RF VISION. WHAT YOU ALWAYS WANTED TO KNOW, A TUTORIAL.The “Poor Man’s Spectrum Analyzer” is designed to give you RF VISION. WithRF VISION you will have a new monitoring mode, with rapid signal detection,modulation analysis, and band condition and activity information constantly available atyour finger tips! This instrument will provide information and operating techniques thatwill add to your appreciation of the RF spectrum in ways you never thought possiblebefore. As an educational tool, it will allow you to actually Electronic Spectrumin “real time”. It will help you understand the real significance of sidebands, and helpdebunk the myth that “the amplitude of the carrier varies in AM, but not in FM”. You willsee that the exact true! More on that later.What we are describing is an instrument that converts any ‘scope from a TIME display into a FREQUENCY display. Spectrum Analyzers havebeen around as laboratory instruments for many years, ranging in price from $4000 to$50,000. What makes this one so special is it’s simplicity and ultra low cost. TheSpectrum Analyzer we will build consists of six individual modules. The addition of aseventh module (Tracking Generator) converts the Spectrum Analyzer into a powerfulreceiver system for stimulus-response measurements. More on that later.WHAT’S IT ALL ABOUT?First, lets talk a bit about the “Spectrum”. Radio, television, and radartransmitters are constantly radiating energy into our environment. This ...
RF VISION. WHAT YOU ALWAYS WANTED TO KNOW,
A TUTORIAL.
The “Poor Man’s Spectrum Analyzer” is designed to give you RF VISION. With
RF VISION you will have a new monitoring mode, with rapid signal detection,
modulation analysis, and band condition and activity information constantly available at
your finger tips! This instrument will provide information and operating techniques that
will add to your appreciation of the RF spectrum in ways you never thought possible
before. As an educational tool, it will allow you to actually Electronic Spectrum
in “real time”. It will help you understand the real significance of sidebands, and help
debunk the myth that “the amplitude of the carrier varies in AM, but not in FM”. You will
see that the exact true! More on that later.
What we are describing is an instrument that converts any ‘scope from a TIME
display into a FREQUENCY display. Spectrum Analyzers have
been around as laboratory instruments for many years, ranging in price from $4000 to
$50,000. What makes this one so special is it’s simplicity and ultra low cost. The
Spectrum Analyzer we will build consists of six individual modules. The addition of a
seventh module (Tracking Generator) converts the Spectrum Analyzer into a powerful
receiver system for stimulus-response measurements. More on that later.
WHAT’S IT ALL ABOUT?
First, lets talk a bit about the “Spectrum”. Radio, television, and radar
transmitters are constantly radiating energy into our environment. This energy is called
“electromagnetic radiation”. Broadcast radio transmitters radiate energy in a band of
frequencies ranging from approximately 500 to 1500 Kilohertz. Commercial FM
transmitters operate in the 88 to 108 Megahertz band. Television and radar signals are
located in the VHF, UHF and microwave bands. The basic difference between these
transmitters is their frequency. If we continue to even higher frequencies, we get into
the realm of infrared radiation. This band of frequencies are so high that we perceive
them in the form of heat, even though they are a form of electromagnetic energy. Going
even higher in frequency, we get into the area of light, starting with red light at lower
end of the band, green at the center and violet at the upper end. Going a bit higher
takes us into the ultraviolet range of frequencies. Energy in this range of frequencies
becomes invisible again, but causes certain materials to fluoresce. Above ultraviolet
frequencies are the X-Rays, Gamma Rays, etc. All are forms of electromagnetic
radiation, with the basic difference being their frequency! Incidentally, all
electromagnetic radiation travels at the speed of light.
Draw a horizontal line on a sheet of paper. Label it “Frequency”. Mark the
location of all the different signals we have discussed along it’s length, with the
TV/FM X RaysBroadcast
Low High
Fig.1
Frequency
Heat/Light
DOMAlN DOMAlN
OPPOSlTEis
SEEthe
DIDN’T KNOW WHO TO ASK!
BUTRF VISION. WHAT YOU ALWAYS WANTED TO KNOW, BUT
A TUTORIAL.
Broadcast Band at the left (LO-Frequency) end and the X-Rays at the right
(HI-Frequency) end. What we have drawn is a simple representation of a major
portion of the ELECTROMAGNET/C SPECTRUM.
There is another piece of the Frequency Spectrum, from 0 Hertz up to the
Broadcast Band which we haven’t mentioned. (“Zero” Hertz actually could be
considered DC, if we assumed some energy present at 0 Hertz.) Most of these lower
frequencies are not considered part of the Electromagnetic Spectrum, since they do not
have the characteristics of Electromagnetic Radiation. For example, the 20 to 20,000
Hertz portion of this lower part of the spectrum is the audio band of frequencies. Since
our analyzer is an Analyzer, it operates in that part of the spectrum above
the broadcast band and extending up through the UHF band. The transmitters in this
range are pumping RF energy into their antennas. Electromagnetic waves radiate out
from these antennas at the speed of light, 186,000 miles per second. As they pass a
receiving antenna, they induce RF currents which are fed into a receiver. A resonant
circuit in the receiver selects the signal from one of the transmitters, rejecting
(hopefully) all the others.
