2020-11-21

QO-100: Bigger Uplink Dish, and Experiments.

I have been updating the QO-100 set-up again.

I picked up a 110cm dish at a nearby radio ham who had used it for QO-100 before upgrading, so he could transmit DATV over the wide band transponder.

This, with the 4-patch feed antenna, makes my SSB signal quite readable. There was, however, a problem with the audio frequency spectrum of the SSB signal, low frequencies were too high, and the higher frequencies too low. An external microphone with a tone control helps, but I suspect that some other solution needs to be found, either a full realignment of the transceiver (which may be needed for the frequency accuracy, anyway

The frequency stability of the up-converter appears to be quite good, though the precision lacks a bit. less than 1kHz offset is not too bad for a non tuneable TCXO. An external reference will remedy this.

I found, however, that making the modification for an external reference requires very good SMD soldering techniques, so I might go to someone with capabilities for this, as I do not think I have a sufficiently fine tip, and the fine motor skills to do it myself. The mod requires moving a "0-Ohm" resistor.

On the receive side I have used a very simple solution for an external 25MHz reference for the LNB. It is placed indoors in a foam insulated enclosure, but the temperature drift is more than I like, about 1kHz per degree Celsius around 25kHz. I can slow the drift with the foam insulation, but the drift is there none the less.

I am actually impressed because the oscillator is a simple 5V DIL-oscillator in a small metal casing, no TCXO or other stabilization (except for the crystal, of course). This has provided very good performance otherwise. The oscillator results in an offset somewhere around 5 - 15kHz, too much for easy re-setting of the receiver frequency after being absent from the receiver.

I have used the same oscillator for controlling a simple LNB (without dish or a further horn antenna) for some beacon monitoring.

The last few days I have tested a low cost Chinese 25MHz TCXO - claimed 0.1ppm stability. The stability was excellent, but the resulted was poor sensitivity (in spite of a sufficient output to the LNB(s)). Further, I observed some spurious responses 200 and 400kHz offset from the wanted frequency. A check with a spectrum analyzer showed, as expected, clear sidebands 200 and 400kHz to each side of the nominal signal, both about 60-70dB down. No wonder I had spurious signals, when that modulation is multiplied by almost 400. 

Further, I suspect that the sideband noise of the oscillator (which I cannot measure) is too high, so the LO signal on 9750MHz is spread out, reducing the signal-to-noise ratio. So right now I am back to using the simple DIL oscillator.

With the simple DIL oscillator, what can be done to stabilize that further? I can think of 2 things:

1) Making a simple "oven" to stabilize the temperature, then adjust the supply voltage to generate the correct frequency.

2) Build a TCXO with a 25MHz Xtal

3) Build or find a VCXO for 25MHz and incorporate a PLL circuit to lock it to a 10MHz reference (OCXO, Rubidium standard, or GPSDO

4) Use a GPSDO set to 25MHz

5) Take a 10MHz reference signal, square it, divide-by-2 (5MHz) and extract the 5th harmonic with a bandpass filter and/or lowpass filter.

Because I need a 10MHz reference frequency (for the uplink converter and other microwave stuff) anyway, I should probably try (3) or (5) first, as it is the simplest. If that works to my satisfaction I am all set with respect to frequency stability, and I can thing of other refinements and other projects on frequencies high and low.

2020-11-04

Getting QRV on 472kHz?

 I looked up how to get on 472 kHz with a minimum of effort.

Looking at 472khz.org I saw them claim that the IC-7300 and the IC-7100 could be used if they had been modified for TX in the full range. I tested my two TRXs with a dummy load, and this is what I found:

The 7300, however, shows an extremely high SWR when connected to a dummy load (filter in-line? - maybe the cable). I would not use that one.

The 7100 seems to run fine up to 50W, showing SWR of close to 1:1. In order to protect the PA ferrite cores. However, I would probably run lower power (e.g. 10W or less) and add an amplifier if I want to run higher power.

Also, I looked at the option for simple CW TXs for the 2 bands:

136kHz: A (ceramic resonator) VXO using a 5500kHz ceramic resonator should be able to cover the full 136kHz band using a divide by 40. 74AC74 and 4017 should provide a clean square-wave.

472kHz:

- a XO of 14296, 14300 or 14318kHz with a division by 30x (/3 then /10) can provide an in-band signal. 2x 4017 should work nicely and provide a clean square-wave.

 - a VXO on 7160 (with a crystal or a ceramic resonator) should provide a few kHz coverage in the band, with a division by 15 (/5 then /3) A good (LP) filter will be needed to generate a clean signal.

- maybe a VXO with a 480kHz ceramic resonator, generating a signal directly on the frequency. I should probably beware of feedback, maybe causing some chirp. 

It will probably take a while to get a decent station up and running, but I think I should be able to make a very local QSO (a few km or so). Even if the radio can generate a TX signal, there is still the question of making a decent antenna. For a first experiment a long piece of wire and a match box might be sufficient, we shall see.