Iterative approximation of fixed points of quasi-contraction mappings in cone metric spaces

In this paper, we establish a full statement of Ćirić’s fixed point theorem in the setting of cone metric spaces. More exactly, we obtain a priori and a posteriori error estimates for approximating fixed points of quasi-contractions in a cone metric space. Our result complements recent results of Zhang (Comput. Math. Appl. 62:1627-1633, 2011), Ding et al. (J. Comput. Anal. Appl. 15:463-470, 2013) and others.

MSC: Primary 54H25; secondary 47H10, 46A19.

In this paper, we study fixed points of quasi-contraction mappings in a cone metric space $(X,d)$ over a solid vector space $(Y,⪯)$. Cone metric spaces have a long history (see Collatz [1], Zabrejko [2], Janković et al. [3], Proinov [4] and references therein). A unified theory of cone metric spaces over a solid vector space was developed in a recent paper of Proinov [4]. Recall that an ordered vector space with convergence structure $(Y,⪯)$ is called:

• a solid vector space if it can be endowed with a strict vector ordering $(\prec )$;

• a normal vector space if the convergence of Y has the sandwich property.

Every metric space $(X,d)$ is a cone metric space over ℝ (with usual ordering and usual convergence). On the other hand, every cone metric space over a solid vector space is a metrizable topological space (see Proinov [4] and references therein). It is well known that a lot of fixed point results in cone metric setting can be directly obtained from their metric versions (see Du [5], Amini-Harandi and Fakhar [6], Feng and Mao [7], Kadelburg et al. [8], Asadi et al. [9], Proinov [4], and Ercan [10]).

For instance, for this purpose we can use the following theorem. This theorem shows that every cone metric is equivalent to a metric which preserves the completeness as well as some inequalities.

Theorem 1.1 ([[4], Theorem 9.3])

Let $(X,d)$ be a cone metric space over a solid vector space $(Y,⪯)$. Then there exists a metric ρ on X such that the following statements hold true.

1. (i)

   The topology of $(X,d)$ coincides with the topology of $(X,\rho )$.

2. (ii)

   $(X,d)$ is complete if and only if $(X,\rho )$ is complete.

3. (iii)

   For $x,x_1,\dots ,x_n\in X$, $y,y_1,\dots ,y_n\in X$ and ${\lambda }_1,\dots ,{\lambda }_n\in \mathbb{R}$,

   $$d(x,y)⪯\sum _{i=1}^n{\lambda }_{i}d(x_i,y_i)\mathit{\text{implies}}\rho (x,y)\le \sum _{i=1}^n{\lambda }_i\rho (x_i,y_i).$$

In 1922, Banach [11] proved his famous fixed point theorem for contraction mappings. Banach’s contraction principle is one of the most useful theorems in the fixed point theory. It has two versions: a short version and a full version. In a metric space setting its full statement can be seen, for example, in the monograph of Berinde [[12], Theorem 2.1]. Recently, full statements of Banach’s fixed point theorem in a cone metric spaces over a solid vector space were given by Radenović and Kadelburg [[13], Theorem 3.3] and Proinov [[4], Theorem 11.1].

Definition 1.2 ([14])

Let $(X,d)$ be a metric space. A mapping $T:X\to X$ is called a quasi-contraction (with contraction constant λ) if there exists $\lambda \in [0,1)$ such that

for all $x,y\in X$.

There are a large number of generalizations of Banach’s contraction principle (see, for example, [14–18] and references therein). In 1974, Ćirić [14] introduced contraction mappings and proved the following well known generalization of Banach’s fixed point theorem.

Theorem 1.3 Let $(X,d)$ be a complete metric space and $T:X\to X$ be a quasi-contraction with contraction constant λ. Then the following statements hold true:

1. (i)

   Existence and uniqueness. T has a unique fixed point ξ in X.

2. (ii)

   Convergence of Picard iteration. For every starting point $x\in X$ the Picard iteration sequence $(T^{n}x)$ converges to ξ.

