Backward difference formula: The energy technique for subdiffusion equation
Abstract
Based on the equivalence of A-stability and G-stability, the energy technique of the six-step BDF method for the heat equation has been discussed in [Akrivis, Chen, Yu, Zhou, Math. Comp., Revised]. Unfortunately, this theory is hard to extend the time-fractional PDEs. In this work, we consider three types of subdiffusion models, namely single-term, multi-term and distributed order fractional diffusion equations. We present a novel and concise stability analysis of time stepping schemes generated by -step backward difference formula (BDF), for approximately solving the subdiffusion equation. The analysis mainly relies on the energy technique by applying Grenander-Szeg\"{o} theorem. This kind of argument has been widely used to confirm the stability of various -stable schemes (e.g., ). However, it is not an easy task for the higher-order BDF methods, due to the loss the -stability. The core object of this paper is to fill in this gap.
Cite
@article{arxiv.2010.13068,
title = {Backward difference formula: The energy technique for subdiffusion equation},
author = {Minghua Chen and Fan Yu and Zhi Zhou},
journal= {arXiv preprint arXiv:2010.13068},
year = {2023}
}
Comments
23 pages, 4 figures