Next Article in Journal
Linear Model Predictive Control for Physical Attractiveness and Risk: Application of Cosmetic Medicine Service
Next Article in Special Issue
An Extension of Fuzzy Competition Graph and Its Uses in Manufacturing Industries
Previous Article in Journal
A Proposal to Fix the Number of Factors on Modeling the Dynamics of Futures Contracts on Commodity Prices
Previous Article in Special Issue
Entropy Measures for Plithogenic Sets and Applications in Multi-Attribute Decision Making
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Applying Fixed Point Techniques to Stability Problems in Intuitionistic Fuzzy Banach Spaces

1
Department of Mathematics, Indian Institute of Engineering Science and Technology, Shibpur, Howrah, West Bengal 711103, India
2
Department of Mathematics, Uluberia College, Uluberia, Howrah, West Bengal 711315, India
3
Department of Mathematics, Bijoy Krishna Girls’ College, Howrah, Howrah, West Bengal 711101, India
4
Institute of Research and Development of Processes, Faculty of Science and Technology, University of the Basque Country, Campus of Leioa, Bizkaia, 48940 Leioa, Spain
*
Author to whom correspondence should be addressed.
Mathematics 2020, 8(6), 974; https://doi.org/10.3390/math8060974
Submission received: 17 February 2020 / Revised: 30 May 2020 / Accepted: 10 June 2020 / Published: 15 June 2020
(This article belongs to the Special Issue Fuzzy Sets, Fuzzy Logic and Their Applications 2020)

Abstract

:
In this paper we investigate Hyers-Ulam-Rassias stability of certain nonlinear functional equations. Considerations of such stabilities in different branches of mathematics have been very extensive. Again the fuzzy concepts along with their several extensions have appeared in almost all branches of mathematics. Here we work on intuitionistic fuzzy real Banach spaces, which is obtained by combining together the concepts of fuzzy Banach spaces with intuitionistic fuzzy sets. We establish that pexiderized quadratic functional equations defined on such spaces are stable in the sense of Hyers-Ulam-Rassias stability. We adopt a fixed point approach to the problem. Precisely, we use a generxalized contraction mapping principle. The result is illustrated with an example.

1. Introduction

In this paper, we derive Hyers-Ulam-Rassias stability results for certain functional equations in the context of intuitionistic fuzzy Banach spaces (IFBS). The problem of stability that we study here was for the first time mathematically formulated by Ulam [1]. It was partly solved and further generalized by Hyers [2] and Rassias [3]. Today we know such stability problems as the problems of the Hyers-Ulam-Rassias (H-U-R) stability. It has many extended forms and has been studied in several domains of mathematics including differential equations [4], functional equations [5], isometries [6], etc. Our interest is in the study of such stabilities for certain functional equations. H-U-R stability for functional equations on linear spaces has been discussed in quite a large number of papers, some of which are noted in [7,8,9,10,11,12,13,14].
The fuzzy concept was mathematically introduced by Zadeh [15] in 1965. Over the following years it was adopted in almost all the domains of mathematics including linear algebra and functional analysis. The idea of a fuzzy set has many extensions of itself. One such extension is the concept of intuitionistic fuzzy set introduced by Atanassov [16]. Here we have an additional degree of membership, which is sometimes referred to as the degree of non-belongingness.
In this paper we consider the intuitionistic fuzzy linear spaces as defined by S. Shakeri [17]. It is a generalization of the definition of fuzzy normed linear space given by Mirmostafaee [18]. Stability of functional equations on the above-mentioned space have been considered in works like [19,20,21]. Precisely in this paper we consider the H-U-R stability problem for pexiderized quadratic functional equations. These equations are generalized quadratic functional equations and appeared in the literature in works like [22,23,24]. Amongst several approaches to H-U-R stability problems we adopt the fixed point approach where the stability is established through an application of a fixed point theorem obtained in complete generalized metric spaces [25].

