On the Uniqueness of the Bounded Solution for the Fractional Nonlinear Partial Integro-Differential Equation with Approximations

Li, Chenkuan; Saadati, Reza; Beaudin, Joshua; Hrytsenko, Andrii

doi:10.3390/math11122752

Open AccessArticle

On the Uniqueness of the Bounded Solution for the Fractional Nonlinear Partial Integro-Differential Equation with Approximations

¹

Department of Mathematics and Computer Science, Brandon University, Brandon, MB R7A 6A9, Canada

²

School of Mathematics, Iran University of Science and Technology, Narmak, Tehran 13114-16846, Iran

^*

Author to whom correspondence should be addressed.

Mathematics 2023, 11(12), 2752; https://doi.org/10.3390/math11122752

Submission received: 19 May 2023 / Revised: 6 June 2023 / Accepted: 15 June 2023 / Published: 17 June 2023

(This article belongs to the Special Issue Fractional Calculus and Mathematical Applications)

Download Versions Notes

Abstract

:

This paper studies the uniqueness of the bounded solution to a new Cauchy problem of the fractional nonlinear partial integro-differential equation based on the multivariate Mittag–Leffler function as well as Banach’s contractive principle in a complete function space. Applying Babenko’s approach, we convert the fractional nonlinear equation with variable coefficients to an implicit integral equation, which is a powerful method of studying the uniqueness of solutions. Furthermore, we construct algorithms for finding analytic and approximate solutions using Adomian’s decomposition method and recurrence relation with the order convergence analysis. Finally, an illustrative example is presented to demonstrate constructions for the numerical solution using MATHEMATICA.

Keywords:

adomian’s decomposition method; banach’s contractive principle; multivariate Mittag–Leffler function; babenko’s approach; analytic and approximate solution

MSC:

35A02; 35C10; 35C15; 26A33

1. Introduction and Preliminaries

The operator

I_{θ}^{β}

is the partial Riemann–Liouville fractional integral of order

β > 0

with respect to

θ

with the initial point zero [1],

(I_{θ}^{β} W) (θ, σ) = \frac{1}{Γ (β)} \int_{0}^{θ} {(θ - ζ)}^{β - 1} W (ζ, σ) d ζ, θ > 0,

and

\frac{_{c} \partial^{α}}{\partial θ^{α}}

is the partial Caputo fractional derivative of order

α

with respect to

θ

(\frac{_{c} \partial^{α}}{\partial θ^{α}} W) (θ, σ) = \frac{1}{Γ (1 - α)} \int_{0}^{θ} {(θ - s)}^{- α} W_{s}^{^{'}} (s, σ) d s, 0 < α \leq 1 .

It follows from [2] that, for

0 < α \leq 1

,

\begin{matrix} I_{θ}^{α} (\frac{_{c} \partial^{α}}{\partial θ^{α}} W) (θ, σ) & = W (θ, σ) - W (0, σ) . \end{matrix}

We define the Banach space

C ([0, 1] \times [0, b])

with the norm for

b > 0

as

∥W∥ = sup_{θ \in [0, 1], σ \in [0, b]} | W (θ, σ) | for W \in C ([0, 1] \times [0, b]) .

In this work, we consider the uniqueness of the bounded solution to the following fractional nonlinear partial integro-differential equation with the initial condition in the Caputo sense for

0 < α_{2} < α_{1} \leq 1

in the space

C ([0, 1] \times [0, b])

:

\{\begin{matrix} \frac{_{c} \partial^{α_{1}}}{\partial θ^{α_{1}}} W (θ, σ) + C \frac{_{c} \partial^{α_{2}}}{\partial θ^{α_{2}}} W (θ, σ) + \sum_{i = 1}^{m} λ_{i} (σ) I_{θ}^{γ_{i}} I_{σ}^{β_{i}} W (θ, σ) \\ = f (θ, σ) + g (W (θ, σ)), \\ W (0, σ) = ϕ (σ), (θ, σ) \in [0, 1] \times [0, b], \end{matrix}

(1)

where

λ_{i} (σ), f (θ, σ), g, ϕ (σ)

are functions satisfying certain conditions and C is a constant. In addition, we avoid computational difficulties in the series and construct the algorithm used to find analytic and approximate solutions to (1) using Adomian’s decomposition method. To the best of the authors’ knowledge, Equation (1) is new and has never been studied before. Furthermore, any existing integral transform seems hard to deal with using this equation due to the variable coefficients and double integral operators involved.

A function W is said to be a solution of Equation (1) if it satisfies the equation over

C ([0, 1] \times [0, b])

and its initial condition.

Definition 1.

The two-parameter Mittag–Leffler function is represented by the following series

E_{ς, ε} (z) = \sum_{l = 0}^{\infty} \frac{z^{l}}{Γ (ς l + ε)},

where

ς, ε > 0

and

z \in C

(the complex plane).

The multivariate Mittag–Leffler function [3] is defined as follows

\begin{matrix} E_{(ς_{1}, \dots, ς_{m}), ε} (z_{1}, \dots, z_{m}) = \sum_{l = 0}^{\infty} \sum_{\begin{matrix} l_{1} + \dots + l_{m} = l \\ l_{1} \geq 0, \dots, l_{m} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m}}) \frac{z_{1}^{l_{1}} \dots z_{m}^{l_{m}}}{Γ (ς_{1} l_{1} + \dots + ς_{m} l_{m} + ε)}, \end{matrix}

where

ς_{i}, ε > 0, z_{i} \in C

for

i = 1, 2, \dots, m

and

(\binom{l}{l_{1}, \dots, l_{m}}) = \frac{l!}{l_{1}! \dots l_{m}!} .

