Solving an Integral Equation via Fuzzy Triple Controlled Bipolar Metric Spaces

Mani, Gunaseelan; Gnanaprakasam, Arul Joseph; Mitrović, Zoran D.; Bota, Monica-Felicia

doi:10.3390/math9243181

Open AccessArticle

Solving an Integral Equation via Fuzzy Triple Controlled Bipolar Metric Spaces

¹

Department of Mathematics, Saveetha School of Engineering, Saveetha Institute of Medical and Technical Sciences, Saveetha University, Chennai 602105, Tamil Nadu, India

²

Department of Mathematics, College of Engineering and Technology, Faculty of Engineering and Technology, SRM Institute of Science and Technology, SRM Nagar, Kattankulathur, Kanchipuram, Chennai 603203, Tamil Nadu, India

³

Faculty of Electrical Engineering, University of Banja Luka, Patre 5, 78000 Banja Luka, Bosnia and Herzegovina

⁴

Department of Mathematics, Faculty of Mathematics and Computer Science, Babeş-Bolyai University, 400084 Cluj-Napoca, Romania

^*

Author to whom correspondence should be addressed.

^†

All authors contributed equally to this work.

Mathematics 2021, 9(24), 3181; https://0-doi-org.brum.beds.ac.uk/10.3390/math9243181

Submission received: 16 November 2021 / Revised: 5 December 2021 / Accepted: 7 December 2021 / Published: 9 December 2021

(This article belongs to the Special Issue New Trends in Fuzzy Sets Theory and Their Extensions)

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Abstract

:

In this paper, motivated by the recent result of Sezen, we introduce the notion of fuzzy triple controlled bipolar metric space and prove some fixed point results in this framework. Our results generalize and extend some of the well-known results from the literature. We also explore some of the applications of our key results to integral equations.

Keywords:

fuzzy metric space; fuzzy bipolar metric space; fuzzy triple controlled bipolar metric space; fixed points

1. Introduction

In their pioneering works, Schweizer and Sklar [1] introduced the notion of continuous triangular norm, and Zadeh [2] provided the theory of fuzzy sets. Using the ideas of Zadeh, in the paper [3], Kramosil and Michalek defined the fuzzy metric space. A modified definition of fuzzy metric spaces is given in the paper of George and Veeramani [4]. After that, Grabiec [5] obtained the well-known fixed-point theorem of Banach to fuzzy metric spaces in the sense of Karamosil and Michalek. Similarly, an extension of the fuzzy Banach contraction theorem to fuzzy metric space in the sense of George and Veeramani was obtained by Gregori and Sapena [6]. Recently Mutlu and Gürdal [7] introduced bipolar metric spaces. Bartwal, Dimri and Prasad [8] introduced fuzzy bipolar metric space and proved some fixed-point theorems in this context. On bipolar metric spaces and fuzzy metric spaces, see [2,9,10,11,12,13,14,15,16].

Recently, Sezen [17] considered some fixed-point results in controlled fuzzy metric spaces. Motivated by Sezen [17], in this paper, we prove fixed-point theorems on fuzzy triple controlled bipolar metric spaces. Using the obtained results, we give an application to the existence and uniqueness of the solution of some classes of integral equations.

2. Preliminaries

In this section, we introduce some basic definitions and auxiliary results.

Definition 1

([4]). Let Θ be a non-empty set. An ordered triple

(Θ, Π, *)

is called a fuzzy metric space if Π is a fuzzy set on

Θ^{2} \times (0, \infty)

and * is a continuous τ-norm satisfying the following conditions for all

ϑ, φ, ζ \in Θ

and

τ, ς > 0

:

(i): $Π (ϑ, φ, τ) > 0$ ;
(ii): $Π (ϑ, φ, τ) = 1$ iff $ϑ = φ$ ;
(iii): $Π (ϑ, φ, τ) = Π (φ, ϑ, τ)$ ;
(iv): $Π (ϑ, ζ, τ + ς) \geq Π (ϑ, φ, τ) * Π (φ, ζ, ς)$ ;
(v): $Π (ϑ, φ, .) : (0, \infty) ⟶ (0, 1]$ is continuous.

Definition 2

([8]). Let Λ and Θ be two non-empty sets. A quadruple

(Λ, Θ, Π_{ϱ}, *)

is said to be fuzzy bipolar metric space, where * is a continuous τ-norm and

Π_{ϱ}

is a fuzzy set on

Λ \times Θ \times (0, \infty)

, satisfying the following conditions for all

τ, ς, γ > 0

:

(FB1): $Π_{ϱ} (ϑ, φ, τ) > 0$ for all $(ϑ, φ) \in Λ \times Θ$ ;
(FB2): $Π_{ϱ} (ϑ, φ, τ) = 1$ iff $ϑ = φ$ for $ϑ \in Λ$ and $φ \in Θ$ ;
(FB3): $Π_{ϱ} (ϑ, φ, τ) = Π_{ϱ} (φ, ϑ, τ)$ for all $ϑ, φ \in Λ \cap Θ$ ;
(FB4): $Π_{ϱ} (ϑ_{1}, φ_{2}, τ + ς + γ) \geq Π_{ϱ} (ϑ_{1}, φ_{1}, τ) * Π_{ϱ} (ϑ_{2}, φ_{1}, ς) * Π_{ϱ} (ϑ_{2}, φ_{2}, γ)$ for all
$ϑ_{1}, ϑ_{2} \in Λ$ and $φ_{1}, φ_{2} \in Θ$ ;
(FB5): $Π_{ϱ} (ϑ, φ, .) : [0, \infty) ⟶ [0, 1]$ is left continuous;
(FB6): $Π_{ϱ} (ϑ, φ, .)$ is non-decreasing for all $ϑ \in Λ$ and $φ \in Θ$ .

Definition 3.

Let Λ and Θ be two non-empty sets. Let

λ, α, β : Λ \times Θ \to [1, \infty)

be three non-comparable functions. A quadruple

(Λ, Θ, Π_{ϱ}, *)

is said to be fuzzy triple controlled bipolar metric space, where * is a continuous τ-norm and

Π_{ϱ}

is a fuzzy set on

Λ \times Θ \times (0, \infty)

, satisfying the following conditions for all

τ, ς, γ > 0

:

(FCB1): $Π_{ϱ} (ϑ, φ, τ) > 0$ for all $(ϑ, φ) \in Λ \times Θ$ ;
(FCB2): $Π_{ϱ} (ϑ, φ, τ) = 1$ iff $ϑ = φ$ for $ϑ \in Λ$ and $φ \in Θ$ ;
(FCB3): $Π_{ϱ} (ϑ, φ, τ) = Π_{ϱ} (φ, ϑ, τ)$ for all $ϑ, φ \in Λ \cap Θ$ ;
(FCB4): $Π_{ϱ} (ϑ_{1}, φ_{2}, τ + ς + γ) \geq Π_{ϱ} (ϑ_{1}, φ_{1}, \frac{τ}{λ (ϑ_{1}, φ_{1})}) * Π_{ϱ} (ϑ_{2}, φ_{1}, \frac{ς}{α (ϑ_{2}, φ_{1})}) * Π_{ϱ} (ϑ_{2}, φ_{2}, \frac{γ}{β (ϑ_{2}, φ_{2})})$ for all $ϑ_{1}, ϑ_{2} \in Λ$ and $φ_{1}, φ_{2} \in Θ$ ;
(FCB5): $Π_{ϱ} (ϑ, φ, .) : [0, \infty) ⟶ [0, 1]$ is left continuous;
(FCB6): $Π_{ϱ} (ϑ, φ, .)$ is non-decreasing for all $ϑ \in Λ$ and $φ \in Θ$ .

