Earth Ground

Most of us overlook the importance of hooking good earth grounds to our antennas and our radios. Some think if lightning hits, its going to do what it wants to do. Probably right! Lightning protection is not why I am stressing the earth ground. Good earth grounds serve two purposes. One they protect against lightning (by routing current to the ground instead of our radios). Secondly, they discharge stray RF energy. There are a few things this does for us. First, it makes our receiver quieter (less static). Secondly it prevents RF from building up on the station equipment and distorting our audio (So many CBers have this problem!). Have you every heard someone who’s audio would distort when they would talk? The number one cause of this is strong RF currents running on the radio chassis and mic (more power and the problem gets worse!). Also grounding stray RF energy cuts down on interference to TVs, Phones etc. Plus, if you are using a vertical antenna (1/2,5/8 Wave) you can improve the performance by lowering the angle of radiation by using ground rods and radials running on the surface of the earth under your antenna. This is a total must if you are co-phasing verticals.

So what constitutes a good ground? Well, it depends on a few things. First, inspect the soil where you have your ground rods (or will you will be putting them). If your soil is rocky or sandy, you better buy a few ground rods and a bag of rock salt. Rocky and sandy soil is a poor conductor and has a high resistance to ground. If you soil is high in mineral or ash content (nice dark top soil deep down for many feet) then you have a nice low resistance to ground. There are two places where you will need to a make good ground. One from the antenna, so the ground should be directly (or as close as possible) underneath the antenna. Figure 1 shows where to place the ground rods around your tower, but if you have your antennas mounted on your roof, still run a wire to three ground rods shaped like a triangle.

Figure 1 – Three ground rods located around the base of the tower. The ground wire runs down the tower from the antenna, and splits into three, and runs to each ground rod. Solder the wires to the rods!

The other ground should run from the back of your radio chassis. Actually, all the station equipment should be grounded together with a heavy copper wire (coax braid is good). This should run to a ground as short as possible, preferable out the window to the ground directly. You must keep this ground under 9ft long (102″) or the effect of a long wire will impede the RF from grounding. If you must have a longer ground wire (really, try not to, this is important), run a separate wire off the back of the radio (where the normal ground is hooked) that is 102″ inches long. just let the wire hang to the floor and then run it across the floor (don’t roll it up). This is called a “counterpoise”. You should have three ground rods outside the window, shaped like a triangle like you have around your tower.

If your soil is rocky or sandy, drive your ground rods, pull them back out and dump the rock salt into the holes where the ground rods go. Then, fill the holes up with water to dilute the salt and let it flow in the ground surrounding the rods. This will greatly improve the conductivity of the earth. Remember to replenish the salt ever year, it disapates into the ground over time. Ground rods should be copper about 6 – 8 feet long. You should have at least three ground rods, located about 6 feet from each other. You will need at least 6 ground rods in total, 3 for the antenna and the other 3 for the radio ground. Solder the wires onto the ground rods (to prevent static ground noise).

If the antenna you are using is a vertical, it would be helpful to place “radials” off of one of the ground rods. You do this by taking a shovel and driving the tip into the ground, rock it back and forth opening up a V shape in the soil (no deeper than 1 inch). Do this at least 8 directions from one of the ground rods (if possible). Radials should be as longs as possible (36 feet is best). Drop the radial wire into the channels you built with the shovel and stomp the channel shut with your foot or the shovel to seal the wire into the ground (to hold it down and so you do nail it with your lawn mower!). This is a great way to improve the DX capability of the vertical! Figure 2 shows a view looking straight down on the tower. You can see how the radials should lay.

Figure 2 – Looking straight down on tower. You can see the radials, but after you install them, they should be buried under the ground about 1/2 inch (no more than 1 inch deep). This will improve the radiation pattern of the vertical antenna. If you are not using a vertical antenna, just go with the three ground rods. Make sure they are about six feet away from each other.

The connection to your antennas should be a good one with the largest practical conductor size. You should hook the ground close to or on the shield of the coax (on the collar of the PL-259). Connect the ground wire to the chassis of you radio, hooking it firmly to metal. If the connection is loose, it will cause more static noise on your receiver! Do not expect to notice a huge difference (or a immediately detectable difference) from doing this. But remember, when you are trying to talk to a DX station with the faintest signal, even that slight bit means hearing or not hearing that DX station.

Article by Scott 2rp789 originally available at http://signalengineering.com:80/ultimate/earth_ground.html

The post Performance Tips – Earth Ground appeared first on IW5EDI Simone - Ham-Radio.

Building a 4 Element Cubical Quad

There are many reasons you should considering building your own antenna. First you can taylor it to the needs of your communication (local or DX and optimize it for the frequency you talk on) and to the needs of your environment (make it strong if you live in a harsh one where ice and wind is a problem). There is the extra part of knowing you did it yourself. To the best of my knowledge, only one company is producing a commercially available quad (Signal Engineering, Hy-Gain did) in the U.S. Another reason that you might build is you might be able to build a beam more cheaply than buying a commercial one (do not be surprised how much more you might have to spend to complete the project than you anticipated however). I assure you, there is nothing like stomping locals on DX contacts. Until your friends catch on and start building their own too (and co-phase them).

Basically, I am going to mainly discuss the setup I used on my 4 element cubical quad. You can build a cubical quad with any number of elements, but make sure you read my section under “Feeding the Antenna” section if you are going to deviate from 4 elements. I seriously recommend building a 4 element quad. Four elements gives the highest gain to size ratio of any type of beam in existence. If you go more than 4 elements the gains are negligible, less than 4 elements and you could have a bit less than you get with 4 elements. These are the simple reasons I recommend the four element quad.

Let’s first discuss some design principles that all beam’s (Quads and Yagi’s) have. Antenna gain, front-to-back, front-to-side and bandwidth are the 4 properties of an antenna that must be balanced to suite the designer’s needs. It is possible to maximize all these properties but then we would be coming up with a design that is a happy medium. You could take the road of designing for the highest gain (or any other principle), but this will cost you somewhere else (lower F/B, bandwidth, etc.)

Lets look at the factors that influence these properties. There are two items that effect the four characteristics of the beam, elements length and element spacing.

Element Lengths

This and the next section are going to refer to Figure 1. Figure 1 has labels for each of the beams dimensions we are going to talk about now. Element lengths play a role in the overall performance of the antenna.

Figure 1 – The important dimensions we must calculate for the frequency you choose. The R1,DR1,D1 and D2 dimensions are just for 1 side of their respective element.

To calculate dimension you can refer to this Quad Antenna Calculator

Element Spacing

The element spacings that are calculated are just suggested spacings. Those numbers do not have to be followed to the exact inch like the element lengths should be. Usings spacings wider than the ones suggested yield higher gain at the cost of front-to-back ratio. So then, if you use closer spacings, you get better front-to-back at the cost of gain. The spacings I have given are a good mix of the two in my opinion. Closer spacing for CB frequencies is from about 4′ to 5′. Wide spacing is from about 5′ to 6′. This is for 4 elements. Once you start adding more than 4 elements, you can go to an even wider spacing (than 6′) for the directors. If you end up making your 4 element quad framework like I suggest below you will have to stick to a S1 – 65″, S2 – 56″ and S3 – 65″ spacing.

Beam framework

We are now ready to get started on the supporting structure for the wire elements. You should have already read the section on “Cubical Quads” under then antennas types to give you an idea of what we are doing here. Figure 2 shows a sample of a parasitic element. We need to insulate the wires from the boom. You cannot just simply just make the spreader arms (the X shaped supporting structure) out of aluminum and then just insulate the wire at the tips of the spreader arm. If you do that you will have too much metal supporting the wires and this will badly interfere with the tight radiation pattern that you are trying to achieve. The supporting structure will actually start becoming part of the antennas, grossly de-tuning it. Ideally, you would make the boom and arms totally from an insulating material (such as fiberglass). If you are skilled enough (and have the money), do it that way. For most of us, we need to at least use an aluminum boom for the antenna (for strength reasons). Your next best bet is to use fiberglass spreader arms attached to an aluminum boom. You can get all the materials you need (if you cannot get them locally) from a company called MAX GAIN SYSTEMS, INC. They sell booms, fiberglass spreader arms, spreader mounts..and everything you need to build a quad plus some more info on design considerations. Unfortunately this route is expensive also. I have not checked into comparing these two options, but it might be cheaper to buy a commercial Quad, if you need to buy all the parts rather than buying all the pieces from Max Gain Systems. If anyone determines the pricing differences, let me know! You need at least a 11 foot boom (to satisfy the minimum suggested element spacing) and enough material for all your elements. The spreader arms (4 for each element) are about 6 1/2 feet per spreader. This means you need to get enough fiberglass and aluminum to make enough elements. The spreaders must be adjustable, meaning they should be able to be lengthen or shortened by a couple inches to tension the element wire, do not think the lengths that were caculated above are the exact sizes you need. A boom to mast mounting plate and some kind of spreader mounting device (sometimes called a spyder or hub, one is pictured below) are required. I recommend that you not use more than 36″ inches of aluminum per spreader arm or you will get start to get pattern deformation. The less aluminum you have to use on the spreader arm the better, where an arm totally made up of fiberglass is ideal.

The cheapest way I have found to build this antenna is to find an old Moonraker 4. If you can find a Moonraker 4 that has at least the Boom and hubs (that are still ok to use) you are halfway home. Figure 3 shows my 4 element quad built with old Moonraker 4 parts on a 40 foot tower. I said you are limited on element spacing if you use my design (Moonraker 4 parts), because you will have to stick with the Moonraker 4 element spacing (S1 – 65″, S2 – 56″, S3 – 65″). I have found these spacing’s to work great for 11 meters. My beam has a good mix of gain and F/B (Mine is designed for 27.555MHz). After you get the Moonraker parts, you will still be short on fiberglass rods (you will need 12 more of them). I was lucky enough to find fiberglass electric fence posts that worked perfect, for free. You could try using bamboo, or wood, but you must weather proof them well, or you this antennas will not last. Ideally, fiberglass is best. Do not even think about ordering new Moonraker fiberglass rods, they are 10$ a piece (that would be 120$). Max Gain Systems also sells pieces to attach the element wire onto the end of the spreader arms. In my case, my fiberglass rods were big enough for me to drill through and pass the wire. This would split the Moonraker fiberglass arms, so you can use the stock way to attach the wire, but if you order other fiberglass rods, you might need to get creative on how to attach the wire to the spreader ends. You can always buy the commercial parts however. Most people say not to drill through the spreader arm, because water will get inbetween the wire and spreader arm, freeze, expand and crack the end of the spreader arm. I haven’t had trouble, but when I take it down to redo it, I am going to seal the holes with some kind of compound. My beam has been in operation for six years without any type of mechanical problems.

(12/1/98)

I have just discovered that the fiberglass I used is available for sale on line, and it is cheap! It is a total bargain, and is the way to go if you need to make spreader arms. HERE is the link to just on

e dealer I found. You can find others by searching for keywords like, “electric fence posts fiberglass”. If you find better prices, let me know ! The proper name of the fiberglass fence posts is “T-Posts”, because they are shaped like a “T”. If you have farm supply stores around, more than likely you can get them there. I will be adding close up photos of my spreader assembly, I used pipe clamps to attach the fiberglass to the outside of the aluminum arm.

“Fiberglass T Post”

Also, I just dropped my tower down for the first time in 6 years..and the effects of the environment are suprising! First off, I read this at some fiberglass distributors site, but I never thought about it. My fiberglass arms are looking worn. The fiberglass is fraying from the rod and they are really stained. They are still strong, I was bending them good. But I really think its necessary to paint the fiberglass with a good quality enamel (Rustolem or Krylon). I read to paint the spreaders flat black, but that does not make sense to me. I am going to paint mine flat white. White reflects heat better than black. The paint offers UV (Sunlight) protection…which destroys mostly everything it hits over time.

Another word to the wise about fiberglass…always use gloves to handle fiberglass, if you don’t your hands will be itchy and burn from the fiberglass strands that will stick in your skin.

Figure 2 – Quad parasitic element. Aluminum and fiberglass arms are held together with pipe clamps. This whole assembly shown slides onto the boom (the hub’s center fits onto the boom).

The Element Wires

The next step after designing and getting our support structure together is to get the elements wires measured and ready to place on the spreader arms. First the choice of wire. There are several choices of wire you can use, solid, braided, etc. There are two that I could suggest. At least #12 wire should be used regarding bandwidth. #10 would be even better, but your spreaders arms must be strong because when #10 loads up with ice or wind, its going to stress yours spreader arms to the max. My choice is #12 solid wire (not braided). Also keep in mind the wire should be bare, not insulated You could also choose a special wire for antennas that people use called “copperweld”. It is a steel wire that has a copper coating on it. It is suppose to be stretch resistant. After awhile, soft drawn copper wire will stretch. That’s what they say, but I prepared my #12 soft drawn wire by stretching it. Figure 4 shows a rather weak way to stretch the wire. Instead of hooking it to a nail, I wrapped it tight around a tree, and stretched the daylights out of it. You can actually feel the wire stretching as you pull on it. Another thing I did (to really straighten the wire) was to start where I hooked the wire to the tree, loop the wire around a large screw driver and then pull the screw driver down towards the other end of the wire One hand on one end of the screw driver, the wire in the middle looped around it, and my other hand on the other end of the screwdriver (click HERE for a visual example of this method). I also usually place a rag around the screwdriver so that the metal screwdriver does not score the soft copper wire. This will take out all the kinks that are in the wire and make it really straight (that’s good). Its best to figure on getting about 40 feet for each element and an extra 40 feet in case you accidentally screw up (badly kink a wire, snap it from pulling too hard, etc.)

Figure 4 – The way to stretch and measure your wire. Mark the corners of the wire with a precise mark. You could use something like red paint, but keep the mark exact..in other words do not just spray it on, you should brush it on making it no wider than 1/8″. Do whatever its takes to mark the wire perfectly. I will refer to these marks as “corner marks” because these will be the corners of the element when it is strung.

Next you want to coat the wire with clear enamel. Copper wire will oxidize (“rust”) rather quickly, so you must coat it with a few really good layers of enamel. You could alternatively buy wire that already has enamel on it. You know you got a good coating of enamel on it if you can take your Ohm meter and not get a circuit (infinite resistance) when you touch the wire with the probes. Coating the wire with enamel serves the purpose of keep the beam as efficient as it can be. Since we said RF travels on the outside “skin” of the wire (at CB frequencies), it is a good idea to keep it shiny. You will have less Ohmic loss, and plain better antenna efficiencies if you do this step (do it!). If you are wondering. why can’t I keep the insulating jacket on the wire, instead of getting bare wire…won’t that protect it better? Yes it will but the wire will be heavy and you really do not want that, it will sag too much. Also, if you do use wire with insulation (don’t!) the element lengths calculated above will not be valid, you will need to re-adjust the formulas I used to take into account the insulation on the wire.

