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Volume 41, Issue 5
On Discrete Energy Dissipation of Maxwell's Equations in a Cole-Cole Dispersive Medium

Baoli Yin, Yang Liu, Hong Li & Zhimin Zhang

DOI: 10.4208/jcm.2210-m2021-0257

J. Comp. Math., 41 (2023), pp. 980-1002.

Published online: 2023-09

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  • Abstract

A simple criterion is studied for the first time for identifying the discrete energy dissipation of the Crank-Nicolson scheme for Maxwell’s equations in a Cole-Cole dispersive medium. Several numerical formulas that approximate the time fractional derivatives are investigated based on this criterion, including the L1 formula, the fractional BDF-2, and the shifted fractional trapezoidal rule (SFTR). Detailed error analysis is provided within the framework of time domain mixed finite element methods for smooth solutions. The convergence results and discrete energy dissipation law are confirmed by numerical tests. For nonsmooth solutions, the method SFTR can still maintain the optimal convergence order at a positive time on uniform meshes. Authors believe this is the first appearance that a second-order time-stepping method can restore the optimal convergence rate for Maxwell's equations in a Cole-Cole dispersive medium regardless of the initial singularity of the solution.

  • Keywords

Discrete energy dissipation, Crank-Nicolson scheme, Maxwell's equations, Shifted fractional trapezoidal rule, Mixed finite element methods.

  • AMS Subject Headings

65N06, 65B99

  • Copyright

COPYRIGHT: © Global Science Press

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@Article{JCM-41-980, author = {Yin , BaoliLiu , YangLi , Hong and Zhang , Zhimin}, title = {On Discrete Energy Dissipation of Maxwell's Equations in a Cole-Cole Dispersive Medium}, journal = {Journal of Computational Mathematics}, year = {2023}, volume = {41}, number = {5}, pages = {980--1002}, abstract = {

A simple criterion is studied for the first time for identifying the discrete energy dissipation of the Crank-Nicolson scheme for Maxwell’s equations in a Cole-Cole dispersive medium. Several numerical formulas that approximate the time fractional derivatives are investigated based on this criterion, including the L1 formula, the fractional BDF-2, and the shifted fractional trapezoidal rule (SFTR). Detailed error analysis is provided within the framework of time domain mixed finite element methods for smooth solutions. The convergence results and discrete energy dissipation law are confirmed by numerical tests. For nonsmooth solutions, the method SFTR can still maintain the optimal convergence order at a positive time on uniform meshes. Authors believe this is the first appearance that a second-order time-stepping method can restore the optimal convergence rate for Maxwell's equations in a Cole-Cole dispersive medium regardless of the initial singularity of the solution.

}, issn = {1991-7139}, doi = {https://doi.org/10.4208/jcm.2210-m2021-0257}, url = {http://global-sci.org/intro/article_detail/jcm/22017.html} }
TY - JOUR T1 - On Discrete Energy Dissipation of Maxwell's Equations in a Cole-Cole Dispersive Medium AU - Yin , Baoli AU - Liu , Yang AU - Li , Hong AU - Zhang , Zhimin JO - Journal of Computational Mathematics VL - 5 SP - 980 EP - 1002 PY - 2023 DA - 2023/09 SN - 41 DO - http://doi.org/10.4208/jcm.2210-m2021-0257 UR - https://global-sci.org/intro/article_detail/jcm/22017.html KW - Discrete energy dissipation, Crank-Nicolson scheme, Maxwell's equations, Shifted fractional trapezoidal rule, Mixed finite element methods. AB -

A simple criterion is studied for the first time for identifying the discrete energy dissipation of the Crank-Nicolson scheme for Maxwell’s equations in a Cole-Cole dispersive medium. Several numerical formulas that approximate the time fractional derivatives are investigated based on this criterion, including the L1 formula, the fractional BDF-2, and the shifted fractional trapezoidal rule (SFTR). Detailed error analysis is provided within the framework of time domain mixed finite element methods for smooth solutions. The convergence results and discrete energy dissipation law are confirmed by numerical tests. For nonsmooth solutions, the method SFTR can still maintain the optimal convergence order at a positive time on uniform meshes. Authors believe this is the first appearance that a second-order time-stepping method can restore the optimal convergence rate for Maxwell's equations in a Cole-Cole dispersive medium regardless of the initial singularity of the solution.

Baoli Yin, Yang Liu, Hong Li & Zhimin Zhang. (2023). On Discrete Energy Dissipation of Maxwell's Equations in a Cole-Cole Dispersive Medium. Journal of Computational Mathematics. 41 (5). 980-1002. doi:10.4208/jcm.2210-m2021-0257
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