Nonlocal Coupled System for (k,φ)-Hilfer Fractional Differential Equations

Samadi, Ayub; Ntouyas, Sotiris K.; Tariboon, Jessada

doi:10.3390/fractalfract6050234

Open AccessArticle

Nonlocal Coupled System for (k,φ)-Hilfer Fractional Differential Equations

by

Ayub Samadi

^1,*

,

Sotiris K. Ntouyas

²

and

Jessada Tariboon

^3,*

¹

Department of Mathematics, Miyaneh Branch, Islamic Azad University, Miyaneh 5315836511, Iran

²

Department of Mathematics, University of Ioannina, 451 10 Ioannina, Greece

³

Intelligent and Nonlinear Dynamic Innovations Research Center, Department of Mathematics, Faculty of Applied Science, King Mongkut’s University of Technology North Bangkok, Bangkok 10800, Thailand

^*

Authors to whom correspondence should be addressed.

Fractal Fract. 2022, 6(5), 234; https://doi.org/10.3390/fractalfract6050234

Submission received: 18 March 2022 / Revised: 16 April 2022 / Accepted: 21 April 2022 / Published: 23 April 2022

(This article belongs to the Special Issue Initial and Boundary Value Problems for Differential Equations)

Download Versions Notes

Abstract

:

In this paper, we study a coupled system consisting of

(k, φ)

-Hilfer fractional differential equations of the order

(1, 2],

supplemented with nonlocal coupled multi-point boundary conditions. The existence and uniqueness of the results are established via Banach’s contraction mapping principle, the Leray–Schauder alternative and Krasnosel’skiĭ’s fixed-point theorem. Numerical examples are constructed to illustrate the obtained results.

Keywords:

(k,φ)-Hilfer fractional derivative; Riemann–Liouville fractional derivative; Caputo fractional derivative; existence; uniqueness; fixed-point theorems

MSC:

34A08; 34B10

1. Introduction

Fractional differential equations have recently been applied as a valuable tool in the modeling of many physical phenomena. There has been substantial theoretical development in fractional calculus and fractional differential equations in recent years; see the monographs [1,2,3,4,5,6,7,8,9]. Usually, fractional derivative operators are defined via fractional integral operators and depend on Euler’s gamma function. Different definitions of fractional derivative operators, such as Riemann–Liouville, Caputo, Erdélyi–Kober, Hadamard and Hilfer fractional operators to name a few, have been proposed in the literature. In [10], the Riemann–Liouville fractional integral operator, with the help of the generalized Euler’s k gamma function, was extended to the k-Riemann–Liouville fractional integral operator. Based on this integral operator, in [11], the k-Riemann–Liouville fractional derivative was defined. We refer to [12,13,14,15,16,17] and the references cited therein for some results on the k-Riemann–Liouville fractional derivative. The

φ

-Riemann–Liouville fractional integral and

φ

-Riemann–Liouville fractional derivative were introduced in [2]. In addition the

φ

-Hilfer fractional derivative was defined in [18]. In [19], the

(k, φ)

-Riemann–Liouville fractional integral was defined, and in [11], the

(k, φ)

-Riemann–Liouville fractional derivative operators were defined. Very recently, in [20], the

(k, φ)

-Hilfer fractional derivative operator was introduced, and several of its properties were studied.

Moreover, in [20], the authors studied the following

(k, φ)

-Hilfer fractional nonlinear initial value problem of the form

\{\begin{matrix} ^{k, H} D_{c +}^{α, β; φ} w (θ) = f (θ, w (θ)), θ \in (c, d], 0 < α < k, 0 \leq β \leq 1, \\ ^{k} I^{k - θ_{k} : φ} w (c) = w_{c} \in R, θ_{k} = α + β (k - α), \end{matrix}

(1)

where

^{k, H} D^{α, β; φ}

is the

(k, φ)

-Hilfer fractional derivative operator of order

\bar{α}

,

0 < \bar{α} \leq 1

and parameter

β

,

0 \leq β \leq 1

, and

f : [c, d] \times R \to R

is a continuous function. An existence and uniqueness result was proved via Banach’s fixed-point theorem.

Recently, motivated by the paper [20], we initiated in [21] the study of boundary value problems for

(k, φ)

-Hilfer fractional derivative of order in

(1, 2]

of the form

\{\begin{matrix} ^{k, H} D^{\bar{α}, \bar{β}; φ} w (θ) = f (θ, w (θ)), θ \in (c, d], \\ w (c) = 0, w (d) = \sum_{i = 1}^{m} λ_{i} w (ξ_{i}), \end{matrix}

(2)

where

^{k, H} D^{\bar{α}, \bar{β}; φ}

is the

(k, φ)

-Hilfer fractional derivative of order

\bar{α}

,

1 < \bar{α} < 2

and parameter

\bar{β}

,

0 \leq \bar{β} \leq 1

,

f : [c, d] \times R \to R

is a continuous function,

λ_{i} \in R,

and

c < ξ_{i} < d, i = 1, 2, \dots, m .

The existence and uniqueness of the results were proved by using Banach’s and Krasnosel’skiĭ’s fixed-point theorems, as well as the Laray–Schauder nonlinear alternative.

As far as we know, in the literature there is no other paper dealing with the

(k, φ)

-Hilfer fractional derivative operator of the order

\bar{α} \in (1, 2],

and therefore, this new area of research needs further exploration. Thus, our main contribution in this paper is to enrich this new research area with new results in other directions. In the present work, we discuss the existence and uniqueness of solutions for a coupled system of nonlinear fractional differential equations involving the

(k, φ)

-Hilfer fractional derivative operator of order

\bar{α}

,

1 < \bar{α} \leq 2

and parameter

\bar{β}

,

0 \leq \bar{β} \leq 1

of the form

\{\begin{matrix} ^{k, H} D^{\bar{α}, \bar{β}; φ} w (θ) = f (θ, w (θ), z (θ)), θ \in (c, d], \\ ^{k, H} D^{α_{1}, β_{1}; φ} z (θ) = f_{1} (θ, w (θ), z (θ)), θ \in (c, d], \\ w (c) = 0, w (d) = \sum_{i = 1}^{m} λ_{i} z (ξ_{i}), \\ z (c) = 0, z (d) = \sum_{j = 1}^{k} μ_{j} w (η_{j}), \end{matrix}

(3)

where

^{k, H} D^{\bar{α}, \bar{β}; φ},

^{k, H} D^{α_{1}, β_{1}; φ}

denote the

(k, φ)

-Hilfer fractional derivative operator of orders

\bar{α}, α_{1}

,

1 < \bar{α}, α_{1} < 2

and parameters

\bar{β}, β_{1}

,

0 \leq \bar{β}, β_{1} \leq 1

, respectively,

f, f_{1} : [c, d] \times R \to R

are continuous functions,

λ_{i}, μ_{j} \in R,

and

a < ξ_{i}, η_{j} < b, i = 1, 2, \dots, m, j = 1, 2, \dots, k .

The existence and uniqueness of the results are proved by using Banach’s contraction mapping principle, the Leray–Schauder alternative and Krasnosel’skiĭ’s fixed-point theorem.

Numerical examples are constructed, illustrating the applicability of our obtained theoretical results.

Nonlocal conditions are considered to be more plausible than the classical conditions, as they can correctly describe certain features of physical problems.

We organize the remaining part of this work as follows. In Section 2, an auxiliary result concerning a linear variant of the system (3) is presented. This lemma is the basic key in transforming the given system iinto an equivalent fixed-point problem. The main results are presented in Section 3, while Section 5 is devoted to illustrative examples. The study of coupled systems of fractional differential equations is a significant area of investigation, as such systems often occur in applications. The work in this paper is new and enriches the literature on coupled systems of

(k, φ)

-Hilfer fractional differential equations. The used methods are standard, but their configuration in the present problem is new.

2. Preliminaries

Definition 1

([2]). Suppose that

h \in L^{1} ([c, d], R)

. Then, the Riemann–Liouville fractional integral is defined by

I_{c +}^{α} h (θ) = \frac{1}{Γ (α)} \int_{c}^{θ} {(θ - s)}^{α - 1} h (s) d s, α > 0, θ > c .

(4)

Here,

Γ (\cdot)

is the classical Euler gamma function.

Definition 2

([2]). Let

h \in C ([c, d], R)

. Then the Riemann–Liouville fractional derivative operator of order

α > 0

is defined by

^{R L} D_{c +}^{α} h (θ) = D^{n} I_{c +}^{n - α} h (θ) = \frac{1}{Γ (n - α)} \frac{d^{n}}{d θ^{n}} \int_{c}^{θ} {(θ - s)}^{n - α - 1} h (s) d s, θ > c,

(5)

where

n - 1 < α \leq n

and

n \in N .

Definition 3

([2]). Let

h \in C^{n} ([c, d], R)

. Then the Caputo fractional derivative operator of order

α > 0

is defined by

^{C} D_{c +}^{α} h (θ) = I_{c +}^{n - α} D^{n} f (θ) = \frac{1}{Γ (n - α)} \int_{c}^{θ} {(θ - s)}^{n - α - 1} h^{(n)} (s) d s, θ > c,

(6)

where

n - 1 < α \leq n

and

n \in N .

Definition 4

([10]). Let

h \in L^{1} ([c, d], R)

and

k, α \in R^{+} .

Then the k-Riemann–Liouville fractional derivative of order α of the function h is given by

^{k} I_{c +}^{α} h (θ) = \frac{1}{k Γ_{k} (α)} \int_{c}^{θ} {(θ - s)}^{\frac{α}{k} - 1} h (s) d s,

(7)

where

Γ_{k}

is the k-gamma function for

z \in C

with

ℜ (z) > 0

and

k \in R, k > 0

which is defined in [22] by

Γ_{k} (z) = \int_{0}^{\infty} s^{z - 1} e^{- \frac{s^{k}}{k}} d s .

