A "few" words on what should be next year's challenge.
0) The open home brew challenge goes on. This is all about making at least one QSO on as many bands as possible, with home made equipment. This could be a kit I built, a fully home constructed transmitter and/or receiver, or modified versions of equipment not designed for amateur radio.
I do intend to get some more kits built next year, and use some of those already built for HF band monitoring. A part of the propagation study may include a WSPR and/or WRSS transmitter, and/or some WSPR/QRSS monitoring, and more bands with FT8 monitoring when I am not actively operating on the bands.
Apart from the kits, I may get to some more home construction. We shall see.
1) The primary challenge for 2023 will be all about improving the solar power system and its efficiency for the amateur radio station.
In particular, all systems for monitoring the radio propagation has the highest priority. This includes both the improvement of the capacity of the solar panel and battery system and reducing the power consumption of the receiving systems.
More solar panels are needed for charging the battery. I expect to increase the peak "capacity" of the panels to somewhere between 600 and 900W. The precise configuration is yet to be decided. Currently I have a peak capacity of 250W and a non-optimal position for the panels.
An improved system of solar charge controllers. MPPT controllers are inherently more efficient, though they tend to be more noisy in the radio spectrum. I found some that seem to be relatively quiet, but the3y are not yet tested at full charge current. I suspect that they can be useful with good RF filtering at the inputs and outputs.
Improved battery capacity. The 12V system for the station should be updated to 400Ah capacity at 100% charge.
The aim is to provide pure solar power to the minimum requirements of the station all through winter.
This leads to the next part: Minimizing the power requirements of the station, especially the parts that will be required to run 24/7, or many hours per day, such as some propagation monitoring and monitoring e.g. local traffic on 2m.
2) The other challenge is concerned with microwave activity (above 1GHz) The aim is to make at least a first QSO on a few microwave bands. starting with 2.4GHz and 10GHz. Long ago I was active on 23cm, but I would very much like to get going on that band, too. If I can get away with making experiments on 3.4, 5.7 and 24GHz, that would be nice, too. Improving the QO100 system is part of this, too.
I am already active on the QO100 satellite. This means that I have transmit capability on 2.4GHz and some receive capability on 10GHz.
This system is rather primitive, and many improvements can be made to it, especially on the receive side.
a) Further, I located a 23cm (1.3GHz) module for the IC-910, as well as a more precise and stable reference oscillator (TCXO) for that transceiver. During the winter nights I need to make sufficient space on the lab desk, so I can get going with mounting those, and also make a fresh alignment of the transceiver. Straight forward when the space is available.
As the IC-910 is quite heavy I intend it for home operation only. If I want to go portable on 1.3GHz I will need a transverter and a portable transceiver. I could use one of the FT817s or the IC-705. Both need modifications, so the transverter(s) are not blown up if they get high power TX signals in.
I will still need to get some antenna up for 1.3GHz. This should happen some time in the spring. I expect to use a Diamond X-5000 (I think) for vertical omnidirectional (mostly FM) with a 23cm preamp, and a small yagi, like the front mounted Flexa antenna for horizontal polarization (mostly SSB/CW/digital modes). The horizontal antenna will need a rotating system that needs to be set up. Lots of work.
For portable work I still have a small 23cm yagi that can be used on hills etc.
b) While it is possible to use my up-converter for the QO100 system for transmitting on 2.4GHZ in general, the existing system will be very cumbersome, especially when going portable.
I could possibly use the up converter with the FT817 as the transmit system, and the AR8600 SSB capable "scanner" as receiver. Operating portable from a parked car could be done with this system, but setup will take time, and I am not sure I have the patience ;)
I think that a much better system can be made with the FT817 driving a transverter from e.g. SG-Labs, and a PA. A bit of relay and sequencing will have to be made. The transverter system should be sufficiently compact for portable use, and should be easily connected to the home system.
Antennas for 2.4GHz? I have some low cost WiFi antennas, such as 16el. yagis, and some patch antennas. Both most likely have a gain of 10-12dBd gain, and can be used for the first light weight portable experiments.
For home use I would likely use a panel antenna with about 20dB gain. Again, as with the 1.3GHz system, a rotator is needed.
c) 10GHz:
It is possible to make some simple, mostly line-of-sight experiments with a modulated HB-100 module, a satellite LNB and a scanner receiver in the 500-700MHz range. Using WBFM this could likely provide 10-20km range without using anything but the modules, no dish antennas or horn antennas. More, if "external" horn extensions or just a dish for the RX part would be used. This is mostly for portable experiments.
A small system for 10GHz narrow band, with a transverter, is also on my list. Most likely a Kuhne/DB6NT transverter, driven by the FT817 or the IC705.
Other narrow band experiments could be a NBFM/CW transmitter used with a satellite LNB down converter.
First experiments will likely be portable, but long term I should have a small station running from home.
Am I likely to get all of this done? Not really, but the minimum will be to get going from home and portable on at least one microwave band.
On the solar power and monitoring front, at least I will get some improved solar energy and *some* "reduced power" monitoring done.
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