Common fixed point theorems for non-compatible self-maps in generalized metric spaces

Abstract

By using R-weak commutativity of type $(A_g)$ and non-compatible conditions of self-mapping pairs in generalized metric space, without the conditions for the completeness of space and the continuity of mappings, we establish some new common fixed point theorems for two self-mappings. Our results differ from other results already known. An example is provided to support our new result.

MSC:47H10, 54H25, 54E50.

1 Introduction and preliminaries

In 1976, Jungck [1] proved a common fixed point theorem of commuting mappings in a metric space. In 1982, Sessa [2] introduced the concept of weakly commuting mappings, which is a generalization of the concept of commuting mappings, and he has proved some fixed point theorems for weakly commuting mappings. In 1986, Jungck [3] introduced more generalized commuting mappings, called compatible mappings, which are more general than commuting and weakly commuting mappings. These concepts have been useful for obtaining more comprehensive fixed point theorems. In 1992, Dhage [4] introduced the concept of D-metric space. Recently, Mustafa and Sims [5] have shown that most of the results concerning Dhage’s D-metric spaces are invalid. Therefore, they introduced an improved version of the generalized metric space structure and called it a G-metric space [6].

Based on the notion of generalized metric spaces, Mustafa et al. [7–9], Aydi et al. [10], Aydi [11], Gajié and Stojakovié [12], Zhou and Gu [13] obtained some fixed point results for mappings satisfying different contractive conditions. Shatanawi [14] obtained some fixed point results for Φ-maps in G-metric spaces. Chugh et al. [15] obtained some fixed point results for maps satisfying property P in G-metric spaces. In 2010, Manro et al. [16] obtained some fixed point results for expansion mappings in G-metric spaces.

The study of common fixed point problems in G-metric spaces was initiated by Abbas and Rhoades [17]. Subsequently, many authors obtained many common fixed point theorems for the mappings satisfying different contractive conditions; see [18–29] for more details. Recently, some authors have used the $(E.A)$ property in generalized metric space to prove common fixed point results, such as Abbas et al. [30], Mustafa et al. [31], Long et al. [32], Gu and Yin [33], Gu and Shatanawi [34].

Very recently, Jleli and Samet [35] and Samet et al. [36] noticed that some fixed point theorems in the context of a G-metric space can be concluded by some existing results in the setting of a (quasi-)metric space. In fact, if the contraction condition of the fixed point theorem on a G-metric space can be reduced to two variables instead of three variables, then one can construct an equivalent fixed point theorem in the setting of a usual metric space. More precisely, in [35, 36], the authors noticed that $d(x,y)=G(x,y,y)$ forms a quasi-metric. Therefore, if one can transform the contraction condition of existence results in a G-metric space in such terms, $G(x,y,y)$, then the related fixed point results become the well-known fixed point results in the context of a quasi-metric space.

Now we give basic definitions and some basic results [6], which are helpful for improving our main results.

Definition 1.1 [6]

Let X be a nonempty set, and let $G:X\times X\times X⟶R^{+}$ be a function satisfying the following axioms:

• (G1) $G(x,y,z)=0$ if $x=y=z$;

• (G2) 0$<G(x,x,y)$ for all $x,y\in X$ with $x\ne y$;

• (G3) $G(x,x,y)\le G(x,y,z)$ for all $x,y,z\in X$ with $z\ne y$;

• (G4) $G(x,y,z)=G(x,z,y)=G(y,z,x)=\cdots$ (symmetry in all three variables); and

• (G5) $G(x,y,z)\le G(x,a,a)+G(a,y,z)$ for all $x,y,z,a\in X$ (rectangle inequality).

Then the function G is called a generalized metric, or more specifically, a G-metric on X and the pair $(X,G)$ is called a G-metric space.

It is well known that the function $G(x,y,z)$ on the G-metric space X is jointly continuous in all three of its variables, and $G(x,y,z)=0$ if and only if $x=y=z$ (see [6]).

