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Article

On Relational Weak Fm,η-Contractive Mappings and Their Applications

1
Department of Mathematics and Statistics, International Islamic University, Islamabad 44000, Pakistan
2
Department of Mathematics, Taiz University, Taiz 6803, Yemen
3
Department of Mathematics and Sciences, Prince Sultan University, P.O. Box 66833, Riyadh 11586, Saudi Arabia
4
School of Computer, Data and Mathematical Sciences, Western Sydney University, Sydney 2150, Australia
*
Author to whom correspondence should be addressed.
Symmetry 2023, 15(4), 922; https://doi.org/10.3390/sym15040922
Submission received: 17 March 2023 / Revised: 9 April 2023 / Accepted: 11 April 2023 / Published: 15 April 2023
(This article belongs to the Special Issue Symmetry in Fixed Point Theory and Applications)

Abstract

:
In this article, we introduce the concept of weak F m , η -contractions on relation-theoretic m-metric spaces and establish related fixed point theorems, where η is a control function and is a relation. Then, we detail some fixed point results for cyclic-type weak F m , η -contraction mappings. Finally, we demonstrate some illustrative examples and discuss upper and lower solutions of Volterra-type integral equations of the form ξ α = 0 α A α , σ , ξ σ m σ + Ψ α , α 0 , 1 .

