Novel Patterns in Fractional-in-Space Nonlinear Coupled FitzHugh–Nagumo Models with Riesz Fractional Derivative
Abstract: In this paper, the Fourier spectral method is used to solve the fractional-in-space nonlinear coupled FitzHugh–Nagumo model.Numerical simulation is carried out to elucidate the diffusion behavior of patterns for the fractional 2D and 3D FitzHugh–Nagumo model. The results of numerical experiments are consistent with the theoretical results of other scholars, which verifies the accuracy of the method. We show that stable spatio-temporal patterns can be sustained for a long time; these patterns are different from… Show more
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Cited by 21 publications
References 40 publications
Ginzburg–Landau equation with fractional Laplacian on a upper- right quarter plane
We consider the initial-boundary value problem for the Ginzburg–Landau equation with fractional Laplacian on a upper-right quarter plane { u t ( t , x ) − ∇ β u ( t , x ) = | u ( t , x ) | σ u ( t , x ) , x ∈ D , t > 0 u ( 0 , x ) = u 0 ( x ) , x ∈ D , u | x i = 0 = h j ( t , x j ) , x j > 0 , j = 1 , 2 , t > 0 , where D = { x 1 > 0 , x 2 > 0 } , β ∈ ( 3 2 , 2 ) , σ > 0 and ∇ β is a fractional Laplacian defined as ∇ β u = ∑ j 1 Γ ( 2 − β ) ∫ 0 x j u y j y j ( x j − y j ) β − 1 d y . We study the main questions of the theory of IBV- problems for nonlocal equations: the existence and uniqueness of a solution, the asymptotic behavior of the solution for large time and the influence of initial and boundary data on the basic properties of the solution. We generalize the concept of the well-posedness of IBV- problem in the L 2 − based Sobolev spaces to the case of a multidimensional domain. We also give optimal relations between the orders of the Sobolev spaces to which the initial and boundary data belong. The lower order compatibility conditions between initial and boundary data are also discussed.
Ginzburg–Landau equation with fractional Laplacian on a upper- right quarter plane
We consider the initial-boundary value problem for the Ginzburg–Landau equation with fractional Laplacian on a upper-right quarter plane { u t ( t , x ) − ∇ β u ( t , x ) = | u ( t , x ) | σ u ( t , x ) , x ∈ D , t > 0 u ( 0 , x ) = u 0 ( x ) , x ∈ D , u | x i = 0 = h j ( t , x j ) , x j > 0 , j = 1 , 2 , t > 0 , where D = { x 1 > 0 , x 2 > 0 } , β ∈ ( 3 2 , 2 ) , σ > 0 and ∇ β is a fractional Laplacian defined as ∇ β u = ∑ j 1 Γ ( 2 − β ) ∫ 0 x j u y j y j ( x j − y j ) β − 1 d y . We study the main questions of the theory of IBV- problems for nonlocal equations: the existence and uniqueness of a solution, the asymptotic behavior of the solution for large time and the influence of initial and boundary data on the basic properties of the solution. We generalize the concept of the well-posedness of IBV- problem in the L 2 − based Sobolev spaces to the case of a multidimensional domain. We also give optimal relations between the orders of the Sobolev spaces to which the initial and boundary data belong. The lower order compatibility conditions between initial and boundary data are also discussed.
This paper studies a quantum particle traveling in a fractal space-time, which can be modelled by a fractional modification of the Schrödinger equation with variable coefficients. The Fourier spectral method is used to reveal the solution properties numerically, and the fractal properties are illustrated graphically by choosing different coefficients and different fractional orders. Some novel isosurface plots of the dynamics of pattern formation in fractional Schrödinger equation with variable coefficients are shown. Keywords: Fractal wave propagation; Multi-dimensional; Schrödinger equation; Fractal symmetry; Fourier spectral method.
Numerical Simulation of the Fractional-Order Lorenz Chaotic Systems with燙aputo Fractional Derivative
Although some numerical methods of the fractional-order chaotic systems have been announced, high-precision numerical methods have always been the direction that researchers strive to pursue. Based on this problem, this paper introduces a high-precision numerical approach. Some complex dynamic behavior of fractional-order Lorenz chaotic systems are shown by using the present method. We observe some novel dynamic behavior in numerical experiments which are unlike any that have been previously discovered in numerical experiments or theoretical studies. We investigate the influence of α 1 , α 2 , α 3 on the numerical solution of fractional-order Lorenz chaotic systems. The simulation results of integer order are in good agreement with those of other methods. The simulation results of numerical experiments demonstrate the effectiveness of the present method.
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