Let X be a nonempty set and let G: X × X × X→R+ be a function satisfying the following properties:

• (1)

  G (x, y, z) = 0 if x = y = z

• (2)

  0 < G (x, x, y) for all x, y ∈ X with x ≠y,

• (3)

  G(x, x, y) ≤ G(x, y, z) for all x, y, z ∈ X with z ≠ y,

• (4)

  G(x, y, z) = G(x, z, y) = G(y, z, x) = ...(symmetry in all three variables)

• (5)

  G(x, y, z) ≤ G(x, a, a) + G(a, y, z) for all x, y, z, a ∈ X (rectangle inequality).

Then the function G is called a G-metric on X, and the pair (X, G) is called a G-metric space.

Let (X,G) be a G-metric space and let {xn} be a sequence of points of X, a point x ∈ X is said to be the limit of the sequence {xn} if limn,m→∞Gx,xn,xm=0 and we say that the sequence {xn} is G-convergent to x. Thus, if {xn}→x in a G-metric space (X, G), then for any ε > 0, there exists a positive integer N such that G(x, xn, xm) < ε, for all n, m ≥ N.

It has been shown in [16] that the G-metric induces a Hausdorff topology and the convergence described in the above definition is relative to this topology. The topology being Hausdorff, a sequence can converge at most to one point.

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

• (1)

  {xn} is G-convergent to x.

• (2)

  G(xn, xn, x)→0 as n→∞.

• (3)

  G(xn, x, x)→0 as n→∞.

• (4)

  G(xm, xn, x)→0 as n→∞.

Let (X,G) be a G-metric space, a sequence {xn} is called G-Cauchy if for every ε > 0, there is a positive integer N such that G(xn, xm,xl) <ε, for all n,m,l ≥ N, that is, if G(xn, xm,xl) →0, as n, m,l →∞.

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

• (1)

  The sequence {xn} is G-Cauchy,

• (2)

  For any,ε >0, there exists N ∈ℕ such that G(xn, xm,xm) < ε, for all m, n ≥ N.

Let (X, G), (X′, G′) be two G-metric spaces. Then a functionf : X → X′ is G -continuous at a point x ∈ X if and only if it is G-sequentially continuous at x, that is, whenever {xn} is G-convergent to x, {f(xn)} is G-convergent to f(x).

A G-metric space (X, G) is called symmetric G-metric space if G(x, y, y) = G(y, x, x) for all x, y ∈ X.

A G-metric space (X, G) is said to be G -complete (or complete G-metric space) if every G-Cauchy sequence in (X, G) is convergent in X.

Matkowski [10] considered the set φ of all real functions ϕ :[0,∞) →[0, ∞) satisfying the following conditions:

• (i)

  ϕ is non-decreasing and upper-semicontinuous from the right at 0,

• (ii)

  (ii) ϕ(t) < t for each t > 0 and ϕ(t) = 0 ⇔t = 0.

Let ϕ [0,∞) → [0, ∞) be a function satisfying the conditions (i) and (ii). Then limn,m→∞ϕnt=0 where ϕn(t) denotes the composition of ϕn (t) with n-times.

Ahmed [2] proved the following common fixed point theorem for expansive mappings in 2-metric spaces:

Let A, B, S and T be mappings of a complete 2-metric space (X, d) into itself such that A and B are surjective. Suppose that one of the mappings A, B, S, T is sequentially continuous and the pairs {A, S} and {B, T} are compatible mappings of type (A). If there exists ϕ∈φ such that the inequality

holds, then A, B, S and T have a unique common fixed point.

Later, Şahin and Telci [20] in 2010 proved the following common fixed point theorem for expansion type of mappings in complete cone metric spaces.

Let (X, d) be a complete cone metric space and P be a cone. Let f and g be surjective self-mappings of X satisfying the following inequalities:

for all x in X, where a, b >1. If either f or g is continuous, then f and g have a common fixed point.

Two self mappings f and g on a metric space (X, d) are said to be compatible if

Whenever xn is a sequence in X such that

for some t ∈ X.

Two self mappings f and g on a metric space (X, d) are said to be compatible of type (A) if

whenever xn is a sequence in X such that limn→∞fxn=limn→∞gxn=t for some t ∈ X.