1. Introduction and Preliminaries

The classical Banach contraction theorem [1] is an important and fruitful tool in nonlinear analysis. In the past few decades, many authors have extended and generalized the Banach contraction mapping principle in several ways (see [2,3,4,5,6,7,8,9,10,11,12]). On the other hand, several authors, such as Boyd and Wong [13], Browder [14], Wardowski [15], Jleli and Samet [16], and many other researchers have extended the Banach contraction principle by employing different types of control functions (see [17,18,19,20,21] and the references therein). Alam et al. [22] introduced the concept of the relation-theoretic contraction principle and proved some well known fixed-point results in this area. Afterward, many researchers focused on fixed-point theorems in relation-theoretic metric spaces. Here, we will present some basic knowledge of relation-theoretic metric spaces (see more detail in [23,24,25,26]). Furthermore, Sawangsup et al. [27] introduced the concept of the F , γ -contractive of mappings to extend F-contractions in metric spaces endowed with binary relations. One of the latest extensions of metric spaces and partial metric spaces [10] was given in paper [28], which completed the concept of m-metric spaces. Using this concept, several researchers have proven some fixed point results in this area (see [20,29,30,31,32,33]). Subsequently, since every F-contraction mapping is contractive and also continuous, Secelean et al. [34] proved that the continuity of an F-contraction can be obtained from condition F 2 . After that, Imdad et al. [35] introduced the idea of a new type of F-contraction by dropping the condition of F 1 and replacing condition F 3 with the continuity of F. They also proved some new fixed point results in relation to theoretic metric spaces.
In this paper, we introduce weak F m , η -contractive mappings and cyclic-type weak F m , η -contractions and provide some new fixed point theorems for such mappings in relation to theoretic m-metric spaces. Finally, as an application, we discuss the lower and upper solutions of Volterra-type integral equations.
Throughout this article, N indicates a set of all natural numbers, R indicates a set of real numbers and R +  indicates a set of positive real numbers. We also denote N 0 = N 0 . Henceforth, U will denote a non-empty set and the self mapping γ : U U with a Picard sequence based on an arbitrary ξ 0 in U is given by ξ n = γ ξ n 1 = γ n ξ 0 , where all n are members of N and γ n denotes the n t h -iteration of γ .
The notion of m-metric spaces was introduced by Asadi et al. [28] as a real generalization of a partial metric space and they supported their claim by providing some constructive examples. For more detail, see, e.g., [29,31].
Definition 1 
([28]). An m-metric space on a non-empty set U is a mapping m : U × U R + such that for all ξ , , U ,
(i)
ξ = m ξ , ξ = m , = m ξ , T 0 -separation axiom ;
(ii)
m ξ m ( ξ , ) minimum self distance axiom ;
(iii)
m ξ , = m , ξ symmetry ;
(iv)
m ξ , m ξ ( m ξ , m ξ ) + ( m , m ) modified triangle inequality
where
m ξ = min m ( ξ , ξ ) , m ( , ) ; M ξ = max m ( ξ , ξ ) , m ( , ) .
The pair U , m is called an m-metric space on nonempty U .
Lemma 1 
([28]). Each partial metric forms an m-metric space but the converse is not true.
Among the classical examples of an m-metric space is a pair U , m , where U = ξ , , and m is a self mapping on U given by m ξ , ξ = 1 , m , = 9 and m , = 5 . It is clear that m is an m-metric space. Note that m does not form a partial metric space.
Every m-metric space m on U generates a T 0 topology, e.g., τ m , on U which is based on a collection of m-open balls:
B m ξ , ϵ : ξ U , ϵ > 0 ,
where
B m ξ , ϵ = { U : m ξ , < m ξ + ϵ } for all ξ U , ε > 0 .
If m is an m-metric space on U , then the functions m w and m s : U × U R + given by
m w ξ , = m ξ , 2 m ξ + M ξ ,
m s = m ξ , m ξ , if ξ 0 , if ξ = . ,
define ordinary metrics on U. It is easy to see that m w and m s are equivalent metrics on U .
Definition 2 
([28]). Let { ξ n } be a sequence in an m-metric space U , m , then
(i)
{ ξ n } is said to be convergent with respect to τ m to ξ if and only if
lim μ m ξ n , ξ m ξ n ξ = 0 . for all n N .
(ii)
If lim n , m m ξ n , ξ m m ξ n ξ m and lim n , m M ξ n , ξ m m ξ n ξ m for all n , m N exists and is finite, then the sequence { ξ n } in a m-metric space U , m is m-Cauchy.
(iii)
If every m-Cauchy ξ n in U is m-convergent with respect to τ m to ξ in U such that
lim n m ξ n , ξ m ξ n ξ = 0 , and lim n M ξ n , ξ m ξ n ξ = 0 . for all n N ,
then U , m is said to be complete.
(iv)
{ ξ n } is an m-Cauchy sequence if and only if it is a Cauchy sequence in the metric space U , m w ,
(v)
U , m is M-complete if and only if U , m w is complete.
Denote F by the collection of all mappings F : 0 , R satisfying [15]:
  • (F1 F ξ < F for all ξ < ;
  • (F2) For each sequence ξ n of positive numbers
    lim n ξ n = 0 if lim n F ξ n = ;
  • (F3) There exists p 0 , 1 such that lim n 0 + ξ p F ξ = 0 .
As in [27], we denote ρ  and π (where ρ and π are two new control functions) by the collection of all mappings F : 0 , R , η : 0 , R , respectively, satisfying:
  • (F2) For each sequence ξ n of positive numbers, lim n ξ n = 0 if lim n F ξ n = ;
  • (F3F is lower semicontinuous;
  • (η1) For each sequence ξ n of positive numbers, lim n ξ n = 0 if lim n η ξ n = ;
  • (η2 η is right upper semicontinuous.
Now, we present some extensive examples of control functions in ρ and η .
Example 1. 
The following functions belong to ρ and π
( 1 ) F 1 ξ = 1 ξ , if ξ 3 , 1 ξ + 1 , if ξ 3 , ( 2 ) F 2 ξ = 1 ξ + ξ , if ξ 2.8 , 2 ξ 3 , if ξ 3 , ( 3 ) η 1 ϖ = 1 ξ , if ξ 0 , 4.6 cos ξ , if ξ 4.6 , ( 4 ) η 2 s = ln ξ 3 + sin ξ , if ξ 0 , 3.2 sin ξ , if ξ 3.2 , .
Let = ξ , U 2 : ξ , U be a relation on U . If ξ , then we say that ξ   ξ precede under denoted by ξ , and the inverse of is denoted by 1 = ξ , U 2 : , ξ . The set S = 1 U 2 consequently illustrates another relation S * on U given by ξ S * S ξ with ξ .
As γ F i x denotes a set of all fixed points of γ , Θ Ψ , S = ξ U : ξ S γ ξ and ϝ ξ , , denotes the fashion of all paths in ∇ from ξ to .
Definition 3 
([22]). Let U  ϕ and γ : U U , and ℜ is a binary relation on U. Then, ℜ is γ-closed if for any Ω , U ,
ξ γ ξ γ .
Definition 4 
([22]). Let U ϕ and ℜ be a binary relation on U. Then, ℜ is transitive if ξ and for all ξ , , U .
Definition 5 
([22]). Let ξ , U . A path of length  n N in ℜ: ξ is a finite sequence t 0 , t 1 , t 2 , , t n U such that
(i)
t 0 = ξ and t n = ;
(ii)
t j , t j + 1 for all j in this set 0 , 1 , 2 , , n 1 .
Consider that a class of all paths from ξ to ℑ in ℜ is written as ξ , , . Note that a path of length n involves n + 1 elements of U, although they are not necessarily distinct.
Definition 6 
([36]). Let U , m be a relation theoratic m-metric space endowed with binary relation ℜ on U, which is regular if for each sequences ξ n in U, we have
ξ n ξ n + 1 for all n N lim n m ξ n , ξ m ξ n ξ = 0 i.e. , ξ n t m ξ ξ n ξ for all n N .
Definition 7 
([36]). Let U , m be a relation theoratic m-metric space endowed with binary relation ℜ on U. A sequence ξ n U is called ℜ-preserving if ξ n ξ n + 1 .
Definition 8 
([36]). Let U , m be a relation theoratic m-metric space endowed with binary relation ℜ on U, which is said to be ℜ-complete if for each ℜ-preserving m-Cauchy sequence ξ n in U, there exists some ξ in U such that
lim n m ξ n , ξ m ξ n ξ = 0 , and lim n M ξ n , ξ m ξ n ξ = 0 .
Definition 9 
([36]). Let U  ϕ and γ : U U . Then, γ is said to be ℜ-continuous at ξ if, for ℜ-preserving sequence ξ n with ξ n →ξ, we have γ ξ n γ ξ as μ . γ is ℜ-continuous if it is ℜ-continuous at each point of U .

