Jithin D. George, Samuel Y. Jung, Niall M. Mangan
Published 2021-10-08, updated 2022-12-04Version 4
Most numerical methods for time integration use real time steps. Complex time steps provide an additional degree of freedom, as we can select the magnitude of the step in both the real and imaginary directions. By time stepping along specific paths in the complex plane, integrators can gain higher orders of accuracy or achieve expanded stability regions. We show how to derive these paths for explicit and implicit methods, discuss computational costs and storage benefits, and demonstrate clear advantages for complex-valued systems like the Schrodinger equation. We also explore how complex time stepping also allows us to break the Runge-Kutta order barrier, enabling 5th order accuracy using only five function evaluations for real-valued differential equations.
Comments: 30 pages, 15 figures
Evaluation of Abramowitz functions in the right half of the complex plane
An efficient method for counting the eigenvalues inside a region in the complex plane
Comparing the geometry of the basins of attraction, the speed and the efficiency of several numerical methods
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