On the Existence Results for a Mixed Hybrid Fractional Differential Equations of Sequential Type

Arab, Meraa; Awadalla, Muath; Manigandan, Murugesan; Abuasbeh, Kinda; Mahmudov, Nazim I.; Nandha Gopal, Thangaraj

doi:10.3390/fractalfract7030229

Open AccessArticle

On the Existence Results for a Mixed Hybrid Fractional Differential Equations of Sequential Type

by

Meraa Arab

¹,

Muath Awadalla

^1,*

,

Murugesan Manigandan

^2,*

,

Kinda Abuasbeh

¹

,

Nazim I. Mahmudov

³

and

Thangaraj Nandha Gopal

²

¹

Department of Mathematics and Statistics, College of Science, King Faisal University, Hafuf 31982, Al Ahsa, Saudi Arabia

²

Sri Ramakrishna Mission Vidyalaya College of Arts and Science, Coimbatore 641020, Tamil Nadu, India

³

Department of Mathematics, Eastern Mediterranean University, North Cyprus, Famagusta 99628, Turkey

^*

Authors to whom correspondence should be addressed.

Fractal Fract. 2023, 7(3), 229; https://doi.org/10.3390/fractalfract7030229

Submission received: 27 January 2023 / Revised: 22 February 2023 / Accepted: 1 March 2023 / Published: 4 March 2023

(This article belongs to the Special Issue Recent Advances in Fractional Evolution Equations and Related Topics)

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Abstract

:

In this article, we study the existence of a solution to the mixed hybrid fractional differential equations of sequential type with nonlocal integral hybrid boundary conditions. The main results are established with the aid of Darbo’s fixed point theorem and Hausdorff’s measure of noncompactness method. The stability of the proposed fractional differential equation is also investigated using the Ulam–Hyer technique. In addition, an applied example that supports the theoretical results reached through this study is included.

Keywords:

existence; fixed point theorems; stability; fractional differential equations

MSC:

26A33; 34B15; 34B18

1. Introduction

Fractional calculus is a well-established subject with applications in many fields, such as electro-chemistry, economics, electromagnetics, physical sciences, and medicine. The idea of fractional calculus is to replace the natural numbers in the derivative order with rational ones. In domains such as visco-elasticity, statistical physics, optics, signal processing, control, defense, electrical circuits, and astronomy, fractional differential equations have become extremely prevalent.

When studying any kind of differential equation, researchers are interested in the existence and unity of solutions and their qualitative properties; these properties include the stability of solutions. Stability was, and still is, the most important question in the theory of dynamic systems, as the study of stability was first conducted in mechanics due to the urgent need to study the balance of a system, and questions of stability increased the motivation to introduce new mathematical concepts to engineering, especially control engineering. The fixed-point theorem is not a single theorem, but belongs to a large family of fixed-point theorems that relate to different mathematical fields. The researchers’ efforts focused on several theorems from this family to study the stability criteria for functional differential equations, including Banach’s fixed point theorem, Schauder’s fixed point theorem, and Krasnoselskii’s fixed point theorem. We recommend monographs [1,2,3,4,5] and the recently mentioned papers [6,7,8,9,10,11,12,13,14,15,16]. The majority of research on FDEs is based on fractional derivatives of the R-L and Caputo types; see [9,17]. Several studies have been conducted to investigate how stability concepts such as the Mittag–Leffler function, exponential, and Lyapunov stability apply to various types of dynamic systems. Ulam and Hyers, on the other hand, identified a previously unknown type of stability, known as Ulam-stability [18]. Hyer’s type of stability study significantly contributes to our understanding of chemical processes and fluid movement, as well as semiconductors, population dynamics, heat conduction, and elasticity. While others have reported results using other types of stability, Ulam’s group designed and implemented a type of stability for ordinary, fractional differential, and difference equations; see [19]. Differential equations are found to be of great utility in systems and stochastic processes. They can be applied in sweeping processes, granular systems, nonlinear dynamics of wheeled vehicles, control problems, etc. The details of pressing issues in the stochastic process, control, differential games, optimization, and their applications can be found in [20], in which the authors studied the existence and uniqueness of the following subject to the following boundary conditions:

\begin{matrix} ^{C H} D^{P} (\frac{u (ξ)}{z_{1} (ξ, u (ξ), v (ξ))}) = w_{1} (ξ, u (ξ), v (ξ)), ξ \in [1, e], P \in (1, 2], \\ ^{C H} D^{Q} (\frac{v (ξ)}{z_{1} (ξ, u (ξ), v (ξ))}) = w_{2} (ξ, u (ξ), v (ξ)), ξ \in [1, e], Q \in (1, 2], \end{matrix}

\begin{matrix} {(\frac{u (ξ)}{z_{1} (ξ, u (ξ), v (ξ))})}_{ξ = 1} = & 0, \\ ^{C H} D {(\frac{u (ξ)}{z_{1} (ξ, u (ξ), v (ξ))})}_{ξ = e} = & λ_{1}^{C H} D {(\frac{u (ξ)}{z_{1} (ξ, u (ξ), v (ξ))})}_{ξ = η_{1}} \\ {(\frac{v (ξ)}{z_{2} (ξ, u (ξ), v (ξ))})}_{ξ = 1} = & 0, \\ ^{C H} D {(\frac{v (ξ)}{z_{2} (ξ, u (ξ), v (ξ))})}_{ξ = e} = & λ_{2}^{C H} D {(\frac{v (ξ)}{z_{2} (ξ, u (ξ), v (ξ))})}_{ξ = η_{2}}, \end{matrix}

where

^{C H} D^{γ}, γ = {P, Q}

is the Caputo—Hadamard fractional derivative of order

1 < γ \leq 2

,

λ_{1}, λ_{2} \in [0, 1),

and

η_{1}, η_{2} \in (1, e)

.

In [21], the authors studied the existence and uniqueness of the following system of mixed hybrid fractional differential equations

\begin{matrix} \{\begin{matrix} (^{C} D_{1 -}^{R L} D_{0 +}^{r}) (\frac{u (ξ)}{z_{1} (ξ, u (ξ), v (ξ))}) = w_{1} (ξ, u (ξ), v (ξ)), ξ \in [0, 1], 1 < q \leq 2, 0 < r \leq 1, \\ (^{C} D_{1 -}^{R L} D_{0 +}^{p}) (\frac{v (ξ)}{z_{1} (ξ, u (ξ), v (ξ))}) = w_{1} (ξ, u (ξ), v (ξ)), 0 < r \leq 1, \\ u (ξ) = u^{'} (ξ) = 0, u (1) = δ u (ζ), δ \in ε, ζ \in (0, 1), \\ v (ξ) = v^{'} (ξ) = 0, v (1) = ϵ v (ξ), ϵ \in ε, ξ \in (0, 1) . \end{matrix} \end{matrix}

In [22] 2022, the authors investigated the existence of the solution for the following hybrid fractional differential equations

\begin{matrix} ^{H} D_{0 +}^{μ, ν; Ψ} [\frac{y (ξ)}{f (ξ, y (ξ))}] = g (ξ, y (ξ)), a . e t \in (0, T], \\ {(Φ (ξ) - Φ (0))}^{1 - ζ} {y (ξ) |}_{t = 0} = y_{0} \in ε, \end{matrix}

where

0 < μ < 1, 0 \leq ν \leq 1

,

ζ = μ + ν (1 - μ),

^{H} D_{0 +}^{μ, ν; Ψ} (\cdot)

is the

Φ

-Hilfer fractional derivative of order

μ

and type

ν, f \in C (J \times ε, ε \ {0})

is bounded,

J = [0, T]

and

g \in C (J \times ε, ε)

= {h |

the map

ω \to h (τ, ω)

is continuous for each

τ

and the map

τ

\to h (τ, ω)

is measurable for each

ω

}.

