High-Order Schemes for Nonlinear Fractional Differential Equations

We propose high-order schemes for nonlinear fractional initial value problems. We split the fractional integral into a history term and a local term. We take advantage of the sum of exponentials (SOE) scheme in order to approximate the history term. We also use a low-order quadrature scheme to approximate the fractional integral appearing in the local term and then apply a spectral deferred correction (SDC) method for the approximation of the local term. The resulting one-step time-stepping methods have high orders of convergence, which make adaptive implementation and accuracy control relatively simple. We prove the convergence and stability of the proposed schemes. Finally, we provide numerical examples to demonstrate the high-order convergence and adaptive implementation.

Automated summary

This study proposes high-order schemes for solving nonlinear fractional initial value problems by approximating the fractional integral into history and local terms. The convergence and stability of the proposed schemes are proved and validated through numerical examples.