A Local Fractional Elzaki Transform Decomposition Method for the Nonlinear System of Local Fractional Partial Differential Equations

Anac, Halil

doi:10.3390/fractalfract6030167

Open AccessArticle

A Local Fractional Elzaki Transform Decomposition Method for the Nonlinear System of Local Fractional Partial Differential Equations

by

Halil Anac

Department of Computer Technologies, Torul Vocational School, Gümüşhane University, Gümüşhane 29800, Turkey

Fractal Fract. 2022, 6(3), 167; https://doi.org/10.3390/fractalfract6030167

Submission received: 29 January 2022 / Revised: 4 March 2022 / Accepted: 9 March 2022 / Published: 18 March 2022

(This article belongs to the Special Issue Discrete Fractional Calculus, Local Fractional Inequalities, and Applications)

Download

Browse Figures

Review Reports Versions Notes

Abstract

:

In this paper, the nonlinear system of local fractional partial differential equations is solved via local fractional Elzaki transform decomposition method. The local fractional Elzaki decomposition transform method combines a local fractional Elzaki transform and the Adomian decomposition method. Applications related to the nonlinear system of local fractional partial differential equations are presented.

Keywords:

local fractional derivative; Elzaki transform; Adomian decomposition method

1. Introduction

With the rapid advancement of human knowledge, there is an urgent need to improve the basic definitions in the various scientific fields. One of these new developments in differential equations is the use of new concepts with local and non-local fractional differential calculus. These concepts have been rapidly applied in various branches of mathematics, physics and engineering [1,2,3,4,5,6,7,8,9,10,11,12,13].

Recently, local fractional calculus has been a considerably important topic in both mathematics and engineering [14,15,16,17,18,19,20,21,22,23]. Researchers have been used the Adomian decomposition method (ADM) [24] to solve local fractional differential equations, local fractional partial differential equations and local fractional integral equations [25,26,27,28]. Local fractional derivative operators with some known transforms, such as the Young–Laplace transform and the Sumudu transform, are combined with a decomposition method. A few of these methods are the local fractional Laplace decomposition method [29], the local fractional Sumudu decomposition method [30,31] and the Yang–Laplace decomposition method [32]. Thus, local fractional differential equations or local fractional partial differential equations are solved by these methods.

This paper analyzes the non-differentiable solutions to the fractional form of the coupled nonlinear system of partial differential equations, including the local fractional derivative (LFD), with the aid of a novel, efficient method. There have been few studies about the solutions of local fractional partial differential equations in the literature [25,26,27,28,29,30,31,32]. We carried out such study, in order to find an effective method among the existing methods in the literature for the existing solutions of such equations, and to gain a new perspective for future studies. The novelty of this paper is to define a local fractional Elzaki transform and give its properties. Additionally, we suggest a local fractional Elzaki transform decomposition method (LFETDM), which is constructed from the local fractional Elzaki transform and the Adomian decomposition method. We note that the local fractional Elzaki transform decomposition method is the same as the Yang–Laplace decomposition method. The nonlinear system of local fractional partial differential equations is solved by LFETDM. The originality of this study is to propose a new hybrid method for obtaining the analytical or numerical solutions of a nonlinear system of local fractional partial differential equations.

2. Preliminaries

In this section, we give the concepts of local fractional derivatives and integrals and polynomial functions on Cantor sets.

Definition 1.

Let the function

f (x) \in C_{α} (a, b)

[33,34]. If there are

| f (x) - f (x_{0}) | < ε^{α}, 0 < α \leq 1,

(1)

where there is

| x - x_{0} | < δ

, for

ε > 0

and

ε \in ℝ,

then

f (x)

is local, fractional and continuous.

Definition 2.

Let the function

f (x) \in C_{α} (a, b)

. The local fractional integral of

f (x)

of order

α

in the interval

[a, b]

is defined by [35,36]

{}_{a}I {_{b}}^{(α)} f (x) = \frac{1}{Г (1 + α)} \int_{a}^{b} f (t) {(d t)}^{α} = \frac{1}{Г (1 + α)} \lim_{Δ t \to 0} \sum_{j = 0}^{N - 1} f (t_{j}) {(Δ t_{j})}^{α},

(2)

where the partitions of the interval

[a, b]

are denoted as

(t_{j}, t_{j + 1}),

j = 0, \dots, N - 1,

t_{0} = a

and

t_{N} = b

with

Δ t_{j} = t_{j + 1} - t_{j}

and

Δ t = m a x {Δ t_{0}, Δ t_{1}, Δ t_{j}, \dots} .

Definition 3.

Let the function

f (x) \in C_{α} (a, b)

[36,37]. The local fractional derivative of

f (x)

of order

α

in the interval

[a, b]

is defined by

\frac{d^{α} f (x_{0})}{d x^{α}} = \frac{Δ^{α} (f (x) - f (x_{0}))}{{(x - x_{0})}^{α}},

(3)

where

Δ^{α} (f (x) - f (x_{0})) ≅ Г (1 + α) [f (x) - f (x_{0})] .

(4)

The local fractional partial differential operator of order

α

(

0 < α \leq 1

) is given by [36,37]

\frac{\partial^{α} u (x_{0}, t)}{\partial t^{α}} = \frac{Δ^{α} (u (x_{0}, t) - u (x_{0}, t_{0}))}{{(t - t_{0})}^{α}},

(5)

where

Δ^{α} (u (x_{0}, t) - u (x_{0}, t_{0})) ≅ Г (1 + α) [u (x_{0}, t) - u (x_{0}, t_{0})] .

(6)

Theorem 1.

(Local fractional Laplace transform of local fractional derivative) [38,39].

Let

L_{α} {f (x)} = f_{s}^{L, α} (s) .

Then, we have

L_{α} {f^{α} (x)} = s^{α} L_{α} {f (x)} - f (0) .

(7)

3. Local Fractional Elzaki Transform

The local fractional Elzaki transform (LFET) is proposed, and some properties of this transform are analyzed. We use the concepts of polynomial functions on Cantor sets.

If there is a new transform operator

{}^{L F}E_{α} : f (x) \to F (u),

so that Equation (8) is valid.

{}^{L F}E_{α} {f (x)} = {}^{L F}E_{α} [\sum_{k = 0}^{\infty} a_{k} x^{α k}] = \sum_{k = 0}^{\infty} Г (1 + α k) a_{k} v^{α (k + 2)} .

(8)

As a classical example, we can use

{}^{L F}E_{α} [\frac{x^{α}}{Г (1 + α)}] = v^{3 α} .

Definition 4.

The local fractional Elzaki transform of

f (x)

of order

α

is defined by

{}^{L F}E_{α} {f (x)} = F_{α} (v) = : \frac{v^{α}}{Г (1 + α)} \int_{0}^{\infty} E_{α} (- v^{- α} x^{α}) f (x) {(d x)}^{α}, 0 < α \leq 1 .

(9)

where the integral converges and

v^{α} \in ℝ^{α} .

The inverse local fractional Elzaki transform of

f (x)

of order

α

is defined by

{}^{L F}E {_{α}}^{- 1} {F_{α} (v)} = f (x), 0 < α \leq 1 .

(10)

Theorem 2.

(linearity)

Let

{}^{L F}E_{α} {f (x)} = F_{α} (v)

and

{}^{L F}E_{α} {g (x)} = G_{α} (v) .

Then, we have

{}^{L F}E_{α} {f (x) + g (x)} = F_{α} (v) + G_{α} (v) .

(11)

Proof.

By using Equation (9), we have

{}^{L F}E_{α} {f (x) + g (x)} = \frac{v^{α}}{Г (1 + α)} \int_{0}^{\infty} E_{α} (- v^{- α} x^{α}) (f + g) (x) {(d x)}^{α}

(12)

= \frac{v^{α}}{Г (1 + α)} \int_{0}^{\infty} E_{α} (- v^{- α} x^{α}) f (x) {(d x)}^{α} + \frac{v^{α}}{Г (1 + α)} \int_{0}^{\infty} E_{α} (- v^{- α} x^{α}) g (x) {(d x)}^{α}

(13)

= F_{α} (v) + G_{α} (v) .