Definition 1.2 [6]

Let $(X,G)$ be a G-metric space, $\{x_n\}\subset X$ be a sequence. Then the sequence $\{x_n\}$ is called:

1. (i)

   a G-convergent sequence if, for any $ϵ>0$, there is an $x\in X$ and an $n_0\in \mathbb{N}$, such that for all $n,m\ge n_0$, $G(x_n,x_m,x)<ϵ$; i.e. if ${lim}_{n,m\to \mathrm{\infty }}G(x_n,x_m,x)=0$;

2. (ii)

   a G-Cauchy sequence if, for any $ϵ>0$, there is an $n_0\in \mathbb{N}$ (the set of natural numbers) such that for all $n,m,l\ge n_0$, $G(x_n,x_m,x_l)<ϵ$; i.e. if $G(x_n,x_m,x_l)\to 0$ as $n,m,l\to \mathrm{\infty }$.

A G-metric space $(X,G)$ is said to be G-complete if every G-Cauchy sequence in $(X,G)$ is G-convergent in X. It is well known that $\{x_n\}$ is G-convergent to $x\in X$.

Proposition 1.1 [6]

Let $(X,G)$ be a G-metric space, then the following statements are equivalent:

1. (1)

   $\{x_n\}$ is G-convergent to x;

2. (2)

   $G(x_n,x_n,x)\to 0$ as $n\to \mathrm{\infty }$;

3. (3)

   $G(x_n,x,x)\to 0$ as $n\to \mathrm{\infty }$;

4. (4)

   $G(x_n,x_m,x)\to 0$ as $n,m\to \mathrm{\infty }$.

Proposition 1.2 [6]

Let $(X,G)$ be a G-metric space. Then the function $G(x,y,z)$ is jointly continuous in all of its three variables.

Definition 1.3 [6]

Let $(X,G)$ and $(X^{\prime },G^{\prime })$ be G-metric space, and $f:(X,G)\to (X^{\prime },G^{\prime })$ be a function. Then f is said to be G-continuous at a point $a\in X$ if and only if for every $ϵ>0$, there is $\delta >0$ such that $x,y\in X$ and $G(a,x,y)<\delta$ implies $G^{\prime }(f(a),f(x),f(y))<ϵ$. A function f is G-continuous at X if and only if it is G-continuous at all $a\in X$.

Proposition 1.3 [6]

Let $(X,G)$ and $(X^{\prime },G^{\prime })$ be a G-metric space. Then $f:X\to X^{\prime }$ is G-continuous at $x\in X$ if and only if it is G-sequentially continuous at x, that is, whenever $\{x_n\}$ is G-convergent to x, $\{f(x_n)\}$ is G-convergent to $f(x)$.

Definition 1.4 [18]

The self-mappings f and g of a G-metric space $(X,G)$ are said to be compatible if ${lim}_{n\to \mathrm{\infty }}G(fg{x}_n,gf{x}_n,gf{x}_n)=0$ and ${lim}_{n\to \mathrm{\infty }}G(gf{x}_n,fg{x}_n,fg{x}_n)=0$, whenever $\{x_n\}$ is a sequence in X such that ${lim}_{n\to \mathrm{\infty }}f{x}_n={lim}_{n\to \mathrm{\infty }}g{x}_n=t$, for some $t\in X$.

In 2010, Manro et al. [16] introduced the concepts of weakly commuting, R-weakly commuting mappings, and R-weakly commuting mappings of type $(P)$, $(A_f)$, and $(A_g)$ in G-metric space as follows.

Definition 1.5 [16]

A pair of self-mappings $(f,g)$ of a G-metric space are said to be weakly commuting if

$$G(fgx,gfx,gfx)\le G(fx,gx,gx),\mathrm{\forall }x\in X.$$

Definition 1.6 [16]

A pair of self-mappings $(f,g)$ of a G-metric space are said to be R-weakly commuting if there exists some positive real number R such that

$$G(fgx,gfx,gfx)\le RG(fx,gx,gx),\mathrm{\forall }x\in X.$$

Remark 1.1 If $R\le 1$, then R-weakly commuting mappings are weakly commuting.