Babenko’s approach [4] is an efficient tool used to solve differential equations (including partial differential equations) with initial conditions or boundary value problems, as well as integral equations [5,6]. In the following, to show the details of this technique, we will deduce the solution to the following fractional integro-differential equation with the initial condition in the space

C [0, b]

for a constant

λ

:

\begin{matrix} \{\begin{matrix} _{c} D_{0}^{α} y (x) + λ I_{0}^{β} y (x) = F (x), F \in C [0, b], 0 < α \leq 1, β > 0, \\ y (0) = 0, \end{matrix} \end{matrix}

where

_{c} D_{0}^{α} y (x) = \frac{1}{Γ (1 - α)} \int_{0}^{x} {(x - s)}^{- α} y^{'} (s) d s,

and

I_{0}^{β} y (x) = \frac{1}{Γ (β)} \int_{0}^{x} {(x - s)}^{β - 1} y (s) d s .

Clearly,

I_{0}^{α} (_{c} D_{0}^{α} y (x)) = y (x) - y (0) = y (x) .

Applying the operator

I_{0}^{α}

to both sides of equation, we obtain

(1 + λ I_{0}^{α + β}) y (x) = I_{0}^{α} F (x) .

Treating the operator

(1 + λ I_{0}^{α + β})

as a variable, we informally derive that, using Babenko’s approach

\begin{matrix} y (x) & = {(1 + λ I_{0}^{α + β})}^{- 1} I_{0}^{α} F (x) = \sum_{l = 0}^{\infty} {(- 1)}^{l} {(λ I_{0}^{α + β})}^{l} I_{0}^{α} F (x) \\ = \sum_{l = 0}^{\infty} {(- 1)}^{l} λ^{l} I_{0}^{l (α + β)} I_{0}^{α} F (x) = \sum_{l = 0}^{\infty} {(- 1)}^{l} λ^{l} I_{0}^{l (α + β) + α} F (x) . \end{matrix}

Obviously,

\begin{matrix} ∥I_{0}^{l (α + β) + α}∥ = sup_{x \in [0, b], ∥ϕ∥ \leq 1} |I_{0}^{l (α + β) + α} ϕ| \\ = sup_{x \in [0, b], ∥ϕ∥ \leq 1} \frac{1}{Γ (l (α + β) + α)} |\int_{0}^{x} {(x - s)}^{l (α + β) + α - 1} ϕ (s)| d s \\ \leq sup_{x \in [0, b], ∥ϕ∥ \leq 1} ∥ϕ∥ \frac{x^{l (α + β) + α}}{Γ (l (α + β) + α + 1)} \\ \leq \frac{b^{l (α + β) + α}}{Γ (l (α + β) + α + 1)}, \end{matrix}

due to the fact that

Γ (l (α + β) + α + 1) = Γ (l (α + β) + α) (l (α + β) + α) .

These imply that

\begin{matrix} ∥y∥ & \leq \sum_{l = 0}^{\infty} {| λ |}^{l} ∥I_{0}^{l (α + β) + α}∥ ∥F∥ \leq b^{α} ∥F∥ \sum_{l = 0}^{\infty} \frac{{(| λ | b^{α + β})}^{l}}{Γ (l (α + β) + α + 1)} \\ = b^{α} ∥F∥ E_{α + β, α + 1} (| λ | b^{α + β}) < + \infty, \end{matrix}

which infers that the series solution

y (x) = \sum_{l = 0}^{\infty} {(- 1)}^{l} λ^{l} I_{0}^{l (α + β) + α} F (x),

is uniformly convergent in

C [0, b]

, and thus well defined.

In particular, for

F (x) = x

,

y (x) = x^{α + 1} \sum_{l = 0}^{\infty} {(- 1)}^{l} λ^{l} \frac{x^{l (α + β)}}{Γ (l (α + β) + α + 2)} .

Nonlinear partial differential equations have been used to describe a wide range of phenomena and dynamical processes in many scientific areas, such as physics, fluid mechanics, geophysics, plasma physics and optical fibres [7]. Atangana [8] introduced new fractal–fractional differential and integral operators to work on more non-local problems using analytic and numerical methods. Researchers have made a great deal of effort to find approximate, stable numerical and analytical methods to solve fractional partial differential equations of physical interest, which include the finite difference method [9], Adomian’s decomposition method [10], variational iteration method [11], and homotopy perturbation method [12]. On the other hand, the uniqueness and existence of solutions are among the most important and interesting topics for fractional nonlinear partial differential or integral equations with initial value or boundary conditions [13]. Very recently, Li et al. [6] applied Babenko’s approach, the multivariate Mittag–Leffler function, and Krasnoselskii’s fixed point theorem, and investigated the existence of solutions to a Liouville–Caputo nonlinear integro-differential equations with variable coefficients and initial conditions in a Banach space.

The rest of this paper is organized as follows. Section 2 deals with the uniqueness of the bounded solution to Equation (1) using the multivariate Mittag–Leffler function and Banach’s contractive principle. Section 3 finds the recurrence algorithms for analytic and approximate solutions based on Adomian’s decomposition method with an order analysis. We further demonstrate the applications of the main results with an example in Section 4. In Section 5, we provide a summary of the work.

2. Uniqueness of Bounded Solution

Theorem 1.

