Chapter 7: Antennas

Section 7.1: Antenna Basics

Review of terminology:

Elements - conducting portions of an antenna that radiate or receive signals
Polarization - orientation of electric field radiated by antenna
Feedpoint impedance - ratio of RF voltage to current at antenna feedpoint
Resonance - when feed point impedance is purely resistive, with no reactance
Radiation pattern - graph of signal strength in every direction
Azimuthal pattern - shows signal strength in horizontal directions (birds eye view)
Elevation pattern - shows signal strength in vertical directions (side view)
Lobes - regions in radiation pattern where signal is being radiated
Nulls - points at which radiation pattern is at a minimum
Isotropic antenna - radiates equally in every possible direction 9horizontal or vertical)
Omnidirectional antenna - radiates a signal of equal strength in every horizontal direction
Directional antenna - radiates preferentially in one or more directions
Gain - concentrating transmitted or received signals in a specific direction
dB - decibels, units of gain
- dBi = gain with respect to isotropic antenna
- dBd = gain with respect to dipole antenna

Dipoles

Dipole = 2 electrical polarities
Dipoles have a figure-8 radiation pattern, signal is strongest broadside to antenna
Actual ground installation changes radiation pattern
Half wave dipole - 1/2 wavelength total, feedpoint in center, each half of the dipole is 1/4 wavelength
Voltage: lowest at feedpoint, highest at ends
Current: highest at feedpoint, lowest at ends
Length of a dipole in feet: 492/f
Feedpoint impedance of center-fed, free-radiating dipole should be 72 Ohms
Becomes several THOUSAND Ohms when feedpoint is connected at the ends
Physical thickness of wire can electrically lengthen wire, meaning you need a shorter antenna
Height above ground affects resonant frequency
Insulation, nearby conductors, and method of insulation all affect resonant frequency and length of dipole
Start near free-space length, and use SWR/antenna tuner to trim dipole
Exam asks to approximate resonant length for dipole. Use 492/f - pick the closest value to that

Ground plane vertical antena:

Dipoleantenna, with missing half: ground plane acts as electric mirror
Ground plane consists of sheet of metal or ground radial wires
Often installed vertically, making them omnidirectional (good for VHF/UHF)
Base impedance is 35 Ohms (half of dipole)
Sloping ground radials down will increase impedance
Downward angle of 30-45 degrees will match 50 Ohm impedance of coax cable
Impedance increases as feed point moved further from the "center"
Start with half of the free-space 1/2 wavelength length: length in feet is 246/f
Example calculation: approximate length of 1/4 wave ground vertical antenna that is resonant at 28.5 MHz is:
- Free space length = fsl = 246/f = 246/28.5 = 8.6 ft

Mobile HF antennas;

Random wires:

Effect of height:

Feed point impedance and radiation pattern affected by antenna's physical height above ground
Presence of electrical image created in conducting ground below antenna affects performance
Image is electrically reversed
As antenna and image get closer, they start to short each other out
Close to ground level, feed point impedance is near zero
Above half wavelength, impedance varies. Goes through maxima and minima
Maxima at 1/4 wavelength, then 1 wavelength
Ground also affects radiation patterns: real radiation patterns composed of energy received by antenna, and energy reflected from ground
Direct and reflected signals take different times to travel, and may combine, cancel out, or anywhere in between
This leads to new lobes/nulls pattern
Depending on height, you can have most radiation going UP, or most radiation going out via side lobes

Polarization:

Polarization can affect amount of signal lost due to ground resistance
Radio waves reflected from ground: lower losses when polarization is parallel to ground
Radiation pattern consists of reflected waves combined with direct waves not reflected
Lower reflection loss means higher maximum signal strength
HF DX done with vertical antennas - lower losses at low angles (but at higher angles, still more effective than horizontally polarized)
Ground-mounted vertical: not polarized efficiently, but still generates stronger signals at lower angles of radiation from horizontally polarized antennas at lower heights
DX or HF bands use verticals, because horizontally polarized antennas require unreasonable hieghts

A capacitance hat on a mobile antenna is used to electrically lengthen/physically shorten an antenna
A corona ball on an HF mobile antenna reduces high voltage discharge from the tip of the antenna
A disadvantage of a shortened mobile antenna is a smaller bandwidth
A disadvantage of a directly-fed random-wire antenna is that you may experience RF burns if you touch it
To adjust the feedpoint impedance of a quarter wave ground plane vertical antenna, slope the radials downward
If a ground plane antenna's radials are changed from horizontal to downward, the feed point impedance increases (maximum angle makes them into a dipole, which has double the feed point impedance of a ground wave vertical antenna)
For a dipole antenna in free space, the radiation pattern is a figure-eight at right angles to the antenna
Antenna height affects horizontal (azimuthal) radiation pattern of a dipole by making antenna omnidirectional if low (less than 1/2 wavelength high)