Generalized probabilistic metric spaces and fixed point theorems

In this paper, we introduce a new concept of probabilistic metric space, which is a generalization of the Menger probabilistic metric space, and we investigate some topological properties of this space and related examples. Also, we prove some fixed point theorems, which are the probabilistic versions of Banach’s contraction principle. Finally, we present an example to illustrate the main theorems.

MSC:54E70, 47H25.

Let ℝ be the set of all real numbers, ${\mathbb{R}}^{+}$ be the set of all nonnegative real numbers, Δ denote the set of all probability distribution functions, i.e., Δ = {$F:\mathbb{R}\cup \{-\mathrm{\infty },+\mathrm{\infty }\}\to [0,1]:F$ is left continuous and nondecreasing on ℝ, $F(-\mathrm{\infty })=0$ and $F(+\mathrm{\infty })=1$}.

Definition 1.1 ([1])

A mapping $T:[0,1]\times [0,1]\to [0,1]$ is called a continuous t-norm if T satisfies the following conditions:

1. (1)

   T is commutative and associative, i.e., $T(a,b)=T(b,a)$ and $T(a,T(b,c))=T(T(a,b),c)$, for all $a,b,c\in [0,1]$;

2. (2)

   T is continuous;

3. (3)

   $T(a,1)=a$ for all $a\in [0,1]$;

4. (4)

   $T(a,b)\le T(c,d)$ whenever $a\le c$ and $b\le d$ for all $a,b,c,d\in [0,1]$.

From the definition of T it follows that $T(a,b)\le min\{a,b\}$ for all $a,b\in [0,1]$.

Two simple examples of continuous t-norm are $T_M(a,b)=min\{a,b\}$ and $T_p(a,b)=ab$ for all $a,b\in [0,1]$.

In 1942, Menger [2] developed the theory of metric spaces and proposed a generalization of metric spaces called Menger probabilistic metric spaces (briefly, Menger PM-space).

Definition 1.2 A Menger PM-space is a triple $(X,F,T)$, where X is a nonempty set, T is a continuous t-norm and F is a mapping from $X\times X\to \mathcal{D}$ ($F_{x,y}$ denotes the value of F at the pair $(x,y)$) satisfying the following conditions:

(PM-1) $F_{x,y}(t)=1$ for all $x,y\in X$ and $t>0$ if and only $x=y$;

(PM-2) $F_{x,y}(t)=F_{y,x}(t)$ for all $x,y\in X$ and $t>0$;

(PM-3) $F_{x,z}(t+s)\ge T(F_{x,y}(t),F_{y,z}(s))$ for all $x,y,z\in X$ and $t,s\ge 0$.

The idea of Menger was to use distribution functions instead of nonnegative real numbers as values of the metric. Since Menger, many authors have considered fixed point theory in PM-spaces and its applications as a part of probabilistic analysis (see [1, 3–14]).

In 1963, Gähler [15] investigated the concept of 2-metric spaces and he claimed that a 2-metric is a natural generalization of an ordinary metric space (for more detailed results, see the books [16, 17]). But some authors pointed out that there are no relations between 2-metric spaces and ordinary metric spaces [18]. Later, Dhage [19] introduced a new class of generalized metrics called D-metric spaces. However, as pointed out in [20], the D-metric is also not satisfactory.

Recently, Mustafa and Sims [21] introduced a new class of metric spaces called generalized metric spaces or G-metric spaces as follows.

Definition 1.3 ([21])

Let X be a nonempty set and $G:X\times X\times X:\to {\mathbb{R}}^{+}$ be a function satisfying the following conditions:

(G1) $G(x,y,z)=0$ if $x=y=z$ for all $x,y,z\in X$;

(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) $G(x,y,z)=G(x,z,y)=G(y,z,x)=\cdots$ for all $x,y,z\in X$;

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

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

It was proved that the G-metric is a generalization of ordinary metric (see [21]). Recently, some authors studied G-metric spaces and obtained fixed point theorems on G-metric spaces [22–24]. Similar work can be found in [25–29].

It is well known that the notion of a PM-space corresponds to the situation that we may know probabilities of possible values of the distance although we do not know exactly the distance between two points. This idea leads us to seek a probabilistic version of G-metric spaces defined by Mustafa and Sims [21].