2. Mathematical Background

The following is the definition of a pexiderized quadratic functional equation.
A mapping f : R R is said to be a quadratic form if f ( x ) = c x 2 for all x , c R .
Let X and Y be a real vector space and a Banach space, respectively, and corresponding to a mapping f : X Y , consider the functional equation
f ( x + y ) + f ( x y ) = 2 f ( x ) + 2 f ( y )
Any solution of Equation ( 1 ) is termed as quadratic mapping. Particularly, if X = Y = R , the quadratic form f ( x ) = c x 2 is a solution of ( 1 ) . The form
f ( x + y ) + f ( x y ) = 2 g ( x ) + 2 h ( y )
is known as pexiderized quadratic functional equation [26,27], which is an extension of the above definition of quadratic functional equation.
Definition 1
([28,29]). Consider the set L * and the order relation L * defined by
Ł * = { ( α 1 , α 2 ) : ( α 1 , α 2 ) [ 0 , 1 ] 2 and α 1 + α 2 1 } ,
( α 1 , α 2 ) L * ( β 1 , β 2 ) α 1 β 1 , α 2 β 2 , ( α 1 , α 2 ) , ( β 1 , β 2 ) L * .
Then ( L * , L * ) is a complete lattice.
The elements 0 L * = ( 0 , 1 ) and 1 L * = ( 1 , 0 ) are its units.
Definition 2
([16]). An intuitionistic fuzzy set A of E where E is a nonempty set, is A = { ( x , μ A ( x ) , ν A ( x ) ) : x E } , in which case the functions μ A : E [ 0 , 1 ] and ν A : E [ 0 , 1 ] are the degree of membership and the degree of non-membership respectively for every x E satisfying 0 μ A ( x ) + ν A ( x ) 1 .
For our notational purposes we denote an intuitionistic fuzzy set on X by any function A μ , ν = X L * given by A μ , ν ( x ) = ( μ A ( x ) , ν A ( x ) ) with μ A , ν A : X [ 0 , 1 ] satisfying 0 μ A ( x ) + ν A ( x ) 1 .
Definition 3
([30]). A triangular norm (t-norm) on L * is a mapping Γ : ( L * ) 2 L * satisfying the following conditions:
(a) 
( α L * ) ( Γ ( α , 1 L * ) = α ) (boundary condition),
(b) 
( ( α , β ) ( L * ) 2 ) ( Γ ( α , β ) = Γ ( β , α ) ) (commutativity),
(c) 
( ( α , β , γ ) ( L * ) 3 ) ( Γ ( α , Γ ( β , γ ) ) = Γ ( Γ ( α , β ) , γ ) ) (associativity),
(d) 
( ( α , α , β , β ) ( L * ) 4 ) ( α L * α and
β L * β Γ ( α , β ) L * Γ ( α , β ) ) (monotonicity).
If Γ is continuous then Γ is called a continuous t-norm.
Definition 4
([30]). A triangular conorm (t-conorm) on L * is a mapping S : ( L * ) 2 L * satisfying the following conditions:
(a) 
( α L * ) ( S ( α , 0 L * ) = α ) (boundary condition),
(b) 
( ( α , β ) ( L * ) 2 ) ( S ( α , β ) = S ( β , α ) ) (commutativity),
(c) 
( ( α , β , γ ) ( L * ) 3 ) ( S ( α , S ( β , γ ) ) = S ( S ( α , β ) , γ ) ) (associativity),
(d) 
( ( α , α , β , β ) ( L * ) 4 ) ( α L * α and β L * β S ( α , β ) L * S ( α , β ) ) (monotonicity).
Example 1.
Let
M ( α , β ) = ( min { α 1 , β 1 } , max { α 2 , β 2 } )
for all α = ( α 1 , α 2 ) , β = ( β 1 , β 2 ) L * .
Then M ( α , β ) is a continuous t-norm.
Definition 5
([30]). A continuous t-norm Γ on L * is said to be continuous t-representable if we can find a continuous t-norm * and a continuous t-conorm ⋄ on [ 0 , 1 ] such that for all x = ( α 1 , α 2 ) , y = ( β 1 , β 2 ) L * , Γ ( x , y ) = ( α 1 * β 1 , α 2 β 2 )
We now define the iterated sequence Γ n recursively by Γ 1 = Γ and
Γ n ( x ( 1 ) , x ( 2 ) , , x ( n + 1 ) ) = Γ ( Γ ( n 1 ) ( x ( 1 ) , x ( 2 ) , x ( n ) ) , x ( n + 1 ) ) ,
n 2 , x ( i ) L * .
Intuitionistic fuzzy normed linear space was defined by Saadati [31]. Shakeri [17] has stated this definition in a more compact form. We state the definition in the form used by Shakeri [17]
Definition 6
([17]). We call the triple ( X , P μ , ν , Γ ) an intuitionistic fuzzy normed space (briefly IFN-space) if X is a vector space, Γ is a continuous t-norm and P μ , ν is a mapping X × ( 0 , ) L * which is an intuitionistic fuzzy set satisfying the following conditions:for all x , y X and t , s > 0 ,
(i) 
P μ , ν ( x , 0 ) = 0 L * ;
(ii) 
P μ , ν ( x , t ) = 1 L * if and only if x = 0 ;
(iii) 
P μ , ν ( α x , t ) = P μ , ν x , t | α | for all α 0 ;
(iv) 
P μ , ν ( x + y , t + s ) L * Γ ( P μ , ν ( x , t ) , P μ , ν ( y , s ) ) .
It can be noted that P μ , ν has the form P μ , ν ( x , t ) = ( μ x ( t ) , ν x ( t ) ) = ( μ ( x , t ) , ν ( x , t ) ) such that 0 μ x ( t ) + ν x ( t ) 1 for all x X and t > 0 . Then with μ and ν the above definition reduces to the more explicit form used in [31].
Definition 7
([17]). ( 1 ) The sequence { x n } is said to be convergent to a point x X if
P μ , ν ( x n x , s ) 1 L * a s n f o r e v e r y s > 0 .
( 2 ) A sequence { x n } in an IFN-space ( X , P μ , ν , M ) is said to be a Cauchy sequence if given any ε > 0 and s > 0 , we can find n 0 N such that
P μ , ν ( x n x m , s ) > L * ( 1 ε , ε ) , n , m n 0
( 3 ) An IFN-space ( X , P μ , ν , M ) is said to be complete if every Cauchy sequence in ( X , P μ , ν , M ) is convergent in ( X , P μ , ν , M ) . A complete intuitionistic fuzzy normed space is called an intuitionistic fuzzy Banach space.
We require the following fixed point result to establish our result of stability in this paper.
Definition 8
([25]). Let X be a nonempty set. A function d : X × X [ 0 , ] is called a generalized metric on X if d satisfies
(i) 
d ( p , q ) = 0 if and only if p = q ;
(ii) 
d ( p , q ) = d ( q , p ) for all p , q X ;
(iii) 
d ( p , q ) d ( p , r ) + d ( r , q ) for all p , q , r X . Then ( X , d ) is called a generalized metric space.
Theorem 1.
([12,23,32]). Let ( X , d ) be a complete generalized metric space and let J : X X be a strictly contractive mapping with Lipschitz constant 0 < L < 1 , that is,
d ( J p , J q ) L d ( p , q ) ,
for all p , q X . Then for each p X , either
d ( J k p , J k + 1 p ) = , k 0
or,
d ( J k p , J k + 1 p ) < k k o
for some non-negative integers k 0 . Moreover, if the second alternative holds then
(1) 
the sequence { J k p } converges to a fixed point q of J;
(2) 
q is the unique fixed point of J in the set
Y = { q X : d ( J k 0 p , q ) < } ;
(3) 
d ( q , q ) ( 1 1 L ) d ( q , J q ) for all q Y .

