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* Correspondence: mailto:[email protected]

Web End =arahim@kfupm. mailto:[email protected]

Web End =edu.sa

3Department of Mathematics and Statistics, King Fahd University of Petroleum and Minerals, Dhahran 31261, Saudi ArabiaFull list of author information is available at the end of the article

RESEARCH Open Access

Common fixed point and invariant approximation in hyperbolic ordered metric spaces

Mujahid Abbas1, Mohamed Amine Khamsi2,3 and Abdul Rahim Khan3*

Abstract

We prove a common fixed point theorem for four mappings defined on an ordered metric space and apply it to find new common fixed point results. The existence of common fixed points is established for two or three noncommuting mappings where T is either ordered S-contraction or ordered asymptotically S-nonexpansive on a nonempty ordered starshaped subset of a hyperbolic ordered metric space. As applications, related invariant approximation results are derived. Our results unify, generalize, and complement various known comparable results from the current literature.2010 Mathematics Subject Classification:47H09, 47H10, 47H19, 54H25.

Keywords: Hyperbolic metric space, common fixed point, Ordered uniformly Cq-commuting mapping, ordered asymptotically S-nonexpansive mapping, Best approximation

1 Introduction

Metric fixed point theory has primary applications in functional analysis. The interplay between geometry of Banach spaces and fixed point theory has been very strong and fruitful. In particular, geometric conditions on underlying spaces play a crucial role for finding solution of metric fixed point problems. Although, it has purely metric flavor, it is still a major branch of nonlinear functional analysis with close ties to Banach space geometry, see for example [1-4] and references mentioned therein. Several results regarding existence and approximation of a fixed point of a mapping rely on convexity hypotheses and geometric properties of the Banach spaces. Recently, Khamsi and Khan [5] studied some inequalities in hyperbolic metric spaces, which lay foundation for a new mathematical field: the application of geometric theory of Banach spaces to fixed point theory. Meinardus [6] was the first to employ fixed point theorem to prove the existence of invariant approximation in Banach spaces. Subsequently, several interesting and valuable results have appeared about invariant approximations [7-9].

Existence of fixed points in ordered metric spaces was first investigated in 2004 by Ran and Reurings [10], and then by Nieto and Lopez [11].

In 2009, Dori [12] proved some fixed point theorems for generalized (, )-weakly contractive mappings in ordered metric spaces. Recently, Radenovi and Kadelburg[13] presented a result for generalized weak contractive mappings in ordered metric spaces (see also, [14,15] and references mentioned theirin). Several authors studied the

2011 Abbas et al; licensee Springer. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0

Web End =http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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problem of existence and uniqueness of a fixed point for mappings satisfying different contractive conditions (e.g., [16-18,13,19]). The aim of this article is to study common fixed points of (i) four mappings on an ordered metric space (ii) ordered Cq-commuting mappings in the frame work of hyperbolic ordered metric spaces. Some results on invariant approximation for these mappings are also established which in turn extend and strengthen various known results.

2 Preliminaries

Let (X, d) be a metric space. A path joining x X to y X is a map c from a closed interval [0, l] to X such that c(0) = x, c(l) = y, and d(c(t), c(t)) = |t - t| for all t, t [0, l]. In particular, c is an isometry and d(x, y) = l. The image of c is called a metric segment joining x and y. When it is unique the metric segment is denoted by [x, y]. We shall denote by (1 - l)x ly the unique point z of [x, y] which satisfies

d(x, z) = d(x, y), and d(z, y) = (1 )d(x, y).

Such metric spaces are usually called convex metric spaces (see Takahashi [20] and Khan at el. [21]). Moreover, if we have for all p, x, y in X

d

1

2p

1

2d(x, y),

then X is called a hyperbolic metric space. It is easy to check that in this case for all x, y, z, w in X and l [0, 1]

d((1 )x y, (1 )z w) (1 )d(x, z) + d(y, w).

Obviously, normed linear spaces are hyperbolic spaces [5]. As nonlinear examples one can consider Hadamard manifolds [2], the Hilbert open unit ball equipped with the hyperbolic metric [3] and CAT(0) spaces [4].

Let X be a hyperbolic ordered metric space. Throughout this article, we assume that (1 - l)x ly (1 - l)z lw for all x, y, z, w in X with x z and y w. A subset Y of X is said to be ordered convex if Y includes every metric segment joining any two of its comparable points. The set Y is said to be an ordered q-starshaped if there exists q in Y such that Y includes every metric segment joining any of its point comparable with q.