We can’t SEE any of the radio signals that are always around us, but we could
use a radio receiver to HEAR them, one at a time. Or, we could use a TV receiver to
see the images carried by the RF signals in the TV part of the spectrum. Imagine what
we might see if we had a device that could look at all those signals at once, and display
them lined up in a row, with the lowest frequency signals at the left! Each signal could
be represented by a vertical line whose height would be directly proportional to it’s
strength at our receiving location.
How could we develop such a display? Lets start with a receiver which covers
the band we are interested in observing. We start by first tuning to the lowest
frequency on the band and slowly tuning up in frequency. As we do this we monitor the
signal strength readings on the meter, recording the frequency and strength of
every signal we receive as we go. Rather than list all the numbers, we’ll use a sheet of
7-
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4-
2-
= l-
0 I
graph paper on which we have drawn a horizontal line across the bottom. This line (the
X axis) should be marked “frequency”, with the lowest frequency we will be tuning on
the left, and the highest on the right. Each square above the line would be marked in
units, starting with 0 on the base line and increasing as we go up. These readings
2
5”
LOHI (X) F=Q.
I
h
3- 3
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5”-
Fig.2
“S”
RFSpectrum
(Fig.1)
DIDN’T KNOW WHO TO ASK!RF VISION. WHAT YOU ALWAYS WANTED TO KNOW, BUT
A TUTORIAL.
on the Y axis will represent received signal strength. Now, as we tune across the band,
draw a vertical line, starting from the horizontal base line at the location corresponding
to the frequency at which the signal was found, and rising vertically as many units as
the meter indicates. When we have completed this task, we will have drawn a
display of a section of the RF spectrum showing all of the signals received and their
relative strengths (Fig.2). Now, if we could replace this tedious, manual procedure with
an all electronic, continuous display on a CRT, we would have a basic Spectrum
Analyzer.
Most commercial spectrum analyzers have a built-in ‘scope to display the
spectrum. The Spectrum Analyzer we will build will work with ANY ‘scope, since it’s
Receiver
Mixer
, Sawtooth
I
Generator
Tuning
- Diode
-
output signals are in the audio range of frequencies. The analyzer itself is an
electronically tuned superhetrodyne radio receiver, similar to a scanner, except that the
tuning is continuous, rather than in steps. An electronically tuned receiver uses
varactor diodes (voltage variable capacitors) in place of mechanically variable
capacitors to tune across the band. A sawtooth voltage is applied to the varactor tuning
diodes. As this tuning voltage increases in amplitude it causes the receiver to
tune across the band. This same sawtooth voltage is also applied to the horizontal
input of the ‘scope. This causes the electron beam in the CRT to trace a horizontal line
across the screen, from left to right. Let’s assume that we are tuning from 50 to 100
MHz. When the sawtooth tuning voltage is at it’s lowest level (point A), the receiver will
be tuned to 50 MHz. At the same time, the horizontal sweep on the ‘scope will be at
the extreme left side of the CRT. As the sawtooth voltage increases in amplitude, the
receiver tunes to a higher frequency and the beam in the CRT moves across the
screen from left to right. When the sawtooth voltage reaches it’s maximum amplitude
(point B), the receiver will be tuned to 100 MHz and the ‘scope beam will be at the
extreme right hand side of the CRT. Therefore, the instantaneous horizontal position of
the electron beam is always directly related to the frequency being tuned by the
receiver. The horizontal axis now represents FREQUENCY, rather than T/ME, as in the
conventional ‘scope application.
3
(Fig.3),
HI LO- Freq. Fig.3
*Right CRT- Left
Varactor
SawtoothLWH?
osc.
Scope
t
Det. -@
1
“S”
DIDN’T KNOW WHO TO ASK!RF VISION. WHAT YOU ALWAYS WANTED TO KNOW, BUT
A TUTORIAL.
At the same time, the meter output of the receiver is applied to the vertical
input of the ‘scope. As the receiver tunes up across the band, the beam of the CRT
moves from left to right in synchronism. When a signal is received, the beam is also
deflected vertically, tracing a vertical line whose height is proportional to the received
signal strength. When the sawtooth voltage reaches it’s maximum value, the receiver is
tuned to it’s highest frequency and the CRT beam is at the extreme right. The sawtooth
voltage then drops rapidly to it’s lowest value, tuning the receiver back to it’s lowest
frequency and snapping the CRT beam back to the left hand side. This process is
repeated continuously, updating the display so that any changes appear instantly.
Since the vertical deflection corresponds to received signal strength, and the horizontal
deflection corresponds to frequency, the resulting display is instantaneous signal
strength versus frequency. The conventional scope is said to be operating in the “The
Domain” while the Spectrum analyzer operates in the “Frequency Domain”.
COMPARING THE FREQUENCY AND TIME DOMAINS.
Now that we have seen how the basic spectrum analyzer uses the ‘scope, lets
delve a bit deeper into the difference between the conventional ‘scope display and the
spectrum analyzer ‘scope display. If we visualize the spectrum as being 3-dimensional,
(Fig.4) the difference becomes
immediately apparent. This
3-dimensional drawing corn bines
the 3 axis we have been
discussing, into one illustration. In
the conventional ‘scope display,
the horizontal (X) axis represents
“Time” and the vertical (Y) axis
represents “Amplitude”. The third
Spectrum axis, “Frequency” would not be
Analyzer visible since it is positioned 90
, View de