Perfectly matched layer media for an unconditionally stable three-dimensional ADI-FDTD method

## Abstract A perfectly matched layer (PML) is constructed for two‐dimensional (2D) unconditionally stable (US) FDTD method based on an approximate Crank‐Nicolson scheme. This novel PML preserves unconditional stability of the 2D US‐FDTD method and has very good absorbing performance. Numerical res

## Abstract In this article, the iterative alternating‐direction‐implicit finite‐difference time‐domain (ADI‐FDTD) method is used to simulate the resonator in electromagnetic field. This method is exactly the same as the original Crank–Nicolson (CN) method, while recognizing the ADI‐FDTD method as

We extend Berenger's perfectly matched layers PML to ( ) conducti¨e media. A finite-difference᎐time-domain FDTD algorithm with PML as an absorbing boundary condition is de¨eloped for solutions of Maxwell's equations in inhomogeneous, conducti¨e media. For a perfectly matched layer in a conducti¨e me

## Abstract In this paper, a novel two‐dimensional unconditionally stable finite‐difference time‐domain (2D US‐FDTD) method based on the Crank–Nicolson (CN) scheme is proposed. In particular, in the proposed 2D US‐FDTD method the field components are defined at only two time steps __n__ and __n + 1

In this paper, an accurate and computationally implicit 3D finite-difference time-domain (FDTD) method based on the unconditionally stable Crank-Nicolson scheme (3D CN-FDTD) is presented. The source excitation in 3D CN-FDTD is described and the numerical simulation of the 3D CN-FDTD method is demons