Let

ϕ (σ), λ_{i} (σ) \in C [0, b]

for all

i = 1, 2, \dots, m

,

f (θ, σ) \in C ([0, 1] \times [0, b])

and g be a continuous and bounded function on

R

(the set of all real numbers). In addition, we assume that

0 < α_{2} < α_{1} \leq 1, γ_{i}, β_{i} \geq 0

for all

i = 1, 2, \dots, m

and C is a constant in R. Then

W (θ, σ)

is a solution of Equation (1) if and only if it is bounded and satisfies the following implicit integral equation in the space

C ([0, 1] \times [0, b])

:

\begin{matrix} W (θ, σ) \\ = \sum_{l = 0}^{\infty} {(- 1)}^{l} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) C^{l_{m + 1}} I_{θ}^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m} (α_{1} + γ_{m}) + l_{m + 1} (α_{1} - α_{2}) + α_{1}} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} f (θ, σ) \\ + \sum_{l = 0}^{\infty} {(- 1)}^{l} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) C^{l_{m + 1}} I_{θ}^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1}} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} g (W (θ, σ)) + \sum_{l = 0}^{\infty} {(- 1)}^{l} \\ \cdot \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) \frac{C^{l_{m + 1}} θ^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2})}}{Γ (l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + 1)} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} ϕ (σ) + C \sum_{l = 0}^{\infty} {(- 1)}^{l} \\ \cdot \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) \frac{C^{l_{m + 1}} θ^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1} - α_{2}}}{Γ (l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1} - α_{2} + 1)} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} . \end{matrix}

(2)

furthermore,

\begin{matrix} ∥W∥ \leq & 2 E_{(α_{1} + γ_{1}, \dots, α_{1} + γ_{m}, α_{1} - α_{2}), α_{1} + 1} (B b^{β_{1}}, \dots, B b^{β_{m}}, | C |) \\ \cdot (max_{(θ, σ) \in [0, 1] \times [0, b]} | f (θ, σ) | + sup_{x \in R} | g (x) |) \\ + 2 E_{(α_{1} + γ_{1}, \dots, α_{1} + γ_{m}, α_{1} - α_{2}), 1} (B b^{β_{1}}, \dots, B b^{β_{m}}, | C |) max_{σ \in [0, b]} | ϕ (σ) | \\ + 2 E_{(α_{1} + γ_{1}, \dots, α_{1} + γ_{m}, α_{1} - α_{2}), α_{1} - α_{2} + 1} (B b^{β_{1}}, \dots, B b^{β_{m}}, | C |) < + \infty, \end{matrix}

where B is a positive constant satisfying

max_{σ \in [0, b]} | λ_{i} (σ) | \leq B, f o r i = 1, 2, \dots, m .

Proof.

Applying the operator

I_{θ}^{α_{1}}

to both sides of Equation (1), we obtain

\begin{matrix} I_{θ}^{α_{1}} \frac{_{c} \partial^{α_{1}}}{\partial θ^{α_{1}}} W (θ, σ) + C I_{θ}^{α_{1} - α_{2}} I_{θ}^{α_{2}} \frac{_{c} \partial^{α_{2}}}{\partial θ^{α_{2}}} W (θ, σ) + \sum_{i = 1}^{m} λ_{i} (σ) I_{θ}^{α_{1} + γ_{i}} I_{σ}^{β_{i}} W (θ, σ) \\ = I_{θ}^{α_{1}} f (θ, σ) + I_{θ}^{α_{1}} g (W (θ, σ)) . \end{matrix}

This implies that

\begin{matrix} W (θ, σ) - ϕ (σ) + C I_{θ}^{α_{1} - α_{2}} (W (θ, σ) - ϕ (σ)) + \sum_{i = 1}^{m} λ_{i} (σ) I_{θ}^{α_{1} + γ_{i}} I_{σ}^{β_{i}} W (θ, σ) \\ = I_{θ}^{α_{1}} f (θ, σ) + I_{θ}^{α_{1}} g (W (θ, σ)) . \end{matrix}

Hence,

\begin{matrix} (1 + C I_{θ}^{α_{1} - α_{2}} + \sum_{i = 1}^{m} λ_{i} (σ) I_{θ}^{α_{1} + γ_{i}} I_{σ}^{β_{i}}) W (θ, σ) \\ = I_{θ}^{α_{1}} f (θ, σ) + I_{θ}^{α_{1}} g (W (θ, σ)) + ϕ (σ) (1 + C \frac{θ^{α_{1} - α_{2}}}{Γ (α_{1} - α_{2} + 1)}) . \end{matrix}

