Existence and Uniqueness Theorems for a Variable-Order Fractional Differential Equation with Delay

Telli, Benoumran; Souid, Mohammed Said; Alzabut, Jehad; Khan, Hasib

doi:10.3390/axioms12040339

Open AccessArticle

Existence and Uniqueness Theorems for a Variable-Order Fractional Differential Equation with Delay

by

Benoumran Telli

¹,

Mohammed Said Souid

²

,

Jehad Alzabut

^3,4,*

and

Hasib Khan

^3,5

¹

Department of Mathematics, University of Tiaret, Tiaret 14035, Algeria

²

Department of Economic Sciences, University of Tiaret, Tiaret 14035, Algeria

³

Department of Mathematics and Sciences, Prince Sultan University, Riyadh 11586, Saudi Arabia

⁴

Department of Industrial Engineering, OSTİM Technical University, 06374 Ankara, Türkiye

⁵

Department of Mathematics, Shaheed Benazir Bhutto University, Sheringal, Dir Upper, Khyber Pakhtunkhwa 18000, Pakistan

^*

Author to whom correspondence should be addressed.

Axioms 2023, 12(4), 339; https://doi.org/10.3390/axioms12040339

Submission received: 31 December 2022 / Revised: 11 March 2023 / Accepted: 27 March 2023 / Published: 30 March 2023

(This article belongs to the Special Issue New Trends in Fractional Operators with Applications in Mathematical Physics)

Download Review Reports Versions Notes

Abstract

:

This study establishes the existence and stability of solutions for a general class of Riemann–Liouville (RL) fractional differential equations (FDEs) with a variable order and finite delay. Our findings are confirmed by the fixed-point theorems (FPTs) from the available literature. We transform the RL FDE of variable order to alternate RL fractional integral structure, then with the use of classical FPTs, the existence results are studied and the Hyers–Ulam stability is established by the help of standard notions. The approach is more broad-based and the same methodology can be used for a number of additional issues.

Keywords:

fractional differential equations of variable order; fixed-point theorems; existence of solutions; Hyers–Ulam stability

MSC:

26A33; 34A08; 35R11

1. Introduction

Numerous studies in science and engineering have shown the importance of mathematical modelling and numerical simulations. Fractional-order modelling is one of the well-researched areas which has provided the scientists a useful technique for the generalization of classical results. Several fractional-order operators were recently used for capturing the dynamics of physical problems. These operators are based on the singular and nonsingular kernels as well as local and nonlocal kernels. Readers can peruse some related literature given in [1,2,3].

Several classes of FDEs were considered and analysed for scientific aims, including sequential FDEs, hybrid FDEs, mixed FDEs, and a large number of other classes that are yet understudied in this field. The use of perturbation methods substantially facilitates the understanding of system dynamics that are described by various mathematical methods in the area of nonlinear analysis. Even if a differential equation describing a specific dynamical system may occasionally be difficult to solve or assess, by perturbing the system in some way, we can gain some insight on the system [4,5,6,7].

In the recent years, fractional operators of variable orders have been investigated and mathematically formalized. Since it is possible to create evolutionary system of equations, these operators have been successfully used to represent complicated real-world issues in a variety of fields, including biology, mechanics, transport processes, and control theory. Fractional calculus is still an active topic of research. Due to the various properties of these fractional-order operators, several operators have been developed and are being used to solve research issues in the disciplines of science and engineering. The scientific community has been actively investigating VO-FC applications for the modelling of engineering and physical systems. The reader who is interested in learning more about this intriguing topic can study [8,9,10,11,12].

The basic idea of VO calculus is based on the generalization of the fractional operators from constant orders, say

ζ^{*}

, to some function

ζ^{*} (.)

. In 2021 and 2022, some papers dealing with this topic were published, see e.g., ([8,9,10,11,12,13,14,15]).

In particular, Bai et al. [16] established results for the existence of a solution for the following nonlinear FDEs of nonvariable order

\begin{matrix} \{\begin{matrix} D_{0^{+}}^{ξ} ϑ (s) = φ (s, ϑ_{s}), & s \in M : = [0, M], ξ \in] 0, 1], \\ ϑ (s) = χ (s), & s \in [- γ, 0], \end{matrix} \end{matrix}

where

D_{0^{+}}^{ξ}

represents an RL fractional operator for the derivative,

φ : M \times C ([- γ, 0], R) \to R

is a given function and

χ \in C ([- γ, 0], R)

via

χ (0) = 0 .

For a well defined

ϑ

on

[- γ, M]

and

s \in M

, we assume

ϑ_{s}

be from

C ([- γ, 0], R)

, such that

ϑ_{s} (ζ^{*}) : = ϑ (s + ζ^{*}), ζ^{*} \in [- γ, 0] .

We have focused in this article on the following FDE with the variable order:

\{\begin{matrix} D_{0^{+}}^{μ (s)} ϑ (s) = φ (s, ϑ_{s}), & s \in M : = [0, M], \\ ϑ (s) = χ (s), & s \in [- γ, 0], γ > 0 \end{matrix}

(1)

where

0 < M < + \infty

,

0 < μ (s) \leq 1

,

φ : M \times C ([- γ, 0], R) \to R

,

χ \in C ([- γ, 0], R)

via

χ (0) = 0

, and

D_{0^{+}}^{μ (s)}

is the RL fractional differential operator with variable order

μ (\cdot) .

Some related results can be studied in the work of Telli et al. [17].

The variable order differential equations are studied in several more related articles. One can see the analytical solutions of the VO-FDEs in [18], boundary value problems with the VO in [19], a detail description about the fractional calculus for the comparison in [20,21], the integral operation in [22] and VO operators with MIttag-Leffler in [23]. These results can be applied on the works in [24,25].

Here, we investigate an FDE for the variable order in the sense of an RL derivative and establish the requirements for the existence of solutions in the subintervals. In our research, the piecewise-constant functions have a vital role in transforming the variable-order RL fractional-order initial value problem to the normal RL fractional initial value problem.

Our purpose in this article was to analyse a variable-order mathematical problem. The desired FDE of variable order is given in Section 1, and relevant notions and results are presented in Section 2. With the help of an iterative sequential technique and a limit point procedure, the existence criterion and its uniqueness property are derived in Section 3. The HU stability of the solutions is demonstrated in Section 4. In the fifth section, an illustrative example is presented. The concluding remarks are summarised in Section 6. At the end, the paper provides basic references.

2. Preliminaries

This section contains the preliminary results which are related to our aims. Consider a Banach space

(E; ∥ \cdot ∥)

and

C (M, E)

a space of E-valued functions which are continuous on

M

with norm

{∥ ϑ ∥}_{M} = s u p {∥ ϑ (s) ∥ : s \in M},

for any

ϑ \in C (M, E) .

Definition 1

([26,27]). For

- \infty < c < d < + \infty

, let us assume

u : [c, d] \to (0, + \infty)

. Then, the left RL fractional integral of order

μ (\cdot)

for

ϑ (\cdot)

is expressed as

I_{c^{+}}^{μ (s)} ϑ (s) = \int_{c}^{s} \frac{{(s - ζ^{*})}^{μ (ζ^{*}) - 1}}{Γ (μ (ζ^{*}))} ϑ (ζ^{*}) d ζ^{*}, s > c,

(2)

where

Γ (.)

represents the gamma function.

Definition 2

([26,27]). For

- \infty < c < d < + \infty

, we assume that

μ : [c, d] \to (m - 1, m)

,

m \in N

. Then, the left RL fractional differential operator of order

μ (\cdot)

for ϑ is expressed as

D_{c^{+}}^{μ (s)} ϑ (s) = {(\frac{d}{d s})}^{m} I_{c^{+}}^{m - μ (s)} ϑ (s) = {(\frac{d}{d s})}^{m} \int_{c}^{s} \frac{{(s - ζ^{*})}^{m - μ (ζ^{*}) - 1}}{Γ (m - μ (ζ^{*}))} ϑ (ζ^{*}) d ζ^{*}, s > c .

(3)

The following characteristics are added from the available literature:

Lemma 1

([28]). Assume

ξ > 0

,

c \geq 0

,

ϑ \in L^{1} (c, d)

,

D_{c^{+}}^{ξ} ϑ \in L^{1} (c, d)

. Then,

D_{c^{+}}^{ξ} ϑ = 0

gives us

ϑ (s) = ς_{1} {(s - c)}^{ξ - 1} + ς_{2} {(s - c)}^{ξ - 2} + . . . + ς_{ℓ} {(s - c)}^{ξ - ℓ} + . . . + ς_{m} {(s - c)}^{ξ - m},

for

m = [ξ] + 1

,

ς_{ℓ} \in R,

ℓ = 1, 2, \dots, m

.

Lemma 2

([28]). For

ξ > 0

,

c \geq 0

,

ϑ \in L^{1} (c, d)

,

D_{c^{+}}^{ξ} ϑ \in L^{1} (c, d)

, then

I_{c^{+}}^{ξ} D_{c^{+}}^{ξ} ϑ (s) = ϑ (s) + ς_{1} {(s - c)}^{ξ - 1} + ς_{2} {(s - c)}^{ξ - 2} + \dots + ς_{ℓ} {(s - c)}^{ξ - ℓ} + \dots + ς_{m} {(s - c)}^{ξ - m},

(4)

where

m = [ξ] + 1

,

ς_{ℓ} \in R,

ℓ = 1, 2, \dots, m

.

Lemma 3

([28]). Let

ξ > 0

,

c \geq 0

,

ϑ \in L^{1} (c, d)

,

D_{c^{+}}^{ξ} ϑ \in L^{1} (c, d)

. Then,

D_{c^{+}}^{ξ} I_{c^{+}}^{ξ} ϑ (s) = ϑ (s) .

Lemma 4

([28]). Let

ξ_{1}, ξ_{2} > 0

,

c \geq 0

,

ϑ \in L^{1} (c, d)

. Then,

I_{c^{+}}^{ξ_{1}} I_{c^{+}}^{ξ_{2}} ϑ (s) = I_{c^{+}}^{ξ_{2}} I_{c^{+}}^{ξ_{1}} ϑ (s) = I_{c^{+}}^{ξ_{1} + ξ_{2}} ϑ (s) .

Remark 1

([29,30]). Generally, for functions

μ_{1} (s)

and

μ_{2} (s)

, the semigroup property does not hold, that is,

I_{c^{+}}^{μ_{1} (s)} I_{c^{+}}^{μ_{2} (s)} ϑ (s) \neq I_{c^{+}}^{μ_{1} (s) + μ_{2} (s)} ϑ (s) .

Definition 3

([31]). The considered Equation (1) is HU stable if for a real number

c_{φ} > 0

such that for each

ϵ > 0

and for each solution

y \in C ([- γ, M], R)

:

\{\begin{matrix} | D_{0^{+}}^{u (s)} y (s) - φ (s, y_{s}) | \leq ϵ, & s \in M : = [0, M], \\ y (s) = χ (s), & s \in [- γ, 0], \end{matrix}

(5)

there is a solution

ϑ \in C ([- γ, M], R)

of Equation (1), which implies

| y (s) - ϑ (s) | \leq c_{φ} ϵ, s \in [- γ, M] .

Remark 2

([31]). A function

y \in C ([0, M], R)

is a solution of the inequality

| D_{0^{+}}^{u (s)} y (s) - φ (s, y_{s}) | \leq ϵ, s \in M = [0, M],

(6)

if and only if there exists a function

h \in C ([0, M], R)

, which depends on a solution y, such that

(i): $| h (t) | \leq ϵ,$ for all $t \in [- γ, M] .$
(ii): $D_{0^{+}}^{μ (t)} y (t) = φ (t, y_{t}) + h (t),$ for all $t \in J .$

Proof.

Assume that

y \in C ([0, M], R)

is a solution of (6). Let

h (s) = D_{0^{+}}^{u (s)} y (s) - φ (s, y_{s}) + h (s)

, for all

s \in J

. Then, with the use of (6), we have

| h (s) | \leq ϵ

for all

s \in [0, M]

and

D_{0^{+}}^{u (s)} y (s) = φ (s, y_{s}) + h (s)

for all

s \in J

. Conversely, we have:

\begin{matrix} | D_{0^{+}}^{u (s)} y (s) - φ (s, y_{s}) | = | h (s) | \leq ϵ, s \in [0, M] . \end{matrix}

(7)

□

3. Existence of Solutions

The assumptions below are important in the proof of our objective results.

(HY1): Let us consider $n \in N$ a positive integer and ${M_{k}}_{k = 0}^{n}$ a finite sequence such that $0 = M_{0} < M_{k - 1} < M_{k} < M_{n} = M$ , $k = 2, \dots, n - 1$ .
Denote $M_{k} : = (M_{k - 1}, M_{k}]$ , $k = 1, 2, \dots, n .$ Then, $P = \{M_{k} : k = 1, 2, \dots, n\}$ is a partition of $M$ .
Consider a piecewise function $μ : M \to (0, 1]$ , with respect to $P$ , given by:

μ (s) = \sum_{k = 1}^{n} μ_{k} I_{k} (s) = \{\begin{matrix} μ_{1}, i f s \in M_{1}, \\ μ_{2}, i f s \in M_{2}, \\ . \\ . \\ . \\ μ_{n}, i f s \in M_{n}, \end{matrix}

where

1 < μ_{k} \leq 1

are positive constants and

I_{k}

are indicator of

M_{k},

for

k = 1, 2, \dots, n

:

I_{k} (s) = \{\begin{matrix} 1, f o r s \in M_{k}, \\ 0, f o r e l s e w h e r e . \end{matrix}

(HY2): Let $s^{σ} φ : M \times C ([- γ, 0], R) \to R$ be continuous, $(0 < σ = {min}_{s \in M} μ (s) < 1)$ , and there exists a $K > 0$ , with $s^{σ} | φ (s, y) - φ (s, z) | \leq {K ∥ y - z ∥}_{[- γ, 0]},$ for $y,$ $z \in C ([- γ, M], R)$ and $s \in M$ .

Then, for any

s \in M_{k}, k = 1, 2, \dots, n

, the left Riemann–Liouville fractional-order operator of variable order

μ (.)

for

ϑ \in C (M, R)

could be sum of left Riemann–Liouville fractional-order derivatives of

μ_{k}, k = 1, 2, \dots, n,

orders

D_{0^{+}}^{μ (s)} ϑ (s) = \frac{d}{d s} (\int_{0}^{M_{1}} \frac{{(s - ζ^{*})}^{- μ_{1}}}{Γ (1 - μ_{1})} ϑ (ζ^{*}) d ζ^{*} + \dots + \int_{M_{k - 1}}^{s} \frac{{(s - ζ^{*})}^{- μ_{k}}}{Γ (1 - μ_{k})} ϑ (ζ^{*}) d ζ^{*})

(8)

Thus, according to (8), the equation of the R-fractional Equation (1) can be written for any

s \in M_{k}, k = 1, 2, \dots, n

, as

\frac{d}{d s} (\int_{0}^{M_{1}} \frac{{(s - ζ^{*})}^{- μ_{1}}}{Γ (1 - μ_{1})} ϑ (ζ^{*}) d ζ^{*} + \dots + \int_{M_{k - 1}}^{s} \frac{{(s - ζ^{*})}^{- μ_{k}}}{Γ (1 - μ_{k})} ϑ (ζ^{*}) d ζ^{*}) = φ (s, ϑ_{s}), s \in M_{k} .

(9)

Here, the solution of Equation (1) is stated, which is important in this paper.

Definition 4.

Subjected to

ϑ_{k}, k = 1, 2, \dots, n,

where

ϑ_{k} \in C ([- γ, M_{k}], R)

, (1) has a solution if (9) is satisfied for

s \in [0, M_{k}]

,

ϑ (s) = χ (s),

and if

s \in [- γ, 0]

with

ϑ_{k} (M_{k - 1}) = 0 .

Consider

ϑ \in C (M, R)

so that

ϑ \equiv 0

on

s \in [0, M_{k - 1}]

, and it is the solution of (9). Then, (9) implies

D_{M_{k - 1}^{+}}^{μ_{k}} ϑ (s) = φ (s, ϑ_{s}), s \in M_{k} .

We shall deal with the following IVP:

\{\begin{matrix} D_{M_{k - 1}^{+}}^{μ_{k}} ϑ = φ (s, ϑ_{s}), s \in M_{k}, \\ ϑ (M_{k - 1}) = 0, \\ ϑ (s) = χ_{k}, s \in [M_{k - 1} - γ^{'}, M_{k - 1}], \end{matrix}

(10)

here

γ^{'} = M_{k - 1} + γ

and

χ_{k} (s) = \{\begin{matrix} 0, i f s \in [0, M_{k - 1}] \\ χ (s), i f s \in [- γ, 0] . \end{matrix}

For the existence of a solution of (10), the following lemma is important.

Lemma 5.

ϑ \in C ([- γ, M_{k}], R)

is a solution of (10) if and only if ϑ is such that

ϑ (s) = \{\begin{matrix} \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, ϑ_{ζ^{*}}) d ζ^{*}, i f s \in M_{k}, \\ χ_{k} (s), i f s \in [- γ, M_{k - 1}] . \end{matrix},

(11)

where

k = 1, 2, \dots, n

.

Proof.

Let

ϑ \in C ([- γ, M_{k}], R)

be a solution of Equation (10). From (4), we have

ϑ (s) = ς_{1} {(s - M_{k - 1})}^{μ_{k} - 1} + I_{M_{k - 1}^{+}}^{u_{k}} φ (s, ϑ_{s}), s \in M_{k}, k \in {1, 2, \dots, n} .

(12)

Using

ϑ (M_{k - 1}) = 0

, we find that

ς_{1} = 0 .

By substituting the value of

ς_{1}

on (12), we obtain

ϑ (s) = I_{M_{k - 1}^{+}}^{μ_{k}} φ (s, ϑ_{s}), s \in M_{k} .

Then, the solution of Equation (10) is given by

ϑ (s) = \{\begin{matrix} \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, ϑ_{ζ^{*}}) d ζ^{*}, i f s \in M_{k}, \\ χ_{k} (s), i f s \in [- γ, M_{k - 1}] . \end{matrix},

For the converse proof, let

ϑ \in C ([- γ, M_{k}], R)

be a solution (11); then, by Lemma 3, we have

ϑ

is the solution of (10). □

We prove the existence of a solution for Equation (10).

Theorem 1.

Assume the conditions

(HY 1)

and

(HY 2)

, with

\frac{K Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} < 1 .

(13)

Then, (10) has a solution on

C ([- γ, M_{k}], R)

.

Proof.

We construct the operator

N : C ([- γ, M_{k}], R) \to C ([- γ, M_{k}], R)

as follows:

(N ϑ) (s) = \{\begin{matrix} χ_{k} (s), s \in [- γ, M_{k - 1}] \\ \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, ϑ_{ζ^{*}}) d ζ^{*}, i f s \in M_{k} \end{matrix}

Let

v (.) : [- γ, M_{k}] \to R

given by:

v = \{\begin{matrix} 0, i f s \in M_{k} \\ χ_{k} (s), i f s \in [- γ, M_{k - 1}] . \end{matrix}

For

z \in C ([M_{k - 1}, M_{k}], R)

, with

z (M_{k - 1}) = 0

, we represent

\bar{z}

as

\bar{z} (s) = \{\begin{matrix} z (s), i f s \in M_{k} \\ 0, i f s \in [- γ, M_{k - 1}] . \end{matrix}

If

ϑ (.)

satisfies

ϑ (s) = \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, ϑ_{ζ^{*}}) d ζ^{*}, i f s \in M_{k},

we can divide in parts

ϑ (.)

as

ϑ (s) = z (s) + v (s), M_{k - 1} \leq s \leq M_{k}

, which yields

ϑ_{s} = {\bar{z}}_{s} + v_{s}

, for

M_{k - 1} \leq s \leq M_{k} .

Set

C_{M_{k - 1}} = \{z \in C ([M_{k - 1}, M_{k}], R) : z (M_{k - 1}) = 0\},

and let

{∥ . ∥}_{M_{k}}

be the norm in

C_{M_{k - 1}}

such that

{∥ z ∥}_{M_{k}} = sup_{s \in M_{k}} | z (s) |, z \in C_{M_{k - 1}} .

Here,

C_{M_{k - 1}}

is a separable Banach space with norm

{∥ . ∥}_{M_{k}}

. Let us define an operator

E : C_{M_{k - 1}} \to C_{M_{k - 1}}

as

(E z) (s) = \frac{1}{Γ (u_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) d ζ^{*}, s \in M_{k},

(14)

By the definition of

s^{σ} φ

, the operator

E : C_{M_{k - 1}} \to C_{M_{k - 1}}

is well-defined in (14).

Then, it is enough to show that the operator

E

has a fixed point z which guarantees that the operator

N

has a fixed point

ϑ = \bar{z} + v

and in consequence, this fixed point will correspond to a solution of Equation (10), indeed

\begin{matrix} κ (s) & = & \bar{z} (s) + v (s) \\ = & \{\begin{matrix} z (s), i f s \in M_{k} \\ χ_{k} (s), i f s \in [- γ, M_{k - 1}] . \end{matrix} \\ = & \{\begin{matrix} \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) d ζ^{*}, i f s \in M_{k} \\ χ_{k} (s), i f s \in [- γ, M_{k - 1}] . \end{matrix} \\ = & \{\begin{matrix} \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, ϑ_{ζ^{*}}) d ζ^{*}, i f s \in M_{k} \\ χ_{i} (s), i f s \in [- γ, M_{k - 1}] . \end{matrix} \\ = & (N ϑ) (s) . \end{matrix}

Let

R_{k} \geq \frac{\frac{Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} ({K ∥ χ ∥}_{[- γ, 0]} + φ^{⋆})}{1 - \frac{K Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{i} - σ}}{Γ (μ_{k} + 1 - σ)}},

with

φ^{⋆} = {sup}_{s \in M_{k}} s^{σ} | φ (s, 0) | .

Let us consider:

B_{R_{k}} = {z \in C_{M_{k - 1}} {, ∥ z ∥}_{M_{k}} \leq R_{k}} .

Thus,

B_{R_{i}}

is nonempty, closed, convex, and a bounded set.

Let

z \in B_{R_{k}}

and

s \in M_{k}

; then,

\begin{matrix} ∥ {\bar{z}}_{s} ∥_{[- γ^{'}, 0]} & = & sup_{- M_{k - 1} - γ \leq θ \leq 0} | {\bar{z}}_{s} (θ) | \\ = & sup_{- M_{k - 1} - γ \leq θ \leq 0} | \bar{z} (s + θ) | \\ \leq & sup_{- γ \leq ζ^{*} \leq M_{k}} | \bar{z} (ζ^{*}) | \\ = & sup_{ζ^{*} \in M_{k}} | z (ζ^{*}) {| = ∥ z ∥}_{M_{k}} \end{matrix}

and

\begin{matrix} ∥ v_{s} ∥_{[- γ^{'}, 0]} & = & sup_{- M_{k - 1} - γ \leq θ \leq 0} | v_{s} (θ) | \\ = & sup_{- M_{k - 1} - γ \leq θ \leq 0} | v (s + θ) | \\ \leq & sup_{- γ \leq ζ^{*} \leq M_{k}} | v (ζ^{*}) | \\ = & sup_{- γ \leq ζ^{*} \leq 0} | v (ζ^{*}) | \\ = & sup_{- γ \leq ζ^{*} \leq 0} | χ (ζ^{*}) | \\ = & {∥ χ ∥}_{[- γ, 0]} \end{matrix}

Now, we show that

E

satisfies the requirements of Schauder’s FPT. For this, we have:

Step 1:

E (B_{R_{k}}) \subseteq (B_{R_{k}}) .

For

z \in B_{R_{k}}

, by

(HY 2)

, we get

\begin{matrix} | E z (s) | & = & | \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) d ζ^{*} | \\ \leq & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} | φ (s, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) | d ζ^{*} \\ \leq & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} {ζ^{*}}^{σ} | φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) - φ (ζ^{*}, 0) | d ζ^{*} \\ + & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} {ζ^{*}}^{σ} | φ (ζ^{*}, 0) | d ζ^{*} \\ \leq & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} (K ∥ {\bar{z}}_{ζ^{*}} + v_{ζ^{*}} ∥_{[- γ^{'}, 0]}) d ζ^{*} \\ + & \frac{φ^{⋆}}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} d ζ^{*} \\ \leq & \frac{K}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} (∥ {\bar{z}}_{ζ^{*}} ∥_{[- γ^{'}, 0]} + ∥ v_{ζ^{*}} ∥_{[- γ^{'}, 0]}) {ζ^{*}}^{- σ} d ζ^{*} \\ + & \frac{φ^{⋆}}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} d ζ^{*} \\ \leq & \frac{K}{Γ (μ_{k})} {(∥ z ∥}_{M_{k}} + {∥ χ ∥}_{[- γ, 0]}) \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} d ζ^{*} \\ + & \frac{φ^{⋆}}{Γ (u_{i})} \int_{M_{i - 1}}^{s} {(s - ζ^{*})}^{u_{i} - 1} {ζ^{*}}^{- σ} d ζ^{*} \\ \leq & \frac{K}{Γ (μ_{k})} {(∥ z ∥}_{M_{k}} + {∥ χ ∥}_{[- γ, 0]}) \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {(ζ^{*} - M_{k - 1})}^{- σ} d ζ^{*} \\ + & \frac{φ^{⋆}}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {(ζ^{*} - M_{k - 1})}^{- σ} d ζ^{*} \\ \leq & \frac{K Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} {(∥ z ∥}_{M_{k}} + {∥ χ ∥}_{[- γ, 0]}) \\ + & \frac{φ^{⋆} Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} \end{matrix}

\begin{matrix} | E z (s) | & \leq & \frac{K Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} {∥ z ∥}_{M_{k}} \\ + & \frac{K Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} {∥ χ ∥}_{[- γ, 0]} \\ + & \frac{φ^{⋆} Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} \\ \leq & \frac{K Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} {∥ z ∥}_{M_{k}} \\ + & \frac{Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} ({K ∥ χ ∥}_{[- γ, 0]} + φ^{⋆}) \\ \leq & \frac{K Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} R_{k} \\ + & \frac{Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} ({K ∥ χ ∥}_{[- γ, 0]} + φ^{⋆}) \\ \leq & R_{k}, \end{matrix}

which means that

E (B_{R_{k}}) \subseteq B_{R_{k}}

.

Step 2:

E

is continuous.

We assume that

(z_{n})

converges to z in

C_{T_{k - 1}}

and

s \in M_{k}

. Then,

\begin{matrix} | (E z_{n}) (s) - (E z) (s) | & = & | \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, {\bar{z_{n}}}_{ζ^{*}} + v_{ζ^{*}}) d ζ^{*} \\ - & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) d ζ^{*} | \\ \leq & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} | φ (ζ^{*}, {\bar{z_{n}}}_{ζ^{*}} + v_{ζ^{*}}) - φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) | d ζ^{*} \\ \leq & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} {ζ^{*}}^{σ} | φ (ζ^{*}, {\bar{z_{n}}}_{ζ^{*}} + v_{ζ^{*}}) - φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) | d ζ^{*} \\ \leq & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} K {∥ {\bar{z_{n}}}_{ζ^{*}} - {\bar{z}}_{ζ^{*}} ∥}_{[- γ^{'}, 0]} d ζ^{*} \\ \leq & (K ∥ z_{n} - z ∥_{M_{k}}) \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} d ζ^{*} \\ \leq & (K ∥ z_{n} - z ∥_{M_{k}}) \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {(ζ^{*} - M_{k - 1})}^{- σ} d ζ^{*} \\ \leq & (K ∥ z_{n} - z ∥_{M_{k}}) \frac{Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} \\ \leq & \frac{K Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} {∥ z_{n} - z ∥}_{M_{k}}, \\ i . e ., we get \\ ∥ (E z_{n}) - (E z) ∥_{M_{k}} \to 0 as n \to \infty . \end{matrix}

Then,

E

is continuous on

C_{M_{k - 1}}

.

Step 3:

E

maps bounded sets into bounded sets in

C_{M_{k - 1}} .

Let

B_{r}

be a bounded subset of

B_{R_{k}}

; as in Step 2, we have

E (B_{r}) \subset E (B_{R_{k}}) \subset B_{R_{k}} .

E

maps bounded sets into bounded sets in

C_{M_{k - 1}} .

Step 4:

E

maps bounded sets into equicontinous sets in

C_{M_{k - 1}} .

We consider

B_{R}

a bounded set in

C_{M_{k - 1}},

for arbitrary

s_{1}, s_{2} \in M_{k}

, with

s_{1} < s_{2}

, let

z \in B_{R}

, and we write

\begin{matrix} | (E z) (s_{2}) - (E z) (s_{1}) | & = & | \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s_{2}} {(s_{2} - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) d ζ^{*} \\ - & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s_{1}} {(s_{1} - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) d ζ^{*} | \\ \leq & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s_{1}} | ({(s_{2} - ζ^{*})}^{μ_{k} - 1} - {(s_{1} - ζ^{*})}^{μ_{k} - 1}) φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) | d ζ^{*} \\ + & \frac{1}{Γ (μ_{k})} \int_{s_{1}}^{s_{2}} | {(s_{2} - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) | d ζ^{*} \\ \leq & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s_{1}} | ({(s_{2} - ζ^{*})}^{μ_{k} - 1} - {(s_{1} - ζ^{*})}^{μ_{k} - 1}) | | φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) | d ζ^{*} \\ + & \frac{1}{Γ (μ_{k})} \int_{s_{1}}^{s_{2}} {(s_{2} - ζ^{*})}^{μ_{k} - 1} | φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) | d ζ^{*} \\ \leq & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s_{1}} | ({(s_{2} - ζ^{*})}^{μ_{k} - 1} - {(s_{1} - ζ^{*})}^{μ_{k} - 1}) | \\ {ζ^{*}}^{- σ} ({ζ^{*}}^{σ} | φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) - φ (ζ^{*}, 0) | + {ζ^{*}}^{σ} | φ (ζ^{*}, 0) |) d ζ^{*} \\ + & \frac{1}{Γ (μ_{k})} \int_{s_{1}}^{s_{2}} {(s_{2} - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} ({ζ^{*}}^{σ} | φ (ζ^{*}, {\bar{z}}_{ζ^{*}} + v_{ζ^{*}}) - φ (ζ^{*}, 0) | + {ζ^{*}}^{σ} | φ (ζ^{*}, 0) |) d ζ^{*} \\ \leq & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s_{1}} | ({(s_{2} - ζ^{*})}^{μ_{k} - 1} - {(s_{1} - ζ^{*})}^{μ_{k} - 1}) | \\ [{ζ^{*}}^{- σ} (K ∥ {\bar{z}}_{ζ^{*}} + v_{ζ^{*}} ∥_{[- γ^{'}, 0]}) + {ζ^{*}}^{- σ} φ^{⋆}] d ζ^{*} \\ + & \frac{1}{Γ (μ_{k})} \int_{s_{1}}^{s_{2}} {(s_{2} - ζ^{*})}^{μ_{k} - 1} [{ζ^{*}}^{- σ} (K ∥ {\bar{z}}_{ζ^{*}} + v_{ζ^{*}} ∥_{[- γ^{'}, 0]}) + {ζ^{*}}^{- σ} φ^{⋆}] d ζ^{*} \end{matrix}

\begin{matrix} | (E z) (s_{2}) - (E z) (s_{1}) | & \leq & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s_{1}} | ({(s_{2} - ζ^{*})}^{μ_{k} - 1} - {(s_{1} - ζ^{*})}^{μ_{k} - 1}) | \\ [{ζ^{*}}^{- σ} K (∥ {\bar{z}}_{ζ^{*}} ∥_{[- γ^{'}, 0]} + ∥ v_{ζ^{*}} ∥_{[- γ^{'}, 0]}) + {ζ^{*}}^{- σ} φ^{⋆}] d ζ^{*} \\ + & \frac{1}{Γ (μ_{k})} \int_{s_{1}}^{s_{2}} {(s_{2} - ζ^{*})}^{μ_{k} - 1} [{ζ^{*}}^{- σ} K (∥ {\bar{z}}_{ζ^{*}} ∥_{[- γ^{'}, 0]} + ∥ v_{ζ^{*}} ∥_{[- γ^{'}, 0]}) + {ζ^{*}}^{- σ} φ^{⋆}] d ζ^{*} \\ \leq & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s_{1}} | ({(s_{2} - ζ^{*})}^{μ_{k} - 1} - {(s_{1} - ζ^{*})}^{μ_{k} - 1}) | \\ [{ζ^{*}}^{- σ} {K (∥ z ∥}_{M_{k}} + {∥ χ ∥}_{[- γ, 0]}) + {ζ^{*}}^{- σ} φ^{⋆}] d ζ^{*} \\ + & \frac{1}{Γ (μ_{k})} \int_{s_{1}}^{s_{2}} {(s_{2} - s ζ^{*})}^{μ_{k} - 1} [{ζ^{*}}^{- σ} {K (∥ z ∥}_{M_{k}} + {∥ χ ∥}_{[- γ, 0]}) + {ζ^{*}}^{- σ} φ^{⋆}] d ζ^{*} \\ \leq & M_{k - 1}^{- σ} [{K (∥ z ∥}_{M_{k}} + {∥ χ ∥}_{[- γ, 0]}) + φ^{⋆}] \times \\ \frac{1}{Γ (μ_{k})} (\int_{M_{k - 1}}^{s_{1}} ({(s_{1} - ζ^{*})}^{μ_{k} - 1} - {(s_{2} - ζ^{*})}^{μ_{k} - 1}) d ζ^{*} + \int_{s_{1}}^{s_{2}} {(s_{2} - ζ^{*})}^{μ_{k} - 1} d ζ^{*}) \\ \leq & \frac{M_{k - 1}^{- σ}}{Γ (μ_{k} + 1)} ({K (∥ z ∥}_{M_{k}} + {∥ χ ∥}_{[- γ, 0]}) + φ^{⋆}) \times \\ ({(s_{2} - s_{1})}^{μ_{k}} + {(s_{1} - M_{k - 1})}^{μ_{k}} - {(s_{2} - M_{k - 1})}^{μ_{k}} + {(s_{2} - s_{1})}^{μ_{k}}), \\ \leq & \frac{2 M_{k - 1}^{- σ}}{Γ (μ_{k} + 1)} ({K (∥ z ∥}_{M_{k}} + {∥ χ ∥}_{[- γ, 0]}) + φ^{⋆}) {(s_{2} - s_{1})}^{μ_{k}} \\ \leq & \frac{2 M_{k - 1}^{- σ}}{Γ (μ_{k} + 1)} ({K (R + ∥ χ ∥}_{[- γ, 0]}) + φ^{⋆}) {(s_{2} - s_{1})}^{μ_{k}} . \end{matrix}

Hence,

| (E z) (s_{2}) - (E z) (s_{1}) | \to 0

as

| s_{2} - s_{1} | \to 0

. It implies that

E (B_{R})

is equicontinuous.

As a consequence of steps one, two, three, and four together with the Ascoli–Arzela theorem, we deduce that

E : C_{M_{k - 1}} \to C_{M_{k - 1}}

is continuous and compact. Therefore, by Shauder’s FP theorem, this implies

E

has an FP

z_{k} \in B_{R_{k}}

. Then,

N

has an FP; thus, the problem (10) has a solution

ϑ_{k} = \bar{z_{k}} + v \in C ([- γ, M_{k}], R)

. □

Theorem 2.

Assume that conditions

(HY 1)

,

(HY 2)

, and relation (13) are fulfilled ∀

k \in {1, 2, \dots, n}

. Then, (1) has a piecewise solution such that

C ([- γ, M], R)

.

Proof.

By Theorem 1, Equation (10) has a piecewise solution such that

ϑ_{1} \in C ([- γ, M_{1}], R)

,

ϑ_{k} \in P C ([- γ, M_{k}], R)

, for any

k \in {2, 3, \dots, n},

such that

\begin{matrix} ϑ_{1} (s) = \bar{z_{1}} (s) + v (s) = \{\begin{matrix} χ (s), s \in [- γ, 0] \\ z_{1} (s), s \in M_{1} . \end{matrix} \end{matrix}

and for any

k \in {2, \dots, n}

\begin{matrix} ϑ_{k} (s) = {\bar{z_{k}}}_{s} + v_{s} = \{\begin{matrix} χ_{s}, s \in [- γ, 0], \\ 0, s \in [0, M_{k - 1}], \\ z_{k} (s), s \in M_{k} . \end{matrix} \end{matrix}

Thus,

ϑ_{1} \in C ([- γ, M_{1}], R)

,

ϑ_{k} \in P C ([- γ, M_{k}], R)

, for any

k \in {2, 3, \dots, n},

is a solution of (9) for

s \in M_{k}

with

ϑ_{k} (M_{k - 1}) = z_{k} (M_{k - 1}) = 0

and

ϑ_{k} (s) = χ (s),

for

s \in [- γ, 0]

.

Then,

ϑ (s) = \{\begin{matrix} ϑ_{1} (s) = \{\begin{matrix} χ (s), s \in [- γ, 0], \\ z_{1} (s), s \in M_{1}, \end{matrix} \\ ϑ_{2} (s) = \{\begin{matrix} χ (s), s \in [- γ, 0], \\ 0, s \in M_{1}, \\ z_{2} (s), s \in M_{2}, \end{matrix} . \\ . \\ . \\ . \\ ϑ_{n} (s) = \{\begin{matrix} χ_{s}, s \in [- γ, 0], \\ 0, s \in [0, M_{n - 1}], \\ z_{n} (s), s \in M_{n}, \end{matrix} \end{matrix}

gives the solution for the Riemann–Liouville Equation (1).

□

4. Ulam–Hyers Stability

Theorem 3.

Consider that

(HY 1)

,

(HY 2)

, and (13) hold true, then (1) is HU stable.

Proof.

Assume

ϵ > 0

is an arbitrary number and

y \in C ([- γ, M], R)

satisfies:

\{\begin{matrix} | D_{0^{+}}^{μ (s)} y - φ (s, y_{s}) | \leq ϵ, & s \in M : = [0, M], \\ y (s) = χ (s), & s \in [- γ, 0], \end{matrix}

(15)

We define the functions

\begin{matrix} y_{1} = \{\begin{matrix} y, s \in [0, M_{1}], \\ χ, s \in [- γ, 0] . \end{matrix} \end{matrix}

(16)

and for

k = 2, 3, \dots, n :

\begin{matrix} y_{k} = \{\begin{matrix} χ (s), s \in [- γ, 0], \\ 0, s \in [0, M_{k - 1}], \\ y, s \in M_{k} . \end{matrix} \end{matrix}

(17)

For any

k \in {1, 2, \dots, n}

, according to (9), for

s \in M_{k}

, we have

D_{0^{+}}^{μ (s)} y_{k} (s) = \frac{1}{Γ (1 - μ_{k})} \frac{d}{d s} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{- μ_{k}} y (ζ^{*}) d ζ^{*} .

Taking

I_{M_{k - 1}^{+}}^{u_{k}}

on both sides of (15) and from Remark (2), we obtain

\begin{matrix} | y (s) - \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, y_{ζ^{*}}) d ζ^{*} | & \leq \frac{ϵ}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} d ζ^{*} \\ \leq ϵ \frac{{(M_{k} - M_{k - 1})}^{μ_{k}}}{Γ (μ_{k} + 1)} . \end{matrix}

As per Theorem 2, the considered problem (1) has a solution

ϑ \in C ([- γ, M], R)

, where

ϑ (s),

for

s \in [0, M_{k}], k = 1, 2, \dots, n

, and

\begin{matrix} ϑ_{1} (s) = \{\begin{matrix} χ (s), s \in [- γ, 0] \\ z_{1} (s), s \in M_{1} \end{matrix} \end{matrix}

(18)

and for any

k \in {2, \dots, n}

\begin{matrix} ϑ_{k} (s) = \{\begin{matrix} χ (s), s \in [- γ, 0], \\ 0, s \in [0, M_{k - 1}], \\ z_{k} (s), s \in M_{k} \end{matrix} \end{matrix}

(19)

and

ϑ_{k} \in P C ([- γ, M_{k}], R)

, for

k = 2, 3, \dots,

is a solution of the RL Equation (10). According to Lemma 5, we have

ϑ_{k} (s) = \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, {(ϑ_{k})}_{ζ^{*}}) d ζ^{*},

(20)

Let

s \in M_{k}

, where

k \in {1, 2, \dots, n}

. Then, by Equations (17)–(20), we obtain

\begin{matrix} | y (s) - ϑ (s) | & = & | y (s) - ϑ_{k} (s) | = | y_{k} (s) - ϑ_{k} (s) | \\ = & | y_{k} (s) - \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, {(ϑ_{k})}_{ζ^{*}}) d ζ^{*} | \\ \leq & | y_{k} (s) - \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} φ (ζ^{*}, {(y_{k})}_{ζ^{*}}) d ζ^{*} | \\ + & \frac{1}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} | φ (ζ^{*}, {(y_{k})}_{ζ^{*}}) - φ (ζ^{*}, {(ϑ_{k})}_{ζ^{*}}) | d ζ^{*} \\ \leq & ϵ \frac{{(M_{k} - M_{k - 1})}^{μ_{k}}}{Γ (μ_{k} + 1)} \\ + & \frac{K}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} {∥ {(y_{k})}_{ζ^{*}} - {(ϑ_{k})}_{ζ^{*}} ∥}_{[- γ^{'}, 0]} d ζ^{*} \\ \leq & ϵ \frac{{(M_{k} - M_{k - 1})}^{μ_{k}}}{Γ (μ_{k} + 1)} \\ + & \frac{K}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} sup_{- M_{k - 1} - γ \leq θ \leq 0} | {(y_{k})}_{ζ^{*}} (θ) - {(ϑ_{k})}_{ζ^{*}} (θ) | d ζ^{*} \\ \leq & ϵ \frac{{(M_{k} - M_{k - 1})}^{μ_{k}}}{Γ (μ_{k} + 1)} \\ + & \frac{K}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} sup_{- M_{k - 1} - γ \leq θ \leq 0} | y_{k} (ζ^{*} + θ) - ϑ_{k} (ζ^{*} + θ) | d ζ^{*} \\ \leq & ϵ \frac{{(M_{k} - M_{k - 1})}^{μ_{k}}}{Γ (μ_{k} + 1)} + \frac{K}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} sup_{- γ \leq t \leq M_{k}} | y_{k} (t) - x_{k} (t) | d ζ^{*} \\ \leq & ϵ \frac{{(M_{k} - M_{k - 1})}^{μ_{k}}}{Γ (μ_{k} + 1)} + (\frac{K}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {ζ^{*}}^{- σ} d ζ^{*})) ∥ y_{k} - ϑ_{k} ∥_{[- γ, M_{k}]} \\ \leq & ϵ \frac{{(M_{k} - M_{k - 1})}^{μ_{k}}}{Γ (μ_{k} + 1)} + (\frac{K}{Γ (μ_{k})} \int_{M_{k - 1}}^{s} {(s - ζ^{*})}^{μ_{k} - 1} {(ζ^{*} - M_{k - 1})}^{- σ} d ζ^{*})) ∥ y_{k} - κ_{k} ∥_{[- γ, M_{k}]} \\ \leq & ϵ \frac{{(M_{k} - M_{k - 1})}^{μ_{k}}}{Γ (k_{k} + 1)} + \frac{K Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} {∥ y_{k} - ϑ_{k} ∥}_{[- γ, M_{k}]} \\ \leq & ϵ \frac{{(M_{k} - M_{k - 1})}^{μ_{k}}}{Γ (μ_{k} + 1)} + ν {∥ y_{k} - ϑ_{k} ∥}_{[- γ, M_{k}]} \end{matrix}

where

ν = max_{k = 1, 2, \dots, n} \frac{K Γ (1 - σ) {(M_{k} - M_{k - 1})}^{μ_{k} - σ}}{Γ (μ_{k} + 1 - σ)} .

Then,

{∥ y - ϑ ∥}_{[- γ, M_{k}]} (1 - ν) \leq ϵ \frac{{(M_{k} - M_{k - 1})}^{μ_{k}}}{Γ (μ_{k} + 1)},

and thus, by assuming

c_{φ} : = \frac{{(M_{k} - M_{k - 1})}^{μ_{k}}}{(1 - ν) Γ (μ_{k} + 1)}

,

{∥ y - ϑ ∥}_{[- γ, M_{k}]} \leq c_{φ} ϵ,

i.e.,

| y (s) - ϑ (s) | \leq c_{φ} ϵ s \in [- γ, M_{k}] .

Then, with the help of Definition 3, the considered problem (1) is HU stable. □

5. Example

Consider:

\{\begin{matrix} D_{0^{+}}^{μ (s)} ϑ (s) = \frac{7}{5 \sqrt{π}} s^{μ (s)} + \frac{s^{- \frac{1}{2}}}{s + 4} ∥ ϑ_{s} ∥_{[- γ, 0]}, s \in M : =] 0, 2], \\ ϑ (s) = χ (s), s \in [- γ, 0], \end{matrix}

(21)

where

μ (s) = \{\begin{matrix} \frac{5}{7}, s \in M_{1} : = [0, 1], \\ \frac{1}{2}, s \in M_{2} : =] 1, 2] . \end{matrix}

(22)

Let

φ (s, y_{s}) = \frac{7}{5 \sqrt{π}} s^{μ (s)} + \frac{s^{- \frac{1}{2}}}{s + 4} {∥ y_{s} ∥}_{[- γ, 0]}, (s, y_{s}) \in [0, 2] \times C ([- γ, 0], R) .

Let

y, z \in C ([- γ, 2], R)

and

s \in M .

Then, we have

\begin{matrix} s^{\frac{1}{2}} | φ (s, y_{s}) - φ (s, z_{s}) | & = & |s^{\frac{1}{2}} \frac{7}{5 \sqrt{π}} s^{μ (s)} + \frac{1}{s + 4} {∥ y ∥}_{[- γ, 0]} - s^{\frac{1}{2}} \frac{7}{5 \sqrt{π}} s^{μ (s)} - \frac{1}{s + 4} {∥ z_{s} ∥}_{[- γ, 0]}| \\ = & \frac{1}{s + 4} |∥ y_{s} ∥_{[- γ, 0]} - {∥ z_{s} ∥}_{[- γ, 0]}| \\ \leq & \frac{1}{s + 4} {(∥ y - z ∥}_{[- γ, 0]}) \\ \leq & \frac{1}{4} {∥ y - z ∥}_{[- γ, 0]} . \end{matrix}

Thus, the condition

(HY 2)

holds with

σ = \frac{1}{2}

and

K = \frac{1}{4}

.

By (22), by (10), two related problems for RL FDE of constant order are considered:

\{\begin{matrix} D_{0^{+}}^{\frac{5}{7}} ϑ (s) = \frac{7}{5 \sqrt{π}} s^{\frac{5}{7}} + \frac{s^{- \frac{1}{2}}}{s + 4} {∥ ϑ_{s} ∥}_{[- γ, 0]}, & s \in M_{1}, \\ ϑ (0) = 0, & , \\ ϑ (s) = χ_{1} (s), & s \in [- γ, 0] \end{matrix}

(23)

and

\{\begin{matrix} D_{0^{+}}^{\frac{1}{2}} ϑ (s) = \frac{7}{5 \sqrt{π}} s^{\frac{1}{2}} + \frac{s^{- \frac{1}{2}}}{s + 4} {∥ ϑ_{s} ∥}_{[- γ, 0]}, & s \in M_{2}, \\ ϑ (1) = 0, & , \\ ϑ (s) = χ_{2} (s), & s \in [- γ, 1] \end{matrix}

(24)

where

χ_{1} = χ

and

χ_{2} (s) = \{\begin{matrix} 0,, i f s \in [0, 1] \\ χ (s), i f s \in [- γ, 0] . \end{matrix}

Next, we prove that (13) is fulfilled for

k = 1

. Indeed,

\begin{matrix} \frac{K Γ (1 - σ) {(M_{1} - M_{0})}^{μ_{1} - σ}}{Γ (μ_{1} + 1 - σ)} & = & \frac{\frac{1}{4} Γ (1 - \frac{1}{2}) {(1 - 0)}^{\frac{5}{7} - \frac{1}{2}}}{Γ (\frac{5}{7} + 1 - \frac{1}{2})} \\ ≃ & 0.484540 \\ < & 1 \end{matrix}

Accordingly the condition (13) is achieved. With the help of Theorem 1, Equation (23) has a solution

ϑ_{1} \in C ([- γ, 1], R),

where

\begin{matrix} ϑ_{1} (s) & = & \{\begin{matrix} χ (s), s \in [- γ, 0] \\ z_{1} (s), s \in M_{1} \end{matrix} \end{matrix}

Indeed,

\begin{matrix} \frac{K Γ (1 - σ) {(M_{2} - M_{1})}^{μ_{2} - σ}}{Γ (μ_{2} + 1 - σ)} & = & \frac{\frac{1}{4} Γ (1 - \frac{1}{2}) {(2 - 1)}^{\frac{1}{2} - \frac{1}{2}}}{Γ (\frac{1}{2} + 1 - \frac{1}{2})} \\ ≃ & 0.443113 \\ < & 1 \end{matrix}

Thus, condition (13) is satisfied.

With the help of Theorem 1, Equation (24) has a solution

ϑ_{2} \in C ([- γ, 2], R),

where

\begin{matrix} ϑ_{2} (s) = \{\begin{matrix} χ (s), s \in [- γ, 0], \\ 0, s \in [0, 1], \\ z_{2} (s), s \in M_{2} \end{matrix} \end{matrix}

Then, by Theorem 2, Equation (21) has a solution

ϑ (s) = \{\begin{matrix} ϑ_{1} (s) = \{\begin{matrix} χ (s), s \in [- γ, 0], \\ z_{1} (s), s \in M_{1}, \end{matrix} \\ ϑ_{2} (s) = \{\begin{matrix} χ (s), s \in [- γ, 0], \\ 0, s \in M_{1}, \\ z_{2} (s), s \in M_{2}, \end{matrix} \end{matrix}

By Theorem 3, Equation (21) is HU stable.

6. Conclusions

We studied a general class of FDEs with a variable order for their existence results and stability criteria. We established that our problem was more complex and needed some essential conditions required for the solution existence and stability result. For the existence of a solution, the FPTs were utilized and an example was presented for the applicability of the work. This approach can be utilized for the extension of FDEs with multipoint boundary conditions for their theoretical and numerical aspects.

In this paper, we worked in a space of continuous functions. We introduced an abstract Riemann–Liouville (RL) fractional differential equations (FDEs) with a variable order and finite delay where the function stood for the variable order of the given system. Then, by defining a partition based on the generalized intervals, we introduced a piecewise-constant function

μ

(s) and converted the given variable–order Riemann–Liouville (RL) fractional differential equations (FDEs) with a variable order and finite delay (1) to equivalent standard Riemann–Liouville (RL) fractional differential equations (FDEs) (8) of a fractional constant order at each interval in this partition. This meant a solution of (1)

C ([- γ, M_{1}], R)

,

P C ([- γ, M_{k}], R)

, for

k = 2, 3, \dots

was an appellation which meant the existence of a finite sequence

ϑ_{k}

,

k = 2, . . ., n,

so that

ϑ_{k} \in P C ([- γ, M_{k}], R)

fulfilled Equation (9), for

s \in [0, M_{k}]

,

ϑ (s) = χ (s),

for

s \in [- γ, 0]

and

ϑ_{k} (M_{k - 1}) = 0 .

Author Contributions

Conceptualization, B.T.; methodology, M.S.S.; formal analysis, J.A.; resources, H.K.; data curation, B.T.; writing—original draft, M.S.S. and J.A.; writing—review and editing, H.K.; visualization, B.T. and M.S.S.; funding acquisition, J.A. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data sharing is not applicable to this article as no datasets were generated nor analysed during the current study.

Acknowledgments

J.A. and H.K. are thankful to Prince Sultan University and OSTIM Technical University for their endless support.

Conflicts of Interest

The authors declare no conflict of interest.

References

Deimling, K. Nonlinear Functional Analysis; Springer: New York, NY, USA, 1985. [Google Scholar]
Samko, S. Fractional integration and differentiation of variable order: An overview. Nonlinear Dyn. 2013, 71, 653–662. [Google Scholar] [CrossRef]
Alshehri, H.M.; Khan, A. A fractional order Hepatitis C mathematical model with Mittag-Leffler kernel. J. Funct. Spaces. 2021, 2021, 2524027. [Google Scholar] [CrossRef]
Khan, H.; Alzabut, J.; Shah, A.; Etemad, S.; Rezapour, S.; Park, C. A study on the fractal-fractional tobacco smoking model. AIMS Math. 2022, 7, 13887–13909. [Google Scholar] [CrossRef]
Khan, H.; Alzabut, J.; Baleanu, D.; Alobaidi, G.; Rehman, M. Existence of solutions and a numerical scheme for a generalized hybrid class of n-coupled modified ABC-fractional differential equations with an application. AIMS Math. 2023, 8, 6609–6625. [Google Scholar] [CrossRef]
Al-Refai, M.; Baleanu, D. On an Extension of the Operator with Mittag-Leffler Kernel. Fractals 2022, 30, 2240129. [Google Scholar] [CrossRef]
Al-Refai, M. Proper inverse operators of fractional derivatives with nonsingular kernels. Rend. Circ. Mat. Palermo Ser. 2 2021, 71, 525–535. [Google Scholar] [CrossRef]
Shah, K.; Ali, A.; Zeb, S.; Khan, A.; Alqudah, M.A.; Abdeljawad, T. Study of fractional order dynamics of nonlinear mathematical model. Alexand. Eng. J. 2022, 61, 11211–11224. [Google Scholar] [CrossRef]
Khan, A.; Khan, Z.A.; Abdeljawad, T.; Khan, H. Analytical analysis of fractional-order sequential hybrid system with numerical application. Adv. Continuous Discr. Models. 2022, 12, 1–9. [Google Scholar] [CrossRef]
Khan, A.; Shah, K.; Abdeljawad, T.; Alqudah, M.A. Existence of results and computational analysis of a fractional order two strain epidemic model. Results Phys. 2022, 39, 105649. [Google Scholar] [CrossRef]
Benkerrouche, A.; Souid, M.S.; Karapinar, E.; Hakem, A. On the boundary value problems of Hadamard fractional differential equations of variable order. Math. Meth. Appl. Sci. 2022, 46, 3187–3203. [Google Scholar] [CrossRef]
Khan, A.; Ain, Q.T.; Abdeljawad, T.; Nisar, K.S. Exact Controllability of Hilfer Fractional Differential System with Non-instantaneous Impluleses and State Dependent Delay. Qual. Theory Dyn. Syst. 2023, 22, 62. [Google Scholar] [CrossRef]
Wang, Y.; Liu, S.; Khan, A. On fractional coupled logistic maps: Chaos analysis and fractal control. Nonlinear Dyn. 2023, 111, 5889–5904. [Google Scholar] [CrossRef]
Akgul, A.; Baleanu, D. On solutions of variable-order fractional differential equations. Int. J. Optim. Control. Theor. Appl. 2017, 7, 112–116. [Google Scholar] [CrossRef] [Green Version]
Refice, A.; Souid, M.S.; Stamova, I. On the boundary value problems of Hadamard fractional differential equations of variable order via Kuratowski MNC technique. Mathematics 2021, 9, 1134. [Google Scholar] [CrossRef]
Bai, Y.; Kong, H. Existence of solutions for nonlinear Caputo-Hadamard fractional differential equations via the method of upper and lower solutions. J. Nonlinear Sci. Appl. 2017, 10, 5744–5752. [Google Scholar] [CrossRef] [Green Version]
Telli, B.; Souid, M.S.; Stamova, I. Boundary-Value Problem for Nonlinear Fractional Differential Equations of Variable Order with Finite Delay via Kuratowski Measure of Noncompactness. Axioms 2023, 12, 80. [Google Scholar] [CrossRef]
Wang, H.; Zheng, X. Analysis and numerical solution of a nonlinear variable-order fractional differential equation. Adv. Comput. Math. 2019, 45, 2647–2675. [Google Scholar] [CrossRef]
Guo, D.; Lakshmikantham, V.; Liu, X. Nonlinear Integral Equations in Abstract Spaces; Springer Science & Business Media: Berlin, Germany, 2013; p. 373. [Google Scholar]
Hristova, S.; Benkerrouche, A.; Souid, M.S.; Hakem, A. Boundary value problems of Hadamard fractional differential equations of variable order. Symmetry 2021, 13, 896. [Google Scholar] [CrossRef]
Podlubny, I. Fractional Differential Equations; Academic Press: San Diego, CA, USA, 1999. [Google Scholar]
Samko, S.G.; Boss, B. Integration and differentiation to a variable fractional order. Integral Transform. Spec. Funct. 1993, 1, 277–300. [Google Scholar] [CrossRef]
Sousa, J.V.D.C.; de Oliveira, E.C. Two new fractional derivatives of variable order with non-singular kernel and fractional differential equation. Comput. Appl. Math. 2018, 37, 5375–5394. [Google Scholar] [CrossRef]
Tarasov, V.E. Fractional Dynamics: Application of Fractional Calculus to Dynamics of Particles, Fields and Media; Springer: Berlin/Heidelberg, Germany; Higher Education Press: Beijing, China, 2010. [Google Scholar]
Zhang, S.; Hu, L. The existence of solutions and generalized Lyapunov-type inequalities to boundary value problems of differential equations of variable order. AIMS Math. 2020, 5, 2923–2943. [Google Scholar] [CrossRef]
Samko, S.G. Fractional integration and differentiation of variable order. Anal. Math. 1995, 21, 213–236. [Google Scholar] [CrossRef]
Valério, D.; Costa, J.S. Variable-order fractional derivatives and their numerical approximations. Signal Process. 2011, 91, 470–483. [Google Scholar] [CrossRef]
Kilbas, A.A.; Srivastava, H.M.; Trujillo, J.J. Theory and Applications of Fractional Differential Equations; North-Holland Mathematics Studies, 204; Elsevier Science B.V.: Amsterdam, The Netherlands, 2006. [Google Scholar]
Zhang, S. Existence of solutions for two-point boundary-value problems with singular differential equations of variable order. Electron. J. Differ. Equ. 2013, 2013, 1–16. [Google Scholar]
Zhang, H.; Li, S.; Hu, L. The existeness and uniqueness result of solutions to initial value problems of nonlinear diffusion equations involving with the conformable variable derivative. Rev. Real Acad. Cienc. Exactas Fis. Nat. Ser. Mat. 2019, 113, 1601–1623. [Google Scholar] [CrossRef]
Benchohra, M.; Lazreg, J.E. Existence and Ulam stability for nonlinear implicit fractional differential equations with Hadamard derivative. Stud. Univ. Babes-Bolyai Math. 2017, 62, 27–38. [Google Scholar] [CrossRef] [Green Version]

Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

© 2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).

Share and Cite

MDPI and ACS Style

Telli, B.; Souid, M.S.; Alzabut, J.; Khan, H. Existence and Uniqueness Theorems for a Variable-Order Fractional Differential Equation with Delay. Axioms 2023, 12, 339. https://doi.org/10.3390/axioms12040339

AMA Style

Telli B, Souid MS, Alzabut J, Khan H. Existence and Uniqueness Theorems for a Variable-Order Fractional Differential Equation with Delay. Axioms. 2023; 12(4):339. https://doi.org/10.3390/axioms12040339

Chicago/Turabian Style

Telli, Benoumran, Mohammed Said Souid, Jehad Alzabut, and Hasib Khan. 2023. "Existence and Uniqueness Theorems for a Variable-Order Fractional Differential Equation with Delay" Axioms 12, no. 4: 339. https://doi.org/10.3390/axioms12040339

APA Style

Telli, B., Souid, M. S., Alzabut, J., & Khan, H. (2023). Existence and Uniqueness Theorems for a Variable-Order Fractional Differential Equation with Delay. Axioms, 12(4), 339. https://doi.org/10.3390/axioms12040339

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

Article Menu

Existence and Uniqueness Theorems for a Variable-Order Fractional Differential Equation with Delay

Abstract

1. Introduction

2. Preliminaries

3. Existence of Solutions

4. Ulam–Hyers Stability

5. Example

6. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

Share and Cite

Article Metrics

Article Access Statistics

Further Information

Guidelines

MDPI Initiatives

Follow MDPI