Remark 1.

Taking

λ (ϑ_{1}, φ_{1}) = α (ϑ_{2}, φ_{1}) = β (ϑ_{2}, φ_{2}) = 1

, we obtain the definition of fuzzy bipolar metric space [8].

Example 1.

Let

Λ = {1, 2, 3, 4}

,

Θ = {2, 4, 5, 6}

and

λ, α, β : Λ \times Θ \to [1, \infty)

be three non-comparable mappings defined as

λ (ϑ, φ) = ϑ + φ + 1

,

α (ϑ, φ) = ϑ^{2} + φ + 1

and

β (ϑ, φ) = ϑ^{2} + φ - 1

. Let

Π_{ϱ} : Λ \times Θ \times (0, + \infty) \to [0, 1]

be defined by

\begin{matrix} Π_{ϱ} (ϑ, φ, υ) = \frac{min {ϑ, φ} + υ}{max {ϑ, φ} + υ}, \end{matrix}

for all

ϑ \in Λ

,

φ \in Θ

and

υ \in (0, + \infty)

. Then

(Λ, Θ, Π_{ϱ}, 🟉)

is a fuzzy triple controlled bipolar metric space with the continuous τ-norm 🟉 such that

σ * ϱ = σ ϱ

. Now,

\begin{matrix} λ (1, 2) & = 4, λ (1, 4) = 6, λ (1, 5) = 7, λ (1, 6) = 8, λ (2, 2) = 5, λ (2, 4) = 7, \\ λ (2, 5) = 8, λ (2, 6) = 9, λ (3, 2) = 6, λ (3, 4) = 8, λ (3, 5) = 9, λ (3, 6) = 10, \\ λ (4, 2) = 7, λ (4, 4) = 9, λ (4, 5) = 10, λ (4, 6) = 11, \end{matrix}

\begin{matrix} α (1, 2) & = 4, α (1, 4) = 6, α (1, 5) = 7, α (1, 6) = 8, α (2, 2) = 7, α (2, 4) = 9, \\ α (2, 5) = 10, α (2, 6) = 11, α (3, 2) = 12, α (3, 4) = 14, α (3, 5) = 15, \\ α (3, 6) = 16, α (4, 2) = 19, α (4, 4) = 21, α (4, 5) = 22, α (4, 6) = 23, \end{matrix}

\begin{matrix} β (1, 2) & = 2, β (1, 4) = 4, β (1, 5) = 5, β (1, 6) = 6, β (2, 2) = 5, β (2, 4) = 7, \\ β (2, 5) = 8, β (2, 6) = 9, β (3, 2) = 10, β (3, 4) = 12, β (3, 5) = 13, β (3, 6) = 14, \\ β (4, 2) = 17, β (4, 4) = 19, β (4, 5) = 20, β (4, 6) = 21, \end{matrix}

Axioms (FCB1)–(FCB3), (FCB5) and (FCB6) are easy to verify; we only prove (FCB4). Let

ϑ_{1} = 1, φ_{2} = 4, φ_{1} = 2

and

ϑ_{2} = 3

. Then

\begin{matrix} Π_{ϱ} (1, 4, υ + ς + γ) & = \frac{min {1, 4} + υ + ς + γ}{max {1, 4} + υ + ς + γ} \\ = \frac{1 + υ + ς + γ}{4 + υ + ς + γ} . \end{matrix}

Now,

\begin{matrix} Π_{ϱ} (1, 2, \frac{υ}{λ (1, 2)}) & = \frac{min {1, 2} + \frac{υ}{λ (1, 2)}}{max {1, 2} + \frac{υ}{λ (1, 2)}} \\ = \frac{1 + \frac{υ}{4}}{2 + \frac{υ}{4}} \\ = \frac{4 + υ}{8 + υ}, \end{matrix}

\begin{matrix} Π_{ϱ} (3, 2, \frac{ς}{α (3, 2)}) & = \frac{min {3, 2} + \frac{ς}{α (3, 2)}}{max {3, 2} + \frac{ς}{α (3, 2)}} \\ = \frac{2 + \frac{ς}{12}}{3 + \frac{ς}{12}} \\ = \frac{24 + ς}{36 + ς} \end{matrix}

and

\begin{matrix} Π_{ϱ} (3, 4, \frac{γ}{β (3, 4)}) & = \frac{min {3, 4} + \frac{γ}{β (3, 4)}}{max {3, 4} + \frac{γ}{β (3, 4)}} \\ = \frac{3 + \frac{γ}{12}}{4 + \frac{γ}{12}} \\ = \frac{36 + γ}{48 + γ} . \end{matrix}

Clearly,

\begin{matrix} \frac{1 + υ + ς + γ}{4 + υ + ς + γ} \geq (\frac{4 + υ}{8 + υ}) (\frac{24 + ς}{36 + ς}) (\frac{36 + γ}{48 + γ}), \end{matrix}

for all

υ, ς, γ > 0

. So,

\begin{matrix} Π_{ϱ} (1, 4, υ + ς + γ) \geq Π_{ϱ} (1, 2, \frac{υ}{λ (1, 2)}) 🟉 Π_{ϱ} (3, 2, \frac{ς}{α (3, 2)}) 🟉 Π_{ϱ} (3, 4, \frac{γ}{β (3, 4)}) . \end{matrix}

On the same steps, one can prove the remaining cases. Hence,

(Λ, Θ, Π_{ϱ}, 🟉)

is a fuzzy triple controlled bipolar metric space.

Example 2.

