Somebody on the list asked how the µBITx receiver performs compared to other transceivers. Allison KB1GMX provides an extensive commentary on factors that relate to receiver performance with the µBITx as a reference point that will be of interest to constructors.
She notes that receiver performance has many dimensions:
- Overload performance and dynamic range.
- Stability, Especially important in the days of VFOs.
- Spurious signals, birdies and unexpected signals.
The µBITx is unique in a new generation of simple radios with microcomputers to provide the basis for the user interface.
From Allison’s perspective, and work she has done, the BITx40 had too much gain and required an attenuator most nights. However, this was an easy fix.
The µBITx when measured on an RX only test bed from about 3-4 years ago reflects a good receiver in the 1-10 mhz range. However, Allison prefers a bit more RF gain for 10 through 30MHz. As you go up in frequency there is more weak signal propagation and reduced manmade noises and sensitivity approaches the background galactic noise floor. At 40m a 1uV senstivity is plenty, at 28mhz .2uV is more useful.
For selectivity, Allison prefers a tight filter: 2.1 to 2.4khz is fine as SSB is about that wide on transmit (except for the ESSB people where a 3khz filter would be better). However, she prefers steeper skirts and that requires more crystals, with 5 crystals being the bare minimum and 7 approaching very good.
Why is this important? Strong signals down the skirts [edges of the filter] are audible if not suppressed adequately and if the same filter is used for TX it assures the unwanted sideband is suppressed.
Overload is a big area for BITx40 users and the same forBITx20 users. There is a lot of RF gain and HF bands are known for big signals. Attenuation or circuit changes help greatly. The uBITX runs without an RF gain control and was optimised for a decently high overload point. So fewer people complain of overload but AGC is a common wish list item.
Stability has been mostly solved by going with Si5351 and Si570 digitally controlled local oscillators in modern HF receiver designs. This requires adding an Arduino microprocessor, LCD display and a some form of encoder to tune. The other implication is there will be signals generated by the microprocessor and in communicating with external devices like the display. It does open up a whole new arena of user interface that didn’t exist in earlier analog designs. An example of this is KB1OIQ’s version of uBitx that is blind user friendly (speech synth output and keypad controls) as its really well thought out.
Adding a Raspberry Pi or similar [STMFxx series] to do signal processing is on face a good idea, but the cost is considerable in terms of software development, and the need for a more sophisticated user interface and power. Power utilisation is an important aspect of a compact portable radio. Many wish to use batteries and a Raspberry Pi eats about 3-4watts continuously. Adding a touch screen adds an additional 3-5 watts to that figure. At some point its no longer a simple radio, no longer inexpensive and has become battery unfriendly. Some problems are easily solved without resorting to a computer.
Look at what is being done for the various SDR radios. If you are going digital its smarter to start with a new architecture and build in the computer rather than hang it on like a laptop on the side.
With all that said, yes the µBITx is a decent receiver in Allison’s view. Can it be improved? Yes. However, improvements depending on the use case. Different constructors will have a different idea of what that may be.