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Archive for category Antennas

SWR meter – how to measure your antenna

Sep 21

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A SWR meter is a very important antenna measure equipment. Everyone that have a radio transmitter need this handy instrument. So If you are an radioamateur, CB radio/walkie talkie user or maybe you have a marine VHF radio in your boat, will need this instrument to tune your antenna for the frequency you want to use. If you forget to tune your antenna, parts, or all power you transmit to your antenna will reflect back to the radio and damage your transmitter.

Under you can see a video on youtube on how to use a SWR meter.

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The vertical groundplane (GP) antenna

Dec 30

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The GP antenna is a very popular antenna. You can use it for every freqency you want as long it’s cut to the correct length. It’s a excellent HF antenna or 27 mhz CB antenna (PR-27).  The typical groundplane antenna is 1/4, 1/2 or 5/8 wavelength long.  The different length have different characteristics. 

The 1/4 will be shorter than the 1/2 or 5/8 wavelength antenna and will have a higher take-off-angle (shorter skip distance). On the other hand the antenna may work  better in a valley. (The signals will shoot out of the valley.  A 5/8 will maybe shoot the signals straight in to the mountains). Read more about take-off-angle here: http://megahertz-radio.com/2008/11/28/skip-distance-and-radiation-angle-toa/ 

The design of the antenna:

gp1

Before you build this antenna, choose your desired length after your needs. If you have the space and area for a big antenna you should make the 1/2 or 5/8 antenna. It will be a better long distance antenna. If yo want to make local contacts in your area you go for the shorter 1/4. 

Here is a little calulator: http://www.csgnetwork.com/antennagpcalc.html

The calulator is for the 1/4 antenna. The 1/2 antenna is double the length and so on. 

Radials and where to install the antenna:

Many places I see a CB antenna without any radials. Well It will look good, but that is not a very efficient antenna. The radial system is HALF the antenna. So a decent radial system will make this to a good antenna. So a home made GP antenna will often be better than a one you buy. 

If you mount the antenna on the ground (GROUNDplane antenna…) you will need a lot of radials. The radials should be from 1/10 wavelength up to 1/2 – 1 wavelength long. The length is not important when them are on the ground. You should lay down ATLEAST 8 radials. If you have the land, the “optimal” is 120 radials (!).  

The best way to make an efficient GP antenna is to have elevated radials. (atleast 2m above the ground). A good way is a roof-mount. This will also place the antenna over noisy obstacles and give a better “line-of-sight” coverage. The most important note for elevated installation is the radials NEED to be correct lengt. (ex. 1/4 long). Opposite of the groundmounted antenna where you can use random length.  You dont need more than 4 radials with this setup and will give you an excellent radial system. 

Read more on radials: http://www.steppir.com/files/radial%20systems%20for%20vertical%20antennas.pdf

 

gp2gp3

The GP antenna is fun and easy to build. with some meters with wire and a fishing-pole you can make this in minutes and you dont need a balun or a matching network. Just hook  it up to your 50 ohm coax and straight to your radio.  Before you transmit you need to check your SWR or you can blow your finals. If you have a low/high SWR the antenna is to short or to long.  If you like to build antennas, I recommend that you buy a MFJ 259B  antenna analyzer. (link)

More about SWR (link)

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Homemade 1/2 wave vertical antenna for Ham radio and CB/Walkie-Talkie

Dec 22

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I made a blogpost about a cheap CB radio, but you will need an antenna for this. The best is to make one yourself. Homebrew antenna is easy to make, cheap and will give you a satisfaction.  Later I will post about other antenna-designs. 

 

Omnidirectional Antennas (From http://www.signalengineering.com/ultimate/verticals.html)

“Omnidirectional” is generic term for an antenna that radiates equally well in all directions. There are several antennas that are considered omnidirectional.

1/2 Wavelength Vertical

Most folks lump all vertical omnidirectional antennas into the same category and call them “Ground Planes”. A ground plane antenna is actually an antenna similar to the vertical dipole. Shown in figure 1, you can see the hollow tubing is now instead brought out at a 45 degree angle (and split into 3 sections) out from where it is on the vertical dipole. These rods are usually called “radials”. This type of antenna is really not a very high gain antenna.