It is well known that

Γ (x) = lim_{k \to 1} Γ_{k} (x), Γ_{k} (x) = k^{\frac{x}{k} - 1} Γ (\frac{x}{k}) and Γ_{k} (x + k) = x Γ_{k} (x) .

Definition 5

([11]). Let

h \in L^{1} ([c, d], R)

and

k, α \in R^{+} .

Then the k-Riemann–Liouville fractional derivative of order

\bar{α}

of the function h is given by

^{k, R L} D_{c +}^{\bar{α}} h (θ) = {(k \frac{d}{d θ})}^{n}^{k} I_{c +}^{n k - \bar{α}} h (θ), n = ⌈\frac{\bar{α}}{k}⌉,

(8)

where

⌈\frac{\bar{α}}{k}⌉

is the ceiling function of

\frac{\bar{α}}{k} .

Definition 6

([2]). Let

h \in L^{1} ([c, d], R)

and an increasing function

φ : [c, d] \to R

with

φ^{'} (θ) \neq 0

for all

θ \in [c, d] .

Then the φ-Riemann–Liouville fractional integral of the function h is given by

I^{\bar{α}; φ} h (θ) = \frac{1}{Γ_{k} (\bar{α})} \int_{c}^{θ} φ^{'} (s) {(φ (θ) - φ (s))}^{\bar{α} - 1} h (s) d s .

(9)

Definition 7

([2]). Let

n - 1 < \bar{α} \leq n,

φ \in C^{n} ([c, d], R),

φ^{'} (θ) \neq 0, θ \in [c, d],

and

h \in C ([c, d], R) .

Then the φ-Riemann–Liouville fractional derivative of the function h of order

\bar{α}

is given by

^{R L} D^{\bar{α}; φ} h (θ) = {(\frac{1}{φ^{'} (θ)} \frac{d}{d t})}^{n} I_{c +}^{n - \bar{α}; φ} h (θ) .

(10)

Definition 8

([23]). Let

n - 1 < \bar{α} \leq n, φ \in C^{n} ([c, d], R),

φ^{'} (θ) \neq 0, θ \in [c, d],

and

h \in C ([c, d], R) .

Then the φ-Caputo fractional derivative of the function h of order α is given by

^{C} D^{\bar{α}; φ} h (θ) = I_{c +}^{n - \bar{α}; φ} {(\frac{1}{φ^{'} (θ)} \frac{d}{d θ})}^{n} h (θ),

(11)

respectively.

Definition 9

([18]). Let

n - 1 < \bar{α} \leq n,

φ \in C^{n} ([c, d], R),

φ^{'} (θ) \neq 0, θ \in [c, d],

and

h \in C ([c, d], R) .

Then the φ-Hilfer fractional derivative of the function

h \in C ([c, d], R)

of order

\bar{α} \in (n - 1, n]

and type

\bar{β} \in [0, 1]

and

φ \in C^{n} ([c, d], R),

φ^{'} (θ) \neq 0, θ \in [c, d],

is defined by

^{H} D^{\bar{α}, \bar{β}; φ} h (θ) = I_{c +}^{β (n - \bar{α}); φ} {(\frac{1}{φ^{'} (θ)} \frac{d}{d θ})}^{n} I_{c +}^{(1 - \bar{β}) (n - \bar{α}); φ} h (θ) .

(12)

Definition 10

([19]). Let

h \in L^{1} ([c, d], R)

and

k > 0 .

Then the

(k, φ)

-Riemann–Liouville fractional integral of order

\bar{α} > 0

(

\bar{α} \in R

) of the function h is given by

^{k} I_{c +}^{\bar{α}; φ} h (θ) = \frac{1}{k Γ_{k} (\bar{α})} \int_{c}^{θ} φ^{'} (s) {(φ (θ) - φ (s))}^{\frac{\bar{α}}{k} - 1} h (s) d s .

(13)

Definition 11

([20]). Let

\bar{α}, k \in R^{+} = (0, \infty),

β \in [0, 1],

φ \in C^{n} ([c, d], R),

φ^{'} (θ) \neq 0, θ \in [c, d]

and

h \in C^{n} ([c, d], R) .

Then the

(k, φ)

-Hilfer fractional derivative of the function h of order

\bar{α}

and type

\bar{β},

is defined by

^{k, H} D^{\bar{α}, \bar{β}; φ} h (\bar{θ}) = I_{c +}^{\bar{β} (n k - \bar{α}); φ} {(\frac{k}{φ^{'} (θ)} \frac{d}{d θ})}^{n}^{k} I_{c +}^{(1 - \bar{β}) (n k - \bar{α}); φ} h (θ), n = ⌈\frac{\bar{α}}{k}⌉ .

(14)

Note the following:

For $\bar{β} = 0$ and $\bar{β} = 1,$ (14) reduces to

$^{k, R L} D^{\bar{α}; φ} h (θ) = {(\frac{k}{φ^{'} (θ)} \frac{d}{d θ})}^{n}^{k} I_{c +}^{(1 - \bar{β}) (n k - \bar{α})} h (θ),$

(15)

and

$^{k, C} D^{\bar{α}; φ} h (θ) = I_{c +}^{n k - \bar{α}; φ} {(\frac{k}{φ^{'} (θ)} \frac{d}{d θ})}^{n} h (θ),$

(16)

which are, respectively, the $(k, φ)$ -Riemann–Liouville and $(k, φ)$ -Caputo fractional derivatives. If, in addition, we take in (15), $φ (θ) = θ,$ then we obtain the k-Riemann–Liouville fractional derivative defined in [11], while if we take $φ (θ) = θ$ in (16), then we obtain the k-Caputo fractional derivative

$^{k, C} D^{\bar{α}; φ} h (θ) = I_{c +}^{n k - \bar{α}; φ} {(k \frac{d}{d θ})}^{n} h (θ) .$

(17)
If $φ (θ) = θ^{ρ}$ then (14) reduces to the k-Hilfer–Katugampola fractional derivative operator. If, in addition, $\bar{β} = 0$ , then (14) reduces to the k-Katugampola fractional derivative, while if $\bar{β} = 1$ reduces to the k-Caputo–Katugampola fractional derivative operator, respectively.
If $φ (θ) = log θ$ , then (14) reduces to the k-Hilfer–Hadamard fractional derivative operator. If, in addition, $\bar{β} = 0$ , then (14) reduces to the k-Hadamard fractional derivative, while if $\bar{β} = 1$ then (14) reduces to the k-Caputo–Hadamard fractional derivative operator.

Remark 1.

If we put

θ_{k} = \bar{α} + \bar{β} (n k - \bar{α}),

then we obtain

(1 - \bar{β}) (n k - \bar{α}) = n k - θ_{k}

and

\bar{β} (n k - \bar{α}) = θ_{k} - \bar{α} .

Hence

\begin{matrix} ^{k, H} D^{\bar{α}, \bar{β}; φ} h (θ) & = & ^{k} I_{c +}^{θ_{k} - \bar{α}; φ} {(\frac{k}{φ^{'} (θ)} \frac{d}{d θ})}^{n}^{k} I_{c +}^{n k - θ_{k}; φ} h (θ) \\ = & ^{k} I_{c +}^{θ_{k} - \bar{α}; φ} (^{k, R L} D^{θ_{k}, φ} h) (θ) . \end{matrix}

which means that the

(k, φ)

-Hilfer fractional derivative can be defined in the form of the

(k, φ)

-Riemann–Liouville fractional derivative.

Note that for

β \in [c, d]

and

n - 1 < \frac{\bar{α}}{k} \leq n,

we have

n - 1 < \frac{θ_{k}}{k} \leq n .

Lemma 1

([20]). Let

μ, k \in R^{+} = (0, \infty)

and

n = ⌈\frac{μ}{k}⌉ .

Assume that

h \in C^{n} ([c, d], R)

and

^{k} I_{c +}^{n k - μ; φ} h \in C^{n} ([c, d], R) .

Then

^{k} I^{μ; φ} (^{k, R L} D^{μ; φ} h (θ)) = h (θ) - \sum_{j = 1}^{n} \frac{{(φ (θ) - φ (c))}^{\frac{μ}{k} - j}}{Γ_{k} (μ - j k + k)} {[{(\frac{k}{φ^{'} (θ)} \frac{d}{d θ})}^{n - j}^{k} I_{c +}^{n k - μ; φ} h (θ)]}_{θ = c} .

Lemma 2

([20]). Let

\bar{α}, k \in R^{+} = (0, \infty)

with

\bar{α} < k,

\bar{β} \in [c, d]

and

θ_{k} = \bar{α} + \bar{β} (k - \bar{α}) .

Then

^{k} I^{θ_{k}, φ} (^{k, R L} D^{θ_{k}, φ} h) (θ) =^{k} I^{\bar{α}; φ} (^{k, H} D^{\bar{α}, \bar{β}; φ} h) (θ), h \in C^{n} ([c, d], R) .

Now we prove an auxiliary result concerning a linear variant of the system (3).

Lemma 3.

Let

c < d,

k > 0,

1 < \bar{α}, α_{1} \leq 2,

\bar{β}, β_{1} \in [0, 1],

θ_{k} = \bar{α} + \bar{β} (2 k - \bar{α}),

q_{k} = α_{1} + β_{1} (2 k - α_{1}),

h \in C^{2} ([c, d], R)

and

A : = A_{1} A_{4} - A_{2} A_{3} \neq 0 .