3. (iii)

   A priori error estimate. For every point $x\in X$ the following a priori error estimate holds:

   $$d(T^{n}x,\xi )\le \frac{{\lambda }^n}{1-\lambda }d(x,Tx)\mathit{\text{for all }}n\ge 0.$$

   (2)

Following Zhang [19], in the next definition, we define a useful binary relation between an ordered vector space Y and the set of all subsets of Y. It plays a very important role in this paper as it is used to prove our main result.

Definition 1.4 ([19])

Let $(Y,⪯)$ be an ordered vector space, $x\in Y$ and $A\subset Y$. We say that $x⪯A$ if there exists at least one vector $y\in A$ such that $x⪯y$.

In 2009, Ilić and Rakočević [20] generalized the concept of quasi-contraction to cone metric space as follows: A selfmapping T of a cone metric space $(X,d)$ over an ordered vector space $(Y,⪯)$ is called a quasi-contraction on X if there exists $\lambda \in [0,1)$ such that

for all $x,y\in X$. They proved the following result [[20], Theorem 2.1]: Let $(X,d)$ be a cone metric space over a normal solid Banach space $(Y,⪯)$; then every quasi-contraction T of the type (3) has a unique fixed point in X, and for all $x\in X$ the Picard iterative sequence $(T^{n}x)$ converges to this fixed point. Kadelburg et al. [[21], Theorem 2.2] improved this result by omitting the assumption of normality provided that $\lambda \in [0,1/2)$. Gajić and Rakočević [[22], Theorem 3] proved this result for any contraction constant $\lambda \in [0,1)$. Rezapour et al. [[23], Theorem 2.1] proved this result in the case when Y is a solid topological vector space and $\lambda \in [0,1)$. Furthermore, Kadelburg et al. [[8], Theorem 3.5(b)] proved that this result is equivalent to the short version of Ćirić’s fixed point theorem.

In 2011, Zhang [19] presented the following new definition for quasi-contractions in cone metric spaces.

Definition 1.5 ([19])

Let $(X,d)$ be a cone metric space over an ordered vector space $(Y,⪯)$. A mapping $T:X\to X$ is called a quasi-contraction (with contraction constant λ) if there exists $\lambda \in [0,1)$ such that

for all $x,y\in X$.

By applying Theorem 1.1 to the first two conclusions of Theorem 1.3, we obtain the following fixed point theorem in a cone metric setting.

Theorem 1.6 Let $(X,d)$ be a complete cone metric space over a solid vector space $(Y,⪯)$ and $T:X\to X$ be a quasi-contraction. Then the following statements hold true:

1. (i)

   Existence and uniqueness. T has a unique fixed point ξ in X.

2. (ii)

   Convergence of Picard iteration. For every starting point $x\in X$ the Picard iteration sequence $(T^{n}x)$ converges to ξ.

In 2011, Zhang [19] proved Theorem 1.6 in the case when Y is a normal solid Banach space. In 2013, Ding et al. [24] proved this theorem in the case when Y is a solid topological vector space.

In this paper, we establish a full statement of Ćirić’s fixed point theorem in the setting of cone metric spaces. Our result complements Theorem 1.6. Thus it extends and complements the corresponding results of Zhang [19], Ding et al. [24], and others.

For some recent results on the topic, we refer the reader to [25–38]. In the papers [37, 38] one can find some applications of cone metric spaces to iterative methods for finding all zeros of polynomial simultaneously.

In this section, we introduce some basic definitions and theorems of cone metric spaces over a solid vector space.

Definition 2.1 ([4])

Let Y be a real vector space and S be the set of all infinite sequences in Y. A binary relation → between S and Y is called a convergence on Y if it satisfies the following axioms:

(C1) If $x_n\to x$ and $y_n\to y$, then $x_n+y_n\to x+y$.

(C2) If $x_n\to x$ and $\lambda \in \mathbb{R}$, then $\lambda x_n\to \lambda x$.

(C3) If ${\lambda }_n\to \lambda$ in ℝ and $x\in Y$, then ${\lambda }_{n}x\to \lambda x$.

A real vector space Y endowed with convergence is said to be a vector space with convergence. If $x_n\to x$, then $(x_n)$ is said to be a convergent sequence in Y, and the vector x is said to be a limit of $(x_n)$.