If we take minimum τ-norm instead of product τ-norm in Example 1, then

(Λ, Θ, Π_{ϱ}, 🟉)

is not a fuzzy triple controlled bipolar metric space. For instance, let

ϑ_{1} = 1, φ_{2} = 4, φ_{1} = 2

,

ϑ_{2} = 3

and

τ = 0.02, ς = 0.03, γ = 0.04

with

λ, α, β : Λ \times Θ \to [1, \infty)

be three non-comparable mappings defined as

λ (ϑ, φ) = ϑ + φ + 1

,

α (ϑ, φ) = ϑ^{2} + φ + 1

and

β (ϑ, φ) = ϑ^{2} + φ - 1

, then

\begin{matrix} Π_{ϱ} (1, 4, 0.02 + 0.03 + 0.04) = \frac{1 + 0.09}{4 + 0.09} = 0.2665, \end{matrix}

and

\begin{matrix} Π_{ϱ} (1, 2, \frac{0.02}{λ (1, 2)}) = \frac{1 + \frac{0.02}{4}}{2 + \frac{0.02}{4}} = 0.50124, \end{matrix}

\begin{matrix} Π_{ϱ} (3, 2, \frac{0.03}{α (3, 2)}) = \frac{2 + \frac{0.03}{12}}{3 + \frac{0.03}{12}} = 0.6669, \end{matrix}

\begin{matrix} Π_{ϱ} (3, 4, \frac{0.04}{β (3, 4)}) = \frac{3 + \frac{0.04}{12}}{4 + \frac{0.04}{12}} = 0.7502 . \end{matrix}

Clearly,

\begin{matrix} Π_{ϱ} (1, 4, 0.02 + 0.03 + 0.04) & ≱ Π_{ϱ} (1, 2, \frac{0.02}{λ (1, 2)}) 🟉 Π_{ϱ} (3, 2, \frac{0.03}{α (3, 2)}) \\ 🟉 Π_{ϱ} (3, 4, \frac{0.04}{β (3, 4)}) . \end{matrix}

Hence,

(Λ, Θ, Π_{ϱ}, 🟉)

is not a fuzzy triple controlled bipolar metric space with minimum τ-norm.

Definition 4.

Let

(Λ, Θ, Π_{ϱ}, *)

be a fuzzy triple controlled bipolar metric space. The points belong to

Λ, Θ

and

Λ \cap Θ

are called left, right and central points, respectively, and sequences that belong to

Λ, Θ

and

Λ \cap Θ

are named left, right and central sequences, respectively.

Lemma 1.

Let

(Λ, Θ, Π_{ϱ}, *)

be a fuzzy triple controlled bipolar metric space such that

\begin{matrix} Π_{ϱ} (ϑ, φ, κ τ) \geq Π_{ϱ} (ϑ, φ, τ) \end{matrix}

for

ϑ \in Λ, φ \in Θ

,

τ \in (0, + \infty)

and

κ \in (0, 1)

. Then

ϑ = φ

.

Proof.

We have

\begin{matrix} Π_{ϱ} (ϑ, φ, κ τ) \geq Π_{ϱ} (ϑ, φ, τ) for τ > 0 . \end{matrix}

(1)

Since

κ τ < τ

for all

τ > 0

and

κ \in (0, 1)

, by (FCB6), we have

\begin{matrix} Π_{ϱ} (ϑ, φ, κ τ) \leq Π_{ϱ} (ϑ, φ, τ) . \end{matrix}

(2)

From (2), (3) and the definition of fuzzy triple controlled bipolar metric space (see (FCB2)), we obtain

ϑ = φ

. □

Definition 5.

Let

(Λ, Θ, Π_{ϱ}, *)

be a fuzzy triple controlled bipolar metric space. A sequence

{ϑ_{η}} \in Λ

converges to a right point φ if

Π_{ϱ} (ϑ_{η}, φ, τ) \to 1

as

η \to + \infty

, for all

τ > 0

. Similarly, a right sequence

{φ_{η}}

converges to a left point ϑ if

Π_{ϱ} (ϑ, φ_{η}, τ) \to 1

as

η \to + \infty

, for all

τ > 0

.

Definition 6.

Let

(Λ, Θ, Π_{ϱ}, *)

be a fuzzy triple controlled bipolar metric space. Then, we have the following:

(i): Sequence $(ϑ_{η}, φ_{η}) \in Λ \times Θ$ is named as a bisequence on $(Λ, Θ, Π_{ϱ}, *)$ .
(ii): If both $ϑ_{η}$ and $φ_{η}$ converge, the sequence $(ϑ_{η}, φ_{η}) \in Λ \times Θ$ is said to be a convergent sequence. If both $ϑ_{η}$ and $φ_{η}$ converge to some center point, bisequence $(ϑ_{η}, φ_{η})$ is said to be a biconvergent sequence.
(iii): A bisequence $(ϑ_{η}, φ_{η})$ on fuzzy triple controlled bipolar metric space $(Λ, Θ, Π_{ϱ}, *)$ is said to be a Cauchy bisequence $Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) \to 1$ as $η, ω \to + \infty$ , for all $τ > 0$ .

Definition 7.

The fuzzy triple controlled bipolar metric space

(Λ, Θ, Π_{ϱ}, *)

is said to be complete if every Cauchy bisequence in

Λ \times Θ

is convergent in it.

Proposition 1.

In a fuzzy triple controlled bipolar metric space, every convergent Cauchy bisequence is biconvergent.

Proof.

Let

(Λ, Θ, Π_{ϱ}, *)

be a fuzzy triple controlled bipolar metric space and a bisequence

(ϑ_{η}, φ_{η}) \in Λ \times Θ

such that

ϑ_{η} \to φ

as

η \to + \infty

and

φ_{η} \to ϑ

as

η \to + \infty

, where

η \in Θ

and

ϑ \in Λ

. Since

(ϑ_{η}, φ_{η})

is a convergent Cauchy bisequence, we obtain

Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) \to 1 as η \to \infty,

(3)

for all

τ > 0

. Now, from (1), we conclude that

Π_{ϱ} (ϑ, φ, τ) = 1,

for all

τ > 0

. Therefore, by (FCB2), we obtain that the bisequence

(ϑ_{η}, φ_{η})

is biconvergent. □

Proposition 2.

In a fuzzy triple controlled bipolar metric space, every biconvergent bisequence is a Cauchy bisequence.

Proof.

Let

(Λ, Θ, Π_{ϱ}, *)

be a fuzzy triple controlled bipolar metric space, and bisequence

(ϑ_{η}, φ_{ω}) \in Λ \times Θ

converges to a point

ϑ_{0} \in Λ \cap Θ

for all

η, ω \in N

and

τ > 0

. By (FCB4), we have

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) & \geq Π_{ϱ} (ϑ_{η}, ϑ_{0}, \frac{τ}{3 λ (ϑ_{η}, ϑ_{0})}) * Π_{ϱ} (ϑ_{0}, ϑ_{0}, \frac{τ}{3 λ (ϑ_{0}, ϑ_{0})}) \\ * Π_{ϱ} (ϑ_{0}, φ_{ω}, \frac{τ}{3 λ (ϑ_{0}, φ_{ω})}) \end{matrix}

As

η, ω \to \infty

, we obtain

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) \geq 1 for all τ > 0 . \end{matrix}

This implies that

Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) \to 1

for all

τ > 0

. Hence,

(ϑ_{η}, φ_{η})

is a Cauchy bisequence. □

Lemma 2.

Let

(Λ, Θ, Π_{ϱ}, *)

be a fuzzy triple controlled bipolar metric space and

μ \in Λ \cap Θ

is a limit of a sequence then it is a unique limit of the sequence.

Proof.

