The TDA7000 FM Receiver
My attention was first drawn to this IC when Elektor in December 1983
published a project called "Personal FM". Then in the late 1980's, Tandy
were selling this IC for about $8. I didn't really take much notice of
it until around that time when I was looking for simple VHF FM receiver
designs, that would function better than super regen circuits. (This
was before I discovered the Pulse
Counting receiver design). I dug out the Elektor article and was
intrigued at how this IC functioned and the lack of coils and alignment
usually associated with superhet receivers. Looking at the Philips data
with its mention of 1.5uV sensitivity also got my attention.
Taken from the 1989 Tandy catalog.
Background
What is unusual about this IC is how it operates. It is a proper FM
superhet receiver, with the usual local oscillator, mixer, IF amplifier,
limiter, and phase detector. The difference is that there's only one tuned
circuit; the local oscillator. Like the Pulse
Counting Receiver, the TDA7000 relies on a low IF so that ordinary
Op Amp circuitry can take care of the gain and bandpass characteristics.
Only 70Kc/s is used with the TDA7000. Now, you might remember that the
deviation of a broadcast FM signal is +/- 75Kc/s. A fully modulated signal
would therefore sound rather distorted. So, how can this IC work?
It's quite simple in that there is what Philips call a Frequency Locked
Loop. Basically, the local oscillator is shifted in response to detector
output so that the bandwidth of the mixer output is never more than +/-
15Kc/s. It is actually compressing the frequency range of the modulated
signal.
The muting or squelch feature is novel to say the least. Although it
performs as any other muting circuit does, the TDA7000 provides an artificial
noise generator so that the receiver still sounds alive while tuned off
station. If you don't need that feature, just remove the .022uF condenser
at pin 3. Not all Philips data sheets show it, but connecting a 10K resistor
from the supply to pin 1 will disable the squelch.
Block diagram of the TDA7000 as used for a typical FM receiver.
Audio output is around 75mv.
At this point I recommend you have a look at the Philips
application notes. They give a good background to the design and use
of this IC. For curiosity value, have a look here
for the application notes regarding Narrow Band FM. In case you were thinking
a low IF would be suitable for a NBFM receiver, you're right. Note that
the TDA7000 is not suitable for feeding into a stereo decoder.
It is interesting to speculate as to why Philips didn't make this IC
a pulse counting receiver. After all, the low IF is ideal, and pulse counting
technology had been around for a while.
The TDA7000
starts a family!
Philips didn't stop with just the TDA7000 in its 18pin DIP package.
Next came the TDA7010T
which is the surface mount version. It comes in a 16pin SMD package. What
of the other two pins? Well, the artificial noise generator has been dispensed
with and so has the connection to one of the IF filter capacitors. The
latter is a bit odd; I'm not sure if it could be dispensed with altogether
or if they managed to fit it inside the chip. The data for both chips is
the same apart from that.
Next comes the TDA7021T
which is also surface mount but is stereo compatible. Lastly comes the
surface mount TDA7088T
which is mono only but has a search type tuning and works on 3V.
The TDA7000 is one of those IC's like the 555 that is a brilliant design
with so many uses, but never really found its way into commercially made
products. Instead it seems that it's kits and other homemade gear that
have kept it going. I have never seen the TDA7010T or TDA7021T used in
anything commercially made, or even a kit. The TDA7088T however does exist
in some of those miniature keyring FM receivers that are popular of late.
R.I.P.
TDA7000
Unfortunately as I write this in early 2004, the TDA7000
is no longer being produced having being withdrawn from manufacture,
December 2003. Actually, it's a pretty long production run when you consider
it is just over 20 years old. So, if you want to play around with this
IC, keep in mind that there won't be any new stock. The last TDA7000's
I bought a few months back were made in 1994, so I'd say there are ample
stocks around for a while. Who knows; it might go the way of the ZN414
and be cloned by some other company.
However, all is not lost for the TDA7010T is electrically the same.
It does mean you have to be able to make a PCB with tracks close enough
together for surface mount. You could probably use it with existing PCB's
by running fine wire to the pins, or even mounting the TDA7010T in an 18
pin header. This IC, the TDA7021T and TDA7088T are still current Philips
production. The TDA7021T can also be used; you don't have to use it for
a stereo receiver. And the TDA7088T can be used with a normal variable
condenser if you want to.