Ok, after you picked out your wire and gotten it ready to use, Its time to measure it all out. Figure 4 shows the way to measure the wire the best. You obviously do not need a 50 foot tape measure to measure the wire like shown. It is most convenient to use at least a 10 foot tape measure. Lets suppose we calculated our antenna above and got a reflector element length of 9′ 4 3/8″ per side. Suppose we are measuring out the reflector element. First, mark your first starting point by where the wire is attached to the nail. Be sure to leave a few feet of extra wire before you make your first mark (we will need to bend the wire back and make a connection). Next for the example, measure down 9′ 4 3/8 ” from the first mark, then mark that spot. Do this three more times like the figure shows. Do the other three elements in a similar manner. You are now done getting the wires ready.

Feeding the Antenna

One of the important parts of getting a really good, high gain radiation pattern from the antenna, is to feed it correctly. Under the Coax Basics section, I discussed that coax cable is unbalanced, which means that no current flows on the shield of the coax. The quad (and yagi) are balanced feed antennas, meaning that they require currents to be balanced at their two connection points. If you would just take the coax and hook it straight up to the antenna, what do you think happens? Well, when we look at radiation patterns (of a beam feed with balanced lines), we see that they are symmetrical. If we were to take our coax and hook it straight up, our pattern will get skewed off to one side (shown in figure 5).

Figure 5 – The radiation pattern of the antenna on the left is a 4 element quad feed directly with coax. The radiation pattern of the antenna on the right shows a quad using a device (balun, gamma match etc.) to match the unbalanced coax feed to the balanced antenna. A clean pattern results.

So, what device is used then to convert the unbalanced feed of the coax to the balanced feed requirement of the antenna? We have talked about one device already. The Gamma Match, not only does it simplify tuning, but it acts as a device to match the balanced antenna to the coax. Another device is known as the balun, which is made from the words BALanced-UNbalanced. A balun takes the input from the coax and balances it. It is possible to build your own balun, but, I am recommending that you buy a commercial one. This is one place where its just best to use a professional designed and built piece for your antenna. Figure 6 shows how you can mount your balun to the spreader arm (shown for horizontal polarization). Figure 7 shows a view of the driven element so you can see where the balun is located. On horizontal polarization, I strongly recommend that you drop the coax straight down from the antenna like I have shown. This keeps the coax out of the immediate field of the antenna and prevents the feedline from disrupting the super pattern of this antenna. There is not a whole lot you can do to avoid this if you feed the antenna for vertical polarization (as shown in figure 8) because you can see the coax has to run down the spreader arm. This is why I recommend using horizontal polarization. If you are building this antenna your main reason must be you want the absolute highest gain, little things like dropping the coax directly away are the little things that add up. When you go to get a commercial balun, make sure you go with a current type balun (as opposed to a voltage type). The quad and yagi require balanced current for a clean pattern. Another specification that you need to get is a 1:1 ratio balun. This does not have anything to do with the SWR ratio (we know 1:1 is perfect). The ratio on the balun indicates what ratio it transforms impedance’s at. Since our antenna (the 4 element quad) has a feedpoint impedance around 50 Ohms and our coax is 50 Ohms, that means we want a 1:1 ratio. If we are building a 2 element quad we would need to use a 2:1 ratio balun because the feedpoint of impedance of the 2 element quad is around 100 Ohms. Thus if we were building a 2 element we would need to match 50 Ohms (coax) to 100 Ohms (antenna), and this is a 2:1 ratio. Keep that in mind if you are building a 2 element quad (Yagi’s are different). So, when you go to buy, get a “1:1 Current Type balun” for your 4 element cubical quad.

Here are the two Baluns I recommend, the first is more expensive, but it might be worth it (I have read a lot of good things about it, but I use the second one listed):

Manufacture: Amidon

Model: W2FMI 1:1 HBH50

Info: 5KW, 10KWpeak (Max wattage)

Price: $49.95

Link: http://www.bytemark.com/amidon/prbalun.html

This one is square, and looks like it might be harder to mount on the spreader arm. I am going to try this on my next quad.

Now we are ready to string the wire on the elements. All we have to do is thread our wire through the spreader tips (through our wire holder). This is where you want to place the marks you made on the wire at the corners (where you wire holder is). This is why you wanted the marks to be exact. For the parasitic elements, take your solder iron and join the two wire ends together. Your marks on the wire should meet at this point. Refer back to figure 1, you can see where the wire splices together. You have to clean the enamel off the wire so you can make a good electrical connection here. Also, a 25 watts pencil tip soldering iron will not do the job here. You must use a high wattage (100+ watts) iron or even a propane torch to solder the wires together. If you merely make a physical connection by twisting and not soldering, eventually over time when the wire “rusts” the connection will go bad (ask me how I know). Now, extend the spread arms out enough just to hold the wire taunt. Figure 6 shows how tight you should make the spreader arms.

Figure 5 – The Balun, simplifies hooking the coax to the driven element wire among other important things. The balun is secured to the spread arm with tie-wraps and outdoor electrical tape (I like 3M’s). Notice here also, the area you should waterproof when you are done, by wrapping either electrical tape around it, or Radio Shacks coax seal.

Figure 7 – The driven element shown with balun at the feedpoint. Fed for horizontal polarization.

Figure 8 – The driven element shown with a balun at the feedpoint. Fed for vertical polarization. You can see the feed line has to run down the spreader arm. I recommend horizontal polarization!

Figure 9 – Shows how much tension to put on the wire. You adjust the tension by extending the spreader arm length or moving your wire holder up the spreader arm, depending on how you made your spreader arms.

For the driven element, make the connection to the balun like shown in figure 5. You want to solder one side of the connection good. The other side you first just want to twist the wires together, making sure there is a good physical connection. We may have to do some adjusting here, so we need to temporarily make this connection this way. After the elements are strung, its time to place them on the boom. Make sure everything is tight and then hoist the antenna into its position (on the tower or mast where you are going to mount it). Connect the coax, and check the SWR. Confirm that the SWR is where you want it to be. This is one place where you cannot expect it to be 1:1 exactly where you designed it for. However it should be close! I designed my beam to be 1:1 on 27.555MHz and it ended up being 1:1 on 27.625MHz. I did not even bother to adjust the beam any further…it was close enough for me. So, lets say that you get it all together and its not close enough for you. We will use the situation that I found when I first checked the SWR. My antenna was 1:1 on 27.625MHz. Since we want the SWR to be 1:1 on 27.555MHz, this means we need to lengthen the driven element wire. By how much? We definitely do not want to have to do this 3 times because you know if we shorten or lengthen our wire now those 90 degree bends we made in our wire will have to move and we will have to bend new corners. The best way to figure out how much you will need to lengthen or shorten the wire is to calculate the length. Since we know that we are 1:1 on 27.625, we can calculate the distance that should be close. You will need to add about 1 1/8 inches of length to the loop. Hopefully you have left enough extra beyond the corner mark to add the 1 1/8. If not, you will have to solder extra length on. But If you have planned right..you shouldn’t have to be doing that! Adding 1 1/8 of an inch to the loop adds a little over 1/4 inch to each side of the loop. Now, lets say your SWR was 1:1 on 27.485MHz and you wanted it to be 1:1 on 27.555MHz. You would need to then shorten the wire by 1 1/8 of an inch. How did I know to the exact length (1 1/8) to lengthen or shorten? I calculated it using simple algebra. More simply, you could just go about adding (or cutting depending on which way your SWR is off) a 1/2 inch at a time, then recheck the SWR. If you need to move the SWR down (ex. from 27.625 to 27.555), then lengthen, if you need to move it up (ex. from 27.485 to 27.555) then shorten the wire, simple. Ok, this is just great, I go through all this..and the SWR is higher than 3:1 on 27.555MHz! Do not fret! I was once told…”If your antenna works right the first time, you did something wrong!”. Ok, if your SWR is sky high, relax, you have a bad connection somewhere. Is there a good connection on all the wires on the parasitic elements? Maybe that enamel is causing one of your elements to be an open circuit? If have done everything correctly to this point, your SWR should be around where you designed it for….if its not, bad connection—somewhere! Antenna building is not rocket science! Hopefully, when you get your quad together, it is close enough where you do not have to make any further adjustments. Depending on the surrounding objects (trees, towers, etc.) or the way you made the supporting structure and what wire size you used, you may have to do some adjusting.

After you have gotten the SWR where you want it, its time to solder that other side to the balun. When I was done making the connections, I then coated the connection with enamel…to further protect the wires from “rusting”.

So there you have it. If you have read this far and are really thinking about doing it…do it! You should get together some other books about quads and do some more reading. Definitely, email me with your questions and comments. When you are all done with this one, you will have an antenna that has 2db more than a Moonraker 4, is quieter on receive, and is better for DX because of its polarization insensitive parasitic elements! I look forward to hearing from you on the air someday.

73s

Article by Scott, 2 Romeo Papa 789 originally available at http://signalengineering.com:80/ultimate/4_element_quad.html

The post Building a 4 Element Cubical Quad appeared first on IW5EDI Simone - Ham-Radio.

4 Element Yagi Building

This article contains discussion of all the different antenna principles previously described elsewhere on this website. A thorough reading and understanding of the other sections are necessary to comprehend all the terms used on this page. It is not necessary to understand all the terms and theories described to build and enjoy this 4 element Yagi however. This particular section is geared towards the “freeband” CB operator – that is one who uses CB channels above (or below) the standard 40 CB channels. These CB “channels” are not legal for use in the United States – but they are quite popular any ways! The frequencies mentioned in this article are legal CB channels in some countries, check your local laws and act responsibly. This article shines little light on finding cheap aluminum or alternative methods of construction materials for Yagi antennas. It is also devoid of information on the physical design of Yagis. Sad but true, useable aluminum tubing in small quantities is expensive. And the physical design of Yagis is a subject beyond my limitations! What this article does do is provide a truly optimized 4 element Yagi design for the 11 meter “freeband” DX operator. Careful consideration was given the operating frequency and “rejection” needs of most 11 meter freeband DXers (CB operators who communicate with other CB operators more than 150 miles away).

Over the past 5 years, I have gotten many emails regarding the Yagi . antenna. They seem to be more popular than the other types of beams. I have built my share of Yagi antennas, but in the last five years (since 1997) there has been tremendous amounts of study done on the Yagi antenna using computer modeling. Since the desktop computer has become so powerful, serious computer modeling of antennas has been put in the reach of many amateur antenna experimenters and this has lead to very optimized versions of the Yagi antenna. These computer optimized Yagi’s feature much “cleaner” patterns – this means the overall forward gain hasn’t increased significantly, but the Front to Back and Front to Rear ratios have really been improved. So trading your old 1970s Hy-Gain Yagi for a brand spanking new computer optimized Yagi antenna won’t yield you a new monster signal – but will certainly increase your ability to reject signals coming from unwanted directions. Most times this is more important that forward gain itself because the CB bands are so crowded that being able to reduce some offending stations signal is more important (than forward gain).

A few words on computer modeling of antennas. Most amateur antenna modelers (like me) are using Numerical Electromagnetics Code or NEC-2 for short. A complete history of NEC-2 may be found at http://www.nec2.org/. NEC-2 is basically a computer program (or application if you like) that is able to simulate the electromagnetic response of antennas and other metal structures on the computer. This means you are able to build a antenna virtually on the computer screen and see its exact performance without even building the antenna. Imagine being able to change antenna length with a few clicks of the mouse and see its effect immediately! NEC-2 has a few limitations but is considered highly accurate if the antenna is built exactly the way it was specified on the computer. By accurate I mean the computer predicted performance of the modeled antenna closely matches the performance of the antenna if it was constructed and tested “in the real world”.

The study of Yagi antennas on the computer has produced some outstanding new Yagi designs and shed some light on the key dimensions of Yagi performance. In the past, gain was really equated with the number of elements a Yagi had. Computer modeling has shown that boom length is the real factor that determines gain. For instance, merely shoving more elements on a boom will have little to no effect on gain. The boom length must be allowed to expand. A classic example of this is you find many CB antenna that place too many elements on a given boom length. For instance, you often find makers of CB antennas cramming 5 elements onto a 20 foot boom. If you study this design on the computer, you’ll find that 4 elements on the 20 foot boom will work the same, if not better. Knowing this, it becomes obvious that it is more important to consider the length of the boom, rather than the number of elements a Yagi has, to gauge performance. Front to Back has really improved as well. Typical Front to Back ratios on the the “cut and try it” Yagi were about 15 dB – 20 dB (max) in the real world. A carefully designed antenna today can see as much as 30 dB – 35 dB of “rejection” (CBer term for “Front to Back ratio”). Some Yagis antennas have “corner nulls” (the back corners of the beam pattern) that can reach numbers as high as -70 dB! Computer modeling also puts to rest the idea that Front to Back (F/B) ratio increases with every element you add (commonly advertised by antenna manufacturers). In fact – you can tune a 3 element Yagi to have as much Front to Back ratio as a 8 element Yagi! Gain usually goes up with a longer boom, but the Front to Back ratio can be tuned up to about 30 dB on almost any multi-element Yagi.

These days the CB band is really crowded. There are many guys out there just jamming the channels – particularly 27.555Mhz (USB). The best thing a serious DXer can do is to build a antenna with a very high Front to Back (F/B) or Front to Rear (F/R) ratio to help knock down these annoying station’s signals (besides completely ignoring them). This also serves to reduce multipath fading that occurs during a DX contact. I set out to design a antenna with the “cleanest” pattern, with the best F/R ratio I could develop and cover from 27.405Mhz – 27.855Mhz with with an optimum performance emphasis on 27.555Mhz . Most of the offending stations I hear (on 27.555Mhz) come from due West, therefore I designed a 4 element Yagi to have the greatest “rejection” to the west when I have the antenna pointed towards the North East (see figure 1). The initial design was based on a 4 element Yagi for 24Mhz (12 Meter Ham Band) from the 19th edition of the ARRL Antenna Book (which also contains great detail on the physical construction of Yagi antennas). I remodeled this antenna for 27.555Mhz using NEC-2, specifically using the computer software “NEC Win Plus”, by Nittany-Scientific and Multi-NEC, by Dan Maguire (Amateur Radio Operator, AC6LA).