(14)

The proof is completed. □

Theorem 3.

(Local fractional Laplace–Elzaki duality).

Let

L_{α} {f (x)} = f_{s}^{L, α} (s)

and

{}^{L F}E_{α} {f (x)} = F_{α} (v) .

Then, we get

{}^{L F}E_{α} {f (x)} = v^{α} L_{α} {f (\frac{1}{x})},

(15)

L_{α} {f (x)} = s^{α} {}^{L F}E_{α} {f (\frac{1}{s})} .

(16)

Proof.

By using the definitions of the local fractional Laplace and Elzaki transforms, then we directly obtain these results. □

Theorem 4.

(Local fractional Elzaki transform of the local fractional derivative).

Let

{}^{L F}E_{α} {f (x)} = F_{α} (v) .

Then, we get

{}^{L F}E_{α} {\frac{d^{α} f (x)}{d x^{α}}} = \frac{F_{α} (v)}{v^{α}} - v^{α} f (0) .

(17)

Proof.

By using Equations (7)–(15), the local fractional Elzaki transform of the local fractional derivative of

f (x)

is obtained as

\begin{matrix} {}^{L F}E_{α} {A (x)} = v^{α} L_{α} {A (\frac{1}{x})} = v^{α} [\frac{1}{v^{α}} L_{α} {f (\frac{1}{x})} - f (0)] = L_{α} {f (\frac{1}{x})} - v^{α} f (0) \\ = \frac{F_{α} (v)}{v^{α}} - v^{α} f (0), \end{matrix}

(18)

where

A (x) = \frac{d^{α} f (x)}{d x^{α}} .

The proof is completed. □

By the direct result of Equation (17), the generalization of Equation (17) is obtained.

Let

{}^{L F}E_{α} {f (x)} = F_{α} (v)

. Then, we get

{}^{L F}E_{α} {\frac{d^{n α} f (x)}{d x^{n α}}} = \frac{F_{α} (v)}{v^{n α}} - [\sum_{k = 0}^{n - 1} v^{(2 - n + k) α} f^{(k α)} (0)] .

(19)

After substituting

n = 2

into Equation (19), we have

{}^{L F}E_{α} {\frac{d^{2 α} f (x)}{d x^{2 α}}} = \frac{F_{α} (v)}{v^{2 α}} - f (0) - v^{α} f^{(α)} (0) .

(20)

4. Local Fractional Elzaki Transform Decomposition Method

Consider the general nonlinear system as a local fractional derivative [33]:

{\begin{matrix} \frac{\partial^{a} X}{\partial τ^{a}} + \frac{\partial^{a} X}{\partial x^{a}} + N_{α, 1} (X, T) + R_{α, 1} (X, T) = φ (x, τ), \\ \frac{\partial^{a} T}{\partial τ^{a}} + \frac{\partial^{a} T}{\partial x^{a}} + N_{α, 2} (X, T) + R_{α, 2} (X, T) = ψ (x, τ), \end{matrix}

(21)

where

\frac{\partial^{α}}{\partial {(.)}^{α}}

represents the linear local fractional derivative operator of order

α

,

R_{α, 1}

and

R_{α, 2}

are the linear local fractional operators,

N_{α, 1}

and

N_{α, 2}

are the nonlinear local fractional operators and

φ (x, τ), ψ (x, τ)

are two unknown functions.

An analytical solution of this system is obtained by the following steps.

Step 1 If the local fractional Elzaki transform (LFET) is applied to both sides of each equation in system (21), then it is obtained as

{\begin{matrix} {}^{L F}E_{α} [\frac{\partial^{a} X}{\partial τ^{a}}] + {}^{L F}E_{α} [\frac{\partial^{a} X}{\partial x^{a}}] + {}^{L F}E_{α} [N_{α, 1} (X, T)] + {}^{L F}E_{α} [R_{α, 1} (X, T)] = {}^{L F}E_{α} [φ (x, τ)], \\ {}^{L F}E_{α} [\frac{\partial^{a} T}{\partial τ^{a}}] + {}^{L F}E_{α} [\frac{\partial^{a} T}{\partial x^{a}}] + {}^{L F}E_{α} [N_{α, 2} (X, T)] + {}^{L F}E_{α} [R_{α, 2} (X, T)] = {}^{L F}E_{α} [ψ (x, τ)] . \end{matrix}

(22)

If the differential property of Elzaki transform is applied, then we have

{\begin{matrix} {}^{L F}E_{α} [X] = v^{2 α} X (x, 0) + v^{α} [{}^{L F}E_{α} [φ (x, τ)]] - {}^{L F}E_{α} [\frac{\partial^{a} X}{\partial x^{a}} + N_{α, 1} (X, T) + R_{α, 1} (X, T)], \\ {}^{L F}E_{α} [T] = v^{2 α} T (x, 0) + v^{α} [{}^{L F}E_{α} [ψ (x, τ)]] - {}^{L F}E_{α} [\frac{\partial^{a} T}{\partial x^{a}} + N_{α, 2} (X, T) + R_{α, 2} (X, T)] . \end{matrix}

(23)

If the inverse LFET is applied to both sides of each system Equation (23), then it is obtained as

{\begin{matrix} X = {}^{L F}E {_{α}}^{- 1} (v^{2 α} X (x, 0)) + {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [φ (x, τ)])]) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{a} X}{\partial x^{a}} + N_{α, 1} (X, T) + R_{α, 1} (X, T)])]), \\ T = {}^{L F}E {_{α}}^{- 1} (v^{2 α} T (x, 0)) + {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [ψ (x, τ)])]) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{a} T}{\partial x^{a}} + N_{α, 2} (X, T) + R_{α, 2} (X, T)])]) . \end{matrix}

(24)

Step 2 Applying the Adomian decomposition method [40], we can show the two unknown functions

X

and

T

as infinite series.

X (u, t) = \sum_{n = 0}^{\infty} X_{n} (u, t),

(25)

T (u, t) = \sum_{n = 0}^{\infty} T_{n} (u, t),

(26)

and the nonlinear terms are decomposed as

{\begin{matrix} N_{α, 1} (X, T) = \sum_{n = 0}^{\infty} A_{n}, \\ N_{α, 2} (X, T) = \sum_{n = 0}^{\infty} B_{n}, \end{matrix}

(27)

where

A_{n}

and

B_{n}

are Adomian polynomials [20].

If Equations (25)–(27) are substituted into Equation (24), then we obtain

{\begin{matrix} \sum_{n = 0}^{\infty} X_{n} (x, τ) = {}^{L F}E {_{α}}^{- 1} (v^{2 α} X (x, 0)) + {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [φ (x, τ)])]) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{a}}{\partial x^{a}} (\sum_{n = 0}^{\infty} X_{n} (x, τ)) + \sum_{n = 0}^{\infty} A_{n} + R_{α, 1} (\sum_{n = 0}^{\infty} X_{n}, \sum_{n = 0}^{\infty} T_{n})])]), \\ \sum_{n = 0}^{\infty} T_{n} (x, τ) = {}^{L F}E {_{α}}^{- 1} (v^{2 α} T (x, 0)) + {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [ψ (x, τ)])]) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a}}{\partial x^{2 a}} (\sum_{n = 0}^{\infty} T_{n} (x, τ)) + \sum_{n = 0}^{\infty} B_{n} + R_{α, 2} (\sum_{n = 0}^{\infty} X_{n}, \sum_{n = 0}^{\infty} T_{n})])]) . \end{matrix}

(28)