Figure 1 – A ground plane antenna.

A much better type of antenna that has more gain is the 1/2 wavelength vertical (Shown in figure 2). We know that the impedance of the 1/2 dipole is 70 Ohms when we attach the coax in the middle, but what if we were to attach our coax directly to the end? The impedance at this point is high, very high, so we must make a matching device to match the antennas impedance to the 50 Ohm coax. What would happen if we did not use this matching device? Well if you have been reading along, you would know that this would result in a very very high SWR.

There are several commercial 1/2 vertical antennas available, the two that I can think of most easily is the Solarcon A99 and the Shakespeare Big Stick. They provide slightly higher gain than the vertical dipole antenna.

The bandwidth of these antennas are good, they can easily span all the CB channels and more with a low SWR.

5/8 Wavelength Vertical

A higher gain antenna than the 1/2 vertical antenna is the 5/8 vertical antenna. As we can figure from the 5/8 wavelength rating the antenna is about 22 feet long (5/8 of 36 feet). This antenna is similar to the 1/2, it needs a matching device at the base to match it to the coax, it cannot be attached directly. This antenna has about 1.2 db gain over the dipole antenna and 1/2 vertical. Figure 2 shows both a 1/2 Wave vertical and a 5/8 Wave vertical antenna. It achieves this extra gain by concentrating its pattern out more at right angles from the antenna instead of wasting signal at high angles, see figure 3.

Figure 2 – A 1/2 Wave vertical is on the left the 5/8 Wave vertical is on the right. A matching device is required to match the high impedance feedpoint of these two antennas to the 50 Ohm coax. The 5/8 Wave vertical has 1.2db more gain over the 1/2 Wave vertical.

I have just heard Solarcon is coming out with a new 5/8 antenna (its about time, this antenna design has been around since the beginning of time!). There are several 5/8 antennas, Hustler 27JR, Antenna Specialist Sigma 5/8, Maco V 5/8. They offer slightly higher gain (about 1.2db) than the popular A99 and Big Stick. Shakespeare was committing a crime claiming their ABS 1600 5/8 wave antennas had 12.5 dbi gain (the “i” means over an isotropic antenna). This was plain ridiculous. A 5/8 wave antennas is a 5/8 wave antenna. Do you think a vertical could have more gain than a beam? Never! This is the perfect example of how out of hand antenna manufactures have gotten with their advertising. Now, everyone thinks their A99 is a low gain piece of junk because Shakespeare claimed 12.5 dbi with their “new” antenna. Shakespeare no longer claims the ABS 1600 has 12.5 dbi gain, but everyone who sells it is still advertising that gain figure.

Even if you do not know the manufacture or anything about the antenna you are looking at, you can tell if the antenna is a 1/2 or 5/8 wave by its length, again 1/2 is about 18 feet and 5/8 wave is about 22 feet (at CB frequencies).

Figure 3 – How one omnidirectional antenna achieves gain over another. Note this is a view of the radiation pattern from the side (as if we were standing on the ground looking at the antenna).

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G5RV multiband HF wire antenna

Dec 19

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Picture by K4EFW.

The G5RV was my first HF multiband antenna and it was a great antenna. Not as great as the “doublet” (see earlier blogpost), but maybe a little easier to tune with a manual tuner. If you have a automatic antennatuner I will prefer the doublet for with the doublet antenna would not suffer transmission loss. size-wize the G5RV are a bit shorter and not so efficient like the doublet. 

The G5RV are around in different sizes. The 160m-10m version is 204 feet long, and the 80-10m is102 feet long. The 40-10m is 51 feet.   The 160m version will give more gain on 20m than the 51 feet version but also more directivity. So bear that in mind before you setup the 160m version. 

Like every other wire-antennas, this will not work magic, but this will get you on the air with a decent signal. IF you have the space and time, a better solution is a regular dipole for every band you will operate. 

Here are some great links if you want more information about this antenna. 

http://www.astrosurf.com/luxorion/qsl-g5rv.htm

http://www.wb0w.com/g5rv/g5rv_antennas.htm

http://www.radioworks.com/cg5rv.html

http://www.iw5edi.com/ham-radio/?g5rv-antenna,66

http://www.dxzone.com/cgi-bin/dir/jump2.cgi?ID=4238

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HF multiband wire antenna (80-10m) : The Doublet!