Using Babenko’s approach and the multinomial theorem,

\begin{matrix} W (θ, σ) \\ = {(1 + C I_{θ}^{α_{1} - α_{2}} + \sum_{i = 1}^{m} λ_{i} (σ) I_{θ}^{α_{1} + γ_{i}} I_{σ}^{β_{i}})}^{- 1} \\ \cdot (I_{θ}^{α_{1}} f (θ, σ) + I_{θ}^{α_{1}} g (W (θ, σ)) + ϕ (σ) (1 + C \frac{θ^{α_{1} - α_{2}}}{Γ (α_{1} - α_{2} + 1)})) \\ = \sum_{l = 0}^{\infty} {(- 1)}^{l} {(C I_{θ}^{α_{1} - α_{2}} + \sum_{i = 1}^{m} λ_{i} (σ) I_{θ}^{α_{1} + γ_{i}} I_{σ}^{β_{i}})}^{l} \\ \cdot (I_{θ}^{α_{1}} f (θ, σ) + I_{θ}^{α_{1}} g (W (θ, σ)) + ϕ (σ) (1 + C \frac{θ^{α_{1} - α_{2}}}{Γ (α_{1} - α_{2} + 1)})) \\ = \sum_{l = 0}^{\infty} {(- 1)}^{l} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) {(λ_{1} (σ) I_{θ}^{α_{1} + γ_{1}} I_{σ}^{β_{1}})}^{l_{1}} \dots \\ \cdot {(λ_{m} (σ) I_{θ}^{α_{1} + γ_{m}} I_{σ}^{β_{m}})}^{l_{m}} {(C I_{θ}^{α_{1} - α_{2}})}^{l_{m + 1}} \\ \cdot (I_{θ}^{α_{1}} f (θ, σ) + I_{θ}^{α_{1}} g (W (θ, σ)) + ϕ (σ) (1 + C \frac{θ^{α_{1} - α_{2}}}{Γ (α_{1} - α_{2} + 1)})) \\ = \sum_{l = 0}^{\infty} {(- 1)}^{l} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) C^{l_{m + 1}} I_{θ}^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m} (α_{1} + γ_{m}) + l_{m + 1} (α_{1} - α_{2}) + α_{1}} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} f (θ, σ) \\ + \sum_{l = 0}^{\infty} {(- 1)}^{l} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) C^{l_{m + 1}} I_{θ}^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1}} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} g (W (θ, σ)) + \sum_{l = 0}^{\infty} {(- 1)}^{l} \\ \cdot \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) \frac{C^{l_{m + 1}} θ^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2})}}{Γ (l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + 1)} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} ϕ (σ) + C \sum_{l = 0}^{\infty} {(- 1)}^{l} \\ \cdot \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) \frac{C^{l_{m + 1}} θ^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1} - α_{2}}}{Γ (l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1} - α_{2} + 1)} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} . \end{matrix}

Clearly, all the above steps are reversible. It remains to be shown that

W \in C ([0, 1] \times [0, b])

. Let B be a positive constant such that

max_{σ \in [0, b]} | λ_{i} (σ) | \leq B, for i = 1, 2, \dots, m .

then,

\begin{matrix} ∥W∥ \\ \leq \sum_{l = 0}^{\infty} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) \frac{{| C |}^{l_{m + 1}} B^{l_{1}} \dots B^{l_{m}}}{Γ (l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1} + 1)} \\ \cdot \frac{b^{l_{1} β_{1} + \dots + l_{m} β_{m}}}{Γ (l_{1} β_{1} + \dots + l_{m} β_{m} + 1)} max_{(θ, σ) \in [0, 1] \times [0, b]} | f (θ, σ) | \\ + \sum_{l = 0}^{\infty} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) \frac{{| C |}^{l_{m + 1}} B^{l_{1}} \dots B^{l_{m}}}{Γ (l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1} + 1)} \\ \cdot \frac{b^{l_{1} β_{1} + \dots + l_{m} β_{m}}}{Γ (l_{1} β_{1} + \dots + l_{m} β_{m} + 1)} sup_{x \in R} | g (x) | + \sum_{l = 0}^{\infty} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) \\ \frac{{| C |}^{l_{m + 1}} B^{l_{1}} \dots B^{l_{m}} b^{l_{1} β_{1} + \dots + l_{m} β_{m}}}{Γ (l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + 1) Γ (l_{1} β_{1} + \dots + l_{m} β_{m} + 1)} max_{σ \in [0, b]} | ϕ (σ) | \\ + | C | \sum_{l = 0}^{\infty} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) \\ \cdot \frac{{| C |}^{l_{m + 1}} {(B b^{β_{1}})}^{l_{1}} \dots {(B b^{β_{m}})}^{l_{m}}}{Γ (l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1} - α_{2} + 1) Γ (l_{1} β_{1} + \dots + l_{m} β_{m} + 1)} . \end{matrix}

Clearly,

Γ (l_{1} β_{1} + \dots + l_{m} β_{m} + 1) \geq 1 / 2 .

Therefore,

\begin{matrix} ∥W∥ \leq & 2 E_{(α_{1} + γ_{1}, \dots, α_{1} + γ_{m}, α_{1} - α_{2}), α_{1} + 1} (B b^{β_{1}}, \dots, B b^{β_{m}}, | C |) \\ (max_{(θ, σ) \in [0, 1] \times [0, b]} | f (θ, σ) | + sup_{x \in R} | g (x) |) \\ + 2 E_{(α_{1} + γ_{1}, \dots, α_{1} + γ_{m}, α_{1} - α_{2}), 1} (B b^{β_{1}}, \dots, B b^{β_{m}}, | C |) max_{σ \in [0, b]} | ϕ (σ) | \\ + 2 E_{(α_{1} + γ_{1}, \dots, α_{1} + γ_{m}, α_{1} - α_{2}), α_{1} - α_{2} + 1} (B b^{β_{1}}, \dots, B b^{β_{m}}, | C |) < + \infty . \end{matrix}

This completes the proof of Theorem 1. □

Theorem 2.

Let

ϕ (σ), λ_{i} (σ) \in C [0, b]

for all

i = 1, 2, \dots, m

,

f (θ, σ) \in C ([0, 1] \times [0, b])

and g be a continuous and bounded function on R, satisfying the following Lipschitz condition for a positive constant

L

:

| g (x) - g (y) | \leq L | x - y |, x, y \in R .

In addition, we assume that

0 < α_{2} < α_{1} \leq 1, γ_{i}, β_{i} \geq 0

for all

i = 1, 2, \dots, m

, C is a constant in R and

q = 2 L E_{(α_{1} + γ_{1}, \dots, α_{1} + γ_{m}, α_{1} - α_{2}), α_{1} + 1} (B b^{β_{1}}, \dots, B b^{β_{m}}, | C |) < 1,

where B is defined in Theorem 1. Then Equation (1) has a unique solution in the space

C ([0, 1] \times [0, b])

.