Let

{ϑ_{η}} \in Λ

be a sequence. Suppose that

{ϑ_{η}} \to φ \in Θ

and also

{ϑ_{η}} \to μ \in Λ \cap Θ

; then, for

τ, ς, γ > 0

, we have

\begin{matrix} Π_{ϱ} (μ, φ, τ + ς + γ) \geq Π_{ϱ} (μ, μ, τ) * Π_{ϱ} (ϑ_{η}, μ, ς) * Π_{ϱ} (ϑ_{η}, φ, γ) \end{matrix}

As

η \to \infty

, we obtain

\begin{matrix} Π_{ϱ} (μ, φ, τ + ς + γ) \geq 1, \end{matrix}

which implies that

μ = φ

, i.e., sequence

{ϑ_{η}}

, has a unique limit. □

Definition 8.

A point

ϑ \in Λ \cap Θ

is said to be a fixed-point of the mapping Γ if

ϑ = Γ ϑ

.

3. Main Results

In this section, we prove the extension of some well-known fixed-point theorems to fuzzy triple controlled bipolar metric spaces.

Theorem 1.

Let

(Λ, Θ, Π_{ϱ}, *)

be a complete fuzzy triple controlled bipolar metric space with three non-comparable functions

λ, α, β : Λ \times Θ \to [1, \infty)

such that

\begin{matrix} lim_{τ \to \infty} Π_{ϱ} (ϑ, φ, τ) = 1 for all ϑ \in Λ, φ \in Θ . \end{matrix}

(4)

Let

Γ : Λ \cup Θ \to Λ \cup Θ

be a mapping satisfying

(i): $Γ (Λ) \subseteq Λ$ and $Γ (Θ) \subseteq Θ$ ;
(ii): $Π_{ϱ} (Γ (ϑ), Γ (φ), κ τ) \geq Π_{ϱ} (ϑ, φ, τ)$ for all $ϑ \in Λ, φ \in Θ$ and $τ > 0$ , where $κ \in (0, 1)$ .

Additionally, assume that for every

ϑ \in Λ

, we obtain that

\begin{matrix} lim_{η \to \infty} λ (ϑ_{η}, φ) and lim_{η \to \infty} λ (φ, ϑ_{η}), \end{matrix}

exist and are finite. Then Γ has a unique fixed point.

Proof.

Fix

ϑ_{0} \in Λ

and

φ_{0} \in Θ

and assume that

Γ (ϑ_{η}) = ϑ_{n + 1}

and

Γ (φ_{η}) = φ_{n + 1}

for all

η \in N \cup {0}

. Then we obtain

(ϑ_{η}, φ_{η})

as a bisequence on fuzzy triple controlled bipolar metric space

(Λ, Θ, Π_{ϱ}, *)

. Now, we have

\begin{matrix} Π_{ϱ} (ϑ_{1}, φ_{1}, τ) = Π_{ϱ} (Γ (ϑ_{0}), Γ (φ_{0}), τ) \geq Π_{ϱ} (ϑ_{0}, φ_{0}, \frac{τ}{κ}) \end{matrix}

for all

τ > 0

and

η \in N

. By simple induction, we obtain

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{η}, τ) = Π_{ϱ} (Γ (ϑ_{n - 1}), Γ (φ_{n - 1}), τ) \geq Π_{ϱ} (ϑ_{0}, φ_{0}, \frac{τ}{κ^{η}}) \end{matrix}

(5)

and

\begin{matrix} Π_{ϱ} (ϑ_{n + 1}, φ_{η}, τ) = Π_{ϱ} (Γ (ϑ_{η}), Γ (φ_{n - 1}), τ) \geq Π_{ϱ} (ϑ_{1}, φ_{0}, \frac{τ}{κ^{η}}) \end{matrix}

(6)

for all

τ > 0

and

η \in N

. Let

η < ω

for

η, ω \in N

. Then,

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) \geq & Π_{ϱ} (ϑ_{η}, φ_{η}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η}, \frac{τ}{3 α (ϑ_{η + 1}, φ_{η})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{ω}, \frac{τ}{3 β (ϑ_{η + 1}, φ_{ω})}) \\ \geq Π_{ϱ} (ϑ_{η}, φ_{η}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η}, \frac{τ}{3 α (ϑ_{η + 1}, φ_{η})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η + 1}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) λ (ϑ_{η + 1}, φ_{η + 1})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 2}, φ_{η + 1}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) α (ϑ_{η + 2}, φ_{η + 1})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 2}, φ_{ω}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω})}) \\ \geq Π_{ϱ} (ϑ_{η}, φ_{η}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η}, \frac{τ}{3 α (ϑ_{η + 1}, φ_{η})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η + 1}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) λ (ϑ_{η + 1}, φ_{η + 1})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 2}, φ_{η + 1}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) α (ϑ_{η + 2}, φ_{η + 1})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 2}, φ_{η + 2}, \frac{τ}{3^{3} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) λ (ϑ_{η + 2}, φ_{η + 2})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 3}, φ_{η + 2}, \frac{τ}{3^{3} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) α (ϑ_{η + 3}, φ_{η + 2})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 3}, φ_{ω}, \frac{τ}{3^{3} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) β (ϑ_{η + 3}, φ_{ω})}) \\ \geq Π_{ϱ} (ϑ_{η}, φ_{η}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η}, \frac{τ}{3 λ (ϑ_{η + 1}, φ_{η})}) 🟉 \dots \\ 🟉 Π_{ϱ} (ϑ_{ω - 1}, φ_{ω - 1}, \frac{τ}{3^{ω - 1} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) \dots λ (ϑ_{ω - 1}, φ_{ω - 1})}) \\ 🟉 Π_{ϱ} (ϑ_{ω}, φ_{ω - 1}, \frac{τ}{3^{ω - 1} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) \dots α (ϑ_{ω}, φ_{ω - 1})}) \\ 🟉 Π_{ϱ} (ϑ_{ω}, φ_{ω}, \frac{τ}{3^{ω - 1} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) \dots β (ϑ_{ω}, φ_{ω})}) . \end{matrix}

Now, applying (5) and (6) on each term of the right-hand side of the above inequality, we obtain

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) & \geq Π_{ϱ} (ϑ_{0}, φ_{0}, \frac{τ}{3 κ^{η} λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{1}, φ_{0}, \frac{τ}{3 κ^{η + 1} λ (ϑ_{η + 1}, φ_{η})}) \\ 🟉 \dots \dots 🟉 Π_{ϱ} (ϑ_{0}, φ_{0}, \frac{τ}{3^{ω - 1} κ^{ω} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) \dots β (ϑ_{ω}, φ_{ω})}) . \end{matrix}

From (4), as

η, ω \to \infty

, we obtain

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) \geq 1 for all τ > 0 . \end{matrix}

Therefore, bisequence

(ϑ_{η}, φ_{η})

is a Cauchy bisequence. Since

(Λ, Θ, Π_{ϱ}, *)

is a complete space, bisequence

(ϑ_{η}, φ_{η})

is a convergent Cauchy bisequence. According to Proposition 1, the bisequence

(ϑ_{η}, φ_{η})

is a biconvergent sequence.

