Relational Strict Almost Contractions Employing Test Functions and an Application to Nonlinear Integral Equations

Abstract

The present study deals with some fixed-point outcomes under a nonlinear formulation of strict almost contractions in a metric space endued with an arbitrary relation. The outcomes established herein enhance and develop various existing outcomes. To convince you of the infallibility of our outcomes, a few examples are presented. We apply our findings to investigate the validity of the unique solution of a nonlinear integral problem.

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1. Introduction

An essential and significant outcome of the theory of metrical fixed points is the Banach contraction principle (BCP). Indeed, BCP guarantees that a contraction on a complete metric space (MS) owns a unique fixed point. This outcome additionally offers a way to estimate the unique fixed point. Many generalizations of the BCP can be found in the literature. BCP and its generalizations are applicable for solving many real world problems (c.f. [1,2]).

A novel and straightforward version of BCP was presented in 2015 by Alam and Imdad [3]. In this version, the metric space is supplied with a relation, and the map preserves this relation. Because of creativity, the findings of Alam and Imdad [3] has been extended and refined by plenty of researchers, e.g., [4,5,6,7,8,9,10,11,12,13,14]. One of the main characteristics of relational contractions is that the contraction-inequality must be satisfied for comparative elements only, not for every pair of elements. It turns out that relational contractions turn out to be weaker than corresponding ordinary contractions and, therefore, they can be used to solve certain types of integral equations and boundary value problems; meanwhile, the outcomes on fixed points of ordinary metric space are not.

In 2004, Berinde [15] implemented a new generalization of BCP, referred to as almost contraction.

Definition 1

([15]). A self-mapping $P$ on a MS $(Z, ϱ)$ is named an almost contraction if there exist $0 < γ < 1$ and $K \geq 0$ , enjoying

$ϱ (P z, P w) \leq γ ϱ (z, w) + K ϱ (z, P w), for all z, w \in Z .$

Owing to symmetry of $ϱ$ , the preceding condition is identical to the following one:

$ϱ (P z, P w) \leq γ ϱ (z, w) + K ϱ (w, P z), for all z, w \in Z .$

Theorem 1

([15]). An almost contraction on a complete MS possesses a fixed point.

The concept of almost contractions has been developed by a number of researchers; for instance, see [16,17,18,19,20,21,22,23,24]. The almost contraction is not uniquely fixed, but Picard’s iterative sequence continues to converge to a fixed point. To formulate a uniqueness theorem, Babu et al. [19] formulated a significantly limited class of almost contractions.

Theorem 2

([19]). Let $P$ be a self-map on a complete MS $(Z, ϱ)$ . If there exist $0 < γ < 1$ and $K \geq 0$ , enjoying

$ϱ (P z, P w) \leq γ ϱ (z, w) + K min {ϱ (z, P w), ϱ (w, P z), ϱ (z, P z), ϱ (w, P w)}, for all z, w \in Z,$

then $P$ possesses a unique fixed point.

With influence from Berinde [15], Turinici [25] proposed the class $Ψ$ of functions $ψ : [0, + \infty) \to [0, + \infty)$ that verifies

$ψ (0) = 0 a n d lim_{r \to 0} ψ (r) = 0 .$

This article deals with the following nonlinear variant of contraction-inequality utilized in Theorem 2 under a binary relation:

$\begin{matrix} ϱ (P z, P w) \leq γ ϱ (z, w) + min {ψ (ϱ (z, P w)), ψ (ϱ (w, P z)), ψ (ϱ (z, P z)), ψ (ϱ (w, P w))} . \end{matrix}$

We incorporate a few examples to demonstrate our findings. By employing our findings, we carry out the unique solution of nonlinear integral equations, verifying some additional hypotheses.

2. Relation-Theoretic Notions

As usual, the sets $R$ , $N$ , and $N_{0}$ will denote, respectively, the sets of: real numbers, natural numbers, and whole numbers. A subset of $Z^{2}$ is defined as a relation ℜ on a set $Z$ . In the concepts that follow, $Z$ will be considered the ambient set, $ϱ$ will be a metric on $Z$ , ℜ will be a relation on $Z$ , and $P : Z \to Z$ will be a mapping.

Definition 2

([3]). $z, w \in Z$ are referred to as ℜ-comparative, symbolized by $[z, w] \in ℜ$ , if

$(z, w) \in ℜ o r (w, z) \in ℜ .$

Definition 3

([26]). $ℜ^{- 1} : = {(z, w) \in Z^{2} : (w, z) \in ℜ}$ is referred to as the inverse of ℜ.

Definition 4

([26]). $ℜ^{s} : = ℜ \cup ℜ^{- 1}$ is referred to as the symmetric closure of ℜ.

Proposition 1

([3]). $(z, w) \in ℜ^{s} \Leftrightarrow [z, w] \in ℜ$ .