3. The Hyers-Ulam-Rassias Stability Result

Throughout the result of the paper, X is considered to be a normed linear space, ( Y , P μ , ν , M ) an IF-real Banach space, ( Z , P μ , ν , M ) an IFN-space and M is continuous t norm defined in Example 2, also consider
M 1 ( x , t )
= M 2 P μ , ν ϕ ( x , x ) , t 3 , P μ , ν ϕ ( x , 0 ) , t 3 ,
P μ , ν ϕ ( 0 , x ) , t 3
where ϕ : X × X Z .
Lemma 1.
Let ( Z , P μ , ν , M ) be an IFN-space. Let ϕ : X × X Z be a mapping and further let E = { g | g : X Y } . Let d : E × E [ 0 , ] be defined by
d ( g , h )
: = inf { k R + : P μ , ν ( g ( x ) h ( x ) , k t ) L * M 1 ( x , t ) for all x X , t > 0 }
and g , h E .
Then ( E , d ) is a complete generalized metric space.
Proof. 
Let f , g , h E and d ( f , g ) = k 1 < , d ( g , h ) = k 2 < .
Then P μ , ν ( f ( x ) g ( x ) , k 1 t ) L * M 1 ( x , t ) and P μ , ν ( g ( x ) h ( x ) , k 2 t ) L * M 1 ( x , t )
Therefore P μ , ν ( f ( x ) h ( x ) , ( k 1 + k 2 ) t )
L * M P μ , ν ( f ( x ) g ( x ) , k 1 t ) , P μ , ν ( g ( x ) h ( x ) , k 2 t ) (by property iv of Definition 6) L * M M 1 ( x , t ) , M 1 ( x , t ) (by the monotonicity property) = L * M 1 ( x , t ) (Idempotent property)s for all x X , t > 0 .
Hence d ( f , h ) k 1 + k 2 so that d ( f , h ) d ( f , g ) + d ( g , h ) which is the triangle inequality. The other axioms are obvious, and hence, ( E , d ) is a generalized metric space. Now we prove that ( E , d ) is complete.
Let { g n } be a Cauchy sequence in ( E , d ) . Now for each fixed x X and for every t > 0 and ϵ > 0 there exists λ > 0 such that M 1 ( x , t λ ) > 1 ε . Since { g n } is a Cauchy sequence in ( E , d ) corresponding to λ > 0 , there exists n 0 N such that d ( g n , g m ) < λ for all m , n n 0 .
Since g n , g m E so we find,
d ( g n , g m ) = inf { k R + : P μ , ν ( g n ( x ) g m ( x ) , k t ) M 1 ( x , t ) }
That is,
d ( g n , g m ) = inf { k R + : P μ , ν ( g n ( x ) g m ( x ) , t ) M 1 ( x , t k ) }
then there exists k 3 [ 0 , ) such that d ( g n , g m ) k 3 < λ for all m , n n 0 and P μ , ν ( g n ( x ) g m ( x ) , t ) M 1 ( x , t k 3 ) M 1 ( x , t λ ) > 1 ε , as P μ , ν ( x , t ) is non-decreasing with respect to t for all m , n n 0 .
Thus, for fixed x X , { g n ( x ) } is a Cauchy sequence in Y. Again since Y is Banach space, every x X , there exists g ( x ) Y such that g n ( x ) g ( x ) as n . Then the mapping g : X Y is such that g n ( x ) g ( x ) as n for all x X .
Again, { g n } is a Cauchy sequence in ( E , d ) therefore for ϵ > 0 , t > 0 there exists n 0 N such that d ( g n , g m ) < ϵ m , n n 0 and hence there exists k [ 0 , ) such that d ( g n , g m ) k < ϵ m , n n 0
P μ , ν ( g n ( x ) g m ( x ) , t ) M 1 ( x , t k ) M 1 ( x , t ϵ ) .
That is
P μ , ν ( g m ( x ) g n ( x ) , ϵ t ) M 1 ( x , t ) , n , m n 0
Now let ϵ , δ > 0 be given and m , n > n 0 , t > 0 , then
P μ , ν ( g n ( x ) g ( x ) , ( ϵ + δ ) t )
L * M { P μ , ν ( g n ( x ) g m ( x ) , ϵ t ) , P μ , ν ( g m ( x ) g ( x ) , δ t ) }
L * M { M 1 ( x , t ) , P μ , ν ( g m ( x ) g ( x ) , δ t ) }
L * M { M 1 ( x , t ) , 1 L * } [ b y t a k i n g l i m i t a s m ] = L * M 1 ( x , t ) )
that is, d ( g n , g ) ϵ + δ for all x X and m , n n 0 .
Taking δ 0 we have a mapping g : X Y such that
g ( x ) = P μ , ν lim n g n ( x ) E .
Therefore, ( E , d ) is a complete generalized metric space. □
For our purpose, we denote
Let D f ( x , y ) = f ( x + y ) + f ( x y ) 2 g ( x ) 2 h ( y )
Theorem 2.
Let X be a linear space, ( Z , P μ , ν , M ) be an IFN-space, ϕ : X × X Z be such that
P μ , ν ( ϕ ( 2 x , 2 x ) , t ) L * P μ , ν ( α ϕ ( x , x ) , t )
for some real α with 0 < α < 2 , ( x X , t > 0 ) and
lim n P μ , ν ( ϕ ( 2 n x , 2 n x ) , 2 n t ) = 1 L *
where x X and t > 0 . Further let ( Y , P μ , ν , M ) be a complete IFN-space. If f , g , h : X Y are odd mappings such that
P μ , ν ( D f ( x , y ) , t ) L * P μ , ν ( ϕ ( x , y ) , t )
( x X , t > 0 ) , where D f ( x , y ) is given by Equation (4). Then there exists a unique additive mapping A : X Y define by A ( x ) : = lim n f ( 2 n x ) 2 n for all x X satisfying
P μ , ν ( f ( x ) A ( x ) , t ) L * M 1 ( x , t ( 2 α ) )