Definition 1.4 A Menger probabilistic G-metric space (shortly, PGM-space) is a triple $(X,G^{\ast },T)$, where X is a nonempty set, T is a continuous t-norm and $G^{\ast }$ is a mapping from $X\times X\times X$ into ($G_{x,y,z}^{\ast }$ denotes the value of $G^{\ast }$ at the point $(x,y,z)$) satisfying the following conditions:

(PGM-1) $G_{x,y,z}^{\ast }(t)=1$ for all $x,y,z\in X$ and $t>0$ if and only if $x=y=z$;

(PGM-2) $G_{x,x,y}^{\ast }(t)\ge G_{x,y,z}^{\ast }(t)$ for all $x,y\in X$ with $z\ne y$ and $t>0$;

(PGM-3) $G_{x,y,z}^{\ast }(t)=G_{x,z,y}^{\ast }(t)=G_{y,x,z}^{\ast }(t)=\cdots$ (symmetry in all three variables);

(PGM-4) $G_{x,y,z}^{\ast }(t+s)\ge T(G_{x,a,a}^{\ast }(s),G_{a,y,z}^{\ast }(t))$ for all $x,y,z,a\in X$ and $s,t\ge 0$.

Remark 1.5 Golet introduced a concept of probabilistic 2-metric (or 2-Menger space) [30] based on 2-metric [15] defined by Gähler. In the concept of probabilistic 2-metric, a 2-t-norm is used. Our definition of a Menger probabilistic G-metric space is different from the one of Golet. The metric of Golet is not continuous in two arguments although it is continuous in any one of its three arguments. But $G^{\ast }$ is continuous in any two arguments as shown in Theorem 2.5.

Example 1.6 Let H denote the specific distribution function defined by

and D be a distribution function defined by

For any $t>0$, define a function $G^{\ast }:X\times X\times X\to {\mathbb{R}}^{+}$ by

where G is a G-metric as in Definition 1.3. Set $T=min$. Then $G^{\ast }$ is a probabilistic G-metric.

Proof It is easy to see that $G^{\ast }$ satisfies (PGM-1)-(PGM-3). Next we show $G^{\ast }(x,y,z)(s+t)\ge T(G^{\ast }(x,a,a)(s),G^{\ast }(a,y,y)(t))$ for all $x,y,z,a\in X$ and all $s,t>0$. In fact, we only need show that D satisfies

Since $G(x,y,z)\le G(x,a,a)+G(a,y,z)$, we have

Furthermore, we have

which, from (1.2) and (1.3), shows that

This implies (1.1) since D is nondecreasing. □

Example 1.7 Let $(X,F,T)$ be a PM-space. Define a function $G^{\ast }:X\times X\times X\to {\mathbb{R}}^{+}$ by

for all $x,y,z,\in X$ and $t>0$. Then $G^{\ast }$ is a probabilistic G-metric.

Proof It is obvious that $G^{\ast }$ satisfies (PGM-1), (PGM-2), and (PGM-3). To prove that $G^{\ast }$ satisfies (PGM-4), we need to show that, for all $x,y,z,a\in X$ and all $s,t\ge 0$,

i.e.,

Now, from

and

we conclude that (1.5), i.e., (1.4) holds. Therefore, $G^{\ast }$ satisfies (PGM-4) and hence $G^{\ast }$ is a probabilistic G-metric. □

Example 1.8 Let $(X,F,T_M)$ be a PM-space. Define a function $G^{\ast }:X\times X\times X\to {\mathbb{R}}^{+}$ by

for all $x,y,z,\in X$ and $t>0$. Then $(X,G^{\ast },T_M)$ is a PGM-space.

Proof In fact, the proofs of (PGM-1)-(PGM-3) are immediate. Now, we show that $G^{\ast }$ satisfies (PGM-4). It follows that

Thus $(X,G,T_M)$ is a PGM-space. □

The following remark shows that the PGM-space is a generalization of the Menger PM-space.

Remark 1.9 For any function $G^{\ast }:X\times X\times X\to {\mathbb{R}}^{+}$, the function $F:X\times X\to {\mathbb{R}}^{+}$ defined by

is a probabilistic metric. It is easy to see that F satisfies the conditions (PM-1) and (PM-2).

Next, we show F satisfies (PM-3). Indeed, for any $s,t\ge 0$ and $x,y,z\in X$, we have

It follows from (PGM-4) that

Since

and

it follows from (PGM-4) that

and

Therefore, we have

This shows that F satisfies (PM-3).