Dec 19

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This article you can find on http://www.hamuniverse.com/hfdoublet.html

I have to recommend this antenna. One great benefit with this setup is no transmission cable loss at all and all the power from your transmitter will reach the antenna. I use an automatic antennatuner and it seems to be a easy match for my MFJ-993B . I Also made a longer “doublet” antenna and it works great on 160m. So if you want a great all-band antenna you should try this. 

 THE ALL BAND HF DOUBLET

This antenna project will get you up and running with an all band Hf antenna using one of the oldest and least expensive ham antennas around…..the all band doublet. If you’ve got some TV twinlead or ladder line laying around and an antenna tuner, some wire, insulators and a bit of time then read on…….Project also includes a novel way of getting the rf to and from the shack using coax rather than ladder line.

ALL BAND DOUBLET DIAGRAM
(80 meter lowest operating frequency shown)

Details and construction

The all band doublet antenna is nothing more than a 1/2 wave dipole cut for your lowest operating frequency and fed with twinlead, ladder line, open wire, etc to a tuner that will accept a balanced line connection. IT IS NOT FED WITH COAX!

It can be designed for use from 160 thru 10 meters very easily using the standard 1/2 wave dipole formula:

468/freqmhz = total length (ft)
The exact length is not critical!

If you don’t have room for the 160 or 80 meter version…then design it for 40 meters and up!  Just remember, don’t operate it on a lower frequency than it was designed for…tuner damage may result! You can always tie the two ends together at the tuner and use it as a random wire antenna with the tuner and it may tune lower bands than it was designed for! 
It can be installed in the horizontal fashion or inverted V style. Get it up as high as possible and have fun!

Remember when working with twinlead (Flat TV feed type) don’t use over about 100 watts of power to be safe. For higher power, use the heavier, ladder, open or window type.

Construction:

The radiator:
After you have determined the total length of the horizontal section of the antenna, lay that amount of your antenna wire out and cut it in half. This will give you two identical lengths for each half of the antenna. It is suggested that you use #14 or #12 gauge wire. You can use smaller size wire but it will tend to break easier with longer antennas due to weight of ice, snow, birds, wind loads, etc.

The Center insulator/strain relief:
Attach a center insulator between the two lengths of antenna wire.  This center insulator can also provide strain relief for the twinlead, ladder line, antenna wire etc.  Leave enough bare wire from each half of antenna wire exposed for soldering to the feedline. See example drawing below:

 


 


Using the drawing above as one example, the center insulator can be made from any non-conductive material such as sealed wood or Plexiglass.  Use your imagination and ham engineering. It should be of a size that will allow the antenna wires to be attached to it from each half of the antenna with strain relief for each wire including the feedline.  Your feedline also needs strain relief. It can be provided by using nylon ties going thru the center insulator (drill holes), and tightened on the other side so as to press the twinlead against the center insulator. In the drawing above, they are the heavy black lines going across the twinlead. If you use TV type twinlead, this will be a must. TV twinlead is very fragile and can break easily from too much strain. The weakest point on the twinlead is where the conductors come out of it on the ends. The wires are very small inside and break easily. 

Each half of the antenna can go thru holes drilled into the center insulator….use at least two holes on each side of the center insulator as in drawing…make certain there are no sharp angles on the edges of the holes to cut the wire. Thread each side of the antenna wire into the first hole near the side of the insulator and out the back….then back thru the other hole leaving enough wire to work with in soldering to the feedline. This type of arrangement provides some strain relief for the antenna wires using the mechanical pressure of the wire against the center insulator. It is important that there are no sharp edges where the wire enters or exits the holes.

 

The two bare wires from each half of the antenna are attached (soldered), one at a time to each side of the 2 conductor twinlead, ladder line, etc. (Meaning one side of antenna to one conductor of feedline and the other side of the antenna to the other conductor of the feedline.) Do not connect all together in the center!
You should end up with 2 continious conductors side by side with one continious conductor from the very end of one half of the antenna to the very end of your feedline at the tuner and the same thing with the other half of the antenna. Do yourself a big favor and do not get in a hurry and just twist the wires together at their junctions! They will soon corrode at the twist and create more problems for you than the time saved by not soldering them together! Believe me, it will take much more time in the long run to do it poorly than to do it properly with solder. You should provide some sort of weatherproof sealer to the solder joints after you are done soldering…and as a last resort…tape well and then tape again. If you “cut corners”, sometimes a “temporary” installation tends to become permanent when forgotton about……then later it will remind you when it does not work!