Figure 1 Coming Soon…

The boom length is short – just under 14 feet long, which is short compared to the common length of 16 feet most used for traditional 4 element Yagi for CB. To make construction simple, I ordered up a MaCo 4 element Yagi M104C . For around 160$US (direct from MaCo), it represents a fair value. You are getting everything you need, including the gamma matching section, which is a pain to homebrew yourself. The stock MaCo 4 element is a pretty average performer out of the box. With around 9 dBi of gain and a F/B around 20 dB, its performance is very typical – see Figure 2.

Figure 2 – The radiation pattern (in free space) of the stock MaCo 4 element Yagi on Channel 20

Frequently the freeband operator takes a beam antenna made for the regular CB channels (26.965Mhz – 27.405Mhz) and uses the dimensions straight from the owners manual. Then the gamma match is adjusted for the best SWR on the frequency of interest. This results in very poor “rejection”, because the beam antenna is being operated so far off its designed center frequency (see Figure 3). This is one reason so many people have resorted to money making snake oil fixes on their beams, such as extra “rejection wires”. The correct fix is to rescale (actually remodeled) the antenna design on the computer for the new center design frequency to insure a useable F/B ratio over the new operating range. Figure 4 shows the performance data for the M104C operating on the “freeband”.

Figure 3 – The radiation pattern (in free space) of the stock MaCo 4 element Yagi operating on 27.555Mhz. Since the antenna is being operated so far off its center design frequency (27.205Mhz, Channel 20) – the performance, primarily the “rejection”, suffers greatly. See the text for more detail.

Figure 4 – Gain, Front to Back and Front to Rear ratio of the stock MaCo 4 element Yagi from 27.405Mhz – 27.855Mhz. Gain is up slightly, but the Front to Back ratio could be greatly improved.

With some adjustment of the boom length, element spacing and element length this antenna is transformed into a very potent performer, due to its new found ability to “reject” signals from unwanted directions better. See new radiation pattern in Figure 5. My NEC-2 computer optimized antenna, that I call the “Freeband 4”, sacrifices about .5 dB over the 16 foot boom length. It is about 1 dB down over a 4 element Yagi on a 20 foot boom. The loss in forward gain is barely perceptible signal wise (remember 1db is roughly only 1/6th of 1 S Unit). The increase in rear signal rejection is amazing! “Back corner” rejection in the real world lives up to the computer predicted values – I can reduce my neighbors 40 dB over S9 signal (that is “way, way in the red” on the signal meter) down to nothing! The shorter boom length is a bonus too – most antenna mounts and rotors can handle a 13 foot – 14 foot boom. Its a mere 4 foot longer than the common 9 foot boom length used for 3 element Yagis. This antenna provides about 1 dB of gain over the tradition 3 element Yagi on a 9 foot boom and as previously noted, probably has a much more usable rear rejection.

Figure 5 – The radiation pattern (in free space) of my computer optimized 4 element Yagi. Notice the reduction in the size of the rear lobe as compared to Figure 2.

Figure 6 – Gain, Front to Back and Front to Rear ratio of the my computer optimized 4 element Yagi from 27.405Mhz – 27.855Mhz. I went for the deepest “corner nulls”, which occur on 27.555Mhz. F/B peaks slightly below this frequency.

The taper schedule of this antenna must be followed exactly for the performance to match the stated figures – “close enough” will yield disappointing results. This is the biggest mistake made by computer modelers – not accurately building the model as entered on the computer. Also limitations in NEC-2 must be accounted for. This antenna can not simply be lengthened for regular CB use (26.965Mhz – 27.405Mhz) – the carefully designed pattern will be lost. I haven’t reworked the design for the standard CB channels yet. Drop me an email if you are interested. See Figure 7 for the dimensions.

Figure 7 – The dimensions for a optimized 4 element Yagi, optimized for 27.555Mhz. Performance is excellent from 27.405Mhz – 27.855Mhz. The 2:1 Bandwidth with the gamma match tuned for a 1.0:1 SWR @ 27.555Mhz is over 1Mhz. SWR is under 2:1 from 27.100Mhz – 28.200Mhz (real world measured SWR made with MFJ-259B SWR Analyzer)

This antenna was design to be operated in the horizontal position (producing horizontal polarization). All the above paragraphs describing antenna performance are strictly referring to this design in the horizontal position. This is the most common polarization used by DXers . The pattern of this design in the vertical position is shown in Figure 8. I display this pattern here just to show the difference that occurs if the Yagi is operated in the vertical position. No attempt whatsoever was made to optimize this antenna in the vertical position. You can see there is a *huge* change in the pattern when the antenna is operated in the vertical position – this fact is rarely pointed out in books on antennas for DXing because they all assume the horizontal position will be used. This is not always true on the 11 meter CB band. The 4 element Yagi in the horizontal position does provide better all around F/R (“rejection”) than it does in the vertical position. Again, I wouldn’t recommend you switch to my design over your current design if you need to use it in the vertical position – I can’t promise better performance.

Figure 8 – The radiation pattern (in free space) of the optimized 4 element yagi in the vertical position. The pattern is very different compared to the antenna in the horizontal position. The overall rear rejection (Front to Rear ratio) is much lower in the vertical position (this happens to all Yagi’s operated in the vertical position).

A final word about computer modeling of antennas. If you understand and enjoy building antennas, computer modeling is the next logical step for the experimenter to take. There are quite a few references out there you should check out, the subject is covered well on other websites, such as http://www.cebik.com/.

Here is the owners manual for the MaCo 4 element Yagi M104C : http://www.majestic-comm.com/assembly/SUPPORT/M104C.PDF. The owners manual gives all the stock dimensions of the antennas and shows assembly detail.

Here is a link to all of MaCo’s antennas owners manuals: http://www.majestic-comm.com/assembly/index.htm .

If you build this antenna – be sure to let me know how it works out for you! 73s Scott

Article originally available at http://signalengineering.com:80/ultimate/4_element_yagi.html

The post 4 Element Yagi Building appeared first on IW5EDI Simone - Ham-Radio.

Mobile Antennas

This is an area of hot competition among antenna manufactures. I am not going to cover how to mount your mobile antenna (Radio Shack sells everything you need to mount antennas), but the basic mobile antenna designs that most mobile antennas manufactures are using today. If you have just started reading my page and are new to antennas, you are going to be confused. You cannot just jump right into putting together an antenna without learning a few things about them first. You have to read “Antennas Basics”, “Coax Basics” and the “Verticals” sections first before you tackle this section. First we need to introduce a new term that we will be using to rate mobile antennas (gain really isn’t a good thing to use, since mobile antennas generally have no gain), “antenna efficiency”. This is how well the antenna converts your power (watts) to signal instead of wasting it as heat. An efficient antenna puts most of the power out as signal, so the range of 95-99% is a perfectly efficient radiator (all antennas waste some power, none are 100% efficient). Most base station antennas are 95-99% efficient. Say you are using 100 watts, and your antenna converts 95 watts to signal and turns the remaining 5 watts into heat, this is a 95% efficient antenna.

The most efficient mobile antenna is the 102″ whip. If you desire the best performance, the 102″ (quarter wave) whip is the only way to go. If you look back to the “Verticals” section and look at the ground plane (figure 1 in “Verticals” section) you can see the main vertical element is basically a 102″ whip. The center wire connects to this part. It must be insulated from the vehicle body. This is usually accomplished by a plastic washer. Now, the vehicle body acts as the ground plane, or like the radials on the ground plane antenna! The feedpoint impedance of the 102″ whip when mounted on most vehicles is 40 Ohms, so the lowest SWR you can get is 1:3:1. When you assemble this antennas system, if the SWR is above 3:1 on all the 40 channels, then you have a bad connection somewhere. If your coax is ok (see “Coax Basics” section) then you probably have a short or open circuit on your connection to the whip. Check the connections with an Ohm meter, center pin of radio side of coax should have an electrical connection to the actual whip and not the body of the vechicle, and the collar of the radio side of the coax should have an electrical connection to the body of the vehicle and not the whip itself. Make sure your assembly is right. If everything is assembled right, you should see an SWR 2:1 and lower (down to about 1:2:1) over the 40 channels. Really, your whip should not need adjustment, so before you think about “pruning” it, you better check to make sure things are working right. Do not let the 2:1 SWR fool you, getting it down to 1:2:1 will not get you much more (if any) performance! The only exception to pruning your whip is if you intend on talking above channel 40. If you use, lets say 27.555MHz, then you will need to trim a few inches off the tip of the antenna. Start by trimming a 1/4 of an inch off at a time and rechecking until your SWR is where you want it.If you need to lengthen the antenna, you can do so by added a spring or quick-disconnect fitting which will add around 2 – 4″ to the overall height. This should get you well below channel 1 with a low SWR.

Most of us do not have room to use a 102″ whip on our vehicle. Plenty of manufactures make a shortened antenna for our use. How do they do that? Simple, somewhere on the antenna (the base, center, top or entire antenna) they wind a coil to compensate for the length that they are shortening the antenna from 102″. So if your mobile antenna is 54 inches, the manufacture has made a coil to compensate for the 48″ inches they are short from 102″ (102 – 54 = 48). When a coil is added to an antenna it does three things. One, it cuts down on the antenna’s efficiency. Second, it cuts down on the bandwidth. Third it cuts down the antennas impedance (it lowers it even more than 40 Ohms). The shorter the antenna is made, the more these three factors are reduced.

Extremely short antennas are to be avoided at all costs. There are differences in efficiency between the different methods of “loading” (placing a coil on the antenna to compensate for shortening it) a mobile antenna. The four types of loading are base, center, top and continuous loading. Figure 1 shows the four types of loading.

Figure 1 – The four different ways to load a shortened mobile antenna. The first three are usually have stainless steel shafts whereas the last one is usually wrapped on a fiberglass rod. That is then covered with a plastic weatherproof covering.

Their performance can be summarized like this. If these antennas are all the same length (say 54 inches) the least efficient antenna is the base loaded whip. Its advantage is that you can make a heavy coil that will have a higher power handling capability than a center loaded or top loaded mobile antenna. A thicker coil handles more wattage, but you could not have a heavy coil in the middle of the antenna or top because the antenna would not be able to support it (it would be too “top heavy”). But still, it is the least efficient of all the shortened antenna types. For improved antenna efficiency, you could use the center or top loaded antenna. The center and top loaded antennas have about the same efficiency, so there really is no difference. You will mainly find only center loaded antenna however. Top loaded antennas are rare because they are more difficult to make strong enough to support the wind load. The most efficient of the shorten mobile antennas is the continuously loaded mobile antenna. It is usually a fiberglass rod wrapped up its whole length with a copper wire or flat ribbon. Use it when you must use a shortened antennas and want maximum performance. Use the longest possible for your vehicle. Its only disadvantage is it usually cannot handle high power (like over 500 watts) because it has to wrapped with a thin wire so its flexible and light.

A glance at the different mobile antennas for sale results in extreme buying confusion. First and foremost, the mounting location is the most important aspect to performance. You must get as much of the antenna over the top of the vehicle as you can. Roof mounting is most desirable, followed by trunk deck / hood mounting then lastly bumper mounting.

Most fiberglass whip makers are claiming their antennas are 1/2 wave, 3/8 wave, 5/8 wave and 3/4 wave antennas. That sounds very impressive. But is it electrically true? Yes, the makers of these antenna wind the respective length of wire onto the fiberglass antenna but does the radiation pattern benefit from the extra wire length as claimed? In a nutshell, no. The extra length of wire (beyond 102″ inches) is coiled so closely together to be able to actually fit on a skinny fiberglass rod that it electrically ends up performing the same as the 1/4 wave antenna. There are some exagerated claims of performance from some companies.

Luckily, the performance difference between different makers is so minimal it almost better to pick antennas based on the antenna you like the looks of most!

Radiation Pattern of Mobile Antennas

Most people think that antennas mounted on vehicles are omnidirectional. This is mostly true, but the radiation pattern is influenced greatly by the body of the vehicle. Remember we stated that the body acts as the “radials” for the antenna? Well, we know that the body does not extend around the base on the antenna equally. Figure 2 shows how the radiation pattern of a whip is influenced by the body of the vehicle. As you can see, the shape of the pattern depends on where you mount the antenna. The pattern is “pulled” to areas where there is the most vehicle body. The pattern is the worst in directions where there is no metal body for a radial.

Figure 2 – The dashed line shows a omnidirectional pattern you would expect from a mobile antenna, but as you can see, the pattern gets distorted from the car body not being even around the base of the antenna. This is why you should try to mount the antenna as close to the center of the vehicle as possible unless you desire a pattern that stresses a certain direction. Do not think of this as gain in a certain direction, this effect is actually detrimental to the overall effiencieny of the antenna.

Co-Phasing Your Mobile Antennas (“Twin Truckers”)

Co-Phasing antennas simply means taking two identical antennas, mounting them on the vehicle and feeding them in-phase. One of the biggest misconception of radio operators is what kind of effect this has on the radiation pattern. Most people think that after you Co-Phase two mobile antennas, your signal will be strongest in line with the vehicle body (meaning the signal is strongest down the road straight in front of you and straight behind you also. This is the theoretical effect that you would get from co-phasing two omnidirectional antennas. However, to realize this effect you need to satisfy a couple of requirements. For one, a good earth ground with long (over a wavelength or so) radial wires is required. Secondly, at CB frequencies the closest you would be able to place these antennas are about 18 feet apart. Since it is impossible to satisfy these requirements, the effect of co-phasing is seriously diminished. Unfortunately, even the “Radio Shack Antenna Book” states that co-phasing two mobile antennas will produce a two directional signal.

So then, is there any advantage to co-phasing two mobile antennas? Why yes, there is. Before we noted that the radiation pattern of a single antenna is “pulled” where there is the most metal vehicle body. You can see the pattern is not perfectly omnidirectional like we would expect it be. As we travel down the road, you will notice signal fade (“flutter” or “waver”) from this uneven radiation pattern. Co-phasing two antennas will even out the pattern irregularities. Instead of making the pattern more two directional, it will make it more omnidirectional. Do not expect more “gain” from two antennas. Figure 3 shows how co-phased antennas clean up the radiation pattern. Read the section “Co-Phasing” for instructions on how to make a harness to feed your co-phased antennas. It best to get them as far apart as possible. The best way would be to mount one on the front bumper in the center and one on the back bumper in the center also. Most people think this looks silly (me included!) and mount one on each side of the vehicle.

