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Fixed point results of pointwise contractions in modular metric spaces
Fixed Point Theory and Applications volume 2013, Article number: 163 (2013)
Abstract
The notion of a modular metric on an arbitrary set and the corresponding modular spaces, generalizing classical modulars over linear spaces like Orlicz spaces, were recently introduced. In this paper we investigate the existence of fixed points of modular contractive mappings in modular metric spaces. These are related to the successive approximations of fixed points (via orbits) which converge to the fixed points in the modular sense, which is weaker than the metric convergence.
MSC: 47H09, 46B20, 47H10, 47E10.
1 Introduction
The purpose of this paper is to give an outline of a fixed point theory for Lipschitzian mappings defined on some subsets of modular metric spaces which are natural generalizations of both function and sequence variants of many important, from applications perspective, spaces like Lebesgue, Orlicz, Musielak-Orlicz, Lorentz, Orlicz-Lorentz, Calderon-Lozanovskii spaces and many others. Modular metric spaces were introduced in [1, 2]. The main idea behind this new concept is the physical interpretation of the modular. Informally speaking, whereas a metric on a set represents nonnegative finite distances between any two points of the set, a modular on a set attributes a nonnegative (possibly, infinite valued) ‘field of (generalized) velocities’: to each ‘time’ (the absolute value of) an average velocity is associated in such a way that in order to cover the - ‘distance’ between points , it takes time λ to move from x to y with velocity . But the way we approached the concept of modular metric spaces is different. Indeed, we look at these spaces as the nonlinear version of the classical modular spaces as introduced by Nakano [3] on vector spaces and modular function spaces introduced by Musielack [4] and Orlicz [5].
In recent years, there was an uptake of interest in the study of electrorheological fluids, sometimes referred to as ‘smart fluids’ (for instance, lithium polymetachrylate). For these fluids, modeling with sufficient accuracy using classical Lebesgue and Sobolev spaces, and , where p is a fixed constant, is not adequate, but rather the exponent p should be able to vary [6, 7]. One of the most interesting problems in this setting is the famous Dirichlet energy problem [8, 9]. The classical technique used so far in studying this problem is to convert the energy functional, naturally defined by a modular, to a convoluted and complicated problem which involves a norm (the Luxemburg norm). The modular metric approach is more natural and has not been used extensively.
The fixed point property in modular function spaces was initiated after the publication of the paper [10] in 1990. More recently, the authors presented a series of fixed point results for pointwise contractions and asymptotic pointwise contractions acting in modular functions spaces [11, 12]. In this paper, we define and investigate the fixed point property in the framework of modular metric spaces. It seems that a timid start has been going on for a few years now but it still lacks some generalities. The importance of applications of fixed points of mappings in modular metric spaces follows the success of such applications in modular function spaces because of the richness of structure of modular function spaces that - besides being Banach spaces (or F-spaces in a more general settings) - are equipped with modular equivalents of norm or metric notions, and also are equipped with almost everywhere convergence and convergence in submeasure. In many cases, particularly in applications to integral operators, approximation and fixed point results, modular type conditions are much more natural as modular-type assumptions can be more easily verified than their metric or norm counterparts. From this perspective, the fixed point theory in modular metric spaces should be considered as complementary to the fixed point theory in modular function spaces and in metric spaces. The theory of contractions and nonexpansive mappings defined on convex subsets of Banach spaces has been well developed since the 1960s (see, e.g., Belluce and Kirk [13, 14], Browder [15], Bruck [16], DeMarr [17], and Lim [18]) and generalized to other metric spaces (see, e.g., [19–21]) and modular function spaces (see, e.g., [10]). The corresponding fixed point results were then extended to larger classes of mappings like pointwise contractions [22, 23] and asymptotic pointwise contractions and nonexpansive mappings [24, 25].
For more on metric fixed point theory, the reader may consult the book [26] and for modular metric spaces [27].
2 Basic definitions and properties
Let X be a nonempty set. Throughout this paper, for a function , we write
for all and .
Definition 2.1 [1, 2] A function is said to be modular metric on X if it satisfies the following axioms:
-
(i)
if and only if for all ;
-
(ii)
for all and ;
-
(iii)
for all and .
If instead of (i) we have only the condition (i′)
then w is said to be a pseudomodular (metric) on X. A modular metric w on X is said to be regular if the following weaker version of (i) is satisfied:
Finally, w is said to be convex if, for and , it satisfies the inequality
Note that for a metric pseudomodular w on a set X, and any , the function is nonincreasing on . Indeed, if , then
Let w be a pseudomodular on X. Fix . The two sets
and
are said to be modular spaces (around ).
It is clear that , but this inclusion may be proper in general. It follows from [1, 2] that if w is a modular on X, then the modular space can be equipped with a (nontrivial) metric, generated by w and given by
for any . If w is a convex modular on X, according to [1, 2], the two modular spaces coincide, , and this common set can be endowed with the metric given by
for any . These distances will be called Luxemburg distances (see example below for the justification).