In this section, we first introduce the concept of neighborhoods in the PGM-spaces. For the concept of neighborhoods in PM-spaces, we refer the readers to [1, 3].

Definition 2.1 Let $(X,G^{\ast },T)$ be a PGM-space and $x_0$ be any point in X. For any $ϵ>0$ and δ with $0<\delta <1$, an $(ϵ,\delta )$-neighborhood of $x_0$ is the set of all points y in X for which $G_{x_0,y,y}^{\ast }(ϵ)>1-\delta$ and $G_{y,x_0,x_0}^{\ast }(ϵ)>1-\delta$. We write

This means that $N_{x_0}(ϵ,\delta )$ is the set of all points y in X for which the probability of the distance from $x_0$ to y being less than ϵ is greater than $1-\delta$.

Lemma 2.2 If ${ϵ}_1\le {ϵ}_2$ and ${\delta }_1\le {\delta }_2$, then $N_{x_0}({ϵ}_1,{\delta }_1)\subset N_{x_0}({ϵ}_2,{\delta }_2)$.

Proof Suppose that $z\in N_{x_0}({ϵ}_1,{\delta }_1)$, so $G_{x_0,z,z}^{\ast }({ϵ}_1)>1-{\delta }_1$ and $G_{z,x_0,x_0}^{\ast }({ϵ}_1)>1-{\delta }_1$. Since F is monotone, we have

and

Therefore, by the definition, $z\in N_{x_0}({ϵ}_2,{\delta }_2)$. This completes the proof. □

Theorem 2.3 Let $(X,G^{\ast },T)$ be a Menger PGM-space. Then $(X,G^{\ast },T)$ is a Hausdorff space in the topology induced by the family $\{N_{x_0}(ϵ,\delta )\}$ of $(ϵ,\delta )$-neighborhoods.

Proof We show that the following four properties are satisfied:

1. (A)

   For any $x_0\in X$, there exists at least one neighborhood, $N_{x_0}$, of $x_0$ and every neighborhood of $x_0$ contains $x_0$.

2. (B)

   If $N_{x_0}^1$ and $N_{x_0}^2$ are neighborhoods of $x_0$, then there exists a neighborhood of $x_0$, $N_{x_0}^3$, such that $N_{x_0}^3\subset N_{x_0}^1\cap N_{x_0}^2$.

3. (C)

   If $N_{x_0}$ is a neighborhood of $x_0$ and $y\in N_{x_0}$, then there exists a neighborhood of y, $N_y$, such that $N_y\subset N_{x_0}$.

4. (D)

   If $x_0\ne y$, then there exist disjoint neighborhoods, $N_{x_0}$ and $N_y$, such that $x_0\in N_{x_0}$ and $y\in N_y$.

Now, we prove that (A)-(D) hold.

1. (A)

   For any $ϵ>0$ and $0<\delta <1$, $x_0\in N_{x_0}(ϵ,\delta )$ since $G_{x_0,x_0,x_0}^{\ast }(ϵ)=1$ for any $ϵ>0$.

2. (B)

   For any ${ϵ}_1,{ϵ}_2>0$ and $0<{\delta }_1,{\delta }_2<1$, let

   $$N_{x_0}^1({ϵ}_1,{\delta }_1)=\{y\in X:G_{x_0,y,y}^{\ast }({ϵ}_1)>1-{\delta }_1,G_{y,x_0,x_0}^{\ast }({ϵ}_1)>1-{\delta }_1\}$$

and

be the neighborhoods of $x_0$. Consider

Clearly, $x_0\in N_{x_0}^3$ and, since $min\{{ϵ}_1,{ϵ}_2\}\le {ϵ}_1$ and $min\{{\delta }_1,{\delta }_2\}\le {\delta }_1$, by Lemma 2.2, $N_{x_0}^3\subset N_{x_0}^1({ϵ}_1,{\delta }_1)$ and $N_{x_0}^3\subset N_{x_0}^2({ϵ}_2,{\delta }_2)$, so

1. (C)

   Let $N_{x_0}=\{z\in X:G_{x_0,z,z}^{\ast }({ϵ}_1)>1-{\delta }_1,G_{z,x_0,x_0}^{\ast }({ϵ}_1)>1-{\delta }_1\}$ be the neighborhood of $x_0$. Since $y\in N_{x_0}$,

   $$G_{x_0,y,y}^{\ast }({ϵ}_1)>1-{\delta }_1,G_{y,x_0,x_0}^{\ast }({ϵ}_1)>1-{\delta }_1.$$

