Tag Archives: G0RVM

What are IQ signals?

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The terms IQ are increasingly commonplace in amateur radio literature.  Open any copy of Radcom or read anything about Software Defined Radio (SDR) and you will see the terms IQ.  But what are they?

Since transitioning from a cherished black-box radio last Autumn to SDR I’ve been meaning to understand the mysteries of IQ.  Fundamentally, its really very simple.  But I’ve read several descriptions on the Internet which, quite frankly, are just confusing – too many words all trying to convey something that is much easier done visually.

Tonight, I discovered the video below.  It is an excellent description of, not only, IQ but of modulation and especially BPSK, 4PSK and 16PSK.  I highly recommend taking a few minutes and watching even if you are not interested in SDR and IQ.

Andrew
G0RVM

The new FT-891

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FT-891_yaesu_dayton_ag1A little news hot off the Dayton press…  Yaesu have a new mobile HF & 6m, 100w transceiver.

Looks a little like the latest series of Icom radio’s with its black on white display.  Its also similar to the FT-857 with function buttons surrounding the its display.  The head is detachable and it claims to have a 32-bit IF DSP capability.

FT-891_yaesu_dayton_2016-ag1

With the IC-7000 now firmly retired and the IC-7100 head more suited to desktop operation than mobile, I just wonder if Yaesu have seen a gap in the market….  What will Icom do next?

But why omit V/UHF?  Seems a little odd.  Of course this could be the first of several re-designs and there may be other models yet to be released.

Perhaps it will be launched into Europe at Friedrichshafen.

Andrew
G0RVM

Strange problems….

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So, for a couple of months I’ve had a growing suspicion that I’m not receiving as well as I am transmitting.  I first noticed the problem when observing the strength of signals from GB3VHF which after one winter storm seemed much weaker than it had been.  However, there seemed to be no impact upon transmit as SWR remained negligible and stations some distance away where still receiving me well even when my transmitter was generating about 0.5W PEP!

Since first noticed I’ve worked many stations and the signal reports always seem to identify that I’m not receiving as well as the remote station.  Establishing this pattern has taken some time.  It should be said at this point that its the same antenna and feeder used for both transmit and receive.

Its been a wet Winter and not really suitable for removing weather proofing from exterior connections and outdoors work.  But now Spring has arrived things are finally starting to get dryer and warmer.  Alongside this I’ve taken down the mast and antenna for work to support an new PRO.SIS.TEL 641D rotator.  This has enabled a detailed inspection and test of feeder and antenna.

Before starting any work I thought about and identified the following possible causes:

  1. failure of the receiver, possibly signal amplifer
  2. damaged feeder, possibly a connector problem or water ingress
  3. damaged feeder at the antenna feed-point. possibly also water ingress.

Problem (a) seemed possible but without a second receiver its very hard to be sure.  But its a quality Transverter (Kuhne TR144H) and I’d be surprised if that had partially failed – remember signals are only 2 – 3 S points down on what I think they should be.

So, (b) or (c) seemed much more likely.

So with the mast down and everything removed back to a dry, warm environment I removed weather seals – no sign of water or even the slightest amount of moisture ingress.  The coax was tested with a DC Ohm meter – no shorts or higher than expected resistances; with an antenna analyser and dummy load – again this looked perfect.

InnovAntenna feed-pointSo attention shifted to the antenna feed-point, pictured before it went outside for the winter and before the connections where weather sealed. Note: Grey plastic tape overlays amalgamating tape.  Again, there was no signs of moisture ingress into the coax, but there where signs of galvanic corrosion between the aluminium driven element and the stainless steel (A2 grade) machine screws to which the feeder connected.  Actually, to be more precise between the aluminium driven element and the flat washers on each machine screw.  It was clear that the liquid rubber sealant which I’d applied had not sufficiently covered these connections and thus water had been in contact between the different metals acting as an electrolyte.

To be clear, the machine screws where not showing any significant signs of corrosion, just the washers.  So the feed-point was thoroughly cleaned and reassembled without using the washers then liberally coated in liquid rubber to seal against contact with water.

Now, at this point I don’t know if this was the problem, but it does make some sense.  Any transmit signal would be of a much higher voltage/current than a received signal so would probably cross a mildly corroded junction with marginal attenuation.  But marginal attenuation of a much weaker signal would be more noticeable.  That’s my reasoning anyway.