Definition 5

([3]). ℜ is referred to as $P$ -closed if

$(z, w) \in ℜ \Rightarrow (P z, P w) \in ℜ .$

For example, if we consider a self-map $P$ on the partially ordered set $(Z, ⪯)$ , then the ‘ $P$ -closedness of relation ⪯’ is equivalent to saying that $P$ is ⪯-increasing.

Proposition 2

( [5]). ℜ is $P^{n}$ -closed for every $n \in N$ , whenever ℜ is $P$ -closed.

Definition 6

([27]). $W \subseteq Z$ is referred to as ℜ-directed set if, for every $z, w \in W$ , $there exists$ $u \in Z$ with $(z, u) \in ℜ$ and $(w, u) \in ℜ$ .

Definition 7

([3]). A sequence ${z_{n}} \subset Z$ is referred to as ℜ-preserving if $(z_{n}, z_{n + 1}) \in ℜ$ , $for all$ $n \in N_{0}$ .

Definition 8

([3]). ℜ is referred to as ϱ-self-closed if convergence limit of any ℜ-preserving convergent sequence in $(Z, ϱ)$ is ℜ-comparative with each term of a subsequence.

Definition 9

([4]). $P$ is referred to as ℜ-continuous if, for all $z \in Z$ , and for any ℜ-preserving sequence ${z_{n}} \subset Z$ , we verify $z_{n} \overset{ϱ}{⟶} z$ ,

$P (z_{n}) \overset{ϱ}{⟶} P (z) .$

Definition 10

([4]). A MS $(Z, ϱ)$ is referred to as ℜ-complete if each ℜ-preserving Cauchy sequence converges.

Proposition 3

([5]). If ℜ is $P$ -closed, then for each $n \in N_{0}$ , ℜ is $P^{n}$ -closed.

Proposition 4.

For any $0 < γ < 1$ and $ψ \in Ψ$ , (I) and (II) are equivalent:

(I). $ϱ (P z, P w) \leq γ ϱ (z, w) + min {ψ (ϱ (z, P z)), ψ (ϱ (w, P w)), ψ (ϱ (z, P w)), ψ (ϱ (w, P z))}, for all (z, w) \in ℜ$ ;
(II). $ϱ (P z, P w) \leq γ ϱ (z, w) + min {ψ (ϱ (z, P z)), ψ (ϱ (w, P w)), ψ (ϱ (z, P w)), ψ (ϱ (w, P z))}, for all [z, w] \in ℜ$ .

Proof.

The conclusion is followed using the symmetry of $ϱ$ . □

3. Main Results

We are now going to demonstrate the following outcomes, ensuring the fixed-point of certain class of nonlinear almost contractions in relational MS (i.e., MS comprised with a relation).

Theorem 3.

Assume that $(Z, ϱ)$ continues to be a MS comprised with a relation ℜ, while $P : Z \to Z$ remains a map. Also,

(a). ℜ is $P$ -closed;
(b). $(Z, ϱ)$ is ℜ-complete;
(c). $There exists$ $z_{0} \in Z$ for which $(z_{0}, P z_{0}) \in ℜ$ ;
(d). $P$ remains ℜ-continuous or ℜ is ϱ-self-closed;
(e). $There exists$ $0 \leq γ < 1$ and $ψ \in Ψ$ , verifying for all $(z, w) \in ℜ$ that
$\begin{matrix} ϱ (P z, P w) \leq γ ϱ (z, w) + min {ψ (ϱ (z, P w)), ψ (ϱ (w, P z)), ψ (ϱ (z, P z)), ψ (ϱ (w, P w))} . \end{matrix}$

Then, $P$ possesses a fixed point.

Proof.

Starting with $z_{0} \in Z$ , define the sequence ${z_{n}} \subset Z$ , such that

(1) $z_{n} = P^{n} (z_{0}) = P (z_{n - 1}), for all n \in N .$

Using (a) and Proposition 2, we find

$(P^{n} z_{0}, P^{n + 1} z_{0}) \in ℜ$

which, utilizing (1), becomes

(2) $(z_{n}, z_{n + 1}) \in ℜ, for all n \in N .$

Thus, ${z_{n}}$ is a ℜ-preserving sequence.