Proof.

We define a nonlinear mapping

T

over the space

C ([0, 1] \times [0, b])

by

\begin{matrix} (T W) (θ, σ) \\ = \sum_{l = 0}^{\infty} {(- 1)}^{l} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) C^{l_{m + 1}} I_{θ}^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m} (α_{1} + γ_{m}) + l_{m + 1} (α_{1} - α_{2}) + α_{1}} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} f (θ, σ) \\ + \sum_{l = 0}^{\infty} {(- 1)}^{l} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) C^{l_{m + 1}} I_{θ}^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1}} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} g (W (θ, σ)) + \sum_{l = 0}^{\infty} {(- 1)}^{l} \\ \cdot \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) \frac{C^{l_{m + 1}} θ^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2})}}{Γ (l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + 1)} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} ϕ (σ) + C \sum_{l = 0}^{\infty} {(- 1)}^{l} \\ \cdot \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) \frac{C^{l_{m + 1}} θ^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1} - α_{2}}}{Γ (l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1} - α_{2} + 1)} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} . \end{matrix}

It follows from Theorem 1 that

T W \in C ([0, 1] \times [0, b])

. We are going to show that

T

is contractive. Indeed, for

W_{1}, W_{2} \in C ([0, 1] \times [0, b])

, we come to

\begin{matrix} T W_{1} - T W_{2} \\ = \sum_{l = 0}^{\infty} {(- 1)}^{l} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) C^{l_{m + 1}} I_{θ}^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1}} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} g (W_{1} (θ, σ)) \\ - \sum_{l = 0}^{\infty} {(- 1)}^{l} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) C^{l_{m + 1}} I_{θ}^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1}} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} g (W_{2} (θ, σ)), \end{matrix}

and

\begin{matrix} ∥T W_{1} - T W_{2}∥ \\ \leq 2 L E_{(α_{1} + γ_{1}, \dots, α_{1} + γ_{m}, α_{1} - α_{2}), α_{1} + 1} (B b^{β_{1}}, \dots, B b^{β_{m}}, | C |) ∥W_{1} - W_{2}∥ \\ = q ∥W_{1} - W_{2}∥, \end{matrix}

from the proof of Theorem 1 and noting that

| g (W_{1}) - g (W_{2}) | \leq L | W_{1} - W_{2} | .

Since

q < 1

, Equation (1) has a unique solution in the space

C ([0, 1] \times [0, b])

by Banach’s contractive principle. This completes the proof of Theorem 2. □

3. Analytic and Approximate Solutions

We begin to derive analytic and approximate solutions to Equation (1) from the implicit integral Equation (2) obtained in Section 2 using an initial value

W_{0} = 0

and the following recurrence (iterative method):

\begin{matrix} W_{n + 1} (θ, σ) \\ = \sum_{l = 0}^{\infty} {(- 1)}^{l} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) C^{l_{m + 1}} I_{θ}^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m} (α_{1} + γ_{m}) + l_{m + 1} (α_{1} - α_{2}) + α_{1}} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} f (θ, σ) \\ + \sum_{l = 0}^{\infty} {(- 1)}^{l} \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) C^{l_{m + 1}} I_{θ}^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1}} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} g (W_{n} (θ, σ)) + \sum_{l = 0}^{\infty} {(- 1)}^{l} \\ \cdot \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) \frac{C^{l_{m + 1}} θ^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2})}}{Γ (l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + 1)} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}} ϕ (σ) + C \sum_{l = 0}^{\infty} {(- 1)}^{l} \\ \cdot \sum_{\begin{matrix} l_{1} + \dots + l_{m + 1} = l \\ l_{1} \geq 0, \dots, l_{m + 1} \geq 0 \end{matrix}} (\binom{l}{l_{1}, \dots, l_{m + 1}}) \frac{C^{l_{m + 1}} θ^{l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1} - α_{2}}}{Γ (l_{1} (α_{1} + γ_{1}) + \dots + l_{m + 1} (α_{1} - α_{2}) + α_{1} - α_{2} + 1)} \\ \cdot {(λ_{1} (σ) I_{σ}^{β_{1}})}^{l_{1}} \dots {(λ_{m} (σ) I_{σ}^{β_{m}})}^{l_{m}}, \end{matrix}

for

n = 0, 1, \dots

.

Let

W_{e x a c t}

be an exact solution to Equation (1). Then, it follows from Theorem 2 that

\begin{matrix} ∥W_{n + 1} - W_{e x a c t}∥ \leq q ∥W_{n} - W_{e x a c t}∥ \leq q^{2} ∥W_{n - 1} - W_{e x a c t}∥ \leq \dots \leq q^{n} ∥W_{1} - W_{e x a c t}∥ \\ \leq 2 q^{n} E_{(α_{1} + γ_{1}, \dots, α_{1} + γ_{m}, α_{1} - α_{2}), α_{1} + 1} (B b^{β_{1}}, \dots, B b^{β_{m}}, | C |) ∥g (W_{0}) - g (W_{e x a c t})∥ \\ \leq 4 q^{n} E_{(α_{1} + γ_{1}, \dots, α_{1} + γ_{m}, α_{1} - α_{2}), α_{1} + 1} (B b^{β_{1}}, \dots, B b^{β_{m}}, | C |) sup_{x \in R} | g (x) |, \end{matrix}

which is the absolute error between

W_{n + 1}

and

W_{e x a c t}

.

We can apply Adomian’s decomposition method to construct an algorithm for finding analytic and approximate solutions to Equation (1).