2. Weak F m , η -Contractions

In this section, we introduce the concept of weak F m , η -contraction relations and establish related fixed point theorems in relation theoretic m-metric space, where η is a control function and is a relation. We begin with the following Lemma.
Lemma 2. 
Assume that U , m is an m-metric space and let ξ n be a sequence in U such that lim n m ξ n , ξ n + 1 = 0 . If ξ n is not an m-Cauchy sequence in U, then there exists ε > 0 and two subsequences ξ α χ and ξ β χ of positive integers such that α χ > β χ > χ and the following sequences converges to ε + as χ  converges to + . With M * ξ , = m ξ , m ξ ;
M * ξ α χ , ξ β χ , M * ξ α χ , ξ β χ + 1 , M * ξ α χ 1 , ξ β χ , M * ξ β χ + 1 ξ β χ 1 , M * ξ β χ + 1 , ξ β χ + 1 .
Proof. 
If ξ n is not an m-Cauchy sequence in U, there exists ε > 0 and two sequences α χ and β χ of positive integers such that α χ > β χ > χ and
M * ξ α χ , ξ β χ 1 < ε , M * ξ α χ , ξ β χ ε ,
for all positive integers χ . Using the triangle inequality of m-metric space, we obtain
ε M * ξ α χ , ξ β χ M * ξ α χ , ξ β χ + M * ξ α χ 1 , ξ β χ < M * ξ α χ , ξ β χ + ε .
Thus,
lim χ M * ξ α χ , ξ β χ = ε ,
which implies
lim χ m ξ α χ , ξ β χ m ξ α χ , ξ β χ = ε .
Furthermore,
lim χ m ξ α χ , ξ β χ = 0 .
Hence,
lim χ m ξ α χ , ξ β χ = ε .
Again, using the triangle inequality,
M * ξ α χ , ξ β χ M * ξ α χ , ξ β χ + 1 + M * ξ α χ + 1 , ξ β χ + 1 + M * ξ α χ + 1 , ξ β χ ,
and
M * ξ α χ + 1 , ξ β χ + 1 M * ξ α χ , ξ β χ + 1 + M * ξ α χ , ξ β χ + M * ξ α χ + 1 , ξ β χ .
Taking χ + in the above inequality and from (3), we have
lim χ M * ξ α χ + 1 , ξ β χ + 1 = ε .
Now, we introduce the concept of weak F m , η -contractions.
Definition 10. 
Given a relation theoretic m-metric space U , m endowed with binary relation ℜ on U . Suppose
Ξ = ξ S * : m ξ , > 0 .
We can say that a self mapping γ : U U is a weak F m , η -contraction if there exists F m ρ , η π and
τ + F m m γ ξ , γ η m ξ , ,
for all ξ , Ξ .
Our main result is demonstrated in the following.
Theorem 1. 
Let U , m be a complete relation theoretic m-metric space endowed with transitive binary relation ℜ on U, γ : U U , satisfying the following conditions:
(i)
Θ γ , is non-empty;
(ii)
ℜ is γ-closed;
(iii)
γ is ℜ-continuous;
(iv)
γ is a weak F m , η -contraction mapping with F m ξ > η ξ for all ξ > 0 .
Then, γ possesses a fixed point in U.
Proof. 
Let ξ 0 Θ γ , . Define a sequence ξ n + 1 in U by ξ n + 1 = γ ξ n = γ n + 1 ξ 0 for each n N . If there exists a member n 0 of N such that γ ξ n 0 = ξ n 0 , then γ has a fixed point ξ n 0 and the proof is complete. Let
ξ n + 1 ξ n ,
for all member n of N such that m ξ n + 1 , ξ n > 0 . Since γ Ω 0 S * Ω 0 , and by the γ -closedness of , Ω n + 1 S * Ω n for all n N . Thus, ξ n , ξ n + 1 Ξ and from ( i v ) we obtain
F m m ξ n + 1 , ξ n = F m m γ ξ n , γ ξ n 1 F m m ξ n , ξ n 1 τ
Let δ n = m ξ n , ξ n + 1 for all n N . Then, δ μ > 0 for all n N , and using (5), one obtains
F m δ n δ n 1 τ < F m δ n 1 τ η δ n 2 2 τ η δ n 2 n τ .
From the above inequality, we obtain lim n F m δ n = . Then, by F 2 , we have
lim n δ n = 0 .
From (3) and (6), we have ξ n + 1 ξ n for all n , m N with n m . Now, we shall prove that ξ n is am m-Cauchy sequence in U , m . Assume, in contrast, that ξ n is not an m-Cauchy sequence. By Lemmas 2.1 and 2.6, there exists ε > 0 and two subsequences ξ α χ and ξ β χ of ξ n such that ξ α χ > ξ β χ > χ and
lim χ m ξ α χ , ξ β χ = ε lim χ m ξ α χ 1 , ξ β χ 1 = ε .
Since is a transitive relation, ξ α χ 1 , ξ β χ 1 . From condition i v , we have
τ + F m m ξ α χ , ξ β χ η m ξ α χ 1 , ξ β χ 1
and so
τ + lim χ inf F m m ξ α χ , ξ β χ lim χ inf η m ξ α χ 1 , ξ β χ 1 lim χ sup η m ξ α χ 1 , ξ β χ 1 .
Thus,
