That may not sound like a profound statement yet, for me, it is. As far as my DXing goes it simply means I don't go there. Until I am in a position to raise effective DX antennas for those bands I stick to 40 meters and higher bands. The dilemma comes from contest operating. If I don't operate on those bands I miss out on some easily-acquired multipliers, whether it be CQ/ITU zones, countries (VE & W), ARRL sections, or states/provinces.
For my proximate need there is no need for a great antenna on those bands. It is minimally sufficient to work only a few stations to give the contest score a big boost. For example, in my report on the CQ WW CW contest in 2013 I mentioned that I used a tuner to put enough of a (poor) signal on 80 meters to work a couple of stations and add 4 multipliers (VE, W, zones 4 and 5). Yes, that really does make a difference to one's contest score and is well worth several minutes of effort to re-cable and fiddle with the tuner.
As it turns out it isn't as easy as it sounds. Certainly I have a tuner, several in fact, including one that is big enough to have only modest losses at high SWR. It has no trouble at all getting a 1.0 SWR match on 80 meters for my currently largest antennas: multi-band inverted vee (30 through 10) and delta loop (40). However the results were not at all equivalent, or even what I expected.
Neither antenna is even close to resonance on 80 meters. The SWR is high, very high. It is so high that EZNEC gives up on the calculation, only indicating that it is above 100. That is the feed point SWR, not what you see in the shack. At such high mismatches there is considerable loss due to transmission line attenuation. It may seem odd but this can be viewed as an advantage since the resulting high (not extremely high) SWR means that the tuner can achieve a match without risk of excessive loss in the tuner.
To give you some idea of how high the SWR is on 80 meters with those two antennas I used EZNEC to quantify the antenna feed point impedance at 3.525 MHz.
- Delta loop: Z = 0.5 - j80 Ω. For 50 Ω transmission line this gives an SWR of ~6700!
- Multi-band inverted vee: Z = 3 - j1000 Ω, for an SWR of ~350.
The drawing of the setup gives us an idea of where to look for trouble spots.
- Tuner loss: Regardless of whether the feed point SWR is 350 or 6700 the SWR at the shack end of the coax will be much the same, since the dominant factor is transmission line loss. Since the actual value is not extreme (measured to be, very roughly, 10 or somewhat less) and is similar for both antennas I will ignore this factor in the analysis. If you like, assume a loss of -2 db, which is typical of a mid-sized tuner matching a high SWR at 3.5 MHz.
- Transmission line loss: There are two components to the loss. The first is the matched loss, when the SWR is 1 (load impedance is 50 Ω). The second is mismatch loss due to the signal reflecting back and forth between source and load, where attenuation is suffered on each reflection.
- Antenna I²R loss: The radiation resistance of an antenna rapidly declines below its resonant frequency. Since the conductor resistance is in series with the radiation resistance, as the latter gets very low more of the source power is dissipated in the conductor.
- Ground loss: As you go lower in frequency the antenna is closer to ground when measured in wavelengths. Near-field losses increase due to interaction with (typically) lossy ground.
- Pattern loss: The radiation pattern can tilt upward due to the lower height in wavelengths, especially for horizontally-polarized antennas. With more power radiating at higher angles there is less going toward low angles. If your objective is DX this factor can be viewed as "loss" even if the antenna is perfectly efficient.
In the above patterns I have normalized the gain to 25° elevation. It should be no surprise that the horizontally-polarized inverted vee directs most of its radiation straight up since it is very low to the ground on 80 meters. The pattern suffers less when using the 40 meters delta loop, remaining primarily low angle and vertically-polarized. Both antennas are close to omnidirectional on 80 meters since they are quite small in terms of wavelength.
Even with its excessive high-angle radiation the low-angle radiation (25°) is 1 db better on the inverted vee. The reason for this is due to ground loss: the modelled loss over medium ground is -1.5 db for the inverted vee versus -6 db for the delta loop.
The antenna I²R loss is low in both cases despite the very low radiation resistance. It is no more than about -0.2 db with 12 AWG insulated wire. I expected worse, so that is one positive outcome.
Now we must deal with transmission line loss. This can be difficult to model since many of the more common equations in use become increasingly inaccurate at very high SWR, and the SWR of these antennas is very high indeed.
Unfortunately the VK1OD transmission line loss calculator I've used in the past has been taken down by the author. There are other calculators on the internet but may suffer from the inaccuracy cited above. Nevertheless that is what I went ahead and did with a couple of online calculators. The true loss could be higher than the figures I am going to report.
- Multi-band inverted vee: -11 db
- 40 meters delta loop: -23 db
Gaze at those loss figures for a moment and think what they mean. If you transmit 1,000 watts on 3.525 MHz on the delta loop more than 990 watts is dissipated in the transmission line. In a way that's a good thing since at these levels of mismatch the high voltage points along the coax could otherwise punch through the dielectric and destroy the cable.
Summing all the losses, at 25° elevation the gain at 3.525 MHz on the inverted vee is -11 dbi and on the delta loop is -24 dbi, minus any tuner loss you wish to include. Most of the loss components are already included in the EZNEC model. I did not use EZNEC to model the transmission line loss. These loss calculations explain why, while both antennas performed poorly on 80 meters with a tuner, I could make a few marginal contest contacts with the inverted vee but not at all with the delta loop.
Using a shack-based antenna tuner can produce far worse results than you might imagine since the SWR can be extraordinarily high. Do not be deceived by the facility with which a non-resonant antenna can be matched in this way. Tuner and other losses pale in comparison to transmission line losses for all but the shortest runs.
In retrospect this is why I was able to do so well with my eaves trough antenna, including making contacts on 80 and 160: there was no transmission line between the tuner and antenna. Although I cannot easily do an A/B comparison, I believe that the eaves trough antenna performed better on 80 meters than either the delta loop or inverted vee. This is despite its low height (6 meters), bends, corners and attachment to a conductor- and dielectric-ridden house.
The options to deal with this problem should be clear. I will list them anyway.
- Put up a resonant antenna (duh!). Even if you have to use loading coils or a matching network at the feed point it will almost always do better than a non-resonant antenna with a long run of coax and matched in the shack with a tuner. A large, efficient tuner makes almost no difference.
- Only use a shack-based tuner for small excursions from resonance for coax-fed antennas. Don't rely on the SWR you measure from the shack since transmission line losses reduce the maximum SWR you'll measure in the shack, telling you nothing about the severity of mismatch at the antenna feed point.
- You can use open-wire line to tame the transmission line losses, but is a lot of trouble to do right. Plastic-encased ladder line is not low loss; you must use true open-wire line, and you'll probably have to make it yourself. Open-wire line is fraught with difficulties, including getting through walls, preserving the differential phase between wires, corrosion, precipitation and coupling to metal obstructions.
Another possibility (one that many have tried, including myself) is to unscrew the coax connector so that only the center conductor of the coax is connected. Then ground the tuner (or transmitter) side of the outer conductor. While there is the risk of RFI, hot grounds and higher ground losses, the antenna can become much more efficient when matched by a tuner. The transmission line becomes part of the antenna. When it does work it usually only works on 160, and not so much on 80.
Non-resonant antennas in typical use are poor performers, as measured by system efficiency and pattern. Unless designed for a specific purpose, a non-resonant antenna that is opportunistically tuned to make QSOs may suit in a pinch but is otherwise a bad idea. It will net a few multipliers in select contests, but nothing more.
If you want an effective signal for DX, contests or other interests, design and build an antenna that will achieve your goal. Opportunistic use of a tuner is rarely effective. You may be better off locking up or selling your tuner so that you never succumb to temptation.