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Article

Fixed Points and λ-Weak Contractions

by
Laura Manolescu
*,† and
Adina Juratoni
Department of Mathematics, Politehnica University of Timişoara, Piaţa Victoriei 2, 300006 Timişoara, Romania
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work.
Symmetry 2023, 15(7), 1442; https://doi.org/10.3390/sym15071442
Submission received: 26 June 2023 / Revised: 10 July 2023 / Accepted: 14 July 2023 / Published: 18 July 2023
(This article belongs to the Special Issue Symmetry in Functional Equations and Analytic Inequalities III)

Abstract

:
In this paper, we introduce a new type of contractions on a metric space ( X , d ) in which the distance d ( x , y ) is replaced with a function, depending on a parameter λ , that is not symmetric in general. This function generalizes the usual case when λ = 1 / 2 and can take bigger values than m 1 / 2 . We call these new types of contractions λ-weak contractions and we provide some of their properties. Moreover, we investigate cases when these contractions are Picard operators.

1. Introduction

Fixed point theory plays an important role in pure and applied mathematics. Among its applications, we mention nonlinear analysis, integral and differential equations, engineering, game theory, economics and so on.
Banach’s famous theorem marks the beginning of the development of the metric fixed point theory. In the following, we recall some well-known results.
We let ( X , d ) be a metric space and T : X X be a mapping. We recall that T is a Banach contraction if there exists λ [ 0 , 1 ) such that
d ( T x , T y ) λ d ( x , y ) , ( ) x , y X .
S. Banach [1] proved that every self-mapping T defined on a complete metric space satisfying (1) has a unique fixed point (i.e., T u = u ), and for every x X , sequence { T n x } converges to fixed point u. Due to its simplicity and wide range of applications, this result was generalized in various ways. See, for example, book [2] and recent papers [3,4,5,6].
Definition 1.
We assert that T is a Picard operator if T has a unique fixed point u in X and for any x X , sequence { T n x } n N converges to u (see [7,8] and book [2]).
Using this definition, the Banach theorem states the following: If ( X , d ) is a complete metric space, the Banach contraction T : X X is a Picard operator.
After this remarkable result was obtained, a number of various generalizations appeared. We mention here one of the most cited results in the fixed point literature, obtained in 1969 by Meir and Keeler [9]. The authors introduced the notion of weakly uniformly strict contraction, which later became known as the Meir–Keeler contraction. Also, they extend Banach’s metric fixed point theorem by replacing the contraction condition with this new type of contraction.
Definition 2.
We assert that T is a Meir–Keeler contraction if for every ε > 0 there exists δ > 0 such that
( ) x , y X , ε d ( x , y ) < ε + δ implies d ( T x , T y ) < ε .
Theorem 1.
(Meir, Keeler [9]) We let ( X , d ) be a complete metric space and T be a Meir–Keeler contraction. Then, T is a Picard operator.
New classes of Meir–Keeler contractions were obtained recently by the first author (see [10,11]).
In paper [12], S. Park and B.E. Rhoades provide fixed point results for weak Meir–Keeler contractions. As a particular case of their theorem, we have the following result. First, we denote
m ( x , y ) = max d ( x , y ) , d ( x , T x ) , d ( y , T y ) , d ( x , T y ) + d ( y , T x ) 2 .
Theorem 2.
We let ( X , d ) be a complete metric space and T be a continuous mapping. We suppose T satisfies the following condition: for ε > 0 , there exists a δ > 0 such that
ε m ( x , y ) < ε + δ implies d ( T x , T y ) < ε .
Then, T is a Picard operator.
Another generalization of Meir–Keeler contractions is given in the following theorem. First, we remember the following definition:
Definition 3.
[13] We assert that T is a CJMP contraction (cf. [14,15,16,17]) if the following conditions hold:
(a) 
T is contractive (i.e., the following inequality d ( T x , T y ) < d ( x , y ) holds for x , y X , x y );
(b) 
(The Matkowski–Wȩgrzyk condition [18]) for every ε > 0 , there exists
δ = δ ( ε ) > 0 such that
( ) x , y X , ε < d ( x , y ) < ε + δ d ( T x , T y ) ε .
Lj. Ćirić [14] proved that the class of CJMP contractions contains the class of Meir–Keeler contractions. In paper [13], we provided a pedagogical proof for the following theorem:
Theorem 3.
(see [14,15,16,17])
We let ( X , d ) be a complete metric space and T be a CJMP contraction on X. Then, T is a Picard operator.
Also, in paper [13], we obtained two general theorems concerning the existence of the Picard operators on complete metric spaces and some applications.
In this this paper, we obtain new classes of Picard operators on a complete metric space ( X , d ) , by replacing distance d ( x , y ) with a non-symmetric function. Many results in the literature are obtained from our results by taking λ = 1 / 2 . Our function is given by
m λ ( x , y ) = max { d ( x , y ) , d ( x , T x ) , d ( y , T y ) , λ d ( y , T x ) + ( 1 λ ) d ( x , T y ) }
and is used here for the first time in the context of fixed point theory. The reason for the introduction of this function is the fact that m λ can take bigger values than m 1 2 = m .
We consider that our results can be applied in the study of Ulam’s type stability and in the theory of integral equations.