τ + F m ε * η ε * < F m ε *
is a contradiction; hence, ξ n is an m-Cauchy sequence in U , m . Since U , m is -complete, there exists ξ * U such that ξ μ converges to ξ * with respect to t m ; that is, m ξ n , ξ * m ξ n , ξ * 0 as n . Now, the -continuity of γ implies that
ξ = lim n ξ n + 1 = lim n γ ξ n = γ ξ .
Therefore, ξ is a fixed point of γ .  □
Example 2. 
Let U = 0 , and m be a relation theoretic m-metric space defined by m ξ , = ξ + 2 for all ξ , U . Then, U , m is a complete m-metric space. Consider a sequence ϖ n U given by ϖ n = n n + 1 n + 2 3 for all μ N . Set a binary relation ℜ on U by = 1 , 1 1 , ϖ Γ : Γ N ϖ Γ , ϖ Λ : Γ < Λ for each Γ , Λ N . Define a mapping γ : U U by
γ ξ = ξ , if ξ 0 , 1 c e i l ln ξ , if ξ 1 , ϖ 1 ξ ϖ 1 ϖ 2 ϖ 1 + 1 , if ξ ϖ 1 , ϖ 2 ϖ n 1 ϖ n + 1 ξ + ϖ n ξ ϖ n ϖ n + 1 ϖ n , if ξ ϖ n , ϖ μ + 1 for all n = 2 , 3 , 100 .
Obviously, ℜ is γ-closed and γ is continuous. Define F m , η : 0 , R by
F m ϖ = { 1 ϖ + 4 5 ϖ if ϖ 0 , 1.1 1 ϖ + ϖ if ϖ 1.1 , and η ϖ = { 1 ϖ + 1 3 ϖ if ϖ 0 , 6.5 2 ϖ + ϖ if ϖ 6.5 ,
Now, we will show that γ is a F m , η -contraction mapping. Assume that ξ , Ξ = ξ S * : m γ ξ , γ > 0 . Therefore, we will discuss four cases.
Case 1 If ξ = 1 and = ϖ 2 , then m ξ , = 4.5 and m γ ξ , γ = 1.5 ,
2 + F m m γ ξ , γ = 2 1 m γ ξ , γ + 4 5 m γ ξ , γ 2 m ξ , + m ξ , = η m ξ ,
Case 2 If ξ = 1 and = ϖ Γ for all Γ > 2 , then m ξ , = 1 + ϖ Γ 2 10.5 and m γ ξ , γ = 1 + ϖ Γ 1 2 4.5 ,
2 1 + ϖ Γ 1 2 1 + ϖ Γ 2 < 2 1 + ϖ Γ 1 2 < 1 + ϖ Γ 2 1 + ϖ Γ 1 2 < 1 + ϖ Γ 2 1 + ϖ Γ 1 2 1 + ϖ Γ 2 1 + ϖ Γ 1 2 2
which implies
2 + 2 1 + ϖ Γ 2 1 1 + ϖ Γ 1 2 1 + ϖ Γ 2 1 + ϖ Γ 1 2 ,
and thus,
2 1 1 + ϖ Γ 1 2 1 + ϖ Γ 1 2 2 1 + ϖ p 2 1 + ϖ Γ 2 .
Then,
2 + F m m γ ξ , γ = 2 1 m γ ξ , γ + m γ ξ , γ 2 m ξ , + m ξ , = η m ξ , .
Case 3 If ξ = ϖ 1 and = ϖ 2 , then m ξ , = 5 and m γ ξ , γ = 1 ,
2 + F m m γ ξ , γ = 2 1 m γ ξ , γ + 4 5 m γ Ω , γ 2 m ξ , + m ξ , = η m ξ , .
Case 4 If ξ = ϖ Γ and = ϖ Λ for all Γ and Λ in N and Γ , Λ is not equal to 1 , 2 with Γ < Λ , then m ξ , = ϖ Γ + ϖ Λ 2 14 and m γ ξ , γ = ϖ Γ 1 + ϖ Λ 1 2 7 ,
2 ϖ Γ 1 + ϖ Γ 1 2 ϖ Γ + ϖ Λ 2 < 2 ϖ Γ 1 + ϖ Λ 1 2 < ϖ Γ + ϖ Λ 2 ϖ Γ 1 + ϖ Λ 1 2 < ϖ Γ + ϖ Λ 2 ϖ Γ 1 + ϖ Λ 1 2 ϖ Γ + ϖ Λ 2 ϖ Γ 1 + ϖ Λ 1 2 2 ,
which implies
2 + 2 ϖ Γ + ϖ Λ 2 1 ϖ Γ 1 + ϖ Λ 1 2 ϖ Γ + ϖ Λ 2 ϖ Γ 1 + ϖ Λ 1 2 .
Then,
2 1 ϖ Γ 1 + ϖ Λ 1 2 + ϖ Γ 1 + ϖ Λ 1 2 2 ϖ Γ + ϖ Λ 2 + 2 ϖ Γ + ϖ Λ 2 .
Hence,
2 + F m m γ ξ , γ = 2 1 m γ ξ , γ + m γ ξ , γ 2 m ξ , + m ξ , = η m ξ , .
Therefore, from all cases, we deduce that
τ + F m m ( γ ξ , γ ) η m ξ , ,
for all ξ , Ξ . Then, γ is a weak F m , η -contraction mapping with τ = 2 . Furthermore, there exists ξ 0 = 1 in U such that Ω 0 S * γ Ω 0 and the class Θ γ , is non-empty. Thus, all conditions of Theorem 2.3 hold and γ has a fixed point.
Theorem 2. 
Theorem 1 remains true if the condition i i is replaced by the following: (ii)′  X , κ , is regular.
Proof. 
Similar to the argument of Theorem 1 we will show the sequence ξ n is m-cauchy and converges to some ξ in U such that m ξ n , ξ m ξ n , ξ as n . Now,
lim n m ξ n , ξ = lim n m ξ n , ξ = lim n min m ξ n , ξ n , m ξ , ξ = m ξ , ξ = lim n , m m ξ n , ξ m = 0 and lim n , m m ξ n , ξ m = 0 .
As ξ n S * ξ n + 1 , then ξ n S * ξ for all n N . Set L = n N : γ ξ n = γ ξ . We have two cases dependent on L.
Case 1: If L is finite , then there exists n 0 N such that γ ξ n γ ξ for every n n 0 . Moreover, ξ n S * ξ and γ ξ n S * γ ξ for all n n 0 . Since γ is a weak F m , η -contraction mapping, we have
τ + F m m γ ξ μ , γ ξ η m ξ μ , ξ .
Since, lim n m ξ n , ξ = 0 ,
lim n F m m ξ n , ξ = .
Hence,
lim n F m m γ ξ n , γ ξ = .
Therefore, lim n m γ ξ n , γ ξ = 0 and γ ξ = ξ , where ξ is a fixed point of γ .