Definition 1.7 [16]

A pair of self-mappings $(f,g)$ of a G-metric space $(X,G)$ are said to be

1. (a)

   R-weakly commuting mappings of type ($A_f$) if there exists some positive real number R such that $G(fgx,ggx,ggx)\le RG(fx,gx,gx)$, for all x in X.

2. (b)

   R-weakly commuting mappings of type $(A_g)$ if there exists some positive real number R such that $G(gfx,ffx,ffx)\le RG(gx,fx,fx)$, for all x in X.

3. (c)

   R-weakly commuting mappings of type $(P)$ if there exists some positive real number R such that $G(ffx,ggx,ggx)\le RG(fx,gx,gx)$, for all x in X.

Proposition 1.4 [6]

Every G-metric on X defines a metric $d_G$ on X by

$$d_G(x,y)=G(x,y,y)+G(y,x,x),\mathrm{\forall }x,y\in X.$$

For a symmetric G-metric space, one obtains

$$d_G(x,y)=2G(x,y,y),\mathrm{\forall }x,y\in X.$$

However, if G is not symmetric, then the following inequality holds:

$$\frac{3}{2}G(x,y,y)\le d_G(x,y)\le 3G(x,y,y),\mathrm{\forall }x,y\in X.$$

It is also obvious that

$$G(x,x,y)\le 2G(x,y,y).$$

2 Main results

Theorem 2.1 Let $(X,G)$ be a G-metric space and $(f,g)$ be a pair of non-compatible self-mappings with $\overline{fX}\subset gX$ (here $\overline{fX}$ denotes the closure of fX). Assume the following conditions are satisfied:

$$\begin{array}{r}G(fx,fy,fz)\\ \le \alpha max\left\{\begin{array}{c}G(gx,gy,gz),\frac{G(fx,gx,gx)+G(fy,gy,gy)}{2},\frac{G(fy,gy,gy)+G(fz,gz,gz)}{2},\\ \frac{G(fz,gz,gz)+G(fx,gx,gx)}{2},\frac{G(fx,gy,gz)+G(gx,fy,gz)}{2},\frac{G(gx,fy,gz)+G(gx,gy,fz)}{2}\end{array}\right\}\end{array}$$

(2.1)

for all $x,y,z\in X$. Here $\alpha \in [0,1)$. If $(f,g)$ are a pair of R-weakly commuting mappings of type $(A_g)$, then f and g have a unique common fixed point (say t) and both f and g are not G-continuous at t.

Proof Since f and g are non-compatible mappings, there exists a sequence $\{x_n\}\subset X$, such that

$$\underset{n\to \mathrm{\infty }}{lim}f{x}_n=\underset{n\to \mathrm{\infty }}{lim}g{x}_n=t,t\in X,$$

but either ${lim}_{n\to \mathrm{\infty }}G(fg{x}_n,gf{x}_n,gf{x}_n)$ or ${lim}_{n\to \mathrm{\infty }}G(gf{x}_n,fg{x}_n,fg{x}_n)$ does not exist or exists and is different from zero. Since $t\in \overline{fX}\subset gX$, there must exist a $u\in X$ satisfying $t=gu$. We can assert that $fu=gu$. If not, from condition (2.1), we get

$$\begin{array}{r}G(fu,f{x}_n,f{x}_n)\\ \le \alpha max\left\{\begin{array}{c}G(gu,g{x}_n,g{x}_n),\frac{G(fu,gu,gu)+G(f{x}_n,g{x}_n,g{x}_n)}{2},\frac{G(f{x}_n,g{x}_n,g{x}_n)+G(f{x}_n,g{x}_n,g{x}_n)}{2},\\ \frac{G(f{x}_n,g{x}_n,g{x}_n)+G(fu,gu,gu)}{2},\frac{G(fu,g{x}_n,g{x}_n)+G(gu,f{x}_n,g{x}_n)}{2},\frac{G(gu,f{x}_n,g{x}_n)+G(gu,g{x}_n,f{x}_n)}{2}\end{array}\right\}.\end{array}$$