and
P μ , ν ( A ( x ) g ( x ) h ( x ) , t ) L * M 1 x , t × 3 ( 2 α ) 5 α .
Proof. 
Interchanging the role of x and y in Equation (6) we get
P μ , ν ( f ( x + y ) f ( x y ) 2 g ( y ) 2 h ( x ) , t )
L * P μ , ν ( ϕ ( y , x ) , t )
Also from Equation (6) and using Equation (9) we get
P μ , ν ( 2 f ( x + y ) 2 g ( x ) 2 h ( y ) 2 g ( y ) 2 h ( x ) , 2 t )
L * M P μ , ν ( ϕ ( x , y ) , t ) , P μ , ν ( ϕ ( y , x ) , t )
that is,
P μ , ν ( f ( x + y ) g ( x ) h ( y ) g ( y ) h ( x ) , t )
L * M P μ , ν ( ϕ ( x , y ) , t ) , P μ , ν ( ϕ ( y , x ) , t )
Now putting y = 0 in Equation (10) we have
P μ , ν ( f ( x ) g ( x ) h ( x ) , t )
L * M P μ , ν ( ϕ ( x , 0 ) , t ) , P μ , ν ( ϕ ( 0 , x ) , t )
Replacing y by x in Equation (11) we get
P μ , ν ( f ( y ) g ( y ) h ( y ) , t )
L * M P μ , ν ( ϕ ( y , 0 ) , t ) , P μ , ν ( ϕ ( 0 , y ) , t )
Hence using Equations (10)–(12) we get
P μ , ν ( f ( x + y ) f ( x ) f ( y ) , 3 t )
L * M 5 P μ , ν ϕ ( x , y ) , t , P μ , ν ϕ ( y , x ) , t
P μ , ν ϕ ( x , 0 ) , t , P μ , ν ϕ ( 0 , x ) , t
P μ , ν ϕ ( y , 0 ) , t , P μ , ν ϕ ( 0 , y ) , t
Therefore
P μ , ν ( f ( x + y ) f ( x ) f ( y ) , t )
L * M 5 P μ , ν ϕ ( x , y ) , t 3 , P μ , ν ϕ ( y , x ) , t 3 ,
P μ , ν ϕ ( x , 0 ) , t 3 , P μ , ν ϕ ( 0 , x ) , t 3 ,
P μ , ν ϕ ( y , 0 ) , t 3 , P μ , ν ϕ ( 0 , y ) , t 3
Also we put y = x in Equation (13)
P μ , ν ( f ( 2 x ) 2 f ( x ) , t )
L * M 5 P μ , ν ϕ ( x , x ) , t 3 , P μ , ν ϕ ( x , x ) , t 3 ,
P μ , ν ϕ ( x , 0 ) , t 3 , P μ , ν ϕ ( 0 , x ) , t 3 ,
P μ , ν ϕ ( x , 0 ) , t 3 , P μ , ν ϕ ( 0 , x ) , t 3
= M 2 P μ , ν ϕ ( x , x ) , t 3 , P μ , ν ϕ ( x , 0 ) , t 3 ,
P μ , ν ϕ ( 0 , x ) , t 3
= M 1 ( x , t )
that is,
P μ , ν ( f ( 2 x ) 2 f ( x ) , t ) L * M 1 ( x , t )
Now define a mapping J : E E by J g ( x ) = 1 2 g ( 2 x ) for all g E and x X , where ( E , d ) is a complete generalized metric space as in Lemma 1. We now prove that J is a strictly contractive mapping of E with the Lipschitz constant α 2 .
Let g , h E and ϵ > 0 . Then there exists k R + satisfying P μ , ν ( g ( x ) h ( x ) , k t ) L * M 1 ( x , t ) such that d ( g , h ) k < d ( g , h ) + ϵ for any ϵ > 0 .
Then inf k R + : P μ , ν ( g ( x ) h ( x ) , k t ) L * M 1 ( x , t ) k < d ( g , h ) + ϵ that is, inf k R + : P μ , ν ( g ( 2 x ) 2 h ( 2 x ) 2 , k t 2 ) L * M 1 ( 2 x , t ) < d ( g , h ) + ϵ that is, inf k R + : P μ , ν ( J g ( x ) J h ( x ) , k t 2 ) L * M 1 ( 2 x , t ) < d ( g , h ) + ϵ that is, inf k R + : P μ , ν ( J g ( x ) J h ( x ) , k α t 2 ) L * M 1 ( x , t ) < d ( g , h ) + ϵ as M 1 ( 2 n x , t ) = M 1 ( x , t α n ) or, d 2 α ( J g , J h ) < d ( g , h ) + ϵ or, d ( J g , J h ) < α 2 d ( g , h ) + ϵ . Taking ϵ 0 we get d ( J g , J h ) < α 2 d ( g , h ) . Therefore, J is strictly contractive mapping with Lipschitz constant α 2 .
Also from Equation (14) d ( f , J f ) 1 2 and d ( J f , J 2 f ) α 2 d ( f , J f ) < . Again, replacing x by 2 n x in Equation (14) we get P μ , ν ( f ( 2 n + 1 x ) 2 f ( 2 n x ) , t ) L * M 1 ( 2 n x , t ) or, P μ , ν ( f ( 2 n + 1 x ) 2 n + 1 f ( 2 n x ) 2 n , t 2 n + 1 ) L * M 1 ( 2 n x , t )
L * M 1 ( x , t α n )
or, P μ , ν J n + 1 f ( x ) J n f ( x ) , t ( α 2 ) n 2 L * M 1 ( x , t )
Hence, d ( J n + 1 f , J n f ) 1 2 ( α 2 ) n < has Lipschitz constant α 2 < 1 for n n 0 = 1 .
Therefore, by Theorem 1 there exists a mapping A : X Y such that the following holds:
1 . A is a fixed point of J for which A ( 2 x ) = 2 A ( x ) for all x X .
Further, A is a unique fixed point of J in the set E 1 = { g E : d ( J n 0 f , g ) = d ( J f , g ) < } . Therefore, d ( J f , A ) < .
Also from Equation (14) d ( J f , f ) 1 2 < . Thus f E 1 . Now, d ( f , A ) d ( f , J f ) + d ( J f , A ) < . Thus, there exists k ( 0 , ) satisfying
P μ , ν ( f ( x ) A ( x ) , k t ) L * M 1 ( x , t )
for all x X , t > 0 ;
2 . d ( J n f , A )
= inf { k R + : P μ , ν ( J n f ( x ) A ( x ) , k t ) L * M 1 ( x , t ) }
= inf { k R + : P μ , ν ( f ( 2 n x ) A ( 2 n x ) , 2 n k t ) L * M 1 ( x , ( 2 α ) n t ) }
Therefore, d ( J n f , A ) ( α 2 ) n 0 as n . This implies the equality
A ( x ) = lim n J n f ( x ) = lim n f ( 2 n x ) 2 n