Definition 2.2 ([4])

Let $(Y,\to )$ be a vector space with convergence. An ordering ⪯ on Y is said to be a vector ordering if it is compatible with the algebraic and convergence structures on Y in the sense that the following are true:

(V1) If $x⪯y$, then $x+z⪯y+z$.

(V2) If $\lambda \ge 0$ and $x⪯y$, then $\lambda x⪯\lambda y$.

(V3) If $x_n\to x$, $y_n\to y$, $x_n⪯y_n$ for all n, then $x⪯y$.

A vector space with convergence Y endowed with vector ordering is called an ordered vector space with convergence.

Definition 2.3 ([4])

Let $(Y,⪯,\to )$ be an ordered vector space with convergence. A strict ordering ≺ on Y is said to be a strict vector ordering if it is compatible with the vector ordering, the algebraic structure and the convergence structure on Y in the sense that the following are true:

(S1) If $x\prec y$, then $x⪯y$.

(S2) If $x⪯y$ and $y\prec z$, then $x\prec z$.

(S3) If $x\prec y$, then $x+z\prec y+z$.

(S4) If $\lambda >0$ and $x\prec y$, then $\lambda x\prec \lambda y$.

(S5) If $x_n\to x$, $y_n\to y$ and $x\prec y$, then $x_n\prec y_n$ for all but finitely many n.

It turns out that an ordered vector space can be endowed with at most one strict vector ordering (see Proinov [[4], Theorem 5.1]).

Definition 2.4 (Solid vector space)

An ordered vector space with convergence endowed with a strict vector ordering is said to be a solid vector space.

Let us consider an important example of a solid vector space.

Example 2.5 Let $(Y,\tau )$ be a topological vector space and $K\subset Y$ be a cone with nonempty interior $K^{\circ }$. Define the vector ordering ⪯ on Y and the strict vector ordering ≺ on Y, respectively, by means of

Then Y is a solid vector space called a solid topological vector space.

Now let us recall the definition of a cone metric space known also as ‘K-metric spaces’ (see Zabrejko [2], Proinov [4] and references therein).

Definition 2.6 (Cone metric space)

Let X be a nonempty set, and let $(Y,⪯)$ be an ordered vector space with convergence. A vector-valued function $d:X\times X\to Y$ is said to be a cone metric on Y if the following conditions hold:

1. (i)

   $d(x,y)⪰0$ for all $x,y\in X$ and $d(x,y)=0$ if and only if $x=y$;

2. (ii)

   $d(x,y)=d(y,x)$ for all $x,y\in X$;

3. (iii)

   $d(x,y)⪯d(x,z)+d(z,y)$ for all $x,y,z\in X$.

The pair $(X,d)$ is called a cone metric space over Y.

Let $(X,d)$ be a cone metric space over a solid vector space $(Y,⪯,\prec )$, $x_0\in X$ and $r\in Y$ with $r\succ 0$. Then the set $U(x_0,r)=\{x\in X:d(x,x_0)\prec r\}$ is called an open ball with center $x_0$ and radius r.

Every cone metric space X over a solid vector space Y is a Hausdorff topological space with topology generated by the basis of all open balls. Then a sequence $(x_n)$ of points in X converges to $x\in X$ if and only if for every vector $c\in Y$ with $c\succ 0$, $d(x_n,x)\prec c$ for all but finitely many n.

Recall also that a sequence $(x_n)$ in X is called a Cauchy sequence if for every $c\in Y$ with $c\succ 0$ there is $N\in \mathbb{N}$ such that $d(x_n,x_m)\prec c$ for all $n,m>N$. A cone metric space X is called complete if each Cauchy sequence in X is convergent.

In order to prove our main result we need the following two theorems.

Theorem 2.7 ([4])

Let $(X,d)$ be a complete cone metric space over a solid vector space $(Y,⪯)$. Suppose $(x_n)$ is a sequence in X satisfying

where $(b_n)$ is a sequence in Y which converges to 0. Then $(x_n)$ converges to a point $\xi \in X$ with error estimate

Theorem 2.8 ([4])

Let $(X,d)$ be a cone metric space over a solid vector space $(Y,⪯)$ and $T:X\to X$. Suppose that for some $x\in X$, the Picard iteration $(T^{n}x)$ converges to a point $\xi \in X$. Suppose also that there exist nonnegative numbers α and β such that

Then ξ is a fixed point of T.