Attach end insulators to both ends of the antenna with UV resistant rope, cord, etc and make sure you have enough to extend to the outside support tie off points. As a further note for those that are not experienced with wire antenna building, there are many ways to build center and end insulators. Do a search on Google.com using their “images” section for more ideas.
Now assuming that you have plenty of feedline to run from the final operating position up in the air for the antenna after raising it…….get help if needed….tie off the end supports…..run the feedline away from the antenna preferably at a 90 degree angle and keep the feedline several inches from any metal conductor such as rain gutters, down spouts, metal house siding, metal windows, etc. With very long antennas, the weight of the wire and feedline, center insulator etc, causes some sizes of wire to sag in the center. If this is the case with yours, some support in the center may be needed by attaching another support rope to the center insulator.

(Another option for the center insulator/strain relief would be to take the feedline and wrap it OVER a “dog bone” type (round), insulator and then back down parallel with and touching the feedline making sure you have a couple of inches left over for attachment of the bare wires from the feedline to each half of the antenna. Then use nylon ties to secure it tightly against the main feedline.
By wraping the feedline over the insulator and securing it to the feedline below the insulator, you will be adding a strain relief to help prevent the weight of the feedline from tearing apart the connections.)
After your antenna is up and secure….attach the feedline to your tuner’s balanced output connectors….and you’re done!

Use your tuner as per mfg’s instructions…have fun.

Added notes of information”

 

There are many methods of “hanging” an antenna like this one and various center supports can be used, like towers, metal pushup poles (masts), etc. The use of a small cross arm made from heavy PVC or other insulated material extending out a couple of feet or more from the tower or metalic pole will help to prevent the feedline or radiating parts of the antenna from touching any metal and shorting out. This also helps to prevent the feedline from rubbing against anything in the wind and eventually coming apart at that point.

 

When bringing the feedline down from the antenna to the radio, always keep it away from sharp corners that can cut it due to rubbing in the wind.

Remember to keep the feedline away from any metalic object by several inches.


 

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Poor Man’s 40 Meter 4 Square

Dec 17

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Submitted by N4JTEA few months ago I submitted an article titled; “Verticals; Got 2?” that basically presented a simple, yet effective, way to phase a couple of vertical wires and make them reversible while achieving a relative gain of 3dbd and a surprising degree of front to back capability based on ON4UN’s design / modeling specifications. It worked very well considering I miscut the phase / feedlines due to my screwed up formula at the time.

 

Read all at http://www.eham.net/articles/20571

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Skip distance and Radiation angle (TOA)

Nov 28

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This will be a very easy explantion of how Radiation angle work and how this will effect your HF radiocommunication below 30 mhz. 

Every antenna have a radiation-pattern. This pattern describe wich angle the signal will leave/enter your antenna.  So before you make/buy an antenna, you need to know the purpose of your radiocommunication. If you want to make long distance contacts (DX) over etc 3000 miles, you will need an antenna with low radiation angle (Take off angle = TOA). If your purpose is domestic contacts in your local area you want an antenna with high angle of radiation. That way the signal will go straight up to the atmosphere and right down.

The picture below will illustrate this. A and B are good for long distance contacts. That could be a vertical antenna with low radiation angle or an dipole that’s elevated atleast 1 wavelength above ground. The C example may be a low elevated dipole (< 1/2 WL over ground) for local contacts. For you can see the signal will go straight up, and straight down.

Horisontal dipoles, long wire’s , yagi’s and other horisontal antennas will work so good you want it to work by decide the hight of the antenna.  A thumb rule are if you want a long skip distance, you have to put the antenna atleast 1 wavelength above ground. (20 meters on 14 mhz).

If you want to rag-chew on the 80m band with your local HAM’s you hang the dipole on a low height. (10-60 feet f.e)

 

Under you can see radiation pattern of different antennas on different hights.

 

 

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