Unfortunately it seems that Sony have dominated the market with their
SMD chips for use in miniature radios. They use the boring kind of 10.7Mc/s
IF circuit, however.
Constructing
a TDA7000 receiver
I bought my first TDA7000 IC in 1988 and tried to build up a receiver
on a piece of matrix board. Here I learnt the first thing of importance.
Layout and groundplanes are critical to using this IC. The Philips data
gives a PCB layout and this should not be altered too much. Of course my
matrix board receiver didn't work properly.
Bought from Tandy in Chatswood; like all their components, packaging
was excessive. An abbreviated reprint of the Philips AN192 application
notes was included.
Soon after, Electronics Australia did an article (June 1988) with a
TDA7000 and LM386 for the audio. So, I purchased the PCB and constructed
just the TDA7000 part. I didn't think much of the LM386 (and still don't)
so I made a two transistor class A amplifier on another PCB instead. The
other alteration was to use a BB809 varicap diode for tuning. I didn't
like the idea of EA using a trimmer capacitor.
The receiver certainly worked but the "1.5uV" sensitivity seemed questionable.
Also the way the squelch worked was a bit strange. Apart from that, the
sound was very good.
Mains operated
TDA7000 receiver
Around November 1990, I built my mains operated TDA7000 receiver. This
used the EA PC board but fed a 6AV6 and 6DX8 amplifier in a plastic box.
A 6X4 half wave rectified the mains with heaters powered off my original
DSE2155 transformer. Of course being a live chassis set, precautions were
taken. External screws were nylon, a mains rated transformer was used for
the output transformer, and 400V isolating condensers were used to connect
the aerial. A few years ago I removed the 6AV6 stage as the audio gain
was much higher than needed. I had originally acquired the 5V supply for
the TDA7000 and varicap diode from the 6DX8 pentode cathode. However,
drift was a problem and found that the 6DX8 cathode current being only
about 20mA was only just enough to power the 7805 regulator, leaving the
TDA7000 barely functional. I simply half wave rectified the 6.3V heater
supply to fix that one.
Very bland looking but functional. At left is the heater transformer,
middle is the output transformer, and at the right is the PCB with the
TDA7000. Note also the yellow ceramic aerial isolating condensers.
The Silicon
Chip November 92 TDA7000 receiver
I built this receiver during 1995 and used it on the train for a few
years. The circuit is very typical using an LM386 for the audio stage.
The LM386 is a very noisy IC and I'm certainly not fond of it.
Originally I built it in a plastic box with speaker, but wanting to
make it smaller, I built a new enclosure out of aluminium, with a lexan
cover. (January 2004). I didn't bother including the speaker as I seldom
used it. However, once I'd done this, the performance seemed very poor.
Sensitivity was really bad. Eventually I noticed that it seemed like some
sort of spurious oscillation was going on. Bridging the negative battery
terminal straight to the case brought up a huge improvement, and a permanent
cure was made by connecting the PCB groundplane to the chassis directly,
not just relying on the headphone socket. It just goes to show how finicky
things are at VHF.
I mounted 4xAA cells on the PCB where Silicon Chip intended the
speaker to be placed. The squelch switch was not used; instead the squelch
is permanently disabled. The telescopic aerial extends to 75cm which is
a quarter wavelength.
Performance
Of late, with designing a radio for my Model T Ford, I have been giving
the TDA7000 some thought so my interest in this IC has been rekindled in
the last few months. Although I have been considering the 12AT7
super regenerative receiver, the TDA7000 has better sound quality and
does not need a regeneration control.
At this point in time I have decided to use the TDA7000 for the front
end of my new car radio. For one thing, the tuning of a pulse counting
or super regenenerative receiver is too distracting while driving a car.
Adjusting regeneration and tuning controls that interact with each other
requires concentration best left to the controls of the car itself. Also,
the TDA7000 is a proper FM receiver and has better interference supression,
unlike super regen sets which are AM receivers. This is important in the
Model T environment where ignition interference is severe. Finally, the
sensitivity is better, meaning less fading of FM stations whilst driving
around.
So, I have been paying a lot of attention to this receiver to learn
of it's limitations as well as its virtues.