In [23], the authors studied the existence of solutions for a class of boundary value problems for nonlinear fractional hybrid differential equations involving a generalized Hilfer fractional derivative

\begin{matrix} ^{α} D_{a^{+}}^{ϑ, r} (\frac{y (ξ)}{f (ξ, y (ξ))}) = ϑ (ξ, x (ξ)), τ \in (a, b] . \\ c_{1} (^{α} J_{a^{+}}^{1 - ζ} (\frac{y (ξ)}{f (ξ, y (ξ))})) (a^{+}) + c_{2} (^{α} J_{a^{+}}^{1 - ζ} (\frac{y (ξ)}{f (ξ, y (ξ))})) (b) = c_{3}, \end{matrix}

where

^{α} D_{a^{+}}^{ϑ, r}

and

^{α} J_{a^{+}}^{1 - ζ}

, respectively, denote the generalized Hilfer derivative operator of order

ϑ \in (0, 1)

and type

r \in [0, 1]

, and generalized fractional integral of order

1 - ζ,

(ζ = ϑ + r - ϑ r), c_{1}, c_{2}, c_{3} \in ε, c_{1} + c_{2} \neq 0, f \in C ([a, b] \times ε, ε) \ {0})

and

ϑ \in C ([a, b] \times ε, ε)

.

In the present work, we use Darbo’s fixed point theorem and Hausdorff’s measure of noncompactness method to investigate the existence results for the following FDE

\begin{matrix} \{\begin{matrix} ^{c} D^{β} (^{c} D^{ϖ} + λ) (\frac{ε_{1} (ξ)}{κ_{1} (ξ, ε_{1} (ξ))}) = J_{1} (ξ, ε_{1} (ξ)) a . e . ξ \in J = [0, 1] \\ \frac{ε_{1} (0)}{κ_{1} (0, ε_{1} (0))} + μ \frac{ε_{1} (1)}{κ_{1} (1, ε_{1} (1))} = ϱ_{1} \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1}, \\ ^{c} D^{ϖ} (\frac{ε_{1} (0)}{κ_{1} (0, ε_{1} (0))}) + φ_{1}^{c} D^{ϖ} (\frac{ε_{1} (1)}{κ_{1} (1, ε_{1} (1))}) = ϱ_{2} \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1}, \\ ^{c} D^{2 ϖ} (\frac{ε_{1} (0)}{κ_{1} (0, ε_{1} (0))}) + φ_{1}^{c} D^{2 ϖ} (\frac{ε_{1} (1)}{κ_{1} (1, ε_{1} (1))}) = ϱ_{3} \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1}, \end{matrix} \end{matrix}

(1)

where

0 < ϖ < 1, 1 < β \leq 2, λ, φ_{1}, ϱ_{i}, \in ε^{*}

for

i = 1, 2, 3,

with

φ_{1} = - 1

.

^{c} D^{ϖ},^{c} D^{β}

are the Caputo’s fractional derivatives, and

κ_{1} : [0, 1] \times ε \to ε {0}, ω \in C ([0, 1] \times ε, ε)

and

g, h, k : [0, 1] \times ε \to ε

are a given continuous functions.

By a solution of the problem (1), we mean a function

ε_{1} \in C (J, ε)

, such that

(i): The function $ξ ↣ (\frac{ε_{1}}{κ_{1} (ξ, ε_{1})})$ is continuous for each $ε_{1} \in ε$ , and
(ii): $ε_{1}$ satisfies the equations in (1).

The originality of this study lies in the use of Darbo’s fixed point theory, which is an important but rarely used theory in the literature. In addition, it verifies the existence of the solution to a nonlinear sequential fractional differential equation of the hybrid type and hybrid boundary conditions. Moreover, the stability of the solutions to this equation was verified using the Ulam–Hyres technique, establishing the relevence of this work.

The rest of the article is as follows: Section 2 presents the basic definitions, lemmas, and theorems that underpin our main conclusions. In Section 3, we provide solutions to the given fractional differential Equation (1) using Darbo’s fixed point theorem. Section 4 looks at the Ulam–Hyers stability of the provided fractional differential Equation (1). In Section 5, an example is provided to further clarify the study’s finding. In Section 6, the conclusion and future works are introduced.

2. Preliminaries

In this section, we state the most important definitions, lemmas, and theorems that are necessary to obtain our main results. In addition, we introduce some useful notations that make our result less complicated. We finish this section with an auxiliary lemma that provides a solution to our proposed fractional differential equation.

Denote the Banach space of all continuous function by:

C ([0, T], E)

with the norm

\begin{matrix} | | ε_{1} {| |}_{\infty} = sup_{ξ \in J} | | J (ξ) | | . \end{matrix}

Let

L^{1} ([0, T])

represent the space of Bochner integrable functions

ε_{1} : [0, T] \to E

, with the norm

\begin{matrix} | | ε_{1} {| |}_{1} = \int_{0}^{T} | | ε_{1} (ξ) | | d ξ . \end{matrix}

Definition 1

([24]). Let

E

be a Banach space and

V_{2}

a bounded subsets of

E

. Then, the Hausdorff measurable of non-compactness of

V_{2}

is defined by

χ (V_{2}) = inf {ξ > 0 : V_{2}

has a finite cover by balls of radius

ξ}

.

To discuss the problem in this paper, we need the following lemmas.

Lemma 1

([24]). Let

V_{1}, V_{2} \subset E

be bounded. Then, HMNC has the following properties:

(1): $V_{1} \subset V_{2} \Rightarrow χ (V_{1}) \leq χ (V_{2})$ ;
(2): $χ (V_{1}) = 0 \Leftrightarrow V_{1}$ is a relatively compact;
(3): $χ (V_{1} \cup V_{2}) = max {χ (V_{1}), χ (V_{2})}$ ;
(4): $χ (V_{1}) = χ (\bar{V_{1}}) = χ (c o n v (V_{1}))$ , where $\bar{V_{1}}$ and $V_{1}$ represent the closure and the convex hull of $V_{1}$ , respectively;
(5): $χ (A + B) \leq χ (V_{1}) + χ (V_{2})$ , where $(V_{1}) + (V_{2}) = {u + v : u \in V_{1}, v \in V_{2}}$ ;
(6): $χ (ϖ V_{1}) \leq | ϖ | χ (V_{1})$ $\forall ϖ \in ε$ ,

Lemma 2

([24]). If

J_{1} \subseteq C ([0, T], E)

is bounded and equi-continuous, then

χ (J_{1} (ξ))

is continuous on

[0, T]

and

\begin{matrix} χ (J) = sup_{ξ \in [0, T]} χ (J_{1} (ξ)) . \end{matrix}

(2)

The set

V_{2} \subset L ([0, T], E)

is (uniformly) bounded if ∃

σ \in L^{1} ([0, T], R^{+})

, such that

\begin{matrix} ∥ u (ι_{1}) ∥ \leq σ (ι_{1}), \forall ε_{1} \in V_{2} . \end{matrix}

(3)