Letting $n\to \mathrm{\infty }$ at both sides, we obtain

$$\begin{array}{r}G(fu,gu,gu)\\ \le \alpha max\left\{\begin{array}{c}G(gu,gu,gu),\frac{G(fu,gu,gu)+G(gu,gu,gu)}{2},\frac{G(fu,gu,gu)+G(fu,gu,gu)}{2},\\ \frac{G(fu,gu,gu)+G(fu,gu,gu)}{2},\frac{G(fu,gu,gu)+G(gu,fu,gu)}{2},\frac{G(gu,fu,gu)+G(gu,gu,fu)}{2}\end{array}\right\}\\ =\alpha G(fu,gu,gu).\end{array}$$

Since $\alpha \in [0,1)$, we get $G(fu,gu,gu)=0$, and so $fu=gu$.

Since $(f,g)$ are a pair of R-weakly commuting mappings of type $(A_g)$, we have

$$G(gfu,ffu,ffu)\le RG(gu,fu,fu)=0.$$

It means $ffu=gfu$.

Next, we prove $ffu=fu$. In fact, if $ffu\ne fu$, from condition (2.1), $fu=gu$ and $ffu=gfu$, we have

$$\begin{array}{r}G(fu,ffu,ffu)\\ \le \alpha max\left\{\begin{array}{c}G(gu,gfu,gfu),\frac{G(fu,gu,gu)+G(ffu,gfu,gfu)}{2},\frac{G(ffu,gfu,gfu)+G(ffu,gfu,gfu)}{2},\\ \frac{G(ffu,gfu,gfu)+G(fu,gu,gu)}{2},\frac{G(fu,gfu,gfu)+G(gu,ffu,gfu)}{2},\frac{G(gu,ffu,gfu)+G(gu,gfu,ffu)}{2}\end{array}\right\}\\ =\alpha G(fu,ffu,ffu).\end{array}$$

From $\alpha \in [0,1)$ we have $fu=ffu$, which implies that $fu=ffu=gfu$, and so $t=fu$ is a common fixed point of f and g.

Next we prove that the common fixed point t is unique.

Actually, suppose w is also a common fixed point of f and g and $w\ne t$, then using the condition (2.1), we have

$$G(t,w,w)=G(ft,fw,fw)\le \alpha G(t,w,w),$$

which implies that $t=w$, so that uniqueness is proved.

Now, we prove that f and g are not G-continuous at t. In fact, if f is G-continuous at t, we consider the sequence $\{x_n\}$; then we have

$$\underset{n\to \mathrm{\infty }}{lim}ff{x}_n=ft=t,\underset{n\to \mathrm{\infty }}{lim}fg{x}_n=ft=t.$$

Since f and g are R-weakly commuting mappings of type $(A_g)$, we get

$$G(gf{x}_n,ff{x}_n,ff{x}_n)\le RG(g{x}_n,f{x}_n,f{x}_n),$$

so that we have

$$\underset{n\to \mathrm{\infty }}{lim}G(gf{x}_n,ff{x}_n,ff{x}_n)=0,$$

it follows that

$$\underset{n\to \mathrm{\infty }}{lim}gf{x}_n=ft.$$

Hence, we can get

$$\underset{n\to \mathrm{\infty }}{lim}G(fg{x}_n,gf{x}_n,gf{x}_n)=G(ft,ft,ft)=0$$

and

$$\underset{n\to \mathrm{\infty }}{lim}G(gf{x}_n,fg{x}_n,fg{x}_n)=G(ft,ft,ft)=0.$$

This contradicts with f and g being non-compatible, so f is not G-continuous at t.

If g is G-continuous at t, then we have

$$\underset{n\to \mathrm{\infty }}{lim}gf{x}_n=gt=t,\underset{n\to \mathrm{\infty }}{lim}gg{x}_n=gt=t.$$

Since f and g are R-weakly commuting mappings of type $(A_g)$, we get

$$G(gf{x}_n,ff{x}_n,ff{x}_n)\le RG(g{x}_n,f{x}_n,f{x}_n),$$

so that we have

$$\underset{n\to \mathrm{\infty }}{lim}G(gf{x}_n,ff{x}_n,ff{x}_n)=0,$$

and it follows that

$$\underset{n\to \mathrm{\infty }}{lim}ff{x}_n=gt=ft=t.$$

This contradicts with f being not G-continuous at t, which implies that g is not G-continuous at t. This completes the proof. □

Next, we give an example to support Theorem 2.1.

