2019
DOI: 10.1016/j.rinam.2019.100080
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TGMFE algorithm combined with some time second-order schemes for nonlinear fourth-order reaction diffusion system

Abstract: In this article, a two-grid mixed finite element (TGMFE) method with some second-order time discrete schemes is developed for numerically solving nonlinear fourth-order reaction diffusion equation. The two-grid MFE method is used to approximate spatial direction, and some second-order θ schemes formulated at time t k−θ are considered to discretize the time direction. TGMFE method covers two main steps: a nonlinear MFE system based on the space coarse grid is solved by the iterative algorithm and a coarse solut… Show more

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Cited by 5 publications
(2 citation statements)
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“…The two-grid method, which was first proposed by Xu [29,30] as a highly efficient discretization method, has been widely used to solve nonsymmetric and nonlinear partial differential equations; see, for example, for elliptic problems [31,32], reaction-diffusion equations [33][34][35][36], miscible displacement problems [37,38], parabolic equations [39], and others [10,41]. It is also used to solve Schrödinger equations [42][43][44][45].…”
Section: Introductionmentioning
confidence: 99%
“…The two-grid method, which was first proposed by Xu [29,30] as a highly efficient discretization method, has been widely used to solve nonsymmetric and nonlinear partial differential equations; see, for example, for elliptic problems [31,32], reaction-diffusion equations [33][34][35][36], miscible displacement problems [37,38], parabolic equations [39], and others [10,41]. It is also used to solve Schrödinger equations [42][43][44][45].…”
Section: Introductionmentioning
confidence: 99%
“…Different fast algorithms, which cover the fast computation of time fractional derivative, fast algorithm of nonlinear problem in time, fast calculation of nonlinear problem in space, fast computation of Matrix and so forth, have different acceleration strategies and features. Jiang et al [36] proposed a fast method of the time Caputo fractional derivative, which can reduce the computing time resulted in by the nonlocality of fractional derivative; Liu et al [25], Liu et al [27], and Yin et al [14] considered the fast calculation for time FPDEs based on the Xu' s two-grid FE methods [26], which can reduce the calculating time yielded by the nonlinear term; Zhao et al [30] developed a fast Hermite FE algorithm to improve the computational efficiency of Matrix, and presented a block circulant preconditioner; Yuste and Quintana-Murillo [28] presented the fast and robust adaptive methods with finite difference scheme for the time fractional diffusion equations; Xu et al [22], Wu and Zhou [23] considered the parareal algorithms for solving the linear time fractional ordinary or partial differential equations (FO(P)DEs), respectively; Zeng et al [8] presented a unified stable fast time-stepping method for fractional derivative and integral operators. Recently, Liu et al [9] proposed a fast TT-M FE algorithm for time fractional water wave model, which is developed to deal with time-consuming problem of nonlinear iteration used in the standard nonlinear Galerkin FE method for nonlinear term.…”
Section: Introductionmentioning
confidence: 99%