Case 2: If L is infinite , then there exists a subsequence ξ n k ξ n such that ξ n k + 1 = γ ξ n k = γ ξ for all k N . Thus, γ ξ n k γ ξ with respect to t m as ξ n ξ , then γ ξ = ξ , i.e., γ has a fixed point. Hence, the proof is complete. □
Now, we discuss various results to ensure the uniqueness of the fixed points:
Theorem 3. 
If ϝ ξ , , ϕ for all ξ , γ F i x in Theorem 1 and Theorem 2, then γ possesses a unique fixed point.
Proof. 
Let ξ ,  Fix  γ such that ξ . Since ϝ ξ , , ϕ , then there exists a path a 0 , a 1 , a n of some finite length μ in ∇ from ξ to with a s a s + 1 for all s 0 , p 1 . Then, a 0 = ξ , a k = , a s S * a s + 1 for every s 0 , p 1 . As a s γ U , γ a s = a s for all s 0 , p 1 and since F η m ξ > η ξ , we obtain
F R m m a s , a s + 1 = F m m γ a s , γ a s + 1 η m a s , a s + 1
Since F m a > η a for all a > 0 ,
F m m a s , a s + 1 < F m m a s , a s + 1 .
Hence, γ possesses a unique fixed point. □
Theorem 4. 
Let U , m be a complete relation theoretic m-metric space endowed with a transitive binary relation ℜ on U. Let γ : U U satisfy the following:
(i)
The class Θ γ , is nonempty;
(ii)
The binary relation ℜ is γ-closed;
(iii)
The mapping γ is ℜ-continuous;
(iv)
There exists F m ρ , η π and ξ > 0 such that
τ + F m κ m ξ , γ 2 ξ η m ξ , γ ξ
for all ξ U , with γ ξ S * γ 2 ξ and F η m ξ > η ξ for all ξ > 0 .
Then, γ has a fixed point.
Furthermore, if the following conditions are satisfied:
(v)
i v
(vi)
ξ γ n Fix for some n N which implies that ξ S * γ ξ .
Then, γ n Fix = γ Fix for each n is a member of N .
Proof. 
Let ξ 0 Θ γ , , i.e., ξ 0 S * γ ξ 0 , then, from i i , we obtain ξ n S * ξ n + 1 for each n N . Denote ξ n + 1 = γ ξ n = γ n + 1 ξ 0 for all n N . If there exists n 0 N such that γ ξ n 0 = ξ n 0 , then γ has a fixed point ξ n 0 . Now, assume that
ξ n + 1 ξ n ,
for every n N . Then, ξ n S * ξ n + 1 for all n N . Continuing this process and from i v we have,
F m m γ ξ n 1 , γ 2 ξ n 1 F m m ξ n 1 , γ ξ n 1 m ξ n 1 , ξ n τ ,
for all n N , which implies,
F m m ξ n , ξ n + 1 η m ξ n 1 , ξ n τ < F m m ξ n 2 , ξ n 1 τ η m ξ n 1 , ξ n 2 τ η m ξ 0 , ξ 1 n τ .
Setting n in the above inequality, we deduce that lim n F m m ξ n , ξ n + 1 = . Since F m ρ , then
lim n m ξ n , ξ n + 1 = 0 .
From conditions (7) and (8), we have ξ n + 1 ξ n for all n , m N with n m . Now, we will prove that ξ n is an m-Cauchy sequence in U , m . Assume, in contrast, that ξ n is not an m-Cauchy sequence; then, by Lemma 2 and (6), there exists ε > 0 and two subsequences ξ α χ and ξ β χ of ξ n such that α χ > β χ > χ and
lim χ m ξ α χ , ξ β χ = ε and lim χ m ξ α χ 1 , ξ β χ 1 = ε .
Since is a transitive relation, ξ α χ 1 , ξ β χ 1 . From condition i v ,
τ + F m m ξ α χ , ξ β χ η m ξ α χ 1 , ξ β χ 1
and hence,
τ + lim χ inf F m m ξ α χ , ξ β χ lim χ inf η m ξ α χ 1 , ξ β χ 1 lim χ sup η m ξ α χ 1 , ξ β χ 1 .
Then,
τ + F m ε * η ε * < F m ε *
it is contradiction. Hence, ξ n is an m-Cauchy sequence in U , m . Since U , m is -complete, there exists ξ U such that ξ n converges to ξ * with respect to t m ; that is, m ξ n , ξ * m ξ n , ξ * 0 as n . By using the -continuity of γ ,
ξ = lim n ξ n + 1 = lim n γ ξ n = γ ξ .
Finally, we will prove that γ n F i x = γ F i x where n N . Assume, in contrast, that ξ γ n F i x and ξ γ F i x for some n N . Then, from condition i v , m ξ , γ ξ > 0 and ξ S * γ ξ . Using i i and i v , we obtain γ n ξ S * γ n + 1 ξ for all n N ,
F m m ξ , γ ξ = F m m γ γ n 1 ξ , γ 2 γ n 1 ξ η m γ γ n 1 ξ , γ 2 γ n 1 ξ τ < F m m γ n 1 ξ , γ n ξ τ η m γ n 2 ξ , γ n 1 ξ 2 τ < F m m γ n 2 ξ , γ n 1 ξ 2 τ η m γ n 3 ξ , γ n 2 ξ 3 τ η m ξ , γ ξ n τ
Taking n in the above inequality, we obtain
F m m ξ , γ ξ =
as a contradiction. Therefore, γ n F i x = γ F i x for any n N .  □