for all x X .
3 . d ( f , A ) 1 1 L d ( f , J f ) with f E 1 which implies the inequality
d ( f , A ) 1 1 α 2 × 1 2 = 1 2 α
then it follows that
P μ , ν ( A ( x ) f ( x ) , 1 2 α t ) L * M 1 ( x , t )
It implies that
P μ , ν ( A ( x ) f ( x ) , t ) L * M 1 ( x , ( 2 α ) t )
for all x X ; t > 0 .
Replacing x and y by 2 n x and 2 n y in Equation (13) we have
P μ , ν f ( 2 n ( x + y ) ) 2 n f ( 2 n x ) 2 n f ( 2 n y ) 2 n , t
L * M 5 P μ , ν ϕ ( 2 n x , 2 n y ) , 2 n t 3 , P μ , ν ϕ ( 2 n y , 2 n x ) , 2 n t 3 ,
P μ , ν ϕ ( 2 n x , 0 ) , 2 n t 3 , P μ , ν ϕ ( 0 , 2 n x ) , 2 n t 3 ,
P μ , ν ϕ ( 2 n y , 0 ) , 2 n t 3 , P μ , ν ϕ ( 0 , 2 n y ) , 2 n t 3
Taking the limit as n in Equation (17) and using
lim n P μ , ν ( ϕ ( 2 n x , 2 n y ) , 2 n t ) = 1 L *
we have
P μ , ν ( A ( x + y ) A ( x ) A ( y ) , t ) = 1 L *
A ( x + y ) = A ( x ) + A ( y )
that is, A is additive.
Also from Equation (11) we have
P μ , ν ( A ( x ) g ( x ) h ( x ) , t 5 α 3 )
= P μ , ν ( A ( x ) f ( x ) + f ( x ) g ( x ) h ( x ) , t + 2 α 3 t )
L * M P μ , ν ( A ( x ) f ( x ) , t ) , P μ , ν f ( x ) g ( x ) h ( x ) , 2 α 3 t
L * M M 1 ( x , ( 2 α ) t ) , M P μ , ν ϕ ( x , 0 ) , 2 α 3 t ,
P μ , ν ϕ ( 0 , x ) , 2 α 3 t
L * M M 1 ( x , ( 2 α ) t ) , M 1 ( x , ( 2 α ) t )
L * M 1 ( x , ( 2 α ) t )
Therefore,
P μ , ν ( A ( x ) g ( x ) h ( x ) , t ) L * M 1 x , t × 3 ( 2 α ) 5 α .
Again, A is the unique fixed point of J with the following property that there exists u ( 0 , ) such that
P μ , ν ( f ( x ) A ( x ) , u t ) L * M 1 ( x , t )
for all x X and t > 0 [23]. This establishes the uniqueness of A . This completes the proof of the theorem. □
Theorem 3
([23]). Let X be a linear space and ( Z , P μ , ν , M ) be an IFN-space. Let ϕ : X × X Z be such that
P μ , ν ( ϕ ( 2 x , 2 x ) , t ) L * P μ , ν ( α ϕ ( x , x ) , t )
for some real α with 0 < α < 4 , ( x X , t > 0 ) and
lim n P μ , ν ( ϕ ( 2 n x , 2 n x ) , 4 n t ) = 1 L *
for all x , y X and t > 0 . Let ( Y , P μ , ν , M ) be a complete IFN-space. If f , g , h : X Y are even mappings with f ( 0 ) = g ( 0 ) = h ( 0 ) = 0 such that
P μ , ν ( D f ( x , y ) , t ) L * P μ , ν ( ϕ ( x , y ) , t )
( x X , t > 0 ) , where D is given by Equation (4). Then there exists a unique quadratic mapping Q : X Y defined by Q ( x ) : = lim n f ( 2 n x ) 4 n for all x X satisfying
P μ , ν ( f ( x ) Q ( x ) , t ) L * M 1 ( x , t ( 4 α ) )
and
P μ , ν ( Q ( x ) g ( x ) , t ) L * M 1 x , t × 6 ( 4 α ) 10 α .
also
P μ , ν ( Q ( x ) h ( x ) , t ) L * M 1 x , t × 6 ( 4 α ) 10 α .
Proof. 
Putting y = x in Equation (20)
P μ , ν ( f ( 2 x ) 2 g ( x ) 2 h ( x ) , t ) L * P μ , ν ( ϕ ( x , x ) , t )
Also putting x = 0 in Equation (20)
P μ , ν ( 2 f ( y ) 2 h ( y ) , t ) L * P μ , ν ( ϕ ( 0 , y ) , t )
Again putting y = 0 in Equation (20)
P μ , ν ( 2 f ( x ) 2 g ( x ) , t ) L * P μ , ν ( ϕ ( x , 0 ) , t )
Now using Equations (20), (24), (25)
P μ , ν f ( x + y ) + f ( x y ) 2 f ( x ) 2 f ( y ) , 3 t
= P μ , ν f ( x + y ) + f ( x y ) 2 g ( x ) 2 h ( y )
{ 2 f ( y ) 2 h ( y ) } { 2 f ( x ) 2 g ( x ) } , 3 t
L * M 2 P μ , ν ϕ ( x , y ) , t , P μ , ν ϕ ( 0 , y ) , t , P μ , ν ϕ ( x , 0 ) , t
Therefore
P μ , ν f ( x + y ) + f ( x y ) 2 f ( x ) 2 f ( y ) , t
L * M 2 P μ , ν ϕ ( x , y ) , t 3 , P μ , ν ϕ ( 0 , y ) , t 3 ,
P μ , ν ϕ ( x , 0 ) , t 3
Now putting y = x in Equation (26) we get
P μ , ν f ( 2 x ) 4 f ( x ) , t
L * M 2 P μ , ν ϕ ( x , x ) , t 3 , P μ , ν ϕ ( 0 , x ) , t 3 ,
P μ , ν ϕ ( x , 0 ) , t 3
= M 1 ( x , t )
Thus,
P μ , ν f ( 2 x ) 4 f ( x ) , t L * M 1 ( x , t )
Similar to before [23], we consider the set E : = { g : X Y } and introduce a complete generalized metric on E. Again, define a mapping J : E E by J g ( x ) = 1 4 g ( 2 x ) for all g E and x X . And in a similar way as before we prove that J is strictly contractive mapping with Lipschitz constant α 4 and d ( f , J f ) 1 4 .
Therefore by Theorem 1 there exists a mapping Q : X Y such that the followings hold:
1 . Q is a fixed point of J, that is, Q ( 2 x ) = 4 Q ( x ) for all x X .
The mapping Q is a unique fixed point of J in the set E 1 = { g E : d ( J n 0 f , g ) = d ( J f , g ) < } and there exists k ( 0 , ) satisfying