As bisequence

(ϑ_{η}, φ_{η})

is biconvergent, there exists a point

μ \in Λ \cap Θ

which is a limit of both sequences

{ϑ_{η}}

and

{φ_{η}}

. By Lemma 2, both sequences

{ϑ_{η}}

and

{φ_{η}}

have a unique limit. From (FCB4), consider

\begin{matrix} Π_{ϱ} (Γ (μ), μ, τ) & \geq Π_{ϱ} (Γ (μ), Γ (φ_{η}), \frac{τ}{3 λ (μ, φ_{η})}) * Π_{ϱ} (Γ (ϑ_{η}), Γ (φ_{η}), \frac{τ}{3 α (ϑ_{η}, φ_{η})}) \\ * Π_{ϱ} (Γ (ϑ_{η}), μ, \frac{τ}{3 β (ϑ_{η}, μ)}) \end{matrix}

for all

η \in N

and

τ > 0

. As

η \to \infty

, we have

\begin{matrix} Π_{ϱ} (Γ (μ), μ, τ) \to 1 * 1 * 1 = 1 . \end{matrix}

From (FCB2), we obtain

Γ (μ) = μ

. Let

ν \in Λ \cap Θ

be another fixed point of

Γ

. Then

\begin{matrix} Π_{ϱ} (μ, ν, τ) = Π_{ϱ} (Γ (μ), Γ (ν), τ) \geq Π_{ϱ} (μ, ν, \frac{τ}{κ}) \end{matrix}

for

κ \in (0, 1)

and for all

τ > 0

. By Lemma 1, we obtain

μ = ν

. □

Example 3.

Let

Λ = [0, 1]

,

Θ = {0} \cup N - {1}

and

λ, α, β : Λ \times Θ \to [1, \infty)

be three non-comparable mappings defined as

λ (ϑ, φ) = ϑ + φ + 1

,

α (ϑ, φ) = ϑ^{2} + φ + 1

and

β (ϑ, φ) = ϑ^{2} + φ - 1

. Define

Π_{ϱ} (ϑ, φ, τ) = \frac{τ}{τ + | ϑ - φ |}

for all

τ > 0

and

ϑ \in Λ

and

φ \in Θ

. Clearly,

(Λ, Θ, Π_{ϱ}, *)

is a complete fuzzy triple controlled bipolar metric space, where * is a continuous τ-norm defined as

σ * ϱ = σ ϱ

.

Define

Γ : Λ \cup Θ \to Λ \cup Θ

by

Γ (μ) = \{\begin{matrix} \frac{μ}{2}, & if μ \in [0, 1], \\ 0, & if μ \in N - {1}, \end{matrix}

for all

μ \in Λ \cup Θ

. Clearly, all the hypotheses of Theorem 1 are satisfied. Hence Γ has a unique fixed point, i.e.,

μ = 0

.

Theorem 2.

Let

(Λ, Θ, Π_{ϱ}, *)

be a complete fuzzy triple controlled bipolar metric space with three non-comparable functions

λ, α, β : Λ \times Θ \to [1, \infty)

such that

\begin{matrix} lim_{τ \to \infty} Π_{ϱ} (ϑ, φ, τ) = 1 for all ϑ \in Λ, φ \in Θ . \end{matrix}

(7)

Let

Γ : Λ \cup Θ \to Λ \cup Θ

be a mapping satisfying

(i): $Γ (Λ) \subseteq Θ$ and $Γ (Θ) \subseteq Λ$ ;
(ii): $Π_{ϱ} (Γ (φ), Γ (ϑ), κ τ) \geq Π_{ϱ} (ϑ, φ, τ)$ , for all $ϑ \in Λ, φ \in Θ$ and $τ > 0$ , where $κ \in (0, 1)$ .

Then Γ has a unique fixed point.

Proof.

Fix

ϑ_{0} \in Λ

and assume that

Γ (ϑ_{η}) = φ_{η}

and

Γ (φ_{η}) = ϑ_{η + 1}

for all

η \in N \cup {0}

. Then, we obtain

(ϑ_{η}, φ_{η})

as a bisequence on fuzzy triple controlled bipolar metric space

(Λ, Θ, Π_{ϱ}, *)

. Now, we have

\begin{matrix} Π_{ϱ} (ϑ_{1}, φ_{0}, τ) = Π_{ϱ} (Γ (φ_{0}), Γ (ϑ_{0}), τ) \geq Π_{ϱ} (ϑ_{0}, φ_{0}, \frac{τ}{κ}) \end{matrix}

for all

τ > 0

and

η \in N

. By simple induction, we obtain

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{η}, τ) = Π_{ϱ} (Γ (φ_{η - 1}), Γ (ϑ_{η}), τ) \geq Π_{ϱ} (ϑ_{0}, φ_{0}, \frac{τ}{κ^{2 η}}) \end{matrix}

(8)

and

\begin{matrix} Π_{ϱ} (ϑ_{η + 1}, φ_{η}, τ) = Π_{ϱ} (Γ (φ_{η}), Γ (ϑ_{η}), τ) \geq Π_{ϱ} (ϑ_{0}, φ_{0}, \frac{τ}{κ^{2 η + 1}}) \end{matrix}

(9)

for all

τ > 0

and

η \in N

. Let

η < ω

, for

η, ω \in N

. Then,

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) \geq & Π_{ϱ} (ϑ_{η}, φ_{η}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η}, \frac{τ}{3 α (ϑ_{η + 1}, φ_{η})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{ω}, \frac{τ}{3 β (ϑ_{η + 1}, φ_{ω})}) \\ \geq Π_{ϱ} (ϑ_{η}, φ_{η}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η}, \frac{τ}{3 α (ϑ_{η + 1}, φ_{η})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η + 1}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) λ (ϑ_{η + 1}, φ_{η + 1})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 2}, φ_{η + 1}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) α (ϑ_{η + 2}, φ_{η + 1})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 2}, φ_{ω}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω})}) \\ \geq Π_{ϱ} (ϑ_{η}, φ_{η}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η}, \frac{τ}{3 α (ϑ_{η + 1}, φ_{η})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η + 1}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) λ (ϑ_{η + 1}, φ_{η + 1})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 2}, φ_{η + 1}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) α (ϑ_{η + 2}, φ_{η + 1})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 2}, φ_{η + 2}, \frac{τ}{3^{3} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) λ (ϑ_{η + 2}, φ_{η + 2})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 3}, φ_{η + 2}, \frac{τ}{3^{3} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) α (ϑ_{η + 3}, φ_{η + 2})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 3}, φ_{ω}, \frac{τ}{3^{3} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) β (ϑ_{η + 3}, φ_{ω})}) \\ \geq Π_{ϱ} (ϑ_{η}, φ_{η}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η}, \frac{τ}{3 λ (ϑ_{η + 1}, φ_{η})}) 🟉 \dots \\ 🟉 Π_{ϱ} (ϑ_{ω - 1}, φ_{ω - 1}, \frac{τ}{3^{ω - 1} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) \dots λ (ϑ_{ω - 1}, φ_{ω - 1})}) \\ 🟉 Π_{ϱ} (ϑ_{ω}, φ_{ω - 1}, \frac{τ}{3^{ω - 1} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) \dots α (ϑ_{ω}, φ_{ω - 1})}) \\ 🟉 Π_{ϱ} (ϑ_{ω}, φ_{ω}, \frac{τ}{3^{ω - 1} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) \dots β (ϑ_{ω}, φ_{ω})}) . \end{matrix}

