Antenna SWR.
SWR
SWR (Standing wave Ratio)
is a measure of how well the antenna is matched to the transmitter. A poorly
matched antenna will not perform as well as if it were correctly tuned.
The Standing Wave Ratio is equal to the ratio of radio and antenna impedances. This
means that for a 50 Ohm radio, an impedance of 75 Ohms will give a
SWR reading of 1.5:1.
The SWR meter
The typical
CB SWR meter does not actually measure
standing waves. The standing wave ratio is calculated by measuring the amplitude of
the forward and reflected signal.
What is a good SWR reading ?
The best reading possible is 1:1, but a reading below 2:1 is often acceptable. It
must also be noted that many
CB
antennas are not exactly 50 Ohms and, as noted above, this will mean that the antenna
will not give a 1:1 reading even if tuned correctly.
Examples include the standard dipole, which has an impedance of 75 Ohms - giving
a 1.5:1 reading when correctly tuned.
Why bother?
There are several reasons why
SWR
is important. It is well known that a high
SWR means that not all the power is being
transmitted, and so a good
SWR
will ensure that you get the most signal out that you can.
There are also the dangers of damage to your transmitter and interference to nearby
equipment. This is discussed in more detail on the other pages in this section.
Coax length
Most radio enthusiasts have heard about the coax length issue. So let's clear
this one up now... As long as your antenna is correctly tuned,
COAX LENGTH DOES
NOT MATTER.
If changing your coax length appears to change your
SWR, then you have a problem with the antenna.
Rather than worrying about coax length, sort out the problem with
the antenna.
For those wanting to understand why coax length may appear to change the readings,
this topic is covered in more depth on the other pages in this section and the feeder
section.
SWR and efficiency.
Chart.
| SWR |
Radiated % |
Loss |
| 1 |
100 |
------- |
| 1.3 |
98.3 |
.08dB |
| 1.5 |
96 |
.18dB |
| 1.8 |
91.8 |
.36dB |
| 2 |
88.9 |
.51dB |
| 2.5 |
81.6 |
.86dB |
| 3 |
75 |
1.25dB |
| 3.5 |
69.1 |
1.61dB |
| 4 |
64 |
1.94dB |
| 5 |
55.6 |
2.55dB |
When using this chart, you should keep it in mind that reflected signal is only
one factor involved in antenna efficiency.
Antenna design, damage and aging can also make a large difference to efficiency.
Some of these may not show up on an SWR meter, as some do not change impedance while
others may be hidden by detuning the antenna to compensate for the problems which
you do not know exist.
This may sound strange but, as the meter is really only showing impedance ratio,
detuning the antenna changes it's impedance which may then cancel out the change
caused by the damage.
The SWR may appear OK, but the antenna will still not be working at it's best. It
can be important to also visually check the antenna for damage or water.
Effects of a high SWR.
Audio circuit feedback.
As the transmitter attempts to deal with reflected signal, which it was not
designed to cope with, this energy may get into other parts of the transmitter.
The effects of this can be squealing, buzzing, warbling and other unwanted
noises on your transmitted signal.
RF circuit feedback.
In really bad cases, or where a transmitter has a poor design (many CBs), reflected
signal can also cause the transmitter to lock on transmit or to go into
self-oscillation.
In this situation, the output is no longer under the control of the internal
circuits - and it may reach levels high enough to cook the output and any supply
feeding it.
Large supplies have disappeared in an equally large cloud of smoke due to this
kind of problem.
Transmitter damage.
Any energy reflected back must be dissipated in some way. That energy which reaches
the transmitter may be converted to heat. The transmitter, being designed to be used
with the correct antenna, may not be able to get rid of this heat effectively.
The resulting increased temperatures reduce the life span of the semiconductors
used in the output stages, and extreme temperatures can instantly destroy such
components.
Some components may also be unable to cope with the higher peak voltages created
by the combination of the transmitted and reflected wave.
Radiation pattern.
A poorly matched antenna can cause the feeder to radiate, resulting in a change to
the radiation pattern. This may not be helpful, as your signal may now be sent into
a nearby hill or even up into space.
More about feeder is included in the Feeder sub-section within this site.
Interference.
As any unwanted radiation may be at lower levels, closer to other electronic
equipment, interference to other devices is a real possibility.
Movement.
Moving or touching any part of your system may change any of the above effects. Even
touching nearby objects, while you have the microphone in your hand, can make the
above effects change in some way.
Changes may involve reduction, increase, or additional symptoms occurring.