Example 2.1 Let $X=[2,20]$ be a G-metric space with

$$G(x,y,z)=|x-y|+|y-z|+|z-x|.$$

We define mappings f and g on X by

$$fx=\{\begin{array}{ll}2,& \text{if }x=2\text{ or }5<x\le 20,\\ 6,& \text{if }2<x\le 5,\end{array}gx=\{\begin{array}{ll}2,& \text{if }x=2,\\ 18,& \text{if }2<x\le 5,\\ \frac{x+1}{3},& \text{if }5<x\le 20.\end{array}$$

Clearly, from the above functions we know that $\overline{fX}\subset gX$, and the pair $(f,g)$ are non-compatible self-maps. To see that f and g are non-compatible, consider a sequence $\{x_n\}=\{5+\frac{1}{n}\}$. We have $f{x}_n\to 2$, $g{x}_n\to 2$, $fg{x}_n\to 6$ and $gf{x}_n\to 2$. Thus

$$\underset{n\to \mathrm{\infty }}{lim}G(gf{x}_n,fg{x}_n,fg{x}_n)=G(2,6,6)=8\ne 0.$$

On the other hand, there exists $R=1$ such that $G(gfx,ffx,ffx)\le RG(gx,fx,fx)$ for all x in X, that is, the pair $(f,g)$ are R-weakly commuting mappings of type $(A_g)$.

Now we prove that the mappings f and g satisfy the condition (2.1) of Theorem 2.1 with $\alpha =\frac{2}{3}$. For this, let

$$M(x,y,z)=max\left\{\begin{array}{c}G(gx,gy,gz),\frac{G(fx,gx,gx)+G(fy,gy,gy)}{2},\frac{G(fy,gy,gy)+G(fz,gz,gz)}{2},\\ \frac{G(fz,gz,gz)+G(fx,gx,gx)}{2},\frac{G(fx,gy,gz)+G(gx,fy,gz)}{2},\frac{G(gx,fy,gz)+G(gx,gy,fz)}{2}\end{array}\right\}.$$

We consider the following cases:

Case (1) If $x,y,z\in \{2\}\cup (5,20]$, then we have $G(fx,fy,fz)=G(2,2,2)=0$, and hence (2.1) is obviously satisfied.

Case (2) If $x,y,z\in (2,5]$, then we have $G(fx,fy,fz)=G(6,6,6)=0$, and hence (2.1) is obviously satisfied.

Case (3) If $x=y=2$, $z\in (2,5]$, then we have $G(fx,fy,fz)=G(2,2,6)=8$ and $G(gx,gy,gz)=G(2,2,18)=32$. Thus we obtain

$$G(fx,fy,fz)=8<\frac{2}{3}\cdot 32=\frac{2}{3}G(gx,gy,gz)\le \frac{2}{3}M(x,y,z).$$

Case (4) If $x=z=2$, $y\in (2,5]$, then we have $G(fx,fy,fz)=G(2,6,2)=8$ and $G(gx,gy,gz)=G(2,18,2)=32$. Thus we obtain

$$G(fx,fy,fz)=8<\frac{2}{3}\cdot 32=\frac{2}{3}G(gx,gy,gz)\frac{2}{3}\le M(x,y,z).$$

Case (5) If $y=z=2$, $x\in (2,5]$, then we have $G(fx,fy,fz)=G(6,2,2)=8$ and $G(gx,gy,gz)=G(18,2,2)=32$. Thus we obtain

$$G(fx,fy,fz)=8<\frac{2}{3}\cdot 32=\frac{2}{3}G(gx,gy,gz)\le \frac{2}{3}M(x,y,z).$$