Now, $G_{x_0,y,y}^{\ast }$ is left-continuous at ${ϵ}_1$, so there exist ${ϵ}_0<{ϵ}_1$ and ${\delta }_0<{\delta }_1$ such that

Let $N_y=\{z\in X:G_{y,z,z}^{\ast }({ϵ}_2)>1-{\delta }_2,G_{z,y,y}^{\ast }({ϵ}_2)>1-{\delta }_2\}$, where $0<{ϵ}_2<{ϵ}_1-{ϵ}_0$ and ${\delta }_2$ is chosen such that

Such a ${\delta }_2$ exists since T is continuous, $T(a,1)=a$ for all $a\in [0,1]$ and $1-{\delta }_0>1-{\delta }_1$.

Now, suppose that $s\in N_y$, so that

Then, since $G^{\ast }$ is monotone, it follows from (PGM-4) that

Similarly, we also have $G_{s,x_0,x_0}^{\ast }({ϵ}_1)>1-{\delta }_1$. This shows $s\in N_{x_0}$ and hence $N_y\subset N_{x_0}$.

1. (D)

   Let $y\ne x_0$. Then there exist $ϵ>0$ and $a_1$, $a_2$ with $0\le a_1,a_2<1$ such that $G_{x_0,y,y}^{\ast }(ϵ)=a_1$ and $G_{y,x_0,x_0}^{\ast }(ϵ)=a_2$. Let

   $$N_{x_0}=\{z:G_{x_0,z,z}^{\ast }(ϵ/2)>b_1,G_{z,x_0,x_0}^{\ast }(ϵ/2)>b_1\}$$

and

where $b_1$ and $b_2$ are chosen such that $0<b_1,b_2<1$, $T(b_1,b_2)>a$, where $a=max\{a_1,a_2\}$. Such $b_1$ and $b_2$ exist since T is continuous, monotone, and $T(1,1)=1$.

Now, suppose that there exists a point $s\in N_{x_0}\cap N_y$ such that

Then, by (PGM-4), we have

and

which are contradictions. Therefore, $N_{x_0}$ and $N_y$ are disjoint. This completes the proof. □

Next, we give the definition of convergence of sequences in PGM-spaces.

Definition 2.4

1. (1)

   A sequence $\{x_n\}$ in a PGM-space $(X,G^{\ast },T)$ is said to be convergent to a point $x\in X$ (write $x_n\to x$) if, for any $ϵ>0$ and $0<\delta <1$, there exists a positive integer $M_{ϵ,\delta }$ such that $x_n\in N_x(ϵ,\delta )$ whenever $n>M_{ϵ,\delta }$.

2. (2)

   A sequence $\{x_n\}$ in a PGM-space $(X,G^{\ast },T)$ is called a Cauchy sequence if, for any $ϵ>0$ and $0<\delta <1$, there exists a positive integer $M_{ϵ,\delta }$ such that $G_{x_n,x_m,x_l}^{\ast }(ϵ)>1-\delta$ whenever $m,n,l>M_{ϵ,\delta }$.

3. (3)

   A PGM-space $(X,G^{\ast },T)$ is said to be complete if every Cauchy sequence in X converges to a point in X.

Theorem 2.5 Let $(X,G^{\ast },T)$ be a PGM-space. Let $\{x_n\}$, $\{y_n\}$ and $\{z_n\}$ be sequences in X and $x,y,z\in X$. If $x_n\to x$, $y_n\to y$ and $z_n\to z$ as $n\to \mathrm{\infty }$, then, for any $t>0$, $G_{x_n,y_n,z_n}^{\ast }(t)\to G_{x,y,z}^{\ast }(t)$ as $n\to \mathrm{\infty }$.

Proof For any $t>0$, there exists $\delta >0$ such that $t>2\delta$. Then, by (PGM-4), we have

and

Letting $n\to \mathrm{\infty }$ in the above two inequalities and noting that T is continuous, we have

and

Letting $\delta \to 0$ in above two inequalities, since $G^{\ast }$ is left-continuous, we conclude that

for any $t>0$. This completes the proof. □

In [31], Sehgal extended the notion of a Banach contraction mapping to the setting of Menger PM-spaces. Later on, Sehgal and Bharucha-Raid [32] proved a fixed point theorem for a mapping under the contractive condition in a complete Menger PM-space. Before proving our fixed point theorems, we first introduce a new concept of contraction in PGM-spaces, which is a corresponding version of Sehgal’s contraction in PM-spaces.

