When I first built this station I put up a few multi-band yagis: TH6, TH7, Explorer 14. When operating SO2R in contests I could not share these yagis since I don't use triplexers but I had enough antennas to get by. Over time these antennas have been displaced by mono-band yagis. The last of them, the TH6, is slated for removal later this year.
Trap yagis are inefficient but they can be very convenient for most hams since it is rare to have more than one tower, or one robust enough to support a "Christmas tree" of mono-band yagis for 20, 15 and 10 meters. Let's set that aside in this article to talk about interference between radios -- SO2R and multi-op contesting -- when using multi-band vs mono-band antennas.
Above are multi-band yagis from Optibeam, DX Engineering and Hy-Gain (clockwise from top left). Only the last has traps. However, non-loaded multi-band yagis suffer various gain and bandwidth deficits in comparison to mono-band, full-size yagis. Coupling among close spaced elements, even if each element is resonant on a single band, create many anomalies. The same is true for mono-band yagis placed too close together.
In general, multi-band antennas are often high-Q, with narrow operating bandwidth, due to traps and other devices to enable resonance on more than a single band. Simple antennas without those devices can also be multi-band by exploiting harmonic behaviour. These include full-wave loops (resonant on all harmonics), dipoles (resonant on odd harmonics), and EFHW (end fed half wave) multi-band antennas that are popular with many hams that lack towers.
Multi-element mono-band directive antennas like yagis may resonate on harmonics but they will not be yagis at those frequencies. Therefore they are potential interaction sources while not being useful at those higher bands. For example, a 40 meter yagi on 15 meters can behave as a resonant long dipole with a complex but largely non-directional pattern. It can seriously degrade the pattern of a 15 meter yagi quite far away, depending on their positioning; reciprocally, the 40 meter yagi will induce significant current from a 15 meter yagi and send it down the transmission line to the receiver.
This brings us to BPF (band pass filters). They are the almost universal choice for managing interference between radios in a contest or DXpedition operation with two or more stations. For the present I'll focus on the most common situation of one station per band and not on the more difficult one where there are in-band stations.
BPF are not a universal solution since there are things they can't do. Our primary concern is reception, where we want the BPF in the transmission and reception paths to minimize interference and performance degradation. It is important for the station designer to understand how BPF function to determine how they can be best deployed. For stations with high power amplifiers the interference can be far worse. In this case the placement of BPF between the rig and amp or between the amp and antennas can have substantially different outcomes.
Other station elements impact inter-station interference, either by enhancing the effects of BPF or rendering them ineffective. For example, poor port isolation in an N×M antenna switch. BPF are critical but are not by themselves sufficient to eliminate interference.
It must also be noted that BPF are not always necessary. I operated SO2R very successfully at QRP power levels. When the antennas don't strongly couple modern receivers typically won't overload from the 5 watt fundamental on a different band. You just need to select operating frequencies to avoid harmonics from the other transmitter. If the antennas are far apart you can even do SO2R with 100 watts, and I have done so. In both cases you must also avoid transceivers that generate unacceptably high broadband noise; there are a few notorious examples that I won't mention here.
For the rest of this discussion let's assume a station that requires BPF for acceptable performance. As noted, BPF are just one element of station design. Now consider the following case of a tri-band yagi.
In this example the receiving radio is on 10 meters while the other station transmits on 20 meters on a different antenna. Even if the transmitter BPF cuts the 2nd harmonic by 70 db it can't be entirely eliminated. It can still be an overwhelmingly strong signal on 28.024 MHz that may require the 10 meter operator to QSY. If the 20 meter amplifier has poor harmonic suppression and the BPF is between the rig and amp (low power BPF), the interference can be worse.
On the other hand, with appropriate protections it is possible to share a tri-band yagi, and to do so without destruction degradation of receiver performance. There are several manufacturers of triplexers and associated high power BPF that make this possible, but it can be very expensive. Yet it may be cheaper than another tower and yagi suitably placed and filtered.
The diagram is from VA6AM's web site where he presents numerous options for antenna sharing and what can be expected with respect to performance. I know sharing can work since I've operated at stations with this setup. One cautionary note: don't try this with trapped tri-banders and high power! The traps are unlikely to survive 2 to 5 kW of combined power from up to 3 transmitters.