Case (6) If $x=2$, $y,z\in (2,5]$, then we have $G(fx,fy,fz)=G(2,6,6)=8$ and $G(gx,gy,gz)=G(2,18,18)=32$. Thus we obtain

$$G(fx,fy,fz)=8<\frac{2}{3}\cdot 32=\frac{2}{3}G(gx,gy,gz)\le \frac{2}{3}M(x,y,z).$$

Case (7) If $y=2$, $x,z\in (2,5]$, then we have $G(fx,fy,fz)=G(6,2,6)=8$ and $G(gx,gy,gz)=G(18,2,18)=32$. Thus we obtain

$$G(fx,fy,fz)=8<\frac{2}{3}\cdot 32=\frac{2}{3}G(gx,gy,gz)\le \frac{2}{3}M(x,y,z).$$

Case (8) If $z=2$, $x,y\in (2,5]$, then we have $G(fx,fy,fz)=G(6,6,2)=8$ and $G(gx,gy,gz)=G(18,18,2)=32$. Thus we obtain

$$G(fx,fy,fz)=8<\frac{2}{3}\cdot 32=\frac{2}{3}G(gx,gy,gz)\le \frac{2}{3}M(x,y,z).$$

Case (9) If $x,y\in (2,5]$, $z\in (5,20]$, then we have $G(fx,fy,fz)=G(6,6,2)=8$ and

$$\frac{G(fx,gx,gx)+G(fy,gy,gy)}{2}=\frac{G(6,18,18)+G(6,18,18)}{2}=24.$$

Thus we obtain

$$G(fx,fy,fz)=8<\frac{2}{3}\cdot 24=\frac{2}{3}\cdot \frac{G(fx,gx,gx)+G(fy,gy,gy)}{2}\le \frac{2}{3}M(x,y,z).$$

Case (10) If $x,z\in (2,5]$, $y\in (5,20]$, then we have $G(fx,fy,fz)=G(6,2,6)=8$ and

$$\frac{G(fz,gz,gz)+G(fx,gx,gx)}{2}=\frac{G(6,18,18)+G(6,18,18)}{2}=24.$$

Thus we obtain

$$G(fx,fy,fz)=8<\frac{2}{3}\cdot 24=\frac{2}{3}\cdot \frac{G(fz,gz,gz)+G(fx,gx,gx)}{2}\le \frac{2}{3}M(x,y,z).$$

Case (11) If $y,z\in (2,5]$, $x\in (5,20]$, then we have $G(fx,fy,fz)=G(2,6,6)=8$ and

$$\frac{G(fy,gy,gy)+G(fz,gz,gz)}{2}=\frac{G(6,18,18)+G(6,18,18)}{2}=24.$$

Thus we obtain

$$G(fx,fy,fz)=8<\frac{2}{3}\cdot 32=\frac{2}{3}\cdot \frac{G(fy,gy,gy)+G(fz,gz,gz)}{2}\le \frac{2}{3}M(x,y,z).$$

Case (12) If $x,y\in (5,20]$, $z\in (2,5]$, then we have $G(fx,fy,fz)=G(2,2,6)=8$ and

$$\frac{G(fx,gy,gz)+G(gx,fy,gz)}{2}=\frac{G(2,\frac{y+1}{3},18)+G(\frac{x+1}{3},2,18)}{2}=32.$$

Thus we obtain

$$G(fx,fy,fz)=8<\frac{2}{3}\cdot 32=\frac{2}{3}\cdot \frac{G(fx,gy,gz)+G(gx,fy,gz)}{2}\le \frac{2}{3}M(x,y,z).$$

Case (13) If $x,z\in (5,20]$, $y\in (2,5]$, then we have $G(fx,fy,fz)=G(2,6,2)=8$ and

$$\frac{G(fx,gx,gx)+G(fy,gy,gy)}{2}=\frac{G(2,\frac{x+1}{3},\frac{x+1}{3})+G(6,18,18)}{2}=10+\frac{x+1}{3}\in (12,17].$$

Thus we obtain

$$G(fx,fy,fz)=8=\frac{2}{3}\cdot 12<\frac{2}{3}\cdot \frac{G(fx,gx,gx)+G(fy,gy,gy)}{2}\le \frac{2}{3}M(x,y,z).$$