Definition 3.1 Let $(X,G^{\ast },T)$ be a PGM-space. A mapping $f:X\to X$ is said to be contractive if there exists a constant $\lambda \in (0,1)$ such that

for all $x,y,z\in X$ and $t>0$.

The mapping f satisfying the condition (3.1) is called a λ-contraction.

Let T be a given t-norm. Then (by associativity) a family of mappings $T^n:[0,1]\to [0,1]$ for each $n\ge 1$ is defined as follows:

for any $t\in [0,1]$.

Definition 3.2 ([33])

A t-norm T is said to be of Hadzić-type if the family of functions ${\{T^n(t)\}}_{n=1}^{\mathrm{\infty }}$ is equicontinuous at $t=1$, that is, for any $ϵ\in (0,1)$, there exists $\delta \in (0,1)$ such that

for each $n\ge 1$.

The t-norm $T=min$ is a trivial example of t-norm of Hadzić-type.

Lemma 3.3 Let $(X,G^{\ast },T)$ be a Menger PGM-space with T of Hadžić-type and $\{x_n\}$ be a sequence in X. Suppose that there exists $\lambda \in (0,1)$ satisfying

for any $n\ge 1$ and $t>0$. Then $\{x_n\}$ is a Cauchy sequence in X.

Proof Since $G_{x_n,x_{n+1},x_{n+1}}^{\ast }(t)\ge G_{x_{n-1},x_n,x_n}^{\ast }(t/\lambda )$, by induction, we have

Since X is a Menger PGM-space, we have $G_{x_0,x_1,x_1}^{\ast }(t/{\lambda }^n)\to 1$ as $n\to \mathrm{\infty }$, so

for any $t>0$.

Now, let $n\ge 1$ and $t>0$. We show, by induction, that, for any $k\ge 0$,

For $k=0$, since $T(a,b)$ is a real number, $T^0(a,b)=1$ for all $a,b\in [0,1]$. Hence, $G_{x_n,x_n,x_n}^{\ast }(t)=1=T^0(G_{x_n,x_{n+1},x_{n+1}}^{\ast })(t-\lambda t)$, which implies that (3.3) holds for $k=0$. Assume that (3.3) holds for some $k\ge 1$. Then, since T is monotone, it follows from (PGM-4) that

so we have the conclusion.

Now, we show that $\{x_n\}$ is a Cauchy sequence in X, i.e., ${lim}_{m,n,l\to \mathrm{\infty }}{G}_{x_n,x_m,x_l}^{\ast }(t)=1$ for any $t>0$. To this end, we first prove that ${lim}_{n,m\to \mathrm{\infty }}{G}_{x_n,x_m,x_m}^{\ast }(t)=1$ for any $t>0$. Let $t>0$ and $ϵ>0$ be given. By hypothesis, $T^n:n\ge 1$ is equicontinuous at 1 and $T^n(1)=1$, so there exists $\delta >0$ such that, for any $a\in (1-\delta ,1]$,

for all $n\ge 1$. From (3.2), it follows that ${lim}_{n\to \mathrm{\infty }}{G}_{x_n,x_{n+1},x_{n+1}}^{\ast }(t-\lambda t)=1$. Hence there exists $n_0\in \mathbb{N}$ such that $G_{x_n,x_{n+1},x_{n+1}}^{\ast }(t-\lambda t)\in (1-\delta ,1]$ for any $n\ge n_0$. Hence, by (3.3) and (3.4), we conclude that $G_{x_n,x_{n+k},x_{n+k}}^{\ast }(t)>1-ϵ$ for any $k\ge 0$. This shows ${lim}_{n,m\to \mathrm{\infty }}{G}_{x_n,x_m,x_m}^{\ast }(t)=1$ for any $t>0$. By (GPM-4), we have

Therefore, by the continuity of T, we conclude that

for any $t>0$. This shows that the sequence $\{x_n\}$ is a Cauchy sequence in X. This completes the proof. □

From Example 1.6 and Lemma 3.3 we get the following corollary.

Corollary 3.4 ([33])

Let $(X,F,T)$ be a PM-space with T of Hadžić-type and $\{x_n\}\subset X$ be a sequence. If there exists a constant $\lambda \in (0,1)$ such that