Two self mappings f and g on a metric space (X, d) are said to be weakly compatible if they commute at coincidence points. Compatible maps are weakly compatible but the converse is not true.

The following lemma asserts that the concept of weak compatibility is more general than the concept of compatibility of type (A). So, in our result we shall make use of this more generalized notion of compatibility called as weak compatibility.

Let A and S be self-mappings of compatible of type (A) of a metric space (X, d). If Ax = Sx for some x ∈ X, then ASx = SAx.

Let A, B, S and T be mappings of a complete symmetric G -metric space (X, G) into itself satisfying the condition (1). Suppose that the pairs {A, S} and {B, T} are weakly compatible mappings. If there exists ϕ ∈ φ such that the inequality (2) holds, then A, B, S and T have a unique common fixed point.

First, we have to prove that the sequence (yn) defined above is a G- Cauchy sequence. Clearly, we have

Therefore, by lemma 2.3, G(yn, yn+l, yn+l)→0 as

Consider,

Using Lemma 2.3, we obtain G(yn, ym, ym)→0 as m,n→∞. Thus, {yn} is a G- Cauchy sequence. Since (X,G) is a complete G-metric space, it yields that (yn) and hence any subsequence thereof, converge to z ∈ X.

So, (Ax2n),(Bx2n+l),(Sx2n) and (Tx2n+1) converge to z ∈ X. Since A(X) is a complete G-metric space, so there exists a point p ∈ X such that Ap = z.

Now, using inequality (2), we have (ϕG(Ap, Bx2n+2, Bx2n+2)) ≥ G (Sp, Tx2n+2, Tx2n+2) letting n → ∞, we have

That is, 0 = ϕ (0) ≥ G(Sp, z, z). This proves that Sp = z. Since A and S are weakly compatible mappings, therefore ASp = SAp ⇒Az=Sz. Now, since B(X) is also a complete G-metric space. So, there exists a point p1 ∈ X such that Bp1 = z.

Now, consider

ϕ (G(Ax2n+1, Bp1, Bp1)) ≥ G(Sx2n+1, Tp1,Tp1) letting n → ∞, we get

Recalling that Bp1= z, we obtain

This implies that Tp1 = z. Since B and T are weakly compatible mappings, therefore, BTp1 = TBp1⇒Bz = Tz.

Now, we have to show that Az = z and Bz = z. Let us suppose that G(Az, z, z) > 0. So, using the inequality (2) and the fact that ϕ(t) < t for all t > 0, we have

which is a contradiction. So, G(Az, z, z) = 0. That is, Az = Sz = z.

Similarly, let us suppose that G(Bz, z, z)>0. Therefore, by using the fact that the G-metric space X is symmetric and Az = Sz = z, we get G(Bz, z, z) > ϕ(G(Bz, z, z)) = ϕ(G(Az, Bz, Bz)) which is ≥ G(Sz, Tz, Tz) = G(Az, Bz, Bz) = G(Bz, z, z), a contradiction. So, G(Bz, z, z) = 0. This proves that Bz = Tz = z. Therefore, Az = Bz = Sz = Tz = z. It follows that z is the unique common fixed point of A, B, S and T.

As a corollary of the previous theorem, we have the following.

Let A,B,S and T be mappings of a complete symmetric G-metric space (X,G) into itself satisfying the condition (1). Suppose that the pairs {A, S} and {B, T} are weakly compatible mappings. Assume that there exists h > 1 such that

for all x,y ∈ X. Then A, B, S and T. have a unique common fixed point.

By taking ϕt=th, where h >1 in Theorem 3.1, we get the proof of the Corollary 3.2.

Let A and B be mappings of a complete symmetric G-metric space (X, G) into itself satisfying the condition (1). If there exists ϕ ∈ φ such that the inequality

Holds, then A and B have a unique common fixed point.

If we put S = T = iX (the identity mapping on X) in Theorem 3.1, we obtain the proof of the Corollary 3.3.

Let A and B be mappings of a complete symmetric G-metric space (X, G) into itself satisfying the condition (1). Assume that there exists h >1 s.t

Then, A and B have a unique common fixed point.

By taking ϕt=th where h > 1 in Corollary 3.3, we obtain the proof of the Corollary 3.4.

Theorem 3.1 is more general than Corollary 3.2 as shown in the following example.