Now applying (5) and (6) on each term of the right-hand side of the above inequality, we obtain

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) & \geq Π_{ϱ} (ϑ_{0}, φ_{0}, \frac{τ}{3 κ^{2 η} λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{0}, φ_{0}, \frac{τ}{3 κ^{2 η + 1} λ (ϑ_{η + 1}, φ_{η})}) \\ 🟉 \dots \dots 🟉 Π_{ϱ} (ϑ_{0}, φ_{0}, \frac{τ}{3^{ω - 1} κ^{2 ω} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) \dots β (ϑ_{ω}, φ_{ω})}) . \end{matrix}

From (7), as

η, ω \to \infty

, we obtain

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) \geq 1 for all τ > 0 . \end{matrix}

Therefore, bisequence

(ϑ_{η}, φ_{η})

is a Cauchy bisequence. Since

(Λ, Θ, Π_{ϱ}, *)

is a complete space, bisequence

(ϑ_{η}, φ_{η})

is a convergent Cauchy bisequence. According to Proposition 1, the bisequence

(ϑ_{η}, φ_{η})

is a biconvergent sequence. As bisequence

(ϑ_{η}, φ_{η})

is biconvergent, there exists a point

μ \in Λ \cap Θ

which is a limit of both sequences

{ϑ_{η}}

and

{φ_{η}}

. By Lemma 2, both sequences

{ϑ_{η}}

and

{φ_{η}}

have a unique limit. From (FCB4), consider

\begin{matrix} Π_{ϱ} (Γ (μ), μ, τ) & \geq Π_{ϱ} (Γ (μ), Γ (ϑ_{η}), \frac{τ}{3 λ (Γ (μ), Γ (ϑ_{η}))}) \\ * Π_{ϱ} (Γ (φ_{η}), Γ (ϑ_{η}), \frac{τ}{3 α (Γ (φ_{η}), Γ (ϑ_{η}))}) \\ * Π_{ϱ} (μ, Γ (ϑ_{η}), \frac{τ}{3 β (μ, Γ (ϑ_{η}))}), \end{matrix}

for all

η \in N

and

τ > 0

. As

η \to \infty

, we have

\begin{matrix} Π_{ϱ} (Γ (μ), μ, τ) \to 1 * 1 * 1 = 1 . \end{matrix}

From (FCB2), we get

Γ (μ) = μ

. Let

ν \in Λ \cap Θ

be another fixed point of

Γ

. Then

\begin{matrix} Π_{ϱ} (μ, ν, τ) = Π_{ϱ} (Γ (ν), Γ (μ), τ) \geq Π_{ϱ} (μ, ν, \frac{τ}{κ}) \end{matrix}

for

κ \in (0, 1)

and for all

τ > 0

. By Lemma 1, we obtain

μ = ν

. □

Example 4.

Let

Λ = [0, 1]

,

Θ = {0} \cup N - {1}

and

λ, α, β : Λ \times Θ \to [1, \infty)

be three non-comparable mappings defined as

λ (ϑ, φ) = ϑ + φ + 1

,

α (ϑ, φ) = ϑ^{2} + φ + 1

and

β (ϑ, φ) = ϑ^{2} + φ - 1

. Define

\begin{matrix} Π_{ϱ} (ϑ, φ, τ) = e^{- \frac{{(ϑ - φ)}^{2}}{τ}}, \forall ϑ \in Λ, φ \in Θ, τ > 0 . \end{matrix}

Then

(Λ, Θ, Π_{ϱ}, *)

is a complete fuzzy triple controlled bipolar metric space with product τ-norm. Define

Γ : Λ \cup Θ \to Λ \cup Θ

by

Γ (μ) = \{\begin{matrix} \frac{1 - 2^{- μ}}{3}, & if μ \in [0, 1], \\ 0, & if μ \in N - {1}, \end{matrix}

for all

μ \in Λ \cup Θ

. Let

ϑ \in [0, 1]

and

φ \in N - {1}

, then

\begin{matrix} Π_{ϱ} (Γ (ϑ), Γ (φ), κ τ) & = Π_{ϱ} (\frac{1 - 2^{- ϑ}}{3}, 0, κ τ) \\ = e^{- \frac{{(\frac{1 - 2^{- ϑ}}{3})}^{2}}{κ τ}} \\ \geq e^{- \frac{{(ϑ - φ)}^{2}}{τ}} \\ = Π_{ϱ} (ϑ, φ, τ) . \end{matrix}

Therefore, all the hypotheses of Theorem 2 are satisfied. Hence Γ has a unique fixed point, i.e.,

μ = 0

.

Theorem 3.

Let

(Λ, Θ, Π_{ϱ}, *)

be a complete fuzzy triple controlled bipolar metric space with three non-comparable functions

λ, α, β : Λ \times Θ \to [1, \infty)

and

Γ : Λ \cup Θ \to Λ \cup Θ

, a mapping satisfying

(i): $Γ (Λ) \subseteq Λ$ and $Γ (Θ) \subseteq Θ$ ;
(ii): For $ϑ \in Λ, φ \in Θ$ and $τ > 0, Π_{ϱ} (ϑ, φ, τ) > 0 \Rightarrow Π_{ϱ} (Γ (ϑ), Γ (φ), τ) \geq Π (Π_{ϱ} (ϑ, φ, τ))$ , where $Π : (0, 1] \to (0, 1]$ is an increasing function such that ${lim}_{η \to \infty} Π^{η} (κ) = 1$ and $Π (κ) \geq κ$ for all $κ \in (0, 1]$ .

Then Γ has a fixed point.

Proof.

