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Easy-to-Implement Signal Leakage
Strategies
Are you doing everything you can to pinpoint and correct egress
sources? A variety of hardware, software and maintenance practices are
available to help you meet FCC leakage mandates
By Ken Eckenroth, Cable Leakage Technologies
Controlling signal leakage is not just about complying with Federal
Communication Commission (FCC) regulations. It’s about
protecting
aircraft in our skies. And it’s working. The inevitable
improvement of the RF electropollution cloud since 1990 is the combined
effort of thousands of individuals. The United States is now a better
place for the safety of the flying public.
An aircraft accident caused by RF interference is highly unlikely in
America. Thanks to the FCC’s creation of signal leakage
rules,
the cable industry has reaped enormous benefits in the form of improved
picture quality and superior cable modem service. Fixing egress
(leakage) corrects most of the problems on the return path.
Signal
Leakage AT A Glance
BOTTM LINE
- The FCC requires us to
monitor our plant for signal leakage four times a year.
Þ Once a year, the FCC requires a cumulative leakage index
(CLI).
- Fixing your leakage can
correct the majority of your ingress problems on the return path.
- You can incorporate the
basics of demand and preventive maintenance by finding and documenting
other system problems while performing the quarterly ride outs.
- There is erroneous RF
that can be confused with a cable leak
- You need to know which
antennas need ground planes and which don’t. Also, be sure to
use
the correct element length for the leakage channel monitored. There are
several types of software packages for signal leakage.
Federal
mandates
What exactly are our requirements? The FCC requires cable operators to
patrol the majority of the cable plant in each of their systems four
times a year for leaks of 20mV/m and higher. Four times a year may seem
excessive, but, on the bright side, cable operators can use this
opportunity to visually inspect and record any obvious problems with
their plants. These are the solid basics for demand and preventative
maintenance. This program can be implemented while satisfying the
FCC’s signal leakage requirements.
In addition to quarterly monitoring, the FCC requires a yearly test
called the cumulative leakage index or CLI. This test yields a figure
of merit that relates to the system’s total signal leakage,
and
can be thought of as a snapshot of system performance. A system is
usually defined by an area serviced by a single head end. Engineers can
perform ground-based measurements or an aerial flyover. A flyover
measures leakage at an altitude of 1,500 feet above ground level.
Ninety percent of the measured leaks must be below 10mV/m to pass. If
the system fails, you must fix the leaks and perform the flyover again.
Ground-based measurements also can satisfy the yearly CLI requirements.
There are two formulas; the I of 3000 and the more commonly used I of
infinity. Each leak 50mV/m and higher is used in the ground-based
formula. The results of the I of infinity formula must be less than 64.
A single leak of 1600 mV/m can cause a failing score. However, all the
cable operator must do is fix the leak and enter the repair results in
the CLI exhibit B report, and that leak can be left out of the CLI
calculation.
Reporting
repaired leaks
Over the years, I have noticed that some cable operators fix large
leaks and do not report the results. I believe they are afraid that it
might trigger an FCC audit just like a tax red flag might trigger an
IRS audit. The fact is, the FCC knows that all plants can have large
leaks. A leak on the output of a line extender with its high signal
levels can be a common scenario for high-level leaks. What the FCC
wants is for these leaks to be found and fixed. The Commission loves
that. And I, as a member of the flying public, love it too. The
questions the FCC will ask will be about engineering practices and
documentation.
An unfortunate reality in searching for signal leakage from our plants
is the presence of erroneous RF. The frequencies we use are shared by
others. You could have an airplane overhead with a pilot keying his
mike producing large amounts of RF that splashes onto the cable
operator’s leakage channel. Aviation navigation aids, like a
VHF
omni-directional range (VOR) are also in our patrolled spectrum and can
be confused with a cable leak. Other sources of erroneous RF include:
ham radio, a competitor’s cable system and power line
interference.
Power
line interference
Electrical interference may be produced by power lines. It is not
necessarily from high-voltage lines. In fact, it is more common to see
it on the lower voltage secondary lines. The power companies use
electrical conductors to transmit voltage from point to point. The
voltage flowing through the conductors is surrounded by a magnetic
field. The conductor is supported at the pole by an insulator. If the
insulator has a crack, the magnetic field can arc across this gap
producing a very disruptive broadband signal, which can splash across
our patrolled cable aeronautical frequencies. If the interference is
close to a headend tower, it can interfere with received over-the-air
TV channels.
VHF channels 2 through 6 can have severe sparkles on their pictures as
a result of electrical interference. A cable operator with the right
equipment can locate the source of the interference and ask the power
company to correct the problem. Another source of interference can be
loose pole hardware. A magnetic field also can arc across this gap.
Power line interference is most evident on dry days and appears to
vanish when it rains because the moisture in the air shorts out the
gap.
Channel
tagging
There is a method for ignoring erroneous RF called channel tagging.
Channel tagging cannot be overemphasized for its importance and value
to the cable operator. It is the most reliable way I have ever seen to
differentiate cable leaks from erroneous RF. It could easily be said
that it is 99.99 percent accurate when installed and used correctly.
