Numerical solution of time domain integral equations for arbitrarily shaped conductor/dielectric composite bodies

In this work, we present a new and efficient numerical method to sol¨e the coupled integral equations, deri¨ed utilizing the equi¨alence principle for arbitrarily shaped dielectric bodies, directly in the time domain. The solution method is based on the method of moments, and in¨ol¨es the triangular

## Abstract In this work, we present a new and efficient numerical method to obtain an unconditionally stable solution for the time‐domain magnetic‐field integral equation (TD‐MFIE) for arbitrarily closed conducting bodies. This novel method does not utilize the customary marching‐on‐in‐time (MOT)

## Abstract Optimal symplectic integrators were proposed to improve the accuracy in numerical solution of time‐domain Maxwell's equations. The proposed symplectic scheme has almost the same stability and numerical dispersion as the mostly used fourth‐order symplectic scheme, but acquires more effic

An unconditionally stable precise integration time-domain method is extended to 3-D circular cylindrical coordinates to solve Maxwell's equations. In contrast with the cylindrical finite-difference time-domain method, not only can it remove the stability condition restraint, but also make the numeri