Define $ϱ_{n} : = ϱ (z_{n}, z_{n + 1})$ . Employing the contraction condition (e) to (2), and by (1), we arrive at

$\begin{matrix} ϱ (z_{n}, z_{n + 1}) & \leq & γ ϱ_{n - 1} + min {ψ (ϱ (z_{n - 1}, P z_{n})), ψ (ϱ (z_{n}, P z_{n - 1})), ψ (ϱ (z_{n - 1}, P z_{n - 1})), ψ (ϱ (z_{n}, P z_{n}))} \\ = & γ ϱ_{n - 1} + min {ψ (ϱ (z_{n - 1}, z_{n + 1})), ψ (0), ψ (ϱ_{n - 1}), ψ (ϱ_{n})} \end{matrix}$

so that

$ϱ_{n} \leq γ ϱ_{n - 1}, for all n \in N,$

which, by easy induction, provides

(3) $ϱ_{n} \leq γ^{n} ϱ_{0}, for all n \in N .$

For all $n < m$ , by (3) and triangular inequality, we arrive at

$\begin{matrix} ϱ (z_{n}, z_{m}) & \leq & ϱ_{n} + ϱ_{n + 1} + ϱ_{n + 2} + \dots + ϱ_{m - 1} \\ \leq & (γ^{n} + γ^{n + 1} + γ^{n + 2} + \dots + γ^{m - 1}) ϱ_{0} \\ = & γ^{n} (1 + γ + γ^{2} + \dots + γ^{m - n - 1}) ϱ_{0} \\ \leq & \frac{γ^{n}}{1 - γ} ϱ_{0} \\ \to & 0 as n (and hence m) \to + \infty . \end{matrix}$

Hence, ${z_{n}}$ is Cauchy. Using ℜ-completeness of $Z$ , $there exists$ $z^{*} \in Z$ with $z_{n} \overset{ϱ}{⟶} z^{*}$ .

For the rest of the proof, we need to verify that $z^{*}$ retains a fixed point of $P$ . Assuming $P$ is ℜ-continuous. Owing to the accessibility of (2) and $z_{n} \overset{ϱ}{⟶} z^{*}$ , we have

$z_{n + 1} = P (z_{n}) \overset{ϱ}{⟶} P (z^{*}) .$

By uniqueness of limit, we find $P (z^{*}) = z^{*}$ . As another option, assume that ℜ is $ϱ$ -self-closed. Owing to the accessibility of (2) and $z_{n} \overset{ϱ}{⟶} z^{*}$ , we can determine a subsequence ${z_{n_{k}}}$ of ${z_{n}}$ , verifying $[z_{n_{k}}, z^{*}] \in ℜ, for all k \in N$ . Set $δ_{n} : = ϱ (z^{*}, z_{n})$ . By contraction condition (e) and Proposition 4, we conclude that

(4) $\begin{matrix} ϱ (z_{n_{k} + 1}, P z^{*}) & = & ϱ (P z_{n_{k}}, P z^{*}) \\ \leq & γ ϱ (z_{n_{k}}, z^{*}) + min {ψ (ϱ (z_{n_{k}}, P z^{*})), ψ (ϱ (z^{*}, P z_{n_{k}})), ψ (ϱ (z_{n_{k}}, P z_{n_{k}})), ψ (ϱ (z^{*}, P z^{*}))} \\ = & γ δ_{n_{k}} + min {ψ (ϱ (z_{n_{k}}, P z^{*})), ψ (δ_{n_{k} + 1}), ψ (ϱ_{n_{k}}), ψ (ϱ (z^{*}, P z^{*}))} . \end{matrix}$

Now, $z_{n_{k}} \overset{ϱ}{⟶} z^{*}$ yields that $δ_{n_{k}} ⟶ 0$ in $[0, + \infty)$ , if $k \to + \infty$ . Thus, allowing $k \to + \infty$ in (4), we arrive at

$\begin{matrix} lim_{k \to + \infty} ϱ (z_{n_{k} + 1}, P z^{*}) = 0 \end{matrix}$

so that

z_{n_{k} + 1} \overset{ϱ}{⟶} P (z^{*})

thereby yielding

P (z^{*}) = z^{*}

. Therefore,

z^{*}

retains a fixed point of

P

in each case. □

Theorem 4.

Alongside Theorem 3, if $P (Z)$ is $ℜ^{s}$ -directed, then $P$ enjoys a unique fixed point.

Proof.

In lieu of Theorem 3, $F (P) \neq \emptyset$ , take $z^{*}, w^{*} \in F (P)$ . We conclude that

(5) $P^{n} (z^{*}) = z^{*} a n d P^{n} (w^{*}) = w^{*}, for all n \in N_{0} .$

As $z^{*}, w^{*} \in P (Z)$ and $P (Z)$ is $ℜ^{s}$ -directed, $there is$ $ω_{0} \in P$ , that verifies $[z^{*}, ω_{0}] \in ℜ$ and $[w^{*}, ω_{0}] \in ℜ$ . Consider the following sequence:

(6) $ω_{n} = P^{n} (ω_{0}) = P (ω_{n - 1}), for all n \in N_{0} .$

Using (5), (6), assumption (a), and Proposition 2, we obtain

(7) $[z^{*}, ω_{n}] \in ℜ a n d [w^{*}, ω_{n}] \in ℜ, for all n \in N_{0} .$

Employing (6), (7), contraction condition (e), and Proposition 4, we conclude that