Lemma 3

([25]). If

{\{{ε_{1}}_{n}\}}_{n = 1}^{\infty} \subset L^{1} ([0, T], E)

is integrable (uniformly), then

χ ({\{{ε_{1}}_{n}\}}_{n = 1}^{\infty})

is measurable, and

\begin{matrix} χ ({\{\int_{0}^{t} {ε_{1}}_{n} (ι_{1}) d ι_{1}\}}_{n = 1}^{\infty}) \leq \int_{0}^{t} χ ({\{{ε_{1}}_{n} (ι_{1})\}}_{n = 1}^{\infty}) d ι_{1} . \end{matrix}

(4)

Lemma 4

([26]). If a set

J_{1}

is bounded, then ∀δ, ∃

{\{{ε_{1}}_{n}\}}_{n = 1}^{\infty} \subset J_{1},

such that

\begin{matrix} χ J_{1} \leq 2 χ ({\{{ε_{1}}_{n} (ι_{1})\}}_{n = 1}^{\infty}) + δ . \end{matrix}

(5)

Definition 2

([27]). A function

J : [c, d] \times E \to E

satisfies the carathéodory conditions, if the following can be satisfied

$J (ξ, ε_{1})$ is continuous w.r.t. ξ for $ε_{1} \in E$ ∀ $ξ \in [c, d]$ .
$J (ξ, ε_{1})$ is measurable w.r.t. ξ for $ε_{1} \in E$ ;

Definition 3

([28]). The function

J : Ω \subset E \to E

is a χ-contraction, if

\exists k

,

0 < k < 1

such that

\begin{matrix} χ (J (V_{1})) \leq k χ V_{1}, \end{matrix}

(6)

for all bounded

V_{1} \subset Ω

.

Next, we state the most important theory on which the results of this work are based. This is called the fixed point theory of “Darbo and Sadovskii” [24,29].

Theorem 1.

Let Ω be a nonempty, bounded, closed and convex subset of a Banach space

E,

and let

J : Ω \to Ω

be a continuous operator. If

J

is a χ-contraction, then

J

has at least one fixed point.

Definition 4

([1]). The RL fractional integral of order

ϱ > 0

for a function

J_{1} : [0, + \infty) \to R

is defined as

\begin{matrix} I_{0 +}^{ϱ} J_{1} (ξ) = \frac{1}{Γ (ϱ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϱ - 1} J_{1} (ι_{1}) d ι_{1} . \end{matrix}

Definition 5

([1]). The Caputo derivative of order

ϱ > 0

for a function

J_{1} : [0, + \infty) \to R

is written as

\begin{matrix} D_{0 +}^{ϱ} J_{1} (ξ) = \frac{1}{Γ (n - ϱ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{n - ϱ - 1} J_{1}^{(n)} (ι_{1}) d ι_{1}, \end{matrix}

where

n = [ϱ] + 1, [ϱ]

is an integral part of ϱ.

Lemma 5.

Let

ϱ > 0

. Then, the differential equation

D_{0 +}^{ϱ} J_{1} (ξ) = 0

has the solution

\begin{matrix} J_{1} (ξ) = c_{0} + c_{1} ξ + c_{1} ξ^{2} + \dots + c_{n - 1} ξ^{n - 1}, \end{matrix}

and

\begin{matrix} I_{0 +}^{ϱ} D_{0 +}^{ϱ} J_{1} (ξ) = J_{1} (ξ) + c_{0} + c_{1} ξ + c_{1} ξ^{2} + \dots + c_{n - 1} ξ^{n - 1}, \end{matrix}

where

c_{i} \in R

and

i = 1, 2 \dots, n = [ϱ] + 1

.

Lemma 6.

Assume that hypothesis

(H_{0})

holds. Then, for any

y \in L^{1} (J; ε)

. The function

ε_{1} \in C (J; ε)

is a solution to the problem

\begin{matrix} \{\begin{matrix} ^{c} D^{β} (^{c} D^{ϖ} + λ) (\frac{ε_{1} (ξ)}{κ_{1} (ξ, ε_{1} (ξ))}) = y (ξ) a . e . ξ \in J = [0, 1] \\ \frac{ε_{1} (0)}{κ_{1} (0, ε_{1} (0))} + φ_{1} \frac{ε_{1} (1)}{κ_{1} (1, ε_{1} (1))} = ϱ_{1} \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1}, \\ ^{c} D^{ϖ} (\frac{ε_{1} (0)}{κ_{1} (0, ε_{1} (0))}) + φ_{1}^{c} D^{ϖ} (\frac{ε_{1} (1)}{κ_{1} (1, ε_{1} (1))}) = ϱ_{2} \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1}, \\ ^{c} D^{2 ϖ} (\frac{ε_{1} (0)}{κ_{1} (0, ε_{1} (0))}) + φ_{1}^{c} D^{2 ϖ} (\frac{ε_{1} (1)}{κ_{1} (1, ε_{1} (1))}) = ϱ_{3} \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1}, \end{matrix} \end{matrix}

(7)

if, and only if,

ε_{1}

and satisfies the hybrid equation:

\begin{matrix} ε_{1} (ξ) = & κ_{1} (ξ, ε_{1} (ξ)) [\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1} + A_{1} (ξ) \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + A_{2} (ξ) \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1} + A_{3} (ξ) \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + \frac{A_{4} (ξ)}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} y (ι_{1}) d ι_{1} + \frac{A_{5} (ξ)}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1} \\ + \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1}] - \frac{λ}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} ε_{1} (ι_{1}) d ι_{1}, \end{matrix}

(8)

where

\begin{matrix} A_{1} & = \frac{ξ^{ϖ} ϱ_{2} (1 - λ Γ (2 - ϖ))}{Γ (ϖ + 1) (1 + φ_{1})} + \frac{ξ^{ϖ + 1} λ ϱ_{2} Γ (2 - ϖ)}{Γ (2 + ϖ) φ_{1}} \\ + (\frac{φ_{1}}{{(1 + φ_{1})}^{2} Γ (ϖ + 1)} - \frac{1}{(1 + φ_{1}) Γ (ϖ + 2)}) Γ (2 - ϖ) λ ϱ_{2} - \frac{φ_{1} ϱ_{2}}{{(1 + φ_{1})}^{2} Γ (ϖ + 1)} \\ A_{2} & = \frac{ξ^{ϖ} λ ϱ_{1}}{Γ (ϖ + 1) (1 + φ_{1})} - \frac{ϱ_{1}}{1 + φ_{1}} + \frac{φ_{1} λ ϱ_{1}}{{(1 + φ_{1})}^{2} Γ (ϖ + 1)}, \\ A_{3} & = - \frac{ξ^{ϖ} Γ (2 - ϖ) ϱ_{3}}{Γ (ϖ + 1) (1 + φ_{1})} + \frac{ξ^{ϖ + 1} Γ (2 - ϖ) ϱ_{3}}{Γ (ϖ + 2) φ_{1}} + \frac{φ_{1} Γ (2 - ϖ) ϱ_{3}}{{(1 + φ_{1})}^{2} Γ (ϖ + 1)} - \frac{Γ (2 - ϖ) ϱ_{3}}{(1 + φ_{1}) Γ (ϖ + 2)}, \\ A_{4} & = \frac{ξ^{ϖ} Γ (2 - ϖ) φ_{1}}{Γ (ϖ + 1) (1 + φ_{1})} - \frac{ξ^{ϖ + 1} Γ (2 - ϖ)}{Γ (ϖ + 2)} \\ + Γ (2 - ϖ) (\frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + 2)} - \frac{φ_{1}^{2}}{{(1 + φ_{1})}^{2} Γ (ϖ + 1)}), \\ A_{5} & = - \frac{ξ^{2} φ_{1}}{Γ (ϖ + 1) (1 + φ_{1})} - \frac{φ_{1}^{2}}{{(1 + φ_{1})}^{2} Γ (ϖ + 1)} . \end{matrix}

Proof.