Let X ={(a, b):a,b∈[0,1]} and G be the G-metric on X defined by G(x, y, z) = max{|x−y |,||x−z|,|y−z|}, where d is the metric on X defined by d((a1, b1), (a2,b2)) = |a1 − a2 | + |b1−b2|

for all (a1, b1),(a2, b2)∈ X. Define A, B, S, T : X→X A(a, b)=B(a, b)=(a,0), by

for each (a, b) ∈ X. Then it is easily seen that A and S are weakly compatible mappings. Consider,

then ϕ ∈φ Further, we see that

all x = (x1, x2), y = (y1, y2)∈X. Therefore, all the hypothesis of Theorem 3.1 are satisfied.

However, condition (4) is not satisfied. Indeed, for x = (0, 0), y = (a, 0), 0 < a ≤; 1 and h > 1, we have

This implies that h < 1, which yields a contradiction.

Now, we prove a common fixed point theorem for expansive mappings in G-metric spaces, which in turn extends the results of Şahin and Telci [20].

Let (X, G) be a complete G-metric space. Let f and g be surjective self mappings of X satisfying the following inequalities:

for all x∈X, where ϕ∈φ If either f or g is continuous, then f and g have a common fixed point.

Let x0∈ X be arbitrary. Due to the reason that the mappings f and g are surjective mappings, there exists points x1∈f−1(x0) and x2∈g−1(x1). Continuing in this way, we obtain the sequence {xn} with x2n+1∈ f−1(x2n) and x2n+2∈ g−1 (x2n+1).

Note that if xn = x+1 for some n, then xn is a common fixed point of f and g. Indeed, if x2n = x2n+1 for some n ≥ 0, then x2n is a fixed point of f.. On the other hand, we have from inequality (6) that

This implies that G(x2n+1, x2n+2+2, x2n+2) = 0. So, by the property of a G-metric, we have x2n+1=x2n+2. Therefore, x2n is a common fixed point (5), we obtain x2n+1 is a common fixed point of f and g. So, let us suppose that xn ≠ xn+1 for all n.

Clearly, we have

Now, we have to prove that {xn} is a G-Cauchy sequence. For this, we need to show that G(xn, xm, xm)→ 0as m,n →∞. Let n, m ∈ℕ with m > n,

Using lemma 2.3, we obtain G(xn,xm,xm)→0 as m,n →∞. Hence, {xn } is a G-Cauchy sequence in X. Since X is G-complete, there exists a point z ∈ X such that limn→∞xn=z. Now, we consider that f is continuous. Since x2n = fx2n+1, so we have

and so z is a fixed point of f. Since g is surjective, therefore there exists y ∈ X such that gy = z. Now, using inequality (6), we have

This implies that G(z, y, y) = 0 which further implies that z = y. Therefore, z is a common fixed point of f and g. Similarly, by considering the continuity of g, it can be proved that f and g have a common fixed point and this completes the proof.

Let (X, G) be a complete G-metric space. Let f and g be surjective self-mappings of X satisfying the following inequalities

for all x in X, where a, b > 1. If either f or g is continuous, then f and g have a common fixed point.

Take ϕt=th, where h = max{a, b}>1 in inequalities (5) and (6) of Theorem 3.5, we get the proof.

Let (X, G) be a complete G-metric space. Let f be a surjective self-mapping of X satisfying the following inequality

for all x in X, where k > 1. If f is continuous, then f has a fixed point.

Putting f = g and k = min{a, b} in Corollary 3.6, we get Corollary 3.7.

Taking

for usual metric space (X, d) in the corollary 3.7, we obtain the following result of Wang et al. [23].

Let (X, d) be a complete metric space and let f be a surjective self-mapping of X satisfying the following inequality

for all x in X, where k > 1. If f is continuous, then f has a fixed point.

We now give the following example in support of our Theorem 3.5.

Let X = [0, ∞) and ϕ:[0, ∞) → [0, ∞) defined by ϕt=t2 Define a G-metric on X by

Define the surjective self mappings f, g : X → X by

for all x in X Then we have

and

hold for all x in X Thus, inequalities (5) and (6) are satisfied and hence all the hypothesis of Theorem 3.5 are satisfied. Clearly, x = 0 is a common fixed point of f and g.