...
T3P
...
is
...
a
...
3D
...
parallel
...
finite-element
...
time-domain
...
solver
...
to
...
calculate
...
transient
...
field
...
response
...
of
...
a
...
electromagnetic
...
structure
...
to
...
imposed
...
fields,
...
and
...
dipole
...
or
...
beam
...
excitations.
...
In
...
our
...
approach,
...
Ampere's
...
and
...
Faraday's
...
laws
...
are
...
combined
...
and
...
integrated
...
over
...
time
...
to
...
yield
...
the inhomogeneous
...
vector
...
wave
...
equation
...
for
...
the
...
time
...
integral
...
of
...
the
...
electric
...
field
...
E
...
:
...
Latex |
---|
...
\begin{eqnarray*}\left( \epsilon \frac{\partial^2}{\partial t^2} + \sigma_{eff} \frac{\partial}{\partial t} + \nabla \times \mu^{-1}\nabla\times \right) \int^t \emph{E} d \tau = -\emph{J}
\end{eqnarray*}
|
...
with
...
permittivity
...
Latex |
---|
$\epsilon = \epsilon_0 \epsilon_r $ |
Latex |
---|
$\mu = \mu_0 \mu_r$
|
Latex |
---|
$\sigma_{ |
...
eff} = \tan \delta \cdot 2 \pi f \cdot \epsilon $
|
Latex |
---|
$f$ |
Latex |
---|
$\tan \delta $ |
The computational domain is discretized into curved tetrahedral elements and
Latex |
---|
$\int^t \emph{E}d \tau $ |
Latex |
---|
$ \emph{N}_i (x) $ |
Latex |
---|
\begin{eqnarray*} \int^t \emph{E} (\emph{x}, \tau) d \tau = \sum^{N_p}_{i=1} e_i (t) \cdot \emph{N}_i (x) \end{eqnarray*}
|
up to order
Latex |
---|
$p$ |
Latex |
---|
$N_1 = 6 $ |
Latex |
---|
$N_2 = 20 $ |
Latex |
---|
$N_6 = 216 $ |