Let Y be an ordered q-starshaped subset of X and f, g : Y Y. Put,

Yfq = {y : y = (1 )q fx and [0, 1], q x or x q}.

Set, for each x in X comparable with q in Y, d(gx, Yfq) = inf

[0,1]

1

2x,

1

2p

1

2y

d(gx, y).

Definition 2.1. A selfmap f on an ordered convex subset Y of a hyperbolic ordered metric space X is said to be affine if

f ((1 )x y) = (1 )fx fyfor all comparable elements x, y Y , and l [0, 1].

Let f and g be two selfmaps on X. A point x X is called (1) a fixed point of f if f(x) = x; (2) coincidence point of a pair (f, g) if fx = gx; (3) common fixed point of a pair (f, g) if x = fx = gx. If w = fx = gx for some x in X, then w is called a point of coincidence

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of f and g. A pair (f, g) is said to be weakly compatible if f and g commute at their coincidence points.

We denote the set of fixed points of f by Fix(f).

Definition 2.2. Let (X, ) be an ordered set. A pair (f, g) on X is said:(i) weakly increasing if for all x X, we have fx gfx and gx fgx, ([22])(ii) partially weakly increasing if fx gfx, for all x X.

Remark 2.3. A pair (f, g) is weakly increasing if and only if ordered pair (f, g) and (g, f) are partially weakly increasing.

Example 2.4. Let X = [0, 1] be endowed with usual ordering. Let f, g : X X be defined by fx = x2 and gx = x. Then fx = x2 x = gfx for all x X. Thus (f, g) is partially weakly increasing. But gx = x x = fgx for x (0, 1). So (g, f) is not partially

weakly increasing.

Definition 2.5. Let (X, ) be an ordered set. A mapping f is called weak annihilator of g if fgx x for all x X.

Example 2.6. Let X = [0, 1] be endowed with usual ordering. Define f, g : X X by fx = x2 and gx = x3. Then fgx = x6 x for all x X. Thus f is a weak annihilator of g.

Definition 2.7. Let (X, ) be an ordered set. A selfmap f on X is called dominating map if x fx for each x in X.

Example 2.8. Let X = [0, 1] be endowed with usual ordering. Let f : X X be

defined by fx = x

n

kn = 1 such that

d(f n(x), f n(y)) knd(gx, gy)

for each x, y in Y with x y and each n N. If kn = 1, for all n N , then f is known as ordered g-nonexpansive mapping. If g = I (identity map), then f is ordered asymptotically nonexpansive mapping;

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13 = fx for all x X. Thus f is a dominating map.

Example 2.9. Let X = [0, ) be endowed with usual ordering. Define f : X X by

fx =

1 3. Then x x

x for x [0, 1),

xn for x [1, ),n N. Then for all x X, x fx so that f is a dominating map.

Definition 2.10. Let (X, ) be a ordered set and f and g be selfmaps on X. Then the pair (f, g) is said to be order limit preserving if

gx0 f x0,

for all sequences {xn} in X with gxn fxn and xn x0.

Definition 2.11. Let X be a hyperbolic ordered metric space, Y an ordered q-starshaped subset of X, f and g be selfmaps on X and q Fix(g). Then f is said to be:

(1) ordered g-contraction if there exists k (0, 1) such that

d(fx, fy) kd(gx, gy);

for x, y Y with x y.(2) ordered asymptotically S-nonexpansive if there exists a sequence {kn}, kn 1, with lim

n

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(3) R-weakly commuting if there exists a real number R > 0 such that

d(fgx, gfx) Rd(fx, gx);

for all x in Y.(4) ordered R-subweakly commuting [23] if there exists a real number R > 0 such that

d(fgx, gfx) Rd(gx, Yfq)

for all x Y.(5) ordered uniformly R-subweakly commuting [23] if there exists a real number R > 0 such that

d(f ngx, gf nx) Rd(gx, Yf

n

q )

for all x Y.(6) ordered Cq-commuting [24], if gfx = fgx for all x Cq(f, g), where Cq(f, g) = U {C(g, fk) : 0 k 1} and fkx = (1 - k)q kfx.(7) ordered uniformly Cq-commuting, if gf nx = f ngx for all x Cq(g, f n) and n N.(8) uniformly asymptotically regular on Y if, for each h >0, there exists N(h) = N such that d(f nx, f n+1x) <h for all h N and all x Y .

For other related notions of noncommuting maps, we refer to [7]; in particular, here Example 2.2 and Remark 3.10(2) provide two maps which are not Cq-commuting. Also, uniformly Cq-commuting maps on X are Cq-commuting and uniformly R-subweakly commuting maps are uniformly Cq-commuting but the converse statements do not hold, in general [23,25]. Fixed point theorems in a hyperconvex metric space (an example of a convex metric space) have been established by Khamsi [26] and Park [27].

Let Y be a closed subset of an ordered metric space X. Let x X. Define d(x, Y ) = inf{d(x, y) : y Y, y x or x y}. If there exists an element y0 in Y comparable with x such that d(x, y0) = d(x, Y ), then y0 is called an ordered best approximation to X out of Y. We denote by PY (x), the set of all ordered best approximation to x out of Y. The reader interested in the interplay of fixed points and approximation theory in normed spaces is referred to the pioneer work of Park [28] and Singh [9].

3 Common fixed point in ordered metric spaces

We begin with a common fixed point theorem for two pairs of partially weakly increasing functions on an ordered metric space. It may regarded as the main result of this article.

Theorem 3.1. Let (X, , d) be an ordered metric space. Let f, g, S, and T be selfmaps on X, (T, f) and (S, g) be partially weakly increasing with f(X) T(X), g(X) S(X), and dominating maps f and g be weak annihilator of T and S, respectively. Also, for every two comparable elements x, y X,

d(fx, gy) hM(x, y),

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where

d(Sx, gy) + d(fx, Ty)2 } (3:1)

for h [0, 1) is satisfied. If one of f(X), g(X), S(X), or T(X) is complete subspace of X, then {f, S} and {g, T} have unique point of coincidence in X provided that for a nondecreasing sequence {xn} with xn yn for all n and yn u implies xn u. Moreover, if {f, S} and {g, T } are weakly compatible, then f, g, S, and T have a common fixed point.

Proof. For any arbitrary point x0 in X, construct sequences {xn} and {yn} in X such that

y2n1 = f x2n2 = Tx2n1 fTx2n1, and y2n = gx2n1 = Sx2n gSx2n.

Since dominating maps f and g are weak annihilator of T and S, respectively so for all n 1,

x2n2 f x2n2 = Tx2n1 fTx2n1 x2n1, and

x2n1 gx2n1 = Sx2n gSx2n x2n.

Thus, we have xn xn+1 for all n 1. Now (3.1) gives that.

d(y2n+1, y2n+2) = d(f x2n, gx2n+1) hM(x2n, x2n+1) for n = 1, 2, 3,..., where

M(x2n, x2n+1)

= max{d(Sx2n, Tx2n+1), d(f x2n, Sx2n), d(gx2n+1, Tx2n+1), d(f x2n, Tx2n+1) + d(gx2n+1, Sx2n)

2

M(x, y) = max{d(Sx, Ty), d(fx, Sx), d(gy, Ty),

= max{d(y2n, y2n+1), d(y2n+1, y2n), d(y2n+2, y2n+1),

d(y2n+1, y2n+1) + d(y2n+2, y2n) 2 }

= max{d(y2n, y2n+1), d(y2n+1, y2n+2),

d(y2n, y2n+1) + d(y2n+1, y2n+2) 2 }

= max{d(y2n, y2n+1), d(y2n+1, y2n+2)}.

Now if M(x2n, x2n+1) = d(y2n, y2n+1), then d(y2n+1, y2n+2) hd(y2n, y2n+1). And if M(x2n, x2n+1) = d(y2n+1, y2n+2), then d(y2n+1, y2n+2) hd(y2n+1, y2n+2) which implies that d(y2n+1, y2n+2) = 0, and y2n+1 = y2n+2. Hence

d(yn, yn+1) hd(yn1, yn) for n = 3, 4, . . .

Therefore

d(yn, yn+1) hd(yn1, xn)

h2d(yn2, yn1) hnd(y0, y1) for all n N. Then, for m > n,

d(yn, ym) d(yn, yn+1) + d(yn+1, yn+2) + + d(ym1, ym)

[hn + hn+1 + + hm]d(y0, y1)

hn1 h

d(y0, y1),

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and so d(yn, ym) 0 as n, m . Hence {yn} is a Cauchy sequence. Suppose that S (X) is complete. Then there exists u in S(X), such that Sx2n = y2n u as n . Con

sequently, we can find v in X such that Sv = u. Now we claim that fv = u. Since, x2n-2

x2n-1 gx2n-1 = Sx2-n and Sx2n Sv. So that x2n-1 Sv and since, Sv gSv and gSv v, implies x2n-1 v. Consider

d(fv, u) d(fv, gx2n1) + d(gx2n1, u) hM(v, x2n1) + d(gx2n1, u),

where

M(v, x2n1) = max{d(Sv, Tx2n1), d(fv, Sv), d(gx2n1, Tx2n1),

d(fv, Tx2n1) + d(gx2n1, Sv)

2

for all n N. Now we have four cases:

If M(v, x2n-1) = d(Sv, Tx2n-1), then d(fv, u) hd(Sv, Tx2n-1)+d(gx2n-1, u) 0 as n

implies that fv = u.