If both sides of Equation (28) are compared, then we obtain

X_{0} (x, τ) = {}^{L F}E {_{α}}^{- 1} (v^{2 α} X (x, 0)) + {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [φ (x, τ)])]),

(29)

X_{1} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{a} X_{0}}{\partial x^{a}} + A_{0} + R_{α, 1} (X_{0}, T_{0})])]),

(30)

X_{2} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{a} X_{1}}{\partial x^{a}} + A_{1} + R_{α, 1} (X_{1}, T_{1})])]),

(31)

X_{3} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{a} X_{2}}{\partial x^{a}} + A_{2} + R_{α, 1} (X_{2}, T_{2})])]),

(32)

T_{0} (x, τ) = {}^{L F}E {_{α}}^{- 1} (v^{2 α} T (x, 0)) + {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [ψ (x, τ)])]),

(33)

T_{1} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{a} T_{0}}{\partial x^{a}} + B_{0} + R_{α, 2} (X_{0}, T_{0})])]),

(34)

T_{2} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{a} T_{1}}{\partial x^{a}} + B_{1} + R_{α, 2} (X_{1}, T_{1})])]),

(35)

T_{3} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{a} T_{2}}{\partial x^{a}} + B_{2} + R_{α, 2} (X_{2}, T_{2})])]),

(36)

and so on.

Step 3 The analytical solution of

(X, T)

of the system (21) is obtained as

{\begin{matrix} X (x, τ) = \lim_{N \to \infty} \sum_{n = 0}^{N} X_{n} (x, τ), \\ T (x, τ) = \lim_{N \to \infty} \sum_{n = 0}^{N} T_{n} (x, τ) . \end{matrix}

(37)

5. Applications

In this section, the proposed method for solving a nonlinear system of LFPDEs (LFETDM) is applied.

Example 1.

Consider the following coupled nonlinear system of local fractional Burger equations [33]:

{\begin{matrix} \frac{\partial^{a} X}{\partial τ^{a}} - \frac{\partial^{2 a} X}{\partial x^{2 a}} - 2 X X_{x}^{α} + {(X T)}_{x}^{α} = 0, \\ \frac{\partial^{a} T}{\partial τ^{a}} - \frac{\partial^{2 a} T}{\partial x^{2 a}} - 2 T T_{x}^{α} + {(X T)}_{x}^{α} = 0, \end{matrix} 0 < α \leq 1,

(38)

with the initial conditions

X (x, 0) = s i n_{α} (x^{α}), T (x, 0) = s i n_{α} (x^{α}) .

(39)

If we apply the LFET to both sides of each equation of the system Equation (38),

{\begin{matrix} {}^{L F}E_{α} [X (x, τ)] = [v^{2 α} s i n_{α} (x^{α})] - v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a} X}{\partial x^{2 a}} - 2 X X_{x}^{α} + {(X T)}_{x}^{α}])], \\ {}^{L F}E_{α} [T (x, τ)] = [v^{2 α} s i n_{α} (x^{α})] - v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a} T}{\partial x^{2 a}} - 2 T T_{x}^{α} + {(X T)}_{x}^{α}])] . \end{matrix}

(40)

By applying the inverse LFET to both sides of each equation in Equation (40), we have

{\begin{matrix} X (x, τ) = s i n_{α} (x^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a} X}{\partial x^{2 a}} - 2 X X_{x}^{α} + {(X T)}_{x}^{α}])]), \\ T (x, τ) = s i n_{α} (x^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a} T}{\partial x^{2 a}} - 2 T T_{x}^{α} + {(X T)}_{x}^{α}])]) . \end{matrix}

(41)

If the Adomian decomposition method is applied, then each function of the solution

(X, T)

is decomposed as an infinite series

{\begin{matrix} X (x, τ) = \sum_{n = 0}^{\infty} X_{n} (x, τ), \\ T (x, τ) = \sum_{n = 0}^{\infty} T_{n} (x, τ), \end{matrix}

(42)

and the nonlinear terns can be decomposed as

X X_{x}^{(α)} = \sum_{n = 0}^{\infty} A_{n} (X),

(43)

{(X T)}_{x}^{(α)} = \sum_{n = 0}^{\infty} B_{n} (X, T),

(44)

and

T T_{x}^{(α)} = \sum_{n = 0}^{\infty} C_{n} (T) .

(45)

If Equations (42)–(45) are substituted into Equation (41), then we have

{\begin{matrix} \sum_{n = 0}^{\infty} X_{n} (x, τ) = s i n_{α} (x^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a}}{\partial x^{2 a}} (\sum_{n = 0}^{\infty} X_{n} (x, τ)) - 2 \sum_{n = 0}^{\infty} A_{n} (X) + \sum_{n = 0}^{\infty} B_{n} (X, T)])]), \\ \sum_{n = 0}^{\infty} T_{n} (x, τ) = s i n_{α} (x^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a}}{\partial x^{2 a}} (\sum_{n = 0}^{\infty} T_{n} (x, τ)) - 2 \sum_{n = 0}^{\infty} C_{n} (T) + \sum_{n = 0}^{\infty} B_{n} (X, T)])]) . \end{matrix}

(46)

By comparing both sides of Equation (46), we obtain

X_{0} (x, τ) = s i n_{α} (x^{α}),

(47)

X_{1} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a} X_{0}}{\partial x^{2 a}} - 2 A_{0} (X) + B_{0} (X, T)])]),

(48)

X_{2} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a} X_{1}}{\partial x^{2 a}} - 2 A_{1} (X) + B_{1} (X, T)])]),

(49)

X_{3} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a} X_{2}}{\partial x^{2 a}} - 2 A_{2} (X) + B_{2} (X, T)])]),

(50)

T_{0} (x, τ) = s i n_{α} (x^{α}),

(51)

T_{1} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a} T_{0}}{\partial x^{2 a}} - 2 C_{0} (T) + B_{0} (X, T)])]),

(52)

T_{2} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a} T_{1}}{\partial x^{2 a}} - 2 C_{1} (T) + B_{1} (X, T)])]),

(53)

T_{3} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [- \frac{\partial^{2 a} T_{2}}{\partial x^{2 a}} - 2 C_{2} (T) + B_{2} (X, T)])]),

(54)

and so on.

The first few components of

A_{n} (X),

B_{n} (X, T)

and

C_{n} (T)

polynomials [41] are obtained as

A_{0} (X) = X_{0} X_{0, x}^{(α)},

(55)

A_{1} (X) = X_{0} X_{1, x}^{(α)} + X_{1} X_{0, x}^{(α)},

(56)

A_{2} (X) = X_{0} X_{2, x}^{(α)} + X_{2} X_{0, x}^{(α)} + X_{1} X_{1, x}^{(α)},

(57)

B_{0} (X, T) = {(X_{0} T_{0})}_{x}^{(α)},

(58)

B_{1} (X, T) = {(X_{0} T_{1} + X_{1} T_{0})}_{x}^{(α)},

(59)

B_{2} (X, T) = {(X_{1} T_{1} + X_{0} T_{2} + X_{2} T_{0})}_{x}^{(α)},

(60)

C_{0} (X) = T_{0} T_{0, x}^{(α)},

(61)

C_{1} (T) = T_{0} T_{1, x}^{(α)} + T_{1} T_{0, x}^{(α)},

(62)

C_{2} (T) = T_{0} T_{2, x}^{(α)} + T_{2} T_{0, x}^{(α)} + T_{1} T_{1, x}^{(α)},

(63)

and so on.