It follows from the proof of Theorem 1 that

\begin{matrix} W (θ, σ) & = & ϕ (σ) (1 + \frac{C θ^{α_{1} - α_{2}}}{Γ (α_{1} - α_{2} + 1)}) - C I_{θ}^{α_{1} - α_{2}} W (θ, σ) - \sum_{i = 1}^{m} λ_{i} (σ) I_{θ}^{α_{1} + γ_{i}} I_{σ}^{β_{i}} W (θ, σ) \\ + I_{θ}^{α_{1}} f (θ, σ) + I_{θ}^{α_{1}} g (W (θ, σ)) . \end{matrix}

(3)

let

W (θ, σ) = W_{1} (θ, σ) + W_{2} (θ, σ) + W_{3} (θ, σ) + \dots,

(4)

by noting that

W_{0} = 0

, and the nonlinear term

g (W (θ, σ)) = A_{1} (W_{1}) + A_{2} (W_{1}, W_{2}) + \dots .

(5)

Substituting (4) and (5) into (3), we have

\begin{matrix} W_{1} + W_{2} + W_{3} + \dots \\ = ϕ (σ) (1 + \frac{C θ^{α_{1} - α_{2}}}{Γ (α_{1} - α_{2} + 1)}) + I_{θ}^{α_{1}} f (θ, σ) - C I_{θ}^{α_{1} - α_{2}} (W_{1} + W_{2} + W_{3} + \dots) \\ - \sum_{i = 1}^{m} λ_{i} (σ) I_{θ}^{α_{1} + γ_{i}} I_{σ}^{β_{i}} (W_{1} + W_{2} + W_{3} + \dots) + I_{θ}^{α_{1}} (A_{1} + A_{2} + A_{3} + \dots), \end{matrix}

which implies, using Adomian’s decomposition method, that

\begin{matrix} \begin{matrix} W_{1} & = ϕ (σ) (1 + \frac{C θ^{α_{1} - α_{2}}}{Γ (α_{1} - α_{2} + 1)}) + I_{θ}^{α_{1}} f (θ, σ), \\ W_{k + 1} & = - C I_{θ}^{α_{1} - α_{2}} W_{k} - \sum_{i = 1}^{m} λ_{i} (σ) I_{θ}^{α_{1} + γ_{i}} I_{σ}^{β_{i}} W_{k} + I_{θ}^{α_{1}} A_{k}, \end{matrix} \end{matrix}

(6)

for

k = 1, 2, \dots

.

Here, a couple of examples to establish

A_{k}

from a given nonlinear function

g (W)

are presented. First, we assume that

g (W) = W \bar{W} = {| W |}^{2}

. Then,

\begin{matrix} (W_{1} + W_{2} + \dots) (\bar{W_{1}} + \bar{W_{2}} + \dots) = A_{1} + A_{2} + \dots, \\ = | W_{1} |^{2} + 2 W_{1} \bar{W_{2}} + \dots + \sum_{i = 0}^{n - 1} W_{i + 1} {\bar{W}}_{n - i} + \dots \end{matrix}

which derives that

\begin{matrix} \begin{matrix} A_{1} & = | W_{1} |^{2}, \\ A_{2} & = W_{1} \bar{W_{2}} + \bar{W_{2}} W_{1} = 2 W_{1} \bar{W_{2}}, \\ ⋮ \\ A_{n} & = \sum_{i = 0}^{n - 1} W_{i + 1} {\bar{W}}_{n - i}, \end{matrix} \end{matrix}

for

n = 1, 2, \dots

from [14].

Secondly, we consider

g (W) = sin W

. Using Taylor’s series, we obtain

g (W) = sin W \approx W - \frac{W^{3}}{3!} + \frac{W^{5}}{5!} .

Thus,

\begin{matrix} (W_{1} + W_{2} + \dots) - \frac{{(W_{1} + W_{2} + \dots)}^{3}}{3!} + \frac{{(W_{1} + W_{2} + \dots)}^{5}}{5!} \\ = A_{1} + A_{2} + \dots . \end{matrix}

This infers that

\begin{matrix} \begin{matrix} A_{1} & = W_{1} - \frac{W_{1}^{3}}{3!} + \frac{W_{1}^{5}}{5!}, \\ A_{2} & = W_{2} - \frac{W_{1}^{2} W_{2}}{2!} + \frac{W_{1}^{4} W_{2}}{4!}, \\ ⋮ \end{matrix} \end{matrix}

In summary, we are able to find analytic and approximate solutions to Equation (1) as

W = W_{1} + W_{2} + W_{3} + \dots + W_{n},

from (6) and the recurrence of

A_{n}

for certain nonlinear functions

g (W)

.

4. Example

Example 1.

Consider the following fractional nonlinear partial integro-differential equation with the initial condition:

\{\begin{matrix} \frac{\partial}{\partial θ} W (θ, σ) + 2 \frac{_{c} \partial^{0.5}}{\partial θ^{0.5}} W (θ, σ) + (σ^{2} + 1) I_{θ} I_{σ}^{0.5} W (θ, σ) \\ = θ + \frac{1}{22216010} cos (W (θ, σ)), \\ W (0, σ) = σ, (θ, σ) \in [0, 1] \times [0, 1] . \end{matrix}

(7)

Then Equation (7) has a unique solution in the space

C ([0, 1] \times [0, 1])

.

Proof.

Clearly,

g (W) = \frac{1}{22216010} cos (W (θ, σ))

is a continuous and bounded function satisfying the following Lipschitz condition for

W \in C ([0, 1] \times [0,])

:

| g (x) - g (y) | \leq \frac{1}{22216010} | x - y |, x, y \in R .

