ABC | absorbing boundary condition |
BE | backward Euler method, BD1 |
BD2 | backward differentiation method, Gear 2 |
CAD | computer-aided design |
Ckt | circuit |
EFIE | electric field integral equation |
EM | electromagnetic |
EMM | electromagneticmodeling |
FDTD | finite difference time domain |
FE | forward Euler method |
FEM | finiteelement method |
FFT | fast Fourier transform |
FIR | digital filter nonrecursive |
FIT | finiteintegration technique |
IIR | digital filter with feedback |
KCL | Kirchhoff's current law |
KVL | Kirchhoff's voltage law |
MFM | multifunction method |
MFIE | magnetic field integralequation |
MNA | modified nodal analysis |
MOR | model order reduction |
NI | noise integrity |
PCB | printed circuit board |
PEEC | partial element equivalent circuit |
PI | power integrity |
PDE | partial differential equation |
PEC | perfect electric conductor |
PMC | perfect magnetic conductor |
PML | perfect matched layer |
PPP | parallel plane PEEC model |
PWTD | plane wave time domain |
RCS | radar cross section |
ROM | reduced order model |
SI | signal integrity |
SPICE | Simulation Program withIntegrated Circuit Emphasis |
TEM | transverse electromagnetic |
Theta,Θ | theta integration method |
TL | transmission line |
TLM | transmission line modeling method |
TR | trapezoidal method |
VFI | volume filament |
WRM | weighted residual method |
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