Figure 3 – Radiation pattern of Co-Phased antennas. The pattern is now more consistent in every direction, and is less influenced by the body of the vehicle.

Article by Scott 2rp789 originally available at http://signalengineering.com/ultimate/mobile_antennas.html

The post Mobile Antennas appeared first on IW5EDI Simone - Ham-Radio.

Directional Antennas

An antenna is known as “directional” if its pattern strongly favors a certain direction. A directional works by concentrating the signal in one direction at the expense of other directions. It is also commonly referred to as the “Beam” antenna. I am going to start with the earliest type of beam discovered, the “Yagi” Beam. This type of beam was discover by Professor Uda but the english translation was done by Hidetsuga Yagi. This design goes back to the 1920s! One would think today there would be better designs. I believe there is, and that’s why I am so interested in antennas!

The Yagi Beam

The yagi is very simple. The basic yagi consists of three elements, as shown in figure 1. The middle element is an antenna you are already familiar with, the simple 1/2 wave dipole antenna. This element is generically called the “driven element”. This is because this is the only element that is connected directly to the radio, it actually drives the whole antenna. The other two outer elements are generically called parasitic elements. One is called the Reflector (some CBers call it the “back door”) and the other one is called the director element. These elements get their name from the job they do. The reflector reflects RF energy, the director directs RF energy. There is no magic circuit located inside the elements, they are simply straight rods! The reflector element is typically 5 % longer than the driven element and the director is typically 5 % shorted than the driven element. How it works. See figure 1. As signal A comes in it strikes all three elements hence generates a current on each element. Remember we said that current on a wire causes it to radiate? Even though the current is very low, this current induced on the antenna actually re-radiates off the antenna again! Ok, back to the action, the signals are re-radiated by the director and reflector and arrive at the driven element in-phase with one another (the two re-radiated signals and the original signal). This basically means, the signals reinforce each other…and make the incoming signal much stronger coming from direction A.

When the signal comes from direction B and C, the same thing happens, except the signals arrive at the driven element out-of-phase with one another which simply means they cancel each other out, significantly reducing signals from direction B and C.

This very useful effect (signals arriving in-phase/out-of-phase) is caused by the special spacing and length of the director and reflector element in relation to the driven element.

Figure 1 – See text for simple explanation of how a beam works! “Element” is the generic term given to each of three rods that actually make up the antenna. The boom is not actually part of radiating antenna, merely a supporting structure.

We can even add more directors elements to increase the gain. Adding more reflector elements has NO more effect on the gain of the antenna, however.

Here is a table for gain figures for some yagi beams:

Note: This table is typical performance of Yagi’s with the stated number of elements. Typically, the gain will be within 2 dB of the indicated gain. However, Front-to-back ratio can vary greatly (as much as 25 dB) from the indicated F/B. F/B is much more sensitive to adjustments to the element length and spacing.

Typically most 2 element Yagi’s use just the reflector element. If you would use just the director on your two element, you would have more forward gain, but you would also not have any rejection of signals coming from direction B, that is why its F/B or Front to Back ratio is zero. The Front to back is the ratio of gain of the forward direction as compared to the reverse direction. So, if we were receiving signal A, and we turned our beam around 180 degrees, how much would the signal be reduced? This ratio is known as Front to Back ratio, and is as important as gain to some. If you have a lot of CB neighbors, getting a beam that has a good F/B will reduce interference from them if you point your beam in opposite directions from them. There is another term, Front-to-Side ratio that works the same way as as the F/B…except it means when you turn you beam to the side (90 degrees away) from the signal how much is it reduce. Typically, Front-to-Side ratios are even higher than the F/B ratio. You can see the deep notches in the radiation pattern in figure 2 that indicate this is where the greatest rejection of signals occurs. It may not be directly at the side of the beam, it is mainly dependent on antenna design (spacing, length).

Figure 2 – How the Yagi distributes its transmit/receive power.

Ok then, we can have variations of this Yagi beam. We can actually still have a beam even if you take off the reflector element or director element and just have a 2 element beam. This beam would have less gain than the three element, but would still be quite directional. It would certainly have more gain than a 5/8 Vertical antenna.

As you can see from the table, it gets difficult to get more gain after 4 elements. Not only that the antenna gets huge, the antenna bandwidth goes down, and it is hard to tune! As a quick note, its better to “stack” or “co-phase” beams rather than go with a large number of elements. For instance, its better to go with co-phasing two 4 elements Yagi’s rather than using an 8 element beam. Read section the section “Performance Tips”, “Co-Phasing”.

I have seen some monsterous gain figures for the Maco line of beam antennas, especially their 6 and 8 element beams. In my opinion, these gain figures are really exaggerated! Be cautious, and read on.

We can see the pattern changing when we compare the radiation pattern of the 2, 3 and 5 element Yagi antenna, see figure 3.

Figure 3 – Comparison of radiation patterns. You can see how the higher number of element beams concentrate their power.

Lets check out some pictures of some yagi beams so you get a better idea what they look like. Figure 4 shows a 4 element Yagi in the horizontal position. It radiates a horizontally polarized signal. You can see a special matching device where the coax connects that looks a small “jumper rod” that connects a few inches out on the driven element. This matching device is called a “Gamma Rod” or “Gamma Match”. It is a device that simplifies adjusting the antenna. The gamma match is a type of matching transformer used to match the feedpoint impedance of the antenna (which rarely is 50 Ohm) to the 50 Ohm coax. This is especially necessary on beams with more elements (more than 4) because the impedance at the feedpoint is naturally low (around 20 Ohms).

Figure 4 – 4 Element Yagi in the horizontal position.

Figure 5 shows the real electrical antenna makeup. You can see the boom is not part of the radiating structure. Figure 7 show the electrical makeup of a 4 element yagi antenna with the Gamma Match.

Figure 6 – Electrical makeup of Yagi beam. Parasitic elements can be bolted directly to the boom OR can be insulated from the boom. The driven element has to insulated from the boom for proper operation. Coax is not shown to scale to clearly show the connection of the coax to the driven element.

Figure 7 – Electrical makeup of Yagi beam with a Gamma Match. Parasitic elements can be bolted directly to the boom OR can be insulated from the boom. The driven element is mounted directly to the boom in this case, it does not have to be insulated with this configuration. The shorting strap is slid up and down the rod to match the feedpoint impedance of the beam to the 50 Ohm coax, this way the operator does not have to adjust element length to tune the antenna. Coax is not shown to scale to clearly show the connection of the coax to the driven element. HERE is a detailed diagram for the proper dimensions of a gamma match for a typical CB beam (drawing courtesy of a friend of mine).

Figure 8 shows a 4 element Yagi in the vertical position. It is the same antenna as pictured in figure 4, just rotated 90 degrees to send out a vertical signal. This is good for talking to omnidirectional vertical antennas (such as the A99 vertical antenna).

Figure 9 shows how you could combine two antennas on the same boom so that you could use either horizontal or vertical polarization. Typically you still need to run two separate coax cable up to the antenna (It has two separate connections, one to the horizontal driven element and one to the vertical driven element). This antenna uses two separate gamma rods for each polarization. When this antenna is operating in either polarization mode (hor. or vert.). It has the same gain as the single antenna (figure 4 and 7). There is no magic to mounting the antenna’s this way.

Figure 8 – Same antenna as in figure 7, but its rotated 90 degrees so that it radiates a vertical signal.

Figure 9 – You do not have to settle for horizontal or vertical, put both on the same boom! This antenna is fed with two separate coax that can be switched at any time, to switch between horizontal and vertical polarization. Usually, just one antenna is used at a time. This is still considered a 4 element beam – some companies try to impress with numbers any way they can (Maco calls this “8” elements)

One last thing, the JoGunn antenna. Let me just say, it is a Yagi antenna. JoGunn came up cheaper way to make a crossed yagi (like in figure 9). Figure 10 shows the JoGunn driven element as if we are looking straight down the boom at it. You can see the horizontal and vertical elements share a ground element. I think this results in slightly lower gain than using a full crossed yagi. However this difference may not even be noticeable. Also, it offers the advantage of lower wind resistance. But do not be fooled when they say it has “the highest gain”. Lets face it this just a simple yagi beam with dipole antenna driving it!

Figure 10 – JoGunn driven element.

Article by scott 2rp789 originally available at http://signalengineering.com/ultimate/yagi.html

The post Antenna Basics : Directional Antennas appeared first on IW5EDI Simone - Ham-Radio.

2.4 GHz Cubical Quad Antenna – Introduction

The Cubic Quad antenna is a commonly homemade antenna in the range of about 150 odd MHz. Our little project was to design one of these for use in the 2.4GHz range for 802.11 wireless LANs. The reason these are seldomly used for 2.4GHz is the size.

The picture below is a 4 element cubic quad for the 147MHz range.  Large isn’t it.

The one we are going to build for 2.4GHz will only be 6cm long!

The Design

I scratched together an initial plan on how I was going to set about putting this together. The measurements came from the second (or third) link above. While each element was made the same as in the design, the support structure was changed to a much easier one. This was about the only advantage of building a really small antenna.

Materials

• 1 hot glue gun
• 1 soldering iron
• 1 soldering god (enter ChrisK)
• short length of coax with connector
• 60cm of builders wiring (stripped to get one solid copper wire ~ 2mm thick)
• 3 cotton buds (hehe I’ll get to that bit later)

Construction

After stripping the copper wire, we constructed the four elements as per the measurements I pilfered from the java application on the previously mentioned page. We bent the wire with a pair of pliars against a small anvil. The reflector and director elements were soldered closed by ChrisK, the driven element left open for connection to the coax.

From left to right…. Reflector, Driven element, Director element 1, Director element 2
The white sticks are cotton buds with the cotton crudely removed.

Each element differs in size from the next. From the reflector through to director 2, the sides of the squares get smaller by only ~0.1mm. Human error can really screw this up. As this is only really a prototype we are not overly concerned. However, when it comes to building the real deal, we have decided that getting a computer driven robot to cut out some copper on a fibreglass board with some precision in length and squareness would be a goer.

The next step is to solder the driven element to a nice thick and chunky bit of LMR400 We did this on an angle to prevent the ‘direct’ short.

Here lies problem number two. The space created by the gap between coax core and outer is huge in comparison to the size of the element. We decided that keeping the length of wire for the element was more important than the shape, so it is also not really square anymore…prototype. This would also ideally feed into a balun rather than directly onto the coax. We just need to figure out how.

We then built the rest of the elements onto the driven element with the assistance of a hot glue gun and some cotton buds. When you put cotton buds in the microwave for one minute next to a glass of water, they do not get hot. Ideal antenna construction material! The elements were distanced according to the java application. However, it should be noted that increasing the distance between the elements will increase gain at the expense of bandwidth. The final version will hopefully be totally adjustable for tuning.

We used three cotton buds and the hot glue gun to hold it all together. It is messy… prototype… but it is also very small. Hehe. You can still see the leftover cotton wool on the ends of the sticks

OK. So once all done, we did some very quick testing.

It worked! We didnt keep logs of the test as we intend to do it properly soon, but it gave a dramatic increase in signal, S/N and reduced noise. I will add test results to this page when they are ready.

Here is a closer look at the prototype.

Test Results

Two laptops with wireless cards were moved apart at such a distance where signal could be improved. One of the laptops was then given a balaxy dish (a galaxy dish that ChrisK modded to have a different balun and dipole). The balaxy dish was then replaces with the prototype cubic quad. Results were logged and the peak of all results were as follows;

 
          RX Signal Noise SNR TX Signal Noise SNR

Internal   -78      -97    20  -78     -94    17
Galaxy     -61      -99    38  -61     -94    34
Cubic      -70      -99    28  -70     -93    25

I am very encouraged by these results. The prototype cubic quad was a complete bodge job with very little precision. More precise elements may give better results. It was not adjustable due to the hotglue used to stick everything together. With tuning these results may be better. And there was no balun used, on account of my having to figure out how to make a balun for this little beasty. A balun would hopefully give me another 3db

Future Directions

The elements need to be more precise. Having them properly machined would be ideal. The support structures should be threaded. This will allow us to put plastic washers at each bend with some plastic nuts, giving us the ability to tune it for maximum gain/bandwidth.

A balun is required (perhaps). The signal is skewed about 15 degrees to the right (guestimate). We also need to figure out how to design the connection to the balun/coax in such a manner that will cause the least hassle to the shape and length of the driven element.

v1.2 is under way. v1.1 was scrapped before I put it together because I am still unhappy with the elements.

We have some good ideas on where to go from here, so watch this space for developments over the next week or so.

article originally available at http://members.iinet.net.au/~stygen/Quad.html

The post 2.4 GHz Cubical Quad Antenna appeared first on IW5EDI Simone - Ham-Radio.

Loop Antennas

The Principles of the Loop Antenna article was in a newsletter of the MDXC. The next three were from a talk that Mike Bates and James Dale gave to the Northland Antique Radio Club’s Radio Workshop at the Pavek Museum of Broadcasting.

Principles of the Loop Antenna

A loop antenna is an antenna primarily for the AM broadcast and the Longwave bands. There are two different types of loop antennas, one is the ferrite bar (as in your am radio), the other is wound on an air core form. A loop antenna is very directional. The pickup pattern is shaped like a figure eight. The loop will allow signals on opposite sides to be received, while off the sides of the loop the signal will decrease or be nulled out. The nulling feature will allow you to remove a local station on a frequency and pick up another on the same frequency by removing the local signal. A loop may have an amplifier or may not.

Air core loop antennas come in many sizes. The larger the loop the more gain there is. A small loop will actually lose part of the signal. That is why most small loops will use an amplifier. There are two ways a loop can be wound, box or spiral. In the box or solenoid loop the plane of the winding are wound perpendicular to the diameter of the loop, so each loop is the same size. In the spiral loop the plane of the windings are wound parallel with the diameter of the loop, so each loop gets smaller as you wind into the center of the loop. A loop needs to be able to rotate to null out a station. And a loop also needs to be able to till from vertical. This also helps in in nulling of a signal (altazimuth feature).

The number of turns the loop needs is determined by the size of the loop, the frequency range that you want to tune and the value of your tuning capacitor. The larger the loop the fewer turns you will need. A 4 foot loop needs 8 turns and a 2 foot loop needs 18 turns. The capacitor that is used is the standard AM tuning capacitor with a range of 10 to 365 pf. The tuning capacitor is used to tune the loop to the frequency that you want to listen to. When you are tuned in to the frequency the signal will peak. You may not be able to tune the full frequency range that you want to tune. So you will need to use a 2 section capacitor and switch the second section in. (more capacitance)

There are three ways that you can connect your loop to your radio.