P μ , ν ( f ( x ) Q ( x ) , k t ) L * M 1 ( x , t )
for all x X , t > 0 ;
2 . d ( J n f , Q ) ( α 4 ) n 0 as n . This implies the equality
Q ( x ) = lim n J n f ( x ) = lim n f ( 2 n x ) 4 n
3 . d ( f , Q ) 1 1 L d ( f , J f ) with f E 1 , which implies the inequality
d ( f , Q ) 1 1 α 4 × 1 4 = 1 4 α
then it follows that
P μ , ν ( Q ( x ) f ( x ) , 1 4 α t ) L * M 1 ( x , t )
It implies that
P μ , ν ( Q ( x ) f ( x ) , t ) L * M 1 ( x , ( 4 α ) t )
for all x X ; t > 0 .
Replacing x and y by 2 n x and 2 n y in Equation(26) we have
P μ , ν f ( 2 n ( x + y ) ) 4 n + f ( 2 n ( x y ) ) 4 n 2 f ( 2 n x ) 4 n 2 f ( 2 n y ) 4 n , t
L * M 2 P μ , ν ϕ ( 2 n x , 2 n y ) , 4 n t 3 , P μ , ν ϕ ( 0 , 2 n y ) , 4 n t 3 ,
P μ , ν ϕ ( 2 n x , 0 ) , 4 n t 3
Taking limit as n we get
P μ , ν ( Q ( x + y ) + Q ( x y ) 2 Q ( x ) 2 Q ( y ) , t ) = 1 L *
that is, Q ( x + y ) + Q ( x y ) = 2 Q ( x ) + 2 Q ( y ) that is, Q is quadratic.
Also from Equation (25) we have
P μ , ν ( Q ( x ) g ( x ) , 10 α 6 t )
= P μ , ν ( Q ( x ) f ( x ) + f ( x ) g ( x ) , t + ( 4 α ) 6 t )
L * M P μ , ν ( Q ( x ) f ( x ) , t ) , P μ , ν f ( x ) g ( x ) , ( 4 α ) 2.3 t
L * M M 1 ( x , ( 4 α ) t ) , M P μ , ν ϕ ( x , 0 ) , ( 4 α ) 3 t
L * M M 1 ( x , ( 4 α ) t ) , M 1 ( x , ( 4 α ) t )
L * M 1 ( x , ( 4 α ) t )
Therefore,
P μ , ν ( Q ( x ) g ( x ) , t ) L * M 1 x , t × 6 ( 4 α ) 10 α .
Similarly,
P μ , ν ( Q ( x ) h ( x ) , t ) L * M 1 x , t × 6 ( 4 α ) 10 α .
Corollary 1.
Let p < 1 be a non-negative real number and X be norm linear space with norm . , ( Z , P μ , ν , M ) be an IFN-space, ( Y , P μ , ν , M ) be a complete IFN-space and z 0 Z . If f , g , h : X Y are odd mappings such that
P μ , ν f ( x + y ) + f ( x y ) 2 g ( x ) 2 h ( y ) , t
L * P μ , ν z 0 x p + y p , t
( x , y X , t > 0 , z 0 Z )
then there exists a unique additive mapping A : X Y such that
P μ , ν ( f ( x ) A ( x ) , t ) L * P μ , ν z 0 x p , t 6 2 2 p
and P μ , ν ( A ( x ) g ( x ) h ( x ) , t ) L * P μ , ν z 0 x p , ( 2 2 p ) 10 2 p + 1 t for all x X and t > 0 , z 0 Z .
Proof. 
Define ϕ ( x , y ) = z 0 x p + y p , then the corollary is proved exactly as Theorem 2 with α = 2 p . □
Corollary 2.
Let p < 2 be a non-negative real number and X be norm linear space with norm . , ( Z , P μ , ν , M ) be an IFN-space, ( Y , P μ , ν , M ) be a complete IFN-space and z 0 Z . If f , g , h : X Y are even mappings such that
P μ , ν f ( x + y ) + f ( x y ) 2 g ( x ) 2 h ( y ) , t
L * P μ , ν z 0 x p + y p , t
( x , y X , t > 0 , z 0 Z )
then there exists a unique quadratic mapping Q : X Y such that
P μ , ν ( f ( x ) Q ( x ) , t ) L * P μ , ν z 0 x p , t 6 4 2 p
and P μ , ν ( Q ( x ) g ( x ) , t ) L * P μ , ν z 0 x p , ( 4 2 p ) 10 2 p t for all x X and t > 0 , z 0 Z .
Proof. 
Define ϕ ( x , y ) = z 0 x p + y p . Then the corollary is proved exactly as Theorem 3 with α = 2 p
Example 2.
Let ( X , . ) be a Banach algebra and let Z be a normed linear space, M a continuous t-norm as defined in Example 1. Then ( X , P μ , ν , M ) is a complete IFN-space in which P μ , ν ( x , t ) = ( μ x ( t ) , ν x ( t ) ) .
Define f , g , h : X X , by f ( x ) = x 2 + A x x 0 , g ( x ) = x 2 + B x x 0 , h ( y ) = y 2 + C y x 0 , | | x 0 | | = 1 in X and A , B , C are positive real numbers.
Then f ( x + y ) + f ( x y ) 2 g ( x ) 2 h ( y ) 2 ( A + B ) x + 2 ( A + C ) y for all x , y X .
Let ϕ : X × X Z be defined as
ϕ ( x , y ) = 2 ( A + B ) x z 0 + 2 ( A + C ) y z 0 for all x , y X and z 0 be a unit vector in Z.
Thus, P μ , ν ( f ( x + y ) + f ( x y ) 2 g ( x ) 2 h ( y ) , t )
L * P μ , ν 2 ( A + B ) x z 0 + 2 ( A + C ) y z 0 , t
= L * P μ , ν ( ϕ ( x , y ) , t )
for all x , y X and t > 0 .
Then P μ , ν ( ϕ ( 2 x , 2 y ) , t ) P μ , ν ( 2 ϕ ( x , y ) , t ) for all x , y X and t > 0 . Hence, all the conditions of Theorem 3 are valid for α = 2 < 4 .
Therefore, f can be approximated by a mapping Q : X X such that
P μ , ν ( f ( x ) Q ( x ) , t )
L * M 1 ( x , 2 t )
= P μ , ν x z 0 , t 6 min { ( A + B ) , ( 2 A + B + C ) , ( A + C ) }
for all x , y X and t > 0 .