A common misconception is that tagging is only needed for overbuild
situations. Channel tagging allows the user to go deep into the noise
floor and reliably detect leaks of 2 and even 1mV/m. This deep
detection is important when monitoring leaks in backyard easements.
After a 20mV/m leak travels 100 feet, its measured strength is only 2
mV/m. So if a cable operator is ignoring 2 mV/m leaks at the street, it
may not be finding all the leaks it’s required to find.
The channel tagger is fast and very sensitive. The cable operator can
look for low-level leaks that may be causing ingress and cable modem
problems. The tagger causes the modulation of the channel to rise and
fall typically 20 times a second. This is definitely a man-made
occurrence and is difficult to confuse with erroneous RF. Those folks
that have been in cable for a while remember the old Cuckoo systems on
the FM bands. With an extremely low-level leak, one could barely hear
the warbling Cuckoo signal, but it was still there. The tagger has the
ability to help us find low-level leaks and automates the process
through hardware and software.
Understanding
antennas
Knowledge of antennas is essential for an effective leakage program.
Let’s start with the element length. Free space wavelength in
inches can be found with the formula 11,811/frequency in MHz. For
example, Ch. 17’s free space visual carrier wavelength is
11,811/139.25 MHz = 87.76 inches. Next, divide by two to get the free
space length of ½ wave dipole or divide by four to get the
element length of a ¼ wave monopole. In practice, actual
antenna
dimensions will be about 95 percent of the free space value.
If this length is off by more than 1 or 2 inches, the resonance will be
wrong, and the antenna will receive less than the total amplitude of
the leak. The next thing to be concerned with is the ground plane
around the antenna. A ¼ wave vertical monopole needs a
ground
plane around it equal to the height of its element. Vehicle metallic
rooftops make a suitable ground plane (see photo 1)
A ½ wave dipole is ideal for use away from the vehicle. It
is
generally used by a technician to measure a leak at 10 feet after the
leak is located. It does not need a ground plane, although its gain
will be affected by proximity to the earth or nearby objects (See Photo
2). A global positioning satellite (GPS) antenna, while it is mounted
on the roof of a vehicle, does not need a ground plane around it (see
Photo 3). It is generally a double dipole or patch antenna turned to
the frequency of 1.575 GHz.
Another type of antenna array used is a Doppler antenna (See Photo 4).
Four ¼ wave vertical monopole antennas are spaced evenly in
a
square. A ground plane around it in all four directions is necessary.
Software
tools
Software used for signal leakage monitoring and maintenance is varied
and widely available. Two popular programs are LES and CLIDE. These
programs provide for all types of reports as well as the CLI formulas.
Other types of software that combine GPS tracking with geographical
information systems (GIS) digital mapping are widely available. These
software packages overlay the leakage measurement results, which are
pinpointed by GPS coordinates, onto a digital map.
A question that I get frequently concerns the coordinate system used in
GIS mapping. GIS coordinates are given in decimal degrees. These are
different from the standard coordinates derived from GPS, which are
degrees and decimal minutes. The coordinates from plotted maps are
given in degrees, minutes and seconds. Let’s look at an
example.
The GIS map coordinates for Dallas, Texas, are decimal degrees:
- Latitude: 32779893
- Longitude: -96789918
The GPS coordinates for Dallas, Texas, are degrees and decimal minutes:
- Latitude: 32 degrees,
46.7936 minutes
- Longitude: -96 degrees,
47.3951 minutes
The plotted map coordinates for Dallas, Texas, are degrees, minutes and
seconds:
- Latitude: 32 degrees,
46 minutes, 48 seconds
- Longitude: -96 degrees,
47 minutes, 24 seconds
Further confusing things is the minus sign in front of the 96. That
minus sign indicates west longitude.
The formula is simple. For the latitude, remove the first two digits,
in this case, 32. This is the degrees. Next, multiply the rest of the
number, 779893 times 0.6 = 467936. Remove the first two digits, 46, to
obtain the minutes. Then multiply the rest of the number, 7936, times
0.6 = 48, to get the seconds.
The same process applies to the longitude. However, if the location is
on the West Coast, the longitudinal degrees will have three digits, so
the first three digits must be removed before multiplying by 0.6.
Usually, the format for an FCC site location report is in degrees,
minutes and seconds. Note that some GPS receivers allow the user to
change the displayed coordinates between degrees-decimal minutes and
degrees-minutes-seconds.
GPS and GIS software is advancing. What was once common PC-based
mapping software is available as a web-based protocol retrievable by
any Internet browser. This has immense logistical value for a local
cable operator as well as a corporate MSO wishing to keep track of its
systems.
Controlling signal leakage doesn’t just satisfy FCC
requirements,
it affects the performance of new technology and new revenue streams.
Some examples are VOIP and cable modems. Technology for finding and
documenting signal leakage has improved dramatically. Having a solid
leakage control plan in place will make the FCC happy, as well as your
customers, who will benefit from better picture quality and digital
service performance.
Ken
Eckenroth is vice president of technology for Cable Leakage
Technologies. E-mail him at ken@wavetracker.com.
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