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[Local QRM/noise reduction]  [Very small vertical magnetic loop]

[Medium size vertical magnetic loop]  [Vertical magnetic Alford loop]

[Vertical magnetic loops in real life]  [Circular polarization]

[Broadband amplification]  [Broadband amplifier]  [Single chip amplifier]

[Dual loop antenna system]  [Hints]

[Phaser 80 – 10 meters]  [Balancing and closed loop antennas]

 

Local QRM/noise reduction

 

It is not always possible or allowed to tackle the sources of local QRM. What remains is trying to reduce the noise level by means of your antenna system.

It all relates to:

signal to noise ratio

 

Every action you do, ask your self what happens to the signal and what happens to the noise.

 

 

Location

The best location for a receiving antenna is the location with the highest signal to noise ratio.

In most cases this is as far away as possible from potential noise sources.

Also the height can make a difference. The signal to noise ratio not necessarily stays the same when changing height. The noise is radiated locally and is received by the antenna at a different elevation and azimuth angle.

 

Coupling / Balancing

Most important is avoiding any coupling with other antennas, feeders, poles, etc., etc.

You don’t want feeders to be a part of your antenna system. On their way to the shack and in the shack they can pick up all kind of noise sources. So your receiving antenna needs to be perfectly balanced.

Coupling with other antennas and object is mainly handled by distance. In a small city lot distance is limited, but never negligible.

 

 

Antenna A (short capacitive active antenna) is an example of an unbalanced receiving antenna. The feeding coax cable is an unwanted functional part of the antenna. Antennas B and C are good examples of balanced antennas.

 

Near field properties

A magnetic loop has mainly a magnetic near field and is told to be insensible to local QRM for that reason.

Near field properties are only relevant when the noise sources are in the near field (<l/6). Even on 80 meters most sources are not in the near field and/or the loop is not in the near field of the source.

The noise source itself is in most cases electrical wiring. Because of the dimensions the radiated field can be magnetic (H) as well as electric (E).

And at distances between 0.1l and l the magnetic loop turns out to be even more sensitive to the electric (E) field [W8JI].

So only on 160mtr and longer wavelength the magnetic loop may have an advantage over a short dipole.

 

Directivity

This is a very effective way of reducing noise. Not only local noise, but all noise.

At first we think of beams, beverages, rhombic or EWE/K9AY terminated loops antennas.

But because of their size they can not be used in a small garden.

The small magnetic loop and the short horizontal dipole both have a figure 8 shaped radiation pattern. Perpendicular to the loop for example we see a null in the pattern that can be used for nulling out a local QRM source.

So for a city lot the small magnetic loop or the short horizontal dipole is the way to go.

 

Polarization

Only when the local noise source is on a more distant location, the groundwave is responsible for the incoming signal. The groundwave is mainly vertically polarised. Then horizontal polarised antennas like the horizontal (short) dipole or horizontal magnetic loop (Alford/K6STI) have an advantage.

 

Circular polarization

Polarization mismatch is one of the mechanisms causing fading (QSB). The signal to noise ratio can be improved by keeping up the signal strength and removing the fading.

The turnstile is an example of an circular polarised antenna.

But circular polarization is also possible with two perpendicular loops fed 90 degrees out of phase.

 

Diversity reception (polarization and spacial)

Placing two antennas with different polarization on a certain distance to each other makes diversity reception possible. Fading by multipath reception or by polarization mismatch works out different for the two antennas. Using two identical and synchronised receivers gives you always the strongest signal. Alternatively you can use only one receiver and switch between the two antennas by hand.

 

Noise cancelling with two antennas

Noise cancelling is a very effective way of eliminating a single noise source. You need two separate antennas. The noise source is eliminated by combining (adding) the signals of both antennas with the matching phase difference and amplitude ratio. Assuming both antennas are receiving the noise source. When one of the antennas doesn’t receive the noise source, noise cancelling is not needed of course and only that antenna can be used.

In principle by adding more antennas more sources can be cancelled.

 

Array with 2 antennas

We can make an array with two (or more) antennas with identical radiation patterns placed on an certain distance to each other.

The phase difference and amplitude ratios of the antenna signals when combined (added) define the overall radiation pattern of the array. The effect is directivity with the advantage that it is electronically controlled.

 

 

In summary the most convincing actions for local QRM reduction are:

• QRM minimising: perfect balancing and maximum distance to noise sources
• one QRM source: nulling or noise cancelling
• more than one QRM sources: combination of nulling, noise cancelling and/or directivity using an array
• QSB reduction: circular polarization or diversity reception

 

 

 

Last update: September 24, 2006

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