Furthermore,

max_{σ \in [0, 1]} | σ^{2} + 1 | \leq B = 2, C = 2,

and

\begin{matrix} q & = 2 L E_{(α_{1} + γ_{1}, \dots, α_{1} + γ_{m}, α_{1} - α_{2}), α_{1} + 1} (B b^{β_{1}}, \dots, B b^{β_{m}}, | C |) \\ = \frac{2}{22216010} E_{(2, 0.5), 2} (2, 2) = \frac{2}{22216010} \sum_{l = 0}^{\infty} \sum_{l_{1} + l_{2} = l} (\binom{l}{l_{1}, l_{2}}) \frac{2^{l_{1}} 2^{l_{2}}}{Γ (2 l_{1} + 0.5 l_{2} + 2)} . \end{matrix}

Using

\begin{matrix} \sum_{l_{1} + l_{2} = l} (\binom{l}{l_{1}, l_{2}}) = 2^{l}, \\ Γ (2 l_{1} + 0.5 l_{2} + 2) = Γ (1.5 l_{1} + 0.5 l + 2) \geq Γ (0.5 l + 2), \end{matrix}

we deduce that

q \leq \frac{2}{22216010} \sum_{l = 0}^{\infty} \frac{4^{l}}{Γ (0.5 l + 2)} \approx \frac{2 * 1.1108 * 10^{6}}{22216010} \approx 0.1 < 1,

using online calculators from the site https://www.wolframalpha.com/ (accessed on 2 March 2023). By Theorem 2, Equation (7) has a unique solution in the space

C ([0, 1] \times [0, 1])

. □

Finally, we are going to find an analytic and approximate solution to (7) using Recurrence (6). Let

g (W) = \frac{1}{22216010} cos W \approx \frac{1}{22216010} (1 - \frac{W^{2}}{2!} + \frac{W^{4}}{4!}) = A_{1} + A_{2} + \dots,

and

W = W_{1} + W_{2} + \dots .

This infers that

\begin{matrix} \begin{matrix} A_{1} & = \frac{1}{22216010} (1 - \frac{W_{1}^{2}}{2!} + \frac{W_{1}^{4}}{4!}), \\ A_{2} & = \frac{1}{22216010} (- \frac{W_{1} W_{2}}{1!} + \frac{W_{1}^{3} W_{2}}{3!}), \\ ⋮ \end{matrix} \end{matrix}

Moreover,

W_{1} = σ (1 + \frac{2 θ^{0.5}}{Γ (0.5 + 1)}) + I_{θ} θ = σ (1 + \frac{4 θ^{0.5}}{\sqrt{π}}) + \frac{θ^{2}}{2!},

and

\begin{matrix} W_{2} & = - 2 I_{θ}^{0.5} W_{1} - (σ^{2} + 1) I_{θ}^{2} I_{σ}^{0.5} W_{1} + I_{θ} A_{1} . \end{matrix}

Using MATHEMATICA and manual simplification, we finally obtain

\begin{matrix} W_{a p p r o} \approx & W_{1} + W_{2} \\ = & σ + \frac{θ (24 - 2132736960 σ - 12 σ^{2} + σ^{4})}{533184240} + \frac{2 θ^{3 / 2} σ^{2} (- 6 + σ^{2})}{99972045 \sqrt{π}} \\ + θ^{2} (\frac{1}{2} + \frac{σ^{2} (- 2 + σ^{2})}{11108005 π} - \frac{2 σ^{3 / 2} (1 + σ^{2})}{3 \sqrt{π}}) \\ + θ^{5 / 2} (- \frac{16}{15 \sqrt{π}} + \frac{32 σ^{4}}{166620075 π^{3 / 2}} - \frac{64 σ^{3 / 2} (1 + σ^{2})}{45 π}) \\ + θ^{3} (\frac{16 σ^{4}}{99972045 π^{2}} + \frac{σ (- 6 + σ^{2})}{799776360}) + \frac{θ^{7 / 2} σ (- 2 + σ^{2})}{77756035 \sqrt{π}} \\ + θ^{4} (\frac{σ^{3}}{22216010 π} - \frac{\sqrt{σ} (1 + σ^{2})}{12 \sqrt{π}}) + \frac{16 θ^{9 / 2} σ^{3}}{299916135 π^{3 / 2}} + \frac{θ^{5} (- 2 + σ^{2})}{1777280800} \\ + \frac{θ^{11 / 2} σ^{2}}{244376110 \sqrt{π}} + \frac{θ^{6} σ^{2}}{133296060 π} + \frac{θ^{7} σ}{7464579360} + \frac{θ^{15 / 2} σ}{1999440900 \sqrt{π}} + \frac{θ^{9}}{76778530560}, \end{matrix}

which is an approximation in a separate form of

θ

and

σ

, arranged in an increasing power of

θ

from 0 to 9. Clearly,

W_{a p p r o} (0, σ) = σ,

which demonstrates that the initial condition is satisfied.

Clearly, the absolute error is

∥W_{a p p r o} - W_{e x a c t}∥ \leq 4 * 0.1 * \frac{1.1168 * 10^{6}}{22216010} \approx 0.02 .

(8)

Remark 1.

Since the exact solution to Equation (7) is unknown, we were unable to set up a table showing absolute errors between the approximate and exact solutions at particular values. In addition, there is no existing available research for comparison as the equation is new. However, Inequality (8) has plainly indicated the efficiency of our proposed method for the first two-term approximation only.