$\begin{matrix} ϱ (z^{*}, ω_{n + 1}) & = & ϱ (P z^{*}, P ω_{n}) \\ \leq & γ ϱ (z^{*}, ω_{n}) + min {ψ (ϱ (z^{*}, P ω_{n})), ψ (ϱ (ω_{n}, P z^{*})), ψ (ϱ (z^{*}, P z^{*})), ψ (ϱ (ω_{n}, P ω_{n}))} \\ = & γ ϱ (z^{*}, ω_{n}) + min {ψ (ϱ (z^{*}, ω_{n})), ψ (ϱ (ω_{n}, z^{*})), 0, ψ (ϱ (ω_{n}, ω_{n + 1})))} \end{matrix}$

so that

ϱ (z^{*}, ω_{n + 1}) \leq γ ϱ (z^{*}, ω_{n})

, which by easy induction gives rise to

(8) $ϱ (z^{*}, ω_{n + 1}) \leq γ^{n + 1} ϱ (z^{*}, ω_{0}) .$

Similarly, we can show that

(9) $ϱ (w^{*}, ω_{n + 1}) \leq γ^{n + 1} ϱ (w^{*}, ω_{0}) .$

From (8) and (9), we find

$\begin{matrix} ϱ (z^{*}, w^{*}) & \leq & ϱ (z^{*}, ω_{n + 1}) + ϱ (ω_{n + 1}, w^{*}) \\ \leq & γ^{n + 1} [ϱ (z^{*}, ω_{0}) + ϱ (w^{*}, ω_{0})] \\ \to & 0, a s n \to + \infty \end{matrix}$

thereby implying

z = w

. This concludes the proof. □

4. Illustrative Examples

The following examples are offered to corroborate the findings explored in the preceding section.

Example 1.

Take $Z = [- 1, 4]$ endued with Euclidean metric ϱ. On $Z$ , define a relation $ℜ = {(z, w) \in Z^{2} : z - w \geq 0}$ . Consider the map $P : Z \to Z$ , such that

$P (z) = \{\begin{matrix} z / 2 if - 1 \leq z \leq 2 \\ 1 if 2 < z \leq 4 . \end{matrix}$

Then, $(Z, ϱ)$ is a ℜ-complete MS, and ℜ is $P$ -closed. It is straightforward to verify that the contraction-inequality of Theorem 3 holds for $γ = 1 / 2$ and $ψ (t) = ln (1 + t)$ . The rest of the hypotheses of Theorems 3 and 4 also hold and, hence, $P$ admits a unique fixed point: $z^{*} = 0$ .

Example 2.

Take $Z = [1, 3]$ endued with Euclidean metric ϱ. On $Z$ , define a relation $ℜ = {(1, 1), (1, 2), (2, 1), (2, 2), (1, 3)}$ . Consider the map $P : Z \to Z$ , such that

$P (z) = \{\begin{matrix} 1 if 1 \leq z \leq 2 \\ 2 if 2 < z \leq 3 . \end{matrix}$

Then, $(Z, ϱ)$ is a ℜ-complete MS, and ℜ is $P$ -closed. It is straightforward to verify that the contraction-inequality of Theorem 3 holds for $γ = 1 / 3$ and $ψ (t) = 3 t$ .

Let ${z_{n}} \subset Z$ be an ℜ-preserving sequence satisfying $z_{n} \overset{ϱ}{⟶} ω$ , so that $(z_{n}, z_{n + 1}) \in ℜ, for all n \in N$ . Here, $(z_{n}, z_{n + 1}) \notin {(1, 3)}$ , thereby implying $(z_{n}, z_{n + 1}) \in {(1, 1), (1, 2), (2, 1), (2, 2)}$ , $for all n \in N$ so that ${z_{n}} \subset {1, 2}$ . As ${1, 2}$ is closed, we have $[z_{n}, ω] \in ℜ$ . Therefore, ℜ is ϱ-self-closed. The rest of hypotheses of Theorems 3 and 4 also hold and, hence, $P$ admits a unique fixed point: $z^{*} = 1$ .

5. Applications

The present section implements our findings to arrive at a (unique) solution of the nonlinear integral equation:

(10) $ξ (τ) = θ (τ) + \int_{a}^{b} Φ (τ, ω) ϝ (ω, ξ (ω)) d ω, τ \in I : = [a, b],$

where

θ : I \to R

Φ : I \times I \to R

, and

ϝ : I \times R \to R

remain functions. As usual,

C (I)

will denote the family of the continuous real valued functions on I.

Definition 11.