(18)

Then the function unique solution of the nonlocal

(k, φ)

-Hilfer fractional system

\{\begin{matrix} ^{k, H} D^{\bar{α}, \bar{β}; φ} w (θ) = h (θ), θ \in (c, d], \\ ^{k, H} D^{α_{1}, β_{1}; φ} z (θ) = h_{1} (θ), θ \in (c, d], \\ w (c) = 0, w (d) = \sum_{i = 1}^{m} λ_{i} z (ξ_{i}), \\ z (c) = 0, z (d) = \sum_{j = 1}^{k} μ_{j} w (η_{j}), \end{matrix}

(19)

is given by

\begin{matrix} w (θ) & = & ^{k} I^{\bar{α}; φ} h (θ) + \frac{{(φ (θ) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{A Γ_{k} (θ_{k})} [A_{4} (\sum_{i = 1}^{m} λ_{i}^{k} I^{α_{1}; φ} h_{1} (ξ_{i}) -^{k} I^{\bar{α}; φ} h (d)) \\ + A_{2} (\sum_{j = 1}^{k} μ_{j}^{k} I^{\bar{α}; φ} h (η_{j}) -^{k} I^{α_{1}; φ} h_{1} (d))], \end{matrix}

(20)

and

\begin{matrix} z (θ) & = & ^{k} I^{α_{1}; φ} h_{1} (θ) + \frac{{(φ (θ) - φ (c))}^{\frac{q_{k}}{k} - 1}}{A Γ_{k} (q_{k})} [A_{1} (\sum_{j = 1}^{k} μ_{j}^{k} I^{\bar{α}; φ} h (η_{j}) -^{k} I^{α_{1}; φ} h_{1} (d)) \\ + A_{3} (\sum_{i = 1}^{m} λ_{i}^{k} I^{α_{1}; φ} h_{1} (ξ_{i}) -^{k} I^{\bar{α}; φ} h (d))], \end{matrix}

(21)

where

\begin{matrix} A_{1} & = & \frac{{(φ (d) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{Γ_{k} (θ_{k})}, A_{2} = \sum_{i = 1}^{m} λ_{i} \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{q_{k}}{k} - 1}}{Γ_{k} (q_{k})} \\ A_{3} & = & \sum_{j = 1}^{k} μ_{j} \frac{{(φ (η_{j}) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{Γ_{k} (θ_{k})}, A_{4} = \frac{{(φ (d) - φ (c))}^{\frac{q_{k}}{k} - 1}}{Γ_{k} (q_{k})} . \end{matrix}

(22)

Proof.

Let w be a solution of the system (19). Operating fractional integral

^{k} I^{\bar{α}; φ}

on both sides of the first equation in (19) and using Lemma 1, we obtain

w (θ) =^{k} I^{\bar{α}; φ} h (θ) + c_{0} \frac{{(φ (θ) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{Γ_{k} (θ_{k})} + c_{1} \frac{{(φ (θ) - φ (c))}^{\frac{θ_{k}}{k} - 2}}{Γ_{k} (θ_{k} - k)},

(23)

where

c_{0} = {[(\frac{k}{φ^{'} (θ)} \frac{d}{d θ})^{k} I^{2 k - θ_{k} : φ} w (θ)]}_{θ = c}, c_{1} = {[^{k} I^{2 k - θ_{k} : φ} w (θ)]}_{θ = c} .

In the same process, let z be a solution of the system (19). Taking fractional integral

^{k} I^{α_{1}; φ}

on both sides of the second equation in (19) and using Lemma 1, we obtain

z (θ) =^{k} I^{α_{1}; φ} h_{1} (θ) + d_{0} \frac{{(φ (θ) - φ (c))}^{\frac{q_{k}}{k} - 1}}{Γ_{k} (q_{k})} + d_{1} \frac{{(φ (θ) - φ (c))}^{\frac{q_{k}}{k} - 2}}{Γ_{k} (q_{k} - k)},

(24)

where

d_{0} = {[(\frac{k}{φ^{'} (θ)} \frac{d}{d θ})^{k} I^{2 k - q_{k} : φ} z (θ)]}_{θ = c}, d_{1} = {[^{k} I^{2 k - q_{k} : φ} z (θ)]}_{θ = c} .

Due to the boundary conditions

w (c) = 0

and

z (c) = 0,

we obtain

c_{1} = 0

and

d_{1} = 0,

since

\frac{θ_{k}}{k} - 2 < 0, \frac{q_{k}}{k} - 2 < 0

by Remark 1. From the second boundary conditions

w (d) = \sum_{i = 1}^{m} λ_{i} z (ξ_{i})

and

z (d) = \sum_{j = 1}^{k} μ_{j} w (η_{j})

we obtain the system

\begin{matrix} ^{k} I^{\bar{α}; φ} h (d) + c_{0} \frac{{(φ (d) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{Γ_{k} (θ_{k})} = \sum_{i = 1}^{m} λ_{i}^{k} I^{α_{1}; φ} h_{1} (ξ_{i}) + d_{0} \sum_{i = 1}^{m} λ_{i} \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{q_{k}}{k} - 1}}{Γ_{k} (q_{k})}, \\ ^{k} I^{α_{1}; φ} h_{1} (d) + d_{0} \frac{{(φ (d) - φ (c))}^{\frac{q_{k}}{k} - 1}}{Γ_{k} (q_{k})} = \sum_{j = 1}^{k} μ_{j}^{k} I^{\bar{α}; φ} h (η_{j}) + c_{0} \sum_{j = 1}^{k} μ_{j} \frac{{(φ (η_{j}) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{Γ_{k} (θ_{k})}, \end{matrix}

or, using the notations (22)

\begin{matrix} A_{1} c_{0} - A_{2} d_{0} & = & \sum_{i = 1}^{m} λ_{i}^{k} I^{α_{1}; φ} h_{1} (ξ_{i}) -^{k} I^{\bar{α}; φ} h (d), \\ - A_{3} c_{0} + A_{4} d_{0} & = & \sum_{j = 1}^{k} μ_{j}^{k} I^{α; φ} h (η_{j}) -^{k} I^{α_{1}; φ} h_{1} (d) . \end{matrix}

(25)

Solving the system (25) for

c_{0}

and

d_{0},

we have

\begin{matrix} c_{0} & = & \frac{1}{A} [A_{4} (\sum_{i = 1}^{m} λ_{i}^{k} I^{α_{1}; φ} h_{1} (ξ_{i}) -^{k} I^{\bar{α}; φ} h (d)) + A_{2} (\sum_{j = 1}^{k} μ_{j}^{k} I^{\bar{α}; φ} h (η_{j}) -^{k} I^{α_{1}; φ} h_{1} (d))], \\ d_{0} & = & \frac{1}{A} [A_{1} (\sum_{j = 1}^{k} μ_{j}^{k} I^{\bar{α}; φ} h (η_{j}) -^{k} I^{α_{1}; φ} h_{1} (d)) + A_{3} (\sum_{i = 1}^{m} λ_{i}^{k} I^{α_{1}; φ} h_{1} (ξ_{i}) -^{k} I^{\bar{α}; φ} h (d))] . \end{matrix}

Substituting the values of

c_{0}, c_{1}

and

d_{0}, d_{1}

in (23) and (24), respectively, we obtain the solutions (20) and (21). We can prove easily the converse by direct computation. The proof is finished. □

3. Existence and Uniqueness Results

Let

X = C ([c, d], R)

be the Banach space of all continuous functions w from

[c, d]

to

R

endowed with the norm

∥ w ∥ = max {| w (θ) |, θ \in [c, d]} .

The product space

(X \times X, ∥ (w, z) ∥)

is a Banach space with norm

∥ (w, z) ∥ = ∥ w ∥ + ∥ z ∥ .

In view of Lemma 3, we define an operator

T : X \times X \to X \times X

by

T (w, z) (θ) = (\begin{matrix} T_{1} (w, z) (θ) \\ T_{2} (w, z) (θ) \end{matrix}),

where

\begin{matrix} T_{1} (w, z) (θ) \\ = & ^{k} I^{\bar{α}; φ} f (θ, w (θ), z (θ)) \\ + \frac{{(φ (θ) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{A Γ_{k} (θ_{k})} [A_{4} (\sum_{i = 1}^{m} λ_{i}^{k} I^{α_{1}; φ} f_{1} (ξ_{i}, w (ξ_{i}), z (ξ_{i})) -^{k} I^{\bar{α}; φ} f (d, w (d), z (d))) \\ + A_{2} (\sum_{j = 1}^{k} μ_{j}^{k} I^{\bar{α}; φ} f (η_{j}, w (η_{j}), z (η_{j})) -^{k} I^{α_{1}; φ} f_{1} (d, w (d), z (d)))], \end{matrix}

(26)

and

\begin{matrix} T_{2} (w, z) (θ) \\ = & ^{k} I^{α_{1}; φ} f_{1} (θ, w (θ), z (θ)) \\ + \frac{{(φ (θ) - φ (c))}^{\frac{q_{k}}{k} - 1}}{A Γ_{k} (q_{k})} [A_{1} (\sum_{j = 1}^{k} μ_{j}^{k} I^{\bar{α}; φ} f (η_{j}, w (η_{j}), z (η_{j})) -^{k} I^{α_{1}; φ} f_{1} (d, w (d), z (d))) \\ + A_{3} (\sum_{i = 1}^{m} λ_{i}^{k} I^{α_{1}; φ} f_{1} (ξ_{i}, w (ξ_{i}), z (ξ_{i})) -^{k} I^{\bar{α}; φ} f (d, w (d), z (d)))] . \end{matrix}

(27)

For convenience, we put

\begin{matrix} Q_{1} & = & \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} + \frac{{(φ (d) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{2} \sum_{j = 1}^{k} | μ_{j} | \frac{{(φ (η_{j}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}], \end{matrix}

(28)

\begin{matrix} Q_{2} & = & \frac{{(φ (d) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} \sum_{i = 1}^{m} | λ_{i} | \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)} \\ + A_{2} \frac{{(φ (d) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)}], \end{matrix}

(29)

\begin{matrix} Q_{3} & = & \frac{{(φ (d) - φ (c))}^{\frac{q_{k}}{k} - 1}}{| A | Γ_{k} (q_{k})} [A_{1} \sum_{j = 1}^{k} | μ_{j} | \frac{{(φ (η_{j}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{3} \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}], \end{matrix}

(30)

\begin{matrix} Q_{4} & = & \frac{{(φ (d) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)} + \frac{{(φ (d) - φ (c))}^{\frac{q_{k}}{k} - 1}}{| A | Γ_{k} (q_{k})} [A_{1} \frac{{(φ (d) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)} \\ + A_{3} \sum_{i = 1}^{m} | λ_{i} | \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)}], \end{matrix}

(31)

and

Q_{1}^{*} = Q_{1} - \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}, Q_{4}^{*} = Q_{4} - \frac{{(φ (d) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)} .