4. Conclusions

Our consideration in this paper is a pexiderized quadratic functional equation, which is an extension of the quadratic functional equation. It may be possible to extend the cubic and higher order functional equations on similar lines. In our proof of the main theorem, we have made extensive use of the characteristics of intuitionistic fuzzy Banach spaces. As a future problem, we can think of the problem of Hyers-Ulam-Rassias stability for more general forms of functional equations in intuitionistic fuzzy linear spaces.

5. Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Author Contributions

Conceptualization, P.S., T.K.S. and P.M.; methodology, T.K.S., P.M. and B.S.C.; validation, P.S., P.M., B.S.C. and M.D.L.S.; formal analysis, T.K.S. and P.M.; writing—original draft preparation, P.S. and B.S.C.; writing—review and editing, P.S., T.K.S., B.S.C. and M.D.L.S.; supervision, P.S., B.S.C. and M.D.L.S.; funding acquisition, M.D.L.S. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Basque Government under the Grant IT 1207-19.

Acknowledgments

The fifth author thanks the Basque Government for Grant IT 1207-19. The suggestions of the referees are acknowledged.

Conflicts of Interest

The authors declare that there are no conflicts of interest regarding the publication of this paper.

References

  1. Ulam, S.M. Problems in Modern Mathematics; Science Editions; Wiley: New York, NY, USA, 1964; Chapter VI. [Google Scholar]
  2. Hyers, D.H. On the stability of the linear functional equation. Proc. Nat. Acad. Sci. USA 1941, 27, 222–224. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  3. Rassias, T.M. On the stability of the linear mapping in Banach spaces. Proc. Am. Math. Soc. 1978, 72, 297–300. [Google Scholar] [CrossRef]
  4. Jung, S.M. Hyers-Ulam stability of linear differential equations of first order, II. App. Math. Lett. 2006, 19, 854–858. [Google Scholar] [CrossRef] [Green Version]
  5. Grabiec, A. The generalized Hyers-Ulam stability of a class of functional equations. Publ. Math. Debrecen 1996, 48, 217–235. [Google Scholar]
  6. Dong, Y. On approximate isometries and application to stability of a function. J. Math. Anal. Appl. 2015, 426, 125–137. [Google Scholar] [CrossRef]
  7. Aoki, T. On the stability of the linear transformation in Banach spaces. Math. Soc. Jpn. 1950, 2, 64–66. [Google Scholar] [CrossRef]
  8. Cholewa, P.W. Remarks on the stability of functional equations. Aequ. Math. 1984, 27, 76–86. [Google Scholar] [CrossRef]
  9. Czerwik, S. On the stability of the quadratic mappings in normed spaces. Abh. Math. Sem. Univ. Hamburg 1992, 62, 59–64. [Google Scholar] [CrossRef]
  10. Gavruta, P. A generalization of the Hyers-Ulam-Rassias Stability of approximately additive mappings. J. Math. Anal. Appl. 1994, 184, 431–436. [Google Scholar] [CrossRef] [Green Version]
  11. Isac, G.; Rassias, T.H. Stability of ψ -additive mapping: Applications to nonlinear analysis. Int. J. Math. Math. Sci. 1996, 19, 219–228. [Google Scholar] [CrossRef] [Green Version]
  12. Mihet, D. The fixed point method for fuzzy stability of the Jensen functional equation. Fuzzy Sets Syst. 2009, 160, 1663–1667. [Google Scholar] [CrossRef]
  13. Samanta, T.K.; Kayal, N.C.; Mondal, P. The stability of a general quadratic functional equation in fuzzy Banach spaces. J. Hyperstruct. 2012, 1, 71–87. [Google Scholar]
  14. Samanta, T.K.; Mondal, P.; Kayal, N.C. The generalized Hyers-Ulam-Rassias stability of a quadratic functional equation in fuzzy Banach spaces. Ann. Fuzzy Math. Inform. 2013, 6, 59–68. [Google Scholar]
  15. Zadeh, L.A. Fuzzy sets. Inf. Control 1965, 8, 338–353. [Google Scholar] [CrossRef] [Green Version]
  16. Atanassov, K.T. Intuitionistic fuzzy sets. Fuzzy Sets Syst. 1986, 20, 87–96. [Google Scholar] [CrossRef]
  17. Shakeri, S. Intutionistic fuzzy stability of Jenson type mapping. J. Nonlinear Sci. Appl. 2009, 2, 105–112. [Google Scholar] [CrossRef]