If M(v, x2n-1) = d(fv, Sv), then d(fv, u) hd(fv, Sv) + d(gx2n-1, u). Taking limit as n we get d(fv, u) hd(fv, u). Since h <1, so that fv = u.

If M(v, x2n-1) = d(gx2n-1, Tx2n-1), then d(fv, u) hd(gx2n-1, Tx2n-1) + d(gx2n-1, u) 0 as n implies that fv = u.

If M(v, x2n1) =

[d(fv, Tx2n1) + d(gx2n1, Sv)]

2 + d(gx2n1, u).

Taking limit as n we get d(fv, u)

Therefore, in all the cases fv = Sv = u.

Since u f(X) T(X), there exists w X such that Tw = u. Now we shall show that gw = u. As, x2n-1 x2n fx2n = Tx2n+1 and Tx2n+1 Tw and so x2n Tw. Hence, Tw fTw and fTw w, imply x2n w. Consider

d(gw, u) d(gw, f x2n) + d(f x2n, u)

= d(f x2n, gw) + d(f x2n, u)

hM(x2n, w) + d(f x2n, u),

where

M(x2n, w) = max

Again we have four cases:

If M(x2n,w) = d(Sx2n, Tw), then d(gw, u) h d(Sx2n, Tw) + d(fx2n, u) 0 as n .

If M(x2n,w) = d(fx2n, Sx2n), then d(gw, u) h d(fx2n, Sx2n) + d(fx2n, u) 0 as n . If M(x2n,w) = d(gw, Tw), then d(gw, u) hd(gw, Tw)+d(fx2n, u) = hd(gw, u)+ d(fx2n, u). Taking limit as n we get d(gw, u) hd(gw, u) which implies that gw = u. If

M(x2n, w) = d(f x2n, Tw) + d(gw, Sx2n)

2 , then

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d(fv, Tx2n1) + d(gx2n1, Sv)

2 , then

d(fv, u) h

h2d(fv, u). Since h <1, so that fv = u.

d(Sx2n, Tw), d(f x2n, Sx2n), d(gw, Tw), d(f x2n, Tw) + d(gw, Sx2n)

2

for all n N.

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d(gw, u) h

d(f x2n, Tw) + d(gw, Sx2n)2 + d(f x2n, u)

h2[d(f x2n, u) + d(gw, Sx2n)] + d(f x2n, u).

Taking limit as n we get d(gw, u)

h2d(gw, u) which implies that gw = u. Following the arguments similar to those given above, we obtain gw = Tw = u. Thus {f, S}

and {g, T} have a unique point of coincidence in X. Now, if {f, S} and {g, T} are weakly compatible, then fu = fSv = Sfv = Su = w1 (say) and gu = gTw = Tgw = Tu = w2 (say).

Now

d(w1, w2) = d(fu, gu) hM(u, u),

where

M(u, u) = max{d(Su, Tu), d(fu, Su), d(gu, Tu),

d(fu, Tu) + d(gu, Su) 2 }

= d(w1, w2).

Therefore d(w1, w2) hd(w1, w2) gives w1 = w2. Hence

fu = gu = Su = Tu.

That is, u is a coincidence point of f, g, S,, and T. Now we shall show that u = gu. Since, v fv = u,

d(u, gu) = d(fv, gu)

hM(v, u) where

M(v, u) = max

d(Sv, Tu), d(fv, Sv), d(gw, Tu), d(fv, Tu) + d(gu, Sv)

2

= d(u, gu).

Thus, d(u, gu) hd(u, gu) implies that gu = u. In similar way, we obtain fu = u. Hence, u is a common fixed point of f, g, S, and T.

In the following result, we establish existence of a common fixed point for a pair of partially weakly increasing functions on an ordered metric space by using a control function r : R+ R+.