Using Lemma, we obtain

\begin{matrix} (^{c} D^{ϖ} + λ) (\frac{ε_{1} (ξ)}{κ_{1} (ξ, ε_{1} (ξ))}) = & I^{β} y (ξ) + a_{0} + a_{1} ξ, \\ (^{c} D^{ϖ}) (\frac{ε_{1} (ξ)}{κ_{1} (ξ, ε_{1} (ξ))}) = & I^{β} y (ξ) + a_{0} + a_{1} ξ - λ (\frac{ε_{1} (ξ)}{κ_{1} (ξ, ε_{1} (ξ))}), \\ \frac{ε_{1} (ξ)}{κ_{1} (ξ, ε_{1} (ξ))} = & I^{ϖ + β} y (ξ) + I^{ϖ} a_{0} + I^{ϖ} a_{1} ξ - I^{ϖ} λ (\frac{ε_{1} (ξ)}{κ_{1} (ξ, ε_{1} (ξ))}) + a_{2}, \end{matrix}

where

a_{1}, a_{2}, a_{0} \in R

.

According to the condition:

^{c} D^{2 ϖ} (\frac{ε_{1} (0)}{κ_{1} (0, ε_{1} (0))}) + φ_{1}^{c} D^{2 ϖ} (\frac{ε_{1} (1)}{κ_{1} (1, ε_{1} (1))}) = ϱ_{3} \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1}

we find that:

\begin{matrix} a_{1} = & Γ (2 - ϖ) (\frac{ϱ_{3}}{φ_{1}} \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1} + \frac{λ ϱ_{2}}{φ_{1}} \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ - \frac{1}{Γ (β - ϖ)} \int_{0}^{1} {(1 - ι_{1})}^{β - ϖ} y (ι_{1}) d ι_{1}) . \end{matrix}

Using the fact that

^{c} D^{ϖ} (\frac{ε_{1} (0)}{κ_{1} (0, ε_{1} (0))}) + φ_{1}^{c} D^{ϖ} (\frac{ε_{1} (1)}{κ_{1} (1, ε_{1} (1))}) = ϱ_{2} \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1}

, and

\frac{ε_{1} (0)}{κ_{1} (0, ε_{1} (0))} + φ_{1} \frac{ε_{1} (1)}{κ_{1} (1, ε_{1} (1))} = ϱ_{1} \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1}

\begin{matrix} a_{0} = & \frac{- Γ (2 - ϖ) ϱ_{3}}{1 + φ_{1}} \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1} + \frac{(1 - λ Γ (2 - ϖ)) ϱ_{2}}{1 + φ_{1}} \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + \frac{λ ϱ_{1}}{1 + φ_{1}} \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + \frac{Γ (2 - ϖ) φ_{1}}{(1 + φ_{1}) Γ (β - ϖ)} \int_{0}^{1} {(1 - ι_{1})}^{β - ϖ - 1} y (ι_{1}) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (β)} \int_{0}^{1} {(1 - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1}, \end{matrix}

\begin{matrix} a_{2} = & \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{ξ} {(1 - ι_{1})}^{ϖ - 1} ε_{1} (ι_{1}) d ι_{1} + (\frac{ϱ_{1}}{1 + φ_{1}} - \frac{φ_{1} λ ϱ_{1}}{Γ (ϖ + 1) {(1 + φ_{1})}^{2}}) \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(1 - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1} \\ + \frac{φ_{1}^{2}}{{(1 + φ_{1})}^{2} Γ (β) Γ (ϖ + 1)} \int_{0}^{1} {(1 - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1} \\ + \frac{Γ (2 - ϖ)}{Γ (β - ϖ)} (\frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + 2)} - \frac{φ_{1}^{2}}{{(1 + φ_{1})}^{2} Γ (ϖ + 1)}) \int_{0}^{1} {(1 - ι_{1})}^{β - ϖ - 1} y (ι_{1}) d ι_{1} \\ + [(\frac{φ_{1}^{2}}{{(1 + φ_{1})}^{2} Γ (ϖ + 1)} - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + 2)}) \frac{Γ (2 - ϖ) λ ϱ_{2}}{φ_{1}} \\ - \frac{φ_{1} ϱ_{2}}{{(1 + φ_{1})}^{2} Γ (ϖ + 1)}] \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1} . \end{matrix}

Substituting the value of

a_{0}, a_{1},

a_{2}

,

b_{0}, b_{1},

and

b_{2}

we obtain

\begin{matrix} ε_{1} (ξ) = & κ_{1} (ξ, ε_{1} (ξ)) [\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1} + A_{1} (ξ) \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + A_{2} (ξ) \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1} + A_{3} (ξ) \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + \frac{A_{4} (ξ)}{Γ (β - ϖ)} \int_{0}^{1} {(1 - ι_{1})}^{β - ϖ - 1} y (ι_{1}) d ι_{1} \\ + \frac{A_{5} (ξ)}{Γ (β)} \int_{0}^{1} {(1 - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1} + \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(1 - ι_{1})}^{ϖ - 1} ε_{1} (ι_{1}) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) (ϖ + β)} \int_{0}^{1} {(1 - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1}] - \frac{λ}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} ε_{1} (ι_{1}) d ι_{1} . \end{matrix}

□

3. Existence Results via DFPT

To set our main results, we introduce the following assumptions

( $A_{1}$ ): The function $J_{1} : [0, T] \times E \to E$ satisfies carthéodory conditions.
( $A_{2}$ ): There exists a function $Ψ \in L^{\infty} ([0, T], R_{+})$ , which shows that

$\begin{matrix} | | J_{1} (ξ, ε_{1} (ξ)) | | \leq Ψ (ξ) (1 + | | ε_{1} | |), \forall ε_{1} \in C ([0, T], E) \end{matrix}$
( $A_{3}$ ): Assume $W \subset E$ is any bounded set ∀ $ξ \in [0, T]$ ; then,

$\begin{matrix} χ (J_{1} (ξ, W)) \leq Ψ (ξ) χ (W) . \end{matrix}$

For easy computation, we let

$\begin{matrix} R : = & κ_{1} \{\frac{J_{1}}{Γ (ϖ + β + 1)} + A_{1} | | h | | + A_{2} | | g | | + A_{3} | | k | | + \frac{A_{4} | | J_{1} | |}{Γ (β - ϖ + 1)} + \frac{A_{5} | | J_{1} | |}{Γ (β + 1)} + \\ \frac{| φ_{1} | | | λ | |}{(| 1 + φ_{1} |) Γ (ϖ + β + 1)} + \frac{| φ_{1} λ |}{(| 1 + φ_{1} |) Γ (ϖ + 1)} | | y | |\} + \frac{| λ |}{Γ | (ϖ + 1) |} | | ε_{1} | |, \end{matrix}$

Theorem 2.

Assume that the assumptions

(A_{1})

–

(A_{3})

hold true, and let

R_{Ψ} = | | Ψ | | R

. If

\begin{matrix} 4 R_{Ψ} < 1, \end{matrix}

(9)

then the BVP (1) has at least one solution, defined on [0,

T

].

