Stability and convergence analysis of a class of continuous piecewise polynomial approximations for time fractional differential equations
Provides a theoretical foundation for a class of numerical schemes for time fractional differential equations, but the analysis is limited to sufficiently smooth solutions and the method is an incremental extension of known backward differentiation formulae.
The authors propose continuous piecewise polynomial approximations for Caputo fractional derivatives in time fractional differential equations, proving local truncation error, global error, and A(π/2)-stability. Numerical experiments confirm the theory.
We propose and study a class of numerical schemes to approximate time fractional differential equations. The methods are based on the approximation of the Caputo fractional derivative by continuous piecewise polynomials, which is strongly related to the backward differentiation formulae for the integer-order case. We investigate their theoretical properties, such as the local truncation error and global error analyses with respect to a sufficiently smooth solution, and the numerical stability in terms of the stability region and $A(\fracπ{2})$-stability by refining the technique proposed in \cite{LubichC:1986b}. Numerical experiments are given to verify the theoretical investigations.