Theorem 3.2. Let (X, , d) be an ordered metric space. Let f and g be R-weakly commuting selfmaps on X, (g, f) be partially weakly increasing with f(X) g(X), dominating map f is weak annihilator of g. Suppose that for every two comparable elements x, y X,

d(fx, fy) r(d(gx, gy)),where r : R+ R+ is a continuous function such that r(t) <t for each t > 0. If either f or g is continuous and one of f(X) or g(X) is complete subspace of X, then f and g have a common fixed point provided that for a nondecreasing sequence {xn} with xn yn for all n and yn u implies xn u.

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Proof. Let x0 be an arbitrary point in X. Choose a point x1 in X such that

f xn = gxn+1 fgxn+1.

Since dominating map f is weak annihilator of g, so that for all n 1,

xn f xn = gxn+1 fgxn+1 xn+1.

Thus, we have xn xn+1 for all n 1. Now

d(f xn, f xn+1) r(d(gxn, gxn+1))

= r(d(f xn1, f xn))

< d(f xn1, f xn).

Thus {d(fxn, fxn+1)} is a decreasing sequence of positive real numbers and, therefore, tends to a limit L. We claim that L = 0. For if L > 0, the inequality

d(f xn, f xn+1) r(d(f xn1, f xn))

on taking limit as n and in the view of continuity of r yields L r(L) <L, a contradiction. Hence, L = 0.

For a given > 0, since r() < , there is an integer k0 such that

d(f xn, f xn+1) < r() n k0. (3:2)

For m, n N with m >n, we claim that

d(f xn, f xm) < n k0. (3:3) We prove inequality (3.3) by induction on m. Inequality (3.3) holds for m = n + 1, using inequality (3.2) and the fact that - r () <. Assume inequality (3.3) holds for m = k. For m = k + 1, we have

d(f xn, f xm) d(f xn, f xn+1) + d(f xn+1, f xm)

< r() + r(d(gxn+1, gxm))

= r() + r(d(f xn, f xm1))

= r() + r(d(f xn, f xk))

< r() + r() = .

By induction on m, we conclude that inequality (3.3) holds for all m n k0.

So {fxn} is a Cauchy sequence. Suppose that g(X) is a complete metric space. Hence {fxn} has a limit z in g(X). Also gxn z as n .

Let us suppose that the mapping f is continuous. Then ffxn fz and fgxn fz. Further, since f and g are R - weakly commuting, we have

d(fgxn, gf xn) Rd(f xn, gxn).

Taking limit as n , the above inequality yields gffxn fz. We now assert that z = fz. Otherwise, since xn fxn, so we have the inequality

d(f xn, ff xn) r(d(gxn, gf xn)).

Taking limit as n gives d(z, fz) r(d(z, fz)) < d(z, fz), a contradiction. Hence, z = fz. As f(X) g(X), there exists z1 in X such that z = fz = gz1.

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Now, since fxn ffxn and ffxn fz = gz1 and gz1 fgz1 z1 imply fxn z1. Consider,

d(ff xn, f z1) r(d(gf xn, gz1)) < d(gf xn, gz1).

Taking limit as n implies that fz = fz1. This in turn implies that

d(fz, gz) = d(fgz1, gf z1) Rd(f z1, gz1) = 0,i.e., z = fz = gz. Thus z is a common fixed point of f and g. The same conclusion is found when g is assumed to be continuous since continuity of g implies continuity of f.

4 Results in hyperbolic ordered metric spaces

In this section, existence of common fixed points of ordered Cq-commuting and ordered uniformly Cq-commuting mappings is established in hyperbolic ordered metric spaces by utilizing the notions of ordered S-contractions and ordered asymptotically S-nonexpansive mappings.

Theorem 4.1. Let Y be a nonempty closed ordered subset of a hyperbolic ordered metric space X. Let T and S be ordered R- subweakly commuting selfmaps on Y such that T(Y ) S(Y ), cl(T(Y )) is compact, q Fix(S) and S(Y ) is complete and q-star-shaped where each x in X is comparable with q. Let (T, S) be partially weakly increasing, order limit preserving and weakly compatible pair such that dominating map T is weak annihilator of S. If T is continuous, S-ordered nonexpansive and S is affine, then Fix(T) Fix(S) is nonempty provided that for a nondecreasing sequence {xn} with xn

u implies that xn u.

Proof. Define Tn : Y Y by

Tn(x) = (1 n)q nTx,for each n 1, where ln (0, 1) with lim

n

n = 1. Then Tn is a selfmap on Y for each n 1. Since S is ordered affine and T(Y ) S(Y ), therefor we obtain Tn(Y ) S

(Y ). Note that,

d(TnSx, STnx ) = d((1 n)q nTSx, (1 n)q nSTx) (1 n)d(q, q) + nd(TSx, STx)

= nd(TSx, STx)

nRd(Sx, (1 n)q nTx)

= nRd(Sx, Tnx).