Proof.

Consider the operator

H : C ([0, T], E) \to C ([0, T], E)

\begin{matrix} (H ε_{1}) (ξ) = & κ_{1} (ξ, ε_{1} (ξ)) [\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1} \\ + A_{1} (ξ) \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + A_{2} (ξ) \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + A_{3} (ξ) \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1} + \frac{A_{4} (ξ)}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} y (ι_{1}) d ι_{1} \\ + \frac{A_{5} (ξ)}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1} + \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1}] \\ - \frac{λ}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} ε_{1} (ι_{1}) d ι_{1}, \end{matrix}

The operator

H

is well-defined as a result of

A_{1}

and

A_{2}

. Therefore, (1) is equivalent to the following operator equation.

\begin{matrix} ε_{1} = H ε_{1} . \end{matrix}

(10)

Subsequently, showing the existence of fixed point for (10) is equivalent to the existence of a solution for (8).

Let

\begin{matrix} B_{ϵ} = {ε_{1} \in C ([0, T], E) : | | ε_{1} {| |}_{\infty} \leq ϵ} \end{matrix}

be a closed convex set with

ϵ > 0

, such that

\begin{matrix} ϵ \geq \frac{R_{Ψ}}{1 - R_{Ψ}} . \end{matrix}

The applicability of the DFPT will be shown in four steps

Step 1. We show that HB

H B_{ϵ} \subset B_{ϵ}

; using (

A_{2}

), we have

\begin{matrix} | H ε_{1} (ξ) | \leq & κ_{1} Ψ (ι_{1}) (1 + | | ε_{1} (ι_{1}) | |) [\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} Ψ (ι_{1}) (1 + | | ε_{1} (ι_{1}) | |) d ι_{1} \\ + A_{1} (ξ) \int_{0}^{1} Ψ (ι_{1}) (1 + | | ε_{1} (ι_{1}) | |) d ι_{1} \\ + A_{2} (ξ) \int_{0}^{1} Ψ (ι_{1}) (1 + | | ε_{1} (ι_{1}) | |) d ι_{1} \\ + A_{3} (ξ) \int_{0}^{1} Ψ (ι_{1}) (1 + | | ε_{1} (ι_{1}) | |) d ι_{1} \\ + \frac{A_{4} (ξ)}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} Ψ (ι_{1}) (1 + | | ε_{1} (ι_{1}) | |) d ι_{1} \\ + \frac{A_{5} (ξ)}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} Ψ (ι_{1}) (1 + | | ε_{1} (ι_{1}) | |) d ι_{1} \\ + \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} Ψ (ι_{1}) (1 + | | ε_{1} (ι_{1}) | |) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} Ψ (ι_{1}) (1 + | | ε_{1} (ι_{1}) | |) d ι_{1}] \\ - \frac{λ}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} Ψ (ι_{1}) (1 + | | ε_{1} (ι_{1}) | |) d ι_{1}, \end{matrix}

\begin{matrix} \leq & | | Ψ | | (1 + | | ε_{1} | |) \{\frac{J_{1}}{Γ (ϖ + β + 1)} + A_{1} | | h | | + A_{2} | | g | | + A_{3} | | k | | + \frac{A_{4} | | J_{1} | |}{Γ (β - ϖ + 1)} + \frac{A_{5} | | J_{1} | |}{Γ (β + 1)} + \\ \frac{| φ_{1} | | | λ | |}{(| 1 + φ_{1} |) Γ (ϖ + β + 1)} + \frac{| φ_{1} λ |}{(| 1 + φ_{1} |) Γ (ϖ + 1)} | | y | |\} + \frac{| λ |}{Γ | (ϖ + 1) |} | | ε_{1} | | . \end{matrix}

\begin{matrix} | | H ε_{1} | | \leq & | | Ψ | | (1 + | | ε_{1} | |) R \\ \leq & (1 + ϵ) R_{Ψ} \\ \leq & ϵ . \end{matrix}

Thus,

| | H ε_{1} | | \leq ϵ

. That is

H B_{ϵ} \subset B_{ϵ}

.

Step 2: The operator

H

is continuous. Let

{{ε_{1}}_{n}}

be a sequence in

B_{ϵ}

, such that

{ε_{1}}_{n} \to ε_{1}

as

n \to \infty

. Then,

J_{1} (ι_{1}, {ε_{1}}_{n} (ι_{1})) \to J_{1} (ι_{1}, ε_{1} (ι_{1})) a s n \to \infty,

as a sequel of the Carathéodory continuity of

J_{1}

.

(A_{2})

implies

\begin{matrix} | | H {ε_{1}}_{n} (ξ) - H ε_{1} (ξ) | | \leq & κ_{1} | | J_{1} (ι_{1}, {ε_{1}}_{n} (ι_{1})) - J_{1} (ι_{1}, ε_{1} (ι_{1})) | | \\ \times [\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} | | J_{1} (ι_{1}, {ε_{1}}_{n} (ι_{1})) - J_{1} (ι_{1}, ε_{1} (ι_{1})) | | d ι_{1} \\ + | | A_{1} (ξ) | | \int_{0}^{1} | | J_{1} (ι_{1}, {ε_{1}}_{n} (ι_{1})) - J_{1} (ι_{1}, ε_{1} (ι_{1})) | | d ι_{1} \\ + | | A_{2} (ξ) | | \int_{0}^{1} | | J_{1} (ι_{1}, {ε_{1}}_{n} (ι_{1})) - J_{1} (ι_{1}, ε_{1} (ι_{1})) | | d ι_{1} \\ + | | A_{3} (ξ) | | \int_{0}^{1} | | J_{1} (ι_{1}, {ε_{1}}_{n} (ι_{1})) - J_{1} (ι_{1}, ε_{1} (ι_{1})) | | d ι_{1} \\ + \frac{| | A_{4} (ξ) | |}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} | | J_{1} (ι_{1}, {ε_{1}}_{n} (ι_{1})) - J_{1} (ι_{1}, ε_{1} (ι_{1})) | | d ι_{1} \\ + \frac{| | A_{5} (ξ) | |}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} | | J_{1} (ι_{1}, {ε_{1}}_{n} (ι_{1})) - J_{1} (ι_{1}, ε_{1} (ι_{1})) | | d ι_{1} \\ + \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} | | J_{1} (ι_{1}, {ε_{1}}_{n} (ι_{1})) - J_{1} (ι_{1}, ε_{1} (ι_{1})) | | d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} | | J_{1} (ι_{1}, {ε_{1}}_{n} (ι_{1})) - J_{1} (ι_{1}, ε_{1} (ι_{1})) | | d ι_{1}] \\ - \frac{λ}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} | | J_{1} (ι_{1}, {ε_{1}}_{n} (ι_{1})) - J_{1} (ι_{1}, ε_{1} (ι_{1})) | | d ι_{1}, \\ \leq & R | | J_{1} (\cdot, {ε_{1}}_{n} (\cdot)) - J_{1} (\cdot, ε_{1} (\cdot)) | | . \end{matrix}

Using the Lebesgue dominated convergence theorem, it is obvious that

| | H {J_{1}}_{n} (ξ) - H ε_{1} (ξ) | | \to 0

as

n \to \infty

, ∀

ξ \in [0, T]

; consequently, we have

\begin{matrix} | | H {ε_{1}}_{n} - H ε_{1} | | \to 0 a s n \to \infty . \end{matrix}