$\underset{̲}{ξ} \in C (I)$ is said to form a lower solution of (10) if $for all τ \in I$

$\underset{̲}{ξ} (τ) \leq θ (τ) + \int_{a}^{b} Φ (τ, ω) ϝ (ω, \underset{̲}{ξ} (ω)) d ω .$

Definition 12.

$\bar{ξ} \in C (I)$ is said to form an upper solution of (10) if $for all τ \in I$

$\bar{ξ} (τ) \geq θ (τ) + \int_{a}^{b} Φ (τ, ω) ϝ (ω, \bar{ξ} (ω)) d ω .$

Finally, we present the main outcomes of this section.

Theorem 5.

Along with Problem (10), we assume that

(i). θ, ϝ and Φ remain continuous;
(ii). $Φ (τ, ω) > 0, for all τ, ω \in I$ ;
(iii). $There exists$ $α > 0$ and $β \geq 0$ , with $α > β$ verifying
$0 \leq α [ϝ (τ, x) - ϝ (τ, y)] \leq β (x - y), for all τ \in I a n d for all x, y \in R w i t h x \geq y,$
(iv). $sup_{τ \in I} \int_{a}^{b} Φ (τ, ω) d ω \leq 1$ .

Then, Equation (10) has a unique solution, provided it enjoys a lower solution.

Proof.

On $Z : = C (I)$ , consider the metric:

(11) $ϱ (ξ, η) = sup_{τ \in I} | ξ (τ) - η (τ) |, for all ξ, η \in Z .$

On $Z$ , define the following relation:

(12) $ℜ = {(ξ, η) \in Z^{2} : ξ (τ) \leq η (τ), for all τ \in I} .$

Define a map $P : Z \to Z$ by

(13) $(P ξ) (τ) = θ (τ) + \int_{a}^{b} Φ (τ, ω) ϝ (ω, ξ (ω)) d ω, for all τ \in I .$

Thus, $ξ \in Z$ remains a solution of Problem (10), if and only if $ξ \in F (P)$ .

We will validate all hypotheses of Theorems 3 and 4.

(a). Clearly, the MS $(Z, ϱ)$ is ℜ-complete.
(b). Take $ξ, η \in Z$ verifying $(ξ, η) \in ℜ$ . From (iii), we find
(14) $ϝ (τ, ξ (ω)) - ϝ (τ, η (ω)) \leq 0, for all τ, ω \in I .$

By (13), (14) and Assumption (ii), we obtain
$\begin{matrix} (P ξ) (τ) - (P η) (τ) = \int_{a}^{b} Φ (τ, ω) [ϝ (ω, ξ (ω)) - ϝ (ω, η (ω))] d ω \leq 0, \end{matrix}$
so that $(P ξ) (τ) \leq (P η) (τ)$ which, using (12), yields that $(P ξ, P η) \in ℜ$ , and hence ℜ is $P$ -closed.
(c). If $\underset{̲}{ξ} \in Z$ forms a lower solution of (10), then
$\underset{̲}{ξ} (τ) \leq θ (τ) + \int_{a}^{b} Φ (τ, ω) ϝ (ω, \underset{̲}{ξ} (ω)) d ω = (P \underset{̲}{ξ}) (τ)$
thereby implying $(\underset{̲}{ξ}, P \underset{̲}{ξ}) \in ℜ$ .
(d). Consider an ℜ-preserving sequence ${ξ_{n}} \subset Z$ that converges to $ω \in Z$ . Then, for every $τ \in I$ , ${ξ_{n} (τ)}$ is increasing in $R$ , converging to $ω (τ)$ . Thus far, $ξ_{n} (τ) \leq ω (τ), for all n \in N$ and $for all τ \in I$ . From (12), we have $(ξ_{n}, ω) \in ℜ, for all n \in N$ . Hence, ℜ is $ϱ$ -self-closed.
(e). Let $ξ, η \in Z$ , such that $(ξ, η) \in ℜ$ . Using (iii), (11), and (13), we obtain
(15) $\begin{matrix} ϱ (P ξ, P η) & = & sup_{τ \in I} | (P ξ) (τ) - (P η) (τ) | = sup_{τ \in I} [(P η) (τ) - (P ξ) (τ)] \\ = & sup_{τ \in I} \int_{a}^{b} Φ (τ, ω) [ϝ (ω, η (ω)) - ϝ (ω, ξ (ω))] d ω \\ \leq & sup_{τ \in I} \int_{a}^{b} Φ (τ, ω) \frac{β}{α} [η (ω) - ξ (ω)] d ω . \end{matrix}$

As $0 \leq η (ω) - ξ (ω) \leq ϱ (ξ, η)$ , so (15) reduces to
$\begin{matrix} ϱ (P ξ, P η) & \leq & \frac{β}{α} ϱ (ξ, η) sup_{τ \in I} \int_{a}^{b} Φ (τ, ω) d ω \\ \leq & \frac{β}{α} ϱ (ξ, η) . 1 \\ = & γ ϱ (ξ, η)), w h e r e γ = β / α \end{matrix}$
so that
$\begin{matrix} ϱ (P ξ, P η) & \leq & γ ϱ (ξ, η) + min {ψ (ϱ (ξ, P ξ)), ψ (ϱ (η, P η)), ψ (ϱ (ξ, P η)), ψ (ϱ (η, P ξ))}, \\ for all & ξ, η \in Z such that (ξ, η) \in ℜ, \end{matrix}$
where $ψ \in Ψ$ is arbitrary.

