A fixed point theorem for Meir-Keeler contractions in ordered metric spaces

Abstract

The purpose of this paper is to present some fixed point theorems for Meir-Keeler contractions in a complete metric space endowed with a partial order.

MSC: 47H10.

1 Introduction and preliminaries

The Banach contraction mapping principle is one of the pivotal results of analysis. It is widely considered as the source of metric fixed point theory. Also, its significance lies in its vast applicability in a number of branches of mathematics.

Generalization of the above principle has been a heavily investigated branch of research. In particular, Meir and Keeler [1] present the following fixed point theorem.

Theorem 1.1. [1] Let (X,d) be a complete metric space and T: X → X an operator. Suppose that for every ε > 0 there exists δ(ε) > 0 such that for x,y ∈ X

$$\epsilon \le d\left(x,y\right)<\epsilon +\delta \left(\epsilon \right)\Rightarrow d\left(Tx,Ty\right)<\epsilon .$$

Then, T admits a unique fixed point ξ ∈ X and for any x ∈ X, the sequence {Tⁿx} converges to ξ.

The purpose of this article is to present a version of Theorem 1.1 in the context of ordered metric spaces.

Existence of fixed point in partially ordered sets has been recently studied in [2–20].

In the context of ordered metric spaces, the usual contraction is weakened but at the expense that the operator is monotone.

2 Fixed point results: nondecreasing case

Our starting point is the following definition.

Definition 2.1. Let (X, ≤) be a partially ordered set and T: X → X a mapping. We say that T is nondecreasing if for x, y ∈ X

$$x\le y\Rightarrow Tx\le Ty.$$

This definition coincides with the notion of a nondecreasing function in the case where X = ℝ and ≤ represents the usual total order in ℝ.

Remark 2.2. The contractive condition given by Meir-Keeler:

For every ε > 0, there exists δ(ε) > 0 such that for x,y ∈ X

$$\epsilon \le d\left(x,y\right)<\epsilon +\delta \left(\epsilon \right)\Rightarrow d\left(Tx,Ty\right)<\epsilon$$

implies that the operator T: X → X is strictly nonexpansive (this means that for x, y ∈ X, x ≠ y, d(Tx, Ty) < d(x, y)).

Therefore, any operator T satisfying the Meir-Keeler condition is continuous.

In what follows, we present the following theorem which is a version of Theorem 1.1 in the context of ordered metric spaces when the operator is nondecreasing.

Theorem 2.3. Let (X, ≤) be a partially ordered set and suppose that there exists a metric d in X such that (X, d) is a complete metric space. Let T: X → X be a continuous and nondecreasing mapping such that for every ε > 0 there exists δ(ε) > 0 satisfying

$$\epsilon \le d\left(x,y\right)<\epsilon +\delta \left(\epsilon \right)andx<y\Rightarrow d\left(Tx,Ty\right)<\epsilon .$$

(1)

If there exists x₀ ∈ X with x₀ ≤ Tx₀, then T has a fixed point.

Remark 2.4. Condition (??) does not imply that T is continuous as it is proven with the following example.

Let X = [0, 1] be the unit interval with the usual metric and the order given by R = {(x, x): x ∈ X}. Consider the operator T: X → X given by Tx = 0 if x ≠ 1 and Tx = 1 if x = 1.

Obviously, T is not continuous and, as the elements in X are only comparable to themselves, T satisfies (??).

This shows that the continuity of T in Theorem 2.3 is not redundant (compare with Remark 2.2 and Theorem 1.1).

Remark 2.5. Condition (1) does not imply that T is strictly nonexpansive but d(Tx, Ty) < d(x, y) is true if x < y as it can be seen using ε = d(x, y) in (1) when x < y.

Proof of Theorem 2.3. If Tx₀ = x₀, then the proof is finished.

Suppose that x₀ < Tx₀ and T is a nondecreasing mapping, we obtain by induction that

$$x_0<T{x}_0\le T^2{x}_0\le T^3{x}_0\le \cdots \le T^n{x}_0\le T^{n+1}{x}_0\le \cdots .$$

Put x_n+1= Tⁿx₀. Obviously, (x _n ) is a nondecreasing sequence.

For better readability, we divide the proof into several steps.

Step 1: lim_{n → ∞}d(x _n , x_{n + 1}) = 0.

