Fast IMEX Time Integration of Nonlinear Stiff Fractional Differential Equations
Efficient long-time integration of nonlinear fractional differential equations is significantly challenging due to the integro-differential nature of the fractional operators. In addition, the inherent non-smoothness introduced by the inverse power-law kernels deteriorates the accuracy and efficienc...
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Zusammenfassung: | Efficient long-time integration of nonlinear fractional differential
equations is significantly challenging due to the integro-differential nature
of the fractional operators. In addition, the inherent non-smoothness
introduced by the inverse power-law kernels deteriorates the accuracy and
efficiency of many existing numerical methods. We develop two efficient first-
and second-order implicit-explicit (IMEX) methods for accurate time-integration
of stiff/nonlinear fractional differential equations with fractional order
$\alpha \in (0,1]$ and prove their convergence and linear stability properties.
The developed methods are based on a linear multi-step fractional Adams-Moulton
method (FAMM), followed by the extrapolation of the nonlinear force terms. In
order to handle the singularities nearby the initial time, we employ
Lubich-like corrections to the resulting fractional operators. The obtained
linear stability regions of the developed IMEX methods are larger than existing
IMEX methods in the literature. Furthermore, the size of the stability regions
increase with the decrease of fractional order values, which is suitable for
stiff problems. We also rewrite the resulting IMEX methods in the language of
nonlinear Toeplitz systems, where we employ a fast inversion scheme to achieve
a computational complexity of $\mathcal{O}(N \log N)$, where $N$ denotes the
number of time-steps. Our computational results demonstrate that the developed
schemes can achieve global first- and second-order accuracy for
highly-oscillatory stiff/nonlinear problems with singularities. |
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DOI: | 10.48550/arxiv.1909.04132 |