According to Equations (47)–(54) and Equations (55)–(63), the first terms of LFETDM of the system Equation (38) are obtained as

X_{0} (x, τ) = s i n_{α} (x^{α}),

(64)

X_{1} (x, τ) = - s i n_{α} (x^{α}) \frac{τ^{α}}{Г (1 + α)},

(65)

X_{2} (x, τ) = s i n_{α} (x^{α}) \frac{τ^{2 α}}{Г (1 + 2 α)},

(66)

X_{3} (x, τ) = - s i n_{α} (x^{α}) \frac{τ^{3 α}}{Г (1 + 3 α)},

(67)

and

T_{0} (x, τ) = s i n_{α} (x^{α}),

(68)

T_{1} (x, τ) = - s i n_{α} (x^{α}) \frac{τ^{α}}{Г (1 + α)},

(69)

T_{2} (x, τ) = s i n_{α} (x^{α}) \frac{τ^{2 α}}{Г (1 + 2 α)},

(70)

T_{3} (x, τ) = - s i n_{α} (x^{α}) \frac{τ^{3 α}}{Г (1 + 3 α)},

(71)

and so on.

Thus, the local fractional series solutions of

X (x, τ)

and

T (x, τ)

are, respectively, obtained as

{\begin{matrix} X (x, τ) = \sum_{n = 0}^{\infty} X_{n} (x, τ), \\ T (x, τ) = \sum_{n = 0}^{\infty} T_{n} (x, τ), \end{matrix}

(72)

Therefore, the local fractional series solutions of the system Equation (38) can be written in the form:

{\begin{matrix} X (x, τ) = s i n_{α} (x^{α}) \lim_{N \to \infty} \sum_{n = 0}^{N} \frac{{(- 1)}^{n} {(τ)}^{n α}}{Г (1 + n α)}, \\ T (x, τ) = s i n_{α} (x^{α}) \lim_{N \to \infty} \sum_{n = 0}^{N} \frac{{(- 1)}^{n} {(τ)}^{n α}}{Г (1 + n α)} . \end{matrix}

(73)

If Equation (73) is rewritten in a closed form, then the non-differentiable solutions of

X (x, τ)

and

T (x, τ)

are obtained as

{\begin{matrix} X (x, τ) = s i n_{α} (x^{α}) E_{α} (- τ^{α}), \\ T (x, τ) = s i n_{α} (x^{α}) E_{α} (- τ^{α}) . \end{matrix}

(74)

After substituting

α = 1

into Equation (74), we obtain

{\begin{matrix} X (x, τ) = \sin (x) e^{- τ}, \\ T (x, τ) = \sin (x) e^{- τ} . \end{matrix}

(75)

Equation (66) can supply the exact solutions of Equation (38). Additionally, the LFETDM solutions of Equation (38) are same as both solutions obtained in [33] by the Yang–Laplace decomposition method and in [42] by the natural decomposition method.

The graph of the LFETDM solution for

a l p h a = 1

and the exact solution of the system (38) is shown in Figure 1.

The graph of LFETDM solutions for

a l p h a = 0.9, a l p h a = 0.8, a l p h a = 0.7, a l p h a = 0.6

and the exact solution of the system (38) is shown in Figure 2.

Example 2.

Consider the following coupled nonlinear system of local fractional KdV equations [39]:

{\begin{matrix} \frac{\partial^{a} X}{\partial τ^{a}} + \frac{\partial^{3 a} X}{\partial x^{3 a}} + 2 X X_{x}^{α} + 2 T X_{x}^{α} = 0, \\ \frac{\partial^{a} T}{\partial τ^{a}} + \frac{\partial^{3 a} T}{\partial x^{3 a}} + 2 T T_{x}^{α} + 2 X T_{x}^{α} = 0, \end{matrix} 0 < α \leq 1,

(76)

with the initial conditions

X (x, 0) = E_{α} (- x^{α}), T (x, 0) = - E_{α} (- x^{α}),

(77)

If we apply the LFET to both sides of each equation of the system in Equation (76),

{\begin{matrix} {}^{L F}E_{α} [X (x, τ)] = [v^{2 α} E_{α} (- x^{α})] - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{3 a} X}{\partial x^{3 a}} + 2 X X_{x}^{α} + 2 T X_{x}^{α}])]), \\ {}^{L F}E_{α} [T (x, τ)] = [- v^{2 α} E_{α} (- x^{α})] - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{3 a} T}{\partial x^{3 a}} + 2 T T_{x}^{α} + 2 X T_{x}^{α}])]) . \end{matrix}

(78)

By applying the inverse LFET to both sides of each equation in Equation (78), then we have

{\begin{matrix} X (x, τ) = E_{α} (- x^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{3 a} X}{\partial x^{3 a}} + 2 X X_{x}^{α} + 2 T X_{x}^{α}])]), \\ T (x, τ) = - E_{α} (- x^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{3 a} T}{\partial x^{3 a}} + 2 T T_{x}^{α} + 2 X T_{x}^{α}])]) . \end{matrix}

(79)

If the Adomian decomposition method is applied, then each function of the solution

(X, T)

is decomposed as an infinite series:

{\begin{matrix} X (x, τ) = \sum_{n = 0}^{\infty} X_{n} (x, τ), \\ T (x, τ) = \sum_{n = 0}^{\infty} T_{n} (x, τ), \end{matrix}

(80)

and the nonlinear terms can be decomposed as

X X_{x}^{α} = \sum_{n = 0}^{\infty} A_{n} (X),

(81)

T X_{x}^{α} = \sum_{n = 0}^{\infty} B_{n} (X, T),

(82)

T T_{x}^{α} = \sum_{n = 0}^{\infty} C_{n} (T),

(83)

and

X T_{x}^{α} = \sum_{n = 0}^{\infty} D_{n} (X, T) .

(84)

If Equations (80)–(84) are substituted in Equation (79), then we have

{\begin{matrix} \sum_{n = 0}^{\infty} X_{n} (x, τ) = E_{α} (- x^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{3 a}}{\partial x^{3 a}} (\sum_{n = 0}^{\infty} X_{n} (x, τ)) + 2 \sum_{n = 0}^{\infty} A_{n} (X) + 2 \sum_{n = 0}^{\infty} B_{n} (X, T)])]), \\ \sum_{n = 0}^{\infty} T_{n} (x, τ) = - E_{α} (- x^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{3 a}}{\partial x^{3 a}} (\sum_{n = 0}^{\infty} T_{n} (x, τ)) + 2 \sum_{n = 0}^{\infty} C_{n} (T) + 2 \sum_{n = 0}^{\infty} D_{n} (X, T)])]) . \end{matrix}

(85)

By comparing both sides of Equation (85), we obtain

X_{0} (x, τ) = E_{α} (- x^{α}),

(86)

X_{1} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{3 a} X_{0}}{\partial x^{3 a}} + 2 A_{0} (X) + 2 B_{0} (X, T)])]),

(87)

X_{2} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{3 a} X_{1}}{\partial x^{3 a}} + 2 A_{1} (X) + 2 B_{1} (X, T)])]),

(88)

X_{3} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{3 a} X_{2}}{\partial x^{3 a}} + 2 A_{2} (X) + 2 B_{2} (X, T)])]),

(89)

T_{0} (x, τ) = - E_{α} (- x^{α}),

(90)

T_{1} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{3 a} T_{0}}{\partial x^{3 a}} + 2 C_{0} (T) + 2 D_{0} (X, T)])]),

(91)

T_{2} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{3 a} T_{1}}{\partial x^{3 a}} + 2 C_{1} (T) + 2 D_{1} (X, T)])]),

(92)

T_{3} (x, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\frac{\partial^{3 a} T_{2}}{\partial x^{3 a}} + 2 C_{2} (T) + 2 D_{2} (X, T)])]),

(93)

and so on.

