Adv. Appl. Math. Mech., 16 (2024), pp. 1197-1222.
Published online: 2024-07
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In this paper, two numerical schemes for the multi-term fractional mixed diffusion and diffusion-wave equation (of order $α,$ with $0<α<2$) are developed to solve the initial value problem. Firstly, we study a direct numerical scheme that uses quadratic Charles Hermite and Newton (H2N2) interpolation polynomials approximations in the temporal direction and finite element discretization in the spatial direction. We prove the stability of the direct numerical scheme by the energy method and obtain a priori error estimate of the scheme with an accuracy of order $3−α.$ In order to improve computational efficiency, a new fast numerical scheme based on H2N2 interpolation and an efficient sum-of-exponentials approximation for the kernels is proposed. Numerical examples confirm the error estimation results and the validity of the fast scheme.
}, issn = {2075-1354}, doi = {https://doi.org/10.4208/aamm.OA-2023-0117}, url = {http://global-sci.org/intro/article_detail/aamm/23291.html} }In this paper, two numerical schemes for the multi-term fractional mixed diffusion and diffusion-wave equation (of order $α,$ with $0<α<2$) are developed to solve the initial value problem. Firstly, we study a direct numerical scheme that uses quadratic Charles Hermite and Newton (H2N2) interpolation polynomials approximations in the temporal direction and finite element discretization in the spatial direction. We prove the stability of the direct numerical scheme by the energy method and obtain a priori error estimate of the scheme with an accuracy of order $3−α.$ In order to improve computational efficiency, a new fast numerical scheme based on H2N2 interpolation and an efficient sum-of-exponentials approximation for the kernels is proposed. Numerical examples confirm the error estimation results and the validity of the fast scheme.