3. Cyclic-Type Weak F m , η -Contraction Mappings

In 2003, Kirk et al. [37] introduced cyclic contractions in metric spaces and investigated the existence of proximity points and fixed points for cyclic contraction mappings. Inspired by [37] and our Theorems 1 and 5 we obtained the following fixed point results for cyclic-type weak F m , η -contraction mappings.
Theorem 5 
([37] ). Assume that U , m is a compete m-metric space and G, H are two non-empty closed subsets of U and γ : U U . Suppose that the following conditions hold:
(i)
γ B D and γ D B ;
(ii)
There exists a constant k 0 , 1 such that
m γ ξ , γ k m ξ , for all ξ B , D .
Then, B D is non-empty and ξ in B D is a fixed point of γ.
Theorem 6. 
Let U , m be a complete relation theoretic m-metric space endowed with a transitive binary relation ℜ on U, G and H are two non-empty closed subsets of U and γ : U U . Assume that the following axioms hold:
(i)
γ G H and γ H G ;
(ii)
There exists F m ρ and η π and ξ > 0 such that
τ + F m m ( γ ξ , γ ) η m ξ ,
for all ξ in G , ℑ in H, with F η m ξ > η ξ for all ξ > 0 .
Then, ξ * Z = G H is a fixed point of γ . Moreover, ξ B D .
Proof. 
From i , Z = G H is closed, so Z is a closed subspace of U. Therefore, U , m is a complete m-metric space. Set the a binary relation on Z by
= G × H .
This implies that
ξ ξ , B × D for all ξ , Z .
The set S = 1 is an asymmetric relation. Directly, we set U , m , S as regular. Let ξ n Z be any sequence and ξ Z be a point such that
ξ n S ξ n + 1 for all n N
and
lim n m ξ n , ξ = lim n min m ξ n , ξ n , m ξ , ξ = m ξ , ξ .
Using the definition of S , we have
ξ n , ξ n + 1 B × D D × B for all n N
Immediately, we obtain the product of Z × Z in the m-metric space m as
m ξ 1 , 1 , ξ 2 , 2 = m ξ 1 , 1 + m ξ 2 , 2 2 .
Since U , m is a complete m-metric space, Z × Z , m is complete. Furthermore, G × H and H × G are close in Z × Z , m because G and H are closed in U , m . Applying the limit n to (11), we have ξ , B × D D × B . This implies that ξ B D . Furthermore, from (11), we have ξ n B D . Thus, we obtain ξ n S * ξ for all n N . Therefore, our theorem is proven. Furthermore, since γ is self mapping, from condition i , for all ξ , U , we obtain
ξ , in G × H γ ξ , γ H × G ξ , in H × G γ ξ , γ G × H .
The binary relation is γ -closed, and as B ϕ , there exists ξ 0 B such that γ ξ 0 D , i.e., ξ 0 S * γ ξ 0 . Therefore, all the hypotheses of Theorem 2.8 are satisfied. Hence, γ F i x ϕ and also γ F i x B D . Finally, as ξ S * for all ξ , G H . Hence, G H is ∇-directed. Hence, all conditions of Theorem 3 are satisfied and γ has a unique fixed point. □

