29 October 2009

Doubling to 6m

SPRAT 140 magazine had an article by G3XBM's Sixbox 50 MHz AM transceiver. It is also documented on this blog/website. His TX is a 3rd overtone XTAL oscillator followed by a buffer and an amplifier both voltage controlled to generate AM modulation. The RX is a freerunning LC regen. The output power is about 200mW peak (modulated).


I got intrigued by his simple circuit and decided to replicate his design.


It turns out that I have one surplus XTAL that would put me on 50.8 MHz and a canned oscillator that goes to 50.35 MHz. All simulations were done using my xtalfind Perl program.

The XTAL has too short leads to be used and it is not an overtone cut, so I decided to use the 25.175 MHz canned oscillator and try to double it with the EX-OR doubler described in the previous post.


The local oscillator signal has a period of T=40ns. I need to delay it of 1/4T, so 10ns. According to the 74HC86 datasheet this amount is right in the typical propagation delay range for 5V supply.


I've assembled dead-bug the circuit and done two tests:
  1. check the output at the oscilloscope (max BW 100 MHz, so quite at the limit)
  2. use my finger to check for the base frequency
  3. see the output spectrum on a spectrum analyzer

Test #1 is visual. The resulting waveform is more sinusoidal than it actually is because I've operated the instrument at the limit of its bandwidth. But the output period is half the input, so there's no 25 MHz output.


Test #2 confirm. Using my FT-817 receiver tuned on 25.175 MHz carrier I touched the canned oscillator output and noticed a signal increase. Then I touched the 74HC86 output and heard only an increase on 50.35 MHz.


Test #3. My spectrum analyzer starts at 45 MHz, so I have no mean to check what happens at the LO frequency. But I measured 5dBm at 50 MHz (through a 7dB attenuator pad) and about -6dBm and 100 MHz.
Curiously there was a rather strong product at 75 MHz that I could null adjusting the delay line.



So in theory I have a 12dBm signal (15mW) at 50.35 MHz. I could directly modulate the 74HC86 chip to produce AM, but the propagation delay is a function of Vcc too.


Now I can either generate AM or DSB-SC. Both need a linear amplifier chain, with DSB being more energy efficient. Since I have a digital signal I could probably drive a simple balanced mixer, or an NE602. In case I use a NE602 then it can be re-used as RX mixer too (for AM or SSB, not DSB).



If the canned oscillator could be pulled I could generate NBFM too, but I think this is not the case.

28 October 2009

The EX-OR frequency doubler

After few years I've had this idea in mind, I could finally melt some solder and put together a frequency doubler using EX-OR digital gates.

The idea for my application is: feed a 2-IN XOR gate from a 74HC86 with properly phased signals and it generates a 2 * f_in (square) wave.

So, what are "properly phased signals"?

If the base frequency f_in, which is in form of a square wave, is delayed of T/4 and fed to the second input of XOR gate, then given the XOR truth table the gate will output a 2x frequency.

I leave the reader draw the two wave forms and XOR them graphically to see the effect.

How to delay the square wave then? Easy, use the intrinsic propagation delay of digital gates! Per datasheet a 74HC86 gate has a propagation delay of 11ns with a load of 50pF at 6V supply. According to another document of OnSemi the delay introduced by a gate varies linearly with the capacitive load, so I see a simple way to control delay between 50ns down to 5-6ns.

Why am I doing this? Besides for the scientific progress :-) I'm aiming at a simple TX/RX system for 50 MHz band.

26 October 2009

FT817 keypad - a completed one

I have built one of my FT-817 keypads for another person, and here's how it looks like when unassembled:


I have included connectors on the serial cable and on both LEDs. All connectors are different so the user will not mix them. The overall footprint of the completed keypad is slightly larger than the matrix keypad itself, which sits on the circuit using a matched pin-header strip.

Except for the book, what is shown is worth 20€ (@2009) of materials and circa 3 hours of work.

08 October 2009

DTT switch-over

2009-10-07: switch over from analogue over-the-air TV to digital (DTT, DVB-T) in my area.

I grabbed the TV remote control and scanned all programmed channels, from 1 to 29: white noise. I ran a complete search in case the condo antenna could pick up some remote signal once masked by stronger local stations: nothing.

RIP analogue TV.

I still have to erect my antennas on the roof. With digital TV signals it will be harder to identify even the lightest TVI, or perhaps the whole system will more immune. At least people won't hear my voice or CW through their TV set loudspeakers, just loose audio or video quality.

Maybe some analogue TV will be thrown away, becoming a good source for scrounged parts to keep aside for future experiments.