In fact, if the sequence (x _n ) is not strictly nondecreasing, then we can find n₀ ∈ ℕ such that $x_{n_0}=x_{n_0+1}$ and the result follows. If (x _n ) is strictly nondecreasing, then by Remark 2.5, (d(x _n , x_n+1)) is strictly decreasing, and hence, it is convergent. Put r = lim_{n → ∞}d(x _n , x_n+1) (notice that r = inf{d(x _n , x_n+1): n ∈ ℕ}).

Now, we will prove that r = 0.

Suppose that r > 0.

Applying condition (??) to r > 0 we can find δ(r) > 0 such that

$$\left.\begin{array}{c}\hfill r\le d\left(x,y\right)<r+\delta \left(r\right)\hfill \\ \hfill \mathsf{\text{and}}x<y\hfill \end{array}\right\}\Rightarrow d\left(Tx,Ty\right)<r.$$

Since r = lim_n→∞ d(x _n , x_n+1), there exists n₀ ∈ ℕ such that $r\le d\left(x_{n_0},x_{n_0+1}\right)<r+\delta \left(r\right)$ and, as $x_{n_0}<x_{n_0+1}$, we have $d\left(T{x}_{n_0},T{x}_{n_0+1}\right)=d\left(x_{n_0+1},x_{n_0+2}\right)<r$.

This is a contradiction because r = inf{d(x _n , x_n+1): n ∈ ℕ}.

Therefore, r = 0. This means that

$$\underset{n\to \infty }{lim}d\left(x_n,x_{n+1}\right)=0.$$

(2)

Step 2: (x _n ) is a Cauchy sequence.

In fact, fix ε > 0 and arbitrary.

By condition (??), there exists δ(ε) > 0 (which can be choosen satisfying δ(ε) ≤ ε) such that

$$\epsilon \le d\left(x,y\right)<\epsilon +\delta \left(\epsilon \right)\mathsf{\text{and}}x<y\Rightarrow d\left(Tx,Ty\right)<\epsilon .$$

(3)

On the other hand, by (??), there exists n₀ ∈ ℕ such that

$$d\left(x_{n-1},x_n\right)<\delta \left(\epsilon \right)\mathsf{\text{for}}\mathsf{\text{any}}n>n_0.$$

(4)

Fix n > n₀ and in order to prove that {x _n } is a Cauchy sequence it is sufficient to show that

$$d\left(x_n,x_{n+p}\right)\le \epsilon \mathsf{\text{for}}p=1,2,3,\dots .$$

(5)

We will use mathematical induction.

For p = 1 by (??) and the fact that δ(ε) ≤ ε we obtain

$$d\left(x_n,x_{n+1}\right)<\delta \left(\epsilon \right)\le \epsilon .$$

Now, we assume that (??) holds for some fixed p.

Then, using (??) and the inductive hypothesis, we get

$$d\left(x_{n-1},x_{n+p}\right)\le d\left(x_{n-1},x_n\right)+d\left(x_n,x_{n+p}\right)<\delta \left(\epsilon \right)+\epsilon .$$

(6)

Now, we consider two cases.

Case 1: d(x_n-1, x_n+p) ≥ ε.

In this case, taking into account (??),

$$\epsilon \le d\left(x_{n-1},x_{n+p}\right)<\epsilon +\delta \left(\epsilon \right)$$

and, since x_n-1< x_n+p, by (??)

$$d\left(T{x}_{n-1},T{x}_{n+p}\right)=d\left(x_n,x_{n+p+1}\right)<\epsilon .$$

This proves that (??) is satisfied by p + 1.

Case 2: d(x_n-1, x_n+p) < ε.

As d(x_n-1, x_n+p) > 0 (because {x _n } is a nondecreasing sequence and d(x _n , x_n+1) > 0 for any n = 0,1, 2,...), applying condition (??) for ε₀ = d(x_n-1, x_n+p) we can get

$$d\left(T{x}_{n-1},T{x}_{n+p}\right)=d\left(x_n,x_{n+p+1}\right)<d\left(x_{n-1},x_{n+p}\right)<\epsilon$$

(notice that x_n-1< x_n+p) and this proves that (??) is satisfied by p + 1.

Therefore, {x _n } is a Cauchy sequence.

Since X is a complete metric space, there exists z ∈ X such that lim_n→∞x _n = z. Finally, the continuity of T implies that

$$z=\underset{n\to \infty }{lim}{x}_{n+1}=\underset{n\to \infty }{lim}T{x}_n=Tz$$

and, therefore, z is a fixed point of T.

