Analysis of transient electromagnetic scattering from closed surfaces using a combined field integral equation

## Abstract In this paper, we analyze the transient electromagnetic response from three‐dimensional (3D) dielectric bodies using a time‐domain combined‐field integral equation. The solution method in this paper is based on the method of moments (MoM), which involves separate spatial and temporal te

## Abstract A marching‐on‐in‐time (MOT)‐based scheme for the analysis of transient scattering from closed surfaces characterized by an impedance boundary condition (IBC) is described. The time‐domain integral equations being solved involve no analytical approximation and are free of spurious soluti

## w x Figure Return loss simulated and measured in 17 for Figure far, the numerical applications of the methodology have relied on a direct LU factorization of the resulting matrix equation at a properly defined complex frequency s . Thus, 0 the GT᎐PML implementation is more attractive since it

## Abstract In this article, the multilevel UV algorithm is utilized to reduce both the memory requirement and CPU time in the time‐domain combined field integral equation (TD‐CFIE) method to analyze transient electromagnetic scattering from conducting structures.The UV method is kernel‐independent

Figure 6 Nonlinearity of PZT Figure 7 Hysteresis of PZT actuator which was controlled by a DrA converter. Many experiments have been done to test the PZT. A typical sample PZT is made of 30 pieces, and its radius is 10 mm. The curves of nonlinearity and hysteresis are shown in Figures 6 and 7. Its n