Efficient multistep methods for tempered fractional calculus: Algorithms and Simulations
Abstract
In this work, we extend the fractional linear multistep methods in [C. Lubich, SIAM J. Math. Anal., 17 (1986), pp.704--719] to the tempered fractional integral and derivative operators in the sense that the tempered fractional derivative operator is interpreted in terms of the Hadamard finite-part integral. We develop two fast methods, Fast Method I and Fast Method II, with linear complexity to calculate the discrete convolution for the approximation of the (tempered) fractional operator. Fast Method I is based on a local approximation for the contour integral that represents the convolution weight. Fast Method II is based on a globally uniform approximation of the trapezoidal rule for the integral on the real line. Both methods are efficient, but numerical experimentation reveals that Fast Method II outperforms Fast Method I in terms of accuracy, efficiency, and coding simplicity. The memory requirement and computational cost of Fast Method II are and , respectively, where is the number of the final time steps and is the number of quadrature points used in the trapezoidal rule. The effectiveness of the fast methods is verified through a series of numerical examples for long-time integration, including a numerical study of a fractional reaction-diffusion model.
Cite
@article{arxiv.1812.00676,
title = {Efficient multistep methods for tempered fractional calculus: Algorithms and Simulations},
author = {Ling Guo and Fanhai Zeng and Ian Turner and Kevin Burrage and George Em Karniadakis},
journal= {arXiv preprint arXiv:1812.00676},
year = {2018}
}