The acid test will be when I erect the mast and antenna again in a few weeks and see if received signals such as GB3VHF have returned to their earlier strength.  When doing this I will also use new feeder, so if signals are stronger I’m never going to be absolutely sure the problem was galvanic corrosion.  Of course the problem may still be present and it could be another cause such as the receiver!

For information, the antenna is an 8-element LFA Yagi from InnovAntennas.

Andrew
G0RVM

Rotor interface

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PST-641 / Fireco InterfaceLast year I purchased a pneumatic 11m mast that can support a head load of 35kg.  Currently I use an SPID RAU rotator from AlfaRadio mounted at the top of the mast to rotate antenna’s.  At 6kg the rotor is reasonably light but for a while I’ve felt it would be better placed at the base as this removes 6kg from the top of the mast.

This little project will need modifications to the masts support/tilt-over base, a new rotor – as the SPID won’t take the vertical load – and an interface between the rotor and mast.

PST-641 / Fireco InterfaceThe project has taken the first step.  After drafting an engineering drawing of the rotor/mast interface a local engineering company made one for me.  For reference the rotor is a Prosistel PST-641D and the mast is a Total Mast Solutions / Fireco 115mm (base tube) pneumatic mast.

I’ll post again next month when I hope to receive the new PST-641D rotor and progress the next stage in the project.

Andrew
G0RVM

Drive levels…

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Over the last few years I have not had to think too hard about ensuring I’m driving my FT-2000 at a good level.  i.e. its not being overdriven.  It has an Automatic Limit Control (ALC) meter and its been a matter of adjusting the audio amplifier gain such that the ALC triggers occasionally and only on the highest signal peaks.  If a good quality transmitted representation of the input signal is to be produced its essential that the equipment stages are not overdriven.  I guess we all rely on the ALC and its correct adjustment is second nature, however, take away the ALC function and what do you do?  How do you ensure you don’t overdrive the radio or downstream amplifiers?  This is the problem I had 🙂

I’m using the FT-2000 as an exciter for my Kuhne Electronic VHF transverter.  In this mode the ALC circuitry of the FT-2000 no longer works and the transverter does not output a drive level signal which I could connect to the FT-2000 or to a homebrew ALC meter.  But the transverter does have a red ALC LED which illuminates when the drive level becomes excessive.

The signals I’m presenting to the radio are audio and are either voice from the microphone (voice chain) or data from a SignaLink USB audio interface (data chain). Each of these chains has several amplifiers which can be adjusted by an operator:

  • Voice chain:  3 x microphone and 2 x RF amplifiers
  • Data chain: 2 x audio and 2 x RF amplifiers.

Ensuring each amplifier is set to a level such that downstream equipment is not  overdriven producing distortion and splatter is essential!

So, how did I adjust everything?  Well, the transverter documentation says to start by setting the radio to full power (0.1mW when using the transverter connector) in RTTY or CW modes and key the transmitter, then adjust the TX Power control of the transverter to output  20 Watts which should be prior to ALC LED illumination.  Having done that using a constant CW modulated signal I had the transverter generating maximum power for a maximum signal drive level from the radio.  That set the upper threshold which could not be breached by the voice or data chains without distortion or the transverters ALC activating.

Next I fed the constant CW, RF output of the radio directly into my digital oscilloscope rather than the transverter and noted the signal power.  Interestingly, the power levels seemed much higher than the figures stated in the FT-2000 Operating Manual.  But from the previous step I knew the transverter was ok with this.

CW Transmission

CW Transmission

This allowed the accurate identification of the RF power level driving the transverter and thus the baseline levels for the voice and data chains.  The next step was to generate a constant RTTY tone using the computer and adjust the amplifiers in the data chain such that the levels identified in the first step where not breached.

RTTY tone generated by DM-780

RTTY tone generated by DM-780

Once done, I performed a similar exercise on the voice chain for J3E (SSB).  By selecting a cumulative display mode it was possible to record the varying power level over several iterations of a CQ call.  As can be seen, most elements of the call resulted in an average level, but interestingly, the ‘G’ or Golf in G0RVM generated significantly more power.

J3E SSB Voice adjustment

J3E SSB Voice adjustment

The gain of the voice amplifiers in the voice chain were adjusted so that the upper threshold identified in the first step were not breached.  The last step was to adjust amplifier gain for A3E (AM).  I had expected this to be very similar to the J3E level but it needed to be slightly higher.