This implies that the pair {Tn, S} is ordered lnR-weakly commuting for each n. Also for any two comparable elements x and y in X, we get

d(Tnx, Tny) = d((1 n)q nTx, (1 n)q nTy) nd(Tx, Ty) nd(Sx, Sy).

Now following lines of the proof of Theorem 3.2, there exists xn in Y such that xn is a common fixed point of S and Tn for each n 1. Note that

d(xn, Txn) = d(Tnxn, Txn) = d((1 n)q nTxn, Txn)

= (1 n)d(q, Txn).

Since cl(T(Y )) is compact, there exists a positive integer M such that

d(xn, Txn) (1 n)M.

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The compactness of cl(Tn(Y )) implies that there exists a subsequence {xk} of {xn} such that xk x0 Y as k . Now,

d(x0, Tx0) d(Tx0, Txk) + d(Txk, xk) + d(xk, x0)and continuity of T give that x0 Fix(T). Since, T is dominating map, therefore Sxk TSxk. As T is weak annihilator of S and T is dominating, so TSxk xk Txk. Thus Sxk Txk and order limit preserving property of (T, S) implies that Sx0 Tx0 = x0. Also x0 Sx0. Consequently, Sx0 = Tx0 = x0. Hence the result follows.

Theorem 4.2. Let Y be a nonempty closed subset of a complete hyperbolic ordered metric space X and let T and S be mappings on Y such that T(Y - {u}) S(Y - {u}), where u Fix(S). Suppose that T is an S-contraction and continuous. Let (T, S) be partially weakly increasing, dominating maps T is weak annihilator of S. If T is continuous, and S and T are R-weakly commuting mappings on Y - {u}, then Fix(T)Fix(S) is nonempty provided that for a nondecreasing sequence {xn} with xn yn for all n and yn u implies xn u.

Proof. Similar to the proof of Theorem 3.2.

Theorem 3.1 yields a common fixed point result for a pair of maps on an ordered startshaped subset Y of a hyperbolic ordered metric space as follows.

Theorem 4.3. Let Y be a nonempty closed q- starshaped subset of a complete hyperbolic ordered metric space X and let T and S be uniformly Cq- commuting selfmapps on Y - {q} such that S(Y ) = Y and T(Y - {q}) S(Y - {q}), where q Fix(S). Let (T, S) be partially weakly increasing, order limit preserving and weakly compatible pair, dominating map T is weak annihilator of S, T is continuous and asymptotically S- nonexpansive with sequence {kn}, as in Definition 2.11 (2), and S is an affine mapping. For

each n 1, define a mapping Tn on Y by Tnx = (1 - an)q anT nx, where n = n

knand

{ln} is a sequence in (0, 1) with lim

n

n = 1. Then for each n N, F (Tn) Fix(S) is nonempty provided that for a nondecreasing sequence {xn} with xn yn for all n and yn u implies xn u.

Proof. For all x, y Y, we have

d(Tn(x), Tn(y))= d((1 n)q nTnx, (1 n)q nTny)

nd(Tn(x), Tn(y)) nd(Sx, Sy).

Moreover, since T and S are uniformly Cq-commuting and S is affine on Y with Sq = q, for each x Cn(S, T ) Cq(S, T ), we have

STnx = S((1 n)q nTnx) = (1 n)q nSTnx

= (1 n)q nTnSx = TnSx.

Thus S and Tn are weakly compatible for all n. Now, the result follows from Theorem 3.1.

The above theorem leads to the following result.

Theorem 4.4. Let Y be a nonempty closed q- starshaped subset of a hyperbolic ordered metric space X and let T and S be selmaps on Y such that S(Y ) = Y and T(Y -{q}) S(Y - {q}), q Fix(S). Let (T, S) be partially weakly increasing, order limit preserving, T is continuous, uniformly asymptotically regular, asymptotically S-nonexpansive

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and S is an affine mapping. If cl(Y - {q}) is compact and S and T are uniformly Cq-commuting selfmaps on Y - {q}, then Fix(T) Fix(S) is nonempty provided that for a nondecreasing sequence {xn} with xn yn for all n and yn u implies xn u.