Step 3. The operator

H

is equicontinuous. For any

0 < ξ_{1} < ξ_{2} < T

and

ε_{1} \in B_{ϵ}

, we can obtain

\begin{matrix} | | H (ε_{1}) (ξ_{2}) - H (ε_{1}) (ξ_{1}) | | \leq & |[\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ_{2}} {(ξ_{2} - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1} \\ - \frac{1}{Γ (ϖ + β)} \int_{0}^{ξ_{1}} {(ξ_{1} - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1} \\ + | A_{1} (ξ_{2}) - A_{1} (ξ_{1}) | \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + | A_{2} (ξ_{2}) - A_{2} (ξ_{1}) | \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + | A_{3} (ξ_{2}) - A_{3} (ξ_{1}) | \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + \frac{| A_{4} (ξ_{2}) - A_{4} (ξ_{1}) |}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} y (ι_{1}) d ι_{1} \\ + \frac{| A_{5} (ξ_{2}) - A_{5} (ξ_{1}) |}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1}]| \end{matrix}

\begin{matrix} | | H (ε_{1}) (ξ_{2}) - H (ε_{1}) (ξ_{1}) | | \leq & |[\frac{1}{Γ (ϖ + β)} \int_{ξ_{1}}^{ξ_{2}} y (ι_{1}) d ι_{1} \\ + | A_{1} (ξ_{2}) - A_{1} (ξ_{1}) | \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + | A_{2} (ξ_{2}) - A_{2} (ξ_{1}) | \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + | A_{3} (ξ_{2}) - A_{3} (ξ_{1}) | \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + \frac{| A_{4} (ξ_{2}) - A_{4} (ξ_{1}) |}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} y (ι_{1}) d ι_{1} \\ + \frac{| A_{5} (ξ_{2}) - A_{5} (ξ_{1}) |}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1}]| \end{matrix}

as

ξ_{1} \to ξ_{2}

is the RHS of the above approaches to zero and is free of

ε_{1} \in B_{ϵ}

. Hence, operator

H

is bounded and equicontinuous.

Step.4. We show that

H

is a

χ

-contraction on

B_{ϵ}

. For all bounded subsets

W \subset B_{ϵ}

and

δ > 0

. With the aid of Lemma 4 and the properties of

χ

, ∃

{{ε_{1}}_{k}}_{k = 1}^{\infty} \subset W

such that

\begin{matrix} χ (H W (ξ)) \leq & 2 χ \{[\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty}) d ι_{1} \\ + A_{1} (ξ) \int_{0}^{1} J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty}) d ι_{1} \\ + A_{2} (ξ) \int_{0}^{1} J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty}) d ι_{1} \\ + A_{3} (ξ) \int_{0}^{1} J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty}) d ι_{1} \\ + \frac{A_{4} (ξ)}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty}) d ι_{1} \\ + \frac{A_{5} (ξ)}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty}) d ι_{1} \\ + \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty}) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty}) d ι_{1}] \\ - \frac{λ}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty}) d ι_{1},\} + δ . \end{matrix}

The properties of

χ

,

(A_{3})

, and Lemma 3 can be used to obtain

\begin{matrix} χ (H W (ξ)) \leq & 4 \{[\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ + A_{1} (ξ) \int_{0}^{1} χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ + A_{2} (ξ) \int_{0}^{1} χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ + A_{3} (ξ) \int_{0}^{1} χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ + \frac{A_{4} (ξ)}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ + \frac{A_{5} (ξ)}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ + \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1}] \\ - \frac{λ}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1},\} + δ, \end{matrix}

\begin{matrix} \leq & 4 \{[\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} Ψ (ι_{1}) χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ + A_{1} (ξ) \int_{0}^{1} Ψ (ι_{1}) χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ + A_{2} (ξ) \int_{0}^{1} Ψ (ι_{1}) χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ + A_{3} (ξ) \int_{0}^{1} Ψ (ι_{1}) χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ + \frac{A_{4} (ξ)}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} Ψ (ι_{1}) χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ + \frac{A_{5} (ξ)}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} Ψ (ι_{1}) χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ + \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} Ψ (ι_{1}) χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} Ψ (ι_{1}) χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1}] \\ - \frac{λ}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} Ψ (ι_{1}) χ (J_{1} (ι_{1}, {{ε_{1}}_{k} (ι_{1})}_{k = 1}^{\infty})) d ι_{1},\} + δ . \end{matrix}

\begin{matrix} \leq 4 R_{Ψ} χ (R_{ϵ}) + δ, \forall δ > 0 . \end{matrix}

(11)

Then

\begin{matrix} χ (H (W)) = sup_{ξ \in [0, T]} χ (H W (ξ)) \leq 4 R_{Ψ} χ (R_{ϵ}) \end{matrix}

Using Theorem 2, we conclude the existence of a fixed point for the operator equation given by (10). This completes the proof. □

4. Stability Results

Let

ϑ > 0

and

Θ : [0, T] \to [0, \infty]

be a continuous function. We consider the following inequalities:

\begin{matrix} |^{c} D^{β} (^{c} D^{ϖ} + λ) (\frac{ε_{1} (ξ)}{κ_{1} (ξ, ε_{1} (ξ))}) - J_{1} (ξ, ε_{1} (ξ)) | \leq & ϑ, ξ \in [0, T], \end{matrix}

(12)

\begin{matrix} |^{c} D^{β} (^{c} D^{ϖ} + λ) (\frac{ε_{1} (ξ)}{κ_{1} (ξ, ε_{1} (ξ))}) - J_{1} (ξ, ε_{1} (ξ)) | \leq & ϑ Θ (ξ), ξ \in [0, T], \end{matrix}

(13)

Definition 6

([30]). Problem (1) is U-H stable if ∃

M > 0

, such that ∀

ϑ > 0

, ∀

ε_{1} \in C

of the inequality (12), ∃ solution

{ε_{1}}^{*} \in C

of problem (1) with

\begin{matrix} | ε_{1} (ξ) - {ε_{1}}^{*} (ξ) | \leq M ϑ, ξ \in [0, T] . \end{matrix}

(14)

Definition 7

([30]). Problem (1) is generalized U-H stable if ∃

Θ_{J_{1}} \in C (R^{+}, R^{+})

and

Θ_{J_{1}} (0) = 0

, such that, ∀

ε_{1} \in C

of the inequality (), ∃ a solution

{ε_{1}}^{*} \in C

of problem (1) with

\begin{matrix} | ε_{1} (ξ) - {ε_{1}}^{*} (ξ) | \leq Θ_{J_{1}} (ϑ), ξ \in [0, T] . \end{matrix}

(15)

Remark 1

([30]). A function

ε_{1} \in C

is a solution of the equality (14) ⟺∃ a function

Z \in C

, such that

(1): $| Z (ξ) | \leq ϑ, ξ \in [0, T],$
(2): $^{c} D^{β} (^{c} D^{ϖ} + λ) (\frac{ε_{1} (ξ)}{κ_{1} (ξ, ε_{1} (ξ))}) = J_{1} (ξ, ε_{1} (ξ)) + Z (ξ), ξ \in [0, T] .$

Lemma 7.