(32)

3.1. Existence of a Unique Solution

Now, by applying Banach’s contraction mapping principle [24], our first result is obtained.

Theorem 1.

Assume that

A \neq 0

and

f, f_{1} : [c, d] \times R^{2} \to R

are two functions for which there exist constants

m_{i}, n_{i}, i = 1, 2

such that for all

θ \in [c, d]

and

u_{i}, v_{i} \in R, i = 1, 2,

| f (θ, u_{1}, u_{2}) - f (θ, v_{1}, v_{2}) | \leq m_{1} | u_{1} - v_{1} | + m_{2} | u_{2} - v_{2} |

and

| f_{1} (θ, u_{1}, u_{2}) - f_{1} (, v_{1}, v_{2}) | \leq n_{1} | u_{1} - v_{1} | + n_{2} | u_{2} - v_{2} | .

In addition, we suppose that

(Q_{1} + Q_{3}) (m_{1} + m_{2}) + (Q_{2} + Q_{4}) (n_{1} + n_{2}) < 1,

where

Q_{i}, i = 1, 2, 3, 4

are given by (28)–(31). Then, the nonlocal

(k, φ)

-Hilfer fractional system (3) has a unique solution.

Proof.

Define

{sup}_{θ \in [c, d]} f (θ, 0, 0) = N < \infty

and

{sup}_{θ \in [c, d]} f_{1} (θ, 0, 0) = N_{1} < \infty

such that

r \geq \frac{(Q_{1} + Q_{3}) N + (Q_{2} + Q_{4}) N_{1}}{1 - [(Q_{1} + Q_{3}) (m_{1} + m_{2}) + (Q_{2} + Q_{4}) (n_{1} + n_{2})]} .

We show that

T B_{r} \subset B_{r},

where

B_{r} = {(w, z) \in X \times X : ∥ (w, z) ∥ \leq r} .

For

(w, z) \in B_{r},

we have

\begin{matrix} | T_{1} (w, z) (θ) | \\ \leq & ^{k} I^{\bar{α}; φ} [| f (θ, w (θ), z (θ)) - f (θ, 0, 0) | + | f (θ, 0, 0) |] \\ + \frac{{(φ (θ) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} (\sum_{i = 1}^{m} | λ_{i} |^{k} I^{α_{1}; φ} [h_{1} (ξ_{i}, w (ξ_{i}), z (ξ_{i})) - f_{1} (ξ_{i}, 0, 0) | \\ + | f (ξ_{i}, 0, 0) |] +^{k} I^{\bar{α}; φ} [| f (d, w (d), z (d)) - f (d, 0, 0) | + | f (d, 0, 0) |]) \\ + A_{2} (\sum_{j = 1}^{k} | μ_{j} |^{k} I^{\bar{α}; φ} [f (η_{j}, w (η_{j}), z (η_{j})) - f (η_{j}, 0, 0) | + | f (η_{j}, 0, 0) |] \\ +^{k} I^{α_{1}; φ} [f_{1} (d, w (d), z (d)) - f_{1} (d, 0, 0) | + | f_{1} (d, 0, 0) |])] \\ \leq & ^{k} I^{\bar{α}; φ} [m_{1} ∥ w ∥ + m_{2} ∥ z ∥ + N] (d) \\ + \frac{{(φ (d) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} (\sum_{i = 1}^{m} | λ_{i} |^{k} I^{α_{1}; φ} [n_{1} ∥ w ∥ + n_{2} ∥ z ∥ + N_{1}] (ξ_{i}) \\ +^{k} I^{\bar{α}; φ} [m_{1} ∥ w ∥ + m_{2} ∥ z ∥ + N] (d)) + A_{2} (\sum_{j = 1}^{k} | μ_{j} |^{k} I^{\bar{α}; φ} [m_{1} ∥ w ∥ + m_{2} ∥ z ∥ + N] (η_{j}) \\ +^{k} I^{α_{1}; φ} [n_{1} ∥ w ∥ + n_{2} ∥ z ∥ + N_{1}] (d))] \\ \leq & \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} [m_{1} ∥ w ∥ + m_{2} ∥ z ∥ + N] \\ + \frac{{(φ (θ) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} (\sum_{i = 1}^{m} | λ_{i} | \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (\bar{α} + k)} [n_{1} ∥ w ∥ + n_{2} ∥ z ∥ + N_{1}] \\ + \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} [m_{1} ∥ w ∥ + m_{2} ∥ z ∥ + N]) \\ + A_{2} (\sum_{j = 1}^{k} | μ_{j} | \frac{φ (η_{j}) - φ (c))^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} [m_{1} ∥ w ∥ + m_{2} ∥ z ∥ + N] \\ + \frac{{(φ (d) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (\bar{α} + k)} [n_{1} ∥ w ∥ + n_{2} ∥ z ∥ + N_{1}])] \\ = & {\frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} + \frac{{(φ (θ) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} \frac{{φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{2} \sum_{j = 1}^{k} | μ_{j} | \frac{{(φ (η_{j}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}]} [m_{1} ∥ w ∥ + m_{2} ∥ z ∥ + N] \\ + {\frac{{(φ (θ) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} \sum_{i = 1}^{m} | λ_{i} | \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{2} \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}]} [n_{1} ∥ w ∥ + n_{2} ∥ z ∥ + N_{1}] \\ = & Q_{1} [m_{1} ∥ w ∥ + m_{2} ∥ z ∥ + N] + Q_{2} [n_{1} ∥ w ∥ + n_{2} ∥ z ∥ + N_{1}] \\ = & (Q_{1} m_{1} + Q_{2} n_{1}) ∥ w ∥ + (Q_{1} m_{2} + Q_{2} n_{2}) ∥ z ∥ + Q_{1} N + Q_{2} N_{1} \\ \leq & (Q_{1} m_{1} + Q_{2} n_{1} + Q_{1} m_{2} + Q_{2} n_{2}) r + Q_{1} N + Q_{2} N_{1} . \end{matrix}

Similarly, we have

\begin{matrix} | T_{2} (w, z) (θ) | & \leq & {\frac{{(φ (θ) - φ (c))}^{\frac{q_{k}}{k} - 1}}{| A | Γ_{k} (q_{k})} [A_{1} \sum_{j = 1}^{k} | μ_{j} | \frac{{(φ (η_{j}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{3} \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}} [m_{1} ∥ w ∥ + m_{2} ∥ z ∥ + N] \\ + {\frac{{(φ (d) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)} + \frac{{(φ (θ) - φ (c))}^{\frac{q_{k}}{k} - 1}}{| A | Γ_{k} (q_{k})} [A_{1} \frac{{(φ (d) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)} \\ + A_{3} \sum_{i = 1}^{m} | λ_{i} | \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)}} [n_{1} ∥ w ∥ + n_{2} ∥ z ∥ + N_{1}] \\ = & Q_{3} (m_{1} ∥ w ∥ + m_{2} ∥ z ∥ + N) + Q_{4} (n_{1} ∥ w ∥ + n_{2} ∥ z ∥ + N_{1}) + \\ = & (Q_{3} m_{1} + Q_{4} n_{1}) ∥ w ∥ + (Q_{3} m_{2} + Q_{4} n_{2}) ∥ z ∥ + Q_{3} N + Q_{4} N_{1} \\ \leq & (Q_{3} m_{1} + Q_{4} n_{1} + Q_{3} m_{2} + Q_{4} n_{2}) r + Q_{3} N + Q_{4} N_{1} . \end{matrix}

Consequently,

\begin{matrix} ∥ T (w, z) ∥ & = & ∥ T_{1} (w, z) ∥ + ∥ T_{2} (w, z) ∥ \\ \leq & [(Q_{1} + Q_{3}) (m_{1} + M_{2}) + (Q_{2} + Q_{4}) (n_{1} + n_{2})] r \\ + (Q_{1} + Q_{3}) N + (Q_{2} + Q_{4}) N_{1} \leq r, \end{matrix}

which implies that

T B_{r} \subset B_{r} .