Case (14) If $y,z\in (5,20]$, $x\in (2,5]$, then we have $G(fx,fy,fz)=G(6,2,2)=8$ and

$$\frac{G(fx,gx,gx)+G(fy,gy,gy)}{2}=\frac{G(6,18,18)+G(2,\frac{y+1}{3},\frac{y+1}{3})}{2}=10+\frac{y+1}{3}\in (12,17].$$

Thus we obtain

$$G(fx,fy,fz)=8=\frac{2}{3}\cdot 12<\frac{G(fx,gx,gx)+G(fy,gy,gy)}{2}\le \frac{2}{3}M(x,y,z).$$

Case (15) If $x=2$, $y\in (2,5]$, $z\in (5,20]$, then we have $G(fx,fy,fz)=G(2,6,2)=8$ and

$$\frac{G(fx,gx,gx)+G(fy,gy,gy)}{2}=\frac{G(2,2,2)+G(6,18,18)}{2}=12.$$

Thus we obtain

$$G(fx,fy,fz)=8=\frac{2}{3}\cdot \frac{G(fx,gx,gx)+G(fy,gy,gy)}{2}\le \frac{2}{3}M(x,y,z).$$

Case (16) If $x=2$, $y\in (5,20]$, $z\in (2,5]$, then we have $G(fx,fy,fz)=G(2,2,6)=8$ and

$$\frac{G(fz,gz,gz)+G(fx,gx,gx)}{2}=\frac{G(6,18,18)+G(2,2,2)}{2}=12.$$

Thus we obtain

$$G(fx,fy,fz)=8=\frac{2}{3}\cdot \frac{G(fz,gz,gz)+G(fx,gx,gx)}{2}\le \frac{2}{3}M(x,y,z).$$

Case (17) If $x\in (2,5]$, $y=2$, $z\in (5,20]$, then we have $G(fx,fy,fz)=G(6,2,2)=8$ and

$$\frac{G(fx,gx,gx)+G(fy,gy,gy)}{2}=\frac{G(6,18,18)+G(2,2,2)}{2}=12.$$

Thus we obtain

$$G(fx,fy,fz)=8=\frac{2}{3}\cdot \frac{G(fx,gx,gx)+G(fy,gy,gy)}{2}\le \frac{2}{3}M(x,y,z).$$

Case (18) If $x\in (5,20]$, $y=2$, $z\in (2,5]$, then we have $G(fx,fy,fz)=G(2,2,6)=8$ and

$$\frac{G(fy,gy,gy)+G(fz,gz,gz)}{2}=\frac{G(2,2,2)+G(6,18,18)}{2}=12.$$

Thus we obtain

$$G(fx,fy,fz)=8=\frac{2}{3}\cdot \frac{G(fy,gy,gy)+G(fz,gz,gz)}{2}\le \frac{2}{3}M(x,y,z).$$

Case (19) If $x\in (2,5]$, $y\in (5,20]$, $z=2$, then we have $G(fx,fy,fz)=G(6,2,2)=8$ and

$$\frac{G(fz,gz,gz)+G(fx,gx,gx)}{2}=\frac{G(2,2,2)+G(6,18,18)}{2}=12.$$

Thus we obtain

$$G(fx,fy,fz)=8=\frac{2}{3}\cdot \frac{G(fz,gz,gz)+G(fx,gx,gx)}{2}\le \frac{2}{3}M(x,y,z).$$

Case (20) If $x\in (5,20]$, $y\in (2,5]$, $z=2$, then we have $G(fx,fy,fz)=G(2,6,2)=8$ and

$$\frac{G(fy,gy,gy)+G(fz,gz,gz)}{2}=\frac{G(6,18,18)+G(2,2,2)}{2}=12.$$

Thus we obtain

$$G(fx,fy,fz)=8=\frac{2}{3}\cdot \frac{G(fy,gy,gy)+G(fz,gz,gz)}{2}\le \frac{2}{3}M(x,y,z).$$

Then in all the above cases, the mappings f and g satisfy the condition (2.1) of Theorem 2.1 with $\alpha =\frac{2}{3}$, so that all the conditions of Theorem 2.1 are satisfied. Moreover, 2 is the unique common fixed point of f and g.