2. Main Results

In this paper, we introduce and investigate a new type of contraction named λ -weak contraction. First, we denote for 0 < λ < 1 and for all x , y X
m λ ( x , y ) = max { d ( x , y ) , d ( x , T x ) , d ( y , T y ) , λ d ( y , T x ) + ( 1 λ ) d ( x , T y ) } .
Definition 4.
We assert that T is a λ-weak contraction if the following conditions hold:
(C1)
d ( T x , T y ) < m λ ( x , y ) , if m λ ( x , y ) > 0 (T is λ-weak contractive)
(C2)
( ) ε > 0 , ( ) δ = δ ( ε ) > 0 such that
( ) x , y X , ε < m λ ( x , y ) < ε + δ d ( T x , T y ) ε .
We remark that function m λ is not symmetric in general. It is a symmetric function if and only if λ = 1 2 . Another motivation for the introduction of this function is the fact that m λ can take bigger values than m 1 2 = m .
We provide an example inspired by paper [19] that justifies the introduction of these new types of contractions.
Example 1.
We consider M = [ 0 , 1 ] , 0 < λ < 1 and mapping T : M M is defined as follows:
T x = λ x , x 0 1 , x = 0 .
M is a complete metric space with the usual metric. In this case,
m λ ( x , 0 ) = max { 1 , λ 2 x + ( 1 λ ) ( 1 x ) } = λ 2 x + ( 1 λ ) ( 1 x ) , if 5 1 2 < λ < 1 1 , otherwise .
We observe that for 5 1 2 < λ < 1 , m λ ( x , 0 ) > m 1 / 2 ( x , 0 ) .
In 1975, J. Matkowski [16] proved that if T is 1 2 -weak contraction on a complete metric space and T is continuous or given ε > 0 , ( ) μ , 0 < μ < ε such that for all x , y X
0 < d ( T x , x ) , d ( T x , y ) + d ( x , T y ) 2 ε 0 < d ( x , y ) , d ( y , T y ) < μ d ( T x , T y ) < ε μ ,
then T is a Picard operator.
In the following, we provide some properties of λ -weak contractions and we prove that if T is a λ-weak contraction and T is continuous or verifies the condition
( C 3 ) given ε > 0 , there exists a μ , 0 < μ ε such that for x , y X ,
0 < d ( T x , x ) , λ d ( y , T x ) + ( 1 λ ) d ( x , T y ) ε 0 < d ( x , y ) , d ( y , T y ) < μ d ( T x , T y ) < ε μ .
Then, T is a Picard operator.
Also, we prove that T is a Picard operator if T verifies conditions (C2) and
( C 4 ) given ε > 0 , ( ) μ , 0 < μ < ε such that if m λ ( x , y ) = ε , then d ( T x , T y ) ε μ .
Proposition 1.
If T is λ-weak contractive and T x T 2 x , then
d ( T x , T 2 x ) < d ( x , T x ) .
Proof. 
We have
m λ ( x , T x ) = max { d ( x , T x ) , d ( T x , T 2 x ) , ( 1 λ ) d ( x , T 2 x ) } ,
hence
m λ ( x , T x ) d ( T x , T 2 x ) > 0 .
In the following, we use the proof by contradiction to prove that d ( T x , T 2 x ) < d ( x , T x ) .
We suppose that d ( T x , T 2 x ) d ( x , T x ) . We obtain
d ( x , T 2 x ) d ( x , T x ) + d ( T x , T 2 x ) 2 d ( T x , T 2 x ) ,
hence
m λ ( x , T x ) max { 1 , 2 ( 1 λ ) } d ( T x , T 2 x ) = d ( T x , T 2 x )
if λ 1 2 . It follows that
d ( T x , T 2 x ) < m λ ( x , T x ) = d ( T x , T 2 x ) ,
which is absurd. Hence, for λ 1 2 , we have d ( T x , T 2 x ) < d ( x , T x ) .
Let λ < 1 2 . We suppose that d ( T x , T 2 x ) d ( x , T x ) . Then,