Let A be a subset of a real vector space Y. Recall that the convex hull of A, denoted coA, is the smallest convex set including A. Suppose $x,x_1,\dots ,x_n\in Y$. It is well known that $x\in co\{x_1,\dots ,x_n\}$ if and only if there exist nonnegative numbers ${\alpha }_1,\dots ,{\alpha }_n$ such that ${\sum }_{i=1}^n{\alpha }_i=1$ and $x={\sum }_{i=1}^n{\alpha }_i{x}_i$.

Lemma 3.1 Let $(Y,⪯)$ be an ordered vector space. Suppose that x, y, $x_1,\dots ,x_n$, $y_1,\dots ,y_m$ are vectors in Y and λ is a real number. Then:

(P1) $x⪯co\{x_1,\dots ,x_n\}\Rightarrow x⪯co\{x_1,\dots ,x_n,y\}$;

(P2) $x⪯co\{x_1,\dots ,x_n\}$ and $x_i⪯y_i$ for all $i\Rightarrow x⪯co\{y_1,\dots ,y_n\}$;

(P3) $x⪯co\{x_1,\dots ,x_n,y\}$ and $y⪯co\{y_1,\dots ,y_m\}\Rightarrow x⪯co\{x_1,\dots ,x_n,y_1,\dots ,y_m\}$;

(P4) $x⪯co\{0,x_1,\dots ,x_n\}\iff x⪯co\{x_1,\dots ,x_n\}$ if $x_i⪰0$ for some i;

(P5) $x⪯co\{\lambda x,x_1,\dots ,x_n\}\iff x⪯co\{x_1,\dots ,x_n\}$ if $\lambda <1$ and $x_i⪰0$ for some i;

(P6) $x⪯co\{x_1,\dots ,x_n,y\}\iff x⪯co\{x_1,\dots ,x_n\}$ if $y=x_i$ for some i.

Proof We only prove the necessity of (P5) since the proofs of the other properties are similar. The inequality $x⪯co\{\lambda x,x_1,\dots ,x_n,\}$ implies that there exist nonnegative numbers $\alpha ,{\alpha }_1,\dots ,{\alpha }_n$ such that $\alpha +{\sum }_{i=1}^n{\alpha }_i=1$ and $x⪯\alpha \lambda x+{\sum }_{i=1}^n{\alpha }_i{x}_i$. From this inequality and $\alpha \lambda <1$, we deduce

where ${\beta }_i={\alpha }_i/(1-\alpha \lambda )$. We have ${\sum }_{i=1}^n{\beta }_i=(1-\alpha )/(1-\alpha \gamma )<1$. By the assumptions, we have $x_i⪰0$ for some i. Without loss of generality we may assume that $x_1⪰0$. Define the nonnegative numbers ${\gamma }_1,\dots ,{\gamma }_n$ by ${\gamma }_1=1-{\sum }_{j=2}^n{\beta }_j$ and ${\gamma }_i={\beta }_i$ for $i\ge 2$. From (6) and ${\beta }_1\le {\gamma }_1$, we obtain

This implies $x⪯co\{x_1,\dots ,x_n\}$ since ${\sum }_{i=1}^n{\gamma }_i=1$. □

Remark 3.2 Note that Lemma 3.1 remains true if we omit the expression ‘co’ from its formulation.

The following lemma was given by Zhang [[19], Lemma 6] in a slightly different form. We give a simple proof of this lemma.

Lemma 3.3 Let $(X,d)$ be a cone metric space over an ordered vector space $(Y,⪯)$, $T:X\to X$ be a quasi-contraction with contraction constant $\lambda \in [0,1)$, and let $x\in X$. Then for every $m\in \mathbb{N}$, we have

Proof We prove the statement by induction on m. It is obviously true for $m=1$. Assume that $n\in \mathbb{N}$ and assume that (7) is satisfied for any natural number $m\le n$. We have to prove that

We divide the proof of (8) into three steps.