One way is not connecting it at all. (This requires a portable radio with a internal loop antenna.) The field of the loop will radiate the peaked signal and you will be able to pick it up with no connection to the radio. You can move the radio around to get the best reception.

You can also direct couple to the loop. This way you connect to each end of the loop and also to the center tap of the loop. Using this method you will need to use it with an amplifier.

The last method is to use a pick up coil. This consists of one turn of wire that is placed inside the loop on the cross arms. This is then connected to the radio. The distance from the main tank coil can be determined by using a pocket radio and moving it inside the loop to find the place were the signal is strongest, and were it peaks sharpest.

In the past loops were made from wood. I have built them and found them to be heavy, clumsy, and flimsy. The mounting system were not very stable. In talking with Mike Bates, he came up with the idea of using PVC to build loops. PVC is easy to cut and because you use PVC molded parts, the loop that you make are is stable. By using PVC cement for some gluing and small nylon screws to connect parts you have no metal parts except the wire and tuning cap to throw the pattern of the loop off. Using PVC it helps to have a drill press, but if a person drills very carefully there should be little problems.

What is a loop and why use it?

1). A loop antenna is a small multi turn loop of less than 1/10th wavelength in length. The loop is wound on a form, which may be either box (solenoid), or spiral (pancake) wound. The core material can either be air, or a powdered iron compound (Ferrite). The gain of a loop is much less than a longwire, but it has much less noise pickup. A properly designed Loop primarily responds to the magnetic component of the radio wave. Note that noise resides primarily in the electrical component. A vertical antenna responds mainly to the electrical component.

2). Why use a loop?

A). No available space for a longwire antenna

B). To eliminate unwanted signals, and noise

C). Radio Direction Finding

D). To improve the performance of a simple receiving system, by providing pre-selection which improves image rejection, and adjacent channel selectivity.

3). History

A) 1915-1920’s Early receivers used loop antennas, until they were discontinued in favor of long wire antennas, prior to 1930.

The loop antenna appeared again about 1938. This time it was used to eliminate the need for a longwire antenna, and to provide for safer operation of the small midget AC/DC sets that came into wide use at that time.

B). The first known use of a high performance loop antenna is the box loop made by Ray Moore in the mid 1940’s(1) This antenna was written up in DX Horizons in 1960. The Moore Loop was wound on a 40″ square box frame. Note: Ray Moore is the Author of the book on the history of Communications Receivers, and a new companion book on Transmitters.

C). The next major advance in Loop Antenna design came about as a result of advances by Gordon Nelson of the National Radio Club. The NRC Loop Antenna(2)was designed by Nelson in the Mid to Late 1960’s time frame, Nelson was at M.I.T. at the time. The major advance that Nelson made was allowing the loop to rotate in the vertical as well as horizontal plane. The addition of the Alt-azimuth adjustment allows for the elimination of the effects of “wave tilt” and allows for much deeper nulling of certain stations. This loop was a 35″ on a side and wound on a wood frame. In one form it utilized another Nelson first, a direct coupled Balanced amplifier using 2N4416 J-FET’s with the outputs fed to a balanced feedline. The other version was link coupled to the receiver.

D). Sanserino Loop (1970-1985) This is a 2 foot Air core box loop designed by Ralph Sanserino, and later marketed by Radio West. This loop antenna used a Differential Amplifier similar to Nelson’s except the output is not balanced. This antenna also has the Alt-azimuth feature. (available as a kit) The amplifier was later used in the Radio West Ferrite Loop Antenna (see below) .

E). Joe Worchester (1970-1977) a retired GE engineer developed the “Space Magnet “, a small 12″ ferrite rod loop antenna using a Bipolar Junction Transistor amplifier(3). Nulls were not as deep as with the Nelson Loop. This is also probably the first loop antenna commercially available to the hobbyist, at a cost of about $45.00 if I remember correctly. Later versions utilized the Nelson Alt-azimuth feature. This antenna also used a Faraday Shield around the Ferrite Bar.

F). Mackay Dymek (1974-Early 1980’s) , Palomar Engineers (1977-current). These are small ferrite antennas made by larger commercial concerns. The Mackay Dymek was primarily for the Broadcast Band, where the Palomar has plug in coils for ranges from 10Khz to 15Mhz. Note that both of these antennas incorporated alt-azimuth design.

G). Radio West(1979-1985) 23” ferrite rod assembly using Sanserino Differential Amplifier, direct coupled, Has Alt-azimuth feature, $160.00 in 1979.High performance for its day, quieter than the “Space Magnet”

H). Quantum Loop (about 1990) by Gerry Thomas is a small ferrite rod less than 1’ in size (length), with a high gain 40Db amplifier. has Alt-azimuth feature, in current production in various forms $135-$200.00.

I). KIWA Loop 1992 First Air core available since Nelson/Sanserino. Uses IC amplifier Opto isolated regeneration and varactor tuning. High performance, solidly built, in current production. $360.00.

J). RSM Communications (Ray Moore) RSM-105 (1994) A high performance transformer coupled, non amplified antenna described by Moore in Dec 1994 IRCA DX Monitor, Later in March 6 1995 issue of NRC DX News. Still in production? Price?? 35″ spiral wound.

4). Electrical Design Characteristics

A). Two main types of Loops available 1). Directly Coupled and 2). Indirectly coupled (Transformer coupled) The Directly Coupled Loop has its windings directly attached to an Amplifier. Usually the main Tank Coil (parallel tuned circuit that forms the loop primary) in the loop is grounded at the center of the winding (center tapped), to allow for electrical balancing. The Amplifiers are usually but not always J-FET’s, with 2 FET’s in a Differential configuration, where the ends of the tank winding go to each FET gate. The Transformer coupled version uses a link winding to couple the signal to the receiver. This version can be amplified or non amplified.

B). The pick up pattern of a properly designed loop should be a figure 8 pattern. The null should be of the same depth, if the antenna is rotated 180 degrees horizontally (loop should not be adjusted for alt-azimuth, but left vertical 90 degrees from the ground). The 180 degree symmetry should be the same + or – one degree. If this condition does not occur the Antenna is not properly balanced. In a transformer loop balance deals with the signals being equal on both lines of the feed line (equal potential to ground). The feed line should preferably be shielded with the shield being grounded to the receiver chassis. If the line is affected by an electric field signal, a metallic object, or some other imbalance to ground, the loop will become unbalanced, resulting in a distortion of its pick up pattern. Balance is critical to getting the best nulls, and for precision Radio Direction Finding. The use of a broadband balun allows for better balance, but thought should be put into the design of the link winding, and receiver feed line, as well as the mechanical integrity of the coil.

C) The transformer coupled loop is the easiest to balance, especially if it is an air core loop. Ferrite loops are not as easy to balance due to the compression of flux lines in the ferrite. These antennas seem to be somewhat more prone to pick up electric fields.

D). In a directly coupled loop, the balance is affected by the gain of the amplifying devices on either side of the center tap being equal. If they are not very close to, or equal, they will cause the voltage in the tank coil to be imbalanced with respect to ground causing the same undesirable effects that the feed line caused in a Transformer Loop.

E). Some loops utilize a Faraday shield to maintain balance (4) Usually a one turn loop. these are usually circular, and are used on ships and other areas where direction finding is necessary. An example of this antenna is the 160 meter loop wound out of coax described by Doug DeMaw (5) Using a Faraday Shield will affect the pick up gain, as well as the “Q” of the tank coil(3) Another variant of the shielded loop is the Mike Hawk Loop(6)

Also note that imbalance is sometimes referred to as “Antenna Effect”(4) Also please note that a balanced loop antenna can be spoiled to a cardioid pattern by putting a vertical sense antenna within its field.(4)

F). The amount of coupling (placement of the link turn) is critical to the performance of the Transformer Coupled Loop. The placement can vary depending upon the load that the antenna sees. The best way to obtain optimum performance is to experiment with various distances from the Tank Coil. Most designs call for this to be wound amongst the tank coil windings, however this coupling is much too tight for most uses, and allows for tuning to be too broad, Q to be too low, and sensitivity to be not quite optimal.

G). The physical size of the Loop Tank Coil affects the overall pickup (capture ability) of the loop. The larger the winding size the greater the pickup. Larger loops will also be easier to balance than smaller ones.

H). The Tuning Sharpness “Q” is determined by the size of the wire (surface area). The lower the resistance the higher the “Q” will be. The loading of the Tank Coil also affects the “Q”. This more than wire resistance affects the Transformer Coupled Loop. In a Transformer Loop, the placement of the Link Coil in relation to the main tank (distance) determines the amount of coupling, and hence the loading of the tank circuit. The point of critical coupling can be found by varying the coupling link distance, while comparing tuning sharpness and gain. the critical coupling point will be found at the sharpest tuning before the gain starts to drop. Tuning will continue to sharpen (slightly), but gain will fall off more rapidly, as one couples more loosely (moving the link physically farther from the Tank Coil). Further improvement can be had by matching the load impedance to the link coil with a matching transformer. This can be done as part of a balun, or following the balun (lead-in side). For optimum performance all impedance’s in the system should be properly matched.

I). The L/C ratio and mechanical design of the coil should be considered when looking at a good design for a loop. The loop should be mechanically stable (wires not flopping loose) The distributed capacitance between turns should be kept low by proper design to allow for wide tuning range, but not too wide to degrade the length to diameter ratio of the coil. Note that the best null performance occurs with the best length to diameter ratio of the Tank Coil. A spiral wound coil affords the best performance in this regard, but does not afford as great a signal pickup as a solenoid coil of the same diameter. (A Trade off)

Also note that the L/C ratio should allow for one 10 to 500pf variable capacitor to tune the whole Medium Wave Broadcast Band.(530-1700 KC)

J). Performance can be further enhanced if the amplifier following a transformer coupled loop is tuned. This provides still better image rejection, and adjacent channel selectivity. It is important that the amplifier be isolated from the loop by a transformer to maintain balance and pattern integrity.

K). Note that the spacing of the windings determines the inter-electrode capacitance. The wider the spacing between windings, the lower the capacitance, and the higher in frequency the loop will tune. the use of interlaced spreaders further reduces this effect (solenoid loop) provided that the spreaders are of sufficient width. Also note that the winding spacing is a compromise with the length to diameter ratio.

Construction Principles

5). Mechanical design

A). Up to now, loops were made from wood. It was used because it was readily available and easy to work with. Wood does have disadvantages. They are, finding good wood, making accurate cuts, and heavy weight.

B). In a wood loop, the alt-azimuth tilting mechanism does not work very well. Wood loops use a bolt for the alt-azimuth tilt. It uses an arm that goes from the loop to a clamping setup on the mounting post. This does not work very well, as you need to tighten the bolt every time that you change the vertical tilt. The bolt will become loose, and on high angle tilts does not hold very well.

C). Most loops use a pipe mounted vertically with a dowel to do the horizontal rotation. This does not work well, as it allows the loop to move on it own. Wood will also wear after some use. This allows the loop to lose its square ness which can affect the loops pick up pattern.

D). The first loop I built was the Harley Loop(7). It is small spiral loop that was easy to build, but had no Alt-Azimuth feature, so the loop would not vertically tilt. It uses two cross arms with saw kerfs part way through to hold the wire.

E). I then built the 4 foot NRC Loop(2). This loop worked well, but the Alt-azimuth tilt needed work so I did some modification on the tilt mechanism. I wanted to design a tilt that would be easy to tilt and would stay in place. I tried different ideas and in my design I used a 3 inch PVC pipe for the mast and the loop head would tilt off that, this did work better but was not perfect.

F). While talking to Mike Bates(1995) about loops, He had the idea to build a large spiral octagon loop(5ft), out of PVC pipe and Alt-azimuth tilt it with a tripod. We built the loop, and this got my interest in using PVC for designing and building loop antennas. The tripod did not work very well due to the heavy weight of the loop head, but the performance was quite good.

G). My next design was a 4 foot PVC spiral loop that is collapsible. New features added to this loop was the use of a lazy susan for the horizontal rotation of the loop, however, you need to use a liberal amount of grease to give it tension. For alt-azimuth tilt I took a 3/4 inch PVC tee, reamed out the inside smooth, and cut a slit length wise. Through this I ran a piece of PVC pipe and with the use of elbows and tees attached it to the loop head. I then used plastic hose clamps to adjust the tension. This worked better, but still did not work very well. It is hard to get the angle just right, it does not move smooth enough.

H). Then I built a 4 foot Loop modeled from the NRC plans(2) out of PVC. For this loop I added the use of PVC in the base. I used the same type of Alt-azimuth tilt mechanism as the earlier spiral. To mount it to the loop head, I used a hole in the crossover of the loop to attach to the alt-azimuth mount. This was done to allow for having the ability to build different loop heads, like one for the longwave beacon band. This allowed the loop head to rotate on the mounting mechanism which made the loop unstable, and not very easy to use. I decided to make the mounting like the spiral loop, but to add the tees, I needed to cut part of the tee to mount it on the loop arms. When I assembled it for fit, I found out that cut out tees worked much better for tilting, and hose clamps are no longer needed. The alt-azimuth tilt mechanism now works very smooth and holds well at all angles.

I). The 2 foot loop was also built based on the NRC plans(8), it employs a gimbal mount for alt-azimuth tilt.

J). These loops are made entirely out of PVC except for the base plate that employs a lazy susan to rotate the loop. I built jigs to drill the holes in the cross pieces. A drill press helps a lot, but with very careful measuring and drilling, a hand drill may work. In my first loops I used PVC cement to glue the loops together. This cement sets up very fast, so you have to be very careful assembling it. I found out that some parts can be glued, but on some it is better to use a small nylon screw. This allows for you to align the pieces right on. To do this drill and tap a hole for the screw and run it though both pieces of plastic (PVC).

K). It helps to make a jig to wind the tank coil onto the frame. To accomplish this I mounted a Lazy Susan to a board, and ran a board with two vertical pieces of PVC Pipe The loop frame slides over the pipes, allowing the loop to be rotated while the wire is brought off of the spool in the same direction, while being laced through the holes in the frame. This helps greatly, in minimizing twisting of the wire.

L). Reasons for using PVC in loop construction:

1). Readily available, at low cost

2). Easy to work with, Saw and drill are main tools required, however, a miter box saw allows for clean perpendicular cuts.

3) Very symmetrical loops can be built, because the fittings are identical, and pre made.

4). Very low weight

5). The ability to come up with modular designs

6). The ability to design a collapsible loop that can be mechanically strong, allowing for easy transport

7). The use of spacers will tighten up the wires, so that they do not flop around, and distort the pickup pattern, as well as reduce inter-electrode capacitance. This makes for a very stable loop.

M). Notes:

Loop shapes: Triangle (Wedge), Square (Also called box, this is the most common shape) Octagon, Circular.

Note that the box loop is used because it is the simplest to build. The circular loop provides the nearest to the perfect shape electrically, but it is very difficult to fabricate a multi turn loop of this type. The octagonal loop is the practical compromise. Also note that the Octagonal is more difficult to fabricate due to it having 8 arms instead of 4, for the box loop.

What Can I use a Loop For

6). Using the Loop practical applications

The small loop is a versatile antenna, and can be used for many different applications, here are a few.

A). The loop can be used for improving the performance of a poorly designed broadcast receiver. Depending on the type of antenna that is in the receiver determines how the loop can be attached. It may be attached via a transmission line if the set has wire or screw binding posts for the Antenna, or it may be inductively coupled (transformer) for a receiver using a very small loop. In the case of the receiver with a small loop the coupling rules apply as if the receivers loop is the link turn in the Transformer loop. (Note that the link coil is not needed for the loop to work for this, as the internal loop in the receiver is receiving the signal from the main tank circuit). The distance from the receiver to the larger loop will determine the amount of coupling, and tank loading. One can vary the pick up pattern by varying the angle of the receivers internal antenna to the external loop. The antennas provide maximum transfer of signal, and closest to a figure 8 pattern. when the pick up angle of the antennas is opposite parallel (90 degrees) (Beams of the antennas aimed at each other) Minimum pickup occurs at 180 degrees. The pattern can be spoiled to a cardioid (null in only one direction) by varying the angle. Please note that the pattern will probably be somewhat spoiled from a figure 8 at the maximum signal 90 degree points. Please note that there are 2 commercially available products designed to inductively couple to the receiver, and improve its signal. These are the “Select A Tenna”, and the “Q Stick” by Radio Plus (Gerry Thomas). However a 2ft or larger loop provides for much better performance provided one properly adjusts the coupling. A Large loop (4 ft) can cause a poorly designed receiver to overload. Loosening the coupling will allow for the overload to be eliminated. One must also be sure for proper operation that the loop is tuned to the same frequency that the loop is tuned to, or unwanted overload effects will likely be noted. All tuned circuits should be “aligned” to the same frequency. Also note that high Q tuned circuits can sometimes be touchy to adjust “spot on”, some practice will probably be necessary. One can be amazed at the improvement in performance when using a properly designed loop. Stations can be brought from out of nowhere on a poor set. Images at the low end of the broadcast band will be cut down significantly or completely eliminated. As stated previously, adding a properly designed tuned amplifier further improves the performance of the system. The amplifier can be fed by feedline to a coupling link that couples to the receivers internal loop, or can be direct attached to a receiver with antenna connections.

B). A loop when properly balanced can be used to “null down” AC Line noise, TV Sweep Harmonics, or other locally generated interference. The Alt-azimuth feature helps greatly reduce, sometimes totally eliminating the noise. This feature is also quite useful for nulling of co-channel, or adjacent channel broadcast band stations. If properly balanced, nulls of over 60 dB may be attained by using the Alt-azimuth feature. Deep nulls can be difficult to find and maintain. A larger antenna allows for one to find the null more easily due to the larger pick up(field) created by the loop. Loops of 2 ft and smaller in diameter, can be quite touchy to null, and electrical balance can be quite hard to attain. Hand capacitance can also affect the null in these small loops, causing the null to move as ones hand is moved away. This effect is minimized when using a large loop, as your whole body is within the pick up pattern of the loop, and it will be less likely to distort the pattern. One needs to be 6″ to 1’ away from the small loop(2ft and smaller) to avoid the hand capacity effects. It is also notable that nulling works best on local ground wave signals. Distant sky wave signals can be more difficult to null. It is difficult to get a null of greater than 30 dB on a sky wave signal at the top end of the broadcast band at night. For Sky wave, phased antennas provide for much better nulling, but are much more complex, and difficult to operate. Also note that the higher the Q of the tank coil, the sharper the null. Sometimes the null will be excessively sharp, and difficult to find, or the null will be so narrow in bandwidth that the carrier of a station will be deeply nulled, but the sidebands will be well received as slop(splash). This affect is more noticeable in small, or amplified direct coupled loops.

C). Radio Direction Finding

One can accurately direction find signals provided that the antenna is properly balanced as described above. The general concept is that the deepest null will be in the direction of the signal being checked. You cannot use the Alt-azimuth feature, you must keep the loop perpendicular 90 degrees to the ground. An accurate compass, and a marked 360 degree circle can be used to pin point the exact bearing that the signal is coming from.

Bibliography from the three articles above can be found at the bottom of this page.

Loop Antennas Another Look

The last 30 years have brought about much refinement in the design of loop antennas. Starting from the basic box loop described by Ray Moore, major developments over this time are; The NRC 4ft Alt-azimuth loop, the Space Magnet, Sanserino Loop, Palomar, Mckay Dymek, Radio West, Quantum, Lankford, Kiwa, and RSM 105, and 103. As time has progressed, so has the design of Receiving Equipment, from the R390A, HQ-180, and SX-122 and Zenith Trans-Oceanic to the Sony 2010, Drake SW-8, Drake R8-B, and the AOR7030 Plus. Antenna needs have changed, with today’s broadband front ends, and synthesizer phase noise a concern, a high performance loop, or other means of pre-selection is more important than ever.

We will show a slightly different twist on the same basic loop antennas of the past, with a couple of refinements, as well as construction details of our antennas.

To explain our antennas we want to start with the design criteria necessary to improve the modern communications receiver, as well as consumer grade radios such as, the Super Radio III, the Radio Shack Optimus, and most other portable short wave/broadcast receivers.

Important loop criteria have been explained before in the pages of DX News, and the NRC Antenna Manuals, however, a review is in order. It is our opinion that there are 4 basic parameters that loop performance should be based upon; 1). The loops signal to noise ratio. 2). The electrical Balance. 3). The selectivity or “Q” of the loop. 4). The mechanical rigidity/integrity of the coil assembly, and Alt-azimuth mechanism.

Signal to Noise Ratio

Most efforts during the last 30 years have dealt with making loops smaller, to allow them to be used by the DXer who has limited space. S/N ratio has suffered as a result. The use of direct-coupled balanced FET amplifiers, and smaller, and smaller loop coils means that the bulk of the work in the system is being done by the amplifier. If you capture a very tiny signal, and add some amplifier noise to it, you have degraded what signal that you have to the point that you may bury a signal slightly above the noise floor. A rule of thumb would be to use no more amplification than is necessary. It is better to make the coil larger to enhance the capture area, and insure that what amplification is used is as low gain, and low noise as possible. The small loops are probably OK for most uses, but when you want to extract the last decibel out of the ether, a larger loop that is properly designed will be best.

Electrical Balance

The electrical balance of the antenna insures that the current at the termination of one end of the loop tank coil is of equal magnitude and opposite polarity to that at the other termination of the loop coil. (A is equal and opposite B) When properly balanced the deepest possible null will be obtained, with the loop. Please note that balance is quite difficult to attain. Anything connected to the tank coil (or other metal brought physically near it) other than the resonating capacitor, can throw this balance (equal and opposite) off. This distorts the theoretical figure 8 pattern of the loop. If a link turn is used to couple the loop to the receiver, this link and the transmission line must be balanced, or coupled to an unbalanced line (Coax Cable) using a Balun. The link coil should be balanced, as well as the main tank coil. Using a balanced FET amplifier on the tank coil will throw off the balance if care is not to insure that the FET’s are not exactly matched in their gain and transconductance. Not to mention that an amplifier not properly balanced, and running at excessive gain will be prone to create intermod products which degrade further the performance of the system. If a loop antenna seems to have a problem with hand capacitance it is a pretty good bet that it is not properly balanced. Refer to Nelson’s article for detailed hints on how to attain balance.

Selectivity

The “Q” or quality factor of the tank coil will determine its selectivity at resonance (the tuned frequency). If the “Q” of the tank coil is loaded (reduced by the effect of a load on the coil), the “Q” will decrease, and the selectivity of the loop will decrease, or broaden. In the late 60’s Nelson devised the balanced FET amplifier as a way to minimize the loading of the tank coil. This allowed for selectivity that was so sharp that a loading potentiometer was added across the tank coil to reduce the “Q” so that the loop could be more easily tuned. Prior to this, loops were of the transformer variety, with the signal being coupled to the receiver via a link turn, wound amongst, but not attached to the windings of the main tank coil. This process did not take into full account transformer theory, as the loop is now a transformer due to the link coupling. The main drawback of the early designs is that they did not use the coefficient of coupling when designing the loops. Moving the winding away, somewhat from the main winding allows for less loading. Maximum energy transfer from the tank to the link would occur at “critical coupling”. The load impedance also affects the loading, and should be matched to the impedance of the link turn, as well. As stated before the link should be balanced. A balun, and matching transformer should be used with a modern receiver with a 50 ohm coaxial input. The distance that the link turn is from the primary tank coil greatly affects the performance of the loop. The “Q” can be greatly improved, as well as the S/N ratio if the link turn is placed at the critical coupling point from the main primary tank winding. This distance from the main winding can be approximately determined prior to winding the link turn using a pocket radio. Tune the pocket radio into a station that is within the tuning range of the loop. Start out with the pocket radio placed facing the plane of the loop (see fig 2) right against the loop winding, rotate the loop capacitor for a peak (maximum signal) on the pocket radio. Now move the pocket radio ½” from the winding and re-peak the loop. Observe how sharply that the loop tunes. Move the pocket radio away from the loop in ½” increments. Observe how sharply the loop peaks on the pocket radio, as well as the signal strength at each point. The loop should peak more sharply, and increase its gain as the radio is moved away. The point of critical coupling is attained when the signal is at maximum, the sharpness may still increase somewhat, but the gain will fall off more rapidly as the radio is moved away. Note the critical coupling point, and wind the link coil this distance from the main winding. This process can also be used when passively coupling the loop to a radio using a ferrite antenna, or when using a device such as a Select-A-Tenna, or a shotgun loop , or “Q” stick with a radio with a built in loop.

Mechanical Integrity

Another consideration when building a loop is the mechanical design. This is often overlooked, and can affect the loop balance if the mechanics are sloppy. There are two different types of loop coil designs, The solenoid or box wound, and the spiral or pancake wound. Each type has several advantages, design trade offs, and dis-advantages. The box loop has a higher gain for the same diameter, but is more difficult to balance. With this type of loop there is a trade off between the inter-electrode capacitance and the length to diameter ratio. Spreaders can be used to cut down on the inter-electrode capacitance, and to maintain coil rigidity. Note that the better the length to diameter ratio of the tank coil, the nulling ability is enhanced and balancing is easier. The spiral loop has the advantage of almost perfect length to diameter ratio, as well as being easier to balance. The main drawback of the spiral is its lower gain than the box loop. Also, if an amplifier is used, it is much more difficult to tap the tank coil at its center. An amplifier can be used more practically with the spiral by attaching it following the balun and matching transformer. This way the amplifier is isolated from the loop, and the undesirable unbalancing effects can be avoided. Note that an amplifier should be used only when necessary, and should be as low in gain as to improve signal strength on very weak signals, where not using it would yield them unreadable. It is important that the loop antenna be well constructed mechanically to insure that the wires do not flop around, to distort the balance, as well as to prohibit the need for re-winding. We have switched from wood to PVC in our designs, with a minimum of metallic objects near the tank, and link coils. Note that metallic objects within the near pick up field of the loop will induce a voltage into the coil unevenly and throw it out of balance.

Bibliography

1). NRC DX News March 6, 1995, IRCA DX Monitor Dec 1994

” The Full size Full Performance Loop Antenna” Ray Moore

2). NRC Antenna reference Manual Vol 1 Dec 1995 Edition

“NRC Alt-azimuth Loop antenna P6

3). NRC Antenna Reference Manual Vol 1 1985 Edition

“HQ tests the Space Magnet” P40

4). ARRL Handbook 1988 Edition P39-3

5). QST Magazine July 1977 “Beat the Noise with a Scoop Loop”

Doug DeMaw

6). NRC Antenna Reference Manual Vol 1 Dec 1995, “The Hawk Loop”

7) NRC Antenna Reference Manual Vol 2 Dec 1995 “The Harley Loop” P 11

8). NRC Antenna Reference Manual Vol 1 Dec 1995 P21 ” The NRC 2 Foot Loop”

Suggested Reading:

1).National Radio Club Antenna Reference Manuals Vol 1 and 2 1995. Available from the National Radio Club P.O Box 164 Mannsville, NY 13661-0164

2). National Radio Club Loop Antennas Design and theory 1995

Available from the National Radio Club P. O. Box 164 Mannesville, NY 13661-0164

3). ARRL Antenna Book 1994 American Radio Relay League, 225 Main St., Newington, CT 06111-1494

4). Joe Carr’s Receiving Antenna Handbook 1993, High Text Publications P.O. Box 1489 Solana Beach, CA 92075

Article originally available at http://www.frontiernet.net:80/~jadale/Loop.htm

The post About Loop Antennas appeared first on IW5EDI Simone - Ham-Radio.

Quickie Vertical

Hear I am sitting in front of the rig listening to everyone working CQ World Wide, and I don’t really have time for this, but I hear a few interesting stations on 20 meters and try to call them. Trying to bust the pile up with 100 watts and my hustler dipole is going to be difficult on this band, so I tune up on 15 meters and there is action, and I have a good wire beam, so I tune up and down the band and can’t find a clear frequency. Then I hear some one say that 10 meters is open. So I tune up there, and there is a world of DX coming in. I choose a few interesting ones to call, but can’t be heard. I should have expected that, as my antenna for this band leaves much to be desired. It is a vertical above my Hustler dipole, but it has no effective ground plane and SWR no better than 3:1 at its best frequency. With no time to assemble a Quad, I start thinking about a better vertical.

Suppose I take the parts for the quad and make a good ground plane and put the mobile whip above it. That won’t take long. So I quickly assemble a short 4′ mast with a center hub and add four 8′ long 1/2″ diameter fiber glass spreaders and set in on my test stand in the center of the back yard. I dig into my portable antenna box and find an extra mirror mount (Radio Shack variety) and mount it at the top of the mast. Oh, the bolts are too short for the 1″ mast, so I am off to the hardware for 2″ bolts. I remembered that I had cut eight #16 solid copper wires for a ground mounted vertical about a year ago, so I unroll 4 of them and attache them to the lower bolts on the mirror mount and tape the other ends to the tips of the spreaders. I then tighten the wires by dropping the hub 30″ below the mirror mount which pulls the spreaders into the horizontal position and allows the radials to drop at about 17 degrees. Quickly, I mount the Hustler 10-meter whip, connect the coax, and check the SWR. The SWR is great, 1.1:1, but at 29.6 MHz. So I add two more inches to the stinger and recheck. That gave 28.6 MHz for best SWR which is now 1.2:1. Not bad, a total of a half hour has passed, and the same stations are still holding the frequencies. So I start down the list that didn’t answer earlier. To my amazement I work each one within a minute. So there I sat wishing I had time to work the contest.

To complete the story, the radials are 101″ inches long. The spreaders were at an elevation of 4 feet above the ground. Later, I raised this to a height of 8 feet, and nothing much changed. I also tried resonators for 12, 15, 17, 20, 30, 40 and 75 meters with equally good impedance matches, but I didn’t raise them up. The table below gives the measured SWR and bandwidth for each band. A photo of this antenna is shown below the table. As I really didn’t design this antenna, we have to call this one just plane luck. By the way, if you want more radials, it is possible to use two hubs with one rotated 45 degrees to the other. Add four more spreaders to get 8 radials. This might reduce the stinger lengths a little, as mine are fully extended on a few of the bands. The 20 meter Ham Stick wasn’t long enough to get down into the CW portion of the band, so I added four alligator clips to the tip of the stinger. This worked about the same as the Hustler, So here is an antenna that can be set up in as little as 15 minutes once you have the parts together. If you paint all the parts black, it is nearly invisible at night and not objectionable by day. Note that this antenna works fairly well on 75 meters, but does not work well on 30 and 40 meters. I’ll tell you why some time later after I figure it out.

Note, the bandwidth is the SWR bandwidth for 2.0:1, and the stinger length is measured from the top of the compression nut. All configurations use the Hustler MO-3 mast part, and all resonators are the low power versions. It is interesting to note the excellent match on 75 meters. Normally, this whip gives a much lower impedance when set on a good ground plane, so this probably means that at least half of the power is going into the ground, even more is lost in the loading coil, but it still works pretty well.

Article by  KQ6RH originally available at http://w2so.org/projects/antennas/quickie-vertical

The post Quickie Vertical appeared first on IW5EDI Simone - Ham-Radio.

The Grid Yagi (or Grid Quad) is a high performance yagi antenna that can be built with readily obtainable inexpensive materials. Described here is a 6 element 2 meter version with a boom length of about 1 wavelength.

The boom is made of 11?2 inch pvc pipe, although any suitable material can be used, such as steel, aluminum, fiberglass, or wood. The elements are cut from 2 inch by 4 inch galvanized welded wire fencing, with a wire diameter of 0.078 inch, which is what #14 steel wire becomes when it is galvanized.

This fencing material and pvc pipe are available in any hardware store. The driven element and the four directors are all 24 inches by 24 inches. The reflector is 32 inches by 24 inches. The driven element has an 18 inch slot in it and is fed at the bottom of the slot. At the other end of the slot is a shorting wire.

I attached the elements to the boom using 1/8 inch diameter fiberglass rods. Holes were drilled in the boom, and the rods passed through the holes and around the wires of the elements, two rods per element. Figure 3 shows the two fiberglass rods passing through the boom and around the wires of director D4. Rods were also used to stiffen the driven element where the feed slot was cut (not shown). The fiberglass rods were obtained locally at Tap Plastics.

It should be possible to use other stiff materials such as shish-kabob skewers. The element positions are shown in the Table. The elements can be glued in place or left unglued for easy disassembly.

Simulations were done using 4nec2, Arie’s version of nec2, available free at Ray Anderson’s Unofficial NEC Archives.

The antenna was fed with approximately 50 feet of RG-8 type coax with a measured loss of 1.3 dB through a W2DU type balun [3] with three Amidon beads, type FB-43- 1020 [4]. Figure 4 shows the simulated and measured SWR. The SWR measurement was done using a MFJ-259B SWR Analyzer. I could have adjusted the length of the slot to move the SWR minimum to another place in the band if I desired.

The simulated gain is 11.9 dBi at 144 MHz, 12.1 dBi at 146 MHz and 12.3 dBi at 148 MHz.

Article by ross_anderson originally available at http://home.comcast.net/~ross_anderson

The post The Grid Yagi appeared first on IW5EDI Simone - Ham-Radio.

Let me first say I make no claims of originality for this item. It is intended as a simple, inexpensive solution for the newcomer to experiment across the 40m band (7.0–7.2MHz) when only restricted space is available. “A picture speaks a thousand words” so by including a couple I’ll keep it as short as possible!

With the rally season upon us, it is an ideal time to pick up those bits and pieces with which to experiment. The antenna described here consists of a 50R coax fed, inductor loaded 5.44m vertical section mounted on a 1m alloy tube driven into the ground and requires no radials although this may well depend on the local soil structure.

The vertical itself is a salvaged unit (probably ex. CB) consisting of 4 telescoping aluminium sections with an extended length of 5.44m and its mounting bracket.

The thick wire in the picture is the coax centre connection from the bracket mounted SO239 connector to the coil.

The coil is of open air construction, 19 turns of 18 gauge copper wire equally spaced over a length of 72mm with an inside diameter of 63mm and with the coax centre connected 9 turns from the antenna end of the coil and to the opposite end of the coil. I know this may seem strange but it works.

Connect to a transceiver, check the SWR and if necessary adjust the antenna length or coil tap slightly and away you go, it’s that simple!

With the antenna set to resonate at 7.1MHz I found there was little need for adjustment by the internal ATU of my TS2000 or FT1000MP-MkV to cover the entire band.

Copyright David Barber G8OQW

Originally available at http://www.southgatearc.org:80/news/march2006/40metre_vertical.htm

The post A 40m Vertical Antenna appeared first on IW5EDI Simone - Ham-Radio.

A windom antenna for 10 to 80 meters band – a design by PU1LHP

The post Windom Antenna 10-80 appeared first on IW5EDI Simone - Ham-Radio.

This 2m yagi uses design data from DK72B’s excellent yagi website. The element to boom mounting used here may be of use to some as it does not use any polamid mounting / insulating clamps at a cost of 2 euro each ( this is a 7 el crossed Yagi so twelve clamps would be needed ).

The photographs show how the 12mm dia tubular elements are mounted to but insulated from the boom ( apart from the electrical center of the element where the bolt passes through ).

A 25mm ( the width of the boom ) length of plastic 15mm dia central heating pipe is cut along its axis. A suitable size hole is drilled through the center of the pipe to allow the mounting bolt to pass. The plastic pipe is then slid over the element and the mounting bolt passed through the element / plastic pipe and secured to the boom. End cheeks made from perspex sheet are then slid over the element and screwed to the boom using stainless steeel self tappers.

All of the aluminium used for this antenna came from a disused 6m Yagi and a scrap 2m ZL special. The dipole centers from the 2m / 6m antennas are also utilised here.

The driven element feed point has a impedance of 28 Ohms, so a quater wave transmission line transformer with a characteristic impedance of 37.5 Ohms ( two 75 ohm coax cables in parallel ) is used to transform the driven element feed point to 50 Ohms.

The quater wave matching section is made from Webro WF100 75 Ohm low loss satelite cable. A MFJ-259B antenna analyser was used to determine the physical length of the matching section. Using the above cable the length is 38cm from one end of the outer sheath to the other ( i.e. the coaxial intact length, not including the flying lead ends ).

The matching section connections to the N connector are thoroughly insulated / sealed using self amalgamating rubber tape. Small drain holes are drilled in the dipole center’s lowest point to allow escape of water rather than it going down the coax, over the years I have given up trying to seal such connector housings, numerous methods have been tried and all have eventually failed, a couple of 4mm drain holes saves a lot of grief.

The driven elements were adjusted slightly ( 3mm ) to bring the antennas exactly resonant in the two parts of the 2m meter band, I set mine for 144.3 MHz ( SSB ) and 145.3 ( FM ), my thanks to my ever patient Wife for holding the antenna / mast whilst these adjustments were carried out.

Article by M0DGQ originally available at http://www.m0dgq.co.uk/2m crossed Yagi.html

The post 2m crossed yagi antenna appeared first on IW5EDI Simone - Ham-Radio.

The Gamma match is the most used matching device used for yagi beams.

What it does is:

A Yagi almost never has an impedance of 50 ohms. In other chapters i told that Gain, bandwith, F/B etc. all relate to eachother these figures are never all high at one point. A well designed yagi has for that reson an impedance around 20..25 ohms.
A Gamma-match can match impedance below 50 ohms right up to that 50 ohms wich your tranceiver wants to see.

The thickness of the rod should be around 1/2 part of the radiating element, The lenght in the order of 0.05 wavelenght long.

This comesdown to

The desgribed Gamma-match is used for 11 meter Yagi’s with an aluminim element thickness around 25mm !!!!!!!!
I am however convident that with slight adjustments it will work for other diameters.
For the dimensions I took the outside diamter of the radiating element (F) in the order of 2,5 CM.

F is an aluminum plate and should be about 0,5 cm thick and wide enough to hold a N-connector female or
the equivelent PL version. Preferbly in an L version so you can attach it to one of the U-bolts holding the
radiating element to the boom. The hart of the connector should be 10 cm from the hart of the radiating element

A the N- connector female or the PL version

!!! is between the two aluminium tubes B and C must be NON-electrical guiding material for example:
the “plastic” used in coax-cable.
The length of it must be a bit longer then the lenght given “G” !!!

C The long aluminum tube about 1,3 cm thick and 70 cm long.

D An aluminium plate drilled with three holes 1) the driving element

2) the tube D

3) on top a screw to hold it in place.

the holes should be from center to center 10 cm separated

E the radiating element also called driven element.

B Aluminum tube with a length of 13,5 CM diameter 1,8 CM (C and D goes into it)

By adjusting the aluminum plate left or right, you should be able to get a low SWR.

This Gamma-match can handle up to a couple KW’s.

Article originally available at http://dx-antennas.com/Gamma_match.htm

The post The gamma match appeared first on IW5EDI Simone - Ham-Radio.

The Wonder Whip?

A £10 QRP Portable Multiband Antenna for HF, VHF and UHF

A variation on the “Miracle Whip” and “Wander Wand”.

The Wonder Whip

Context

I enjoy low power, portable operations, from various headlands on St Mary’s and also from some of the more remote off-islands around my home, on the Islands of Scilly.  My Yaesu FT857D acquires its RF signals from an ad-hoc antenna system, based around; a telescopic fishing pole, various bits and pieces of wire, a lightweight MFJ-901B ATU for HF; and a SOTA beam for 144MHz operations.  Many of the locations I visit are remote, rocky and without topsoil. In many circumstances, it is almost impossible to erect any form of antenna.  Often the soil is only millimetres thick and it is not possible to guy the telescopic pole.  Vegetation is low lying and making attachments to the granite rocks, to gain height, is not really feasible.  I wish to combine my interests in amateur radio with my desire to operate from the picturesque locations these islands have to offer.

 Existing Products

There are several commercial solutions to my problem: Miracle Whip, Wander Wand, Buddistick, ATX Walk-about and various Maldol and Diamond systems.  Reviews of these products suggest that they all work well, within the limits of a very short antenna and radiating elements. It is notable that many of the reviews, highlight the lack of any facility to attach a counterpoise. These ready made, commercial solutions, come at a high economic price. Against the background of what I need, I have set myself the task of designing and constructing a portable multiband QRP antenna system. The main constraints are economic, my limited antenna design expertise, the availability of materials (no radio shops in the Atlantic!) and my very limited test equipment.

The Autotransformer – Miracle Whip

Trawling through the Internet I discovered an article by Robert Victor, VA2ERY, who described his investigations with an autotransformer, as a solution to achieving multiband, QRP, portable, HF operations. Briefly, he describes methods of transforming impedance, using a transformer rather than a loading coil to match a short whip over a wide range of frequencies. The autotransformer may be considered as a double wound transformer; the bottom, primary part being connected to the rig, whilst the secondary is connected to the whip. The impedance transformation is the square of the ratio between the secondary and primary windings.  The tapping point varies the ratio between the secondary and primary windings and establishes an impedance transformation. The article can be read in full in QST, July 2001 © ARRL. 

 The VA2ERY design is a continuously variable autotransformer, based on a coil transformer of 60 turns with the impedance ratio selected by a wiper sourced from an “Ohmite” rheostat. Clearly there are considerable manufacturing difficulties in producing and winding the transformer core and the need for accurate construction and placement of a wiper mechanism. 

 Using VA2ERY’s autotransformer concept as a starting point, I experimented with a compromise design which would allow me incremented tuning (rather than continuously variable), with the advantage of less rigorous mechanical complexity.  After some experimentation (trial and error) my final design employs a 36mm outside diameter, ferrite ring and is wound with 48 turns of  either 16, 18 or 20 gauge copper wire.  The core is tapped at every second turn. Fine adjustment is achieved by altering the length of the whip.

23 TAPS

To allow finer tuning, particularly, for 7MHz through to 1.8MHz the “23 TAPS” diagram may be amended as follows:

• inserting an additional single tap at the point marked B;
• connecting the whip to the pole of a S.P.D.T. switch (single throw, double pole switch);
• connecting points A and B to the relevant “Throw contacts” of the S.P.D.T.;
• switching between A and B, reduces the inductance, and effectively gives access to the turn between each physical tap.

