Circuit of the receiver. Note the designations on the UJT are incorrect. They should be E, B1 and B2.
The following is a design for a separately quench super regen receiver
I first tried in early 1992. It worked far better than any other solid
state design, so I built a portable version for use during my commuting
from the Blue Mountains to Sydney on the train. Running off 10x AA nicads,
this gave me a weeks listening before recharging. Only recently,
I submitted the basic circuit to Silicon Chip, whereupon it was published
in the April 2003 issue (and I won a nice true RMS meter as a result).
My portable version differs in that I use varicap tuning, the output transformer
has a 1K primary, and the output transistor is a BC108, with bias components
to suit. It also uses the headphone lead for the aerial.
Circuit of the receiver. Note the designations on the UJT
are incorrect. They should be E, B1 and B2.
Circuit description
This is the article as submitted to Silicon Chip and edited by them:
This little super-regenerative receiver is essentially
an AM receiver, with "slope detection" used for FM. By tuning to one side
of the carrier, the receiver's tuned circuit converts FM to AM. The bandwidth
is about 200KHz so wideband FM stations can be demodulated by tuning the
receiver to the most linear point of the response curve, rather than the
top of the curve as one would for AM. In practice, this simply means tuning
for clearest sound.
The heart of the receiver is Q2 which is a Hartley oscillator,
with its tuned circuit in the base circuit. It determines the frequency
of oscillation and hence the receiving frequency.
RF amplifier Q1 is a self biased untuned common emitter amplifier,
included to prevent aerial loading from affecting the detector's oscillation
frequency and amplitude. It also reduces any RF radiated from the aerial.
RF is coupled into the oscillator coil by C2. The aerial can be a piece
of wire cut to 75cm. A 75cm telescopic rod aerial is better but a proper
outdoor FM aerial is preferred for non portable use.
Most simple super-regenerative detectors are self-quenched,
however this makes it difficult to obtain the optimum quench waveform.
Particularly for wideband FM, the quench waveform has considerable effect
on sound quality.
In this receiver, the quenching of the detector is achieved
by Q6, a unijunction transistor (UJT) relaxation oscillator. The emitter
of the UJT provides an approximate sawtooth waveform, which as it also
provides the bias supply for Q2 takes the detector in and out of oscillation
at about 50KHz.
It is necessary to be able to set the optimum quenching voltage
and this is done by adjusting Q6's supply by pot VR2. This effectively
functions as the regeneration control.
Present at the collector of Q2 is the demodulated AM or FM signal
as well as the supersonic quench. This is of sufficient amplitude to overload
the following audio stages, so C6, R7,C7 and C9 provide simple low-pass
filtering.
Transistors Q4 and Q5 form a class A amplifier which can provide
about 80mW output. Bias stabilisation is automatic using current feedback.
If the current in Q5 rises then Q4 turns on harder, reducing the bias for
Q5. Negative feedback is obtained from the secondary of the speaker transformer
and fed into Q4 via R18. The windings of the transformer must be phased
correctly, otherwise the amplifier will oscillate. The transformer is a
standard DSE/Jaycar 500 ohm to 8 ohm output type.
The prototype receiver uses the local oscillator section of
a plastic AM radio tuning capacitor, in the same way as Silicon Chip did
with the TDA7000 receiver (November 1992 issue). (The aerial section tunes
a ZN414 AM receiver in the same enclosure, sharing the same audio amp).
The air-cored coil (L1) consists of four turns of 18 gauge B&S
tinned copper wire on a former with 3/8" ID and tapped at one turn. With
this coil, frequency coverage is
about 60-150MHz depending on tuning capacitance.
As with all VHF circuitry, some care needs to be taken with
construction. My portable version was built on a small piece of Veroboard.
When using this, or any other super-regenerative receiver, it may often
be found that an audible tone is heard in the background when listening
to a station transmitting stereo or SCA programs. This is a result of subcarriers
beating with the quench frequency. Adjustment of the quench frequency will
usually minimise the problem.
In this receiver, if adjusting VR2 doesn't get rid of it, then
it's worth experimenting with C11. It's important to note that raising
the quench frequency too high will reduce receiver sensitivity. Decreasing
the quench frequency will improve sensitivity but the subcarrier beat will
be more evident.
Further decreasing it will make the quench audible at all times.
For non FM stereo/SCA applications, C11 can be increased until just before
the quench becomes audible.
Optimum sensitivity occurs with VR2 adjusted to the point where
the receiver has just gone into oscillation.
At this point, a "rushing" noise becomes evident and stations can be
tuned in. With very weak signals, it will become obvious that the settings
of VR2 and C4 interact slightly. I tested this receiver with an HP8654
signal generator and could receive a 3uV signal, albeit with some noise.
Note the three pots. This portable version uses varicap tuning.
The prototype, February 1992. The small PCB on the left is an MK484
receiver for Medium Waves, while the PCB on the right is a two germanium
transistor audio amp.
Taken from my original notes, this is how to use varicap tuning
and the headphone lead as an aerial.
Fellow enthusiast, Andy
Mitz, decided to have a go at building this receiver with a few minor
changes.
The front end was kept as is, but an audio amp IC replaced my two transistor
circuit, and an 18V supply was used. This is what Andy had to say: I
have attached some photos of a regen build using much of your design. This
version uses a Motorola varicap diode and a Philips audio amp chip. The
unit is sensitive (does not need the whip antenna), selective, and has
enough audio to overdrive the speaker.
Inside and outside views of Andy's receiver. The 18V supply would provide
better
stability for the varicap tuner's zener diode stabiliser as well as
providing high audio output.
Here's
the circuit in .pdf.
email me: cablehack at yahoo dot com