5. Conclusions

We obtained sufficient conditions for the uniqueness of the bounded solution to the new Cauchy problem of the fractional nonlinear partial integro-differential Equation (1) using the multivariate Mittag–Leffler function as well as Banach’s contractive principle. In addition, we constructed the algorithm for finding analytic and approximate solutions based on Adomian’s decomposition method and presented an approximation order analysis, with one example showing the applications of the main results. Clearly, the technique used in this work can be applied to other nonlinear differential equations with initial or boundary conditions as well as integral equations with variable coefficients.

Author Contributions

All authors conceived of the study, participated in its design and coordination, and drafted the manuscript. All authors have read and agreed to the published version of the manuscript.

Funding

This research is supported by the Natural Sciences and Engineering Research Council of Canada (Grant No. 2019-03907).

Data Availability Statement

No data were used to support this study.

Acknowledgments

The authors are thankful to the reviewers and editor for their valuable comments, corrections and suggestions.

Conflicts of Interest

The authors declare no conflict of interest.

References

Kilbas, A.A.; Srivastava, H.M.; Trujillo, J.J. Theory and Applications of Fractional Differential Equations; Elsevier: Amsterdam, The Netherlands, 2006. [Google Scholar]
Li, C.; Saadati, R.; Srivastava, R.; Beaudin, J. On the boundary value problem of nonlinear fractional integro-differential equations. Mathematics 2022, 10, 1971. [Google Scholar] [CrossRef]
Hadid, S.B.; Luchko, Y.F. An operational method for solving fractional differential equations of an arbitrary real order. Panamer. Math. J. 1996, 6, 57–73. [Google Scholar]
Babenko, Y.I. Heat and Mass Transfer; Khimiya: Leningrad, Russian, 1986. (In Russian) [Google Scholar]
Li, C. Uniqueness of the partial integro-differential equations. J. Integral Equ. Appl. 2021, 22, 463–475. [Google Scholar] [CrossRef]
Li, C.; Saadati, R.; Allahviranloo, T. Conditions to guarantee the existence of solutions for a nonlinear and implicit integro-differential equation with variable coefficients. Math. Meth. Appl. Sci. 2022, 8890. [Google Scholar] [CrossRef]
Seadawy, A.R.; Lu, D.; Yue, C. Travelling wave solutions of the generalized nonlinear fifth-order KdV water wave equations and its stability. J. Taibah. Univ. Sci. 2017, 11, 623–633. [Google Scholar] [CrossRef] [Green Version]
Atangana, A. Fractal-fractional differentiation and integration: Connecting fractal calculus and fractional calculus to predict complex system. Chaos Solitons Fractals 2020, 102, 396–406. [Google Scholar] [CrossRef]
Meerschaert, M.M.; Tadjeran, C. Finite difference approximations for two-sided space-fractional partial differential equations. Appl. Numer. Math. 2006, 56, 80–90. [Google Scholar] [CrossRef]
Rida, S.Z.; El-Sherbinyb, H.M.; Arafa, A.A.M. On the solution of the fractional nonlinear Schrödinger equation. Phys. lett. A 2008, 372, 553–558. [Google Scholar] [CrossRef]
He, J.H. Approximate analytical solution for seepage flow with fractional derivatives in porous media. Comput. Methods Appl. Mech. Eng. 1998, 167, 57–68. [Google Scholar] [CrossRef]
Momani, S.; Odibat, Z. Homotopy perturbation method for nonlinear partial differential equations of fractional order. Phys. Lett. A 2007, 365, 345–350. [Google Scholar] [CrossRef]
Adjabi, Y.; Jarad, F.; Baleanu, D.; Abdeljawad, T. On Cauchy problems with Caputo-Hadamard fractional derivatives. J. Comput. Anal. Appl. 2016, 21, 661–681. [Google Scholar]
Li, C.; Nonlaopon, K.; Hrytsenko, A.; Beaudin, J. On the analytic and approximate solutions for the fractional nonlinear Schrodinger equations. J. Nonlinear Sci. Appl. 2023, 16, 51–59. [Google Scholar] [CrossRef]

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

Li, C.; Saadati, R.; Beaudin, J.; Hrytsenko, A. On the Uniqueness of the Bounded Solution for the Fractional Nonlinear Partial Integro-Differential Equation with Approximations. Mathematics 2023, 11, 2752. https://doi.org/10.3390/math11122752

AMA Style

Li C, Saadati R, Beaudin J, Hrytsenko A. On the Uniqueness of the Bounded Solution for the Fractional Nonlinear Partial Integro-Differential Equation with Approximations. Mathematics. 2023; 11(12):2752. https://doi.org/10.3390/math11122752

Chicago/Turabian Style

Li, Chenkuan, Reza Saadati, Joshua Beaudin, and Andrii Hrytsenko. 2023. "On the Uniqueness of the Bounded Solution for the Fractional Nonlinear Partial Integro-Differential Equation with Approximations" Mathematics 11, no. 12: 2752. https://doi.org/10.3390/math11122752

APA Style

Li, C., Saadati, R., Beaudin, J., & Hrytsenko, A. (2023). On the Uniqueness of the Bounded Solution for the Fractional Nonlinear Partial Integro-Differential Equation with Approximations. Mathematics, 11(12), 2752. https://doi.org/10.3390/math11122752

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

Article Menu

On the Uniqueness of the Bounded Solution for the Fractional Nonlinear Partial Integro-Differential Equation with Approximations

Abstract

1. Introduction and Preliminaries

2. Uniqueness of Bounded Solution

3. Analytic and Approximate Solutions

4. Example

5. Conclusions

Author Contributions

Funding

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

Share and Cite

Article Metrics

Article Access Statistics

Further Information

Guidelines

MDPI Initiatives

Follow MDPI