m λ ( y , x ) = max { d ( x , y ) , d ( y , T y ) , d ( x , T x ) , λ d ( x , T y ) + ( 1 λ ) d ( y , T x ) } ,
m λ ( T x , x ) = max { d ( x , T x ) , d ( T x , T 2 x ) , λ d ( x , T 2 x ) } .
Because d ( T x , T 2 x ) d ( x , T x ) , it follows that
d ( x , T 2 x ) d ( x , T x ) + d ( T x , T 2 x ) 2 λ d ( T x , T 2 x ) .
We obtain
m λ ( T x , x ) max { d ( T x , T 2 x ) , 2 λ d ( T x , T 2 x ) } = d ( T x , T 2 x ) .
But T is λ -weak contractive, hence
d ( T 2 x , T x ) < m λ ( T x , x ) = d ( T x , T 2 x ) ,
which is absurd. □
Corollary 1.
If T is λ-weak contractive and x X is such that T x T 2 x , then
if λ 1 2 , it follows that m λ ( x , T x ) = d ( x , T x ) ;
if 0 < λ < 1 2 , it follows that m λ ( T x , x ) = d ( x , T x ) .
Proof. 
If λ 1 2 , it follows that
m λ ( x , T x ) = { d ( x , T x ) , d ( T x , T 2 x ) , ( 1 λ ) d ( x , T 2 x ) } .
From Proposition 1, it follows that
d ( x , T 2 x ) d ( x , T x ) + d ( T x , T 2 x ) 2 d ( x , T x ) .
Hence,
m λ ( x , T x ) max { d ( x , T x ) , 2 ( 1 λ ) } d ( x , T x ) ,
because 2 ( 1 λ ) 1 λ 1 2 .
If 0 < λ < 1 2 , we have
m λ ( T y , y ) = max { d ( T y , y ) , d ( T y , T 2 y ) , λ ( y , T 2 y ) } .
From Proposition 1,
d ( T y , T 2 y ) < d ( y , T y ) .
Using the triangle inequality, we obtain
λ d ( y , T 2 y ) λ d ( y , T y ) + λ d ( T y , T 2 y ) 2 λ d ( y , T y ) .
Hence,
m λ ( T y , y ) = max { d ( T y , y ) , 2 λ d ( y , T y ) } = d ( T y , y )
if 1 < 2 λ λ < 1 2 .
Proposition 2.
We let T : X X be a λ-weak contraction as in Definition 4 and
η = η ( ε ) δ ( ε ) 2 = δ 2 .
If d ( x , T x ) < η , d ( y , T y ) < η and d ( x , y ) η + ε , then d ( T x , T y ) ε .
Proof. 
If x = y , it is obvious. If x y , then m λ ( x , y ) > 0 and
d ( y , T x ) d ( y , x ) + d ( x , T x ) ε + 2 η ,
and, respectively,
d ( x , T y ) d ( x , y ) + d ( y , T y ) ε + 2 η .
We have
λ d ( y , T x ) + ( 1 λ ) d ( x , T y ) ε + 2 η ,
Hence,
m λ ( x , y ) ε + 2 η < ε + δ .
If m λ ( x , y ) ε , from ( C 1 ) , it follows that d ( T x , T y ) < m λ ( x , y ) ε .
If m λ ( x , y ) > ε , from ( C 2 ) , it follows that d ( T x , T y ) ε .
Proposition 3.
We let T : X X be an arbitrary mapping. If
λ d ( x , y ) + ( 1 λ ) d ( x , T y ) ( 1 λ ) d ( x , T x ) ,
then m λ ( x , y ) = d ( x , T x ) .
Proof. 
From the definition of m λ , it follows that d ( x , T x ) m λ ( x , y ) . Using the triangle inequality, we have
d ( y , T x ) d ( y , x ) + d ( x , T x ) ;
hence,
λ d ( y , T x ) + ( 1 λ ) d ( x , T y ) λ d ( x , y ) + λ d ( x , T x ) + ( 1 λ ) d ( x , T y ) ( 1 λ ) d ( x , T x ) + λ d ( x , T x ) = d ( x , T x ) .
In the following Theorem, we provide a generalization of the theorem of Matkowski [16] (see also [15]) by taking, instead of
d ( y , T x ) + d ( x , T y ) 2 ,
a convex combination of d ( y , T x ) + d ( x , T y ) , i.e.,
λ d ( y , T x ) + ( 1 λ ) d ( x , T y ) .
Also, we assign new conditions ( C 2 ) and ( C 4 ) for T to be a Picard operator.
Theorem 4.
We let ( X , d ) be a complete metric space and T : X X be a mapping. We suppose that T verifies one of the conditions:
(1) 
T is a λ-weak contraction and T is continuous;
(2) 
T verifies conditions ( C 2 ) and ( C 4 ) ;
(3) 
T is a λ-weak contraction and verifies condition ( C 3 ) .
Then, T is a Picard operator.
Proof. 
Step I. We prove that in sequence { x n } defined by x n + 1 = T n x n , n N has the limit of 0 .
We can suppose that
d ( x n , x n + 1 ) > 0 , ( ) n N .
Indeed, if there exists n such that d ( x n , x n + 1 ) = 0 , it follows that x n = T x n , hence x n is a fixed point.
From Proposition 1, it follows that { d ( x n , x n + 1 ) } is strictly decreasing and bounded below by 0. Hence, { d ( x n , x n + 1 ) } is convergent.
We denote by ε 0 = lim n d ( x n , x n + 1 ) and we show that ε 0 = 0 . We assume that ε 0 > 0 .
Because T is a λ -weak contraction, there exists δ = δ ( ε 0 ) > 0 such that
ε 0 < m λ ( x , y ) < ε 0 + δ d ( T x , T y ) ε 0 .
We have ε 0 < d ( x n , x n + 1 ) < ε 0 + δ , for n n 0 . From Corollary 1, we have
d ( x n , x n + 1 ) = m λ ( x n , T x n ) ,
hence
ε 0 < m λ ( x n , T x n ) < ε 0 + δ .
From ( C 2 ) , it follows that
d ( T x n , T 2 x n ) ε 0 ,
hence
d ( x n + 1 , x n + 2 ) ε 0
for n n 0 , which is absurd.
Step II. We prove that { x n } is a Cauchy sequence.
From Step I, we have that for all ε > 0 , n 1 = n 1 ( ε ) exists such that
d ( x n 1 , x n ) < γ : = m i n ε , δ 2 , n n 1 .
We use induction to prove that d ( x n , x n + p ) ε , p N . We suppose that
d ( x n , x n + p ) ε
and we prove that d ( x n , x n + p + 1 ) ε .
For p = 1 , we have d ( x n , x n + 1 ) < d ( x n 1 , x n ) < γ ε . If the induction hypothesis is true, it follows that
d ( x n 1 , x n + p ) d ( x n 1 , x n ) + d ( x n , x n + p ) < γ + ε .
From Proposition 2, it follows that
d ( T x n 1 , T x n + p ) ε , n n 1 .
Step III. We prove that T is a Picard operator.
From Step II, we have that { x n } is a Cauchy sequence. Since ( X , d ) is a complet metric space, it follows that { x n } is convergent. We denote p = lim n x n .
  • If T is continuous, we have lim n T x n = T p .
    From the uniqueness of the limit, we obtain p = T p ; hence, p is a fixed point.
  • If T verifies conditions ( C 2 ) and ( C 4 ) , it is obvious that T is a λ-weak contraction. In this case, we prove also that p = T p . If p T p ,
    m λ ( p , x n ) = d ( p , T p ) = ε 1 .
    From ( C 4 ) it follows that d ( T p , T x n ) ε 1 μ < ε 1 . By taking the limit as n moves to infinity, we obtain d ( T p , p ) ε 1 μ < ε 1 , which is a contradiction.
  • If T is a weak contraction and verifies ( C 3 ) , we suppose that T p p .
    We denote by ε = d ( p , T p ) > 0 . Since x n p , we have the following inequality:
    λ d ( p , x n ) + ( 1 λ ) d ( p , x n + 1 ) ( 1 λ ) μ
    for a large enough n . Then,
    λ d ( T p , x n ) + ( 1 λ ) d ( p , T x n ) λ [ d ( T p , p ) + d ( p , x n ) ] + ( 1 λ ) d ( p , x n + 1 ) λ d ( T p , p ) + [ λ d ( p , x n ) + ( 1 λ ) d ( p , x n + 1 ) ] λ ε + ( 1 λ ) μ < λ ε + ( 1 λ ) ε = ε .
    Hence, from ( C 3 ) , it follows d ( T p , T x n ) < ε μ and so