The first few components of

A_{n} (X),

B_{n} (X, T),

C_{n} (T)

and

D_{n} (X, T)

polynomials [39] are obtained as

A_{0} (X) = X_{0} X_{0, x}^{(α)},

(94)

A_{1} (X) = X_{0} X_{1, x}^{(α)} + X_{1} X_{0, x}^{(α)},

(95)

A_{2} (X) = X_{0} X_{2, x}^{(α)} + X_{2} X_{0, x}^{(α)} + X_{1} X_{1, x}^{(α)},

(96)

B_{0} (X, T) = T_{0} X_{0, x}^{(α)},

(97)

B_{1} (X, T) = T_{0} X_{1, x}^{(α)} + T_{1} X_{0, x}^{(α)},

(98)

B_{2} (X, T) = T_{0} X_{2, x}^{(α)} + T_{1} X_{1, x}^{(α)} + T_{2} X_{0, x}^{(α)},

(99)

C_{0} (X) = T_{0} T_{0, x}^{(α)},

(100)

C_{1} (T) = T_{0} T_{1, x}^{(α)} + T_{1} T_{0, x}^{(α)},

(101)

C_{2} (T) = T_{0} T_{2, x}^{(α)} + T_{2} T_{0, x}^{(α)} + T_{1} T_{1, x}^{(α)},

(102)

D_{0} (X, T) = X_{0} T_{0, x}^{(α)},

(103)

D_{1} (X, T) = X_{0} T_{1, x}^{(α)} + X_{1} T_{0, x}^{(α)},

(104)

D_{2} (X, T) = X_{0} T_{2, x}^{(α)} + X_{1} T_{1, x}^{(α)} + X_{2} T_{0, x}^{(α)},

(105)

and so on.

According to Equations (86)–(93) and Equations (94)–(105), the first terms of LFETDM of the system in Equation (76) are obtained as

X_{0} (x, τ) = E_{α} (- x^{α}),

(106)

X_{1} (x, τ) = E_{α} (- x^{α}) \frac{τ^{α}}{Г (1 + α)},

(107)

X_{2} (x, τ) = E_{α} (- x^{α}) \frac{τ^{2 α}}{Г (1 + 2 α)},

(108)

X_{3} (x, τ) = E_{α} (- x^{α}) \frac{τ^{3 α}}{Г (1 + 3 α)},

(109)

and

T_{0} (x, τ) = - E_{α} (- x^{α}),

(110)

T_{1} (x, τ) = - E_{α} (- x^{α}) \frac{τ^{α}}{Г (1 + α)},

(111)

T_{2} (x, τ) = - E_{α} (- x^{α}) \frac{τ^{2 α}}{Г (1 + 2 α)},

(112)

T_{3} (x, τ) = - E_{α} (- x^{α}) \frac{τ^{3 α}}{Г (1 + 3 α)},

(113)

and so on.

Thus, the local fractional series solutions of

X (x, τ)

and

T (x, τ)

are, respectively, obtained as

{\begin{matrix} X (x, τ) = \sum_{n = 0}^{\infty} X_{n} (x, τ), \\ T (x, τ) = \sum_{n = 0}^{\infty} T_{n} (x, τ), \end{matrix}

(114)

Therefore, the local fractional series solutions of the system in Equation (76) can be written in the form

{\begin{matrix} X (x, τ) = E_{α} (- x^{α}) \lim_{N \to \infty} \sum_{n = 0}^{N} \frac{τ^{n α}}{Г (1 + n α)}, \\ T (x, τ) = - E_{α} (- x^{α}) \lim_{N \to \infty} \sum_{n = 0}^{N} \frac{τ^{n α}}{Г (1 + n α)} . \end{matrix}

(115)

If Equation (115) is rewritten in a closed form, then the non-differentiable solutions of

X (x, τ)

and

T (x, τ)

are obtained as

{\begin{matrix} X (x, τ) = E_{α} (- x^{α}) E_{α} (τ^{α}), \\ T (x, τ) = - E_{α} (- x^{α}) E_{α} (τ^{α}) . \end{matrix}

(116)

By substituting

α = 1

into Equation (116), we obtain

{\begin{matrix} X (x, τ) = e^{- x + τ}, \\ T (x, τ) = - e^{- x + τ} . \end{matrix}

(117)

Equation (117) provides the exact solutions of Equation (76). Additionally, the LFETDM solutions of Equation (76) are the same as the solutions obtained in [42] by the LFRDTM.

Example 3.

Consider the following coupled nonlinear system of local fractional partial differential equations [33]. For

0 < α \leq 1,

{\begin{matrix} X_{τ}^{(α)} + T_{x}^{(α)} Z_{ν}^{(α)} - T_{ν}^{(α)} Z_{x}^{(α)} = - X, \\ T_{τ}^{(α)} + X_{x}^{(α)} Z_{ν}^{(α)} + X_{ν}^{(α)} Z_{x}^{(α)} = T, \\ Z_{τ}^{(α)} + X_{x}^{(α)} T_{ν}^{(α)} + X_{ν}^{(α)} T_{x}^{(α)} = Z, \end{matrix}

(118)

with the initial conditions

X (x, ν, 0) = E_{α} (x^{α} + ν^{α}), T (x, ν, 0) = E_{α} (x^{α} - ν^{α}), Z (x, ν, 0) = E_{α} (- x^{α} + ν^{α}) .

(119)

If we apply the LFET to both sides of each equation of the system in Equation (118),

{\begin{matrix} {}^{L F}E_{α} [X (x, ν, τ)] = [v^{2 α} E_{α} (x^{α} + ν^{α})] - v^{α} [({}^{L F}E_{α} [T_{x}^{(α)} Z_{ν}^{(α)} - T_{ν}^{(α)} Z_{x}^{(α)} + X])], \\ {}^{L F}E_{α} [T (x, ν, τ)] = [v^{2 α} E_{α} (x^{α} - ν^{α})] - v^{α} [({}^{L F}E_{α} [X_{x}^{(α)} Z_{ν}^{(α)} + X_{ν}^{(α)} Z_{x}^{(α)} - T])], \\ {}^{L F}E_{α} [Z (x, ν, τ)] = [v^{2 α} E_{α} (- x^{α} + ν^{α})] - v^{α} [({}^{L F}E_{α} [X_{x}^{(α)} T_{ν}^{(α)} + X_{ν}^{(α)} T_{x}^{(α)} - Z])] . \end{matrix}

(120)

By applying the inverse LFET on both sides of each equation of Equation (120), we have

{\begin{matrix} X (x, ν, τ) = E_{α} (x^{α} + ν^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [T_{x}^{(α)} Z_{ν}^{(α)} - T_{ν}^{(α)} Z_{x}^{(α)} + X])]), \\ T (x, ν, τ) = E_{α} (x^{α} - ν^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [X_{x}^{(α)} Z_{ν}^{(α)} + X_{ν}^{(α)} Z_{x}^{(α)} - T])]), \\ Z (x, ν, τ) = E_{α} (- x^{α} + ν^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [X_{x}^{(α)} T_{ν}^{(α)} + X_{ν}^{(α)} T_{x}^{(α)} - Z])]) . \end{matrix}

(121)

By applying the Adomian decomposition method (ADM), each function of the solution

(X, T, Z)

is decomposed as an infinite series

{\begin{matrix} X (x, ν, τ) = \sum_{n = 0}^{\infty} X_{n} (x, ν, τ), \\ T (x, ν, τ) = \sum_{n = 0}^{\infty} T_{n} (x, ν, τ), \\ Z (x, ν, τ) = \sum_{n = 0}^{\infty} Z_{n} (x, ν, τ), \end{matrix}

(122)

and the nonlinear terns can be decomposed as

T_{x}^{(α)} Z_{ν}^{(α)} = \sum_{n = 0}^{\infty} A_{n} (T, Z), T_{ν}^{(α)} Z_{x}^{(α)} = \sum_{n = 0}^{\infty} A_{n}^{'} (T, Z),

(123)

X_{x}^{(α)} Z_{ν}^{(α)} = \sum_{n = 0}^{\infty} B_{n} (X, Z), X_{ν}^{(α)} Z_{x}^{(α)} = \sum_{n = 0}^{\infty} B_{n}^{'} (X, Z),

(124)

X_{x}^{(α)} T_{ν}^{(α)} = \sum_{n = 0}^{\infty} C_{n} (X, T), X_{ν}^{(α)} T_{x}^{(α)} = \sum_{n = 0}^{\infty} C_{n}^{'} (X, T) .