Step 1. We claim that for every natural number $i\le n$ the following inequality holds:

By the definition of the quasi-contraction mapping, we obtain

From the induction hypothesis and properties (P1) and (P2), we get the following three inequalities:

From the last four inequalities and properties (P3) and (P6), we obtain the desired inequality.

Step 2. We claim that for every natural number $i\le n$ the following inequality holds:

We prove this by finite induction on i. Setting $i=1$ in the claim of Step 1, we immediately arrive at the following inequality:

which proves the claim of Step 2 for $i=1$. Assume that for some $i\le n$, the claim of Step 2 holds. Now we shall show that

It follows from Step 1 that

By the finite induction hypothesis and property (P2), we have

From (10), (11), and properties (P3) and (P6), we obtain (9).

Step 3. Now we shall prove (8). From the claim of Step 2 with $i=n$, we get

According to the property (P5), this inequality is equivalent to

which by (P2) implies

Finally, by the claim of Step 2 and the inequality (12), taking into account the properties (P3) and (P6), we obtain (8). This completes the proof of the lemma. □

In the following lemma, we show that if T is a quasi-contraction of a cone metric space X, then for every starting point $x\in X$, the Picard iteration sequence $(T^{n}x)$ is bounded in the space X.

Lemma 3.4 Let $(X,d)$ be a cone metric space over an ordered vector space $(Y,⪯)$, $T:X\to X$ be a quasi-contraction with contraction constant $\lambda \in [0,1)$, and let $x\in X$. Then for every $m\in \mathbb{N}$, we have

Proof We prove the statement by induction on m. If $m=1$, then inequality (13) holds since $0\le \lambda <1$. Assume that $n\in \mathbb{N}$ and assume that (7) is satisfied for any natural number $m\le n$. Then we have to prove that

From the triangle inequality, we obtain

By Lemma 3.3, we get

By the induction hypothesis, we have that (13) holds for all $m\le n$. Then it follows from (16), (P2), and (P6) that

This inequality implies that there exists $\alpha \in [0,1]$ such that

Combining (15) and (17), we get

which is equivalent to the following inequality:

Multiplying both sides of this inequality by $1/(1-\lambda +\alpha \lambda )$, we obtain (14). This completes the proof of the lemma. □

Lemma 3.5 Let $(X,d)$ be a cone metric space over an ordered vector space $(Y,⪯)$, and let $T:X\to X$ be a quasi-contraction with contraction constant $\lambda \in [0,1)$. Then for all $x,y\in X$, we have

where $\alpha =\lambda /(1-\lambda )$ and $\beta =(1+\lambda )/(1-\lambda )$.

Proof Let $x,y\in X$ be fixed. First we shall prove that

It follows from Definition 1.5 that there exist five nonnegative numbers $\alpha ,\beta ,\gamma ,\mu ,\nu$ such that $\alpha +\beta +\gamma +\mu +\nu =1$ and

From this and the inequalities

we obtain

This inequality yields (19) since $\alpha +\gamma +\nu \le 1$, $\beta +\nu \le 1$ and $\gamma +\mu \le 1$. Now we are ready to prove (18). From the triangle inequality, we get

From this and (19), we obtain

which can be presented in the following equivalent form:

Multiplying both sides of this inequality by $1/(1-\lambda )$, we get (18). □

Lemma 3.6 Let $(X,d)$ be a cone metric space over an ordered vector space $(Y,⪯)$. Then every quasi-contraction $T:X\to X$ has at most one fixed point in X.

Proof Suppose that x and y are two fixed points of T. It follows from the inequality (4) and properties (P4) and (P6) that $d(x,y)⪯\lambda d(x,y)$ which implies $d(x,y)⪯0$. On the other hand, $d(x,y)⪰0$. Hence, $d(x,y)=0$, which yields $x=y$. □

Now we are ready to state the main result of this paper. Let $(X,d)$ be a complete cone metric space over an ordered vector space Y. Recall that for a point $x_0\in X$ and a vector $r\in Y$ with $r⪰0$, the set $\overline{U}(x_0,r)=\{x\in X:d(x,x_0)⪯r\}$ is called a closed ball with center $x_0$ and radius r.

