Optimal error estimates of an IPDG scheme for the resistive magnetic induction equation

Abstract

In this paper, we develop the framework for error analysis of a fully-discrete interior penalty discontinuous Galerkin (IPDG) scheme designed for the initial-boundary value problem associated with the resistive magnetic induction equation. We demonstrate the error estimates for semi-discrete IPDG schemes, in which the obtained convergence rates are optimal in the energy norm, but sub-optimal in the L2 -norm. For sufficiently smooth solution, we derive optimal a-priori error estimates in the L2 -norm O(h1+l) , where l denotes the polynomial degree and h mesh size. Furthermore, we extend the error analysis to the fully-discrete schemes. For the fully-discrete schemes, the optimal convergence rates are obtained in the energy norm and L2 -norm for both space and time using the backward Euler and second order backward difference schemes for time discretization. © 2023, The Author(s), under exclusive licence to Springer Nature Switzerland AG.