Local Fractional Laplace Variational Iteration Method for Fractal Vehicular Traffic Flow

We discuss the line partial differential equations arising in fractal vehicular traffic flow.The nondifferentiable approximate solutions are obtained by using the local fractional Laplace variational iteration method, which is the coupling method of local fractional variational iteration method and Laplace transform. The obtained results show the efficiency and accuracy of implements of the present method.


Introduction
Fractional differential equations with arbitrary orders were applied to model the real-world problems for science and engineering. Many researchers present their applications with solid mechanics, heat transfer, fluid mechanics, transport process, water motion, and quantum mechanics. For example, Tarasov studied the wave equation for fractal solid string based on the fractional calculus [1]. Momani and Odibat presented the linear, nonlinear, and fractional partial differential equations arising in fluid mechanics [2,3]. Povstenko suggested the fractional heat conduction equation [4], and Vázquez gave the second law of thermodynamics with fractional derivative [5]. Lutz considered the fractional transport equation for Levy stable processes [6], and Kadem et al. discussed its solution using the spectral method [7]. Laskin presented the fractional Schrodinger equation [8], and Muslih et al. suggested its solution [9]. There are many methods for finding the solutions to the fractional differentiable equations [10]. For example, Jafari and Seifi used the homotopy analysis method to deal with linear and nonlinear fractional diffusion-wave equations [11]. Jafari et al. applied the fractional subequation method to solve the Cahn-Hilliard and Klein-Gordon equations [12]. Hristov suggested the heat-balance integral method for fractional heat diffusion and transient flow [13,14]. Bhrawy and Alghamdi proposed the shifted Jacobi-Gauss-Lobatto collocation method to find the solution for nonlinear fractional Langevin equation with two variables [15] and the shifted Legendre spectral method for solving the fractional-order multipoint boundary value problems [16]. Bhrawy and Baleanu considered the spectral Legendre-Gauss-Lobatto collocation method to solve the space-fractional advection diffusion equations [17]. Atangana and Baleanu presented the two difference methods to solve the fractional parabolic equations [18].
Recently, the local fractional calculus is proposed and developed to describe the fractal problems in various fields, such as physics [19][20][21], applied mathematics [22,23], signal processing [24][25][26][27], fluid mechanics [28], quantum mechanics [29], fractal forest gap [30], vehicular traffic flow [31], and silk cocoon hierarchy [32]. The linear differential equation arising in fractal vehicular traffic flow was suggested in [31]. The local fractional Laplace variational iteration method was suggested in [23] and developed in [33]. In this paper, we use the local fractional Laplace variational iteration method to solve the linear differential equation arising in fractal vehicular traffic flow. The structure of the paper is suggested as follows. In Section 2, the basic theory of local fractional calculus and local fractional Laplace transform are introduced. Section 3 gives the local fractional Laplace variational 2 Advances in Mathematical Physics iteration method. In Section 4, the nondifferentiable solutions for line partial differential equations arising in fractal vehicular traffic flow are presented. Finally, the conclusions are considered in Section 5.

The Lighthill-Whitham-Richards Model on a Finite Length Highway
In this section, we present the Lighthill-Whitham-Richards model on a finite length highway, the conceptions of local fractional derivative and integral, and the local fractional Laplace transform. The Lighthill-Whitham-Richards model on a finite length highway reads as follows [31]: where the initial and boundary conditions are presented as follows: with for | − 0 | < , | − 0 | < for , , , > 0, 0 < < 1, and the local fractional partial derivative of ( ) of order is given as [19] with This is the line partial differential equation arising in fractal vehicular traffic flow. The local fractional derivative of ( ) of order is expressed as [19,20] where The local fractional integral of ( ) of order in the interval [ , ] is defined through [19,21,22] where the partitions of the interval [ , ] are ( , +1 ), with Δ = +1 − , 0 = , = , and Δ = max{Δ 0 , Δ 1 , Δ , . . .}, = 0, . . . , − 1.

Local Fractional Laplace Variational Iteration Method
In this section, we introduce the local fractional Laplace variational iteration method. Let us consider the following local fractional differential operator: where the linear local fractional differential operator is = ( / ) and ( ) is a nondifferential function.

3
According to the local fractional Laplace variational iteration method [23,33], the local fractional functional formula is presented as follows: Applying the local fractional Laplace transform gives the following: Taking the local fractional variation of (15), we obtain From (16) such that where Therefore, we get̃{ Using formula (20), we arrive at new iteration algorithm as follows: where the initial value reads as Thus, the local fractional series solution of (13) is

The Nondifferentiable Solutions for Line Partial Differential Equations Arising in Fractal Vehicular Traffic Flow
In this section, we present the boundary value problems for line partial differential equations arising in fractal vehicular traffic flow.
Example 1. The initial and boundary conditions for line partial differential equations arising in fractal vehicular traffic flow read as follows: In view of (21), we havẽ where the initial value is Making use of (26) and (27), we have the first approximatioñ 4

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In view of (26) and (28), we arrive at the second approximatioñ From (26) and (29), the third approximation is Applying (26) and (29) gives the fourth approximatioñ In view of (26) and (31), we give the fifth approximatioñ Therefore, we obtaiñ which reduces to and its graph is shown in Figure 1 with the parameters = ln 2/ ln 3 and = 2.
where the initial value is In view of (36) and (37), we get the first approximatioñ From (36) and (38), we obtain the second approximation as follows: Using (36) and (39), we have the third approximatioñ Making use of (36) and (40), we have the fourth approximatioñ Advances in Mathematical Physics From (36) and (41), we get the fifth approximation as follows: Thus, we obtain the local fractional series as follows: and its graph is shown in Figure 2.

Conclusions
In this paper, the boundary value problems for line partial differential equations arising in fractal vehicular traffic flow were solved by using the local fractional Laplace variational iteration method, which is the coupling method of local fractional variational iteration method (a generalization of variational iteration method based upon the local fractional calculus) and Laplace transform (a generalization of Fourier transform based upon the local fractional calculus). The nondifferentiable approximate solutions were obtained and their graphs were also shown.