Keywords:
antenna, electromagnetics, current source
Dipole antennas are the simplest and most widely used type of antenna. In the most basic setup, a dipole antenna is composed of an oscillating current/voltage source in between two electrodes. The frequency of the source will determine the wavelength of the electromagnetic radiation emitted from the antenna according to the dispersion relation
Most commonly, the electrodes will be 1/4 of the emitted wavelength. In this example, the antenna will be driven with a current oscillating with a frequency of 1 GHz. Therefore, the emitted wavelength will be roughly 30 cm, meaning we will make each of the electrodes 7.5 cm. This will make the total length of the antenna 15 cm, which is why dipole antennas are sometimes called half-wave antennas. It is easiest to drive the antenna when the electrodes are a quarter wavelength.
For more background information on dipole antennas, visit the Wikipedia page: https://en.wikipedia.org/wiki/Dipole_antenna
This simulation can be run with a VSimEM, VSimMD, or VSimPD license.
The Dipole Antenna example is accessed from within VSimComposer by the following actions:
The resulting Setup Window is shown Fig. 179.
In this simulation, we will excite the antenna and watch the dipole electromagnetic radiation emanate from the antenna. A distributed current source is used to apply the driving current. A volume for the current source and the functional form of the current is set under Field Dynamics \(\rightarrow\) CurrentDistriubtions \(\rightarrow\) DrivingCurrent. The user has the ability to set all three components of the current within the volume. In this example, we set the x-component of the current using the drivingCurrent spacetime function. The drivingCurrent function is a sine wave oscillating at 1 GHz to which a smooth turn on profile has been applied.
There are open boundaries on the walls of the simulation.
To run the simulation:
After performing the above actions, the results can be visualized as follows:
Un-check the E_y box, then check the box for E_magnitude. Then go back to the Colors Options and switch Fix Minimum to -.1. The magnitude of the electric field at the end of the simulation is shown in Fig. 182.