Now for

(w_{2}, z_{2}), (w_{1}, z_{1}) \in X \times X,

and for any

θ \in [c, d],

we obtain

\begin{matrix} | T_{1} (w_{2}, z_{2}) (θ) - T_{1} (w_{1}, z_{1}) (θ) | \\ \leq & ^{k} I^{\bar{α}; φ} | f (θ, w_{2} (θ), z_{2} (θ)) - f (θ, w_{1} (θ), z_{1} (θ) | \\ + \frac{{(φ (θ) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} (\sum_{i = 1}^{m} | λ_{i} |^{k} I^{α_{1}; φ} | f_{1} (ξ_{i}, w_{2} (ξ_{i}), z_{2} (ξ_{i})) - f_{1} (ξ_{i}, w_{1} (ξ_{i}), z_{1} (ξ_{i}) | \\ +^{k} I^{\bar{α}; φ} | f (d, w_{2} (d), z_{2} (d)) - f (d, w_{1} (d), z_{1} (d) |) \\ + A_{2} (\sum_{j = 1}^{k} | μ_{j} |^{k} I^{\bar{α}; φ} | f (η_{j}, w_{2} (η_{j}), z_{2} (η_{j})) - f (η_{j}, w_{1} (η_{j}), z_{1} (η_{j})) | \\ +^{k} I^{α_{1}; φ} | f_{1} (d, w_{2} (d), z_{2} (d)) - f_{1} (d, w_{1} (d), z_{1} (d) |)] \\ \leq & {\frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} + \frac{{(φ (θ) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{2} \sum_{j = 1}^{k} | μ_{j} | \frac{{(φ (η_{j}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}]} (m_{1} ∥ w_{2} - w_{1} ∥ + m_{2} ∥ z_{2} - z_{1} ∥) \\ + {\frac{{(φ (θ) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} \sum_{i = 1}^{m} | λ_{i} | \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{2} \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}]} (n_{1} ∥ w_{2} - w_{1} ∥ + n_{2} ∥ z_{2} - z_{1} ∥) \\ = & Q_{1} (m_{1} ∥ w_{2} - w_{1} ∥ + m_{2} ∥ z_{2} - z_{1} ∥) + Q_{2} (n_{1} ∥ w_{2} - w_{1} ∥ + n_{2} ∥ z_{2} - z_{1} ∥) \\ = & (Q_{1} m_{1} + Q_{2} n_{1}) ∥ w_{2} - w_{1} ∥ + (Q_{1} m_{2} + Q_{2} n_{2}) ∥ z_{2} - z_{1} ∥, \end{matrix}

and consequently, we obtain

∥ T_{1} (w_{2}, z_{2}) (θ) - T_{1} (w_{1}, z_{1}) ∥ \leq (Q_{1} m_{1} + Q_{2} n_{1} + Q_{1} m_{2} + Q_{2} n_{2}) [∥ w_{2} - w_{1} ∥ + ∥ z_{2} - z_{1} ∥] .

(33)

Similarly,

∥ T_{2} (w_{2}, z_{2}) (θ) - T_{2} (w_{1}, z_{1}) ∥ \leq (Q_{3} m_{1} + Q_{4} n_{1} + Q_{3} m_{2} + Q_{4} n_{2}) [∥ w_{2} - w_{1} ∥ + ∥ z_{2} - z_{1} ∥] .

(34)

It follows from (33) and (34) that

∥ T (w_{2}, z_{2}) (θ) - T (w_{1}, z_{1}) (θ) ∥ \leq [(Q_{1} + Q_{3}) (m_{1} + m_{2}) + (Q_{2} + Q_{4}) (n_{1} + n_{2})] (∥ w_{2} - w_{1} ∥ + ∥ z_{2} - z_{1} ∥) .

Since

(Q_{1} + Q_{3}) (m_{1} + m_{2}) + (Q_{2} + Q_{4}) (n_{1} + n_{2}) < 1,

the operator T is a contraction. By Banach’s contraction mapping principle, a unique solution of the operator T is gained, and this completes the proof. □

3.2. Existence Results

Our first existence results for the nonlocal

(k, φ)

-Hilfer fractional system (3) is based on the Leray–Schauder alternative [25].

Theorem 2.

Assume that

A \neq 0

and

f, f_{1} : [c, d] \times R^{2} \to R

are continuous functions for which there exist real constants

k_{i}, ν_{i} \geq 0 (i = 1, 2)

and

k_{0} > 0, ν_{0} > 0

such that

\forall w_{i} \in R, (i = 1, 2)

. We have

| f (θ, w_{1}, w_{2}) | \leq k_{0} + k_{1} | w_{1} | + k_{2} | w_{2} |,

| f_{1} (θ, w_{1}, w_{2}) | \leq ν_{0} + ν_{1} | w_{1} | + ν_{2} | w_{2} | .

In addition, it is assumed that

(Q_{1} + Q_{3}) k_{1} + (Q_{2} + Q_{4}) ν_{1} < 1 a n d (Q_{1} + Q_{3}) k_{2} + (Q_{2} + Q_{4}) ν_{2} < 1,

where

Q_{i}, i = 1, 2, 3, 4

are given by (28)–(31). Then, there exists at least one solution for the nonlocal

(k, φ)

-Hilfer fractional system (3).

Proof.

Note that the operator T is continuous since f and

f_{1}

are continuous. Next, we will show that the operator T is completely continuous.

For any bounded set

Ω \subset X \times X

, there exist positive constants

L_{1}

and

L_{2}

such that

| f (θ, w (θ), z (θ) | \leq L_{1}, | f_{1} (θ, w (θ), z (θ) | \leq L_{2}, \forall (w, z) \in Ω .

Then, for any

(w, z) \in Ω,

we have

\begin{matrix} | T_{1} (w, z) (θ) | & \leq & {\frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} + \frac{{(φ (d) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{2} \sum_{j = 1}^{k} | μ_{j} | \frac{{(φ (η_{j}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}} L_{1} \\ + {\frac{{(φ (d) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} \sum_{i = 1}^{m} | λ_{i} | \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{2} \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}]} L_{2}, \end{matrix}

which implies that

\begin{matrix} ∥ T_{1} (w, z) ∥ & \leq & Q_{1} L_{1} + Q_{2} L_{2} . \end{matrix}

Similarly, we obtain

\begin{matrix} ∥ T_{2} (w, z) ∥ \leq Q_{3} L_{1} + Q_{4} L_{2} . \end{matrix}

Hence,

∥ T (w, z) ∥ = ∥ T_{1} (w, z) ∥ + ∥ T_{2} (w, z) ∥ \leq (Q_{1} + Q_{3}) L_{1} + (Q_{2} + Q_{4}) L_{2},

which means the uniformly bounded property of the operator T.

The equicontinuity of T is proved now. Let

θ_{1}, θ_{2} \in [c, d]

with

θ_{1} < θ_{2} .

Then, we have

\begin{matrix} | T_{1} (w (θ_{2}), z (θ_{2})) - T_{1} (w (θ_{1}), z (θ_{1})) | \\ \leq & \frac{1}{Γ_{k} (\bar{α})} | \int_{c}^{θ_{1}} φ^{'} (s) [{(φ (θ_{2}) - φ (s))}^{\frac{\bar{α}}{k} - 1} - {(φ (θ_{1}) - φ (s))}^{\frac{\bar{α}}{k} - 1}] f (s, w (s), z (s)) d s \\ + \int_{θ_{1}}^{θ_{2}} φ^{'} (s) {(φ (θ_{2}) - φ (s))}^{\frac{\bar{α} 3}{k} - 1} f (s, w (s), z (s)) d s | \\ + \frac{{(φ (θ_{2}) - φ (c))}^{\frac{θ_{k}}{k} - 1} - {(φ (θ_{1}) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| Λ | Γ_{k} (θ_{k})} [A_{4} (\sum_{i = 1}^{m} | λ_{i} |^{k} I^{α_{1}; φ} | f_{1} (ξ_{i}, w (ξ_{i}), z (ξ_{i})) | \\ +^{k} I^{\bar{α}; φ} | f (d, w (d), z (d)) |) + A_{2} (\sum_{j = 1}^{k} | μ_{j} |^{k} I^{\bar{α}; φ} | f (η_{j}, w (η_{j}), z (η_{j})) | \\ +^{k} I^{α_{1}; φ} | f_{1} (d, w (d), z (d)) |)] \\ \leq & \frac{L_{1}}{Γ_{k} (\bar{α} + k)} [2 {(φ (θ_{2}) - φ (θ_{1}))}^{\frac{\bar{α}}{k}} + | {(φ (θ_{2}) - φ (c))}^{\frac{\bar{α}}{k}} - {(φ (θ_{1}) - φ (c))}^{\frac{\bar{α}}{k}} |] \\ + \frac{{(φ (θ_{2}) - φ (c))}^{\frac{θ_{k}}{k} - 1} - {(φ (θ_{1}) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| Λ | Γ_{k} (θ_{k})} [A_{4} (\sum_{i = 1}^{m} | λ_{i} | \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (\bar{α} + k)} L_{2} \\ + \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} L_{1}) + A_{2} (\sum_{j = 1}^{k} | μ_{j} | \frac{{(φ (η_{j}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} L_{1} + \frac{{(φ (d) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (\bar{α} + k)} L_{2})], \end{matrix}

which is independent of

(w, z)

and tend to zero as

θ_{2} - θ_{1} \to 0 .

Thus,

T_{1} (w, z)

is equicontinuous.

Analogously, we can obtain that

T_{2} (w, z)

is equicontinuous. Consequently the operator

T (w, z)

is completely continuous.

Finally, we will show the boundedness of the set

E = {(w, z) \in X \times X : (w, z) = λ T (w, z), 0 \leq λ \leq 1} .

Let

(w, z) \in E,

then

(w, z) = λ T (w, z) .

For any

θ \in [c, d],

we have

w (θ) = λ T_{1} (w, z) (θ), z (θ) = λ T_{2} (w, z) (θ) .