    d ( T p , p ) d ( T p , T x n ) + d ( T x n , p ) < ε μ + μ = ε ,
    which is a contradiction; therefore, T p = p .
Now, we prove that the fixed point is unique in each case.
We suppose that there exists another fixed point q such that T q = q , with p q . Since T is λ -weak contractive, we obtain
d ( T p , T q ) < m λ ( p , q ) .
But we also have d ( T p , T q ) = d ( p , q ) and
m λ ( p , q ) = max { d ( p , q ) , d ( p , T p ) , d ( q , T q ) , λ d ( q , T p ) + ( 1 λ ) d ( p , T q ) } = max { d ( p , q ) , d ( p , q ) , d ( q , q ) , λ d ( q , p ) + ( 1 λ ) d ( p , q ) } = max { d ( p , q ) , d ( p , q ) } = d ( p , q ) .
It follows that d ( p , q ) < d ( p , q ) , which is absurd. □
We apply Theorem 4 to obtain new fixed point theorems, generalizing the idea from paper [13].
Definition 5.
([13]) We let E , F be two real functions defined on ( 0 , ) . We assert that ( E , F ) is a compatible pair of functions if the following conditions hold:
(E1)
for t , s ( 0 , ) ,   t s E ( t ) < F ( s ) ;
(E2)
given t > 0 and { t n } n N ( t , ) , a sequence with lim n t n = t , for any sequence { s n } n N , t < s n < t n , n N , we have
lim sup n ( F ( s n ) E ( t n ) ) > 0 .
Here, we introduce a new type of contraction called ( λ , E , F )-weak contraction.
Definition 6.
We assert that T is a ( λ , E , F )-weak contraction if ( E , F ) is a compatible pair of functions such that
T x T y F ( d ( T x , T y ) ) E ( m λ ( x , y ) ) .
Theorem 5.
We let ( X , d ) be a complete metric space and T : X X be a ( λ , E , F )-weak contraction. Moreover, we suppose that one of the following conditions holds:
(i) 
T is continuous;
(ii) 
T verifies condition ( C 3 ) ;
(iii) 
T verifies condition ( C 4 ) .
Then, T is a Picard operator.
Proof. 
First, we prove that T is λ -contractive, i.e.,
d ( T x , T y ) < m λ ( x , y ) , if m λ ( x , y ) > 0 .
If T x = T y , the above inequality is obvious.
If T x T y , we suppose that d ( T x , T y ) m λ ( x , y ) . By condition ( E 1 ) , we have
F ( d ( T x , T y ) ) > E ( m λ ( x , y ) ) ,
which is in contradiction with (3).
We prove that T verifies condition ( C 2 ) . On the contrary, there is ε 0 > 0 such that for any δ > 0 , there are x δ , y δ X such that
ε 0 < m λ ( x , y ) < ε 0 + δ and d ( T x δ , T y δ ) > ε 0 .
We consider { γ n } n N a sequence of strict positive numbers such that lim n γ n = 0 . For n N , we take δ = γ n . Then, there are two sequences { x n } n N , { y n } n N X such that
ε 0 < m λ ( x n , y n ) < ε 0 + γ n
and
d ( T x n , T y n ) > ε 0 , n N .
From the above relations, with notations
t n = m λ ( x n , y n ) , s n = d ( T x n , T y n ) , n N ,
we obtain that
{ s n } n N , { t n } n N ( ε 0 , ) ;
hence, lim n t n = ε 0 , and since T is λ -contractive, we also have s n < t n , n N .
From condition ( E 2 ) , we have
lim sup ( F ( s n ) E ( s n ) ) > 0 .
From relation (3), we have F ( s n ) E ( t n ) , n N , so
lim sup n ( F ( s n ) E ( t n ) ) 0 ,
which is a contradiction. □