This finishes the proof.

In what follows we prove that Theorem 2.3 is still valid for T not necessarily continuous, assuming the following hypothesis:

$$\begin{array}{c}\mathsf{\text{if}}\left(x_n\right)\mathsf{\text{is}}\mathsf{\text{a}}\mathsf{\text{nondecreasng}}\mathsf{\text{sequence}}\mathsf{\text{such}}\mathsf{\text{that}}{x}_n\to x,\mathsf{\text{then}}\\ \mathsf{\text{there}}\mathsf{\text{exists}}\mathsf{\text{a}}\mathsf{\text{subsequence}}\left(x_{n\left(k\right)}\right)\mathsf{\text{of}}\left(x_n\right)\mathsf{\text{such}}\mathsf{\text{that}}{x}_{n\left(k\right)}\le x\mathsf{\text{for}}\mathsf{\text{all}}k\in \mathbb{N}\end{array}$$

(7)

Theorem 2.6. If in Theorem 2.3 we replace the continuity of T by condition (??) the result is true.

Proof. Following the proof of Theorem 2.3, we only have to check that Tz = z.

As (x _n ) is a nondecreasing sequence in X with x _n → z, by condition (??), we can find a subsequence (x_n(k)) such that x_n(k)≤ z for all k ∈ ℕ.

If there exists k₀ ∈ ℕ such that $x_{n\left(k_0\right)}=z$, then the nondecreasing character of (x _n ) gives us that

$$x_k=z\mathsf{\text{for}}\mathsf{\text{all}}k\ge n\left(k_0\right).$$

Particularly, $x_{n\left(k_0\right)}=z=x_{n\left(k_0\right)+1}=T\left(x_{n\left(k_0\right)}\right)$, and $x_{n\left(k_0\right)}=z$ is a fixed point of T.

Suppose that for any k ∈ ℕ, x_n(k)< z.

Applying condition (??) to ε = d(x_n(k), z) for k fixed and arbitrary, we have

$$d\left(T{x}_{n\left(k\right)},Tz\right)=d\left(x_{n\left(k\right)+1},Tz\right)<d\left(x_{n\left(k\right)},z\right).$$

As x_n(k)→ z, the last inequality implies that x_n(k)+1→ Tz.

As (x_n(k)+1) is a subsequence of (x _n ) and x _n → z we have x_n(k)+1→ z.

Now, the uniqueness of the limit in complete metric spaces gives us Tz = z.

This finishes the proof.

Now, we present an example where it can be appreciated that assumptions in Theorems 2.3 and 2.6 do not guarantee uniqueness of the fixed point.

Let X = {(1,0), (0,1)} ⊂ ℝ² and consider the usual order

$$\left(x,y\right)\le \left(z,t\right)\iff x\le z\mathsf{\text{and}}\mathsf{\text{y}}\le \mathsf{\text{t}}\mathsf{\text{.}}$$

Then, (X, ≤) is a partially ordered set whose different elements are not comparable. Besides, (X, d₂) is a complete metric space considering d₂ the Euclidean distance. The identity map T(x, y) = (x, y) is trivially continuous and nondecreasing and condition (??) of Theorem 2 is satisfied since elements in X are only comparable to themselves. Moreover, (1,0) ≤ T(1, 0) = (1, 0) and the operator T has two fixed points.

In what follows, we present a sufficient condition for the uniqueness of the fixed point in Theorems 2.3 and 2.6. This condition appears in [15] and says:

$$\mathsf{\text{For}}x,y\in X,\mathsf{\text{there}}\mathsf{\text{exists}}z\in X\mathsf{\text{which}}\mathsf{\text{is}}\mathsf{\text{comparable}}\mathsf{\text{to}}x\mathsf{\text{and}}y.$$

(8)

Theorem 2.7. Adding condition (??) to the hypotheses of Theorem 2.3 (or Theorem 2.6) we obtain the uniqueness of the fixed point of T.

Proof. Suppose that there exist z, y ∈ X which are fixed points of T and z ≠ y.

We consider two cases.

Case 1: Suppose that z and y are comparable.

Without loss of generality, we suppose z < y.

Putting ε = d(z, y) and applying condition (??) of Theorem 1, we get

$$d\left(Tz,Ty\right)=d\left(z,y\right)<\epsilon =d\left(z,y\right)$$

which is a contradiction.

Case 2: Suppose that z and y are not comparable.

