Title :
Stability of absorbing boundary conditions
Author_Institution :
Compaq Comput. Corp., Houston, TX, USA
fDate :
4/1/1999 12:00:00 AM
Abstract :
Higher order absorbing boundary conditions (ABCs) exhibit instabilities that can be detrimental to a wide class of finite-difference time-domain (FDTD) open-region simulations. Earlier works attributed the cause of instabilities to the intrinsic construction or makeup of the ABCs, and consequently to the pole-zero distribution of the transfer function that characterizes the boundary condition. We investigate the cause of instability, We focus on axial boundary conditions such as Higdon (1986, 1990), Bayliss-Turkel (1980), and Liao, and show through an empirical study that these ABCs are not intrinsically unstable in their original unmodified forms. Furthermore, we show that the instability typically observed in FDTD open-region simulations is caused by an artifact of the rectangular computational domain, contrary to previously conjectured hypotheses or theories. These findings will have strong implications that can aid in the construction of stable FDTD schemes
Keywords :
boundary-value problems; digital simulation; electromagnetic wave absorption; electromagnetic wave scattering; finite difference time-domain analysis; numerical stability; FDTD open-region simulations; absorbing boundary conditions stability; axial boundary conditions; finite-difference time-domain; higher order absorbing boundary conditions; instabilities; open-region simulations; pole-zero distribution; rectangular computational domain artifact; scattering problems; stable FDTD schemes; transfer function; Boundary conditions; Computational modeling; Electromagnetic scattering; Energy capture; Finite difference methods; Frequency response; Physics computing; Stability; Time domain analysis; Transfer functions;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