Next we give the main example that motivated this paper.
Example 2.1 Let Ω be a nonempty set and Σ be a nontrivial σ-algebra of subsets of Ω. Let be a δ-ring of subsets of Ω such that for any and . Let us assume that there exists an increasing sequence of sets such that . By ℰ we denote the linear space of all simple functions with supports from . By we denote the space of all extended measurable functions, i.e., all functions such that there exists a sequence , and for all . By we denote the characteristic function of the set A. Let be a nontrivial, convex and even function. We say that ρ is a regular convex function pseudomodular if:
-
(i)
;
-
(ii)
ρ is monotone, i.e., for all implies , where ;
-
(iii)
ρ is orthogonally subadditive, i.e., for any such that , ;
-
(iv)
ρ has the Fatou property, i.e., for all implies , where ;
-
(v)
ρ is order continuous in ℰ, i.e., and implies .
Similarly, as in the case of measure spaces, we say that a set is ρ-null if for every . We say that a property holds ρ-almost everywhere if the exceptional set is ρ-null. As usual, we identify any pair of measurable sets whose symmetric difference is ρ-null as well as any pair of measurable functions differing only on a ρ-null set. With this in mind, we define
where each is actually an equivalence class of functions equal ρ-a.e. rather than an individual function. Where no confusion exists, we write ℳ instead of . Let ρ be a regular function pseudomodular.
-
(a)
We say that ρ is a regular function semimodular if for every implies ρ-a.e.;
-
(b)
We say that ρ is a regular function modular if implies ρ-a.e.
The class of all nonzero regular convex function modulars defined on Ω is denoted by ℜ. Let us denote for , . It is easy to prove that is a function pseudomodular in the sense of Def. 2.1.1 in [27] (more precisely, it is a function pseudomodular with the Fatou property). Therefore, we can use all results of the standard theory of modular function space as per the framework defined by Kozlowski in [27–29]; see also Musielak [4] for the basics of the general modular theory. Let ρ be a convex function modular.
(a) The associated modular function space is the vector space , or briefly , defined by
(b) The following formula defines a norm in (frequently called the Luxemburg norm):
A modular function space furnishes a wonderful example of a modular metric space. Indeed, let be a modular function space. Define the function w by
for all and . Then w is a modular metric on . Note that w is convex if and only if ρ is convex. Moreover, we have
for any .
Other easy examples may be found in [1, 2].
Definition 2.3 Let be a modular metric space.
-
(1)
The sequence in is said to be w-convergent to if and only if as for some .
-
(2)
The sequence in is said to be w-Cauchy if as for some .
-
(3)
A subset C of is said to be w-closed if the limit of a w-convergent sequence of C always belongs to C.
-
(4)
A subset C of is said to be w-complete if any w-Cauchy sequence in C is a convergent sequence and its limit is in C.
-
(5)
A subset C of is said to be w-bounded if for some , we have
In general if for some , then we may not have for all . Therefore, as it is done in modular function spaces, we say that w satisfies -condition if this is the case, i.e., for some implies for all . In [1] and [2], one can find a discussion about the connection between w-convergence and metric convergence with respect to the Luxemburg distances. In particular, we have
for any and . And, in particular, we have w-convergence and convergence are equivalent if and only if the modular w satisfies the -condition. Moreover, if the modular w is convex, then we know that and are equivalent, which implies
for any and [1, 2]. Another question that arises in this setting is the uniqueness of w-limit. Assume that w is regular, then we have the uniqueness of w-limit. Indeed, let be a sequence such that w-converges to and . Then we have
for any . Our assumptions imply . Since w is regular, we must have as claimed.
Let us finish this section with the modular metric definitions of Lipschitzian mappings. The definitions are straightforward generalizations of their norm and metric equivalents [10].
Definition 2.4 Let be a modular metric space. Let C be a nonempty subset of . A mapping is called a Lipschitzian mapping if there exists a constant such that
The smallest such constant k is known as . A point is called a fixed point of T whenever . The set of fixed points of T is denoted by .
In the next definition, we introduce the concept of pointwise contraction mappings in this setting.
Definition 2.5 Let be a modular metric space. Let C be a nonempty subset of . A mapping is called
-
(i)
a contraction mapping if there exists a constant such that
-
(ii)
a pointwise contraction mapping if there exists a function such that
In [1, 2] the author defined Lipschitzian mappings in modular metric spaces and proved some fixed point theorems. Our definition is more general. Indeed, in the case of modular function spaces, it is proved in [10] that
if and only if
Moreover, an example is given to show that
but T is not Lipschitzian with respect to with constant 1.
3 Banach contraction principle in modular metric spaces
The statement of Banach contraction principle in modular metric spaces is as follows.
Theorem 3.1 Let be a modular metric space. Assume that w is regular. Let C be a nonempty subset of . Assume that C is w-complete and w-bounded, i.e., . Let be a contraction. Then T has a unique fixed point . Moreover, the orbit w-converges to for each .