Returning to the previous example, the 10 meter station's antenna contributes to the problem. The tri-band yagi is resonant on 10 meters and will take that harmonic and deliver it to the amplifier. It will pass through the amp unattenuated (on receive) and be attenuated by the BPF. It would seem that disaster has been averted, but has it? There is more to the story.
The annotated Google satellite view of my station shows the south pointing TH6 in relation to the high band stacks, the 40 meter antennas and the Skyhawk tri-band yagi. Let's say the TH6 is used by the 10 meter station in our example and the other station uses the 20 meter stack pointing to Europe (northeast).
As already shown, the 20 meter station's 10 meter harmonic is loud but is otherwise not a serious problem. It is usually sufficient for the 10 meter op to QSY 5 to 10 kHz on CW -- more separation is needed on SSB due to the wider signal (~6 kHz for a clean signal on the 2nd harmonic). Despite the actions of the two stations' BPF, during last year's CQ WW SSB our team discovered a serious interaction that I had not anticipated or previously experienced.
The 10 meter amplifier tripped and went offline. The problem wasn't the harmonic, it was the fundamental 20 meter signal that did it. The full kilowatt on 20 meters on the stack pointing at the TH6 was unattenuated by the yagi since it is resonant on 20 meters. The 10 meter station's BPF, which in my case are low power BPF between the rig and amplifier, protect the receiver but not the amplifier.
Still surprised? Here is what happened. Quite a lot of power appeared at the 10 meter station amp's antenna port. It is clearly visible on the amp's power meter which, like many modern amps, measures power whether the amp is in transmit or receive (bypass). There were several 10s of watts displayed on the amp's power meter.
In this instance the amp was an Acom 1200S. The amp's protection circuits saw this as unexpected power output during receive. It was interpretted as an amp fault, such as oscillation while in receive (standby). The protection circuit flags this when there is no corresponding RF power on the input (transceiver) port. It's a sensible precaution despite the aggravation it caused us.
Had there been a high power BPF on the antenna side of the amplifier the problem would not have occurred since it would block the 20 meter fundamental signal picked up by the tri-band yagi. Our options were to switch to a 10 meter mono-band antenna -- which passively rejects 20 meter energy -- or turn the Skyhawk tri-bander south and hope that it was far enough out of the 20 meter stack's main beam not to pose a problem for the amp. Fortunately both options worked, but it was inconvenient for the operator to deal with.
I've previously discussed why I chose low power as opposed to high power BPF for my station, so I won't repeat that here. With that as a given, my task is to minimize interactions using some combination of BPF, stubs and antennas. Stubs can greatly attenuate harmonics produced by amplifiers if that is a problem; low power BPF filter the transmitter's harmonics.
Solid state amps are more likely to generate harmonics than tube amps. Hams tend to run amps hard and that can markedly reduce linearity. Tube amps are better at harmonic suppression when that happens since the output impedance matching network (usually Π or T) also serves as a low pass filters. The output transformers typically used in a solid state amp don't have that feature.
Since my objective is to have solid state amps on both operating positions in my station -- for contesting agility and guest operator convenience -- it is worthwhile to invest in amps that have enough headroom with respect to our legal limit so that they are less likely to be operated beyond their linear range. The 1200S may have to be replaced.
There is more that I can do with antennas to reduce interaction. As already noted, even a dipole is resonant on odd multiples. That also applies to mono-band yagis that are made with dipole elements. They will pick up substantial harmonic energy from other antennas even though they are not exactly resonant on the harmonics.
One good example in my station is the 3-element 40 meter yagi. Through extensive modelling I discovered that the pattern of the 15 meter stack could be severely distorted when point at the 40 meter yagi, which is on the popular European path. I used small capacitance hats to move the 3rd harmonic well outside the 15 meter band to solve that problem. A side effect is that the 15 meter fundamental signal from the stack is greatly attenuated in the direction of the 40 meter receiver when using the big yagi.
The reversible Moxon on the same tower is naturally non-resonant on 15 meters since the topology of Moxon elements incorporates capacitance hats. It is also true to a lesser degree for the more conventional Moxon rectangle. The XM240 and similar inductively shortened 40 meter yagis are the same. The only difference in this respect is that inductive loading lowers the 3rd harmonic resonant frequency while capacitive loading raises it.
The XM240 works pretty well on 17 meters and the 3-element 40 meter yagi works well on 12 meters. Since I have no resonant antennas for 17 and 12 meters the designs of those loaded 40 meter yagis had an accidental benefit for operating on those bands.
