An implicit numerical scheme for a class of multi-term time-fractional diffusion equation

Kanth, A. S. V. Ravi; Garg, Neetu

doi:10.1140/epjp/i2019-12696-8

Cited by 16 publications

(6 citation statements)

References 28 publications

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“…Development of accurate fractional differential equation solution is a critical endeavor since it aids in understanding the qualitative characteristics of relevant phenomena and mechanisms in science and engineering. A significant amount of work has gone into developing numerical and analytical solutions for various fractional differential equations, including as linear and nonlinear fractional differential equations [16], non‐linear fractional Schrodinger equation [17], fractional telegraph equation [18], nonlinear fractional Klein–Gordon equation [19], time‐fractional gas dynamics equations [20], third‐order dispersive fractional partial differential equation [21], time‐fractional nonlinear coupled Boussinesq–Burger's equations [22], time fractional Black–Scholes European option pricing model [23], fractional vibration equation [24], time fractional diffusion model [25], fractional Drinfeld–Sokolov–Wilson equation [26], time fractional mobile–immobile advection–dispersion model [27], time‐fractional Fisher's equation [28], fractional order multi‐dimensional telegraph equation [29], multi‐term time‐fractional diffusion model [30], non‐linear space–time fractional Burgers–Huxley and reaction–diffusion equation [31], fractional immunogenetic tumors model [32], time‐fractional reaction–diffusion equation [33], fractional Kaup–Kupershmidt equation [34], time fractional multi‐dimensional heat equations [35], time‐fractional Brusselator reaction–diffusion system [36], Lotka–Volterra system of fractional differential equations [37], conformable Klein–Gordon equation [38], Kaup–Kupershmidt equation [39], time fractional Klein–Fock–Gordon equation [40], multi‐term time‐fractional advection–diffusion equation [41], fractional Lotka–Volterra population model [42] and others (see, e.g., [43–50]). The aim of this paper is to extend the scope of the natural transform decomposition method (NTDM) to the following time‐fractional Burgers–Huxley equation

\begin{matrix} lefttrue \\ D_{sans-serift}^{μ} u false(ζ, sans-serift false) = k {frakturu}_{ζ ζ} false(ζ, s... \end{matrix}

…”

Section: Introductionmentioning

confidence: 99%

Natural transform decomposition method for the numerical treatment of the time fractional Burgers–Huxley equation

Kanth

Aruna

Raghavendar

2022

Numerical Methods Partial

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In this article, we studied the time-fractional Burgers-Huxley equation using the natural transform decomposition method. The fractional operator is treated in the Caputo, Caputo-Fabrizio, and Atangana-Baleanu senses. We employed the natural transform with the Adomian decomposition process on time-fractional Burgers-Huxley equation to obtain the solution. To establish the uniqueness and convergence of the accomplished solution, the Banach's fixed point theorem is used. The obtained findings are visually shown in two-and three-dimensional graphs for various fractional orders. To illustrate the efficacy of the method under discussion, numerical simulations are provided. The proposed solution captures the behavior of the reported findings for various fractional orders. A comparative study was conducted to ascertain the proposed method's correctness. The findings of this study establish that the technique investigated is both efficient and accurate for solving nonlinear fractional differential equations that arise in science and technology.

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\begin{matrix} lefttrue \\ D_{sans-serift}^{μ} u false(ζ, sans-serift false) = k {frakturu}_{ζ ζ} false(ζ, s... \end{matrix}

…”

Section: Introductionmentioning

confidence: 99%

Natural transform decomposition method for the numerical treatment of the time fractional Burgers–Huxley equation

Kanth

Aruna

Raghavendar

2022

Numerical Methods Partial

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“…The exponential B‐spline technique is based on piece‐wise non‐polynomial functions and was developed by McCartin, 23 and it is the generalization of the cubic spline. Several differential equations have been solved by utilizing this method 24–30 . Using this technique, one can avail of the solution even between nodes, which is an advantage over the finite difference scheme.…”

Section: Introductionmentioning

confidence: 99%

A computational procedure and analysis for multi‐term time‐fractional Burgers‐type equation

Kanth

Garg

2022

Math Methods in App Sciences

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This paper presents a new numerical algorithm dealing with multi-term time-fractional Burgers-type equation involving the Caputo derivative. The proposed method consists of temporal discretization of L2 formula and spatial discretization using the exponential B-splines. The semi implicit approach is applied to discretize the nonlinear term u𝜕 x u. We adopt the Von-Neumann method to study stability. We also establish the convergence analysis. The proposed method is employed to solve a few numerical examples in order to test its efficiency and accuracy. Comparisons with the recent works confirm the efficiency and robustness of the proposed method.

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“…Te kinetic equation with two fractional derivatives of diferent orders describes subdifusive motion in velocity felds. Multiterm fractional diferential equations can model anomalous difusion phenomena in complex systems and highly heterogeneous aquifers [11][12][13][14]. Furthermore, the proposed model is used to discretize distributed-order derivatives in DEs.…”

Section: Introductionmentioning

confidence: 99%

Computational Study of Multiterm Time‐Fractional Differential Equation Using Cubic B‐Spline Finite Element Method

2022

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Due to the symmetry feature in nature, fractional differential equations precisely measure and describe biological and physical processes. Multiterm time-fractional order has been introduced to model complex processes in different physical phenomena. This article presents a numerical method based on the cubic B-spline finite element method for the solution of multiterm time-fractional differential equations. The temporal fractional part is defined in the Caputo sense while the B-spline finite element method is employed for space approximation. In addition, the four-point Gauss−Legendre quadrature is applied to evaluate the source term. The stability of the proposed scheme is discussed by the Von Neumann method, which verifies that the scheme is unconditionally stable. L 2 and L ∞ norms are used to check the efficiency and accuracy of the proposed scheme. Computed results are compared with the exact and available methods in the literature, which show the betterment of the proposed method.

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An implicit numerical scheme for a class of multi-term time-fractional diffusion equation

Cited by 16 publications

References 28 publications

Natural transform decomposition method for the numerical treatment of the time fractional Burgers–Huxley equation

Natural transform decomposition method for the numerical treatment of the time fractional Burgers–Huxley equation

A computational procedure and analysis for multi‐term time‐fractional Burgers‐type equation

Computational Study of Multiterm Time‐Fractional Differential Equation Using Cubic B‐Spline Finite Element Method

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