Proof Since T is a contraction, therefore there exists such that
First note that T has at most one fixed point. Indeed, let be two fixed points of T. Then we have
Our assumption on C implies . This forces , which implies because w is regular. Next we fix . Then we have
for any and . This clearly implies that is w-Cauchy. Since C is w-complete, therefore w-converges to some point . Next let us show that is a fixed point of T. Indeed, we have
which implies
for any . Since w-converges to , therefore we get , i.e., . Since T has at most one fixed point, we conclude that any orbit of T w-converges to the only fixed point of T. □
Remark 3.1 In the classical Banach contraction principle, the metric space is not supposed to be bounded. In fact the contractive condition of the mapping implies that any orbit is bounded. In the case of a modular metric space, due to the failure of the triangle inequality, it is not true that the contractive condition of the mapping implies the boundedness of the orbit. Note that if T has a fixed point, then it is obvious that an orbit of T is bounded. Conversely, if T has a bounded orbit for some , then we have
for any and . This clearly implies that is w-Cauchy. Since C is w-complete, then is w-convergent to some . Since
we conclude that w-converges to . Since w is regular, we must have , i.e., is the only fixed point of T. Next, for any such that , we have
for any . Hence the orbit w-converges to as well. In this remark, we show how one has to be careful when dealing with modulars. Indeed, a modular may take infinite value. This is the problem that the authors of [30] did not pay attention to. This was also pointed out in the short note [31]. In fact, the authors of [30] did try to fix this problem in another short note [32] but they used the triangle inequality in their proof knowing that w does not in general satisfy the triangle inequality. Therefore our Theorem 3.1 properly establishes the classical Banach contraction principle in the best possible way in modular metric spaces and improves a number of earlier known results in this setting.
4 Pointwise contraction mappings in modular metric spaces
Pointwise contractive behavior was introduced in [22] to extend the contractive behavior in the Banach contraction principle. The central fixed point result in the metric setting for such mappings is the following theorem.
Let K be a weakly compact convex subset of a Banach space and suppose that is a pointwise contraction. Then T has a unique fixed point . Moreover, the orbit converges to for each .
The main focus of this paper is on the fixed point problem, so we would like to make some observations here. It is easy to prove that a pointwise contraction has a fixed point in the same way as in the case of contractions. Indeed, let a be a fixed point of T. Then the orbit w-converges to a for each such that . Indeed, we have
for any . Since , we conclude that w-converges to a. Moreover, if b is another fixed point of T, then from , we must have . But it is not clear how to prove the existence of the fixed point from the convergence of the orbits, which is the case in the classical proof of the Banach contraction principle. In this case, we have to use a different technique than the one used in Theorem 3.1.
Let be a modular metric space. In the rest of this work, we assume that w satisfies the Fatou property, i.e., if w-converges to x and w-converges to y, then we must have
For any and , we define the modular ball
Note that if w satisfies the Fatou property, then modular balls are w-closed. An admissible subset of is defined as an intersection of modular balls. Denote by the family of admissible subsets of . Note that is stable under intersection. At this point we introduce some notation which will be used in the remainder of this work. For a subset A of a modular metric space , set
Recall that A is w-bounded if .
Definition 4.1 Let be a modular metric space. We say that is compact if any family of elements of has a nonempty intersection provided for any finite subset .
Remark 4.1 Note that if is compact, then is w-complete. Indeed, let be a w-Cauchy sequence. Set
for any . Since is a w-Cauchy sequence, then . By the definition of , we get for any and . Hence, for any , we have
for any . Since is compact, then
If , then we have for any . Hence w-converges to z, which completes the proof of our statement.
The main result in [22, 23] may be stated in modular metric spaces as follows.
Theorem 4.2 Let be a modular metric space. Let C be a nonempty w-closed w-bounded subset of . Assume that the family is compact. Let be a pointwise contraction. Then T has a unique fixed point . Moreover, the orbit w-converges to for each .
Proof Since is compact, therefore there exists a minimal nonempty such that . It is easy to check that . Let us prove that , i.e., K is reduced to one point. Indeed, since C is w-bounded, then , i.e., K is also w-bounded. As T is a pointwise contraction, so there exists a mapping such that
For any , set . We have for any . Moreover, it is easy to check that for any , which implies . So, for any . Next we fix and define
Clearly, is not empty since . Moreover, we have
And since for any , we get . The minimality behavior of K implies . In particular, we have for any . Hence for any . Hence . And since , we get , i.e., K is reduced to one point which is fixed by T. Hence the fixed point set of T is not empty. The remaining conclusion of the theorem follows from the general properties of pointwise contractions. □
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Abdou, A.A., Khamsi, M.A. Fixed point results of pointwise contractions in modular metric spaces. Fixed Point Theory Appl 2013, 163 (2013). https://doi.org/10.1186/1687-1812-2013-163
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DOI: https://doi.org/10.1186/1687-1812-2013-163