The WSPR Transmitter is multimode.
The Ultimate3S is a versatile WSPR, CW, QRSS beacon Transmitter that can transmit messages on up to 6 bands. The basic kit is single band. A clever mod enables up to 11 bands to be used.
Along with a few other popular mods found here. http://www.qrp-labs.com/ultimate3/u3mods.html
There is also the option of the temperature compensated crystal reference for the SI3151a synth module, rather than the plain vanilla PCB, this can help to reduce frequency drift to 1 part per billion. The synth can produce up to 3 separate frequencies, on 3 separate pins, at the same time. One of these outputs is used to drive the transmitter. Another appears to be sampled by the processor. And the third is used as a ‘park’ frequency when the transmitter is NOT transmitting. I propose to program this frequency to be used as the VFO in my homebrew WSPR receiver.
My order included a single LPF for 40 Mtrs. I subsequently modified this for 30 Mtrs which appears to be a more popular WPSR band. The mod was simply a turn or 2 less on the toroids and changing 2 capacitors for the next lower value. A table of values is included in the LPF construction details. http://www.qrp-labs.com/images/lpfkit/instructions2a.pdf
Front and left is the single PA transistor, with places for 2 more. The option also exists to run the PA from 12v rather than the default 5v.
The OCXO SI5351A Synthesiser.
The electronics part of the kit is just a handful of parts. Constructing the enclosure for the temperature controlled oven looks a bit more daunting. It all needs to be square. Thankfully the only SMD part is already soldered to the board. Thanks go to QRP Labs !
The manual is 45 pages, as opposed to the transmitter kit which is only 15.
Completed the assembly, and some basic setup done for testing. Synchronising the kit clock with the PC clock was tedious. You have to do this every time you cycle the power. Fortunately it is the first item in the menu once everything is setup.
Programming other parameters is a bit long winded due to only 2 buttons and a menu system. For example, inside the MESSAGE parameter, the ENTER key is a character that you have to select with the LEFT button in order to save the message. It all works OK. Just read the manual, over and over.
The dummy load is a couple of 100 Ohm resistors in parallel, tack soldered to the output pins of the 30 Mtrs LPF. Idle current was 66mA. I adjusted the FET bias pot to increase this to 75mA. Thats 375mW standing power. At 80% class ‘E’ efficiency, I calculate the ouput power at approx 300mW. I hope thats correct, I’m no expert on class E amplifiers.
Receiving on my K2, and my Ultimate3S is being decoded. The receive antenna for the K2 was a 6″ terminal screwdriver. The drift looks good considering the temperature controlled oven is not fully installed or calibrated.
It worked. But the performance leaves a lot to be desired. I have since built 2 other versions of this and none of them were very good.
The 2 earlier NE602 / LM386 efforts were hopeleesly inadequate, including the ‘Improved’ version, even with the DDS VFO. Why do so many operators extoll the virtues of this ‘toy’ radio. Its as deaf as a post and as hissy as an Asp. No offence ………
Next step is a superhet. I will base the circuit on the Elecraft K2, itself based on circuits from the classic work, Solid State Design for the Radio Amateur, now updated as Experimental Methods in RF Design. I have both these books, so there is no shortage of research material, or inspiration !
Since I have a couple of 9MHz SSB crystal filters, the receiver will have a 9MHz i/f. The VFO will be the ubiquitous AD9850 DDS, controlled by the equally ubiquitous Arduino. Not exactly a K2 then.