Proof. By Theorem 4.3, for each n N, F(Tn) Fix(S) is singleton in Y. Thus,

Sxn = xn = (1 n)q nTnxn.

Also,

d(xn, Tnxn) = d((1 n)q nTnxn, Tnxn)

= (1 n)d(q, Tnxn).

Since T(Y - {q}) is bounded so d(xn, T nxn) 0 as n . Note that,

d(xn, Txn)

d(xn, Tnxn) + d(Tnxn, Tn+1xn) + d(Tn+1xn, Txn) d(xn, Tnxn) + d(Tnxn, Tn+1xn) + kld(STnxn, Sxn) d(xn, Tnxn) + d(Tnxn, Tn+1xn) + kld(STnxn, S((1 n)q nTnxn)) d(xn, Tnxn) + d(Tnxn, Tn+1xn) + kld(STnxn, (1 n)q nSTnxn) d(xn, Tnxn) + d(Tnxn, Tn+1xn) + k1(1 n)d(STnxn, Sq) d(xn, Tnxn) + d(Tnxn, Tn+1xn) + k1(1 n)d(STnxn, Sq).

Consequently, d(xn, Txn) 0, when n . Since cl(Y - {q}) is compact and Y is closed, therefore there exists a subsequence {xni} of {xn} such that xni x0 Y as i . By the

continuity of T , we have T(x0) = x0. Since, T is dominating map, therefore Sxk TSxk. As T is weak annihilator of S and T is dominating, so TSxk xk Txk. Thus, Sxk Txk and order limit preserving property of (T, S) implies that Sx0 Tx0 = x0. Also x0 Sx0. Consequently, Sx0 = Tx0 = x0. Hence, the result follows.

As another application of Theorem 3.1, we obtain yet an other result for two maps satisfying a very general contractive condition on the set Y.

Theorem 4.5. Let Y be a nonempty q-starshaped complete subset of a hyperbolic ordered metric space and T, f, and g be selfmaps on Y . Suppose that T is continuous, cl(T(Y )) is compact and f and g are affine and continuous and T(Y ) f(Y ) g(Y ). Let (T, f) and (T, g) be partially weakly increasing, and dominating maps f and g be weak annihilators of T. If the pairs {T, f} and {T, g} are Cq-commuting and satisfy for all x, y Y,

d(Tx, Ty) max{d(fx, gy), d(fx, YTq), d(gy, YTq),

1

2[d(fx, YTq) + d(gy, YTq)]},

(4:1)

then T, f, and g have a common fixed point provided that for a nondecreasing sequence {xn} with xn yn for all n and yn u implies xn u.

Proof. Define Tn : Y Y by

Tn(x) = (1 n)q nTx, where ln (0, 1) with lim

n

n = 1. Then Tn is a selfmap on Y for each n 1. Since f and g are affine and T(Y ) f(Y ) g(Y ), therefore we obtain Tn(Y ) f (Y ) g(Y ).

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Now f and T are Cq-commuting and f is affine on Y with fq = q, for each x Cn(f, T ) Cq(f, T ), so we have

f Tnx = f ((1 n)q nTx) = (1 n)q nfTx

= (1 n)q nTfx = Tnfx.

Thus, f and Tn are weakly compatible for all n. Also since g and T are Cq-commuting and g is affine on Y with gq = q, therefore, g and Tn are weakly compatible for all n. Moreover using (4.1) we have

d(Tnx, Tny) nd(Tx, Ty)

n max{d(fx, gy), d(fx, YT(x)q),d(gy, YT(y)q), 12[d(fx, YT(y)q) + d(gy, YT(x)q)]

n max{d(fx, gy), d(fx, Tnx),d(gy, Tny), 12[d(fx, Tny) + d(gy, Tnx)]}.

By Theorem 3.1, for each n 1, there exists xn in Y such that xn is a common fixed point of f, g and Tn. The compactness of cl(T (Y )) implies that there exists a subsequence {Txk} of {Txn} such that Txk y as k . Now, the definition of Tkxk gives that xk y and the result follows using continuity of T, f, and g.

5 Invariant approximation

In this section, we obtain results on best approximation as a fixed point of R-sub-weakly and uniformly R-subweakly commuting mappings in the setting of hyperbolic ordered metric spaces. In particular, as an application of Theorem 4.4 (respectively Theorem 4.5), we demonstrate the existence of common fixed point for one pair (respectively two pairs) of maps from the set of best approximation.