(125)

If Equations (122)–(125) are substituted into Equation (121), then we have

{\begin{matrix} \sum_{n = 0}^{\infty} X_{n} (x, ν, τ) = E_{α} (x^{α} + ν^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\sum_{n = 0}^{\infty} A_{n} (T, Z) - \sum_{n = 0}^{\infty} A_{n}^{'} (T, Z) + \sum_{n = 0}^{\infty} X_{n} (x, ν, τ)])]), \\ \sum_{n = 0}^{\infty} T_{n} (x, ν, τ) = E_{α} (x^{α} - ν^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\sum_{n = 0}^{\infty} B_{n} (X, Z) + \sum_{n = 0}^{\infty} B_{n}^{'} (X, Z) - \sum_{n = 0}^{\infty} T_{n} (x, ν, τ)])]), \\ \sum_{n = 0}^{\infty} Z_{n} (x, ν, τ) = E_{α} (- x^{α} + ν^{α}) - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [\sum_{n = 0}^{\infty} C_{n} (X, T) + \sum_{n = 0}^{\infty} C_{n}^{'} (X, T) - \sum_{n = 0}^{\infty} Z_{n} (x, ν, τ)])]) . \end{matrix}

(126)

By comparing both sides of Equation (126), we obtain

X_{0} (x, ν, τ) = E_{α} (x^{α} + ν^{α}),

(127)

X_{1} (x, ν, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [A_{0} (T, Z) - A_{0}^{'} (T, Z) + X_{0} (x, ν, τ)])]),

(128)

X_{2} (x, ν, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [A_{1} (T, Z) - A_{1}^{'} (T, Z) + X_{1} (x, ν, τ)])]),

(129)

X_{3} (x, ν, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [A_{2} (T, Z) - A_{2}^{'} (T, Z) + X_{2} (x, ν, τ)])]),

(130)

T_{0} (x, ν, τ) = E_{α} (x^{α} - ν^{α}),

(131)

T_{1} (x, ν, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [B_{0} (X, Z) - B_{0}^{'} (X, Z) + T_{0} (x, ν, τ)])]),

(132)

T_{2} (x, ν, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [B_{1} (X, Z) - B_{1}^{'} (X, Z) + T_{1} (x, ν, τ)])]),

(133)

T_{3} (x, ν, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [B_{2} (X, Z) - B_{2}^{'} (X, Z) + T_{2} (x, ν, τ)])]),

(134)

Z_{0} (x, ν, τ) = E_{α} (- x^{α} + ν^{α}),

(135)

Z_{1} (x, ν, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [C_{0} (X, T) - C_{0}^{'} (X, T) + Z_{0} (x, ν, τ)])]),

(136)

Z_{2} (x, ν, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [C_{1} (X, T) - C_{1}^{'} (X, T) + Z_{1} (x, ν, τ)])]),

(137)

Z_{3} (x, ν, τ) = - {}^{L F}E {_{α}}^{- 1} (v^{α} [({}^{L F}E_{α} [C_{2} (X, T) - C_{2}^{'} (X, T) + Z_{2} (x, ν, τ)])]),

(138)

and so on.

The first few components of

A_{n} (T, Z), B_{n} (X, Z)

and

C_{n} (X, T)

polynomials [41] are obtained as

A_{0} (T, Z) = T_{0 x}^{(α)} Z_{0 ν}^{(α)},

(139)

A_{1} (T, Z) = T_{1 x}^{(α)} Z_{0 ν}^{(α)} + T_{0 x}^{(α)} Z_{1 ν}^{(α)},

(140)

A_{2} (T, Z) = T_{0 x}^{(α)} Z_{2 ν}^{(α)} + T_{2 x}^{(α)} Z_{0 ν}^{(α)} + T_{1 x}^{(α)} Z_{1 ν}^{(α)},

(141)

B_{0} (X, Z) = X_{0 x}^{(α)} Z_{0 ν}^{(α)},

(142)

B_{1} (X, Z) = X_{1 x}^{(α)} Z_{0 ν}^{(α)} + X_{0 x}^{(α)} Z_{1 ν}^{(α)},

(143)

B_{2} (X, Z) = X_{0 x}^{(α)} Z_{2 ν}^{(α)} + X_{2 x}^{(α)} Z_{0 ν}^{(α)} + X_{1 x}^{(α)} Z_{1 ν}^{(α)},

(144)

C_{0} (X, T) = X_{0 x}^{(α)} T_{0 ν}^{(α)},

(145)

C_{1} (X, T) = X_{1 x}^{(α)} T_{0 ν}^{(α)} + X_{0 x}^{(α)} T_{1 ν}^{(α)},

(146)

C_{2} (X, T) = X_{0 x}^{(α)} T_{2 ν}^{(α)} + X_{2 x}^{(α)} T_{0 ν}^{(α)} + X_{1 x}^{(α)} T_{1 ν}^{(α)},

(147)

and so on.

Additionally, the polynomials

A_{n}^{'}, B_{n}^{'}

and

C_{n}^{'}

are similarly computed.

According to Equations (127)–(138) and Equations (139)–(147), the first terms of the local fractional Elzaki transform decomposition method of the system Equation (118) are obtained as

X_{0} (x, v, τ) = E_{α} (x^{α} + ν^{α}),

(148)

X_{1} (x, v, τ) = - E_{α} (x^{α} + ν^{α}) \frac{τ^{α}}{Г (1 + α)},

(149)

X_{2} (x, v, τ) = E_{α} (x^{α} + ν^{α}) \frac{τ^{2 α}}{Г (1 + 2 α)},

(150)

X_{3} (x, v, τ) = - E_{α} (x^{α} + ν^{α}) \frac{τ^{3 α}}{Г (1 + 3 α)},

(151)

T_{0} (x, v, τ) = E_{α} (x^{α} - ν^{α}),

(152)

T_{1} (x, v, τ) = E_{α} (x^{α} - ν^{α}) \frac{τ^{α}}{Г (1 + α)},

(153)

T_{2} (x, v, τ) = E_{α} (x^{α} - ν^{α}) \frac{τ^{2 α}}{Г (1 + 2 α)},

(154)

T_{3} (x, v, τ) = E_{α} (x^{α} - ν^{α}) \frac{τ^{3 α}}{Г (1 + 3 α)},

(155)

and

Z_{0} (x, v, τ) = E_{α} (- x^{α} + ν^{α}),

(156)

Z_{1} (x, v, τ) = E_{α} (- x^{α} + ν^{α}) \frac{τ^{α}}{Г (1 + α)},

(157)

Z_{2} (x, v, τ) = E_{α} (- x^{α} + ν^{α}) \frac{τ^{2 α}}{Г (1 + 2 α)},

(158)

Z_{3} (x, v, τ) = E_{α} (- x^{α} + ν^{α}) \frac{τ^{3 α}}{Г (1 + 3 α)},

(159)

and so on.

