Eigenvalue perturbation theory is applied to justify using complex-valued linear scalar test equations to characterize the stability of implicit-explicit general linear methods (IMEX GLMs) solving autonomous linear ordinary differential equations (ODEs) when the implicitly treated term is sufficiently stiff relative to the explicitly treated term. The stiff and non-stiff matrices are not assumed to be simultaneously diagonalizable or triangularizable and neither matrix is assumed to be symmetric or negative definite. The stability of IMEX GLMs solving complex-valued scalar linear ODEs displaying parabolic and hyperbolic stiffness is analyzed and related to the higher dimensional theory. The utility of the theoretical results is highlighted with a stability analysis of a family of IMEX Runge-Kutta methods solving IVPs of a linear 2D shallow-water model and a linear 1D advection-diffusion model.
Partitioned and implicit-explicit general linear methods for ordinary differential equations
Convergence Results for Implicit--Explicit General Linear Methods
Energy harvest via parametric super-resonance and temporal homogenization of linear ODEs
![QR code for arXiv:1806.07478 [math.NA]](http://oss.arxitics.com/images/favicon.svg)