Theorem 5.1. Let M be a nonempty subset of a hyperbolic ordered metric space X, T, and S be continuous selfmaps on X such that T(M M) M, M stands for boundary of M, and u Fix(S) Fix(T) for some u in X, where u is comparable with all x X. Let (T, S) be partially weakly increasing, order limit preserving, T is uniformly asymptotically regular, asymptotically S-nonexpansive and S is affine on PM (u) with S(PM (u)) = PM (u), q Fix(S), and PM (u) is q-starshaped. If cl(PM (u))

is compact, PM (u) is complete and S and T are uniformly Cq-commuting mappings on PM (u) {u} satisfying d(Tx, Tu) d(Sx, Su), then PM (u) Fix(T ) Fix(S) j provided that for a nondecreasing sequence {xn} with xn yn for all n and yn u implies xn u.

Proof. Let x PM (u). Then d(x, u) = d(u, M ). Note that for any l (0, 1),

d(y, u) = d((1 )u x, u)

= d(x, u) < d(x, u) = d(u, M).

This shows that YI = {y : y = (1 )u x} M = . So x M M which

further implies that Tx M. Since Sx PM (u), u is a common fixed point of S and T, therefore by the given contractive condition, we obtain

d(Tx, u) = d(Tx, Tu )

d(Sx, Su) = d(Sx, u) = d(u, M).

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Thus, PM (u) is T -invariant. Hence,

T(PM(u)) PM(u) = S(PM(u)).

Now the result follows from Theorem 4.4.

Theorem 5.2. Let M be a nonempty subset of a hyperbolic ordered metric space X, T, f, and g be selfmaps on X such that u is common fixed point of f, g, and T and T (M M) M. Suppose that f and g are continuous and affine on PM (u), q Fix(f )

Fix(g), and PM (u) is q-starshaped with f(PM (u)) = PM (u) = g(PM (u)). Let (T, f ) and (T, g) be partially weakly increasing, and dominating maps f and g be weak annihilator of T. Assume that the pairs {T, f} and {T, g} are Cq-commuting and satisfy for all x

PM (u) {u}

d(Tx, Ty)

d(fx, gu), if y = u max{d(fx, gy), d(fx, YTq), d(gy, YTq),

1

2 [d(fx, YTq) + d(gy, YTq)]}, if y PM(u).

If cl(PM (u)) is compact and PM (u) is complete, then PM (u)Fix(T )Fix(f ) Fix(g) j provided that for a nondecreasing sequence {xn} with xn yn for all n and yn u implies xn u.

Proof. Let x PM (u). Then d(x, u) = d(u, M ). Note that for any l (0, 1)

d(y, u) = d((1 )u x, u)

= d(x, u) < d(x, u) = d(u, M),

which shows that M and Yx = {y : y = (1 )u x} are disjoint. So x M M

which further implies that Tx M. Since fx PM (u), u is a common fixed point of f, g, and T, therefore by the given contractive condition, we obtain

d(Tx, u) = d(Tx, Tu )

d(fx, gu) = d(fx, u) = d(u, M).

Thus PM (u) is T -invariant. Hence,

T(PM(u)) PM(u) = f (PM(u)) = g(PM(u)).

The result follows from Theorem 4.5.

Remark 5.3.

(a) Theorem 3.2 extends and improves Theorem 2.2 of Al-Thagafi [8] and Theorem2.2(i) of Hussain and Jungck [25] in the setup of hyperbolic ordered metric spaces.(b) Theorems 4.4 and 4.5 extend the results in [23] to more general classes of mappings defined on a hyperbolic ordered metric space.(c) Theorems 5.1 and 5.2 set analogues of Theorems 2.11(i) and 2.12(i) in [25], respectively.

Acknowledgements

The second and third authors are grateful to King Fahd University of Petroleum and Minerals and SABIC for supporting research project SB100012.

Author details

1Department of Mathematics, Lahore University of Management Sciences, 54792- Lahore, Pakistan 2Department of Mathematical Sciences, The University of Texas at El Paso, El Paso, TX 79968, USA 3Department of Mathematics and Statistics, King Fahd University of Petroleum and Minerals, Dhahran 31261, Saudi Arabia

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Authors contributions

The authors have contributed in this work on an equal basis. All authors have read and approved the final manuscript.

Competing interests

The authors declare that they have no competing interests.

Received: 30 January 2011 Accepted: 4 August 2011 Published: 4 August 2011

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doi:10.1186/1687-1812-2011-25Cite this article as: Abbas et al.: Common fixed point and invariant approximation in hyperbolic ordered metric spaces. Fixed Point Theory and Applications 2011 2011:25.

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