Theorem 4.1 Let $(X,d)$ be a complete cone metric space over a solid vector space $(Y,⪯)$, and let $T:X\to X$ be a quasi-contraction with contraction constant $\lambda \in [0,1)$. Then the following statements hold true:

1. (i)

   Existence, uniqueness and localization. T has a unique fixed point ξ which belongs to the closed ball $\overline{U}(x,r)$ with radius

   $$r=\frac{1}{1-\lambda }d(x,Tx),$$

where x is any point in X.

1. (ii)

   Convergence of Picard iteration. Starting from any point $x\in X$ the Picard sequence $(T^{n}x)$ remains in the closed ball $\overline{U}(x,r)$ and converges to ξ.

2. (iii)

   A priori error estimate. For every point $x\in X$ the following a priori estimate holds:

   $$d(T^{n}x,\xi )⪯\frac{{\lambda }^n}{1-\lambda }d(x,Tx)\mathit{\text{for all }}n\ge 0.$$

   (20)
3. (iv)

   A posteriori error estimates. For every point $x\in X$ the following a posteriori estimate holds:

   $$d(T^{n}x,\xi )⪯\frac{1}{1-\lambda }d(T^{n}x,T^{n+1}x)\mathit{\text{for all }}n\ge 0,$$

   (21)
   $$d(T^{n}x,\xi )⪯\frac{\lambda }{1-\lambda }d(T^{n}x,T^{n-1}x)\mathit{\text{for all }}n\ge 1.$$

   (22)

Proof Let x be an arbitrary point in X. By Lemma 3.3, for all $m,n\in \mathbb{N}$ with $m\ge n$, we have

From this, Lemma 3.4, and properties (P2) and (P6), we deduce

Note that $(b_n)$ is a sequence in Y which converges to 0 since ${\lambda }^n\to 0$ in ℝ. Now applying Theorem 2.7 to the Picard sequence $(T^{n}x)$, we conclude that there exists a point $\xi \in X$ such that $(T^{n}x)$ converges to ξ and $d(T^{n}x,\xi )⪯b_n$ for every $n\ge 0$. The last inequality coincides with the estimate (20). Setting $n=0$ in (20), we get

which means that $\xi \in \overline{U}(x,r)$. The inequality (24) holds for every point $x\in X$. Applying (24) to the point $T^{n}x$, we obtain (21). Setting $n=1$ in (20), we get

Applying (25) to the point $T^{n-1}x$, we get (22). Setting $n=0$ in (23), we obtain $d(x,T^{m}x)⪯b_0$ for every $m\ge 0$. Hence, the sequence $(T^{n}x)$ lies in the ball $\overline{U}(x,r)$ since $r=b_0$.

It follows from Lemma 3.5 that ξ satisfies condition (5). Hence, by Theorem 2.8, we conclude that ξ is a fixed point of T. The uniqueness of the fixed point follows from Lemma 3.6. □

Theorem 4.1 extends and complements the recent results of Ding et al. [[24], Theorem 3.1] and Zhang [[19], Theorem 3] as well as previous results due to Ilić and Rakočević [[20], Theorem 2.1], Kadelburg et al. [[21], Theorem 2.2], Rezapour et al. [[23], Theorem 2.1] and Kadelburg et al. [[8], Theorem 3.5(b)] who have studied quasi-contraction mappings of the type (3).

Theorem 4.1 also extends and complements the results of Abbas and Rhoades [[39], Corollary 2.3], Olaleru [[40], Theorem 2.1], Azam et al. [[41], Theorem 2.2], Song et al. [[42], Corollary 2.1]. These authors have studied the class of mappings satisfying a contractive condition of the type

for all $x,y\in X$, where α, β, γ, μ and ν are five nonnegative constants such that $\alpha +\beta +\gamma +\mu +\nu <1$. In this case Theorem 4.1 holds with $\lambda =\alpha +\beta +\gamma +\mu +\nu$ since condition (26) implies condition (4) with this λ. Let us note that in this special case Theorem 4.1 holds even with $\lambda =(\alpha +\delta )/(1-\delta )$, where $\delta =(\beta +\gamma +\mu +\nu )/2$.

