{λ T} - 1} d s] \\ = λ \sqrt[p]{ln (d (x, y) + 1)} [\frac{1}{λ (e^{λ T} - 1)} (e^{λ (T + s - t)} |_{0}^{t} + e^{λ (s - t)} |_{t}^{T})] \\ = λ \sqrt[p]{ln (d (x, y) + 1)} [\frac{1}{λ (e^{λ T} - 1)} (e^{λ T} - e^{λ (T - t)} + e^{λ (T - t)} - 1)] \\ = \sqrt[p]{ln (d (x, y) + 1)} \\ \leq \sqrt[p]{ln (M (x, y) + 1)}, \end{aligned}

or, equivalently,

2^{p - 1} {(| S x (t) - S y (t) |)}^{p} \leq ln (M (x, y) + 1),

which shows that

2^{p - 1} d (S x, S y) \leq ln (M (x, y) + 1),

where

M (x, y) = max {d (x, y), \frac{d (x, S x) d (y, S y)}{1 + d (x, y)}, \frac{d (x, S x) d (y, S y)}{1 + d (S x, S y)}}

or

\begin{array}{rcl} M (x, y) & = & max {d (x, y), \frac{d (x, S x) d (x, S y) + d (y, S y) d (y, S x)}{1 + 2^{p - 1} [d (x, S x) + d (y, S y)]}, \\ \frac{d (x, S x) d (x, S y) + d (y, S y) d (y, S x)}{1 + d (x, S y) + d (y, S x)}}, \end{array}

or

\begin{array}{rcl} M (x, y) & = & max {d (x, y), \frac{d (x, S x) d (y, S y)}{1 + 2^{p - 1} [d (x, y) + d (x, S y) + d (y, S x)]}, \\ \frac{d (x, S y) d (x, y)}{1 + 2^{p - 1} d (x, S x) + 2^{3 p - 3} [d (y, S x) + d (y, S y)]}} . \end{array}

Finally, let α be a lower solution for (3.1). In [26] it was shown that $α ⪯ S (α)$ .

Hence, the hypotheses of Theorem 8 are satisfied with $ψ (t) = ln (t + 1)$ . Therefore, there exists a fixed point $\hat{x} \in C [0, T]$ such that $S \hat{x} = \hat{x}$ .

Remark 2 In the above theorem, we can replace (3.3) by the following inequality:

| f (t, x (t)) + λ x (t) - f (t, y (t)) - λ y (t) | \leq \frac{λ}{2^{\frac{p^{2} - 1}{p}}} \sqrt[p]{e^{- M (x, y)} M (x, y)}

(3.5)

for all $x \neq y \in X$ .

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The authors are grateful to the referees for valuable remarks that helped them to improve the exposition in the paper.

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Department of Mathematics, Science and Research Branch, Islamic Azad University, Tehran, Iran
Rogheieh J Shahkoohi & Abdolrahman Razani

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Shahkoohi, R.J., Razani, A. Some fixed point theorems for rational Geraghty contractive mappings in ordered b-metric spaces. J Inequal Appl 2014, 373 (2014). https://doi.org/10.1186/1029-242X-2014-373

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Received: 16 May 2014
Accepted: 09 September 2014
Published: 26 September 2014
DOI: https://doi.org/10.1186/1029-242X-2014-373

Some fixed point theorems for rational Geraghty contractive mappings in ordered b-metric spaces

Abstract

1 Introduction

2 Main results

3 Application

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