The price of wireless networking hardware has fallen dramatically in a very short time. Wireless adapters now come standard with many computers, and access points are commonplace. Even the price of antennas and related components has fallen sharply as high demand and extreme competition have driven the industry to an increasingly high-volume, low-margin business.
But this hasn’t stopped people from experimenting with finding out just how little it takes to build a working network. There is something almost magical about radio networking. Tales of war driving (and even war walking) aside, just imagine that today in many cities around the world, dozens of invisible networks exist on any given street corner. As you sit at a cafe eating your lunch, you may be completely unaware of the dozens of people simultaneously using the environment around you to communicate with people around the world. I believe that it is largely this mysterious, intangible aspect of unseen global communications that draws people to embark on their own antenna projects. The deeply rewarding feeling of making something useful out of virtually nothing is worth much more than saving a few dollars on a network component.
When comparing antenna designs, there are a number of important
factors to keep in mind. The first antenna property that people
usually refer to is
gain
.
The gain
of an antenna is a measurement of how well it radiates in the
direction you intend it to, measured in decibels. This measurement is
actually the antenna’s performance as compared to an
imaginary invention called an isotropic
radiator
(this is the i in
dBi). Imagine an infinitely small light suspended in the vacuum of
space. It radiates light equally in all directions, and by definition
has no gain in any direction. Now take this light and place it in the
head of a flashlight. Without increasing the brightness of the bulb,
you can turn the head of the flashlight to focus its beam in a
particular direction. This is gain. By directing the energy in a
particular direction, you both make the light cover a smaller area,
and appear to be brighter in the area it does cover. The higher the
gain, the tighter and brighter the beam appears to be. Also note that
antenna gain is
reciprocal
, meaning that it works for both
transmit and receive. Adding an antenna to either end of a radio link
will help performance for both ends of the link.
Another important
property to keep in mind when designing or
purchasing an antenna is that it must be tuned to the frequency for
which you are using it. An antenna that is well matched to the radio
it is connected to is said to have a
low Standing Wave
Ratio
, or SWR. The SWR of an antenna is measured using an
SWR meter or reflectometer. It is a measurement of how much energy
actually leaves the antenna versus how much energy is reflected back
at the radio from the antenna itself. At (legal) 802.11-power levels,
a badly mismatched antenna with a high SWR simply results in poor
performance. At higher power levels, a mismatched SWR can actually
damage your radio or amplifier. As we will see in the antenna designs
in this chapter, the antenna is tuned by manipulating a number of
factors, including the size of various active components, and their
relative distance away from reflective components.
One property of antennas that is frequently overlooked by beginners
is their front-to-back
ratio
. This is a measurement of how much
energy radiates in the expected direction (at the center of the
strongest beam) versus the average amount of energy radiated in the
opposite direction. A high front-to-back (or F/B) ratio
means that most of the energy goes in the direction that the antenna
is pointed. A low F/B ratio means that more energy is lost in the
reverse direction, potentially causing unwanted interference with
nearby devices. This is particularly important if you are using two
or more antennas adjacent to each other, pointed in different
directions. A higher F/B means that it is less likely that adjacent
antennas will interfere with each other.
Finally, one last important property of antennas to keep in mind is
their
polarization
.
Briefly, this refers to the orientation of the electrical and
magnetic parts of the radio wave as they leave the antenna.
Polarization is discussed in greater detail in [Hack #84]. There is also a comparison of the
various general types of antennas and their typical uses in [Hack #64].
The following hacks describe a number of inexpensive, highly effective antenna designs that you might find useful for your own wireless networking project.
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