Title :
The Body-of-Revolution Hybrid Implicit–Explicit Finite-Difference Time-Domain Method With Large Time Step Size
Author :
Chen, Juan ; Wang, Jianguo
Author_Institution :
Key Lab. for Phys. Electron. & Devices, Xi´´an Jiaotong Univ., Xian
fDate :
5/1/2008 12:00:00 AM
Abstract :
A novel body-of-revolution finite-difference time- domain method (BOR-FDTD) based on the hybrid implicit-explicit (HIE) difference is presented in this paper. The time step in this method is independent of mode number to. It is only determined by the spatial increments Deltar and Deltaz. Compared with the conventional BOR-FDTD method, this novel BOR-FDTD method has larger time step size, especially when the value of to is large. This novel BOR-FDTD method does not require the solution of tridiagonal matrices, and all the updates in this method are explicit. The stability condition of the proposed BOR-FDTD method is presented analytically, and the numerical performance is demonstrated through numerical examples.
Keywords :
electromagnetic fields; finite difference time-domain analysis; BOR-FDTD method; body-of-revolution; finite-difference time-domain method; implicit-explicit difference; stability condition; time step size; Finite difference methods; Helium; Lattices; Maxwell equations; Nuclear electronics; Numerical stability; Performance analysis; Stability analysis; Symmetric matrices; Time domain analysis; Body-of-revolution finite-difference time-domain method (BOR-FDTD) method; hybrid implicit–explicit (HIE)-FDTD method; hybrid implicit--explicit (HIE)-FDTD method; rotationally symmetric structures;
Journal_Title :
Electromagnetic Compatibility, IEEE Transactions on
DOI :
10.1109/TEMC.2008.922791