4. Application

In this section, we study existence of a solution for a Volterra-type integral equation by using Theorem 2.6. Consider the following Volterra-type integral equation:
ξ α = 0 α A α , σ , ξ σ m σ + Ψ α , α 0 , 1 ,
where A : 0 , 1 × 0 , 1 × 0 , 1 0 , 1 and Ψ : 0 , 1 0 , 1 . Consider the Banach contraction δ = C 0 , 1 , 0 , 1 of all continuous functions ξ : 0 , 1 0 , 1 equipped with norm ξ = max 0 α 1 ξ α . Define an m-metric space m on δ by m ξ , = ξ + 2 for each ξ , in δ . Then δ , m is a complete m-metric space.
Definition 11. 
Lower and upper solutions of (9) are functions Λ and Θ in Banach space δ, respectively, such that
Λ α 0 α A α , σ , ξ σ κ σ + Ψ α and Θ α 0 α A α , σ , ξ σ m σ + Ψ α , α 0 , 1
In this section, we prove the existence and unique solution to the Volterra-type integral Equation (12).
Theorem 7. 
Consider Volterra-type integral Equation (12). Assume that there is a positive real number τ such that
A α , σ , ξ + A α , σ , 2 ξ + 2 e 1 1 + Ω + 2 τ ,
for all α , σ in 0 , 1 and ξ , in δ . if (12) has a lower solution, then a solution exists for the integral Equation (12).
Proof. 
We define an operator γ : δ δ , F m , η : R + R  by
γ ξ α = 0 α A α , σ , ξ σ m σ + Ψ α , ξ δ ,
η ϖ = ln ϖ 1 1 + ϖ
and
F m ϖ = ln ϖ
for all ϖ R + , F m ρ and η π , respectively. We can verify easily that γ is well defined and ⪯ on is γ -closed. Note that ξ is a fixed point of γ if and only if there is a solution to (12). Now, we want to prove that γ is a F m -contraction mapping with η . Let
ξ , Ξ = ξ S * : m ξ , > 0 , where m is Banach space ,
which implies that ξ . Since is γ -closed, then γ ξ γ ,
γ ξ α + γ α 2 = 0 α A α , σ , ξ σ m σ + Ψ α + 0 α A α , σ , σ m σ + Ψ α 2 0 α A α , σ , ξ σ m σ + Ψ α + 0 α A α , σ , σ m σ + Ψ α 2 0 α ξ + 2 e 1 1 + ξ + 2 τ 0 α ξ + 2 e 1 1 + ξ + 2 τ 0 α max α 0 , 1 ξ + 2 e 1 1 + ξ + 2 τ ξ + 2 e 1 1 + ξ + 2 τ ,
and so
γ ξ α + γ α 2 ξ + 2 e 1 1 + ξ + 2 τ .
Taking the supremum norm on both sides, we have
γ ξ α + γ α 2 ξ + 2 e 1 1 + ξ + 2 τ .
This implies that
ln γ ξ α + γ α 2 ln ξ + 2 e 1 1 + ξ + 2 τ ,
then
ln γ ξ α + γ α 2 = ln ξ + 2 1 1 + ξ + 2 τ .
Consequently,
τ + F m γ ξ + γ 2 t r η ξ + 2 t r .
Thus,
τ + F m m γ ξ , γ η m ξ , .
Therefore, γ is an F R m , η -contraction and thus, Inequality (4) holds. Since ξ μ is an -preserving sequence ξ n in Z 0 , 1 such that ξ n converges with respect to t m to ξ for some ξ in Z 0 , 1 , we obtain
ξ 0 α ξ 1 α ξ 2 α ξ n α ξ n + 1 α ,
for all α 0 , 1 . Which implies,
ξ n α ξ α for all α 0 , 1 .
Thus, ξ , γ F i x . Then, = max ξ , Z 0 , 1 , and thus ξ , , ξ S *  and S * . Hence, all axioms of Theorem 3 hold and the integral Equation (12) has a solution. □
Theorem 8. 
Consider Volterra-type integral Equation (12). Assume that A is non-decreasing in the third variables; then, there is positive real number τ such that
A α , σ , ξ + A α , σ , 2 ξ + 2 e 1 1 + ξ + 2 τ ,
for all α , σ in 0 , 1 and ξ , in δ . If (12) has an upper solution, then a solution exists for the integral Equation (12).
Proof. 
Define a binary relation on Banach space as follows
ξ , Ξ = ξ S * with α ξ α : m ξ , > 0 , where m is a Banach space .
Now, due to the proof of the above Theorem, then all conditions of Theorem 8 and integral Equation (12) have unique solutions. □
Example 3. 
Assume that a function
ξ α = α 2 , for all α in 0 , 1
is a solution of Equation (12)
ξ α = 3 2 α 1 + α ln 1 + α + 0 α ln 1 + ξ σ m σ , for all α in 0 , 1 .
Proof. 
Let γ be a self operator from δ to δ, which is given by
γ ξ α = 3 2 α 1 + α ln 1 + α + 0 α ln 1 + ξ σ m σ , for all α in 0 , 1 .
Now, we take τ 0.0091 , ,
A α , σ , ξ = ln 1 + ξ σ
and
Ψ α = 3 2 α 1 + α ln 1 + α .
Observe that given function A α , σ , ξ = ln 1 + ξ σ in the third variable is non-decreasing and that α 2 3 2 α 1 + α ln 1 + α + 0 σ ln 1 + ξ σ m σ for all α in 0 , 1 such that ξ α = α 2 is a lower solution of (16), then the following below inequality holds,
A α , σ , ξ + A α , σ , 2 ξ + 2 e 1 1 + ξ + 2 τ .
Now, from the non-decreasing function α e 1 1 + α 2 0.091 , we have
ln 1 + ξ + ln 1 + 2 ξ + 2 e 1 1 + ξ + 2 0.091 .
Hence, all conditions of Theorem 7 hold and the integral Equation (12) has a unique solution ξ α = α 2 for all α in 0 , 1 .  □
Example 4. 
Assume that a function
ξ α = α , for all α 0 , 1
is a solution of Equation (12):
ξ σ = α 1 α ln 2 α ln 2 + 0 α ln 2 ξ σ m σ , for all α in 0 , 1 .
Proof. 
In view of the above example, the following below inequality holds for all ξ , in 0 , 1 and τ = 0.091
ln 2 ξ + ln 2 2 ξ + 2 e 1 1 + ξ + 2 τ .
Using the arguments of the above example, we can say that the all conditions of Theorem 8 hold. Hence, the integral Equation (12) has a unique solution ξ α = α for all α in 0 , 1 .  □
Finally, we give an example different to the above example and others given in the literature [38] which satisfies all conditions of Theorem 15.
Example 5. 
Assume that a function
ξ α = 1 3 α , for all α in 0 , 1
is a solution of Equation (12):
ξ α = 5 3 α α 1 + α + 0 α ξ σ 1 + ξ σ m σ , for all α in 0 , 1 .
Proof. 
Let γ be a self operator from δ to δ , which is given by
γ ξ α = 5 3 α α 1 + α + 0 α ξ σ 1 + ξ σ m σ , for all α in 0 , 1 .
Now, we take τ 0.091 , ,
A α , σ , ξ = ξ σ 1 + ξ σ
and
Ψ α = 5 3 α α 1 + α .
Observe that given the function A α , σ , ξ = ξ σ 1 + ξ σ in the third variable is non-decreasing and that 1 3 α 5 3 α α 1 + α + 0 α ξ σ 1 + ξ σ m σ for all α in 0 , 1 such that ξ α = 1 3 α is a lower solution of (16), then the following below inequality holds:
A α , σ , ξ + A α , σ , 2 ξ + 2 e 1 1 + ξ + 2 τ .
Now, from the non-decreasing function α e 1 1 + α 2 0.9 , we have
ξ 1 + ξ + 1 + 2 ξ + 2 e 1 1 + ξ + 2 0.9 .
Hence, all axioms of Theorem 7 hold and the integral Equation (12) has a unique solution ξ α = α 3 for all α in 0 , 1 .  □
Example 6. 
Assume that a function
ξ α = 3 5 α + 1 3 , for all α 0 , 1
is a solution of Equation (12):
ξ σ = 3 5 α + 1 3 1 α 2 α + 2 + 0 α 1 + ξ σ m σ , for all α in 0 , 1 .
Proof. 
In view of the above example, the following below inequality holds for all ξ , in 0 , 1 and τ = 0.9
1 + ξ + 1 + 2 ξ + 2 e 1 1 + ξ + 2 τ .
Using the arguments of the above example, we can say that the all conditions of Theorem 7 hold. Hence, the integral Equation (12) has a unique solution ξ α = 3 5 α + 1 3 for all α in 0 , 1 .  □

