A short dipole provides another way of exciting a planar structure in [[EM.Picasso]]. A short dipole source acts like an infinitesimally small ideal current source. You can also use an incident plane wave to excite your planar structure in [[EM.Picasso]]. In particular, you need a plane wave source to compute the radar cross section of a planar structure. The direction of incidence is defined by the θ and Ï angles of the unit propagation vector in the spherical coordinate system. The default values of the incidence angles are θ = 180° and Ï = 0° corresponding to a normally incident plane wave propagating along the -Z direction with a +X-polarized E-vector. Huygens sources are virtual equivalent sources that capture the radiated electric and magnetic fields from another structure that was previously analyzed in another [[EM.Cube]] computational module.
<table><tr><td> [[Image:PMOM64A.png|thumb|550px|A multilayer planar structure containing a CPW line with a single coupled port and a lumped element on an overpassing metal strip.]]</td></tr></table>Â
=== Modeling Lumped Elements in EM.Picasso ===
=== Calculating Scattering Parameters Using Prony's Method ===
[[Image:PMOM71.png|thumb|600px|Minimum and maximum current locations of the standing wave pattern on a microstrip line feeding a patch antenna.]]
The calculation of the scattering (S) parameters is usually an important objective of modeling planar structures especially for planar circuits like filters, couplers, etc. As you saw earlier, you can use lumped sources like gaps and probes and even active lumped elements to calculate the circuit characteristics of planar structures. The admittance / impedance calculations based on the gap voltages and currents are accurate at RF and lower microwave frequencies or when the port transmission lines are narrow. In such cases, the electric or magnetic current distributions across the width of the port line are usually smooth, and quite uniform current or voltage profiles can easily be realized. At higher frequencies, however, a more robust method is needed for calculating the port parameters.
In practical planar structures for which you want to calculate the scattering parameters, each port line normally supports one, and only one, dominant propagating mode. Multi-mode transmission lines are seldom used for practical RF and microwave applications. Nonetheless, each port line carries a superposition of incident and reflected dominant-mode propagating signals. An incident signal, by convention, is one that propagates along the line towards the discontinuity, where the phase reference plane is usually established. A reflected signal is one that propagates away from the port plane. Prony's method can be used to extract the incident and reflected propagating and evanescent exponential waves from the standing wave data. From a knowledge of the amplitudes (expansion coefficients) of the incident and reflected dominant propagating modes at all ports, the scattering matrix of the multi-port structure is then calculated. In Prony's method, the quality of the S parameter extraction results depends on the quality of the current samples and whether the port lines exhibit a dominant single-mode behavior. Clean current samples can be drawn in a region far from sources or discontinuities, typically a quarter wavelength away from the two ends of a feed line.
Â
<table>
<tr>
<td> [[Image:PMOM71.png|thumb|600px|Minimum and maximum current locations of the standing wave pattern on a microstrip line feeding a patch antenna.]] </td>
</tr>
</table>
=== Defining Independent & Coupled Ports ===