A3E (AM) Transmission

A3E (AM) Transmission

AM is not a mode I use very often, if at all, so I didn’t spend too much time adjusting amplifier gain but I did change the gain from the factory default to ensure that the upper threshold identified by the first step was not breached.  It could still go a little higher but it will do…

So, the result of all this testing is that I am now confident that using the voice or data chain’s I’m not going to overdrive the radio or transverter.  Downstream of the transverter is an RF power amplifier, but that is specified to generate 1kW for 25 Watts of drive, and as I don’t wish to run it at full power, overdriving should not be an issue.

I’ll just add at this point that the above approach is applicable to amplitude modulated signals only and thus not those that are frequency modulated.

Andrew
G0RVM

Back to the Future…

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Back in the 80’s I received my first amateur radio license, a ‘B’ license as it was back then entitling me to use, if I recall correctly, bands above 30 MHz only.  We didn’t have 6m and 4m band allocations then so it meant 2m and 70cms were the bands of choice for me and the majority of other ‘B’ license holders.

So I started with 2m and 70cms SSB and my interest was soon peeked by space communications with Oscar 10 etc.  Those early Oscar’s were excellent as, if I recall correctly, they where in elliptical orbits which meant that they appeared to hang in the sky for some time, not shooting overhead as do satellites in lower more circular orbits.  Their transponders were just like big SSB repeaters in the sky and I worked all over Europe.  Happy days.  But working those Oscars was not that easy especially at Acquisition of Satellite (AOS) as they were pretty far from the Earth so a good station was needed.  My station grew to a 2m, 9 element crossed Yagi; a 70cms, 19 element crossed Yagi, both circularly polarised; azimuth plus elevation rotators and mast head preamplifiers.  The radio was a Yaesu FT-736 which I only sold last year…It was a wonderful radio.

Of course with those antenna’s it was perfectly possible to work terrestrial communications too.  I made contacts across the UK and Europe using sporadic E and Tropospheric propagation.  Those were exciting times indeed as not only was amateur radio new, to me, but it was such fun learning about different types of propagation, satellite communications and having great fun talking to people.

Ok, so by now some of you will be asking – what is the point of this article?  Well, bear with me…  I learnt Morse code and in the early 90’s received my ‘A’ license.  Soon afterwards the world changed as I started doing radio professionally for a few years.  This removed all interest to do amateur radio stuff when I got home from work.  Anyhow, time passed and I started to operate on HF talking to people all over the world – it was fascinating – I learn’t lots more.

With solar cycle 24 rapidly fading and with the real possibility that cycle 25 may be no better, probably worse, I’ve been looking back and found myself comparing my V/UHF experiences with those of HF.

My conclusion is that HF is fun, its pretty easy to work stations across the UK, Europe and further afield depending on your station.  Take a minute and think about that, especially the ‘depending on your station’ bit.  Do you have the space to erect, for example, a 9 element Yagi for the 20m band?  I’m seriously impressed if you do 😉  I bet most of us are using simple HF antenna’s and we are constrained by space, interference and the cost of erecting a high-performance HF station.  But move on up to VHF and things get so much easier.  I bet many of us could erect a 9 element Yagi for the 2m band and mount it several wavelengths above ground too….  Such an antenna will cost a tiny fraction of its HF equivalent; its small, light and easily rotated too.  Interference does certainly exist above HF but its nowhere near as bad.  But, FM repeaters and modes such as D-Star aside, VHF is dead these days I hear you say?  I cannot deny that it is much quieter than in the 80’s and 90’s but its still a happening place…  Its perfectly possible to work stations using phone and data modes across the UK and into Europe when propagation is flat.  All those exotic data modes are present and in active use too, people are exploiting Tropospheric propagation, meteor scatter, satellite communications, auroral propagation to name a few.

So its back to the future for me, the HF antenna is now down and until I receive my new VHF antenna I’ve elevated one of my original 9 element Yagi’s.  Already I’m hearing beacons GB3ANG in Scotland, GB3VHF in Kent and GB3SSS in Cornwall.  I even worked an old friend towards London using CW (RST:559) and Olivia with 20 watts.  Who says VHF is line-of-sight. 🙂

I guess you realise the message by now…. V/UHF is lots of fun, you can work DX, high-performance stations are much more achievable than on HF and you learn lots.  Amateur radio is so much more than HF, FM, repeaters, D-Star etc.  So, why not explore our higher bands?

Andrew
G0RVM

Cobwebb resonating. Part 2

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Last week I wrote about recent work that identified where my G3TPW Cobwebb antenna was resonating on each of its five bands (20m, 17m, 15m, 12m and 10m).  Following on from that work G0MGM and myself spent a day recently adjusting my Cobwebb so that it was resonant around the SSB sections of each band and this article summarises that work.

The instructions supplied by G3TPW for his Cobwebb are excellent and identify the tuning effect of shortening/lengthening each dipole leg.  For reference I have identified these below:

Band Change
 20m  40kHz/cm
 17m  50kHz/cm
 15m  75kHz/cm
 12m  100kHz/cm
 10m  120kHz/cm

What the instructions omit is whether the dipoles interact, whether they should be adjusted in any sequence (e.g. 20m before 17m) and the impact of extending/reducing the gap between each dipole leg (spanned by the string) upon resonance.  These were all questions that were going through my mind prior to starting adjustment work and which drove the approach adopted.

The reactance, resistance and impedance data presented in Part 1 was collected using my MFJ-259b antenna analyser.  The MFJ-259b is a basic analyser and does not have any capability for data logging or data export necessitating the collection of data at multiple manually sampled frequencies.  This process was laborious and constrained the number of samples it was practical to collect and thus the accuracy of the overall result.  As I foresaw the need to resample each of the five bands for each single adjustment, it clearly, was not going to be practical to use the MFJ analyser.  Fortunately, a good friend, G0MGM, has a miniVNA analyser that can auto-sweep a band, log the results and export them in a CSV formatted file, which we later imported into Microsoft Excel. This capability made it practical to capture data samples, visualise and analyse the impact on each band of every change.

All graphs in this article may be enlarged by ‘clicking’ upon them.

Baseline

Because a different analyser was used, two new sets of baseline data were captured with the antenna at 3m and 8.5m above ground.  The lower height represents the  height of the antenna when my mast is retracted.  The baseline data presented in this article is that sampled at 8.5m.  Measurements were taken in the radio room at the end of the RG-213 coax feeding the antenna.

20m (Baseline)17m (Baseline)15m (Baseline)12m (Baseline)10m (Baseline)

It is interesting comparing the baseline results above with those captured previously using the MFJ analyser and presented in Part 1.  It should be noted that the comparison was performed with the antenna at the same height, with the same coaxial feeder, but on different days, that the weather was similar and that on both occasions the antenna and its surroundings were completely dry.  Furthermore it should be noted scales and colours vary thus some interpretation is required.

Adjustment

Based on experience of adjusting a Butternut HF-6V antenna, now made by DX Engineering, and a need to start somewhere, the decision was made to sequence adjustments from 20m, progressing to 10m.

After analysing baseline results it was decided to adjust the 20m, 17m and 15m elements.  Starting with the 20m element we reduced the length of each leg by 2cm and resampled data across each of the five bands.  Results showed that the change had a positive impact, raising the 20m resonant frequency by the amount expected with little or no change on any of the other bands.  This was good news and was the first indication that there was little interaction between the five elements. We then repeated the process removing a further 2cm from each leg.  Again the results were the same. i.e. the change on 20m was that expected and there had been little or no change on the others.  The graph below is the final result of the two changes.

20m band (Final)

Next the 17m dipole element was adjusted, reducing each leg by 2cm.  The process of sampling across all five bands was repeated and again it was found that the change had no significant effect upon the frequency of resonance for the other bands.  This really gave confidence that each element could be adjusted independently and that no sequence of adjustment was necessary.

Only one change was necessary and it raised the resonance point to the frequency required.

17m Band (Final)

Sticking with the original plan, although it was almost certain by now, the 15m element was adjusted reducing each leg by 1cm.  This raised the resonant frequency to that required.  This time some minor changes were noted to the point of resonance on the other bands, however, the change was very small.

The changes to 20m, 17m and 15m had necessitated the retying of the string between there individual leg elements.  The string between the unchanged elements had remained unchanged and it was now observed that there was noticeably more slack in the wire at the leg ends for those elements.  It was thought that this additional slack may be causing the very small changes observed.

15m Band (Final)

With changes complete the results from sampling each of the five bands were analysed and found to be acceptable so again the antenna was lowered and the length of string on the unchanged elements reduced so as to tighten the wires slightly.  The change in string length was small but afterwards it was noted the resonant frequency had raised a little on those band elements.  This was expected as reducing the gap between each leg end adds capacitance.

The results for 12m and 10m are shown below.

12m Band (Final)10m Band (Final)

Conclusion

Adjusting the Cobwebb proved to be much simpler than expected.  Results showed that each dipole element could be adjusted without impacting other elements and that adjustment need not take place in any particular sequence.  It was also found that frequency change per cm as specified by G3TPW in his instructions was accurate.

In writing this article it was realised that it would have been useful to capture the length between the ends of each element leg.  i.e. the string length.  When these can next be measured I will update this article with the information.  Describing the tautness of the elements is difficult.  They are neither taut nor slack, but ‘just right’.  i.e. there is a little movement of the wire.  Perhaps it is better to describe by stating that their tautness does not deform the cross shape of the fiberglass spreading arms.

Key to the success of the adjustment work was the miniVNA analyser and its ability to visualise and log sampled data.  Without it, what took approximetly 5hrs would have taken much longer.

Finally, thanks to Rob, G0MGM, for his assistance and his miniVNA and enjoy the bottle of sake 😉

Andrew
G0RVM

Cobwebb resonating. Part 1

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cobwebbI’ve had a G3TPW Cobwebb for almost a year but recently its moved location and is now on the top of a Total Mast Solutions 11m pneumatic mast.  Because previously it was in a temporary installation I didn’t think much about ensuring that resonance on its five HF bands (20m, 17m, 15m, 12m & 10m) was where I wanted it to be.  I just used a manual coupler (aka ATU) to ensure its match to the transceiver was close to 50 Ohms.

The antenna has been performing very well considering its very small size and has yielded worldwide contacts but I decided recently it was time to do some investigative work to see just where it was resonating and thus whether it could be further improved.  I have an MFJ-259b antenna analyser which lets me identify the resistive and reactive components at a given frequency.  However, and annoyingly, it doesn’t support any sort of automated band sweep or result logging capability.  Therefore its necessary to take and record multiple individual measurements then manually enter these into a graphing tool (MS-Excel in my case) to visualise the results.

To provide a reference baseline I captured the resistive and reactive components both with the antenna at 3m and 10m above ground.  As the results were similar I’ve included only those results when at the greater height and these are shown below.

Select each for a larger size.

20m 17m 15m 12m 10m

In the coming days a good friend G0MGM who has a MiniVNA analyser has agreed to help.  His analyser has two of the key capabilities my MFJ-259b lacks: Band sweep and result logging.  The intention is to adjust each dipole individually to achieve resonance just where I want it.  However, I’m not clear how the five dipole’s interact, I assume they must to some degree as they are closely spaced, or whether its best to adjust them in any sequence.  i.e. 20m before 17m.

In part 2 of this post I hope to report what we found, the adjustment methodology and importantly the results.

Andrew
G0RVM

The Hexbeam

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MW0JZE HexbeamHi Andrew (G0RVM) here…  I really enjoy working HF portable due to a home that’s in a noisy urban conurbation and the joy of being out in the country, often with seriously impressive scenery all-around.  This post is about my recent purchase, a MW0JZE constructed G3TXQ Hexbeam antenna.

Up to now I’ve been using simple wire antenna’s such as monoband dipoles and delta loops strung over or between portable fibreglass telescopic masts when operating portable.  Due to the exceptionally low noise floors found at portable sites I can hear just about anything if its there, but its difficult to get heard due to the negligible gain of simple antenna’s.  Enter the hexbeam, a 2-element Yagi for 6m, 10m, 12m, 15m, 17m and 20m giving useful forward gain (approx. 3 to 3.5dBd), a good front to back ratio and deep side nulls that should help during crowded band conditions.  For example, a few years ago I planted a multi band vertical on the beach of a Scottish island.  Yes, the antenna worked well, but it was just impossible because of very strong signals from all directions.  Having some directivity and more importantly some useful nulls should greatly help.

MW0JZE HexbeamOf course antenna beam pattern is not everything when operating portable; other significant considerations are the collapsed size, weight & portability, the erected size and finally ease of assembly/disassembly.  The hexbeam scores highly on all these characteristics.  Conscious that the Thornbury and South Gloucestershire Amateur Radio Club (TSGARC), my club, had a field weekend during May I decided to take the plunge and get a hexbeam in time for the event.  The TSGARC as a 12m trailer tower so supporting the hex would not be a problem.

The hexbeam is not a complicated antenna and quite frankly I could make one myself, however, I wanted more than a prototype antenna, I wanted something that would cope with the vagaries of the English climate and was robust.  i.e. it would stay dry in a wet English climate and would withstand multiple rounds of assembly/disassembly.  Importantly, I wanted something which when arriving at a portable location was dependable.  There are a few manufacturers of commercial hex beams and each seems to do a fixed and a portable variant.  The portable versions are lighter and designed to fold.  As my primary use was to be portable, a portable version seemed the right choice…  However, I wanted something that was also robust and which could be erected full-time if I ever got a property where that should be possible.  So I went for a fixed version!

MW0JZE HexbeamAfter some Internet research I opted for one constructed by Anthony (MW0JZE) partly because of his good website, partly because of the excellent Youtube construction video’s but also because when we spoke he was very helpful and had experience of portable operations.

His antenna arrived in a cardboard box, inside everything was wrapped, even double and triple wrapped in news paper.  Not quite what I expected and a real nuisance to unpack, but hey, you only unpack it once, the packing worked well and its eco-friendly – none of that plastic packing which is such a nightmare to dispose off 🙂  At home there is nowhere to assemble the antenna but I checked that the major components were present and just hoped the smaller bits and pieces (cable clips, nuts etc) were all present as I’d only find out for sure at the field event.

I need not have worried as everything was present, Anthony had even included some extra ‘wing-nuts’ as he knew my intention was to use it portable.  So it was a warm, sunny Saturday when I constructed the antenna in a large field with plenty of space.  From the outset I had a good feeling about the antenna as the build quality of the parts I’d seen at home was high.  The fiberglass spreader arms fitted together perfectly, the arms into the baseplate and the radius and diameter cords just dropped into place.  Anthony had obviously taken great care in its design and build.

MW0JZE HexbeamAs mentioned before, assembly was done in a field so it was a little disappointing that there were no hardcopy assembly instructions.   Fortunately I had good Internet access via a TSGARC members cellphone and thus I could watch the assembly YouTube instructions.  What would be really nice is if Anthony could supply the videos on a CD or include some instructions.  Had Internet access not been possible, I’m confident I’d have worked it out, but having the reassurance was nice.

MW0JZE HexbeamThe antenna has a sexy blue engraved baseplate with ‘G3TXQ’ and a diagram of a hexbeam.  It also has a large arrow with no associated text…   I constructed the antenna as per the video’s (which didn’t show the arrow) but in haste I assumed the arrow indicated the forward direction of the antenna and thus mounted it to the tower so that the arrow pointed North.  Wrong.  If constructed as in the video’s the arrow points towards the back of the antenna 😉  Anyway, it was terribly easy to fix.  Just a 180 degree rotation of the stub mast that fixed the rotor to the tower.  This change took about 5 mins and that included lowering and raising the tower!

I purchased the toroidal choke balun with the antenna and this fixed to the centre post with a plastic clamp.  There was a minor misalignment of its fixing holes but nothing a very slight enlargement of the fixing holes didn’t sort.  On air, the antenna performed as expected; it demonstrated reasonable f/b ratio and good nulls to the sides.  It was fed with around 400w and we received good reports from countries such as Japan, Argentina, Aruba, the USA, St. Helena Is to mention a few.  So it worked and better than a wire dipole would have done I’m sure 😉  Perhaps next time I’ll do some side-by-side tests.

MW0JZE HexbeamI pondered for some time the best way to dismantle the antenna at the end of the field event.  I didn’t want to completely dismantle the antenna but only dismantle sufficiently to allow it to be packed and transported.  It was actually a simpler problem than I had first thought.  The element wires were disconnected from the centre post; the radius and diameter cords were disconnected; the spreader arms were disconnected from the base plate, the spreader arms were disconnected from each other and placed next to each other then finally all spreader arm parts were brought together in a neat pile. Finally the mass of spreader arms and element wires were dropped into a bag.  The baseplate was left attached to the centre post.  Next time it should be just a matter of getting it out the bag and reversing the process described above…  Time will tell. 🙂

A good strong bag, something about 170cm long and 60cm in diameter with carry handles and compression straps would be an excellent addition 🙂

Thanks for the antenna Anthony, I’m really looking forward to using it again and perhaps performing a more scientific comparison with another antennas.

Andrew
G0RVM