By condition (??), there exists x ∈ X comparable to z and y.

Suppose z < x (the same argument serves for x < z).

Monotonicity of T implies that Tⁿz = z ≤ Tⁿx for n = 1, 2, 3,...

We consider two possibilities:

1. (a)

   Suppose that there exists n₀ ∈ ℕ such that $T^{n_0}z=z=T^{n_0}x$. Since z is a fixed point of T, Tⁿx = z for n ≥ n₀, and, consequently, Tⁿx → z.

2. (b)

   Suppose that Tⁿz = z < Tⁿx for any n = 1, 2, 3,.... Applying condition (??) of Theorem 1 for ε = d(Tⁿz, Tⁿx) (where n ∈ ℕ is fixed but arbitrary), we have

   $$d\left(T^{n+1}z,T^{n+1}x\right)=d\left(z,T^{n+1}x\right)\le d\left(T^{n}z,T^{n}x\right)=d\left(z,T^{n}x\right).$$

Thus, {d(z, Tⁿx)} is a decreasing sequence of positive real numbers and, consequently, there exists r ≥ 0 such that

$$\underset{n\to \infty }{lim}d\left(z,T^{n}x\right)=r.$$

Suppose r > 0.

Applying condition (??) of Theorem 2.3 for ε = r we find δ(r) > 0 such that

$$r\le d\left(u,v\right)<r+\delta \left(r\right)\mathsf{\text{and}}u<v\Rightarrow d\left(Tu,Tv\right)<r.$$

(9)

As lim_n→∞d(z, Tⁿx) = r = inf {d(z, Tⁿx): n ∈ ℕ}, there exists n₀ ∈ ℕ such that

$$r\le d\left(z,T^{n_0}x\right)<r+\delta \left(r\right)$$

and, since $z<T^{n_0}x$, (??) gives us

$$d\left(Tz,T^{n_0+1}x\right)=d\left(z,T^{n_0+1}x\right)<r,$$

which contradicts to r = inf{d(z, Tⁿx): n ∈ ℕ}.

Therefore, z = y.

This finishes the proof.

3 Fixed point results: nonincreasing case

We start this section with the following definition.

Definition 3.1. Let (X, ≤) be a partially ordered set and T: X → X. We say that T is nonincreasing if for x, y ∈ X

$$x\le y\Rightarrow Tx\ge Ty.$$

The main result of this section is the following theorem.

Theorem 3.2. Let (X, ≤) be a partially ordered set satisfying condition (??) and suppose that there exists a metric d in X such that (X, d) is a complete metric space. Let T: X → X be a nonincreasing mapping such that for any ε > 0 there exists δ(ε) > 0 satisfying

$$\epsilon \le d\left(x,y\right)<\epsilon +\delta \left(\epsilon \right)\mathsf{\text{and}}x<y\Rightarrow d\left(Tx,Ty\right)<\epsilon .$$

(a) If there exists x₀ ∈ X with x₀ ≤ Tx₀ or x₀ ≥ Tx₀, then inf{d(x, Tx): x ∈ X} = 0.

(b) If, in addition, X is compact and T is continuous, then T has a unique fixed point.

Proof. (a) If Tx₀ = x₀, then it is obvious that inf{d(x, Tx): x ∈ X} = 0. Suppose that x₀ < Tx₀ (the same argument serves for Tx₀ < x₀).

In virtue that T is nonincreasing the consecutive terms of the sequence (Tⁿx₀) are comparable.

Suppose that there exists n₀ ∈ ℕ such that $T^{n_0}{x}_0=T^{n_0+1}{x}_0$.

In this case, $T\left(T^{n_0}{x}_0\right)=T^{n_0}{x}_0$ and, consequently, inf{d(x, Tx): x ∈ X} = 0 and this finishes the proof.

Now, we suppose that Tⁿx₀ ≠ Tⁿ⁺¹x₀ for any n = 1,2,....

Since Tⁿx₀ and Tⁿ⁺¹x₀ are comparable applying the contractive condition we obtain

$$d\left(T^{n+1}{x}_0,T^{n+2}{x}_0\right)<d\left(T^n{x}_0,T^{n+1}{x}_0\right)$$

and this inequality is satisfied by any n ∈ ℕ.

Thus, {d(Tⁿx₀, Tⁿ⁺¹x₀)} is a decreasing sequence of positive real numbers and, consequently, lim_n→∞d(Tⁿx₀, Tⁿ⁺¹x₀) = r for certain r ≥ 0.

