Page tree

Versions Compared


  • This line was added.
  • This line was removed.
  • Formatting was changed.


Or you can open the project directly from this page using this button. Make sure to select the Enable Guided Help before clicking this button.


<script src=""
<button class="gh-button gh-projectopen" onclick="runAwrScript('awrGhOpenProject','Dielectric_Resonator_Antenna.emp')">Open Install Example</button>

AWR Version 13


<button class="gh-button gh-green" title = "" onclick="window.location.href='' ">Download Project</button>

Design Notes

Dielectric Resonator Antenna

This example illustrates a dielectric resonator antenna on an infinite ground plane


The antenna consists of a rectangular solid box of a ceramic material (ER=16, tand=0.0007) shorted from one end, and fed by extended inner conductor of a coaxial cable from below. The excitation model is a short patch connected to the bottom of the probe, which is then excited as a lumped port. There is a narrow gap between the bottom ground and the probe.


The dielectric dice height is 15.9mm and it is introduced as a dielectric "via". The topmost air layer thickness depends on how far the Perfectly Matched Layer absorbing Boundary Condition is placed. The minimum frequency of interest is 1.5GHz which is 200mm lambda. The antenna is simulated for lambda/2 (100mm), lambda/4 (50mm) and lambda/8 (25mm) and named accordingly. For accurate representation of the circular probe shape RelativeMinCurveSize=0.05 is set under Mesh options. The response is insensitive to the distance of the Perfectly Matched Layer, even if it is brought closer than the recommended lambda/4. On the other hand, the computational overhead is small between lambda/8 and lambda/4, while lambda/2 is considerably more expensive. Thus lambda/4 appears to be a justified recommendation.

There are two resonances in the antenna. It is recommended to look at the field profile at the resonant frequencies. The conventional way is to make copies of the EM document, simulate it at a frequency of interest, and click the Show Currents/Fields annotation button on the toolbar after simulation. For first resonance at 2050MHz , looking at power flow in a y-directed cut plane of "DRA_Lambda_by_8_2050MHz" 3D view shows that the probe and the short circuit are strongly coupled, while the other side of the dice is cold. For the second resonance at 3100MHz, looking at the power flow in DRA_Lambda_by_8_31000MHz" is very different, representing essentially dielectrically loaded probe's monopole type resonance.

EM Structure 3D - DRA_Lambda_by_8_3100MHz

Image Modified

Graph - Smith

Image Modified

Graph - S_Data_Comparision

Image Modified

Graph - S11

Image Modified