Thus, the local fractional series solutions of

X (x, ν, τ),

T (x, ν, τ)

and

Z (x, ν, τ)

are, respectively, obtained as

{\begin{matrix} X (x, ν, τ) = \sum_{n = 0}^{\infty} X_{n} (x, ν, τ), \\ T (x, ν, τ) = \sum_{n = 0}^{\infty} T_{n} (x, ν, τ), \\ Z (x, ν, τ) = \sum_{n = 0}^{\infty} Z_{n} (x, ν, τ), \end{matrix}

(160)

Therefore, the local fractional series solutions of the system Equation (118) can be written in the form

{\begin{matrix} X (x, v, τ) = E_{α} (x^{α} + ν^{α}) \lim_{N \to \infty} \sum_{n = 0}^{N} \frac{{(- 1)}^{n} τ^{n α}}{Г (1 + n α)}, \\ T (x, v, τ) = E_{α} (x^{α} - ν^{α}) \lim_{N \to \infty} \sum_{n = 0}^{N} \frac{τ^{n α}}{Г (1 + n α)}, \\ Z (x, v, τ) = E_{α} (- x^{α} + ν^{α}) \lim_{N \to \infty} \sum_{n = 0}^{N} \frac{τ^{n α}}{Г (1 + n α)} . \end{matrix}

(161)

If Equation (161) is rewritten in a closed form, then the non-differentiable solutions of

X (x, v, τ), T (x, v, τ)

and

Z (x, v, τ)

are obtained as

{\begin{matrix} X (x, v, τ) = E_{α} (x^{α} + ν^{α}) E_{α} (- τ^{α}), \\ T (x, v, τ) = E_{α} (x^{α} - ν^{α}) E_{α} (τ^{α}), \\ Z (x, v, τ) = E_{α} (- x^{α} + ν^{α}) E_{α} (τ^{α}) . \end{matrix}

(162)

Additionally, Equation (163) is obtained from Equation (162) as [32]

{\begin{matrix} X (x, v, τ) = E_{α} (x^{α} + ν^{α} - τ^{α}), \\ T (x, v, τ) = E_{α} (x^{α} - ν^{α} + τ^{α}), \\ Z (x, v, τ) = E_{α} (- x^{α} + ν^{α} + τ^{α}) . \end{matrix}

(163)

By substituting

α = 1

into Equation (163), it is obtained as

{\begin{matrix} X (x, v, τ) = e^{x + v - τ}, \\ T (x, v, τ) = e^{x - v + τ}, \\ Z (x, v, τ) = e^{- x + v + τ} . \end{matrix}

(164)

The solutions in Equation (164) are the exact solutions of Equation (118). Additionally, the LFETDM solutions in Equation (163) are the same as the solution obtained in [32] by the Yang–Laplace decomposition method and in [41] by the natural decomposition method.

6. Discussion

It has observed from the solutions of a coupled nonlinear system of local fractional Burger equations that LFETDM, LFRDTM, the Yang–Laplace decomposition method and the natural decomposition method give the same results. Additionally, Figure 1 and Figure 2 show the results obtained by using LFETDM for Example 1. Besides, it has been observed that the solutions decrease as the alpha values move away from 1. Additionally, we saw from the solutions of a coupled nonlinear system of local fractional partial differential equations that LFETDM, the Yang–Laplace decomposition method, LFRDTM and the natural decomposition method give the same results. It is seen that the overall structure of the curve obtained from Maple software differs for different values of fractional order αlpha for Example 1.

7. Conclusions

The nonlinear systems of local fractional partial differential equations have been solved by the local fractional Elzaki transform decomposition method (LFETDM). Additionally, Figure 1 and Figure 2 show the results obtained by using LFETDM for Example 1. It has been seen that the solutions decrease as the alpha values move away from 1. Additionally, it has observed from the non-differentiable solutions of a coupled nonlinear system of local fractional partial differential equations that LFETDM, the Yang–Laplace decomposition method, LFRDTM and the natural decomposition method give the same results. In addition, it was seen that the overall structure of the graph obtained from Maple software differed for different values of fractional order αlpha. It has been shown that LFETDM is an effective algorithm. Additionally, it was shown that this algorithm provides the solution in a series form which converges quickly and successfully to the exact solution. Thus, it is concluded that LFETDM is reliable, effective and powerful in obtaining the analytical solutions for different classes of linear and nonlinear local fractionals of ordinary and partial differential equations.

Funding

This research received no external funding.

Data Availability Statement

Not applicable.

Conflicts of Interest

The author declares no conflict of interest.