Using a similar argument that in Theorem 2.3, we prove that r = 0.

Finally, the fact lim_n→∞d(Tⁿx₀, Tⁿ⁺¹x₀) = 0 implies that inf{d(x, Tx): x ∈ X} = 0.

This finishes the proof of (a).

1. (b)

   Suppose that X is compact and T is continuous.

Taking into account that the mapping

$$\begin{array}{c}X\to {ℝ}^{+}\\ x\mapsto d\left(x,Tx\right)\end{array}$$

is continuous and the fact that X is compact, we can find z ∈ X such that

$$d\left(z,Tz\right)=inf\left\{d\left(x,Tx\right):x\in X\right\}.$$

By (a), d(z, Tz) = inf{d(x, Tx): x ∈ X} = 0 and, therefore, z is a fixed point of T.

The uniqueness of the fixed point is proved as in Theorem 2.7.

Remark 3.3. A parallel result in the nonincreasing case cannot be obtained using a similar argument as in Theorem 2.3 because the proof that (x _n ) is a Cauchy sequence uses that x_n-1and x_{n + p}are comparable and this can be false when T is a nonincreasing operator (see, Theorem 2.3).

4 Examples

In this section, we present some examples which illustrate our results.

Example 4.1. Let X = {(0,1), (1, 0), (1,1)} ⊂ ℝ² with the Euclidean distance d₂. (X, d₂) is a complete metric space. We consider the order ≤ in X given by R = {(x, x): x ∈ X}.

Notice that the elements in X are only comparable to themselves. Therefore, condition (??) of Theorem 2.3 is satisfied for any operator T: X → X.

We consider the operator T: X → X defined by

$$\begin{array}{c}T\left(1,0\right)=\left(0,1\right)\\ T\left(0,1\right)=\left(1,0\right),\\ T\left(1,1\right)=\left(1,1\right).\end{array}$$

Obviously, T is a continuous and nondecreasing operator satisfying (1,1) ≤ T(1, 1) = (1,1).

Theorem 2.3 gives us the existence of a fixed point for T (which is the point (1,1)).

On the other hand, the operator T does not satisfy Meir-Keeler condition appearing in Theorem 1.1, because for $\epsilon =d_2\left(\left(0,1\right),\left(1,0\right)\right)=\sqrt{2}$ the inequality

$$d_2\left(T\left(0,1\right),T\left(1,0\right)\right)=d_2\left(\left(1,0\right),\left(0,1\right)\right)=\sqrt{2}<\epsilon$$

fails.

Therefore, this example cannot be treated by Theorem 1.1.

Notice that in Example 4.1, we have uniqueness of the fixed point and condition (??) is not satisfied by (X, ≤) (notice that condition (??) fails for the elements (0,1), (1, 0) ∈ X). This proves that condition (??) is not a necessary condition for the uniqueness of the fixed point.

Example 4.2. Consider the same space X that in Example 4.1 with the Euclidean distance d₂ and with the order given by

$$R=\left\{\left(x,x\right):x\in X\right\}\cup \left\{\left(\left(0,1\right),\left(1,1\right)\right)\right\}.$$

Consider the operator T: X → X given by T(0, 1) = (0, 1), T(1, 1) = (0, 1) and T (1, 0) = (1, 0).

It is easily checked that T is a continuous and nondecreasing operator (notice that (0, 1) ≤ (1, 1) and T(0, 1) = (0, 1) ≤ T(1, 1) = (0,1)).

Moreover, as the unique pair of elements in X satisfying x < y is ((0,1), (1,1)) and d(T(0, 1), T(1, 1)) = d((0, 1), (0, 1)) = 0, condition (??) of Theorem 2.3 is satisfied.

As (0, 1) ≤ T(0, 1), Theorem 2.3 says us that T has a fixed point (in this case (0, 1) and (1, 0) are fixed points of T).

On the other hand, the operator T does not satisfy Meir-Keeler condition appearing in Theorem 1.1 because for $\epsilon =d_2\left(\left(0,1\right),\left(1,0\right)\right)=\sqrt{2}$ the inequality

$$d_2\left(T\left(0,1\right),T\left(1,0\right)\right)=d_2\left(\left(0,1\right),\left(1,0\right)\right)=\sqrt{2}<\epsilon$$

fails.

Thus, this example cannot be studied by Meir-Keeler Theorem (Theorem 1.1).