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Antennas are simply lengths of conductive metal that
radiate radio signals into the air. Most common antennas are
designed to be one-quarter, sometimes one-half, the wavelength of
the radio signal they are to transmit/receive. Wavelength is
calculated with the formula: Wavelength (meters) = 300/frequency
(MHz)
. 
For example, Phoenix Contact wireless modules use frequencies
ranging from 902-928MHz, so based on this formula, the wavelength of
our radio signals are approximately one-third of a meter, or
one-foot.
Keeping in mind then that antennas are generally one-quarter
wavelength of the radio signal, our basic antennas for the 900MHz
are typically no more than 3 inches in height.
ANTENNA TYPES
There are wide varieties of antennas used for the transmission of
radio signals in the world today. The basic antenna is known as an
“omni-directional.” Omni antennas radiate their RF energy in all
directions, essentially outwards in a three-dimensional spherical
pattern. Omni antennas usually resemble vertical rods but can come
in other shapes as well. Some have horizontal rods of the same
length placed at their base to increase their performance/distance.
These are called “ground planes.”
Other antenna types include the “dipole”, where a section of wire,
one-half the wavelength, is positioned either horizontally or
vertically in the air to transmit signals. Dipoles emit their
signals in more of a two dimensional semi-circular or “doughnut”
pattern, the key being both the transmitter and receiver’s antennas
must be aligned the same (horizontally or vertically). Dipoles do
not require a ground-plane are considered “bi-directional,” in that
their signals travel in two opposite directions, depending on how
the antenna is oriented.
The more focused (uni-directional) type of antenna is called a
“Yagi.” A Yagi antenna is basically a standard one-half wavelength
antenna, but with additional “elements” placed in front of it to
focus the
energy for transmission in one direction. The “reflector” and
“director” elements are just similar-sized resonators spaced
appropriately to increase the strength and narrow the direction of
the signal prior to
transmission. Again, the key to successfully using Yagi antennas is
the correct orientation and alignment of the transmitting/receiving
antennas.
ANTENNA GAIN
Antenna "gain" is a word that seems to strike fear in the hearts
and minds of uninitiated radio users everywhere. It is often the
word used to refer to some sort of mysterious signal amplifier, yet
never really
understood. However, one antenna with a “higher” gain does not amplify
the signal more than another with "less" gain, as most people think.
An antenna with greater gain simply focuses the energy of the signal
differently.
To get a handle on "gain," let's talk about it in terms using a
megaphone. When you want to get your message across a noisy stadium
you can do two things with that megaphone to get the result: 1) you
can shout into it as loudly as possible, and 2) you can direct the
focused end of the megaphone toward the listener. The same two
actions can be applied to sending a radio signal farther. First you
can increase the transmit power (to a limit of 1 Watt for spread
spectrum radios, FCC Part 15), and second you can "aim" the power
that's radiating from the antenna toward the receiver. Aiming the
power is the "gain." Taking this one step further, if someone in the
stadium also had a megaphone and really wanted to hear what you had
to say they could put their megaphone to their ear and aim the open
end toward you, thereby focusing in on what's being transmitted from
your location. Likewise, a receiving radio gets "gain" by focusing
the direction of the "listening" antenna toward the source. In other
words, gain is simply how you focus the radiated energy at the
transmitter and how you focus the ear of the receiver.
Now, how does gain apply to the two types of antennas (omni and
yagi) most commonly used in spread spectrum industrial radio
installations? In very simple terms, omni antennas radiate transmit
power (the signal) in all directions (360 degrees) and listen for
incoming messages from all directions. Yagi (directional) antennas
focus their radiated transmit power in one direction and also listen
for incoming signals with a more focused ear. Yagi antennas,
therefore, tend to send a signal farther than omni antennas with the
same gain. Yagis are the megaphones in the antenna world.