References

Yang, X.J.; Baleanu, D.; Srivastava, H.M. Local Fractional Integral Transforms and Their Applications; Academic Press: London, UK, 2015. [Google Scholar]
Babakhani, A.; Daftardar-Gejji, V. On calculus of local fractional derivatives. J. Math. Anal. Appl. 2002, 270, 66–79. [Google Scholar] [CrossRef] [Green Version]
Sun, W. Some Hermite–Hadamard type inequalities for generalized h-preinvex function via local fractional integrals and their applications. Adv. Differ. Equ. 2020, 2020, 1–14. [Google Scholar] [CrossRef]
Yan, S.P.; Jafari, H.; Jassim, H.K. Local fractional Adomian decomposition and function decomposition methods for Laplace equation within local fractional operators. Adv. Math. Phys. 2014, 2014. [Google Scholar] [CrossRef]
Abdeljawad, T.; Rashid, S.; Hammouch, Z.; Chu, Y.M. Some new local fractional inequalities associated with generalized (s, m) (s, m)-convex functions and applications. Adv. Differ. Equ. 2020, 2020, 406. [Google Scholar] [CrossRef]
Yang, X.J.; Gao, F.; Tenreiro Machado, J.A.; Baleanu, D. Exact Travelling Wave Solutions for Local Fractional Partial Differential Equations in Mathematical Physics. In Mathematical Methods in Engineering. Nonlinear Systems and Complexity; Taş, K., Baleanu, D., Machado, J., Eds.; Springer: Cham, Switzerland, 2019; Volume 24. [Google Scholar] [CrossRef]
Wang, K.; Wang, K. A new analysis for Klein-Gordon model with local fractional derivative. Alex. Eng. J. 2020, 59, 3309–3313. [Google Scholar] [CrossRef]
Kumar, S.; Kumar, R.; Cattani, C.; Samet, B. Chaotic behaviour of fractional predator-prey dynamical system. Chaos Solitons Fractals 2020, 135, 109811. [Google Scholar] [CrossRef]
Ghanbari, B.; Kumar, S.; Kumar, R. A study of behaviour for immune and tumor cells in immunogenetic tumour model with non-singular fractional derivative. Chaos Solitons Fractals 2020, 133, 109619. [Google Scholar] [CrossRef]
Goufo, E.F.D.; Kumar, S.; Mugisha, S.B. Similarities in a fifth-order evolution equation with and with no singular kernel. Chaos Solitons Fractals 2020, 130, 109467. [Google Scholar] [CrossRef]
Kumar, S.; Nisar, K.S.; Kumar, R.; Cattani, C.; Samet, B. A new Rabotnov fractional-exponential function-based fractional derivative for diffusion equation under external force. Math. Methods Appl. Sci. 2020, 43, 4460–4471. [Google Scholar] [CrossRef]
Kumar, S.; Kumar, A.; Samet, B.; Gómez-Aguilar, J.F.; Osman, M.S. A chaos study of tumor and effector cells in fractional tumor-immune model for cancer treatment. Chaos Solitons Fractals 2020, 141, 110321. [Google Scholar] [CrossRef]
Kumar, S.; Ghosh, S.; Samet, B.; Goufo, E.F.D. An analysis for heat equations arises in diffusion process using new Yang-Abdel-Aty-Cattani fractional operator. Math. Methods Appl. Sci. 2020, 43, 6062–6080. [Google Scholar] [CrossRef]
Adda, F.B.; Cresson, J. About non-differentiable functions. J. Math. Anal. Appl. 2001, 263, 721–737. [Google Scholar] [CrossRef] [Green Version]
Carpinteri, A.; Cornetti, P.; Kolwankar, K.M. Calculation of the tensile and flexural strength of disordered materials using fractional calculus. Chaos Solitons Fractals 2004, 21, 623–632. [Google Scholar] [CrossRef]
Chen, W. Time–space fabric underlying anomalous diffusion. Chaos Solitons Fractals 2006, 28, 923–929. [Google Scholar] [CrossRef] [Green Version]
Chen, Y.; Yan, Y.; Zhang, K. On the local fractional derivative. J. Math. Anal. Appl. 2010, 362, 17–33. [Google Scholar] [CrossRef] [Green Version]
Chen, W.; Zhang, X.D.; Korošak, D. Investigation on fractional and fractal derivative relaxation-oscillation models. Int. J. Nonlinear Sci. Numer. Simul. 2010, 11, 3–10. [Google Scholar] [CrossRef]
He, J.H.; Wu, G.C.; Austin, F. The variational iteration method which should be followed. Nonlinear Sci. Lett. A 2010, 1, 1–30. [Google Scholar]
He, J.H. A new fractal derivation. Therm. Sci. 2011, 15, 145–147. [Google Scholar] [CrossRef]
Kolwankar, K.M.; Gangal, A.D. Fractional differentiability of nowhere differentiable functions and dimensions. Chaos Interdiscip. J. Nonlinear Sci. 1996, 6, 505–513. [Google Scholar] [CrossRef] [Green Version]
Kolwankar, K.M.; Gangal, A.D. Local fractional Fokker-Planck equation. Phys. Rev. Lett. 1998, 80, 214. [Google Scholar] [CrossRef] [Green Version]
Yang, X.J. Local fractional integral transforms. Prog. Nonlinear Sci. 2011, 4, 1–225. [Google Scholar]
Wazwaz, A.M. A reliable modification of Adomian decomposition method. Appl. Math. Comput. 1999, 102, 77–86. [Google Scholar] [CrossRef]
Ahmad, J.; Mohyud-Din, S.T.; Yang, X.J. Applications of local fractional decomposition method to integral equations. J. Sci. Arts 2014, 14, 81. [Google Scholar]
Jafari, H.; Jassim, H.K. Local fractional Adomian decomposition method for solving two dimensional heat conduction equations within local fractional operators. J. Adv. Math. 2014, 9, 2574–2582. [Google Scholar]
Yang, X.J.; Baleanu, D.; Zhong, W.P. Approximate solutions for diffusion equations on Cantor space-time. Proc. Rom. Acad. A 2013, 14, 127–133. [Google Scholar]
Yang, X.J.; Baleanu, D.; Lazaveric, M.P.; Cajic, M.S. Fractal boundary value problems for integral and differential equations with local fractional operators. Therm. Sci. 2015, 19, 959–966. [Google Scholar] [CrossRef]
Jassim, H.K. Local fractional Laplace decomposition method for nonhomogeneous heat equations arising in fractal heat flow with local fractional derivative. Int. J. Adv. Appl. Math. Mech. 2015, 2, 1–7. [Google Scholar]
Ziane, D.; Cherif, M.H.; Belghaba, K. Exact solutions for linear systems of local fractional partial differential equations. Malaya J. Mat. 2018, 6, 53–60. [Google Scholar] [CrossRef] [Green Version]
Ziane, D.; Baleanu, D.; Belghaba, K.; Cherif, M.H. Local fractional Sumudu decomposition method for linear partial differential equations with local fractional derivative. J. King Saud Univ. Sci. 2019, 31, 83–88. [Google Scholar] [CrossRef]
Ziane, D.; Cherif, M.H.; Cattani, C.; Belghaba, K. Yang-Laplace Decomposition Method for Nonlinear System of Local Fractional Partial Differential Equations. Appl. Math. Nonlinear Sci. 2019, 4, 489–502. [Google Scholar] [CrossRef] [Green Version]
Baleanu, D.; Tenreiro Machado, J.A.; Cattani, C.; Baleanu, M.C.; Yang, X.J. Local fractional variational iteration and decomposition methods for wave equation on Cantor sets within local fractional operators. Abst. Appl. Anal. 2014, 6, 48. [Google Scholar] [CrossRef]
Ma, X.J.; Srivastava, H.M.; Baleanu, D.; Yang, X.J. A new Neumann series method for solving a family of local fractional Fredholm and Volterra integral equations. Math. Probl. Eng. 2013, 7, 121. [Google Scholar] [CrossRef] [Green Version]
Yang, X.J. Local Fractional Functional Analysis and Its Applications; Asian Academic: Hong Kong, China, 2011. [Google Scholar]
Yang, X.J. Advanced Local Fractional Calculus and Its Applications; World Science: New York, NY, USA, 2012. [Google Scholar]
Yang, X.J.; Baleanu, D.; Machado, J.A.T. Mathematical aspects of the Heisenberg uncertainty principle within local fractional Fourier analysis. Bound. Value Probl. 2013, 1, 131. [Google Scholar] [CrossRef]
Srivastava, H.M.; Golmankhaneh, A.K.; Baleanu, D.; Yang, X.J. Local fractional Sumudu transform with application to IVPs on Cantor sets. Abstr. Appl. Anal. 2014, 8, 529. [Google Scholar] [CrossRef] [Green Version]
Kumar, S.; Kumar, A.; Baleanu, D. Two analytical methods for time-fractional nonlinear coupled Boussinesq–Burger’s equations arise in propagation of shallow water waves. Nonlinear Dyn. 2016, 85, 699–715. [Google Scholar] [CrossRef]
Zhu, Y.; Chang, Q.; Wu, S. A new algorithm for calculating Adomian polynomials. Appl. Math. Comput. 2005, 169, 402–416. [Google Scholar] [CrossRef]
Rawashdeh, M.S.; Al-Jammal, H. New approximate solutions to fractional nonlinear systems of partial differential equations using the FNDM. Adv. Differ. Equ. 2016, 1, 1–19. [Google Scholar] [CrossRef] [Green Version]
Jafari, H.; Jassim, H.K.; Baleanu, D.; Chu, Y.M. On the approximate solutions for a system of coupled Korteweg–de Vries equations with local fractional derivative. Fractals 2021, 29, 2140012. [Google Scholar] [CrossRef]

$Fractalfract 06 00167 g001 550$

Figure 1. A comparison of the LFETDM solution and the exact solution of the system (38).

$Fractalfract 06 00167 g001$

$Fractalfract 06 00167 g002 550$

Figure 2. A comparison of the LFETDM solutions for

a l p h a = 0.9, a l p h a = 0.8, a l p h a = 0.7, a l p h a = 0.6

and the exact solution of the system (38).

Figure 2. A comparison of the LFETDM solutions for

a l p h a = 0.9, a l p h a = 0.8, a l p h a = 0.7, a l p h a = 0.6

and the exact solution of the system (38).

$Fractalfract 06 00167 g002$

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

© 2022 by the author. 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

Anac, H. A Local Fractional Elzaki Transform Decomposition Method for the Nonlinear System of Local Fractional Partial Differential Equations. Fractal Fract. 2022, 6, 167. https://doi.org/10.3390/fractalfract6030167

AMA Style

Anac H. A Local Fractional Elzaki Transform Decomposition Method for the Nonlinear System of Local Fractional Partial Differential Equations. Fractal and Fractional. 2022; 6(3):167. https://doi.org/10.3390/fractalfract6030167

Chicago/Turabian Style

Anac, Halil. 2022. "A Local Fractional Elzaki Transform Decomposition Method for the Nonlinear System of Local Fractional Partial Differential Equations" Fractal and Fractional 6, no. 3: 167. https://doi.org/10.3390/fractalfract6030167

Article Menu

A Local Fractional Elzaki Transform Decomposition Method for the Nonlinear System of Local Fractional Partial Differential Equations

Abstract

1. Introduction

2. Preliminaries

3. Local Fractional Elzaki Transform

4. Local Fractional Elzaki Transform Decomposition Method

5. Applications

6. Discussion

7. Conclusions

Funding

Data Availability Statement

Conflicts of Interest

References

Share and Cite

Article Metrics

Article Access Statistics

Further Information

Guidelines

MDPI Initiatives

Follow MDPI