Then

\begin{matrix} | w (θ) | & \leq & {\frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} + \frac{{(φ (d) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} \frac{{φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{2} \sum_{j = 1}^{k} | μ_{j} | \frac{{(φ (η_{j}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}} (k_{0} + k_{1} ∥ w ∥ + k_{2} ∥ z ∥) \\ + {\frac{{(φ (d) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} \sum_{i = 1}^{m} | λ_{i} | \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{2} \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}]} (ν_{0} + ν_{1} ∥ w ∥ + ν_{2} ∥ z ∥), \end{matrix}

and

\begin{matrix} | z (θ) | & \leq & {\frac{{(φ (d) - φ (c))}^{\frac{q_{k}}{k} - 1}}{| A | Γ_{k} (q_{k})} [A_{1} \sum_{j = 1}^{k} | μ_{j} | \frac{{(φ (η_{j}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{3} \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}} (k_{0} + k_{1} ∥ w ∥ + k_{2} ∥ z ∥) \\ + {\frac{{(φ (d) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)} + \frac{{(φ (d) - φ (c))}^{\frac{q_{k}}{k} - 1}}{| A | Γ_{k} (q_{k})} [A_{1} \frac{{(φ (d) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)} \\ + A_{3} \sum_{i = 1}^{m} | λ_{i} | \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)}} (ν_{0} + ν_{1} ∥ w ∥ + ν_{2} ∥ z ∥) . \end{matrix}

Hence, we have

∥ w ∥ \leq Q_{1} (k_{0} + k_{1} ∥ w ∥ + k_{2} ∥ z ∥) + Q_{2} (ν_{0} + ν_{1} ∥ w ∥ + ν_{2} ∥ z ∥)

and

∥ z ∥ \leq Q_{3} (k_{0} + k_{1} ∥ w ∥ + k_{2} ∥ z ∥) + Q_{4} (ν_{0} + ν_{1} ∥ w ∥ + ν_{2} ∥ z ∥),

which imply that

\begin{matrix} ∥ w ∥ + ∥ z ∥ & \leq & (Q_{1} + Q_{3}) k_{0} + (Q_{2} + Q_{4}) ν_{0} + [(Q_{1} + Q_{3}) k_{1} + (Q_{2} + Q_{4}) ν_{1}] ∥ w ∥ \\ + [(Q_{1} + Q_{3}) k_{2} + (Q_{2} + Q_{4}) ν_{2}] ∥ z ∥ . \end{matrix}

Consequently,

∥ (w, z) ∥ \leq \frac{(Q_{1} + Q_{3}) k_{0} + (Q_{2} + Q_{4}) ν_{0}}{M_{0}},

for any

θ \in [c, d],

where

M_{0}

is defined by

M_{0} = min {1 - [(Q_{1} + Q_{3}) k_{1} + (Q_{2} + Q_{4}) ν_{1}], 1 - [(Q_{1} + Q_{3}) k_{2} + (Q_{2} + Q_{4}) ν_{2}]},

which proves that

E

is bounded. Thus, by the Leray–Schauder alternative, the operator T has at least one fixed point. Hence, we gain at least one solution of the nonlocal

(k, φ)

-Hilfer fractional system (3) on

[a, b] .

The proof is complete. □

The second existence result in this subsection is based on Krasnosel’skiĭ’s fixed-point theorem [26].

Theorem 3.

Let

f, f_{1} : [c, d] \times R \times R \to R

be continuous functions satisfying

(H_{1}) .

In addition, we assume the following:

$(H_{3})$: There exist continuous nonnegative functions P and $Q \in C ([c, d], R^{+})$ such that

$| f (θ, w, z) | \leq P (θ), | f_{1} (θ, w, z) | \leq Q (θ), f o r e a c h (θ, w, z) \in [c, d] \times R \times R .$

Then, the nonlocal

(k, φ)

-Hilfer fractional system (3) has at least one solution on

[c, d],

provided that

[Q_{1}^{*} + Q_{3}] (m_{1} + m_{2}) + [Q_{2} + Q_{4}^{*}] (n_{1} + n_{2}) < 1 .

(35)

Proof.

Let the operator T be decomposed into four operators

T_{1, 1}, T_{1, 2}, T_{2, 1}

and

T_{2, 2}

as

\begin{matrix} T_{1, 1} (w, z) (θ) & = & ^{k} I^{\bar{α}; φ} f (θ, w (θ), z (θ)), \\ T_{1, 2} (w, z) (θ) & = & \frac{{(φ (θ) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{A Γ_{k} (θ_{k})} [A_{4} (\sum_{i = 1}^{m} λ_{i}^{k} I^{α_{1}; φ} f_{1} (ξ_{i}, w (ξ_{i}), z (ξ_{i})) \\ -^{k} I^{\bar{α}; φ} f (d, w (d), z (d))) \\ + A_{2} (\sum_{j = 1}^{k} μ_{j}^{k} I^{\bar{α}; φ} f (η_{j}, w (η_{j}), z (η_{j})) -^{k} I^{α_{1}; φ} f_{1} (d, w (d), z (d)))], \\ T_{2, 1} (w, z) (θ) & = & ^{k} I^{α_{1}; φ} f_{1} (θ, w (θ), z (θ)), \\ T_{2, 2} (w, z) (θ) & = & \frac{{(φ (θ) - φ (c))}^{\frac{q_{k}}{k} - 1}}{A Γ_{k} (q_{k})} [A_{1} (\sum_{j = 1}^{k} μ_{j}^{k} I^{\bar{α}; φ} f (η_{j}, w (η_{j}), z (η_{j})) \\ -^{k} I^{α_{1}; φ} f_{1} (d, w (d), z (d))) \\ + A_{3} (\sum_{i = 1}^{m} λ_{i}^{k} I^{α_{1}; φ} f_{1} (ξ_{i}, w (ξ_{i}), z (ξ_{i})) -^{k} I^{\bar{α}; φ} f (d, w (d), z (d)))] . \end{matrix}

Note that

T_{1} = T_{1, 1} + T_{1, 2}, T_{2} = T_{2, 1} + T_{2, 2}

. Let

B_{ρ} = {(w, z) \in X \times X : ∥ (w, z) ∥ \leq ρ}

be a ball, where

ρ \geq (Q_{1} + Q_{3}) ∥ P ∥ + (Q_{2} + Q_{4}) ∥ Q ∥ .

For any

w = (w_{1}, w_{2}), z = (z_{1}, z_{2}) \in B_{ρ}

we have, as in Theorem 2, that

\begin{matrix} | T_{1, 1} (w_{1}, w_{2}) (θ) + T_{1, 2} (z_{1}, z_{2}) (θ) | \leq Q_{1} ∥ P ∥ + Q_{2} ∥ Q ∥ . \end{matrix}

Similarly, we can find that

\begin{matrix} | T_{2, 1} (w_{1}, w_{2}) (θ) + T_{2, 2} (z_{1}, z_{2}) (θ) | \leq Q_{3} ∥ P ∥ + Q_{4} ∥ Q ∥ . \end{matrix}

Consequently we have

∥ T_{1} w + T_{2} z ∥ \leq (Q_{1} + Q_{3}) ∥ P ∥ + (Q_{2} + Q_{4}) ∥ ∥ Q ∥ < ρ .

This yields

T_{1} w + T_{2} z \in B_{ρ} .

To show that the operator

(T_{1, 2}, T_{2, 2})

is a contraction mapping, for

(w_{1}, w_{2}),

(z_{1}, z_{2}) \in B_{ρ},

we have, as in Theorem 1, that

\begin{matrix} | T_{1, 2} (x_{2}, y_{2}) (θ) - T_{1, 2} (x_{1}, y_{1}) (θ) | \\ \leq & {\frac{{(φ (d) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{2} \sum_{j = 1}^{k} | μ_{j} | \frac{{(φ (η_{j}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}]} (m_{1} ∥ w_{2} - w_{1} ∥ + m_{2} ∥ z_{2} - z_{1} ∥) \\ + {\frac{{(φ (d) - φ (c))}^{\frac{θ_{k}}{k} - 1}}{| A | Γ_{k} (θ_{k})} [A_{4} \sum_{i = 1}^{m} | λ_{i} | \frac{{(φ (ξ_{i}) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} \\ + A_{2} \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)}]} (n_{1} ∥ w_{2} - w_{1} ∥ + n_{2} ∥ z_{2} - z_{1} ∥) \\ = & Q_{1}^{*} (m_{1} ∥ w_{2} - w_{1} ∥ + m_{2} ∥ z_{2} - z_{1} ∥) + Q_{2} (n_{1} ∥ w_{2} - w_{1} ∥ + n_{2} ∥ z_{2} - z_{1} ∥) \\ = & [Q_{1}^{*} m_{1} + Q_{2} n_{1}] ∥ w_{2} - w_{1} ∥ + [Q_{1}^{*} m_{2} + Q_{2} n_{2}] ∥ z_{2} - z_{1} ∥, \end{matrix}

(36)

and

\begin{matrix} | T_{2, 2} (w_{1}, z_{1}) (θ) - T_{2, 2} (w_{2}, z_{2}) (θ) | \\ \leq & [(Q_{3} m_{1} + Q_{4}^{*} n_{1}] ∥ w_{2} - w_{1} ∥ + [Q_{3} m_{2} + Q_{4}^{*} n_{2}] ∥ z_{2} - z_{1} ∥] . \end{matrix}

(37)

It follows form (36) and (37) that

\begin{matrix} ∥ (T_{1, 2}, T_{2, 2}) (w_{1}, z_{1}) - (T_{1, 2}, T_{2, 2}) (w_{2}, z_{2}) ∥ \\ \leq & \{[Q_{1}^{*} + Q_{3}] (m_{1} + m_{2}) + [Q_{2} + Q_{4}^{*}] (n_{1} + n_{2})\} (∥ w_{1} - w_{2} ∥ + ∥ z_{1} - z_{2} ∥), \end{matrix}

which is a contraction by inequality (35).

The operator

(T_{1, 1}, T_{2, 1})

is continuous by the continuity of

f, f_{1} .

Additionally,

(T_{1, 1}, T_{2, 1})

is uniformly bounded on

B_{ρ}

since

∥ T_{1, 1} (w, z) ∥ \leq \frac{{(φ (d) - φ (c))}^{\frac{\bar{α}}{k}}}{Γ_{k} (\bar{α} + k)} ∥ P ∥ a n d ∥ T_{2, 1} (w, z) ∥ \leq \frac{{(φ (d) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)} ∥ Q ∥ .