Even the 30 meter delta loop shown at left has interesting interactions that prevent its resonance on 15 and 10 meters, which are close to the 2nd and 3rd harmonics. In the EZNEC plot above, the currents are for the delta loop excited at 28.5 MHz. There are two effects that are worth attention.
First, the location of currents can be quite complex at harmonic frequencies. In this case there is very strong coupling to the tower; it is less at 21 MHz but still quite large. For the interaction case we are more interested in the feed point impedance than the pattern. The SWR is very high on both of these higher bands. At 21 MHZ the impedance is around 210-170j Ω and 2+20j Ω at 28.5 MHz.
Part of the effect is due to tower coupling but also the 75 Ω ¼λ transformer (cut for the 30 meter band). The transformer is approximately ½λ at 21 MHz and ¾λ at 28.5 MHz. Although in the last case it is approximately a ¼λ transformer, the loop's feed point resistance can be quite different on it harmonics. This is an excellent example of how a matching network can beneficially filter unwanted energy from other antennas.
This is only bad news if your intent is to use this antenna on other bands. I am not. It's potentially good news for antennas with "interesting" matching networks. Matching networks, other than transformers, are narrow band, typically working on just one band or a portion of a band.
Antennas that are resonant on harmonic bands typically will strongly reject the fundamental signal since the feed point impedance, due to the antenna being quite short on the fundamental frequency, and the feed point matching network (gamma, beta, etc.) presents a large mismatch to the signal on a different band. For example, a 10 meter yagi with a beta match presents a high SWR to a received 20 meter signal. Checking the impedance on other bands of a few mono-band yagi models in my files confirms this.
While inconvenient, you can test what you have by making and testing a model of the antennas on other bands. Or you can climb the tower and measure the feed point impedance on those bands. A high SWR in this case is desirable because the antenna is unusable on those bands. This is exactly what you want for contesting. The time spent can be especially beneficial before an antenna is bought or built.
To conclude this long article, I'll give my thoughts with respect to my own station:
- No triplexers or high power BPF: It's expensive, but so is another tower and antenna. While not ideal, I will make do with more modest objectives for contesting using low power BPF. The TH6 is being replaced since, due to its placement, there is no good way to effectively decouple it from the 15 meter stack. Its replacement will be 20 meter mono-band yagi, and possibly 15 and 10 meter mono-band yagis on a different tower. Harmonic pickup will thus be strongly attenuated. The Skyhawk is far enough out of the stacks' lines of fire (west of the big towers) that it doesn't suffer the same ills.
- Stubs: I've been planning to experiment with coax stubs to better deal with amplifier harmonics (I use low power BPF) but haven't gotten around to it yet. That may be enough to solve the few remaining interaction issues I experience, especially on CW where you often find yourself on the other station's harmonic. These must be switched and installed at both stations' amplifiers.
- Transceivers with high blocking and mixing dynamic range: Direct sampling receivers like on my Icom 7610 are susceptible to overload that can be somewhat ameliorated with its internal filtering option. Superhet designs are still typically more resilient than direct sampling receivers. The advantage is gradually diminishing as SDR technology evolves.
- Situational awareness: Understand the potential for interference from the other station and each station's antenna choice, then avoid those situations. You might think this is easier when operating SO2R than in multi-ops since I know the station well and control all choices, but it's really easy to make mistakes in the heat of high rates and frequent band and antenna changes. There's a lot to keep track of.
- Polarity: Antennas with opposite polarity interact far less than those with the same polarity. It is for this reason that multi-ops will use verticals for their in-band stations. I haven't done this yet in my station but I may yet do so if I get more serious about hosting multi-op teams. Keep in mind that the often quoted 20 to 30 db of polarization attenuation is an exaggeration. Relative positioning, induction in various structures and squint angle can reduce attenuation to 10 db or less.
Decades ago I did many multi-op contests using kilowatt class amps without BPF or stubs and we somehow survived. The receivers didn't always survive so we kept spares on hand. Repairs weren't difficult with those simpler rigs, often no more than replacing a neon lamp: the so-called lamp fuse. Mostly we just argued about who should QSY when inter-station interference became a problem.
No matter your contesting objectives, hopefully there are a few useful ideas in this article. There is a wealth of data out there if you want to do a deep dive into the topic.