Let

1 \leq ϱ \leq 2

. If a function

ε_{1} \in C

is a solution to the inequality, then

ε_{1}

is a solution of the following integral inequality:

\begin{matrix} | ε_{1} (ξ) - E_{ε_{1}} | \leq R ϑ, \end{matrix}

(16)

where

\begin{matrix} E_{ε_{1}} = & κ_{1} (ξ, ε_{1} (ξ)) [\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1} \\ + A_{1} (ξ) \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + A_{2} (ξ) \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + A_{3} (ξ) \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1} + \frac{A_{4} (ξ)}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} y (ι_{1}) d ι_{1} \\ + \frac{A_{5} (ξ)}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1} + \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1}] \\ - \frac{λ}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} ε_{1} (ι_{1}) d ι_{1}, \end{matrix}

Proof.

Using Remark 1,

\begin{matrix} ε_{1} (ξ) = & [\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1} \\ + A_{1} (ξ) \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + A_{2} (ξ) \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + A_{3} (ξ) \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1} + \frac{A_{4} (ξ)}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} y (ι_{1}) d ι_{1} \\ + \frac{A_{5} (ξ)}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1} + \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1}] \\ - \frac{λ}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} ε_{1} (ι_{1}) d ι_{1}, \\ + [\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1} \\ + A_{1} (ξ) \int_{0}^{1} Z (ι_{1}) d ι_{1} \\ + A_{2} (ξ) \int_{0}^{1} Z (ι_{1}) d ι_{1} \\ + A_{3} (ξ) \int_{0}^{1} Z (ι_{1}) d ι_{1} + \frac{A_{4} (ξ)}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} Z (ι_{1}) d ι_{1} \\ + \frac{A_{5} (ξ)}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} Z (ι_{1}) d ι_{1} + \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} Z (ι_{1}) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} Z (ι_{1}) d ι_{1}] \\ - \frac{λ}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} Z (ι_{1}) d ι_{1}, \end{matrix}

(17)

implies

\begin{matrix} | ε_{1} (ξ) - E_{ε_{1}} | = & |[\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1} \\ + A_{1} (ξ) \int_{0}^{1} Z (ι_{1}) d ι_{1} \\ + A_{2} (ξ) \int_{0}^{1} Z (ι_{1}) d ι_{1} \\ + A_{3} (ξ) \int_{0}^{1} Z (ι_{1}) d ι_{1} + \frac{A_{4} (ξ)}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} Z (ι_{1}) d ι_{1} \\ + \frac{A_{5} (ξ)}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} Z (ι_{1}) d ι_{1} + \frac{φ_{1} λ}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} Z (ι_{1}) d ι_{1} \\ - \frac{φ_{1}}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} Z (ι_{1}) d ι_{1}] \\ - \frac{λ}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} Z (ι_{1}) d ι_{1},| \\ \leq ϑ [\{\frac{J_{1}}{Γ (ϖ + β + 1)} + A_{1} | | h | | + A_{2} | | g | | + A_{3} | | k | | + \frac{A_{4} | | J_{1} | |}{Γ (β - ϖ + 1)} + \frac{A_{5} | | J_{1} | |}{Γ (β + 1)} \\ + \frac{| φ_{1} | | | λ | |}{(| 1 + φ_{1} |) Γ (ϖ + β + 1)} + \frac{| φ_{1} λ |}{(| 1 + φ_{1} |) Γ (ϖ + 1)} | | y | |\} + \frac{| λ |}{Γ | (ϖ + 1) |} | | ε_{1} | |] \\ \leq R ϑ . \end{matrix}

(18)

□

We now state the main theorem as follows:

Theorem 3.

Assume that

(A_{1})

and

(A_{2})

are satisfied with

R_{Ψ} < 1

. Then, problem (1) is U-H and is generalized as U-H stable.

Proof.

Suppose that

ε_{1} \in C

is a solution of inequality (14) and

{ε_{1}}^{*} \in C

is a unique solution of problem (1). Then, it follows from Lemma 7 that

\begin{matrix} | ε_{1} (ξ) - {ε_{1}}^{*} (ξ) | = & |[\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1} \\ + | A_{1} (ξ) | \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + | A_{2} (ξ) | \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1} \\ + | A_{3} (ξ) | \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1} + \frac{| A_{4} (ξ) |}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} y (ι_{1}) d ι_{1} \\ + \frac{| A_{5} (ξ) |}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1} + \frac{| φ_{1} λ |}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} y (ι_{1}) d ι_{1} \\ - \frac{| φ_{1} |}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} y (ι_{1}) d ι_{1}] \\ - \frac{| λ |}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} ε_{1} (ι_{1}) d ι_{1}| \end{matrix}

\begin{matrix} \leq & | ε_{1} (ξ) - E_{ε_{1}} | + |[\frac{1}{Γ (ϖ + β)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ + β - 1} J_{1} (ι_{1}, ε_{1} (ι_{1})) - J_{1} (ι_{1}, {ε_{1}}^{*} (ι_{1})) d ι_{1} \\ + | A_{1} (ξ) | \int_{0}^{1} J_{1} (ι_{1}, ε_{1} (ι_{1})) - J_{1} (ι_{1}, {ε_{1}}^{*} (ι_{1})) d ι_{1} \\ + | A_{2} (ξ) | \int_{0}^{1} J_{1} (ι_{1}, ε_{1} (ι_{1})) - J_{1} (ι_{1}, {ε_{1}}^{*} (ι_{1})) d ι_{1} \\ + | A_{3} (ξ) | \int_{0}^{1} J_{1} (ι_{1}, ε_{1} (ι_{1})) - J_{1} (ι_{1}, {ε_{1}}^{*} (ι_{1})) d ι_{1} \\ + \frac{| A_{4} (ξ) |}{Γ (β - ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - ϖ - 1} J_{1} (ι_{1}, ε_{1} (ι_{1})) - J_{1} (ι_{1}, {ε_{1}}^{*} (ι_{1})) d ι_{1} \\ + \frac{| A_{5} (ξ) |}{Γ (β)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} J_{1} (ι_{1}, ε_{1} (ι_{1})) - J_{1} (ι_{1}, {ε_{1}}^{*} (ι_{1})) d ι_{1} \\ + \frac{| φ_{1} λ |}{(1 + φ_{1}) Γ (ϖ)} \int_{0}^{1} {(ξ - ι_{1})}^{β - 1} J_{1} (ι_{1}, ε_{1} (ι_{1})) - J_{1} (ι_{1}, {ε_{1}}^{*} (ι_{1})) d ι_{1} \\ - \frac{| φ_{1} |}{(1 + φ_{1}) Γ (ϖ + β)} \int_{0}^{1} {(ξ - ι_{1})}^{ϖ + β - 1} J_{1} (ι_{1}, ε_{1} (ι_{1})) - J_{1} (ι_{1}, {ε_{1}}^{*} (ι_{1})) d ι_{1}] \\ - \frac{| λ |}{Γ (ϖ)} \int_{0}^{ξ} {(ξ - ι_{1})}^{ϖ - 1} J_{1} (ι_{1}, ε_{1} (ι_{1})) - J_{1} (ι_{1}, {ε_{1}}^{*} (ι_{1})) d ι_{1}| \\ \leq R ϑ + Ψ R | ε_{1} (ξ) - {ε_{1}}^{*} (ξ) |, \end{matrix}

which implies

\begin{matrix} | | ε_{1} (ξ) - {ε_{1}}^{*} | | \leq M ϑ, \end{matrix}

where

\begin{matrix} M = \frac{R}{1 - Ψ R} > 0 . \end{matrix}

Hence, we conclude that problem (1) is U-H stable. In addition, by denoting

Θ_{J_{1}} (ϑ) = M ϑ

, such that

Θ_{J_{1}} (0) = 0

, problem (1) is generalized U-H stable. □

5. Example

Example 1.