Then we obtain the following fact:

∥ (T_{1, 1}, T_{2, 1}) (w, z) ∥ \leq \frac{{(φ (d) - φ (c))}^{\frac{φ}{k}}}{Γ_{k} (φ + k)} ∥ P ∥ + \frac{{(φ (d) - φ (c))}^{\frac{α_{1}}{k}}}{Γ_{k} (α_{1} + k)} ∥ Q ∥,

which implies that the set

(T_{1, 1}, T_{2, 1}) B_{ρ}

is uniformly bounded. In the next step, we show that the set

(T_{1, 1}, T_{2, 1}) B_{ρ}

is equicontinuous. For

θ_{1}, θ_{2} \in [c, d], θ_{1} < θ_{2},

and for any

(w, z) \in B_{ρ}

, we can prove that

\begin{matrix} | T_{1, 1} (w, z) (θ_{2}) - T_{1, 1} (w, z) (θ_{1}) | \\ \leq & \frac{1}{Γ_{k} (\bar{α})} | \int_{c}^{θ_{1}} φ^{'} (s) [{(φ (θ_{2}) - φ (s))}^{\frac{\bar{α}}{k} - 1} - {(φ (θ_{1}) - φ (s))}^{\frac{\bar{α}}{k} - 1}] f (s, w (s), z (s)) d s \\ + \int_{θ_{1}}^{θ_{2}} φ^{'} (s) {(φ (θ_{2}) - φ (s))}^{\frac{α}{k} - 1} f (s, w (s), z (s)) d s | \\ \leq & \frac{∥ P ∥}{Γ_{k} (\bar{α} + k)} [2 {(φ (θ_{2}) - φ (θ_{1}))}^{\frac{\bar{α}}{k}} + | {(φ (θ_{2}) - φ (c))}^{\frac{\bar{α}}{k}} - {(φ (θ_{1}) - φ (c))}^{\frac{\bar{α}}{k}} |], \end{matrix}

which tends to zero, as

θ_{1} \to θ_{2}

independently of

(w, z) \in B_{ρ} .

Similarly, we can show that

| T_{2, 1} (w, z) (θ_{2}) - T_{2, 1} (w, z) (θ_{1}) | \to 0

as

θ_{1} \to θ_{2}

independently of

(w, z) \in B_{ρ} .

Thus,

| (T_{1, 1}, T_{2, 1}) (w, z) (θ_{2}) - (T_{1, 1}, T_{2, 1}) (w, z) (θ_{1}) |

tends to zero, as

θ_{1} \to θ_{2} .

Therefore,

(T_{1, 1}, T_{2, 1})

is equicontinuous. From the Arzelá–Ascoli theorem, we conclude that the operator

(T a_{1, 1}, T_{2, 1})

is compact on

B_{ρ} .

Thus, the hypotheses of Krasnosel’skiĭ’s fixed-point theorem are satisfied, and therefore, there exists at least one solution on

[c, d] .

The proof is finished. □

4. Illustrative Examples

Now, we give some examples to show the benefits of our results.

Example 1.

Consider the following nonlocal coupled system for

(k, φ)

-Hilfer fractional differential equations of the form

\{\begin{matrix} ^{\frac{7}{4}, H} D^{\frac{3}{2}, \frac{1}{4}; θ^{5} e^{- θ}} w (θ) = f (θ, w (θ), z (θ)), θ \in (\frac{1}{7}, \frac{10}{7}], \\ ^{\frac{7}{4}, H} D^{\frac{5}{3}, \frac{3}{4}; θ^{5} e^{- θ}} z (θ) = f_{1} (θ, w (θ), z (θ)), θ \in (\frac{1}{7}, \frac{10}{7}], \\ w (\frac{1}{7}) = 0, w (\frac{10}{7}) = \frac{1}{22} z (\frac{3}{7}) + \frac{3}{44} z (\frac{5}{7}) + \frac{5}{66} z (\frac{9}{7}), \\ z (\frac{1}{7}) = 0, z (\frac{10}{7}) = \frac{2}{33} w (\frac{2}{7}) + \frac{4}{55} w (\frac{4}{7}) + \frac{6}{77} w (\frac{6}{7}) + \frac{8}{99} w (\frac{8}{7}) . \end{matrix}

(38)

Here, we set

k = 7 / 4

,

\bar{α} = 3 / 2

,

\bar{β} = 1 / 4

,

α_{1} = 5 / 3

,

β_{1} = 3 / 4

,

φ (θ) = θ^{5} e^{- θ}

,

c = 1 / 7

,

d = 10 / 7

,

m = 3

,

λ_{1} = 1 / 22

,

λ_{2} = 3 / 44

,

λ_{3} = 5 / 66

,

ξ_{1} = 3 / 7

,

ξ_{2} = 5 / 7

,

ξ_{3} = 9 / 7

,

k = 4

,

μ_{1} = 2 / 33

,

μ_{2} = 4 / 55

,

μ_{3} = 6 / 77

,

μ_{4} = 8 / 99

,

η_{1} = 2 / 7

,

η_{2} = 4 / 7

,

η_{3} = 6 / 7

,

η_{4} = 8 / 7

. Then we can compute that

θ_{\frac{7}{4}} = 2

,

q_{\frac{7}{4}} = 73 / 24

,

Γ_{\frac{7}{4}} (θ_{\frac{7}{4}}) \approx 1.013291796

,

Γ_{\frac{7}{4}} (q_{\frac{7}{4}}) \approx 1.385078519

,

A_{1} \approx 1.038187892

,

A_{2} \approx 0.06296417348

,

A_{3} \approx 0.2031397681

,

A_{4} \approx 0.9380941984

,

A \approx 0.9611275107

,

Γ_{\frac{7}{4}} (\bar{α} + 7 / 4) \approx 1.531211531

,

Γ_{\frac{7}{4}} (α_{1} + 7 / 4) \approx 1.671252637

,

Q_{1} \approx 1.785558660

,

Q_{2} \approx 0.1062650045

,

Q_{3} \approx 0.2266775746

,

Q_{4} \approx 1.698531866

,

Q_{1}^{*} \approx 0.9003865435

,

Q_{4}^{*} \approx 0.8596622443

.

(i) Consider the nonlinear unbounded functions

f, f_{1} : [(1 / 7), (10 / 7)] \times R^{2} ⟶ R

presented as

\begin{matrix} f (θ, w, z) & = & \frac{e^{- {(7 θ - 1)}^{2}}}{12} (\frac{w^{2} + 2 | w |}{1 + | w |}) + \frac{1}{7 (θ + 1)} sin | z | + \frac{1}{2} θ + \frac{2}{3}, \end{matrix}

(39)

\begin{matrix} f_{1} (θ, w, z) & = & \frac{{cos}^{2} π θ}{10} {tan}^{- 1} | w | + \frac{1}{8 {(7 θ + 1)}^{2}} (\frac{3 z^{2} + 4 | z |}{1 + | z |}) + \frac{1}{4} θ + \frac{1}{5} . \end{matrix}

(40)

Then we can find that

| f (θ, w_{1}, z_{1}) - f (θ, w_{2}, z_{2}) | \leq \frac{1}{6} | w_{1} - w_{2} | + \frac{1}{8} | z_{1} - z_{2} |

and

| f_{1} (θ, w_{1}, z_{1}) - f_{1} (θ, w_{2}, z_{2}) | \leq \frac{1}{10} | w_{1} - w_{2} | + \frac{1}{8} | z_{1} - z_{2} |,

for all

w_{1}, w_{2}, z_{1}, z_{2} \in R

. By choosing

m_{1} = 1 / 6

,

m_{2} = 1 / 8

,

n_{1} = 1 / 10

and

n_{2} = 1 / 8

, we obtain

(Q_{1} + Q_{3}) (m_{1} + m_{2}) + (Q_{2} + Q_{4}) (n_{1} + n_{2}) \approx 0.9929815310 < 1

. By Theorem 1, we conclude that the nonlocal coupled system for

(k, φ)

-Hilfer fractional differential Equation (38) with

f, f_{1}

defined by (39) and (40) respectively, has a unique solution on

[(1 / 7), (10 / 7)]

.

(ii) Let the nonlinear bounded functions

f, f_{1} : [(1 / 7), (10 / 7)] \times R^{2} ⟶ R

be given by

\begin{matrix} f (θ, w, z) & = & \frac{1}{k} {sin}^{4} π θ (\frac{| w |}{1 + | w |}) + \frac{1}{7 θ + 2} {tan}^{- 1} | z | + \frac{1}{4}, \end{matrix}

(41)

\begin{matrix} f_{1} (θ, w, z) & = & \frac{1}{6} sin | w | e^{- {(7 θ - 1)}^{4}} + \frac{1}{{(7 θ + 1)}^{2}} (\frac{| z |}{1 + | z |}) + \frac{1}{5} . \end{matrix}

(42)

Note that

f, f_{1}

are bounded by

| f (θ, w, z) | \leq \frac{1}{k} {sin}^{4} π θ + \frac{π}{2 (7 θ + 2)} + \frac{1}{4}, | f_{1} (θ, w, z) | \leq \frac{1}{6} e^{- {(7 θ - 1)}^{4}} + \frac{1}{{(7 θ + 1)}^{2}} + \frac{1}{5} .

In addition, functions

f, f_{1}

satisfy

| f (θ, w_{1}, z_{1}) - f (θ, w_{2}, z_{2}) | \leq \frac{1}{k} | w_{1} - w_{2} | + \frac{1}{3} | z_{1} - z_{2} |

and

| f_{1} (θ, w_{1}, z_{1}) - f_{1} (θ, w_{2}, z_{2}) | \leq \frac{1}{6} | w_{1} - w_{2} | + \frac{1}{4} | z_{1} - z_{2} | .

By setting

m_{1} = 1 / k

,

m_{2} = 1 / 3

,

n_{1} = 1 / 6

and

n_{2} = 1 / 4

and from

(Q_{1} + Q_{3}) (1 / 3) + (Q_{2} + Q_{4}) ((1 / 6) + (1 / 4)) \approx 1.422744108

, we get

(Q_{1} + Q_{3}) ((1 / k) + (1 / 3)) + (Q_{2} + Q_{4}) ((1 / 6) + (1 / 4)) > 1

, for all

k \in R^{+}

, which means that we cannot obtain the uniqueness result to this problem by applying Theorem 1. However, if

k > 5.080474967

, then we have

[Q_{1}^{*} + Q_{3}] (m_{1} + m_{2}) + [Q_{2} + Q_{4}^{*}] (n_{1} + n_{2}) < 1

. Therefore, using the conclusion of Theorem 3, the nonlocal coupled system for

(k, φ)

-Hilfer fractional differential Equation (38) with

f, f_{1}

defined by (41) and (42) respectively, has at least one solution on

[(1 / 7), (10 / 7)]

.