3. Applications

In the following, we apply Theorem 5 for the case when
E ( t ) = F ( t ) τ ,
where τ > 0 is a constant and F is a nondecreasing function. Conditions ( E 1 ) and ( E 2 ) take place. Indeed,
If t s , F ( s ) E ( t ) = F ( s ) F ( t ) + τ τ > 0 , so condition ( E 1 ) is verified. To verify condition ( E 2 ) , we observe that
lim sup ( F ( s n ) E ( t n ) ) = F ( t + 0 ) F ( t + 0 ) + τ = τ > 0 ,
where ( t n ) n N ( t , ) is a sequence with lim n t n = t and
( s n ) n N , t < s n < t n , n N .
We obtain the following result, comparable with the main result of the paper [20]:
Theorem 6.
We let ( X , d ) be a complete metric space and T : X X be a mapping. We let τ > 0 and F : ( 0 , ) R be a nondecreasing mapping. We suppose that
τ + F ( d ( T x , T y ) ) F ( m λ ( x , y ) )
for x , y X with d ( T x , T y ) > 0 . If T verifies one of the following conditions,
(i) 
T is continuous;
(ii) 
T verifies condition ( C 3 ) ;
(iii) 
T verifies condition ( C 4 ) ;
Then, T is a Picard operator.
In the following, we provide a fixed point theorem for λ -weak Meir–Keeler contractions, which is a generalization of Theorem 2.
Definition 7.
We assert that T is a λ-weak Meir–Keeler contraction if ( ) ε > 0 , ( ) δ = δ ( ε ) > 0 such that
( ) x , y X , ε m λ ( x , y ) < ε + δ
implies
d ( T x , T y ) < ε .
It is clear that every λ -weak Meir–Keeler contraction is a λ -weak contraction. Hence, we have the following result:
Theorem 7.
We let ( X , d ) be a complete metric space and T : X X . If T is a λ-weak Meir–Keeler contraction and T is continuous or T verifies condition ( C 3 ) or condition ( C 4 ) , then T is a Picard operator.

4. Conclusions

In this this paper, we obtained new classes of Picard operators on a complete metric space ( X , d ) . These classes are provided by a weak type contraction by replacing distance d ( x , y ) with a non-symmetric function. This function is given by
m λ ( x , y ) = max { d ( x , y ) , d ( x , T x ) , d ( y , T y ) , λ d ( y , T x ) + ( 1 λ ) d ( x , T y ) }
and is used here for the first time in the context of fixed point theory.
We consider that our results can be applied in the study of Ulam’s type stability and in the theory of integral equations.

Author Contributions

Conceptualization, L.M. and A.J.; methodology, L.M.; validation, L.M. and A.J.; formal analysis, A.J.; investigation, L.M. and A.J.; writing—review and editing, L.M. and A.J.; funding acquisition, L.M. and A.J. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by a grant of the Romanian Ministry of Research, Innovation and Digitalization, project number PFE 26/30.12.2021, PERFORM-CDI@UPT100- The increasing of the performance of the Polytechnic University of Timișoara by strengthening the research, development and technological transfer capacity in the field of “Energy, Environment and Climate Change” at the beginning of the second century of its existence, within Program 1—Development of the national system of Research and Development, Subprogram 1.2—Institutional Performance-Institutional Development Projects–Excellence Funding Projects in RDI, PNCDI III.

Data Availability Statement

Not applicable.