 Materials

• Telescopic Whip   Maplin LB10 HQ 10-section 1.31 metres    
• Ferrite ring           Fair-rite FT140-43 or RSGB 36mm                                
• Rotary switch       Maplin N89BX 12 way (2 off)      
• Black Knobs          Maplin KB4                               
• Antenna wire       16, 18 or 20 gauge
• S0239                  Sockets (2 off)                          
• Binding post        4mm
• Enclosure            Floppy disk box
• (Additionally I have included a 3/8th socket for mobile whips)

Construction

From Figure 1 it should be possible to assemble the various elements of the design, however the toroid requires further explanation. The toroid core is wound with 47/48 turns of 16-gauge antenna wire (see note above about smaller diameter Cu wire). The core is tapped at every second turn. Because 24 pole, 1 way rotary switches are not readily or economically available, two 12 pole rotary switches are used. The 12th pole of the first rotary switch is connected to the centre rotor connector of the second switch, to give 23 positions of adjustment. The 23 wire connectors to the toroid are directly soldered to the windings. This was achieved by: a, cleaning and “tinning” the relevant core winding; b, forming a small “tinned” loop to each connecting wire; c, positioning each wire on the tinned core winding, applying the heated soldering iron, which will melt the two tinned surfaces to fuse a secure joint. This process requires patience and care. The telescopic whip is 10mm diameter at the base, with a 4mm hole to accommodate the antenna wire. I modified an PL259 connector by drilling out the cable entry connector to 10mm interference fit, into which I screwed the telescopic whip. The whip is secured to the PL259 connector by finally soldering the antenna wire into position. The green 4mm post identifies the socket for the earth/counterpoise. A counterpoise may assist in lowering the SWR on some frequencies, particularly, below 14Mhz. Above 14MHz the use of a counterpoise does not seem to make any significant difference to on air reports – I disconnected my CP, halfway through a QSO on 18MHz and the other station reported no change in signal strength. I use approximately 10 Metres of 1.5mm diameter wire for all situations. Results suggest that a quarter wave length for the required operating frequency will work satisfactorily.

Operation

The antenna is tuned by selecting the required band on the radio, and then rotating the two rotary switches on the ATU until the highest background noise or signal is achieved.  The antenna peaks on receive and this will provide a good starting point for transmitting. Set your rig to a low power setting (5 watts) and transmit while observing the SWR meter. Rotate the rotary switch knobs until the SWR is optimised at the lowest level.  Fine adjustments to the SWR may be made by altering the length of the telescopic whip (not whilst transmitting).

VHF and UHF operation is performed by selecting position one on the control knobs and adjusting the antenna to a quarter wave length.

Horizontal polarisation, particularly for SSB 144MHZ operation  is achieved by turning the antenna on its side.

Performance

My subjective feeling is that receive performance is first rate. S meter readings appear very respectable. 

Transmit SWR results, using a 5 Watts carrier (23 Taps, without a counterpoise):

• 432MHz           1.5.1
• 144MHz           1.5:1
• 50MHz             1.1
• 28MHz             1:1
• 24MHz             1:1 
• 21MHz             1:75
• 18MHz             1:1
• 14MHz             1.5:1
• 10MHz             1.5:1
•  7Mhz              3:1
• 3.5MHz            8:1

SWR results, 5 watts carrier with (23 Taps with a counterpoise):

• 28MHz             1:1
• 24MHz             1:1 
• 21MHz             1:1
• 18MHz             1:1
• 14MHz             1:1
• 10MHz             1:1
•  7Mhz              1.5:1
• 3.5MHz            6:1

SWR results, 5 watts carrier (46 “Virtual Taps” with counterpoise):

•  7Mhz              1.3:1
• 3.5MHz            3:1
• 1.8MHz            4:1 

On Air Reports

Does it work well?  Emphatically YES.

 My first portable contact on 40 metres, using 10 Watts, was on Sunday 29th January 2006. Jan, at GB2IWM, gave me a 53 signal report on 7.057MHz.

SM4YPG, Lars, north of Stockholm reported, on the 31st January, 4/7 to 5/7. I was using just 5 watts.

 On Wednesday 1st February I contacted AC5N, /Portable from Star Castle G/008/C. Terry, in Oklahoma, USA, on 21MHz, using 15 Watts, reported 59 on his QSL card! A distance of 4400 miles using just 15 Watts into a 51 inch telescopic whip!

Early results are encouraging and I am hopeful that this little box of tricks, and my 51-inch telescopic whip, will serve me well on my next “pedestrian portable expedition” to the remote corners of the islands.  My initial enthusiasm is, however, tempered by realism, I have little expectation of making ground breaking DX. But if I can bridge the gap between Scilly and the Mainland and enjoy the occasional QSO when conditions permit, I will be happy. If not, well there is always the view……

Article by M1IOS John originally available at myweb.tiscali.co.uk/m1ios/html/wonder whip.htm

© M1IOS, John Goody January 2006

The post Wonder Whip Antenna appeared first on IW5EDI Simone - Ham-Radio.

I’ve installed the GAP Titan DX some years ago. Due to maintenance works on my roof, I had to put the antenna down for some weeks.

This week I’ve been able to restore the antenna on the roof. The Gap Titan DX is a vertical dipole with no traps, and with vertical elements making this antenna resonating on from 12 to 30 meters. 80 meters provided from a top capacitor, while 10 and 40 meters depends on the tuning of a cross shaped counterpoise at the base of the antenna.

I’ve already written several times about this antenna and how to tune it on several bands providing also a quick antenna reference you can seen here behind.

According to some OM there is a relation between the 20 meter stub and the 40 meter copper wire length.

Well, today after having restored back the antenna on the roof, I’ve not been able to obtain an acceptable SWR on the 40 meters.

With acceptable I mean SWR < 2.0 on the band. According to GAP this antenna shoud be able to perform well with acceptable SWR on all bands, but in the 10 years I’ve on the top of my head, it never performed on the 30 meters. SWR on 10 MHz has been always > 3.5.

Even today high SWR does not allow me to use on that band.

Here below the SWR reading I’ve captured with my new Antenna Analyzer by HG7AN.

It’s evident how 30 and 40 meters need some solutions.

I’ll try to contact GAP and will post the updates here.

Some pictures of current setup

The post GAP Titan DX Maintenance appeared first on IW5EDI Simone - Ham-Radio.

They say if it didn’t blow down it was not big enough, this one was big enough and it did blow, not off but up and over the top of the tower like an umbrella one very windy day in January 1974. I was at work and the XYL called and said the “thing” blew off the top of the tower- WOW, I imagined it in somebody’s living room. In fact it did not blow off it blew over the top, broke in two and slid down about ten feet an hung on the safety cable. When I originally built the thing I rigged this safety line of 3/8 inch aircraft cable from the tower to the four inch diameter boom just in case. I remember I used to laugh when I told people about the safety cable never thinking it would actually blow off the tower. The storm was really a bad one, very high winds with ice covering the boom and elements. In fact a drive in movie screen blew over just down the street from me. It was a very sad occasion, I was the one sad and the neighbors were glad. The obliging neighbors called the building inspector and he was waiting for me when I got down from the top after attaching a rope, disconnecting safety cable and cutting the coax cable and letting it down, smoothly. The inspector notified me that one of my neighbors said that it had blown down three times already this year. This beam worked very well for me for several years.

I apologies for the quality of the photo. Its the only one I have. What you see is what you get. Very narrow beam pattern, that’s not QSB man that’s my beam swinging in the wind.

The omega match was motorized because it was so far out on the boom.

The post 7 element Yagi for 20 Meters band appeared first on IW5EDI Simone - Ham-Radio.

2.4 GHz Cubical Quad Antenna – Introduction

The Cubic Quad antenna is a commonly homemade antenna in the range of about 150 odd MHz. Our little project was to design one of these for use in the 2.4GHz range for 802.11 wireless LANs. The reason these are seldomly used for 2.4GHz is the size.

The picture below is a 4 element cubic quad for the 147MHz range.  Large isn’t it.

The one we are going to build for 2.4GHz will only be 6cm long!

The Design

I scratched together an initial plan on how I was going to set about putting this together. The measurements came from the second (or third) link above. While each element was made the same as in the design, the support structure was changed to a much easier one. This was about the only advantage of building a really small antenna.

Materials

• 1 hot glue gun
• 1 soldering iron
• 1 soldering god (enter ChrisK)
• short length of coax with connector
• 60cm of builders wiring (stripped to get one solid copper wire ~ 2mm thick)
• 3 cotton buds (hehe I’ll get to that bit later)

Construction

After stripping the copper wire, we constructed the four elements as per the measurements I pilfered from the java application on the previously mentioned page. We bent the wire with a pair of pliars against a small anvil. The reflector and director elements were soldered closed by ChrisK, the driven element left open for connection to the coax.

From left to right…. Reflector, Driven element, Director element 1, Director element 2
The white sticks are cotton buds with the cotton crudely removed.

Each element differs in size from the next. From the reflector through to director 2, the sides of the squares get smaller by only ~0.1mm. Human error can really screw this up. As this is only really a prototype we are not overly concerned. However, when it comes to building the real deal, we have decided that getting a computer driven robot to cut out some copper on a fibreglass board with some precision in length and squareness would be a goer.

The next step is to solder the driven element to a nice thick and chunky bit of LMR400 We did this on an angle to prevent the ‘direct’ short.

Here lies problem number two. The space created by the gap between coax core and outer is huge in comparison to the size of the element. We decided that keeping the length of wire for the element was more important than the shape, so it is also not really square anymore…prototype. This would also ideally feed into a balun rather than directly onto the coax. We just need to figure out how.

We then built the rest of the elements onto the driven element with the assistance of a hot glue gun and some cotton buds. When you put cotton buds in the microwave for one minute next to a glass of water, they do not get hot. Ideal antenna construction material! The elements were distanced according to the java application. However, it should be noted that increasing the distance between the elements will increase gain at the expense of bandwidth. The final version will hopefully be totally adjustable for tuning.

We used three cotton buds and the hot glue gun to hold it all together. It is messy… prototype… but it is also very small. Hehe. You can still see the leftover cotton wool on the ends of the sticks

OK. So once all done, we did some very quick testing.

It worked! We didnt keep logs of the test as we intend to do it properly soon, but it gave a dramatic increase in signal, S/N and reduced noise. I will add test results to this page when they are ready.

Here is a closer look at the prototype.

Test Results

Two laptops with wireless cards were moved apart at such a distance where signal could be improved. One of the laptops was then given a balaxy dish (a galaxy dish that ChrisK modded to have a different balun and dipole). The balaxy dish was then replaces with the prototype cubic quad. Results were logged and the peak of all results were as follows;

 
          RX Signal Noise SNR TX Signal Noise SNR

Internal   -78      -97    20  -78     -94    17
Galaxy     -61      -99    38  -61     -94    34
Cubic      -70      -99    28  -70     -93    25

I am very encouraged by these results. The prototype cubic quad was a complete bodge job with very little precision. More precise elements may give better results. It was not adjustable due to the hotglue used to stick everything together. With tuning these results may be better. And there was no balun used, on account of my having to figure out how to make a balun for this little beasty. A balun would hopefully give me another 3db

Future Directions

The elements need to be more precise. Having them properly machined would be ideal. The support structures should be threaded. This will allow us to put plastic washers at each bend with some plastic nuts, giving us the ability to tune it for maximum gain/bandwidth.

A balun is required (perhaps). The signal is skewed about 15 degrees to the right (guestimate). We also need to figure out how to design the connection to the balun/coax in such a manner that will cause the least hassle to the shape and length of the driven element.

v1.2 is under way. v1.1 was scrapped before I put it together because I am still unhappy with the elements.

We have some good ideas on where to go from here, so watch this space for developments over the next week or so.

article originally available at http://members.iinet.net.au/~stygen/Quad.html

The post 2.4 GHz Cubical Quad Antenna appeared first on IW5EDI Simone - Ham-Radio.

An on the field comparison with the GAP Titan DX

Since the GAP Titan DX did not completely satisfied me completely on 40 meters band, last summer I decided that the time to test some alternatives had come.

The choice was between a typical multiband fan-dipole, or a single band dipole. Space on my roof is limited to aproximately 20 meters, that is not so much, but is even enougth to setup a decent wire antenna.

After a short period of analysis and choices among antenna design, I came to to the Bazooka antenna design, and I ended up to opt for the EAntenna Bazooka Antenna for 40 meters band.

Bazooka dipoles are done by using a mix of coax cables and single wire as main part of dipole arms, and as main characteristics they feature low noise and bandwith. Concerning antenna gain above single dipole antenna, I’ve read several articles with conflicting opinions, some report an higher values above the dipole, and some other that even state a similar or even lower values.

Based on my experience I can tell you what the real life comparison amont the GAP Titan DX, a vertical multiband antenna I own, and that is erected in the same roof.

Setting up and tuning the Bazooka Antenna

The installation is very simple, as the antenna does not require any special mounting work. I installed a vertical pole about six meters high, to which I attached a bracket I had available, and to which I attached a pulley I had bought some years ago in Fredrickshaffen and which came in very handy.

The centre of the antenna is, as I said, about six metres high, while the ends of the antenna are about two metres high. The whole thing is positioned at the edge of the roof, which is about 10 metres above the ground.

Tuning the antenna was very simple, I had to shorten the antenna by about thirty centimetres on each side to get the lowest SWR in the area I was most interested in, the CW area.

The bandwidth turned out to be very wide, allowing SWR values always below 1.5:1.

Tuning has been done by placing my Antenna Analyzer at the shack, and by monitoring the SWR behaviour almost in real-time via a tablet connected via WI-FI to my Analyzer. It took me just 15 minutes to get the optimal values.

Antenna performance Tests

Reception

Reception is the easiest and immediate test. It outperfomed the GAP Titan in silence and sensibility. Stong signals had a clear and evident improvement, signals received at S8-S9 with the Bazooka were S9+20.

But the main advantage is the lower noise, that made signal slightly compresible on the GAP Titan DX, completely readable on the the Bazooka. In the clear QRM is S9 on the GAP and S7 on the Bazooka.

Transmission

To evaluate performace in tramsission I did use the Reverse Beacon Network method. I called CQ intermittenly with both antennas, changing frequency and speed, in order to have get spotted from receivers and then I compared the received signal reports.

In the table below, you will see the receptions reports with the Winner Antenna in the last column.

In some cases, I’ve been spotted just using the Bazooka. Of course, we may consider the polarization of the receiving station, that is currently unknown to me, and the direction of the receiving staion. The Vertical being an omnidirectional, in some cases outperforms the dipole.

Using the Bazooka during CQ WW SSB

Well, the 2021 edition of the CQ WW SSB was a really a very hard to work contest o 40 meters, with lots of stations and strong signals, therefore it is difficult to evalutate the antenna performance, but I’ve been able to compare it again with the vertical, and from a reception point of view it confirmed the impression of a lowr QRM threshold and stronger signals.

Conclusions

The results were as expected, the Bazooka antenna offers an higher gain in reception and transmission, and a lower noise level that permit optimal reception. Cons, are directivity of dipole, and wire diamater size, that makes wire very visible. Concerning the product, looks weel assembled and with a good quality of materials. Center balun is completely sealed and waterproofed. 4 KW power looks generous for my habits. The price, is around 70 Euros.

Currently very satisfied.

The post EAntenna 40m Bazooka Antenna Review appeared first on IW5EDI Simone - Ham-Radio.