The Cădariu-Radu Method for Existence, Uniqueness and Gauss Hypergeometric Stability of Ω-Hilfer Fractional Differential Equations

Aderyani, Safoura Rezaei; Saadati, Reza; Fečkan, Michal

doi:10.3390/math9121408

Open AccessArticle

The Cădariu-Radu Method for Existence, Uniqueness and Gauss Hypergeometric Stability of Ω-Hilfer Fractional Differential Equations

by

Safoura Rezaei Aderyani

¹,

Reza Saadati

^1,*

and

Michal Fečkan

^2,*

¹

School of Mathematics, Iran University of Science and Technology, Narmak, Tehran 1311416846, Iran

²

Department of Mathematical Analysis and Numerical Mathematics, Comenius University in Bratislava, Mlynská dolina, 84248 Bratislava, Slovakia

^*

Authors to whom correspondence should be addressed.

Mathematics 2021, 9(12), 1408; https://doi.org/10.3390/math9121408

Submission received: 20 May 2021 / Revised: 11 June 2021 / Accepted: 15 June 2021 / Published: 17 June 2021

(This article belongs to the Special Issue Qualitative Theory of Fractional-Order Systems)

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Abstract

:

Using the Cădariu–Radu method derived from the Diaz–Margolis theorem, we study the existence, uniqueness and Gauss hypergeometric stability of Ω-Hilfer fractional differential equations defined on compact domains. Next, we show the main results for unbounded domains. To illustrate the main result for a fractional system, we present an example.

Keywords:

hypergeometric control function; stability; Ω-Hilfer fractional differential equations; Diaz–Margolis theorem

MSC:

46L57; 39B62

1. Introduction

In 1941, Hyers proved that for each

ϑ > 0,

there exists a

σ > 0

such that if

∥ h (z + w) - h (z) - h (w) ∥ < σ

, then there exists an additive mapping

h^{'} (z)

with

∥ h (z) - h^{'} (z) ∥ \leq ϑ

. Next, the Hyers’ results has been developed by Th. M. Rassias. In fact, he attempted to weaken the condition as follows:

∥ h (z + w) - h (z) - h (w) ∥ < σ (∥ z ∥ + ∥ w ∥),

this led to the generalization of what is known as Hyers–Ulam–Rassias stability of functional equations [1,2].

On the other hand, in 1695, the question of the semi-derivative was raised. The first known references can be found in inventing of the concept of the derivative of nth order, belonging to Marquis de l’Hospital and Gottfried Leibniz. This question attracted the interest of many mathematicians like Liouville, Riemann, Euler, Laplace and many others. The theory of fractional calculus (FC), developed rapidly and its application is done very widely nowadays. For more details, see [3,4,5,6,7,8].

Motivated by [9], in this paper we replace Mittag–Leffler control functions by Hypergeometric control functions to investigate Hypergeometric stability of the following Ω-Hilfer fractional differential equation, through the Cădariu–Radu method derived from the Diaz–Margolis theorem,

\{\begin{matrix} ^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} g (τ) = F (τ, g (τ), g (μ (τ))), & τ \in (0, p], \\ I_{0^{+}}^{1 - S_{3}; Ω} g (0^{+}) = E_{\circ}, & E_{\circ} \in R, \end{matrix}

(1)

in which

^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} (.)

is the

Ω

-Hilfer fractional derivative of order

0 < S_{1} \leq 1

and type

0 \leq S_{2} \leq 1

,

I_{0^{+}}^{1 - S_{3}; Ω} (.)

is the Riemann–Liouville fractional integral of order

1 - S_{3}

,

S_{3} = S_{1} + S_{2} (1 - S_{1})

w.r.t the mapping

Ω

([10]), and

F : (0, p] \times R^{2} ⟶ R

is a given mapping.

2. Preliminaries

Let

[M_{1}, M_{2}] (0 \leq M_{1} < M_{2} < \infty)

be a finite interval on

R^{+}

, and let

C [M_{1}, M_{2}]

be the space of continuous functions

μ : [M_{1}, M_{2}] ⟶ R

with norm

{∥ μ ∥}_{C [M_{1}, M_{2}]} = sup_{M_{1} \leq B_{\circ} \leq M_{2}} | μ (B_{\circ}) | .

The weighted space

C_{1 - S_{3}; Ω} [M_{1}, M_{2}]

of continuous

μ

on

(M_{1}, M_{2}]

is defined by (see [5]).

C_{1 - S_{3}; Ω} [M_{1}, M_{2}] = \{μ : (M_{1}, M_{2}] ⟶ R; {(Ω (B_{\circ}) - Ω (M_{1}))}^{1 - S_{3}} μ (B_{\circ}) \in C [M_{1}, M_{2}]\},

in which

0 \leq S_{3} < 1

, with norm

{∥ μ ∥}_{C_{1 - S_{3}; Ω} [M_{1}, M_{2}]} = sup_{B_{\circ} \in [M_{1}, M_{2}]} | {(Ω (B_{\circ}) - Ω (M_{1}))}^{1 - S_{3}} μ (B_{\circ}) | .

Definition 1

([11]). Consider the Gamma function Γ. Let

(M_{1}, M_{2}) (- \infty \leq M_{1} < M_{2} \leq \infty)

be an interval on

R

, and

S_{1} > 0

. Furthermore, consider the increasing map

Ω (B_{\circ}) > 0

on

(M_{1}, M_{2}]

, which has a continuous derivative

Ω^{'} (B_{\circ})

on

(M_{1}, M_{2})

. The fractional integrals of a function μ, w.r.t Ω, on

[M_{1}, M_{2}]

are defined as

I_{M_{1}^{+}}^{S_{1}; Ω} μ (B_{\circ}) = \frac{1}{Γ (S_{1})} \int_{M_{1}}^{B_{\circ}} Ω^{'} (τ) {(Ω (B_{\circ}) - Ω (τ))}^{S_{1} - 1} μ (τ) d τ .

Definition 2

([11]). Let

S_{1} \in (ı - 1, ı)

with

ı \in N

, and suppose

F, Ω \in C^{ı} [M_{1}, M_{2}]

are two mappings such that Ω is increasing and

Ω^{'} (B_{\circ}) \neq 0

for any

B_{\circ} \in [M_{1}, M_{2}]

. Then the Ω-Hilfer fractional derivative

^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} (.)

of a mapping μ of order

S_{1}

and type

0 \leq S_{2} \leq 1

is defined as

^{H} D_{M_{1}^{+}}^{S_{1}, S_{2}; Ω} μ (B_{\circ}) = I_{M_{1}^{+}}^{S_{2} (ı - S_{1}); Ω} {(\frac{1}{Ω^{'} (B_{\circ})} \frac{d}{d B_{\circ}})}^{ı} I_{M_{1}^{+}}^{(1 - S_{2}) (ı - S_{1}); Ω} μ (B_{\circ})

.

Theorem 1

([11]). Let

μ \in C^{1} [0, M_{2}]

, and

S_{2} \in [0, 1]

. Then

^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} I_{0^{+}}^{S_{1}; Ω} μ (B_{\circ}) = μ (B_{\circ})

.

Theorem 2

([11]). Let

μ \in C^{1} [0, M_{2}]

, and

S_{2} \in [0, 1]

. Then

I_{0^{+}}^{S_{1}; Ω}^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} μ (B_{\circ}) = μ (B_{\circ}) - \frac{{(Ω (B_{\circ}) - Ω^{'} (0))}^{S_{3} - 1}}{Γ (S_{3})} I_{0^{+}}^{(1 - S_{2}) (1 - S_{1}); Ω} μ (0)

.

Lemma 1

([12]). Let

ℏ_{1}, ℏ_{2} > 0

. If

Ψ (τ) = {(Ω (τ) - Ω (M_{1}))}^{ℏ_{2} - 1},

then

I_{M_{1}^{+}}^{ℏ_{1}; Ω} Ψ (τ) = \frac{Γ (ℏ_{2})}{Γ (ℏ_{2} + ℏ_{1})} {(Ω (τ) - Ω (M_{1}))}^{ℏ_{1} + ℏ_{2} - 1} .

For

F \in C ((0, p] \times R^{2}, R)

and

θ > 0

, consider the following equations

^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} g (τ) = F (τ, g (τ), g (μ (τ))), τ \in (0, p],

(2)

I_{0^{+}}^{1 - S_{3}; Ω} g (0^{+}) = E_{\circ}, E_{\circ} \in R,

(3)

and consider the inequality

|^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} f (τ) - F (τ, f (τ), f (μ (τ))) | \leq θ B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}}), τ \in (0, p],

(4)

where

B (α, β, γ; ξ)

is the Gauss Hypergeometric series (see [10]) defined by

B (α, β, γ; ξ) = \sum_{s = 0}^{\infty} \frac{{(α)}_{s} {(β)}_{s}}{{(γ)}_{s}} \frac{ξ^{s}}{s!} = \frac{Γ (c)}{Γ (a) Γ (b)} \sum_{s = 0}^{\infty} \frac{Γ (α + s) Γ (β + s)}{Γ (γ + s)} \frac{ξ^{s}}{s!},

in which

ξ, α, β, γ \in C

, and

ℜ (α), ℜ (β), ℜ (γ) > 0

.

Motivated by [9], we define the following concept.

Definition 3.

Equations (2) and (3) have Gauss Hypergeometric stability w.r.t

B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}})

if we can find

c > 0

such that, for each

θ > 0

and each solution

f \in C_{1 - S_{3}; Ω} (0, p]

to (4) and

I_{0^{+}}^{1 - S_{3}; Ω} g (0^{+}) = E_{\circ}

, there exists a solution

g \in C_{1 - S_{3}; Ω} (0, p]

to (2) and (3) with

| f (τ) - g (τ) | \leq c θ B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}}), τ \in (0, p] .

Lemma 2

([5]). Consider the continuous mapping

F : (0, p] \times R \times R ⟶ R

. Then (2) and (3) are equivalent to

g (τ) = \frac{{(Ω (τ) - Ω (0))}^{S_{3} - 1}}{Γ (S_{3})} E_{\circ} + \frac{1}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (τ^{'}) {(Ω (τ) - Ω (τ^{'}))}^{S_{1} - 1} F (τ^{'}, g (τ^{'}), g (μ (τ^{'}))) d τ^{'} .

Remark 1.

Suppose

f \in C_{1 - S_{3}; Ω} (0, p]

is a solution of inequality (4) and

I_{0^{+}}^{1 - S_{3}; Ω} g (0^{+}) = E_{\circ}

. Then, f is a solution of the following integral inequality:

\begin{matrix} | f (τ) - \frac{{(Ω (τ) - Ω (0))}^{S_{3} - 1}}{Γ (S_{3})} E_{\circ} - \frac{1}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (s) {(Ω (τ) - Ω (s))}^{S_{1} - 1} F (s, f (s), f (μ (s))) d s | \\ \leq \frac{θ}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (s) {(Ω (τ) - Ω (s))}^{S_{1} - 1} B (α, β, γ; {(Ω (s) - Ω (0))}^{S_{1}}) d s \\ \leq \frac{θ}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (s) {(Ω (τ) - Ω (s))}^{S_{1} - 1} \frac{Γ (γ)}{Γ (α) Γ (β)} \sum_{k = 0}^{\infty} \frac{Γ (α + k) Γ (β + k)}{Γ (γ + k)} \frac{{(Ω (s) - Ω (0))}^{k S_{1}}}{k!} d s \\ = \frac{θ}{Γ (S_{1})} \frac{Γ (γ)}{Γ (α) Γ (β)} \sum_{k = 0}^{\infty} \frac{Γ (α + k) Γ (β + k)}{Γ (γ + k)} \frac{1}{k!} \int_{0}^{τ} {(Ω (τ) - Ω (s))}^{S_{1} - 1} {(Ω (s) - Ω (0))}^{k S_{1}} d Ω (s) \\ = \frac{θ}{Γ (S_{1})} \frac{Γ (γ)}{Γ (α) Γ (β)} \sum_{k = 0}^{\infty} \frac{Γ (α + k) Γ (β + k)}{Γ (γ + k)} \frac{1}{k!} \int_{0}^{Ω (τ) - Ω (0)} {(Ω (τ) - Ω (0) - u)}^{S_{1} - 1} {(u)}^{k S_{1}} d u \\ (u = Ω (s) - Ω (0)) \\ \leq \frac{θ}{Γ (S_{1})} \frac{Γ (γ)}{Γ (α) Γ (β)} \sum_{k = 0}^{\infty} \frac{Γ (α + k) Γ (β + k)}{Γ (γ + k)} \frac{1}{k!} {(Ω (τ) - Ω (0))}^{S_{1} - 1} \int_{0}^{Ω (τ) - Ω (0)} {(1 - \frac{u}{Ω (τ) - Ω (0)})}^{S_{1} - 1} u^{k S_{1}} d u \\ = \frac{θ}{Γ (S_{1})} \frac{Γ (γ)}{Γ (α) Γ (β)} \sum_{k = 0}^{\infty} \frac{Γ (α + k) Γ (β + k)}{Γ (γ + k)} \frac{1}{k!} {(Ω (τ) - Ω (0))}^{(k + 1) S_{1}} \int_{0}^{1} {(1 - v)}^{S_{1} - 1} v^{k S_{1}} d v \\ (v = \frac{u}{Ω (τ) - Ω (0)}) \\ = \frac{θ}{Γ (S_{1})} \frac{Γ (γ)}{Γ (α) Γ (β)} \sum_{k = 0}^{\infty} \frac{Γ (α + k) Γ (β + k)}{Γ (γ + k)} \frac{1}{k!} {(Ω (τ) - Ω (0))}^{(k + 1) S_{1}} \frac{Γ (k S_{1} + 1) Γ (S_{1})}{Γ ((k + 1) S_{1} + 1)} \\ \leq θ \frac{Γ (γ)}{Γ (α) Γ (β)} \sum_{k = 0}^{\infty} \frac{Γ (α + k) Γ (β + k)}{Γ (γ + k)} \frac{{(Ω (τ) - Ω (0))}^{k S_{1}}}{k!} \\ = θ B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}}) . \end{matrix}

Now, we present an alternative fixed point theorem from the literature:

Theorem 3

([13]). Let

M

be a set with a complete

[0, \infty]

-valued metric φ, and also let the self map δ on

M

satisfy

φ (δ y, δ x) \leq κ φ (y, x), κ < 1 i s a L i p s c h i t z c o n s t a n t .

Let

y \in M

. Then, we have two options:

(I) φ (δ^{m} y, δ^{m + 1} y) = \infty, \forall m \in N,

or

(II) we can find

m_{0} \in N

such that:

(1): $φ (δ^{m} y, δ^{m + 1} y) < \infty, \forall m \geq m_{0}$ ;
(2): the fixed point $x^{*}$ of δ is the convergence point of the sequence ${δ^{m} y}$ ;
(3): in the set $V = {x \in M ∣ φ (δ^{m_{0}} y, x) < \infty}$ , $x^{*}$ is the unique fixed point of δ;
(4): $(1 - κ) φ (x, x^{*}) \leq φ (x, δ x)$ for every $x \in M$ .

3. Hypergeometric Stability

Using the Diaz–Margolis theorem (i.e., Theorem 3), we obtain a new stability approximation result for (2), for more details, we refer to [13,14,15,16,17,18,19,20,21,22,23,24]. In these sources, one can find new problems.

We assume the following conditions hold:

(J_{1})

F \in C ((0, p] \times R^{2}, R), μ \in C ([0, p], [0, p]), μ (τ) \leq τ, τ \geq 0

.

(J_{2})

There exists

0 < Θ < \frac{1}{2}

such that

| F (τ, S_{1}, S_{2}) - F (τ, R_{1}, R_{2}) | \leq Θ \sum_{j = 1}^{2} | S_{j} - R_{j} | for all τ \in (0, p], S_{j}, R_{j} \in R, j = 1, 2 .

Theorem 4.

Assume that

(J_{1})

and

(J_{2})

are satisfied. If f in

C_{1 - S_{3}; Ω} (0, p]

satisfies (4) and

I_{0^{+}}^{1 - S_{3}; Ω} g (0^{+}) = E_{\circ}

, thus, we can find a unique function g satisfying in (2) and (3) such that

| g (τ) - f (τ) | \leq \frac{θ}{1 - 2 Θ} B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}}),

(5)

for every

τ \in (0, p]

.

Proof.

Set

Ξ = C_{1 - S_{3}; Ω} (0, p]

and define a mapping

φ : Ξ \times Ξ \to [0, \infty]

by

φ (ρ, ϱ) = inf \{∁ \geq 0 : | ρ (τ) - ϱ (τ) | \leq ∁ θ B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}})\} .

(6)

We prove that

(Ξ, φ)

is a complete

[0, \infty]

-valued metric space. For the metric part, it is enough to assume that

φ (ρ, ϱ) > φ (ρ, ν) + φ (ν, ϱ)

, for some

ρ, ϱ

and

ν \in Ξ

. Thus, we can find

τ_{\circ} \in (0, p]

with

| ρ (τ_{\circ}) - ϱ (τ_{\circ}) | > (φ (ρ, ν) + φ (ν, ϱ)) θ B (α, β, γ; {(Ω (τ_{\circ}) - Ω (0))}^{S_{1}}) .

Hence, from the definition of

φ

, we get

\begin{matrix} | ρ (τ_{\circ}) - ϱ (τ_{\circ}) | \\ > & | ρ (τ_{\circ}) - ν (τ_{\circ}) | + | (ν (τ_{\circ}) - ϱ (τ_{\circ}) |, \end{matrix}

which is a contradiction. Next, we prove that

(Ξ, φ)

is complete. Assume

ω_{n}

is a Cauchy sequence in

(Ξ, φ)

. Thus, for each

ϵ > 0

we can find

ℵ_{ϵ} \in N

such that

φ (ω_{m}, ω_{n}) \leq ϵ

for each

m, n \geq ℵ_{ϵ}

. According to (6), we have

\begin{matrix} | ω_{m} (τ) - ω_{n} (τ) | \leq ϵ θ B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}}), \end{matrix}

(7)

for any

τ \in (0, p]

. If

τ

is fixed, (7) implies that

{ω_{n} (τ)}

is a Cauchy sequence in

R

. Since

R

is complete,

{ω_{n} (τ)}

converges for any

τ \in (0, p]

. Thus, we can define a mapping

ω

by

ω (τ) : = lim_{n \to \infty} ω_{n} (τ), (τ \in (0, p]) .

It is easy to check

ω \in Ξ

. If we let

m \to \infty

, it infers from (7) that

\begin{matrix} | ω (τ) - ω_{n} (τ) | \leq ϵ θ B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}}) . \end{matrix}

Considering (6), we receive

φ (ω, ω_{n}) \leq ϵ .

This implies that the Cauchy sequence

{ω_{n}}

converges to

ω

in

(Ξ, φ)

. Therefore,

(Ξ, φ)

is complete. According to Lemma 2, we have that (2) is equivalent to the following system:

g (τ) = \frac{{(Ω (τ) - Ω (0))}^{S_{3} - 1}}{Γ (S_{3})} E_{\circ} + \frac{1}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (τ^{'}) {(Ω (τ) - Ω (τ^{'}))}^{S_{1} - 1} F (τ^{'}, g (τ^{'}), g (μ (τ^{'}))) d τ^{'},

(8)

for every

τ \in (0, p]

. To see this note applying the fractional integral operator

I_{0^{+}}^{S_{1}; Ω} (.)

on both sides of the fractional Equation (1) and using Theorem 2, we get (8).

On the other hand, if g satisfies (8), then g satisfies (1). However, applying the fractional derivative

^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} (.)

on both sides of (8), we have

^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} f (τ) =^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} [\frac{{(Ω (τ) - Ω (0))}^{S_{3} - 1}}{Γ (S_{3})} E_{\circ}] +^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} I_{0^{+}}^{S_{1}; Ω} F (τ^{'}, f (τ^{'}), f (μ (τ^{'}))) .

Applying Theorem 1 and

^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} {(Ω (τ) - Ω (0))}^{S_{3} - 1} = 0, 0 < S_{3} < 1,

we conclude that

g (τ)

satisfies the initial value problem Equation (1) if and only if

g (τ)

satisfies the integral Equation (8).

Consider

δ : Ξ ⟶ Ξ

such that for

ρ \in Ξ

,

\begin{matrix} δ (ρ (τ)) \\ = & \frac{{(Ω (τ) - Ω (0))}^{S_{3} - 1}}{Γ (S_{3})} E_{\circ} + \frac{1}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (τ^{'}) {(Ω (τ) - Ω (τ^{'}))}^{S_{1} - 1} F (τ^{'}, ρ (τ^{'}), ρ (μ (τ^{'}))) d τ^{'}, \end{matrix}

(9)

for every

τ \in (0, p]

.

For

ρ \in Ξ

, we have

\begin{matrix} | δ (ρ (τ)) - δ (ρ (τ_{0})) | \\ = & | \frac{{(Ω (τ) - Ω (0))}^{S_{3} - 1}}{Γ (S_{3})} E_{\circ} + \frac{1}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (τ^{'}) {(Ω (τ) - Ω (τ^{'}))}^{S_{1} - 1} F (τ^{'}, ρ (τ^{'}), ρ (μ (τ^{'}))) d τ^{'} \\ - & \frac{{(Ω (τ_{0}) - Ω (0))}^{S_{3} - 1}}{Γ (S_{3})} E_{\circ} - \frac{1}{Γ (S_{1})} \int_{0}^{τ_{0}} Ω^{'} (τ^{'}) {(Ω (τ_{0}) - Ω (τ^{'}))}^{S_{1} - 1} F (τ^{'}, ρ (τ^{'}), ρ (μ (τ^{'}))) d τ^{'} | \\ ⟶ & 0 \end{matrix}

as

τ ⟶ τ_{0}

, which implies the the continuity property of

δ ρ

and so

δ ρ \in Ξ

.

Next, we show that the self-mapping

δ

is contractive on

Ξ

. Consider

δ : Ξ ⟶ Ξ

defined in (9).

Suppose

ρ, ϱ \in C_{1 - S_{3}; Ω} (0, p], k \in [0, \infty]

, and

φ (ρ (τ), ϱ (τ)) \leq k .

Then for every

τ \in (0, p]

,

| ρ (τ) - ϱ (τ) | \leq k θ B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}}) .

Using Remark 1, for all

τ \in (0, p]

, we have

\begin{matrix} | δ (ρ (τ)) - δ (ϱ (τ)) | \\ \leq & \frac{1}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (τ^{'}) {(Ω (τ) - Ω (τ^{'}))}^{S_{1} - 1} | F (τ^{'}, ρ (τ^{'}), ρ (μ (τ^{'}))) - F (τ^{'}, ϱ (τ^{'}), ϱ (μ (τ^{'}))) | d τ^{'} \\ \leq & \frac{Θ}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (τ^{'}) {(Ω (τ) - Ω (τ^{'}))}^{S_{1} - 1} [| ρ (τ^{'}) - ϱ (τ^{'}) | + | ρ (μ (τ^{'})) - ϱ (μ (τ^{'})) |] d τ^{'} \\ \leq & \frac{2 Θ}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (τ^{'}) {(Ω (τ) - Ω (τ^{'}))}^{S_{1} - 1} B (α, β, γ; {(Ω (τ^{'}) - Ω (0))}^{S_{1}}) d τ^{'} \\ \leq & 2 Θ k θ B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}}) . \end{matrix}

Then we have

φ (δ ρ, δ ϱ) \leq 2 Θ φ (ρ, ϱ) .

Now, since

0 < Θ < \frac{1}{2}

, we can conclude the contractively property of

δ

.

Let

f \in Ξ

. Since

δ f \in Ξ

, we have that

\begin{matrix} | δ (f (τ)) - f (τ) | \\ \leq & | f (τ) - \frac{{(Ω (τ) - Ω (0))}^{S_{3} - 1}}{Γ (S_{3})} E_{\circ} - \frac{1}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (τ^{'}) {(Ω (τ) - Ω (0))}^{S_{1} - 1} F (τ^{'}, f (τ^{'}), f (μ (τ^{'}))) d τ^{'} | \\ \leq & θ B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}}) \end{matrix}

for

τ \in (0, p]

, which implies that

φ (δ f, f) \leq 1 .

(10)

and hence for every

n \in N

, we have

φ (δ^{n} f, δ^{n + 1} f) \leq + \infty

. Now, we can apply the second part of Theorem 3 and so we can find a unique map

g \in {\tilde{σ} \in Ξ : φ (δ f, \tilde{σ}) < \infty}

such that

δ g = g

and so

g (τ) = \frac{{(Ω (τ) - Ω (0))}^{S_{3} - 1}}{Γ (S_{3})} E_{\circ} + \frac{1}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (τ^{'}) {(Ω (τ) - Ω (τ^{'}))}^{S_{1} - 1} F (τ^{'}, g (τ^{'}), g (μ (τ^{'}))) d τ^{'},

for every

τ \in (0, p]

, where

I_{0^{+}}^{1 - S_{3}; Ω} g (0^{+}) = E_{\circ} \in R .

Using Theorem 3 and (10), we have

\begin{matrix} φ (g, f) & \leq & \frac{1}{1 - 2 Θ} φ (δ f, f) \\ \leq & \frac{1}{1 - 2 Θ}, \end{matrix}

which implies (5). □

In Theorem 4, we proved Gauss Hypergeometric stability of the

Ω

-Hilfer fractional differential Equation (1) on bounded domains. Now, we extend our result to unbounded domains. Let

S = C_{1 - S_{3}; Ω} (R)

.

Theorem 5.

Let

(J_{1})

and

(J_{2})

be hold. If f in

S

satisfies (4) and

I_{0^{+}}^{1 - S_{3}; Ω} g (0^{+}) = E_{\circ},

thus, we can find a unique function g satisfying in (2) and (3) such that satisfies (5) for every

τ \in R

.

Proof.

We are going to show the result for

R

. By the same way, we can prove the theorem for

(- \infty, 0]

or

[0, + \infty)

.

For each

n \in N,

we consider

P_{n} = [P - n, P + n] .

As stated by Theorem 4, we can find a unique mapping

g_{n} \in C_{1 - S_{3}; Ω} (P_{n}, R),

such that

^{H} D_{0^{+}}^{S_{1}, S_{2}; Ω} g_{n} (τ) = F (τ, g_{n} (τ), g_{n} (μ (τ))),

(11)

I_{0^{+}}^{1 - S_{3}; Ω} g_{n} (0^{+}) = E_{\circ}, E_{\circ} \in R,

(12)

and

| g_{n} (τ) - f (τ) | \leq \frac{θ}{1 - 2 Θ} B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}}),

(13)

for every

τ \in P_{n}

. The uniqueness of

g_{n}

implies that if

τ \in P_{n},

then

g_{n} (τ) = g_{n + 1} (τ) = g_{n + 2} (τ) = \dots .

(14)

For all

τ \in R,

we define

n (τ) \in N

as

n (τ) = min {n \in N | τ \in P_{n}} .

In addition, we consider a mapping g, as

g (τ) = g_{n (τ)} (τ), τ \in R,

and we claim that

g \in S

. For a real number

τ_{1} \in R,

we consider

n_{1} = n (τ_{1}) \in N

. Thus,

τ_{1} \in {(P_{n_{1} + 1})}^{\circ}

(the interior) and we can find an

ϵ > 0

such that

g (τ) = g_{n + 1} (τ)

for all

τ

with

τ_{1} - ϵ < τ < τ_{1} + ϵ

.

Now, we want to show that g satisfies (2), (3) and (5) for any

τ \in R .

For any

τ \in R,

we consider

n (τ) \in N

. Therefore,

τ \in P_{n (τ)}

and it concludes from (11) and (12) that

\begin{matrix} g (τ) & = g_{n (τ)} (τ) \\ = \frac{{(Ω (τ) - Ω (0))}^{S_{3} - 1}}{Γ (S_{3})} E_{\circ} \\ + \frac{1}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (τ^{'}) {(Ω (τ) - Ω (τ^{'}))}^{S_{1} - 1} F (τ^{'}, g_{n (τ^{'})} (τ^{'}), g_{n (τ^{'})} (μ (τ^{'}))) d τ^{'}, \\ = \frac{{(Ω (τ) - Ω (0))}^{S_{3} - 1}}{Γ (S_{3})} E_{\circ} \\ + \frac{1}{Γ (S_{1})} \int_{0}^{τ} Ω^{'} (τ^{'}) {(Ω (τ) - Ω (τ^{'}))}^{S_{1} - 1} F (τ^{'}, g (τ^{'}), g (μ (τ^{'}))) d τ^{'}, \end{matrix}

where the above equality holds true because

n (τ^{'}) \leq n (τ)

for each

τ^{'} \in P_{n (τ)}

and it concludes from (14) that

g (τ^{'}) = g_{n (τ^{'})} (τ^{'}) = g_{n (τ)} (τ^{'}) .

Since

g (τ) = g_{n (τ)} (τ)

and

τ \in P_{n (τ)}

for all

τ \in R,

(13) implies that

\begin{matrix} | g (τ) - f (τ) | = | g_{n (τ)} (τ) - f (τ) | \leq \frac{θ}{1 - 2 Θ} B (α, β, γ; {(Ω (τ) - Ω (0))}^{S_{1}}) . \end{matrix}

In the end, we claim that g is unique. Let

g^{'} \in S

be another function, which satisfies (2), (3) and (5), for all

τ \in R .

Since

{g |}_{P_{n (τ)}} (= g_{n (τ)})

and

g^{'} |_{P_{n (τ)}}

both satisfy (2), (3) and (5), for all

τ \in P_{n (τ)},

the uniqueness of

g_{n (τ)} {= g |}_{P_{n (τ)}}

implies that

{g (τ) = g |}_{P_{n (τ)}} (τ) = g^{'} |_{P_{n (τ)}} (τ) = g^{'} (τ)

as required. □

4. Application

In this section, as an application, we apply our main result to prove an example. Our main result can be applied for recent results presented in [25,26,27,28,29,30,31,32,33,34,35].

Example 1.

Consider the following fractional system

\{\begin{matrix} ^{H} D_{0^{+}}^{\frac{1}{4}, \frac{3}{4}; e^{τ}} g (τ) = \frac{1}{4} sin (g (\frac{3}{4} τ)) + \frac{1}{4} a r c c o t (g (τ)), & τ \in (0, 1], \\ I_{0^{+}}^{\frac{3}{16}; e^{ζ}} g (0^{+}) = g_{0}, \end{matrix}

(15)

and the inequality

|^{H} D_{0^{+}}^{\frac{1}{4}, \frac{3}{4}; e^{τ}} g (τ) - F (τ, g (τ), g (\frac{3}{4} τ)) | \leq θ B (α, β, γ; {(e^{τ} - 1)}^{\frac{1}{4}}) .

Let

S_{1} = \frac{1}{4}, S_{2} = \frac{3}{4}

, then

S_{3} = S_{1} + S_{2} (1 - S_{1}) = \frac{13}{16}, p = 1, Ω (.) = e^{.}, μ (.) = \frac{3}{4} (.)

,

F (., g (.), g (μ (.))) = \frac{1}{4} sin (g (\frac{3}{4} (.))) + \frac{1}{4} a r c c o t (g (.))

, and

Θ = \frac{1}{4}

. Thus,

2 Θ = \frac{1}{2}

.

We want to show that

F (., g (.), g (μ (.)))

satisfies in

(J_{2})

:

\begin{matrix} | \frac{1}{4} sin (g_{1}) + \frac{1}{4} a r c c o t (g_{1}) - \frac{1}{4} sin (g_{2}) - \frac{1}{4} a r c c o t (g_{2}) | \\ \leq & | \frac{1}{4} sin (g_{1}) - \frac{1}{4} sin (g_{2}) | + | \frac{1}{4} a r c c o t (g_{1}) - \frac{1}{4} a r c c o t (g_{2}) | \\ \leq & | \frac{1}{4} (g_{1} - g_{2}) | + | \frac{1}{4} {(a r c c o t (C))}^{'} (g_{1} - g_{2}) | \\ \leq & | \frac{1}{4} (g_{1} - g_{2}) | + | \frac{1}{4} \frac{- 1}{1 + C^{2}} (g_{1} - g_{2}) | \\ \leq & | \frac{1}{4} (g_{1} - g_{2}) | + | \frac{1}{4} (g_{1} - g_{2}) | \\ \leq & \frac{1}{2} | g_{1} - g_{2} |, \end{matrix}

in which

g_{1} \leq C \leq g_{2}

, thus F is a contraction.

Now, Theorem 4 implies that problem (15) has a unique solution and also is Hypergeometric stable with

| g (τ) - f (τ) | \leq 2 θ B (α, β, γ; {(e^{τ} - 1)}^{\frac{1}{4}}), τ \in (0, 1] .

5. Conclusions

In this paper, we introduced a class of

Ω

-Hilfer fractional-order delay differential equations and through the Cădariu–Radu method derived from the Diaz–Margolis theorem, we studied the Hypergeometric stability for both bounded and unbounded domains. Finally, as an application, we investigated the Hypergeometric stability of a fractional system.

Author Contributions

Investigation, S.R.A.; methodology, M.F.; supervision, R.S. All authors have read and agreed to the published version of the manuscript.

Funding

M.F. is partially supported by the Slovak Research and Development Agency under the contract No. APVV-18-0308 and by the Slovak Grant Agency VEGA No. 1/0358/20.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The authors are thankful to the area editor for giving valuable comments and suggestions.

Conflicts of Interest

The authors declare that they have no competing interest.

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Aderyani, S.R.; Saadati, R.; Fečkan, M. The Cădariu-Radu Method for Existence, Uniqueness and Gauss Hypergeometric Stability of Ω-Hilfer Fractional Differential Equations. Mathematics 2021, 9, 1408. https://doi.org/10.3390/math9121408

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Aderyani SR, Saadati R, Fečkan M. The Cădariu-Radu Method for Existence, Uniqueness and Gauss Hypergeometric Stability of Ω-Hilfer Fractional Differential Equations. Mathematics. 2021; 9(12):1408. https://doi.org/10.3390/math9121408

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Aderyani, Safoura Rezaei, Reza Saadati, and Michal Fečkan. 2021. "The Cădariu-Radu Method for Existence, Uniqueness and Gauss Hypergeometric Stability of Ω-Hilfer Fractional Differential Equations" Mathematics 9, no. 12: 1408. https://doi.org/10.3390/math9121408

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The Cădariu-Radu Method for Existence, Uniqueness and Gauss Hypergeometric Stability of Ω-Hilfer Fractional Differential Equations

Abstract

1. Introduction

2. Preliminaries

3. Hypergeometric Stability

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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