Denote the Banach space of real sequences by

C_{0} = {ε_{1} = ({ε_{1}}_{1}, {ε_{1}}_{2}, \dots) : {ε_{1}}_{n} \to 0 (n \to \infty)}

, with the norm

\begin{matrix} | | ε_{1} {| |}_{\infty} = sup_{n \geq 1} | {ε_{1}}_{n} | \end{matrix}

Consider the following BVP

\begin{matrix} \{\begin{matrix} ^{c} D^{β} (^{c} D^{ϖ} + λ) (\frac{ε_{1} (ξ)}{κ_{1} (ξ, ε_{1} (ξ))}) = J_{1} (ξ, ε_{1} (ξ)) a . e . ξ \in J = [0, 1] \\ \frac{ε_{1} (0)}{κ_{1} (0, ε_{1} (0))} + φ_{1} \frac{ε_{1} (1)}{κ_{1} (1, ε_{1} (1))} = ϱ_{1} \int_{0}^{1} g (ι_{1}, ε_{1} (ι_{1})) d ι_{1}, \\ ^{c} D^{ϖ} (\frac{ε_{1} (0)}{κ_{1} (0, ε_{1} (0))}) + φ_{1}^{c} D^{ϖ} (\frac{ε_{1} (1)}{κ_{1} (1, ε_{1} (1))}) = ϱ_{2} \int_{0}^{1} h (ι_{1}, ε_{1} (ι_{1})) d ι_{1}, \\ ^{c} D^{2 ϖ} (\frac{ε_{1} (0)}{κ_{1} (0, ε_{1} (0))}) + φ_{1}^{c} D^{2 ϖ} (\frac{ε_{1} (1)}{κ_{1} (1, ε_{1} (1))}) = ϱ_{3} \int_{0}^{1} k (ι_{1}, ε_{1} (ι_{1})) d ι_{1}, \end{matrix} \end{matrix}

(19)

where Here

ϖ = 1 / 3, β = 4 / 3, λ = 1 / 300, φ_{1} = 1, ϱ_{1} = ϱ_{2} = ϱ_{3} = 1 / 200

and

\begin{matrix} R < 1.354 . \end{matrix}

Here

J_{1} : [0, 1] \times C_{0} \to C_{0}

given by

\begin{matrix} J_{1} (ξ, ε_{1}) = {\{\frac{1}{\sqrt{ξ^{2} + 49}} (\frac{ξ sin ε_{1}}{49} + e^{ξ} cos ξ)\}}_{n \geq 1}, f o r ξ \in [0, 1], ε_{1} = {{ε_{1}}_{n}}_{n \geq 1} \in C_{0} . \end{matrix}

It is clear that condition

(A_{1})

holds, and as

\begin{matrix} | | J_{1} (ξ, ε_{1}) | | = & ∥\frac{1}{\sqrt{ξ^{2} + 49}} (\frac{ξ sin ε_{1}}{49} + e^{ξ} cos ξ)∥ \\ \leq \frac{1}{\sqrt{ξ^{2} + 49}} (1 + | | ε_{1} | |) \\ = Ψ (ξ) (1 + | | ε_{1} | |) . \end{matrix}

Therefore,

(A_{2})

satisfied, with

\begin{matrix} Ψ (ξ) = \frac{1}{\sqrt{ξ^{2} + 49}}, ξ \in [0, 1] . \end{matrix}

And the bounded set

J_{1} \subset C_{0},

we have

\begin{matrix} χ (J_{1} (ξ, J_{1})) \leq \frac{1}{\sqrt{ξ^{2} + 49}} χ (J_{1}), \forall ξ \in [0, 1] . \end{matrix}

So,

(A_{3})

holds true. Indeed,

4 R_{Ψ} = 0.76593

and

(1 + ϵ) R_{Ψ} = ϵ

. Thus,

\begin{matrix} ϵ \geq \frac{R_{Ψ}}{1 - R_{Ψ}} = \frac{0.15471}{1 - 0.19148} = \frac{0.19148}{0.80852} \approx 0.236827784 . \end{matrix}

Then ϵ can be chosen as

ϵ = 0.2 > 0.183

. Consequently, all conditions of Theorem 2 hold true. This yields the existence of a solution

ε_{1} \in C ([0, 1], C_{0})

for the problem (1).

6. Conclusions

We discussed the existence results for a mixed hybrid fractional differential equation of sequential type with nonlocal integral hybrid boundary conditions. The main results are established with the aid of Darbo’s fixed point theorem and Hausdorff’s measure of noncompactness method. Using standard functional analysis, we showed Ulam–Hyers stability. Our results in this configuration are novel, and add to the body of knowledge on the theory of fractional differential equations. For future work, we suggest using other types of fractional derivative operator, such as the generalized Hilfer fractional derivative. Anyone interested in the subject can also investigate the existence and uniqueness of solutions to the coupled or tripled systems using several fixed points theorems, such as Banach contraction, mapping principle, Leray–Schuader’s alternative, and Mönch’s fixed point theorem.

Author Contributions

Methodology, M.A. (Muath Awadalla); Writing—original draft, M.A. (Muath Awadalla) and M.M.; Writing—review & editing, M.A. (Meraa Arab), K.A., N.I.M. and T.N.G.; Supervision, M.A. (Muath Awadalla); Project administration, M.A. (Muath Awadalla). All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Deanship of Scientific Research, Vice Presidency for Graduate Studies and Scientific Research, King Faisal University, Saudi Arabia [Grant No. 2785].

Data Availability Statement

No data were used to support this study.

Conflicts of Interest

The authors declare no conflict of interest.

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Arab, M.; Awadalla, M.; Manigandan, M.; Abuasbeh, K.; Mahmudov, N.I.; Nandha Gopal, T. On the Existence Results for a Mixed Hybrid Fractional Differential Equations of Sequential Type. Fractal Fract. 2023, 7, 229. https://doi.org/10.3390/fractalfract7030229

AMA Style

Arab M, Awadalla M, Manigandan M, Abuasbeh K, Mahmudov NI, Nandha Gopal T. On the Existence Results for a Mixed Hybrid Fractional Differential Equations of Sequential Type. Fractal and Fractional. 2023; 7(3):229. https://doi.org/10.3390/fractalfract7030229

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Arab, Meraa, Muath Awadalla, Murugesan Manigandan, Kinda Abuasbeh, Nazim I. Mahmudov, and Thangaraj Nandha Gopal. 2023. "On the Existence Results for a Mixed Hybrid Fractional Differential Equations of Sequential Type" Fractal and Fractional 7, no. 3: 229. https://doi.org/10.3390/fractalfract7030229

APA Style

Arab, M., Awadalla, M., Manigandan, M., Abuasbeh, K., Mahmudov, N. I., & Nandha Gopal, T. (2023). On the Existence Results for a Mixed Hybrid Fractional Differential Equations of Sequential Type. Fractal and Fractional, 7(3), 229. https://doi.org/10.3390/fractalfract7030229

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On the Existence Results for a Mixed Hybrid Fractional Differential Equations of Sequential Type

Abstract

1. Introduction

2. Preliminaries

3. Existence Results via DFPT

4. Stability Results

5. Example

6. Conclusions

Author Contributions

Funding

Data Availability Statement

Conflicts of Interest

References

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