Take $ξ, η \in P (Z)$ , and define $ϖ (τ) : = max {ξ (τ), η (τ)}$ . Then, $(ξ, ϖ) \in ℜ$ and $(η, ϖ) \in ℜ$ . It follows that $P (Z)$ is $ℜ^{s}$ -directed. Henceforth, by applying Theorem 4, $P$ admits a unique fixed point, which is a unique solution of (10). □

Theorem 6.

Along with conditions (i)–(iv) of Theorem 5, Problem (10) has a unique solution, provided that it has an upper solution.

Proof.

Consider a metric $ϱ$ on $Z : = C (I)$ , and a map $P : Z \to Z$ , the same as in the proof of Theorem 5. On $Z$ , take a relation

(16) $ℜ^{'} = {(ξ, η) \in Z^{2} : ξ (τ) \geq η (τ), for all τ \in I} .$

Now, we will check all hypotheses of Theorems 3 and 4.

(a). Clearly, the MS $(Z, ϱ)$ is $ℜ^{'}$ -complete.
(b). Take $ξ, η \in Z$ verifying $(ξ, η) \in ℜ^{'}$ . By (iii), we find
(17) $ϝ (τ, ξ (ω)) - ϝ (τ, η (ω)) \geq 0, for all τ, ω \in I .$

By (13), (17) and (ii), we find
$\begin{matrix} (P ξ) (τ) - (P η) (τ) = \int_{a}^{b} Φ (τ, ω) [ϝ (ω, ξ (ω)) - ϝ (ω, η (ω))] d ω \geq 0, \end{matrix}$
so that $(P ξ) (τ) \geq (P η) (τ)$ which, using (16), yields that $(P ξ, P η) \in ℜ^{'}$ , and hence $ℜ^{'}$ is $P$ -closed.
(c). If $\bar{ξ} \in Z$ is an upper solution of (10), then we have
$\bar{ξ} (τ) \geq θ (τ) + \int_{a}^{b} Φ (τ, ω) ϝ (ω, \bar{ξ} (ω)) d ω = (P \bar{ξ}) (τ)$
thereby implying $(\bar{ξ}, P \bar{ξ}) \in ℜ^{'}$ .
(d). Consider an $ℜ^{'}$ -preserving sequence ${ξ_{n}} \subset Z$ that converges to $ω \in Z$ . Then, for every $τ \in I$ , ${ξ_{n} (τ)}$ is decreasing in $R$ , converging to $ω (τ)$ . Thus far, $ξ_{n} (τ) \geq ω (τ), for all n \in N$ and $for all τ \in I$ . From (16), we have $(ξ_{n}, ω) \in ℜ^{'}, for all n \in N$ . Hence, $ℜ^{'}$ is $ϱ$ -self-closed.
(e). Let $ξ, η \in Z$ , such that $(ξ, η) \in ℜ^{'}$ . By (iii), (11) and (13), we obtain
(18) $\begin{matrix} ϱ (P ξ, P η) & = & sup_{τ \in I} | (P ξ) (τ) - (P η) (τ) | = sup_{τ \in I} [(P ξ) (τ) - (P η) (τ)] \\ = & sup_{τ \in I} \int_{a}^{b} Φ (τ, ω) [ϝ (ω, ξ (ω)) - ϝ (ω, η (ω))] d ω \\ \leq & sup_{τ \in I} \int_{a}^{b} Φ (τ, ω) \frac{β}{α} [ξ (ω) - η (ω)] d ω . \end{matrix}$

As $0 \leq ξ (ω) - η (ω) \leq ϱ (ξ, η)$ , (18) reduces to
$\begin{matrix} ϱ (P ξ, P η) & \leq & \frac{β}{α} ϱ (ξ, η) sup_{τ \in I} \int_{a}^{b} Φ (τ, ω) d ω \\ \leq & \frac{β}{α} ϱ (ξ, η) . 1 \\ = & γ ϱ (ξ, η)), w h e r e γ = β / α \end{matrix}$
so that
$\begin{matrix} ϱ (P ξ, P η) & \leq & γ ϱ (ξ, η) + min {ψ (ϱ (ξ, P ξ)), ψ (ϱ (η, P η)), ψ (ϱ (ξ, P η)), ψ (ϱ (η, P ξ))}, \\ for all & ξ, η \in Z such that (ξ, η) \in ℜ^{'}, \end{matrix}$
where $ψ \in Ψ$ is arbitrary.