Let

ϑ_{0} \in Λ

and

φ_{0} \in Θ

such that

Γ (ϑ_{η}) = ϑ_{η + 1}

and

Γ (φ_{η}) = φ_{η + 1}

for all

η \in N \cup {0}

, then

(ϑ_{η}, φ_{η})

be a bisequence on fuzzy triple controlled bipolar metric space

(Λ, Θ, Π_{ϱ}, *)

. By the definition of (FCB2) for all

τ > 0

and condition b, we have

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{η}, τ) \geq Π^{η} (Π_{ϱ} (ϑ_{0}, φ_{0}, τ)) \end{matrix}

(10)

and

\begin{matrix} Π_{ϱ} (ϑ_{η + 1}, φ_{η}, τ) \geq Π^{η} (Π_{ϱ} (ϑ_{1}, φ_{0}, τ)) . \end{matrix}

(11)

Let

η < ω

, for

η, ω \in N

. Then

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) \geq & Π_{ϱ} (ϑ_{η}, φ_{η}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η}, \frac{τ}{3 α (ϑ_{η + 1}, φ_{η})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{ω}, \frac{τ}{3 β (ϑ_{η + 1}, φ_{ω})}) \\ \geq Π_{ϱ} (ϑ_{η}, φ_{η}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η}, \frac{τ}{3 α (ϑ_{η + 1}, φ_{η})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η + 1}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) λ (ϑ_{η + 1}, φ_{η + 1})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 2}, φ_{η + 1}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) α (ϑ_{η + 2}, φ_{η + 1})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 2}, φ_{ω}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω})}) \\ \geq Π_{ϱ} (ϑ_{η}, φ_{η}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η}, \frac{τ}{3 α (ϑ_{η + 1}, φ_{η})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η + 1}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) λ (ϑ_{η + 1}, φ_{η + 1})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 2}, φ_{η + 1}, \frac{τ}{3^{2} β (ϑ_{η + 1}, φ_{ω}) α (ϑ_{η + 2}, φ_{η + 1})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 2}, φ_{η + 2}, \frac{τ}{3^{3} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) λ (ϑ_{η + 2}, φ_{η + 2})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 3}, φ_{η + 2}, \frac{τ}{3^{3} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) α (ϑ_{η + 3}, φ_{η + 2})}) \\ 🟉 Π_{ϱ} (ϑ_{η + 3}, φ_{ω}, \frac{τ}{3^{3} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) β (ϑ_{η + 3}, φ_{ω})}) \\ \geq Π_{ϱ} (ϑ_{η}, φ_{η}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})}) 🟉 Π_{ϱ} (ϑ_{η + 1}, φ_{η}, \frac{τ}{3 λ (ϑ_{η + 1}, φ_{η})}) 🟉 \dots \\ 🟉 Π_{ϱ} (ϑ_{ω - 1}, φ_{ω - 1}, \frac{τ}{3^{ω - 1} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) \dots λ (ϑ_{ω - 1}, φ_{ω - 1})}) \\ 🟉 Π_{ϱ} (ϑ_{ω}, φ_{ω - 1}, \frac{τ}{3^{ω - 1} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) \dots α (ϑ_{ω}, φ_{ω - 1})}) \\ 🟉 Π_{ϱ} (ϑ_{ω}, φ_{ω}, \frac{τ}{3^{ω - 1} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) \dots β (ϑ_{ω}, φ_{ω})}) . \end{matrix}

Now applying (10) and (11) on each term of the right-hand side of the above inequality, we obtain

\begin{matrix} Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) & \geq Π^{η} (Π_{ϱ} (ϑ_{0}, φ_{0}, \frac{τ}{3 λ (ϑ_{η}, φ_{η})})) 🟉 Π^{η} (Π_{ϱ} (ϑ_{1}, φ_{0}, \frac{τ}{3 λ (ϑ_{η + 1}, φ_{η})})) \\ 🟉 \dots \dots 🟉 Π^{η} (Π_{ϱ} (ϑ_{0}, φ_{0}, \frac{τ}{3^{ω - 1} β (ϑ_{η + 1}, φ_{ω}) β (ϑ_{η + 2}, φ_{ω}) \dots β (ϑ_{ω}, φ_{ω})})) . \end{matrix}

As

η, ω \to \infty

, we have

Π_{ϱ} (ϑ_{η}, φ_{ω}, τ) \to 1

for all

τ > 0

. Apply the same lines of the proof of Theorem 1 here. We have, if

μ \in Λ \cap Θ

is a unique limit of sequences,

{ϑ_{η}}

and

{φ_{η}}

, then we have to show

μ

is a fixed point of

Γ

. Since we have

Π_{ϱ} (ϑ_{η}, μ, τ) \to τ

for all

τ > 0

and

Π_{ϱ} (ϑ_{η + 1}, Γ (μ), τ) = Π_{ϱ} (Γ (ϑ_{η}), Γ (μ), τ) \geq Π (Π_{ϱ} (ϑ_{η}, μ, τ)) \geq Π_{ϱ} (ϑ_{η}, μ, τ)

, it follows that

ϑ_{η + 1} \to Γ (μ)

, which implies that

Γ (μ) = μ

. □

Example 5.

Let

Λ = {2, 4, 5, 6}, Θ = {1, 2}, σ * ϱ = σ ϱ

for all

σ, ϱ \in [0, 1]

and

λ, α, β : Λ \times Θ \to [1, \infty)

be three non-comparable mappings defined as

λ (ϑ, φ) = ϑ + φ + 1

,

α (ϑ, φ) = ϑ^{2} + φ + 1

and

β (ϑ, φ) = ϑ^{2} + φ - 1

. Define

\begin{matrix} Π_{ϱ} (ϑ, φ, τ) = \frac{min {ϑ, φ} + τ}{max {ϑ, φ} + τ} for all ϑ \in Λ, φ \in Θ and for all τ > 0 . \end{matrix}

Then

(Λ, Θ, Π_{ϱ}, *)

is a complete fuzzy triple controlled bipolar metric space. Now, define

Π : (0, 1] \to (0, 1]

such that

Π (κ) = \sqrt{κ}

. Clearly,

Π (κ) = \sqrt{κ}

satisfies the conditions of the Π function.

Let

Γ : Λ \cup Θ \to Λ \cup Θ

be a mapping such that

Γ (2) = Γ (4) = Γ (1) = 2, Γ (5) = Γ (6) = 4

. Then all the conditions of Theorem 3 are satisfied. The fixed point of Γ is

ϑ = 2

.

Theorem 4.

Let

(Λ, Θ, Π_{ϱ}, *)

be a complete fuzzy triple controlled bipolar metric space with three noncomparable functions

λ, α, β : Λ \times Θ \to [1, \infty)

and

Γ : Λ \cup Θ \to Λ \cup Θ

, a mapping satisfying the following:

(i): $Γ (Λ) \subseteq Θ$ and $Γ (Θ) \subseteq Λ$ ;
(ii): For $ϑ \in Λ, φ \in Θ$ and $τ > 0, Π_{ϱ} (ϑ, φ, τ) > 0 ⟹ Π_{ϱ} (Γ (φ), Γ (ϑ), τ) \geq Π (Π_{ϱ} (ϑ, φ, τ))$ .

Then Γ has a fixed point.

Proof.

The proof of the theorem follows along the lines of the proof of Theorem 3 and Theorem 2. □

4. Application

In this section, we study the existence and uniqueness of the solution of an integral equation as an application of Theorem 1.

Theorem 5.

