Title :
Convergence of the reverberation chambers to the equilibrium analyzed with the finite-difference time-domain algorithm
Author_Institution :
Dipt. di Elettromagnetismo e Bioingegneria, Univ. Politecnica delle Marche, Italy
Abstract :
Over recent years, reverberation chambers have been analyzed by many numerical techniques. This contribution studies how the finite-difference time-domain algorithm converges to the steady state conditions as a function of the cavity Q factor, changing the wall conductivity or the internal lossy media. By lowering the reflection coefficient of the chamber walls, the computation time could be considerably reduced without a significant effect on the field distribution for any analyzed antennas. The field distributions are strongly correlated when the conductivity of the wall is one hundredth of the copper conductivity or greater, whereas when the conductivity is lower the correlation between field distributions is low.
Keywords :
Q-factor; absorbing media; convergence of numerical methods; dipole antennas; electrical conductivity; electromagnetic compatibility; finite difference time-domain analysis; reverberation chambers; wire antennas; cavity Q factor; dipole; field distribution; finite-difference time-domain algorithm; internal lossy media; reflection coefficient; reverberation chamber convergence; steady state condition; wall conductivity; wire antenna; Algorithm design and analysis; Conductivity; Convergence; Distributed computing; Finite difference methods; Q factor; Reflection; Reverberation chamber; Steady-state; Time domain analysis; FDTD; Finite-difference time-domain; finite wall conductivity; numerical convergence; reverberation chambers; time constant;
Journal_Title :
Electromagnetic Compatibility, IEEE Transactions on
DOI :
10.1109/TEMC.2004.831904