  18. Mirmostafee, A.K.; Moslehian, M.S. Fuzzy versions of Hyers-Ulam-Rassias theorem. Fuzzy Sets Syst. 2008, 159, 720–729. [Google Scholar] [CrossRef]
  19. Kayal, N.C.; Samanta, T.K.; Saha, P.; Choudhury, B.S. A Hyers-Ulam-Rassias stability result for functional equations in intuitionistic fuzzy Banach spaces. Iran. J. Fuzzy Syst. 2016, 13, 87–96. [Google Scholar]
  20. Mondal, P.; Kayal, N.C.; Samanta, T.K. Stability of a quadratic functional equation in intuitionistic fuzzy banach spaces. J. New Results. Sci. 2016, 10, 52–59. [Google Scholar]
  21. Wang, Z.; Rassias, T.M.; Saadati, R. Intuitionistic fuzzy stability of Jensen-type quadratic functional equations. Filomat 2014, 28, 663–676. [Google Scholar] [CrossRef]
  22. Mohiuddine, S.A.; Sevli, H. Stability of Pexiderized quadratic functional equation in intuitionistic fuzzy normed space. J. Comp. Appl. Math. 2011, 235, 2137–2146. [Google Scholar] [CrossRef] [Green Version]
  23. Mondal, P.; Kayal, N.C.; Samanta, T.K. The stability of Pexider type functional equation in intuitionistic fuzzy banach spaces via fixed point technique. J. Hyperstruct. 2015, 4, 37–49. [Google Scholar]
  24. Xu, T.Z.; Rassias, M.J.; Xu, W.X.; Rassias, J.M. A fixed point approach to the intuitionistic fuzzy stability of quintic and sextic functional equations. Iran. J. Fuzzy Syst. 2012, 9, 21–40. [Google Scholar]
  25. Diaz, J.B.; Margolisi, B. A fixed point theorem of the alternative for contractions on a generalized complete metric space. Bull. Am. Math. Soc. 1968, 74, 305–309. [Google Scholar] [CrossRef] [Green Version]
  26. Jung, S.M. On the Hyers-Ulam stability of functional equations that have the quadratic property. J. Math. Anal. Appl. 1998, 222, 126–137. [Google Scholar] [CrossRef] [Green Version]
  27. Jung, S.M. Quadratic functional equations of Pexider type. J. Math. Math. Sci. 2000, 24, 351–359. [Google Scholar] [CrossRef] [Green Version]
  28. Atanassov, K.T. Geometrical interpretation of the elements of the intuitionistic fuzzy objects. Int. J. Bioautomat. 2016, 20, S27–S42. [Google Scholar]
  29. Deschrijiver, G.; Kerre, E.E. On the relationship between some extensions of fuzzy set theory. Fuzzy Sets Syst. 2003, 23, 227–235. [Google Scholar] [CrossRef]
  30. Deschrijver, G.; Cornelis, C.; Kerre, E.E. On the representation of intuitionistic fuzzy t-norms and t-conorms. IEEE Trans. Fuzzy Sust. 2004, 12, 45–61. [Google Scholar] [CrossRef]
  31. Saadati, R.; Park, J.H. On Intuitionistic fuzzy topological spaces. Chaos Solitons Fractals 2006, 27, 331–344. [Google Scholar] [CrossRef] [Green Version]
  32. Cadariu, L.; Radu, V. Fixed points and stability for functional equations in probabilistic metric and random normed spaces. Fixed Point Theory Appl. 2009, 2009, 589143. [Google Scholar] [CrossRef] [Green Version]

Share and Cite

MDPI and ACS Style

Saha, P.; Samanta, T.K.; Mondal, P.; Choudhury, B.S.; De La Sen, M. Applying Fixed Point Techniques to Stability Problems in Intuitionistic Fuzzy Banach Spaces. Mathematics 2020, 8, 974. https://doi.org/10.3390/math8060974

AMA Style

Saha P, Samanta TK, Mondal P, Choudhury BS, De La Sen M. Applying Fixed Point Techniques to Stability Problems in Intuitionistic Fuzzy Banach Spaces. Mathematics. 2020; 8(6):974. https://doi.org/10.3390/math8060974

Chicago/Turabian Style

Saha, P., T. K. Samanta, Pratap Mondal, B. S. Choudhury, and Manuel De La Sen. 2020. "Applying Fixed Point Techniques to Stability Problems in Intuitionistic Fuzzy Banach Spaces" Mathematics 8, no. 6: 974. https://doi.org/10.3390/math8060974

APA Style

Saha, P., Samanta, T. K., Mondal, P., Choudhury, B. S., & De La Sen, M. (2020). Applying Fixed Point Techniques to Stability Problems in Intuitionistic Fuzzy Banach Spaces. Mathematics, 8(6), 974. https://doi.org/10.3390/math8060974

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop