Abstract

The purpose of this paper is to investigate the approximate solution of the casting-mould heterogeneous system with Caputo derivative under the homotopy idea. The symmetry design of the system contains the integer partial differential equations and the fractional-order partial differential equations. We apply Yang transform homotopy perturbation method (T-HPM) to find the approximate solution of temperature distribution in the casting-mould heterogeneous system. The T-HPM is a combined form of Yang transform (T) and the homotopy perturbation method (HPM) using He’s polynomials. Some examples are provided to demonstrate the superiority of the suggested technique. The significant findings reveal that T-HPM minimizes the enormous without imposing any assumptions. Due to its powerful and robust support for nonlinear problems, this approach presents a remarkable appearance in the functional studies of fractal calculus.

1. Introduction

A differential problem of symmetry is a modification that generates the differential equation continuously in such a way that these symmetries can help to achieve the solution of the differential equation. Solving these equations is sometimes easier than solving the original differential equations. In the past few decades, nonlinear fractional differential equations (FDEs) in mathematical physics have been contending for a prominent role in a variety of fields, including biological research, applied science, signal processing, control theory, finance, and fractal dynamics [1–3]. Debnath [4] presents some recent applications of fractional calculus and obtained the numerical computation of fractional derivatives and integrals. Heydari et al. [5] applied the Legendre polynomials to obtain the numerical solution of nonlinear fractal-fractional optimal control problems. Wang and Wang [6] employed a semi-inverse method to obtain the fractal variational principles for two different types of discontinuous plasma physics. FDEs are the generalized forms of the integer-order differential equations but some nonlinear mathematical models of integer-order derivatives do not implement well in most of the circumstances [7–9]. This is because integer-order derivatives are limited operators that are unsuitable for infinite variance, whereas the fractional-order derivatives are global to account for neighborhood dominance.

Various types of differential equations with the fractional derivative can be used to precisely characterize many proceedings of physics and engineering. Khan et al. [10] constructed an operator using the Caputo fractional differentiation to validate the performance of this approach. The challenge of discovering approximate and exact solutions to FDEs is much critical. The homotopy perturbation technique (HPM) [11] is a well-known method for obtaining series solutions to a variety of linear and nonlinear differential equations of arbitrary order. Many powerful and efficient strategies have been proposed such as Laplace homotopy perturbation method [12], weighted least squares method [13], iterative method [14], homotopy perturbation Sumudu transform method [15], Elzaki transform decomposition approach [16], Laplace decomposition method [17], and natural homotopy transform method [18] with a logic sensitivity function and small diffusivity. Grzymkowski et al. [19] employed HPM whereas Tripathi and Mishra [20] adopted HPM together with the Laplace transform to determine the temperature distribution in the casting-mould heterogeneous system as a continuous function, which is particularly useful for analyzing the mould. Vanani et al. [21] used a weighted approach based on HPM to solve the heat equation in the cast-mould heterogeneous domain. Later, this proposed approach has also been examined in more than one spatial dimension, indicating that this method has a broader application in nonlinear PDE systems [22, 23]. This study is particularly powerful for fractal theory and fractal calculus, and it can be seen as dependable in getting analytical solutions and suitable for other nonlinear issues [24–26].

This study presents the idea of T-HPM to obtain the solution of casting-mould heterogeneous system with fractional order in Caputo sense. Yang transform coupled with the homotopy perturbation method presents the results in the form of series and this series approaches to the exact solution very rapidly. The quality of the current method is appropriate to provide the analytical results to the given examples. This study is summarized as follows: in Section 2, we start with some primary definitions in Caputo sense. In Sections 3 and 4, we formulate the problem for the implementation of T-HPM. In Section 6, we apply this scheme to two numerical problems to show its capability and efficiency. Results and discussion with concluding remarks are given in Sections 7 and 8.

2. Preliminary Concepts

In this segment, we demonstrate some fundamental properties of fractional calculus along with Yang transform, which help to construct the idea of T-HPM.

Definition 1. The fractional-order derivative in Caputo sense is given as [27]

Definition 2. Recently, Yang [28] introduced the Yang-Laplace transform that if is a function, then T can be written as

Definition 3. The inverse transform is defined as where is the inverse Yang operator.

Definition 4. The Yang transform for th derivatives is defined a [28]

Definition 5. The Yang transform for fractional-order derivatives is defined as [29]

3. Remarks

The T of some helpful expressions are as follows:

4. The Description of the Problem

In this segment, we formulate the casting-mould system to analyze the temperature distribution. Let us consider, two regions, indicating for casting and for mould on the boundary of the problem as shown in Figure 1, such that with the boundaries on these domains are distributed as

Figure 1 

Domain of the problem.

These functions satisfy the heat conduction equation inside the domains such as: where is the derivative of functions and order in Caputo sense, and are the thermal diffusivity, and represent the temperature, and and refer to the time and spatial, respectively [30]. These boundaries satisfy the following initial and boundary conditions:

The selection of these boundary conditions is an important task for the determination of the casting-mould problem.

5. Idea of T-HPM

In this part, we will demonstrate the concept of YHPTM. Let us assume fractional-order PDE such as where and are linear and nonlinear differential operators, respectively, and is called the source function. Applying the T to Equation (11),

By using inverse ,

However, HPM is stated as where is the homotopy parameter and

The following strategy can be operated to acquire He’s polynomials:

With the help of Equations (15) and (16), we can get Equation (14) such as

We can get the following terms by evaluating the components

Thus, we can summarize the set of Equation (19) in the series form such as

6. Numerical Examples

Case I: let us consider

Thus, system of Equation (9) becomes

Now, taking T and using its property definition, we get

Thus, inverse T takes place as

Using the initial condition Equation (21) into Equation (24), we get

Applying HPM to get with He’s polynomials, we get

Start with the initial condition to get the following iteration in the form of series

Consequently, the series may be demonstrated as: which can be written as follows

For , the above equations may reduce to the classical casting system

Case II: let us consider again

Thus, system of Equation (9) becomes

According to T-HPM, we get

Start with the initial condition to get the following iteration in the form of series

Consequently, the series may be demonstrated as: which can be written as follows:

For , the above equations may reduce to the classical casting system

7. Results and Discussion

In case I, Figures 2(a)–2(d) indicate the surface solution of casting system, whereas Figures 3(a)–3(d) indicates the surface solution of mould system, respectively, with fractional order , , , and at and . Figures 4 and 5 indicate the graphical results of and , respectively, for different values of at and . Table 1 represents the absolute error of the casting system, and Table 2 represents absolute error of the mould system.

(a) Surface solution of when

(b) Surface solution of when

(c) Surface solution of when

(d) Surface solution of when

(a) Surface solution of when
(b) Surface solution of when
(c) Surface solution of when
(d) Surface solution of when

Figure 2 

The surfaces solution of for distinct values of .

(a) Surface solution of when

(b) Surface solution of when

(c) Surface solution of when

(d) Surface solution of when

(a) Surface solution of when
(b) Surface solution of when
(c) Surface solution of when
(d) Surface solution of when

Figure 3 

Plot of for different values of

Figure 4 

The surfaces solution of for distinct values of .

Figure 5 

Plot of for different values of .

In case II, Figures 6(a)–6(d) indicate the surface solution of casting system with fractional order , , , and at and . Figure 7 indicates the graphical results of for different values of at and . However, the graphical results for the mould system remain same because only changing the initial condition in casting system is studied to show the performance of this approach in this case. Table 3 represents the absolute error of casting system.

(a) Surface solution of when

(b) Surface solution of when

(c) Surface solution of when

(d) Surface solution of when

(a) Surface solution of when
(b) Surface solution of when
(c) Surface solution of when
(d) Surface solution of when

Figure 6 

The surfaces solution of for distinct values of .