Theorem 2.2 Let $(X,G)$ be a G-metric space and let $(f,g)$ be a pair of non-compatible self-mappings such that

$$\begin{array}{r}G(fx,fy,fz)\\ \le \alpha max\{G(gx,gy,gz),G(fx,gy,gz),G(fy,gy,gz),\frac{G(fz,gx,gy)+G(fy,gx,gz)}{2}\}\end{array}$$

(2.2)

for any $x,y,z\in X$. Here $\alpha \in [0,1)$. Assume the following conditions hold:

1. (i)

   for any sequence $\{x_n\}$ that satisfies the condition ${lim}_{n\to \mathrm{\infty }}f{x}_n={lim}_{n\to \mathrm{\infty }}g{x}_n=t\in X$, we have ${lim}_{n\to \mathrm{\infty }}ff{x}_n=ft$ and ${lim}_{n\to \mathrm{\infty }}gf{x}_n=gt$;

2. (ii)

   $(f,g)$ are a pair of R-weakly commuting mappings of type $(A_g)$.

Then f and g have a unique common fixed point in X.

Proof Since f and g are non-compatible mappings, there exists a sequence $\{x_n\}\subset X$, such that

$$\underset{n\to \mathrm{\infty }}{lim}f{x}_n=\underset{n\to \mathrm{\infty }}{lim}g{x}_n=t,t\in X,$$

but, either ${lim}_{n\to \mathrm{\infty }}G(fg{x}_n,gf{x}_n,gf{x}_n)$ or ${lim}_{n\to \mathrm{\infty }}G(gf{x}_n,fg{x}_n,fg{x}_n)$ does not exist or exists and is different from zero.

From condition (i), we have

$$\underset{n\to \mathrm{\infty }}{lim}ff{x}_n=ft,\underset{n\to \mathrm{\infty }}{lim}gf{x}_n=gt.$$

Since $(f,g)$ are a pair of R-weakly commuting mappings of type $(A_g)$, we can get

$$G(gf{x}_n,ff{x}_n,ff{x}_n)\le RG(g{x}_n,f{x}_n,f{x}_n).$$

Letting $n\to \mathrm{\infty }$, we have $G(gt,ft,ft)\le RG(t,t,t)=0$. Thus we know $ft=gt$.

From the condition (2.2), we have

$$\begin{array}{r}G(ft,f{x}_n,f{x}_n)\\ \le \alpha max\{G(gt,g{x}_n,g{x}_n),G(ft,g{x}_n,g{x}_n),G(f{x}_n,g{x}_n,g{x}_n),\\ \frac{G(f{x}_n,gt,g{x}_n)+G(f{x}_n,gt,g{x}_n)}{2}\}.\end{array}$$

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

$$\begin{array}{rcl}G(ft,t,t)& \le & \alpha max\{G(gt,t,t),G(ft,t,t),G(t,t,t),\frac{G(t,gt,t)+G(t,gt,t)}{2}\}\\ =& \alpha G(ft,t,t).\end{array}$$

Since $\alpha \in [0,1)$, therefore, $G(ft,t,t)=0$. Thus, we get $t=ft=gt$.

Suppose w is another fixed point of f and g and $w\ne t$. Letting $x=t$, $y=w$, $z=w$ under the condition (2.2), we obtain

$$\begin{array}{r}G(ft,fw,fw)\\ \le \alpha max\{G(gt,gw,gw),G(ft,gw,gw),G(fw,gw,gw),\frac{G(fw,gt,gw)+G(fw,gt,gw)}{2}\}\\ =\alpha max\{G(t,w,w),G(t,w,w),G(w,w,w),\frac{G(w,t,w)+G(w,t,w)}{2}\}\\ =\alpha G(t,w,w).\end{array}$$

Since $\alpha \in [0,1)$, we find that $G(t,w,w)=0$. Therefore, we have $t=w$. So, the common fixed point of f and g is unique. Thus, we complete the proof. □