Take $ξ, η \in P (Z)$ , and define $ϖ (τ) : = min {ξ (τ), η (τ)}$ . Then, $(ξ, ϖ) \in ℜ^{'}$ and $(η, ϖ) \in ℜ^{'}$ . It follows that $P (Z)$ is $ℜ^{s}$ -directed. Thus, by applying Theorem 4, $P$ admits a unique fixed point, which is a unique solution of (10). □

6. Conclusions

In this study, our investigation examined findings on fixed-points under a nonlinear formulation of almost contractions on in relational MS. A number of examples were also conducted to illustrate these findings. Our findings extend the corresponding findings of Babu et al. [19] under the restriction $ℜ = Z^{2}$ and $ψ (t) = K \cdot t$ ( $K \geq 0$ ), and Theorem 4 reduces to Theorem 2. Our result can be applied in the ares of nonlinear matrix equations, periodic boundary value problems, and nonlinear integral equations.

In particular, we applied our findings to a special types of nonlinear integral equations. The general formulations of such nonlinear integral equations can be solved directly by employing the BCP (see Theorem 5.2.2 of [1]). However, the nonlinear integral equations investigated herewith require additional conditions (especially the existence of lower or upper solutions) that are solvable using the fixed point findings involving relational-theoretic contractions.

For future works, the outcomes investigated herewith can be further expanded to relatively generalized contraction conditions, on replacing the term $γ ϱ (z, w)$ by the terms involved in $φ$ -contractions, or weak contractions. Following similar lines of research, we can extend some recent outcomes of graph MS (e.g., [28,29,30]) to relational MS.

Author Contributions

Conceptualization, D.F. and F.A.K.; methodology, F.A.K.; formal analysis, F.A.K.; resources, D.F. and F.A.K.; writing—original draft, F.A.K.; writing—review and editing, D.F.; funding acquisition, D.F. All authors have read and agreed to the published version of the manuscript.

Data Availability Statement

The original contributions presented in the study are included in the article, further inquiries can be directed to the corresponding author.

Conflicts of Interest

All authors declare no conflicts of interest.

Footnotes

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References

1. Atkinson, K.; Han, W. Theoretical Numerical Analysis, a Functional Analysis Framework; 3rd ed. Texts in Applied Mathematics, 39 Springer: New York, NY, USA, 2009.

2. Younis, M.; Abdou, A.A.N. Novel fuzzy contractions and applications to engineering science. Fractal Fract.; 2024; 8, 28. [DOI: https://dx.doi.org/10.3390/fractalfract8010028]

3. Alam, A.; Imdad, M. Relation-theoretic contraction principle. J. Fixed Point Theory Appl.; 2015; 17, pp. 693-702. [DOI: https://dx.doi.org/10.1007/s11784-015-0247-y]

4. Alam, A.; Imdad, M. Relation-theoretic metrical coincidence theorems. Filomat; 2017; 31, pp. 4421-4439. [DOI: https://dx.doi.org/10.2298/FIL1714421A]

5. Alam, A.; Imdad, M. Nonlinear contractions in metric spaces under locally T-transitive binary relations. Fixed Point Theory; 2018; 19, pp. 13-24. [DOI: https://dx.doi.org/10.24193/fpt-ro.2018.1.02]

6. Abbas, M.; Iqbal, H.; Petrusel, A. Fixed points for multivalued Suzuki type (θ,R)-contraction mapping with applications. J. Funct. Spaces; 2019; 2019, 9565804. [DOI: https://dx.doi.org/10.1155/2019/9565804]

7. Almarri, B.; Mujahid, S.; Uddin, I. New fixed point results for Geraghty contractions and their applications. J. Appl. Anal. Comp.; 2023; 13, pp. 2788-2798. [DOI: https://dx.doi.org/10.11948/20230004]

8. Alam, A.; Arif, M.; Imdad, M. Metrical fixed point theorems via locally finitely T-transitive binary relations under certain control functions. Miskolc Math. Notes; 2019; 20, pp. 59-73. [DOI: https://dx.doi.org/10.18514/MMN.2019.2468]

9. Arif, M.; Imdad, M.; Alam, A. Fixed point theorems under locally T-transitive binary relations employing Matkowski contractions. Miskolc Math. Notes; 2022; 23, pp. 71-83. [DOI: https://dx.doi.org/10.18514/MMN.2022.3220]

10. Sk, F.; Khan, F.A.; Khan, Q.H.; Alam, A. Relation-preserving generalized nonlinear contractions and related fixed point theorems. AIMS Math.; 2022; 7, pp. 6634-6649. [DOI: https://dx.doi.org/10.3934/math.2022370]