Acknowledgments

We want thank the reviewers for their comments and remarks on our paper.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Banach, S. Sur les opérations dans lesensembles abstraits et leur application aux équations intégrales. Fundam. Math. 1922, 3, 133–181. [Google Scholar] [CrossRef]
  2. Rus, I.A.; Petruşel, A.; Petruşel, G. Fixed Point Theory; Cluj University Press: Cluj, Romania, 2008; p. 514. [Google Scholar]
  3. Okeke, G.A.; Olaleru, J.O. Fixed points of demicontinuous ϕ-nearly Lipschitzian mappings in Banach spaces. Thai J. Math. 2019, 17, 141–154. [Google Scholar]
  4. Okeke, G.A.; Ofem, A.E. A novel three-step implicit iteration process for three finite family of asymptotically generalized Φ-hemicontractive mapping in the intermediate sense. Appl.-Math. J. Chin. Univ. 2023, 38, 248–263. [Google Scholar] [CrossRef]
  5. Rahmat, G.; Sarwar, M.; Tunc, C. Strong convergence to a fixed point of nonexpensive discrete semigroup in strictly convex Banach spaces. J. Math. Anal. 2021, 12, 26–37. [Google Scholar]
  6. Zada, M.B.; Sarwar, M.; Tunc, C. Fixed point theorems in b-metric spaces and their applications to non-linear fractional differential and integral equations. J. Fixed Point Theory Appl. 2018, 20, 25. [Google Scholar] [CrossRef]
  7. Rus, I.A. Generalized contractions. In Seminar on Fixed Point Theory; Babeş Bolyai University: Cluj-Napoca, Romania, 1983; Volume 3, pp. 1–130. [Google Scholar]
  8. Rus, I.A. Picard operators and applications. Sci. Math. Jpn. 2003, 58, 191–219. [Google Scholar]
  9. Meir, A.; Keeler, E. A theorem on contraction mapping. J. Math. Anal. Appl. 1969, 28, 326–329. [Google Scholar] [CrossRef] [Green Version]
  10. Găvruţa, L.; Găvruţa, L.; Khojasteh, F. Two classes of Meir-Keeler contractions. arXiv 2014, arXiv:1405.5034. [Google Scholar]
  11. Manolescu, L.; Găvruţa, P.; Khojasteh, F. Some Classes of Meir–Keeler Contractions. In Approximation and Computation in Science and Engineering; Daras, N.J., Rassias, T.M., Eds.; Springer Optimization and Its Applications; Springer: Cham, Switzerland, 2022; pp. 609–617. [Google Scholar]
  12. Park, S.; Rhoades, B.E. Meir-Keeler type contractive conditions. Math. Japon 1981, 26, 13–20. [Google Scholar]
  13. Găvruţa, P.; Manolescu, L. New classes of Picard operators. J. Fixed Point Theory Appl. 2022, 24, 56. [Google Scholar] [CrossRef]
  14. Ćirić, L. A new fixed point theorem for contractive mappings. Publ. Inst. Math. 1981, 30, 25–27. [Google Scholar]
  15. Jachymski, J. Equivalent conditions and the Meir-Keeler type theorems. J. Math. Anal. Appl. 1995, 194, 293–303. [Google Scholar] [CrossRef]
  16. Matkowski, J. Fixed point theorems for contractive mappings in metric spaces. Časopis Pěst. Mat. 1980, 105, 341–344. [Google Scholar] [CrossRef]
  17. Proinov, P.D. Fixed point theorems in metric spaces. Nonlinear Anal. 2006, 64, 546–557. [Google Scholar] [CrossRef]
  18. Matkowki, J.W. On equivalence of some fixed point theorems for self mappings of metrically convex space. Boll. Un. Mat. Ital. A 1978, 15, 359–369. [Google Scholar]
  19. Ćirić, L.B. Fixed points of weakly contraction mappings. Publ. Inst. Math. 1976, 20, 79–84. [Google Scholar]
  20. Wardowski, D.; Van Dung, N. Fixed Points Of F-Weak Contractions On Complete Metric Spaces. Demonstr. Math. 2014, 47, 146–155. [Google Scholar] [CrossRef]
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Manolescu, L.; Juratoni, A. Fixed Points and λ-Weak Contractions. Symmetry 2023, 15, 1442. https://doi.org/10.3390/sym15071442

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Manolescu L, Juratoni A. Fixed Points and λ-Weak Contractions. Symmetry. 2023; 15(7):1442. https://doi.org/10.3390/sym15071442

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Manolescu, Laura, and Adina Juratoni. 2023. "Fixed Points and λ-Weak Contractions" Symmetry 15, no. 7: 1442. https://doi.org/10.3390/sym15071442

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Manolescu, L., & Juratoni, A. (2023). Fixed Points and λ-Weak Contractions. Symmetry, 15(7), 1442. https://doi.org/10.3390/sym15071442

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