Altronics K 5171 Manual - Halaman 3

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K 5171
ar as polypropylene or polystyrene dielectrics,
none of those capacitors are critical enough to
cause a measurable increase in distortion, as
demonstrated by our performance graphs.
But there are some capacitors with values be-
low 1nF where the dielectric is important and
this presents us with some difficulty, since
MKT capacitors with values below 1nF are not
particularly easy to get. However, we've found
them (see parts list) and that is what we have
used in our prototype, with good result.
If you can get MKP (polypropylene) capacitors
instead, those will certainly work well and we
would encourage that. But we have also men-
tioned the possibility of using NP0 ceramics.
We have tested these in the past and found
that they are just as good as the best plastic
dielectrics in situations where linearity is
critical. But be careful because many ceramic
capacitors are not NP0 (also known as C0G)
types, especially values above 100pF. Fig.5
shows a distortion plot for a simple low-pass
filter comparing two capacitors of the same
value, one polypropylene and one ceramic
(not NP0/C0G). As you can see, the ceramic
capacitor produces a lot more distortion. So
make sure you use one of the types specified.
Regarding resistance, you may find it a bit
strange that we have specified a 5kΩ volume
control potentiometer as values in the range
of 10kΩ-100kΩ are more commonly used.
But we have chosen 5kΩ because the ther-
mal noise contribution of the volume control
pot can be a major limiting factor in the
performance of a low-distortion preamplifier
and suitable motorised pots are available.
Op amps IC1a & IC2a buffer the signal from
the source so that it does not have to drive
the 5kΩ impedance; the op amps are more
than capable of driving such a load without
increased distortion.
If you can't get the 5kΩ motorised pot (availa-
ble from Altronics; see parts list), you can use
a 20kΩ pot instead; also a pretty standard
value.
In that case, we have made provision for two
4.7kΩ shunt resistors to lower the impedance
seen by the following stage, giving you most of
the performance benefits of a 5kΩ pot. These
have minimal effect on the pot curve, so it still
works well as a volume control.
Fig.6 shows the difference in distortion with
and without these shunts (the signal level is
lower here than in the other figures, hence the
higher base level). The performance with the
proper 5kΩ pot is slightly better again.
Remote control
Pressing the Volume Up or Volume Down
buttons on the infrared remote causes the mo-
torised pot to rotate clockwise or anticlockwise.
It takes about nine seconds for the pot to travel
from one end to the other using these controls.
For finer adjustment, the Channel Up and
3
ULTRA LOW DISTORTION PREAMPLIFIER WITH TONE CONTROLS
Channel Down buttons on the remote can be
used instead. These cause the pot shaft to ro-
tate about one degree each time one of these
buttons is briefly pressed. Holding one of
these buttons down rotates the pot from one
end to the other in about 28 seconds.If any
of these buttons is held down when the pot
reaches an end stop, a clutch in the motor's
gearbox begins to slip so that no damage is
done to the motor.
The code also provides a convenient auto-
matic muting feature. Press the Mute button
on the remote and the volume control pot
automatically rotates to its minimum position
and the motor stops. Hit the button again and
it returns to its original position. If you don't
want the pot to return all the way to its original
setting, you can simply increase the volume to
your desired new level instead.
So how does the unit remember its original
setting during muting? The answer is that the
microcontroller monitors the time it takes for
the pot to reach its minimum setting and the
minimum pot setting is detected when the
load on the motor increases at the potentiom-
eter end stop, as the clutch begins to slip.
When the Mute button is pressed again, pow-
er is applied to the motor drive for the same
amount of time, rotating it back to the original
position.
The orange "Ack" LED flashes whenever an
infrared signal is being received from the
remote, while the yellow Mute LED flashes
while the muting operation is in progress and
then remains on when the pot reaches its
minimum setting.
Circuit description
Fig.7 shows the main preamplifier circuit but
only the left channel components are shown,
for clarity. The right channel is identical and
the matching part designators are provided,
in brackets. The following description refers to
the left-channel part names.
The audio signal from the Input Switching
board is AC-coupled to the input of the first
op amp (IC1a) via a 22µF non-polarised (NP)
electrolytic capacitor and 100Ω resistor. A
22kΩ resistor to ground provides input DC
biasing and sets the input impedance to
around 22kΩ. The 100Ω resistor, ferrite bead
and 470pF capacitor form a low-pass filter to
attenuate radio frequency (RF) signals ahead
of the op amp input.
IC1a operates as a voltage amplifier with a
gain of two, due to the two 2.2kΩ feedback
resistors. The 470pF capacitor combines with
the feedback resistors to roll off the top-end
frequency response, with a -3dB point at
about 150kHz. This gives a flat response
over the audio spectrum while eliminating the
possibility of high-frequency instability or RF
demodulation. IC1a's pin 1 output is fed to
the top of volume control potentiometer VR1a
(5kΩ log) via a 22µF non-polarised capacitor.
The signal on its wiper is then AC-coupled
to the pin 5 non-inverting input of IC1b via a
4.7µF non-polarised capacitor. This coupling
arrangement prevents direct current from
flowing through any part of the volume control
potentiometer, VR1. Even a small direct
current can cause noise when the volume is
adjusted.
As mentioned earlier, the circuit was designed
for a 5kΩ motorised volume control pot as
this results in good noise performance but in
case you can't get one, you can use a more
common 20kΩ potentiometer and fit resistors
R1 and R2, so that the circuitry has a similar
impedance, resulting in the same overall
frequency response.
lC1b operates as a unity-gain buffer and
provides a low-impedance output regardless
of the volume control setting. Its pin 7 output
is fed to the tone control section and also to
switch S4a. When S4a is set to the 'tone out'
position, the output from IC1b is coupled via
the 22µF capacitor to output socket CON3,
via a 100Ω resistor. Therefore, the tone con-
trols are effectively out of circuit. The 100Ω
resistor isolates the op amp output from any
capacitive loads that might be connected, to
ensure stability. This resistor and ferrite bead
in series with the output also attenuate any
RF noise which may have been picked up by
the board.
Tone controls
When S4a is in the 'tone in' position, output
CON3 is instead driven from the tone control
circuitry, so potentiometers VR2a and VR3a
adjust the amount of bass and treble in the
signal. Op amp IC3a forms the active tone
control in conjunction with VR2a and VR3a
and associated resistors and capacitors. The
bass and treble tone circuitry is a traditional
Baxandall-style design. This is an inverting
circuit, so it must be inverted again by unity
gain buffer IC3b to restore the original signal
phase.
When the wipers of potentiometers VR2a and
VR3a are centred, the impedance between
output pin 1 of IC3a and each wiper is equal
to the impedance between the wiper and out-
put pin 7 of IC1b. So in this condition, IC3a
operates as a unity gain inverting amplifier
for all audio frequencies. Therefore, in this
case, the tone controls have little effect on the
signal – they just add a little noise.
Bass adjustment
The bass control (VR2a) provides cut (an-
ti-clockwise) or boost (clockwise) to low fre-
quencies. The impedance of each of the two
100nF capacitors for high-frequency signals