How does it perform? For strong local stations it works very well,
with excellent sound quality. Sensitivity is good...I would hesitate to
agree with Philips claim of 1.5uV...more inclined to agree with Elektor's
7uV. I should mention that the Elektor article did include an RF amplifier
which supposedly increased the sensitivity to .5uV.
The first notable limitation is the very wide capture range due to
the AFC circuit. It's quoted as +/- 300Kc/s. That makes it impossible to
receive weaker stations close in frequency to strong ones. For example,
at home where I have 2ONE on 96.1Mc/s about 5 km away, I cannot receive
2WL on 96.5Mc/s which is about 90 km away. Nova on 96.9Mc/s from Sydney
(50 km away) just makes it worse.
The worst feature by far is on weak signals. Instead of just being
noisy, there is an awful disortion present. The super regen and pulse counting
receivers are much easier to listen to on weak signals.
Tuning the receiver is critical, despite what Philips say in their
application notes. It is actually better to have the squelch enabled when
tuning as you will only hear a signal when the receiver is correctly tuned.
Highly Recommended
The mention of these limitations is in no way meant to be a negative
criticism. All receivers eventually are limited in some way; I'm merely
determining how the TDA7000 performs. The average listener is not going
to use a receiver the same way I do. In this regard, the TDA7000 performs
no worse than most commercially made portable FM radios. In fact it performs
a lot better than some I have tried.
My recommendation is that you gear down the tuning control with a reduction
drive, or use a pot with varicap diode. Leave the squelch enabled, or at
least have a switch if you want to disable it. And don't expect it to perform
as a Super DX receiver. As with all kinds of receiver, give it a decent
aerial!
I highly recommend this IC for where non technical users are involved
and where sound quality is important. For what it is, and the simplicity
of use, it makes an excellent FM receiver.
TDA7088T Receiver.
I found this in a $2 box at the Jaycar
stall at the Wyong amateur radio field day 2004. When I realised what it
was I had to have it. So how did I know it contained a TDA7088T? First
thing that gives away this IC is the "scan"
and "reset"
buttons. Through the tinted plastic case I could see it ran off 3V (another
TDA7088T characteristic), and just the lack of peripheral components (ceramic
filters/IF tansfromers) around the surface mount IC.
Those earphones are awful.
This tiny receiver is not much bigger
than an AA cell. It is powered off two LR44 button cells, which are expensive
and I assume wouldn't last terribly long. I'll be on the lookout for LR44's
at the markets and $2 shops now that I've got this radio! As with all these
sorts of radios, the headphone lead functions as the aerial. Supplied with
this receiver were a pair of those awful "in-the-ear" type of miniature
type earphones. Apart from the appalling sound quality, they are insensitive,
unhygenic and dirty, fragile, and do not block out external sounds. So,
I use the normal kind of headphones instead.
The enclosure is all clipped together,
and once I'd opened it, sure enough, a TDA7088T was visible.
The audio amp appears to be one
transistor; ie. single ended class A. I don't know what current it's drawing
so I can't say whether it's consuming much more battery current than a
class B amp would. In any case I would prefer AAA cells rather than the
LR44's.
Opened up, this shows two LR44 cells, the switch and headphone socket.
Note the two RF chokes to allow the headphones lead to be used as the aerial.
The TDA7088T is on the other side of the PCB.
The power switch is a minature slide
switch on the side, which has an extra position for volume. This is obviously
done to avoid a space consuming potentiometer. So, we have only two levels
of volume; full and something a bit less.
How well does it work? Quite well
actually. Performance is the same as the TDA7000 IC in terms of sensitivity
and sound quality. However, the TDA7088 has the mute permanently enabled
so some weaker stations that could otherwise be received with a TDA7000
or TDA7010T cannot be received on the TDA7088T. Also, the headphone lead
aerial is not as efficient as a 75cm telescopic aerial so this needs to
be taken into account.
Close up of the TDA7088T. The scan and reset switches are to the
left.
The scanning circuit works very well,
there is virtually no waiting for the radio to find the next occupied frequency.
Once you have reached the 108Mc/s limit, you have to press "reset" to get
back to the 88Mc/s end of the band. It does not automatically do this like
a PLL type of circuit would.
These TDA7088 receivers seem to
be common at the moment for under $10. They're well worth collecting, but
use a decent pair of headphones!
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