Zhang [[19], Example 1] gives an example showing that the set of all quasi-contractions of the type (3) is a proper subset of the set of all quasi-contractions defined by (4). In order to prove this, he considers a selfmapping of a cone metric space X over a normal solid vector space Y. Ding et al. [[24], Example 4.1] provide a similar example, but for the case of a non-normal solid vector space Y.

The aim of this section is to unify these two examples. Let ℬ denote the set of all quasi-contractions of the type (3), and let denote the set of all quasi-contractions defined by (4), that is,

Now we shall construct a family of examples which show that ℬ is a proper subset of . In particular, this family contains both the example of Zhang [19] and the example of Ding et al. [24].

Definition 5.1 Let $(Y,⪯)$ be an ordered vector space, and let $a,b,c⪰0$ be three vectors in Y. We say that the triple $(a,b,c)$ satisfies property (C) if the following two statements hold:

• $a⪯\lambda co\{b,c\}$ for some $\lambda \in [0,1)$, $b⪯a+c$ and $c⪯a+b$.

• $a⪯k\{b,c\}$ is wrong for every $k\in [0,1)$.

Proposition 5.2 Let $Y=\mathbb{R}$ be endowed with the usual ordering ≤. Then there are no triples $(a,b,c)$ in Y satisfying property (C).

Proof Assume that there is a triple $(a,b,c)$ in Y with property (C). Then $a⪯\lambda max\{b,c\}$ for some $\lambda \in [0,1)$. On the other hand, $a⪯kmax\{b,c\}$ is wrong for every $k\in [0,1)$. This is a contradiction which proves the proposition. □

Proposition 5.3 Let $Y={\mathbb{R}}^n$ ($n\ge 2$) be endowed with coordinate-wise ordering ⪯. Then in Y there exist infinitely many triples $(a,b,c)$ satisfying property (C).

Proof Choose three real numbers α, β and γ such that

Then the vectors $a=(\alpha ,\dots ,\alpha )$, $b=(\beta ,\dots ,\beta ,\gamma )$ and $c=(\gamma ,\dots ,\gamma ,\beta )$ satisfy property (C) with $\lambda =\frac{2\alpha }{\beta +\gamma }$. □

Proposition 5.4 Let $Y=C^n[0,1]$ ($n\ge 2$) be endowed with point-wise ordering ⪯. Then in Y there exist infinitely many triples $(a,b,c)$ satisfying property (C).

Proof Choose three real numbers α, β and γ as in the proof of Proposition 5.3, then choose a real number δ such that

Then the functions $a(t)=\alpha$, $b(t)=\beta +\delta t$ and $c(t)=\gamma -\delta t$ satisfy property (C) with $\lambda =\frac{2\alpha }{\beta +\gamma }$. □

Example 5.5 Let $(Y,⪯)$ be an arbitrary solid vector space, and let $(a,b,c)$ be any triple in Y with property (C). Furthermore, let $X=\{x,y,z\}$, and let $d:X\times X\to Y$ be defined by

$d(u,v)=d(u,v)$ and $d(u,u)=0$ for $u,v\in X$. Then $(X,d)$ is a complete cone metric space over Y since the triple $(a,b,c)$ satisfies property (C). Consider now the mapping $T:X\to X$ defined by

Using Lemma 3.1, it is easy to prove that $T\in \mathcal{C}$ if and only if $a⪯\lambda co\{b,c\}$ for some $\lambda \in [0,1)$. Analogously, taking into account Remark 3.2, one can easily prove that $T\in \mathcal{B}$ if and only if $a⪯k\{b,c\}$ for some $k\in [0,1)$. Now taking into account that the triple $(a,b,c)$ satisfies property (C), we conclude that $T\in \mathcal{C}$ and $T\notin \mathcal{B}$. Hence, ℬ is a proper subset of .

The research is supported by Project NI13 FMI-002 of Plovdiv University.

Authors and Affiliations

1. Faculty of Mathematics and Informatics, University of Plovdiv, Plovdiv, 4000, Bulgaria

   Petko D Proinov & Ivanka A Nikolova

Corresponding author

Correspondence to Petko D Proinov.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

Both authors contributed equally and significantly in writing this paper. Both authors read and approved the final manuscript.

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0), which permits use, duplication, adaptation, distribution, and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.

Reprints and permissions