11. Alharbi, A.F.; Khan, F.A. Almost Boyd-Wong type contractions under binary relations with applications to boundary value problems. Axioms; 2023; 12, 896. [DOI: https://dx.doi.org/10.3390/axioms12090896]

12. Algehyne, E.A.; Altaweel, N.H.; Areshi, M.; Khan, F.A. Relation-theoretic almost ϕ-contractions with an application to elastic beam equations. AIMS Math.; 2023; 8, pp. 18919-18929. [DOI: https://dx.doi.org/10.3934/math.2023963]

13. Filali, D.; Khan, F.A. Relation-preserving functional contractions involving a triplet of auxiliary functions with an application to integral equations. Symmetry; 2024; 16, 691. [DOI: https://dx.doi.org/10.3390/sym16060691]

14. Aljawi, S.; Uddin, I. Relation-theoretic nonlinear almost contractions with an application to boundary value problems. Mathematics; 2024; 12, 1275. [DOI: https://dx.doi.org/10.3390/math12091275]

15. Berinde, V. Approximating fixed points of weak contractions using the Picard iteration. Nonlinear Anal. Forum.; 2004; 9, pp. 43-53.

16. Berinde, V. On the approximation of fixed points of weak contractive mappings. Carpathian J. Math.; 2003; 19, pp. 7-22.

17. Berinde, M.; Berinde, V. On a general class of multi-valued weakly Picard mappings. J. Math. Anal. Appl.; 2007; 326, pp. 772-782. [DOI: https://dx.doi.org/10.1016/j.jmaa.2006.03.016]

18. Păcurar, M. Sequences of almost contractions and fixed points. Carpathian J. Math.; 2008; 24, pp. 101-109.

19. Babu, G.V.R.; Sandhy, M.L.; Kameshwari, M.V.R. A note on a fixed point theorem of Berinde on weak contractions. Carpathian J. Math.; 2008; 24, pp. 8-12.

20. Păcurar, M. Remark regarding two classes of almost contractions with unique fixed point. Creat. Math. Inform.; 2010; 19, pp. 178-183.

21. Ćirić, L.; Abbas, M.; Saadati, R.; Hussain, N. Common fixed points of almost generalized contractive mappings in ordered metric spaces. Appl. Math. Comput.; 2011; 217, pp. 5784-5789. [DOI: https://dx.doi.org/10.1016/j.amc.2010.12.060]

22. Choudhury, B.S.; Metiya, N. Fixed point theorems for almost contractions in partially ordered metric spaces. Ann. Univ. Ferrara; 2012; 58, pp. 21-36. [DOI: https://dx.doi.org/10.1007/s11565-011-0144-2]

23. Altun, I.; Acar, Ö. Fixed point theorems for weak contractions in the sense of Berinde on partial metric spaces. Topol. Appl.; 2012; 159, pp. 2642-2648. [DOI: https://dx.doi.org/10.1016/j.topol.2012.04.004]

24. Al-Mezel, S.A.; Ahmad, J. Fixed point results with applications to nonlinear fractional differential equations. AIMS Math.; 2023; 8, pp. 19743-19756. [DOI: https://dx.doi.org/10.3934/math.20231006]

25. Turinici, M. Weakly contractive maps in altering metric spaces. ROMAI J.; 2013; 9, pp. 175-183.

26. Lipschutz, S. Schaum’s Outlines of Theory and Problems of Set Theory and Related Topics; McGraw-Hill: New York, NY, USA, 1964.

27. Samet, B.; Turinici, M. Fixed point theorems on a metric space endowed with an arbitrary binary relation and applications. Commun. Math. Anal.; 2012; 13, pp. 82-97.

28. Younis, M.; Bahuguna, D. A unique approach to graph-based metric spaces with an application to rocket ascension. Comp. Appl. Math.; 2023; 42, 44. [DOI: https://dx.doi.org/10.1007/s40314-023-02193-1]

29. Younis, M.; Ahmad, H.; Chen, L.; Han, M. Computation and convergence of fixed points in graphical spaces with an application to elastic beam deformations. J. Geom. Phys.; 2023; 192, 104955. [DOI: https://dx.doi.org/10.1016/j.geomphys.2023.104955]

30. Jabeen, S.; Koksal, M.E.; Younis, M. Convergence results based on graph-Reich contraction in fuzzy metric spaces with application. Nonlinear Anal. Model. Control; 2024; 29, pp. 71-95. [DOI: https://dx.doi.org/10.15388/namc.2024.29.33668]

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Relational Strict Almost Contractions Employing Test Functions and an Application to Nonlinear Integral Equations

Content area

Abstract

Full text

2. Relation-Theoretic Notions

3. Main Results

4. Illustrative Examples

5. Applications