5. Conclusions

In this article, we have introduced the notion of weak F m , η -contractions and proved related fixed point theorems in relation theoretic m-metric space endowed with a relation using a control function η . Examples and applications to Volterra-type integral equations are given to validate our main results. Analogously, such results can be extended to generalized distance spaces (such as symmetric spaces, m b m -spaces, r m m -spaces, r m b m - spaces, p m -spaces and p b m -spaces) endowed with relations.

Author Contributions

M.T.: writing—original draft, methodology; M.A.: conceptualization, supervision, writing—original draft; E.A.: conceptualization, writing—original draft; A.A.: methodology, writing—original draft; S.S.A.: investigation, writing—original draft; N.M.: conceptualization, supervision, writing—original draft. All authors read and approved the final manuscript.

Funding

This research received no external funding.

Data Availability Statement

Not applicable.

Acknowledgments

The authors A. ALoqaily, S. S. Aiadi and N. Mlaiki would like to thank Prince Sultan University for paying the publication fees for this work through TAS LAB.

Conflicts of Interest

The authors declare to support that they have no competing interests concerning the publication of this article.

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Tariq, M.; Arshad, M.; Ameer, E.; Aloqaily, A.; Aiadi, S.S.; Mlaiki, N. On Relational Weak Fm,η-Contractive Mappings and Their Applications. Symmetry 2023, 15, 922. https://doi.org/10.3390/sym15040922

AMA Style

Tariq M, Arshad M, Ameer E, Aloqaily A, Aiadi SS, Mlaiki N. On Relational Weak Fm,η-Contractive Mappings and Their Applications. Symmetry. 2023; 15(4):922. https://doi.org/10.3390/sym15040922

Chicago/Turabian Style

Tariq, Muhammad, Muhammad Arshad, Eskandar Ameer, Ahmad Aloqaily, Suhad Subhi Aiadi, and Nabil Mlaiki. 2023. "On Relational Weak Fm,η-Contractive Mappings and Their Applications" Symmetry 15, no. 4: 922. https://doi.org/10.3390/sym15040922

APA Style

Tariq, M., Arshad, M., Ameer, E., Aloqaily, A., Aiadi, S. S., & Mlaiki, N. (2023). On Relational Weak Fm,η-Contractive Mappings and Their Applications. Symmetry, 15(4), 922. https://doi.org/10.3390/sym15040922

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