Let us consider the integral equation

\begin{matrix} ϑ (ρ) = ϱ (ρ) + \int_{Ξ_{1} \cup Ξ_{2}} Ω (ρ, ς, ϑ (ς)) d ς, ρ \in Ξ_{1} \cup Ξ_{2}, \end{matrix}

where

Ξ_{1} \cup Ξ_{2}

is a Lebesgue measurable set. Suppose

(T1): $Ω : (Ξ_{1}^{2} \cup Ξ_{2}^{2}) \times [0, \infty) \to [0, \infty)$ and $b \in L^{\infty} (Ξ_{1}) \cup L^{\infty} (Ξ_{2})$ ;
(T2): There is a continuous function $θ : Ξ_{1}^{2} \cup Ξ_{2}^{2} \to [0, \infty)$ and $κ \in (0, 1)$ such that

$\begin{matrix} | Ω (ρ, ς, ϑ (ς)) - Ω (ρ, ς, φ (ς)) | \leq κ θ (ρ, ς) (| ϑ (ρ) - φ (ρ) |), \end{matrix}$

for $ρ, ς \in Ξ_{1}^{2} \cup Ξ_{2}^{2}$ ,
(T3): ${sup}_{ρ \in Ξ_{1} \cup Ξ_{2}} \int_{Ξ_{1} \cup Ξ_{2}} θ (ρ, ς) d ς \leq 1$ .

Then the integral equation has a unique solution in

L^{\infty} (Ξ_{1}) \cup L^{\infty} (Ξ_{2})

.

Proof.

Let

Λ = L^{\infty} (Ξ_{1})

and

Θ = L^{\infty} (Ξ_{2})

be two normed linear spaces, where

Ξ_{1}, Ξ_{2}

are Lebesgue measurable sets and

m (Ξ_{1} \cup Ξ_{2}) < \infty

.

Consider

Π_{ϱ} : Λ \times Θ \times (0, \infty) \to [0, 1]

by

\begin{matrix} Π_{ϱ} (ϑ, φ, τ) = e^{- \frac{{sup}_{ρ \in Ξ_{1} \cup Ξ_{2}} | ϑ (ρ) - φ (ρ) |}{τ}} . \end{matrix}

for all

ϑ \in Λ, φ \in Θ

. Define

λ, α, β : Λ \times Θ \to [1, \infty)

as three non-comparable mappings defined as

λ (ϑ, φ) = ϑ + φ + 1

,

α (ϑ, φ) = ϑ^{2} + φ + 1

and

β (ϑ, φ) = ϑ^{2} + φ - 1

. Then

(Λ, Θ, Π_{ϱ}, 🟉)

is a complete fuzzy triple controlled bipolar metric space. Define a mapping

Γ : L^{\infty} (Ξ_{1}) \cup L^{\infty} (Ξ_{2}) \to L^{\infty} (Ξ_{1}) \cup L^{\infty} (Ξ_{2})

by

\begin{matrix} Γ (ϑ (ρ)) = ϱ (ρ) + \int_{Ξ_{1} \cup Ξ_{2}} Ω (ρ, ς, ϑ (ς)) d ς, ρ \in Ξ_{1} \cup Ξ_{2} . \end{matrix}

Now, we have

\begin{matrix} Π_{ϱ} (Γ ϑ (ρ), Γ φ (ρ), κ τ) & = e^{- {sup}_{ρ \in Ξ_{1} \cup Ξ_{2}} \frac{| Γ ϑ (ρ) - Γ φ (ρ) |}{κ τ}} \\ = e^{- {sup}_{ρ \in Ξ_{1} \cup Ξ_{2}} \frac{| ϱ (ρ) + \int_{Ξ_{1} \cup Ξ_{2}} Ω (ρ, ς, ϑ (ς)) d ς - ϱ (ρ) - \int_{Ξ_{1} \cup Ξ_{2}} Ω (ρ, ς, φ (ς)) d ς) |}{κ τ}} \\ = e^{- {sup}_{ρ \in Ξ_{1} \cup Ξ_{2}} \frac{| ϱ (\int_{Ξ_{1} \cup Ξ_{2}} Ω (τ, ς, ϑ (ς)) d ς - \int_{Ξ_{1} \cup Ξ_{2}} Ω (τ, ς, φ (ς)) d ς |}{κ τ}} \\ \geq e^{- {sup}_{ρ \in Ξ_{1} \cup Ξ_{2}} \frac{\int_{Ξ_{1} \cup Ξ_{2}} | Ω (ρ, ς, ϑ (ς)) - Ω (ρ, ς, φ (ς)) | d ς}{κ τ}} \\ \geq e^{- {sup}_{ρ \in Ξ_{1} \cup Ξ_{2}} \frac{\int_{Ξ_{1} \cup Ξ_{2}} κ θ (ρ, ς) (| ϑ (ρ) - φ (ρ) |) d ς}{κ τ}} \\ \geq e^{- {sup}_{ρ \in Ξ_{1} \cup Ξ_{2}} \frac{\int_{Ξ_{1} \cup Ξ_{2}} κ θ (ρ, ς) (| ϑ (ρ) - φ (ρ) |) d ς}{κ τ}} \\ \geq e^{- {sup}_{ρ \in Ξ_{1} \cup Ξ_{2}} \frac{| ϑ (ρ) - φ (ρ) |}{τ}} \\ = Π_{ϱ} (ϑ, φ, τ) . \end{matrix}

Hence, all the hypotheses of Theorem 1 are verified, and consequently, the integral equation has a unique solution. □

5. Conclusions

Motivated by the recent result of Sezen [17], we introduce the notion of fuzzy triple controlled bipolar metric space. In these spaces, we proved some fixed-point results in this framework. Our results generalize and extend some of the well-known results from the literature. In addition, as an application of our results, we show that some classes of integral equations have a unique solution. The examples that are given have the role of strengthening the obtained results.

We find it interesting to research, in future works, other conditions that would guarantee the existence of fixed points in fuzzy triple controlled bipolar metric spaces.

Author Contributions

All authors contributed equally. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The last author would like to thank Babeş-Bolyai University for the support.

Conflicts of Interest

The authors declare no conflict of interest.

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Mani, G.; Gnanaprakasam, A.J.; Mitrović, Z.D.; Bota, M.-F. Solving an Integral Equation via Fuzzy Triple Controlled Bipolar Metric Spaces. Mathematics 2021, 9, 3181. https://0-doi-org.brum.beds.ac.uk/10.3390/math9243181

AMA Style

Mani G, Gnanaprakasam AJ, Mitrović ZD, Bota M-F. Solving an Integral Equation via Fuzzy Triple Controlled Bipolar Metric Spaces. Mathematics. 2021; 9(24):3181. https://0-doi-org.brum.beds.ac.uk/10.3390/math9243181

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Mani, Gunaseelan, Arul Joseph Gnanaprakasam, Zoran D. Mitrović, and Monica-Felicia Bota. 2021. "Solving an Integral Equation via Fuzzy Triple Controlled Bipolar Metric Spaces" Mathematics 9, no. 24: 3181. https://0-doi-org.brum.beds.ac.uk/10.3390/math9243181

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Solving an Integral Equation via Fuzzy Triple Controlled Bipolar Metric Spaces

Abstract

1. Introduction

2. Preliminaries

3. Main Results

4. Application

5. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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