(iii) Assume that the nonlinear functions

f, f_{1} : [(1 / 7), (10 / 7)] \times R^{2} ⟶ R

are expressed by

\begin{matrix} f (θ, w, z) & = & \frac{1}{7 t + 1} + \frac{1}{4} e^{- z^{2}} (\frac{{| w |}^{181}}{1 + w^{180}}) + \frac{z}{6} {sin}^{4} w, \end{matrix}

(43)

\begin{matrix} f_{1} (θ, w, z) & = & \frac{1}{14 t + 1} + \frac{2}{5 π} w {tan}^{- 1} | z | + \frac{z^{150}}{3 (1 + | z |^{149})} {cos}^{6} w . \end{matrix}

(44)

Next, we can compute the linear bounded of two above functions as

| f (θ, w, z) | \leq \frac{1}{2} + \frac{1}{4} | w | + \frac{1}{6} | z | and | f_{1} (θ, w, z) | \leq \frac{1}{3} + \frac{1}{5} | w | + \frac{1}{3} | z | .

Then, choosing

k_{0} = 1 / 2

,

k_{1} = 1 / 4

,

k_{2} = 1 / 6

,

ν_{0} = 1 / 3

,

ν_{1} = 1 / 5

,

ν_{2} = 1 / 3

, we have

(Q_{1} + Q_{3}) k_{1} + (Q_{2} + Q_{4}) ν_{1} \approx 0.8640184328 < 1

and

(Q_{1} + Q_{3}) k_{2} + (Q_{2} + Q_{4}) ν_{2} \approx 0.9369716625 < 1

. Therefore, by Theorem 2, the nonlocal coupled system for

(k, φ)

-Hilfer fractional differential Equation (38) with

f, f_{1}

defined by (43) and (44), respectively, has at least one solution on

[(1 / 7), (10 / 7)]

.

5. Conclusions

In this paper, we presented the existence and uniqueness criteria for the solutions of a system of

(k, φ)

-Hilfer fractional differential equation complemented with nonlocal multi-point boundary conditions. The given nonlinear problem was converted into a fixed-point problem via an auxiliary lemma concerning a linear variant of the problem. Then we first proved the existence of a unique solution via Banach contraction mapping principle, and next we established two existence results by applying the Leray–Schauder alternative and Krasnosel’skiĭ’s fixed-point theorem. Numerical examples were constructed to illustrate the obtained results. Our results are new in the given configuration and enrich the literature on coupled systems for

(k, φ)

-Hilfer fractional differential equations of the order

(1, 2] .

Author Contributions

Conceptualization, A.S., S.K.N. and J.T.; methodology, A.S., S.K.N. and J.T.; validation, A.S., S.K.N. and J.T.; formal analysis, A.S., S.K.N. and J.T.; writing—original draft preparation, A.S., S.K.N. and J.T.; funding acquisition, J.T. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by National Science, Research and Innovation Fund (NSRF), and King Mongkut’s University of Technology North Bangkok with Contract no. KMUTNB-FF-65-36.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

References

Diethelm, K. The Analysis of Fractional Differential Equations; Lecture Notes in Mathematics; Springer: New York, NY, USA, 2010. [Google Scholar]
Kilbas, A.A.; Srivastava, H.M.; Trujillo, J.J. Theory and Applications of the Fractional Differential Equations; North-Holland Mathematics Studies; Elsevier: Amsterdam, The Netherlands, 2006; Volume 204. [Google Scholar]
Lakshmikantham, V.; Leela, S.; Devi, J.V. Theory of Fractional Dynamic Systems; Cambridge Scientific Publishers: Cambridge, UK, 2009. [Google Scholar]
Miller, K.S.; Ross, B. An Introduction to the Fractional Calculus and Differential Equations; John Wiley: New York, NY, USA, 1993. [Google Scholar]
Podlubny, I. Fractional Differential Equations; Academic Press: New York, NY, USA, 1999. [Google Scholar]
Samko, S.G.; Kilbas, A.A.; Marichev, O.I. Fractional Integrals and Derivatives; Gordon and Breach Science: Yverdon, Switzerland, 1993. [Google Scholar]
Ahmad, B.; Alsaedi, A.; Ntouyas, S.K.; Tariboon, J. Hadamard-Type Fractional Differential Equations, Inclusions and Inequalities; Springer: Cham, Switzerland, 2017. [Google Scholar]
Ahmad, B.; Ntouyas, S.K. Nonlocal Nonlinear Fractional-Order Boundary Value Problems; World Scientific: Singapore, 2021. [Google Scholar]
Zhou, Y. Basic Theory of Fractional Differential Equations; World Scientific: Singapore, 2014. [Google Scholar]
Mubeen, S.; Habibullah, G.M. k–fractional integrals and applications. Int. J. Contemp. Math. Sci. 2012, 7, 89–94. [Google Scholar]
Dorrego, G.A. An alternative definition for the k-Riemann-Liouville fractional derivative. Appl. Math. Sci. 2015, 9, 481–491. [Google Scholar] [CrossRef] [Green Version]
Mittal, E.; Joshi, S. Note on k-generalized fractional derivative. Discrete Contin. Dyn. Syst. 2020, 13, 797–804. [Google Scholar]
Magar, S.K.; Dole, P.V.; Ghadle, K.P. Pranhakar and Hilfer-Prabhakar fractional derivatives in the setting of ψ-fractional calculus and its applications. Krak. J. Math. 2024, 48, 515–533. [Google Scholar]
Agarwal, P.; Tariboon, J.; Ntouyas, S.K. Some generalized Riemann-Liouville k-fractional integral inequalities. J. Ineq. Appl. 2016, 2016, 122. [Google Scholar] [CrossRef] [Green Version]
Farid, G.; Javed, A.; Rehman, A.U. On Hadamard inequalities for n-times differentiable functions which are relative convex via Caputo k-fractional derivatives. Nonlinear Anal. Forum 2017, 22, 17–28. [Google Scholar]
Azam, M.K.; Farid, G.; Rehman, M.A. Study of generalized type k-fractional derivatives. Adv. Differ. Equ. 2017, 2017, 249. [Google Scholar] [CrossRef]
Romero, L.G.; Luque, L.L.; Dorrego, G.A.; Cerutti, R.A. On the k-Riemann-Liouville fractional derivative. Int. J. Contemp. Math. Sci. 2013, 8, 41–51. [Google Scholar] [CrossRef]
Sousa, J.V.d.; de Oliveira, E.C. On the ψ-Hilfer fractional derivative. Commun. Nonlinear Sci. Numer. Simul. 2018, 60, 72–91. [Google Scholar] [CrossRef]
Kwun, Y.C.; Farid, G.; Nazeer, W.; Ullah, S.; Kang, S.M. Generalized Riemann-Liouville k-fractional integrals associated with Ostrowski type inequalities and error bounds of Hadamard inequalities. IEEE Access 2018, 6, 64946–64953. [Google Scholar] [CrossRef]
Kucche, K.D.; Mali, A.D. On the nonlinear (k,ψ)-Hilfer fractional differential equations. Chaos Solitons Fractals 2021, 152, 111335. [Google Scholar] [CrossRef]
Tariboon, J.; Samadi, A.; Ntouyas, S.K. Multi-point boundary value problems for (k,ϕ)-Hilfer fractional differential equations and inclusions. Axioms 2022, 11, 110. [Google Scholar] [CrossRef]
Diaz, R.; Pariguan, E. On hypergeometric functions and Pochhammer k-symbol. Divulg. Mat. 2007, 2, 179–192. [Google Scholar]
Almeida, R. A Caputo fractional derivative of a function with respect to another function. Commun. Nonlinear Sci. Numer. Simul. 2017, 44, 460–481. [Google Scholar] [CrossRef] [Green Version]
Deimling, K. Nonlinear Functional Analysis; Springer: New York, NY, USA, 1985. [Google Scholar]
Granas, A.; Dugundji, J. Fixed Point Theory; Springer: New York, NY, USA, 2005. [Google Scholar]
Krasnosel’skiĭ, M.A. Two remarks on the method of successive approximations. Uspekhi Mat. Nauk 1955, 10, 123–127. [Google Scholar]

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

© 2022 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

Samadi, A.; Ntouyas, S.K.; Tariboon, J. Nonlocal Coupled System for (k,φ)-Hilfer Fractional Differential Equations. Fractal Fract. 2022, 6, 234. https://doi.org/10.3390/fractalfract6050234

AMA Style

Samadi A, Ntouyas SK, Tariboon J. Nonlocal Coupled System for (k,φ)-Hilfer Fractional Differential Equations. Fractal and Fractional. 2022; 6(5):234. https://doi.org/10.3390/fractalfract6050234

Chicago/Turabian Style

Samadi, Ayub, Sotiris K. Ntouyas, and Jessada Tariboon. 2022. "Nonlocal Coupled System for (k,φ)-Hilfer Fractional Differential Equations" Fractal and Fractional 6, no. 5: 234. https://doi.org/10.3390/fractalfract6050234

Article Menu

Nonlocal Coupled System for (k,φ)-Hilfer Fractional Differential Equations

Abstract

1. Introduction

2. Preliminaries

3. Existence and Uniqueness Results

3.1. Existence of a Unique Solution

3.2. Existence Results

4. Illustrative Examples

5. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Conflicts of Interest

References

Share and Cite

Article Metrics

Article Access Statistics

Further Information

Guidelines

MDPI Initiatives

Follow MDPI