For the majority of MCR-RAD applications, the standard 1/4 wave
whip unity-gain antennas purchased along with the equipment work
just fine. However, sometimes you need to send the signal further
and to do so, you must play within the rules laid out by the FCC in
Part 15 of their guidelines. The two rules of most interest to the
spread spectrum radio user are: 1) the maximum transmit power of the
spread spectrum radio is 1 Watt, and 2) the maximum gain of a spread
spectrum system must not exceed 6dB.
WHAT DOES “dB” STAND FOR?
Here’s the technical definition. “dBm” (often referred to simply
as “dB”) is the Power Ratio of the radio relative to 1mW. For
example, a 1mW power level is referred to as 0dB. Likewise, a
1000mW, or 1W, power level can be referred to as 30dB. A 1/1000mW
power level is –30dB, and the threshold sensitivity of an MCR-RAD,
which exceeds 1/10000000000mW, can be more easily expressed as
–110dB. As you can see, a MCR-RAD receiver doesn’t need to capture
very much energy from its transmitter in order to maintain a solid
lock and secure data.
Now let’s make this easier. Since many folks who use the MCR-RADs
are unfamiliar with radio theory and are simply looking for an
easy-to-use cable and conduit replacement, we reassure them it is
simply sufficient to know that 6dB of antenna gain (remember that
"gain" has to do with focusing the energy radiated from the antenna)
more or less doubles the distance a signal will travel with no
obstructions. For example, if a "no gain" (0dB) 1/4 wave omni
antenna sends a 1 Watt MCR-wireless device signal 4 miles in perfect
line-of-sight conditions, a 6dB gain antenna should send the signal
8 miles. In other words, we say "Don't worry about the specifics of
dB measurement, it's not necessary to be a radio expert."
How do antennas increase the distance like that? Simply put,
omni antennas that radiate energy in a sphere with no gain "squish
the sphere into a donut shape" as the gain is increased. The more
you “squish the sphere,” the larger the radius of the donut becomes.
Less energy sent vertically means more energy sent out in a
horizontal direction. In a similar fashion, a directional yagi
antenna takes the energy about to be radiated and focuses it in one
direction. Using an analogy, the higher the gain a yagi antenna has
the more narrowly its energy is focused, so that its "beam" changes
from a street lamp to a lighthouse to a laser as the gain is
increased. You can see why aiming becomes important with a high gain
yagi.
dB LOSES AND CABLING
Now, back to the FCC rules. At first glance, it may appear that if
you were using a 1 Watt MCR-wireless devices you would never need an
antenna that exceeds a 6dB rating, but this isn't quite true. The
6dB applies to the system and the system includes cables and
connectors as well as the antenna. But what do the cables and
connectors have to do with it? Cables and connectors have a "dB
loss" rating. For example, RG58 cable loses 16dB per 100', RG213
loses 7.6dB per 100' and LMR400 cable loses 3.9dB per 100'.
Connectors also have loss ratings, although they are minimal. So if
you have an application where you need to add quite a bit of cable
in order to get out of a building, or up a tower, these losses have
to be taken into account.
Here's an example. Let's say you have an MCR-RAD at a water
tank, nine miles away from your control room. You know you'll need
to get as much gain as possible to send the signal so you decide on
a 6dB directional yagi antenna, thinking this is the maximum antenna
gain you’re allowed. But let's say you've decided to put the yagi
antenna near the top of a tower close to the tank so that you can
clear a stand of trees and a few houses. The antenna will be 60 feet
in the air and the rest of the cable run adds another 40 feet. You
decide on LMR400 cable with a few connectors. Based on the cable
losses quoted above, this means that the total system loss will be
approximately -4dB. Add this to the antenna gain of +6dB and your
system now has a total gain of only 2dB. Will this get the signal
nine miles? Probably not. So in this case, you would need to
purchase a 10dB directional yagi so that once all the losses (-4dB)
are factored in you still end up with the maximum gain allowed (6dB)
and required.
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Sun Path for Chart
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choose what DC voltage your system
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